THERMODYNAMICS: ENG APPROACH LOOSELEAF
THERMODYNAMICS: ENG APPROACH LOOSELEAF
9th Edition
ISBN: 9781266084584
Author: CENGEL
Publisher: MCG
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Textbook Question
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Chapter 10.9, Problem 52P

A steam power plant operates on an ideal regenerative Rankine cycle with two open feedwater heaters. Steam enters the turbine at 8 MPa and 550°C and exhausts to the condenser at 15 kPa. Steam is extracted from the turbine at 0.6 and 0.2 MPa. Water leaves both feedwater heaters as a saturated liquid. The mass flow rate of steam through the boiler is 24 kg/s. Show the cycle on a T-s diagram, and determine (a) the net power output of the power plant and (b) the thermal efficiency of the cycle.

(a)

Expert Solution
Check Mark
To determine

The power output of plant.

Answer to Problem 52P

The power output of the plant is 28.8MW.

Explanation of Solution

Draw the schematic diagram of the given ideal regenerative Rankine cycle as shown in

Figure 1.

THERMODYNAMICS: ENG APPROACH LOOSELEAF, Chapter 10.9, Problem 52P , additional homework tip  1

Draw the Ts diagram of the given ideal regenerative Rankine cycle as shown in

Figure 2.

THERMODYNAMICS: ENG APPROACH LOOSELEAF, Chapter 10.9, Problem 52P , additional homework tip  2

Here, water (steam) is the working fluid of the regenerative Rankine cycle. The cycle involves three pumps.

Write the formula for work done by the pump during process 1-2.

wpI,in=v1(P2P1) (I)

Here, the specific volume is v, the pressure is P, and the subscripts 1 and 2 indicates the process states.

Write the formula for enthalpy (h) at state 2.

h2=h1+wpI,in (II)

Write the formula for work done by the pump during process 3-4.

wpII,in=v3(P4P3) (III)

Here, the specific volume is v, the pressure is P, and the subscripts 3 and 4 indicates the process states.

Write the formula for enthalpy (h) at state 4.

h4=h3+wpII,in (IV)

Write the formula for work done by the pump during process 5-6.

wpIII,in=v5(P6P5) (V)

Here, the specific volume is v, the pressure is P, and the subscripts 5 and 6 indicates the process states.

Write the formula for enthalpy (h) at state 6.

h6=h5+wpIII,in (VI)

At state 9:

The steam expanded to the pressure of 0.2MPa and the steam is at the state of saturated mixture.

The quality of water at the exit of the turbine (state 9) is expressed as follows.

x9=s9sf,9sfg,9 (VII)

The enthalpy at state 9 is expressed as follows.

h9=hf,9+x9hfg,9 (VIII)

Here, the enthalpy is h, the entropy is s, the quality of the water is x, the suffix f indicates the fluid condition, the suffix fg indicates the change of vaporization phase; the subscript 9 indicates the process state 9.

At state 10:

The steam enters the condenser at the pressure of 10kPa and at the state of saturated mixture.

The quality of water at state 10 is expressed as follows.

x10=s10sf,10sfg,10 (IX)

The enthalpy at state 10 is expressed as follows.

h10=hf,10+x10hfg,10 (X)

Here, the subscript 10 indicates the process state 10.

Refer Figure 1 and 2.

Write the formula for heat in (qin) and heat out (qout) of the cycle.

qin=h7h6 (XI)

qout=(1yz)(h10h1) (XII)

Here, the mass fraction steam extracted from the turbine to the feed water entering the boiler via feed water heater-I (m˙8/m˙5) is y and the mass fraction steam extracted from the turbine to feed water entering the boiler via the feed water heater-II (m˙9/m˙5) is z.

Write the general equation of energy balance equation.

E˙inE˙out=ΔE˙system (XIII)

Here, the rate of net energy inlet is E˙in, the rate of net energy outlet is E˙out and the rate of change of net energy of the system is ΔE˙system.

At steady state the rate of change of net energy of the system (ΔE˙system) is zero.

ΔE˙system=0

Refer Equation (XIII).

Write the energy balance equation for open feed water heater-II.

E˙inE˙out=0E˙in=E˙outm˙inhin=m˙outhoutm˙8h8+m˙4h4=m˙5h5 (XIV)

Rewrite the Equation (XIV) in terms of mass fraction y.

yh8+(1y)h4=1h5yh8+h4yh4=h5y(h8h4)=h5h4y=h5h4h8h4 (XV)

Refer Equation (XIII).

Write the energy balance equation for open feed water heater-I.

E˙inE˙out=0E˙in=E˙outm˙inhin=m˙outhoutm˙9h9+m˙2h2=m˙3h3 (XVI)

Rewrite the Equation (XVI) in terms of mass fraction yandz.

zh9+(1yz)h2=(1y)h3zh9+(1y)h2zh2=(1y)h3z(h9h2)=(1y)h3(1y)h2z=h3h2h9h2(1y) (XVII)

Write the formula for net power output of the cycle per unit mass.

wnet=qinqout (XVIII)

Write the formula for net power output of the cycle.

W˙net=m˙wnet (XIX)

Here, the mass flow rate is m˙.

At state 1: (Pump I inlet)

The water exits the condenser as a saturated liquid at the pressure of 15kPa. Hence, the enthalpy and specific volume at state 1 is as follows.

h1=hf@15kPav1=vf@15kPa

Refer Table A-5, “Saturated water-Pressure table”.

The enthalpy (h1) and specific volume (v1) at state 1 corresponding to the pressure of 15kPa is 225.94kJ/kg and 0.001014m3/kg respectively.

At state 3: (Pump II inlet)

The water exits the open feed water heater-I as a saturated liquid at the pressure of 0.2MPa(200kPa). Hence, the enthalpy and specific volume at state 3 is as follows.

h3=hf@200kPav3=vf@200kPa

Refer Table A-5, “Saturated water-Pressure table”.

The enthalpy (h3) and specific volume (v3) at state 3 corresponding to the pressure of 0.2MPa(200kPa) is 504.71kJ/kg and 0.001061m3/kg respectively.

At state 5: (Pump III inlet)

The water exits the open feed water heater-II as a saturated liquid at the pressure of 0.6MPa(600kPa). Hence, the enthalpy and specific volume at state 5 is as follows.

h5=hf@600kPav5=vf@600kPa

Refer Table A-5, “Saturated water-Pressure table”.

The enthalpy (h5) and specific volume (v5) at state 5 corresponding to the pressure of 0.6MPa(600kPa) is 670.38kJ/kg and 0.001101m3/kg respectively

At state 7:

The steam enters the turbine as superheated vapor.

Refer Table A-6, “Superheated water”.

The enthalpy (h7) and entropy (s7) at state 7 corresponding to the pressure of 8MPa(8000kPa) and the temperature of 550°C is as follows.

h7=3521.8kJ/kgs7=6.8800kJ/kgK

From Figure 2.

s7=s8=s9=s10=6.8800kJ/kgK

At state 8:

The steam expanded to the pressure of 0.6MPa(600kPa) and in the state of superheated vapor.

Refer Table A-6, “Superheated water”.

The enthalpy (h8) at state 8 corresponding to the pressure of 0.6MPa(600kPa) and the entropy of 6.8800kJ/kgK is as follows.

h8=2809.6kJ/kg

At state 9:

The steam expanded to the pressure of 0.2MPa(200kPa) and in the state of saturated mixture.

Refer Table A-5, “Saturated water-Pressure table”.

Obtain the following properties corresponding to the pressure of 0.2MPa(200kPa).

hf,9=504.71kJ/kghfg,9=2201.6kJ/kgsf,9=1.5302kJ/kgKsfg,9=5.5968kJ/kgK

At state 10:

The steam enters the condenser at the pressure of 15kPa and at the state of saturated mixture.

Refer Table A-5, “Saturated water-Pressure table”.

Obtain the following properties corresponding to the pressure of 15kPa.

hf,10=225.94kJ/kghfg,10=2372.3kJ/kgsf,10=0.7549kJ/kgKsfg,10=7.2522kJ/kgK

Conclusion:

Substitute 0.001014m3/kg for v1, 15kPa for P1, and 200kPa for P2 in Equation (I).

wpI,in=(0.001014m3/kg)(200kPa15kPa)=0.18759kPam3/kg×1kJ1kPam3=0.188kJ/kg

Substitute 225.94kJ/kg for h1, and 0.188kJ/kg for wpI,in in Equation (II).

h2=225.94kJ/kg+0.188kJ/kg=226.13kJ/kg

Substitute 0.001061m3/kg for v3, 200kPa for P3, and 600kPa for P4 in

Equation (III).

wpII,in=(0.001061m3/kg)(600kPa200kPa)=0.4244kPam3/kg×1kJ1kPam30.42kJ/kg

Substitute 504.71kJ/kg for h3, and 0.42kJ/kg for wpII,in in Equation (IV).

h4=504.71kJ/kg+0.42kJ/kg=505.13kJ/kg

Substitute 0.001101m3/kg for v5, 600kPa for P5, and 8000kPa for P4 in

Equation (V).

wpIII,in=(0.001101m3/kg)(8000kPa600kPa)=8.1474kPam3/kg×1kJ1kPam38.15kJ/kg

Substitute 670.38kJ/kg for h5, and 8.15kJ/kg for wpIII,in in Equation (VI).

h6=670.38kJ/kg+8.15kJ/kg=678.53kJ/kg

From Figure 1.

s7=s8=s8=s10=6.8800kJ/kgK

Substitute 6.8800kJ/kgK for s9, 1.5302kJ/kgK for sf,9, and 5.5968kJ/kgK for sfg,9 in Equation (VII).

x9=6.8800kJ/kgK1.5302kJ/kgK5.5968kJ/kgK=0.9559

Substitute 504.71kJ/kg for hf,9, 2201.6kJ/kg for hfg,9, and 0.9559 for x9 in

Equation (VIII).

h9=504.71kJ/kg+0.9559(2201.6kJ/kg)=504.71kJ/kg+2104.5094kJ/kg=2609.2194kJ/kg

Substitute 6.8800kJ/kgK for s10, 0.7549kJ/kgK for sf,10, and 7.2522kJ/kgK for sfg,10 in Equation (IX).

x10=6.8800kJ/kgK0.7549kJ/kgK7.2522kJ/kgK=0.8446

Substitute 225.94kJ/kg for hf,10, 2372.3kJ/kg for hfg,10, and 0.8446 for x10 in

Equation (X).

h10=225.94kJ/kg+0.8446(2372.3kJ/kg)=225.94kJ/kg+1977.6037kJ/kg=2229.5846kJ/kg2229.6kJ/kg

Consider the open feed water heater-II alone.

Substitute 670.38kJ/kg for h5, 505.13kJ/kg for h4, and 2809.6kJ/kg for h8 in Equation (XIV).

y=670.38kJ/kg505.13kJ/kg2809.6kJ/kg505.13kJ/kg=165.252304.47=0.07171

Consider the open feed water heater-I alone.

Substitute 504.71kJ/kg for h3, 226.13kJ/kg for h2, 2609.2194kJ/kg for h9, and 0.07171 for y in Equation (XVII).

z=504.71kJ/kg226.13kJ/kg2609.2194kJ/kg226.13kJ/kg(10.07171)=278.582383.0894(0.92829)=0.1085

Substitute 3521.8kJ/kg for h7, and 678.53kJ/kg for h6 in Equation (XI).

qin=3521.8kJ/kg678.53kJ/kg=2843.27kJ/kg2843.3kJ/kg

Substitute 0.07171 for y, 0.1085 for z, 2229.6kJ/kg for h10, and 225.94kJ/kg for h1 in Equation (XII).

qout=(10.071710.1085)(2229.6kJ/kg225.94kJ/kg)=0.81979(2003.66kJ/kg)=1642.5804kJ/kg=1642.6kJ/kg

Substitute 2843.3kJ/kg for qin, and 1642.6kJ/kg for qout in Equation (XVIII).

wnet=2843.3kJ/kg1642.6kJ/kg=1200.7kJ/kg

Substitute 24kg/s for m˙ and  1200.7kJ/kg for wnet in Equation (XIX).

W˙net=24kg/s(1200.7kJ/kg)=28816.8kJ/s×1MW103kJ/s=28.8168MW28.8MW

Thus, the power output of the plant is 28.8MW.

(b)

Expert Solution
Check Mark
To determine

The thermal efficiency of the cycle.

Answer to Problem 52P

The thermal efficiency of the cycle is 42.2%.

Explanation of Solution

Write the formula for thermal efficiency of the cycle (ηth).

ηth=1qoutqin (XX)

Conclusion:

Substitute 1642.6kJ/kg for qout, and 2843.3kJ/kg for qin in Equation (XV).

ηth=11642.6kJ/kg2843.3kJ/kg=10.5777=0.4222×100=42.2%

Thus, the thermal efficiency of the cycle is 42.2%.

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Chapter 10 Solutions

THERMODYNAMICS: ENG APPROACH LOOSELEAF

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