Fundamentals of Heat and Mass Transfer
7th Edition
ISBN: 9780470917855
Author: Bergman, Theodore L./
Publisher: John Wiley & Sons Inc
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Chapter 12, Problem 12.123P
Growers use giant fans to prevent grapes from freezing when the effective sky temperature is low. The grape, which may be viewed as a thin skin of negligible thermal resistance enclosing a volume of sugar water, is exposed to ambient air and is irradiated from the sky above and ground below. Assume the grape to be an isothermal sphere of 15-mm diameter, and assume uniform blackbody irradiation over itstop and bottom hemispheres due to emission from the sky and the earth, respectively.
(a) Derive an expression for the rate of change of the grape temperature. Express your result in terms of a convection coefficient and appropriate temperatures and radiative quantities.
(b) Under conditions for which
(c) With all conditions remaining the same, except that the fans are now operating with
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Keep in mind that both the bottom and top surfaces of the workpiece are exposed to radiation and convection. The workpiece is suspended in air in the furnace.
1. A small gray sphere, with an emissivity coefficient of 0.5 and
a surface temperature of 537°C, is located in a black body
wrap with a temperature of 35°C. For this system, calculate
the net rate of heat transfer per unit of surface area of the
sphere.
2. Gaseous oxygen is maintained at pressures of 2 atm and 1
atm on the opposite sides of a rubber membrane, which has
a thickness of 0.5 mm, and the entire system is at
25°C. What is the diffusive mass flow of gas through the
membrane?
DAB=0.21x10^-9 m^2/s; O = 16 g/mol
3. Pure oxygen gas at 2 bar and 25°C is flowing through a
rubber hose of 10 m long, with 40 mm internal diameter and
2 mm wall thickness. The external surface is exposed to an
air stream in which the partial pressure of the gas is 0.1 bar.
The diffusivity and solubility of the gas in the hose material
are 0.21x10^-9 m^2/s and 3.12x10^-3 kmol/m^3.bar.
respectively. Determine the mass rate at which the gas leaks
out of the hose.
4. Consider the diffusion of gaseous…
Liquid oxygen is stored in a thin-walled, spherical container 0.8 m in diameter, which is enclosed within a second thin-walled, spherical container 1.4 m in diameter. The opaque, diffuse, gray container surfaces have an emissivity of 0.05 and are separated by an evacuated space. If the outer surface is at 270 K and the inner surface is at 95 K, what is the mass rate of oxygen lost due to evaporation, in kg/s? (The latent heat of vaporization of oxygen is 2.13 × 105 J/kg.)
Chapter 12 Solutions
Fundamentals of Heat and Mass Transfer
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A procedure for measuring the thermal conductivity...Ch. 12 - One scheme for extending the operation of gas...Ch. 12 - The equipment for heating a wafer during a...Ch. 12 - Neglecting the effects of radiation absorption,...Ch. 12 - Consider the evacuated tube solar collector...Ch. 12 - Solar flux of 900W/m2 is incident on the top side...Ch. 12 - Consider an opaque, gray surface whose directional...Ch. 12 - A contractor must select a roof covering material...Ch. 12 - It is not uncommon for the night sky temperature...Ch. 12 - Plant leaves possess small channels that connect...Ch. 12 - In the central receiver concept of solar energy...Ch. 12 - Radiation from the atmosphere or sky can be...Ch. 12 - A thin sheet of glass is used on the roof of a...Ch. 12 - Growers use giant fans to prevent grapes from...Ch. 12 - A circular metal disk having a diameter of 0.4 m...Ch. 12 - The neighborhood cat likes to sleep on the roof of...Ch. 12 - The exposed surface of a power amplifier for an...Ch. 12 - 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