INTRO.TO CHEM.ENGR.THERMO.-EBOOK>I<
INTRO.TO CHEM.ENGR.THERMO.-EBOOK>I<
8th Edition
ISBN: 9781260940961
Author: SMITH
Publisher: INTER MCG
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Chapter 6, Problem 6.54P
Interpretation Introduction

Interpretation:

Determine the entropy change for propane gas caused by the given process.

Concept Introduction:

Since at first the gas is not ideal gas, so the actual path of the process is divided into two step process in which at first step the gas will convert from real gas into ideal gas at given T1 and P1 . The properties will change accordingly. In the second steps the ideal gas changes state from (T1,P1) to (T2,P2) during throttling process.

The entropy change is calculated as:

  ΔS=T1T2CPigdTTRlnP2P1+S2RS1R....(1)

And the temperature change for an ideal gas during throttling is zero because throttling process is isenthalpic and for an ideal gas enthalpy is the function of temperature only, so the temperature does not change during throttling process for an ideal gas.

Expert Solution & Answer
Check Mark

Answer to Problem 6.54P

Entropy change is

  ΔS=24.65Jmol K

Explanation of Solution

Given information:

It is given that propane is at 22bar and 423K and is throttled in a steady state flow process to 1bar .

It is also given that at final state gas is assumed to be an ideal gas.

Step 1,

A hypothetical process that transforms a real propane gas into an ideal gas at T1 and P1 before throttling process,

The entropy and enthalpy change for this process are:

  H1igH1=H1R

and

  S1igS1=S1R

Where H1R and S1R are calculated from

  H1R=(H1R)0+ω(H1R)1

And

  S1R=(S1R)0+ω(S1R)1

For pure species propane, the properties can be written down using Appendix B, Table B.1

ω=0.152, Tc=369.8K, Pc=42.48bar, ZC=0.276, Tn=231.1K, VC=200cm3mol

  Tr=T1TcTr=423K369.8K=1.144

  Pr=P1PcPr=22bar42.48bar=0.518

So, at above values of Tr and Pr, The values of ( H R)RTC0 and ( H R)RTC1 can be written from Appendix D

Tr=1.144 lies between reduced temperatures Tr=1.1 and Tr=1.15 and Pr=0.518 lies in between reduced pressures Pr=0.4 and Pr=0.6 .

At Tr=1.1 and Pr=0.4

( H R)RTC0=0.367, ( S R)R0=0.23

At Tr=1.1 and Pr=0.6

( H R)RTC0=0.581, ( S R)R0=0.371

At Tr=1.15 and Pr=0.4

( H R)RTC0=0.334, ( S R)R0=0.201

At Tr=1.15 and Pr=0.6

( H R)RTC0=0.523, ( S R)R0=0.319

And

At Tr=1.1 and Pr=0.4

( H R)RTC1=0.251, ( S R)R1=0.229

At Tr=1.1 and Pr=0.6

( H R)RTC1=0.381, ( S R)R0=0.35

At Tr=1.15 and Pr=0.4

( H R)RTC1=0.199, ( S R)R0=0.183

At Tr=1.15 and Pr=0.6

( H R)RTC1=0.296, ( S R)R0=0.275

Applying linear interpolation of two independent variables, From linear double interpolation, if M is the function of two independent variable X and Y then the value of quantity M at two independent variables X and Y adjacent to the given values are represented as follows:

  X1XX2Y1M1,1M1,2YM=?Y2M2,1M2,2

  M=[( X 2 X X 2 X 1 )M1,1+( X X 1 X 2 X 1 )M1,2]Y2YY2Y1+[( X 2 X X 2 X 1 )M2,1+( X X 1 X 2 X 1 )M2,2]YY1Y2Y1( H R )RTC0=[( 0.60.518 0.60.4)×0.367+( 0.5180.4 0.60.4)×0.581]×1.151.1441.151.1+[( 10.815 10.8)×0.334+( 0.8150.4 10.8)×0.523]×1.1441.11.151.1( H R )RTC0=0.451

  M=[( X 2 X X 2 X 1 )M1,1+( X X 1 X 2 X 1 )M1,2]Y2YY2Y1+[( X 2 X X 2 X 1 )M2,1+( X X 1 X 2 X 1 )M2,2]YY1Y2Y1( S R )R0=[( 0.60.518 0.60.4)×0.23+( 0.5180.4 0.60.4)×0.371]×1.151.1441.151.1+[( 10.815 10.8)×0.201+( 0.8150.4 10.8)×0.319]×1.1441.11.151.1( S R )R0=0.276

And

  M=[( X 2 X X 2 X 1 )M1,1+( X X 1 X 2 X 1 )M1,2]Y2YY2Y1+[( X 2 X X 2 X 1 )M2,1+( X X 1 X 2 X 1 )M2,2]YY1Y2Y1( H R )RTC1=[( 0.60.518 0.60.4)×0.251+( 0.5180.4 0.60.4)×0.381]×1.151.1441.151.1+[( 10.815 10.8)×0.199+( 0.8150.4 10.8)×0.296]×1.1441.11.151.1( H R )RTC1=0.265

  M=[( X 2 X X 2 X 1 )M1,1+( X X 1 X 2 X 1 )M1,2]Y2YY2Y1+[( X 2 X X 2 X 1 )M2,1+( X X 1 X 2 X 1 )M2,2]YY1Y2Y1( S R )R1=[( 0.60.518 0.60.4)×0.229+( 0.5180.4 0.60.4)×0.35]×1.151.1441.151.1+[( 10.815 10.8)×0.183+( 0.8150.4 10.8)×0.275]×1.1441.11.151.1( S R )R1=0.245

Now, from equation,

  H1R=(H1R)0+ω(H1R)1

Or

  H1RRTC=( H 1 R )0RTC+ω( H 1 R )1RTCH1RRTC=0.451+0.152×0.265H1RRTC=0.4913H1R=0.4913×8.314Jmol K×369.8KH1R=1510.51Jmol

And

  S1R=(S1R)0+ω(S1R)1

Or

  S1RR=( S 1 R )0R+ω( S 1 R )1RS1RR=0.276+0.152×0.245S1RR=0.6344S1R=0.313×8.314Jmol KS1R=2.6JmolK

For Step 2

Enthalpy will not change during throttling of propylene, so ΔH=0

Enthalpy of propylene which is now in ideal state is same in final state and hence

  H1R=1510.51Jmol

  ΔH=T1T2CPigdTH1R0=T1T2CPigdTH1RH1R=RT1T2CPigRdTH1RR=T1T2CPigRdT

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

Where τ=TT0

Values of above constants forpropane in above equation are given in appendix C table C.1 and noted down below:

  iA103B106C105Dpropane1.21328.7858.8240

  1510.51Jmol8.314Jmol K=AT0(τ1)+B2T02(τ21)+C3T03(τ31)+DT0(τ1τ)181.68=1.213×423×(τ1)+28.785×1032×4232×(τ21)+8.824×1063×4233(τ31)τ=0.963

And

Hence

  0.963=T423KT=407.35K

Now for entropy change

  ΔS=T1T2CPigdTTRlnP2P1S1R

  T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ1lnτ)]×lnτ

  τ=0.963

Values of above constants for propane in above equation are given in appendix C table C.1 and noted down below:

  iA103B106C105Dpropane1.21328.7858.8240

  T1T2 C P igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2 )( τ+12)}(τ1lnτ)]×lnτT1T2CP igRdTT=[1.213+{28.785×103×423+(8.824×106×4232+0× 10 5 0.963 2× 423 2)(0.963+12)}(0.9631ln0.963)]×ln0.963T1T2CPigRdTT=0.439

Hence,

  ΔS=RT1T2 C P igRdTTRln P 2 P 1S1RΔS=8.314Jmol K×0.4398.314Jmol K×ln122(2.6JmolK)ΔS=24.65Jmol K

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