Physics for Scientists and Engineers With Modern Physics
Physics for Scientists and Engineers With Modern Physics
9th Edition
ISBN: 9781133953982
Author: SERWAY, Raymond A./
Publisher: Cengage Learning
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Chapter 22, Problem 31P

(a)

To determine

The temperature at exit.

(a)

Expert Solution
Check Mark

Answer to Problem 31P

The temperature at exit is 564K.

Explanation of Solution

Write the pressure volume relation in adiabatic expansion.

  PiViγ=PfVfγ                                                                                                              (I)

Here, Pi is the initial pressure, Pf is the final pressure, Vi is the initial volume, Vf is the final volume and γ is the adiabatic constant.

Write pressure volume temperature relation in adiabatic process.

  (PiViTi)γ=(PfVfTf)γ                                                                                                  (II)

Here, Ti is the initial temperature and Tf is the final temperature.

Divide equation (I) by (II) to get Tf.

  PiViγ(PiViTi)γ=PfVfγ(PfVfTf)γTiγPiγ1=TfγPfγ1Tfγ=TiγPfγ1Piγ1Tf=Ti(PfPi)γ1γ                                                                                              (III)

Write the expression to convert temperature in degree Celsius into Kelvin scale.

  T(K)=T(°C)+273                                                                                              (IV)

Here, T(K) is the temperature in Kelvin scale and T(°C) is the temperature in degree Celsius.

Conclusion:

For argon, value for adiabatic constant is 53.

Substitute 800°C for T(°C) in equation (IV) to get T(K).

  T(K)=800°C+273=1073K

Substitute 1073K for Ti, 53 for γ, 300kPa for Pf and 1.50MPa for Pi in equation (III) to get Tf.

  Tf=(1073K)(300kPa1000 Pa1 kPa1.50MPa106 Pa1 MPa)53153=(1073K)(300×103Pa1.50×106Pa)25=564K

Therefore, the temperature at exit is 564K.

(b)

To determine

The maximum power output of the engine.

(b)

Expert Solution
Check Mark

Answer to Problem 31P

The maximum power output of the engine is 212kW .

Explanation of Solution

Write the expression for the change in internal energy.

  ΔEint=nCVΔT                                                                                                         (V)

Here, ΔEint is the change in internal energy, n is the number of moles, CV is the specific heat capacity at constant volume and ΔT is the change in temperature.

Write the expression for the change in internal energy using first law of thermodynamics.

  ΔEint=QWeng                                                                                                      (VI)

Here, Q is the heat absorbed by argon gas and Weng is the work done by the engine.

For an adiabatic process total heat change will be zero.

Substitute 0 for Q in equation (VI) to get Weng.

  ΔEint=0WengWeng=ΔEint                                                                                                       (VII)

Substitute nCVΔT for ΔEint in equation (VII) to get Weng.

  Weng=nCVΔT                                                                                                    (VIII)

Write the expression for the power output of the turbine.

  P=WengΔt                                                                                                                (IX)

Here, Δt is the time.

Substitute nCVΔT for Weng in above equation to get P.

  P=nCVΔTΔt                                                                                                            (X)

Write the expression for n.

  n=m(kg)×1mol0.0399kg

Here, m(kg) is the mass in kilogram.

Write the expression for ΔT.

  ΔT=TfTi

Here, Ti is the initial temperature and Tf is the final temperature.

Substitute TfTi for ΔT and m(kg)×1mol0.0399kg for n in equation (X) to get P.

  P=(m(kg)×1mol0.0399kg)CV(TfTi)Δt                                                                 (XI)

Conclusion:

Substitute 80.0kg for m(kg), 32 for CV, 564K for Tf and 1073K for Ti and 1min for Δt in equation (XI) to get P.

  P=(80.0kg×1mol0.0399kg)32(564K1073K)1min×60s1min=2.12×105W×1kW1000W=212kW

Therefore, the maximum power output of the engine is 212kW .

(c)

To determine

The maximum efficiency of the engine.

(c)

Expert Solution
Check Mark

Answer to Problem 31P

The maximum efficiency of the engine is 0.475.

Explanation of Solution

Write the expression for the efficiency of Carnot engine.

  ec=1TcTh

Conclusion:

Substitute 564K for Tc and 1073K for Th in above equation to get maximum efficiency.

  ec=1564K1073K=0.475K

Therefore, the maximum efficiency of the engine is 0.475.

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Chapter 22 Solutions

Physics for Scientists and Engineers With Modern Physics

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