Answer:
thermal conductivity of the insulation;k_ins = 0.062 W/m.k
Step-by-step explanation:
We are given;
inner radii of sphere;r_i = 0.15 m
outer radii of sphere;r_o = 0.18 m
Thickness of given insulation is 0.12m
outer radius of given insulation;r = 0.18 + 0.12 = 0.30 m
convective coefficient; h= 30 W/m².K
inner temperature of surface;T_s = 250 °C = 250 + 273K = 523 k
T(∞) = 20°C = 20 + 273 = 293K
Thermal conductivity of aluminium;k_Al = 234 W/m.K
For this problem, the formula for the rate of heat transfer is given as;
q = [T_s - T(∞)]/R
R is thermal resistance and is given by the formula;
R = R_cond + R_cond,ins + R_conv
When expanded, it results in;
R = (1/(4•π•234))[1/r_i - 1/r_o] + (1/(4•π•k_ins))[1/r_o - 1/r] + (1/(4•π•r²•h))
Where k_ins is thermal conductivity of insulator
Plugging in the relevant values to obtain;
R = (1/(4•π•234))[1/0.15 - 1/0.18] + (1/(4•π•k_ins))[1/0.18 - 1/0.3] + (1/(4•π•0.3²•30))
R = 0.00037786 + 0.1768/k_ins + 0.02947
R = 0.029848 + 0.1768/k_ins
We recall that;
q = [T_s - T(∞)]/R
We are given; q = 80W
Thus;
80 = 523 - 293/(0.029848 + 0.1768/k_ins)
Thus;
80(0.029848 + 0.1768/k_ins) = 230
Divide both sides by 80;
(0.029848 + 0.1768/k_ins) = 230/80
0.1768/k_ins = 230/80 - 0.029848
0.1768/k_ins = 2.8452
Thus;
k_ins = 0.1768/2.8452
k_ins = 0.062 W/m.k