ThermoSolutions CHAPTER15

15-1

Chapter 15 CHEMICAL REACTIONS

Fuels and Combustion 15-1C Gasoline is C8H18, diesel fuel is C12H26, and natural gas is CH4. 15-2C Nitrogen, in general, does not react with other chemical species during a combustion process but its presence presence affect affectss the outcome outcome of the process process because because nitrogen nitrogen absorbs a large large proportion proportion of the heat heat released released during the chemical process. 15-3C Moisture, Moisture, in general, general, does not react react chemica chemically lly with any of the species species present present in the combustio combustion n chamber, but it absorbs some of the energy released during combustion, and it raises the dew point temperature of the combustion gases. 15-4C The dew-poin dew-pointt temperature temperature of the product product gases is the temperat temperature ure at which the water water vapor vapor in the product gases starts to condense as the gases are cooled at constant pressure. It is the saturation temperature corresponding to the vapor pressure of the product gases. 15-5C The number of atoms are are preserved preserved during a chemical chemical reaction, but the total mole numbers numbers are not. 15-6C Air-fuel ratio is the ratio of the mass of air to the mass of fuel during a combustion process. Fuelair ratio ratio is the inverse inverse of the air-fue air-fuell ratio. ratio.

Because the the molar molar mass mass of the the fuel and and the molar molar mass mass of the the air, in general, general, are different different.. 15-7C No. Because

Theoretical and Actual Combustion Combustion Processes Processes 15-8C The causes of incomplete combustion are insufficient insufficient time, insufficient oxygen, insufficient insufficient mixing, and dissociation. 15-9C CO. Because oxygen is more strongly attracted to hydrogen than it is to carbon, carbon, and hydrogen hydrogen is usually burned to completion even when there is a deficiency deficiency of oxygen. 15-10C It represent the amount of air that contains the exact amount of oxygen needed for complete combustion. 15-11C No. The theoretical combustion is also complete, complete, but the products of theoretical combustion does not contain any uncombined uncombined oxygen. 15-12C Case (b).

15-2

15-13 Methane Methane is burned burned with with the stoichiom stoichiometric etric amount amount of air during during a combustio combustion n process. process. The The AF and and FA ratios ratios are to be determine determined. d. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, and N2 only. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis This is a theoretica theoreticall combustio combustion n process process since since methane is burned completely with stoichiometric amount of air. The stoichiometric stoichiometric combustion combustion equation of CH4 is

CH 4  a th O 2  3.76N 2     CO 2  2H 2 O  3.76a th N 2 a th  1  1

O2 balance: Substituting,

 

a th  2

CH4 Products Air stoichiometric

CH 4  2O 2  3.76N2     CO 2  2H 2O  7.52N 2

The air-fue air-fuell ratio is determ determined ined by taking taking the ratio of the mass mass of the air air to the mass mass of the fuel, fuel, AF 

mair



mfuel

2  4.76 kmol29 kg/kmol  17.3 1 kmol12 kg/kmol  2 kmol2 kg/kmol

kg air/kg fuel

The fuel-air ratio is the inverse of the air-fuel ratio, ratio, FA 

1 AF



1 17.3 kg air/kg fuel

 0.0578 kg fuel/kg air

15-14 Propane is burned with 75 percent excess air during a combustion combustion process. The AF ratio is to be determined. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, O2, and N2 only.

The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively Properties The (Table A-1). Analysis The combustion equation in this case can be written as

C 3 H 8  1.75a th O 2  3.76N 2     3CO 2  4H 2 O  0.75a th O 2  (1.75  3.76)a th N 2 where ath is the stoi stoichi chiom ometr etric ic coeffi coefficie cient nt for for air. air. We have have automatically accounted for the 75% excess air by using the C3H8 factor 1.75a 1.75ath instead of a of ath for air. The stoichiometric amount of oxygen (a (athO2) will will be used to oxidize oxidize the the fuel, and the the remaining remaining Air excess amount (0.75a (0.75athO2) will appear appear in in the products products as free free oxygen. The coefficient ath is determined determined from the the O2 balance, 75% excess O2 balance:

1.75a th  3  2  0.75ath

Substituting,

C3 H8  8.75 O2  3.76 N2

 

a th  5

 3CO2 4 H2 O 3.75O2 32.9 N2


mair mfuel



8.75  4.76 kmol29 kg/kmol   27.5 kg air/kg fuel 3 kmol12 kg/kmol  4 kmol 2 kg/kmol

Products

15-3

15-15 Acetylene Acetylene is burne burned d with the the stoichiom stoichiometric etric amount amount of air during during a combustion combustion process. process. The AF ratio is to be deter determin mined ed on a mass mass and and on a mole mole basi basis. s. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, and N2 only. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis This This is a theo theore reti tica call comb combus usti tion on proc proces esss sinc sincee C2H2 is burned completely with stoichiometric amount amount of air. The stoichiome stoichiometric tric combustion combustion equation equation of C2H2 is

  2CO 2  H 2 O  3.76a th N 2 C 2 H 2  a th O 2  3.76N 2   O2 balance:

a th  2  0.5

 

C2H2 Products

ath  2.5 100% theoretical air

Substituting,

  2CO 2  H 2 O  9.4N 2 C 2 H 2  2.5O 2  3.76N 2   The air-fue air-fuell ratio is determ determined ined by taking taking the ratio of the mass mass of the air air to the mass mass of the fuel, fuel, AF 

mair mfuel



2.5  4.76 kmol29 kg/kmol  13.3 2 kmol12 kg/kmol  1 kmol2 kg/kmol

kg air/kg fuel

On a mole basis, the air-fuel air-fuel ratio is expressed as the ratio of the mole mole numbers of the air to the mole numbers numbers of the fuel, fuel, AFmole basis 

N air N fuel



(2.5  4.76) kmol 1 kmol fuel

 11.9 kmol air/kmol fuel

15-16 Ethane is burned with an unknown amount amount of air during during a combustion process. The AF ratio and the percentage of theoretical air used are to be determined. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, O2, and N2 only. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis (a) The combu combustion stion equation equation in this this case case can be written written as

C2H6 Products

C 2 H 6  aO 2  3.76N 2     2CO 2  3H 2 O  3O 2  3.76a N 2

  a  6.5 a  2  1.5  3 

O2 balance: Substituting,

air

C 2 H 6  6.5O 2  3.76N 2     2CO 2  3H 2 O  3O 2  24.44N 2


mair mfuel



6.5  4.76 kmol29 kg/kmol  29.9 kg air/kg fuel 2 kmol12 kg/kmol  3 kmol2 kg/kmol

(b) To find find the percent percent theore theoretical tical air air used, used, we need need to know the theoreti theoretical cal amount amount of air, air, which which is determine determined d from the theoretic theoretical al combustio combustion n equation equation of C2H6, C2 H 6  a th O 2  3.76N 2 O2 balance: Then,

a th  2  1.5

  2CO2 3H2 O 3.76ath N2

 

Percent theoretical air 

mair,act mair,th

a th  3.5



N air,act N air,th



a a th



6.5 3.5

 186%

15-4

15-17E Ethylene is burned burned with 200 percent theoretical air during during a combustion process. The AF ratio and the dew-poi dew-point nt temperat temperature ure of the the products products are are to be determine determined. d. Assumptions 1 Combustion is complete. 2 The combustion products contain CO2, H 2O, O2, and N2 only. 3 Combustion Combustion gases gases are ideal gases. gases. The molar olar masse assess of of C, C, H2, and air are 12 12 lbm/lbmol, lbm/lbmol, 2 lbm/lbmol, lbm/lbmol, and and 29 lbm/lbmol, lbm/lbmol, Properties The respective respectively ly (Table (Table A-1E). A-1E). Analysis (a) The combus combustion tion equation equation in this this case case can be written written as C2H4 C2 H 4  2a th O 2  3.76N 2  2CO2 2H2 O ath O2 (2  3.76)ath N2 Products where ath is the stoichiometric stoichiometric coefficient coefficient for air. 200% It is determin determined ed from theoretical air O2 balance: 2a th  2  1  a th   ath  3

C2 H 4  6 O2  3.76 N2

Substituting,

  2 CO2 2 H2 O 3O2 22.56N2

The air-fue air-fuell ratio is determ determined ined by taking the the ratio of the mass mass of the air air to the mass mass of the fuel, fuel, AF 

mair mfuel



6  4.76 lbmol29 lbm/lbmol  29.6 lbm air/lbm fuel 2 lbmol12 lbm/lbmol  2 lbmol2 lbm/lbmol

(b) The dew-point dew-point tempe temperatur raturee of a gas-va gas-vapor por mixtur mixturee is the saturat saturation ion temperat temperature ure of the water water vapor vapor in the product gases corresponding corresponding to its partial pressure. pressure. That That is,

 N v  2 lbmol   P prod    14.5 psia   0.981 psia     29.56 lbmol   N prod  T dp  T sat @ 0.981 psia  101 F

P v

Thus,

15-18 Propylene is burned with 50 percent excess air during a combustion combustion process. The AF ratio ratio and the temperature at which the water vapor in the products will start condensing are to be determined. Assumptions 1 Combustion is complete. 2 The combustion products contain CO2, H 2O, O2, and N2 only. 3 Combustion Combustion gases gases are ideal gases. gases. Properties The molar molar masses masses of C, H2, and air are are 12 kg/kmol, kg/kmol, 2 kg/kmol, kg/kmol, and 29 kg/kmol, kg/kmol, respectively respectively (Table (Table A-1). Analysis (a) The combus combustion tion equation equation in this case case can can be written as

C3H6

Products

50% excess air

C 3 H 6  1.5a th O 2  3.76N 2     3CO 2  3H 2 O  0.5a th O 2  (1.5  3.76)a th N 2 where ath is the stoichiometric stoichiometric coefficient coefficient for air. It is determined determined from from O2 balance:

1.5a th  3  1.5  0.5a th

Substituting, C3 H 6  6.75 O2  3.76 N 2

 

ath  4.5

  3CO2 3H2 O 2.25O2 25.38N2


mair mfuel




kg air/kg fuel


 N v   3 kmol   P 105 kPa   9.367 kPa   prod  N prod  33.63 kmol     T dp  T sat @9.367 kPa  44.5C

P v   Thus,

15-5

15-19 Propal Propal alcohol alcohol C3H7OH C3H7OH is burned burned with 50 percent percent excess excess air. air. The balanced balanced reaction reaction equatio equation n for complete complete combustion combustion is to to be written written and the air-to-f air-to-fuel uel ratio is to be determined determined.. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, O2, and N2 only. Properties The The mola molarr mass masses es of C, H2, O2 and air are 12 kg/kmol, kg/kmol, 2 kg/kmol, 32 kg/kmol, and 29 kg/kmol, respective respectively ly (Table (Table A-1). A-1). Analysis The combustion equation in this case can be written as

  B CO 2  D H 2 O  E O 2  F N 2 C 3 H 7 OH  1.5a th O 2  3.76N 2   where ath is the stoichiometric coefficient for air. We have automatically accounted for the 50% excess air by usin using g the factor factor 1.5 1.5ath instead of ath for air. The coefficient ath and other other coeff coefficien icients ts are are to be determined from the mass mass balances Carbon balance:

B=3

Hydrogen balance:

  D  4 2 D  8 

C3H7OH Products Air

1  2  1.5a th  2 B  D  2 E

Oxygen balance:

0.5a th  E

50% eccess

1.5a th  3.76  F

Nitrogen balance:

Solving the above equations, we find the coefficients E ( E = 2.25, F = 25.38, and ath = 4.5) and write the balanced balanced reaction reaction equation equation as C 3 H 7 OH  6.75O 2  3.76N 2    3 CO 2  4 H 2 O  2.25 O 2  25.38 N 2 The air-fue air-fuell ratio is determ determined ined by taking taking the ratio of the mass mass of the air air to the mass mass of the fuel, fuel, AF 

mair mfuel



(6.75  4.75 kmol)(29 kg/kmol) (3  12  8  1  1 16) kg

 15.51 kg air/kg fuel

15-6

15-20 Buta Butane ne C4H10 is burned with 200 percent theoretical air. The kmol of water that needs needs to be sprayed into the combustio combustion n chamber chamber per kmol kmol of fuel is to be determine determined. d. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, O2, and N2 only. Properties The The mola molarr mass masses es of C, H2, O2 and air are 12 kg/kmol, kg/kmol, 2 kg/kmol, 32 kg/kmol, and 29 kg/kmol, respective respectively ly (Table (Table A-1). A-1). Analysis The reaction reaction equation equation for 200% theoret theoretical ical air air without without the additio additional nal water is is

  B CO 2  D H 2 O  E O 2  F N 2 C 4 H 10  2a th O 2  3.76N 2   where ath is the stoichiometric stoichiometric coefficient for air. We have automatically accounted for the 100% excess air by using the factor 2a 2ath instead of a of ath for air. The coefficient ath and other other coefficient coefficientss are to be determ determined ined from the the mass balances balances Carbon balance:

B=4

Hydrogen balance:

  D  5 2 D  10 

Oxygen balance:

2  2a th  2 B  D  2 E

C4H10 Products Air 200% theoretical

a th  E 2a th  3.76  F

Nitrogen balance:

Solving the above equations, we find the coefficients E (E = 6.5, F = 48.88, and ath = 6.5) and write the balanced balanced reaction reaction equation equation as C 4 H 10  13O 2  3.76N 2     4 CO 2  5 H 2 O  6.5 O 2  48.88 N 2 With the additional water sprayed sprayed into the combustion combustion chamber, the balanced reaction equation is

  4 CO 2  (5  N v ) H 2 O  6.5 O 2  48.88 N 2 C 4 H 10  13O 2  3.76N 2   N v H 2 O  The partial partial pressure pressure of water water in the saturated saturated product product mixture mixture at the dew point is P v , prod  P sat@60C  19.95 kPa The vapor mole mole fraction fraction is y v 

P v , prod P prod



19.95 kPa 100 kPa

 0.1995

The amount of water that needs to be sprayed into the combustion combustion chamber can be determined from from y v 

N water N total, product

   0.1995 

5  N v 4  5  N v  6.5  48.88

   N v  9.796 kmol

15-7

15-21 A fuel mixtur mixturee of 20% by by mass mass methane, methane, CH4, and 80% by mass ethanol, C2H6O, is burned completely with theoretical air. The The required flow rate rate of air is to be determined. determined. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, and N2 only. Properties The The mola molarr mass masses es of C, H2, O2 and air are 12 kg/kmol, kg/kmol, 2 kg/kmol, 32 kg/kmol, and 29 kg/kmol, respective respectively ly (Table (Table A-1). A-1). Analysis The combustion equation in this case can be written as

  B CO 2  D H 2 O  F N 2 x CH 4  y C 2 H 6 O  a th O 2  3.76N 2   where ath is the stoichiometric coefficient for air. The coefficient ath and other other coeff coefficient icientss are to be determined from the mass mass balances Carbon balance:

x  2 y  B

Hydrogen balance:

4 x  6 y  2 D

Oxygen balance:

2ath  y  2 B  D

Nitrogen Nitrogen balance: balance:

3.76a th  F

20% CH4 80% C2H6O Products

Air 100% theoretical

Solving Solving the above equations, equations, we find the coefficie coefficients nts as x  0.4182

B  1.582

y  0.5818

D  2.582

ath  2.582

F  9.708

Then, we write write the balanced balanced reaction reaction equation equation as 0.4182 CH 4  0.5818 C 2 H 6O  2.582 O 2  3.76N 2     1.582 CO 2  2.582 H 2O  9.708 N 2

The air-fue air-fuell ratio is determ determined ined by taking the the ratio of the mass mass of the air air to the mass mass of the fuel, fuel, AF 



mair mfuel (2.582  4.76 kmol)(29 kg/kmol) (0.4182 kmol)(12  4  1) kg/kmol  (0.5818 kmol)( 2  12  6  1  16)kg/kmol

Then, the the required required flow rate of air becomes becomes  air  AFm  fuel  (10.64)(31 kg/s)  330 kg/s m


15-8

15-22 Octane is is burned burned with 250 percent percent theoretical theoretical air air during during a combustio combustion n process. process. The The AF ratio ratio and the dew-pint dew-pint temperat temperature ure of the products products are to be determine determined. d. Assumptions 1 Combustion is complete. 2 The combustion products contain CO2, H 2O, O2, and N2 only. 3 Combustion Combustion gases gases are ideal gases. gases. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis (a) The combu combustion stion equation equation in this this case case can be written written as

C8 H18  2.5a th O 2  3.76N 2

 8CO2 9H2 O 1.5ath O2 (2.5 3.76)ath N2

where ath is the stoichiometric stoichiometric coefficient coefficient for air. It is determin determined ed from O2 balance:

C8H18

2.5a th  8  4.5  1.5a th    a th  12.5

Air

Substituting, C 8 H 18  31.25O 2  3.76N 2   8CO 2  9H 2 O  18.75O 2  117.5N 2 Thus,

AF 

mair mfuel



25C


Combustion chamber P = 1 atm

Products

kg air/kg fuel


 N v   9 kmol   P P v   prod    153.25 kmol 101.325 kPa   5.951 kPa  N prod      Thus,

T dp  T sat @5.951 kPa  36.0C

15-23 Gasoline Gasoline is burned burned steadil steadily y with air in a jet jet engine. engine. The AF ratio ratio is given. given. The percentage percentage of excess excess air used is to be determine determined. d. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, and N2 only. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis The theoretical combustion equation in this case can be written as

C8 H18  a th O 2  3.76N 2

Gasoline

  8CO2 9H2 O 3.76ath N2

where ath is the stoichiometric stoichiometric coefficient coefficient for air. It is determined determined from from O2 balance:

a th  8  4.5

 

a th  12.5

(C8H18)

Jet engine

Products

Air

The air-fuel ratio for the theoretical reaction is determined determined by taking the ratio of the mass of the air to the mass of the fuel for, AFth 

m air,th m fuel



12.5  4.76 kmol29 kg/kmol  15.14 kg air /kg fuel 8 kmol12 kg/kmol  9 kmol2 kg/kmol

Then the percent theoretical theoretical air air used can be determined from Percent theoretical air 

AFact AFth



18 kg air/kg fuel 15.14 kg air/kg fuel

 119%

15-9

15-24 Ethane is burned with air steadily. The mass flow rates rates of ethane and air are given. The The percentage of excess excess air used is to be determined determined.. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, and N2 only. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis The theoretical theoretical combustion combustion equation in this case can be written as

C2 H 6  a th O 2  3.76N 2

  2CO2 3H2 O 3.76ath N2

C2H6

where ath is the stoichiometric stoichiometric coefficient coefficient for air. It is determined determined from from O2 balance:

a th  2  1.5

 

a th  3.5

The air-fue air-fuell ratio for for the theoretic theoretical al reaction reaction is determine determined d by taking the the ratio of of the mass mass of the air to to the mass mass of the the fuel for, AFth 

m air,th m fuel



 air m  fuel m



Air

3.5  4.76 kmol29 kg/kmol  16.1 kg air /kg fuel 2 kmol12 kg/kmol  3 kmol2 kg/kmol

The actual actual air-fuel air-fuel ratio ratio used used is is AFact 

Combustion chamber

176 kg/h 8 kg/h

 22 kgair /kgfuel


AFact AFth




Thus the exces excesss air used during this this process process is 37%.

 137%

Products

15-10

15-25 Butane is burned with air. The masses masses of butane and air are given. The percentage percentage of theoretical theoretical air used and the dew-point dew-point temperat temperature ure of the products products are to be determine determined. d.

combust ustion ion produc products ts contai contain n CO2, H2O, an and N2 only. 3 Assumptions 1 Combustion is complete. 2 The comb Combustion Combustion gases gases are ideal gases. gases. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis (a) The theoretical combustion equation in this case can be written as

C4 H10  a th O 2  3.76N 2

  4CO2 5H2 O 3.76ath N2

where ath is the stoichiometric coefficient for air. It is determined from a th  4  2.5

O2 balance:

 

C4H10 Combustion chamber

ath  6.5

The air-fuel ratio for the theoretical reaction is determined by taking the the ratio of of the mass mass of the air to to the mass mass of the the fuel for, AFth 

m air,th m fuel



Products

Air

6.5  4.76 kmol29 kg/kmol  15.5 kg air /kg fuel 4 kmol12 kg/kmol  5 kmol 2 kg/kmol


mair mfuel



25kg 1 kg

 25 kg air / kg fuel


AFact AFth




 161%

(b) The The combusti combustion on is complete, complete, and thus thus products products will contain contain only CO CO2, H2O, O2 and N2. The air-fuel ratio for for this combustion combustion process process on a mole basis basis is AF 

N air N fuel



m air / M air m fuel / M fuel



25 kg / 29 kg/kmol  50 kmol air /kmol fuel 1 kg / 58 kg/kmol

Thus the combusti combustion on equation equation in this case can be written written as C 4 H10  50/4.76O 2  3.76N 2     4CO 2  5H 2 O  4.0O 2  39.5N 2 The dew-point dew-point temperat temperature ure of a gas-vapor gas-vapor mixture mixture is the saturation saturation temperat temperature ure of the water vapor vapor in the product product gases correspon corresponding ding to its partial partial pressur pressure. e. That is, is,

 N v  5 kmol   P prod    90 kPa   8.571 kPa  N prod  52.5 kmol    

P v   Thus,

T dp  T sat @8.571

kPa

 42.8C

15-11

15-26E Butane is burned with air. The masses of butane and air are given. The percentage of theoretical air used and the dew-point dew-point temperat temperature ure of the products products are to be determine determined. d.

combust ustion ion produc products ts contai contain n CO2, H2O, an and N2 only. 3 Assumptions 1 Combustion is complete. 2 The comb Combustion Combustion gases gases are ideal gases. gases. Properties The The molar olar mass masses es of C, H2, and air are 12 12 lbm/lbmol, lbm/lbmol, 2 lbm/lbmol, lbm/lbmol, and and 29 lbm/lbmol, lbm/lbmol, respective respectively ly (Table (Table A-1). A-1). Analysis (a) The theoretical combustion equation in this case can be written as

C 4 H 10  ath O 2  3.76N 2

   4CO2 5H 2 O 3.76ath N2

where ath is the stoichiometric coefficient for air. It is determined from a th  4  2.5

O2 balance:

 


ath  6.5

The air-fue air-fuell ratio for for the theoretic theoretical al reaction reaction is determine determined d by taking the the ratio of of the mass mass of the air to to the mass mass of the the fuel for, AFth 

m air,th mfuel



Products

Air

6.5  4.76 lbmol29 lbm/lbmol  15.5 lbm air /lbm fuel 4 lbmol12 lbm/lbmol  5 lbmol2 lbm/lbmol


m air mfuel



25 lbm 1 lbm

 25 lbm air /lbm fuel


AFact AFth



25 lbm air/lbm fuel 15.5 lbm air/lbm fuel

 161%

(b) The combusti combustion on is complete, complete, and and thus products products will will contain contain only CO2, H2O, O2 and N2. The air-fuel ratio for for this combustion combustion process process on a mole basis basis is AF 

N air N fuel



m air / M air m fuel / M fuel



25 lbm/ 29 lbm/lbmol  50 lbmol air /lbmol fuel 1 lbm/ 58 lbm/lbmol

Thus the combusti combustion on equation equation in this case can be written written as

  4CO 2  5H 2 O  4O 2  39.5N 2 C 4 H 10  50/4.76O 2  3.76N 2   The dew-point dew-point temperat temperature ure of a gas-vapor gas-vapor mixture mixture is the saturation saturation temperat temperature ure of the water vapor vapor in the product product gases correspon corresponding ding to its partial partial pressur pressure. e. That is, is,

 N v  5 lbmol   P prod    14.7 psia   1.4 psia  N prod  52.5 lbmol    

P v   Thus,

T dp  T sat @1.4 psia  113.2F

15-12

15-27 The volumetric fractions fractions of the constituents of a certain natural gas are given. The AF ratio ratio is to be determine determined d if this gas is burned burned with the stoichiom stoichiometric etric amount amount of dry air. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, and N2 only. Properties The molar molar masses masses of C, H2, N2, O2, and air are 12 kg/kmol, 2 kg/kmol, 28 kg/kmol, 32 kg/kmol, and 29 kg/kmol, kg/kmol, respective respectively ly (Table (Table A-1). Analysis Considering 1 kmol of fuel, the combustion combustion equation can can be written as

(0.65CH 4  0.08H 2  0.18N 2  0.03O 2  0.06CO 2 )  a th (O 2  3.76N 2 )    xCO 2  yH 2 O  z N 2 The unknown coefficients in the above equation equation are determined from mass balances, balances, C : 0.65  0.06  x

   x  0.71

H : 0.65  4  0.08  2  2 y

Natural gas

   y  1.38

Combustion chamber

  a th  1.31 O 2 : 0.03  0.06  a th  x  y / 2  N 2 : 0.18  3.76a th  z

   z  5.106

Products

Dry air

Thus, (0.65CH 4  0.08H 2  0.18N 2  0.03O2  0.06CO2 )  1. 31( O2  3. 76N 2 )

   0.71CO 2

1 .38H 2 O

5.106N 2 

The air-fuel ratio for the this reaction is determined by taking the ratio of the mass of the air to the mass of the fuel, mair  1.31 4.76 kmol 29 kg/kmol  180.8 kg mfuel  0.65  16  0.08  2  0.18  28  0.03  32  0.06  44kg  19.2 kg and AFth 

m air,th mfuel



180.8 kg 19.2 kg


15-13

15-28 The compos composition ition of a certain certain natural natural gas gas is given. given. The gas is burned burned with stoichio stoichiometr metric ic amount amount of moist moist air. air. The AF ratio is to to be determ determined. ined. Assumptions 1 Combustion is complete. 2 The combustion combustion products contain contain CO2, H2O, and N2 only. Properties The molar molar masses masses of C, H2, N2, O2, and air are 12 kg/kmol, 2 kg/kmol, 28 kg/kmol, 32 kg/kmol, and 29 kg/kmol, kg/kmol, respective respectively ly (Table (Table A-1). Analysis The fuel is burned completely with the stoichiometric amount of air, and thus the products will contai contain n only only H2O, CO2 and N2, but no free O2. The moisture in the air does not react react with anything; it simply shows up as additional H2O in the products. products. Therefore, we can simply simply balance the combustion combustion equation equation using dry air, air, and then then add the moistur moisturee to both sides sides of the the equation. equation. Consideri Considering ng 1 kmol kmol of fuel, the combustion equation can be written as as

(0.65CH 4  0.08H2  0.18N2  0.03O2  0.06CO2 ) a th (O2  3.76N2 )   x CO2  y H2 O z N2 The unknown coefficients in the above equation equation are determined from mass balances, balances, C : 0.65  0.06  x

   x  0.71

H : 0.65  4  0.08  2  2 y

Natural gas

   y  1.38

Combustion chamber

O 2 : 0.03  0.06  a th  x  y / 2    a th  1.31 N 2 : 0.18  3.76a th  z

   z  5.106

Products

Moist air

Thus, (0.65CH 4  0.08 H 2  0.18 N 2  0.03O 2  0.06CO 2 )  1.31( O 2  3.76 N 2 )

   0.71CO 2

 1.38 H 2 O  5.106 N 2

Next we determine determine the the amount amount of moistur moisturee that accomp accompanies anies 4.76 4.76a ath = (4.76)(1.31) = 6.24 kmol of dry air. The partial pressure pressure of the moisture in the air is

P v,in   air P sat@25C  (0.85)(3.1698 kPa)  2.694 kPa Assuming Assuming ideal gas behavio behavior, r, the number number of moles moles of the moisture moisture in the air (Nv, in) is determined to be

 P v,in   2.694 kPa       N v,air  0.17 kmol  P  N total   101.325 kPa 6.24  N v,in      total 

N v ,in  

The balanced balanced combusti combustion on equation equation is obtained obtained by substituting substituting the coefficient coefficientss determined determined earlier earlier and adding adding 0.17 kmol of of H2O to both sides of the the equation equation,, (0.65CH 4  0.08 H 2  0.18 N 2  0.03O 2  0.06CO 2 )  1.31( O 2  3.76 N 2 )  0.17 H 2 O

   0.71CO 2

1.55H 2 O 5  .106N 2

The air-fuel ratio for the this reaction is determined by taking the ratio of the mass of the air to the mass of the fuel, m air  1.31 4.76 kmol 29 kg/kmol   0.17 kmol  18 kg/kmol   183.9 kg m fuel  0.65  16  0.08  2  0.18  28  0.03  32  0.06  44 kg  19.2 kg

and AFth 

m air, th m fuel



183.9 kg 19.2kg


15-14

15-29 The composition of a gaseous fuel is given. It is burned with 130 percent theoretical air. The AF ratio and the fraction fraction of water vapor vapor that would would condense condense if the product product gases were were cooled are to be determine determined. d. Assumptions 1 Combustion is complete. 2 The combustion products contain contain CO2, H2O, O2, and N2 only.

molar masse massess of C, C, H2, N2, and air are 12 kg/kmol, kg/kmol, 2 kg/kmol, kg/kmol, 28 kg/kmol, kg/kmol, and 29 kg/kmol, kg/kmol, Properties The molar respectivel respectively y (Table (Table A-1). Analysis (a) The fuel is burned burned completely with excess air, air, and thus the products will contain H2O, CO2, N2, and some free O 2. Considering Considering 1 kmol of fuel, fuel, the combustion combustion equation equation can can be written written as

 x CO2 y H2 O 0.3ath O2 z N2 (0.60CH 4  0.30H2  0.10N2 )  1.3a th (O2  3.76N2 )  The unknown coefficients coefficients in the above equation are determined determined from mass balances, C : 0.60  x

   x  0.60

H : 0.60  4  0.30  2  2 y

   y  1.50

O 2 : 1.3a th  x  y / 2  0.3a th N 2 : 0.10  3.76  1.3a th  z

   a th  1.35    z  6.70

Gaseous fuel Air

Combustion chamber

Products

30% excess

Thus,

 0.6CO2 1.5H2 O 0.405O2 6.7N2 (0.60CH 4  0.30H2  0.10N2 )  1.755(O2  3.76N2 )  The air-fuel ratio for the this reaction is determined by taking the ratio of the mass of the air to the mass of the fuel, m air  1.755  4.76 kmol 29 kg/kmol   242.3 kg m fuel  0.6  16  0.3  2  0.1 28kg  13.0 kg

and AF 

mair mfuel



242.3 kg 13.0 kg


(b) For each kmol kmol of fuel burned, burned, 0.6 + 1.5 + 0.405 + 6.7 = 9.205 kmol kmol of products are formed, formed, including 1.5 1.5 kmo kmoll of H2O. Assuming Assuming that that the the dew-poin dew-pointt tempera temperature ture of the the products products is is above above 20C, some of the water vapor vapor will will condense condense as the products products are are cooled cooled to 20C. If N If N w kmol of H2O condenses, there will be 1.5 - N w kmol of water vapor left in the products. products. The mole number number of the products products in in the gas phase will also decrease to 9.205 - N - N w as a result. result. Treating the product product gases (including the remaining water vapor) as ideal gases, N w is determined by equating the mole mole fraction of the water vapor to to its pressure fraction, fraction, N v N prod,gas



P v P prod

  

1.5  N w 9.205  N w



2.3392 kPa 101.325 kPa

   N w  1.32 kmol

since P v = P sat sat @ 20C = 2.3392 kPa. Thus the fraction of water vapor that condenses is 1.32/1.5 = 0.88 or 88%.

15-15

15-30 EES Problem Problem 15-29 15-29 is reconsi reconsidered dered.. The effects effects of varying varying the percent percentages ages of CH4, H2 and N2 making making up the fuel and and the product product gas temperat temperature ure are are to be studied. studied. Analysis The problem is solved solved using EES, and the solution is given given below.

Let's modify this problem to include the fuels butane, ethane, methane, and propane in pull down menu. Adiabatic Combustion of fuel CnHm entering at T_fuel with Stoichiometric Air at T_air: Reaction: aCxHy+bH2+cN2 + (a*y/4 + a*x+b/2) (Theo_air/100) (O2 + 3.76 N2) <--> a*xCO2 + ((a*y/2 ((a*y/2)+b) )+b) H2O + (c+3.76 (a*y/4 + a*x+b/2 a*x+b/2)) (Theo_ (Theo_air/100 air/100)) )) N2 + (a*y/4 + a*x+b/2) (Theo_air/100 - 1) O2 T_prod is the product gas temperature. Theo_air is the % theoretical air. " Procedure H20Cond(P_prod,T_prod,Moles_H2O,M_other:T_DewPoint,Moles_H2O_vap,Moles_H2O_liq,Re sult$) P_v = Moles_H2O/(M_other+Moles_H2O)*P_prod T_DewPoint = temperature(steam,P=P_v,x=0) IF T_DewPoint T_DewPoint <= T_prod T_prod then Moles_H2O_vap = Moles_H2O Moles_H2O_liq=0 Result$='No condensation occurred' ELSE Pv_new=pressure(steam,T=T_prod,x=0) Moles_H2O_vap=Pv_new/P_prod*M_other/(1-Pv_new/P_prod) Moles_H2O_liq = Moles_H2O - Moles_H2O_vap Result$='There is condensation' ENDIF END "Input data from the diagram window" {P_prod = 101.325 [kPa] Theo_air = 130 "[%]" a=0.6 b=0.3 c=0.1 T_prod = 20 [C]} Fuel$='CH4' x=1 y=4 "Composition of Product gases:" A_th = a*y/4 +a* x+b/2 AF_ratio = 4.76*A_th*Theo_air/100*molarmass(Air)/(a*16+b*2+c*28) "[kg_air/kg_fuel]" Moles_O2=(a*y/4 +a* x+b/2) *(Theo_air/100 - 1) Moles_N2=c+(3.76*(a*y/4 + a*x+b/2))* (Theo_air/100) Moles_CO2=a*x Moles_H2O=a*y/2+b M_other=Moles_O2+Moles_N2+Moles_CO2 Call H20Cond(P_prod,T_prod,Moles_H2O,M_other:T_DewPoint,Moles_H2O_vap,Moles_H2O_liq,Re sult$) Frac_cond = Moles_H2O_liq/Moles_H2O*Convert(, %) "[%]" "Reaction: "React ion: aCxHy+ aCxHy+bH2+cN2 bH2+cN2 + A_th Theo_ai Theo_air/100 r/100 (O2 + 3.76 N2) <--> a*xCO2 + (a*y/2+ (a*y/2+b) b) H2O + (c+3.7 (c+3.76 6 A_th Theo_ai Theo_air/100) r/100) N2 + A_th (Theo_a (Theo_air/100 ir/100 - 1) O2"

15-16

AFratio [kgair/ kgfuel] 18.61 18.61 18.61 18.61 18.61 18.61 18.61 18.61 18.61 18.61 18.61 18.61 18.61

Fraccond [%] 95.54 91.21 83.42 69.8 59.65 46.31 28.75 17.94 5.463 0.5077 0.1679 0 0

MolesH2O,liq

MolesH2O,vap

1.433 1.368 1.251 1.047 0.8947 0.6947 0.4312 0.2691 0.08195 0.007615 0.002518 0 0

0.06692 0.1319 0.2487 0.453 0.6053 0.8053 1.069 1.231 1.418 1.492 1.497 1 .5 1 .5

Tprod [C] 5 15 25 35 40 45 50 52.5 55 55.9 55.96 60 85

1.6 1.4

O 2 H

1.2

Vapor

1

Liquid

0.8 0.6 0.4

Dew Point = 55.96 C

0.2 0 0

10

20

30

40

50

Tprod [C]

60

70

80

90

15-17

15-31 The composition of a certain coal is given. The coal is burned burned with 50 percent excess air. The AF ratio is to be determined.

Combustion n is compl complete. ete. 2 The combustio combustion n products products contain contain CO2, H2O, O2, N2, and ash Assumptions 1 Combustio only. Properties The molar molar masse massess of C, C, H2, O2, and air are 12 kg/kmol, kg/kmol, 2 kg/kmol, kg/kmol, 32 kg/kmol, kg/kmol, and 29 kg/kmol, kg/kmol, respectivel respectively y (Table (Table A-1).

compos positi ition on of the coal coal is is given given on a mass mass basis, basis, but we we need need to know know the comp composi ositio tion n on a Analysis The com mole basis basis to balance balance the combustio combustion n equation. equation. Consideri Considering ng 1 kg of coal, the numbers numbers of mole mole of the each component are determined to be N C  m / M C  0.82 / 12  0.0683 kmol N H 2O  m / M H 2O  0.05 / 18  0.0028 kmol N H 2  m / M H 2  0.02 / 2  0.01 kmol N O 2  m / M O 2  0.01 / 32  0.00031 kmol

Coal Air

Combustion chamber

Products

50% excess

Considering 1 kg of coal, the combustion equation can be written as as (0.0683C  0.0028H2 O  0.01H2  0.00031O2  ash) 1.5ath (O2  3.76N2 )



x O2  H y 2 O 0.5 tah O2 1.5 3.76 a C th N2  ash

The unknown coefficients coefficients in the above equation are determined determined from mass balances,

  x  0.0683 C : 0.0683  x  H : 0.0028  2  0.01 2  2 y

   y  0.0128

  a th  0.073 O 2 : 0.0028 / 2  0.00031  1.5a th  x  y / 2  0.5a th  Thus, (0.0683C  0.0028H 2O  0.01H 2  0.00031O 2  ash)  0.1095(O 2  3.76N 2 )

   0.0683CO 2  0.0128H 2O  0.0365O 2  0.4117N 2  ash The air-fuel ratio for the this reaction is determined by taking the ratio of the mass of the air to the mass of the coal, coal, which which is taken taken to be 1 kg, mair  0.1095  4.76 kmol29 kg/kmol  15.1 kg mfuel  1 kg and AF 

mair mfuel



15.1 kg 1 kg


15-18

15-32 Octane Octane is burned with dry dry air. The volumetric volumetric fractio fractions ns of the products products are given. given. The AF ratio and the percentage of theoretical theoretical air used are to be determined.

Combustion is comple complete. te. 2 The combustio combustion n products products contain contain CO2, CO, H2O, O2, and N2 Assumptions 1 Combustion only. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis Consideri Considering ng 100 kmol kmol of dry dry products products,, the combustion combustion equation equation can can be written written as as

C8 H1x8 

O 2 a3.76N 2

 9.21CO 2 0.61CO 7.06O 2 83.12N 2  H 2O b

The unknown coefficients x, a, and b are determined from from mass mass balances, N 2 : 3.76a  83.12 C:

   a  22.11

8 x  9.21  0.61

H : 18 x  2b

C8H18

   x  1.23

Combustion chamber

   b  11.07

(Check O 2 : a  9.21  0.305  7.06  b / 2    22.11  22.10)

Products

Dry air

Thus, 1.23C 8 H 18  22.11O 2  3.76N 2     9.21CO 2  0.61CO  7.06O 2  83.12N 2  11.05H 2 O

The combustion combustion equation equation for 1 kmol of fuel fuel is obtained obtained by dividing dividing the the above above equation equation by 1.23, 1.23, C 8 H 18  18.0O 2  3.76N 2     7.50CO 2  0.50CO  5.74O 2  67.58N 2  9H 2 O

(a) The air-fuel ratio is determined determined by taking the ratio of the mass mass of the air to the mass mass of the fuel, AF 

mair mfuel



18.0  4.76 kmol29 kg/kmol  21.8 kg air/kg fuel 8 kmol12 kg/kmol  9 kmol 2 kg/kmol

(b) To find find the percent percent theoreti theoretical cal air air used, used, we need need to know the theoreti theoretical cal amount amount of air, air, which which is determine determined d from the theoretica theoreticall combustion combustion equation equation of the fuel, C8 H18  a th O 2  3.76N 2 O 2:

  8CO 2 9H 2O 3.76 a th N 2

a th  8  4.5   a th  12.5

Then, Percent theoretical air 

mair,act m air,th



N air,act N air,th



18.04.76 kmol  144% 12.54.76 kmol

15-19

15-33 Carbon Carbon is burned burned with dry air. air. The volumetric volumetric analys analysis is of the products products is given. given. The AF ratio ratio and the percentage of theoretical air used are to be determined. Assumptions 1 Combustion is complete. 2 The combustion products contain contain CO2, CO, CO, O2, and N2 only.

The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively Properties The (Table A-1). Considering ng 100 kmol kmol of dry dry products products,, the combustion combustion equation equation can can be written written as as Analysis Consideri xC  a O 2  3.76N 2

   10.06CO 2 0.42 CO 10.69 O 2 78.83N 2

The unknown coefficients x and a are determined from mass balances, N 2 : 3.76a  78.83 C : x  10.06  0.42

   a  20.965

Carbon

   x  10.48

Combustion chamber

(Check O 2 : a  10.06  0.21  10.69    20.96  20.96)

Products

Dry air

Thus, 10.48C  20.96 O 2  3.76 N 2

   10.06CO 2 0.42 CO 10.69 O 2 78.83 N 2

The combustion combustion equation equation for 1 kmol of fuel fuel is obtained obtained by dividing dividing the the above above equation equation by 10.48, 10.48, C  2.0 O 2  3.76 N 2

  0.96CO 2 0.04 CO 1.02 O 2 7.52 N 2

(a) The air-fuel ratio is determined determined by taking the ratio of the mass mass of the air to the mass mass of the fuel, AF 

m air m fuel



2.0  4.76 kmol29 kg/kmol  23.0 1 kmol12 kg/kmol

kg air/kg fuel

(b) To find find the the percen percentt theore theoretic tical al air air used, used, we need need to to know know the theo theoret retica icall amoun amountt of air, air, which which is determine determined d from the theoretica theoreticall combustion combustion equation equation of the fuel, C  1 O 2  3.76N 2

  CO 2  3.76N 2


m air,act m air,th



N air,act N air,th



2.04.76 kmol  200% 1.04.76 kmol

15-20

15-34 Methane is burned burned with dry air. The volumetric analysis analysis of the products products is given. The AF ratio and the percentage of theoretical theoretical air used are to be determined.

Combustion is comple complete. te. 2 The combustio combustion n products products contain contain CO2, CO, H2O, O2, and N2 Assumptions 1 Combustion only. Properties The The mola molarr mass masses es of of C, H2, and air are 12 kg/kmol, 2 kg/kmol, and 29 kg/kmol, respectively (Table A-1). Analysis Consideri Considering ng 100 kmol kmol of dry dry products products,, the combustion combustion equation equation can can be written written as as

CH 4 x

O 2 a 3.76N 2

  5.20CO 2 0.33CO 11.24 O 2 83.23N 2  H 2O b

The unknown coefficients x, a, and b are determined from from mass mass balances, N 2 : 3.76a  83.23 C : x  5.20  0.33 H : 4 x  2b

   a  22.14 CH4

   x  5.53

Combustion chamber

   b  11.06

(Check O 2 : a  5.20  0.165  11.24  b / 2    22.14  22.14)

Products

Dry air

Thus, 5.53CH 4  22.14 O 2  3.76 N 2

  5.20CO 2 0.33CO 11.24 O 2 83.23N 2 11.06 H 2O

The combustion combustion equation equation for 1 kmol of fuel fuel is obtained obtained by dividing dividing the the above above equation equation by 5.53, 5.53, CH 4  4.0 O2  3.76N 2

 0.94CO 2 0.06CO 2.03O 2 15.05N 2 2H 2O

(a) The air-fuel ratio is determined from its definition, AF 

m air m fuel



4.0  4.76 kmol29 kg/kmol  34.5 1 kmol 12 kg/kmol  2 kmol 2 kg/kmol

kg air/kg fuel

(b) To find find the percent percent theoreti theoretical cal air air used, used, we need need to know the theoreti theoretical cal amount amount of air, air, which which is determine determined d from the theoretica theoreticall combustion combustion equation equation of the fuel, CH 4  a th O 2  3.76N 2 O 2:

  CO 2 2H 2O 3.76 a th N 2

a th  1  1   a th  2.0


m air,act m air,th



N air,act N air,th



4.04.76 kmol  200% 2.04.76 kmol

15-21

Enthalpy of Formation Formation and Enthalpy Enthalpy of Combustion 15-35C For combustion processes the enthalpy of reaction is referred referred to as the enthalpy of combustion, combustion, which represents represents the amount of heat heat released released during a steady-flow combustion process. 15-36C Enthalpy Enthalpy of formation formation is the the enthalp enthalpy y of a substan substance ce due to its its chemical chemical compositio composition. n. The enthalpy of formation is related to elements elements or compounds compounds whereas the enthalpy enthalpy of combustion is related to a particula particularr fuel. 15-37C The heating heating value is called called the the higher higher heating heating value when the the H2O in the products is in the liquid form, and it is called the lower heating value when the H2O in the products is in the vapor vapor form. form. The heating value of a fuel is equal to the absolute absolute value of the the enthalpy of combustion of that fuel. 15-38C If the combus combustion tion of a fuel results results in a single single compound, compound, the the enthalpy enthalpy of formati formation on of that compound compound is identical identical to the enthalpy of combustion combustion of that fuel. 15-39C Yes. 15-40C No. The enthal enthalpy py of formation formation of N2 is simply assigned a value of zero at the standard reference state for convenience. 15-41C 1 kmol kmol of of H2. This is evident evident from the observation that when chemical chemical bonds of H2 are destroyed to form H2O a large amount of energy is released.

enthalpy of combusti combustion on of methane methane at a 25 25C and 1 atm is to be determined using the data from from 15-42 The enthalpy Table A-26 and to be compared compared to the value value listed listed in Table A-27. Assumptions The water in the products products is in the liquid liquid phase. phase. Analysis The stoichiometric equation for this reaction is

CH 4  2O 2  3.76N 2     CO 2  2H 2 O   7.52N 2

Both the reactants and the products are at the standard reference state of 25C and 1 atm. Also, N2 and O2 are stable elements, and thus their enthalpy of formation is zero. Then the enthalpy of combustion combustion of CH4 becomes hC  H P  H R 

 N h



P f , P



 N h



R f , R

  N h f 

CO 2

  N h f 

H2O

  N h f 

CH 4

Using h f  values values from Table Table A-26, A-26, hC  1 kmol 393,520 kJ/kmol  2 kmol285,830 kJ/kmol

 1 kmol 74,850 kJ/kmol  890,330 kJ  per kmol CH 4  The listed value in Table Table A-27 is -890,868 -890,868 kJ/kmol, which is almost identical to the calculated value. Since the water in the products is assumed assumed to be in the liquid liquid phase, this hc value corresponds to the higher heating heating value of CH4.

15-22

15-43 EES Problem 15-42 is reconsidered. reconsidered. The effect of temperature temperature on the enthalpy of combustion is to be studied. Analysis The problem is solved solved using EES, and the solution is given given below.

Fuel$ = 'Methane (CH4)' T_comb =25 [C] T_fuel = T_comb +273 "[K]" T_air1 = T_comb +273 "[K]" T_prod =T_comb +273 "[K]" h_bar_comb_TableA27 h_bar_comb_TableA27 = -890360 [kJ/kmol] "For theoretical dry air, the complete combustion equation is" "CH4 + A_th(O2+3.76 N2)=1 CO2+2 H2O + A_th (3.76) N2 " A_th*2=1*2+2*1 "theoretical O balance" "Apply First Law SSSF" h_fuel_EES=enthalpy(CH4,T=298) "[kJ/kmol]" h_fuel_TableA26=-74850 "[kJ/kmol]" h_bar_fg_H2O=enthalpy(Steam h_bar_fg_H2O=enthalpy(Steam_iapws,T=298 _iapws,T=298,x=1)-enthalp ,x=1)-enthalpy(Steam_iapws y(Steam_iapws,T=298,x=0) ,T=298,x=0) "[kJ/kmol]" HR=h_fuel_EES+ A_th*enthalpy(O2,T=T_air1)+A_th*3.76 *enthalpy(N2,T=T_air1) "[kJ/kmol]" HP=1*enthalpy(CO2,T=T_ HP=1*enthalpy(CO2,T=T_prod)+2*(enthal prod)+2*(enthalpy(H2O,T=T_ py(H2O,T=T_prod)-h_bar_fg_ prod)-h_bar_fg_H2O)+A_th*3 H2O)+A_th*3.76* .76* enthalpy(N2,T=T_prod) "[kJ/kmol]" h_bar_Comb_EES=(HP-HR) "[kJ/kmol]" PercentError=ABS(h_bar_Comb_EESh_bar_comb_TableA27)/ABS h_bar_comb_TableA27)/ABS(h_bar_comb_ (h_bar_comb_TableA27)*Con TableA27)*Convert(, vert(, %) "[%]"

hCombEES [kJ/kmol]

TComb [C]

-890335 -887336 -884186 -880908 -877508 -873985 -870339 -866568 -862675 -858661

25 88.89 152.8 216.7 280.6 344.4 408.3 472.2 536.1 600

-855000 -860000

l

-865000 -870000 -875000

S E E , b m o C

-880000 -885000 -890000 -895000 0

100

200

300

400

Tcomb [C]

500

600

15-23

enthalpy of combustio combustion n of gaseous gaseous ethane at at a 25C and and 1 atm is to be determ determined ined using the data 15-44 The enthalpy from Table Table A-26 A-26 and to be compared compared to the the value listed listed in Table Table A-27. Assumptions The water in the products products is in the liquid liquid phase. phase. Analysis The stoichiometric equation for this reaction is

C 2 H 6  3.5O 2  3.76N 2     2CO 2  3H 2 O   13.16N 2

Both the reactants and the products are at the standard reference state of 25C and 1 atm. Also, N2 and O2 are stable stable elements, elements, and and thus their their enthalpy enthalpy of formation formation is zero. Then Then the enthalpy enthalpy of combustio combustion n of C2H6 becomes hC  H P  H R 

 N h

P f , P  

 N h



R f , R

  N h f 

CO 2

  N h f 

H 2O

  N h f 

C2 H 6

Using h f  values values from Table Table A-26, A-26, hC  2 kmol393,520 kJ/kmol  3 kmol285,830 kJ/kmol

 1 kmol  84,680 kJ/kmol  1,559,850 kJ  per kmolC 2 H 6  The listed value in Table Table A-27 is -1,560,633 kJ/kmol, which is almost almost identical to the calculated calculated value. Since the water in the products is assumed assumed to be in the liquid phase, thish this hc value corresponds to the higher heating heating value value of C2H6.

enthalpy of combusti combustion on of liquid liquid octane octane at a 25C and 1 atm is to be determined using the data 15-45 The enthalpy from Table Table A-26 A-26 and to be compared compared to the the value listed listed in Table A-27. Assumptions The water in the products products is in the liquid liquid phase. phase. Analysis The stoichiometric equation for this reaction is

  8CO 2  9H 2 O   47N 2 C 8 H 18  12.5O 2  3.76N 2   Both the reactants and the products are at the standard reference state of 25C and 1 atm. Also, N2 and O2 are stable elements, and thus their enthalpy of formation is zero. Then the enthalpy of combustion of C8H18 becomes hC  H P  H R 

 N h

P f , P  

 N h



R f , R

  N h f  CO   N h f  H 2

2O

  N h f  C H 8

18

Using h f  values values from Table Table A-26, A-26, hC  8 kmol393,520 kJ/kmol   9 kmol 285,830 kJ/kmol 

 1 kmol 249,950 kJ/kmol   5,470,680 kJ The listed value in Table A-27 is -5,470,523 kJ/kmol, which is almost almost identical to the calculated value. Since the the water in the product productss is assumed assumed to be in the liquid phase, phase, thish this hc value corresp corresponds onds to the higher heating heating value value of C8H18.

15-24

First Law Analysis of Reacting Systems 15-46C In this case U + W b =  H , and the conser conservation vation of energy energy relation relation reduces reduces to the form form of the steady-flow energy relation. 15-47C The heat transfer transfer will be the same same for all cases. The excess oxygen and nitrogen enters and leaves the combustion combustion chambe chamberr at the same state, state, and thus has no effect effect on the energy energy balance. balance.

(b), which contains contains the the maximum maximum amount amount of nonreactin nonreacting g gases. gases. This is because because part of 15-48C For case (b the chemical energy released released in the combustion combustion chamber chamber is absorbed and and transported transported out by the nonreacting nonreacting gases.

burned completely during a steady-flow steady-flow combustion combustion process. The heat transfer from the 15-49 Methane is burned combustion chamber is to be determined for two cases. Assumptions 1 Steady operating conditions exist. 2 Air and combustion combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and potential energies are negligible. 4 Combustion is complete. Analysis The fuel is burned completely with the stoichiometric amount of air, and thus the products will contain only H2O, CO2 and N2, but no no fr free O2. Consideri Considering ng 1 kmol of of fuel, fuel, the theoretica theoreticall combustio combustion n equation can be written as Q

CH 4  a th O 2  3.76N 2    CO2  2H 2O  3.76a th N 2

CH4

where ath is determined determined from from the O2 balance,

25C

a th  1  1  2

Air

Substituting,

  CO2  2H 2O  5.64N 2 CH 4  2O 2  3.76N 2  

Combustion chamber P = P = 1 atm

Products 25C

100% theoretical

The heat transfer for this combustion combustion process is determined from from the energy balance Ein  Eout   Esyst em applied applied on the combustio combustion n chamber chamber with W = reduces to W = 0. It reduces

 Qout 

 N h



P f

 h  h  P 

 N h R



f

 h  h  R 

 N h

P f , P  

 N h



R f , R

since both the the reactant reactantss and the products products are at at 25C and both the air and the combustion gases can be treated treated as ideal ideal gases. gases. From the tables, tables,

Substance

CH4 O2 N2 H2O () CO2

h f  kJ/kmol -74,850 0 0 -285,830 -393,520

Thus,

 Qout  1 393 ,520  2  285 ,830  0  1 74 ,850   0  0  890,330 kJ / kmol CH 4 or Qout  890,330 kJ / kmol CH 4 If combustion is achieved with 100% excess air, the answer would still be the same since since it would enter and leave at 25C, and absorb absorb no energy. energy.

15-25

15-50 Hydrogen is burned completely completely during a steady-flow steady-flow combustion combustion process. The heat transfer from the combustion chamber is to be determined for two cases.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 Combustion is complete. Analysis The H2 is burned completely with the stoichiometric amount of air, and thus the products will contain only H2O and N2, but no free O2. Considering 1 kmol of H2, the theoretical combustion equation can be written as

  H 2O  3.76a th N 2 H 2  a th O 2  3.76N 2  

Q H2

where ath is determined determined from from the O2 balanc balancee to be Substituting, g, ath = 0.5. Substitutin

25C

  H 2O  1.88N 2 H 2  0.5O 2  3.76N 2   The heat transfer for this combustion process is determined from the energy balance E in  E out  E system applied on

Air

Combustion chamber P = P = 1 atm

Products 25C

100% theoretical

the combustion combustion chamber chamber with W = It reduces reduces to W = 0. It

 Qout 

 N h



P f

 h  h  P 

 N h R



f

 h  h  R 

 N h

P f , P  

 N h



R f , R

since both the the reactant reactantss and the products products are at at 25C and both the air and the combustion gases can be treated treated as ideal ideal gases. gases. From the tables, tables,

Substance

H2 O2 N2 H2O ()

h f  kJ/kmol 0 0 0 -285,830

Substituting,

 Qout  1 285 ,830  0  0  0  0  285,830 kJ / kmol H 2 or Qout  285,830 kJ / kmol H 2 If combustion is achieved with 50% excess air, the answer would still be the same since it would enter and leave at 25C, and absorb absorb no energy. energy.

15-26

15-51 Liquid propane is burned with 150 percent excess excess air during during a steady-flow combustion process. process. The mass flow rate of air and the rate of heat transfer transfer from the combustion combustion chamber are are to be determined.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 Combustion is complete. are 44 kg/kmol and 29 kg/kmol, respectively respectively (Table (Table A-1). Properties The molar masses of propane and air are Analysis The fuel is burned completely completely with excess air, and thus the products will contain only CO2, H 2O, N2, and some free O 2. Consid Consideri ering ng 1 kmol kmol of C3H8, the combustio combustion n equation equation can be written written as

  3CO 2  4H 2 O  1.5a th O 2  2.53.76a th  N 2 C 3 H 8    2.5a th O 2  3.76N 2   where ath is the stoichiometric coefficient and is determine determined d from the O2 balance, 2.5a th  3  2  1.5a th

 

 Q

ath  5

C3H8 25C

Thus, C 3 H 8    12.5O 2  3.76N 2     3CO 2  4H 2 O  7.5O 2  47N 2 (a) The air-f air-fuel uel ratio ratio for for this combustio combustion n process process is AF  Thus,

mair mfuel



Air 12C

Combustion chamber

Products 1200 K

P = P = 1 atm

12.5  4.76 kmol29 kg/kmol  39.22 kg air/kg fuel 3 kmol12 kg/kmol  4 kmol 2 kg/kmol

 air  AFm  fuel   39.22 kg air/kg fuel 1.2 kg fuel/min   47.1 kg air/min m

(b) The heat heat transf transfer er for this this comb combust ustion ion proces processs is determ determine ined d from from the ener energy gy balanc balancee applied on the combustio combustion n chamber chamber with W = reduces to E in  E out  E system applied W = 0. It reduces

 Qout 

 N h P



f

 h  h   P 

 N h R



f

 h  h   R

Assuming Assuming the air and and the combu combustion stion products products to be be ideal ideal gases, gases, we haveh have h = h(T ). ). From From the tables tables,,

Substance

C3H8 () O2 N2 H2O ( g g ) CO2

h f 

h 285 K

h 298 K

h1200 K

kJ/kmol -118,910 0 0 -241,820 -393,520

kJ/kmol --8296.5 8286.5 -----

kJ/kmol --8682 8669 9904 9364

kJ/kmol --38,447 36,777 44,380 53,848

The h f  of liquid liquid propan propanee is is obtain obtained ed by adding adding h fg of propane at at 25C to h f  of gas propane. Substituting,

Qout  3393,520  53,848  9364  4 241,820  44,380  9904   7.5 0  38,447  8682   47 0  36,777  8669  1 118,910  h298  h298   12.5 0  8296.5  8682   47 0  8286.5  8669  190,464 kJ/kmol C 3 H 8 or

Qout  190,464 kJ/kmol C 3 H 8

Then the the rate of heat transf transfer er for a mass flow rate of 1.2 kg/min kg/min for the the propane propane becomes becomes

 1.2 kg/min   m  190,464 kJ/kmol  5194 kJ/min Qout    N   44 kg/kmol 

Q Q out  N out  

15-27

15-52E Liquid propane is burned with 150 percent excess air during a steady-flow combustion process. The mass mass flow rate rate of air and and the rate of heat transf transfer er from the combustion combustion chamber chamber are to to be determine determined. d.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 Combustion is complete. Properties The molar masses of propane and air are are 44 lbm/lbmol lbm/lbmol and 29 lbm/lbmol, respectively (Table (Table A-1E). Analysis The fuel is burned completely with the excess air, and thus the products will contain only CO2, H2O, N2, and some free O 2. Considering 1 kmol of C3H8, the combustion combustion equation can be written as

C3H 8    2.5a th O 2  3.76N 2     3CO2  4H 2O  1.5a th O2  2.53.76ath  N 2 where ath is the stoichiometric coefficient and is determine determined d from the O2 balance,

 Q

C3H8

  ath  5 2.5a th  3  2  1.5a th 

77F

Thus, C3H 8    12.5O 2  3.76N 2    3CO2  4H 2O  7.5O2  47N 2

Air 40F

Combustion chamber

Products 1800 R

P = P = 1 atm

(a) The air-f air-fuel uel ratio ratio for for this combustio combustion n process process is AF  Thus,

mair mfuel

12.5  4.76 lbmol29 lbm/lbmol  39.2 lbmair/lbmfuel 3 lbmol 12 lbm/lbmol  4 lbmol2 lbm/lbmol



 air  AFm  fuel   39.2 lbm air/lbm fuel 0.75 lbm fuel/min   29.4 lbm air / min m

(b) The heat heat transf transfer er for this this comb combust ustion ion proces processs is determ determine ined d from from the ener energy gy balanc balancee chamber withW with W = = 0. It reduces reduces to E in  E out  E system applied on the combustion chamber

 Qout 

 N h



P f

 h  h  P 

 N h R



f

 h  h  R


Substance

C3H8 () O2 N2 CO2 H2O ( g g )

h f 

h 500R

h 537 R

h1800 R

Btu/lbmol -51,160 0 0 -169,300 -104,040

Btu/lbmol --3466.2 3472.2 -----

Btu/lbmol --3725.1 3729.5 4027.5 4258.0

Btu/lbmol --13,485.8 12,956.3 18,391.5 15,433.0

The h f  of liquid propane propane is obtained obtained by adding adding the h fg of propane at 77F to the h f  of gas propane. Substituting,

Qout  3169,300  18,391.5  4027.5  4 104,040  15,433  4258  7.5 0  13,485.8  3725.1  47 0  12,959.3  3729.5  1 51,160  h537  h537   12.5 0  3466.2  3725.1  47 0  3472.2  3729.5  262,773 Btu / lbmol C 3 H 8 or

Qout  262 ,773 Btu / lbmol C3 H 8

Then the rate rate of heat transfer transfer for a mass flow flow rate of 0.75 kg/min for the propane becomes becomes

 0.75 lbm/min   m  262,773 Btu/lbmol  4479 Btu/min Qout   44 lbm/lbmol  N   


15-28

15-53 Acetylene gas is burned with 20 percent excess air during a steady-flow combustion process. The AF ratio ratio and the the heat heat transfe transferr are to be determ determine ined. d.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 Combustion is complete. molar masses masses of C2H2 and air are 26 kg/kmol and 29 kg/kmol, respectively (Table (Table A-1). A-1). Properties The molar Analysis The fuel is burned burned comple completely tely with with the excess excess air, air, and thus thus the the products products will contain contain only CO CO2, H2O, N2, and some free O 2. Considering 1 kmol of C2H2, the combustion combustion equation can be written as

  2CO2  H 2O  0.2ath O2  1.23.76ath  N 2 C2 H 2  1.2ath O 2  3.76N 2   Q

where ath is the stoichiometric coefficient and is determine determined d from the O2 balance, 1.2a th  2  0.5  0.2a th

 

C2H2 25C

ath  2.5

Air

Thus, C 2 H 2  3O 2  3.76N 2     2CO 2  H 2 O  0.5O 2  11.28N 2 (a)

AF 

mair mfuel



20% excess air

Combustion chamber

Products 1500 K

P = P = 1 atm

3  4.76 kmol29 kg/kmol  15.9 kg air/kg fuel 2 kmol12 kg/kmol  1 kmol 2 kg/kmol

(b) The heat heat transf transfer er for this this comb combust ustion ion proces processs is determ determine ined d from from the ener energy gy balanc balancee W = 0. It reduces chamber with W = reduces to Ein  Eout   Esyst em applied on the combustion chamber

 Qout 

 N h P



f

h h

P



 N h R



f

h h

R



 N h P



f

h h

P



 N h



R f , R

since all of the reactants are at 25C. Assuming the air and the combustion products to be ideal gases, gases, we have h = h(T ). ). From the tables, tables,

Substance

C2H2 O2 N2 H2O ( g g ) CO2

h f 

h 298 K

h1500 K

kJ/kmol 226,730 0 0 -241,820

kJ/kmol --8682 8669 9904

kJ/kmol --49,292 47,073 57,999

-393,520

9364

71,078

Thus,

Qout  2393,520  71,078  9364  1241,820  57,999  9904   0.5 0  49,292  8682   11.280  47,073  8669  1226,730   0  0  630,565 kJ/kmol C 2 H 2 or 630,565 kJ / kmol C2 H 2 Qout  630,565

15-29

15-54E Liquid octane is burned with 180 percent theoretical theoretical air during during a steady-flow steady-flow combustion combustion process. The AF ratio and the heat transfer transfer from the combustion combustion chamber are to be determined. determined.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 Combustion is complete. molar masses masses of C3H18 and air air are are 54 kg/kmol kg/kmol and 29 kg/kmol, kg/kmol, respect respectively ively (Table (Table A-1). A-1). Properties The molar Analysis The fuel is burned burned comple completely tely with with the excess excess air, air, and thus thus the the products products will contain contain only CO CO2, H2O, N2, and some free O 2. Cons Consid ider erin ing g 1 kmol kmol of of C8H18, the combustion combustion equation can be written as

  8CO2  9H 2O  0.8ath O 2  1.83.76ath  N 2 C8 H18    1.8ath O 2  3.76N 2   Q

where ath is the stoichiometric coefficient and is determine determined d from the O2 balance, 1.8a th  8  4. 4.5  0.8ath

 

C8H18 77F

ath  12.5

Air

Combustion chamber

Products 2500 R

P = P = 1 atm

80% excess air 77F

Thus,

  8CO2  9H 2O  10O2  84.6N2 C8 H18    22.5O 2  3.76N 2   (a)

AF 

mair mfuel



22.5  4.76 lbmol29 lbm/lbmol  27.2 8 lbmol 12 lbm/lbmol  9 lbmol2 lbm/lbmol

lbmair/lbmfuel

(b) The heat heat transf transfer er for this this comb combust ustion ion proces processs is determ determine ined d from from the ener energy gy balanc balancee applied on the combus combustion tion chambe chamberr with W = It reduces reduces to Ein  Eout   Esyst em applied W = 0. It

 Qout 

 N h P



f

h h

P



 N h R



f

h h

R



 N h P



f

h h

P



 N h



R f , R

since all of the reactants are at 77F. Assuming the air and the combustion combustion products to be ideal gases, gases, we have h = h(T ). ). From the tables, tables,

Substance

C8H18 () O2 N2 CO2 H2O ( g g )

h f 

h 537 R

h 2500 R

Btu/lbmol -107,530 0 0 -169,300 -104,040

Btu/lbmol --3725.1 3729.5 4027.5 4258.0

Btu/lbmol --19,443 18,590 27,801 22,735

Thus,

Qout  8169,300  27,801  4027.5  9 104,040  22,735  4258  10 0  19,443  3725.1  84.6 0  18,590  3729.5  1 107,530   0  0  412,372 Btu/lbmol C 8 H 18 or Qout  412,372 Btu/lbmol C 8 H 18

15-30

15-55 Benzene Benzene gas is burned with 95 percent percent theoretical theoretical air during during a steady-f steady-flow low combustion combustion process. process. The mole fraction fraction of the the CO in the produc products ts and and the heat transf transfer er from from the combus combustion tion chamber chamber are are to be determined.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. Analysis (a) The fuel is burned with insufficient amount amount of air, and and thus the products will contain some CO as well as CO2, H2O, and N2. The theoreti theoretical cal combusti combustion on equation equation of C6H6 is Q

  6CO2  3H 2O  3.76a th N 2 C6 H 6  a th O 2  3.76N 2  

C6H6 25C

where ath is the stoichiometric coefficient and is determine determined d from the O2 balance,

Air

a th  6  1.5  7.5 Then the actual actual combustion combustion equation equation can can be written written as

95% theoretical 25C

Combustion chamber

Products 1000 K

P = P = 1 atm

C6 H 6  0.95  7.5O 2  3.76N 2     xCO2  6  x CO  3H 2O  26.79N 2 0.95  7.5  x  6  x  / 2  1.5    x  5.25

O2 balance: Thus,

 5.25CO2  0.75CO  3H 2O  26.79N 2 C6 H 6  7.125O2  3.76N 2  

The mole fraction fraction of CO in the products is yCO 

N CO N total



0.75 5.25  0.75  3  26.79

 0021 . or 2.1%

(b) The heat heat transf transfer er for this this comb combust ustion ion proces processs is determ determine ined d from from the ener energy gy balanc balancee W = 0. It reduces chamber with W = reduces to Ein  Eout   Esyst em applied on the combustion chamber

 Qout 

 N h



P f

 h  h  P 

 N h R



f

 h  h  R 

 N h



P f

 h  h  P 

 N h



R f , R

since all of the reactants are at 25C. Assuming the air and the combustion products to be ideal gases, gases, we have h = h(T ). ). From the tables, tables,

Substance

C6H6 ( g g ) O2 N2 H2O ( g g ) CO CO2

h f 

h 298 K

h1000 K

kJ/kmol 82,930 0 0 -241,820 -110,530 -393,520

kJ/kmol --8682 8669 9904 8669 9364

kJ/kmol --31,389 30,129 35,882 30,355 42,769

Thus,

Qout  5.25393,520  42,769  9364   0.75 110,530  30,355  8669   3 241,820  35,882  9904   26.79 0  30,129  8669   182,930   0  0  2,112,779 kJ / kmol C 6 H 6 or

Q out  2,112,800 kJ/kmol C 6 H 6

15-31

15-56 Diesel Diesel fuel fuel is burned burned with with 20 percent percent exces excesss air during during a steady steady-f -flow low combus combustion tion proce process. ss. The required mass mass flow rate of the diesel fuel fuel to supply heat at a specified rate is to be determined.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 Combustion is complete. Analysis The fuel is burned burned comple completely tely with with the excess excess air, air, and thus thus the the products products will contain contain only CO CO2, H2O, N2, and some free O 2. Cons Consid ider erin ing g 1 kmol kmol of of C12H26, the combustion combustion equation can be written as

C12 H 26  1.2a th O 2  3.76N 2     12CO 2  13H 2 O  0.2a th O 2  1.2 3.76 a th  N 2

where ath is the stoichiometric coefficient and is determine determined d from the O2 balance, 1.2a th  12  6. 6.5  0. 0.2 a th

 

2

kJ/

C12H26 25C

ath  18.5

Combustion chamber

500 K

Air 20% excess air 25

Substituting,

Products

P = P = 1 atm

C12 H 26  22.2O 2  3.76N 2     12CO 2  13H 2O  3.7O 2  83.47N 2

The heat transfer for for this combustion combustion process is determined determined from the energy balance E in  E out  E system applied applied on the combustio combustion n chamber chamber with W = reduces to W = 0. It reduces

 Qout 

 N

P

h f   h  h 

P



 N

R

h f   h  h 

R



 N

P

h f   h  h 

P



 N h



R f , R

since all of the reactants are at 25C. Assuming the air and the combustion products to be ideal gases, gases, we h h T have = ( ). ). From the tables, tables, 

Substance

C12H26 O2 N2 H2O ( g g ) CO2

hf

h 298 K

h 500 K

kJ/kmol -291,010 0 0 -241,820 -393,520

kJ/kmol --8682 8669 9904 9364

kJ/kmol --14,770 14,581 16,828 17,678

Thus,

Q out  12 393,520  17,678  9364   13241,820  16,828  9904   3.7 0  14,770  8682   83.47 0  14,581  8669   1 291,010   0  0  6,869,110 kJ/kmol C 12 H 26 or

Q out  6,869,110 kJ/kmol C12 H 26

Then the required required mass flow rate of fuel for a heat heat transf transfer er rate of 2000 kJ/s becomes becomes

 Q out    2000 kJ/s  M    6,869,110 kJ/kmol 170 kg/kmol  0.0495 kg/s  49.5 g/s Q     out 

 M     N m

15-32

15-57E Diesel Diesel fuel is burned with with 20 percent excess excess air during during a steady-flow steady-flow combustion combustion process process.. The required required mass mass flow rate of the diesel diesel fuel for a specified specified heat transfer transfer rate rate is to be determined. determined.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 Combustion is complete. Analysis The fuel is burned burned comple completely tely with with the excess excess air, air, and thus thus the the products products will contain contain only CO CO2, H2O, N2, and some free O 2. Cons Consid ider erin ing g 1 kmol kmol of of C12H26, the combustion combustion equation can be written as

C12 H 26  1.2a th O 2  3.76N 2    12CO 2  13H 2 O  0.2a th O 2  1.2 3.76a th  N 2   1800 Btu/s Q

where ath is the stoichiometric coefficient and is determined from the O2 balance, 1.2a th  12  6. 6.5  0. 0.2a th

 

C12H26 77F

ath  18.5

Air

Substituting,


Combustion chamber

Products 800 R

P = P = 1 atm

C12 H 26  22.2O 2  3.76N 2     12CO 2  13H 2 O  3.7O 2  83.47N 2

The heat transfer for this combustion combustion process is determined from from the energy balance Ein  Eout   Esyst em applied applied on the combustio combustion n chamber chamber with W = reduces to W = 0. It reduces

 Qout 

 N

P

h f   h  h 

P



 N

R

h f   h  h 

R



 N

P

h f   h  h 

P



 N h



R f , R

since all of the reactants are at 77F. Assuming the air and the combustion combustion products to be ideal gases, gases, we have h = h(T ). ). From the tables, tables,

Substance

C12H26 O2 N2 g ) H2O ( g CO2

hf 

h537 R

h800 R

Btu/lbmol -125,190 0 0 -104,040 -169,300

Btu/lbmol --3725.1 3729.5 4258.0 4027.5

Btu/lbmol --5602.0 5564.4 6396.9 6552.9

Thus,

Q out  12 169,300  6552 .9  4027.5  13104,040  6396.9  4258   3.7 0  5602.0  3725.1  83.47 0  5564.4  3729 .5   1 125,190   0  0  3,040,716 Btu/lbmol C12 H 26 or

Qout  3,040,716 Btu/lbmol C12 H 26

Then the required required mass flow rate of fuel for a heat heat transf transfer er rate of 1800 Btu/s becomes becomes

 Q    1800 Btu/s  M    3,040,716 Btu/lbmol 170 lbm/lbmol  0.1006 lbm/s  Q    

 M     N m 

15-33

15-58 [ Also solved by EES on enclosed CD] Octane gas is burned with 30 percent excess air during a steady-fl steady-flow ow combustio combustion n process. process. The heat trans transfer fer per unit unit mass of octane octane is to be determined determined.. Assumptions 1 Steady operating conditions exist. 2 Air and combustion combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and potential energies are negligible. 4 Combustion is complete. Properties The molar molar mass of of C8H18 is 114 kg/kmol kg/kmol (Table (Table A-1). A-1). Analysis The fuel is burned burned comple completely tely with with the excess excess air, air, and thus thus the the products products will contain contain only CO CO2, H2O, N2, and some free O2. The moistur moisturee in the air does not react react with with anything; anything; it simply simply shows shows up as additional H2O in the products. products. Therefor Therefore, e, for simpli simplicity, city, we will balanc balancee the combustio combustion n equation equation using using dry air, and then add the moisture moisture to both both sides of the equation. equation. Consideri Considering ng 1 kmol kmol of C8H18, the combustion equation can be written as

C8 H18 g   1.3ath O 2  3.76N 2     8CO 2  9H 2O  0.3ath O 2  1.33.76ath  N 2

where ath is the stoichiometric stoichiometric coefficient coefficient for air. It is determined determined from from

 ath  12.5 O 2 balance: 1.3a th  8  4.5  0.3a th 

q

C8H18

Thus,

  8CO 2  9H 2O  3.75O 2  61.1N 2 C8 H18 g   16.25 O 2  3.76N 2   Therefore, 16.25  4.76 = 77.35 77.35 kmol of dry air will will be used used per per kmol kmol of the fuel. fuel. The partia partiall pres pressur suree of the water water vapor vapor present in the incoming air is P v ,in   air P sat @ 25C  0.60 3.1698 kPa   1.902 kPa

25C Air

30% excess air

Combustion chamber

Products 600 K

P = P = 1 atm

Assuming ideal gas behavior, the number number of moles of the moisture that accompanies accompanies 77.35 kmol of incoming dry air is determined to be

 P v,in   1.902 kPa   N total     N v,in  1.48 kmol  101.325 kPa 77.35  N v,in    P     total 

N v ,in  

The balanced balanced combustion combustion equation equation is obtained obtained by adding 1.48 kmol of H2O to both sides of the equation, C 8 H 18 g   16.25O 2  3.76N 2   1.48H 2 O    8CO 2  10.48H 2 O  3.75O 2  61.1N 2

The heat transfer for this combustion combustion process is determined from from the energy balance Ein  Eout   Esyst em W = 0. It reduces applied applied on the combustio combustion n chamber chamber with W = reduces to

 Qout 

 N

P

h f   h  h 

P



 N

R

h f   h  h 

R



 N

P

h f   h  h 

P



 N h



R f , R

since all all of the reactants reactants are at 25C. Assuming the air and the combustion products to be ideal gases, we have h = h(T ). ). From the tables, tables, h 298 K h 600 K hf  Substance kJ/kmol kJ/kmol kJ/kmol C8H18 ( g ) -208,450 ----O2 0 8682 17,929 N2 0 8669 17,563 g ) H2O ( g -241,820 9904 20,402 CO2 -393,520 9364 22,280 Substituting, Qout  8393,520  22,280  9364   10.48 241,820  20,402  9904   3.750  17,929  8682   61.10  17,563  8669   1 208,450   1.48  241,820   0  0  4,324,643 kJ/kmol C8H18 Thus Thus 4,324, 4,324,643 643 kJ of heat heat is transf transferr erred ed from from the combus combustion tion chamb chamber er for each each kmol kmol (114 (114 kg) kg) of C8H18. Then the the heat heat transfer transfer per kg of C8H18 becomes q

Qout M



4,324,643 kJ 114kg

 37,935 kJ/kg C8H18

15-34

15-59 EES Problem Problem 15-58 15-58 is reconsidere reconsidered. d. The effect effect of the amount amount of excess excess air on the heat transfer transfer for the combustion process is to be investigated. Analysis The problem problem is solved solved using EES, EES, and the solution solution is given given below.

Fuel$ = 'Octane (C8H18)' T_fuel = (25+273) "[K]" {PercentEX = 30 "[%]"} Ex = PercentEX/100 "[%Excess air/100]" P_air1 = 101.3 [kPa] T_air1 = 25+273 "[K]" RH_1 = 60/100 "[%]" T_prod = 600 [K] M_air = 28.97 [kg/kmol] M_water = 18 [kg/kmol] M_C8H18=(8*12+18*1) "[kg/kmol]" "For theoretical dry air, the complete combustion equation is" "C8H18 + A_th(O2+3. A_th(O2+3.76 76 N2)=8 N2)=8 CO2+9 CO2+9 H2O + A_th (3.76) N2 " A_th*2=8*2+9*1 "theoretical O balance" "now to find the amount of water vapor associated with the dry air" w_1=HUMRAT(AirH2O,T=T_air1,P=P_air1,R=RH_1) "Humidity ratio, kgv/kga" N_w=w_1*(A_th*4.76*M_air)/M_water "Moles of water in the atmoshperic air, kmol/kmol_fuel" "The balanced combustion equation with Ex% excess moist air is" "C8H18 + (1+EX) (1+EX)[A_th( [A_th(O2+3.76 O2+3.76 N2)+N_ N2)+N_w w H2O]=8 CO2+(9 CO2+(9+(1+Ex +(1+Ex)*N_w) )*N_w) H2O + (1+Ex) A_th (3.76) N2+ Ex( A_th) O2 " "Apply First Law SSSF" H_fuel = -208450 [kJ/kmol] "from Table A-26" HR=H_fuel+ (1+Ex)*A_th*enthalpy(O2,T=T_air1)+(1+Ex)*A_th*3.76 *enthalpy(N2,T=T_air1)+(1+Ex)*N_w*enthalpy(H2O,T=T_air1) HP=8*enthalpy(CO2,T=T_prod)+(9+(1+Ex)*N_w)*enthalpy(H2O,T=T_prod)+(1+Ex)*A_th*3.76* enthalpy(N2,T=T_prod)+Ex*A_th*enthalpy(O2,T=T_prod) Q_net=(HP-HR)"kJ/kmol" Q_net=(HP-HR)"kJ/kmol"/(M_C8H18 /(M_C8H18 "kg/kmol" "kg/kmol")) "[kJ/kg_C8H18]" Q_out = -Q_net "[kJ/kg_C8H18]" "This solution used the humidity ratio form psychrometric data to determine the moles of water vapor in in atomspheric atomspheric air. One should should calculate calculate the moles of water water contained contained in in the atmosphe atmospheric ric air by the method shown in Chapter 14 which uses the relative humidity to find the partial pressure of the water vapor and, thus, the moles of water vapor. Explore what happens to the results as you vary the percent excess air, relative humidity, and product temperature." Qout [kJ/kgC8H18]

PercentEX [%]

39374 38417 37460 36503 35546 34588 33631 32674 31717 30760 29803

0 20 40 60 80 100 120 140 160 180 200

40000

] 8 1 H 8 C

37800 35600 33400

t u o

31200 29000 0

40

80

120

PercentEX [%]

160

200

15-35

15-60 Ethane gas is burned with stoichiometric stoichiometric amount of air during a steady-flow combustion combustion process. process. The rate of heat transf transfer er from the combustio combustion n chamber chamber is to be determine determined. d.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 Combustion is complete. molar mass of of C2H6 is 30 kg/kmol kg/kmol (Table A-1). A-1). Properties The molar Analysis The theoretical theoretical combustion equation of C2H6 is

C 2 H 6  a th O 2  3.76N 2     2CO 2  3H 2 O  3.76a th N 2

where ath is the stoichiometric coefficient and is determined from the O2 balance, ath  2  1.5  3.5

 Q

C2H6 25C Air

Combustion chamber

Products 800 K

P = P = 1 atm

500 K

Then the actual actual combustion combustion equation equation can be written written as

  1.9CO 2  0.1CO  3H 2 O  0.05O 2  13.16N 2 C 2 H 6  3.5O 2  3.76N 2   The heat transfer for this combustion combustion process is determined from from the energy balance Ein  Eout   Esyst em applied applied on the combustio combustion n chamber chamber with W = reduces to W = 0. It reduces

 Qout 

 N h



P f

 h  h   P 

 N h R



f

 h  h   R

Assuming Assuming the air and and the combu combustion stion products products to be be ideal ideal gases, gases, we haveh have h = h(T ). ). From From the tables tables,, 

Substance

C2H6 ( g g ) O2 N2 H2O ( g g ) CO CO2

hf

h 500 K

h 298 K

h 800 K

kJ/kmol -84,680 0 0 -241,820 -110,530 -393,520

kJ/kmol --14,770 14,581 -------

kJ/kmol --8682 8669 9904 8669 9364

kJ/kmol --24,523 23,714 27,896 23,844 32,179

Thus,

Qout  1.9393,520  32,179  9364  0.1110,530  23,844  8669  3 241,820  27,896  9904  0.050  24,523  8682  13.160  23,714  8669  1 84,680  h298  h298   3.50  14,770  8682  13.160  14,581  8669  1,201,005 kJ / kmol C 2 H 6 or

Qout  1,201,005 kJ / kmol C 2H 6

Then the the rate rate of heat transfe transferr for a mass mass flow flow rate of of 3 kg/h for the the ethane ethane becomes becomes

 5 kg/h   m  1,201,005 kJ/kmol   200,170 kJ/h Qout    M   30 kg/kmol 


15-36

mixture of methane methane and oxygen oxygen contained contained in a tank is 15-61 [ Also solved by EES on enclosed CD] A mixture burned at constant volume. The final pressure in the tank and the heat transfer during this process are to be determined. Assumptions 1 Air and combustion combustion gases are ideal gases. 2 Combustion is complete.

molar masses masses of CH4 and O2 are 16 kg/kmol kg/kmol and 32 kg/kmol, respectively (Table A-1). Properties The molar Analysis (a) The combustion is assumed to be complete, complete, and thus all the carbon in in the methane burns to CO2 and all of the hydrogen hydrogen to H2O. The number number of moles moles of CH4 and O2 in the tank are

mCH 4

N CH 4  N O 2 

M CH 4

m O2 M O 2





0.12 kg 16 kg/kmol 0.6 kg

32 kg/kmol

 7.5 10 3 kmol  7.5 mol

Q O2 + CH4 25C, 200 kPa

 18.75 10 3 kmol  18.75 mol

Then the combustion combustion equation can be written as

1200 1200 K

7.5CH 4  18.75O 2    7.5CO 2  15H 2 O  3.75O 2

At 1200 K, water exists in the gas phase. Assuming both the reactants and the products to be ideal gases, the final pressure pressure in the tank is determined to be P  N P  T P  RV  N R Ru T R     P P  P R  P P V  N P Ru T P   N R  T R  Substituting,

 26.25 mol  1200 K     805 kPa 26.25 mol 298 K   

P P  200 kPa  

which is relatively low. Therefore, the ideal gas assumption assumption utilized earlier is appropriate. appropriate. (b) The heat transfer for this this constant volume combustion process is determined determined from the energy energy balance Ein  Eout   Esyst em applied applied on the combustio combustion n chamber chamber with W = reduces to W = 0. It reduces

 Qout 

 N

P

h f   h  h   P v

P



 N

R

h f   h  h   P v

R

Since both the reactants and products are assumed assumed to be ideal ideal gases, all the internal energy and enthalpies depend on temperature only, and the P v terms terms in this equation equation can be replaced replaced by RuT . It yie yield ldss

 Q out 

 N

P

h f   h1200 K  h298 K  R u T

P



 N

R

h f   Ru T

R

since the reactants are at the standard reference reference temperature of 25C. From From the the tabl tables es,, Substance

CH4 O2 g ) H2O ( g CO2

hf 

h 298 K

h1200 K

kJ/kmol -74,850 0 -241,820 -393,520

kJ/kmol --8682 9904 9364

kJ/kmol --38,447 44,380 53,848

Thus,

Qout  7.5393,520  53,848  9364  8.314 1200   15 241,820  44,380  9904  8.314 1200   3.750  38,447  8682  8.314 1200   7.5 74,850  8.314  298   18.75  8.314  298  5,251,791 J  5252 kJ Thus Qout  5252 kJ of heat is transferred from the combustion chamber as 120 g of CH4 burned in this combustion chamber.

15-37

reconsidered. The effect of the final temperature temperature on the final pressure pressure and the 15-62 EES Problem 15-61 is reconsidered. heat transfe transferr for the combus combustion tion process process is to be investigat investigated. ed. Analysis The problem is solved solved using EES, and the solution is given given below.

"Input Data" T_reac = (25+273) "[K]" "reactant mixture temperature" P_reac = 200 [kPa] "reactant mixture pressure" {T_prod = 1200 [K]} "product mixture temperature" m_O2=0.600 [kg] "initial mass of O2" Mw_O2 = 32 [kg/kmol] m_CH4 = 0.120 [kg] "initial mass of CH4" Mw_CH4=(1*12+4*1) "[kg/kmol]" R_u = 8.314 [kJ/kmol-K] "universal gas constant" "For theoretical oxygen, the complete complete combustion equation is" "CH4 + A_th O2=1 CO2+2 H2O H2O " 2*A_th=1*2+2*1"theoretical 2*A_th=1*2+2*1"theoretical O balance" "now to find the actual actual moles of O2 supplied supplied per mole of fuel" N_O2 = m_O2/Mw_O2/N_CH4 m_O2/Mw_O2/N_CH4 N_CH4= m_CH4/Mw_CH4 "The balanced complete combustion combustion equation with Ex% excess excess O2 is" "CH4 + (1+EX) A_th O2=1 CO2+ 2 H2O + Ex( A_th) O2 " N_O2 = (1+Ex)*A_th "Apply First First Law to the closed closed system system combustion chamber chamber and assume ideal gas behavior. (At 1200 K, water exists in the gas phase.)" E_in - E_out = DELTAE_sys E_in = 0 E_out = Q_out "kJ/ "kJ/kmol_ kmol_CH4" CH4" "No work work is done beca because use volume volume is constant" constant" DELTAE_sys = U_prod - U_reac "neglect KE and PE and note: U = H - PV = N(h - R_u T)" U_reac = 1*(enthalpy(CH4, T=T_reac) - R_u*T_reac) +(1+EX)*A_th*(enthalpy +(1+EX)*A_th*(enthalpy(O2,T=T_reac) (O2,T=T_reac) - R_u*T_reac) U_prod = 1*(enthalpy(CO2, T=T_prod) - R_u*T_prod) +2*(enthalpy(H2O, T=T_prod) R_u*T_prod)+EX*A_th*(enthalpy(O2,T=T_pr R_u*T_prod)+EX*A_th*(enthalpy(O2,T=T_prod) od) - R_u*T_prod) "The total heat transfer out, in kJ, is:" Q_out_tot=Q_out"kJ/kmol_CH4" Q_out_tot=Q_out"kJ/kmol_CH4"/(Mw_CH4 /(Mw_CH4 "kg/kmol_CH4" "kg/kmol_CH4")) *m_CH4"k *m_CH4"kg" g" "k "kJ" J" "The final pressure in the tank is the pressure of the product product gases. Assuming ideal gas behavior for the gases in the constant volume tank, the ideal gas law gives:" P_reac*V =N_reac * R_u *T_reac P_prod*V = N_prod * R_u * T_prod N_reac = N_CH4*(1 + N_O2) N_prod = N_CH4*(1 + 2 + Ex*A_th) 5900

Tprod [K] 500 700 900 1100 1300 1500

Qout,tot [kJ] 5872 5712 5537 5349 5151 4943

Pprod [kPa] 335.6 469.8 604 738.3 872.5 1007

1100 1000

5700

t o t; t u o

900

] a P 700 k [

5500

800

5300

600 d 500

5100

400 4900 500

700

900

1100

Tprod [K]

1300

300 1500

o r p

P

15-38

stoichiometric etric mixture mixture of octane octane gas and and air contained contained in in a closed closed combu combustion stion chamber chamber is ignited. ignited. 15-63 A stoichiom The heat transfer from the combustion chamber chamber is to be determined. Assumptions 1 Both the reactants and products are ideal gases. 2 Combustion is complete. Analysis The theoretical theoretical combustion equation of C8H18 with stoichiometric amount of air is

C8 H18 g   ath O 2  3.76N 2     8CO2  9H 2O  3.76 ath N 2

where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, a th  8  4.5  12.5

P = P = const. C8H18+ Air 25C, 300 kPa

Thus, C 8 H 18 g   12.5 O 2  3.76N 2     8CO 2  9H 2 O  47N 2

The heat transfer transfer for this constant volume combustion combustion process is determined from the energy balance Ein  Eout   Esyst em applied on the combustion chamber with W other other = 0,

 Qout 

 N



P h f

 h  h   P v P 

 N

R

Q

1000 K

h f   h  h   P v

R

For a constant pressure quasi-equilibrium process process U + first law relation relation in this this case case is U + W b =  H . Then the first

 Qout 

 N



P h f

 h1000 K  h298K P 

 N h



R f , R

since the reactants reactants are at the standard reference reference temperature of 25C. Since Since both both the reacta reactants nts and the products behave as ideal gases, we haveh have h = h(T ). ). From From the tables tables,,

Substance

C8H18 ( g ) O2 N2 H2O ( g g ) CO2

hf 

h 298 K

h1000 K

kJ/kmol -208,450 0 0 -241,820 -393,520

kJ/kmol --8682 8669 9904 9364

kJ/kmol --31,389 30,129 35,882 42,769

Thus,

Qout  8393,520  42,769  9364   9 241,820  35,882  9904   47 0  30,129  8669   1 208,450   0  0  3,606,428 kJ  per kmol of C 8 H 18  or

Qout  3,606,428 kJ  per kmol of C8 H18  .

Total mole numbers numbers initially present present in the combustion chamber chamber is determined determined from the ideal ideal gas relation,

300 kPa 0.5 m 3    0.06054 kmol N 1  RuT 1 8.314 kPa  m 3/kmol  K 298 K  P 1V 1

Of these, these, 0.06054 0.06054 / (1 (1 + 12.5 12.54.76) = 1.00110-3 kmol of them is C8H18. Thus Thus the amoun amountt of heat heat -3 transferred from from the combustion chamber chamber as 1.00110 kmol of C8H18 is burned is



Qout  1.001  10 3 kmol C 8 H 18 3,606,428 kJ/kmol C 8 H 18   3610 kJ

15-39

15-64 A mixture of benzene gas and 30 percent excess air contained in a constant-volume tank is ignited. The heat transfer from the combustion chamber chamber is to be determined. Assumptions 1 Both the reactants and products are ideal gases. 2 Combustion is complete.

theoretical combustion equation of C6H6 Analysis The theoretical with stoichiometric amount of air is

Q C6H6+ Air 25C, 1 atm

  6CO 2  3H 2O  3.76 ath N 2 C6 H 6 g   ath O 2  3.76N 2   where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, a th  6  1.5  7.5

1000 1000 K

Then the actual combustion combustion equation with 30% excess air becomes becomes C6 H 6 g   9.75 O 2  3.76N 2     5.52CO 2  0.48CO  3H 2O  2.49O 2  36.66N 2

The heat transfer transfer for this constant constant volume volume combus combustion tion process process is is determ determined ined from the energy energy balance balance Ein  Eout   Esyst em applied applied on the combustio combustion n chamber chamber with W = reduces to W = 0. It reduces

 Qout 

 N

P

h f   h  h   P v

P



 N

R

h f   h  h   P v

R

Since both the reactants and the products behave behave as ideal gases, gases, all the internal energy and enthalpies enthalpies depend on temperature only, and the P v terms terms in in this this equation equation can be replaced replaced by RuT . It yields

 Q out 

 N

P

h f   h1000 K  h298 K  R u T

P



 N

R

h f   R u T

R

since the reactants are at the standard reference reference temperature of 25C. From From the the tabl tables es,,

Substance

C6H6 ( g g ) O2 N2 H2O ( g g ) CO CO2

h f 

h 298 K

h1000 K

kJ/kmol 82,930 0 0 -241,820 -110,530 -393,520

kJ/kmol --8682 8669 9904 8669 9364

kJ/kmol --31,389 30,129 35,882 30,355 42,769

Thus,

Qout  5.52393,520  42,769  9364  8.314 1000  0.48 110,530  30,355  8669  8.314 1000  3 241,820  35,882  9904  8.314 1000  2.490  31,389  8682  8.314 1000  36.660  30,129  8669  8.314 1000  182,930  8.314  298  9.754.76 8.314  298  2,200,433 kJ or

Qout  2,200,433 kJ

15-40

mixture of benzene benzene gas and 30 percent percent excess excess air contained contained in a constant-vo constant-volume lume tank tank is ignited. 15-65E A mixture The heat transfer from the combustion chamber chamber is to be determined. Assumptions 1 Both the reactants and products are ideal gases. 2 Combustion is complete.

theoretical combustion equation of C6H6 Analysis The theoretical with stoichiometric amount of air is

Q C6H6+ Air 77F, 1 atm

  6CO 2  3H 2O  3.76 ath N 2 C6 H 6 g   ath O 2  3.76N 2   where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, a th  6  1.5  7.5

180 1800 R

Then the actual combustion combustion equation with 30% excess air becomes becomes C6 H 6 g   9.75 O 2  3.76N 2     5.52CO 2  0.48CO  3H 2O  2.49O 2  36.66N 2

The heat transfer transfer for this constant constant volume volume combus combustion tion process process is determ determined ined from the energy energy balance balance Ein  Eout   Esyst em applie applied d on the combus combustio tion n chamb chamber er with with W = 0. It redu reduces ces to

 Qout 

 N

P

h f   h  h   P v

P



 N

R

h f   h  h   P v

R

Since both the reactants and the products behave behave as ideal gases, gases, all the internal energy and enthalpies enthalpies depend on temperature only, and the Pv terms in this equation can be replaced replaced by RuT . It yields

 Qout 

 N



P h f

 h1800 R  h537 R  RuT P 

 N

R

h f   RuT

R

since the reactants are at the standard reference reference temperature of 77F. From the tables, tables,

Substance

C6H6 ( g g ) O2 N2 H2O ( g g ) CO CO2

h f 

h537 R

h1800 R

Btu/lbmol 35,6860 0 0 -104,040 -47,540 -169,300

Btu/lbmol --3725.1 3729.5 4258.0 3725.1 4027.5

Btu/lbmol --13,485.8 12,956.3 15,433.0 13,053.2 18,391.5

Thus,

Qout  5.52169,300  18,391.5  4027.5  1.986  1800  0.48 47,540  13,053.2  3725.1  1.986  1800  3 104,040  15,433.0  4258.0  1.986 1800  2.490  13,485.8  3725.1  1.986 1800  36.660  12,956.3  3729.5  1.986 1800  135,680  1.986  537  9.754.76 1.986  537  946,870 Btu or

Qout  946,870 Btu

15-41

15-66 A high efficiency gas furnace burns gaseous propane C3H8 with 140 percent theoretical air. The volume flow rate of water condensed from the product product gases is to be determined. Assumptions 1 Combustion is complete. 2 The combustion products contain contain CO2, H2O, O2, and N2 only. Properties The molar molar masses masses of C, C, H2, O2 and air are 12 kg/kmol, kg/kmol, 2 kg/kmol, 32 kg/kmol, and 29 kg/kmol, respectivel respectively y (Table (Table A-1). Analysis The reaction reaction equation equation for 40% excess excess air (140% (140% theoretica theoreticall air) is

  B CO 2  D H 2O  E O 2  F N 2 C3H 8  1.4ath O 2  3.76N 2   where ath is the stoichiometric coefficient for air. We have automatically accounted for the 40% excess air by usin using g the factor factor 1.4 1.4ath instead of ath for air. The coefficient ath and other other coeff coefficien icients ts are are to be determined from the mass mass balances Q Carbon balance: B=3 C3H8   D  4 Hydrogen balance: 2 D  8  25C Combustion Products Oxygen balance: 2  1.4a th  2 B  D  2 E chamber 0.4a th  E Air Nitrogen balance: 1.4a th  3.76  F 40% excess Solving Solving the above equations equations,, we find the coeffici coefficients ents E = (E = 2, F = F = 26.32, and ath = 5) and write the balanced reaction equation as

  3 CO 2  4 H 2 O  2 O 2  26.32 N 2 C 3 H 8  7 O 2  3.76N 2   The partial pressure of water in the saturated product mixture at the dew point is P v , prod  P sat@40C  7.3851 kPa The vapor mole mole fraction fraction is P v , prod 7.3851 kPa   0.07385 y v  100 kPa P prod The kmoles kmoles of water condensed condensed is determ determined ined from N water 4  N w    0.07385     N w  1.503 kmol yv  3  4  N w  2  26.32 N total, product The steady-flow steady-flow energy balance is expressed expressed as    N fuel H R  Qfuel  N fuel H P

where

Q fuel 

Q out  furnace

H R  h f o



31,650 kJ/h

fuel@25 C

0.96

 32,969 kJ/h

 7hO2@25C  26.32h N2@25C

 (103,847 kJ/kmol)  7(0)  26.32(0)  103,847 kJ/kmol H P  3hCO2@25C  4hH2O@25C  2hO2@25C  26.32h N2@25C  N w ( h f o

H2O(liq)

)

 3(393,520 kJ/kmol)  4(-241,820 kJ/kmol)  2(0)  26.32(0)  1.503(285,830 kJ/kmol)  2.577  10 6 kJ/kmol Substituting into the energy balance equation, equation,    N fuel H R  Qfuel  N fuel H P 6      N N fuel (103,847 kJ/kmol)  32,969 kJ/h  N fuel (2.577  10 kJ/kmol)  fuel  0.01333 kmol/h

The molar and mass mass flow rates of the liquid water are   N w  N w N fuel  (1.503 kmol/kmol fuel)(0.01333 kmol fuel/h)  0.02003 kmol/h  M  (0.02003 kmol/h)(18 kg/kmol)  0.3608 kg/h  w  N m w w

The volume volume flow rate rate of liquid liquid water is is  V w

 (v f @25C )m w  (0.001003 m 3 /kg)(0.3608 kg/h)  0.0003619 m 3 /h  8.7 L/day

15-42

steady-flow combustion chamber chamber with 40 percent 15-67 Liquid ethyl alcohol, C2H5OH (liq), is burned in a steady-flow excess excess air. The required required volume volume flow rate of the liquid ethyl ethyl alcohol is to be determine determined. d. Assumptions 1 Combustion is complete. 2 The combustion products contain contain CO2, H2O, O2, and N2 only.

molar masses masses of C, C, H2, O2 and air are 12 kg/kmol, kg/kmol, 2 kg/kmol, 32 kg/kmol, and 29 kg/kmol, Properties The molar respectivel respectively y (Table (Table A-1). reaction equation equation for 40% excess excess air is Analysis The reaction

  B CO 2  D H 2O  E O 2  F N 2 C2 H 5OH  1.4ath O 2  3.76N 2   where ath is the stoichiometric coefficient for air. We have automatically accounted for the 40% excess air by usin using g the factor factor 1.4 1.4ath instead of ath for air. The coefficient ath and other other coeff coefficien icients ts are are to be determined from the mass mass balances Carbon balance:

B=2

Hydrogen balance:

  D  3 2 D  6 

Oxygen balance:

1  2  1.4a th  2 B  D  2 E

Q

25C Air

0.4a th  E Nitrogen balance:

C2H5OH (liq)

1.4a th  3.76  F

Combustion chamber

Products 600 K

40% excess

Solving the above equations, we find the coefficients E (E = 1.2, F = 15.79, and ath = 3) and write the balanced balanced reaction reaction equation equation as C 2 H 5 OH  4.2O 2  3.76N 2     2 CO 2  3 H 2 O  1.2 O 2  15.79 N 2 The steady-flow steady-flow energy balance is expressed expressed as    N fuel H R  Qout  N fuel H P

where H R  (h f o  h fg ) fuel  [email protected] K  ( 4.2  3.76)h [email protected] K

 235,310 kJ/kmol - 42,340 kJ/kmol  4.2(-4.425 kJ/kmol)  (4.2  3.76)(4.376 kJ/kmol)  277,650 kJ/kmol H P  2hCO2@600 K  3hH2O@600 K  1.2hO2@600 K  15.79h N2@600 K

 2(380,623 kJ/kmol)  3(-231,333 kJ/kmol)  1.2(9251 kJ/kmol)  15.79(8889 kJ/kmol)  1.304 10 6 kJ/kmol The enthalpies are obtained from EES EES except for the enthalpy of formation formation of the fuel, which is obtained in Table A-27 of the book. Substituting into the energy energy balance equation,    N fuel H R  Qout  N fuel H P 6      N N fuel (277,650 kJ/kmol)  2000 kJ/s  N fuel ( 1.304  10 kJ/kmol)  fuel  0.001949 kmol/s

The fuel mass mass flow flow rate is   fuel  N m fuel M fuel  (0.001949 kmol/s)(2  12  6  1  16) kg/kmol  0.08966 kg/s

Then, the the volume volume flow rate of the fuel fuel is determined determined to be  V fuel



 fuel m

 fuel



0.08966 kg/s  6000 L/min 



790 kg/m 3 

1 m 3 /s

  6.81 L/min 

15-43

Adiabatic Flame Temperature Temperature 15-68C For the case case of stoichi stoichiomet ometric ric amount amount of pure oxygen since we have the same same amount amount of chemi chemical cal energy released but a smaller amount of mass to absorb it. 15-69C Under the conditions of complete combustion with stoichiometric amount of air. 15-70 [ Also Also solved by EES on enclosed CD ] Hydrogen Hydrogen is burned burned with 20 percent percent excess excess air during a steadysteadyflow combustion combustion process. process. The exit temperature of product product gases is to be determined.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 There are no work interactions. 5 The combustion chamber is adiabatic. Analysis Adiabatic flame temperature is the temperature at which the products leave the combustion chamber chamber under under adiabati adiabaticc conditions conditions (Q = 0) with with no work work inte intera ract ctio ions ns (W (W = 0). Under steady-flow conditions the energy balance E in  E out  E system applied on the combustion chamber reduces to

 N h P



f

 h  h   P 

 N h R



f

 h  h   R

H2 7C

The combustion combustion equation equation of H2 with 20% excess excess air air is H 2  0.6O 2  3.76N 2     H 2 O  0.1O 2  2.256N 2

Air

Combustion chamber

Products T P

20% excess air 7C

From the tables,

Substance

H2 O2 N2 H2O ( g g )

h f 

h 280 K

h 298 K

kJ/kmol 0 0 0 -241,820

kJ/kmol 7945 8150 8141 9296

kJ/kmol 8468 8682 8669 9904

Thus,

1 241,820  hH O  9904  0.10  hO  8682  2.2560  h N  8669  10  7945  8468  0.6 0  8150  8682   2.256 0  8141  8669 2

It yields

2

2

hH 2O  0.1hO 2  2.256h N 2  270,116 kJ

The adiabatic flame temperature temperature is obtained from a trial and error solution. A first guess guess is obtained obtained by dividing the right-hand side of the equation by the total number of moles, which yields 270,116/(1 + 0.1 + 2.256) = 80,488 kJ/kmol. This enthalpy value corresponds to about 2400 K for N2. Noting that the majority majority of the moles are N2, T P will be close to 2400 K, but somewh somewhat at under it because because of the higher higher specific specific heat of H2O. At 2300 K:

hH 2O  0.1hO 2  2.256h N 2  198,199  0.179,316   2.256 75,676 

 276,856 kJ Higher than 270,116 kJ  At 2250 K:

hH 2O  0.1hO 2  2.256h N 2  195,562  0.177,397   2.256 73,856 

 269,921 kJ Lower than 270,116 kJ  By interpolation,

T P = 2251.4 K

15-44

15-71 EES Problem Problem 15-70 15-70 is reconsi reconsidere dered. d. This problem problem is to be modifie modified d to include include the fuels butane butane,, ethane, methane, methane, and propane propane as well as as H2; to include the effects of inlet air and fuel temperatures; temperatures; and the percent theoretical air supplied. Analysis The problem problem is solved solved using EES, EES, and the solution solution is given given below.

Adiabatic Combustion of fuel CnHm entering at T_fuel with Stoichiometric Air at T_air: Reaction: CxHy + (y/4 + x) (Theo_air/100) (O2 + 3.76 N2) <--> xCO xCO2 2 + (y/2) H2O + 3.76 (y/4 + x) x) (Theo (Theo_air/ _air/100) 100) N2 + (y/4 + x) x) (Theo_ (Theo_air/1 air/100 00 - 1) 1) O2 O2 T_prod is the adiabatic combustion combustion temperature, assuming assuming no dissociation. Theo_air is the % theoretical theoretical air. " "The initial guess value of T_prod = 450K ." Procedure Fuel(Fuel$:x,y,Name$) Fuel(Fuel$:x,y,Name$) "This procedure takes the fuel name and returns the moles of C and moles moles of H" If fuel$='C2H fuel$='C2H6' 6' then x=2;y=6 Name$='ethane' else Product temperature vs % theoretical air for hydrogen If fuel$='C3H fuel$='C3H8' 8' then 3000 x=3; y=8 Name$='propane' else Calculated point If fuel$='C4H10' then x=4; x=4; y=10 y=10 Name$='butane' 2000 else if fuel$='CH4' then x=1; y=4 d Name$='methane' o r else p 1000 if fuel$='H2' then x=0; y=2 Name$='hydrogen' endif; endif; endif; endif; endif end {"Input data from the diagram window" 0 T_fuel = 280 [K] 100 200 300 400 500 T_air = 280 [K] Theoair [%] Theo_air = 200 "%" Fuel$='H2'} Call Fuel(fuel$:x,y,Name$) Fuel(fuel$:x,y,Name$) HR=enthalpy(Fuel$,T=T_fuel)+ HR=enthalpy(Fuel$,T=T _fuel)+ (y/4 + x) *(Theo_air/100) *enthalpy(O2,T=T_air)+3.76*(y/4 *enthalpy(O2,T=T_air)+3.76*(y/4 + x) *(Theo_air/100) *enthalpy(N2,T=T_air) HP=HR "Adiabatic" HP=x*enthalpy(CO2,T=T_prod)+(y/2)*e HP=x*enthalpy(CO2,T=T_prod)+(y/2)*enthalpy(H2O,T=T_prod) nthalpy(H2O,T=T_prod)+3.76*(y/4 +3.76*(y/4 + x)* (Theo_air/100)*enthalpy(N2,T=T_prod)+(y/4 (Theo_air/100)*enthalpy(N 2,T=T_prod)+(y/4 + x) *(Theo_air/100 - 1)*enthalpy(O2,T=T_prod) Moles_O2=(y/4 + x) *(Theo_air/100 - 1) Moles_N2=3.76*(y/4 + x)* (Theo_air/100) Moles_CO2=x; Moles_H2O=y/2 T[1]=T_prod; xa[1]=Theo_air "arr "array ay variable variable are plotted plotted in Plot Window Window 1" Theoair [%] 100 144.4 188.9 233.3 277.8 322.2 366.7 411.1 455.6 500

Tprod [K] 2512 2008 1693 1476 1318 1197 1102 1025 960.9 907.3

15-45

15-72E Hydrogen is burned with 20 percent excess air during a steady-flow steady-flow combustion process. process. The exit temperatu temperature re of product product gases is to be determ determined. ined. Assumptions 1 Steady operating conditions exist. 2 Air and combustion combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and potential energies are negligible. 4 There are no work interactions. 5 The combustion chamber is adiabatic. Analysis Adiabatic flame temperature is the temperature at which the products leave the combustion chamber chamber under under adiabati adiabaticc conditions conditions (Q = 0) with with no work work inte intera ract ctio ions ns (W (W = 0). Under steady-flow conditions the energy balance Ein  Eout   Esyst em applied on the combustion chamber reduces to

 N h



P f

 h  h  P 

 N h R



f

 h  h  R

H2 40F

The combustion combustion equation equation of H2 with 20% excess excess air air is

  H 2O  0.1O2  2.256N2 H 2  0.6O2  3.76N 2  

Air

Combustion chamber

Products T P


From the tables,

Substance

H2 O2 N2 g ) H2O ( g

h f 

h 500 R

h 537 R

Btu/lbmol 0 0 0 -104,040

Btu/lbmol 3386.1 3466.2 3472.2 3962.0

Btu/lbmol 3640.3 3640.3 3725.1 3729.5 4258.0

Thus,

1 104,040  hH O  4258  0.10  hO  3725.1  2.2560  h N  3729.5  10  3386.1  3640.3  0.6 0  3466.2  3725.1  2.256 0  3472.2  3729.5  2

It yields

2

2

hH 2O  0.1hO 2  2.256h N 2  116,094 Btu

The adiabatic adiabatic flame flame temperatur temperaturee is obtained obtained from a trial trial and error solution solution.. A first guess guess is obtained obtained by dividing the right-hand side of the equation by the total number number of moles, moles, which yields 116,094/(1 + 0.1+ 2.256) = 34,593 Btu/lbmol. Btu/lbmol. This enthalpy enthalpy value corresponds to about 4400 R for N2. Noting Noting that that the majority of the moles are N2, T P will be close to 4400 R, but somewhat under it because of the higher specific heat of H2O. At 4020 R:

hH 2O  0.1hO 2  2.256h N 2  140,740  0.132,989   2.256 31,503

 115,110 Btu Lower than 116,094 Btu  At 4100 R:

hH 2O  0.1hO 2  2.256h N 2  141,745  0.133,722   2.256 32,198 

 117,756 Btu Higher than 116,094 Btu  By interpolation,

T P = 4054 R

15-46

15-73 Acetylene gas is burned with 30 percent excess air during a steady-flow combustion process. The exit temperatu temperature re of product product gases is to be determined. determined.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 There are no work interactions. Analysis The fuel is burned burned comple completely tely with with the excess excess air, air, and thus thus the the products products will contain contain only CO CO2, H2O, N2, and some free O 2. Cons Consid ider erin ing g 1 kmol kmol of of C2H2, the combustion combustion equation can can be written as

  2CO2  H 2O  0.3ath O2  1.33.76ath N 2 C 2 H 2  1.3ath O2  3.76N 2   where ath is the stoichiometric coefficient and is determined from the O2 balance, 1.3a th  2  0.5  0.3a th

 

75,000 kJ/kmol

C2H2

ath  2.5

25C Air

Thus, C2 H 2  3.25O 2  3.76N 2     2CO2  H 2O  0.75O2  12.22N2

Combustion chamber

Products T P


Under steady-flow steady-flow conditions the energy balance Ein  Eout   Esyst em applied applied on the combustio combustion n chamber chamber with W = reduces es to W = 0 reduc

 Qout 

 N h



P f

 h  h  P 

 N h R



f

 h  h  R

Assuming Assuming the air and and the combu combustion stion products products to be be ideal ideal gases, gases, we haveh have h = h(T ). ). From From the tables tables,, Substance

C2H2 O2 N2 H2O ( g g ) CO2

h f 

h 298 K

h 300 K

kJ/kmol 226,730 0 0 -241,820 -393,520

kJ/kmol --8682 8669 9904 9364

kJ/kmol --8736 8723 -----

Thus,

 75,000  2 393,520  hCO 2  9364  1 241,820  hH 2O  9904

 0.750  hO2  8682  12.220  h N 2  8669  1226,730   3.250  8736  8682  12.22 0  8723  8669 

2hCO 2  hH2O  0.75hO 2  12.22hN 2  1,321,184 kJ

It yields

The temperature of the product gases gases is obtained from a trial and error solution. A first guess is obtained by dividing the the right-hand side of the equation by the total number of moles, moles, which yields 1,321,184/(2 + 1 + 0.75 + 12.22) 12.22) = 82,729 82,729 kJ/kmol. kJ/kmol. This enthalpy enthalpy value value corresp corresponds onds to about 2500 2500 K for N2. Noting that the majority of the moles are N 2, T P will be close to to 2500 K, but somewhat somewhat under under it it because because of the higher higher specific heats of CO2 and H2O. At 2350 K: 2hCO2  hH 2 O  0.75hO 2  12.22h N 2  2 122,091  1100,846   0.75 81,243  12.22 77,496 

 1,352,961 kJ Higher than 1,321,184 kJ  At 2300 K: 2hCO2  hH 2 O  0.75hO 2  12.22h N 2  2 119,035  198,199   0.7579,316   12.22 75,676 

 1,320,517 kJ Lower than 1,321,184 kJ  By interpolation,

T P = 2301 K

15-47

15-74 A mixture of hydrogen and the stoichiometric amount of air contained in a constant-volume tank is ignited. The final temperature in the tank is to be determined. Assumptions 1 The tank is adiabatic. 2 Both the reactants and products are ideal gases. 3 There are no work interactions. 4 Combustion is complete.

combustion n equation of H2 with stoichiometric amount of air is Analysis The combustio H 2  0.5O2  3.76N 2     H 2O  1.88N2

H2, AIR

The final temperature temperature in the tank is determined determined from the energy balance relation Ein  Eout   Esyst em for reacting closed systems under

25C, 1 atm

adiabatic adiabatic conditions conditions (Q = 0) with no work interac interactions tions (W (W = = 0),

 N h P



f

 h  h   P v  P 

 N h R



f

T P

 h  h   P v  R

Since both the reactants and the products behave behave as ideal gases, gases, all the internal energy and enthalpies enthalpies depend on temperature only, and the P v terms terms in this equation equation can be replaced replaced by RuT . It yields

 N h P



f

 hT P  h298 K  Ru T P 

 N h R T 

R

f

u

R

since the reacta reactants nts are at the standard standard referen reference ce temperatu temperature re of 25°C. From the tables, tables,

Substance

H2 O2 N2 H2O ( g g )

h f 

h 298 K

kJ/kmol 0 0 0 -241,820

kJ/kmol 8468 8682 8669 9904

Thus,

1 241,820  hH O  9904  8.314  T P   1.880  h N  8669  8.314  T P   10  8.314  298  0.50  8.314  298  1.88 0  8.314  298  2

It yields

2

hH 2 O  1.88hN 2  23.94  T P  259,648 kJ

The temperature of the product gases is obtained from a trial and error solution, At 3050 K:

hH 2O  1.88h N 2  23.94  T P  1139,051  1.88103,260   23.94 3050 

 260,163 kJ Higher than 259,648 kJ  At 3000 K:

hH 2O  1.88h N 2  23.94  T P  1136,264  1.88101,407   23.94 3000 

 255,089 kJ Lower than 259,648 kJ  By interpolation,

T P = 3045 K

15-48

15-75 Octane gas is burned with 30 percent excess air during a steady-flow steady-flow combustion process. process. The exit temperatu temperature re of product product gases is to be determ determined. ined. Assumptions 1 Steady operating conditions exist. 2 Air and combustion combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and potential energies are negligible. 4 There are no work interactions. 5 The combustion chamber is adiabatic. Analysis Under steady-flow conditions the energy balance Ein  Eout   Esyst em applied on the combustion

chambe chamberr with with Q = W = reducess to W = 0 reduce

 N h P



f

 h  h   P 

 N h R



f

 h  h   R   

 N h P



f

 h  h   P 

 N h



R f , R

since all the reactants reactants are at the standard standard reference reference temperat temperature ure of 25°C. Then, C8 H18 g   1.3ath O 2  3.76N2     8CO2  9H 2O  0.3ath O2  1.33.76 ath N 2 where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, 1.3a th  8  4. 4.5  0. 0.3a th

 

ath  12.5

  8CO 2  9H 2 O  3.75O 2  61.1N 2 Thus, C 8 H 18 g   16.25O 2  3.76N 2   Therefore, 16.254.76 4.76 = 77.35 77.35 kmol kmol of dry air will will be be used used per kmol of the fuel. The partial partial pressure of the water water vapor present in the incoming air is P v ,in   air P sat @ 25C  0.60 3.1698 kPa   1.902 kPa

C8H18 25C Air

Assuming ideal gas behavior, the number of moles of the moisture that accompanies 77.35 kmol of incoming dry air is determi determined ned to be

Combustion chamber

Products T P


 P v,in   1.902 kPa       N v,in  1.48 kmol  P  N total   101.325 kPa 77.35  N v,in      total 

N v ,in  

The balanced balanced combustion combustion equation equation is obtained obtained by adding 1.48 kmol of H2O to both sides of the equation,

  8CO2  10.48H2O  3.75O2  61.1N2 C8 H18 g   16.25O2  3.76N 2   1.48H2O  From the tables, Substance

C8H18 ( g ) O2 N2 g ) H2O ( g CO2 Thus,

h f 

h 298 K

kJ/kmol -208,450 0 0 -241,820 -393,520

kJ/kmol --8682 8669 9904 9364

8 393,520  hCO  9364  10.48 241,820  hH O  9904  3.750  hO  8682  61.10  h N  8669  1 208,450  1.48 241,820   0  0 2

2

2

2

It yields

8hCO 2  10.48hH 2O  3.75hO 2  61.1h N 2  5,857,029 kJ

The adiabatic adiabatic flame flame temperatur temperaturee is obtained obtained from a trial trial and error solution solution.. A first guess guess is obtained obtained by dividing dividing the right-hand right-hand side side of the equation equation by the total number number of moles, moles, which yields 5,857,02 5,857,029/(8 9/(8 + 10.48 + 3.75 + 61.1) = 70,287 kJ/kmol. kJ/kmol. This enthalpy value corresponds to about 2150 K for N2. Noting that that the major majority ity of of the moles moles are are N2, T P will be close to 2150 K, but somewhat under it because of the higher specific heat of H2O. At 2000 K: 8hCO 2  10.48hH 2O  3.75hO 2  61.1h N 2  8100,804  10.4882,593  3.75 67,881  61.164,810   5,886,451 kJ Higher than 5,857,029 kJ  At 1980 K: 8hCO 2  10.48hH 2O  3.75hO 2  61.1h N 2  899,606  10.4881,573  3.75 67,127   61.164,090   5,819,358 kJ Lower than 5,857,029 kJ  By interpolation,

T P = 1991 K

15-49

15-76 EES Problem 15-75 is reconsidered. reconsidered. The effect of the relative humidity humidity on the exit temperature of the product product gases is is to be investiga investigated. ted. Analysis The problem problem is solved solved using EES, EES, and the solution solution is given given below.

"The percent excess excess air and relative humidity are input by the diagram diagram window." {PercentEX = 30"[%]"} {RelHum=60"[%]"} "Other input data:" Fuel$ = 'Octane (C8H18)' T_fuel = (25+273) "[K]" Ex = PercentEX/100 "[%Excess air/100]" P_air1 = 101.3 [kPa] T_air1 = 25+273 "[K]" RH_1 = RelHum/100 M_air = 28.97 [kg/kmol] M_water = 18 [kg/kmol] M_C8H18=(8*12+18*1) "[kg/kmol]" "For theoretical dry air, the complete complete combustion equation is" is" "C8H18 + A_th(O2+3.76 N2)=8 N2)=8 CO2+9 H2O + A_th (3.76) N2 " A_th*2=8*2+9*1 "theoretical O balance" "now to find the amount of water vapor associated with the dry air" w_1=HUMRAT(AirH2O,T=T_air1,P=P_ w_1=HUMRAT(AirH2O,T=T_air1,P=P_air1,R=RH_1) air1,R=RH_1) "Humidity ratio, kgv/kga" N_w=w_1*((1+Ex)*A_th*4.76*M_air)/M_water"Moles N_w=w_1*((1+Ex)*A_th*4.76*M_air)/M_water "Moles of water in the atmoshperic air, kmol/kmol_fuel" "The balanced combustion equation with with Ex% excess moist moist air is" "C8H18 + (1+EX)[A_th(O2+3.76 N2)+N_w N2)+N_w H2O]=8 CO2+(9+N_w) H2O + (1+Ex) (1+Ex) A_th (3.76) N2+ Ex( A_th) O2 " "Apply First Law SSSF" H_fuel = -208450 [kJ/kmol] "from Table A-26" HR=H_fuel+ (1+Ex)*A_th*enthalpy(O2,T=T_air1)+(1+Ex (1+Ex)*A_th*enthalpy(O2,T=T_air1)+(1+Ex)*A_th*3.76 )*A_th*3.76 *enthalpy(N2,T=T_air1)+N_w*enthalpy(H2O,T=T_air1) HP=8*enthalpy(CO2,T=T_prod)+(9+N_w)* HP=8*enthalpy(CO2,T=T_prod)+(9+N_w)*enthalpy(H2O,T=T_prod) enthalpy(H2O,T=T_prod)+(1+Ex)*A_th*3.76* +(1+Ex)*A_th*3.76* enthalpy(N2,T=T_prod)+Ex*A_th*enthalpy(O2,T=T_prod) "For Adiabatic Combustion:" HP = HR "This solution used used the humidity ratio form psychrometric psychrometric data to determine the moles of water vapor in atomspheric air. One should calculate the moles moles of water contained contained in the atmospheric air by the the method shown in Chapter 14, which uses the relative humidity to find the partial pressure of the water vapor and, thus, the moles of water vapor. Explore what happens to the results as you vary the percent excess air, relative humidity, and product temperature. " RelHum [%] 0 10 20 30 40 50 60 70 80 90 100

Tprod [K] 2024 2019 2014 2008 2003 1997 1992 1987 1981 1976 1971

2030

Adiabatic Flame Temperature for 30% Excess air

2020 2010 2000 1990

d o r p

1980 1970 1960 1950 0

20

40

60

RelHum [%]

80

100

15-50

Entropy Change and Second Second Law Analysis of Reacting Systems Systems 15-77C Assuming the system exchanges heat with the surroundings at T 0, the increase-in-entropy principle can be express expressed ed as

Sgen 

N

Ps P 

N s

R R

Qout T 0

15-78C By subtracting Rln( P P / P P 0) from the tabulated value at 1 atm. Here P Here P is is the actual actual pressur pressuree of the substance and P 0 is the atmospheric pressure. 15-79C It represent representss the reversi reversible ble work associ associated ated with the forma formation tion of that compound. compound.

15-80 Hydrogen is burned steadily with oxygen. The reversible reversible work and exergy destruction destruction (or irreversibility) are to be determined. determined. Assumptions 1 Combustion is complete. 2 Steady operating conditions exist. 3 Air and the combustion gases are are ideal gases. gases. 4 Changes Changes in kinetic kinetic and potential potential energies energies are negligible. negligible.

H 2  0.5O 2   H 2 O.

Analysis The combustion equation is

The H2, the O2, and the H2O are are at at 25C and 1 atm, which which is the standard standard referenc referencee state and also the the state of the surroundings. surroundings. Therefore, the reversible work in this case is simply the difference difference between the Gibbs function of formation of the reactants reactants and that of the products, products, W rev 



N R g f  , R 



N P g f  , P  N H 2 g f  , H 2

0

 N O2 g f  ,O 2

0

 N H 2 O g f  , H 2O   N H 2O g f  , H 2O

 1 kmol 237,180 kJ/kmol  237,180 kJ (per kmol of H 2 )  since the g f of stable elements at 25C and 1 atm atm is zero. zero. There Therefor fore, e, 237,18 237,180 0 kJ kJ of of work work could could be done done as as

1 kmol kmol of H2 is burn burned ed with with 0.5 0.5 kmol kmol of O2 at 25C and 1 atm in an environment at the same state. The reversible work in this case case represents the exergy of the reactants since the product (the H2O) is at the state of the surroundings. This process process involve involvess no actual actual work. work. Therefor Therefore, e, the the revers reversible ible work and exergy exergy destructi destruction on are are identical, X destruction destruction = 237,180 kJ

(per (per kmol kmol of H2)

We could also determine determine the reversible reversible work without without involving involving the Gibbs function, function,

 N h   N h

W rev 



R

f

R

f



 h  h   T 0 s  R   T 0 s  R 

 N h

 N h



P f



P f

 T 0 s  P

 h  h   T 0 s  P

 N H 2 h f   T 0 s  H  N O 2 h f   T 0 s  O  N H 2O h f   T 0 s  H 2

2

2O

Substituting, W rev  10  298  130.58  0.50  298  205.03  1285,830  298  69.92   237,204 kJ which is almost almost identical to the result result obtained before.

15-51

15-81 Ethylene gas is burned steadily with 20 percent excess air. The temperature temperature of products, the entropy generation, generation, and the exergy destruction destruction (or irreversi irreversibility bility)) are to be determine determined. d. Assumptions 1 Combustion is complete. 2 Steady operating conditions exist. 3 Air and the combustion gases are are ideal gases. gases. 4 Changes Changes in kinetic kinetic and potential potential energies energies are negligible. negligible. is burned burned complete completely ly with the the excess excess air, air, and thus thus the products products will contain contain only CO2, Analysis (a) The fuel is H2O, N2, and some free O 2. Cons Consid ider erin ing g 1 kmol kmol of of C2H4, the combustion combustion equation can can be written as

  2CO2  2H 2O  0.2ath O 2  1.2 3.76 ath N 2 C2 H 4 g   1.2ath O2  3.76N2   where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, 1.2a th  2  1  0.2ath Thus,

 

ath  3

  2CO2  2H 2O  0.6O2  13.54N 2 C2 H 4  g   3.6O 2  3.76N 2  

Under steady-flow conditions, the exit temperature of the product gases can be determined from the steadysteadyflow energy energy equatio equation, n, which reduces reduces to

 N h



P f

 h  h  P 

 N h



R f , R

  N h f 

C2H 4

since all all the reactants reactants are are at the standard standard refere reference nce state, state, and for O2 and N2. From the tables,  h 298 K h f Substance C2H4 kJ/kmol kJ/kmol g ) C2H4 ( g 52,280 --25C Combustion O2 0 8682 chamber Air N2 0 8669 H2O ( g -241,820 9904 g ) 20% excess air CO2 -393,520 9364 25C Substituting,

Products T P

2 393,520  hCO  9364  2 241,820  hH O  9904  0.60  hO  8682  13.540  h N  8669  152,280 2

2

2

2

2hCO 2  2hH 2O  0.6hO 2  13.54h N 2  1,484,083 kJ

or,

By trial and error, T P = 2269.6 K (b) The entropy entropy genera generation tion during during this adiabati adiabaticc process process is determ determined ined from Sgen  S P  S R 

N

Ps P 

N

Rs R

The C2H4 is at 25C and 1 atm, atm, and and thus thus its absolu absolute te entrop entropy y is is 219.83 219.83 kJ/km kJ/kmol· ol·K K (Table (Table A-26). A-26). The entropy entropy values values listed in the ideal ideal gas gas tables tables are are for 1 atm pressure pressure.. Both the the air and the product product gases are at a total pressure pressure of 1 atm, atm, but the entropies entropies are to be calculated calculated at the partial partial pressure pressure of the componen components ts y i which is equal equal to P i = yi P total , where is the mole fraction frac tion of compo c omponent nent . Also, total i



S i  N i s i T , P i   N i s i T , P 0   Ru ln y i P m  The entropy entropy calculations calculations can be presented presented in tabular form form as  Ni yi s i T,1atm  C2H4 O2 N2

1 3.6 13.54

1.00 0.21 0.79

219.83 205.14 191.61

CO2 H2O O2 N2

2 2 0.6 13.54

0.1103 0.1103 0.0331 0.7464

316.881 271.134 273.467 256.541

R u lny i Pm 

N i si

--219.83 -12.98 784.87 -1.96 2620.94 3625.6 .64 4 kJ/K kJ/K S R = 3625 -18.329 670.42 -18.329 578.93 -28.336 181.08 -2.432 3506.49 S P = 4936 4936.9 .92 2 kJ/K kJ/K

Thus, S gen  S P  S R  4936.92  3625.64  1311.28 kJ/kmol  K and (c (c) X destroyed  T 0 S gen  298 K 1311.28 kJ/kmol  K C 2 H 4   390,760 kJ  per kmol C 2 H 4 

15-52

15-82 Liquid octane is burned steadily with 50 percent excess air. The heat transfer rate from the combustion combustion chambe chamber, r, the entropy entropy generation generation rate, rate, and the reversib reversible le work and exergy exergy destruction destruction rate are are to be determined. Assumptions 1 Combustion is complete. 2 Steady operating conditions exist. 3 Air and the combustion gases are are ideal gases. gases. 4 Changes Changes in kinetic kinetic and potential potential energies energies are negligible. negligible. Analysis (a) The fuel is burned burned completely completely with the excess excess air, and thus thus the the products products will contain contain only CO2, H2O, N2, and some some free free O2. Considering 1 kmol C8H18, the combustio combustion n equation equation can be written written as

  8CO2  9H 2O  0.5ath O 2  1.53.76ath N 2 C8 H18    1.5ath O 2  3.76N 2   where ath is the stoichiom stoichiometric etric coeffi coefficient cient and is determ determined ined from the the O2 balance, 1.5a th  8  4. 4.5  0. 0.5ath

 

ath  12.5

Thus,

  8CO2  9H 2O  6.25O2  70.5N 2 C8 H18    18.75O 2  3.76N 2   Under steady-flow conditions the energy balance Ein  Eout   Esyst em applied on the combustion chamber W = 0 reduces to with W =

 Qout 

 N h P



f

h h

P



 N h R



f

h h

R



 N h

P f , P  

 N h



R f , R

since all of the reactants are at 25°C. Assuming the air and the combustion combustion products to be ideal gases, we have h = h(T ). ). From the tables, tables, T 0 = 298 K

h f 

Substance

kJ/kmol -249,950 0 0 -285,830 -393,520

C8H18 () O2 N2 H2O (l (l ) CO2

 Q

C8H18 () 25C Air

Combustion chamber

Products 25C


Substituting, or

Qout  8393,520  9285,830  0  0  1249,950  0  0  5,470,680 kJ/kmol of C8H18 Qout  5,470,680 kJ/kmol of C 8 H 18

The C8H18 is burned burned at a rate of 0.25 0.25 kg/min kg/min or   N

Thus,

 m

M



0.25 kg/min

812  181 kg/kmol



 2.193  10 3 kmol/min



3 Q Q out  N kmol/min 5,470,680 kJ/kmol  11,997 kJ/min out  2.193  10

The heat transf transfer er for this this process process is also also equivale equivalent nt to the enthalpy enthalpy of combu combustion stion of liquid liquid C8H18, which could easily be de determined from from Table A-27 A-27 to be hC = 5,470,740 5,470,740 kJ/kmol kJ/kmol C8H18.

15-53

(b) The entrop entropy y generati generation on during during this this proces processs is determi determined ned from from S gen  S P  S R 

Qout T surr

   S gen 

 N s   N s P P

R R



Qout T surr

The C8H18 is at 25°C and and 1 atm, and thus thus its absolute entropy is s C8H18 = 360.79 kJ/kmol. kJ/kmol.K K (Table A-26). A-26). The entropy entropy values values listed listed in the ideal ideal gas tables tables are for 1 atm pressure pressure.. Both the air air and and the the product product gases are at a total total press pressure ure of 1 atm, atm, but but the entrop entropies ies are to be calc calcula ulated ted at the the par partia tiall press pressure ure of the the component componentss which is equal equal to P i = yi P total fraction of compon component ent i. Also, total, where yi is the mole fraction



S i  N i s i T , P i   N i s i T , P 0   Ru ln y i P m  The entropy entropy calculations calculations can be presented presented in tabular form form as Ni

yi

s i T,1atm 

C8H18 O2 N2

1 18.75 70.50

1.00 0.21 0.79

360.79 205.14 191.61

CO2 H2O () O2 N2

8 9 6.25 70.50

0.0944 --0.0737 0.8319

213.80 69.92 205.04 191.61



R u lny i Pm 

N i si

--360.79 -12.98 4089.75 -1.96 13646.69 18,097 97.2 .23 3 kJ/K kJ/K S R = 18,0 -19.62 1867.3 --629.3 -21.68 1417.6 -1.53 13,616.3 S P = 17,531 kJ/K

Thus, S gen  S P  S R  and



Qsurr T surr

 17,531  18,097 

5,470,523 kJ 298 K

 17,798 kJ/kmol  K



3   kmol/min 17,798 kJ/kmol  K   39.03 kJ/min  K S gen  N S gen  2.193  10

(c) The exergy exergy destruct destruction ion rate associ associated ated with with this process process is determin determined ed from from   X destroyed  T 0 S gen  298 K 39.03 kJ/min  K   11,632 kJ/min  193.9 kW

15-54

15-83 Acetylene gas is burned steadily with 20 percent excess air. The temperature of the products, the total entrop entropy y change, change, and and the exergy exergy destruction destruction are to to be determined determined.. Assumptions 1 Combustion is complete. 2 Steady operating conditions exist. 3 Air and the combustion gases are are ideal gases. gases. 4 Changes Changes in kinetic kinetic and potential potential energies energies are negligible. negligible. Analysis (a) The fuel is is burned burned complete completely ly with the the excess excess air, air, and thus thus the products products will contain contain only CO2, H2O, N2, and some free O 2. Cons Consid ider erin ing g 1 kmol kmol C2H2, the combustion equation can be written as

C 2 H 2  g   1.2ath O 2  3.76N 2     2CO 2  H 2O  0.2ath O 2  1.2 3.76 ath N 2

where ath is the stoichiom stoichiometric etric coeffi coefficient cient and is determ determined ined from the the O2 balance, 1.2ath  2  0.5  0.2a th

 

300,000 kJ/kmol

ath  2.5

Substituting,

C2H2

C 2 H 2 g   3O 2  3.76N 2     2CO 2  H 2 O  0.5O 2  11.28N 2

25C Air

Under steady-flow conditions the exit temperature of the product gases can be determined determined from the energy energy balance Ein  Eout   Esyst emapplied on the

Combustion chamber

Products T P


combustion combustion chamber, chamber, which which reduces reduces to

 Qout 

 N h P



f

 h  h  P 

 N h



R f , R



 N h P



f

 h h

P

  N h f 

C2H 2

since all the reactants are at the standard reference state, and h f  = 0 for O2 and N2. From the tables, tables,

Substance

C2H2 ( g g ) O2 N2 H2O ( g g ) CO2

h f 

h 298 K

kJ/kmol 226,730 0 0 -241,820 -393,520

kJ/kmol --8682 8669 9904 9364

Substituting,

 300,000  2 393,520  hCO 2  9364  1 241,820  hH 2O  9904

 0.50  hO 2  8682  11.280  h N 2  8669  1226,730

or,

2hCO 2  hH 2O  0.5hO 2  11.28h N 2  1,086,349 kJ

By trial and error,

T P = 2062.1 K

(b) The entropy entropy generation generation during during this process process is determine determined d from S gen  S P  S R 

Qout T surr



 N s   N s P P

R R



Qout T surr

The C2H2 is at 25°C and 1 atm, and thus its absolute entropy is s C2 H 2  200.85 kJ/kmol  K (Table A-26). The entropy entropy values values listed listed in the ideal ideal gas tables tables are for for 1 atm pressure. pressure. Both the the air and and the product product gases are at a total total press pressure ure of 1 atm, atm, but but the entrop entropies ies are to be calc calcula ulated ted at the the par partia tiall press pressure ure of the the component componentss which is equal equal to P i = yi P total fraction of compon component ent i. Also, total, where yi is the mole fraction S i  N i si T , P i   N i si T , P 0   Ru ln  yi P m 

15-55

The entropy entropy calculations calculations can be presented presented in tabular form form as Ni

yi

s i T,1atm

C2H2 O2 N2

1 3 11.28

1.00 0.21 0.79

200.85 205.03 191.502

CO2 H2O O2 N2

2 1 0.5 11.28

0.1353 0.0677 0.0338 0.7632

311.054 266.139 269.810 253.068

R u lny i Pm 

N i si

--200.85 -12.98 654.03 -1.96 2182.25 3037.1 .13 3 kJ/K kJ/K S R = 3037 -16.630 655.37 -22.387 288.53 -28.162 148.99 -2.247 2879.95 3972.8 .84 4 kJ/K kJ/K S P = 3972

Thus, S gen  S P  S R 

Qsurr T surr

 3972.84  3037.13 

300,000 kJ 298 K

 1942.4 kJ/kmol  K

(c) The exergy exergy destruct destruction ion rate associ associated ated with with this process process is determin determined ed from from X destruction  T 0 S gen  298 K 1942.4 kJ/kmol  K   578,835 kJ  per kmol C 2 H 2 

15-56

15-84 CO gas is burned steadily with air. The heat transfer transfer rate from the combustion combustion chamber chamber and the rate of exergy exergy destruction destruction are are to be determine determined. d. Assumptions 1 Combustion is complete. 2 Steady operating conditions exist. 3 Air and the combustion gases are are ideal gases. gases. 4 Changes Changes in kinetic kinetic and potential potential energies energies are negligible. negligible.

molar masses masses of CO and and air are 28 kg/kmol kg/kmol and 29 kg/kmol, kg/kmol, respectivel respectively y (Table (Table A-1). Properties The molar Analysis (a) We first first need need to calculate calculate the the amount amount of air air used used per kmol kmol of CO before we can write the combustion equation, equation, v CO



 CO  m

RT P

0.2968 kPa  m 

3



/kg  K 310 K 

110 kPa

 V CO

0.4 m 3 /min



v CO

0.836 m 3 /kg

800 K

 0.836 m /kg

N air N fuel



 air / M air m  fuel / M fuel m



CO 37C

 0.478 kg/min

110 kPa

Air

Products 900 K

25C

Then the molar molar air-fue air-fuell ratio becomes becomes AF 

 Q

3

1.5 kg/min / 29 kg/kmol  3.03 kmol air/kmol fuel 0.478 kg/min / 28 kg/kmol

Thus Thus the numb number er of moles moles of O2 used per mole mole of CO is 3.03/4.76 3.03/4.76 = 0.637. Then the combustio combustion n equation equation in this case case can be written written as

  CO 2  0.137O 2  2.40N 2 CO  0.637O 2  3.76N 2   Under steady-flow steady-flow conditions the energy balance Ein  E out   E system applied applied on the combustion combustion chamber chamber with W = W = 0 reduces to

 Qout 

 N



P h f

 h  h  P 

 N

R

h f   h  h 

R


Substance

CO O2 N2 CO2

h f 

h 298 K

h 310 K

h 900 K

kJ/kmol -110,530 0 0 -393,520

kJ/kmol 8669 8682 8669 9364

kJ/kmol 9014 -------

kJ/kmol --27,928 26,890 37,405

Substituting,

Qout  1393,520  37,405  9364   0.137 0  27,928  8682   2.4 0  26,890  8669   1 110,530  9014  8669   0  0  208,929 kJ/kmol of CO Thus 208,929 208,929 kJ of heat heat is transferr transferred ed from the the combustion combustion chamber chamber for for each kmol kmol (28 kg) of CO. This corres correspon ponds ds to 208,92 208,929/2 9/28 8 = 7462 kJ of heat heat transf transfer er per kg of CO. CO. Then Then the rate rate of heat heat trans transfe ferr for a mass mass flow rate of 0.478 kg/min kg/min for CO becomes becomes  q out  0.478 kg/min 7462 kJ/kg   3567 kJ/min Q out  m

15-57

(b) This process process involves involves heat transfer transfer with with a reservoir reservoir other than than the surround surroundings. ings. An exergy exergy balance balance on the combusti combustion on chamber chamber in this this case case reduces reduces to the following following relation relation for reversib reversible le work, work, W rev 

 N

R

h f   h  h   T 0 s

R

 N



 h  h   T 0 s P  Qout 1  T 0 / T R 



P h f

The entropy values listed listed in the ideal gas tables are are for 1 atm = 101.325 kPa pressure. The entropy of each each reactant and the product is to be calculated at the partial pressure of the components components which is equal toP to P i = 110/101.325 5 = 1.0856 1.0856 atm. atm. Also, yi P total total, where yi is the mole fraction of component i, and P m = 110/101.32





S i  N i s i T , P i   N i s i T , P 0   Ru ln y i P m 

The entropy entropy calculations calculations can be presented presented in tabular tabular form as Ni

yi

s i T,1atm

R u lny i Pm 

CO O2 N2

1 0.637 2.400

1.00 0.21 0.79

198.678 205.04 191.61

0.68 -12.29 -1.28

CO2 O2 N2

1 0.137 2.400

0.2827 0.0387 0.6785

263.559 239.823 224.467

-9.821 -26.353 -2.543

N i si

198.00 138.44 462.94 S R = 799.38 kJ/K 273.38 36.47 544.82 S P = 854.67 kJ/K

The rate of exergy exergy destruction destruction can be determine determined d from





   X destroyed  T 0 S gen  T 0 m S gen / M

where S gen  S P  S R  Thus,

Qout T res

 854.67  799.38 

208,929 kJ 800 K

 316.5 kJ/kmol  K

 X destroyed  298 K 0.478 kg/min 316.5/28 kJ/kmol  K   1610 kJ/min

15-58

15-85E Benzene Benzene gas is burne burned d steadily steadily with with 95 percent percent theoretica theoreticall air. The The heat heat transfer transfer rate rate from from the combustio combustion n chamber chamber and the exergy exergy destruction destruction are are to be determined determined..

Steady operating operating conditio conditions ns exist. exist. 2 Air and the combustion gases are ideal gases. 3 Assumptions 1 Steady Changes Changes in kinetic kinetic and potential potential energies energies are negligible. negligible. Analysis (a) The fuel is burned with insufficient amount amount of air, and and thus the products will contain some CO as well as CO2, H2O, and N2. The theoreti theoretical cal combusti combustion on equation equation of C6H6 is Q

C6 H 6  ath O 2  3.76N 2     6CO 2  3H 2O  3.76 ath N 2

C6H6

where ath is the stoichiometric coefficient and is determine determined d from the O2 balance,

77F Air

a th  6  1.5  7.5

Products

Combustion chamber

1500 R

95% theoretical

Then the actual actual combustion combustion equation equation can be written written as

C6 H 6  0.95 7.5O 2  3.76N 2     xCO 2  6  x CO  3H 2O  26.79N 2

The value value of x of x is determine determined d from an an O2 balance,

0.957.5  x  6  x/2  1.5    x  5.25 Thus, C 6 H 6  7.125O 2  3.76N 2     5.25CO 2  0.75CO  3H 2 O  26.79N 2 Under steady-flow conditions the energy balance Ein  E out   E system applied on the combustion chamber with W = W = 0 reduces to

 Q out 

 N

P

h f   h  h 

P



 N

R

h f   h  h 

R



 N

P

h f   h  h 

P



 N h



R f , R

since all of the reactants are at 77°F. Assuming the air and the combustion products to be ideal gases, we have h = h(T ). ). From the tables,

Substance

C6H6 ( g g ) O2 N2 H2O ( g g ) CO CO2

hf 

h537 R

h1500 R

Btu/lbmol 35,680 0 0 -104,040 -47,540 -169,300

Btu/lbmol --3725.1 3729.5 4258.0 3725.1 4027.5

Btu/lbmol --11,017.1 10,648.0 12,551.4 10,711.1 14,576.0

Thus,

Q out  5.25169,300  14,576  4027.5  0.75 47,540  10,711.1  3725.1  3 104,040  12,551.4  4258   26.79 0  10,648  3729.5   135,680   0  0  1,001,434 Btu/lbmol of C 6 H 6

15-59

(b) The entropy entropy generation generation during during this process process is determine determined d from S gen  S P  S R 

Qout T surr



 N s   N s P P

R R



Qout T surr

The C6H6 is at 77°F and 1 atm, and thus its absolute entropy is sC6H6 = 64.34 Btu/lbmol·R (Table A-26E). The entropy entropy values values listed listed in the ideal ideal gas tables tables are are for 1 atm pressure. pressure. Both the air air and the the product product gases are at a total total pres pressur suree of 1 atm, atm, but but the entrop entropies ies are to be calc calcula ulated ted at the the par partia tiall press pressure ure of the the component componentss which is equal equal to P i = yi P total fraction of component component i. Also, total, where yi is the mole fraction S i  N i s i T , P i   N i s i T , P 0   Ru ln  y i P m  The entropy entropy calculations calculations can be presented presented in tabular form form as Ni

yi

s i T,1atm

R u lny i Pm 

C6H6 O2 N2

1 7.125 26.79

1.00 0.21 0.79

64.34 49.00 45.77

---3.10 -0.47

CO2 CO H2O ( g g ) N2

5.25 0.75 3 26.79

0.1467 0.0210 0.0838 0.7485

61.974 54.665 53.808 53.071

-3.812 -7.672 -4.924 -0.575

N i si

64.34 371.21 1238.77 1674..32 Btu/ Btu/R R S R = 1674 345.38 46.75 176.20 1437.18 2005..51 Btu/ Btu/R R S P = 2005


Qout T surr

 2005.51  1674.32 

 1,001,434 537

 2196.1 Btu/R

Then the exergy destroyed is determined from X destroyed  T 0 S gen  537 R 2196.1 Btu/lbmol  R   1,179,306 Btu/R  per lbmol C 6 H 6 

15-60

15-86 [ Also solved by EES on enclosed CD ] Liquid propane is burned steadily with 150 percent excess air. The mass flow rate rate of air, the heat transfer rate from the combustion combustion chamber, and the rate of entropy generation are are to be determined. Assumptions 1 Combustion is complete. 2 Steady operating conditions exist. 3 Air and the combustion gases are are ideal gases. gases. 4 Changes in kinetic and potential energies are negligible.

molar masses masses of C3H8 and air are 44 kg/kmol and 29 kg/kmol, respectively (Table (Table A-1). A-1). Properties The molar burned comple completely tely with the excess excess air, air, and and thus the produc products ts will contain contain only only CO2, Analysis (a) The fuel is burned H2O, N2, and some free O 2. Cons Consid ider erin ing g 1 kmol kmol of of C3H8, the combustion equation can be written as C3H 8    2.5ath O 2  3.76N 2     3CO 2  4H 2O  1.5ath O 2  2.53.76 ath N 2

where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, 2.5a th  3  2  1.5a th

 

ath  5

Substituting, C3H 8    12.5 O 2  3.76N 2     3CO 2  4H 2O  7.5O 2  47N 2

The air-fuel ratio for this combustion process process is AF  Thus,

mair mfuel



12.5  4.76 kmol29 kg/kmol   39.2 kg air/kg fuel 3 kmol12 kg/kmol  4 kmol 2 kg/kmol

 air  AFm  fuel   39.2 kg air/kg fuel0.4 kg fuel/min  15.7 kg air/min m

(b) Under steadysteady-flow flow conditions conditions the energy energy balance balance Ein  E out   E system applied on the combustion W = 0 reduces to chamber with W =

 Qout 

 N



P h f

 h  h  P 

 N

R

h f   h  h 

R

Assuming Assuming the the air air and and the combustio combustion n products products to be ideal ideal gases, gases, we haveh have h = h(T ). ). From the tables, (The gaseous propane). propane). h f  of liquid propane is obtained by adding the h fg at 25°C to h f  of gaseous

Substance

C3H8 () O2 N2 H2O ( g g ) CO2

h f 

h 285 K

h 298 K

h1200 K

kJ/kmol -118,910 0 0 -241,820 -393,520

kJ/kmol --8296.5 8286.5 -----

kJ/kmol --8682 8669 9904 9364

kJ/kmol --38,447 36,777 44,380 53,848

Thus,

Qout  3393,520  53,848  9364  4241,820  44,380  9904  7.50  38,447  8682  470  36,777  8669  1 118,910  h298  h298   12.50  8296.5  8682  470  8286.5  8669  190,464 kJ/kmol of C 3 H 8 Thus 190,464 kJ of heat is transferred from the combustion combustion chamber for each kmol (44 kg) of propane. This corre correspond spondss to 190,464/ 190,464/44 44 = 4328.7 4328.7 kJ of of heat transfer transfer per per kg of propane. propane. Then Then the rate rate of heat heat transfer transfer for a mass flow flow rate of 0.4 kg/min kg/min for the propane propane becom becomes es  q out  0.4 kg/min 4328.7 kJ/kg   1732 kJ/min Q out  m

15-61

(c) The entrop entropy y generatio generation n during during this process process is is determ determined ined from Sgen  S P  S R 

Qout T surr



N

Ps P 

N

Rs R 

Qout T surr

The C3H8 is at 25°C and 1 atm, and and thus its absolute absolute entropy for for the gas phase is s C3H8  269.91 kJ/kmol·K (Table (Table A-26). A-26). Then Then the entr entropy opy of of C3H8() is obtained from s C3H 8    s C3H8 g   s fg  s C 3H8 g  

h fg T

 269.91 

15,060 298.15

 219.4 kJ/kmol  K

The entropy entropy values values listed listed in the ideal ideal gas tables tables are are for 1 atm pressure. pressure. Both the air air and the the product product gases are at a total total pres pressur suree of 1 atm, atm, but but the the entro entropie piess are are to be calc calcula ulated ted at the the part partial ial pressu pressure re of of the the y i component componentss which is equal equal to P i = yi P total , where is the mole fraction of component . T h e n , total i S i  N i s i T , P i   N i s i T , P 0   Ru ln  y i P m  The entropy entropy calculations calculations can be presented presented in tabular form form as Ni

yi

s i T,1atm

R u lny i Pm 

C3H8 O2 N2

1 12.5 47

--0.21 0.79

219.40 203.70 190.18

---12.98 -1.96

CO2 H2O ( g g ) O2 N2

3 4 7.5 47

0.0488 0.0650 0.1220 0.7642

279.307 240.333 249.906 234.115

-25.112 -22.720 -17.494 -2.236

N i si

219.40 2708.50 9030.58 S R = 11,9 11,958 58.4 .48 8 kJ/K kJ/K 913.26 1052.21 2005.50 11108.50 15,079 79.4 .47 7 kJ/K kJ/K S P = 15,0


Qout T surr

 15,079.47  11,958.48 

190,464 298

 3760.1 kJ/K  per kmol C 3 H 8 

Then the rate of entropy generation generation becomes

 



 0.4  kmol/min 3760.1 kJ/kmol  K   34.2 kJ/min  K  44 

  S gen  N S gen  

15-62

15-87 EES Problem 15-86 is reconsidered. The effect of the surroundings temperature on the rate of exergy destruction destruction is to be studied. studied. Analysis The problem is solved solved using EES, and the solution is given given below.

Fuel$ = 'Propane (C3H8)_liq' T_fuel = (25 + 273.15) "[K]" P_fuel = 101.3 [kPa] m_dot_fuel = 0.4 [kg/min]*Convert(kg/min, kg/s) Ex = 1.5 "Excess air" P_air = 101.3 [kPa] T_air = (12+273.15) "[K]" T_prod = 1200 [K] P_prod = 101.3 101.3 [kPa] [kPa] Mw_air = 28.97 "lbm/lbmol_air" Mw_C3H8=(3*12+8*1) "kg/kmol_C3H8" {TsurrC {Tsu rrC = 25 [C]} [C]} T_surr = TsurrC+273.15 "[K]" "For theoretical dry air, the complete combustion equation is" "C3H8 + A_th(O2+ A_th(O2+3.76 3.76 N2)=3 CO2+4 CO2+4 H2O + A_th (3.76) (3.76) N2 " 2*A_th=3*2+4*1"theoretical 2*A_th=3*2+4*1"theoretical O balance" "The balanced combustion equation with Ex%/100 excess moist air is" "C3H8 + (1+EX)A_th(O2+3.76 N2)=3 CO2+ 4 H2O + (1+Ex) A_th (3.76) N2+ Ex( A_th) A_th) O2 " "The air-fuel ratio on a mass basis is:" AF = (1+Ex)*A_th*4.76*Mw_air/(1*Mw_C3H8) "kg_air/kg_fuel" "The air mass flow rate is:" m_dot_air = m_dot_fuel * AF "Apply First Law SSSF SSSF to the combustion process per kilomole of fuel:" E_in - E_out = DELTAE_cv E_in =HR "Since EES gives the enthalpy of gasesous components, we adjust the EES calculated enthalpy to get the liquid enthalpy. Subtracting the enthalpy of vaporizatio vaporization n from the gaseous enthal enthalpy py gives the enthalpy enthalpy of the the liquid liquid fuel. h_fuel(liq) = h_fuel(gas) - h_fg_fuel" h_fg_fuel = 15060 "kJ/km "kJ/kmol ol from Table Table A-27" A-27" HR = 1*(enthalpy(C3H8, 1*(enthalpy(C3H8, T=T_fuel) T=T_fuel) - h_fg_fuel)+ (1+Ex)*A_th*enthalpy(O2,T=T_air)+(1+Ex)*A_th*3.76 *enthalpy(N2,T=T_air) E_out = HP + Q_out HP=3*enthalpy(CO2,T=T_prod)+4*enthalpy(H2O,T=T_prod)+(1+Ex)*A_th*3.76* enthalpy(N2,T=T_prod)+Ex*A_th*enthalpy(O2,T=T_prod) DELTAE_cv = 0 "Steady-flow requirement" "The heat transfer rate from the combustion combustion chamber is:" Q_dot_out=Q_out"kJ/kmol_fuel" Q_dot_out=Q_out"kJ/kmol_fuel"/(Mw_C3H8 /(Mw_C3H8 "kg/kmol_fuel" "kg/kmol_fuel")*m_dot_fuel )*m_dot_fuel"k "kg/ g/s" s" "k "kW" W" "Entopy Generation due to the combustion process and heat rejection to the surroundings:" "Entopy of the reactants per kilomole of fuel:" P_O2_reac= 1/4.76*P_air "Dalton's law of partial pressures for O2 in air" s_O2_reac=entropy(O2,T=T_air,P=P_O2_reac)

15-63

P_N2_reac= 3.76/4.76*P_air "Dalto "Dalton's n's law of partial pressu pressures res for N2 in air" s_N2_reac=entropy(N2,T=T_air,P=P_N2_reac) s_C3H8_reac=entropy(C3H8, T=T_fuel,P=P_fuel) - s_fg_fuel "Adjust the EES gaseous value by s_fg" "For phase change, s_fg s_fg is given by:" s_fg_fuel = h_fg_fuel/T_fuel SR = 1*s_C3H8_reac + (1+Ex)*A_th*s_O2_reac + (1+Ex)*A_th*3.76*s_N2_reac "Entopy of the products per kilomle of fuel:" "By Dalton's law the partial pressures of the product gases is the product of the mole fraction and P_prod" N_prod = 3 + 4 + (1+Ex)*A_th* (1+Ex)*A_th*3.76 3.76 + Ex*A_th Ex*A_th "total kmol of products" P_O2_prod = Ex*A_th/N_prod*P_prod "Patrial pressure O2 in products" s_O2_prod=entropy(O2,T=T_prod,P=P_O2_prod) P_N2_prod = (1+Ex)*A_th*3.76/N_prod*P_prod "Patrial pressure N2 in products" s_N2_prod=entropy(N2,T=T_prod,P=P_N2_prod) P_CO2_prod = 3/N_prod*P_prod "Patrial pressure CO2 in products" s_CO2_prod=entropy(CO2, T=T_prod,P=P_CO2_prod) P_H2O_prod = 4/N_prod*P_prod "Patrial pressure H2O in products" s_H2O_prod=entropy(H2O, T=T_prod,P=P_H2O_prod) SP = 3*s_CO2_prod + 4*s_H2O_prod 4*s_H2O_prod + (1+Ex)*A_th*3.76*s_N2_prod + Ex*A_th*s_O2_prod "Since Q_out is the heat rejected to the surroundings per kilomole fuel, the entropy of the surroundings is:" S_surr = Q_out/T_surr "Rate of entropy generation:" S_dot_gen S_dot_gen = (SP - SR +S_surr) +S_surr)"kJ/kmol_fuel" "kJ/kmol_fuel"/(Mw_C3H8 /(Mw_C3H8 "kg/kmol_fuel" "kg/kmol_fuel")*m_dot_fuel )*m_dot_fuel"kg/s" "kg/s" "kW/K" X_dot_dest = T_surr*S_dot_gen"[kW]" T_surr*S_dot_gen"[kW]" TsurrC [C] 0 4 8 12 16 20 24 28 32 36 38

Xdest [kW] 157.8 159.7 161.6 163.5 165.4 167.3 169.2 171.1 173 174.9 175.8

177.5

173.5

169.5

[ t s e d

165.5

161.5

157.5 0

5

10

15

20

25

TsurrC [C]

30

35

40

15-64

Review Problems

sample le of a cert certai ain n fluid fluid is bur burne ned d in a bomb bomb calo calori rime mete ter. r. The The hea heatin ting g valu valuee of the the fuel fuel is to to be 15-88 A samp determined. Properties The specifi specificc heat of water water is 4.18 4.18 kJ/kg. kJ/kg.C (Table A-3). Analysis We take the the water as the system, system, which is a closed closed system system,, for which which the energy energy balance balance on the system Ein  Eout   Esyst em with W = W = 0 can be written as

Qin   U or Qin  mcT

 2 kg 4.18 kJ/kg  C 2.5C  20.90 kJ  per gram of fuel Theref Therefore ore,, heat heat transf transfer er per kg of the the fuel fuel would would be be 20,900 kJ/kg fuel. Disregarding the slight energy stored in the gases of the combustion chamber, this value corresp corresponds onds to the heating heating value of the fuel.

WATER 2 kg

Reaction chamber Fuel 1g T = 2.5 C

15-65

15-89E Hydrogen is burned burned with 100 percent excess excess air. The AF ratio and the volume flow rate of air are to be determined. Assumptions 1 Combustion is complete. 2 Air and the combustion combustion gases are are ideal gases. Properties The molar molar masses masses of H2 and air air are are 2 kg/kmol kg/kmol and 29 kg/kmol, kg/kmol, respec respectivel tively y (Table (Table A-1). A-1).

combustio tion n is is com comple plete, te, and thus thus produc products ts will will cont contain ain only only H2O, O2 and N2. The Analysis (a) The combus moisture in the air does not react with anything; it simply shows up as additional H2O in the products. Therefore, for simplicity, we will balance the combustion equation using using dry air, and then add the moisture to both sides sides of the equation equation.. The combusti combustion on equation equation in this case case can be written written as H 2  2ath O 2  3.76N2     H 2O  ath O 2  23.76ath N 2 where ath is the stoichiometric stoichiometric coefficient coefficient for air. It is determined determined from from O2 balance:

2a th  0.5  ath

 

ath  0.5

Substituting,

H 2  O2  3.76N2     H 2O  0.5O2  3.76N2

Therefore, 4.76 lbmol of dry air will be used per kmol of the fuel. fuel. The partial partial pressure pressure of the water vapor present present in the the incoming incoming air air is

 Q

H2 Combustion chamber Air

Products

P = P = 14.5 psia

90F

P v ,in   air P sat @90 F  0.60 0.69904 psi   0.419 psia The number of moles moles of the moisture that accompanies accompanies 4.76 lbmol of incoming dry air (Nv, in) is determined to be

 P v,in   0.419 psia   N total     N v,in  0.142 lbmol  14.5 psia 4.76  N v,in    P     total 

N v ,in  

The balanced balanced combustion combustion equation equation is obtained obtained by substituti substituting ng the coefficie coefficients nts determ determined ined earlie earlierr and adding 0.142 lbmol of H2O to both both sides sides of the equatio equation, n,

  1.142H 2 O  0.5O 2  3.76N 2 H 2  O 2  3.76N 2   0.142H 2 O  The air-fue air-fuell ratio is determ determined ined by taking taking the ratio of the mass mass of the air air to the mass mass of the fuel, fuel, AF 

mair mfuel



4.76 lbmol29 lbm/lbmol  0.142 lbmol18 lbm/lbmol  70.3 lbm air/lbmfuel 1 lbmol2 lbm/lbmol

(b) The mass mass flow rate of H2 is given given to be 10 10 lbm/h. lbm/h. Since we need need 70.3 lbm lbm air air per lbm of H2, the required mass flow rate of air is  air  AFm  fuel   70.3 25 lbm/h   1758 lbm/h m

The mole fractions fractions of water vapor and the dry air in the incoming air are are y H 2O 

N H 2O N total



0.142 4.76  0.142

 0.029 and y dryair  1  0.029  0.971

Thus, M   yM H 2O   yM dryair  0.029 18  0.97129   28.7 lbm/lbmol v  V



RT P



10.73/28.7 psia  ft

3



/lbm  R 550 R 

14.5 psia

 14.18 ft 3 /lbm

 m v  1758 lbm/h 14.18 ft 3 /lbm  24,928 ft 3 /h

15-66

composition ion of a gaseous gaseous fuel is given. given. The fuel fuel is burned with 120 percent percent theoretical theoretical air. air. The 15-90 The composit AF ratio and the volume volume flow rate of air intake are to be determine determined. d. Assumptions 1 Combustion is complete. 2 Air and the combustion combustion gases are are ideal gases.

molar masses masses of C, H2, N2, O2, and air are are 12, 2, 28, 32, and and 29 kg/kmol kg/kmol (Table (Table A-1). A-1). Properties The molar is burned burned comple completely tely with with excess excess air, and and thus thus the products products will will contain contain H2O, CO2, Analysis (a) The fuel is N2, and some free O2. The moisture in the air does not react with anything; it simply shows up as additional H2O in the products. products. Therefor Therefore, e, we can can simply simply balance balance the the combustio combustion n equation equation using dry air, air, and then add the the moistur moisturee to both sides of the the equation equation.. Consideri Considering ng 1 kmol of fuel, fuel, the the combus combustion tion equati equation on can can be written as

0.80CH4  0.15N2  0.05O2   1.2ath O2  3.76N2     xCO 2  yH 2O  0.2ath O 2  z N 2 The unknown coefficients in the above equation are determined determined from from mass mass balances, balances,

80% CH4 15% N2 5% O2

C : 0.80  x

   x  0.80   y  1.6 H : 0.804   2 y  O 2 : 0.05  1.2a th  x  y / 2  0.2a th    a th  1.55   z  7.14 3.76a th  z  N 2 : 0.15  1.2 

air

Combustion chamber

Pr duct

120% theoretical

Next we determine determine the amount of moisture that accompanies accompanies 4.761.2a 1.2ath = 4.761.21.55 1.55 = 8.85 8.85 kmol kmol of dry air. air. The partial partial press pressure ure of the moistur moisturee in the air air is P v ,in   air P sat @30C  0.604.247 kPa   2.548 kPa N v, in) is determined to be The number number of moles moles of the moisture moisture in the air air ( N

 P v,in   2.548 kPa   N total     N v,in  0.23 kmol  100 kPa 8.85  N v,in    P  total    

N v ,in  

The balanced balanced combustion combustion equation equation is obtaine obtained d by substitut substituting ing the coefficie coefficients nts determ determined ined earlie earlierr and adding 0.23 kmol of H2O to both sides of the the equatio equation, n,

0.80CH 4  0.15N 2  0.05O 2   1.86O2  3.76N 2   0.23H 2O    0.8CO 2  1.83H 2O  0.31O 2  7.14N 2 The air-fuel ratio for the this reaction is determined by taking the ratio of the mass of the air to the mass of the fuel, mair  1.864.76kmol29 kg/kmol  0.23 kg 18 kg/kmol  260.9 kg mfuel  0.816   0.1528  0.05 32 kg  18.6 kg and

AF 

mair mfuel



260.9 kg 18.6 kg


(b) The mass mass flow rate of the the gaseou gaseouss fuel fuel is given given to be 2 kg/min. kg/min. Since we need need 14.0 14.0 kg kg air per kg of fuel, the required mass flow rate of air is  air  AFm  fuel   14.0  2 kg/min   28.0 kg/ min m

The mole fractions fractions of water vapor and the dry air in the incoming air are are y H 2O 

N H 2 O N total



0.23 8.85  0.23

 0.025 and y dryair  1  0.025  0.975

Thus, M   yM H 2O  yM dryair  0.02518   0.975 29   28.7 kg/kmol v  V



RT P

8.314/28.7 kPa  m 

3



/kg  K 303 K 

100 kPa

 0.878 m 3 /kg

 m v  28.0 kg/min 0.878 m 3 /kg   24.6 m 3 /min

15-67

15-91 A gaseous gaseous fuel with with a known compositio composition n is burned burned with dry air, and and the volumetric volumetric analysis analysis of products products gases is determi determined. ned. The AF ratio, ratio, the percent percent theoreti theoretical cal air used, used, and and the volume volume flow rate rate of air air are to be determined. Assumptions 1 Combustion is complete. 2 Air and the combustion combustion gases are are ideal gases. Properties The molar molar masses masses of of C, H2, N2, O2, and air are 12, 2, 28, 28, 32, and 29 kg/km kg/kmol, ol, resp respect ective ively ly (Table A-1). Analysis Consideri Considering ng 100 kmol of dry dry products, products, the combustio combustion n equation equation can can be written written as x0.80CH 4  0.15N 2  0.05O 2   a O 2  3.76N 2 

   3.36CO 2  0.09CO  14.91O2  81.64N 2  bH 2O The unknown coefficients x, a, and b are determined from mass balances,

80% CH4 15% N2 5% O2

C : 0.80 x  3.36  0.09    x  4.31 H : 3.2 x  2b

   b  6.90   a  21.54 N 2 : 0.15 x  3.76a  81.64 

Check O

2:

Combustion chamber

Air

3.36 3.36% % CO2 0.09% CO 14.91% O2 81.64% N2



0.05 x  a  3.36  0.045  14.91  b / 2   a  21.54

Thus, 4.310.80CH 4  0.15N 2  0.05O2   21.54O 2  3.76N 2 

   3.36CO 2  0.09CO  14.91O2  81.64N 2  6.9H 2O The combustion combustion equation equation for 1 kmol of fuel fuel is obtaine obtained d by dividing dividing the above equation equation by 4.31, 4.31,

0.80CH 4  0.15N 2  0.05O2   5.0O 2  3.76N 2     0.78CO 2  0.02CO  3.46O 2  18.95N 2  1.6H 2O (a) The air-fuel air-fuel ratio ratio is determined determined from from its definition, definition, AF 

mair mfuel



5.0  4.76 kmol29 kg/kmol 0.8  16  0.15  28  0.05  32


(b) To find find the percent percent theore theoretical tical air air used, used, we need need to know the theoreti theoretical cal amount amount of air, air, which which is determine determined d from the theoretica theoreticall combustion combustion equation equation of the fuel,

0.80CH 4  0.15N 2  0.05O 2   a th O 2  3.76N 2     0.8CO 2  1.6H 2 O  0.15  3.76a th  N 2   a th  1.55 O 2 : 0.05  a th  0.8  0.8  Then,


mair,act mair,th



N air,act N air,th



5.0 4.76 kmol  323% 1.554.76 kmol

(c) The specific volume, mass flow rate, rate, and the volume flow rate of air at the inlet conditions are v



RT P



0.287 kPa  m

3



/kg  K 298 K 

100 kPa

 0.855 m 3 /kg

3  air  (AF) m  fuel  37.1 kg air/kg fuel 1.4 kg fuel/min  51.94 m /min m

 V air

 m v air  51.94 kg/min 0.855 m 3 /kg   44.4 m 3 /min

15-68

15-92 CO gas is burned burned with air air during during a steady-f steady-flow low combusti combustion on process. process. The rate of heat transf transfer er from the combustio combustion n chamber chamber is to be determine determined. d.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 There are no work interactions. 5 Combustion is complete. molar masses masses of CO and and air are 28 kg/kmol kg/kmol and 29 kg/kmol, kg/kmol, respectivel respectively y (Table (Table A-1). Properties The molar Analysis We first need to calculate the amount of air used per kmol of CO before we can write the combustion equation, v CO



 CO  m

RT P  V CO v CO



0.2968 kPa  m

3



/kg  K 310 K 

110 kPa  0.4 m 3 /min



0.836 m 3 /kg

Q

 0.836 m 3 /kg

CO 37C

 0.478 kg/min

Air

N air N fuel



 air / M air m  fuel / M fuel m



Products 900 K

25C

Then the molar molar air-fue air-fuell ratio becomes becomes AF 

Combustion chamber

1.5 kg/min / 29 kg/kmol  3.03 kmol air/kmol fuel 0.478 kg/min / 28 kg/kmol

Thus Thus the numb number er of moles moles of O2 used per mole mole of CO is 3.03/4.76 3.03/4.76 = 0.637. Then the combustio combustion n equation equation in this case case can be written written as CO  0.637O 2  3.76N 2     CO 2  0.137O 2  2.40N 2 Under steady-flow conditions the energy balance E in  E out  E system

applied on the combustion

chamber with W = reduce cess to W = 0 redu

 Qout 

 N h



P f

 h  h   P 

 N h R



f

 h  h   R

Assuming Assuming the air and and the combu combustion stion products products to be be ideal ideal gases, gases, we haveh have h = h(T ). ). From From the tables tables,, h f 

h 298 K

h 310 K

h 900 K

kJ/kmol

kJ/kmol

kJ/kmol

kJ/kmol

CO

-110,530

8669

9014

27,066

O2

0

8682

---

27,928

N2

0

8669

---

26,890

CO2

-393,520

9364

---

37,405

Substance

Thus,

Qout  1393,520  37,405  9364  0.137 0  27,928  8682  2.40  26,890  8669  1 110,530  9014  8669   0  0  208,927 kJ/kmol of CO Then the the rate rate of heat trans transfer fer for for a mass mass flow flow rate of 0.956 kg/min kg/min for CO CO becomes becomes

 0.478 kg/min   m  208,927 kJ/kmol  3567 kJ/min Qout   28 kg/kmol  N   


15-69

15-93 Methane gas is burned burned steadily with dry air. air. The volumetric analysis analysis of the products is given. The percentage of theoretical air used and the heat transfer transfer from the combustion chamber chamber are to be determined.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 There are no work interactions. equation can be written as Analysis (a) Considering 100 kmol of dry products, the combustion equation CH 4 x

O2 a 3.76N 2

 5.20CO2 0.33CO 11.24O2 83.23N2  H2 Ob

The unknown coefficients x, a, and b are determined from from mass mass balances, N 2 : 3.76a  83.23

   a  22.14

C : x  5.20  0.33 H : 4 x  2b

CH4

   x  5.53

25C

   b  11.06

Air

5.53CH4  22.14 O2  3.76N2

Combustion chamber

Products 700 K

17C

(Check O 2 : a  5.20  0.165  11.24  b / 2    22.14  22.14) Thus,

Q

 5.20CO2 0.33CO 11.24O2 83.23N2 11.06H2 O

The combustion combustion equation equation for 1 kmol of fuel fuel is obtaine obtained d by dividing dividing the above equation equation by 5.53 5.53 CH 4  4O 2  3.76N 2     0.94CO 2  0.06CO  2.03O 2  15.05N 2  2H 2 O To find the percent percent theoretical air used, we need to know the theoretical theoretical amount of air, which is determined from the theoretic theoretical al combustion combustion equation equation of the fuel, fuel, CH 4  ath O 2  3.76N 2

 ath  2.0 a th  1  1 

O 2: Then,

  CO2 2H2 O 3.76ath N2


mair,act mair,th



N air,act N air,th



4.04.76 kmol  200% 2.04.76 kmol

(b) Under steady-flow conditions, energy balance balance applied on the combustion combustion chamber reduces to

 Qout 

 N h



P f

 h  h  P 

 N h R



f

 h  h  R


Substance

CH4 ( g g ) O2 N2 g ) H2O ( g CO CO2

h f 

h 290 K

h 298 K

h 700 K

kJ/kmol -74,850 0 0 -241,820 -110,530 -393,520

kJ/kmol --8443 8432 -------

kJ/kmol --8682 8669 9904 8669 9364

kJ/kmol --21,184 20,604 24,088 20,690 27,125

Thus,

Qout  0.94 393,520  27,125  9364  0.06 110,530  20,690  8669   2 241,820  24,088  9904  2.030  21,184  8682   15.04 0  20,604  8669   1 74,850  h298  h298   4 0  8443  8682   15.04 0  8432  8669   530,022 kJ/kmolCH 4 or

Qout  530,022 kJ/kmol CH 4

15-70

15-94 A mixture of hydrogen hydrogen and the stoichiometric amount amount of air contained in a rigid rigid tank is ignited. The fracti fraction on of H2O that condense condensess and the heat transfe transferr from the combustio combustion n chamber chamber are to be determine determined. d.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 There are no work interactions. 5 Combustion is complete. theoretical combustion equation of H2 with stoichiometric amount of air is Analysis The theoretical H 2  ath O2  3.76N 2     H 2O  3.76ath N 2 where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance,

Q

H2, Air

ath  0.5 Thus,

25C 25C

  H 2O  1.88N 2 H 2  0.5O 2  3.76N 2  

(a) At 25C part part of the water water (say, (say, N w moles) moles) will condense, condense, and the the number number of moles moles of products products that that remain remainss in the gas gas phase phase will will be 2.88 2.88 - N w. Neglec Neglecting ting the the volume volume occu occupie pied d by the liqui liquid d water water and and treating treating all the product gases as ideal gases, the final pressure in the t ank can be expressed as P f 

N f ,gas Ru T f



V

2.88  N w kmol8.314 kPa  m 3 /kg  K 298 K  6 m3

 412.92.88  N w kPa Then, N v N gas



P v P total

  

1  N w



2.88  N w

3.169 kPa 412.92.88  N w kPa

   N w  0.992 kmol

Thus 99.2% of the the H2O will will condense condense when the produc products ts are are cooled cooled to to 25C. (b) The energy energy balance balance Ein  Eout   Esyst em applied applied for this constant constant volume volume combustion combustion process process with W = W = 0 reduc reduces es to

 Qout 

 N h P



f

 h  h   P v P 

 N h R



f

 h  h   P v R

With the exception exception of liquid liquid water water for which the P v term is negligible, both the reactants and and the products are assum assumed ed to be ideal ideal gases, gases, all the the internal internal energy energy and enthalpie enthalpiess depend depend on temperatu temperature re only, only, and the P v terms in this equation can be replaced by RuT . It yie yields lds

 N h   N h

 Qout 

P



f

 Ru T  P 

P f , P  

 N h

 N h

R



R f , R



f

 Ru T  R

 N

 Ru T 

P , gas



 N 

R R


Substance

H2 O2 N2 g ) H2O ( g H2O ()

h f  kJ/kmol 0 0 0 -241,820 -285,830

Thus,

Qout  0.008241,820  0.992 285,830   0  0  0  0  8.314  2981.89  3.38   281,786 kJ  per kmol H 2  or

Qout  281,786 kJ (per kmol H 2 )

15-71

15-95 Propa Propane ne gas is burned burned with with air air during during a stead steady-f y-flow low combus combustio tion n proce process. ss. The adiaba adiabatic tic flame flame temperatu temperature re is to be determined determined for different different cases. cases.

combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and Assumptions 1 Steady operating conditions exist. 2 Air and combustion potential energies are negligible. 4 There are no work interactions. 5 The combustion chamber is adiabatic. Analysis Adiabatic flame temperature is the temperature at which the products leave the combustion chamber chamber under under adiabati adiabaticc conditions conditions (Q = 0) with with no work work inte intera ract ctio ions ns (W (W = 0). Under steady-flow conditions the energy balance E in  E out  E system applied on the combustion chamber reduces to

 N h P



f

 h  h   P 

 N h R



f

 h  h   R   

 N h P



f

 hT  h   P   N h f  C H 3

8

since all the reactants are at the standard reference reference temperature temperature of 25C, and h f   0 for O2 and N2. (a) The theore theoretic tical al comb combust ustion ion equa equatio tion n of C3H8 with stoichiometric stoichiometric amount of air is

  3CO2  4H 2O  18.8 N 2 C3H8  g   5O 2  3.76N2   From the tables, Substance

C3H8 ( g g ) O2 N2 H2O ( g g ) CO CO2

h f 

h 298 K

C3H8

kJ/kmol -103,850 0 0 -241,820 -110,530 -393,520

kJ/kmol --8682 8669 9904 8669 9364

25C

Combustion Products chamber T P Air

25C

Thus,

3 393,520  hCO  9364  4 241,820  hH O  9904  18.80  h N  8669  1 103,850 2

2

2

It yields 3hCO 2  4hH 2O  18.8h N 2  2,274,675 kJ The adiabatic adiabatic flame flame temperatur temperaturee is obtained obtained from a trial trial and error solution solution.. A first guess guess is obtained obtained by dividing the right-hand side of the equation by the total number of moles, which yields 2,274,675 / (3 + 4 + 18.8) = 88,165 kJ/kmol. This enthalpy value value corresponds corresponds to about 2650 K for N2. Noting that the majority majority of the moles are N2, T P will be close close to 2650 K, but somewhat somewhat under under it because because of the higher higher specific specific heats of CO2 and H2O. At 2400 K:

3hCO 2  4hH 2O  18.8h N 2  3125,152  4 103,508  18.8 79,320   2,280,704 kJ Higher than 2,274,675 kJ 

At 2350 K:

3hCO 2  4hH 2O  18.8h N 2  3122,091  4 100,846   18.8 77,496   2,226,582 kJ Lower than 2,274,675 kJ 

By interpolation,

T P = 2394 K

(b) The balanced balanced combu combustion stion equation equation for complete complete combustion combustion with 300% theoretica theoreticall air air is is C3H8  g   15O2  3.76N2     3CO2  4H 2O  10O2  56.4 N 2 Substituting known numerical values,

3  393,520  hCO  9364  4  241,820  hH O  9904  100  hO  8682  56.40  h N  8669  1 103,850 2

2

2

which yields

2

15-72

3hCO 2  4hH 2O  10hO 2  56.4h N 2  2,687,450 kJ The adiabatic adiabatic flame flame temperatur temperaturee is obtained obtained from a trial trial and error solution solution.. A first guess guess is obtained obtained by dividing the right-hand side of the equation by the total number of moles, moles, which yields 2,687,449 / (3 + 4 + 10 + 56.4) 56.4) = 36,614 36,614 kJ/kmol. kJ/kmol. This enthalp enthalpy y value corre correspond spondss to about about 1200 K for N2. Noting that the majority of the moles are N2, T P will be close close to 1200 1200 K, but somewhat somewhat under under it becaus becausee of the higher higher specific heats of CO2 and H2O. At 1160 K: 3hCO 2  4hH 2O  10hO 2  56.4h N 2  351,602  4 42,642   10 37,023  56.4 35,430   2,693,856 kJ Higher than 2,687,450 kJ  At 1140 K: 3hCO 2  4hH 2O  10hO 2  56.4h N 2  350,484  4 41,780   10 36,314   56.4 34,760   2,642,176 kJ Lower than 2,687,450 kJ  By interpolation,

T P = 1158 K

(c) The balanced balanced combustion combustion equation equation for incomplete incomplete combustion combustion with 95% theoretica theoreticall air is C3H8  g   4.75O 2  3.76N2     2.5CO2  0.5CO  4H 2O  17.86 N 2 Substituting known numerical values,

2.5 393,520  hCO  9364  0.5 110,530  hCO  8669  4 241,820  hH O  9904  17.86 0  h N  8669  1 103,850 2

2

2

which yields 2.5hCO 2  0.5hCO  4hH 2O  17.86h N 2  2,124,684 kJ The adiabatic adiabatic flame flame temperatur temperaturee is obtained obtained from a trial trial and error solution solution.. A first guess guess is obtained obtained by dividing the right-hand side of the equation by the total number of moles, which yields 2,124,684 / (2.5 + 4 + 0.5 + 17.86) 17.86) = 85,466 85,466 kJ/kmol. kJ/kmol. This enthalp enthalpy y value corre correspond spondss to about about 2550 K for N2. Noting that the majority of the moles are N2, T P will be close close to 2550 2550 K, but somewhat somewhat under under it becaus becausee of the higher higher specific heats of CO2 and H2O. At 2350 K: 2.5hCO 2  0.5hCO  4hH 2O  17.86h N 2  2.5122,091  0.578,178  4 100,846   17.86 77,496   2,131,779 kJ Higher than 2,124,684 kJ  At 2300 K: 2.5hCO 2  0.5hCO  4hH 2 O  17.86h N 2  2.5119,035  0.576,345  4 98,199   17.86 75,676   2,080,129 kJ Lower than 2,124,684 kJ  By interpolation,

T P = 2343 K

15-73

15-96 The highest possible temperatures temperatures that can be obtained when liquid gasoline is burned steadily with air and with pure oxygen oxygen are to be determine determined. d. Assumptions 1 Steady operating conditions exist. 2 Air and combustion combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and potential energies are negligible. 4 There are no work interactions. 5 The combustion chamber is adiabatic. highest possible possible temperatu temperature re that that can can be be achieved achieved during during a combustio combustion n process process is the the Analysis The highest temperatur temperaturee which occurs occurs when a fuel is burned burned completel completely y with stoichiom stoichiometric etric amount amount of air in an adiabatic adiabatic combus combustion tion chamb chamber. er. It is deter determined mined from

 N h P



f

 h  h   P 

 N h R



f

 h  h   R   

 N h P



f

 hT  h   P   N h f  C H 8

18

since all the reactants are at at the standard reference reference temperature of 25C, and for O2 and N2. The theoretical combustion equation of C8H18 air is C8 H18  12.5O 2  3.76N2     8CO2  9H 2O  47 N 2 From the tables, Substance

C8H18 () O2 N2 g ) H2O ( g CO2 Thus,

h f 

h 298 K

C8H18

kJ/kmol -249,950 0 0 -241,820 -393,520

kJ/kmol --8682 8669 9904 9364

25C

Combustion chamber

Air

Products T P, max

25

8 393,520  hCO  9364  9 241,820  hH O  9904  470  h N  8669  1 249,950 2

2

2

It yields 8hCO 2  9hH 2O  47 h N 2  5,646,081 kJ The adiabatic adiabatic flame flame temperatur temperaturee is obtained obtained from a trial trial and error solution solution.. A first guess guess is obtained obtained by dividing dividing the right-han right-hand d side of the equation equation by the total number number of moles, moles, which yields yields 5,646,081/(8 5,646,081/(8 + 9 + 47) = 88,220 kJ/kmol. This enthalpy value corresponds to about 2650 K for N2. Noting that the majority majority of the moles are N2, T P will will be close close to to 2650 2650 K, but somewh somewhat at unde underr it becaus becausee of the the higher higher specif specific ic heat heat of H2O. At 2400 K:

8hCO 2  9hH 2O  47h N 2  8125,152  9 103,508  47 79,320   5,660,828 kJ Higher than 5,646,081 kJ 

At 2350 K:

8hCO 2  9hH 2O  47h N 2  8122,091  9 100,846   47 77,496   5,526,654 kJ Lower than 5,646,081 kJ 

By interpolation, T P = 2395 K If the fuel is burned burned with stoichiom stoichiometric etric amount amount of pure O2, the combustio combustion n equation equation would be

  8CO 2  9H 2 O C 8 H 18  12.5O 2  Thus,

8 393,520  hCO  9364  9 241,820  hH O  9904  1 249,950 2

2

It yields 8hCO 2  9hH 2O  5,238,638 kJ The adiabatic adiabatic flame flame temperature temperature is obtaine obtained d from a trial trial and error solution solution.. A first guess guess is obtained obtained by dividing dividing the right-han right-hand d side of the equation equation by the total number number of moles, moles, which yields yields 5,238,638/ 5,238,638/(8 (8 + 9) = 308,155 308,155 kJ/kmol. kJ/kmol. This enthalp enthalpy y value value is higher higher than than the highest highest enthalpy enthalpy value value listed listed for H2O and and CO2. Thus an estimate estimate of the adiabatic adiabatic flame temperatu temperature re can be obtained obtained by extrapolation extrapolation.. At 3200 K:

8hCO 2  9hH 2O  8174,695  9 147,457   2,724,673 kJ

At 3250 K:

8hCO 2  9hH 2O  8177,822  9 150,272   2,775,024 kJ

By extrapolati extrapolation, on, we get T P = 3597 K . However However,, the soluti solution on of this this proble problem m using using EES gives gives 5645 K . The large difference between these these two values is due to extrapolation.

15-74

15-97E The work potent potential ial of diesel diesel fuel fuel at a given state is is to be determine determined. d. Assumptions 1 Steady operating conditions exist. 2 Air and combustion combustion gases gases are ideal ideal gases. gases. 3 Kineti Kineticc and potential energies are negligible. potentiall or availabili availability ty of a fuel at a specifi specified ed state is is the reversibl reversiblee work that would be Analysis The work potentia obtained if that fuel were burned completely with stoichiometric amount of air and the products are returned returned to the state of the surroundin surroundings. gs. It is determine determined d from

or,

 N h   N h

W rev 

R

f

W rev

R

f





 h  h   T 0 s R   T 0 s R 

 N h P

 N h P



f



f

 h  h   T 0 s P

 T 0 s P

since both the reactants and the products are at the state of the surroundings. surroundings. Considering 1 kmol kmol of C12H26, the theoretical combustion equation can can be written as C12H 26  ath O 2  3.76N 2     12CO2  13H 2O  3.76ath N 2 where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, a th  12  6.5 Substituting,

 

a th  18.5

C12H 26  18.5O 2  3.76N 2     12CO2  13H2O  69.56N 2

For each lbmol of fuel burned, 12 + 13 + 69.56 = 94.56 lbmol lbmol of products are formed, including 13 lbmol of H2O. Assumi Assuming ng that that the the dew-po dew-point int temp tempera eratur turee of the the produ products cts is above above 77F, some of the water will exist in the liquid form in the products. If N condenses, there there will be 13 - N - N w lbmol of water N w lbmol of H2O condenses, vapor left in the products. The mole number of the products products in the gas phase will also decrease to 94.56 (including the remaining water water vapor) as ideal gases, N gases, N w is N w as a result. Treating the product gases (including determine determined d by equating equating the mole fraction fraction of the water vapor vapor to pressure pressure fraction, fraction, N v N prod,gas



P v P prod

  

13  N w 94.56  N w



0.4648 psia 14.7 psia

   N w  10.34 lbmol

since P v = P sat 0.4648 psia. Then the the combustio combustion n equation equation can be written written as sat @ 77F = 0.4648

  12CO2  10.34H2O   2.66H2Og   69.56N2 C12H 26  18.5O2  3.76N2   The entropy entropy values values listed listed in the ideal ideal gas tables tables are for 1 atm pressure pressure.. Both the air air and and the the product product gases are at a total total press pressure ure of 1 atm, atm, but but the entrop entropies ies are to be calc calcula ulated ted at the the par partia tiall press pressure ure of the the component componentss which is equal equal to P i = y P , where is the mole fraction frac tion of component comp onent . Also, y i i total total i



S i  N i si T , P i   N i si T , P 0   Ru ln yi P m  The entropy entropy calculations calculations can be presented presented in tabular form form as Ni

yi

s i 77  F,1atm

R u lny i Pm 

si

h f  ,Btu/lbmol

C12H26 O2 N2

1 18.5 69.56

--0.21 0.79

148.86 49.00 45.77

---3.10 -0.47

148.86 52.10 46.24

-125,190 0 0

CO2 H2O ( g g )

12 2.66 10.34

0.1425 0.0316 ---

51.07 45.11 16.71

-3.870 -6.861 ---

54.94 51.97 16.71

-169,300 -104,040 -122,970

69.56

0.8259

45.77

-0.380

46.15

0

H2O () N2 Substituting,

W rev  1125,190  537  148.86   18.50  537  52.10   69.56 0  537  46.24   12 169,300  537  54.94   2.66  104,040  537  51.97   10.34 122,970  537 16.71  69.56 0  537  46.15  3,375,000 Btu  per lbmol C12 H 26 

15-75

15-98 Liquid Liquid octa octane ne is burn burned ed with with 200 200 perce percent nt excess excess air during during a steady steady-fl -flow ow combus combustio tion n proce process. ss. The heat transfer rate from the combustion chamber, the power output of the turbine, and and the reversible reversible work and exergy destruction destruction are to be determined.  Q

Assumptions 1 Combustion is complete. 2 Steady operating operating conditions conditions exist. exist. 3 Air and the combustion gases are ideal gases. 4 Changes Changes in kinetic kinetic and potential potential energies energies are negligible. negligible.


25C, 8 atm

Properties The molar molar mass mass of of C8H18 is 114 114 kg/k kg/kmo moll (Table A-1).

Air =

200% excess air

Analysis (a) The fuel fuel is burned burned comple completel tely y with with the the excess air, and thus the products will contain only CO2, H2O, N2, and some free O2. Considering 1 kmol of C8H18, the combusti combustion on equation equation can can be written written as

1300 1300 K 8 atm

  8CO2  9H 2O  2ath O 2  33.76ath  N 2 C8 H18  3ath O 2  3.76N 2  

Combustion gases

 W

where ath is the stoichiometric coefficient and is determine determined d from the O2 balance, 950 K 2 atm

  ath  12.5 3ath  8  4.5  2ath  Substituting,

 8CO2  9H 2O  25O 2  141N 2 C8 H18  37.5O 2  3.76N 2   The heat transfer for this combustion process is determined from the energy balance E in  E out  E system applied applied on the combustio combustion n chamber chamber with W = W = 0,

 Qout 

 N h



P f

 h  h  P 

 N h R



f

 h  h  R

Assuming Assuming the air and and the combu combustion stion products products to be be ideal ideal gases, gases, we haveh have h = h( ). From From the the tabl tables, es, h(T ).

Substance

C8H18 () O2 N2 H2O ( g g ) CO2 Substituting,

h f 

h 500 K

h 298 K

h1300 K

h 950 K

kJ/kmol -249,950 0 0 -241,820 -393,520

kJ/kmol --14,770 14,581 -----

kJ/kmol --8682 8669 9904 9364

kJ/kmol --42,033 40,170 48,807 59,552

kJ/kmol --26,652 28,501 33,841 40,070

Qout  8393,520  59,522  9364  9 241,820  48,807  9904   250  42,033  8682  1410  40,170  8669   1 249,950  h298  h298   37.50  14,770  8682   1410  14,581  8669   109,675 kJ/kmol C 8 H 18 The C8H18 is burned at a rate of 0.8 kg/min or   N

Thus,

 m

M



0.8 kg/min

812   181 kg/kmol



 7.018 10 3 kmol/min



3 Q kmol/min 109,675 kJ/kmol  770 kJ/min Q out  N out  7.018  10

15-76

(b) Noting that no chemical chemical reactions occur in the turbine, the turbine is adiabatic, and the product gases gases can be treated as ideal gases, the power output of the turbine can be determined from the steady-flow energy energy balance balance equation equation for for nonreactin nonreacting g gas mixtures, mixtures,

 W out 

 N h P

e

 hi     W out 

 N h P

1300 K  h950 K



Substituting, W out  859,522  40,070  9 48,807  33,841  25 42,033  29,652   14140,170  28,501  2,245,164 kJ/kmol C 8 H 18 Thus Thus the power power output output of the the turbin turbinee is



3   kmol/min 2,245,164 kJ/kmol  15,756 kJ/min  262.6 kW W out  N W out  7.018  10

(c) The entrop entropy y generatio generation n during during this this process process is is determ determined ined from S gen  S P  S R 

Qout T surr



 N s   N s P P

R R



Qout T surr

where the entropy entropy of the products are to be evaluated at the turbine exit state. The C8H18 is at 25C and and 8 atm, and thus its absolute entropy is s C8 H18 =360.79 =360.79 kJ/kmol·K kJ/kmol·K (Table (Table A-26). A-26). The entropy entropy values values listed listed in the ideal ideal gas tables tables are for for 1 atm pressur pressure. e. The entropie entropiess are to be calculated calculated at at the partial partial pressur pressuree of the component componentss which is equal equal to P i = y P fraction of component component i. Also, i total total, where yi is the mole fraction S i  N i si T , P i   N i si T , P 0   Ru ln yi P m  The entropy entropy calculations calculations can be presented presented in tabular tabular form as Ni

yi

s i T,1 atm 

C8H18 O2 N2

1 37.5 141

1.00 0.21 0.79

360.79 220.589 206.630

CO2 H2O O2 N2

8 9 25 141

0.0437 0.0490 0.1366 0.7705

266.444 230.499 241.689 226.389

R u lny i Pm 

N i si

17.288 343.50 4.313 8,110.34 15.329 26,973.44 S R = 35,4 35,427 27.2 .28 8 kJ/K kJ/K -20.260 2,293.63 -19.281 2,248.02 -10.787 6,311.90 3.595 31,413.93 42,267 67.4 .48 8 kJ/K kJ/K S P = 42,2

Thus, S gen  42,267.48  35,427.28 

109,675 kJ 298 K

 7208.2 kJ/K  per kmol 

Then the rate rate of entropy entropy generation generation becomes becomes





3   S gen  N S gen  7.018  10 kmol/min 7208.2 kJ/kmol  K   50.59 kJ/min  K

and   X destruction  T 0 S gen  298 K 50.59 kJ/min  K   15,076 kJ/min  251.3 kW    W rev  W  X destruction  262.6  251.3  513.9 kW

15-77

15-99 Methyl Methyl alcohol alcohol vapor is burned burned with the the stoichio stoichiometr metric ic amount amount of air in a combustio combustion n chamber. chamber. The maximum pressure pressure that can occur in the combustion chamber if the combustion takes place at constant volume and the maximum volume of the combustion chamber chamber if the combustion occurs at constant pressure are to be determined.

combustion n gases are are ideal gases. gases. 4 Changes in Assumptions 1 Combustion is complete. 2 Air and the combustio kinetic kinetic and potential potential energies energies are negligible. negligible. Analysis (a) The The combus combustion tion equation equation of CH CH3OH(g) with stoichiometric amount of air is

  CO 2  2H 2O  3.76ath N 2 CH3OH  ath O 2  3.76N 2   where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, 1  2a th  2  2

 

ath  1.5

CH3OH( g g ) AIR 25C,98 kPa

Thus, CH3OH  1.5O 2  3.76N 2     CO 2  2H 2O  5.64N 2 The final temperature in the tank is determined from the energy balance relation E in  E out  E system for W = 0), reacting closed systems under adiabatic conditions (Q (Q = 0) with no work work interac interactions tions (W = 0

 N h P



f

 h  h   P v P 

 N h R



f

 h  h   P v R

Assuming both the reactants and the products to behave as ideal ideal gases, all the internal internal energy and and enthalpies enthalpies depend depend on tempe temperatur raturee only, only, and and the the P v terms in this equation can be replaced by RuT . It yields

 N h P



f

 hT P  h298 K  Ru T P 

 N h R



f

 Ru T R


Substance

CH3OH O2 N2 H2O ( g g ) CO2

h f 

h 298 K

kJ/kmol -200,670 0 0 -241,820 -393,520

kJ/kmol --8682 8669 9904 9364

Thus,

1 393,520  hCO  9364  8.314  T P   2 241,820  hH O  9904  8.314  T P   5.640  h N  8669  8.314  T P   1 200,670  8.314  298  1.50  8.314  298  5.640  8.314  298 2

2

2

It yields hCO2  2hH 2 O  5.64 hN 2  71.833  T P  7 34, 388 kJ The temperature of the product gases is obtained from a trial and error solution, At 2850 K: hCO 2  2hH 2O  5.64h N 2  71.833  T P  1152,908  2 127,952   5.64 95,859   71.8332850   744,733 kJ Higher than 734,388 kJ 

15-78

At 2800 K: hCO 2  2hH 2O  5.64h N 2  71.833  T P  1149,808  2 125,198  5.64 94,014   71.833 2800   729,311 kJ Lower than 734,388 kJ  By interpolation

T P = 2816 K

Since both the reactants reactants and the products products behave behave as ideal gases, gases, the the final final (maximum (maximum)) pressure pressure that can occur in the combustion chamber is determined to be P 1V P 2V



N 1 Ru T 1 N 2 Ru T 2

   P 2 

N 2 T 2

P 1 

N 1T 1

8.64 kmol2816 K  98 kPa   983 8.14 kmol298 K 

kPa

(b) The combustion combustion equation of CH3OH( g remains the same in the case of constant pressure. Further, the g ) remains boundary work in this case can be combined with the u terms so that the first law relation can be expressed in terms of enthalpies enthalpies just like the steady-fl steady-flow ow process, process, Q

 N h P



f

 h  h   P 

 N h R



f

 h  h   R

Since both the reactants and the products behave as ideal gases, we have have h = h(T ). ) . Also Also not notin ing g that that Q = 0 for an an adiabatic adiabatic combustio combustion n process, process, the the 1st law relation relation reduces reduces to

 N h P



f

 hT P  h298 K P 

 N h R



f R

since the reactants are at the standard reference temperature of 25 C. Then using data from from the mini table above, we get

1 393,520  hCO  9364  2 241,820  hH O  9904  5.640  h N  8669  1 200,670  1.5 0   5.64 0  2

2

2

It yields hCO2  2hH 2O  5.64h N 2  754,555 kJ The temperature of the product gases is obtained from a trial and error solution, At 2350 K:

hCO 2  2hH 2O  5.64h N 2  1122,091  2 100,846   5.64 77,496   760,860 kJ Higher than 754,555 kJ 

At 2300 K:

hCO 2  2hH 2O  5.64h N 2  1119,035  2 98,199   5.64 75,676   742,246 kJ Lower than 754,555 kJ  T P = 2333 K

By interpolation,

Treating both the reactants and the products as ideal gases, gases, the final (maximum) (maximum) volume that the combustion combustion chambe chamberr can have is determine determined d to be P V 1 P V 2



N 1 Ru T 1 N 2 Ru T 2

   V 2 

N 2T 2 N 1T 1

V 1



8.64 kmol2333 K  0.8 L   6.65 L 8.14 kmol298 K 

15-79

15-100 Problem 15–99 is reconsidered. The effect effect of the initial volume of the combustion chamber on the maximum pressure pressure of the chamber chamber for constant volume combustion combustion or the maximum volume of the chamber for constant pressure combustion is to be investigated. Analysis The problem problem is solved solved using EES, EES, and the solution solution is given given below.

"Input Data" T_reac = (25+273) "[K]" "reacta "reactant nt mixtur mixture e temperat temperature" ure" P_reac = 98 [kPa] "reactant mixture pressure" {V_chamber_1 = 0.8 [L]} h_CH3OH = -200670 [kJ/kmol] Mw_O2 = 32 [kg/kmol] Mw_N2 = 28 [kg/kmol] Mw_CH3OH=(3*12+1*32+4*1) "[kg/kmol]" R_u = 8.314 [kJ/kmol-K] "universal gas constant" "For theoretical oxygen, the complete combustion equation is" "CH3OH "CH 3OH + A_th A_th O2= O2=1 1 CO2+ CO2+2 2 H2O " 1+ 2*A_th=1*2+2*1"theoretical 2*A_th=1*2+2*1"theoretical O balance" "The balanced complete combustion equation with theroetical air is" "CH3OH + A_th A_th (O2+3.7 (O2+3.76 6 N2)=1 N2)=1 CO2+ CO2+ 2 H2O + A_th(3 A_th(3.76) .76) N2 " "now to find the actual moles of reactants and products per mole of fuel" N_Reac = 1 + A_th*4.76 N_Prod=1+2+A_th*3.76 "Apply First Law to the closed system combustion chamber and assume ideal gas behavior. Assume the water formed in the combustion process exists in the gas phase." "The following is the constant volume, adiabatic solution:" E_in - E_out = DELTAE_sys E_in = 0 "No heat transfer for the adiabatic combustion combustion process" process" E_out = 0"kJ/kmol_CH3OH" 0"kJ/kmol_CH3OH" "No work is done because volume is constant" DELTAE_sys DELTAE_sys = U_prod U_prod - U_reac "neglect KE and PE and note: U = H - PV = N(h - R_u T)" U_reac = 1*(h_CH3OH - R_u*T_reac) +A_th*(enthalpy(O2,T=T_reac) R_u*T_reac)+A_th*3.76*(enthalpy(N2,T=T_reac) - R_u*T_reac) U_prod = 1*(enthalpy(CO2, 1*(enthalpy(CO2, T=T_prod) - R_u*T_prod) R_u*T_prod) +2*(enthalpy(H2O, +2*(enthalpy(H2O, T=T_prod) T=T_prod) R_u*T_prod)+A_th*3.76*(enthalpy(N2,T=T_prod) - R_u*T_prod) V_chamber_2 = V_chamber_1 "The final final pressure pressure and volume of the tank are are those of the product gases. Assumi Assuming ng ideal gas behavior for the gases in the constant volume tank, the ideal gas law gives:" P_reac*V_chamber_1*convert(L,m^3) =N_reac*N_fuel* R_u *T_reac P_prod*V_cha P_prod*V_chamber_2* mber_2*convert convert(L,m^3) (L,m^3) = N_prod*N_fuel N_prod*N_fuel** R_u * T_prod { "The following is the constant pressure, adiabatic solution:" P_prod = P_Reac H_reac=H_prod H_reac = 1*h_CH3OH +A_th*enthalpy(O2,T=T_reac) + A_th*enthalpy(O2,T=T_reac) +A_th*3.76*enthalpy(N2,T=T_reac) H_prod = 1*enthalpy(CO2,T=T_prod)+2*enthalpy(H2O,T=T_prod) +A_th*3.76*enthalpy(N2,T=T_prod) }

15-80

Nfuel [kmol] 4.859E-07 0.000001512 0.000002538 0.000003564 0.000004589 0.000005615 0.000006641 0.000007667 0.000008693 0.000009719

Pprod [kPa] 983.5 983.5 983.5 983.5 983.5 983.5 983.5 983.5 983.5 983.5

Tprod [K] 2817 2817 2817 2817 2817 2817 2817 2817 2817 2817

Vchamber,1 [L] 0 .1 0.3111 0.5222 0.7333 0.9444 1.156 1.367 1.578 1.789 2

Constant pressure combustion of CH3OH 18

Preac = Pprod = 98 kPa

16 14

Adiabatic Tprod = 2334 K

12

2, r e b m a h c

10 8 6 4 2 0 0

0.4

0.8

1.2

1.6

2

Vchamber,1 [L]

Constant volume combustion of CH3OH 1500

Preac = 98 kPa 1300

Adiabatic Tprod = 2817 K 1100

d o r p

900 700 500 0

0.4

0.8

1.2

Vchamber,1 [L]

1.6

2

15-81

15-101 Methane is burned burned with the stoichiometric stoichiometric amount of air in a combustion chamber. chamber. The maximum maximum pressure that can occur in the combustion chamber if the combustion combustion takes place at constant volume and the maximum maximum volume volume of the combusti combustion on chamber chamber if the combustion combustion occurs occurs at constant constant pressure pressure are to be determined.

combustion n gases are are ideal gases. gases. 4 Changes in Assumptions 1 Combustion is complete. 2 Air and the combustio kinetic kinetic and potential potential energies energies are negligible. negligible. The combus combustion tion equation equation of CH CH4( g ) with stoichio stoichiometr metric ic amount amount of air is Analysis (a) The CH 4  ath O 2  3.76N2     CO2  2H 2O  3.76ath N 2 where ath is the stoichiometric coefficient coefficient and is determined from the O2 balance, a th  1  1

 

g ) CH4 ( g AIR 25C,98 kPa

a th  2

Thus,

  CO2  2H 2O  7.52N2 CH 4  2O2  3.76N 2   The final temperature in the tank is determined from the energy balance relation Ein  Eout   Esyst em for reacting closed systems under adiabatic conditions (Q (Q = 0) with no work work interac interactions tions (W = W = 0), 0

 N h



P f

 h  h   P v  P 

 N h R

 h  h   P v  R



f

Since both the reactants and the products behave behave as ideal gases, gases, all the internal energy and enthalpies enthalpies depend on temperature only, and the P v terms terms in this equation equation can be replaced replaced by RuT . It yie yield ldss

 N h



P f

 hT P  h298 K  RuT P 

 N h R



f

 RuT R


Substance

CH4 O2 N2 g ) H2O ( g CO2

h f 

h 298 K

kJ/kmol -74,850 0 0 -241,820 -393,520

kJ/kmol --8682 8669 9904 9364

Thus,

1 393,520  hCO  9364  8.314  T P   2  241,820  hH O  9904  8.314  T P   7.520  h N  8669  8.314  T P   1 74,850  8.314  298  2 0  8.314  298  7.52 0  8.314  298 2

2

2

It yields hCO2  2hH 2O  7.52h N 2  87.463  T P  870,609 kJ The temperature of the product gases is obtained from a trial and error solution, At 2850 K: hCO 2  2hH 2 O  7.52h N 2  87.463  T P  1152,908  2 127,952   7.52 95,859   87.463 2850   880,402 kJ Higher than 870,609 kJ  At 2800 K: hCO 2  2hH 2 O  7.52h N 2  87.463  T P  1149,808  2 125,198   7.52 94,014   87.463 2800   862,293 kJ Lower than 870,609 kJ  By interpolation,

T P = 2823 K

15-82

Treating both the reactants and the products as ideal gases, the final final (maximum) (maximum) pressure that can occur in the combustion chamber is determined to be P 1V P 2V



N 1 Ru T 1 N 2 Ru T 2

   P 2 

N 2T 2

P 1 

N 1T 1

10.52 kmol2823 K  98 kPa   928 10.52 kmol 298 K 

kPa

(b) The combustion equation of CH4( g case of constant pressure. pressure. Further, the g ) remains the same in the case boundary work in this case can be combined with the u terms so that the first law relation can be expressed in terms of enthalpies enthalpies just like the steady-fl steady-flow ow process, process, Q

 N h P



f

h h

P



 N h R



f

h h

R

Again since both the reactants and the products behave as ideal ideal gases, we haveh have h = h(T ). ). Also noting noting that that Q = 0 for an adiabatic combustion combustion process, the energy balance relation reduces to

 N h P



f

 hT P  h298 K P 

 N h R



f R

since the reactants are at the standard reference temperature of 25 C. Then using data from from the mini table above, we get

1 393,520  hCO  9364  2 241,820  hH O  9904  7.520  h N  8669  1 74,850  2 0   7.52 0  2

2

2

It yields hCO2  2hH 2O  7.52h N 2  896,673 kJ The temperature of the product gases is obtained from a trial and error solution, At 2350 K:

hCO 2  2hH 2O  7.52h N 2  1122,091  2 100,846   7.52 77,496   906,553 kJ Higher than 896,673 kJ 

At 2300 K:

hCO 2  2hH 2O  7.52h N 2  1119,035  2 98,199   7.52 75,676   884,517 kJ Lower than 896,673 kJ 

By interpolation,

T P = 2328 K

Treating both the reactants and the products as ideal gases, gases, the final (maximum) (maximum) volume that the combustion combustion chambe chamberr can have is determine determined d to be P V 1 P V 2



N 1 Ru T 1 N 2 Ru T 2

   V 2 

N 2T 2 N 1T 1

V 1



10.52 kmol2328 K  0.8 L   6.25 10.52 kmol298 K 

L

ThermoSolutions CHAPTER15

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