Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
9th Edition
ISBN: 9781260048766
Author: CENGEL
Publisher: MCG
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Chapter 7.13, Problem 154P

Liquid water at 200 kPa and 15°C is heated in a chamber by mixing it with superheated steam at 200 kPa and 150°C. Liquid water enters the mixing chamber at a rate of 4.3 kg/s, and the chamber is estimated to lose heat to the surrounding air at 20°C at a rate of 1200 kJ/min. If the mixture leaves the mixing chamber at 200 kPa and 80°C, determine (a) the mass flow rate of the superheated steam and (b) the rate of entropy generation during this mixing process.

FIGURE P7–154

Chapter 7.13, Problem 154P, Liquid water at 200 kPa and 15C is heated in a chamber by mixing it with superheated steam at 200

a)

Expert Solution
Check Mark
To determine

The mass flow rate of the superheated steam.

Answer to Problem 154P

The mass flow rate of the superheated steam is 0.4806kg/s.

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 in to 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.

Write the expression to calculate the mass balance of the system.

m˙inm˙out=Δm˙system (II)

Here, inlet mass flow rate is m˙in and outlet mass flow rate is m˙out and change in mass flow rate is Δm˙system.

Conclusion:

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

E˙inE˙out=0E˙in=E˙outm˙1h1+m˙2h2=Q˙out+m˙3h3Q˙out=m˙1h1+m˙2h2m˙3h3 (III)

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, enthalpy at entry 1 is h1, enthalpy at entry 2 is h2 and enthalpy at exit is h3.

Substitute m˙1+m˙2 for m˙3 in Equation (I).

Q˙out=m˙1h1+m˙2h2(m˙1+m˙2)h3=m˙1(h1h3)+m˙2(h2h3) (IV)

Rewrite the Equation (IV) to calculate the mass flow rate at entry 2.

m˙2=Q˙outm˙1(h1h3)(h2h3) (V)

From Table A-4, “the saturated water table”, select the initial enthalpy at entry 1 (h1), and initial entropy (s1) at the temperature of 15°C as 62.98kJ/kg, and 0.2245kJ/kgK respectively.

From Table A-6, “Superheated water”, select the initial enthalpy at entry 2 (h2), initial entropy (s2) and specific volume (v1) at the pressure of 200kPa and temperature of 150 C as 2769.1kJ/kg, and 7.2810kJ/kgK respectively.

From Table A-4, “the saturated water table”, select the enthalpy at exit (h3), and exit entropy (s3) at the temperature of 80 C as 335.02kJ/kg, and 1.0756kJ/kgK respectively.

Substitute 1200kJ/min for Q˙out, 4.3kg/s for m˙1, 62.98kJ/kg for h1, 2769.1kJ/kg for h2 and 335.02kJ/kg for h3 in Equation (V).

m˙2=(1200kJ/min)4.3kg/s(62.98kJ/kg335.02kJ/kg)(2769.1kJ/kg335.02kJ/kg)=(1200kJ/min)(1min60sec)4.3kg/s(62.98kJ/kg335.02kJ/kg)(2769.1kJ/kg335.02kJ/kg)=0.4806kg/s

Thus, the mass flow rate of the superheated steam is 0.4806kg/s.

b)

Expert Solution
Check Mark
To determine

The rate of heat entropy generation during the process.

Answer to Problem 154P

The rate of heat entropy generation during the process is 0.746kW/K.

Explanation of Solution

Write the expression for the entropy balance during the process.

S˙inS˙out+S˙gen=ΔS˙system (VI)

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˙2s2 for S˙in, m˙3s3+Q˙outTsurr for S˙out and 0 for ΔS˙system in Equation (VII).

m˙1s1+m˙2s2m˙3s3Q˙outTsurr+S˙gen=0S˙gen=m˙3s3m˙1s1m˙2s2+Q˙outTsurr (VII)

Here, entropy at entry 1 is s1, entropy at entry 2 is s2 and entropy at exit is s3 and surrounding temperature is Tsurr.

Substitute m˙1+m˙2 for m˙in, m˙3 for m˙out and 0 for Δm˙system in Equation (II).

m˙1+m˙2m˙3=0m˙3=m˙1+m˙2 (VIII)

Substitute 4.3kg/s for m˙1, and 0.4806kg/s for m˙2 in Equation (VIII).

m˙3=(4.3kg/s)+(0.4806kg/s)=4.781kg/s

Substitute 4.781kg/s for m˙3, 1.0756kJ/kgK for s3, 4.3kg/s for m˙1, 0.2245kJ/kgK for s1, 0.4806kg/s for m˙2, 7.2810kJ/kgK for s2, 1,200kJ/min for Q˙out, and 20 C for Tsurr in Equation (VII).

S˙gen={(4.781kg/s)(1.0756kJ/kgK)(4.3kg/s)(0.2245kJ/kgK)(0.4806kg/s)(7.2810kJ/kgK)+(1200kJ/min)20°C}={(4.781kg/s)(1.0756kJ/kgK)(4.3kg/s)(0.2245kJ/kgK)(0.4806kg/s)(7.2810kJ/kgK)+(1200kJ/min)(1min60sec)(20+273)K}=0.746kW/K

Thus, the rate of heat entropy generation during the process is 0.746kW/K.

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Chapter 7 Solutions

Thermodynamics: An Engineering Approach

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