Respuesta :
Answer:
The answers to the question are
(i) The rate of heat loss per-unit-length (W/m) from the pipe is 131.62 W
(ii) The temperature of the outer surface of the insulation is 49.89 °C
Explanation:
To solve the question, we note that the heat transferred is given by
[tex]Q = \frac{2\pi L(t_{hf} - t_{cf}) }{\frac{1}{h_{hf}r_1}+\frac{ln(r_2/r_1)}{k_A} + \frac{ln(r_3/r_2)}{k_B} +\frac{1}{h_{cf}r_3}}[/tex]
Where
[tex]t_{hf}[/tex] = Temperature at the inside of the pipe = 300 °C
[tex]t_{f}[/tex] = Temperature at the outside of the pipe = 20 °C
r₁ =internal radius of pipe = 4.0 cm
r₂ = Outer radius of pipe = 4.5 cm
r₃ = Outer radius of the insulation = r₂ + 2.5 = 7.0 cm
[tex]k_A[/tex] = 15 W/m·K
[tex]k_B[/tex] = 0.038 W/m·K
[tex]h_{hf}[/tex] = 75 W/m²·K
[tex]h_{cf}[/tex] = 10 W/m²·K
Plugging in the values in the above equation where for a unit length L = 1 m, we have
Q = 131.32 W
From which we have, for the film of air at the pipe outer boundary layer
[tex]Q = \frac{t_A-t_B}{R_T}[/tex] Where [tex]R_T[/tex] for the air film on the pipe outer surface is given by
[tex]R_T= \frac{1}{\alpha A}[/tex]
where A =area of the outside of the pipe
= [tex]\frac{1}{10*2\pi*0.07*1 }[/tex] = 0.227 K/W
Therefore
131.32 W = [tex]\frac{t_A-20}{0.227}[/tex] which gives
[tex]t_A[/tex] = 49.89 °C
Heat transferred by radiation = q' = ε×σ×(T₁⁴ - T₂⁴)
Where ε = 0.9, σ, = 5.67×10⁻⁸W/m²·(K⁴)
T₁ = Surface temperature of the pipe = 49.89 °C and
T₂ = Temperature of the surrounding = 20.00 °C
Plugging in the values gives, q' = 0.307 W per m²
Total heat lost per unit length = 131.32 + 0.307 =131.62 W
