Solar radiation is incident on a 5-m 2 solar absorber plate surface at a rate of 800 W/m2. Ninety-three percent of the solar radiation is absorbed by the absorber plate, while the remaining 7 percent is reflected away. The solar absorber plate has a surface temperature of 40 o C with an emissivity of 0.9 that experiences radiation exchange with the surrounding temperature of − 5 o C . In addition, convective heat transfer occurs between the absorber plate surface and the ambient air of 20 o C with a convection heat transfer coefficient if 7 W/m 2 . K . Determine the efficiency of the solar absorber, which is defined as the ratio of the usable heat collected by the absorber to the incident solar radiation on the absorber.
Solar radiation is incident on a 5-m 2 solar absorber plate surface at a rate of 800 W/m2. Ninety-three percent of the solar radiation is absorbed by the absorber plate, while the remaining 7 percent is reflected away. The solar absorber plate has a surface temperature of 40 o C with an emissivity of 0.9 that experiences radiation exchange with the surrounding temperature of − 5 o C . In addition, convective heat transfer occurs between the absorber plate surface and the ambient air of 20 o C with a convection heat transfer coefficient if 7 W/m 2 . K . Determine the efficiency of the solar absorber, which is defined as the ratio of the usable heat collected by the absorber to the incident solar radiation on the absorber.
Solar radiation is incident on a 5-m2 solar absorber plate surface at a rate of 800 W/m2. Ninety-three percent of the solar radiation is absorbed by the absorber plate, while the remaining 7 percent is reflected away. The solar absorber plate has a surface temperature of
40
o
C
with an emissivity of 0.9 that experiences radiation exchange with the surrounding temperature of
−
5
o
C
.
In addition, convective heat transfer occurs between the absorber plate surface and the ambient air of
20
o
C
with a convection heat transfer coefficient if
7 W/m
2
.
K
.
Determine the efficiency of the solar absorber, which is defined as the ratio of the usable heat collected by the absorber to the incident solar radiation on the absorber.
The interior surface of a 25 cm thick wall has a temperature of 27 \deg C as shown in the figure. The outer surface is exposed to a solar radiation of 150 W/m^2 and exchanges heat by radiation and convection with the surroundings and the air that are at the same temperature of 40 \deg C. The coefficient of heat transfer by convection is 8 W/m^2* K, consider both the absorptivity (\alpha ) and emissivity (\epsi equal to 0.8. Assuming transfer of 1D heat and at steady state, determine the surface temperature outside and the heat flow by conduction in the wall in three conditions different: a) If the wall is made of brick (k=0.72 W/m*K) b) If the wall is made of wood (k=0.17 W/m*K) c) If the wall is made of rigid foam (polyurethane) (k=0.026 W/m*KMake a diagram of the corresponding thermal resistance circuit and a diagram of the variation of temperatures from the interior wall to the air abroad.
A wood stove is used to heat a single room. The stove is cylindrical in shape, with a diameter of 26 cm and a length of 52 cm, and operates at a temperature of 490°F. If the temperature of the room is 60°F, and if the emissivity is 0.844, then
Calculate, the amount of radiant energy delivered to the room by the stove each second (KW)
Answer
Two parallel plates are sustained at 1073.15K and 573.15K which has emissivityof 0.3 and 0.5 respectively. If a polished shield made from aluminum with Є =0.05 is placed between the two parallel plates, determine the following:a) Net radiant heat exchange per square meter of the two parallel plates beforethe aluminum plate was placed between both plates b) Percentage reduction of heat transfer after the aluminum was place betweenthe plates
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