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 3.18P
The composite wall of an oven consists of three materials,two of which are of known thermal conductivity,
Under steady-state operating conditions, measurementsreveal an outer surface temperature of
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The composite wall of an oven consists of three materials, two of which are ofknown thermal conductivity, kA = 25 W/m ⋅ K and kC = 60 W/m ⋅ K, and knownthickness, LA = 0.40 m and LC = 0.20 m. The third material, B, which is sandwichedbetween materials A and C, is of known thickness, LB = 0.20 m, but unknownthermal conductivity kB. Under steady-state operating conditions, measurementsreveal an outer surface temperature of Ts,o = 20°C, an inner surface temperature ofTs,i = 600°C, and an oven air temperature of T∞ = 800°C. The inside convection coefficient h is known to be 25 W/m2 ⋅K. Neglecting convection transfer effect,what is the value of kB?
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
(Q4) A 4m x 6m wall consists of 4 glass windows of 2m x 1.5m
dimensions. The wall has thickness of 0.13m and a thermal
conductivity of 0.5 W/m.K, while the glass windows are 6 mm thick
with a thermal conductivity of 1.228 W/m.K. The values of intemal and
external surface conductance for the wall (including glass) are 7.8
W/m? K and 34.4 W/m².K, respectively. The intemal and extemal
temperatures are 22° C and 42°C, respectively. Calculate the total heat
transfer rate through the wall. What percentage of this heat transfer is
through the windows?
Chapter 3 Solutions
Introduction to Heat Transfer
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