Loose Leaf For Introduction To Chemical Engineering Thermodynamics
Loose Leaf For Introduction To Chemical Engineering Thermodynamics
8th Edition
ISBN: 9781259878084
Author: Smith Termodinamica En Ingenieria Quimica, J.m.; Van Ness, Hendrick C; Abbott, Michael; Swihart, Mark
Publisher: McGraw-Hill Education
Question
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Chapter 5, Problem 5.28P

(a)

Interpretation Introduction

Interpretation:

Entropy change of the gas for given steady state flow process at atmospheric pressure should be determined.

(a)

Expert Solution
Check Mark

Answer to Problem 5.28P

  ΔS=900.86JK

Explanation of Solution

Given information:

When 800kJ is added to 10mol of ethylene initially at 200C

  T0=200C+273.15=473.15K

And entropy of process at constant pressure is calculated by following formula,

  ΔS=nRT0TCPRdTTwhere,T0TCPRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ1lnτ)]×lnτ

where

  τ=TT0

And values of constants for ethylene in above equation are given in appendix C table C.1 and noted down below:

  iA103B106C105DEthylene1.42414.3944.3920

For final temperature,

  Q=ΔH=T1T2CPigdTQ=nRT1T2CPigRdT

Where

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

and τ=TT0

Put the values

  QnR=AT0(τ1)+B2T02(τ21)+C3T03(τ31)+DT0(τ1τ)800kJ×1000J1kJ10mol×8.314Jmol K=1.424×473.15(τ1)+14.394×1032×473.152(τ21)+4.392×1063×473.153(τ31)9622K=673.76(τ1)+1611.199(τ21)155.07(τ31)τ=2.905

Hence final temperature is:

  τ=TT0T=2.905×473.15KT=1374.5K

Now, the entropy change is:

  T1T2CP igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2)(τ+12)}(τ1lnτ)]×lnτT1T2CPigRdTT=[1.424+{14.394×103×473.15+(4.392×106×473.152)(2.905+12)}(2.9051ln2.905)]×ln2.905T1T2CPigRdTT=10.8355

Therefore entropy change is

  ΔS=nRT0TCPRdTTΔS=10mol×8.314Jmol K×10.8355ΔS=900.86JK

(b)

Interpretation Introduction

Interpretation:

Entropy change of the gas for given steady state flow process at atmospheric pressure should be determined.

(b)

Expert Solution
Check Mark

Answer to Problem 5.28P

  ΔS=2657.75JK

Explanation of Solution

Given information:

When 2500kJ is added to 15mol of 1-butene initially at 260C

  T0=260C+273.15=533.15K

And entropy of process at constant pressure is calculated by following formula,

  ΔS=nRT0TCPRdTTwhere,T0TCPRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ1lnτ)]×lnτ

where

  τ=TT0

And values of constants for1-butene in above equation are given in appendix C table C.1 and noted down below:

  iA103B106C105D1Butene1.96731.6309.8730

For final temperature,

  Q=ΔH=T1T2CPigdTQ=nRT1T2CPigRdT

Where

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

and τ=TT0

Put the values

  QnR=AT0(τ1)+B2T02(τ21)+C3T03(τ31)+DT0(τ1τ)2500kJ×1000J1kJ15mol×8.314Jmol K=1.967×533.15(τ1)+31.63×1032×533.152(τ21)+9.873×1063×533.153(τ31)τ=2.652

Hence, final temperature is

  τ=TT0T=2.652×533.15KT=1413.9K

Now, the entropy change is:

  T1T2CP igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2)(τ+12)}(τ1lnτ)]×lnτT1T2CPigRdTT=[1.967+{31.63×103×533.15+(9.873×106×533.152)(2.652+12)}(2.6521ln2.652)]×ln2.652T1T2CPigRdTT=21.3114

Therefore entropy change is

  ΔS=nRT0TCPRdTTΔS=15mol×8.314Jmol K×21.3114ΔS=2657.75JK

(c)

Interpretation Introduction

Interpretation:

Entropy change of the gas for given steady state flow process at atmospheric pressure should be determined.

(c)

Expert Solution
Check Mark

Answer to Problem 5.28P

  ΔS=1238441.845JK=1.24×106JK

Explanation of Solution

Given information:

When 106(btu) is added to 40lb-mol of ethylene initially at 500F

  T0=(500F-32)(59)+273.15=533.15KandQ=106(btu)=1.05×106kJn=40lb-mol=18.14kmol

And entropy of process at constant pressure is calculated by following formula,

  ΔS=nRT0TCPRdTTwhere,T0TCPRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ1lnτ)]×lnτ

where

  τ=TT0

And value of constants for ethylene in above equation are given in appendix C table C.1 and noted down below:

  iA103B106C105DEthylene1.42414.3944.3920

For final temperature,

  Q=ΔH=T1T2CPigdTQ=nRT1T2CPigRdT

Where

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

and τ=TT0

Put the values

  QnR=AT0(τ1)+B2T02(τ21)+C3T03(τ31)+DT0(τ1τ)1.05×106kJ18.14kmol×8.314Jmol K=1.424×533.15(τ1)+14.394×1032×533.152(τ21)+4.392×1063×533.153(τ31)τ=2.25

Hence, final temperature is

  τ=TT0T=2.25×533.15KT=1199.587K

Now, the entropy change is:

  T1T2CP igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2)(τ+12)}(τ1lnτ)]×lnτT1T2CPigRdTT=[1.424+{14.394×103×533.15+(4.392×106×533.152)(2.25+12)}(2.251ln2.25)]×ln2.25T1T2CPigRdTT=8.21161

Therefore entropy change is

  ΔS=nRT0TCPRdTTΔS=18.14kmol×8.314Jmol K×8.21161×1000mol1kmolΔS=1238441.845JK=1.24×106JK

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