Introduction to Heat Transfer
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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Chapter 2, Problem 2.65P

A plane wall of thickness L = 0.1 m experiences uniformvolumetric heating at a rate q . . One surface of the wall x = 0 is insulated, and the other surface is exposed to afluid at T = 20 ° C, with convection heat transfer characterizedby h = 1000 W/m 2 K . Initially, the temperaturedistribution in the wall is T x , 0 = a b x 2 , where a = 300 ° C, b = 1.0 × 10 4 ° C/m 2 , and x is in meters.Suddenly, the volumetric heat generation is deactivated q . = 0 for t 0 , while convection heat transfer continuesto occur at x = L . The properties of the wall are ρ = 7000 kg/m 3 , c p = 450 J/kg K, and k = 90 W/m K .

Chapter 2, Problem 2.65P, A plane wall of thickness L=0.1m experiences uniformvolumetric heating at a rate q.. One surface of

  1. Determine the magnitude of the volumetric energygeneration rate q . associated with the initial condition t < 0 . On T x coordinates, sketch the temperature distributionfor the following conditions: initial condition t < 0 , steady-state condition t , andtwo intermediate conditions.
  2. On q x " t coordinates, sketch the variation withtime of the heat flux at the boundary exposed to theconvection process, q x " L , t . Calculate the correspondingvalue of the heat flux at t = 0 , q x " L , 0 . Calculate the amount of energy removed from thewall per unit area J/m 2 by the fluid streamas the wall cools from its initial to steady-statecondition.

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Q1/ Consider a large plane wall of thickness L=0.03 m. The wall surface at x =0 is insulated, while the surface at x =L is maintained at a temperature of 30°C. The thermal conductivity of the wall is k=25 W/m °C, and heat is generated in the wall at a rate of g = 9oe0.5x/L W/m³ Where g, = 8 x 10 W /m². Assuming steady one-dimensional heat transfer, (a) express the differential equation and the boundary conditions for heat conduction through the wall, (b) obtain a relation for the variation of temperature in the wall by solving the differential equation, and (c) determine the temperature of the insulated surface of the wall.

Chapter 2 Solutions

Introduction to Heat Transfer

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