(i) Explanation Given: The inside temperature of cylindrical configuration is T i . The surface temperature of cylinder boundary is T ∞ . The heat transfer coefficient is h . The angular spacing is Δ ϕ . The radial spacing is Δ r . The radial spacing at inside surface is r i . Formula Used: The incoming energy in the system is given by, E i n = q a + q b + q c + q d The heat generated in the cylindrical configuration is given by, E g = 0 The energy balance equation is given by, E i n + E g = 0 Calculation: The conduction heat transfer from node 5 to node 2 is calculated as, q a = k [ ( r i + 3 2 Δ r ) Δ ϕ ] ( T 5 − T 2 Δ r ) The conduction heat transfer from node 3 to node 2 is calculated as, q b = k Δ r ( T 3 − T 2 ( r i + Δ r ) Δ ϕ ) The conduction heat transfer from node i to node 2 is calculated as, q c = k [ ( r i + 1 2 Δ r ) Δ ϕ ] ( T i − T 2 Δ r ) The conduction heat transfer from node 1 to node 2 is calculated as, q d = k Δ r ( T 1 − T 2 ( r i + Δ r ) Δ ϕ ) The steady energy balance is calculated as, E i n + E g = 0 q a + q b + q c + q d + 0 = 0 { k [ ( r i + 3 2 Δ r ) Δ ϕ ] ( T 5 − T 2 Δ r ) + k Δ r ( T 3 − T 2 ( r i + Δ r ) Δ ϕ ) + k [ ( r i + 1 2 Δ r ) Δ ϕ ] ( T i − T 2 Δ r ) + k Δ r (ii) To determine The finite difference equation for the node 3 . (iii) To determine The finite difference equation for the node 1 .

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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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Chapter 4, Problem 4.44P

(i)

To determine

The finite difference equation for the node 2 .

(ii)

To determine

The finite difference equation for the node 3 .

(iii)

To determine

The finite difference equation for the node 1 .

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Chapter 4, Problem 4.43P

Chapter 4, Problem 4.45P

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Solution Summary: The author explains the finite difference equation for the node 2. The inside temperature of cylindrical configuration is T_i.

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