Thermal performance of air-heating solar collectors with thick, poorly conducting absorber plates

Abstract

Expressions are derived for the efficiency and loss factors of a coverless, air-heating solar collector in which it is possible to assign finite values for the thickness and thermal conductivity of the absorber plate. In the geometry treated, air flow is beneath a flat absorber, and heat transfer is both steady state and one dimensional. The expressions are validated by outdoor measurements from a fullscale tile roof used as a collector and by indoor measurements from tile and metal roof sections tested in a heating simulator. For the tile roofs, the expressions presented give better agreement with experiment than do expressions based on the usual “thin plate” models since the absorber is thick and poorly conducting. Efficiency characteristics of the full-scale tile roof are also presented. Trapezoidally profiled metal panels are commonly used as a cladding for industrial buildings; it is shown that their performance as collectors may be described by a “fin and tube” model. Information is presented in a format that is useful for design and may be used in computer models of the thermal performance of solar-assisted buildings comprising these, or similar, collection devices.