Standard analyses of solar collector thermal performance are based upon an energy balance in which the environments adjoining the front and rear of the collector are assumed to be at the same temperature. This assumption is inappropriate for some collector designs, particularly building-integrated collectors. An approach for analyzing such situations is presented based upon a new conceptual temperature termed the “equivalent ambient temperature.” The concept is explained, the new temperature is defined, and the approach is applied to a typical collector geometry. The approach retains the convenience of the standard analysis while accounting for the unequal front/rear ambient temperatures and permits collector characterization in terms of the conventional parameters: plate efficiency factor, F; heat removal factor, FR; overall heat loss coefficient, UL, and effective transmittance–absorptance product, ταe.

1.
Jefferson, M. 1994, “Global Prospects for Renewable Energy,” World Renewable Energy Congress, September 1994, Reading, UK, 1, pp. 5–11.
2.
Posnansky, M., and Gnos, S., 1994, “Building Integrated Photovoltaic Systems: Examples of Realised Hybrid PV Power Plants with Specially Conceived PV-Modulues for Building Integration,” ASME/JSME/JSES Int. Solar Energy Conf., San Francisco, CA, March, pp. 421–424.
3.
Takashima, T., Tani, T., and Horigoma, T., 1994, “New Proposal for Arrangement of Photovoltaic-Thermal Panel,” ASME/JSME/JSES Int. Solar Energy Conf., San Francisco, California, March, pp. 425–431.
4.
Brinkworth
,
B. J.
,
Cross
,
B. M.
,
Marshall
,
R. H.
, and
Yang
,
H.
,
1997
, “
Thermal Regulation of Photovoltaic Cladding
,”
Sol. Energy
,
61
(
3
), pp.
169
178
.
5.
Holmes
,
M. J.
,
1994
, “
Optimisation of the Thermal Performance of Mechanically and Naturally Ventilated Glazed Facades
,”
Renewable Energy
,
5
(
2
), pp.
1091
1098
.
6.
Hottel
,
H. C.
, and
Woertz
,
B. B.
,
1942
, “
The Performance of Flat-Plate Solar-Heat Collectors
,”
ASME J. Appl. Mech.
,
64
, pp.
91
104
.
7.
Bliss
,
R. W.
,
1959
, “
The Derivation of Several Plate-Efficiency Factors Useful in the Design of Flat-Plate Solar Heat Collectors
,”
Sol. Energy
,
2
(
4
), pp.
55
64
.
8.
Duffie, J. A., and Beckman, W. A., 1991, Solar Engineering of Thermal Processes, 2nd Edition, John Wiley and Sons, New York.
9.
Huang
,
H.
, and
Howell
,
J. R.
,
1985
, “
Precision of Solar Collector Testing and Selection of Measurement Instruments
,”
Sol. Energy
,
35
(
5
), pp.
457
460
.
10.
Onur
,
N.
,
Sivrioglu
,
M.
, and
Turgut
,
O.
,
1996
, “
An Experimental Study on Air Window Collector having a Vertical Blind for Active Solar Heating
,”
Sol. Energy
,
57
(
5
), pp.
375
380
.
11.
Loveday
,
D. L.
,
1988
, “
Thermal Performance of Air-Heating Solar Collectors with Thick, Poorly Conducting Absorber Plates
,”
Sol. Energy
,
41
(
6
), pp.
593
602
.
12.
Ho
,
K. T. K.
, and
Loveday
,
D. L.
,
1997
, “
Covered Profiled Steel Cladding as an Air Heating Solar Collector: Laboratory Testing, Modelling and Validation
,”
Energy Build.
,
26
, pp.
293
301
.
13.
CIBSE 1986, CIBSE Guide B, Chartered Institute of Building Services Engineers, London.
14.
Ho, K. T. K., 1999, “The Potential of Covered Profiled Steel Cladding as a Building-Integrated Solar Collector for the UK Climate,” Ph.D. thesis, Loughborough Univ., Loughborough, UK.
15.
Carpenter, S. C., and Kokko, J. P., 1991, “Performance of Solar Pre-Heat Ventilation Air Systems,” Proc. of ISES Solar World Congress, Denver, CO, 2(1), pp. 1537–1542.
16.
Cengel, Y. A., 1998, Heat Transfer: A Practical Approach, WCB/McGraw-Hill, USA.
You do not currently have access to this content.