a. Explanation Given information: The thermodynamic efficiency is given as, η therm = p M = 1 q 1 Here, p M = 1 is the power for one module and q 1 is the heat transfer rate of first state. Concept used: Write the expression for the heat transfer rate of first state. q 1 = h 1 W 2 ( T ∞ , 1 − T 1 ) Here, h 1 is the convection heat transfer coefficient of first state, W is the width of a slot nozzle, T ∞ , 1 is the ambient temperature for the first state and T 1 is the temperature of first state. Find the heat transfer rate of first state. q 1 = h 1 W 2 ( T ∞ , 1 − T 1 ) Here, h 1 is the convection heat transfer coefficient of first state, W is the width of a slot nozzle, T ∞ , 1 is the ambient temperature for the first state and T 1 is the temperature of first state. Substitute ( 550 + 273 ) K for T ∞ , 1 , ( 173 + 273 ) K for T 1 , 0 b. To determine To find: The figure of merit and the thermoelectric efficiency. c. To determine To find: The Carnot efficiency. d. To determine To find: The thermoelectric efficiency and the Carnot efficiency for h 1 = h 2 → ∞ . e. To determine To find: The thermoelectric efficiency.

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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 3, Problem 3.168P

To determine

To find: The thermodynamic efficiency.

To determine

To find: The figure of merit and the thermoelectric efficiency.

To determine

To find: The Carnot efficiency.

To determine

To find: The thermoelectric efficiency and the Carnot efficiency for h1=h2→∞ .

To determine

To find: The thermoelectric efficiency.

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Chapter 3, Problem 3.166P

Chapter 3, Problem 3.173P

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Fundamentals of Heat and Mass Transfer

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The thermodynamic efficiency.

Solution Summary: The author explains the thermodynamic efficiency, which is 2.2%, and the heat transfer rate of first state.

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To find: The thermodynamic efficiency.

To find: The figure of merit and the thermoelectric efficiency.

To find: The Carnot efficiency.

To find: The thermoelectric efficiency and the Carnot efficiency for h1=h2→∞ .

To find: The thermoelectric efficiency.

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Chapter 3 Solutions