Introduction to Heat Transfer
6th Edition
ISBN: 9780470501962
Author: Frank P. Incropera, David P. DeWitt, Theodore L. Bergman, Adrienne S. Lavine
Publisher: Wiley, John & Sons, Incorporated
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Textbook Question
Chapter 3, Problem 3.5P
A dormitory at a large university, built 50 years ago, hasexterior walls constructed of
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Q1.
Consider a plane wall (thermal conductivity, k = 0.8 W/mK, and thickness, fb1 = 100 mm) of a
house as shown in Fig. Q1(a). The outer surface of the wall is exposed to solar radiation and has
an absorptivity of a = 0.5 for solar energy, or=600 W/m². The temperature of the interior of
the house is maintained at T1 = 25 °C, while the ambient air temperature outside remains at
T2 = 5 °C. The sky, the ground and the surfaces of the surrounding structures at this location
can be modelled as a surface at an effective temperature of Tsky = 255 K for radiation exchange
on the outer surface. The radiation exchange inside the house is negligible. The convection heat
transfer coefficients on the inner and the outer surfaces of the wall are h₁ = 5 W/m²-K and
/1₂ = 20 W/m².K, respectively. The emissivity of the outer surface is = 0.9.
T1 = 25 °C
Ţ₁
Too1 = 25 °C
T₁
k
100 mm
Fig. Q1(a)
Assuming the heat transfer through the wall to be steady and one-dimensional:
(a) Solve the steady 1D heat…
Q2. Steam pumped through a long-
insulated pipe at a temperature of
T= 500 K and provides a convection
coefficient of h, = 100 W/m?K at the inner
surface of the pipe. The inner and outer
radius of the pipe and insulation material
are r1 = 10, r2 = 12 and r3 = 17 cm,
respectively. The thermal conductivity of
the pipe is 100 W/mK. The insulation
material is glass fiber and its outer surface
is exposed to ambient air at 300 K. If the ambient air provides a convection coefficient of ho = 20
Internal flow
Ambient air
W/m?K, determine the followings:
a. What are the thermal resistance coefficients for convections and conductions
b. What is the heat transfer rate per unit length of the pipe
c. If the pipe is 30 m long, what will be total heat transfer rate from the pipe.
t00 noints)
Homework
O H.W. 1:
The walls of a refrigerator are typically constructed by sandwiching a layer of
insulation between sheet metal panels. Consider a wall made from fiberglass
insulation of thermal conductivity k; = 0.046 W/m.K and thickness L, = 50 mm
and steel panels, each of thermal conductivity k, = 60 W/m.K and thickness L,
= 3 mm. If the wall separates refrigerated air at T = 4 C from ambient air at T,.
= 25 C, what is the heat gain per unit surface area? Coefficients associated
with natural convection at the inner and outer surfaces may be approximated
as h, = h, = 5 W/m?.K.
%3D
%3D
L; = 0.050 m K
K Lo = 0.003 m
Refrigerated
air
Ambient air
Too.i = 4°C
hi = 5 W/m2-K
To,o = 25°C
ho = 5 W/m2-K
%3D
Panel (2)
kp = 60 W/m-K
Insulation
k; = 0.046 W/m-K
22
Warith Alanbiyaa (Dr. ALI M)
Heat Transfer
Page 11 of
Chapter 3 Solutions
Introduction to Heat Transfer
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