Explanation Given information: Distance L = 0.20 Heat flux q r a d " = 800 W/m 2 Thickness of plate, t = 6mm Uniform Temperature T w = 60° C Calculation: For a unit length of the tube the temperature distribution governed by the differential equation is written as: q x ' + q r a d " ( d x ) − q x + d x ' = 0 Here, q x + d x ' = q x ' + d q x ' d x d x a n d , q x ' = − Kt dT dx By substituting the values in above equation. − Kt dT dx + q r a d " ( d x ) +Kt dT dx + d [ − Kt dT dx ] d x d x = 0 q r a d " − d d x [ − Kt dT dx ] = 0 d 2 T dx 2 + q r a d " kt = 0 Integrating twice the above equation, the general solution for temperature distribution is obtained as T ( x ) = − q r a d " 2 k t x 2 + C 1 x + C 2 Now applying the boundary conditions, x = 0

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ISBN: 9780470501962

Author: Frank P. Incropera, David P. DeWitt, Theodore L. Bergman, Adrienne S. Lavine

Publisher: Wiley, John & Sons, Incorporated

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Heat transfer is an essential discipline in thermal engineering that deals with the transfer, conversion, usability, and creation of heat or thermal energy. Transfer of heat occurs through various mechanisms like conduction, convection, radiation, and ch…

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Chapter 3, Problem 3.108P

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The maximum temperature and rate of per unit length of heat transfer.

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