Thermodynamics: An Engineering Approach
Thermodynamics: An Engineering Approach
8th Edition
ISBN: 9780073398174
Author: Yunus A. Cengel Dr., Michael A. Boles
Publisher: McGraw-Hill Education
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Chapter 5.5, Problem 116P

(a)

To determine

The final pressure in the tank.

(a)

Expert Solution
Check Mark

Answer to Problem 116P

The final pressure in the tank is 67.028psia.

Explanation of Solution

At the final observation, the valve is closed and the tank composed with one-half water and vapor at the temperature of 300°F. The temperature of the tank is kept constant.

Hence, the pressure (P2) of mixture in the tank at final state is equal to the saturation pressure (Psat) of that mixture.

P2=Psat@300°F

Refer Table A-4E, “Saturated water-Temperature table”.

The saturation pressure corresponding to the temperature of 300°F is 67.028psia.

Conclusion:

Hence, the pressure of the mixture in the tank at the final state is 67.028psia.

(b)

To determine

The amount of steam entered in the tank.

(b)

Expert Solution
Check Mark

Answer to Problem 116P

The amount of steam entered in the tank is 85.7279lbm.

Explanation of Solution

Write the equation of mass balance.

minme=Δmsystem (I)

Here, the inlet mass is min, the exit mass is me and the change in mass of the system is Δmsystem.

The change in mass of the system for the control volume is expressed as,

Δmsystem=(m2m1)cv

Here, the suffixes 1 and 2 indicates the initial and final states of the system.

Consider the given rigid tank as the control volume.

At final state, the valve is close and the steam is not allowed to exit, i.e. me=0.

Rewrite the Equation (I) as follows.

min0=(m2m1)cvmin=m2m1 (II)

At initial state, the tank consist of saturated water vapor (g).

Write the formula for mass of steam (m1) at initial.

m1=ν1v1 (III)

Here, the volume is ν and the specific volume is v; the suffix 1 indicates the initial state.

At final state, the tank consist of mixture of vapor (g) and liquid (f).

Write the formula for mass of steam (m2) at final.

m2=mf,2+mg,2=νf,2vf,2+νg,2vg,2 (IV)

Here, the suffixes g,f indicates the gaseous (vapor) and fluid (liquid) condition and the suffix 1 and 2 indicates the initial and final states.

It is given that the tank consist of one-half of the volume of the tank is occupied by liquid water.

νf,2=1.5ft3νg,2=1.5ft3

At the initial state (1):

The tank consist of saturated water vapor (g).

Refer Table A-4E, “Saturated water-Temperature table”.

Obtain the initial specific volume (v1=vg) corresponding to the temperature of 300°F.

vg=v1=6.4663ft3/lbm

At the final state (2):

The tank consist of mixture of vapor (g) and liquid (f).

Refer Table A-4E, “Saturated water-Temperature table”.

Obtain the final fluid and gaseous specific volume corresponding to the temperature of 300°F.

vf,2=0.01745ft3/lbm

vg,2=6.4663ft3/lbm

Conclusion:

Substitute 3ft3 for ν1 and 6.4663ft3/lbm for v1 in Equation (III).

m1=3ft36.4663ft3/lbm=0.4639lbm

Substitute 1.5ft3 for νf,2, 0.01745ft3/lbm for vf,2, 1.5ft3 for νg,2 and 6.4663ft3/lbm for vg,2 in Equation (IV).

m2=1.5ft30.01745ft3/lbm+1.5ft36.4663ft3/lbm=85.9599lbm+0.2319lbm=86.1919lbm

Substitute 86.1919lbm for m2 and 0.4639lbm for m1 in Equation (II).

min=86.1919lbm0.4639lbm=85.7279lbm

Thus, the amount of steam entered in the tank is 85.7279lbm.

(c)

To determine

The amount of the heat transfer.

(c)

Expert Solution
Check Mark

Answer to Problem 116P

The amount of the heat transfer is 80896.0151Btu.

Explanation of Solution

Write the energy balance equation.

EinEout=ΔEsystem{[Qin+Win+min(h+ke+pe)in][Qe+We+me(h+ke+pe)e]}=[m2(u+ke+pe)2m1(u+ke+pe)1]system (V)

Here, the heat transfer is Q, the work transfer is W, the enthalpy is h, the internal energy is u, the kinetic energy is ke, the potential energy is pe and the change in net energy of the system is ΔEsystem; the suffixes 1 and 2 indicates the inlet and outlet of the system.

Since the tank is not insulated, the heat transfer occurs through the tank wall. In control volume, there is no work transfer, i.e. (Win=We=0). Neglect the kinetic and potential energy changes i.e. (Δke=Δpe=0). There is no exit for the tank, the exit mass is neglected i.e. (me=0).

The Equation (V) reduced as follows.

Qin+minhin=m2u2m1u1Qin=m2u2m1u1minhin (VI)

At the final state, the tank is composed of vapor and liquid. Hence, the final state energy is expressed as follows.

m2u2=mf,2uf,2+mg,2ug,2=νf,2vf,2uf,2+νg,2vg,2ug,2=85.9599uf+0.2319ug (VII)

At the line (while entering the tank):

The supply line consist of superheated water vapor.

Refer Table A-6E, “Superheated water”.

Obtain the line enthalpy (hin) corresponding to the pressure of 200psia and the temperature of 400°F.

hin=1210.9Btu/lbm

At the initial state (1):

The tank consist of saturated water vapor (g).

Refer Table A-4E, “Saturated water-Temperature table”.

Obtain the initial internal energy (u1=ug) corresponding to the temperature of 300°F.

ug=u1=1099.8Btu/lbm

At the final state (2):

The tank consist of mixture of vapor (g) and liquid (f).

Refer Table A-4E, “Saturated water-Temperature table”.

Obtain the final fluid and gaseous internal energies corresponding to the temperature of 300°F.

uf,2=269.51Btu/lbm

ug,2=1099.8Btu/lbm

Conclusion:

Substitute 269.51Btu/lbm for uf,2 and 1099.8Btu/lbm for ug,2 in Equation (VII).

m2u2=85.9599(269.51Btu/lbm)+0.2319(1099.8Btu/lbm)=23167.0527Btu+255.0436Btu=23422.0963Btu

Substitute 23422.0963Btu for m2u2, 0.4639lbm for m1, 1099.8Btu/lbm for u1,85.7279lbm for min, and 1210.9Btu/lbm for hin in Equation (VI).

Qin=[23422.0963Btu/lbm(0.4639lbm)(1099.8Btu/lbm)(85.7279lbm)(1210.9Btu/lbm)]=(23422.0963510.1972103807.9141)Btu=80896.0151Btu

Here, the negative sign indicates that the heat transfer occurs from the tank to the surrounding.

Qout=80896.0151Btu

Thus, the amount of the heat transfer is 80896.0151Btu.

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Chapter 5 Solutions

Thermodynamics: An Engineering Approach

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