Microsoft Word - Cengel and Boles TOC _2-03-05_.doc

Chapter 16 | 821

16–83 A constant-volume tank contains a mixture of 1 mol

of H 2 and 0.5 mol of O 2 at 25°C and 1 atm. The contents of

the tank are ignited, and the final temperature and pressure in

the tank are 2800 K and 5 atm, respectively. If the combustion

gases consist of H 2 O, H 2 , and O 2 , determine (a) the equilib-

rium composition of the product gases and (b) the amount of

heat transfer from the combustion chamber. Is it realistic to

assume that no OH will be present in the equilibrium mixture?

Answers:(a) 0.944H 2 O, 0.056H 2 , 0.028O 2 , (b) 132,574 J/mol H 2

16–84 A mixture of 2 mol of H 2 O and 3 mol of O 2 is

heated to 3600 K at a pressure of 8 atm. Determine the equi-

librium composition of the mixture, assuming that only H 2 O,

OH, O 2 , and H 2 are present.

16–85 A mixture of 3 mol of CO 2 and 3 mol of O 2 is

heated to 3400 K at a pressure of 2 atm. Determine the equi-

librium composition of the mixture, assuming that only CO 2 ,

CO, O 2 , and O are present. Answers:1.313CO 2 , 1.687CO,

3.187O 2 , 1.314O

16–86 Reconsider Prob. 16–85. Using EES (or other)

software, study the effect of pressure on the

equilibrium composition by varying pressure from 1 atm to

10 atm. Plot the amount of CO present at equilibrium as a

function of pressure.

16–87 Estimate the enthalpy of reaction for the com-

bustion process of hydrogen at 2400 K, using (a) enthalpy

data and (b) KPdata.

Answers:(a) 252,377 kJ/kmol, (b)252,047 kJ/kmol

16–88 Reconsider Prob. 16–87. Using EES (or other)

software, investigate the effect of temperature

on the enthalpy of reaction using both methods by varying

the temperature from 2000 to 3000 K.

16–89 Using the enthalpy of reaction data and the KP

value at 2800 K, estimate the KPvalue of the dissociation

process O 2 2O at 3000 K.

16–90 Show that when the three phases of a pure substance

are in equilibrium, the specific Gibbs function of each phase

is the same.

16–91 Show that when the two phases of a two-component

system are in equilibrium, the specific Gibbs function of each

phase of each component is the same.

16–92 A constant-volume tank initially contains 1 kmol of

carbon monoxide CO and 3 kmol of oxygen O 2 (no nitrogen)

at 25°C and 2 atm. Now the mixture is ignited and the CO

burns completely to carbon dioxide CO 2. If the final tempera-

ture in the tank is 500 K, determine the final pressure in the

tank and the amount of heat transfer. Is it realistic to assume

that there will be no CO in the tank when chemical equilib-

rium is reached?

16–93 Using Henry’s law, show that the dissolved gases in

a liquid can be driven off by heating the liquid.

∆

hR

hR

16–94 Consider a glass of water in a room at 25°C and 100

kPa. If the relative humidity in the room is 70 percent and the

water and the air are in thermal equilibrium, determine

(a) the mole fraction of the water vapor in the room air,

(b) the mole fraction of the water vapor in the air adjacent to

the water surface, and (c) the mole fraction of air in the water

near the surface.

16–95 Repeat Prob. 16–94 for a relative humidity of

25 percent.

16–96 A carbonated drink is fully charged with CO 2 gas at

17°C and 600 kPa such that the entire bulk of the drink is in

thermodynamic equilibrium with the CO 2 –water vapor mix-

ture. Now consider a 2-L soda bottle. If the CO 2 gas in that

bottle were to be released and stored in a container at 20°C

and 100 kPa, determine the volume of the container.

16–97 Ethyl alcohol (C 2 H 5 OH(g)) at 25°C is burned

in a steady-flow adiabatic combustion chamber

with 40 percent excess air that also enters at 25°C. Determine

the adiabatic flame temperature of the products at 1 atm

assuming the only significant equilibrium reaction is CO 2 

CO  O 2. Plot the adiabatic flame temperature as the per-

cent excess air varies from 10 to 100 percent.

16–98 Tabulate the natural log of the equilibrium con-

stant as a function of temperature between 298

to 3000 K for the equilibrium reaction CO H 2 O CO 2 

H 2. Compare your results to those obtained by combining the

ln KPvalues for the two equilibrium reactions CO 2 CO 

O 2 and H 2 O H 2  O 2 given in Table A–28.

16–99 It is desired to control the amount of CO in the

products of combustion of octane C 8 H 18 so that

the volume fraction of CO in the products is less than 0.1

percent. Determine the percent theoretical air required for the

combustion of octane at 5 atm such that the reactant and

product temperatures are 298 K and 2000 K, respectively.

Determine the heat transfer per kmol of octane for this

process if the combustion occurs in a steady-flow combustion

chamber. Plot the percent theoretical air required for 0.1 per-

cent CO in the products as a function of product pressures

between 100 and 2300 kPa.

Fundamentals of Engineering (FE) Exam Problems

16–100 If the equilibrium constant for the reaction H 2 

is K, the equilibrium constant for the reaction

2H 2 O →2H 2 O 2 at the same temperature is

(a) 1/K (b) 1/(2K)(c) 2K (d) K^2 (e) 1/K^2

16–101 If the equilibrium constant for the reaction CO 

is K, the equilibrium constant for the reaction

at the same temperature is

(a) 1/K (b) 1/(K3) (c) 4K (d) K (e) 1/K^2

CO 2 3N 2 SCO^12 O 2 3N 2

1

2 O^2 SCO^2

1

2 O 2 SH 2 O

1

2

1

2

1

2

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