THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<
9th Edition
ISBN: 9781266657610
Author: CENGEL
Publisher: MCG CUSTOM
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Chapter 15.7, Problem 83P

Reconsider Prob. 15–82. The combustion products are expanded in an isentropic turbine to 140 kPa. Calculate the work produced by this turbine in kJ/kg fuel.

Expert Solution & Answer
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To determine

The work produced by an isentropic turbine.

Answer to Problem 83P

The work produced by an isentropic turbine is 6365kJ/kgfuel.

Explanation of Solution

Express the balanced equation.

[0.7215C+0.2535H2+0.01618O2+0.00711N2+0.00177S+1.2509(O2+3.76N2)0.7215CO2+0.2535H2O+0.00177SO2+4.710N2+0.4170O2] (I)

Here, carbon is C, hydrogen is H2, oxygen is O2, nitrogen is N2, sulfur is S, carbon dioxide is CO2, water is H2O and sulfur oxide is SO2.

Express the change in entropy of the mixture during the mixture when there is no entropy change during an isentropic process.

y(s¯2os¯1o)=RalnP2P1(NCO2+NH2O+NSO2+NN2+NO2) (II)

Here, final entropy is s¯2o, initial entropy is s¯1o, universal gas constant of air is Ra, final and initial pressure is P2andP1, number of moles of carbon dioxide, water, sulfur dioxide, nitrogen and oxygen is NCO2,NH2O,NSO2,NN2,andNO2 respectively.

Express the change in entropy of the mixture at temperature of 1000K.

y(s¯2os¯1o)=[NCO2(s¯2os¯1o)CO2+NH2O(s¯2os¯1o)H2O+NN2(s¯2os¯1o)N2+NO2(s¯2os¯1o)O2] (III)

Express the change in entropy of the mixture at temperature of 1200K.

y(s¯2os¯1o)=[NCO2(s¯2os¯1o)CO2+NH2O(s¯2os¯1o)H2O+NN2(s¯2os¯1o)N2+NO2(s¯2os¯1o)O2] (IV)

Express the work produced during the isentropic expansion of combustion gases.

w¯out=y(h¯1h¯2)=[NCO2(h¯1h¯2)CO2+NH2O(h¯1h¯2)H2O+NN2(h¯1h¯2)N2+NO2(h¯1h¯2)O2] (V)

Here, initial and final enthalpy is h¯1andh¯2 respectively.

Express molar mass of the product gases.

Mm=NCO2MCO2+NH2OMH2O+NSO2MSO2+NN2MN2+NO2MO2NCO2+NH2O+NSO2+NN2+NO2 (VI)

Here, molar mass of carbon dioxide, water, sulfur dioxide, nitrogen and oxygen is MCO2,MH2O,MSO2,MN2,andMO2 respectively.

Express the work produced per kg of the fuel.

wout=w¯outMm (VII)

Conclusion:

Refer Equation (I), and write the number of moles.

NCO2=0.7215kmolNH2O=0.2535kmolNSO2=0.0018kmol

NN2=4.71kmolNO2=0.4170kmol

Refer Table A-1, “molar mass, gas constant and critical point properties”, and write the molecular masses.

MCO2=44kg/kmolMH2O=18kg/kmolMSO2=64kg/kmol

MN2=28kg/kmolMO2=32kg/kmol

Refer Table A-1, “molar mass, gas constant and critical point properties”, and write the universal gas constant of air.

Ra=8.314kJ/kmolK

Substitute 8.314kJ/kmolK for Ra, 140kPaand1380kPa for P2andP1 respectively, 0.7215kmol for NCO2, 0.2535kmol for NH2O, 0.0018kmol for NSO2, 4.71kmol for NN2 and 0.4170kmol for NO2 in Equation (II).

y(s¯2os¯1o)=(8.314kJ/kmolK)[ln140kPa1380kPa][0.7215kmol+0.2535kmol+0.0018kmol+4.71kmol+0.4170kmol]=(8.314kJ/kmolK)(2.288)(6.1038kmol)=116.1kJ/K

Refer Table A-18, A-19, A-20, A-21, A-22, and A-23, and write the initial and final entropy at temperature of 1000K as in Table (1).

Components

s¯1o

(kJ/kmolK)

s¯2o

(kJ/kmolK)

CO2307.992269.215
H2O263.542232.597
N2251.424228.057
O2267.891243.471

Substitute 0.7215kmol for NCO2, 0.2535kmol for NH2O, 4.71kmol for NN2, 0.4170kmol for NO2 and values from Table (I) in Equation (III) to get,

y(s¯2os¯1o)=[(0.7215)(269.215307.992)+(0.2535)(232.597263.542)+(4.71)(228.057251.242)+(0.417)(243.471267.891)]=155.2kJ/K

Refer Table A-18, A-19, A-20, A-21, A-22, and A-23, and write the initial and final entropy at temperature of 1200K as in Table (2).

Components

s¯1o

(kJ/K)

s¯2o

(kJ/K)

CO2307.992297.307
H2O263.542240.333
N2251.242234.115
O2267.891249.906

Substitute 0.7215kmol for NCO2, 0.2535kmol for NH2O, 4.71kmol for NN2, 0.4170kmol for NO2 and values from Table (II) in Equation (IV) to get,

y(s¯2os¯1o)=[(0.7215)(297.307307.992)+(0.2535)(240.333263.542)+(4.71)(234.115251.242)+(0.417)(249.906267.891)]=101.8kJ/K

Perform the interpolation method to obtain the final temperature.

Write the formula of interpolation method of two variables.

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

Here, the variables denote by x and y is entropy change and final temperature respectively.

Show the final temperature corresponding to entropy change as in Table (3).

Entropy change

y(s¯2os¯1o)(kJ/K)

Final temperature

T2(K)

155.2 (x1)1000 (y1)
116.1 (x2)(y2=?)
101.8 (x3)1200 (y3)

Substitute 155.2kJ/K,116.1kJ/Kand101.8kJ/K for x1,x2andx3 respectively, 1000K for y1 and 1200K for y3 in Equation (VIII).

y2=[{116.1(155.2kJ/K)}kJ/K][(12001000)K][{101.8(155.2kJ/K)}kJ/K]+1000K=1146K=T2

Thus, the final temperature is,

T2=1146K

Refer Table A-18, A-19, A-20, A-21, A-22, and A-23, and write the initial and final enthalpy during the isentropic expansion of combustion gases from 1956Kto1146K as in Table (4).

Components

h¯1

(kJ/kmol)

h¯2

(kJ/kmol)

CO298,16050,189
H2O80,35242,037
N263,23634,961
O266,22336,527

Substitute 0.7215kmol for NCO2, 0.2535kmol for NH2O, 4.71kmol for NN2, 0.4170kmol for NO2 and values from Table (III) in Equation (V) to get,

w¯out=[(0.7215)(98,16050,819)+(0.2535)(80,35242,037)+(4.71)(63,23634,961)+(0.417)(66,22336,527)]=189,428kJ/kmolfuel

Substitute 0.7215kmol for NCO2, 0.2535kmol for NH2O, 4.71kmol for NN2, 0.4170kmol for NO2, 0.0018kmol for NSO2, 44kg/kmol for MCO2, 18kg/kmol for MH2O, 64kg/kmol for MSO2, 28kg/kmol for MN2 and 32kg/kmol for MO2 in Equation (VI).

Mm=[(0.7215×44)+(0.2535×18)+(0.0018×64)+(4.71×28)+(0.4170×32)]kg(0.7215+0.2535+0.0018+4.71+0.417)kmol=29.76kg/kmol

Substitute 189,428kJ/kmolfuel for w¯out and 29.76kg/kmol for Mm in Equation (VII).

wout=189,428kJ/kmolfuel29.76kg/kmol=6365kJ/kgfuel

Hence, the work produced by an isentropic turbine is 6365kJ/kgfuel.

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Chapter 15 Solutions

THERMODYNAMICS (LL)-W/ACCESS >CUSTOM<

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