Fundamentals of Heat and Mass Transfer
7th Edition
ISBN: 9780470501979
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 3.105P
Unique characteristics of biologically active materials such as fruits, vegetables, and other products require special care in handling. Following harvest and separation from producing plants, glucose is catabolized to produce carbon dioxide, water vapor, and heat. with attendant internal energy generation. Consider a carton of apples, each of 80-mm diameter, which is ventilated with air at 5°C and a velocity of 0.5 m/s. corresponding value of the heat transfer coefficient is
- Determine the apple center and surface temperatures.
- For the stacked arrangement of apples within the crate, the convection coefficient depends on the velocity as
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O H.W.:
The heat transfer coefficient for air flowing over a sphere is to be
determined by observing the temperature-time history of a sphere
fabricated from pure copper. The sphere, which is 12.7 mm in
diameter, is at 66°C before it is inserted into an airstream having a
temperature of 27°C. A thermocouple on the outer surface of the
sphere indicates 55°C 69 s after the sphere is inserted in the
airstream. Assume, and then justify, that the sphere behaves as a
spacewise isothermal object and calculate the heat transfer
coefficient.
p= 8933 kg/m", Cp
3
= 389 J/kg-K, k= 398
%3D
-T(0)= 66°C
T(69s) =55°C
Teo =27°C
-D=12.7mm
Worith Alenbiveo (Dr ALLMA
Hoot Tronofor
FE
O H.W.:
The heat transfer coefficient for air flowing over a sphere is to be
determined by observing the temperature-time history of a sphere
fabricated from pure copper. The sphere, which is 12.7 mm in
diameter, is at 66°C before it is inserted into an airstream having a
temperature of 27°C. A thermocouple on the outer surface of the
sphere indicates 55°C 69 s after the sphere is inserted in the
airstream. Assume, and then justify, that the sphere behaves as a
spacewise isothermal object and calculate the heat transfer
coefficient.
3.
p= 8933 kg/m", Cp = 389 J/kg-K, k = 398
T(0) = 66°C
T(69s) = 55°C
Teo =27°C
-D=12.7mm
Warith Alanbiyaa (Dr. ALI M)
Heat Transfer
21
for COVID vaccine. The volume of the storage container will
be 1 m³. You are debating on three shapes: (a) a rectangular shaped box with 20-cm thickness, 1-m
56.42 cm diameter, and
width, and 5-m length; (b) a cylindrical storage with 4-m length and
(a) a sphere. AS part of your design decision, find out the convective heat transfer rate from each of
these containers. Assume the surface temperature to be uniform at –-10°C, and the ambient air is
flowing at 20°C. The velocity of the air is 0.8 m/s. The direction of flow is over the 1-mx5-m sides
of the box along the length (5-m) and across the cylinder and the sphere. Ignore the heat transfer
from the end areas (i.e., the thickness of the rectangular box and the ends of the cylinder).
Chapter 3 Solutions
Fundamentals of Heat and Mass Transfer
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