(a) Explanation Given: The process is subjected to convection process. Concept used: Write the expression for energy balance. E ˙ i n − E ˙ o u t = 0 ..... (1) Here, E ˙ i n is the energy inside the convection process and E ˙ o u t is the energy outside the convection process. Write the expression for heat transfer from node ( m − 1 ) to m . q ( m − 1 , n ) → ( m , n ) = k ( Δ y ⋅ 1 ) T m − 1 , n − T m , n Δ x Here, q ( m − 1 , n ) → ( m , n ) is the heat transfer from node ( m − 1 ) to m , k is the thermal coefficient, ( Δ y ⋅ 1 ) is the heat transfer area and T m − 1 , n − T m , n Δ x is the finite difference approximation to temperature gradient. Write the expression for heat transfer from node ( n − 1 ) to n . q ( m , n − 1 ) → ( m , n ) = k ( Δ x 2 ⋅ 1 ) T m , n − 1 − T m , n Δ y Here, q ( m , n − 1 ) → ( m , n ) is the heat transfer from node ( n − 1 ) to n , k is the thermal coefficient, ( Δ x 2 ⋅ 1 ) is the heat transfer area and T m , n − 1 − T m , n Δ y is the finite difference approximation to temperature gradient. Calculation: Substitute q 1 + q 2 + q 3 + q 4 for E ˙ i n − E ˙ o u t in equation (1) (b) To determine To derive the finite difference equations under steady condition of both boundary of external corner insulated.

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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Chapter 4, Problem 4.40P

(a)

To determine

To derive the finite difference equations under steady condition of upper boundary of external corner insulated.

(b)

To determine

To derive the finite difference equations under steady condition of both boundary of external corner insulated.

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Chapter 4, Problem 4.39P

Chapter 4, Problem 4.41P

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To derive the finite difference equations under steady condition of upper boundary of external corner insulated.

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To derive the finite difference equations under steady condition of both boundary of external corner insulated.

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