THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
9th Edition
ISBN: 9781266657610
Author: CENGEL
Publisher: MCG CUSTOM
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Textbook Question
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Chapter 9.12, Problem 126P

Repeat Prob. 9–125, assuming an efficiency of 86 percent for each compressor stage and an efficiency of 90 percent for each turbine stage.

a)

Expert Solution
Check Mark
To determine

The back work ratio and thermal efficiency of the gas-turbine without regenerator.

Answer to Problem 126P

The back work ratio for the ideal gas-turbine cycle without regenerator is 43.3%.

The thermal efficiency of the gas-turbine without regenerator is 29.5%.

Explanation of Solution

Draw the Ts diagram for an ideal gas turbine cycle with two stages of compression and expansion as shown in Figure (1).

THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<, Chapter 9.12, Problem 126P

Write the pressure ratio relation for the process 1-2.

Pr2=P2P1Pr1 (I)

Here, relative pressure at state 1 is Pr1 and relative pressure at state 2 is Pr2.

Write the pressure ratio relation for the process 5-6.

Pr6=P6P5Pr5 (II)

Here, pressure at state 6 is P6 , pressure at state 5 is P5 , relative pressure at state 6 is Pr6 and relative pressure at state 5 is Pr5.

Write the expression to calculate the work input per kg to the compressors (wC,in).

wC,in=2(h2h1) (III)

Here, enthalpy at state 2 is h2  and enthalpy at state 1 is h1 .

Write the expression to calculate the work done per kg by the turbines (wT,out).

wT,out=2(h5h6) (IV)

Here, enthalpy at state 5 is h5  and enthalpy at state 6 is h6.

Write the expression to calculate the back work ratio (rbw).

rbw=wC,inwT,out (V)

Write the expression to calculate the heat input for ideal gas-turbine cycle

(qin).

qin=(h5h4)+(h7h6) (VI)

Here, enthalpy at state 4 is h4  and enthalpy at state 7 is h7.

Write the expression to calculate the net work output per kg by the gas-turbine cycle

(wnet).

wnet=wT,outwC,in (VII)

Write the expression to calculate the thermal efficiency of the gas-turbine cycle (ηth).

ηth=wnetqin (VIII)

Write the expression for the efficiency of the compressor (ηC)

ηC=h2sh1h2h1h2=h1+(h2sh1)/ηC (IX)

Here, the specific heat at constant pressure is cp.

Write the expression for the efficiency of the turbine (ηT).+

ηT=h5h6h5h6sh6=h5ηT(h5h6s) (X)

Conclusion:

From Table A-17, “Ideal-gas properties of air”, obtain the following properties at the temperature of 300K.

h1=300.19kJ/kgPr1=1.386

Substitute 3 for P2P1, and 1.386 for Pr1 in Equation (I).

Pr2=(3)(1.386)=4.158

From the Table A-17, “Ideal-gas properties of air”.

Obtain the value of enthalpy on isentropic state (h2s) at the relative pressure (Pr2) of 4.158 by using interpolation method.

Write the formula of interpolation method of two variables.

y2=(x2x1)(y3y1)(x3x1)+y1 (XI)

Here, the variables denoted by x and y are relative pressure and enthalpy on isentropic state.

Show relative pressure and enthalpy on isentropic state values from the Table A-17.

Relative pressure (Pr2)Enthalpy (h2s), in kJ/kg
4.153411.12
4.158?
4.522421.26

Substitute 4.153 for x1, 4.158 for x2, 4.522 for x3, 411.12 for y1, and 421.26 for y3 in Equation (XI).

y2=(4.1584.153)(421.26411.12)(4.5224.153)+411.12=411.257=411.26

The enthalpy on isentropic state (h2s) at the relative pressure (Pr2) of 4.158 by using interpolation method is 411.26kJ/kg.

Substitute 300.19kJ/kg for h1, 411.26kJ/kg for h2s, and 0.86 for ηC in Equation (IX).

h2=300.19kJ/kg+(411.26kJ/kg300.19kJ/kg)/0.86h2=h4=429.34kJ/kg

From Table A-17, “Ideal-gas properties of air”, obtain the following properties at the temperature of 1200K.

h5=h7=1277.79kJ/kgPr5=238

Substitute 13 for P6P5, and 238 for Pr5 in Equation (II).

Pr6=(13)(238)=79.33

From the Table A-17, “Ideal-gas properties of air” obtain the values of enthalpy on isentropic states h6s and h8s.at the relative pressure (Pr4) of 79.33 as 946.36kJ/kg by interpolation method as shown in Equation (XI).

Substitute 1277.79kJ/kg for h5, 946.36kJ/kg for h6s, and 0.90 for ηT in Equation (X).

h6=1277.79kJ/kg0.90(1277.79kJ/kg946.36kJ/kg)h6=h8=979.50kJ/kg

Substitute 429.34kJ/kg for h2, and 300.19kJ/kg for h1 in Equation (III).

wC,in=2(429.34kJ/kg300.19kJ/kg)=258.3kJ/kg

Substitute 1277.79kJ/kg for h5, and 258.3kJ/kg for h6 in Equation (IV).

wT,out=2(1277.79kJ/kg979.50kJ/kg)=596.6kJ/kg

Substitute 258.3kJ/kg for wC,in, and 596.6kJ/kg for wT,out in Equation (V).

rbw=258.3kJ/kg596.6kJ/kg=0.433×100%=43.3%

Thus, the back work ratio for the ideal gas-turbine cycle without regenerator is 43.3%.

Substitute 1277.79kJ/kg for h5, 429.34kJ/kg for h4, 1277.79kJ/kg for h7, and 979.50kJ/kg for h6 in Equation (VI).

qin=(1277.79429.34)kJ/kg+(1277.79979.50)kJ/kg=1146.7kJ/kg

Substitute 596.6kJ/kg for wT,out, and 258.3kJ/kg for wC,in in Equation (VII).

wnet=(596.6kJ/kg258.3kJ/kg)=338.3kJ/kg

Substitute 338.3kJ/kg for wnet, and 1146.7kJ/kg for qin in Equation (VIII).

ηth=338.3kJ/kg1146.7kJ/kg=0.295×100%=29.5%

Thus, the thermal efficiency of the gas-turbine without regenerator is 29.5%.

b)

Expert Solution
Check Mark
To determine

The thermal efficiency of the gas turbine with regenerator.

Answer to Problem 126P

The thermal efficiency of the gas turbine with regenerator is 46.1%.

Explanation of Solution

Write the expression to calculate the heat used for the regeneration process (qregen).

qregen=ε(h8h4) (X)

Here, the effectiveness of the regenerator is ε and enthalpy at state 8 is h8.

Write the expression to calculate the new heat input to the gas-turbine cycle (qin).

qin=qin,oldqregen (XI)

Write the expression to calculate the thermal efficiency of the gas-turbine with regenerator (ηth).

ηth=wnetqin (XII)

Conclusion:

Substitute 0.75 for ε, 979.50kJ/kg for h8, and 429.34kJ/kg for h4 in Equation (X).

qregen=(0.75)(946.36kJ/kg429.34kJ/kg)=412.6kJ/kg

Substitute 1146.7kJ/kg for qin,old, and 412.6kJ/kg for qregen in Equation (XI).

qin=(1146.7kJ/kg412.6kJ/kg)=734.1kJ/kg

Substitute 338.3kJ/kg for wnet, and 734.1kJ/kg for qin in Equation (XII).

ηth=338.3kJ/kg734.1kJ/kg=0.461×100%=46.1%

Thus, the thermal efficiency of the gas turbine with regenerator is 46.1%.

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Chapter 9 Solutions

THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<

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