Liquid and air-type collectors

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Design: Solar Heating of Buildings and Domestic Hot Water

MIL-HDBK-1003/13A

Advances in collector cost reduction will probably be made in the direction

of cheaper manufacturing processes. Some collectors not made from tube and

sheet may not tolerate DHW line pressures. Specifications for pressurized

collector circuits should require collectors which will take proof test

pressure equal to 150% of expected circuit pressure.

In hot climates, it is important to reduce roof heat load due to collector

heat gain in summer; this can be accomplished by venting the space between

collector plate and glazes with dampers or by covering the collectors. A

normal amount of dirt and dust on the glass cover will reduce heat collected

by about 5%. Normal rainfall is usually sufficient to relieve this problem.

Except for warm climates with high insolation (I > / - 1400 Btu/ft2-Day),

two cover glasses may be optimum (see Section 2.1.3). In warm climates, one

glass is optimum. Many plastics have an undesirable transparency to infrared

radiation, to which glass is nearly opaque, so the desired "greenhouse

effect" is not so pronounced with plastic materials as with glass. However,

losses by radiation from the collector are small compared with convective

losses due to wind; thus plastics can be employed to reduce breakage and

cost, but with some loss in collector performance. Plastics with maximum

opaqueness to infrared and maximum transparency to ultraviolet (UV) and

visible radiation and with high resistance to UV degradation should be

specified. Collector orientation should follow the guidelines given in

Section 1.3.3. Collector sizing will be given in Section 3.0. The following

sections give more detailed information on collector designs and components.

2.1.1 Liquid and air-type collectors. Liquid and air type collectors each

have some advantages which are summarized in Table 2-1 (Kimbell, 1978).

Liquid types are more suited to DHW, the collector area is usually smaller,

and more information is available about liquid systems. Collectors for

heating air do not require protection from freezing and have minimal

corrosion problems, leaks do not cause serious damage, they may cost less per

unit area, and are better suited to direct space heating for residences where

duct-work is already present. However, since leaks in air systems are less

easily detected, they can degrade system performance if not corrected.

Wherever this manual discusses liquid collectors, air collectors are

included, and cost analyses apply equally to both. The design procedure for

air collectors differs, however. Heat transfer oils used in liquid systems

offer freeze protection and some corrosion protection, but they also require

heat exchangers for heating domestic hot water, as do antifreeze-water

mixtures.

2.1.2 Selective surfaces. Some collectors are manufactured with a black

coating which absorbs the high frequency incoming solar radiation very well

and which emits low frequency infrared radiation poorly. This is a highly

desirable combination of properties for a collector. The absorptance should

be 0.9 or higher and emittance may be 0.1 or lower. Such coatings are

approximately equal in effect to one cover glass. Thus, a selective coating

plus one cover glass may be expected to be about equal in efficiency to a

collector with two cover glasses and a flat black painted surface.