EBK THERMODYNAMICS: AN ENGINEERING APPR
EBK THERMODYNAMICS: AN ENGINEERING APPR
8th Edition
ISBN: 8220102809444
Author: CENGEL
Publisher: YUZU
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Chapter 15.7, Problem 89P

A steady-flow combustion chamber is supplied with CO gas at 37°C and 110 kPa at a rate of 0.4 m3/min and air at 25°C and 110 kPa at a rate of 1.5 kg/min. Heat is transferred to a medium at 800 K, and the combustion products leave the combustion chamber at 900 K. Assuming the combustion is complete and T0 = 25°C, determine (a) the rate of heat transfer from the combustion chamber and (b) the rate of exergy destruction.

(a)

Expert Solution
Check Mark
To determine

The rate of heat transfer from the combustion chamber.

Answer to Problem 89P

The rate of heat transfer from the combustion chamber is 3567kJ/min_.

Explanation of Solution

Determine the volume of the CO in the combustion chamber.

νCO=RTP (I)

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

Determine the mass flow rate of the CO in the combustion chamber.

m˙CO=ν˙COνCO (II)

Here, the volume flow rate of the CO in the combustion chamber is ν˙CO.

Determine the molar air-fuel ratio.

AF¯=NairNfuel=m˙air/Mairm˙fuel/Mfuel (III)

Here, the mass flow rate of the air is m˙air, the molar mass of the air is Mair, the mass flow rate of the fuel is m˙fuel, the molar mass of the fuel is Mfuel.

Write the energy balance equation using steady-flow equation.

EinEout=ΔEsystem (IV)

Here, the total energy entering the system is Ein, the total energy leaving the system is Eout, and the change in the total energy of the system is ΔEsystem.

Substitute 0 for Ein, Qout for Eout, and ΔU for ΔEsystem in Equation (IV)

(0)Qout=ΔUQout=NP(h¯f°+h¯h°¯)PNR(h¯f°+h¯h°¯)RQout=NPh¯f,P°NRh¯f,R° (V)

Here, the enthalpy of formation for product is h¯f,P°, the enthalpy of formation for reactant is h¯f,R°, the mole number of the product is NP, and the mole number of the reactant is NR.

Determine the heat transfer per kg of CO.

qout=QoutMCO (VI)

Here, the molar mass of the CO is MCO.

Determine the rate of heat transfer.

Q˙out=m˙qout (VII)

Conclusion:

Perform unit conversion of temperature at state 1 from degree Celsius to Kelvin.

For air temperature enter in the combustion chamber,

Tair=25°C=(25+273)K=298K

For CO temperature enter in the combustion chamber,

TCO=37°C=(37+273)K=310K

From the Table A-1 “Molar mass, gas-constant, and critical-point properties”, obtain the value of molar mass for air and carbon monoxide and universal gas constant of CO as:

Mair=29kg/kmolMCO=28kg/kmolRCO=0.2968kJ/kgK

Substitute 0.2968kJ/kgK for RCO, 37°C for T, and 110kPa for P in Equation (I).

νCO=(0.2968kJ/kgK)(37°C)(110kPa)=(0.2968kJ/kgK)×(1kPam31kJ)(37°C+273)(110kPa)=(0.2968kPam3/kgK)(310K)(110kPa)=0.836m3/kg

Substitute 0.4m3/min for ν˙CO and 0.836m3/kg for νCO in Equation (II).

m˙CO=0.4m3/min0.836m3/kg=0.478kg/min

Substitute 1.5kg/min for m˙air, 29kg/kmol for Mair, 0.478kg/min for m˙fuel and 28kg/kmol for Mfuel in Equation (III).

AF¯=(1.5kg/min)/(29kg/kmol)(0.478kg/min)/(28kg/kmol)=3.03kmolair/kmolfuel

Here, the number of mole of oxygen used per mole of carbon monoxide is 3.03/4.76=0.637.

Write the combustion equation of 1 kmol for CO.

{CO+0.637ath(O2+3.76N2)}{CO2+0.137O2+2.40N2} (VIII)

Here, stoichiometric coefficient of air is ath, oxygen is O2, nitrogen is N2, and carbon monoxide is CO.

From the Table-21, 19, 18, and 20, obtain the enthalpy of formation, at 298 K, 310 K, and 900 K for O2, N2, CO, and CO2 is given in a tabular form as:

Substanceh¯f°kJ/kmolh¯298KkJ/kmolh¯310KkJ/kmolh¯900KkJ/kmol
CO-110,53086699014---
O208682---27,928
N208669---26,890
CO2-393,5209364---37,405

Substitute the value of substance in Equation (V).

Qout=[(1)(393,520kJ/kmol+37,405kJ/kmol9364kJ/kmol)+(0.137)(0+27,928kJ/kmol8682kJ/kmol)+(2.4)(0+26,890kJ/kmol8669kJ/kmol)(1)(110,530kJ/kmol+9014kJ/kmol8669kJ/kmol)(0)(0)]=208,929kJ/kmol

Therefore the heat transfer for CO is 208,929kJ/kmol for each kmol.

Substitute 208,929kJ/kmol for Qout and 28kg/kmol for MCO in Equation (VI).

qout=208,929kJ/kmol28kg/kmol=7462kJ/kg

Substitute 7462kJ/kg for qout and 0.478kg/min for m˙ in Equation (VII).

Q˙out=(0.478kg/min)×(7462kJ/kg)=3567kJ/min

Thus, the rate of heat transfer from the combustion chamber is 3567kJ/min_.

(b)

Expert Solution
Check Mark
To determine

The exergy destruction from the combustion chamber.

Answer to Problem 89P

The exergy destruction from the combustion chamber is 1610kJ/min_.

Explanation of Solution

Write the expression for the relation of reversible work using the exergy balance on the combustion chamber.

Wrev=[NR(h¯f°+h¯h¯°T0s¯)RNP(h¯f°+h¯h¯°T0s¯)PQout(1T0/TR)]

In the ideal gas table the value of entropy for 1 atm is equal to 101.325 kPa of pressure. Each reactant of the entropy and the product is to be calculated at the partial pressure of the components which is equal to:

Pi=yiPtotal

Here, the mole fraction of component i is yi, and

Pm=110101.325=1.0856atm.

Write the expression for entropy generation during this process.

Sgen=SPSR+QoutTsurr (VIII)

Write the combustion equation of Equation (VI)

Sgen=SPSR+QoutTsurrSgen=NPs¯PNRs¯R+QoutTsurr (IX)

Here, the entropy of the product is s¯P, the entropy of the reactant is s¯R, the heat transfer for CO is Qout, and the surrounding temperature is Tsurr.

Determine the entropy at the partial pressure of the components.

Si=Nis¯i(T,Pi)=Nis¯i°(T,P0)Ruln(yiPm) (X).

Here, the partial pressure is Pi, the mole fraction of the component is yi, the total pressure of the mixture is Pm, and the universal gas constant is Ru.

Write the expression for rate of exergy destruction during this process.

X˙dest=T0S˙gen=T0m˙(Sgen/M) (XI)

Here, the thermodynamic temperature of the surrounding is T0

Conclusion:

The entropy calculation can be presented in tabular form as:

For reactant entropy,

SubstanceNiyi

s¯i°

(T, 1 atm)

Ruln(yiPm)Nis¯i
CO11.00198.6780.68198.00
O20.6370.21205.04-12.29138.44
N22.4000.79191.61-1.28462.94
SR=799.38kJ/kmolK

For product entropy,

SubstanceNiyi

s¯i°

(T, 1 atm)

Ruln(yiPm)Nis¯i
CO210.2827263.559-9.821273.38
O20.1370.0387239.823-26.35336.47
N22.4000.6785224.467-2.543544.82
SP=854.67kJ/kmolK

Substitute 854.67kJ/kmolK for SP and 799.38kJ/kmolK for SR in Equation (VIII).

Sgen=(854.67799.38)kJ/kmolK+208,929kJ800K=55.29kJ/kmolK+208,929kJ800K=316.5kJ/kmolK

Substitute 25°C for T0, 0.478kg/min for m˙, 28kg/kmol for M, and 316.5kJ/kmolK for Sgen in Equation (XI).

X˙dest=(25°C)(0.478kg/min)(316.5kJ/kmolK/28kg/kmol)=(25°C+273)(0.478kg/min)(316.5kJ/kmolK/28kg/kmol)=1610kJ/min

Thus, the exergy destruction from the combustion chamber is 1610kJ/min_.

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Chapter 15 Solutions

EBK THERMODYNAMICS: AN ENGINEERING APPR

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