Solar radiation

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Design: Solar Heating of Buildings and Domestic Hot Water

MIL-HDBK-1003/13A

Subject

Document

Miscellaneous Tests (cont.)

National Bureau of Standards, NBSIR 81-

2199, "Wind, Earthquake, Snow, and Hail

Loads on Solar Collectors" Jan 1981; and

NBSIR 82-2487, "Hail Impact Testing Proce-

dures for Solar Collector Covers" Apr 1982

Product Safety

National Bureau of Standards, NBSIR78-

(See also HUD Report 4930.2)

1532, "Environmental and Safety

Considerations for Solar Heating and

Cooling Applications"

Certified Test Labs

National Bureau of Standards, NBSIR

78-1535, "Laboratories Technically

Qualified to Test Solar Collectors in

Accordance with ASHRAE Standard 93-77" Nov

1978

In addition to these standards, there are plumbing standards published

by The International Association of Mechanical and Plumbing Officials

(IAMPO), and various state building codes.

1.3 Solar energy.

1.3.1 Solar radiation. Energy from the sun is received by the earth as

electromagnetic radiation. Most of the energy is received in the visible and

infrared portions and a small amount as ultraviolet radiation. North of the

Tropic of Cancer (23 deg. N latitude), the sun makes a daily arc across the

southern sky from east to west as shown in Figure 1-1. For a typical

location at 32 deg. N latitude the sun would be 81.5 deg. above the southern

horizon or nearly overhead at noon (solar time) on June 21 while on December

21 it would be only 34.6 deg. above the horizon (Barnaby et al., 1977).

Solar insolation (I) is measured in Langleys (L) or Btu/ft2. One Langley

equals 3.688 Btu/ft2. The amount of solar energy that exists outside the

atmosphere, often called the solar constant, is 116.4 L/hr or 429.2

Btu/ft2-hr. At most 70% to 80% of this amount will strike the earth's

surface, the remainder being absorbed or reflected in the atmosphere.

Monthly average and yearly average daily insolation data for numerous

locations are given in Table 1-1. In general, the higher the latitude, the

less insolation is received on a horizontal surface.

1.3.2 Collecting solar energy. Collection of solar energy is based on the

very high absorption of radiant energy by dull, black surfaces and on the

"greenhouse effect." The latter refers to the ability of glass to transmit

visible radiation but prevent the loss of heat from the collector plate which

radiates at longer wavelengths (infrared frequencies). Glass (or plastic)

cover plates are generally used over flat absorber plates to reduce heat loss

(see Figure 1-2). The heated absorber plate may have a fluid (water, air or

other) pass over it or through tubes attached to the plate. The fluid thus

heated may be used to heat potable water, heat spaces, or drive an absorption

or Rankine power cycle air conditioner.