(a) Explanation Given: The internal diameter of the cylindrical rod is D i = 200 mm . The thermal conductivity of the rod material is k r = 0.5 W / m ⋅ K . The volumetric heat generation rate is q ˙ = 24000 W / m 3 . The outer diameter of the sleeve is D o = 400 mm . The thermal conductivity of the sleeve material is k s = 4 W / m ⋅ K . The temperature of the free stream is T ∞ = 27 ° C . The convection coefficient of the stream is h = 25 W / m 2 ⋅ K . Formula used: The rate of Energy generated in the cylindrical rod is given as, Q = π r i 2 L V ˙ Here, r i is internal diameter of the rod and L is the length of the rod. The thermal conductance resistance is given as, R cond = ln ( r o r i ) 2 π k L Here, r o is the outer diameter of the sleeve, k is the thermal conductivity. The thermal convection resistance is given as, R conv = 1 h A Here, A is the area perpendicular to heat transfer. The total heat transfer due to conduction is given as, Q = Δ T R Here, Δ T is the temperature difference between the two surfaces and R is the total resistance. The temperature distribution in the cylinder is given as, T ( r ) = T 1 + q ˙ r i 2 4 k ( 1 − ( r 2 r i 2 ) ) Calculation: The rate of energy generated in the cylindrical rod can be calculated as, Q = π r i 2 L q ˙ = π × ( 0.1 m ) 2 × L × ( 24000 W / m 3 ) = ( 754 L ) W / m The thermal conductance resistance can be calculated as, R cond = ln ( r o r i ) 2 π k s L = ln ( 0 (b) To determine The temperature at the centre of the cylindrical rod.

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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When energy travels from one object to another it is said to have undergone heat transfer. Heat transfer is nothing but the transfer of thermal energy or internal energy from one thing to another, like e.g., when a vessel with water, kept on top of a bur…

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Chapter 3, Problem 3.101P

(a)

To determine

The temperature between rod and sleeve.

The temperature at the outer surface of the sleeve.

(b)

To determine

The temperature at the centre of the cylindrical rod.

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Chapter 3, Problem 3.100P

Chapter 3, Problem 3.102P

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The temperature between rod and sleeve. The temperature at the outer surface of the sleeve.

Solution Summary: The author explains the temperature between rod and sleeve, the thermal conductivity of the rod material, and the convection coefficient.