Explanation Given: The combustion gases temperature is, T g = 1100 K . The infinity temperature is T ∞ = 320 K . The convective heat transfer coefficient for combustion gases is h g = 150 W / m 2 ⋅ K . The outer radius is r o = 95 mm . The inner radius is r i = 60 mm . The thickness is t = 2 mm . The radius is r 1 = 66 mm . The radius is r 2 = 70 mm . The efficiency of the fin is η f = 85 % . The heat transfer coefficient is h = 100 W / m 2 ⋅ K . The number of fins is N = 250 . The conductive heat transfer coefficient for cooper is k c = 50 W / m ⋅ K . The resistance for copper is R ″ t , c = 10 − 4 . The resistance for aluminum is R A l = 10 − 6 The conductive heat transfer coefficient for aluminum is k a = 240 W / m ⋅ K . Formula used: The expression for the outer radius of the fin is given as, r o c = r o + t 2 The expression for the area of the fin is given as, A f = 2 π ( r o c 2 − r 2 2 ) The expression for the characteristic length of the fin is given as, L c = r o c − r 2 The area of the profile is given as, A p = L c t The expression for the total surface area is given as, A t = N A f + 2 π r 2 ( N t ) The expression for the overall efficiency is given as, η o = 1 − N A f A t ( 1 − η f ) The expression for the equivalent resistance is given as, R e q = 1 η o h A t The expression for the total resistance is given as, R = 1 h g ( 2 π r i ) + ln ( r 1 r i ) 2 π k c + R ″ t , c 2 π r i + ln ( r 2 r 1 ) 2 π k o + R e q The expression for the heat rate per unit length of the cylinder is given as, q = T g − T ∞ R The expression for the cylinder inner surface temperature is given as, T i = T g − q ( 1 h g × 2 π r i ) The expression for the interface temperature T 1 , i is given as, T 1 , i = T i − q × ln ( r 1 r i ) 2 π k c The expression for the interface temperature T 1 , 0 is given as, T 1 , 0 = T 1 , j − q ( R ″ t , c A ) The expression for the fin base temperature is given as, T b = T 1 , 0 − q R A l Calculation: The outer radius of the fin can be calculated as, r o c = r o + t 2 r o c = 95 + 2 2 r o c = 96 mm The area of the fin can be calculated as, A f = 2 π ( r o c 2 − r 2 2 ) A f = 2 π [ ( 96 mm ( 1 m 1000 mm ) ) 2 − ( ( 70 mm ) ( 1 m 1000 mm ) ) 2 ] A f = 0.0271 m 2 The characteristic length of the fin can be calculated as, L c = r o c − r 2 L c = 96 mm − 70 mm L c = 26 mm The area of the profile can be calculated as, A p = L c t A p = 26 mm × 2 mm A p = 52 mm 2 The total surface area can be calculated as, A t = N A f + 2 π r 2 ( N t ) A t = 250 ( 0.0271 m 2 ) + 2 π 70 mm ( 1 m 1000 mm ) ( 250 × 2 mm ( 1 m 1000 mm ) ) A t = 6.99 m 2 The overall efficiency can be calculated as, η o = 1 − N A f A t ( 1 − η f ) η o = 1 − 250 × 0

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 3.161P

To determine

The heat rate per unit length of the cylinder.

The cylinder inner surface temperature.

The interface temperature T1,i .

The interface temperature T1,0 .

The fin base temperature.

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Chapter 3, Problem 3.160P

Chapter 3, Problem 3.164P

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Introduction to Heat Transfer

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The heat rate per unit length of the cylinder. The cylinder inner surface temperature. The interface temperature T 1 , i . The interface temperature T 1 , 0 . The fin base temperature.

Solution Summary: The author explains the heat rate per unit length of the cylinder, the interface temperature, and the fin base temperature.

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The heat rate per unit length of the cylinder.

The cylinder inner surface temperature.

The interface temperature T1,i .

The interface temperature T1,0 .

The fin base temperature.

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Chapter 3 Solutions

The heat rate per unit length of the cylinder. The cylinder inner surface temperature. The interface temperature T 1 , i . The interface temperature T 1 , 0 . The fin base temperature.

Solution Summary: The author explains the heat rate per unit length of the cylinder, the interface temperature, and the fin base temperature.

Concept explainers

Videos

The heat rate per unit length of the cylinder. The cylinder inner surface temperature. The interface temperature T1,i . The interface temperature T1,0 . The fin base temperature.

Want to see the full answer?

Chapter 3 Solutions

The heat rate per unit length of the cylinder.

The cylinder inner surface temperature.

The interface temperature T1,i .

The interface temperature T1,0 .

The fin base temperature.