Loose Leaf For Fundamentals Of Thermal-fluid Sciences Format: Looseleaf
Loose Leaf For Fundamentals Of Thermal-fluid Sciences Format: Looseleaf
5th Edition
ISBN: 9781259160240
Author: CENGEL
Publisher: Mcgraw Hill Publishers
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Conduction and Convection
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 17, Problem 127RQ

(a)

To determine

The heat transfer rate for the infinitely long fin.

(a)

Expert Solution
Check Mark

Explanation of Solution

Given:

Thermal conductivity of the fins (k) is 240 W/mK.

Heat transfer coefficient (h) is 250 W/m2K.

Length of the fin (L) is 50 mm.

Diameter of the fin (D) is 10 mm.

Calculation:

Determine the perimeter of the circular fin.

  p=πD=π(0.01 m)=0.03142m

Determine the cross section area of the circular fin.

  Ac=πD24=π(0.01 m)24=7.854×105m2

Determine the value of m.

  m=hpkAc=(250 W/m2°C)(0.03142 m)(240 W/m°C)(7.854×105m2)=20.41 m1

Determine the following factor.

  hpkAc=(250 W/m2°C)(0.03142m)(240 W/m°C)(7.854×105m2)=0.3848 W/°C

Determine the heat transfer rate for an infinitely long fin.

  Q˙long fin =hpkAc(TbT)=(0.3848 W/°C)(350°C25°C)=125 W

Thus, the heat transfer rate for the infinitely long fin is 125 W_.

Write the expression of the temperature variation along the fin.

  T(x)TTbT=emx

(b)

To determine

The heat transfer rate for the adiabatic fin tip.

(b)

Expert Solution
Check Mark

Explanation of Solution

Determine the heat transfer rate for an adiabatic fin tip.

  Q˙adiabatic tip=hpkAc(TbT)tanhmL=(0.3848 W/°C)(350°C25°C)tanh[(20.41 m1)(0.05 m)]=96.3 W

Thus, the heat transfer rate for the adiabatic fin tip is 96.3 W_.

Write the expression of the temperature variation along the fin.

  T(x)TTbT=coshm(Lx)coshmL

(c)

To determine

The heat transfer rate for the fin with tip temperature of 250°C.

(c)

Expert Solution
Check Mark

Explanation of Solution

Determine the heat transfer rate for fin with tip temperature of 250°C.

  Q˙specificad temp =hpkAc(TbT)coshmL(TLT)(TbT)sinhmL=(0.3848 W/°C)(350°C25°C)(0.725)=90.7 W

Thus, the heat transfer rate for the fin with tip temperature of 250°C is 90.7 W_.

Write the expression of the temperature variation along the fin.

  T(x)TTbT=(TLT)(TbT)sinhmx+sinhm(Lx)sinhmL

(d)

To determine

The heat transfer rate for fin with convection from the fin tip.

(d)

Expert Solution
Check Mark

Explanation of Solution

Determine the heat transfer rate for fin with convection from the tip.

  Q˙conv tip =hpkAc(TbT)sinhmL+(hmk)coshmLcoshmL+(hmk)sinhmL=(0.3848 W/°C)(350°C25°C)(0.7901)=98.8 W

Thus, the heat transfer rate for fin with convection from the fin tip is 98.8 W_.

Write the expression of the temperature variation along the fin.

  T(x)TTbT=coshm(Lx)+(hmk)sinhm(Lx)coshmL+(hmk)sinhmL

Tabulate the values of the temperature variation of the single fin.

L, m

T(x)°C
Part (a)Part (b)Part (c)Part (d)
0350350350350
0.005318326328325
0.01290305308304
0.015264288292285
0.02241272279270
0.025220260268256
0.03201250259246
0.035184242253237
0.04169237250231
0.045155233249227
0.05142232250224

Plot the temperature variation of the single fin as in Figure (1).

Loose Leaf For Fundamentals Of Thermal-fluid Sciences Format: Looseleaf, Chapter 17, Problem 127RQ

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Chapter 17 Solutions

Loose Leaf For Fundamentals Of Thermal-fluid Sciences Format: Looseleaf

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