Active Solar Collectors and Their Applications

The threshold for sellback is

For photovoltaic systems Fri0 is interpreted as electric conversion efficiency r)c and hence

System Models

309

can be sold per year at a price of $6500. The total electricity production is

1 1 .4 MONTHLY UTILIZABILITY METHOD For some solar energy systems a simple annual analysis is not appropriate. More detailed calculations are necessary for systems that operate only part of the year (e.g., space heating), for systems that discard excess energy during part of the year, and for equipment whose efficiency varies with time of year. The month is a convenient interval, fine enough to discern seasonal trends yet large enough to permit analysis by hand calculator. In this section we present the monthly utilizability method. The utilizability concept evolved in the classic work of Hottel and Whillier [1958] and of Liu and Jordan [1963]. It has recently been simplified and generalized to include both flat plates and concentrators [Collares-Pereira and Rabl, 1979a, 1979b]. An equivalent formulation, but for flat plates only, has been developed by Klein [1978]. The monthly utilizability method serves as basis for many calculations, in particular the 0, /chart of Klein and Beckman [1979] for the analysis of certain systems with storage. The calculation proceeds in two steps. First one calculates the monthly average daily total solar radiation H on the aperture. This is sufficient for systems whose efficiency is independent of insolation level, e.g., photovoltaic systems. For systems with a threshold (e.g., thermal systems), one needs a second step, the calculation of the utilizability. The daily total solar radiation Tl on the collector aperture is obtained by evaluating the formula

where Hh is the daily total hemispherical irradiation on the horizontal surrace, TJjTf^ is the monthly ratio of diffuse over hemispherical irradiation given by Eq. (3.6.1) and Fig. 3.6.1, and Rh and Rd are the functions listed in Tables 11.4.1-11.4.5. [The reader will recognize /?d and Rh as time integrals of rd and rh, Eqs. (3.6.4) and (3.6.5), multiplied by cos 0].9 The quantities a, b, and d in these tables are given by

9 The formulas for tracking collectors assume that the concentration is high enough to make the contribution of diffuse radiation negligible. More complete formulas that include diffuse radiation on tracking collectors can be found in Collares-Pereira and Rabl [1979].

310 TABLE 11.4.1

Active Solar Collectors and Their Applications Function Rh and Ra for Flat Plate Collector. pgrOLnd = Reflectance of Ground"

"From Collares-Pereira and Rabl [1979].

Rh and Rd depend on several hour angles, in particular, the sunset hour angle (or sunset hour ts):

given by

TABLE 11.4.2 Functions Rd and Rh for Concentrators with Fixed Aperture; e.g., Compound Parabolic Concentrator (CPC). C - Concentration"

"From Collares-Pereira and Rabl [1979],

System Models

311

TABLE 11.4.3 Function Rh and Rd for a Collector That Tracks About East-West Axis"

Simpson's rule with one step will be adequate in most cases (error < 3%; for greater accuracy two steps can be used):

"From Collares-Pereira and Rabl [1979].

In the equations for flat plate and CPC there is also the angle u's given by

One further variable remains to be explained, the collector cutoff time tc, or equivalently, the cutoff angle

If the collector is placed due south (i.e., with zero azimuth) and if its time constant is short, it will operate symmetrically around solar noon, being turned on at 4 h before noon and turned off at tc h after noon. Obviously the largest possible value of tc is the sunset time 4. In some cases tc is further

TABLE 11.4.4 Functions Rh and Rd for Collector That Tracks About North-South Axis"

The integrals can be evaluated by Simpson's rule. "From Collares-Pereira and Rabl [1979],

312

Active Solar Collectors and Their Applications

TABLE 11.4.5 Functions Rh and Rd for Collector with Two-Axis Tracking"

a

From Collares-Pereira and Rabl [1979].

limited by optical constraints, for example, shading. For CPCs the cutoff hour angle wc depends on the acceptance angle and is given by Eqs. (2.5.9) or (2.5.11). For collectors with heat loss, one proceeds to the second step of calculating the utilizability 0. The function <$> is denned in such a way that the energy Q delivered by a collector array is

K is the all-day average of the incidence angle modifier K(d) and can be approximated by

The utilizability is a function of the monthly average clearness index ~KT, the ratio

and the critical intensity ratio

Xc is the ratio of average daily heat loss and average daily absorbed solar radiation. For nontracking collectors is given by (for 0 < Xc < 1.2)

313

System Models

For tracking collectors the R dependence can be neglected and the fit

can be used for all values of KT-£ 0.75 and for 0 < Xc < 1.2. For exceptionally clear climates, i.e., with KT > 0.75, the simple expression

should be used for all collector types. These curves are shown in Figs. 11.4.1-11.4.6. The fits were derived with emphasis on accuracy at reasonably large values of because collectors with low utilizability will not collect enough energy to be economical. The above expressions for are only reliable when (j> is larger than approximately 0.4 and when Xc < 1.2. Outside of this range these expressions for are not recommended. In fact, since the above fits may increase with Xc at large Xa they must not be used outside10 the range 0 < Xc< 1.2. The cutoff time tc for thermal collectors can be determined by the following simple iteration procedure, which is justified in Collares-Pereira and Rabl[1979a]. '°For flat plates larger critical intensity ratios can be explored with the correlations of [Klein, 1978]. The reader should be careful not to mix the notation used_by different authors. In particular 0 and H have different definitions; however, the product 0/fT of Klein is equal to our 4>H. Klein's definition of Xc is different.

Figure 11.4.1 Utilizability versus the critical ratio Xc for KI = 0.7 and nine values of R from 0-0.8 (From Collares-Pereira and Rabl [1979]).

314

Active Solar Collectors and Their Applications

Figure 11.4.2 Utilizability <j> versus the critical ratio X,. for K-I- = 0.6 and nine values of R from 0-0.8 (From Collares-Pereira and Rabl [1979]).

(i) Start with tc — tc] = maximum permitted by optics, as discussed at the end of the previous section; for example, tcl = ts for flat plate or for tracking collectors if there is no shading. For the CPC, tcl is given by Eq. (2.5.9) or (2.5.11). (ii) Calculate corresponding output Q,. (iii) Decrease tc by A/ c to get new tc2 = tA — A/C(A^ = 0.5 h will give sufficient accuracy in most cases). (iv) Calculate output Q2 for tc2 and repeat procedure until maximal Q is found. The smaller the heat loss, the closer the optimal tc will be to tc[. This is

Figure 11.4.3 Utilizability versus the critical ratio Xc for K, = 0.5 and nine values of R from 0-0.8 (From Collares-Pereira and Rabl [1979]).

System Models

315

Figure 11.4.4 Utilizability 4> versus the critical ratio X, for K, — 0.4 and nine values of R from 0-0.8 (From Collares-Pereira and Rabl [1979]).

illustrated by the sample calculations in Tables 11.4.6 and 11.4.7 that were carried out with a rather small decrement &tc — 0.1 h. This small value was chosen only for the sake of illustration. For example, in Table 11.4.6 a value of A^. = 0.5 h would have yielded Q — 3.714 MJ/m2 on the second iteration, only 1% less than the value Q = 3.743 MJ/m2 obtained with A?c = 0.1 h on the 14th iteration. The maximum is broad and quite insensitive to uncertainties in tL., and a time step A/c = 0.5 h is adequate in practice. EXAMPLE 11.4.1

To provide an example, we calculate the energy delivery of several collector types for an average February day in New York, NY. The latitude is X = 40.5° and the sunset time ts = 5.24 h on February 15. The relevant values

Figure 11.4.5 Utilizability versus the critical ratio Xc for K, = 0.3 and nine values of R from 0-0.8 (From Collares-Pereira and Rabl [1979]).

316

Active Solar Collectors and Their Applications

Figure 11.4.6 Utilizability versus the critical ratio Xc for collectors with high values of concentration and five KT from 0.3-0.7 (From CollaresPereira and Rabl [ 1979]).

of insolation Hh, clearness index Kr and daytime ambient temperature Tarab

are

TABLE 11.4.6 50°Ca

Collector Parameters and Energy Collected 15 February in New York at

1o#

U[W/m 2 °C] C Fm tc (h from noon) «*

Rd

R = Rd/Rh H [MJ/m 2 ][Eq. (11.4.1)] ^.[Eq. (11.4.12)] 0(#7-, «. ^) (GA4) = »o<*# [MJ/m2] rabs = 50°c

Flat plate

CPC evacuated

Parabolic trough EW tracking axis

0.75 4 1 0.9

0.6 0.8 1.5 0.99

0.65 0.7 20 0.95

3.934 1.626 0.783 0.481

4.651 1.723 1.089 0.632

5.234 1.874 1.932 1.031

5.234 2.377 2.549 1.072

5.234 2.441 2.617 1.072

10.616 0.697 0.470

10.278 0.213 0.807

8.385 0.237 0.856

10.274 0.194 0.881

10.550 0.054 0.966

3.743

4.976

4.667

5.886

6.624

3.369

4.926

4.434

5.592

5.962

(Ql A) = F,^007? [MJ/m2] ym = 50°c "From Collarcs-Perdra and Rabl [1979].

Parabolic trough polar tracking axis

2-axis tracker

0.65 0.7 20 0.95

0.65 0.2 500 0.9

317

System Models TABLE 11.4.7 Some Results of the Iteration Procedure to Determine the Cutoff Time Corresponding to the Maximum Energy (max (?) Collected" Iteration no. 1st 10th 14th (max. Q) 15th

Cutoff time

tc

R»

R«

H

Xc

Q

5.234 4.334 3.934 3.834

1.801 1.700 1.626 1.604

0.943 0.839 0.783 0.768

11.482 11.027 10.616 10.491

0.858 0.739 0.697 0.688

3.405 3.714 |3.743| 3.738

"Flat plate, tilt = latitude, at rabs = 50°C in New York in February as in Table 11.4.6. Iterations start with tc = ts = 5.234 sunset time (h from noon); decrement Arc = 0.1 h; for the sake of illustration Arc has been chosen much smaller than necessary (from Collares-Pereira and Rabl [1979]).

The correlation for the diffuse/hemispherical ratio, Eq. (3.6.1), yields a diffuse component of Hd = 3.78 MJ/m2 per day for these conditions. For the ground reflectance we assume pground = 0-2. We consider the following five collectors. (i) Flat plate collector with optical efficiency r/0Z = 0.75, U value U = 4.0 W/m2 °C, and heat extraction efficiency factor Fm = 0.90, typical of double glazing and selective coating. (ii) Fixed CPC collector with evacuated receiver, having TJOA" = 0.60, U = 0.8 W/m 2 °C, Fm = 0.99, concentration C - 1.5, and acceptance angle 26a = 68°. (iii) One-axis tracking concentrator with horizontal east-west axis and collector parameters ^K = 0.65, U = 0.7 W/m2 °C, and Fm = 0.95. (iv) Same collector as (iii) but with polar mount, i.e., tracking axis in north-south direction with tilt equal latitude. (v) Two-axis tracking Fresnel lens collector with ?j0 = 0.65, U = 0.2 W/ m2 °C, and Fm = 0.9. The operating temperature is specified as mean fluid temperature Tm = 50°C; this temperature is in the range appropriate for some space heating applications. The entries in Table 11.4.6 are obtained by iteration over tc with A^ = 0.1 h; details of the intermediate iterations are provided in Table 11.4.7. Rows 5 to 8 list the cutoff time tc, the functions Rh and Rd of Tables 11.4.1 to 11.4.5, and the ratio R = RJRh- The insolation H incident on the aperture during operating hours is obtained from Eq. (11.4.1) and listed in row 9. Row 10 lists the critical intensity ratio Xc of Eq. (11.4.12), and the corresponding value of the utilizability <j> of Eqs. (11.4.13) through (11.4.15) is entered in row 11. The final result for the delivered energy at !Tabs = 50°C is given in row 12 and at Tm - 50°C in row 13. At this operating temperature the heat loss from the flat plate is already so high that all the concentrating collectors in Table 11.4.6 outperform the flat plate. 11.5

THE , /-CHART

The correlations of Sections 11.3 and 11.4 can be used directly whenever the average operating temperature of the collector is known. For many sys-

318

Active Solar Collectors and Their Applications

terns with thermal storage the analysis is more complex because the collector temperature is not known a priori; rather, it fluctuates with the storage temperature which in turn depends on collector output during preceeding periods. Klein and Beckman [1979] have developed a shorthand procedure, the 0, /chart, for the analysis of the system shown in Fig. 1 1.1. la. This is essentially the schematic for an active space heating system; it could also be used for process heat (however, for the latter application, different designs are likely to be more efficient, as discussed in Section 12.3). Solar energy is supplied whenever the temperature of the storage tank is above Tmin, the minimum temperature useable by the load. The backup or auxiliary is in parallel with the solar system and supplies the entire load whenever storage falls below rmin. If the temperature of the collector were always equal to Tm-m (e.g., if storage were infinite), then the monthly delivered energy would simply be calculated according to Section 11.4, using the critical intensity ratio, Eq. (11.4.12),

for the collector inlet temperature rmin. The utilizability corresponding to XCi min serves as intermediate step in the $, /chart procedure. One calculates the variables

where L is the average daily load [in J]. If the system contains a heat exchanger between collector and storage, both X' and Y are multiplied by an additional factor Fx. [The numbers 100°C and 24 X 3600 sec in Eq. (11.5.3) have no fundamental significance; they were included by Klein and Beckman to make X' dimensionless.] With these values of X' and Fone can now determine how large a fraction/of the load the solar system will supply on the average. From the graphs in Fig. 11.5.1,/can be found using the X' and Y values as abscissa and ordiriate, respectively. The four storage capacities included in Fig. 11.5.1 cover the range of practical interest. The information in these figures is also contained in the equation

Rs is the ratio of the standard storage capacity (350 kJ/°C per m2 of collector) over the actual capacity. Equation (11.5.4) is implicit because/appears on both sides, but it can readily be solved by iteration. The difference between

System Models

319

y and / is the difference between finite storage and infinite storage. With finite storage Tm rises above 7^,, and hence /is lower than Y. With the , /chart method one calculation should be done for the central day of each month. The annual total delivered solar energy is then the sum of the monthly contributions

where Nt is the number of days and/L, the average daily solar contribution in each month.

EXAMPLE 11.5.1

A flat plate collector with ij0K =0.75 and ( 7 = 4 W/m 2 K is to supply pro cess heat at a minimum temperature Tm,n = 50°C. The location is New York, the collector tilt is equal to latitude, and the system schematic is as in Fig. 11.5.1. The average daily load is L = 430 MJ and the collector area is A = 100 m2. The storage capacity is 35 MJ/°K. Flow rate and heat exchanger are such that FmFx = 0.80. Calculate the solar energy delivered to the process, if storage is well insulated. SOLUTION

This is the flat plate used in Table 11.4.6, and the results can be used as basis for this calculation. The critical intensity ratio is the same, whether it is the mean fluid temperature Tm or the inlet temperature rHX, m on the storage side of the collector heat exchanger that is specified. Hence the calculation is the same as in Table 11.4.6, up to and including H = 10.616 MJ/m2 and
From Fig. 1 l.S.lb one finds/ = 0.60. This is a 14% reduction in delivered energy due to the rise of storage temperature above rmin. The solar energy delivered to the load during an average February day is NfL = 28.25 days X 0.60 X 430 MJ/day = 7.3 GJ. The , /chart assumes that the storage tank is well insulated and that there is no heat exchanger between storage and load. As for heat losses from the storage tank, they should be a small correction and thus only a rough estimate is needed. Usually the approximation

will be adequate. For a more accurate determination one can estimate the average collector inlet temperature rin by backtracking the utilizability cal-

320

Active Solar Collectors and Their Applications

Figure 11.5.1 , /charts for various storage capacities (a) Storage capacity 175 KJ/°C nr; (b) Storage capacity 350 kJ/°C nr; (c) Storage capacity 700 kJ/°C nr; (d) Storage capacity 1400 kJ/°C m2 (From Klein and Beckman [1979]; reprinted by permission of John Wiley & Sons).

culation. For this purpose one replaces Fin Eq. (11.5.2) by the value of/ that has been obtained for the month, and then one calculates the corresponding value of the utilizability:

Knowing , one can use Eqs. (11.4.12) through (11.4.15) to solve for Xc,m and hence Tin. Klein and Beckman [1979] recommend that the arithmetic average of Tmm and Tm be used instead of Tmir, in Eq. (11.5.6)." "A more accurate correlation for tank Josses has recently been presented by Braun et al. [1982].

System Models

Figure 11.5.1

321

(continued)

If there is a heat exchanger between storage and load, Duffie and Beckman [1980] assume that Tmm must be increased by

where L is the average load rate [in W], eL is heat exchanger effectiveness, and (mc)mm is the smaller of the two fluid capacity rates in the heat exchanger.

322

Active Solar Collectors and Their Applications

EXAMPLE 11.5.2 The storage tank for the previous example has a loss coefficient-area product (UA)Mr = 6 W/K and is placed in an environment with Tmv — 12°C. What is the loss from storage in February? SOLUTION If one assumes Eq. (11.5.6) one finds

approximately an 8% loss compared to 7.3 GJ. Let us see how much this estimate changes if we take into account the temperature rise above Tmm. Comparing Eqs. (11.5.2) and (11.5.7) we find

and hence 4>(X^n) = 0.403. From Fig. 11.4.4 we read Xc-m = 0.84. Since X.in/X.min = (tin - l\mb)/(Tmm - T.dmb) one obtains Tm = 60°C. With the new storage temperature estimate of (50°C — 60°C)/2 = 55°C, the storage loss estimate increases to 0.63 GJ. This increase amounts to about 1% of the delivered energy and is not significant in view of the overall errors. Hence the simple estimate, Eq. (11.5.6), gives an acceptable answer for the storage tank loss in this case.

REFERENCES Alcone, J. M. and Herman, R. W. 1981. "Simplified Methodology for Choosing Controller Set Points." ASME 3rd Conference on System Simulation, Economic Analysis, Solar Heating and Cooling Operational Results. Reno, NV. Braun, J. E., Klein, S. A., and Pearson, K. A. 1982. "An Improved Design Method for Solar Water Heating Systems." University of Wisconsin Report. Beckman, W. A., Klein, S. A., and Duffie, J. A. 1977. Solar Heating Design by thefchart Method. New York: John Wiley & Sons. Boes, E. C. et al. 1977. "Availability of Direct, Total and Diffuse Solar Radiation to Fixed and Tracking Collectors in the USA." Report SAND-77-0885. Sandia Laboratories. Bruno, R. 1979. "Which Models for What?" Philips GmbH Forschungslaboratorium Aachen, Report No. 7/79. In Proc. Joint German-Australian Workshop (CCMS) on Solar Energy System Design. Collares-Pereira, M. and Rabl, A. 1979a. "Derivation of Method for Predicting Long Term Average Energy Delivery of Solar Collectors." Solar Energy 23:223. Collares-Pereira, M. and Rabl, A. 1979b. "Simple Procedure for Predicting Longterm Average Performance of Nonconcentrating and of Concentrating Solar Collectors." Solar Energy 23:235.

System Models

323

Dickinson, W. C. 1978. "Annual Available Radiation for Fixed and Tracking Collectors." Solar Energy 21:249. Dudley, V. E. and Workhoven, R. M. 1979. Summary Report: Concentrating Solar Collector Test Results Collector Module Test Facility. Report SAND-78-0977. Albuquerque, NM: Sandia Laboratories. Duffie, J. A. and Beckman, W. A. 1980. Solar Engineering of Thermal Processes. New York: John Wiley & Sons. Fewell, M. E. and Grandjean, N. R. 1979. "User's Manual for Computer Code SOLTES-1 (Simulator of Large Thermal Energy Systems)." Report SAND 781315. Albuquerque, NM: Sandia Laboratories. Gaul, H. W. and Rabl, A. 1980. "Incidence Angle Modifier and Average Optical Efficiency of Parabolic Trough Collectors." Trans. ASME J. Solar Energy Eng., 102:16. Gordon, J., and Zarmi, Y. 1982. "A Simple Method for Calculating Annual Insolation on Solar Collectors." Solar Energy 28:483. Gordon, J. M. and Rabl, A. 1982. "Design, Analysis and Optimization of Solar Industrial Process Heat Plants Without Storage." Solar Energy 28:519. Gordon, J. M. and Zarmi, Y. 1983a. "The Utilizability Function: Theoretical Development of a New Approach." Solar Energy 31:529. Gordon, J. M. and Zarmi, Y. 1983b. "The Utilizability Function: Validation of Theory Against Data-Based Correlations." Solar Energy 31:537. Hall, I. J. et al. 1978. "Generation of Typical Meteorological Years for 26 SOLMET Stations." Report SAND 78-1601. Albuquerque, NM: Sandia Laboratories. Hottel, H. C. and Whillier, A. 1955. "Evaluation of Rat Plate Solar Collector Performance." Transactions of the Conference on the Use of Solar Energy: The Scientific Basis, Vol. II, Part 1, Section A, pp. 74-104. Klein, S. A. et al. 1978. "Calculation of Flat-Plate Collector Utilizability." Solar Energy 21:393. Klein, S. A. et al. 1979. "TRNSYS-A Transient Simulation Program; Users Manual." Engineering Experiment Station Report 38. Madison, WI: Solar Energy Laboratory, University of Wisconsin. Klein, S. A. and Beckman, W. A. 1979. "A General Design Method for Closed-Loop Solar Energy Systems." Solar Energy 22:269. Kusuda, T. 1981. "A Comparison of Energy Calculation Procedures." ASHRAE J. August:21. Kutscher, C. F., Davenport, R. L., Dougherty, D. A., Gee, R. C., Masterson, P. M., and May, E. K. 1982. "Design Approaches for Solar Industrial Process Heat Systems." Report SERI/TR-253-1356. Golden, CO: Solar Energy Research Institute. Liu, B. Y. H. and Jordan, R. C. 1963. "A Rational Procedure for Predicting the Long Term Average Performance of Flat-Plate Solar-Energy Collectors." Solar Energy 7:53. Lunde, P. J. 1980. Solar Thermal Engineering. New York: John Wiley & Sons. Mitchell, J. D., Theilacker, J. C., and Klein, S. A. 1981. "Calculation of Monthly Average Collector Operating Time and Parasitic Energy Requirements." Solar Energy 26:555. Rabl, A. 1981. "Yearly Average Performance of the Principal Solar Collector Types." Solar Energy 27:215. Sicgel, M. D., Klein, S. A., and Beckman, W. A. 1981. "A Simplified Method for

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Active Solar Collectors and Their Applications

Estimating the Monthly Performance of Photovoltaic Systems." Solar Energy 26:413. SOLMET. 1978. "SOLMET, Volume 1-User's Manual TD-9724, Hourly Solar Radiation-Surface Meteorological Observations." Asheville, NC: National Climatic Center. Zarmi, Y. 1982. "Transition Time Effects in Collector Systems Coupled to a WellMixed Storage." Solar Energy 29:1.

12. APPLICATIONS

In this chapter we discuss the principal uses of active solar collectors: space heating and/or cooling, water heating, industrial process heat, and power generation. For some of the most common applications explicit design procedures are presented. A design procedure consists of the following steps: (i) selection of system configuration (flow diagram) (ii) selection of manufacturer, model, and size for each of the system components (collector, storage, etc.) (iii) calculation of system performance (iv) economic analysis (v) variation of size and model selection for each system component to determine economic optimum The design procedures in this chapter deal with the first three stages, in particular the calculation of system performance. The economic analysis and optimization, described in Chapters 14 and 15, are the same for all applications. 12.1 ACTIVE SPACE HEATING AND COOLING There are basically two approaches to space heating with solar energy. Active solar heating employs mechanical equipment (e.g., collectors, pumps, ducts, pipes, storage tanks) that is separate from the architecture of the building. The passive approach, on the other hand, relies on parts of the building itself (e.g., windows, storage walls, atrium) to collect and store solar heat. Sometimes one may also combine active and passive elements in a hybrid design. This book deals only with active systems. For passive solar heating the reader is referred elsewhere; for instance, Kreider and Kreith [1982], Balcomb [1980], and Anderson and Michal [1980]. In most regions active solar space heating is a challenging task because the load tends to be highest when there is least insolation. To compensate as much as possible for this mismatch, one tilts the collectors towards the low winter sun; in midlatitudes a good rule of thumb gives the collector tilt as latitude plus 15°. During summer the collectors are idle, and one may have to take precautions to keep the system from overheating. As an alternative one could use seasonal storage from summer to winter, for example, large water tanks [Sillman, 1981] or deep solar ponds [Rabl and Nielsen,

325

326

Active Solar Collectors and Their Applications

1975]. For a given space heating demand, the seasonal storage approach requires less collectors but much more storage than the conventional active system with short term storage. For conventional systems one recommends on the order of 300 kJ/°C m2 of thermal storage capacity per collector area; this is enough for at most a few cloudy days. The heat available during summer could be utilized for solar cooling by means of an absorption chiller or a desiccant chiller. 12.1.1 System configurations The two main classes of active space heating systems are distinguished by the heat transfer fluid in the collector: liquid systems and air systems. Schematics for each are shown in Figs. 12.1.1 and 12.1.2. In general, heat transfer to air is poor. Nonetheless solar air systems may be practical, if the heat distribution system of the building uses air anyway. In that case at least one heat exchange between collector and air is necessary, and that heat exchange might as well take place in the collector rather than in a separate heat exchanger. For this reason the overall system performance of an air based system is comparable to that of a liquid system despite the seemingly lower collector efficiency (as reflected in lower values for the heat transfer factors Fm and Fm of the collector efficiency equation). Typical design parameters are listed in Table 12.1.1 for liquid and in Table 12.1.2 for air systems.

Figure 12.1.1 Typical system schematic for liquid space heating system (From Kreider and Kreith [1982]).

Applications

327

Figure 12.1.2 Typical system schematic for air space heating system (From Kreider and Kreith [1982]). 12.1.2

Performance prediction for space heating

Many computer programs and shorthand procedures have been developed for predicting the performance of solar heating systems; some of them are described by Kreider and Kreith [1982] and by Bendt and Soto [1980]. In this chapter we present the /chart method of Beckman, Klein, and Duffie [1977]. This method has been derived as curve fits to the results of a large number of computer simulations. It requires one calculation per month. TABLE 1 2. 1 . 1 Typical Design Parameter Ranges for Liquid Solar Heating Systems" Collector flow rate Collector slope Collector azimuth Collector heat exchanger Storage capacity Load heat exchanger Water preheat tank capacity

0.0 10-0.020 kg/seem2 (\ + 15°) ± 15° 0° ± 15° F, > 0.9 50-100 liters/m2 1 < f(mc)min/L < 5 1.5 X capacity of conventional heater

"From Duffie and Beckman [1980]. Reprinted by permission of John Wiley & Sons.

328

Active Solar Collectors and Their Applications TABLE 1 2. 1 .2 Typical Design Parameter Ranges for Solar Air Heating Systems3 Collector air flow rate Collector slope Collector surface azimuth angle Storage capacity Pebble size (graded to uniform size) Bed length, flow direction Pressure drops Pebble bed Collectors Ductwork Maximum entry velocity of air into pebble bed (at 55 Pa pressure drop in bed) Water preheat tank capacity a

5-20 liters/m2 sec (A + 15°) ± 15° 0° ± 15° 0.1 5-0.35 in3 pebbles/m2 0.01-0.03 m 1. 25-2.5 m 55 Pa minimum 50 to 200 Pa 10 Pa 4 m/sec 1.5 X conventional water heater

From Duffic and Beckman [1980]. Reprinted by permission of John Wiley & Sons.

The input variables of the system enter the calculation in two dimensionless groups:

and

where A Fm Fx U ramb Tday

L j]0 K H

= = = = = = = -

collector area [m2] heat transfer factor heat exchanger factor collector heat loss coefficient (U value) [W/m2 K] monthly average ambient temperature [C°] 24 X 3600 sec total daily heat load [J] averaged over the month optical efficiency all-day average of incidence angle modifier [Eq. (11.4.10)] daily solar irradiation incident on collector [J/m2] [Eq. (11.4.1) with cut off time tc = ts]

The variable Xf represents the collector heat loss, the variable Yf the absorbed solar radiation; both are normalized by the heating load L. One wants to find / the fraction of the load L that is supplied by solar energy. The quantity /is a function of Xf and Yf and is given both in equation and graph form. For liquid systems/is given by Fig. 12.1.3 or by the equation

329

Applications

Figure 12.1.3 The/-chart for systems with liquid heat transfer and storage media (From Beckman, Klein, and Duffie [1977]; reprinted by permission of John Wiley & Sons).

For air systems one uses Fig. 12.1.4 or the equation / = 1.040}}- 0.0651}- 0.1591^ + 0.00187^ - 0.0095Y}.

(12.1.4)

These equations should not be used outside the range shown by the curves in Figs. 12.1.3 and 12.1.4. This procedure is repeated for each month of the heating season. The annual delivered solar heat Q is the sum of the monthly contributions:

where Nt is the number of days and /L, is the average daily solar contribution in each month. The/chart correlations are based on standard storage capacities 75 kg of water per m2 of collector for liquid systems and 350 kJ/°C per m2 of collector for air systems. For other storage capacities one simply corrects the variable

Figure 12.1.4 The/chart for air systems (From Beckman, Klein, and Duffie [1977]; reprinted by permission of John Wiley & Sons).

330

Active Solar Collectors and Their Applications

Xfby the correction factor

with the exponent

This correction is valid for the range 0.5 <

< 4.0.

In general, /chart results agree within a few percent with the results of detailed computer simulations, in particular, the TRNSYS model from which the /chart was developed. 12.1.3 Measured system performance Several solar heated houses have been instrumented and monitored. Examples are the MIT solar houses [Engebretson, 1964], the Lof residence [Lof et al., 1964], and the Colorado State University solar houses [Karaki et al., 1977; Karaki et al., 1978]. Performance data for one of these, the Colorado State University Solar House II, are summarized in Table 12.1.3. Of particular interest are the system efficiency and the solar fraction. The monthly average system efficiency, based on total insolation incident on the collector, is on the order of 25%-30% during the heating season. The solar fraction varies with time of year from about 0.6 to about 0.9. These numbers are quite typical of active solar heating systems. The performance data for this house have been used to validate the /chart procedure. The measured annual solar heating fraction was 0.72 while/chart predicted 0.76 [Duffi and Beckman, 1980]. The agreement is really quite good, considering how many reasons there could be for a discrepancy. If the system, as actually built and operated, had some defect (e.g., leaks or control failures) the performance would be lower than predicted by /-chart, even if the latter were perfectly accurate. For a recent survey of systems with measured performance and a comparison to/chart predictions the reader is referred to Duffle and Mitchell [1983]. More recently measured performance data have become available for a large number of solar heating and cooling systems, as published in an impressive series of reports by Vitro Labs [1981], 12.1.4 Solar cooling Solar energy could provide cooling by several techniques, the most important being the absorption chiller, the desiccant chiller, and the compression chiller. The first two use solar heat directly while the latter operates on mechanical power from a photovoltaic or a solar thermal generator. Desic-

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Applications

TABLE 12.1.3 Thermal Performance Data for a Solar Space Heating System (Air SystemColorado State University Solar House II)a 1977

1976

Collector (MJ/m 2 day): Total solar insolation Solar insolation while collecting Heat collected Efficiency (percent) Based on total solar insolation Based on solar insolation while collecting Space and DW Heating (MJ/day): Total energy required Space

DHW Total Solar contribution Space

DHW Total Solar fraction Space

DHW Total

Nov. 24 days

Dec. 10 days

Jan. 26 days

Feb. 20 days

Mar. 27 days

Apr. 18 days

13.5

15.8

15.1

15.6

17.7

14.2

11.2

13.8

12.9

3.1

4.9

4.6

13.6

15.6

12.2

5.0

3.7

23.0

31.0

30.0

30.0

28.0

26.0

28.0

36.0

36.0

35.0

32.0

30.0

311.6 40.6 352.2

323.2 52.3 375.5

432.9 73.0 505.9

319.9 82.9 402.8

319.0 75.4 394.4

192.3 62.8 255.1

198.7 21.3 220.0

257.5 30.8 288.5

231.4 63.5 294.9

239.6 75.4 315.0

245.8 67.4 313.2

166.1 51.8 217.9

0.64 0.52 0.62

0.80 0.59 0.77

0.53 0.87 0.58

4.7

0.75 0.91 0.78

0.77 0.89 0.79

0.86 0.82 0.85

"From Karakietal. [1977],

cant cooling is still in the development stage, and it may hold promise. Absorption cooling is a well developed technology. Of the two cycles in common use, the lithium bromide cycle is usually operated at 100-120°C and is thus better matched to solar collectors, whereas the ammonia water cycle requires temperatures around 150-180°C. Lithium bromide chillers can be modified to run on heat at temperatures as low as 85°C, but then their capacity is reduced. Energy storage with solar absorption chillers is fairly costly because only a small temperature interval is available, whether the energy is stored as chilled water or as hot water. Furthermore, the transient operation typical of solar energy systems imposes penalties. To evaluate the prospects of solar cooling with compression chillers, it is helpful to think of this approach in two separate steps: first power is generated, then that power is used for cooling. These two processes are really independent of each other. Therefore one might as well compare the following two systems for generating power: (i) a compression chiller driven by mechanical power from a flat plate solar thermal system on a building, and (ii) the same chiller driven by electricity from a central station high temperature solar thermal power plant. Not only does the local system lack economies of scale, but with a flat plate system the conversion efficiency to elec-

332

Active Solar Collectors and Their Applications

tricity would be far too low, as shown by the example in Table 12.5.2. The comparison is so unfavorable for local solar thermal power generation that it is not substantially altered if one were to use evacuated tubes or other medium-temperature collectors that could reasonably be deployed on an individual house. Thus one should not expect to improve the cost effectiveness of a solar heating system by adding solar cooling with compression chillers. When considering compression chillers, the real question is: what is the most appropriate technology for generating power? Perhaps the best cooling technologies with renewable energy are not based on active solar approaches. For example, in dry climates evaporative cooling seems to be the most economical [Supple, 1982]. In dry climates radiative cooling at night can also be very effective [Hay and Yellot, 1970]. In humid climates with cold winters the ice pond may be cost effective for large applications such as commercial buildings; using a snow machine, one makes ice/snow in winter and stores it for use in summer [Kirkpatrick et al., 1983]. 12.2 WATER HEATING The heating of domestic or service water, water heating in short, is one of the oldest applications of solar energy. In the time from 1920-1950 thousands of solar water heaters were in use in California and Florida [Butti and Perlin, 1980]. They fell out of favor when conventional energy became cheap, but since the energy shortage of the seventies they have reappeared in ever increasing numbers. In some countries with plentiful sunshine and high energy prices, most notably in Israel, solar water heaters are very cost effective and popular. There are two good reasons why solar energy is well suited for water heating. The temperature range is well matched to inexpensive flat plate collectors, and the demand for hot water is quite uniform throughout the year. 12.2.1 System types There are several possible ways of connecting solar collectors to a water supply system. The most important solar water heater configurations are shown in Fig. 12.2.1. The first two systems Figs. 12.2.la and 12.2.Ib are called direct because the water makes direct contact with the collector, by contrast to the indirect systems of Figs. 12.2.1c and 12.2. Id, where a heat exchanger separates the collector loop from the water supply. Typically one uses a water-antifreeze mixture in the collector loop. Because of the toxicity of most commercial antifreezes (glycol), U.S. building codes require a double wall heat exchanger in that case. Obviously a heat exchanger increases the cost and it imposes a performance penalty on the order of a few percent. However, in locations with frost the indirect systems may be the most desirable choice, and they are the most popular ones in the U.S. Also, direct systems may be problematic in areas where the pressure of the water mains

Applications

333

Figure 12.2.1 Schematics of common configurations of water heaters, (a) A natural circulation system, (b) One tank forced circulation system, (c) System with antifreeze loop and internal heat exchanger, (d) System with antifreeze loop and external heat exchanger. Auxiliary is shown added in the tank, in a line heater, or in a second tank; any of these auxiliary methods can be used with any of the collector-tank arrangements. (From Duffie and Beckman [1980]; reprinted by permission of John Wiley & Sons).

exceeds the rated pressure limit of the collector or where water hardness is excessive. Frost protection for direct systems requires special care. In regions where frost is light and rare, one can afford to heat the collector artificially when necessary, by circulating a small amount of warm water through it. One particularly elegant design uses a valve that opens whenever the ambient approaches freezing temperatures. When the valve opens, cold water is allowed to drain slowly out of the collector into the open, and warmer water from tank or mains enters the collector as replenishment until this warmer water reaches the valve and closes it again. The cost of the discarded water is negligible. The valve is a simple passive device based on the differential thermal expansion of dissimilar materials. In regions with more severe frost one needs to drain the collector to prevent freeze-ups. In the U.S. the draindown approach has been taken most frequently when a direct system has been used at all. In principle the design of a draindown system is straight-

334

Active Solar Collectors and Their Applications

forward, requiring only valves that are activated when the absorber temperature sinks below a specified value. However, in practice there are problems with reliability.' A single failure may destroy the entire collector and can be more costly than the cost and performance penalties of indirect systems. The simplest system is the thermosyphon in Fig. 12.2. la. Neither pump nor controls are needed because the fluid circulates by virtue of its own thermal expansion whenever the temperature in the collector is above the temperature at the top of the storage tank. The flow rate depends on the flow resistance in the collector loop. As shown by a theorem of Gordon and Zarmi [1981] and by the computer simulations of Mertol et al. [1981], the flow rate has little effect on daily average performance, provided the flow rate is high enough to move the entire storage volume through the collector at least once during a sunny day. This conclusion about flow rate independence holds for pumped systems just as much as for thermosyphons. As a completely passive system the thermosyphon is the most efficient and the most reliable. However, it can only be used if certain conditions are satisfied. Apart from the above-mentioned problem of frost protection, the storage tank must not be located below the collector. Since the collector is usually mounted on the roof of a building, this requirement may be unacceptable on architectural grounds. Also, a storage tank on the roof may require special protection against freezing. It is possible to combine the simplicity of a passive thermosyphon with the fail-safe free/e protection of an indirect system by adding a heat exchanger. However, the requirement for placing the storage tank above the collector still remains. If the tank must be located below the collector, then the fluid must be pumped actively through the collector. This necessitates not only controls, as indicated in Fig. 12.2.1b, but also a check valve to prevent thermosyphon flow at night from storage back to the collector. The indirect system of Fig. 12.2. Ic differs from Fig. 12.2.1b only by the addition of a heat exchanger. Finally, Fig. 12.2. Id shows an indirect system with two tanks. In a two-tank system the solar components act as preheater to the conventional system. Much of the time the temperature in the preheat tank is below the water use temperature, and hence the collector can operate at higher efficiency than in a single tank system. In practice this advantage is more or less canceled by losses from the increased tank surface. In onetank systems one can capture at least some of the benefit of preheating by placing the auxiliary heater at the top of the tank while solar heat is added only at the bottom of the tank, as indicated by the placement of the lines in Fig. 12.2.1. For improved performance one can place the auxiliary tank directly on top of the solar preheater tank, with a thermal diode (e.g., a heatpipe) between the tanks. Such a system has been developed by Grunes et al. [1982]. 'Also, some collectors have serpentine flow paths and do not drain well.

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Applications

12.2.2 Performance comparison

Several of the standard solar water heating systems have been evaluated experimentally in a study by the National Bureau of Standards [Fanney and Liu, 1979; Farrington et al., 1980]. Six systems were operated side by side, exposed to the same climatic conditions and supplying approximately the same thermal load. The systems were selected as typical of those being installed commercially. The most important performance results are summarized in Table 12.2.1, in terms of the thermal efficiency of the collector, system efficiency, and solar fraction. Before interpreting the results, one should keep in mind that the single-tank direct system and the air system had different collector areas from the other four systems. The system efficiency can be significantly lower due to parasitic power requirements and due to losses from the tank. Since parasitic power is supplied as electricity from a conventional central station power plant, the system efficiency and net solar fraction have also been calculated considering the fossil fuel energy consumed at the power plant; the latter numbers are given in parentheses in Table 12.2.1. The following conclusions are suggested. Air systems have such a high airto-water heat exchanger penalty and require so much parasitic power as to be impractical. For liquid systems the collector efficiency is in the range of about 23%-35% while the system efficiency is in the range of 18%-29%. Taking into account the fuel consumed by the central station power plant for the parasitic energy, the system efficiency is in the range of 8%-24%. Thermosyphon systems and single-tank direct systems have the highest efficiency. (The higher collector efficiency of the single-tank direct system in Table 12.2.1 is probably due to the smaller collector area, which results in lower solar fractions and lower tank temperatures.) The system efficiency for indirect systems and for double-tank systems is significantly lower. When one considers systems costs in addition, one finds that the cost of solar energy for indirect and for double-tank systems is likely to be 2 to 3 times higher than for the thermosyphon system. TABLE 1 2.2. 1 Performance Results for Six Water Heater Systems"

System

Collector area (m2)

Thermal efficiency (%)

System efficiency (%)

Solar fraction0

Net solar fraction

Thermosyphon Single, dir. Single, ind. Double, dir. Double, ind. Air system

5.0 3.3 5.0 5.0 5.0 7.3

26.4 35.3 24.7 23.3 22.5 11.5

25.7 (24.3)b 28.5 (14.9) 22.3(17.5) 18.1 (7.7) 20.0(15.4) 8.1 (1.30)

0.57 0.51 0.54 0.52 0.50 0.38

0.56 (0.52) 0.42 (0.22) 0.49 (0.38) 0.41 (0.17) 0.44 (0.33) 0.26 (0.03)

"Adapted from Farrington et al. [1980]. b Figures in parentheses represent values if parasitic energy consumption were considered as energy required at a fossil-fueled electric generating plant (33% electric plant efficiency assumed). c Collector areas must be considered when comparing solar fractions.

336

Active Solar Collectors and Their Applications

12.2.3 Performance prediction for water heaters The performance of solar water heaters can be predicted by the /chart method described in Section 12.1.2 for space heating. Only one slight modification is required to adapt the /-chart for water heating. The variable Xfi which accounts for collector heat losses, needs to include a correction for the temperature rmains of the main water supply and for the minimum acceptable hot water temperature Tlmd since both of these have an effect on the collector operating temperature. Duffie and Beckman [1980] recommend the following expression for the variable Xf.

where all temperatures are in °C. The other symbols and the variable I/are the same as in Section 12.1.2. The solar fraction/is given by the same function of Xf and 7/as for liquid space heating systems, i.e., Eq. (12.1.3) and Fig. 12.1.3. The calculation is to be repeated for each month of the year. The/chart correlation for water heating is based on the two-tank configuration of Fig. 12.2. Id. It assumes a standard storage capacity of 75 kg/m2 of collector area. The effect of different storage sizes depends on the load pattern and is difficult to predict. The tanks are assumed to be well mixed and the energy in water above r,oad is considered not to be useful. The latter two assumptions yield conservative predictions. Heat losses from the auxiliary tank are to be included as part of the load (as they are normally included in the energy supplied in a conventional water heater). EXAMPLE 12.2.1

Calculate the useful solar heat supplied by a flat plate system in Denver, CO, in March. The collector is deployed at tilt equal latitude and receives an average irradiation of JJ = 21.6 MJ/m2 per day. The aperture area is A = 6 m2 and the storage capacity has the standard value of 75 kg/m2 of collector area. The collector-plus-heat exchanger combination has the parameter FxFmrj0K = 0.65 and FxFmU = 3.6 W/m2 K. The hot water demand is 400 kg/day at r,oad = 50°C. The temperature of the_water supply is Tmains = 10°C, and the average ambient air temperature is ramb = 3°C. To estimate heat losses from the auxiliary tank, assume a value (UA)stor = 1.2 W/K and a tank environment at 7"env = 20°C. SOLUTION

The daily hot water load is

Applications

337

To this, one has to add the heat loss from the auxiliary tank:

Thus the total daily load is

The variable Xffor the/chart is, from Eq. (12.2.1),

The variable 7, is, from Eq. (12.1.2),

From Eq.(12.1.3) or Fig. 12.1.3 we obtain the solar fraction

Hence this solar system saves

12.2.4 Swimming pool heaters Swimming pools are an obvious candidate for solar heating because of the low temperature required. In many cases the cheapest collector, a simple unglazed flat plate, will turn out to be the most cost-effective choice for an active pool heater. However, one should not overlook the following passive alternative. If an outdoor pool is used only during a few hours of the day, it may be best to cover it with a transparent insulating cover for the rest of the time. Such a cover can be made of a double plastic film with an enclosed air layer; it reduces heat losses while admitting solar radiation. A detailed evaluation is necessary in each case to determine which approach is best. To evaluate a solar pool heater one needs to calculate both the delivered solar heat and the heat loss from the pool. The temperature of a swimming

338

Active Solar Collectors and Their Applications

pool during the swimming season will be within a rather narrow comfort range; furthermore the heat capacity is so large that the temperature change during the day has negligible effect on the efficiency of a solar collector. Therefore one can employ the monthly utilizability method of Section 11.4 for calculating the useful solar heat, as pointed out by Govaer [1984]. The calculation of the load is more complicated, and the procedure of Govaer and Zarmi [1981] can be used. 12.3 INDUSTRIAL PROCESS HEAT 12.3.1 General considerations Heat is used in a wide variety of industrial processes. As long as solar equipment is relatively expensive one needs to select the applications carefully to obtain a good match between a process and a solar system. The higher the temperature, the lower the efficiency of the collector. Hence one should take advantage, as much as possible, of opportunities to supply heat at low temperatures. This necessitates a close examination of the process characteristics. Consider, for example, a plant where a central steam distribution system is used to heat a water bath; in such a case a solar retrofit could provide hot water directly to the bath rather than high-temperature heat to the central boiler. In many process heat systems a process fluid is heated over a range of temperatures; a relatively small collector field used as preheater can operate more efficiently than a large field that supplies the entire load. In theory the possibility of small and highly efficient solar preheaters exists also in domestic hot water applications, but in practice such systems would be too small to be economical. Industrial loads, on the other hand, are so large that even a solar preheater is large enough to reap the benefit of economies of scale. In the near term it is thus advisable to limit solar applications in industry to those cases that are most favorable by virtue of temperature, load distribution, etc. In the future as research, development, and growing mass production reduce the cost of solar installations, an ever larger number of applications will become economically attractive for solar. Of course, in evaluating the use of solar energy for an industrial application, one should not overlook opportunities for energy conservation. Frequently, solar equipment and energy conservation measures compete directly with each other. A heat recovery unit, for instance, will save low-temperature heat, thereby eliminating some of the best solar potential. As with all capital intensive technologies the load distribution is crucial. Most industries operate at a more or less uniform rate. Capital intensive industries tend to run continuously, 24 h/day, 7 days/week, while labor intensive industries are likely to shut down for nights and weekends. Other load patterns (e.g., 16 h/day, 6 days/week) also occur. It is easy to achieve good utilization of solar equipment in an industry with constant load 7 days/week. One simply chooses the size so that the peak output of the solar

Applications

339

system will just meet the load. The situation is more difficult if the industry shuts down for the weekend. In that case one either discards the solar energy collected during weekends or one adds storage. Because of differences in load distribution, the role of solar storage for industry differs from residential applications. Several distinct uses of storage are possible. Buffer storage for short periods (on the order of 1 h) may be necessary if the process is discontinuous (batch process) or if the backup cannot respond quickly to variations of solar input. Day/night storage permits use of solar heat at night. Weekend storage is an option for factories that close for the weekend. Finally there is the possibility of long term storage. Each of these requires different storage capacities. Which type of storage one wants, if any, depends on the characteristics of a particular application. In fact, in many situations, a design without storage may be preferable. After all, most industries have a load while the sun is shining. Thus, solar energy need not be stored to be useful (by contrast to solar domestic hot water, which must be stored because the load is out of phase with the sun). Storage increases the cost of solar energy because of added cost of the storage tank and because of losses from storage. Therefore the least expensive solar industrial process heat systems will contain minimal storage or none at all, and they will use fossil fuel backup for times when the amount of sunshine is insufficient. In view of this, one can distinguish the following three possibilities: 1. solar without storage costs more than fossil fuel 2. solar without storage costs less, and solar with storage costs more than fossil fuel 3. solar with storage costs less than fossil fuel In case (1) solar cannot compete. In case (2) one will build a solar system without storage that provides only the daylight portion of the load. Finally in case (3) the optimal system contains storage and supplies a large portion of the total load. The design of a solar industrial process heat system depends on the use of storage. Accordingly we discuss several different designs. The system of Section 12.3.2 contains no storage; it is the simplest possible solar energy design and the most efficient. The single-pass system of Section 12.3.3 contains storage and is nearly as efficient as the no-storage system. However, its application is somewhat limited because it is essentially an open-loop design. In practice it is very well suited for hot water loads. For high-temperature applications (e.g., with oil as heat transfer medium), it would require two separate storage tanks. For air systems it does not appear practical. Finally the multiple-pass system with storage, Section 12.3.4, can be used for all applications, but its efficiency is significantly below that of the first two designs. The formulas we present for the single-pass designs are for the most important case of a load that is constant in temperature and flow rate. If the heat rate of the process varies with time, it may be most economical to match the solar system to the constant base component of the load rather than to the total load. If solar equipment is sufficiently cheap, one may want to choose a larger system with added stor-

340

Active Solar Collectors and Their Applications

age to bridge load variations. If the load varies with season, a monthly calculation based on the monthly utilizability model of Section 11.4 is needed. The basic design philosophy of the single-pass open-loop approach still applies. The formulas also hold for the case of plants with batch operation, provided a buffer storage is included to make the load essentially continuous. 12.3.2 Systems without storage for constant loads For the no-storage constant load system, the simplest possible flow diagram is shown in Fig. 12.3.1. The collector is in series with backup and load. The process requires fluid at a temperature r,oad and the return temperature from the process is the inlet temperature Tm of the collector field. The flow rate m through the collector field equals the process flow rate m,oad. Flow rate and collector inlet temperature are constant. [Gordon and Rabl, 1982]. The load rate L [in W] is

Even though Fig. 12.3.1 shows a closed loop, it covers the open-loop case as well, e.g., a system where water from the water mains or ambient air is pumped through the collector and discarded after the process. For the purpose of the analysis, an open-loop is equivalent to a closed loop where the

Figure 12.3.1 Flow diagram for industrial process heat system without storage, (a) Direct, (b) With heat exchanger.

Applications

341

return temperature from the process equals the temperature of the water mains or of ambient air. In some cases the process fluid may be incompatible with the collector, and a heat exchanger must be interposed between collector and process. The effect of the heat exchanger can be accounted for very easily by multiplying the instantaneous efficiency equation by the heat exchanger factor Fx. The starting point of the analysis is the instantaneous efficiency equation of the collector field

with

The collectors are turned on if and only if the solar irradiance on the collector aperture exceeds the threshold X:

Under these conditions the yearly heat Q delivered by the collector field is given by

where q(X) is the correlation

displayed in Figs. 11.3.1-11.3.7. This equation gives the yearly useful energy as long as no collected heat is discarded. However, as shown in Chapter 1 5, the economic optimum i likely to correspond to areas large enough to incur some energy dumping. Hence we need to generalize the expression for Q to include energy dumping. As the first step let us calculate the area at which dumping begins. Let us call this value Adump. It is determined by the simple requirement that the power delivered under peak insolation just match the load rate L. The peak insolation for the collectors under consideration is, for midlatitudes near sea level, 0.85-1.10 k W/m for flat plates 0.801.00 k W/m for concentrators,

the range of numbers corresponding to the range from cloudy to clear climates. (More precisely 7max is equal to that value of X at which the correla-

342

Active Solar Collectors and Their Applications

tions in Figs. 11.3.1-11.3.7 vanish.) Equating the instantaneous peak output of the collector field of area A = AAamp with load rate L, we find

Before solving for Adamp we note that F-m has an implicit dependence on collector area; since the overall flow rate m is fixed, the flow rate per collector area and, by Eq. (12.3.3), Fm will change when the collector area is changed. For the following discussion it is convenient to recast this equation in the form

After inserting Eq. (12.3.3) for Fm in Eq. (12.3.8), one obtains

which can be solved for /4 dump . For direct systems (Fx = 1) the result can be written as

For systems with heat exchangers the result is slightly more complicated because Fv also depends on AAump. Inserting Eq. (10.4.11) for Fv one obtains

Since the economically optimal area is likely to be fairly close to Adumi,, it is instructive to calculate the corresponding yearly useful solar energy Q explicitly. Combining Eqs. (12.3.5) and (12.3.8) one can write the yearly useful energy collected with a system of area A = ^dump in the form

Applications

343

Sometimes the performance of a solar energy system is expressed as solar fraction / denned in the ratio of useful solar energy to load, in our case

where rioad is the number of seconds per year during which there is a load. Equation (12.3.12) gives an explicit expression for the solar fraction for A

From Figs. 11.3.1-11.3.7 we see that q(X) is in the range of 4-8 GJ/(m2 y) for most climates. Typical thresholds are in the range of 0.0-0.3 kW/m2. Taking 0.8 kW/m 2 as a typical value of (7max — X), one finds

for loads of 24 h/day in clear climates. In cloudy climates the solar fraction /at A = ^ dump is smaller. Now consider what happens if A is made larger than Adump while the total flow rate m is kept fixed. In that case the collector supplies more than the load whenever the insolation exceeds the threshold Xdump:

which follows from Eq. (12.3.8) (with Xdump instead of 7max). The annual discarded energy Qdump is equal to the energy that could be collected by a system with threshold ^dump. Thus it can be calculated by Eq. (12.3.5) if one simply replaces X by ^dump:

The useful energy delivered by the system is the difference between the energy Q(X) that could be collected in the absence of dumping, and the discarded energy Qdump:

Inserting Eqs. (12.3.15) and (11.3.2) we can write Eq. (12.3.17) in the form

344

Active Solar Collectors and Their Applications

Before we can optimize, we must display all dependences on collector area A explicitly. The only area dependent quantity in Eq. (12.3.18) is Xdump, for which we substitute Eq. (12.3.15) to obtain

Recalling Eq. (12.3.3) for Fm, we obtain

This is the final result when A > Adump. In addition to the coefficients q\ and
on process load rate L, on the flow rate-specific heat product me, and on the collector parameters Fmt)0 and Fm U. EXAMPLE 12.3.1

For a textile factory water must be heated from the water mains temperature to a process temperature 7ioad = 80°C. The water mains temperature is equal to the average ambient temperature Tamb = 19°C. The flow rate is constant at m = 0.75 kg/sec for 24 h/day but the plant operates only 290 days of the year, the rest being downtime due to weekends, holidays, and maintenance. The latitude is 32°N, the yearly average daytime beam irradiance 7h = 0.523 kW/m2, and the peak irradiance on a flat plate collector at tilt equal latitude is /max = 1-0 kW/m2. Consider the use of a flat plate collector array (including losses from pipes) with the parameters

as preheater, without heat exchanger and without storage. SOLUTION

Since the load is year-round, the flat plate should be deployed at tilt equal latitude. For this location the correlation of Fig. 11.3.1 yields

Applications

345

The threshold X is zero in this case because Tin = T3mb. Following Section 4.2 we find for this flow rate Fin?70 = 0.574. The load rate is

The threshold area for dumping is, by Eq. (12.3.10),

and with this area the yearly useful energy is

Equation (12.3.14) shows that such a system supplies/= 23.4% of the 24h load. It is of interest to note that the annual average system efficiency is KFinr)0 = 0.92 X 0.574 = 53% (apart from the factor 290/365 = 0.79 for holidays and weekends). This is significantly higher than the efficiency of typical residential solar systems. If the area is increased beyond the dumping threshold, Q is calculated from Eq. (12.3.20), again with the correction 290/365 for actual plant operation,

12.3.3 Single-pass open-loop system with storage Many industrial processes consume hot water as opposed to reusing it. This is particularly common in the food and textile industries. For example, in the beverage industry the water used for washing returnable bottles is so contaminated that it must be discarded. One may be able to recover some of the energy with heat exchangers to preheat the incoming fresh water, but the fluid itself is not reused. This feature is of crucial importance for the design of solar heat systems with storage. As shown in this subsection, one can design single-pass open-loop systems for this type of application that are significantly more efficient and economical than conventional multipass closed-loop systems. This single-pass strategy can also be applied in closedloop systems, even high temperature oil systems, but there it requires an additional tank to hold one day's worth of process fluid. The flow diagram for the single-pass open-loop system with storage is shown in Fig. 12.3.2. Figure 12.3.2a shows a direct system, Fig. 12.3.2b an

346

Active Solar Collectors and Their Applications

Figure 12.3.2 Single-pass open-loop waterbearing design with variable volume tank, (a) Direct, (b) With heat exchanger (From Collares-Pereira et al. [1984]).

indirect system where a heat exchanger separates the collector from storage and process. The heat exchanger may be necessary either to circumvent the freezing of water in the collectors (in cold climates) or in cases where possible corrosion of collectors by water is to be avoided. Our analysis covers both systems, the only difference being an additional heat exchanger factor Fx for the indirect system. For simplicity we consider only the case of greatest practical importance; namely, a process that is constant in temperature and flow rate. Fluid from the water mains is passed through the collectors at a constant flow rate m whenever the collectors can deliver useful heal. Water enters the collectors at temperature T{n. The outlet temperature 7"out varies with insolation. The heated water flows into the storage tank. Whenever hot water is available in the tank, it is withdrawn to the process at constant flow rate m,oad. The tank should be mixed because that ensures best storage utilization in the single-pass open-loop design. The backup heater is in series with the solar system and operates at variable heat rate to bring the fluid up to the process temperature T'k)ad. When no solar heat is available, the incoming

Applications

347

water bypasses the solar system and goes directly to the backup heater. The storage tank starts out empty at collector turn-on time and is sized to fill up with solar heated water during the course of an average sunny day. The storage tank is a variable volume tank. It need not be pressurized because it is not exposed to the pressure of the water mains (typically on the order of 5 times atmospheric pressure). Instead, the closed tank can have an internal insulating float. Such tanks are commercially available at much lower cost than pressurized tanks, but only for use below the boiling point. This system design stands in marked contrast to the conventional multipass closed-loop design of Section 12.3.4. In the latter the fluid is returned from storage to the collector for further heating. The flow rate is so high that the storage volume makes on the order of 5-10 passes through the collector during a single sunny day and the temperature rise for each pass is small. In a closed-loop water system the tank is exposed to the water mains and must be pressurized. According to the conventional wisdom, the low flow rates of the singlepass design imply a low collector efficiency. It is certainly true that for a given inlet temperature the outlet temperature goes up as the flow rate is decreased and hence the instantaneous collector efficiency decreases. However, in a multipass system the inlet temperature rises during the course of the day and hence the efficiency decreases anyway. In a single-pass system, collection efficiency decreases across the collector from inlet to outlet while in a multipass system it decreases during the course of the day. On balance the daily average collector efficiency is essentially the same—if not slightly higher for the one-pass system—as shown by a theorem of Gordon and Zarmi [1981] and by the computer simulations of Mertol et al. [1981]. The system efficiency of the single-pass system actually turns out to be significantly higher than for the multipass design, as demonstrated by the examples in this chapter. The lower system efficiency of multipass closedloop systems is primarily caused by mixing in storage, during charging and/ or during discharging, an effect that prevents complete utilization of the heat in the storage tank, quite apart from the larger pumping energy. To explain the selection of storage mass M and collector flow rate m let us for the moment assume that all days have the same operating period rop, given by Eq. (11.3.34). The length of time per day when the collector does not operate is rday — rop with rday = 24 h = 86,400 sec. During this time, any available hot water is withdrawn from storage at the process flow rate mload. Clearly one should not make storage any larger than mload(Tday — rop) because any storage in excess of this value would never be depleted; i.e., it would be useless. As shown by Collares-Pereira et al [1984] this storage size is actually close to the optimum; hence we shall assume a storage mass

To determine the flow rate m through the collector we note that the collector is to supply hot water both to the process, at rate mload and to storage.

348

Active Solar Collectors and Their Applications

If the tank is to just fill up during the operating period, then the net inflow m — rn\0aa into the tank must be equal to Af/rop. This fixes the collector flow rate in terms of storage mass M as

If the flow rate were larger, hot water would be discarded at the end of the day, while smaller flow rates would leave the top of the tank unused. If the collector area is A, then the annual collected solar energy is, by Eq. (12.3.5),

The net useful energy Q delivered by the system during the year is obtained by subtracting losses from storage <2loss and any excess energy QAumv (if any) that cannot be utilized,

In well designed systems Qloss is a few percent of Q; hence it need not be calculated very accurately. For example, if Q]oss is 5% of Q, then a 20% error in doss causes only a 1% error in Q, such a small error is insignificant. Hence we estimate <2ioss by considering the steady state heat loss from the storage tank. The average tank temperature at the end of an average day's energy collection rslor can be obtained from the daily energy balance of the tank. Since the daily water flow through the collectors is mrop the water mass M collected in the tank by the end of the day represents a fraction M/(rhTop) of the total water flow. All the water from the collectors passes through the tank, where it is mixed. Therefore the fraction M/(rarop) of the water flow approximately equals the fraction of the daily collected energy Gx>n/365 that is in the storage tank at the end of the day. Thus one obtains the energy balance of the storage tank as

where c = 4186 J/(kg K) is the specific heat of water, (2coll is in GJ/yr, Mis in kg, rop is in sec/day, and m is in kg/sec. _ Using Eq. (12.3.23), we readily solve for Tstm. If the tank is located in an environment at average temperature Tenv then the annual loss from storage is approximated by

Applications

349

where (UA) slm is the effective tank surface-heat transfer coefficient of the tank [in W/°C]. To complete the calculation of Q we need to know the excess energy Qdump. If the collector area is sufficiently small in relation to the load then no energy dumping will ever occur and the calculation is complete. Before worrying about energy dumping, it is advisable to check how large the collector area can be without exceeding the upper tolerance temperature of collector or heat transfer fluid during periods of peak insolation. Typically one wants to keep the collector outlet temperature below 90-95°C to prevent boiling in the collector. Suppose the peak outlet temperature is specified as Tmax, corresponding to peak insolation 7max. Then the largest permissible collector area Amm is given by the instantaneous energy balance

where Fin is evaluated at A = Amm. Inserting Eq. (12.3.3) for F-m and solving for Am^ one finds

In the single-pass open-loop design with fixed flow rate there are two distinct mechanisms that can cause energy dumping: mass dumping and temperature dumping. Mass dumping occurs if a larger mass of heated water is collected than can be consumed by the process. Our choice of storage mass, Eq. (12.3.21), and flow rate, Eq. (12.3.22), guarantees that mass dumping does not occur, at least if all days have the same operating period. CollaresPereira et al. [1984] find that the effect of mass dumping is negligible even when variations in operating period are taken into account. Temperature dumping occurs if the storage tank temperature exceeds the process temperature. One could minimize temperature dumping by adding a tempering valve and varying the flow from storage to process; this complicates the controls a little. Furthermore the use of a tempering valve will not necessarily solve the problem due to conservation of mass, wherein the heated water not consumed on one day by the load will lead to mass dumping the following day. We opt instead for a choice of collector area that avoids temperature dumping. As a simple criterion, for avoiding temperature dumping, we take the condition

where Adump is the collector area that corresponds to the onset of temperature dumping, and a is a number between zero and unity. As shown by CollaresPereira et al. [1984], proper solution of the problem of temperature dumping

350

Active Solar Collectors and Their Applications

shows that selecting

affords a conservative estimate of Adump; i.e., a lower limit for Adump. Since F-m depends on area, this is not yet the explicit solution for Adump. After inserting Eq. (12.3.3) for F-m with A = Adump, one obtains the explicit result

If A is less than this value then we can safely assume that energy dumping is negligible. Note that energy dumping for a system with storage involves the daily, rather than the instantaneous energy balance. For that reason ^dump for the storage system is different from Eq. (12.3.10). EXAMPLE 12.3.2

Consider an industrial hot water load in Sde Bpker, Israel (latitude = 30.9°N, yearly average daytime beam irradiance 7b = 0.502 kW/m2, and average ambient 2"amb = 18.3°C). The process runs 365 days/yr, 24 h/day, and consumes water from the mains (at a temperature equal to Tamb), heated to a process temperature Tload = 70°C. The flow rate is wload = 1.0 kg/sec. Design a single-pass open-loop system with storage, using a flat plate array with A = 970 m2 and efficiency parameters Fmi)0 = 0.75 and FmU = 5.0 W/ m 2 °C. The storage tank has height = diameter and heat loss coefficient f/stor = 0.5 W/m 2 °C. Calculate the yearly useful solar energy. SOLUTION

From Fig. 11.3.1 we find the correlation

The threshold is X = 0 because 7'in = ramb. Then Eq. (11.3.34) yields the average operating time

With that the storage mass is chosen according to Eq. (12.3.21) as

The collector flow rate is, from Eq. (12.3.22),

351

Applications

Now we transform from Fm to Fin according to Section 4.2, with the result

Before proceeding to the calculation of Q, let us check the upper limits on collector area imposed by temperature limits and energy dumping. With a maximum outlet temperature of 95°C to prevent boiling in the collector, Eq. (12.3.28) yields an upper limit Am^ = 1338 m2. The onset of energy dumping occurs at an area AAump = 1058 m2, by Eq. (12.3.31). Hence we can safely assume that Q dump = 0. The yearly collected energy is, from Eq. (12.3.23),

To find the tank losses we estimate the mean storage temperature from Eq. (12.3.25) (with T i n = ?;mb)as

The tank has radius 1.99 m and surface Aslor = 74.9 m2; hence (UA)slor = 37.5 W/°C. With Eq. (12.3.26) we find an annual tank loss Qloss = 37 GJ, less than 1% of QmH. Thus the final result is, from Eq. (12.3.24),

and the solar fraction is/ = 0.60 of the 24-h load. 12.3.4 Closed-loop configurations If the process fluid is not discarded, one can still employ the basic ideas of the single-pass open-loop design, provided one adds a second storage tank to hold one day's worth of return fluid from the process. This is shown in Fig. 12.3.3. The analysis is the same as for the system of Fig. 12.3.2.

Figure 12.3.3 Single-pass design with two variable volume tanks (From KLutscher et al. [1982]).

352

Active Solar Collectors and Their Applications

With a single storage tank there are two different system configurations, as shown in Figs. 12.3.4 and 12.3.5. For simplicity they are only shown as direct systems, but a heat exchanger can be included between the collector and the rest of the system, just as in the other cases that we have considered. The configuration of Fig. 12.3.4 seems to be the most common. It has usually been the preferred choice in residential applications. This system may be called "multipass" design because it is operated at such high flow rates that the storage volume makes on the order of 5-10 passes through the collector during the course of a single sunny day. The tank has four pipe connections: one inlet-outlet pair for the collector loop and one inlet-outlet pair for the storage loop. This arrangement permits the two loops to operate independently of each other. Thus the collectors can provide heat to storage whether or not the load is withdrawing heat from it. Conversely the load can be supplied from storage regardless of whether the collectors are running. This flexibility is desirable in applications where the load is highly variable, as it is in space heating and domestic hot water. There is, however, a performance penalty associated with this design. Since this system is operated at high flow rates, the tank tends to be more or less mixed. Consequently the collector temperature is higher than the load return temperature. In space heating this penalty need not be too severe because the temperature difference between load supply and load return is usually small. For industrial process heat the multipass design is generally not the best choice. The temperature difference between load supply and load return is usually quite large, and the performance penalty of the multipass design can be severe. Also there is no need for independent operation of the collector and of the load loop, because the load is constant. Thus one can use designs with significantly higher efficiency, either the single-pass open-loop design of Fig. 12.3.2 or the two-pipe storage configuration of Fig. 12.3.5. This configuration has been called "two-pipe configuration" by Kutscher et al. [1982] because only two pipes are connected to the storage tank, in contrast to the four pipes in Fig. 12.3.4. If the flow rate is chosen so that the storage volume makes one pass through the collector on a sunny day and if the tank remains

Figure 12.3.4 Multipass closed-loop design (From Kutscher ctal. [1982]).

Applications

353

Figure 12.3.5 Two-pipe storage configuration. (From Kutscher et al. [1982]).

stratified (as it should since the flow is slow), the performance is essentially equal to that of the single-pass open-loop design. As for the performance analysis, the multipass design can be treated with the 0,/chart method of Section 11.5. Since the multipass design has been so popular, we present a numerical example that quantifies the performance penalty relative to a single-pass design. EXAMPLE 12.3.3

Consider the same application as in Example 12.3.2, but designed according to the multipass configuration of Fig. 12.3.4 with a flow rate per collector area rh/A = 0.015 kg/sec m2 (as recommended for this design in Table 12.1.1), about 6 times larger than in Example 12.3.2. Take the same collector area A = 970 m2 and the standard storage capacity of 75 kg water per m2 of collector. (Note that this implies a total storage mass of 72,750 kg, much larger than the 49,800 kg employed in the single-pass design of Example 12.3.2.) The collector is the same as in Example 12.3.2; it has parameters F,,Mo — 0.75, FmV = 5.0 W/m2 °C and average incidence angle modifier K = 0.92. SOLUTION

As pointed out by Pearson, Klein, and Duffle [1981], the performance of this system type can be calculated not only by the general $, /chart method, but if the system parameters are in the range of the original /chart method one may use the /chart for water heating. In this example the parameters (in particular, the storage size and the water temperature) are indeed compatible with the/chart and hence we use the/chart because it is simpler. The monthly results are listed below in tabular form. Hh is the daily average hemispherical solar irradiation on the horizontal. The daily average irradiation H on the aperture is calculated according to Eq. (11.4.1) with cutoff time tc = ts. The parameters A} and Yf of the /chart correlation are obtained from Eqs. (12.2.1) and (12.1.2), respectively. Adding up the monthly sola energy one finds a solar fraction / = 0.48 for the year.

354

Active Solar Collectors and Their Applications

Jan. Feb. Mar. Apr.

May Jun. Jul. Aug. Sep. Oct. Nov. Dec.

7Iamb fC)

77h (MJ/m 2 )

H (MJ/m 2 )

9.6 11.6 13.6 17.0 20.9 24.2 24.8 25.3 23.6 20.6 16.0 11.4

11.9

16.8 18.3 19.4 21.9 23.1 25.0 24.8

14.4 17.5 22.0 25.3 28.8 28.0 25.9 22.1 17.8 13.9 10.3

Yearly/' 0.479

24.7

23.5 21.6 19.1 14.9

xf 3.18 3.08 2.98 2.80 2.60 2.43 2.40 2.37 2.46 2.61 2.85 3.09

Y

f 0.60 0.65 0.69 0.78 0.82 0.89 0.89 0.88 0.84 0.77 0.68 0.53

./load

/

(GJ per mo)

0.346 0.391 0.426 0.499 0.537 0.593 0.589 0.589 0.555 0.500 0.425 0.298

201 205 248 280 312 333 342 342 312 291 239 173

Yearly solar energy [GJ] 3277.47

By comparison the single-pass open-loop design of Example 12.3.2 yielded an annual solar fraction of 0.60, which is 25% higher even though it uses less storage; for the same storage, the difference in solar fraction would be even larger. One key reason for the thermal superiority of the one-pass open-loop design is the fact that all energy stored on a given day is depleted by the nighttime load by collector turn-on time the following day. The more conventional system design, with mixed storage, can never fully deplete the energy stored on a given day by collector turn-on time the following day. The single-pass open-loop design has an additional advantage that does not show up in a comparison with/chart or 0,/chart results because transients are neglected. In a single-pass design penalties due to collector warmup and cool-down are much smaller than in a multipass design because the collector operates at lower inlet temperature and any heat above Tm is useful since the solar system acts as preheater only. The low flow rate has another benefit beyond the comparison of thermal efficiency. In multipass systems the parasitic power consumption for pumping has been found to represent typically 3%-10% of the collected energy. Since pumping energy is supplied as electricity, its cost can easily eat up a sizable portion of the energy savings from solar heat. 12.4 CENTRAL HEAT COLLECTION In large solar process heat installations and solar thermal power plants the transport of heat to a central point of use raises some problems. Basically there are two approaches: either an array of distributed thermal collectors, from which heat is brought to a central point by means of a piping network; or else the optical transport of energy in a central receiver. Choosing the best approach for a given application may involve complicated trade-offs between collector costs, piping costs, collector spacing, optical losses due to

355

Applications

shading, heat losses, etc. For example, by placing the collectors very close together one minimizes piping costs and piping losses, but at the price of poor optical performance due to shading. There are, however, some simple general recommendations that have emerged from many detailed studies. The higher the temperature, the higher the cost and the losses of a heat collection network. This gives the central receiver approach a clear advantage at high temperatures. To be more quantitative we summarize the results of a study by lannucci [1980]. In this work, parabolic trough, parabolic dish, and central receiver systems were compared for industrial process heat applications at three temperatures: 93°C, 149°C, and 316°C. System size ranged from 3-1500 MW, for each. Each system was optimized to deliver heat at the lowest possible cost. The results are summarized in Tables 12.4.1 and 12.4.2. Table 12.4.1 gives the cost of the heat centralization network, in $/m2 of collector aperture. A range of values is shown, corresponding to the range of system sizes. Generally the cost increases with temperature. The most striking result is the difference between the three collector types. For the central receiver the heat centralization adds only 0.5-2.5 $/m2 of aperture, while for the dish system it adds 50-100 $/m2. The latter is quite large, considering that total system costs should remain below about 200 $/m2 to be competitive with fossil fuel. The trough system falls in between the dish and the central receiver in this comparison. The piping heat loss results of Table 12.4.2 show a similar trend. For the central receiver they are very small, a fraction of a percent of the collected energy. For the dish, on the other hand, they are in the range of 4% to 20%, increasing with temperature. Again the trough system is intermediate in its losses. The reason for these results is easy to understand from the length of the piping network required in each case. For example, the 1500-MW, system requires roughly 6, 130, and 1000 km of pipe length for the central receiver, the trough, and the dish system, respectively. The central receiver only needs a riser and a downcomer between top and base of the tower. A trough system needs less piping than a dish system because the troughs can be interconnected in a way that requires little additional piping; the troughs themselves are part of the centralization network. In a dish system, on the other TABLE 12.4.1 Thermal Energy Centralization Cost Summary (in $/m2)a Technology

temperature (°C)

Central receiver

Trough

Dish

93 149 316

0.5-1.5 0.5-1.0 1.5-2.5

7-7.5 7-8 10-16

50-55 51-56 69-99

a From lannucci [1980]. All costs in rounded 1979 dollars; the ranges represent variations in system power rating from 3-1500 MW,,,.

356

Active Solar Collectors and Their Applications TABLE 12.4.2 Thermal Losses of Heat Centralization Network, as Percentage of Total Delivered Heata Technology

Temperature (•C)

Central receiver

Trough

Dish

93 149 316

0.05- .15 0.10-0.2 0.30-0.7

0.7-0.9 1.2-1.6 3.6-3.8

3.6- 4.8 5.0- 7.0 16.6-20.4

"From lannucci [1980].

hand, heat is focused at individual points and all these points must be connected by pipes. Of course, the heat centralization network is only one part of the system, and what really matters is the total cost per energy. To some extent the high heat centralization penalties of the dish system are compensated by superior optical performance. As shown by Fig. 3.8.1, the dish, being always normal to the sun, receives about one-third more radiation than the trough. The radiation incident on the heliostats of a central receiver depends on the design details, but generally it is comparable to or even a little less than the radiation incident on parabolic troughs with east-west axis. Which of the three collector types is best for a given process heat application must be decided by weighing the energy centralization penalties of Tables 12.4.1 and 12.4.2 against the cost and energy collection capabilities of the different collectors. In the temperature range up to about 300°C there does not appear to be a clear general favorite at the present time.2 However, for power generation the case is different. While many industrial applications can use heat below 300°C, for power generation one needs far higher temperatures, 500-1000°C, to obtain acceptable system efficiency. The heat centralization penalties in Tables 12.4.1 and 12.4.2 increase so rapidly with temperature that a solar thermal power plant with distributed collectors and central conversion does not appear to be practical. Hence for high-temperature solar thermal power conversion there appear to be only two practical solutions: the central receiver and the point-focus-distributed collector (e.g., dish), with heat engines at the focus of each collector and collection of energy as electricity. 12.5

POWER GENERATION

There are many ways of converting solar radiation to mechanical or electrical power. Some of these (e.g., wind or wave power) involve natural conversion processes. Since this book is concerned with active solar collectors, 2 The comparison between dish, trough, and central receiver looks different if the load is small enough to be satisfied by a single dish or at most a few dishes. In that case the cost of collecting heat is about the same for the dish as for the trough system, and the size may not be large enough to make a central receiver practical. Thus the dish may turn out to be the preferred collector for small high-temperature process heat loads.

357

Applications

we address only photovoltaic and solar thermal conversion schemes. The major options are listed in Table 12.5.1 and discussed below. 12.5.1 Photovoltaics The field of photovoltaics is in a state of flux (e.g., see Sunworld, 1980, 1982; Backus, 1980; Carlson, 1982; Wolf, 1980]. Vigorous research and development programs are in progress in several countries and are producing many new results. There are certainly many unexplored possibilities since the photovoltaic effect can take place in a large number of semiconductor materials and material combinations. At the present time, single crystal silicon cells are the best known and the most developed. But other materials, especially amorphous silicon, cadmium sulfide (CdS), cuprous sulfide (Cu2S), and gallium arsenide (GaAs) may hold more promise for the future. There are two basic approaches towards reducing the cost of photovoltaic electricity, as outlined in Table 12.5.la. One can try to reduce the cost of the cells and deploy them as simple flat plates. Alternatively one can use concentrators to reduce the required area of the cells. Many combinations of cells and concentrator optics have been studied and the consensus has emerged that in the long run the extremes of flat plate and high concentration (C > 100) hold the greatest promise [Bos and deMeo, 1978]. Commercial viability also seems to require that the cell efficiencies be above certain lower bounds, on the order of 10% for flat panels and 25% for cells in concentrators. With lower efficiencies the costs of the nonphotovoltaic system components (land and support structures) would become prohibitive. Currently the efficiency of thin film cells (e.g., amorphous silicon) is around 7%10% for laboratory samples and lower in mass production, but with further TABLE 12.5.la Photovoltaic Power Generation Schemes Cell efficiency [%] Collector type Flat plate

Concentrator

Cell type

Typical

Highest demonstrated

Single crystal Si Polycrystalline Si Amorphous Si, CdS, Cu2S

10-14

18

Best developed

4-6 5-8

10 10

Low-cost thin film cells, probably cell efficiency above 10% needed for commercial success

Single-crystal Si GaAs

15

20 26

High cell efficiency (probably 25%) needed for commercial success; probably best with point focus and high concentration; utilization of waste heat may be practical

Comments

358

Active Solar Collectors and Their Applications

research and development one expects to surpass the 10% hurdle. Cell efficiencies about 25% can be reached with GaAs and with combinations of cells that are matched to different portions of the solar spectrum. From the point of view of systems analysis one needs to understand how the cell output depends on operating conditions. The principal determining factors are cell temperature and insolation level. By contrast to thermal collectors the variation of photovoltaic efficiency with insolation is quite weak: the efficiency increases only logarithmically with insolation.3 For systems calculations one usually assumes a single constant efficiency value corresponding to intermediate insolation levels. The variation of cell efficiency with temperature is quite pronounced and can be approximated by a linear relationship. For a typical silicon cell the temperature variation is characterized by

The temperature variation of cell efficiency for several cell materials can be estimated from Fig. 12.5.1. The dashed curves indicate the theoretical maximum cell efficiency as a function of energy gap for various temperatures. The solid lines show the energy gaps of the most important cell materials. For example, one sees that the maximal efficiency of Si cells decreases from 24% at 273 K to 15% at 373 K. The temperature effect makes it necessary to pay attention to cell cooling. For flat panels cooling by natural convection of ambient air will usually be 3 This logarithmic variation allows the attainment of higher cell efficiencies with concentrators. A cell efficiency of 20% has been demonstrated with a specially designed silicon cell under high concentration [O'Donnell et al., 1978].

Figure 12.5.1 Maximum efficiency as a function of energy gap Ex for various temperatures (From Wolf [1980]).

359

Applications

adequate; but for concentrators, active cooling may be required. If there is demand for low-temperature heat, the heat from the cells can be collected and utilized. This cogeneration of heat and electricity can be accomplished both with flat panels and with concentrators. Concentrators are better suited for cogeneration because the heat is already concentrated and the incremental cost of the necessary heat collection equipment is low. 12.5.2 Solar thermal power The foremost constraint on solar thermal power generation is imposed by the Carnot efficiency

where rhigh and Tiow are the absolute temperatures of heat source and sink, respectively. This equation can be taken as guideline for systems considerations because in practice most heat engines can achieve roughly half of the Carnot efficiency.4 Therefore there are two extreme approaches to solar thermal power generation: low-temperature schemes with a cheap or free source of heat, and high-temperature schemes with relatively expensive collectors but high efficiency. Between these extremes lies a spectrum of possibilities as sketched in Table 12.5.1b. 4 At very low-temperature differences the efficiency achievable in practice tends to be lower than this rule of thumb because of the difficulty of transferring heat across very small temperature differences.

TABLE 12.5. Ib Solar Thermal Power Generation Schemes Collector type Ocean Solar ponds

Flat plates, evacuated tubes, collectors with low or intermediate concentration (C < 50) Point-focus high concentration central receiver

Point-focus parabolic dish Fresnel lens

Conversion scheme

Comments

Closed Rankine cycle (ammonia or freon) or open cycle with water Organic Rankine cycle

Very low efficiency but free heat; only practical for baseload power Low system efficiency (—1%) but practical for sunny regions with salt lakes; built-in storage (a few weeks to a few months)

Organic Rankine cycle

Fairly low efficiency; collectors must deliver heat at a fraction of the cost of heat from fossil fuel

Steam Rankine cycle Gas turbine (Brayton cycle)

10 MWe pilot plant operating; utilization of waste heat may be practical (cogeneration)

Stirling cycle

Under development

360

Active Solar Collectors and Their Applications

The surface waters of the tropical oceans reach temperatures of 25-30°C while the bottom, even in the tropics, remains at 4°C. This represents an enormous amount of free and renewable heat that can be converted to electricity. This electricity can be transmitted to shore or used by energy intensive industries on floating platforms. An ocean thermal power plant is under test off the shore of Hawaii. Salt-gradient solar ponds are a source of low cost heat up to the boiling point of water. The system efficiency of a solar pond power plant is on the order of 1 %. This is acceptable if solar ponds can be built at extremely low cost, something that should be possible with salt lakes in sunny regions. A demonstration solar pond power plant (with 150 kWf peak and about 20 kWP average power) is being operated at the Dead Sea in Israel. Solar pond and ocean thermal power plants are unique among solar power plants because they can supply baseload electricity. When solar thermal power plants received widespread attention in the early seventies, many systems were proposed based on organic Rankine cycles powered by flat plates, evacuated tubes, parabolic troughs, or other low- and intermediate-temperature solar collectors. This made sense as long as the cost of point-focus high-temperature collectors was expected to be much higher than that of collectors for lower temperatures. But in the meantime it has become clear that low- and intermediate-temperature collectors will not be sufficiently cheaper than high-temperature point-focus collectors and the latter will be preferable for power generation by virtue of the higher conversion efficiency. The examples in Table 12.5.2 illustrate this point by comparing the use of several collector types for process heat and for power generation: a low-temperature system (r high = 90°C) with flat plate collectors, an intermediate temperature system (rhigh = 300°C), and a high-temperature system (7i,igh = 600°C) with central receiver.5 The first line lists system cost estimates C in $/m2 of aperture area, assuming mass production. The next few lines list thermal efficiency and delivered heat q,, in GJ,/ m 2 of aperture, for a sunny location at midlatitudes. Needless to say, there is some arbitrariness in the choice and performance figures since both are estimates of realistic goals for future technologies. However, the readers will find that the basic conclusion about the ranking of different power options remains unchanged over a wide range of input assumptions. As discussed in Chapter 14 the cost of solar heat is the ratio of system cost C per aperture area [in $/m2] and delivered heat #, multiplied by the annual charge rate ~fa\

For the annual charge rate we take 0.10 in constant currency as a typical value. Similarly the cost of solar electricity is JaC/qt^ where qe is the annual 5

As a reference on central receivers, see, e.g., ASME [1984].

361

Applications TABLE 12.5.2 Cost and Performance Comparison of Hat Plate, Parabolic Trough, and Central Receiver for Process Heat and for Power Generation

1.

2. 3. 4. 5. 6. 7. 8. 9.

System cost, per aperture area ($/m2) Temperature 7"high (°C) Yearly irradiation on aperture (GJ/m2 yr) Yearly average thermal efficiency (%) Annual collected heat per aperture area (GJ,/m2 yr) Cost of heat ($/GJ,) if annual charge rate /cr = 0.10 in Eq. (12.5.3) Electric conversion efficiency (%) taken as lcW2 with rlow = 293 K(20°C) Annual electricity production per aperture area (GJf/m2) Cost of electricity ($/GJe) if annual charge rate /cr =

0.10

Flat plate

Parabolic trough

Central receiver

150 90 8.0 30%

170 300 6.8 50%

190 600 6.5 60%

2.4

3.5

4.0

6.3

4.9

4.8

10%

24%

33%

0.23 64.8

0.86 19.9

1.3 14.3

electricity production, in GJ<,/m2 of aperture area. qe is the product of the heat q, and of the electric efficiency ??<, taken as half of the Carnot efficiency. The results show that while all three collectors can deliver heat at comparable costs [4.8-6.3 $/GJ,], the high electric conversion efficiency puts the central receiver at a clear advantage when it comes to generating power. While the conversion efficiency from heat to electricity in a point-focus collector (33%) is comparable to the efficiency of a fossil-fired power plant, the efficiency of low-temperature solar thermal schemes is very much lower. Thus the latter approach to power generation can be practical only if lowtemperature collectors can deliver heat at a small fraction of the cost of heat from fuel. This is very unlikely. Certainly the flat plate system has such a low electric efficiency as to be uneconomical for any reasonable collector cost. Even for the intermediate-temperature scheme the electric efficiency is fairly low, and hence the parabolic trough appears to be a poor candidate for power generation. REFERENCES Anderson, B. N. and Michal, C. J. 1980. "Passive Solar Design." In Chapter 31, Solar Energy Technology Handbook, Dickinson, W. C. and Cheremisinoff, P. N., editors. New York: Marcel-Dekker. ASME. 1984. The February 1984 issue of the ASME J, Solar Energy Eng. 106:2 103 is devoted to central receivers. Backus, C. E. 1980. "Principles of Photovoltaic Conversion." In Solar Energy Technology Handbook, Dickinson, W. C. and Cheremisinoff, P. N., editors. New York: Marcel-Dekker. Balcomb, J. D. 1980. "Passive Solar Energy Systems for Buildings." In Chapter 16 Solar Energy Handbook, Kreider, J. F. and Kreith, F., editors. New York: McGraw-Hill.

362

Active Solar Collectors and Their Applications

Beckman, W. A., Klein, S. A., and Duffie, J. A. 1977. Solar Heating Design by thefchart Method. New York: Wiley-Interscience. Bendt, P. and Soto, R. 1980. "Home Owner's Solar Sizing Workbook." Golden, CO: Solar Energy Research Institute. Bos, P. B. and deMeo, E. A. 1978. "Perspectives on Utility Central Station Photovoltaic Applications." Solar Energy 21:177. Butti, K. and Perlin, J. 1980. The Golden Thread. New York: Van Nostrand-Reinhold; also, 1980. "The History of Terrestrial Uses of Solar Energy." In Chapter 1, Solar .Energy Handbook, Kreider, J. F. and Kreith, F. editors. New York: McGraw-Hill. Carlson, D. E. 1982. Press Conference, 26 February. RCA. Collares-Pereira, M., Gordon, J. M., Rabl, A., and Zarmi, Y. 1984. "Design and Optimization of Solar Industrial Hot Water Systems with Storage." Solar Energy 32:121. Duffie, J. A. and Beckman, W. A. 1980. Solar Engineering of Thermal Processes. New York: John Wiley & Sons. Duffie, J. A., Beckman, W. A., and Mitchell, J. W. 1980. "Solar Cooling." In Chapter 30, Solar Energy Technology Handbook, Dickinson, W. C. and Cheremisinoff, P. N., editors. New York: Marcel-Dekker. Duffie, J. A. and Mitchell, J. W. 1983. "F-Chart: Predictions and Measurements." ASME J. Solar Energy Eng. 105:3. Engebretson, C. D. 1964. "The Use of Solar Energy for Space Heating—M.I.T. Solar House IV." In Proc. of the UN Conference on New Sources of Energy, Vol. 5, p. 159. Faiman, D., Gordon, J. M., and Govaer, D. 1979. "Optimization of a Solar Water Heating System for a Negev Kubbutz." Israel J'. Technol. 17:19. Fanney, A. H. and Lin, S. T. 1979. "Experimental System Performance and Comparison with Computer Prediction for Six Solar Domestic Hot Water Systems." In Proc. of the 1979 International Congress of the International Solar Energy Society, Atlanta, GA. Farrington, R., Murphy, L. M., and Noreen, D. 1980. "An Analysis of Solar Domestic Hot Water Systems from a System Perspective." In Proc. of the 1980 American Section International Solar Energy Society Meeting, Vol. 3.1, p. 162, Phoenix, AZ. Gordon, J. M. and Zarmi, Y. 1981. "Thermosyphon Systems: Single vs. Multi-Pass." Solar Energy 27:441. Gordon, J. M. and Rabl, A. 1982. "Design, Analysis and Optimization of Solar Industrial Process Heat Plants Without Storage." Solar Energy 28:519. Govaer, D. and Zarmi, Y. 1981. "Analytical Evaluation of Direct Solar Heating of Swimming Pools." Solar Energy 27:529. Govaer, D. 1984. "Determining the Solar Heating of Swimming Pools by the Utilizability Method." Solar Energy 32:667. Grunes, H., deWinter, F., and Kittle, L. 1982, "Solar Augmented Gas-Fired Water Heater." Sunworld6(l):16. Hay, H. R. and Yellot, J. I. 1970. "A Naturally Air Conditioned Building." Mech. Eng. 92(1): 19. Harrigan, R. W. 1980. "Total Energy Systems Design." In Chapter 32, Solar Energy Technology Handbook, Dickinson, W. C. and Cheremisinoff, P. N., editors. New York: Marcel-Dekker. lannucci, J. J. 1980. "Thermal Energy Centralization Networks: Design, Cost and Performance for Dish, Trough and Central Receiver Systems." In Proceedings of

Applications

363

the 1980 American Section of International Solar Energy Society Meeting, Vol. 3.1, p. 44, Phoenix, AZ. Karaki, S., Armstrong, P. R., and Bechtel, T. N. 1977. "Evaluation of a Residential Solar Air Heating and Nocturnal Cooling System." Report COO-2868-3. U.S. Department of Energy. Karaki, S., Duff, W. S., and Lof, G. I. G. 1978. "A Performance Comparison Between Air and Liquid Residential Solar Heating Systems." Report COO-2868-4. U.S. Department of Energy. Kirkpatrick, D. K., Masoero, M., Rabl, A., Roedder, C. E., Socolow, R. H., and Taylor, T. B. 1983. "The Ice Pond—Production and Seasonal Storage of Ice for Cooling." Report CEES 149. Center for Energy and Environmental Studies, Princeton University, to be publ. in Solar Energy. Klein, S. A. and Beckman, W. A. 1979. "A General Design Method for Closed-Loop Solar Energy Systems." Solar Energy 22:269. Kreider, J. F. and Kreith, F. 1982. Solar Heating and Cooling, 2nd ed. New York: McGraw-Hill. Kutscher, C. F. 1981. "Design Considerations for Solar Industrial Process Heat Systems." Report SERI/TR-632-783. Golden, CO: Solar Energy Research Institute. Kutscher, C. F., Davenport, R. L., Dougherty, D. A., Gee, R. C., Masterson, P. M., and May, E. K. 1982. "Design Approaches for Solar Industrial Process Heat Systems." Report SERI/TR-253-1356. Golden, CO: Solar Energy Research Institute. Lof, G. O. G. et al. 1964. "Design and Performance of Domestic Heating System Employing Solar Heated Air—The Colorado House." In Proc. of the UN Conference on New Sources of Energy, Vol. 5, p. 185. Mertol, A., Place, W., Webster, T., and Greif, R. 1981. "Detailed Loop Model Analysis of Liquid Solar Thermosyphons with Heat Exchangers." Solar Energy 27:367. O'Donnell, D. T., Robb, S. P., Rule, T. T., Sanderson, R. W., and Backus, C. E. 1978. Arizona State University Report. Pearson, K. A., Klein, S. A., and Duffie, J. A. 1981. "Generalized 0, f-chart Design Method for Solar Hot Water Heating Systems." American Section oflSES Meeting, Philadelphia, PA. Rabl, A. 1981. "Direct Solar Industrial Process Heat." Report CEES 118. Princeton, NJ: Center for Energy and Environmental Studies, Princeton University. Rabl, A. and Nielsen, C. E. 1975. "Solar Ponds for Space Heating." Solar Energy 17:1. Shelpuk, B. 1978. "Proc. of the Desiccant Cooling Conference." Report SERI 22 (1978). Golden, CO: Solar Energy Research Institute. Sillman, S. 1981. "The Trade-off Between Collector Area, Storage Volume, and Building Conservation in Annual Storage Solar Heating Systems." Report SERI/ TR-781-907. Golden, CO: Solar Energy Research Institute. Supple, R. G. 1982. "Evaporative Cooling for Comfort." ASHRAE J. (August):36. Sunworld. 1980, 1982. Special issue on solar photovoltaics, Sunworld4(1) (1980) and 6(3) (1982). Wolf, M. 1980. "Photovoltaic Solar Energy Conversion Systems." In Chapter 24, Solar Energy Handbook, Kreider, J. F. and Kreith, F., editors. New York: McGraw-Hill. Wang, Y. F., Li, Z. L., and Sun, X. L. 1982. "A Once-Through Solar Water Heating System." Solar Energy 29:541. Vitro Labs. 1981. "National Solar Data Program Performance Results." Report SOLAR/0005-81. Silver Spring, MD: Automation Industries, Inc., Vitro Labs Div.

13. PRACTICAL CONSIDERATIONS

Experience is the name everyone gives to their mistakes. Oscar Wilde

The best design is of little use if it is built improperly or with inappropriate materials. The requirements for materials are severe. Collectors are outdoors, exposed to wind, rain, hail, frost, ultraviolet radiation, and dirt. They experience thermal cycling, not only between day and night but in irregular intervals due to clouds. They should perform well over a long time span, preferably at least 10-20 years. And of course the cost should be low. Finally the system must be installed correctly. Even though many components of a solar energy system are familiar from other applications, such as conventional space conditioning or industrial processes, one cannot always rely on experience gained elsewhere. Solar technologies are sufficiently new and unfamiliar that a great deal of learning and experience is required before these technologies can be considered mature. This has been one of the lessons of the solar demonstration projects in the U.S. The sort of problems that were encountered'may be highlighted by that famous story about a flat plate collector imported from Australia to the U.S. The instructions said "Install facing due north," and for once the installers followed all the instructions. .. . The past decade has provided much experience about the practical problems of solar equipment. Engineers and technicians have been trained for solar jobs, and hopefully the errors of the past will be avoided in the future. Much has been written about the practical aspects of solar energy. Within the scope of this book we can present only a brief summary. More can be found in the references at the end of this chapter; in particular, Kutscher [1981] and Kreider and Kreith [1982]. Materials are discussed in Section 13.1, installation problems in Section 13.2, and maintenance in Section 13.3. 13.1

MATERIALS

13.1.1 Absorber

The absorber should have as high an absorptivity for solar radiation as possible, and it should conduct the absorbed heat efficiently into the heat trans364

Practical Considerations

365

fer fluid. Most absorber materials do not have a very high absorptivity, and they need to be covered with special solar coatings. A large number of combinations of coatings and substrates is possible. The absorber substrate must be compatible with the heat transfer fluid, and it must resist corrosion. It must be able to withstand not only the temperature swings of normal operation, but also stagnation conditions (unless some other protection against overheating is provided; e.g., defocusing or shading in case of pump failure). How important the thermal conductivity of the absorber material is depends very much on the design of the collector. In many flat plate collectors the fluid flows through tubes that are bonded to an absorber sheet. Since the tubes are some distance (on the order of 10 cm) apart, good conductivity of the absorber sheet is important. For this design, copper is the preferred material for its high conductivity and corrosion resistance; unfortunately it is also expensive. In typical collectors the fin efficiency of the copper plate is on the order of 95% relative to a plate with infinite conductivity. Aluminum offers fairly high conductivity at a lower cost, but most manufacturers have avoided it because of its susceptibility to corrosion. Of course the bonding between tubes and plate should provide good thermal contact. The conductivity of the absorber material is not critical in designs where the fluid flow reaches the entire absorber area. For example, in a parabolic trough with tubular receiver the heat needs to travel only through the wall of the tube, and with any reasonable material the resistance across the tube wall is small compared to the resistance from the inner tube surface to the bulk of the fluid. (High circumferential conductivity may be desirable to minimize differential heating of tube top and bottom; however, this can also be achieved by making the fluid spiral through the tube.) Similarly the conductivity of the absorber material does not matter in flat plate air collectors, where the air flows past the entire absorber plate. The effect of absorber conductivity on collector efficiency has been illustrated quantitatively by the examples in Section 10.2. The absorptivity a of the absorber coating for solar radiation should be as high as possible. On the other hand one would also like to minimize heat losses by having a low emissivity e for thermal radiation at typical absorber temperatures. Of course KirschhofPs law says that at any one wavelength X, the spectral absorptivity ax must equal the spectral emissivity ex. However, the thermal radiation emitted by solar collectors is contained mostly in the wavelength range above 2 nm while most of the solar spectrum has wavelengths shorter than 2 /urn. This fact allows the possibility of so-called selective absorbers with high absorptance a (integrated over the solar spectrum) and low emittance «(integrated over the thermal spectrum). An ideal selective absorber would have «x - 1 for X < 2 pm and ex = 0 for X > 2 ^ m. The exact value of the ideal cutoff wavelength depends on collector temperature; the value of 2 ^m is approximately optimal. In practice quite a few selective coatings have been developed with « around 0.95 and e around 0.1. The spectral absorptivity for a typical selective coating, black chrome, is

366

Active Solar Collectors and Their Applications

shown by the solid line in Fig. 13.1.1. Nonselective coatings (e.g., ordinary black paints) have a ~ e = 0.95. Some of the most important absorber coatings are listed in Table 13.1.1. For a given solar absorptance a the performance of a collector is always improved if one reduces e. But in practice one does not have the freedom to choose a and e independently; rather, a given coating comes with a given a and t. For some coatings (e.g., black chrome), one can vary a andeby varying the deposition process. Usually an attempt to raise a causes also an increase in e, and careful fine tuning of the coating process is needed to find an optimal coating. The choice of the optimal coating for a given application involves a trade-off between optical and thermal losses.' As a general rule a should be at least 0.85, preferably above 0.90. The performance benefit of selective coatings is greatest in evacuated collectors; in fact if one goes to the trouble of evacuating a collector, then one should also use a selective coating with a low emissivity. In nonevacuated collectors convection begins to dominate if e is reduced below a certain value (0.2-0.5 depending on temperatures and absorber design). In a flat plate collector, for example, the heat loss is reduced dramatically if e is reduced from 0.95 to 0.3, but a further reduction in e from 0.3 to 0.1 brings 'Sometimes the ratio a/e has been used as a ranking index for selective coatings. However, it determines only the stagnation temperature of a surface in vacuum. For practical solar applications the ratio aft by itself is irrelevant.

Figure 13.1.1 Wavelength correlation between solar spectrum, thermal spectrum (100°C And 300°C), and spectral reflectivity of selective surface. Solid line shows black chrome (From Lampert and Washburn [1979]).

TABLE 13.1.1 Properties of Absorber Coatings Material

Type

Supplier/ developer

Absorptance

Emittance

Temperature stability (°C)

Pyromark PbS pigment with silicon binder

Paint Paint

Tempi! Experimental

0.95 0.90

0.85 (500°C) 0.37

750 350

Copper-chromium oxide pigment, ethylene-propylene diene monomer binder

Paint

Harshaw Chemical (pigment) Exxon (binder)

0.92-0.94

0.30-0.45

—

Solkote Hi/Sorb-I

Paint

Solar Energy Corporation

0.95

0.45

870

Black chrome

Electrodeposited

Many

0.94-0.96

0.20-0.25 (300°C)

300

Black nickel (Tabor black) Black copper

Miromit Electrodeposited Chemically Ethone, Inc. deposited

0.91

0.14

—

0.88-0.91

0.12-0.20

190

Comments Expected life less than 2 yr; may require repainting of local hot spots Durability expected to be better than acrylic paint; estimated life less than 5 yr Manufacturer's data for lab application on Al Estimated life greater than 30 yr — Sensitive to humidity

References a b, c

b

a, b

a

b

TABLE 13.1.1 Properties of Absorber Coatings (continued) Material Alcoa black

Type

Absorptance

Emittance

Temperature stability (°C)

0.90

0.30-0.40

175

Seraphin and Carver

0.91

0.11 (at 500°C)

500

University of Sydney

0.92

0.05 (at 120°C)

—

Chemically Alcoa deposited

Chemical vapor deposited Graded metal-carbon Sputtered on copper Silicon nitride over molybdenum

Supplier/ developer

Comments

References

Estimated life greater than 10 yr; coating destroyed by water Withstood 1000 h at 500°C, 1 torr vacuum

b

—

e

d

"Call [1979]; bVresk [1981]; cKreider and Kreith [1982]; dSeraphin and Carver [1979]; 'Harding and Window [1980] and Harding and Moon [1981].

Practical Considerations

369

only a small benefit. Therefore the selective paints with their low cost look especially attractive for flat plates. The optimal choice of an absorber coating depends not only on collector efficiency but also on cost and durability. Generally, paints are cheaper and easier to apply than coatings deposited by chemical or electric processes. As Table 13.1.1 shows, there are quite a few coatings that can be used up to about 200°C, but at high temperatures durability becomes a problem. Black chrome, a favorite because of performance and durability, begins to degrade above 350°C. For temperature stability the Solkote coating looks particularly impressive: it has a = 0.95, e = 0.45, and a temperature limit of 870°C. The higher the operating temperature, the more difficult it is to achieve selectivity. Not only does material degradation become more severe a problem at high temperature, but the emissivity increases with temperature; furthermore, the overlap between solar and thermal radiation spectra becomes greater. Some sophisticated multilayer coatings have been developed that maintain high selectivity up to SOOT; in particular, a coating by Seraphin and Carver [1979] with « = 0.91 and « = 0.11 at 500°C. Above 500°C no coatings with high selectivity are presently available. Many factors influence the durability of absorber coatings. Paints, in particular, are sensitive to ultraviolet radiation and thermal cycling, and they may crack and separate from the absorber substrate. Water vapor and atmospheric contaminants may cause degradation. For example black nickel degrades when exposed to high humidity at high temperature. Freon-blown insulating foams next to the absorber may release hydrofluoric and hydrochloric acid, causing corrosion of the absorber. The absorptivity of a solar absorber can be enhanced by using the cavity effect; i.e., shaping the absorber as a cavity or cavities or texturing its surface. The cavity effect decreases the selectivity of a selective absorber because the small emissivity is enhanced more than the absorptivity which is already large to begin with. A good analysis of the cavity effect can be found in Sparrow and Cess [1978]. 13.1.2 Cover Most collectors have a transparent cover in front of or around the absorber to reduce heat losses. In some collectors multiple glazing is used to reduce heat losses even more. The heat loss could also be reduced by selective coatings, evacuation, or concentration; which approach is most cost effective depends on many factors. In practice one rarely uses more than two covers. The ideal cover is a transparent insulator; it has high transmittance for solar radiation, low transmittance for thermal radiation from the absorber, high durability, sufficient strength and low cost. The properties of the most common glazing materials are listed in Table 13.1.2. Optical losses of the glazing are due to reflection at the glazing surfaces and due to absorption inside the glazing material. The reflection lossdepends on incidence angle and on index of refraction and is given by Fres-

TABLE ! 3.1.2 Properties of Cover Materials3

Material Soda lime float glass Water white low-iron glass Fiberglass reinforced polyester (Sunlite) Acrylic (plexiglass) Polycarbonate (Lexan) Polytetrafluoroethylene (Teflon) Polyvinyl fluoride (Tedlar) Polyester (Mylar) Polyvinylidene fluoride (Kynar) Polyethylene (Marlex)

Index of refraction

Short wave transmittance (0.4-2.5 M)

Long wave transmittance (2.5-40.0 M)

Density (kg/m3)

Thickness (mm)

Maximum temperature (°C)

1.52 1.52 1.54

0.84 0.90 0.87

0.01 0.01 0.076

2500 2473 1399

3.175 3.175 0.635

232 204 NA

5.4 10.6 NA

1.49 1.586 1.343

0.90 0.84 0.96

0.02 0.02 0.256

1189 1199 2148

3.175 3.175 0.0508

93 121 NA

9.0-13.0 24.0-31.0 NA

1.46 1.64 1.413

0.92 0.87 0.93

0.207 0.178 0.230

1379 1394 1770

0.1016 0.1270 0.1016

66 NA NA

0.60 NA NA

1.500

0.92

0.810

910

0.1016

NA

NA

"Adapted from Butler and Claassen [1980] and Jorgenson [1979]. NA = not available.

Cost (in 1979 dollars, $/m2)

Practical Considerations

371

nel's equation, Eqs. (5.2.4) and (5.2.5). Almost all glazing materials for solar collectors have an index of approximately 1.5 and the corresponding reflective loss at normal incidence is 4% per surface or 8% per glazing. Teflon has the lowest index of refraction, 1.34, and the highest solar transmittance, 96%. Absorption losses depend on extinction coefficient and thickness according to Bouguer's law, Eq. (5.2.15). Ordinary window glass (soda lime glass) has high absorption losses because of its iron content. Its overall solar transmittance of 84% for 3 mm thickness is undesirably low. Low iron glass has almost no absorption loss but it is more expensive. Actually it is not so much the iron content itself that matters as the nature of the iron bond since Fe2+ ions absorb much more strongly than Fe3+ ions. Hence one can cut absorption losses by reducing the concentration of Fe2+ ions rather than eliminating iron altogether. For example, Corning 0317 fusion glass has good transmittance despite high iron content [Vitko, 1978]. Many plastics have some absorptivity for the infrared portion of the solar spectrum. Borosilicate glass is excellent; it is stronger than soda lime glass and much more resistant to thermal shock. Its absorption coefficient for solar radiation is very low. Unfortunately it is relatively expensive.2 Two comments must be added to the solar transmittance values in Table 13.1.2. First, these values refer to normal incidence; at larger incidence angles the transmittance is smaller. (See Fig. 5.2.4.) Second, these transmittance values are for total as opposed to specular transmittance. In a flat plate collector only the total transmittance is of interest since the scattered rays also reach the absorber. Even textured glass can be used. On the other hand for a cover of a focusing collector (e.g., an inflated plastic dome enclosure for lightweight heliostats or parabolic dishes) the specular transmittance is relevant, and it may be significantly lower than the values in Table 13.1.2. Surface scratching has little effect on total transmittance but it can seriously reduce the specular transmittance. The infrared transmittance affects radiative heat losses from the absorber. Glass and thick layers of plastic transmit little or no thermal infrared. The thin plastic films are far less effective in blocking infrared. The importance of that point depends on collector design and application, in particular on the emissitivity of the absorber. If the absorber has a low emissivity then radiative losses are small anyway and it does not matter very much whether this radiation goes to cover or to ambient. Table 13.1.2 also lists density, thickness, maximum temperature, and cost of the glazing materials. Of crucial concern is the durability. In this regard glass is unsurpassed, with the possible exception of breakage from thermal shock, hail, and vandalism. But even the risk of breakage can be greatly reduced by tempering [Vresk, 1981]. Glass is hardly affected by ultraviolet radiation and it is very scratch resistant. The durability of glass as collector cover is highlighted by 2 At the present time borosilicate glass is used in the evacuated tubes sold by Owens-Illinois and by Sunmaster, while the evacuated tubes of General Electric are made of soda lime glass.

372

Active Solar Collectors and Their Applications

Jorgensen [1979], who found that samples of 20-40-year-old glass from south facing windows showed less than 2% decrease in transmittance compared to unexposed glass from the same windows. Results of some aging tests are summarized in Table 13.1.3 [Vresk, 1981]. Several cover materials were exposed for 1-3 years in three locations: Chicago, IL, Miami, FL, and Phoenix, AZ. For glass the data indicate slight increase of solar transmittance with time; this is difficult to believe and may be an indication of uncertainties in these measurements. In any case, the durability of glass is excellent, and the transmittance can be maintained at the original value over the lifetime of the collector. The next most durable glazing is acrylic (also known as Plexiglas) provided it contains ultraviolet (UV) stabilizers; i.e., small amounts of UV-absorbing pigments. Lifetimes of acrylic collector covers are estimated to be in the range of 5-10 years. TABLE 13.1.3 Results of Aging Test for Collector Glazing3 Transmittance (%)

Material

Initial

Chicago

Miami

Phoenix

Exposure time (mo)

Self-supporting Regular float glass (% in., Libby-Owens-Ford)

82.6

83.8

84.0

85.1

32

Indefinite

Plexiglass (% in.-thick molded acrylic; Rohm and Mass V-100 type 045)

87.4

86.4

87.7

88.0

35

5-10

Polycarbonate with clear protective coating (Ye in., Mobay "Merlon")

82.8

NA

78.6

73.3

33

Less than 8

87.5

NA

67.3

76.9

32

2-7

990.7

78.8

86.0

88.7

24

2-5

Polyester (3M Scotchpar* 10; 0.002 in.)

86.9

86.0

83.4

NA

12

1.5-2

Vinylidenefluoride homopolymer (0.0038 in., Kynar 450, Penwalt Corp.)

82.5

78.6

81.1

81.6

33

1-5

Value after exposure at

Plastic film Fiberglass-reinforced modified polyester sheet (Kalwall "Sunlite Premium"; 0.04 in.) Thin film plastics Polyvinyl fluoride (0.004 in., DuPont Tedlar)

"From Vresk [1981]. NA = not available.

Estimated life (yr)

Practical Considerations

373

Polycarbonate, also known as Lexan, showed significant deterioration in these tests. The thin film plastics in this table maintained their transmittance reasonably well. Degradation may be aggravated by environmental pollutants, by humidity, and by elevated temperature, thermal cycling, or flapping in the wind. Thin films may have problems with sagging. At the present time there is still much uncertainty about the use of plastic covers in solar collectors. The most reliable plastic, acrylic, offers no cost advantage over glass. The thin films can be significantly cheaper in first cost, but they may have to be replaced after several years. Thus it is not surprising that so far almost all commercial collectors have used glass covers. This situation may well change with further research and development in the chemical industry. This process takes time because of the need for long term outdoor testing of collector materials. But if plastic films with high transmittance and long life are developed, the cost reductions of solar collectors could be very significant [Atkinson and Caesar, 1983]. Another area for progress lies in coatings. Two kinds of coatings are of interest for collector covers: antireflection (AR) coatings and infrared reflecting coatings, also known as heat mirrors. Coatings of tin and/or indium oxide are examples of the latter. They can be added to glass and they have been tested in solar collectors. In their effect on collector performance they are equivalent to selective absorber coatings. The main drawback of the heat mirror/coatings known so far is their low solar transmittance, caused by a high index of refraction. A typical heat mirror with a nonselective absorber will be equivalent to a selective absorber with e around 0.1 and a around 0.8-0.85. Selective absorbers offer better performance at lower cost. This might change as a result of further research; e.g., by combining AR coatings with a heat mirror. The principal advantage of a heat mirror is that the absorber can get very hot without degradation of the selectivity. Antireflection (AR) coatings are produced by adding a layer with an index of refraction intermediate between air and cover material. Ideally the intermediate layer should have an index equal to the square root of the index of the cover, and its thickness should be one quarter wavelength. Several lowcost AR coatings are available for solar collectors. Etching by hydrofluoric acid can produce a gradual transition in the refractive index at the surface of glass. Reflection losses can easily be reduced below 1% per glass/air interface [Peterson and Ramsey, 1975]. This type of etching is microscopically fine and does not increase the sensitivity to dirt or dust [Vresk, 1981]. Thin films of polymers with appropriate index of refraction can also provide lowcost AR coatings. A reduction of reflection losses from 6% to 0.50% at 550 nm has been reported with a coating of this type by Beauchamp [1975]. 13.1.3

Reflector

Reflectors for solar collectors should have as high a reflectivity as possible. Furthermore the reflectors should be highly specular since scattered radiation is likely to miss the absorber. Only collectors with very low concentra-

374

Active Solar Collectors and Their Applications

tion (side reflectors, V-troughs, and CPCs) can use reflectors with relatively low specularity, provided the total reflectance is high. Apart from total internal reflection there are only two practical materials with sufficiently high specular reflectivity to be suitable for solar reflectors: aluminum and silver (Fig. 13.1.2). Uses for total internal reflection in solar collectors are limited; some possible designs have been analyzed by Winston [1976], Rabl [1978], and Smestad and Hamill [1982]. A pure polished aluminum surface has a solar reflectance of 0.90, while polished silver has 0.96. Both silver and aluminum must be protected from the environment; otherwise the reflectance would rapidly deteriorate to unacceptable levels. Unprotected aluminum tarnishes less rapidly because upon contact with air, aluminum immediately develops a thin transparent oxide coating that inhibits further oxidation; however, this coating is not enough to protect against the moisture and pollutants found in most environments. To protect the reflector surface, one places the aluminum or silver layer behind a transparent cover of glass or plastic. This is called a second surface reflector by contrast to a first surface reflector, where the aluminum or silver are directly exposed. The back of a second surface solar reflector must also be protected, but that is relatively easy because one can use opaque coatings. First surface aluminum or silver reflectors can be used in a vacuum, e.g., in the shaped tube CPC collector of Fig. 1.3.6b. The protective oxide layer of an aluminum sheet can be enhanced by an anodizing process to the point where aluminum can be used as first surface reflector outdoors. Aluminum sheets of this type are sold under the tradenames Alzak or Kinglux and are frequently used for lighting and interior decorating. Outdoors they survive quite well in dry unpolluted environments, but in other areas they may tarnish within years or even months. Most reflectors that are exposed to the elements will probably be second

Figure 13.1.2 Spectral dependence of hemispherical reflectivity (From Seraphin and Meinelf 1976]).

Practical Considerations

375

surface reflectors. Glass provides the best protection, but it is rigid and fragile. Most concentrators need curved reflectors, and curving glass can be a problem. One could shape the glass while it is hot, but such a process is very capital intensive and justifiable only by a large production volume. The problems of shaping cold glass mirrors increase with curvature; the stresses induced in the glass make it more susceptible to breakage. In this regard a plastic film like acrylic looks much better. In fact quite a few manufacturers offer solar reflector sheets consisting of aluminized plastic films with adhesive backing. They are easy to handle and to attach to a shaped substrate. The main problem with these plastic reflector foils is durability. The plastic surface scratches easily and loses specular reflectivity. Also, pollutants may reach the metal surface through scratches or pinholes and corrosion will set in. Silver reflectors with plastic coating seem to be particularly vulnerable; so far none have been developed that hold promise of surviving outdoors for 20 years. Absorption in the cover material causes another problem with second surface reflectors. In mirrors with ordinary window glass the absorption is too large to be practical (note that the path of a light ray through the glass is twice the thickness, divided by the cosine of the incidence angle in the glass). Hence one needs either low-iron glass or very thin glass, 1 mm or less in thickness. The latter, also called microsheet, looks most promising for the future. Since microsheet by itself is extremely fragile, one needs to bond it to a thin plastic substrate. Such a sandwich of microsheet glass, silver, and plastic substrates could be rolled and unrolled easily. It combines the highest possible reflectance with durability, and it can readily be bonded to curved reflector substrates. Unfortunately the development costs of this material are high and require a large market. At the present time microsheet reflectors are not yet commercially available, but they do appear to be the solar reflector material of the future. Reflectance and beam spread data for some typical solar reflectors are shown in Table 13.1.4. For the optical analysis of focusing collectors one needs not only the total reflectivity but also the distribution of reflected rays about the specular direction. Table 13.1.4 provides this information according to the formalism explained in Section 5.4.2. Rs(2ir) is the total or hemispherical reflectivity. The distribution of reflected rays is modeled either as a single Gaussian of width
376

Active Solar Collectors and Their Applications

TABLE 13.1.4 Properties of Reflector Materials3 Material Second surface glass Laminated glass (Carolina Mirror Co.) Laminated glass (Gardner Mirror Co.) Perpendicular to streaks Parallel to streaks Corning microsheet (vacuum chuck) Corning 03 17 glass (1.5

Measurement wavelength (nm)

Rt

500

0.92

600

0.92

500 800 500 550

0.92 0.88 0.92 0.77

K,(2ir)

7 for 9'a = 4 mrad

0.15

0.83

0.83

0.4

0.90

0.90

0.95

0.76

0.95

0.95

0.85

0.60

0.85

0.83

0.87

0.70

0.85

0.61

(mrad)

R2

(mrad)

0.4 <0.05 <0.05 1.1

0.18

6.2

mm) Metallized plastic films 3M Scotchcal 5400

3M FEK-163

Sheldahl aluminized teflon

Polished bulk aluminum Alcoa Alzak Perpendicular to rolling marks

500 600 700 900 500 600 700 900 400

0.86 0.86 0.82 0.84 0.86 0.86 0.82 0.84 0.73

0.90 0.78 0.86 0.86 1.4

0.15

12.1

500 700 900

0.80 0.80 0.81

1.3 1.6 1.4

0.07 0.04 0.03

30.9 39.8 31.4

670

0.66

0.39

0.21

9.7

505

0.56 0.45 0.70

0.42 0.53 0.24

0.33 0.42 0.17

10.1 9.8 7.7

407.5

0.62 0.58

0.29 0.46

0.27 0.29

7.1 9.0

498

0.65

0.37

0.23

16.1

498

0.67

0.43

0.21

18.5

550

0.44

1.4

0.43

10.3

407.5 Parallel to rolling marks Kingston Ind. Kinglux Perpendicular to rolling marks Parallel to rolling marks Metal Fabrications Bright aluminum

670 505

1.9

2.0 2.1 1.9

0.68

0.85

0.67 0.69

0.84

0.44

B

Rs(2ir) is hemispherical reflectivity,
vantage in applications with high concentration. For example, if the acceptance half-angle of the collector is 4 mrad, then only 0.67-0.69 of the light incident on Kinglux is reflected to the absorber even though the hemispherical reflectance is 0.85. As for costs, metalized plastic reflector films sell for about 8-35 $/m2 and

Practical Considerations

377

silvered glass for about 10-15 $/m2 (the cost of the silver itself makes only a small contribution because the layer can be very thin). Polished aluminum sheet like Alzak or Kinglux can be bought for about 25 $/m2. Of course the cost of a collector is not determined by the reflector surface alone. For example, an aluminum sheet has some rigidity by itself and may not need the extra expense of a shaped substrate. 13.1.4 Other materials Collector enclosures, collector support, insulation, seals, pipes, and heat transfer fluids are vital parts of a collection system. A serious failure of any of these parts can cause malfunction of the entire system. In the past when energy was cheap, little attention was paid to insulation. Following that tradition many of the early collectors were insulated with less than the economically optimal amount of insulation. Insulation is crucial if a collector is to have good thermal performance. In flat plate collectors, for example, both back and sides should have adequate insulation. Hot pipes and ducts and storage tanks should of course also be well insulated. Of course, insulating materials should have low thermal conductivities and low cost. They must also withstand the highest expected operating temperatures and thermal cycling. Insulation on outdoor pipes should be encased with metal cladding or UV inhibited PVC jackets; simply painting it will usually not provide sufficient protection [Meeker and Boyd, 1981]. Moisture can cause severe problems. For example, if fiberglass or open cell foam become wet, they can act like a heatpipe: water evaporates near the absorber and condenses near the enclosure, creating a thermal short circuit from absorber to ambient. Hence it is crucial to protect the insulation from external or internal leaks. Closed cell insulation is preferable because it avoids this problem. However, freon-blown insulation releases corrosive hydrofluoric or hydrochloric vapors if heated above 180°C. In fact many insulating materials outgas at elevated temperatures, and these gases may condense on the inside of the glazing thereby reducing the transmittance even if they are noncorrosive. Figure 13.1.3 displays the conductivity as a function of temperature for several insulating materials. Most conductivities increase rapidly with temperature. Therefore heat losses must be calculated with the conductivity at operating temperature. Glasswool (fiberglass) is the cheapest insulation and it can be used up to 370°C if it is made with a minimum of organic binders and preheated to drive off volatiles [Vresk, 1981]. Preformed seals (gaskets) and other sealing compounds are needed to form a seal between covers and collector or receiver enclosure. The sealing material should not outgas or lose its elasticity. For high-temperature applications (over 195°C) fluorocarbon seals are recommended, while for lower temperatures seals of silicone, acrylic, or acrylic copolymers are acceptable. Collector enclosures and supports must provide enough rigidity to keep the collector components in place. The rigidity requirement is particularly severe for collectors with high concentration. The enclosure should keep the

378

Active Solar Collectors and Their Applications

Figure 13.1.3 Conductivity as function of temperature for several insulating materials (From ASHRAE[ 1981], with permission).

inside dry and clean. It should allow rain and snow to run off. Common materials for collector enclosures or support are galvanized or painted steel, aluminum, fiberglass, plastics, wood and wood products, and concrete. Compatibility of materials is important. For instance, different metals in close contact with each other can cause severe electrolytic corrosion. Also the possibility of differential thermal expansion must be taken into account to prevent warping or breakage of glazing or absorber. In this context one might also emphasize the need for expansion tanks, and for expansion loops and/or bellows in the piping to accommodate thermal expansion. The materials and paints should be resistant to UV and other environmental influences. Wood is a risky choice as collector enclosure; it may outgas, warp, rot, or ignite. Last not least one needs to select the heat transfer fluid. Table 13.1.5 lists the properties of the most important candidates for solar application. Air costs nothing, is noncorrosive, and stable at all temperatures, but its heat transfer coefficient is low and the pumping power requirement high. Air is practical only for applications where hot air itself is the desired product. Water is the ideal heat transfer fluid as long as there is no risk of freezing or boiling. It offers the best possible heat transfer and pumping requirements

TABLE 13.1.5 Properties of Heat Transfer Fluids3 Commercial name (manufacturer) Propylene glycol Dowfrost (Dow)1 59 weight percent aqueous solution Sunsol 60 (Sunworks)2 60 weight percent aqueous solution Ethylene glycol Dowtherm SR-1 (Dow)3 59 weight aqueous solution Polyglycols UCON 500 (Union Carbide)

Chemical composition

Freezing point

Boiling point

Thermal conductivity (W/m °K)

Specific heat (kJ/kg °K)

Viscosity [10 m2/s]

6

Volume expansion (10~ 4 K~')

Specific gravity at °C

Propylene glycol K2HPO41%

-31"

102°

0.39

3.6 at 27°C

3.0 at 38°C 70 a t - 18°C

7.3

1.033 at 27°C

Propylene glycol inhibitor

-48°

109°

0.35

3.4 at 25°C

4.0 at 38°C 140 at- 20°C

7.5

1.055 at 25°C

Ethylene glycol K2HPO4 2%

-37°

110°

0.42

3.4 at 27°C

2.6 at 38"C 22 at - 18°C

6.3

1.074 at 20°C

Polyglycol 90% inhibitor

-37°

289° rec max temp

0.15

2.2 at 100°C

11.5atlOO°C 61 at38°C

7.9

0.98 at 100°C

TABLE 13.1.5 Properties of Heat Transfer Fluids3 (continued) Commercial name (manufacturer) Paraffinic hydrocarbon oils Caloria HT 43 (Exxon)4

Synthetic Hydrocarbon oils Brayco 888 HF (Bray Oil Co.)5 Silicone oils Syltherm 444 (Dow Corning)6 Water

Freezing point

Boiling point

Thermal conductivity (W/m °K)

Specific heat (kJ/kg °K)

Viscosity [10~6 m2/s]

Petroleum distillate moderate molecular weight, low aromatic content

-9.5°

311° rec max temp

0.13

2.1atlOO°C

Polymerized 1-decene

-85°

227° flash point

0.13

Polydimethysiloxane

-46°

> 315°

0°

100°

Chemical composition

CO

CO

Volume expansion (10~ 4 K-')

Specific gravity at °C

5.0atlOO°C 31 at38°C

10.0

0.80 at 100'C

2.3 at 25°C

4.5 at 100'C 22.5 at 38°C

4.8

0.83 at 15°C

0.14

1.6atlOO°C

7.0atlOO°C 20 at25°C

10.7

0.95 at 25°C

0.60

4.2 at 93°C

0.3 at 93°C

2.1

1.00 at4"C

Notes. Similar physical properties exist for ( I ) TJCAR 35, 50 percent solution (Union Carbide); Sunsafe 230, 50 percent solution (NPD Energy Systems); (2) Solar Winter Ban (CAMCO); Corona Solar Fluid (A. O. Smith); (3) UCAR 17, 50 percent solution (Union Carbide); (4) Mobiltherm 603 (Mobil); Thermia C (Shell); Dowtherm HP (Dow); (5) PAO-20E (Uniroyal): H-30 (Mark Enterprises); (6) SF-96 (General Electric). "From Sullivan [1980].

Practical Considerations

381

are low.3 Possible problems with corrosion can be prevented by adding inhibiting agents and following the recommendations in Table 13.1.6 concerning compatibility with absorber materials. The temperature limits of water can be extended by adding antifreeze. Typically one chooses a 50/50 mixture of water and glycol; this prevents freezing down to almost — 40°C and permits operation up to about 120°C. At higher temperatures glycols may decompose into corrosive byproducts. Hence it is advisable to check the condition of the antifreeze occasionally, in particular after an accidental overheating. Glycols are somewhat toxic, and U.S. building codes require a double wall heat exchanger between a drinking water supply and a collector with glycol. For operation in the range of 100-300°C one can use water only if one is willing to pay the price for high-pressure pipes. Otherwise one will resort to heat transfer oil. In their heat transfer characteristics oils are inferior to water, but certainly far better than air. Hydrocarbon oils are flammable and require precautions against fire. Also they tend to become very viscous or even freeze at ambient temperatures, thereby posing problems for system startup. Silicone oils avoid the flammability and viscosity problems of hydrocarbon oils, but they are more expensive, and they are even more leak prone. For applications above 300°C, the principal heat transfer fluids are air, steam, helium, molten salt, and liquid metal. Typical heat transfer coefficients for these fluids are listed in Table 9.1.1. For a more precise performance ranking, the reader is referred to Fried [1973], who has defined a convenient criterion, the heat transfer efficiency factor. 13.2 Installation 13.2.1

Collector location and orientation

The most obvious criterion for collector location is access to sunlight. Shading is acceptable only early in the morning or late in the afternoon when the collector would be able to deliver no or almost no useful energy anyway, but at other times shading should be minimized. If shading may be a problem, it is advisable to calculate sun angles and shadows cast by trees, buildings, etc. and carry out a system performance calculation for a clear day using the clear day insolation model of Section 3.5.2. As a general rule shading between 9 am and 3 pm should be avoided. In large collector arrays some shading from one collector row to the next is inescapable. Here a compromise must be made between losses due to shading on one hand and cost of land and longer piping runs on the other. The collector spacing can be expressed as ground cover ratio defined as ratio of total aperture and total 3 However, water has a high specific heat, and in some applications the heat capacity of a water-filled absorber can impose significant transient losses.

TABLE 13.1.6 Compatibility of Metals and Aqueous Solutions" Generally unacceptable use conditions Aluminum 1. When in direct contact with untreated tap 1. water with pH <5 or >9. 2. When in direct contact with liquid containing copper, iron, or halide ions. 2. 3. When specified data regarding the behavior of a particular alloy are not available, the velocity of aqueous liquids shall not exceed 4 ft/sec. Copper 1. When in direct contact with an aqueous 1. liquid having a velocity greater than 4 ft/ sec. 2. 2. When in contact with chemicals that can form copper complexes such as ammonium 3. compounds.

Generally acceptable use conditions When in direct contact with distilled or deionized water that contains appropriate corrosion inhibitors, When in direct contact with stable anhydrous organic liquids,

When in direct contact with untreated tap, distilled, or deionized water. When in direct contact with stable anhydrous organic liquids. When in direct contact with aqueous liquids that do not form complexes with copper.

Steel 1. When in direct contact with liquid having a 1. When in direct contact with untreated velocity greater than 6 ft/sec. tap, distilled, or deionized water. 2. When in direct contact with untreated tap, 2. When in direct contact with stable distilled, or deionized water with pH <5 or anhydrous organic liquids. > 12. 3. When in direct contact with aqueous liquids of 5 < pH < 12. Stainless steel 1. When the grade of stainless steel selected is 1. When the grade of stainless steel not corrosion resistant in the anticipated selected is resistant to pitting, crevice heat transfer liquid. corrosion, intergranular attack, and 2. When in direct contact with a liquid that is stress corrosion cracking in the in contact with corrosivefluxes. anticipated use conditions. 2. When in direct contact with stable anhydrous organic liquids. Galvanized steel 1. When in direct contact with water with pH 1. When in contact with water of pH > 7 <7or>12. but<12. 2. When in direct contact with an aqueous liquid with a temperature >55°C (131°F). Brass and other copper alloys Binary copper-zinc brass alloys (CDA 2XXX series) exhibit generally the same behavior as copper when exposed to the same conditions. However, the brass selected will resist dezincification in the operating conditions anticipated. At zinc contents of 15% and greater, these alloys become increasingly susceptible to stress corrosion. Selection of brass with a zinc content below 15% is advised. There are a variety of other copper alloys available, notably copper-nickel alloys, which have been developed to provide improved corrosion performance in aqueous environments. "From Kreiderand Kreith [1982]

382

Practical Considerations

383

ground area of a collector field. The optimal ground cover ratio depends on latitude and collector type; typical values for midlatitudes range from 0.20.4 for point-focus collectors and 0.4-0.6 for line-focus and nontracking collectors. The collector orientation should be chosen to maximize useful solar energy. Nontracking collectors should face due south, although some deviation from the rule is acceptable. At midlatitudes a collector azimuth (deviation from due south) up to 10° imposes little penalty, but azimuths in excess of 20° should be avoided. Close to the equator the tolerance for azimuth deviations is greater because the collector tilt is smaller. The optimal tilt for a fixed aperture is approximately equal to the latitude for year-round loads and approximately equal to latitude + 15° in the northern hemisphere for space heating. For parabolic troughs and linear Fresnel reflectors the basic goal is to keep the incidence angle small on the average. The optimal orientation for year-round loads is the polar mount (i.e., tracking axis northsouth with tilt equal latitude), but outside the equatorial regions, this may cause problems with collector supports, wind loading, and long piping connections. Hence one frequently prefers to keep the tracking axis horizontal. In this case the usual choices are to align the tracking axis either in the eastwest or the north-south direction. The north-south direction yields more yearly energy, but is highly nonuniform over the year (see Section 3.9); the optimal choice depends on the application. In any case the precise orientation of the tracking axis does not matter; just as with fixed collectors there is some tolerance. In fact a sloping ground facilitates draining of the collector. Also, a south-facing slope (in the northern latitudes) enhances energy collection. Linear Fresnel lenses are more demanding. If they are designed for a fixed tracking axis at all, then it must be the polar axis. If the concentration of a linear Fresnel lens is sufficiently high, then seasonal adjustments of the tracking axis are required or even full 2-axis tracking must be used to maintain proper focus. Frequently the choice arises between mounting the collectors on the ground or on the roof. This involves many factors. While unused roof area usually comes free, the roof may not be strong enough to bear the weight and wind loading of a collector, especially in a retrofit. In new buildings one can design the roof for the collector. When mounting collectors on the roof one should be careful to avoid leaks through roof penetrations needed for the collector supports. With ground mounting, on the other hand, the availability of land may be a problem (note that in most locations the cost of land is small compared to the cost of solar collectors). In residential applications, one usually places the collectors on the roof; for space heating a south-facing wall may also be excellent. There are additional considerations for the choice of the collector location. Accessibility is important for maintenance and repair. Collector, storage, and load should be near each other to minimize piping costs and pumping power. In particular, the hot lines should be kept short to reduce heat

384

Active Solar Collectors and Their Applications

losses.4 Environmental contaminants may be a problem in some industrial applications, and one should avoid placing a collector downwind from a source of dirty or corrosive effluents. On some roofs vapors from tar may condense on the collector and reduce its optical efficiency. Another selection criterion for the collector location may be the strength of wind. 13.2.2 Pumps and piping Careful attention should be given to the pipes/ducts of a solar energy system. The main issues are: flow diagrams, pipe diameter(s), pipe insulation; heat losses (both steady state and transient), and pumping power. Careful analysis and optimization of the piping subsystem can be a complicated task. The pumping power must be included with due attention for the higher value of mechanical energy as compared to thermal energy. Pumping power has often turned out to be unexpectedly large. With regard to flow diagram, there are several ways of interconnecting collector modules in an array: series, parallel, or some combination thereof. Series connection guarantees uniform flow but the pressure drop is likely to be prohibitive, especially in large arrays. For that reason one usually chooses parallel flow. Whenever collectors are put in series, the pressure drop should be checked. With parallel connections the main problem is nonuniformity of flow. This can be prevented by either making the feeder pipe large compared to the collector pipe(s) or else adding balancing valves to the individual collector modules. The latter approach is more labor intensive as the balancing may have to be checked periodically. To check whether the flow is indeed uniform in an actual installation, an infrared camera is most convenient; collectors with insufficient flow will be hotter than the others. With parallel connections there are two arrangements for the return pipe, direct return and reverse return, as shown in Fig. 13.2.1. Reverse return requires somewhat longer pipe connections but it automatically creates a nearly uniform flow distribution. In direct return networks the collectors on the far side of the inlet are likely to get starved, and balancing valves become necessary. Note that Fig. 13.2.1 also illustrates how inlet and outlet are located to minimize the length of the hotter pipe. Sufficient expansion loops or bellows should be provided to accommodate thermal expansion. Flex hoses should be installed in such a fashion that they suffer a minimum of torque and tension. Pipe supports and pump seals can cause unexpectedly large heat lakes. The piping connections at the storage tank should be properly placed to maximize storage utilization and efficiency. In particular, the outlet from tank to collector should be at the very bottom of the tank and the return from the collector should be at the top. Diffusers may be added to enhance stratification. In air systems with rock 4 In some cases heat losses from pipes and ducts may not be a real loss if they reduce the heat load of a building; but of course one has to make sure that this does not cause an increased cooling load.

Practical Considerations

385

Figure 13.2.1 Possible interconnection of collector modules in an array: (a) direct return; (b) reverse return (From Kutscher [1981]).

beds the inlet plenum from collector to storage should be large enough to ensure uniform flow; for this the plenum area should be at least 10% of the cross section of the bed. The rocks should be fairly smooth and uniform in size (% to 1 % times the nominal diameter). Pipe and tank materials, insulation, pumps, seals, and gaskets must be chosen to withstand the highest expected temperatures and pressures. (Note that water mains pressure can be several atmospheres.) To increase reliability one can install several pumps. In the right size combination they can provide a good low-cost approximation to variable speed pumps. Leaks can be a problem anywhere in a solar thermal system. Particularly prone to leakage are systems with air and systems with oil. The reason for air systems has to do with the construction of air ducts because of the need for large cross sections. They are made of sheet metal, and the seams are rarely airtight. Heat transfer oils have a low surface tension and they are notorious for their ability to seep through the finest cracks. Needless to say they are also a fire hazard. Several kinds of valves may be necessary. There must be a sufficient number of pressure relief valves to prevent undue pressure buildup in the collector field. They must be positioned so they do not discharge fluid onto collectors or people. Shut-off valves are needed to facilitate repairs. In some systems the collectors are higher than the storage, and at night, warm fluid

386

Active Solar Collectors and Their Applications

from storage could thermosyphon to the collectors; this can be prevented by check valves. Finally before starting a system one should flush out any dirt that might have gotten into pipes, collectors, tank, or filter. 13.2.3 Safety and protection of equipment Freeze protection of water systems has already been discussed in Section 12.2.1. Water is the only practical heat transfer fluid that expands upon freezing. But even without such expansion the solidifying of the heat transfer fluid can cause problems. Certain high-temperature systems use molten salt or oil as heat transfer fluid, and at night the fluid in the pipes may solidify or become very viscous. This may paralyze the pump and allow overheating in the receiver, or the strain on the pump may cause excessive wear. To forestall this possibility one either adds trace heaters to the pipes or else one keeps circulating the fluid at all times (provided the heat losses from the receiver are small enough); or else one selects a different heat transfer fluid. One also needs to worry about overheating of the collectors. This can happen under several circumstances: during construction and before startup, during pump or power failures, and in space heating systems during the summer season. Overheating must be prevented unless the collector and the fluid are certified to be stagnation proof. In any case extended periods of stagnation during construction should be avoided by proper scheduling; or better, by keeping the aperture covered or in the shade. In space heating systems the collector could be vented to ambient in summer (if it is an air system), or else to an extra heat exchanger; otherwise a collector cover may be necessary. Overheating during brief pump failures may not be a serious problem in flat plate collectors, although antifreeze in the collector may degrade. Also, after boiling has occurred and the pressure relief valve has opened, harmful underpressure may develop when the collector cools down again. A particularly destructive phenomenon can occur with overheated evacuated collectors; if cold liquid reaches the tubes before they have cooled down, the thermal shock will break the tubes. Without thermal shock most of the evacuated collectors on the market today can survive stagnation for extended periods, even though their stagnation temperature may exceed 300°C. With tracking collectors the protection against stagnation is easy. One simply turns the reflector away from the sun. Of course this will not work if tracker and pump fail at the same time, as they will during a power outage. If the heat capacity of the receiver is large enough the sun will be out of focus before any harm is done. This is likely to be the case, with the exception of collectors with east-west tracking axis for which, at equinox, the sun remains in focus all day. If overheating of a tracking collector is possible, then an emergency mechanism is advisable to turn the collector out of the sun. Tracking collectors should also be turned to a safe stowing position during

Practical Considerations

387

dangerously high winds (in excess of 30-50 m/sec depending on collector construction). A safety concern with concentrating collectors arises from high flux levels near the receiver while the collector is being turned into or out of the sun. Insulation, pipes, and other parts in the vicinity of the absorber could get burnt unless they are adequately shielded. People who are near concentrators should wear protective glasses and be extremely careful. Central receivers should be located away from flight paths of airplanes or balloons. In some areas fence may be advisable to keep inadvertent intruders or worse, vandals, from getting on-site. High-temperature systems with oil present a fire hazard and proper precautions should be taken. For example, the operating personnel should be properly trained, and a central switch, accessible to firemen, should allow turning off the flow and stowing the reflectors at the same time.

13.3 MAINTENANCE AND CLEANING 13.3.1 Maintenance Solar energy systems perform best if they are properly maintained and cleaned. The amount of maintenance depends on the complexity of the system and on collector type. In general, tracking collectors and high-temperature systems require more attention. For focusing collectors the most important maintenance problem is cleaning. Cleaning is discussed in the following section. As always there is a trade-off between the cost of maintenance and the benefit of improved system performance and system life. Any system should be inspected after accidental stagnation. Antifreeze and heat transfer oils decompose at high temperatures and may need to be replaced if stagnation has occurred. Regular inspections are advisable to check temperatures, pressures, valves, and controls, to test level and condition of heat transfer liquid, to look for damage or leaks, and to do any adjustments, cleaning, or repair that may have become necessary. Inspections are all the more necessary as long as the technology is new and long term operating experience is scant. Even for relatively simple residential systems yearly inspections are recommended by Solar Age [1982]. In systems with heat transfer oils one needs to guard against leaks because of the fire hazard. Needless to say, if a system is shut down for maintenance it cannot collect energy; hence it is preferable to schedule repair and maintenance for overcast days or periods without load or at night. For industrial installations, the size of a solar system has an interesting implication for the attitude of the maintenance personnel: if the system is very small compared to the load, it may not be taken seriously and receive the proper attention. Proper training of the maintenance personnel is important.

388

13.3.2

Active Solar Collectors and Their Applications

Cleaning

The need for collector cleaning varies widely with collector type and location. To understand the effect of dirt on different collector types, let us take a closer look at the interaction of light with dust particles. Dust causes both absorption and scattering. Most dust particles are very small and they affect the passage of light as much by scattering as by absorption [Berg, 1978]. Since the scattered radiation is distributed over a wide range of angles it will miss the receiver of a focusing collector. In a flat plate collector, by contrast, even the radiation scattered by dust on the cover (at least the radiation scattered into the forward hemisphere) will reach the absorber. For that reason flat plate collectors are quite insensitive to dust; they may function surprisingly well even when they look terrible. Besides, most flat plate collectors are deployed at a tilt where rain provides adequate cleaning. In residential applications people rarely bother to clean flat plate collectors. Industrial systems are larger and economies of scale may make cleaning of flat plate collectors cost effective, at least in dusty environments. Concentrating collectors with large acceptance angle (e.g., CPCs) lose some of the scattered radiation and are intermediate between flat plate and focusing collectors in their sensitivity to dust. The effect of dust depends on optical design in yet another way. On an exposed second surface reflector a light ray has to penetrate the dust layer twice on its way to the receiver. The thickness of the protective coating in front of the reflective metal layer itself is large compared to the size of dust particles. Therefore the scattering and absorption on the way to the metal layer is uncorrelated with the scattering and absorption on the way out from the metal layer. Hence the loss of radiation with an exposed second surface reflector is twice as large as it would be if light had to pass the dust layer only once. The latter is the case with Fresnel lenses (assuming the back of the lens stays clean) and with parabolic dish collectors that are completely enclosed inside inflated transparent bubbles. Several factors determine the accumulation of dust on collectors. The deposition of dust depends on wind velocity, surface shape, and particle size. The bonds that dust or dirt particles form with a surface may be chemical or physical. There is a tendency for the bond to become stronger with time. Atmospheric moisture plays an important role in this bonding process because moisture brings a dust particle closer to the surface, thereby increasing the forces of adhesion; the increased bond persists even after the moisture has evaporated again [Berg, 1978]. Dust accumulation is most severe at night when dew condenses on airborne dust, and makes it settle on a collector, with the water acting like a glue. A light rain in the desert causes similar problems if the precipitation is only enough to collect dust from the air but not enough to rinse off the collector. For this reason it is important to stow reflectors so they do not face upwards at night or during dust storms. For heliostats the vertical position, facing out of the wind, is also acceptable. Fixed reflector systems (i.e., the hemispherical bowl and the cylindrical slats [See Section 7.4]) suffer in this regard and require extra cleaning.

Practical Considerations

389

For a more quantitative discussion of the effect of dirt on reflectors we cite a study by Freese [1978]. The specular reflectances of mirrors were monitored through nine months of outdoor exposure and different cleaning frequencies. Differences in reflector elevation and mounting angle (other than inverted) were found to have no significant effect on the rate of dirt and dust accumulation. Figures 13.3.1a-13.3.1c show reflectance as a function of time for mirrors cleaned every 2, 6, and 12 days. The sawtooth pattern indicates that reflectance deteriorates rapidly after cleaning but is restored to a fairly constant maximum with each cleaning. Figure 13.3. Id depicts the same relationship for a mirror never cleaned except by natural weather conditions. It was found that specular reflectance decreased most rapidly on just-cleaned mirrors, that light rain with windy, dusty conditions could decrease reflectance up to 15-20 percentage points, and that rain on a newly cleaned mirror slightly decreased its reflectance, but rain and melting snow on dirty mirror surfaces cleaned them well. In fact, snow conditions could increase reflectance to within 0.01 reflectance units of the value obtained after ultrasonically cleaning the mirrors in a laboratory. Ultrasonic cleaning, of course, is not a practical solution to problems of dirt and dust accumulation on reflectors. Realistic cleaning methods include high-pressure water sprays, sprays of commercial detergents, and wiping with soap and water, all followed by a water rinse. Wiping may not be feasible if access to reflectors is blocked by supports, receivers, or guy wires. Cleaning large reflector arrays with detergent may not be environmentally sound and it does not appear to be significantly more effective than cleaning with plain water [Pettit and Butler, 1977]. High-pressure plain water sprays of 3.5 MPa are recommended; they can recover about 95% of the reflectance lost due to particle accumulation [Berg, 1978]. Either an automatic sprinkler system or a spray truck with water tanks can supply the water jets. To minimize particle accumulation between cleanings, reflectors should be stowed facing vertically or downward when possible, and they can be rinsed after cleanings with an antistatic solution [Champion, 1978]. Dust and dirt on an exposed surface is relatively easy to clean off. Dirt on the inside of a glazing or on the absorber poses a more serious problem. Dirt on the absorber affects both absorptivity and emissivity. The absorptivity of dirt tends to be lower than that of most absorbers. Furthermore the emissivity of most dirt is high, and it can significantly affect the performance of a selective absorber. To illustrate this point, suppose that one-tenth of a selective absorber with eabs = 0.1 is covered with dust, grease, or fingerprints of emissivity edirt = 0.9. Then the average emissivity is almost doubled:

The absorber and inside of the glazing are difficult or impossible to clean. Therefore these surfaces should be adequately protected. In a nonevacuated collector hermetic sealing seems impractical because of the thermal expan-

Figure 13.3.1 Specular reflectance versus time for a mirror under several different cleaning cycles: (a) cleaning every 2 days; (b) cleaning every 6 days; (c) cleaning every 12 days; (d) no cleaning (From Freese [1978]). 390

Figure 13.3.1

(continued)

391

392

Active Solar Collectors and Their Applications

sion of the air inside the collector; instead, vent holes should be covered with dust niters. 13.3.3

Tracking

The performance of tracking collectors depends on the tracking accuracy that can be maintained in actual operation. Many of the tracking collectors installed during the 1970s fared rather poorly in this regard [Gee, 1982]. A frequent problem was caused by the inability of the first generation of tracking sensors to function well under variable insolation. They could be adjusted to work correctly for a fixed insolation level, but with changing beam or diffuse insolation they would become erratic. Sometimes these trackers would chase the silver lining of a cloud instead of the sun. Another common problem with the early trackers had to do with misalignment between sensor and collector. Some systems tried to bypass the problems caused by a sun sensor and instead used a computer to calculate the position of the sun at any moment. However, this latter approach requires very careful determination of the orientation of the collector; otherwise there will be a serious systematic tracking error. Apparently these early problems have been more or less solved. When measuring the accuracy of recent commercial trackers for parabolic troughs, Gee [1982] found that correct tracking could be maintained within about 1 mrad. With heliostats, tracking accuracies in the range of 1-2 mrad have been demonstrated at the Central Receiver Test Facility in Albuquerque, NM [Holmes, 1982]. Tracker improvements have been achieved by more sophisticated electronics and by changes in sensor design, thereby reducing the impact of diffuse insolation. Also some new trackers have been developed that measure directly the flux at the receiver, thus eliminating many of the alignment problems experienced with trackers mounted on the aperture. While tracking accuracy of the new trackers is best for high levels of beam irradiance, it remains good down to beam irradiance levels of 200 W/

Figure 13.3.2 Effect of tracking errors on annual collectible energy (From Gee [1983]).

Practical Considerations

393

m2, and only the beam-normal irradiance seems to matter, not the angle of incidence or the diffuse irradiance [Gee, 1982]. To provide a measure of the importance of tracking accuracy, Fig. 13.3.2 shows the decrease in annual collected energy as a function of tracking error for parabolic troughs. Curves are shown for several values of concentration ratio C and mirror contour error amMam. The higher the concentration, the greater the sensitivity to tracking errors. Tracking errors of 5 mrad are quite serious; they cause a loss of about 1% for C = 15 and 7% for C = 35. But if the tracking error is less than 1 mrad, then the loss is negligible (a fraction of 1%) even for C as high as 35. REFERENCES Atkinson, B and Caesar, R. 1983. "The Volkspanel Model T." Solar Age (April):33. ASHRAE. 1981. Handbook of Fundamentals. Atlanta, GA: Society of Heating, Refrigeration and Air Conditioning Engineers. Beauchamp, E. K. 1975. "Low Reflectance Films for Solar Collector Cover Plates." Report SAND 75-0035. Albuquerque, NM: Sandia Laboratories. Berg, R. S. 1978. "Heliostat Dust Buildup and Cleaning Studies." Report SAND 780510. Albuquerque, NM: Sandia Laboratories. Butler, B. L. and Claassen, R. S. 1980. "Survey of Solar Materials." Trans. ASME/ J. Solar Energy Eng. 102:175. Call, P. and Masterson, K. 1978. "Absorber Surfaces and Reflective Materials." Proc. of the Solar Thermal Concentrating Collector Technology Symposium, Report SERI/TP-34-048. Golden, CO: Solar Energy Research Institute. Call, P. J. 1979. "National Program Plan for Absorber Surfaces R & D." Report SERI/TR-31-103. Golden, CO: Solar Energy Research Institute. Cash, M. 1978. "Learning from Experience." Solar Age 3:11. Champion, R. L. 1978. "Cleaning and Maintenance." Proc. of the Solar Thermal Concentrating Collector Technology Symposium. Report SERI/TP-34-048. Golden, CO: Solar Energy Research Institute. Clements, L. D. 1978. "High Temperature Receiver Materials Performance." Proc. of the Solar Thermal Concentrating Collector Technology Symposium. Report SERI/TP-34-048. Golden, CO: Solar Energy Research Institute. Freese, J. M. 1978. "Effects of Outdoor Exposure on the Solar Reflectance Properties of Silvered Glass Mirrors." Report SAND 78-1649. Albuquerque, NM: Sandia Laboratories. Fried, J. R. 1973. "Heat Transfer Agents for High Temperature Systems." Chem. Eng. May 28. Gee, R. C. 1982. "An Experimental Performance Evaluation of Line Focus Sun Trackers." Report SERI/TR-632-646. Golden, CO: Solar Energy Research Institute. Gerwin, H. 1978. "Line Focus Receiver Technology." Proc. of the Solar Thermal Concentrating Collector Technology Symposium. Report SERI/TP-34-048. Golden, CO: Solar Energy Research Institute. Godolphin, D. 1982. "Reliability and Durability in Solar Energy Systems." Solar Age 7:10. Harding, G. L. and Window, B. 1980. "Graded Metal Carbide Selective Absorbing

394

Active Solar Collectors and Their Applications

Surfaces Coated onto Glass Tubes by a Magnetron Sputtering System." J. Vac. Sci. Technol. 16:2101. Harding, G. L. and Moon, T. T. 1981. "Calorimetric Measurement of Absorptance and Emittance of the Sydney University Evacuated Collector." Solar Energy 26:281. Holmes, J. T. 1982. "Heliostat Operation at the Central Receiver Test Facility." ASMEJ. Solar Energy Eng. 104:133. Kutscher, C. F. 1981. "Design Considerations for Solar Industrial Process Heat Systems." Report SERI/TR-632-783. Golden, CO: Solar Energy Research Institute. Kutscher, C. F. et al. 1982. "Design Approaches for Solar Industrial Process Heat Systems." Report SERI/TR-253-1356. Golden, CO: Solar Energy Research Institute. Lampert, C. M. 1982. "Durable Innovative Solar Optical Materials—The International Challenge." In Optical Coatings for Energy Efficiency and Solar Applications, " p. 324. Soc. of Photo-Optical Instrumentation Engineers. Lampert, C. M. and Washburn, J. 1979. "Microstructure and Optical Properties of Black Chrome Before and After Exposure to High Temperatures." Proc. of the Second Annual Conference on Absorber Surfaces for Solar Receivers. Report SERI/TP49-182. Golden, CO: Solar Energy Research Institute. Leonard, J. A. 1978. "Linear Concentrating Solar Collectors—Current Technology and Applications." Proc. of the Solar Thermal Concentrating Collector Technology Symposium. Report SERI/TP-34-048. Golden, CO: Solar Energy Research Institute. Lind, M. A., Pettit, R. B., and Masterson, K. D. 1980. "The Sensitivity of Solar Transmittance, Reflectance and Absorptance to Selected Averaging Procedures and Solar Irradiance Distributions." ASME J. Solar Energy Eng. 102:34. Jorgensen, G. 1979. "Long-Term Glazing Performance." Report SERI/TP-31-193. Golden, CO: Solar Energy Research Institute. Kreider, J. and Kreith, F. 1982. Solar Heating and Cooling: Active and Passive Design, 2nd ed. New York: McGraw-Hill. Meeker, J. and Boyd, L. 1981. "Domestic Hot Water Installations: The Great, the Good, and the Unacceptable." Solar Age 6:10. Modern Plastics Encyclopedia. Published annually, New York: McGraw-Hill. Muenker, A. H. 1979. "High Temperature Solar Absorber Paints." Proc. of the Second Annual Conference on Absorber Surfaces for Solar Receivers. Report SERI/TP49-182. Golden, CO: Solar Energy Research Institute. Peterson, R. E. and Ramsey, J. W. 1975. "Thin Film Coatings in Solar-Thermal Power Systems."/. Vacuum Sci. Technol. 12:174. Pettit, R. B. 1977. "Characterization of the Reflected Beam Profile of Solar Mirror Materials." Solar Energy 19:733. Pettit, R. B. and Butler, B. L. 1977. "Semiannual Review ERDA Thermal Power Systems, Dispersed Power Systems, Distributed Collectors, and Research and Development: Mirror Materials and Selective Coatings." Report SAND 77-0111. Albuquerque, NM: Sandia Laboratories. Rabl, A. 1977. "Prisms with Total Internal Reflection as Solar Reflectors." Solar Energy 19:555. Seraphin, B. O. and Meinel, A. B. 1976. "Photothermal Solar Conversion and the Optical Properties of Solids." In Optical Properties of Solids: New Developments, Seraphin, B. O., editor. Amsterdam: North Holland. Seraphin, B. O. and Carver, G. E. 1979. "Chemical Vapor Deposition of Refractory

Practical Considerations

395

Metal Reflectors for Spectrally Selective Solar Absorbers." Annual Report: May 1, 1978 to April 30, 1979. Tucson, AZ: Optical Sciences Center, University of Arizona. Smestad, G. and Hamill, P. 1982. "Concentration of Solar Radiation by White Painted Transparent Plates." Appl. Opt. 21:1298. Solar Age. 1982. "Questions and Answers." (August): 8. Solar Energy Corporation. Specifications Sheet for Solkote Hi/Sorb-I Selective Solar Coating. Solar Energy Corporation, Box 3065, Princeton, NJ 08540. Sparrow, E. M. and Cess, R. D. 1978. Radiation Heat Transfer. New York: McGrawHill. St. Amand, R. P., Williams, J. C, and Farrauto, R. J. 1979. "Improved Solar Absorber Coatings." Proc. of the Second Annual Conference on Absorber Surfaces for Solar Receivers. Report SERI/TP-49-183. Golden, CO: Solar Energy Research Institute. Sullivan, T. 1980. "Solar Heat Transfer Fluids." Solar Age (December):!!. Tortorello, A. J. and Wolf, R. E. 1979. "Outgassing Studies of Some Solar Absorber Coatings." Proc. of the Second Annual Conference on Absorber Surfaces for Solar Receivers. Report SERI/TP-49-182. Golden, CO: Solar Energy Research Institute. USDOE. 1978. "National Solar Heating and Cooling Demonstration Program: Project Experience Handbook." Report DOE/CS-0045/D. U.S. Department of Energy. Vitko, J., Jr. 1978. "Optical Studies of Second Surface Mirrors Proposed for Use in Solar Heliostats." Report SAND 78-8228. Livermore, CA: Sandia Laboratories. Vresk, J. et al. 1981. "Final Reliability and Materials Design Guidelines for Solar Domestic Hot Water Systems." Report ANL/SDP-11. Argonne National Laboratory. Winston, R. 1976. "Dielectric Compound Parabolic Concentrators." Appl. Opt. 15:291.

14. ECONOMIC ANALYSIS

Money does not talk, it swears. Bob Dylan

A solar energy system can be considered an investment that produces revenue in the form of fuel savings. The purpose of the economic analysis is to evaluate the profitability of a solar energy project and to compare it with alternative investments. The alternatives might include an oil-fired boiler, a heat recovery unit, a cogeneration system, or nonenergy investments such as stocks, bonds, and real estate. The economic analysis' provides the criterion not only for deciding whether to build a solar energy system but also for optimizing its design. The simplest way to deal with inflation is based on constant currency and real rates of return. This is explained in Section 14.1. The basic tools for the economic analysis are developed in Section 14.2. They are applied in Section 14.3 to derive the principal criteria for evaluating the economic attractiveness of an investment. Section 14.4 discusses life cycle costs and includes operation and maintenance expenses. Section 14.5 addresses complications that arise from debt financing and tax laws and for which an analysis in current dollars is more appropriate. 14.1 CONSTANT CURRENCY When analyzing future cash flows one cares about their real value, not about their nominal value in a currency that has been eroded by inflation. If one describes future cash flows in terms of inflating dollars (also called current dollars), one must therefore correct them for inflation. Inflation affects costs and benefits alike, leaving the balance unchanged. In this sense the inflation rate is a spurious variable. The simplest way to deal with inflation is to eliminate it from the analysis by working with constant currency and real discount rates. Real rates are defined as the difference between market rates and the inflation rate. For example, suppose in 1980 a sum of $1000 is 'The analysis might be based on strictly financial considerations or it might attempt to include other considerations such as reduced pollution, reduced dependence on fossil fuel supplies, or, for the nation as a whole, reduced risks associated with oil imports or with CO2 buildup in the atmosphere.

396

Economic Analysis

397

invested in a certificate of deposit bearing interest at rmarket = 1 5% whil inflation rate is / = 1 2%. After 1 year the investment has grown to $ 1 1 50 i 1981 dollars, but the value in 1980 dollars is $1150/1.12 = $1027. The value has grown at a real interest rate rrea, = 2.7%. The real rate is given by

or

As proved in Section 14.5.4, for an equity investment without taxation an analysis in constant currency is exactly equivalent to one in inflating currency.2 The former has the advantage of being simpler and more transparent because one needs to specify one variable less. Above all, the inflation rate is difficult to predict, while real rates are fairly well known. For example, from 1955-1980 the real interest rate on first rate corporate bonds has consistently been close to 2.2%, despite large fluctuations of the inflation rate [Jones, 1982]. The high real interest rates of the early 1980s are probably an anomaly. Riskier investments (e.g., the stock market) offer higher returns, but they, too, tend to be fairly constant in constant dollars. On the other hand, when an investment is financed by a loan or when the investor can claim tax benefits from depreciation there may be numerical differences between a constant currency analysis and one in inflating currency. Also, loan payments are usually arranged to have fixed amounts in inflating currency (at least that is current practice in the U.S.). The real value of the individual annual loan payments is different between two methods of analysis.3 For these reasons we use current dollars in the formulas for debt financing and depreciation in Section 14.5. 14.2

14.2.1

COMPARING PRESENT AND FUTURE COSTS

The time value of money

A dollar that is to be paid in the future does not have the same value as a dollar available today. This is true even if there is no inflation or if one is talking about constant currency. Since a dollar that is available today can 2 For that reason the equations of Section 14.3 can be used with real or with market rates, provided one is consistent and uses only one kind throughout. 3 If transactions have a fixed amount in inflating currency then their real value decreases with time. In the limit of very high inflation a long term loan becomes meaningless if its repayment schedule is fixed in inflating currency because then most of its value would be repaid during the first year. The fixed charge rate J^r of Eq. (14.4.9) is different in constant and in inflating currency.

398

Active Solar Collectors and Their Applications

be invested and bear interest, its future value is increased by the interest. Suppose an amount P (present worth) is invested at an interest rate r with annual compounding of interest. After the first year the value has increased to P(\ + r), after the second year to P(l + r)2, etc. Hence the future worth F after N years is

The ratio P/F is called the present worth factor, and its inverse is the compound amount factor. In accordance with the recommendations of the Engineering Economy Division of the American Society for Engineering Education we shall use the mnemonic notation

Analogous expressions can be written for other factors that are useful for economic analysis. In particular the compound amount factor is

Numerical values are listed in Table 14.2.1. These formulas are the basic tools for comparing payments that are made at different times. 14.2.2 How to choose the rate for discounting the future The present worth factor reduces or discounts the value of future transactions; hence, the rate r can be thought of as a discount rate. The higher r, the lower the present value of a future amount of money. This discounting of the future is a consequence of the productivity of capital. If all capital investment yielded the same rate of return or interest rate r, then all future cash flows would have to be discounted at the rate r. But while the need for discounting is clear, the choice of the rate is not, because different investments yield different returns. A few examples will illustrate how the discount rate may be chosen in a particular situation. First consider a homeowner who has enough cash in his savings account to purchase a solar water heater. Instead of buying the water heater he could leave the money in his savings account. If he does buy the water heater he foregoes the interest he could otherwise earn from his savings account. Hence his discount rate is the interest rate of his savings account. If he had no savings, he would have to borrow money for the water heater. In that case his discount rate would be the interest rate of his loan. Loan interest rates are generally higher than the rales for savings accounts. The situation is more complex if there are several investment alternatives. For example, a homeowner might invest his money in real estate,

399

Economic Analysis TABLE 14.2.1 Present Worth Factor (P/F, r, N) = (1 + r)-"toT Discount Rate r and Number of Years N

(%) 1

2

3

4 5 6 7 8 9 10 11

12 13 14

15 16 17 18 19 20

N

5

10

15

20

25

30

0.9515 0.9057 0.8626 0.8219 0.7835 0.7473 0.7130 0.6806 0.6499 0.6209 0.5935 0.5674 0.5428 0.5194 0.4972 0.4761 0.4561 0.4371 0.4190 0.4019

0.9053 0.8203 0.7441 0.6756 0.6139 0.5584 0.5083 0.4632 0.4224 0.3855 0.3522 0.3220 0.2946 0.2697 0.2472 0.2267 0.2080 0.1911 0.1756 0.1615

0.8613 0.7430 0.6419 0.5553 0.4810 0.4173 0.3624 0.3152 0.2745 0.2394 0.2090 0.1827 0.1599 0.1401 0.1229 0.1079 0.0949 0.0835 0.0736 0.0649

0.8195 0.6730 0.5537 0.4564 0.3769 0.3118 0.2584 0.2145 0.1784 0.1486 0.1240 0.1037 0.0868 0.0728 0.0611 0.0514 0.0433 0.0365 0.0308 0.0261

0.7798 0.6095 0.4776 0.3751 0.2953 0.2330 0.1842 0.1460 0.1160 0.0923 0.0736 0.0588 0.0471 0.0378 0.0304 0.0245 0.0197 0.0160 0.0129 0.0105

0.7419 0.5521 0.4120 0.3083 0.2314 0.1741 0.1314 0.0994 0.0754 0.0573 0.0437 0.0334 0.0256 0.0196 0.0151 0.0116 0.0090 0.0070 0.0054 0.0042

stocks, or bonds, each with a different rate of return and a different risk. Industrial and commercial investors usually have quite a range of investment opportunities. In such cases the appropriate discount rate for the analysis of a solar investment is the rate of return for investments of comparable risk that would be made if the money were not spent on the solar energy system. When a project is examined from the point of view of society, the discount rate should be based on the rate of return for society as a whole. This rate is called the social discount rate. It is the subject of much controversy, touching as it does on delicate problems such as intergenerational equity. A high discount rate de-emphasizes the importance of future costs or benefits; in other words it favors the present generation over future generations. The above discussion shows that the discount rate is easy to determine when there is a single alternative investment (or, equivalently, a single source of funds) such as a savings account. But when there are several investments with different rates of return, the choice of the discount rate may involve a difficult evaluation of risk. Hence the question arises whether one could base the discount rate on the productivity (i.e., rate of return) of the solar investment itself rather than on the productivity (i.e., interest rate) of money in general. This approach is indeed taken for many industrial enterprises. One writes down the formula for the economic analysis in terms

400

Active Solar Collectors and Their Applications

of an unspecified discount rate r and determines r at the end by setting the cost of solar energy (which depends on r) equal to the cost of conventional energy. This method, called internal rate of return method, is explained more fully in Section 14.3.2. 14.2.3 Levelizing It is convenient to express costs or revenues that occur once or in irregular intervals as equivalent equal payments in regular intervals. This is called levelizing. It is a useful technique because regularity facilitates understanding and planning. To explain this technique let us consider an example. A bank wants loan payments to be arranged as a series of equal monthly or yearly installments. Suppose a loan of value P is repaid in equal annual payments A over N years. (The fraction of A that pays for interest varies with time, as discussed in Section 14.4.1, but for the purpose of levelizing we need not worry about that.) To derive the formula for A, consider first a loan of value Pn that is repaid with a single payment Fn at the end of n years. With n years worth of interest on the amount Pn the payment is

In other words, the loan amount Pn equals the present value of the future payment F,,:

A loan that is repaid in N equal installments can be considered as the sum of TV loans, one for each year, the nth loan being repaid in a single installment A at the end of the «th year. Hence the value P of the loan equals the sum of the present values of all loan payments:

Using the well known formula for geometric series one can evaluate this sum, with the result

Even though derived for the specific case of a bank loan, the result is perfectly general and relates any single present value P to a series of equal payments A, given the discount rate r and the number of payments N. When r vanishes, Eq. (14.2.5) is singular but its limit as r -* 0 is easily found to be 1//V, reflecting the fact that the present values of the loan payments become equal. Following the notation introduced above we designate the ratio of A

Economic Analysis

401

and P by

It is called capital recovery factor. Numerical values4 are listed in Table 14.2.1. The inverse

is known as series present worth factor since P is the present value of a series of equal payments A. EXAMPLE 14.2.1

What are the annual payments for a loan P = $1000 at interest rate r = 8% over N = 20 years? SOLUTION

The capital recovery factor is (A/P,r,N) = 0.1019, from Table 14.2.2. Hence the annual payments are $101.90, approximately one-tenth of the loan amount. The following example shows how present worth factors and capital recovery factors can be used. Suppose a solar energy system with life N needs a major overhaul in the nth year at a cost C. What is the levelized cost of this overhaul? The present value of the cost is

Hence the levelized cost is

From Eqs. (14.2.2) and (14.2.6) one finds

4

For the limit of long life, N -> oo, it is worth noting that (A/P, r, N) -» r if r > 0.

402

Active Solar Collectors and Their Applications TABLE 14.2.2 Capital Recovery Factor (A/P, r, N) = r/[\ - (1 + r)~N] for Discount Rate r and Life N of Investment

N

(%) -4

3

-2 J

0 1 2 3 4 5 6 7

8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25

5

10

0.1767 0.1824 0.1882 0.1940 0.2000 0.2060 0.2122 0.2184 0.2246 0.2310 0.2374 0.2439 0.2505 0.2571 0.2638 0.2706 0.2774 0.2843 0.2913 0.2983 0.3054 0.3126 0.3198 0.3271 0.3344 0.3418 0.3492 0.3567 0.3642 0.3718

0.0793 0.0843 0.0893 0.0946 0.1000 0.1056 0.1113 0.1172 0.1233 0.1295 0.1359 0.1424 0.1490 0.1558 0.1627 0.1698 0.1770 0.1843 0.1917 0.1993 0.2069 0.2147 0.2225 0.2305 0.2385 0.2467 0.2549 0.2632 0.2716 0.2801

15

20

25

30

0.0474 0.0518 0.0565 0.0615 0.0667 0.0721 0.0778 0.0838 0.0899 0.0963 0.1030 0.1098 0.1168 0.1241 0.1315 0.1391 0.1468 0.1547 0.1628 0.1710 0.1794 0.1878 0.1964 0.2051 0.2139 0.2228 0.2317 0.2408 0.2499 0.2591

0.0317 0.0358 0.0402 0.0449 0.0500 0.0554 0.0612 0.0672 0.0736 0.0802 0.0872 0.0944 0.1019 0.1095 0.1175 0.1256 0.1339 0.1424 0.1510 0.1598 0.1687 0.1777 0.1868 0.1960 0.2054 0.2147 0.2242 0.2337 0.2433 0.2529

0.0225 0.0263 0.0304 0.0350 0.0400 0.0454 0.0512 0.0574 0.0640 0.0710 0.0782 0.0858 0.0937 0.1018 0.1102 0.1187 0.1275 0.1364 0.1455 0. 1 547 0.1640 0.1734 0.1829 0.1925 0.2021 0.2118 0.2215 0.2313 0.2411 0.2509

0.0166 0.0201 0.0240 0.0284 0.0333 0.0387 0.0447 0.0510 0.0578 0.0651 0.0726 0.0806 0.0888 0.0973 0.1061 0.1150 0.1241 0.1334 0.1428 0.1523 0.1619 0.1715 0.1813 0.1910 0.2008 0.2107 0.2206 0.2305 0.2404 0.2503

Thus any future transaction can be expressed as an equivalent series of equal annual payments. EXAMPLE 14.2.2

A system has salvage value S = $1000 at the end of its useful life of N = 20 years. What is the equivalent levelized annual salvage value if the discount rate is r = 8%? SOLUTION

From Eq. (14.2.8) with n = TV and C = S we get, using Tables 14.2.1 and 14.2.2,

A = 0.1019 X 0.2145 S = 0.02186 S = $21.86.

Economic Analysis

403

Some payments can be assumed to increase or decrease at a constant annual rate. Fuel prices, in particular, are likely to exhibit real growth; i.e., to increase faster than general inflation in the foreseeable future. It is convenient to replace a growing or decreasing cost by an equivalent constant or levelized cost. Suppose, for example, that the price of energy is pe at the start of the first year, escalating at a real rate re. Including escalation and discount factors, one obtains the present value Pe of the total energy payments for a constant annual energy consumption Q:

(This assumes that payments are made at the end of each year.) Introducing a new variable fe

or

one can write the present value as

The levelized annual payment corresponding to this present value is obtained by multiplying by (A/P, r, N). Hence the levelized energy price pe is

Numerical results for this levelizing factor

can be found in Table 14.2.3 for several values of r and re. EXAMPLE 14.2.3

Fuel costs pe = $5/GJ at the start of the first year and grows at a real rate of 4% per year. What is the equivalent levelized fuel price over N = 20 years if the discount rate is r = 6%?

404

Active Solar Collectors and Their Applications TABLE 14.2.3 Levelizing Factor (A/P, r, N)/(A/P, r'e, N) with r'e = (r - re)/ (1 +/•,) for Several Values of Lifetime N, Discount Rate r, and Escalation Rate rc

\

N = 10 c

r(%\/-X /o)

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

-1

0

1

2

3

4

0.947 0.948 0.949 0.950 0.950

1.000 1.000 1.000 1.000 1.000

1.115 1.113 1.111 1.110 1.108

.178 1.175 1.172 .170 .167

1.245 1.241 1.237 1.233 1.229

0.951 0.952 0.953 0.953 0.954

1.000 1.000 1.000 1.000 1.000

1.056 1.055 1.054 1.053 1.052 1.052 1.051 1.050 1.049 1.049

1.106 1.105 1.103 1.101 1.100

.164 .162 .159 .156 .154

1.225 1.222 1.218 1.215 1.211

0.955 0.955 0.956 0.957 0.957

1.000 1.000 1.000 1.000 1.000

1.048 1.047 1.046 1.046 1.045

1.098 1.097 1.095 1.094 1.092

.151 .149 .147 .144 .142

1.208 1.204 1.201 1.198 1.195

N = 20

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15

0.904 0.907 0.910 0.913 0.916

1.000 1.000 1.000 1.000 1.000

1.108 1.105 1.101 1.098 1.094

1.231 1.223 1.215 1.208 1.200

1.370 1.357 1.344 1.332 1.319

1.529 1.509 1.490 1.472 1.454

0.919 0.921 0.924 0.926 0.929

1.000 1.000 1.000 1.000 1.000

1.091 1.088 1.085 1.082 1.079

1.193 1.186 1.179 1.173 1.167

1.308 1.296 1.285 1.27 1.264

1.436 1.419 1.403 5 1.388 1.373

0.931 0.933 0.935 0.937 0.939

1.000 1.000 1.000 1.000 1.000

1.076 1.074 1.071 1.069 1.067

1.161 1.155 1.150 1.145 1.140

1.255 1.245 1.236 1.228 1.220

1.359 1.345 1.332 1.320 1.308

SOLUTION

From Table 14.2.3 the levelizing factor for this case is 1.436. Hence the levelized fuel price is $7.18 /GJ. Several features may be noted in Table 14.2.3. First, the levelizing factor is unity if there is no cost escalation. Secondly, for a given energy escalation rate, the levelized cost decreases as the discount rate increases. This makes sense because a high discount rate deemphasizes the role of high costs in the future.

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405

14.2.4 Discrete and continuous cash flows The formulas derived above assume that all costs and revenues occur in discrete intervals. This is common accounting practice and reflects the fact that bills are paid in discrete installments. Even though a solar energy system produces energy continuously the benefit of this production is realized only in discrete intervals whenever fuel bills are paid. Also the rates for interest, general inflation, fuel escalation, etc., are quoted as annual rates. Hence, we follow common practice and work with the discrete formulas. Nonetheless, it is instructive to consider the continuous case. Whether one chooses a discrete or a continuous analysis is a matter of convention. Instead of an interest rate based on annual compounding, one could quote a slightly lower rate based on continuous compounding; the annual payments would be the same. To establish the connection between the discrete and the continous growth rates, consider something that grows at an annual rate r. At the end of 1 year it will have grown by a factor (1 + r). If, however, the growth is compounded in m equal intervals per year, the growth per interval is (1 + r/m) and by the end of the year the growth amounts to

Using the well known formula

one finds that the annual growth factor corresponding to continuous compounding is If the total growth during the year is to be the same, then the growth rate in the continuous formula must be smaller than the rate in the discrete formulas. Designating the corresponding rates by subscripts and equating the annual growth factors, one finds the following relation between the rates:

For sufficiently small rates, say less than 20%, one can approximate this relation by keeping only the lowest terms in the series expansion of the exponential function

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Active Solar Collectors and Their Applications

With the replacement of rates according to Eq. (14.2.16), the continuous formulas in Table 14.2.4 yield the same results as the discrete ones. To develop a better intuitive understanding of growth rates, it is instructive to consider the doubling time N2 corresponding to a growth rate r. It is given by

or

This is the basis of a very convenient rule, sometimes called the "seventyyear rule": the product of the doubling time and the growth rate r (in units of percent) is 70 years: 70 years (with r = %)

N r = 69.3 ... years

EXAMPLE 14.2.4

If energy costs grow at 5% per year, in how many years will they double? SOLUTION

The doubling time is 70 years 5

= 14 years.

TABLE 14.2.4 Factors for Economic Analysis" Expression for discrete analysis

Expression for continuous analysis

(F/P, r, N)

(1 + r)»

exp (rN)

P

(P/F, r, N)

(1 + r)~N

exp ( — rN)

P

A

(A/P, r, N)

r 1 - (1 + r)~N

exp (r) - 1 1 — exp ( — rN)

A

P

(PI A, r, N)

1 - (1 + /•)-" r

1 - exp(-rJV) exp (r) - 1

Quantity known

Quantity to be found

Factor

P

F

F

a (/( = annual payment, P = present value, /•' = future value, r = discount rate, N — life lime).

Economic Analysis

14.3

407

ECONOMIC EVALUATION CRITERIA

In this section we develop the principal criteria for the economic analysis of a solar energy system. To clarify the issues let us consider the simplest possible case: a solar energy system of capital cost C that delivers an annual amount of useful energy Q, without any expenses for operation and maintenance. (Of course, the formulas apply equally well to an investment in energy conservation.) The system is assumed to last N years without any decline in performance, and any salvage value or benefit after these N years is neglected. The equipment is paid for with cash; this is called equity financing by contrast to debt financing (i.e., borrowing). Once the basic criteria have been explained, it is straightforward to extend the formulas to more complicated cases. In Section 14.4 we add expenses for operation and maintenance and we include the cost of the backup or auxiliary to get the total life cycle cost of the system. Complications arising from debt financing and from taxes are addressed in Section 14.5. 14.3.1 Life cycle savings If one did not install the solar energy system, then the energy Q would have to be supplied by some other energy source, for instance, a gas-fired furnace. Let us designate this alternative as backup or auxiliary. If the price of fuel is pe and if the auxiliary converts this fuel with an efficiency »?aux, then the annual cost of supplying Q would be Qpji\mv This is therefore the value of the annual energy savings due to the solar energy system. If the fuel price escalates at a rate ra one needs to levelize the fuel savings by using the levelized fuel price pe of Eq. (14.2.13): with Hence the levelized annual fuel savings are levelized annual fuel saving = The levelized annual cost of capital is acap,

for system life N and discount rate r. The levelized annual net saving s is the difference between these two terms:

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Active Solar Collectors and Their Applications

The life cycle savings (also known as net present value) are obtained by dividing the levelized annual saving by the capital recovery factor:

This is the true value of the solar energy investment. It is the difference between the life cycle fuel savings and the capital cost. Sometimes one wants to consider the life cycle cost of the entire energy system, not just the solar component by itself. This is described explicitly in later sections. For the moment we merely point out that an analysis based on life cycle cost and one based on life cycle savings are essentially the same, the only difference being the inclusion of the auxiliary. However, the criteria to be discussed next are quite different.

14.3.2 Internal rate of return In order to calculate the life cycle savings one needs to specify the discount rate r. Ideally r should be the interest rate that reflects the cost of the money invested in the solar energy system. However, as discussed in Section 14.2.2, this rate is not always known with sufficient accuracy. Many investors have a wide choice of investment opportunities, each with a different rate of return and a different risk. Such investors like to compare different investments in terms of their individual productivities or rates of return. Hence it is desirable to define a rate of return for a solar energy system in terms of the revenue produced by that system. This rate is called internal rate of return because it is based only on the project itself, without any reference to the cost of money. Suppose an amount of money Cis invested at an interest rate r over N years. Then it produces a levelized annual revenue of

On the other hand, if the amount C is invested in a solar energy system, then it yields a levelized annual revenue

Hence the solar investment behaves like a bank account whose interest rate r is determined by equating the last two equations and solving for n

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409

This is the internal rate of return of the solar investment, designated by r,. Of course pe is also levelized with discount rate r, as with Comparison with Eq. (14.3.5) shows that the internal rate of return is that discount rate for which the life cycle savings vanish. That is the general definition of the internal rate of return

In general this equation cannot be solved in closed form, but r, can be found by iterations or by using Figs. 14.3.1 or 14.3.2 as discussed below. If r, for a particular project is greater than the average rate of return on other investments of comparable risk, then that project is a good investment; otherwise it is not. Thus the internal rate of return is a rational and a convenient criterion for evaluating the desirability of a solar investment.

14.3.3

Cost of saved energy

Another possible criterion for the evaluation of energy investments is the cost of energy. If a system produces an amount of energy Q and thus saves 2/^aux in fuel per year and if the annual cost for capital is (A/P, r, N)C, then this saved energy costs

Figure 14.3.1 The relation (r,Np)= 1 -exp[-WV,)W Np)] between internal rate of return r,, simple payback period N,,, and investment lifetime N, for continuous analysis.

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Active Solar Collectors and Their Applications

Figure 14.3.2 Relation between internal rate of return, simple payback period, and lifetime of an energy investment for discrete analysis. Shifted axes show effect of energy price escalation re.

The cost psavcd of saved energy has units of $/GJ and is levelized; it can be directly compared with levelized prices of conventional energy forms. The cost of saved energy presumes a discount rate, but it is independent of the fuel escalation rate. When more than one end use energy form is involved (e.g., heat and electricity in a cogeneration system), the definition of the cost of saved energy becomes ambiguous. 14.3.4 Payback period The payback period is denned as ratio of capital cost over annual savings. At the end of the payback period the system has paid for the initial investment and any revenue produced thereafter is pure gain. Several different kinds of payback time can be denned (e.g., simple, discounted, corrected for fuel inflation, etc.), but the simple payback period Np seems to be the most useful.5 It is the ratio of capital cost C and first year savings R = Qpe/Jiam: ^Attempts to overcome the deficiencies of the simple payback period by including discounting, fuel escalation, etc., lead to formulas so complicated one might as well do a proper analysis.

Economic Analysis

41 1

The payback period is a particularly simple criterion but it is not the correct criterion for evaluating energy investments. It fails to account for system life, discount rate, fuel escalation, and benefits accrued during the remainder of the lifetime. It gives a myopic perspective by overemphasizing the short term. It can be very misleading, and economists have been unanimous in rejecting it. Nonetheless it is instructive to think about the payback period. As pointed out by Socolow [1981], the payback period can provide the correct criterion if used in conjunction with the system lifetime. For this discussion it is convenient to use the formulas for continuous compounding. To simplify the argument, let us at first neglect fuel escalation. Let us recall Eq. (14.3.8) for the relation between internal rate of return r, and system cost C:

(with pe as levelized energy cost since pe = pe in the absence of fuel escalation). Dividing by C we obtain the inverse of the payback period on the right-hand side. Using the capital recovery factor for continuous compounding (Table 14.2.4) we can thus rewrite Eq. (14.3.12) in the form

For small rates, say r, < 0.2, one can approximate exp (r,) — 1 by r,. Thus the equation can be rearranged as

This is a one-to-one relationship between the variables y = (r/Np) and x = (N/NP). The dimensionless ratio N/NP is the system lifetime in units of payback period. Equation (14.3.14) is plotted in Fig. 14.3.1, with N/NP as the x axis and r/Np as the y axis. This universal curve

contains much wisdom and is worth knowing. First, when a system lasts forever, x -» oo, then y -» 1; i.e., the rate of

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Active Solar Collectors and Their Applications

return is one over the payback period

Second, the return on investment r, is positive if and only if the system life is longer than the payback period, quite an obvious result. Thirdly, the figure shows that y increases rapidly between x = 1 and x = 2, reaching 0.8 at x = 2.0. Beyond x = 2 it grows much more slowly. This means that the rate of return r, is very sensitive to the value ofN/Np as long as N/Np is small, say less than 2. But beyond that range, further increases in lifetime bring only a relatively small benefit for the rate of return. For example, at N/NP = 3 the rate reaches 94% of its asymptotic value l/Np, only a small increase over the value Q.8NP at N/NP = 2. Hence system life is critical for N < 2NP, but for N > 3NP the rate of return is close to its asymptotic value. This analysis is readily generalized to include the effects of fuel price escalation or of operating costs. If fuel prices escalate at a rate /•„ then pe in Eq. (14.3.12) is to be replaced by the levelized price of Eq. (14.2.13), with the formulas for continuous compounding of course,

Repeating the argument leading to Eq. (14.3.14), one obtains Eq. (14.3.14) with only one modification: rt is replaced by r, — re. Hence the curve in Fig. 14.3.1 still applies if the y axis is interpreted as the difference between the internal rate of return r, and the fuel escalation rate re.6 Without the approximation exp (r,) — 1 ^ r, used for Eq. (14.3.14), the relationship depends on r, and on Np separately. Hence one needs a family of curves. To derive these curves for arbitrary fuel escalation let us rewrite Eq. (14.3.8) explicitly in terms of first year fuel price as

Inserting the payback period one obtains the result

This relationship is plotted in Fig. 14.3.2, based on the discrete capital recovery factor of Eq. (14.2.6). The curves are labeled by the system life N ""Operating and maintenance costs (if they can be assumed to grow like fuel costs) can be included by replacing 2p,/i)aux by Qpe/rja^ — fa&MC in the equation for the payback period.

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413

and, for a given payback time Np on the abscissa, one finds the corresponding value of fe on the ordinate. If the energy price escalation rate re is zero, then fe is equal to the internal rate of return r,. Otherwise it is given by

To provide a nomogram for finding r,, lines have been drawn parallel to the ordinate corresponding to re = 1%, 2%, 3%, and 4%.

EXAMPLE 14.3.1

A solar domestic water heater costs C = $1000 and supplies Q = 12 GJ per year. The backup has an efficiency ?jaux = 0.70 and burns oil costing pe = $7/GJ. The oil price remains constant over the system life of N = 20 years. Calculate (a) the payback period (b) the life cycle savings at r = 5% discount rate (c) the cost of saved energy at r — 5% (c) the internal rate of return SOLUTION

(a) Equation (14.3.11) yields the payback time as

(b) The capital recovery factor is

and the life cycle savings are, from Eq. (14.3.5),

(c) The cost of saved energy is obtained from Eq. (14.3.10),

at r = 0.05. (d) The internal rate of return can be found from Fig. 14.3.2 or, by trial and error, from Eq. (14.3.8), and turns out to be

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Active Solar Collectors and Their Applications

EXAMPLE 14.3.2

Same as Example 14.3.1 but with oil price escalating at re = 4% per year. SOLUTION

The levelized oil price is

and the life cycle savings are

For the internal rate of return the oil price must be levelized with discount rate rn as in Eq. (14.3.18). The result for the rate of return is

The price of saved energy and the payback time remain the same as before.

EXAMPLE 14.3.3

Same as Example 14.3.1 but performance degrades by 1% per year while oil price stays constant. SOLUTION

Now we must levelize the energy Q according to Eq. (14.2.13): with where rQ is the yearly loss of performance; in our case rQ = —0.01. The result is (from Table 14.2.3 with N = 20, r = 5%, and re = -1%)

With that we obtain the new life cycle savings

much lower than before. For the internal rate of return calculation Q is of course levelized using r, as discount rate, analogous to Eq. (14.3.18) (with r'Q instead of r£). The result is

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Economic Analysis

The levelized cost of saved energy increases to

because less energy is saved in later years. The payback period remains, of course, unaffected. 14.3.5 Comparison of criteria We have presented four basic criteria for the evaluation of energy investments. Their main characteristics are summarized in Table 14.3.1. Which criterion one should use depends on the circumstances. In particular, it depends on the assumptions one is willing to make. Ideally one would like to calculate life cycle costs or life cycle savings. As explained in Section 15.1 the life cycle cost (or equivalently the life cycle saving) is the appropriate criterion for system optimization. However, one can calculate life cycle costs or savings only if one specifies the discount rate and the energy escalation rate. If one does not know the discount rate but is willing to make a guess about energy escalation, one can calculate the rate of return based on the annual revenue produced by the system. This rate is called internal rate of return and provides a comparison with all types of investments independent of their magnitude. The internal rate of return is that discount rate for which the life cycle savings of the system vanish, or equivalently for which the cost of solar energy equals the cost of backup energy.7 Conversely, if one 'For a + + + . . . . . . + + + annual cash flow sequence, the equation for r, may have two solutions, and r, is not a suitable criterion. This can happen if the debt fraction is high.

TABLE 14.3.1 Comparison of Economic Evaluation Criteria Criterion

Input

Comments

Life cycle saving = Ciifei no S0|ar — Qfe, with soiar

Discount rate and energy escalation rate

This is the true saving. Appropriate for optimization of system parameters. No direct comparison of profitability with other investments.

Internal rate of return

Energy escalation rate

Internal rate of return r> is value of discount rate for which life cycle savings vanish. Provides direct comparison with profitability of other investments.

Cost of saved energy

Discount rate

Only good for ranking of energy investments that involve a single end use energy form.

Payback period

Very simple, but misleading if taken by itself. However, in conjunction with system lifetime it yields internal rate of return directly from Fig. 14.3.1 or Fig. 14.3.2.

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Active Solar Collectors and Their Applications

knows the discount rate but does not want to guess the future energy prices, one can still rank energy investments in terms of their cost of saved energy. Finally there is the payback period, a simple criterion but much maligned. However, when combined with the system lifetime, the payback period yields directly the internal rate of return, at least for the simple case considered so far. Sometimes it is desirable to have an index that characterizes the economics of a solar installation without any reference to a specific economic scenario. A suitable and frequently used index is the ratio of capital cost Cand annual delivered energy Q. It is sometimes called the energy capacity cost:

energy capacity cost For a given annual charge rate Jcr [see Eq. (14.4.9)], this quantity yields directly the cost of solar energy [in $/GJ] as

If in addition the cost of operation and maintenance is known, one can calculate the internal rate of return. Hence the energy capacity cost is a very convenient criterion for ranking solar installations. Another useful criterion is the saving/investment ratio SMc/C. 14.4 OTHER COSTS So far we have restricted our attention to the solar components of the system. A typical solar energy system contains a backup or auxiliary as well. Frequently one wants to know the total cost of supplying the energy requirements of the load. The total capital cost Csys of the system is the sum of the solar cost C and the cost Caux of the backup:

Almost all solar systems have a complete backup that is determined by the load alone, independent of the solar components. The total annual load is Qtot. A portion Q

of this is supplied by the sun. The levelized annual cost for the auxiliary is

Economic A nalysis

417

and the levelized annual cost of capital is

The total annual cost is the sum of these two terms

The life cycle cost Clife is obtained by dividing the levelized annual cost by the capital recovery factor

Without solar the cost would be

Comparison with Eq. (14.3.5) shows that the life cycle savings of the solar portion are the difference between the life cycle cost without solar and the life cycle cost with solar

Since C|ife no so,ar is independent of the solar portion we see that the life cycle savings of the solar portion are a constant term minus the total life cycle cost. Therefore a life cycle cost analysis is essentially equivalent to an analysis of life cycle savings. In particular for system optimization there is no difference between maximizing Stife or minimizing C|ife, since the derivative of a constant vanishes. Most mechanical systems require some maintenance. In addition there will usually be operating expenses; e.g., to power the pump(s). Thus the analysis would be incomplete without consideration of these costs. The first year cost a0&M for operation and maintenance may of course change, say at an annual rate r0&M, in which case it needs to be levelized according to Eq. (14.2.14):

with

41 8

Active Solar Collectors and Their Applications

Including operation and maintenance the expression for the life cycle cost becomes

Sometimes the expense for operation and maintenance is expressed as a fraction 7^&M of the capital cost. In that case the total levelized annual cost can be written in the form

The factor multiplying the system cost Csys is sometimes called annual charge ratejm

For the sake of completeness we restate the formulas derived in the preceding section for life cycle savings, cost of saved energy, and payback time if there are expenses for operation and maintenance. In that case the annual energy cost savings QpJ^^ must be reduced byJ^&MC. The resulting expression for the life cycle savings is

The internal rate of return r, is of course still determined as that value of the discount r for which Sm vanishes. The cost of saved energy is

Finally the payback time becomes

14.5 DEBT FINANCING, TAXES, AND INFLATING CURRENCY The formulas derived in the preceding section do not include any effects of tax deductions. They are appropriate for investments made by nonprofit organizations or by homeowners who pay with their savings. They should also be used when assessing the benefits of a technology for society. On the other hand, homeowners who borrow money can deduct the interest pay-

Economic Analysis

419

ments from their income tax. For profit-making organizations the analysis is even more complicated because an energy investment can be depreciated and because the cost of fuel is deductible. 14.5.1

Principal and interest

Part of the annual payment A for a loan is interest while the rest, called principal, serves to reduce the loan balance. U.S. tax law allows interest payments as a tax deduction, while payments for the principal are not deductible. Therefore a tax-paying investor needs to know what portion of the loan payment A is interest. Let /„ = interest and pn = principal in year n. The sum is equal to A:

During the nth year the remaining debt is

Hence the interest for the «th year is

Comparing in+l with in one finds

By means of Eq. (14.5.1) pn can be eliminated, with the result

This recursion relation has the solution

as can readily be proved by mathematical induction. This can be rewritten in the form

It is worth noting that the year n enters Eq. (14.5.7) only in the combination (n — N). This implies that the fractional allocation to principal and interest depends only on the number of years (n — N) left in the loan, not on the original loan period. A loan has no memory, so to speak. In general the loan interest rate r, is different from the discount rate r used

420

Active Solar Collectors and Their Applications

in the economic analysis. Furthermore, the loan period NI may be different from the system life N. Hence these rates and times have to be kept apart when calculating the present value of the tax deduction for interest. In Eq. (14.5.7) the interest payment /„ in year n for a loan amount Pioan is given as

The present value PiM of all interest payments is found by discounting each /„ by (1 + r)~" and summing over n

The result can be written in the form

with rj = (r — r/)/( 1 + r,). If the incremental tax rate is T, the total tax payments are reduced by rPml. [This assumes a constant tax rate; a variable tax rate would have to be included in the summation in Eq. (14.5.9).] EXAMPLE 14.5.1

A homeowner finances a $2000 solar water heater with a 5-year loan at r, = 8% interest rate. His discount rate r is also equal to 8%, and his income tax bracket is r = 40%. The levelized annual fuel savings (including O&M) are R = $200. What are the life cycle savings of this water heater if it lasts N = 20 years? SOLUTION

First find the present value P-ml of the interest using Eq. (14.5.10) with r1, = 0, (A/P, fh N,) = I/TV, = 0.20 and (A/P, r,, N,) = 0.2505 = (A/P, r, N,)

The life cycle fuel savings are

The total life cycle savings are obtained by adding r.Pint to Eq. (14.3.5):

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Economic Analysis

(In this particular example the savings are positive with tax deduction, negative without.) 74.5.2

Depreciation

U.S. tax law allows business property to be depreciated. This means that for tax purposes the value of the property is assumed to decrease by a certain amount each year and this decrease is treated as a tax deductible business loss. For an economic analysis it is convenient to express the depreciation claimed over the year as an equivalent present value. The tax law may permit several different schedules for depreciating property. For straight line depreciation over JVdep years the present value of the total depreciation is, as fraction of system cost,

For sum-of-yearly-digits depreciation the corresponding formula is

[Dickinson and Brown, 1979]. (With changes in U.S. tax law, the formula for/iep has changed). 14.5.3 The complete formula The government may choose to stimulate the commercialization of a new technology by granting tax credits. This is current U.S. policy vis-a-vis conservation and renewable resources. A tax credit rcred on an investment / means that the tax payments are reduced by Tcred/. For example, up to $10,000 of the cost of a residential solar system qualifies for a 40% federal tax credit. Thus a homeowner buying a $ 3000 solar water heater saves $ 1 20 in income tax, and in effect the water heater costs him only $1800, provided that his tax liability exceeds his tax credit. Some states grant state income tax credit in addition to any applicable federal credit. (The U.S. solar tax credits expired at the end of 1 984.) Taking into account all applicable tax deductions one obtains the following formula for the life cycle cost of a solar energy system for a homeowner: cost of auxiliary energy down payment

422

Active Solar Collectors and Their Applications cost of loan tax deduction for interest payments tax credit operation & maintenance salvage value

where

Csys = total system cost = C + Caux ./tan = fraction of investment paid by loan ./O&M = levelized annual cost of operation & maintenance, as fraction of Csys /s"alv = salvage value, as fraction of Csys / = general inflation rate TV = system lifetime TV/ = loan period pe = first year energy price Qaux = Got ~ Q — annual auxiliary energy r(. = market energy escalation rate r'c = (r- fe)l(\ + re)

r - market discount rate r, = market loan interest rate r', Tcred T ??ailx

= = = =

(r-./•/)/(! + r,) tax credit incremental income tax rate fuel efficiency of backup

For an industrial investor the formula is different because fuel costs and operating costs are tax deductible and the cost of the solar energy system can be depreciated. The equation can be stated either in terms of before-tax cost or in terms of after-tax cost. These two forms of the equation differ only by an overall factor of (1 — T), where T is the income tax rate. For example, if the market price of fuel oil is $6/GJ and T - 50%, then the before-tax cost of fuel is $6/GJ while the after-tax cost of fuel is (1 - T) X $6/GJ = $3/ GJ. Stated in terms of after-tax cost the equation for the life cycle cost of an

423

Economic Analysis industrial solar energy system reads cost of auxiliary energy down payment cost of loan tax deduction for interest payments tax credit depreciation operation & maintenance salvage

The symbols are the same as in the previous equation. fdep is the present value of the depreciation given by Eq. (14.5.11) or (14.5.12), and Tsa,v is the salvage tax rate, which may be different from the corporate income tax rate. For simplicity f0&M is assumed to include property tax and insurance, as well as the levelized cost of repairs and overhauls. The rate r is the after-tax discount rate; in other words when setting the life cycle savings to zero, one obtains the after-tax internal rate of return. 14.5.4

Constant currency versus inflating currency

To close this section let us examine under what conditions an analysis in constant currency is equivalent to one in inflating currency. For an equity investment without tax deduction the life cycle cost is simply

if we neglect for simplicity O&M and salvage. Inflation can enter only through the rate fn

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Active Solar Collectors and Their Applications

that accounts for energy escalation [Eq. (14.2.11)]. Suppose r and re are the market discount and the market energy escalation rates, respectively, while the general inflation rate is /'. Then the real rates are

Inserting r = i + (1 + i)rrcat and re — i + (1 + i)re real into Eq. (14.5.16) one obtains

This rate is the same whether calculated with real or with market rates! The inflation rate drops out completely. This proves the claim made earlier that a constant currency analysis is exactly equivalent to one in inflating currency for an equity investment in the absence of taxes. This conclusion is not changed if operation and maintenance, salvage, and tax credit are included. On the other hand, for loan payments and tax deductions inflation can have a real effect. One can see this when one tries to rewrite the loan payments in terms real rates and finds that, for example,

Numerically the effect is small but quite noticeable for inflation rates around 5%-10%. Dickinson and Brown [ 1979] present some examples. For an inflation rate / = 6% they find that there can be a real difference on the order of 10% between a constant dollar analysis and one in inflating dollars. But if both depreciation and loan terms are present, the errors tend to compensate and the net error is only a few percent. For an intuitive explanation of the difference between a constant dollar and an inflating dollar analysis, consider the deduction for straight-line depreciation. Since the depreciation allowance has a fixed numerical value in inflating dollars, its real value in future years is decreased by inflation. In the limit of very high inflation the investor loses the benefits of all but the first year's depreciation. REFERENCES Dickinson, W. C. and Brown, K. C. 1979. "Economic Analysis for Solar Industrial Process Heat Systems." Report UCRL—52814. Livermore, CA: Lawrence Livermore Laboratory.

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Jones, B. W. 1982. Inflation in Engineering Economic Analysis. New York: Wiley Interscience. Kreider, J. F. 1979. Medium and High Temperature Solar Processes. New York: Academic Press. Riggs, J. L. 1982. Engineering Economics. New York: McGraw-Hill. Socolow, R. H. 1981. "The Utility of the Payback Period in Scaling the Durability of Savings." Internal note. Princeton, NJ: Center for Energy and Environmental Studies.

15. SYSTEM OPTIMIZATION

Nowadays people know the price of everything and the value of nothing. Oscar Wilde

Having developed the formulas for evaluating system performance and cost, one can address the question of system optimization. In a narrow sense this means varying the system configuration and the sizes of the system components until the most cost-effective combination has been found. In a broader sense one would like to identify the best match between solar technologies and the energy needs of society, taking into account the full social costs. 15.1 OPTIMIZATION CRITERIA In Chapter 14 several criteria were developed for evaluating the economic attractiveness of an energy investment; in particular, life cycle cost (or savings), internal rate of return, cost of saved energy, and payback period. The system optimization depends on which criterion one chooses to measure the economic benefit, and the reader may wonder which criterion to choose. Minimization of total life cycle costs is the rational choice, for the following reason. Supplying energy is not a goal in itself but only a necessary step in order to provide comfort or produce goods. To maximize the benefit of these goods, one needs to minimize the cost of providing them. Hence one should minimize the life cycle cost of an energy system (if, as is usually the case, it is appropriate to consider the energy system in isolation from other items). By contrast, optimization according to an internal rate of return or cost of saved energy amounts to an inappropriate suboptimization as can be seen from the following example. Suppose a factory needs to heat water from the water mains to 70°C at a constant flow rate and assume collector costs proportional to area. Since the temperature of the water mains is close to the average ambient temperature, one could use a small flat plate collector field as preheater to raise the water temperature by just a few degrees. Since the collector efficiency would be very high, the cost of this solar energy is low; equivalently the internal rate of return for this small collector field is high. 426

System Optimization

427

If the collectors are cost effective even when operating at 70°C, then one can further reduce the total life cycle energy costs by making the field large enough to heat the water to 70°C, even though the extra collectors operate at lower efficiency. For these incremental collectors the cost of solar energy is higher and the internal rate of return lower than for the small collector field. Maximization of life cycle savings corresponds to a large collector field while maximization of rate of return would yield a small collector field and small savings. This example demonstrates that the internal rate of return, while a valuable tool for comparing the attractiveness of energy investments, is not the correct criterion for system optimization.

15.2

OPTIMIZATION

15.2.1 Equations for optimization The life cycle cost C and the delivered solar energy Q are functions of the system components; in particular, collector area, storage capacity, heat exchanger size, flow rate, etc. Suppose there are n such variables x}, x2, . . . , xn, to be optimized. This means that one wants to vary these n variables until one finds the minimum of the life cycle cost,1 Eq. (14.4.3),

where (2tot = total annual demand for delivered energy Pe/T]m* - effective energy cost [ = market price, levelized according to Eq. (14.2.13) and divided by efficiency i?aux of backup] (A/P, r, N) = capital recovery factor, Eq. (14.2.6) Cut = C + Caux = total capital cost of system (solar + backup) The life cycle cost is minimized by setting the derivatives of Ciife with respect to all the x, equal to zero. Since only Q and C,0, depend on x,, this implies the system of n equations

'To keep the argument simple, we neglect operation and maintenance as well as possible effects of taxes. In a real calculation they should certainly be included and therefore one should use the full formulas, Eq. (14.5.13) or (14.5.14) instead of (15.2.1). If only operation and maintenance need to be added, then the modification of Eqs. (15.2.1) to (15.2.5) is particularly simple: replace (A/P, r, N) by (A/P, r, N) + J0&u where J0&M is the levelized annual expense for operation and maintenance, expressed as a fraction of the capital cost of the system.

428

Active Solar Collectors and Their Applications

These equations have a simple intuitive interpretation. At the optimum for each variable the incremental cost

of increasing the system equals the incremental value in energy savings

(This is a general optimization rule in the entire field of economics.) Usually one will be able to choose among several different manufacturers and models for the system components. In that case the optimization is to be repeated for each possible (and reasonable) combination of models to identify the best overall choice. As an important illustration consider the case where only the collector area A and the storage capacity M are to be optimized, and where costs vary linearly with A and with M,2

where c0 = fixed cost CA = incremental collector cost CM = incremental storage cost Then Eq. (15.2.2) becomes

and

If Q is given as an explicit function of A and M, these two equations can be readily solved to find the optimal values A0ft and Mopt. Otherwise one will resort to a numerical search of the results of computer simulations. 2 The linearity of system cost with collector area seems to be quite a good rule. Storage costs are more complicated, being determined not only by the storage material, but by the container cost (approximately proportional to A/2'3), and by the charging and discharging rates.

System Optimization

429

The optimization is particularly simple for systems without storage. This is illustrated in the following paragraphs for photovoltaics and for process heat. 15.2.2 Photovoltaics with sellback to utility Storage of electricity is quite expensive, and for customers that are connected to the utility grid it may be more cost effective to rely on the utility for backup than to store energy on-site. Thus in a wider sense the utility can provide storage, by averaging over many customers and by using the energy storage implicit in its fuel supply. In some cases the characteristics of the utility (its power plant types and demand profile) will make storage of electricity desirable. But even then it is likely that the utility can store electricity at a lower cost than local storage at the customer's side because of economies of scale and because the utility can average over demand fluctuations of the individual customers. A crucial feature of this grid integration is the possibility of selling excess electricity (i.e., greater than the demand of the local customer) back to the utility. There is a large potential for local power generation (a lot of free surface area is available on roofs of buildings), but this potential will be utilized only if the utility pays an adequate price for excess electricity. In the United States this has been recognized and codified by the law regulating public utilities [PURPA, 1978]. This law requires the utility to pay a fair price, essentially the avoided cost, to anyone who wants to sell electricity. The avoided cost is the cost that the utility would otherwise have to pay in order to generate this electricity. For example, if at a particular time it would cost a utility $20 to generate an additional GJ, then the utility has to pay $20 to anyone who is willing to sell a GJ to the utility. The PURPA regulation stimulates competition and enhances the overall economic efficiency of electric power generation because it encourages local generation whenever that can be done at a lower cost than the cost of central generation. A regulation of this type is a boon for many alternative energy technologies because their optimal scale is small. An exact optimization of the integration of local photovoltaic generators into the grid of a central utility is complicated and highly dependent on the characteristics of the utility. But from the perspective of the local customer it is only the rate structure of the utility that matters. The charges for electricity may depend not only on the total quantity but on time of day and on instantaneous demand. In the following we discuss as an important example the case of a user with constant daytime demand L, as is typical of industrial operations. For this case the optimization can be carried out in closed form. For photovoltaic systems the generated electricity is proportional to collector area A because the efficiency r\e is essentially constant and independent of A. Thus the optimization condition, Eq. (15.2.4), will generally not have a solution. If the cells are cost effective at all, then the savings increase linearly with A, up to the point where electricity is generated in excess of the

430

Active Solar Collectors and Their Applications

load. At that point there is a break in the value of the electricity. Let us designate the purchase price of electricity by #,uy and the selling price (to the utility) by p^. (The case where the excess must be discarded corresponds to Aeii = 0-) To find the optimal area Aopl we need to rederive the equation for the life cycle savings. The instantaneous electric output is

where / is the instantaneous irradiance on the collector. Selling (or storing or dumping) becomes necessary whenever this output Q exceeds the load L, which is assumed to be constant. As discussed in Section 11.3.4 one can define an insolation threshold X for sellback; excess is generated whenever

Of course, this can occur only if A is larger than the threshold area Axn,

Both the annual total electricity produced by the cells and the excess above the threshold can be calculated with the help of the correlation q(X) ofEq. (11.3.2):

The total production is

Of this a portion Qxlb

is above the threshold for selling and can be sold at the price psc,r; the rest,

displaces electricity that would otherwise be purchased at the price pbur Hence the levelized value of the annual electricity production is

System Optimization

431

The life cycle savings Sti{e are obtained by dividing by the capital recovery factor (A/P, r, N) and subtracting the initial capital investment (c0 + c^A):

With Eqs. (15.2.10) and (15.2.11) this can be written as

Let us now find the optimal area Aopt that maximizes S\ife. In most cases Aeii is less than pbuy, and we shall assume that to be the case (otherwise one would sell the entire production and there would be in effect only one price). If the system is cost effective even at the lower electricity price psdb then again there is no optimum; rather one would make the area as large as permitted by other constraints such as land availability. More likely is the case where psen is relatively low and Eq. (15.2.13) has a genuine optimum obtained by setting the derivative with respect to A equal to zero:

Inserting the polynomial (15.2.9) for q(K) and Eq. (15.2.7) for Zone obtains after some straightforward algebra the result

EXAMPLE 15.2.1

A factory with constant electric load L — 10 kW is in a location with latitude X = 32° and yearly average daytime beam irradiance //, = 0.523 kW/ m2. The levelized electricity prices are pbuy = $20 /GJ and pM = $10 / GJ($10 /GJ = 3.6 0/kWh). A photovoltaic system with r,e = 10% efficiency can be installed for CA — $100/m2 (this corresponds to cA/(ri,, X 1 kWpk/m2) = $ 1 /Wpk in terms of the dollar per peak watt rating); the fixed cost c0 = 0. Evaluate the life cycle savings without sellback and at the optimal area, for discount rate r = 8% and system life TV = 20 years. SOLUTION

The capital recovery factor is (A/P, r, N) = 0.1019. Evaluating the curve fit listed under Fig. 11.3.1, one finds the coefficients of the polynomial q(x) to

432

Active Solar Collectors and Their Applications

be

q0 = 7.384 GJ/m2, ql = n^OCGJ/m^kW/m 2 )- 1 q2 = 6.046 (GJ/m2)(kW/m2r2 The peak insolation /max for this location is the value of X for which q(X) vanishes; solving the quadratic equation

one finds (choosing the smaller solution, of course, because the curve fit is not good past the first zero)

The largest area without sellback is given by Eq. (15.2.8),

At this area the life cycle savings are

It is positive, and hence the optimal area is larger than A^. The optimal area is found from Eq. (15.2.15):

The corresponding threshold is

System Optimization

433

Inserting q(Xopt) = 1.06 GJ/m2 into Eq. (15.2.13) one finds the maximum of the life cycle savings,

EXAMPLE 15.2.2

Same as Example 15.2.1 but higher electricity prices pbuy = $25/GJ and Aell = $15/GJ. SOLUTION

Now the denominator in Eq. (15.2.15) is negative and there is no real solution for Aopt. This is a reflection of the fact that the system would be cost effective even if all the electricity were worth only $15/GJ; hence the savings increase indefinitely with A. Another way to see this is to note that the cost of saved energy, Eq. (14.3.10) (with ?jaux = 1.0 for electricity, and with C = c^A and Q - q^Ai]^ is

if no energy is discarded. Since pxK is greater than psaved in this example, it is profitable to generate as much as possible. Note that the denominator vanishes as /7sdi approaches psaved, and in that limit Aopl becomes infinite.

15.2.3 Industrial process heat systems Industrial process heat systems with constant load rate L are another instance where the optimization can be carried out in closed form [Gordon and Rabl, 1982]. For systems without storage the basic equations have been derived in Section 12.3. The features of the optimization are quite similar to the photovoltaic example. For simplicity let us consider only direct systems; i.e., set Fx = 1. A critical quantity is the threshold ^dump for dumping of energy in excess of the load (unlike photovoltaics, selling of excess heat will rarely be worthwhile). Adumf is given by Eq. (12.3.10):

434

Active Solar Collectors and Their Applications

The annual useful energy Q is given by Eq. (12.3.5) if A is less than J dump and by Eq. (12.3.20) if A is greater:

This must be reduced if the system does not operate every day. The notation is as in Section 12.3; in particular, L is the load rate and q(X) = q0 — q\X + q2X2 is the correlation of Eq. (1 1.3.2). This Q is inserted into the equation for life cycle savings, Eq. (14.3.5),

Setting the derivative with respect to A equal to 0, one obtains Eq. (15.2.4) for the optimal area Aopl,

This can be solved since Q is given explicitly as illustrated by the following example. EXAMPLE 15.2.3

A factory at a location with latitude 32° and Ih - 0.523 kW/m 2 needs to heat water from the mains (at temperature Tm = Tamb = 19°C) to the process temperature r]0ad = 80°C. The load is constant at L = 191.5 kW, corresponding to a constant water flow rate w,oad = 0.75 kg/sec. The process runs 24 h/day, 290 days of the year, the rest being downtime for holidays, weekends, and maintenance. The levelized effective fuel cost of the backup is pj T?aux = $16.88/GJ. The solar system costs CA = $165 /m2 (with c0 = 0), and operation and maintenance costs JO&M = 2% of the capital cost per year. The collector parameters are Fmij0 = 0.74 and FmU = 5 W/m2 K. Calculate the useful yearly energy Q as a function of area and find the optimal area that maximizes the life cycle savings, assuming a discount rate r = 5% and a system life N = 10 years. SOLUTION

The polynomial q(X) of Fig. 11.3.1 has the coefficients
System Optimization

435

0, = n^OCGJ/m^kW/m 2 )-', q2 = 6.046 (GJ/m2)(kW/m2;r2. This implies a peak insolation Imax = 1.026 kW/M2,

corresponding to q(X = 7max) = 0. The threshold area for the onset of dumping is obtained from Eq. (15.2.16): Adump = 334 m2.

Evaluating Eq. (15.2.17) one finds

where the factor 290/365 has been added to account for the number of days of actual operation. Q and life cycle savings are plotted in Fig. 15.2.1. The life cycle savings increase from $82,300 at A = AAump to a maximum of $84,600 at the optimal area Aopl = 397 m2. The optimum is really very broad, and Aopl need not be determined with great accuracy. The figure may be misleading in this regard unless one keeps in mind that the origin has been shifted in order to focus on the region of interest. Also shown in Fig. 15.2.1 is the internal rate of return r-t as a function of A. (Note that rt depends on the fuel cost escalation rate; for Fig. 15.2.1 an escalation rate of 10% per year over N = 10 years has been assumed.) Figure 15.2.1 exemplifies the point made in Section 15.1 about the choice

Figure 15.2.1 Annual useful energy Q, life cycle savings (L.C.S.), and internal rate of return r, as functions of collector area A. The specific numbers are based on Example 15.2.3 (From Gordon and Rabl [ 1982]).

436

Active Solar Collectors and Their Applications

of the optimization criterion. The area that maximizes life cycle savings is larger than the one that maximizes rate of return. The latter drops sharply as soon as dumping sets in. 15.3

SYSTEM VALUE

15.3.1 Definition of value The value V of a solar energy system is defined as its highest permissible cost; i.e., the highest cost at which it can compete with conventional energy. Suppose the solar energy system has a capital cost Cand delivers an amount Q of useful solar energy per year. It saves conventional energy, for example, fuel with a levelized price /7fud that is burned in a boiler with efficiency ?jaux. Then the effective cost of conventional energy is

The annual levelized cost of the solar energy system is JaC, where fcr is the annual charge rate [see Eq. (14.4.9)] for capital and for operation and maintenance (for an equity investment without taxes the charge rate is

where (A/P, r, N) is the capital recovery factor, and JOSM is the levelized annual cost for operation and maintenance, expressed as fraction of the system cost C). The system is cost effective if and only if the annual cost is less than the annual fuel savings, in other words if

The value V of the solar energy system is therefore given by

It depends only on this ratio, not on the individual factors. Also, the value depends equally on performance and on the assumed economic scenario. EXAMPLE 15.3.1

A system delivers 10 GJ per year and displaces natural gas with a levelized price /?fuci = $7/GJ, the efficiency of the backup being r;aux = 0.70. The capital recovery factor is 0.08 (corresponding, for example, to a discount rate r = 5% and a system life TV = 20 years) and the annual charge for operation and maintenance is f0&M = 2%.

System Optimization

437

SOLUTION

The annual charge rate isfcr = 0.10, the effective fuel cost is $7/GJ/0.70 = $10/GJ, and hence the value of the system is

If the system costs more, it is not cost effective under this particular economic scenario. 15.3.2

Value of system changes

Frequently the question arises whether a system could be made more cost effective by a particular modification. For example, one might replace ordinary glazing by more expensive glazing with antireflection coating to improve the performance. Or one might use steel absorber plates instead of copper, reducing both cost and performance. As the following discussion shows, there are two basic criteria that must be satisfied if a system change is to be cost effective. Let us start with a reference system ("old") which costs Cold dollars and delivers QM per year. The value Fold of the system is defined as the highest permissible cost of a cost effective system

Now let us consider a change in the system which alters the cost by

and the performance by

Under what conditions is this change cost effective? Clearly the new system must be cost effective,

otherwise one would not build it. But in addition, one must examine the cost effectiveness of the change itself. Only if

438

Active Solar Collectors and Their Applications

is the change worth the trouble; after all, the investment for the change must be judged by the same criteria as any other solar energy investment. The value Fchange of the system change is the highest permissible cost of the system change. The two inequalities, Eqs. (15.3.8) and (15.3.9), imply that Fchange is determined by two conditions. The highest permissible cost of the new system is the sum of C0]d and Fchange, and of course it must satisfy Eq. (15.3.8):

In addition Fchangc is bounded by the right-hand side of Eq. (15.3.9).

Change is the lowest number consistent with these two inequalities, and it can be written in the form

The fact that the value of a system change is bounded by two conditions, rather than a single one, has frequently been overlooked. Which of the two conditions is more restrictive depends on the circumstances, as illustrated by the following example. EXAMPLE 15.3.2

Suppose the reference system costs CM - $1100 and delivers Qold = 10 GJ per year. If the effective fuel price is $10/GJ and the annual charge rate/J r = 0.10, then the value is

less than the system cost; i.e., it is not worth building. Consider now a system change that increases the annual energy output by A(2 = 2 GJ to Qnew = 12 GJ per year. Then the value of the system change is

Had one looked only at Eq. (15.3.9), one would have reached the erroneous conclusion that the value of the change would be $200. The latter is not correct because the old system is not cost effective, and the cost of the change must be low enough to make the new system competitive.

System Optimization

439

EXAMPLE 15.3.3

Assume the same conditions as in the preceding example, except for a lower cost of the reference system Cold = $900. In that case the value of the change is

because the old system by itself is already competitive. 15.4 VALUE OF STORAGE 15.4.1

General formulation

To assess the value of storage for solar energy systems, it is instructive to think of the addition of storage as a change in the system that affects both cost and performance. In this sense the addition of storage is like any other change in a solar energy system, for example, like the replacement of nonselective by selective coatings in solar collectors. To compare a system with and without storage, let us use subscripts "ns" for "no storage" and "ws" for "with storage." In general the cost, collector area, and performance of these two systems will be quite different. A nostorage system will usually be small and supply only a portion of the daytime load, while a system with storage will be larger and can supply a larger portion of the load.3 The cost of the no-storage system is

where c0 = fixed cost and CA = cost per collector area [in $/m2], while the system with storage costs

where Cstor is the cost of storage. The incremental cost AC = Cws — Cns is therefore

and it must be less than the incremental value of the fuel savings

-'While storage is essential for space heating, because of the mismatch between the times of supply and demand, the situation is different for power generation and process heat because there is a large demand during daylight hours; in this situation a system without storage may be able to provide solar energy at a lower cost per unit energy than a system with storage.

440

Active Solar Collectors and Their Applications

in order to satisfy criterion (15.3.9). The other criterion, Eq. (15.3.8), becomes

The value Fstor of storage is defined as the highest permissible cost of storage consistent with Eqs. (15.4.4) and (15.4.5). Isolating the storage cost on the left-hand sides of Eqs. (15.4.4) and (15.4.5), one can write the equation for the storage value Fstor in the form

The second term in Eq. (15.4.6) increases with gws — <2ns. Roughly speaking (2ws — Qns is the yearly amount of energy that is cycled through storage. For a given storage capacity (?ws — Qns increases with the number of times that storage is charged and discharged. This is the basis for the folklore that the value of storage is proportional to the number of times storage is used. It explains why, for a given storage technology, long term storage is less cost effective than short term storage. In particular, seasonal and annual energy storage of heat can be practical only with the cheapest materials (i.e., water, solar ponds, aquifers) and the like. However, the simple folklore is not exact, and for a careful analysis one should use Eq. (15.4.6). In fact, some of the examples in the next subsection show that sometimes the value of storage does not increase with (?ws — Qns because of the second criterion in Eq. (15.4.6). A general feature of Eq. (15.4.6) is the dependence of storage value on collector cost. This fact may appear disturbing, since it precludes the possibility of assigning an intrinsic value to storage. This is inescapable. Storage is, by its very nature, a dependent technology: first a product must be supplied, then it can be stored. For example, who would build a wine cellar, if wine were not worth making? This remark is not to belittle the importance of storage. In fact, the very stability of our society rests on our ability to store goods for future use. Storage of solar energy is crucial if solar is to make a large contribution to our energy demand. In the near term, however, while solar equipment is relatively expensive, it is worth looking at applications where storage of solar energy is not essential, because such applications may be more cost effective. 15.4.2

Value of storage for industrial process heat

It is instructive to apply the formalism of the preceding subsection to the case of storage of solar industrial process heat. There are two types of storage

441

System Optimization

to be distinguished: storage from day to night, and storage of energy collected during weekends without load (for industries that operate only 5 or 6 days/week). The results for these two types of storage will turn out qute different, because weekend storage is not associated with an increase in collector area and the number of charge and discharge cycles is smaller than for day-night storage. The results reported below were obtained in the course of an assessment of the value of future storage technologies [Rabl and Gaul, 1981]. They were derived for the particular case of systems that provide steam at 180°C,4 but the general trends of the results have a bearing on other applications as well. The load is assumed constant (24 h/day) and the system size large enough (25 MW,) to justify using a central receiver; in addition the parabolic trough and the parabolic dish were also considered. Designs for such systems without storage have been analyzed by Bicker et al. [1981]. The results presented in this subsection have been obtained using the methods of Chapter 11, based on the collector properties of Bicker et al. [1981], As the first step, the field and receiver data of this reference were translated into a linearized efficiency equation. Table 15.4.1 lists the parameters Fmri0 and FmUfor the linearized instantaneous efficiency equation of the collector field. It also lists a term "nightloss," which expresses the losses due to cool-down at night as a percentage of total collected energy. Table 15.4.1 also states the economic assumptions. For assessing the value of future storage technologies one needs to predict both fuel costs and cost and performance of solar collectors. Both are uncertain, to say the least, and the uncertainty of the result is magnified because storage value is the difference between two uncertain terms. Under these circumstances it can be very misleading to quote a single number for the value of a future storage technology. "Assuming Tin = 176.7°Cand rout = 260"C for the collector. TABLE 15.4.1 Input for Analysis of Storage Value for Industrial Process Heat System" Collector

type

Parameters (i) Performance11 ^mlo

F m t/(W/m 2 °C) Nightloss (%) (ii) Economics c0 (K$) CA ($/m2) PWlaux [$/GJ] 7cr

Central receiver

Parabolic dish

Parabolic trough

0.86 0.22 0.54

0.87 0.42 4.60

0.77 0.39 2.50

438.00 189.00 7.73 0.169

438.00 350.00 7.73 0.169

438.00 172.00 7.73 0.169

"From Rabl and Gaul [1981]. 'Equivalent linearized efficiency equation.

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Active Solar Collectors and Their Applications

To emphasize the sensitivity of storage value to uncertainties of the input, the calculations were carried out not only for the reference values listed in Table 15.4.1 but also for variations about these reference values. The dominant uncertainties lie in the four terms Jm Q, pfml and CA, and it seems prudent to consider + 30% variations in each of these factors. Since the first three enter only in the combination V = p^d/J^w the uncertainty of this product is \/3 X 30% = 50%. Hence we have presented the output in a 3 X 3 matrix, where the rows correspond to 0.5, 1.0, and 1.5 times the reference values of Fand the columns correspond to 0.7, 1.0, and 1.3 times the reference values of collector costs CA. The results of the value analysis are presented in Table 15.4.2 for daynight storage and in Table 15.4.3 for weekend storage. Table 15.4.2 shows TABLE 1 5.4.2 Value of Day-Night Storage [in $/MJJ for Several Collector Types and Two Locations. For Each Location and Collector Type a Matrix of 3 X 3 Values is Shown to Display the Effect of Cost and Performance Variations About the Reference Values in Table 15.4.1." Albuquerque, NM ^\

v^

Central receiver Nv^l/Cf.ref

0.5 1.0 1.5

1.0

1.3

-11 2 11

-19 -5 6

0.7

-4 7 16

Parabolic dish VI V^ "\cVQrcf 0.5 1.0 1.5

1.0

1.3

-10 3 12

-17 -3 7

0.7

-3 7 17

North-south parabolic trough V/Vrt

\ClMl.ref

1.0

1.3

-9 3 11

-16 -3 7

0.7

0.5 1.0 1.5

-3 7 16

Charleston, SC North-south parabolic trough

v^ \ C 4 / C 0.5 1.0 1.5

/l.rrf

0.7

-12 _4 3

"From Rabl and Gaul [1981].

1.0

1.3

-21 -12 -4

-30 -21 -12

443

System Optimization TABLE 1 5.4.3 Value of Weekend Storage for Two Locations for North-South Parabolic Trough. Same Format as Table 15.4.2 Albuquerque CA/CA.K*'

Y/Y«\

0.5 1.0 1.5

0.7

1.0

1.3

-1

-3 1 3

-4 -1 2

2 3

Charleston V/Vrf\

0.5 1.0 1.5

x

CA/CA.K! 0.7

1.0

-3 -1 1

-5

3 o

1.3 -7

-5 ~1

the value of storage for a process heat plant with constant load (24 h/day, 7 days/week). The first three entries are for Albuquerque, NM (A = 35°N and //, = 0.60 kW/m2) and for three collector types: parabolic trough with horizontal north-south axis, central receiver, and parabolic dish. The fourth entry is for a location with much lower insolation, Charleston, SC (X = 32.9°N, lh = 0.310 kW/m 2 ) in order to show the effect of climate. The three different collector types do not differ very much in the value they permit for storage. For the nominal case the value of storage in Albuquerque is in the range of $2-3/MJ. The effect of climate is, however, very pronounced. For Charleston the value of storage is negative except under the most optimistic assumption for performance and collector cost. Table 15.4.2 shows that storage value is extremely sensitive to cost and performance: the values range all the way from —$30/MJ (Charleston with cA/cA,nf = 1.3 and F/Fref = 0.5) to +$17/MJ (parabolic dish in Albuquerque, with cA/c4Tef = 0.7 and V/VKf = 1.5). Results for weekend storage are shown in Table 15.4.3 for a parabolic trough in Albuquerque and in Charleston. The load is 24 h/day, but only 5 days/week. For the reference case, weekend storage has a value of $1/MJ in Albuquerque and — $3/MJ in Charleston. Comparison of day-night storage with weekend storage shows weekend storage to have lower value. This is to be expected since day-night storage is useable every day, whereas weekend storage is useable roughly one-seventh of the time. The effect of collector cost reductions, while dramatic for day/night storage, disappears for weekend storage when V is large. This is a consequence of the shift from one criterion to the other in Eq. (15.4.6). These storage values are to be compared with cost projections for various storage technologies suitable for this temperature range, e.g., oil tanks, tanks

444

Active Solar Collectors and Their Applications

with oil plus rocks, and phase change salt. Tanks with oil plus rocks seem to have the lowest storage cost, on the order of $2/MJ, (Steams-Rogers Services, Inc., 1981). (The rocks also improve performance by stratification.) In sunny locations oil with rocks does look promising. REFERENCES Bergeron, K. D. 1981. "A Simple Formula for Calculating the Optimal Frequency for Cleaning Concentrating Solar Collectors." Report SAND 81-1823J. Albuquerque, NM: Sandia National Laboratories. Eason, E. D. 1978. "The Cost and Value of Washing Heliostats." Report SAND 788813. Livermore, CA: Sandia Livermore Laboratories. Eicker, P. J. et al. 1981. "Design, Cost and Performance Comparisons of Several Solar Thermal Systems for Process Heat." Reports SAND 79-8279, 8280, 8281, 8282, and 8283. Livermore, CA: Sandia Livermore Laboratories. Gordon, J. M. and Rabl, A. 1982. "Design, Analysis and Optimization of Solar Industrial Process Heat Plants Without Storage." Solar Energy 28:519. Kreider, J. F. 1979. Medium and High Temperature Solar Processes. New York: Academic Press. Kreider, J. F. and Kreith, F. 1982. Solar Heating and Cooling—Active and Passive Design, 2nd ed. New York: Hemisphere Publishing Corporation, McGraw-Hill. PURPA. 1978. Public Utilities Regulatory Policy Act. U.S. Congress. Rabl, A. and Gaul, H. W. 1981, "An Assessment of Thermal Storage Technologies for Solar Industrial Process Heat." Presented at Storage Technology Review Meeting, Golden, CO. Steams-Rogers Services, Inc. 1981. "Cost and Performance of Thermal Storage Concepts in Solar Thermal Systems—Phase I, Water/Steam, Organic Fluid and Closed Air Brayton Receivers," by Dubberly, L. J. et al., under subcontract XP-0-9001-1 for SERI. Report no. SERI/PR-XP-O-9001-l-A. Denver, CO: Steams-Rogers Services, Inc.

APPENDIX A. NOMENCLATURE

I have attempted to make the subscripts as logical and self-expanatory as possible. Also, to keep subscripts to a minimum, I have not used subscripts for quantities that refer directly to the solar collector. Therefore a few symbols differ slightly from those in other texts; for example, I have designated the U value of the collector by a simple U rather than UL. In these instances the traditional notation is indicated. Greek and special symbols are listed separately. If no units are shown in [], the quantities are dimensionless. ~d A A A^ -4dump Ag B(B) C C difc c d D / / Ji /(#) F

= = = = = = = = = = = = = = = = = =

Fm

=

F-m

=

Fx FJ.J g Gr

= = = =

levelized annual cost [$] Aap — aperture area of collector [m2] annual payment [$] absorber surface area [m2] threshold area for energy dumping [m2] ground area covered by collector array [m2] brightness distribution [W/m2 rad] or [W/m2 sterad] concentration ratio = A^/A^ capital cost of solar energy system [$] life cycle cost [$] specific heat at constant pressure [J/gm K] (also known as cp) absorber width or diameter [m] aperture width or diameter [m] solar fraction focal length [m] annual charge rate angular acceptance function 1, Fm, Fm, or FxFia depending on specification of collector temperature heat transfer factor based on mean fluid temperature Tm (also known as F and collector efficiency factor) heat transfer factor based on fluid inlet temperature T"in (also known as FR and heat removal factor) heat exchanger factor (also known as F'R/FR) radiation shape factor earth's acceleration = 9.80 m/sec2 Grasshof number 445

446

Active Solar Colectors and Their Applications

h = heat transfer coefficient [W/m2 K] ^amb — total (i.e., convective plus radiative) heat transfer coefficient from a surface to ambient [W/m2 K] ^wind = convective heat transfer coefficient from a surface to ambient [W/ m2K] H = daily total solar irradiation on collector aperture [J/m2] H(l = daily diffuse solar irradiation on horizontal [J/m2] Hh = daily hemispherical solar irradiation on horizontal [J/m2] H0 = daily extraterrestrial solar irradiation on horizontal [J/m2] i - inflation rate i = direction of incident ray / = solar irradiance [W/m2] on collector aperture Ih = beam solar irradiance at normal incidence (also called direct normal irradiance) [W/m2] 7fi = long term average of Ib during daylight hours [kW/m2] (12 h average) Id = diffuse solar irradiance on horizontal [W/m2] //, = hemispherical solar irradiance on horizontal [W/m2] /in = solar irradiance incident on aperture and accepted by absorber [W/ m2] A™ = peak solar irradiance on aperture [W/m2] /o = solar constant = 1373 W/m 2 /O.eff = effective solar constant (Eq. 2.2.1) k = thermal conductivity [W/m K] k, = hourly clearness index KT = daily clearness index = ratio of terrestrial over extraterrestrial solar radiation = Hh/H0 (also known as cloudiness index) K = extinction coefficient [m"'] K(6) - incidence angle modifer at incidence angle 0 K = all-day average incidence angle modifier L = latitude [radians] L = length [m] L = daily load [J] L - load rate [W] m = air mass m = flow rate in collector ^load = flow rate of load M = storage mass [kg] n = index of refraction n — day of year (n = 1 for 1 Jan) n = unit vector, with subscripts (e.g., c for collector normal, h for normal of horizontal surface, s for direction from earth to sun) N = lifetime for economic analysis [yr] Np = payback time [yr] A'2 = doubling time [yr] Nu = Nusselt number

Nomenclature

447

- present value [$] = energy price [$/GJ] = Prandtl number = energy [J] (daily, monthly, or yearly) = power [W] — energy per unit area [J/m2] or per unit length [J/m] = q0 — q{X + q2X2 = correlation for yearly collectible energy per aperture area [GJ/m2] as function of threshold X Qam = annual energy supplied by backup [J] q = power per unit area [W/m2] 4abs = power absorbed by collector [W/m2] 4ioSS = heat loss of collector [W/m2] R = sun-earth distance [m] r = radius of solar disk [m] r = discount rate rd = ratio of instantaneous diffuse irradiance/daily diffuse irradiance [sec~'] re = energy price escalation rate rh = ratio of instantaneous hemispherical irradiance/daily hemispherical irradiance [sec"'] r, = internal rate of return f = direction of reflected ray Ra = Rayleigh number Re = Reynolds number Sufi, = life cycle saving [$] ! = direction of transmitted ray t = solar time (i.e., time of day from solar noon) [h] (pm is +) tc = collector cutoff time [h] ts = sunset time [h] T = temperature [°C] rabs = absorber temperature [°C] Tamb = ambient temperature [°C] rcoll = collector temperature [°C] (Tabs, T-m, Tm, or rHX,,n) T"env = temperature of storage tank environment [°C] THXM - inlet temperature on load side of collector heat exchanger [°C] Tin = fluid inlet temperature [°C] ?"ioad = inlet temperature of process or load [°C] Tm = mean fluid temperature = (T-m + 7"out)/2 Toul = fluid outlet temperature [°C] ^mains = temperature of water mains [°C] rstag = stagnation temperature of collector [°C] ^stor = temperature of storage [°C] U = total heat loss coefficient of collector relative to aperture area [ W/ m 2 °C] (also known as U,) t/back = heat loss coefficient for losses through back of collector [W/m2 °C] t^from = neat loss coefficient for losses through front of collector [W/m2 °C] P pe Pr <2 Q q q(X)

448

^equiv v V X X' Xf Xf Y Yf

Active Solar Colectors and Their Applications

= = = = = = =

(— 1) X slope of linearized efficiency curve [ W/m2 °C] wind speed [m/sec] value [$] threshold = U(Tcotl - Tamb)/r,0 [kW/m2] dimensionless heat loss parameter in 0, /chart critical intensity ratio in utilizability method dimensionless heat loss parameter in /chart dimensionless insolation parameter in 0, /chart dimensionless insolation parameter in/chart

GREEK SYMBOLS a a /3 /30 &T 7 F(0) 5 A3. t 7j 7jaux ?70 ^oefr 'Jo.equiv 0 0, 0|,0i 6x: X \ v p Pground p a a a ^contour

= = = = — = = = = = = = =

absorptivity for solar radiation thermal diffusivity [m2/sec] collector tilt from horizontal [°] (+ is up) collector tilt from equatorial plane, /30 = /? — \ coefficient of thermal expansion [K~'] intercept factor end loss factor for parabolic trough at incidence angle 8 declination [°] angular radius of solar disk [mrad] emissivity efficiency efficiency of backup optical efficiency = optical efficiency including effects due to warming of glazing or reflectors = intercept of linearized efficiency curve = angle of incidence on collector [°] = solar zenith angle (angle of incidence on horizontal surface) [°] = projected angles of incidence parallel and perpendicular to collector axis [°] ~ projected indicidence angle on xz plane [°] = wavelength [nm] = latitude [°] (+ is north) = kinematic viscosity [m2/sec] = reflectance = reflectance of ground = density [g/cm3] = Stephan-Boltzmann constant = 5.670 X 10" 8 W/m 2 K 4 = rms angular half-width of radiation source or of error distribution [mrad] = optical error, with subscripts as appropriate (one-sided rms deviation from design direction) [mrad] = contour error [mrad]

Nomenclature

449

^displacement = error due to displacement of receiver relative to aperture (equivalent angular rms deviation) [mrad] o^toi = total optical error [mrad] ocular - error due to lack of perfect specularity [mrad] o-sun = rms angular width of sun [mrad] tracking T r T Tday

T,oad TOP rycar $ 0 0S 0 4> 4/ a) w, Wj

= = = = = = = = = = = — = = = =

2 [ 0"sun

i 2 ll/2 + ffoptj

tracking error [mrad] tax rate transmittance time interval or cumulative time [sec] 24 X 3600 sec = 86,400 sec annual operating time of load [sec] daily operating time of collector [sec] 365.25 X 24 X 3600 sec = 3.16 X 107 sec rim angle [°] azimuth (+ is west) [°] azimuth of sun (+ is west) [°] utilizability ground cover ratio tracking angle hour angle = 360° t/24 h sunset hour angle [°] hour angle of Eq. (2.3.18) [°]

SPECIAL SYMBOLS

£[ ]+ ^i-i

= sum over positive terms only = fraction of radiation emitted by surface / that reaches surface j, either directly or via intervening reflection(s) and/or refraction (A/P, r, N) = capital recovery factor (P/F, r, N) = present worth factor overbars = bars j3ver_insolation variables designate long term average; e.g., KT, Hh, Ib bars over economic variables indicate levelizing; e.g., pe

APPENDIX B. UNITS1

SI UNITS

SOME CONVERSIONS OF UNITS

Basic units (name, symbol, quantity)

Exact conversion factors are indicated by an asterisk(*)

meter, m length kilogram, kg mass second, s time kelvin, K thermodynamic temperature Derived units All other units are derived from basic and supplementary units. Some derived units have special names.

Length m, tn/s 1 1 1 1 1 1

ft = 0.304 8* m in = 25.4* mm mile = 1.609km ft/min = 0.00508* m/s mile/hr = 0.447 0 m/s km/hr = 0.277 78 m/s

Area m2 Decimal multiples of units The following prefixes are recommended for use with SI units: teraT 1012, gigaG 109, megaM 10", kilo k 103, milli m 10"3, micro M 10~6, nano n 10 9, pico p 1(T12, femtof 10~15, attoa 1(T18 The use of the following prefixes should be limited: hectoh 102, decada 10, decid 10~', centi c 10~2

1 ft2 = 0.092 903 04* m2 1 in.2 = 0.000645 16*m 2 1 mile2 = 2.590 km2 Volume m3, m3/kg, m3/s (Note: 1 liter = 1(T3 m3) 1 ft 3 = 28.32 liters 1 U.K. gal = 4.546 liters 1 U.S. gal = 3.785 liters 1 ft3/lb = 0.062 43 m3/kg 1 cfm = 0.471 9 liters/s 1 U.K. gpm = 0.075 77 liters/s 1 U.S. gpm = 0.063 09 liters/s 1 cfm/ft 2 = 5.080 liters/s m 2

'Reprinted from Duffie and Bcckman [1980], with permission of John Wiley & Sons.

450

451

Units

Force newton N = kg m/s2, N/m2 pascal Pa = N/m2 1 Jbf = 4.448 N 1 Ibf/ft = 14.59 N/m

1 dyne/cm = 1 (mN)/m 1 mm H2O = 9.806 65* Pa 1 bar = 105 Pa 1 psi = 6.894 kPa 1 inH 2 O = 249.1 Pa 1 mmHg = 133.3 Pa 1 at = kgf/cm2 = 98.066 5* kPa 1 atm = 101.325* kPa Energy joule J = Nm = Ws, J/kg, J/kg °C 1 kWh = 3.6* MJ 1 Btu = 1.055kJ 1 Therm = 105.5MJ 1 kcal = 4.186 8* kJ 1 Btu/lb = 2.326 kj/kg 1 Btu/lb F = 4.186 8* kJ/kg °C 1 Btu/ft2 = 0.01136MJ/m 2

1 cal/cm2 = 0.04187 MJ/m2 Power watt = J/s = N m/s, W/m2, W/m2 °C, W/m °C 1 Btu/h = 0.293 1 W 1 kcal/h = 1.163* W

1 hp = 0.745 7 kW 1 Tonrefr. = 3.51 7 kW 1 w/ft2 = 10.76 W/m2 1 Btu/h ft2 F = 5.678 W/m2 °C 1 Btu/h f t F = 1.731 W/m°C 1 Btu/h ft2 (F/in) = 0.1443 W/m °C 1 Btu/ft2h = 3.155 W/m2 Viscosity Pas = N s/m2 = kg/m s 1 cP (centipoise) = 10"3 Pa s 1 lbfh/ft 2 = 0.1724MPas Mess kg, kg/m3, kg/s, kg/s m2 1 Ib = 0.453 56* kg 1 oz = 28.35 g 1 Ib/ft3 = 16.02 kg/m2 1 g/cm3 = 103 kg/m3 1 Ib/h = 0.000 125 6 kg/s 1 Ib/h ft2 = 0.001 356 kg/s m2 Plane angle rad 2ir rad = 360* degrees Diffusivity

nf/s

1 cST (centistoke) = 10~6 m2/s 1 ft2/h = 25.81 X 10- 6 m 2 /s

APPENDIX C. PROPERTIES OF MATERIALS

Aluminum Copper Steel Stainless steel Window glass Concrete (building) Glass wool Mineral wool Polyurethane foam (rigid) Polystyrene (expanded) Ice Water Steam (at 100°C, atm. press.) Air (at 20°C, atm. press.)

k = thermal conductivity (W/m K)

p = density (kg/m3)

210 385 47.6 18 1.05 1.73 0.04-0.05 0.04 0.025 0.04 2.26 0.598 at 20°C

2675 8795 7850 7850 2500 2400 24 32 24 16 918 1000at4°C

0.025

0.60 1.204

0.026

c = specific heat at constant pressure [kJ/kg K] 0.94 at 100°C 0.39 at 100°C 0.50 — 0.84 0.84 —

2.10 4.186 1.95 1.012

Other properties Latent heat Heat of melting, ice/water Heat of vaporization, water/steam Kinematic viscosity v Air Water Thermal diffusivity a Air Water

452

333 kJ/kg 2257kJ/kgat 100°C 14.95 X 10"6 m2/sec at 20°C, atm. press. 1.01 X 10~6 m2/sec at 20°C, atm. press. 21.2 X 10~6 m2/sec at 20°C, atm. press. 0.142 X 10"6 m2/sec at 20°C, atm. press.

APPENDIX D. METEOROLOGICAL DATA

TABLE D. 1 Extraterrestrial Daily Solar Irradiation on Horizontal Surface, in MJ/m2, as Function of Latitude and Time of Year3 1 Feb. 14 Feb.

1 Mar.

15 Mar.

1 Apr.

15 Apr.

1 May

15 May

1 Jun.

15 Jun.

0.00 0.43 2.66 5.44

0.49 2.99 5.95 9.04

4.27 7.49 10.68 13.82

10.86 13.83 16.78 19.63

19.08 20.78 23.04 25.35

28.85 28.35 29.34 30.89

36.69 35.99 35.21 35.77

42.34 41.53 40.40 39.66

44.79 43.93 42.74 41.50

5.55 8,50 11.54 14.62

8.43 11.50 14.56 17.58

12.14 15.21 18.20 21.07

16.85 19.76 22.52 25.11

22.35 24.91 27.29 29.47

27.59 29.68 31.60 33.30

32.51 34.05 35.44 36.64

36.72 37.70 38.59 39.31

39.96 40.44 40.90 41.23

41.43 41.66 41.91 42.06

15.20 18.28 21.29 24.20

17.66 20.64 23.51 26.24

20.51 23.32 25.98 28.47

23.79 26.35 28.72 30.88

27.52 29.71 31.68 33.41

31.42 33.14 34.61 35.82

34.77 35.99 36.95 37.65

37.61 38.34 38.81 39.01

39.82 40.11 40.15 39.93

41.38 41.32 41.01 40.47

42.03 41.80 41.34 40.65

25.95 28.70 31.29 33.70

26.99 29.62 32.08 34.33

28.81 31.20 33.38 35.33

30.76 32.84 34.68 36.28

32.81 34.50 35.94 37.11

34.89 36.10 37.04 37.69

36.75 37.41 37.79 37.87

38.07 38.21 38.06 37.64

38.95 38.60 37.99 37.10

39.44 38.70 37.69 36.43

39.67 38.62 37.33 35.79

39.70 38.52 37.10 35.44

35.90 37.87 39.61 41.09

36.36 38.15 39.70 40.99

37.04 38.50 39.70 40.62

37.62 38.68 39.47 39.97

38.00 38.61 38.93 38.96

38.06 38.14 37.93 37.44

37.68 37.19 36.43 35.38

36.93 35.96 34.71 33.21

35.95 34.55 32.90 31.02

34.93 33.19 31.22 29.05

34.03 32.04 29.86 27.49

33.56 31.48 29.20 26.75

42.32 43.29 44.00 44.45

42.01 42.76 43.24 43.46

41.26 41.62 41.71 41.51

40.19 40.12 39.77 39.13

38.70 38.15 37.32 36.22

36.65 35.59 34.26 32.67

34.08 32.51 30.69 28.65

31.47 29.50 27.31 24.93

28.93 26.63 24.16 21.54

26.70 24.18 21.52 18.74

24.96 22.30 19.52 16.65

24.15 21.42 18.60 15.71

44.65 44.64 44.44 44.12

43.42 43.16 42.69 42.07

41.06 40.36 39.43 38.31

38.23 37.07 35.68 34.07

34.85 33.23 31.38 29.31

30.83 28.76 26.47 23.99

26.39 23.93 21.29 18.50

22.37 19.66 16.82 13.88

18.78 15.92 13.00 10.05

15.87 12.96 10.04 7.18

13.75 10.83 7.97 5.23

12.80 9.90 7.07 4.41

43.80 43.78 45.00 46.25

41.39 40.87 41.26 42.41

37.08 35.83 34.84 35.16

32.30 30.42 28.56 27.06

27.04 24.63 22.11 19.60

21.32 18.49 15.53 12.47

15.57 12.53 9.42 6.27

10.89 7.87 4.91 2.15

7.14 4.34 1.81 0.05

4.45 2.00 0.20 0.00

2.72 0.70 0.00 0.00

2.04 0.28 0.00 0.00

1 Jul.

15 Jul.

1 Aug.

15 Aug.

1 Sep.

1 5 Sep.

1 Oct.

15 Oct.

44.36 43.51 42.33 41.15

41.10 40.31 39.21 38.72

34.69 34.03 33.56 34.38

26.31 26.15 27.53 29.27

16.07 18.30 20.80 23.29

8.57 11.68 14.72 17.65

3.04 6.14 9.29 12.41

0.06 2.11 4.90 7.90

1 Jan.

15 Jan.

0.00 0.00 0.00 0.38

32

46

0.00 0.00 0.00 1.08

0.00 0,00 0.63 2.84

2.33 4.89 7.76 10.78

3.37 6.10 9.05 12.11

40 35 30 25 20 15 10 5

13.87 16.98 20.05 23.05

0

Latitude

80 75 70 65 60 55 50 45

~5

-10 -15 -20 -25 -30 -35 -40 -45 -50 -55 -60 -65 -70 -75 Latitude

80 75 70 65

1

182

16

197

213

228

60

244

75

259

91

274

106

289

121

136

1 Nov. 15 Nov.

305

320

0.00 0.00 1.66 4.21

0.000 0.00 0.13 1.93

152

167

1 Dec. 15 Dec.

335

350

0.00 0.00 0.00 0.72

0.00 0.00 0.00 0.29

453

454

Active Solar Colectors and Their Applications

TABLE D. 1 Extraterrestrial Daily Solar Irradiation on Horizontal Surface, in MJ/m2, as Function of Latitude and Time of Year3 (continued) 1 Jul. 182

15 Jul. 197

1 Aug. 213

1 5 Aug. 228

1 Sep. 244

15 Sep. 259

1 Oct. 274

15 Oct. 289

1 Nov. 305

15 Nov. 320

60 55 50 45

41.14 41.42 41.70 41.87

39.15 39.74 40.28 40.68

35.49 36.60 37.60 38.43

31.04 32.71 34.22 35.53

25.67 27.90 29.94 31.78

20.46 23.11 25.59 27.87

15.45 18.38 21.18 23.82

10.96 14.01 17.00 19.89

7.08 10.08 13.13 16.15

4.46 7.30 10.29 13.35

2.85 5.50 8.40 11.43

2.16 4.69 7.53 10.54

40 35 30 25

41.87 41.66 41.22 40.55

40.90 40.90 40.67 40.18

39.05 39.43 39.57 39.44

36.61 37.45 38.04 38.36

33.39 34.76 35.87 36.72

29.95 31.79 33.40 34.75

26.29 28.56 30.61 32.44

22.65 25.26 27.69 29.93

19.11 21.98 24.71 27.29

16.40 19.41 22.33 25.14

14.52 17.60 20.63 23.58

13.63 16.74 19.81 22.82

20 15 10 5

39.63 38.47 37.07 35.43

39.45 38.46 37.23 35.75

39.06 38.41 37.50 36.33

38.40 38.18 37.68 36.91

37.30 37.59 37.61 37.35

35.84 36.65 37.19 37.44

34.01 35.34 36.39 37.17

31.94 33.72 35.26 36.54

29.69 31.88 33.86 35.60

27.80 30.29 32.58 34.66

26.40 29.08 31.59 33.91

25.73 28.50 31.11 33.54

0 -5 -10 -15

33.57 31.50 29.24 26.81

34.04 32.12 29.98 27.66

34.92 33.26 31.38 29.29

35.87 34.58 33.04 31.26

36.80 35.99 34.90 33.55

37.41 37.10 36.50 35.63

37.66 37.88 37.80 37.44

37.54 38.27 38.71 38.87

37.08 38.31 39.27 39.94

36.51 38.12 39.47 40.56

36.01 37.89 39.52 40.90

35.77 37.77 39.54 41.05

-20 -25 -30 -35

24.23 21.51 18.70 15.82

25.18 22.55 19.80 16.97

27.01 24.56 21.95 19.23

29.27 27.07 24.68 22.13

31.96 30.12 28.07 25.81

34.48 33.07 31.42 29.52

36.79 35.87 34.68 33.22

38.74 38.33 37.64 36.67

40.34 40.45 40.29 39.84

41.37 41.91 42.18 42.18

42.01 42.86 43.45 43.77

42.32 43.32 44.07 44.56

-40 -45 -50 -55

12.91 10.01 7.19 4.51

14.08 11.18 8.31 5.55

16.40 13.52 10.62 7.74

19.44 16.64 13.75 10.83

23.36 20.74 17.98 15.11

27.40 25.07 22.55 19.86

31.51 29.57 27.41 25.04

35.44 33.96 32.24 30.31

39.14 38.18 36.99 35.60

41.92 41.42 40.70 39.82

43.85 43.70 43.36 42.88

44.80 44.83 44.68 44.42

-60 -65 -70 -75

2.13 0.33 0.00 0.00

3.01 0.90 0.00 0.00

4.98 2.46 0.46 0.00

7.90 5.06 2.43 0.35

12.15 9.14 6.13 3.22

17.02 14.05 10.99 7.84

22.49 19.77 16.93 14.00

28.19 25.93 23.59 21.32

34.06 32.44 30.93 30.09

38.84 37.91 37.43 38.34

42.37 42.07 42.88 44.08

44. 17 44.25 45.58 46.85

Latitude

a

Number under date shows day of year.

1 Dec. 15 Dec. 335 350

Figure D. 1 Monthly average clearness index KT for the United States in January (From SERI [1980]).

Figure D.2 Monthly average clearness index KT for the United States in February (From SERI [1980]).

Figure D.3 Monthly average clearness index KT for the United States in March (From SERI [1980]).

Figure D.4 Monthly average clearness index KT for the United States in April. (From SERI [1980]).

Figure D.5 Monthly average clearness index KT for the United States in May. (From SERI [1980]).

Figure D.6 Monthly average clearness index Kr for the United States in June. (From SERI [1980]).

Figure D.7 Monthly average clearness index KT for the United States in July. (From SERI [1980]).

Figure D.8 Monthly average clearness index KT for the United States in August. (From SERI [1980]).

Figure D.9 Monthly average clearness index Kr for the United States in September. (From SERI [1980]).

Figure D.10 Monthly average clearness index KT for the United States in October. (From SERI [1980]).

Figure D. 11 Monthly average clearness index KT for the United States in November. (From SERI[1980]).

Figure D. 12 Monthly average clearness index KT for the United States in December. (From SERI[1980]).

Meteorological Data

467

Figures D.I3 through D.24 depict the monthly average clearness index KT for the world from January to December (From World Meteorological Association [1980]). D.I3 January D. 14 February D.I5 March D.I6 April D. 17 May D. 18 June

D.I9 July D.20 August D.21 September D.22 October D.23 November D.24 December

Figure D. 13 January

Figure D.I4 February

Figure D. 15 March

Figure D. 16 April

Figure D. 17 May

Figure D. 18 June

Figure D.I9 July

Figure D.20 August

Figure D.21 September

Figure D.22 October

Figure D.23

November

Figure D.24 December

Figure D.25 Annual average daytime (dry bulb) temperature [°C] (From SERI [1981]).

Figure D.26 Annual heating degree days [°C day] to base 18.3°C (From SERI [1981]).

Figure D.27 Annual cooling degree days [°C day] to base 18.3°C (From SERI [1981]).

APPENDIX E. CIRCUMSOLAR DATA

TABLE E. 1 Monthly Average Circumsolar Ration Rm(X) versus Threshold Xa X(W/m2)

Yr/Mo

Hours of data

0

50

150

300

500

Atlanta, GA

77/06 77/07 77/08 77/09 77/10 77/11 77/12 78/01 78/02 78/03 78/04 78/05 78/06

163 251 273 123 246 103 73 191 234 228 135 173 216

0.081 0.063 0.109 0.076 0.036 0.039 0.049 0.057 0.055 0.043 0.068 0.050 0.071

0.078 0.059 0.100 0.071 0.034 0.033 0.044 0.051 0.049 0.040 0.064 0.045 0.066

0.070 0.051 0.083 0.058 0.031 0.029 0.034 0.045 0.044 0.037 0.056 0.033 0.061

0.057 0.041 0.060 0.043 0.027 0.020 0.022 0.034 0.033 0.030 0.050 0.023 0.050

0.039 0.026 0.039 0.024 0.019 0.013 0.018 0.022 0.023 0.025 0.039 0.018 0.031

Albuquerque, NM

76/05 76/06 76/07 76/08 76/09 76/10 76/11 76/12 77/02 77/02 77/03 77/04 77/05 77/06 77/07 77/09 77/10 77/11 77/12

80 318 199 326 106

0.021

0.020 0.028 0.026 0.031 0.039 0.039 0.024 0.035 0.037 0.045 0.058 0.037 0.035 0.053 0.040 0.039 0.040 0.057 0.052

0.019 0.025 0.024 0.028 0.037 0.035 0.023 0.033 0.031 0.040 0.051 0.033 0.031 0.050 0.036 0.036 0.039 0.054 0.049

0.016 0.022 0.017 0.025 0.027 0.030 0.022 0.029 0.023 0.036 0.039 0.028 0.026 0.042 0.031 0.031 0.037 0.048 0.042

0.015 0.018 0.014 0.020 0.019 0.021 0.017 0.024 0.017 0.028 0.027 0.022 0.022 0.031 0.024 0.027 0.032 0.034 0.036

Location

297

260 254 254 242 59 301 282 159 383 234 239 221 202

0.029 0.027 0.032 0.040 0.040 0.024 0.036 0.040 0.046 0.060 0.039 0.036 0.054 0.041 0.039 0.041 0.058 0.053

483

484

Active Solar Colectors and Their Applications

TABLE E. 1 Monthly Average Circumsolar Ration Rm(X) versus Threshold X" (continued) X(W/m2)

Location

Yr/Mo

Hours of data

Ft. Hood, TX

76/07 76/08 76/09 76/10 76/11 76/11 76/12 77/01 77/02 77/03 77/04 77/07

131 361 121 115 88 84 155 155 165 248 101 74

0.040 0.034 0.041 0.050 0.027 0.035 0.053 0.062 0.053 0.084 0.027 0.040

0.039 0.033 0.040 0.049 0.026 0.032 0.051 0.061 0.052 0.081 0.027 0.038

0.037 0.031 0.036 0.047 0.025 0.026 0.044 0.058 0.049 0.075 0.026 0.037

0.035 0.026 0.036 0.041 0.024 0.021 0.036 0.047 0.042 0.063 0.024 0.036

0.027 0.022 0.029 0.033 0.011 0.016 0.027 0.037 0.031 0.049 0.021 0.031

Argonne, IL

77/08 77/09 77/10 77/11 77/12

63 140 152 130 115

0.124 0.095 0.079 0.094 0.148

0.120 0.091 0.069 0.083 0.127

0.098 0.085 0.062 0.073 0.112

0.078 0.076 0.055 0.067 0.100

0.063 0.055 0.046 0.043 0.078

China Lake, CA

76/07 76/08 76/09 76/10 76/11 76/12 77/01 77/02 77/03

187 392 35 262 246 268 176 248 143

0.031 0.013 0.030 0.023 0.025 0.026 0.044 0.045 0.052

0.030 0.013 0.030 0.023 0.024 0.026 0.043 0.044 0.052

0.027 0.012 0.026 0.021 0.023 0.025 0.038 0.043 0.051

0.025 0.011 0.022 0.019 0.020 0.023 0.036 0.036 0.043

0.017 0.009 0.020 0.016 0.016 0.016 0.025 0.027 0.037

Barstow, CA

77/07 77/08 77/09 77/10 77/11 77/12 78/01 78/02 78/03 78/04 78/05 78/06

33 341 265 232 268 236 59 65 136 284 411 247

0.083 0.030 0.028 0.042 0.061 0.058 0.080 0.061 0.030 0.042 0.034 0.024

0.082 0.029 0.028 0.041 0.059 0.054 0.074 0.058 0.028 0.040 0.034 0.024

0.080 0.027 0.026 0.040 0.056 0.050 0.064 0.054 0.025 0.039 0.032 0.023

0.077 0.024 0.023 0.034 0.047 0.039 0.060 0.041 0.017 0.033 0.028 0.022

0.064 0.019 0.020 0.027 0.033 0.025 0.039 0.029 0.014 0.022 0.025 0.020

"From Rabl and Bendt [1982].

0

50

150

300

500

485

Circumsolar Data TABLE E.2 Standard Solar Brightness Distribution"

Break in size of angular interval

6 (mrad)b

B(0) (W/m2 sterad)c

0.218 0.654 1.091 1.527 1.963 2.400 2.836 3.272 3.709 4.145 4.581 5.018 5.454 5.890 6.327 6.763 7.199 7.636 8.072 8.508 9.381 10.690 11.999 13.308 14.617 15.926 17.235 18.544 19.853 21.162 22.471 23.780 25.089 26.398 27.707 29.016 30.325 31.634 32.943 34.252 34.561 36.870 38.179 39.488 40.797 42.106 43.415 44.724 46.033 47.342

13,631,252 13,561,148 13,441,701 13,263,133 13,012,331 12,668,456 12,185,726 11,443,798 10,061,047 7,002,494 1,730,196 144,818 63,325 51,116 43,669 36,973 31,935 27,979 24,767 21,830 17,444 13,084 10,194 8,177 6,716 5,634 4,807 4,147 3,633 3,213 2,867 2,579 2,337 2,133 1,,958 1,805 1,672 1,550 1,444 1,353 1,268 1,194 1,127 1,070 1,018 969 923 882 845 811

Solar disk

Circumsolar region

486

Active Solar Colectors and Their Applications TABLE E.2 Standard Solar Brightness Distribution3 (continued) 6 (mrad)b Break in size of angular interval

48.651 49.960 51.269 52.578 53.887 55.196

B(6) (W/m2 steradf 777 747 722 700 681 665

"From Rabl and Bendt [1982]. b Solar radius 0.275 deg (disk plus resolution of instrument). 'Brightness at angle 8 from center of sun.

487

Circumsolar Data TABLE E.3 Solar and Circumsolar Intercept Factors for Parabolic Trough with 90° Rim Angle, Cyclindrical Receiver, Concentration C, and Optical Error o-opta

C 10. 10. 10. 10.

10. 10. 10.

10. 15.

15. 15. 15. 15. 15. 15. 15. 20. 20. 20. 20. 20. 20. 20. 20. 25. 25. 25. 25. 25. 25. 25. 25. 30. 30. 30. 30. 30. 30. 30. 30. 40. 40. 40. 40. 40. 40. 40. 40.

"opt

Ts,av

3.0 4.0 5.0 6.0 8.0 10.0 15.0 20.0 3.0 4.0 5.0 6.0 8.0 10.0 15.0 20.0 3.0 4.0 5.0 6.0 8.0 10.0 15.0 20.0 3.0 4.0 5.0 6.0 80. 10.0 15.0 20.0 3.0 4.0 5.0 6.0 8.0 10.0 15.0 20.0 3.0 4.0 5.0 6.0 8.0 10.0 15.0 20.0

1.0000 1.0000 1.0000 1.0000 1.0000 0.9999 0.9946 0.9733 1.0000 1.0000 1.0000 0.9999 0.9989 0.9941 0.9549 0.8830 1.0000 1.0000 0.9997 0.9986 0.9905 0.9712 0.8815 0.7714 1.0000 0.9996 0.9976 0.9926 0.9696 0.9302 0.7972 0.6701 0.9998 0.9977 0.9914 0.9793 0.9369 0.8775 0.7167 0.5861 0.9960 0.9844 0.9625 0.9311 0.8504 0.7641 0.5841 0.4625

"From Rabl and Bendt [1982].

Ts,av

Tc,av

0.0262 0.0269 0.0279 0.0292 0.0324 0.0366 0.0490 0.0568 0.1031 0.1045 0.1064 0.1089 0.1149 0.1205 0.1221 0.1068 0.1787 0.1812 0.1845 0.1880 0.1929 0.1916 0.1626 0.1219 0.2432 0.2471 0.2510 0.2534 0.2501 0.2354 0.1750 0.1199 0.2990 0.3034 0.3056 0.3037 0.2866 0.2565 0.1731 0.1121 0.3903 0.3892 0.3799 0.3627 0.3132 0.2595 0.1551 0.0945

488

Active Solar Colectors and Their Applications TABLE E.4 Solar and Circumsolar Intercept Factors for Parabolic Dish of Rim Angle <j>, Flat One-Sided Receiver, Concentration C, and Optical Error aoff

30.

30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 30. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40.

ff

opt

C

[mrad]

Ts,av

200. 200. 200. 200. 200. 500. 500. 500. 500. 500. 1 000. 1000. 1 000. 1 000. 1000. 2000. 2000. 2000. 2000. 2000. 5000. 5000. 5000. 5000. 5000. 10000. 10000. 10000. 10000. 10000. 200. 200. 200. 200. 200. 500. 500. 500. 500. 500. 1000. 1 000. 1000. 1 000. 1 000. 2000. 2000. 2000.

14.0 18.0 22.0 26.0 30.0 10.0 12.0 14.0 16.0 18.0 6.0 7.0 8.0 9.0 10.0 3.0 4.0 5.0 6.0 7.0 1.5 2.0 2.5 3.0 3.5 1.0 1.5 2.0 2.5 3.0 14.0 18.0 22.0 26.0 30.0 10.0 12.0 14.0 16.0 18.0 6.0 7.0 8.0 9.0 10.0 3.0 4.0 5.0

0.9539 0.8489 0.7206 0.6000 0.4984 0.9067 0.8126 0.7115 0.6163 0.5325 0.9531 0.9017 0.8372 0.7668 0.6966 0.9914 0.9525 0.8786 0.7850 0.6882 0.9874 0.9560 0.9060 0.8431 0.7737 0.9275 0.8515 0.7670 0.6810 0.5982 0.9913 0.9499 0.8711 0.7735 0.6752 0.9757 0.9305 0.8645 0.7879 0.7095 0.9911 0.9738 0.9440 0.9028 0.8535 0.9992 0.9912 0.9644

Ts,av

Tc,av

0.2467 0.2175 0.1715 0.1283 0.0943 0.3858 0.3377 0.2827 0.2310 0.1867 0.5184 0.4910 0.4511 0.4053 0.3590 0.6444 0.6294 0.5794 0.5087 0.4339 0.8029 0.7807 0.7380 0.6812 0.6171 0.8722 0.7883 0.6979 0.6078 0.5224 0.1530 0.1640 0.1537 0.1312 0.1062 0.3228 0.3124 0.2869 0.2532 0.2177 0.4422 0.4424 0.4329 0.4139 0.3878 0.5503 0.5594 0.5540

489

Circumsolar Data TABLE E.4 Solar and Circumsolar Intercept Factors for Parabolic Dish of Rim Angle , Flat One-Sided Receiver, Concentration C, and Optical Error (Topta (continued)

40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 40. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 50. 60. 60. 60. 60. 60. 60.

C

2000. 2000. 5000. 5000. 5000. 5000. 5000. 10000. 10000. 10000. 10000. 10000. 200. 200. 200. 200. 200. 500. 500. 500. 500. 500. 1000. 1000. 1 000. 1000. 1000. 2000. 2000. 2000. 2000. 2000. 5000. 5000. 5000. 5000. 5000. 10000. 10000. 10000. 10000. 10000. 200. 200. 200. 200. 200. 500.

fopi

[mrad] 6.0 7.0 1.5 2.0 2.5 3.0 3.5 1.0 1.5 2.0 2.5

3.0 14.0 18.0 22.0 26.0 30.0 10.0 12.0 14.0 16.0 18.0

6.0 7.0 8.0 9.0 10.0 3.0 4.0 5.0 6.0 7.0 1.5 2.0 2.5 3.0 3.5 1.0 1.5 2.0 2.5 3.0 14.0 18.0 22.0 26.0 30.0 10.0

7s,av

0.9145 0.8472 0.9991 0.9934 0.9779 0.9497 0.9094 0.9909 0.9627 0.9132 0.8487 0.7762 0.9961 0.9761 0.9300 0.8616 0.7817 0.9890 0.9656 0.9258 0.8724 0.8107 0.9961 0.9881 0.9730 0.9497 0.9186 0.9996 0.9961 0.9836 0.9567 0.9145 0.9995 0.9971 0.9902 0.9764 0.9542 0.9959 0.9836 0.9581 0.9181 0.8659 0.9945 0.9757 0.9394 0.8869 0.8234 0.9871

Ts,av

Tc,av

0.5277 0.4847 0.7108 0.7152 0.7108 0.6938 0.6641 0.8395 0.8185 0.7740 0.7131 0.6437 0.0931 0.1114 0.1178 0.1121 0.0992 0.2565 0.2587 0.2510 0.2345 0.2126 0.3779 0.3823 0.3823 0.3765 0.3647 0.4888 0.4973 0.5009 0.4935 0.4731 0.6477 0.6526 0.6548 0.6512 0.6399 0.7762 0.7719 0.7551 0.7233 0.6786 0.0732 0.0859 0.0921 0.0913 0.0850 0.2132

490

Active Solar Colectors and Their Applications TABLE E.4 Solar and Circumsolar Intercept Factors for Parabolic Dish of Rim Angle <j>. Flat One-Sided Receiver, Concentration C, and Optical Error
60. 60. 60. 60. 60. 60. 60. 60. 60.

60. 60. 60. 60. 60. 60. 60. 60. 60. 60. 60. 60. 60. 60. 60.

"opt

C

[mrad]

7s,av

500. 500. 500. 500. 1 000. 1 000. 1 000. 1000. 1 000. 2000. 2000. 2000. 2000. 2000. 5000. 5000. 5000. 5000. 5000. 10000. 10000. 10000. 10000. 10000.

12.0 14.0 16.0 18.0 6.0 7.0 8.0 9.0 10.0 3.0 4.0 5.0 6.0 7.0 1.5 2.0 2.5 3.0 3.5 1.0 1.5 2.0 2.5 3.0

0.9671 0.9361 0.8952 0.8469 0.9944 0.9863 0.9731 0.9545 0.9306 0.9991 0.9944 0.9821 0.9599 0.9275 0.9988 0.9952 0.9878 0.9755 0.9577 0.9925 0.9802 0.9597 0.9298 0.8905

"From Rabl and Bendt [1982].

Ts,av

Tc,av

0.2154 0.2119 0.2030 0.1896 0.3386 0.3409 0.3402 0.3360 0.3283 0.4544 0.4599 0.4608 0.4547 0.4407 0.6130 0.6153 0.6151 0.6111 0.6025 0.7355 0.7291 0.7159 0.6940 0.6629

AUTHOR INDEX

Abdel-Khalik, S. I., 227 Adams, W. J., 137, 142 Aerospace Corp., 55, 65 Alcone, J. M., 279 Anderson, B. N., 325 Andrews, J. W., 11 Antal, M. J., 5 n ASHRAE, 83 n, 88, 220, 378 ASME, 22, 1 7 5 « 3 6 0 n Atkinson, B., 373 Atterkvist, S., 8 Atwater, M. A., 59 Backus, C. E., 357, 358 Balcomb, J. D., 325 Ball, J. T., 59 Baranov, V. K., 147 Bassett, I. M., 164 Battleson, K. W., 10, 175 n Beauchamp, E. K., 373 Beckman, W. A., 28, 30, 31, 59, 120-23, 225, 226, 245-48, 261, 265, 272-74, 285,321,327-29,450 Bendt, P., 72, 111, 144, 145, 201, 202, 207, 327 Berg, R. S., 388 Bergeron, K. D., 174 Biggs, F., 136, 138, 142, 174-81, 196, 207 Boes, E. C., 64, 65, 303 n Born, M. 114 Bos, P. B., 357 Braun, J. E., 320 Brown, K. C., 421,424 Bruno, R., 286 BSE, 101 Buchberg, H., 235 Butler, B. L., 137, 141, 370, 376, 389 Butti, K., 332

Caesar, R., 373 Call, P., 368 Carlson, D. E., 357 Catton, I., 235 Cess, R. D., 128,222,237,369 Champion, R. L., 389 Chiam, H. F., 167 Claassen, R. S., 370, 376 Clark, A. F., 11, 12 Clausing, A. M., 186 Collares-Pereira, M., 18, 65-70, 103, 164, 184, 185, 309-17, 346-49 Cooper, P. I., 89 Cramer, H., 137, 142 Dellin, T. A., 174 De Meo, E. A., 357 De Winter, F., 268 Dickinson, W. C, 11, 12, 303 n, 421, 424 Dudley, V. E., 102, 300 Duffle, J. A., 28, 30, 31, 59, 120-23, 225, 226, 245-48, 261, 265, 272, 285, 321, 330, 450 Dunkle, R. V., 89 Eckart, E. R. G., 269 Edmonds, I. R., 187 Dewards, D. K., 121 n, 235, 236, 248 Eggers, G. H., 189 Eicker, P. J., 174, 175,441 Engebretson, C. D., 330 Erbs, D, G., 62, 64, 66 Faiman, D., 362 Fanney, A. H., 335 Farrington, R., 335 Felland, J. R., 235

491

492

Author Index

Fewell, M. E., 285 Francia, G., 177,235 Freese, J. M., 389-91 Fried, J. R., 381 Frohlich, C, 29, 46 Garg, H. P., 249 Gaul, H. W., 98, 112, 300, 441 Gee, R. C, 237, 240, 241, 252, 392 Gerich, J. W., 187-89 Giutronich, J. E., 156, 187 Goldstein, R. G., 226 Gordon, J. M., I l l , 292-97, 304, 305, 334, 340, 435 Govaer, D., 338 Graham, B. J., 14-15 Grandjean, N. R., 285 Grassie, S. L., 166, 167 Grether, D. F, 136,209 Grunes, H., 334 Hall, I. J., 285 Harding, G. L., 368 Harrison, T. D., 101 Hay, H. R., 332 Hay, J. E., 56, 61, 66 Hickey, J. R., 29, 47 Hildebrandt, A. F, 175 n Hill, J. E., 99, 101, 103, 105-9 Hinterberger, H., 147, 149 Hollands, K. G. T., 81, 168, 223, 224, 235 Holmes, J. T., 392 Hottel, H. C, 62-63, 81, 268, 275, 309 Howell, J. R., 128 Hunn, B. D., 51 Hunt, A., 54, 136

Kreider, J. E., 29, 44, 47, 49, 186, 215, 229, 230, 252, 260, 270, 325, 327, 364, 368, 382 Kreilh, F, 29, 44, 47, 49, 215, 221, 229-31, 252, 258, 260, 261, 270, 325, 327, 364, 368, 382 Kritchman, E., 182-84, 192 Kuehn, T. H., 226 Kurzweg, U. H., 190 Kusuda, T., 286 Kutscher, C. F., 302, 351-53, 364, 385 Lamm, L. O., 47 n Lampert, C. M., 366 Larson, D. C. 167 Lcary, P., 174 Lind, M. A., 49, 50 Lipps, F. W., 174 Liu, B. Y. H., 63, 71-72, 81, 309 Lof, G. O. G., 81, 330, 363 Lunde, P. J., 254, 284 McAdams, W. H., 220, 221 McCormick, P. G., 190 McDaniels, D. K., 167 Mclntire, W. R., 154, i 61, 162, 164 Masterson, K., 81, 112 Melnikov, G. K., 147 Mertol, A., 334, 347 Meyer, B. A., 235 Michal, C. J., 325 Mills, D. R., 149, 156, 187 Minardi, J. E., 92 n Mitchell, J. W., 305, 330 Moon, T. T., 368 NASA, 29 Nielsen, C. E., 11, 12

lannucci, J. J., 355-56 Jenkins, J. P., 103 Jones, B. W., 397 Jordan, R. C, 63, 71-72, 81, 309 Jorgenson, G., 370, 372 Karaki, S., 330 Kays, W. M., 269 Kirkpatrick, D. L., 99, 332 Klein, S. A., 81, 243, 278, 284, 285, 309, 313/z, 318, 320-21,327-29, 353 Kondratyev, K. Y., 49 Kooi, C. F, 94

O'Donnell, D. T., 358 O'Gallagher, J. J., 18, 101, 158 O'Neill, M. J., 184, 186 Owens-Illinois, Inc., 98, 99 Pearson, K. A., 353 Perlin, J., 332 Peterson, R. E., 373 Pettit, R. B., 81, 138, 141, 376, 389 Pitman, C. L., 174 Ploke, M., 147 PURPA, 429

Author Index Ratal, A., 13, 65-67, 73, 75-79, 86, 111, 116, 124, 134, 136, 148-51, 154-56, 159, 196, 210, 227, 228, 287, 291-300, 305, 309-17, 340. 374, 441, 483-90 Ramsey, J. W., 373, 221 Randall, C. M., 55, 65 Reed, K. A., 103, 132, 145 Rhee, S. J., 236 Riaz, M., 174 Ross, M, H., 5 n Russell, J. L., 189 SANDIA, 102 Schrenck, G. M., 196 Selcuk, M. K., 165 Seraphin, B. O., 368, 374 SERI, 7, 8, 57, 58, 455-66, 480-82 Sheridan, N. R., 166, 167 Siegel, R., 128 Sillman, S., 8, 325 Smestad, G., 374 Socolow, R. H., 363,411 Solar Age Magazine, 387 Solar Products Specifications Guide, 9-10 SOLMET, 53, 55, 78, 281 Sparrow, E. M, 128, 221, 222, 237, 369 Streed, E. R., 107 Sullivan, T., 380 Sunmaster, Inc. 17, 100 Sunworld Magazine, 357 Supple, R. G., 332 Tabor, H., 11, 88, 189, 218, 222, 223, 225, 231,233 Thodos, G., 268

493

USDOC, 7 U.S. Home Finance Agency, 222 Vant-Hull, L. L., 174, 194 Vitko, J., 371 Vitro Labs, 330 Vittitoe, C. N., 136, 138, 142, 174-81, 196, 207 Von Hippel, F., 76-79 Vresk, J., 368, 371-73, 377 Walton, J. D., 190 Walzel, M. D., 174 Weinberger, Z., 11 Welford, W. T., 151, 156, 192 Whillier, A., 35, 47, 268, 275, 309 Wilhelm, W. G., 11 Williams, R. H., 5 n Window, B., 164, 368 Winston, R., 26, 112, 146, 147, 149-51, 161-62, 164, 374 WMO, 58, 61,467-79 Wolf, M., 357, 358 Wood, R. L., I l l Workhoven, R. M., 102, 300

Yellot, J. I., 332 Yekutieli, G., 182-84

Zarmi, Y., 112, 303-5, 334, 338, 347, 362 Zeimer, H., 189

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SUBJECT INDEX

(A/P, r, N) definition, 401 values, 402 Absorber size approximate optimum, 171 optimization, 170 Absorptance, data, 367-68 Absorption at absorber, 122-23 atmospheric, 48-49, 174 within cover, 121-22 Absorption cooling, 331 Acceptance of diffuse radiation, 131-32 Acceptance half-angle and concentration, 125-31 of CPC, 147 definition, 84, 125 parabola, 171-72 Accuracy of tracking, data, 392-93 Acrylic, 370, 372 Air mass, 48 Air-inflated collectors, 189, 190 Albedo. See Reflectivity of ground Alzak aluminum sheet, 138, 374, 376 Ambient temperature data, U.S., 480 Amorphous silicon cells, 357 Angle of incidence equations, 40 fixed surfaces, derivation, 32-37 on horizontal, 33 tracking surfaces, derivation, 37-39 Angular acceptance function of CPC, 148 definition, 197 parabolic dish, 200-202 parabolic trough, 200 of V-trough, 165 Anisotropy of diffuse insolation, 56, 61 Annual charge rate definition, 418 effect of inflation, 397 n Annual energy. See Insolation on aperture

Annulus heat transfer equations, 225-27 results, 240-41 Antireflection coatings, 373 Aperture area, 83 n, 126 Area absorber surface, 126, 239 aperture, 83 n, 126 of collector array, 273 gross vs. net, 83 n, 103 reflector CPC, 154 parabolic, 172 ASHRAE test procedure, 88, 101, 103 accuracy, 107 specification of area, 83 Auxiliary, efficiency of, 407 Azimuth angle definition, 34 of sun, 36 Back loss, 232-34 Backup, energy form and storage, 24-25; see also Auxiliary, efficiency of Beam. See Insolation, beam Bellows, 13 Bias of data fit, 303 Biomass, 5 Black chrome, 365-67 Black fluid collectors, 92 n Black nickel, 367 Blackbody radiation, 127, 132 Blackbody spectrum, 49, 366 Blocking, 173 Bond, dust-surface, 388 Borosilicate glass, 371 Bouguer's law, 121-22, 371 Brewster angle, 119 Brightness distribution, solar/circumsolar, 133-36, 485-86 Buffer storage, 339

495

496

Subject Index

Calibrated heat source, 103-4 Capital recovery factor definition, 401 values, 402 Carnot efficiency, 359 Cassegrain optics, 193 Central heat collection, 354-56 Central limit theorem, 137 Central receiver atmospheric attenuation, 174 heat centralization, 354-56 incidence angle modifier, 174-75 optical analysis, 174-81 performance, 299-300, 441 power generation, 359, 361 power plant, 22, 175 Characteristic length, convection, 221 Charge rate, effect of inflation, 397 n Circumsolar distribution, standard, 134, 485-86 Circumsolar intercept factor, 210, 487-90 Circumsolar radiation and acceptance angle, 135-36 and collector performance, 209-11 definition, 134 Circumsolar ratio definition, 210 monthly data, 483-84 Circumsolar telescope, 54 Cleaning, 388-92 methods, 389 and reflectance, data, 390-91 Clear sky circumsolar radiation, 136 diffuse radiation, 63 radiation model, 62-63 Clearness index correlation with cloud cover, 52 correlation with sunshine hours, 52 data annual U.S., 58 annual world, 60 monthly U.S., 455-66 monthly world, 467-79 definition, 58 hourly, 64 typical values, 58 Closed loop, 106, 351-54 Cloud cover, 59 Coatings absorber, 365-69 antireflection, 373 heat mirror, 373 Cogeneration, 8, 287 photovoltaic systems, 359 Collectible radiation. See Insolation

Collector cost data, 9-10 efficiency. See Efficiency of collector efficiency factor definition, 90, 253-54 results, 254-63 mounting, 383 orientation, 381-83 technology survey, 8-23 Compound amount factor definition, 398 values, 399 Compound interest, growth rates, 405-6 Compound parabolic concentrator. See CPC Computer codes DELSOL, 174 HELIOS, 174 MIRVAL, 174 SCRAM, 174 SOLTES, 285 TRNSYS, 284-86 Computer simulation, 280-86 Concentration ratio definition, 125 and operating temperature, 132-33 of parabolic concentrators, 171-72 thermodynamic limit, 125-31 of tubular collectors, 239 Conduction back loss, 232-34 pipes, 231 Conductivity, temperature dependence, 378 Conic reflector, 190 Constant dollars, 396-97 Continuous compounding, 405-6 Contour error and reflected ray, 138-41 Controls, 277-79 Convection. See Heat transfer Conversion factors (units), 450-51 Convolution integral, 203 Cooldown rate, 108 Cooling, 330-32 Cosine loss, 175, 187 Cost avoided, 429 of collectors, 9, 10 cover materials, 370 fixed, 428 incremental, 428 reflector materials, 376-77 of saved energy comparison with other criteria, 41516

Subject Index definition, 409-10 example, 433 social, 2, 396 n of storage, 23, 444 Cover materials, 369-73 materials, data, 370 thermal effects of absorption, 246-48 transmittance, equations, 119-22 CPC angular acceptance, 148, 156 asymmetric, 149-50, 153 collector designs, 17-18 cutoff time, 43 definition, 147 design principle, 151-52 different absorber shapes, 149 for evacuated tubes, 157-64 gap, reflector-absorber, 159-64 gap loss, 159, 164 intercepted radiation, 85-86, 131-32 optical errors, 148, 156 restricted exit angles, 149, 151 n in three dimensions, 151 transmitted radiation, 154 truncation, 154-56 for tube, equation, 153 without gap loss, 161-64 Critical intensity ratio, monthly utilizability, 312 Currency, constant vs. inflating, 396-97 Current dollars, 396-97 Cutoff time, CPC, 43 Cylindrical reflector with tracking receiver, 186-88 Daily radiation. See Insolation Day number, 30 Debt financing, 407, 418-23 Declination equation, 31 graph, 35 Degree days cooling, data, U.S., 482 heating, data, U.S., 481 DELSOL (computer code), 174 Depreciation, 421, 422, 423, 424 definition, 421 effect of inflation, 424 and life cycle cost, 422, 423 Desiccant cooling, 330 Diffuse radiation. See Insolation, diffuse Direct radiation. See Insolation, beam Direct return, interconnection, 384-85

497

Dirt,388-92 Discount rate, 398-99 Diurnal variation of solar radiation, 68-69 Doubling time, 406 Dumping of energy electricity, 429-33 process heat, 341-44, 349-50 threshold for, 308 Durability, cover materials, 371-73 Dust, 388-92

Ecliptic, 29 Effective optical efficiency, 87, 247 Effective source, 196, 202-5 Effectiveness, heat exchanger, 269-70 Efficiency of auxiliary, 407 Carnot, 359 of collector conversion of temperature, 92-93 definition, 83 specification of insolation, 84-86 temperature base, 94 test procedures, 101-8 test results, 99-102 optical definition, 86 effective, 87, 247 equation, 87, 122, 205 equivalent, 89 of typical systems, 6, 331, 335, 345, 357, 361 Electric utilities, 24-25, 429 Electricity, 7, 335, 356-61 Emittance absorber, data, 367-68 of cavity, 237 effective, 214, 222 of glass, 222 Enclosure, collector, 377-78 End loss factor, parabolic trough, 98 Energy capacity cost, 416 conservation, 338 consumption industrial, 7 residential, 1 U.S., 7 world, 1 utilization, 5-8 Equation of time, 30-31 Equatorial plane, 32, 33 Equity financing, 407

498

Subject Index

Equivalent parameters for linearized efficiency, 89 Etched glass, antireflection coating, 373 Evacuated tubes designs, 13-16 optical efficiency, 239 U value, 236-40 Excess energy. See Dumping of energy Extraterrestrial. See Insolation, extraterrestrial

Fin definition, 91,264 derivation, 263-65

Fm definition, 90, 253-54 results, 254-63 ./-chart industrial process heat, 354 space heating, 327-30 water heating, 336-37 /•-number, 130 Field of view. See Acceptance half-angle Fin efficiency, 260, 365 First surface reflector, 374 Fixed reflectors with moving receiver, 18689 Flat plate collector calculation of efficiency, 241-45 description, 11 test data, 99, 100, 300 Flow balancing, 384 Flow rate measurement, 103 multi-pass systems, 327, 328 single-pass vs. multi-pass, 352-54 for specified TOM, 296 Flux concentration, 125 Focal length off-axis lens, 184-85 reflector, 117 for sagittal rays, 179 for tangential rays, 178 Fractional time distribution, 71-73 Fresnel equations, 118-19 Fresnellens, 21, 182-86 off-axis focal length, 184-85 optical design, 182-85 optical losses, 186 and tracking errors, 184 n Fresnel reflector. See also Central receiver line focus, 20 point focus, 22, 1 73-82 tracking angle, 175-76

Frost protection, 333 Fuel, 5 price escalation, 403 Gallium arsenide cells, 357 Gaussian approximation, optical analysis, 142, 206-8 Gaussian distribution, 138, 203 Getters, 16 Glass tubes, optics of, 124 Glazing. See Cover Global radiation. See Insolation, hemispherical Glycol, 379-81 Grashof number, 220 Gross area, 83 n Ground cover ratio definition, 173, 301 recommendations, 383 Ground reflectance, 51 Heat exchanger effectiveness definition, 269 results, 270 factor definition, 271 results, 272 Heat loss coefficient of collector. See U value Heat mirror, 373 Heat pipe, 13 n, 15 Heat removal factor definition, 91, 264 derivation, 263-65 Heat transfer to ambient, 217-21 approximate, 220 coefficient convectivc, typical values, 215 radiative, 214 concentrator configuration, 227-29 convection suppression, 234-35 convectivc flat surface, 220-21 honeycomb, 235 parallel plates, 222-25 tubes 221,226-27 factors, collector, 90-92 fluids, 378-81 collector test, 103 inside tubes and ducts, 229-31 radiative, plates, 222 radiative, tubes, 225 HELIOS (computer code), 174

Subject Index Heliostat cost, 10 curvature, 173, 180-81 tracking accuracy, 392 Hemispherical insolation. See Insolation, hemispherical Hemispherical reflectivity, 375 Honeycomb, 234-35 Hottel-Whillier-Bliss equation, 265, 268 Hourly clearness index, 64 Hourly radiation. See Insolation Hydraulic diameter, 229

Ideal concentrator, 147; see also CPC Imaging, 114 Incidence angle equations, 40 fixed surfaces, derivation, 32-37 modifier all-day average, 292, 312 for central receiver, 174-75 curve fits, 96, 300 definition, 96 longitudinal and transverse directions, 46 test results, 97, 98, 100, 102 trading surfaces, derivation, 37-39 Index of refraction, 117 data, 370 Industrial process heat general considerations, 338-40 multipass with storage, 351-54 no-storage system, 340-45 single-pass with storage, 345-51 temperature distribution, 7 Inflation, 396-97 effect on economic analysis, 423-24 Inlet temperature, 103, 263-65 Insolation on aperture annual, 74, 287-90 annual, above threshold, 290-99 annual, derivation, 300-305 instantaneous, 51, 301-2 monthly, 309-12 monthly, above threshold, 312-17 peak, 304, 341,432 seasonal variation, 75-78 beam data, annual U.S., 57 from hemispherical, annual, 74, 75 from hemispherical, hourly, 64-65 circumsolar. See Circumsolar radiation clear sky model, 62-63

499

diffuse accepted by collector, 131-32 clear sky, 63 data, annual U.S., 57 from hemispherical, daily, 65-66 from hemispherical, hourly, 64 from hemispherical, monthly, 67 hourly/daily, 68-69 model for anisotropy, 56, 61 extraterrestrial, daily, equation, 37, 79 daily, values, 453-54 instantaneous, 29, 30 spectrum, 48-50 frequency distribution, 71-73, 305-6 hemispherical annual data, U.S., 58 annual data, world, 60 hourly/daily, 68-69 monthly data, U.S., 455-66 monthly data, world, 467-79 instruments, 52-54 long term average, 66-71 validity of algorithm, 70 terminology, 28, 49-50 Installation, solar systems, 381-87 Insulation materials, 377-78 Intercept factor and circumsolar radiation, 209-11 definition, 205 gaussian approximation, 206-8 values, 487-90 Interconnection, collectors, 273, 384-85 Interest, present value of, 420 Interest rates, data, 397 Internal rate of return comparison, other criteria, 415-16 definition, 409 multiple solutions, 415 n Involute, 156-157 Iron, effect on transmittance of glass, 371 Irradiance. See Insolation Kinglux aluminum sheet, 374, 376 Leaks, 385 Lens, 21, 182-85 Levelizing factor definition, 403 values, 404 Life cycle cost for business, 422-23 for individual, 421-22

500

Subject Index

Life cycle (continued) and optimization, 427-28 without debt or taxes, 417-18 savings comparison, other criteria, 415-16 definition, 408 Lifetime, economic analysis, 401, 410-13 Limb darkening, 134 Line focus concentrators, image width, 142-45 Linearized efficiency equation, 88-89 Liu and Jordan correlations, 63, 64-73 Load distribution, 338 Loan annual payments, 400 effect of inflation, 397 n, 424 Long term average insolation, 66-71 Longitude, time meridians, 30

Operating temperature, photovoltaic cells, 358 Operating time, 305-7 Operation and maintenance, 3-4, 417-18 Optical efficiency. See Efficiency, optical Optical errors classification, 137 combined effect, 141-42 measurement, 111 Optimization absorber size, 170-71, 196 by computer simulation, 286 economic criteria, 415, 426-27 photovoltaic system, 429-33 process heat system, 433-36 Organic Rankine cycle, 359, 360 Outlet temperature, 103, 271 Overheating, 386-87

Maintenance, recommendations, 387 Market rates, 396-97 Materials, 364-81 absorber, 364-69 compatibility, 378, 382 cover, 369-73 heat transfer fluids, 378-81 insulation, 377-78 properties, 365-81, 452 reflector, 373-77 Microsheet, reflector material, 375, 376 MIRVAL (computer program), 174 Monthly. See Insolation Mortgage. See Loan Multiple reflections in concentrator, 116, 154,239 cover-absorber, 122-23 ground-sky, 66 within cover, 119-21

(P/F, r, N) definition, 398 values, 399 Parabola equation, 198 off-axis aberration, 197 Parabolic dish heat centralization, 354-56 power generation, 359, 361 Parabolic reflectors concentration/acceptance angle, 170-72 Parabolic trough, 10, 19 heat centralization, 354-56 power generation, 359, 361 test data, 101-2 Parasitic power, 8 n, 335, 354 Payback period comparison, other criteria, 415-16 definition, 411 and rate of return, 411-13 peak insolation, on aperture, 304, 341, 432 0,/-chart, 309, 317-22 industrial process heat, 353-54 Photovoltaics economic analysis, 429-33 power generation, 357-59 Pipe loss factors, 274-75 Pipes, 384-85 Polar tracking. See Tracking Polarization, 118 Polycarbonate, 370, 373 Power generation, 356-61 photovoltaics, 357-59 thermal, 359-61 Power tower. See Central receiver

Net area, 83 n Net present value comparison, other criteria, 415-16 definition, 408 Night loss, values, 441 Nomenclature, 445-49 Nonimaging. See CPC Nusselt Number, 215 Ocean thermal power, 359, 360 Open loop process heat system, 340-51 test procedure, 106

Subject Index Prandtl number, 220 Present worth factor definition, 398 values, 399 Principal and interest, fraction of total payment, 419-20 Prismatic reflector, 156 Profile angles, 39-43 Projected incidence angles, 39-43 Projected ray diagram, 116-17 width of sun, 143 Properties of materials, 365-81, 452 Pumps, 384-85 PURPA, utility regulation, 429 Pyranometer, 52 Pyrheliometer, 53 Radiation. See Insolation; see also Heat transfer passage, transmitted radiation, 116 shape factor, 127 Rain and cleaning, 389-91 Rate of return, internal comparison, other criteria, 415-16 definition, 409 Rates, real or market, choice for analysis, 423-24 market, 396-97 real, 396-97 Rayleigh number, 220 Real rates, 396-97 Receiver. See Absorber Reciprocity relation (radiation), 128 Reflectance data, 375, 376 of ground, 51 Reflection, law of, 115 Reflections, average number of, 116 Reflector slats fixed, 188-89 tracking, 173-77 Refraction index of, 117 law of, 117-18 Reverse return, interconnection, 384-85 Reynolds number, 221 Rim angle, 171 rms error, data fit, 303 Rock storage, 384 Rules of thumb absorber size, 171 clearness index, 58 operating temperatures, 9-11 payback time/rate of return, 410-12 seventy-year rule (doubling time), 406

501

storage value/charging cycles, 440 10% rule (annual cost), 3-4 Safety, 386-87 Sagittal rays, 177 Salvage value, 402, 422, 423 Scattering due to dust, 388 of reflected radiation, 138 SCRAM (computer code), 174 Scratches, cover, 371 Seals, 377 glass-to-metal, 13 Seasonal variation insolation on collectors, 75-78 insolation correlations, 66-67 Second law of thermodynamics, 126, 128 Second surface reflector, 374 Second-stage concentrators, 190-93 CPC, 149, 151 trumpet, 156 V-groove, 164 Selective absorber and cavity effect, 369 data, 367-68 definition, 365 Sellback of electricity, 308, 429-33 Series present worth factor, 401 Seventy-year rule, 406 Shade ring, 54 Shading, 173,381 analysis, 302 fixed surfaces, 44 Shape factor (radiation), 127 Shaped tube design, 18 test data, 101 Short circuit, thermal, 13, 268 Shorthand procedures annual insolation on aperture, 287-90 annual derivation, 300-307 utilizability, 290-99 circumsolar radiation, 289-90 general comments, 286-87 industrial process heat, 341-54 monthly, utilizability, 309-22 space heating, 327-30 water heating, 336 Side reflectors, 165-67 Silicon cells, 357, 358 Sky temperature, 218-19 and collector testing, 88 SLATS. See Reflector slats Snell's law of refraction, 117-18 Social costs, 396 n

502

Subject Index

Social discount rate, 399 Soda lime glass, 370, 371 Solar constant, 28-29 effective, 30 Solar fraction industrial process heat, 343, 351, 354 phi, f-chart, 318 space heating, 327-30 water heating, 336-37 Solar noon, 30 Solar pond deep (salt-gradient), 11-13 power generation, 359, 360 shallow, 11-12 Solar radiation. See Insolation Solar time, 30 SOLMET beam data, 55 stations, 55 typical meteorological year, 285 n weather tapes, 281 Space cooling, 330-32 Space heating performance data, 330 performance prediction, 327-30 system configurations, 326-27 Spectrum blackbody, 49, 366 solar, 48-50 standard solar, 50 Specular reflectance, 373 Specular transmittance, 371 Specularity, 138 Spherical reflectors off-axis aberrations, 177-80 with tracking receiver, 186-87 Spillover of radiation. See Intercept factor; see also End loss factor Stability of controls, 279 Stagnation, 110 Standard atmosphere, 63 Steady state and test procedure, 104-5 Stefan-Boltzmann constant in medium, 130 in vacuum, 127 Storage buffer, 339 cost, 23, 444 day-night, 339, 442 and energy use, 5-8 heat loss, 319 long term, 8, 25, 339 technologies, 23-24 value of, 439-44 weekend, 339, 443

Stratification, 24 analysis, 285 enhancement, 384 Sun, 28 angular radius, 133-36 brightness distribution, 133-36, 485-86 rms width, 135-36 spectrum, 48-50 Sunset time equation, 33 nomogram, 35 Sunshape. See Brightness distribution, solar/circumsolar Sunshine hours, 59 Support of collector, 377-78 Swimming pool heating, 337-38 System configuration, 277-78

Tangential rays, 177 Tau-alpha product. See Efficiency, optical Tax credit, 421, 422,423 Temperature ambient, data, 480 base for collector efficiency, 94 conversion, 92-93 distribution in collector, 251-52 fluid mean vs. average, 266 inlet, 91-93, 263-65 mean fluid, 90,251 stagnation, 110 typical operating, 9-10 10% rule, economic analysis, 3-4 Test procedures simplified, 108-11 standard, 101-8 Thermal network, 213 Thermal shock, 386 Thermosyphon, 334 Threshold definition, 291 for dumping or sellback, 307-8, 430 variation, 304 Tilt, effect on U value, 245 Time constant of collector, 108 equation of, 30-31 operating, 305-7 solar, 30 sunset, 33, 35 value of money, 397-98 Total energy system, 8, 287, 359 Total internal reflection, 374

Subject Index Tracking, 392-93 angle east-west axis, 39 Fresnel reflectors, 175-76 north-south axis, 38 error and collected energy, 392-93 modes, 37-39 Transients and collector efficiency, 105-6, 354 Transmittance, 119-22, 370 Transpired collector, 236 TRNSYS (computer code), 284-86 Trumpet concentrator, 156 Typical meteorological year, 285 n U value definition, 87 equivalent, linearized efficiency, 89 evacuated tubes, 236-40 flat plate collector, 242-45 parabolic troughs, 240-41 temperature dependence, 89 Units, 450-51 Utilizability annual, 290-99 definition, 290, 312 evacuated tubes, 291-92 general constraints, 304-5 monthly, 309-22

V-trough, 164-65 Value of solar system, 436 of storage, 439-44 of system changes, 437-38 Valves, 385-86 Variable volume tank, 346-47 Visibility, 63

Warmup rate, 108 Water heating, 332-38 performance data, 335 performance prediction, 336-37 system configurations, 332-34 Water mains, pressure, 347 Wind and collector testing, 88 n effect on performance, 219 effect on U value, 243-44

Yearly. See Annual; see also Insolation

Zenith Angle, 33

503

Active Solar Collectors and Their Applications

ARI RABL

OXFORD UNIVERSITY PRESS

Active Solar Collectors and Their Applications

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Copyright © 1985 by Oxford University Press, Inc. Published by Oxford University Press, Inc., 200 Madison Avenue, New York, New York 10016 All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, pholocopying, recording, or otherwise, without the prior permission of Oxford University Press. Library of Congress Cataloging in Publication Data Rabl, Ari. Active solar collectors and their applications. Includes index. 1. Solar collectors. TJ812R33 1985 ISBN 0-19-503546-1

Printing (last digit):

1. Title. 621.47

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