EBK THERMODYNAMICS: AN ENGINEERING APPR
EBK THERMODYNAMICS: AN ENGINEERING APPR
8th Edition
ISBN: 8220100257056
Author: CENGEL
Publisher: YUZU
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Chapter 16.6, Problem 34P

(a)

To determine

The equilibrium composition of product gases.

(a)

Expert Solution
Check Mark

Answer to Problem 34P

Thus, the equilibrium composition of mixture of CO2, CO and O2 at 16 psia pressure and 3600 R is 0.9966CO2+0.0034CO+0.1587O2_.

Explanation of Solution

Write the expression for the volume of oxygen used per lbmol of carbon monoxide (vCO).

vCO=RTP (I)

Here, gas constant is R, temperature is T, and pressure is P.

Calculate the mass flow rate of carbon monoxide (m˙CO).

m˙CO=v˙COvCO (II)

Here, volume flow rate of carbon monoxide is v˙CO.

Calculate the molar air fuel ratio (AF).

AF=NO2NCO

AF=m˙O2/MO2m˙CO/MCO (III)

Here, number of moles of oxygen is NO2, number of moles of fuel is Nfuel, mass flow rate of oxygen is m˙O2, molecular weight of oxygen is MO2, mass flow rate of fuel is m˙CO, and molecular weight of fuel is MCO.

Express the stoichiometric reaction for the dissociation process.

CO2CO+12O2 (IV)

From the stoichiometric reaction, infer that the stoichiometric coefficient for carbon monoxide (vCO) is 1, for oxygen (vO2) is 0.5, and for carbon dioxide (vCO2) is 1.

Express the actual reaction for the dissociation process.

CO+0.657O2xCO2+(1x)CO+(0.6570.5x)O2 (V)

From the actual reaction, infer that the equilibrium composition contains x amount of carbon dioxide (NCO2), (1x) amount of carbon monoxide (NCO), and (0.6570.5x) amount of nitrogen (NO2).

Express the formula for total number of moles (Ntotal).

Ntotal=NCO2+NCO+NO2 (VI)

Here, number of moles of carbon dioxide is NCO2, number of moles of carbon monoxide is NCO, and number of moles of oxygen is NO2.

Write the expression for the equilibrium constant (Kp) for the dissociation process.

Kp=NCOvCONO2vO2NCO2vCO2(PNtotal)(vCO+vO2vCO2) (VII)

Conclusion:

Substitute 0.3831psiaft3/lbmR for R, 560 R for T, and 16 psia for P in Equation (I).

vCO=(0.3831psiaft3/lbmR)(560R)16psia=13.41ft3/lbm

Substitute 12.5ft3/min for v˙CO, and 13.41ft3/lbm for vCO in Equation (II).

m˙CO=12.5ft3/min13.41ft3/lbm=0.932lbm/min

Substitute 0.7lbm/min for m˙O2, 0.932lbm/min for m˙CO, 32lbm/lbmol for MO2, and 28lbm/lbmol for MCO in Equation (III).

AF=(0.7lbm/min)/(32lbm/lbmol)(0.932lbm/min)/(28lbm/lbmol)=0.657lbmol O2/lbmol fuel

Substitute xfor NCO2, (1x) for NCO, and (0.6570.5x) for NO2 in Equation (VI).

Ntotal=x+(1x)+(0.6570.5x)=1.6570.5x

Convert the temperature unit from Rankine to Kelvin.

T=3600R=3600R(1 K1.8R)=2000K

Refer table A-28, “natural logarithm of equilibrium constants”, select the value of lnkp for carbon dioxide as 6.635 at 2000 K. Hence, the value of equilibrium constant (Kp) for carbon dioxide dissociation process is 1.313×103.

Substitute 1.313×103 for kp, x for NCO2, (1x) for NCO, (0.6570.5x) for NO2, 0.5 for vO2, 1 for both vCO2 and vCO, 16 psia for P, and 1.6570.5x for Ntotal in Equation (VII).

1.313×103=(1x)(0.6570.5x)0.5x(16psia1atm14.7psia1.6570.5x)(1+0.51)(1.313×103)x=(1x)(0.6570.5x)0.5(1.0881.6570.5x)0.51.7125×106x=(1+x22x)(0.6570.5x)(1.0881.6570.5x)

Solve the equation and find the value of x as 0.9966.

Substitute 0.9966 for x in Equation (V).

CO+0.657O2xCO2+(1x)CO+(0.6570.5x)O2CO+0.657O20.9966CO2+(10.9966)CO+(0.6570.5(0.9966))O2CO+0.657O20.9966CO2+0.0034CO+0.1587O2

Thus, the equilibrium composition of mixture of CO2, CO and O2 at 16 psia pressure and 3600 R is 0.9966CO2+0.0034CO+0.1587O2_.

(b)

To determine

The rate of heat transfer from the combustion chamber

(b)

Expert Solution
Check Mark

Answer to Problem 34P

The rate of heat transfer from the combustion chamber is 2,602Btu/min_.

Explanation of Solution

Write the expression for the energy balance equation for the combustion process.

Qout=NP(h¯f+h¯h¯)PNR(h¯f+h¯h¯)R={NCO2(h¯f+h¯h¯)CO2+NCO(h¯f+h¯h¯)CO+NO2(h¯f+h¯h¯)O2NCO(h¯f+h¯h¯)CO} (VII)

Here, heat released during combustion is Qout, number of moles of product is NP, number of moles of reactants is NR, number of moles of CO2 is NN2, number of moles of CO2 is NCO2, number of moles of CO is NCO, enthalpy at reference state is h¯f, sensible enthalpy at specified state is h¯, and sensible enthalpy at reference state is h¯.

Write the expression for the mass flow rate of CO (N˙).

N˙CO=m˙COMCO (VIII)

Write the expression for the rate of heat transfer (Q˙out).

Q˙out=N˙COQout (IX)

Conclusion:

Refer Table A-26, “Enthalpy of formation, Gibbs function of formation, and absolute entropy at

778F, 1 atm”, select the enthalpy of CO((h¯f)CO) as 47,540Btu/lbmol.

Refer Table A-21, “Ideal-gas properties of carbon monoxide”, obtain the following properties of CO gas from the table ‘Ideal gas properties of carbon monoxide’ in the text book.

Enthalpy of CO gas at 3580 K, (h¯)CO,3580=27,954Btu/lbmol.

Enthalpy of CO gas at 3620 K, (h¯)CO, 3620=28,300Btu/lbmol.

Enthalpy of CO gas at 298 K, (h¯)CO=3,725.1Btu/lbmol.

Use interpolation to get the Enthalpy of water vapor at 3600 K ((h¯)CO, 3600).

(h¯)CO, 3600(h¯)CO,3580(h¯)CO, 3620(h¯)CO,3580=3600K3580K3620K3580K

Here, Enthalpy of CO gas at 3580 K is (h¯)CO,3580, and Enthalpy of CO gas at 3620 K is (h¯)CO,3620.

Substitute 27,954Btu/lbmol for (h¯)CO,3580, and 28,300Btu/lbmol for (h¯)CO,3620.

(h¯)CO, 360027,954Btu/lbmol28,300Btu/lbmol27,954Btu/lbmol=3600K3580K3620K3580K(h¯)CO, 3600=28,127Btu/lbmol

Refer Table A-26, “Enthalpy of formation, Gibbs function of formation, and absolute entropy at

778F, 1 atm”, select the enthalpy of CO2((h¯f)CO2) as 163,300Btu/lbmol.

Refer Table A-20, ‘Ideal gas properties of carbon dioxide’ find out the following enthalpies at different temperature.

Enthalpy of CO2 gas at 3580 K, (h¯)CO2=43,121Btu/lbmol.

Enthalpy of CO2 gas at 3620 K, (h¯)CO2=43,701Btu/lbmol.

Enthalpy of CO2 gas at 298 K, (h¯)CO2=4,027.5Btu/lbmol.

Similarly, use interpolation and obtain the enthalpy of CO2 gas at 3600 K as 43,411Btu/lbmol.

Refer Table A-26, “Enthalpy of formation, Gibbs function of formation, and absolute entropy at

778F, 1 atm”, select the enthalpy of O2((h¯f)O2) as 0.

Refer Table A-19, ‘Ideal gas properties of oxygen’, choose the enthalpy at the following temperatures.

Enthalpy of O2 gas at 3580 K, (h¯)O2=28,994kJ/kmol.

Enthalpy of O2 gas at 3620 K, (h¯)O2=29,354kJ/kmol.

Enthalpy of O2 gas at 298 K, (h¯)O2=3,725.1Btu/lbmol.

Similarly, use interpolation and obtain the enthalpy of O2 gas at 3600 K as 29,174Btu/lbmol.

Substitute 0 for (h¯)O2, 29,174Btu/lbmol for (h¯)O2, 3,725.1Btu/lbmol for (h¯)O2, 163,300Btu/lbmol for (h¯f)CO2, 43,411Btu/lbmol for (h¯)CO2, 4,027.5Btu/lbmol for (h¯)CO2, 47,540Btu/lbmol for (h¯f)CO, 28,127Btu/lbmol for (h¯)CO, 3,725.1Btu/lbmol for (h¯)CO 0.9966 mol for NCO2, 0.0034 mol for NCO, and 0.1587 mol for NO2 in Equation (VII).

Qout={(0.9966mol)(163,300Btu/lbmol+43,411Btu/lbmol4,027.5Btu/lbmol)+(0.0034mol)(47,540Btu/lbmol+28,127Btu/lbmol3,725.1Btu/lbmol)+(0.1587mol)(0+29,174Btu/lbmol3,725.1Btu/lbmol)1(47,540Btu/lbmol+3,889.5Btu/lbmol3,725.1Btu/lbmol)}=78,139Btu/lbmolofCO

Qout=78,139Btu/lbmolofCO

Substitute 0.932lbm/min for m˙CO, and 28lbm/lbmol for MCO in Equation (VIII).

N˙CO=0.932lbm/min28lbm/lbmol=0.0333lbmol/min

Substitute 0.0333lbmol/min for N˙CO, and 78,139Btu/lbmolofCO for Qout in Equation (IX).

Q˙out=(0.0333lbmol/min)(78,139Btu/lbmolofCO)=2,602Btu/min

Thus, the rate of heat transfer is 2,602Btu/min_.

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Chapter 16 Solutions

EBK THERMODYNAMICS: AN ENGINEERING APPR

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