Fundamentals Of Thermal-fluid Sciences In Si Units
Fundamentals Of Thermal-fluid Sciences In Si Units
5th Edition
ISBN: 9789814720953
Author: Yunus Cengel, Robert Turner, John Cimbala
Publisher: McGraw-Hill Education
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Chapter 8, Problem 133P

a)

To determine

The mass flow rate of the steam.

a)

Expert Solution
Check Mark

Explanation of Solution

Given:

The initial pressure of the steam (P1) is 7 MPa.

The initial temperature of the steam (T1) is 500°C.

The initial velocity (V1) is 45m/s.

The final pressure of the steam (P2) is 100 kPa.

The final velocity (V2) is 75m/s.

The power output of the turbine (W˙a) is 5 MW.

The isentropic efficiency (η) is 77%.

Conclusion:

Refer the Table A-6, “superheated water table”, obtain the following properties at a pressure of 7MPa and temperature of 500 C.

The initial enthalpy (h1) is 3,411.4kJ/kg.

The initial entropy (s1) is 6.800kJ/kgK.

The entropy remains constant since the process is isentropic (s2s=s1).

Refer the Table A-6, “superheated water table”, obtain the following properties at a pressure of 100kPa and entropy of 6.800kJ/kgK.

The enthalpy at final state in isentropic process (h2s) is 2466.6kJ/kg.

Calculate the power output for the isentropic process.

  W˙s=W˙aηT

  W˙s=5,000kW70%=5,000kW70(1100)=6494kW=6494kJ/s

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.

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

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

  E˙inE˙out=0E˙in=E˙outm˙(h1+V122)=m˙(h2s+V222)+W˙s

  m˙(3411.4kJ/kg+(45m/s)22)={m˙(2466.6kJ/kg+(75m/s)22)+6494kJ/s}m˙(3411.4kJ/kg+(45m/s)22(1kJ/kg1000m2/s2))={m˙(2466.6kJ/kg+(75m/s)22(1kJ/kg1000m2/s2))+6494kJ/s}m˙=6.886kg/s

Thus, the mass flow rate of the steam is 6.886kg/s.

b)

To determine

The exit temperature of the steam.

b)

Expert Solution
Check Mark

Explanation of Solution

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

  m˙(h1+V122)=m˙(h2s+V222)+W˙a

  6.886kg/s(3411.4kJ/kg+(45m/s)22)={6.886kg/s×(h2+(75m/s)22)+5000kJ/s}6.886kg/s(3411.4kJ/kg+(45m/s)22(1kJ/kg1000m2/s2))={6.886kg/s×(h2+(75m/s)22(1kJ/kg1000m2/s2))+5000kJ/s}h2=2683.5kJ/kg

Refer the Table A-6, “superheated water table”, obtain final entropy at pressure of 100kPa and enthalpy of 2683.5kJ/kg as 7.3817kJ/kgK.

Refer the Table A-6, “Superheated water”, obtain the value of exit temperature (T2) at final enthalpy (h2) of 2683.5kJ/kg by using interpolation method.

Show exit temperature and enthalpy values from the Table A-6.

Temperature (T2),in °CEnthalpy (h2), in Btu/lbmR
2675100
2683.5?
2776.6150

Write the formula of interpolation method of two variables.

  y2=(x2x1)(y3y1)(x3x1)+y1        (V)

Here, the variables denoted by x and y are exit temperature and enthalpy.

Substitute x1=2675, x2=2683.5, x3=2776.6, y1=100, and y3=150 in Equation (V).

  y2=(2683.52675)(150100)(2776.62675)+100=104.18

The value of exit temperature (T2) at final enthalpy (h2) of 2683.5kJ/kg is 104.18°C.

Thus, the exit temperature of the steam is 104.18°C.

c)

To determine

The entropy generation in the turbine.

c)

Expert Solution
Check Mark

Explanation of Solution

Calculate the entropy generation in the turbine (Sgen).

  Sgen=m˙(s2s1)

  Sgen=6.886kg/s(7.3817kJ/kgK6.800kJ/kgK)=4.01kJ/Ks(1kW1kJ/s)=4.01kW/K

Thus, the entropy generation in the turbine is 4.01kW/K.

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Chapter 8 Solutions

Fundamentals Of Thermal-fluid Sciences In Si Units

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