EBK THERMODYNAMICS: AN ENGINEERING APPR
EBK THERMODYNAMICS: AN ENGINEERING APPR
8th Edition
ISBN: 8220100257056
Author: CENGEL
Publisher: YUZU
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Chapter 7.13, Problem 176RP
To determine

The work and heat transfer for each process.

Expert Solution & Answer
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Answer to Problem 176RP

The heat transfer for the isothermal process 1–2 is 117.7kJ.

The work done during the process 1-2 is 117.7kJ.

The work done during the isentropic compression process 2-3 is 97.1kJ.

The heat transfer for the isentropic process 2–3 is 0kJ.

The work done during constant pressure compression process 3-1 is 37kJ.

The heat transfer during constant pressure compression process 3-1 is 135.8kJ.

Explanation of Solution

Write the expression to calculate the enthalpy change in process 1-2.

ΔS12=mRlnP2P1        (I)

Here, pressure at process 1 is P1 , mass of the air is m, gas constant of air is R and pressure at process 2 is P2.

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

m=P1ν1RT1        (II)

Here, mass of the air is m , volume at process 1 is ν1 and temperature at process1 is T1

Write the expression to calculate the heat transfer for the isothermal process 1–2.

Qin,12=T1ΔS12             (III)

Here, enthalpy change in process 1-2 is ΔS12, heat transfer for the isothermal process 1–2 is Qin,12 and temperature at 1 stage is T1,

Write the expression to calculate the work done during the process 1-2 (Wout,12).

Wout,12=Qin,12      (IV)

Write the expression to calculate the work done during the isentropic compression process 2-3 (Win,23).

Win,23=m(u3u2)        (V)

Here, mass of the air is m, internal energy at process 3 is u3 and internal energy at process 2 is u2.

Write the expression to calculate the relative pressure at process 3 (Pr3).

Pr3=P3P2Pr2        (VI)

Here, relative pressure at process 2 is Pr2.

Write the expression to calculate the volume at process 3(ν3)

ν3=mRT3P3      (VII)

Write the expression to calculate the work done during constant pressure compression process 3-1 (Win,31).

Win,31=P3(ν3ν1)      (VIII)

Here, volume at process 3 is ν3 and volume at process 1 is ν1.

Write the expression to calculate the heat transfer during constant pressure compression process 3-1(Qout,31).

Qout,31=Win,31m(u1u3)    (IX)

Here, heat transfer during constant pressure compression process 3-1 is Qout,31 and internal energy at process 1 is u1

Conclusion:

From Table A-1 “the molar mass, gas constant and critical point properties table”, obtain the gas constant (R) of air as 0.287kJ/kgK.

Substitute 400kPa for P1, 0.3m3 for ν1, 0.287kJ/kgK for R and 300 K for T1 in Equation (II).

m=(400 kPa)(0.3m3)(0.287kJ/kgK)(300K)=1.394kg

Substitute 1.394 kg for m, 0.287kJ/kgK for R, 400kPa for P1 and 150kPa for P2 in Equation (I).

ΔS12=(1.394kg)(0.287kJ/kgK)ln150kPa400kPa=0.3924kJ/K

Substitute 27°C for T1 and 0.3924kJ/K for ΔS12 in Equation (III).

Qin,12=27°C(0.3924kJ/K)=(27+273)K(0.3924kJ/K)=117.7kJ

Thus, the heat transfer for the isothermal process 1–2 is 117.7kJ.

Substitute 117.7kJ for Qin,12 in Equation (IV).

Wout,12=117.7kJ

Thus, the work done during the process 1-2 is 117.7kJ.

From Table A-17, “Ideal-gas properties of air”, obtain the internal energy (u1) or (u2), entropy (s1) or (s2), and relative pressure (Pr1) or (Pr2), at temperature of 300K as

214.07kJ/kg, 1.70203kJ/kgK and 1.3860 respectively.

Substitute 400kPa for P3, 150kPa for P2 and 1.3860 for Pr2 in Equation (VI).

Pr3=400kPa150kPa(1.3860)=3.696

Refer to Table A-17, “Ideal-gas properties of air”.

Obtain the select the internal energy (u3) and temperature (T3) at the relative pressure of 3.696 by using interpolation method.

Write the formula of interpolation method of two variables.

y2=(x2x1)(y3y1)(x3x1)+y1 (X)

Here, the variables denoted by x and y are relative pressure and internal energy.

Show relative pressure and internal energy values from the Table A-17.

Relative pressure (Pr3)Internal energy (u3), in kJ/kg
3.481278.93
3.696?
3.806286.16

Substitute 3.481 for x1, 3.696 for x2, 3.806 for x3, 278.93 for y1, and 286.16 for y3 in Equation (X).

y2=(3.6963.481)(286.16278.931)(3.8063.481)+278.93=283.71

The value of internal energy process 1 (u3) at the relative pressure of 3.696 is 283.71kJ/kg.

Show temperature and initial internal energy values from the Table A-17.

Temperature (T3)Internal energy (u3), in kJ/kg
3.481390
3.696?
3.806400

Substitute 3.481 for x1, 3.696 for x2, 3.806 for x3, 390 for y1, and 400 for y3 in Equation (X).

y2=(3.6963.481)(400390)(3.8063.481)+390=396.615

The value of Temperature (T3) at the relative pressure of 3.696 is 396.615K.

Substitute 1.394 kg for m, 283.71kJ/kg for u3 and 214.07kJ/kg for u2 in Equation (V).

Win,23=(1.394kg)(283.71kJ/kg214.07kJ/kg)=97.1kJ

Thus, the work done during the isentropic compression process 2-3 is 97.1kJ.

The heat transfer for the isentropic process 2–3 is zero when entropy change remains unchanged for the isentropic compression process.

Thus, the heat transfer for the isentropic process 2–3 is 0kJ.

Substitute 1.394 kg for m, 0.287kJ/kgK for R, 396.6 K for T3 and 400 kPa for P3 in Equation (VII).

ν3=(1.394 kg)(0.287kJ/kgK)(396.6K)(400kPa)=0.3967m3

Substitute 400kPa for P3, 0.3967m3 for v3 and 0.3m3 for v1 in Equation (VIII).

Win,31=(400 kPa)(0.3967m30.3m3)=37kJ

Thus, the work done during constant pressure compression process 3-1 is 37kJ.

Substitute 37 kJ for Win,31, 1.394 kg for m, 214.07kJ/kg for u1 and 283.71kJ/kg for u3 in Equation (IX).

Qout,31=37kJ(1.394 kg)(214.07kJ/kg283.71kJ/kg)=135.8kJ

Thus, the heat transfer during constant pressure compression process 3-1 is 135.8kJ.

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Chapter 7 Solutions

EBK THERMODYNAMICS: AN ENGINEERING APPR

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 - Prob. 14PCh. 7.13 - Prob. 15PCh. 7.13 - Prob. 16PCh. 7.13 - Steam is accelerated as it flows through an actual...Ch. 7.13 - Prob. 18PCh. 7.13 - Prob. 19PCh. 7.13 - Prob. 20PCh. 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 - 7–23 A completely reversible heat pump produces...Ch. 7.13 - During the isothermal heat addition process of a...Ch. 7.13 - Prob. 25PCh. 7.13 - During the isothermal heat rejection process of a...Ch. 7.13 - Prob. 27PCh. 7.13 - Prob. 28PCh. 7.13 - Two lbm of water at 300 psia fill a weighted...Ch. 7.13 - A well-insulated rigid tank contains 3 kg of a...Ch. 7.13 - The radiator of a steam heating system has a...Ch. 7.13 - A rigid tank is divided into two equal parts by a...Ch. 7.13 - 7–33 An insulated piston–cylinder device contains...Ch. 7.13 - Prob. 34PCh. 7.13 - Prob. 35PCh. 7.13 - Onekg of R-134a initially at 600 kPa and 25C...Ch. 7.13 - Refrigerant-134a is expanded isentropically from...Ch. 7.13 - Prob. 38PCh. 7.13 - Refrigerant-134a at 320 kPa and 40C undergoes an...Ch. 7.13 - A rigid tank contains 5 kg of saturated vapor...Ch. 7.13 - A 0.5-m3 rigid tank contains refrigerant-134a...Ch. 7.13 - Prob. 44PCh. 7.13 - Prob. 45PCh. 7.13 - Steam enters an adiabatic diffuser at 150 kPa and...Ch. 7.13 - Prob. 47PCh. 7.13 - An isentropic steam turbine processes 2 kg/s of...Ch. 7.13 - Prob. 50PCh. 7.13 - 7–51 0.7-kg of R-134a is expanded isentropically...Ch. 7.13 - Twokg of saturated water vapor at 600 kPa are...Ch. 7.13 - Steam enters a steady-flow adiabatic nozzle with a...Ch. 7.13 - Prob. 54PCh. 7.13 - In Prob. 755, the water is stirred at the same...Ch. 7.13 - A pistoncylinder device contains 5 kg of steam at...Ch. 7.13 - Prob. 57PCh. 7.13 - Prob. 59PCh. 7.13 - A 50-kg copper block initially at 140C is dropped...Ch. 7.13 - Prob. 61PCh. 7.13 - Prob. 62PCh. 7.13 - A 30-kg aluminum block initially at 140C is...Ch. 7.13 - A 30-kg iron block and a 40-kg copper block, both...Ch. 7.13 - An adiabatic pump is to be used to compress...Ch. 7.13 - Prob. 67PCh. 7.13 - Can the entropy of an ideal gas change during an...Ch. 7.13 - An ideal gas undergoes a process between two...Ch. 7.13 - Prob. 72PCh. 7.13 - Prob. 73PCh. 7.13 - Prob. 74PCh. 7.13 - Prob. 75PCh. 7.13 - A 1.5-m3 insulated rigid tank contains 2.7 kg of...Ch. 7.13 - An insulated pistoncylinder device initially...Ch. 7.13 - A pistoncylinder device contains 0.75 kg of...Ch. 7.13 - Prob. 80PCh. 7.13 - 7–81 Air enters a nozzle steadily at 280 kPa and...Ch. 7.13 - A mass of 25 lbm of helium undergoes a process...Ch. 7.13 - One kg of air at 200 kPa and 127C is contained in...Ch. 7.13 - Prob. 85PCh. 7.13 - Air at 3.5 MPa and 500C is expanded in an...Ch. 7.13 - 7–87E Air is compressed in an isentropic...Ch. 7.13 - An insulated rigid tank is divided into two equal...Ch. 7.13 - An insulated rigid tank contains 4 kg of argon gas...Ch. 7.13 - Prob. 90PCh. 7.13 - Prob. 91PCh. 7.13 - Prob. 92PCh. 7.13 - Air at 27C and 100 kPa is contained in a...Ch. 7.13 - Prob. 94PCh. 7.13 - Helium gas is compressed from 90 kPa and 30C to...Ch. 7.13 - Five kg of air at 427C and 600 kPa are contained...Ch. 7.13 - Prob. 97PCh. 7.13 - The well-insulated container shown in Fig. P 795E...Ch. 7.13 - Prob. 99PCh. 7.13 - Prob. 100PCh. 7.13 - It is well known that the power consumed by a...Ch. 7.13 - Prob. 102PCh. 7.13 - Prob. 103PCh. 7.13 - Saturated water vapor at 150C is compressed in a...Ch. 7.13 - Liquid water at 120 kPa enters a 7-kW pump where...Ch. 7.13 - Prob. 106PCh. 7.13 - Consider a steam power plant that operates between...Ch. 7.13 - Helium gas is compressed from 16 psia and 85F to...Ch. 7.13 - Nitrogen gas is compressed from 80 kPa and 27C to...Ch. 7.13 - Saturated refrigerant-134a vapor at 15 psia is...Ch. 7.13 - Describe the ideal process for an (a) adiabatic...Ch. 7.13 - Is the isentropic process a suitable model for...Ch. 7.13 - On a T-s diagram, does the actual exit state...Ch. 7.13 - Steam at 100 psia and 650F is expanded...Ch. 7.13 - Prob. 117PCh. 7.13 - Combustion gases enter an adiabatic gas turbine at...Ch. 7.13 - Steam at 4 MPa and 350C is expanded in an...Ch. 7.13 - Prob. 120PCh. 7.13 - Prob. 122PCh. 7.13 - Prob. 123PCh. 7.13 - Refrigerant-134a enters an adiabatic compressor as...Ch. 7.13 - Prob. 126PCh. 7.13 - Argon gas enters an adiabatic compressor at 14...Ch. 7.13 - Air enters an adiabatic nozzle at 45 psia and 940F...Ch. 7.13 - Prob. 130PCh. 7.13 - An adiabatic diffuser at the inlet of a jet engine...Ch. 7.13 - Hot combustion gases enter the nozzle of a...Ch. 7.13 - Refrigerant-134a is expanded adiabatically from...Ch. 7.13 - Oxygen enters an insulated 12-cm-diameter pipe...Ch. 7.13 - Prob. 135PCh. 7.13 - Prob. 136PCh. 7.13 - Steam enters an adiabatic turbine steadily at 7...Ch. 7.13 - 7–138 In an ice-making plant, water at 0°C is...Ch. 7.13 - Water at 20 psia and 50F enters a mixing chamber...Ch. 7.13 - Prob. 140PCh. 7.13 - Prob. 141PCh. 7.13 - Prob. 142PCh. 7.13 - Prob. 143PCh. 7.13 - In a dairy plant, milk at 4C is pasteurized...Ch. 7.13 - An ordinary egg can be approximated as a...Ch. 7.13 - Prob. 146PCh. 7.13 - Prob. 147PCh. 7.13 - In a production facility, 1.2-in-thick, 2-ft 2-ft...Ch. 7.13 - Prob. 149PCh. 7.13 - Prob. 150PCh. 7.13 - A frictionless pistoncylinder device contains...Ch. 7.13 - Prob. 152PCh. 7.13 - Prob. 153PCh. 7.13 - Prob. 154PCh. 7.13 - Prob. 155PCh. 7.13 - Liquid water at 200 kPa and 15C is heated in a...Ch. 7.13 - Prob. 157PCh. 7.13 - Prob. 158PCh. 7.13 - Prob. 159PCh. 7.13 - Prob. 160PCh. 7.13 - Prob. 161PCh. 7.13 - Prob. 162PCh. 7.13 - Prob. 163PCh. 7.13 - Prob. 164PCh. 7.13 - Prob. 165PCh. 7.13 - The space heating of a facility is accomplished by...Ch. 7.13 - Prob. 167PCh. 7.13 - Prob. 168PCh. 7.13 - Prob. 169RPCh. 7.13 - A refrigerator with a coefficient of performance...Ch. 7.13 - Prob. 171RPCh. 7.13 - Prob. 172RPCh. 7.13 - Prob. 173RPCh. 7.13 - A 100-lbm block of a solid material whose specific...Ch. 7.13 - Prob. 175RPCh. 7.13 - 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Prob. 202RPCh. 7.13 - Prob. 203RPCh. 7.13 - Prob. 204RPCh. 7.13 - Prob. 205RPCh. 7.13 - Prob. 206RPCh. 7.13 - Prob. 207RPCh. 7.13 - Prob. 208RPCh. 7.13 - (a) Water flows through a shower head steadily at...Ch. 7.13 - Prob. 211RPCh. 7.13 - Prob. 212RPCh. 7.13 - Prob. 213RPCh. 7.13 - Consider the turbocharger of an internal...Ch. 7.13 - Prob. 215RPCh. 7.13 - Prob. 216RPCh. 7.13 - Prob. 217RPCh. 7.13 - Consider two bodies of identical mass m and...Ch. 7.13 - Prob. 220RPCh. 7.13 - Prob. 222RPCh. 7.13 - Prob. 224RPCh. 7.13 - The polytropic or small stage efficiency of a...Ch. 7.13 - Steam is compressed from 6 MPa and 300C to 10 MPa...Ch. 7.13 - An apple with a mass of 0.12 kg and average...Ch. 7.13 - A pistoncylinder device contains 5 kg of saturated...Ch. 7.13 - Prob. 229FEPCh. 7.13 - Prob. 230FEPCh. 7.13 - A unit mass of a substance undergoes an...Ch. 7.13 - A unit mass of an ideal gas at temperature T...Ch. 7.13 - Prob. 233FEPCh. 7.13 - Prob. 234FEPCh. 7.13 - Air is compressed steadily and adiabatically from...Ch. 7.13 - Argon gas expands in an adiabatic turbine steadily...Ch. 7.13 - Water enters a pump steadily at 100 kPa at a rate...Ch. 7.13 - Air is to be compressed steadily and...Ch. 7.13 - Helium gas enters an adiabatic nozzle steadily at...Ch. 7.13 - Combustion gases with a specific heat ratio of 1.3...Ch. 7.13 - Steam enters an adiabatic turbine steadily at 400C...Ch. 7.13 - Liquid water enters an adiabatic piping system at...Ch. 7.13 - Prob. 243FEPCh. 7.13 - Steam enters an adiabatic turbine at 8 MPa and...Ch. 7.13 - Helium gas is compressed steadily from 90 kPa and...
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