THERMODYNAMICS-SI ED. EBOOK >I<
THERMODYNAMICS-SI ED. EBOOK >I<
9th Edition
ISBN: 9781307573022
Author: CENGEL
Publisher: MCG/CREATE
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Chapter 7.13, Problem 206RP

a)

To determine

The average temperature of the room after 30 min.

a)

Expert Solution
Check Mark

Answer to Problem 206RP

The average temperature of the room after 30 min is 12.3°C.

Explanation of Solution

Write the expression for the energy balance equation for closed system without air in the room.

EinEout=ΔEsystem (I)

Here, energy transfer into the control volume is Ein, energy transfer exit from the control volume is Eout and change in internal energy of system is ΔEsystem.

Write the expression to calculate the final vapor quality.

x2=v2vfvgvf (II)

Here, final vapor quality is x2, final molar volume is v2, saturated liquid molar volume is vf and saturated vapor molar volume is vg.

Write the expression to calculate the final internal energy of the system.

u2=uf+x2ufg (III)

Here, final internal energy of the system is u2, saturated liquid internal energy is uf, final vapor quality is x2, and evaporation internal energy is ufg.

Write the expression to calculate the final entropy of the system.

s2=sf+x2sfg (IV)

Here, final entropy of the system is s2, saturated liquid entropy is sf, final vapor quality is x2, and evaporation entropy is sfg.

Write the expression to calculate the mass of the steam.

m=ν1v1 (V)

Here, mass of the steam is m, volume of the steam is ν1 and initial specific volume of steam is v1.

Write the expression to calculate the ideal gas equation, to find the mass of the air.

mair=P1ν1RT1 (VI)

Here, mass of the air is mair, initial pressure is P1, initial volume is ν1, gas constant is R and initial temperature is T1.

Write the expression to calculate the total work done by the fan.

Wfan,in=W˙fan,in(Δt) (VII)

Here, rate of work done by fan is W˙fan,in and time is Δt.

Conclusion:

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

0Qout=ΔUQout=m(u2u1)Qout=m(u1u2) (VIII)

Here, change in internal energy of system is ΔU, heat transfer out is Qout, mass of the steam is m, initial internal energy is u1 and final internal energy is u2.

From the Table A-6, “Superheated water table”, obtain the following properties of steam at temperature of 200 °C and pressure of 200kPa.

v1=1.0805m3/kgu1=2654.4kJ/kgs1=7.5081kJ/kgK

From the Table A-6, “Saturated water-Pressure table”, obtain the following properties of steam at pressure of 100kPa.

vf=0.001043m3/kgvg=1.6941m3/kg

Here, Saturated liquid specific volume is vf and saturated vapor specific volume is vγ.

Substitute 1.0805m3/kg for v2, 0.001043m3/kg for vf and 1.6941m3/kg for vg in Equation (II).

x2=1.0805m3/kg0.001043m3/kg1.6941m3/kg0.001043m3/kg=0.6376

From the Table A-6, “Saturated water-Pressure table”, obtain the following properties of steam at pressure of 100kPa.

uf=417.40kJ/kgufg=2088.2kJ/kg

Here, Saturated liquid internal energy is uf and Evaporation internal energy is ufg.

Substitute 417.40kJ/kg for uf, 0.6376 for x2 and 2088.2kJ/kg for ufg in Equation (III).

u2=417.40kJ/kg+(0.6376)(2088.2kJ/kg)=1748.7kJ/kg

From the Table A-6, “Saturated water-Pressure table”, obtain the following properties of steam at pressure of 100kPa.

sf=1.3028kJ/kgKsfg=6.0562kJ/kgK

Here, Saturated liquid entropy is sf and evaporation entropy is sfg.

Substitute 1.3028kJ/kgK for sf, 0.6376 for x2 and 6.0562kJ/kgK for sfg in Equation (IV).

s2=1.3028kJ/kgK+(0.6376)(6.0562kJ/kgK)=5.1642kJ/kgK

Substitute 0.015m3 for ν1 and 1.0805m3/kg for v1 in Equation (V).

m=0.015m31.0805m3/kg=0.01388kg

Substitute 0.01388 kg for m, 2654.4kJ/kg for u1 and 1748.7kJ/kg for u2 in Equation (VIII).

Qout=(0.01388kg)(2654.4kJ/kg1748.7kJ/kg)=12.6kJ

Substitute Qin+Wfan,in for Ein, Wb,out for Eout and ΔU for ΔEsystem in Equation (I).

Qin+Wfan,inWb,out=ΔUQin+Wfan,in=ΔU+Wb,outQin+Wfan,in=ΔHQin+Wfan,in=mcp(T2T1) (IX)

Here, heat transfer in is Qin, work done by the fan is Wfan,in, mass of the air is m, specific heat at constant pressure is cp, initial temperature is T1 and final temperature is T2.

From the Table A-1, “the molar mass, gas constant and critical point properties table”, select the gas constant of air as 0.2870kJ/kgK.

Substitute 100kPa for P1, (4m×4m×5m) for ν1, 0.2870kJ/kgK for R and 10 °C for T1 in Equation (VI).

mair=(100 kPa)(4m×4m×5m)(0.2870kJ/kgK)10°C=(100 kPa)(80m3)(0.2870kJ/kgK)(1kPam31kJ)(10+273)K=98.5kg

Substitute 0.120kJ/s for W˙fan,in and 30 min for Δt in Equation (VII).

Wfan,in=(0.120kJ/s)(30min)=(0.120kJ/s)(30min)(60sec1min)=216kJ

From the Table A-2, “the ideal–gas equation specific heats of various common gases table”, select the specific heat at constant pressure for air as 1.005kJ/kgK.

Substitute 12.6 kJ for Qin, 216 kJ for Wfan,in, 98.5 kg for m, 1.005kJ/kgK for cp and 10 °C for T1 in Equation (IX).

12.6kJ+216kJ=(98.5 kg)(1.005kJ/kgK)(T210 °C)T2=12.3°C

Thus, the average temperature of the room after 30 min is 12.3°C.

b)

To determine

The entropy change of the steam.

b)

Expert Solution
Check Mark

Answer to Problem 206RP

The entropy change of the steam is 0.0325kJ/K.

Explanation of Solution

Write the expression to calculate the change of entropy of the steam.

ΔSsteam=m(s2s1) (X)

Here, mass of the steam is m, final entropy is s2 and initial entropy is s1.

Conclusion:

Substitute 0.01388 kg for m, 5.1642kJ/kgK for s2 and 7.5081kJ/kgK for s1 in Equation (X).

ΔSsteam=(0.01388 kg)(5.1642kJ/kgK7.5081kJ/kgK)=0.0325kJ/K

Thus, the entropy change of the steam is 0.0325kJ/K.

c)

To determine

The entropy change of the air.

c)

Expert Solution
Check Mark

Answer to Problem 206RP

The entropy change of the air is 0.8013kJ/K.

Explanation of Solution

Write the expression to calculate the entropy change of air.

ΔSair=mcplnT2T1mRlnP2P1

Since, P2=P1.

ΔSair=mcplnT2T1 (XI)

Conclusion:

Substitute 98.5 kg for m, 1.005kJ/kgK for cp, 12.3 °C for T2 and 10 °C for T1 in Equation (XI).

ΔSair=(98.5 kg)(1.005kJ/kgK)ln12.3 °C10 °C=(98.5 kg)(1.005kJ/kgK)ln(12.3+273)K(10+273)K=0.8013kJ/K

Thus, the entropy change of the air is 0.8013kJ/K.

d)

To determine

The entropy generation in the turbine.

d)

Expert Solution
Check Mark

Answer to Problem 206RP

The entropy generation in the turbine is 4.01kW/K.

Explanation of Solution

Write the expression for the entropy balance equation of the system.

SinSout+Sgen=ΔSsystem (XII)

Here, rate of net entropy in is Sin, rate of net entropy out is Sout, rate of entropy generation is Sgen and change of entropy of the system is ΔSsystem

Conclusion:

Substitute 0 for Sin, 0 for Sout and ΔSair+ΔSsteam for ΔSsystem in Equation (XII).

00+Sgen=ΔSair+ΔSsteamSgen=ΔSair+ΔSsteam (XIII)

Here, entropy change of air is ΔSair and entropy change of steam is ΔSstean.

Substitute 0.8013kJ/K for ΔSair and 0.0325kJ/K for ΔSsteam in Equation (XIII).

Sgen=0.8013kJ/K+0.0325kJ/K=0.7688kJ/K

Thus, the total entropy generated during the process is 0.7688kJ/K.

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Chapter 7 Solutions

THERMODYNAMICS-SI ED. EBOOK >I<

Ch. 7.13 - A pistoncylinder device contains helium gas....Ch. 7.13 - A pistoncylinder device contains nitrogen gas....Ch. 7.13 - A pistoncylinder device contains superheated...Ch. 7.13 - The entropy of steam will (increase, decrease,...Ch. 7.13 - During a heat transfer process, the entropy of a...Ch. 7.13 - Steam is accelerated as it flows through an actual...Ch. 7.13 - Heat is transferred at a rate of 2 kW from a hot...Ch. 7.13 - A completely reversible air conditioner provides...Ch. 7.13 - Heat in the amount of 100 kJ is transferred...Ch. 7.13 - In Prob. 719, assume that the heat is transferred...Ch. 7.13 - During the isothermal heat addition process of a...Ch. 7.13 - Prob. 22PCh. 7.13 - During the isothermal heat rejection process of a...Ch. 7.13 - Air is compressed by a 40-kW compressor from P1 to...Ch. 7.13 - Refrigerant-134a enters the coils of the...Ch. 7.13 - A rigid tank contains an ideal gas at 40C that is...Ch. 7.13 - A rigid vessel is filled with a fluid from a...Ch. 7.13 - 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