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 128P

An insulated 0.15-m3 tank contains helium at 3 MPa and 130°C. A valve is now opened, allowing some helium to escape. The valve is closed when one-half of the initial mass has escaped. Determine the final temperature and pressure in the tank.

Expert Solution & Answer
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To determine

The final temperature and pressure in the tank.

Answer to Problem 128P

The final temperature in the tank is 257K.

The final pressure in the tank is 956kPa.

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 tank as the control volume. Initially the tank is filled with helium and the valve is closed. No mass is allowed to inlet the tank i.e. min=0.

Rewrite the Equation (I) as follows.

0me=(m2m1)cvme=m1m2 (II)

It is given that the valve is opened until the initial mass of the helium reached into half (final mass).

m2=12m1 (III)

Write the formula for initial and final masses.

m1=P1ν1RT1 (IV)

m2=P2ν2RT2 (V)

Here, the pressure is P, the volume is ν, the gas constant of is R, the temperature is T and the subscripts 1 and 2 indicates the initial and final states.

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 (VI)

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.

When the valve is opened the mass (helium) is allowed to escape and no work is done i.e. Win=We=0. There is no heat transfer .i.e. Qin=Qe=0. Neglect the kinetic and potential energy changes i.e. (Δke=Δpe=0).

The Equation (VI) reduced as follows.

mehe=m2u2m1u1m2u2m1u1+mehe=0 (VII)

Write the general expressions for enthalpy and internal energy.

h=cpTu=cvT

Here, the specific heat at constant pressure is cp, the specific heat at constant volume is cv and the temperature is T.

Here, the enthalpy of the helium changes continuously while leaving the tank. For simplicity, consider the properties of exiting helium as constant corresponding to the average temperature of initial and final states.

he=cp(T1+T22)

Rewrite the equation (VII) as follows with reference to the exit enthalpy and general expression of internal energy.

m2cvT2m1cvT1+mecp(T1+T22)=0 (VIII)

Refer Table A-2 (a), “Ideal-gas specific heats of various common gases”.

The specific heat at constant pressure (cp) is 5.1926kJ/kgK and the specific heat at constant volume (cv) is 3.1156kJ/kgK. The specific heat ratio (k) is 1.667.

Conclusion:

Substitute 12m1 for m2 in Equation (II).

me=m112m1=12m1

Substitute 12m1 for m2,me in Equation (VIII).

(12m1)cvT2m1cvT1+(12m1)cp(T1+T22)=012m1cvT2m1cvT1+14m1cp(T1+T2)=0 (IX)

Divide the Equation (IX) by m12 on both sides.

12m1cvT2m1cvT1+14m1cp(T1+T2)m12=0m12cvT22cvT1+12cp(T1+T2)=0 (X)

Divide the Equation (X) by cv on both sides.

cvT22cvT1+12cp(T1+T2)cv=0cvT22T1+12cpcv(T1+T2)=0

The specific heat ratio is, k=cpcv.

Substitute k for cpcv.

T22T1+12k(T1+T2)=02T24T1+k(T1+T2)=02T24T1+kT1+kT2=0T2(2+k)T1(4k)=0

T2=T1(4k)2+k (XI)

Substitute 130°C for T1 and 1.667 for k in Equation (XI).

T2=(130°C)(41.667)2+1.667=(130+273)K(41.667)2+1.667=403K(2.333)3.667=256.3946K

257K

Thus, the final temperature in the tank is 257K.

Divide the Equation (V) by Equation (IV).

m2m1=P2ν2RT2P1ν1RT1m2m1=P2ν2RT2×RT1P1ν1m2m1=P2ν2T2P1ν1T2P2=m2P1ν1T2m1ν2T1 (XII)

Here, the volume of the tank cannot change. Hence, the initial and final volumes are equal.

v1=v2

The Equation (XII) becomes as follows.

P2=m2P1T2m1T1 (XIII)

Substitute 12m1 for m2, 3MPa for P1, 130°C for T1 and 257K in Equation (XIII).

P2=(12m1)(3MPa)(257K)m1(130°C)=(3MPa×1000kPa1MPa)(257K)2(130+273)K=7710000kPaK806K=956.5757kPa

956kPa

Thus, the final pressure in the tank is 956kPa.

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Chapter 5 Solutions

Thermodynamics: An Engineering Approach

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