THERMODYNAMICS-SI ED. EBOOK >I<
THERMODYNAMICS-SI ED. EBOOK >I<
9th Edition
ISBN: 9781307573022
Author: CENGEL
Publisher: MCG/CREATE
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Chapter 7.13, Problem 142P

a)

To determine

The rate of heat transfer to the air.

a)

Expert Solution
Check Mark

Answer to Problem 142P

The rate of heat transfer to the air is 205.7kW.

Explanation of Solution

Write the expression for the energy balance equation for closed system.

E˙inE˙out=ΔE˙system (I).

Here, rate of net energy transfer into the control volume is E˙in, rate of net energy transfer exit from the control volume is E˙out and rate of change in internal energy of system is ΔE˙system.

Conclusion:

The rate of change in internal energy of the system is zero at the steady flow system.

Substitute 0 for ΔE˙system in Equation (I).

E˙inE˙out=0m˙h1=Q˙out+m˙h2Q˙out=m˙(h1h2)Q˙out=[m˙cp(T1T2)]gas (II).

Here, mass flow rate is m˙, enthalpy at initial state is h1, enthalpy at final state is h2, rate of heat transfer to the air is Q˙out, specific heat at constant pressure is cp, inlet temperature is T1 and exit temperature is T2.

The specific heat at constant pressure (cp) for combustion gas is 1.10kJ/kg°C.

Substitute 2.2kg/s for m˙, 1.10kJ/kg°C for cp, 180°C for T2 and 95°C for T1 in Equation (II).

Q˙out=(2.2kg/s)(1.10kJ/kg°C)(180°C95°C)=(2.2kg/s)(1.10kJ/kg°C)[90°C]=205.7kJ/s(1kW1kJ/s)=205.7kW

Thus, the rate of heat transfer to the air is 205.7kW.

b)

To determine

The outlet temperature of the air.

b)

Expert Solution
Check Mark

Answer to Problem 142P

The outlet temperature of the air is 133.2°C.

Explanation of Solution

Write the expression to calculate the mass flow rate of air.

m˙air=P1V˙RT3 (III)

Here, volume flow rate of air at inlet is V˙, the temperature of air at inlet is T3, gas constant is R and the pressure of air inlet is P1.

Write the expression for the rate of heat transfer output.

Q˙in=m˙aircp(T4T3) (IV).

Here, heat gained by the air is Q˙in , outlet temperature of air is T4 and inlet temperature of air is T3.

Conclusion:

Substitute 95kPa for P1, 0.6m3/s for V˙, 0.287kJ/kgK for R and 20°C for T3 in Equation (I).

m˙air=95kPa(0.6m3/s)(0.287kJ/kgK)(20°C)=95kPa(0.6m3/s)(0.287kJ/kgK)(20+273)K=1.808kg/s

Heat loss by the exhaust gases is equal to heat gained by the air.

Q˙in=Q˙out

Substitute 20°C for T3, 205.7kW for Q˙out, 1.808kg/s for m˙air, and 1.005kJ/kg°C for cp in Equation (III).

205.7kW=1.808kg/s(1.005kJ/kg°C)(T420°C)T4=20°C+205.7kW(1.808kg/s)(1.005kJ/kg°C)T4=133.2°C

Thus, the outlet temperature of the air is 133.2°C.

c)

To determine

The rate of entropy generation

c)

Expert Solution
Check Mark

Answer to Problem 142P

The rate of entropy generation is 0.091kW/K.

Explanation of Solution

Write the expression for the entropy balance in the heat exchanger.

S˙inS˙out+S˙gen=ΔS˙system (V).

Here, rate of net input entropy is S˙in, rate of net output entropy is S˙out, rate of entropy generation is S˙gen, and rate of change of entropy of the system is ΔS˙system.

Conclusion:

Substitute m˙1s1+m˙3s3 for S˙in, m˙2s2+m˙3s4 for S˙out and 0 for ΔS˙system in Equation (V).

m˙1s1+m˙3s3(m˙2s2+m˙3s4)+S˙gen=0m˙1s1+m˙3s3m˙2s2m˙3s4+S˙gen=0

m˙exhausts1+m˙airs3m˙exhausts2m˙airs4+S˙gen=0S˙gen=m˙exhaust(s2s1)+m˙air(s4s3)S˙gen=m˙exhaustcpln(T2T1)+m˙aircpln(T4T3) (VI)

Here, mass flow rate at entry 1 is m˙1, mass flow rate at entry 2 is m˙2, mass flow rate at exit is m˙3, entropy at state 3 is s3 , entropy at state 4 is s4, entropy at state 2 is s2 and entropy at state 1 is s1.

Substitute 1.808kg/s for m˙air, 1.005kJ/kgK for cp,air, 95°C for T2, 180°C for T1.2.2kg/s for m˙exhaust, 1.1kJ/kgK for cp,exhaust, 20°C for T3, and 133.2°C for T4 in Equation (VI).

S˙gen=[(2.2kg/s)(1.1kJ/kgK)ln(95°C)(180°C)+(1.808kg/s)(1.005kJ/kgK)ln(133.2°C)(20°C)]=[(2.2kg/s)(1.1kJ/kgK)ln(95+273)K(180+273)K+(1.808kg/s)(1.005kJ/kgK)ln(133.2+273)K(20+273)K]=0.091kJ/sK(1kW1kJ/s)=0.091kW/K

Thus, the rate of entropy generation is 0.091kW/K.

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Chapter 7 Solutions

THERMODYNAMICS-SI ED. EBOOK >I<

Ch. 7.13 - A pistoncylinder device contains helium gas....Ch. 7.13 - A pistoncylinder device contains nitrogen gas....Ch. 7.13 - A pistoncylinder device contains superheated...Ch. 7.13 - The entropy of steam will (increase, decrease,...Ch. 7.13 - During a heat transfer process, the entropy of a...Ch. 7.13 - Steam is accelerated as it flows through an actual...Ch. 7.13 - Heat is transferred at a rate of 2 kW from a hot...Ch. 7.13 - A completely reversible air conditioner provides...Ch. 7.13 - Heat in the amount of 100 kJ is transferred...Ch. 7.13 - In Prob. 719, assume that the heat is transferred...Ch. 7.13 - During the isothermal heat addition process of a...Ch. 7.13 - Prob. 22PCh. 7.13 - During the isothermal heat rejection process of a...Ch. 7.13 - Air is compressed by a 40-kW compressor from P1 to...Ch. 7.13 - Refrigerant-134a enters the coils of the...Ch. 7.13 - A rigid tank contains an ideal gas at 40C that is...Ch. 7.13 - A rigid vessel is filled with a fluid from a...Ch. 7.13 - 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