INTRO.TO CHEM.ENGR.THERMO.-EBOOK>I<
INTRO.TO CHEM.ENGR.THERMO.-EBOOK>I<
8th Edition
ISBN: 9781260940961
Author: SMITH
Publisher: INTER MCG
Question
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Chapter 5, Problem 5.47P

(a)

Interpretation Introduction

Interpretation:

What is the minimum power requirement in hp of air.

Concept Introduction:

The minimum power requirement is calculated by following formula if air is assumed as an ideal gas:

  Wideal=ΔHTσΔS

    ....(1)

(a)

Expert Solution
Check Mark

Answer to Problem 5.47P

  Wideal=1.848hp

Explanation of Solution

Given information:

It is given that air at70Fand 1 atm is cooled at the rate of100000ft3hr to20F by refrigeration. The surrounding temperature is given as70F .

Hence

  T0=70F+459.67=529.67Rankine

  T=20F+459.67=479.67Rankine

  Tσ=70F+459.67=529.67Rankine

  V=100000ft3hr

From equation (1),

  Wideal=ΔHTσΔS

For an ideal gasΔH=RT1T2CPRdT where,

  T0TΔCPRdT=AT0(τ1)+B2T02(τ21)+C3T03(τ31)+DT0(τ1τ)

    ....(2)

And

  τ=TT0

Values of above constants for air in equation (2) are given in appendix C table C.1 and noted down below:

  iA103B106C105Dair3.3550.57500.016

Hence

  τ=TT0τ=479.67Rankine529.67Rankine=0.906

And

  T0TΔCPRdT=AT0(τ1)+B2T02(τ21)+C3T03(τ31)+DT0(τ1τ)T0TΔCPRdT=3.355×529.67×(0.9061)+0.575×1032×529.672×(0.90621)+03×529.673(0.90631)+0.016×105529.67(0.90610.906)T0TΔCPRdT=181.18Rankine

Therefore,

  ΔH=RT1T2CPRdTΔH=1.987btulb-mol Rankine×181.18RankineΔH=360btulb-mol 

And

For an ideal isobaric gasΔS=RT1T2CPRdTT where,

  T0TΔCPRdTT=[A+[BT0+(CT02+Dτ2T02)(τ+12)](τ1lnτ)]lnτ

    ....(3)

And

  τ=TT0

Values of above constants for air in equation (3) are given in appendix C table C.1 and noted down below:

  iA103B106C105Dair3.3550.57500.016

Hence

  τ=TT0τ=479.67Rankine529.67Rankine=0.906

And

  T0TΔCPRdTT=[A+[BT0+(CT02+Dτ2T02)(τ+12)](τ1lnτ)]lnτT0TΔCPRdTT=[3.355+[0.575×103×529.67+(0.016×1050.9062×529.672)(0.906+12)](0.9061ln0.906)]ln0.906T0TΔCPRdTT=0.3592

Therefore,

  ΔS=RT1T2CPRdTTΔS=1.987btulb-mol Rankine×0.3592ΔS=0.714btulb-mol Rankine

Hence

  Wideal=ΔHTσΔSWideal=360btulb-mol +529.67Rankine×0.714btulb-mol RankineWideal=18.184btulb-mol 

And we know that for an ideal gas, ideal gas law is applicable and hence

  PV=nRTn=PVRT=1atm×100000ft3hr0.730ft3.atmlb-mol Rankine×529.67Rankine=258.626lb-molhr

Hence

  Wideal=18.184btulb-mol ×258.626lb-molhr=4702.953btuhrWideal=4702.953btuhr×0.000393hp1btuhr=1.848hpWideal=1.848hp

(b)

Interpretation Introduction

Interpretation:

What is the minimum power requirement inkW of air.

Concept Introduction:

The minimum power requirement is calculated by following formula if air is assumed as an ideal gas:

  Wideal=ΔHTσΔS

    ....(1)

(b)

Expert Solution
Check Mark

Answer to Problem 5.47P

  Wideal=2.019kW

Explanation of Solution

Given information:

It is given that air at25Cand 1 atm is cooled at the rate of3000m3hr to8C by refrigeration. The surrounding temperature is given as25C .

Hence

  T0=25C+273.15=298.15K

  T=8C+273.15=265.15K

  Tσ=25C+273.15=298.15K

  V=3000m3hr

From equation (1),

  Wideal=ΔHTσΔS

For an ideal gasΔH=RT1T2CPRdT where,

  T0TΔCPRdT=AT0(τ1)+B2T02(τ21)+C3T03(τ31)+DT0(τ1τ)

    ....(2)

And

  τ=TT0

Values of above constants for air in equation (2) are given in appendix C table C.1 and noted down below:

  iA103B106C105Dair3.3550.57500.016

Hence

  τ=TT0τ=265.15K298.15K=0.8893

And

  T0TΔCPRdT=AT0(τ1)+B2T02(τ21)+C3T03(τ31)+DT0(τ1τ)T0TΔCPRdT=3.355×298.15×(0.88931)+0.575×1032×298.152×(0.889321)+03×298.153(0.889331)+0.016×105298.15(0.889310.8893)T0TΔCPRdT=115.41K

Therefore,

  ΔH=RT1T2CPRdTΔH=8.314Jmol K×115.41KΔH=959.52Jmol

And

For an ideal isobaric gasΔS=RT1T2CPRdTT where,

  T0TΔCPRdTT=[A+[BT0+(CT02+Dτ2T02)(τ+12)](τ1lnτ)]lnτ

    ....(3)

And

  τ=TT0

Values of above constants for air in equation (3) are given in appendix C table C.1 and noted down below:

  iA103B106C105Dair3.3550.57500.016

Hence

  τ=TT0τ=265.15K298.15K=0.8893

And

  T0TΔCPRdTT=[A+[BT0+(CT02+Dτ2T02)(τ+12)](τ1lnτ)]lnτT0TΔCPRdTT=[3.355+[0.575×103×298.15+(0.016×1050.8892×298.152)(0.889+12)](0.8891ln0.889)]ln0.889T0TΔCPRdTT=0.411

Therefore,

  ΔS=RT1T2CPRdTTΔS=8.314Jmol K×0.411ΔS=3.417Jmol K

Hence

  Wideal=ΔHTσΔSWideal=959.52Jmol298.15K×3.417Jmol KWideal=59.275Jmol

And we know that for an ideal gas, ideal gas law is applicable and hence

  PV=nRTn=PVRT=1atm×3000m3hr8.205×105m3atmmol K×298.15K=122633.142molhr

Hence

  Wideal=59.275Jmol×122633.142molhr=7269079.494JhrWideal=7269079.494Jhr×1hr3600s×1kJs1000Js×1kW1kJs=2.019kWWideal=2.019kW

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