Question 6.7: A spherical vacuum bottle consists of two silvered, concentr...
A spherical vacuum bottle consists of two silvered, concentric glass spheres, the inner being 15 cm in diameter and the evacuated gap between the spheres being 0.65 cm. The emissivity of the silver coating is 0.02. If hot coffee at 368 K is in the bottle and the outside temperature is 294 K, what is the initial radiative heat leakage rate from the bottle?
Equation 6.23
Q_1=-Q_2=\frac{A_1\sigma (T_1^4-T_2^4)}{[1/\epsilon _1(T_1)]+[1/\epsilon _2(T_2)]-1} (6.23)
applies for concentric specular spheres. For the small rate of heat leakage expected, it is assumed that the surfaces will be close to 368 K and 294 K. This gives
Q_1=\frac{\pi (0.15)^25.6704\times 10^{-8}(368^4-294^4)}{(1/0.02)+(1/0.02)-1} =0.440 W
If, instead of using the specular formulation, both surfaces are assumed diffuse reflectors with ϵ still 0.02, then Equation 5.23 applies. The denominator of the Q_1 equation becomes
Q_1=\frac{A_1\sigma (T_1^4-T_2^4)}{1/\epsilon _1(T_1)+(A_1/A_2)[1/\epsilon _2(T_2)-1]} (5.23)
\frac{1}{\epsilon _1}+ \frac{A_1}{A_2} \left\lgroup\frac{1}{\epsilon _1}-1 \right\rgroup =\frac{1}{0.02} +\left\lgroup\frac{15}{16.3} \right\rgroup^2\left\lgroup\frac{1}{0.02} -1\right\rgroup =91.50
instead of 99 as in the specular case. For diffuse surfaces the heat loss is increased to 0.476 W.