Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethane are calculated by equations for an ideal gas. Concept Introduction: The entropy change for an ideal gas is calculated by, Δ S = ∫ T 1 T 2 C P i g d T T − R ln P 2 P 1 . ...(1)

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Answer 1

Question

Chapter 6, Problem 6.59P

(a)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethane are calculated by equations for an ideal gas.

Concept Introduction:

The entropy change for an ideal gas is calculated by,

ΔS=∫T1T2CPigdTT−RlnP2P1. ...(1)

(a)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=367.4 K

Work done is

W=−8746.9 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (1)

ΔS=∫T1T2CPigdTT−Rln P 2 P 10=R∫T1T2CP igRdTT−RlnP2P1∫T1T2CPigRdTT=lnP2P1

wherE

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

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

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτlnP2P1=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτln2.630=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.745

τ=TT00.745=T493.15 KT=367.4 K

For work produced

W=ΔH for ideal gas

And for ideal gas

ΔH=∫T1T2CPigdTΔH=R∫T1T2CP igRdT

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.745−1)+19.225×10−32×493.152×(0.7452−1)+−5.561×10−63×493.153(0.7453−1)∫T0TΔC∘PRdT=−1052.07 K

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1052.07 KW=−8746.9 Jmol

(b)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethylene are calculated by appropriate generalized correlations.

Concept Introduction:

The entropy change by appropriate generalized correlations is

ΔS=∫T1T2CPigdTT−RlnP2P1+S2R−S1R. ...(2)

(b)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=362.56 K

Work done is

W=−8453.15 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (2),

ΔS=∫T1T2CPigdTT−Rln P 2 P 1+S2R−S1RR∫T1T2CP igRdTT−RlnP2P1+S2R−S1R=0R∫T1T2CPigRdTT=RlnP2P1−S2R+S1R

Initial statE

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

ω=0.1, Tc=305.3 K, Pc=48.72 bar, ZC=0.279

Tr=T1TcTr=493.15 K305.3 K=1.615

Pr=P1PcPr=30bar48.72 bar=0.61576

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=1.615 lies between reduced temperatures Tr=1.6and Tr=1.7 and Pr=0.61576 lies in between reduced pressures Pr=0.6 and Pr=0.8 .

At Tr=1.6 and Pr=0.6

( H R)RTC0=−0.261, ( S R)R0=−0.12

At Tr=1.6 and Pr=0.8

( H R)RTC0=−0.35, ( S R)R0=−0.162

At Tr=1.7 and Pr=0.6

( H R)RTC0=−0.231, ( S R)R0=−0.102

At Tr=1.7 and Pr=0.8

( H R)RTC0=−0.309, ( S R)R0=−0.137

And

At Tr=1.6 and Pr=0.6

( H R)RTC1=−0.013, ( S R)R1=−0.057

At Tr=1.6 and Pr=0.8

( H R)RTC1=−0.011, ( S R)R1=−0.073

At Tr=1.7 and Pr=0.6

( H R)RTC1=0.009, ( S R)R1=−0.044

At Tr=1.7 and Pr=0.8

( H R)RTC1=0.017, ( S R)R1=−0.056

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.8−0.61576 0.8−0.6)×−0.261+( 0.61576−0.6 0.8−0.6)×−0.35] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.231+( 0.61576−0.6 0.8−0.6)×−0.309] ×1.615−1.61.7−1.6( HR )RTC0=−0.263

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.8−0.61576 0.8−0.6)×−0.12+( 0.61576−0.6 0.8−0.6)×−0.162] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.102+( 0.61576−0.6 0.8−0.6)×−0.137] ×1.615−1.61.7−1.6( SR )R0=−0.1205

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.8−0.61576 0.8−0.6)×−0.013+( 0.61576−0.6 0.8−0.6)×−0.011] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×0.009+( 0.61576−0.6 0.8−0.6)×0.017] ×1.615−1.61.7−1.6( HR )RTC1=−0.0095

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.8−0.61576 0.8−0.6)×−0.057+( 0.61576−0.6 0.8−0.6)×−0.073] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.044+( 0.61576−0.6 0.8−0.6)×−0.056] ×1.615−1.61.7−1.6( SR )R1=−0.056

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R)0RTC+ω( H 1 R)1RTCH1RRTC=−0.263+0.1×−0.0095H1RRTC=−0.26395H1R=−0.26395×8.314 Jmol K×305.3 KH1R=−669.97 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R)0R+ω( S 1 R)1RS1RR=−0.1205+0.1×−0.056S1RR=−0.1261S1R=−0.1261×8.314 Jmol KS1R=−1.048 Jmol K

Final state

Final state temperature is calculated in part (a), T=367.4 K

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

Tr=T2TcTr=367.4 K305.3 K=1.204

Pr=P2PcPr=2.6 bar48.72 bar=0.0534

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=1.204 lies between reduced temperatures Tr=1.2and Tr=1.3 and Pr=0.0534 lies in between reduced pressures Pr=0.05 and Pr=0.1 .

At Tr=1.2 and Pr=0.05

( H R)RTC0=−0.036, ( S R)R0=−0.021

At Tr=1.2 and Pr=0.1

( H R)RTC0=−0.073, ( S R)R0=−0.042

At Tr=1.3 and Pr=0.05

( H R)RTC0=−0.031, ( S R)R0=−0.017

At Tr=1.3 and Pr=0.1

( H R)RTC0=−0.063, ( S R)R0=−0.033

And

At Tr=1.2 and Pr=0.05

( H R)RTC1=−0.02, ( S R)R1=−0.019

At Tr=1.2 and Pr=0.1

( H R)RTC1=−0.04, ( S R)R1=−0.037

At Tr=1.3 and Pr=0.05

( H R)RTC1=−0.013, ( S R)R1=−0.013

At Tr=1.3 and Pr=0.1

( H R)RTC1=−0.026, ( S R)R1=−0.026

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.1−0.0534 0.1−0.05)×−0.036+( 0.0534−0.05 0.1−0.05)×−0.073] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.031+( 0.0534−0.05 0.1−0.05)×−0.063]×1.204−1.21.3−1.2( HR )RTC0=−0.0383

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.1−0.0534 0.1−0.05)×−0.021+( 0.0534−0.05 0.1−0.05)×−0.042] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.017+( 0.0534−0.05 0.1−0.05)×−0.033]×1.204−1.21.3−1.2( SR )R0=−0.022

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.1−0.0534 0.1−0.05)×−0.02+( 0.0534−0.05 0.1−0.05)×−0.04] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( HR )RTC1=−0.02106

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.1−0.0534 0.1−0.05)×−0.019+( 0.0534−0.05 0.1−0.05)×−0.037] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( SR )R1=−0.02

Now, from equation,

H2R=(H2R)0+ω(H2R)1

Or

H2RRTC=( H 2 R)0RTC+ω( H 2 R)1RTCH2RRTC=−0.0383+0.1×−0.02106H2RRTC=−0.0404H2R=−0.0404×8.314 Jmol K×305.3 KH2R=−102.561 Jmol

And

S2R=(S2R)0+ω(S2R)1

Or

S2RR=( S 2 R)0R+ω( S 2 R)1RS2RR=−0.022+0.1×−0.02S2RR=−0.024S2R=−0.024×8.314 Jmol KS2R=−0.1995 Jmol K

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CPigdTT=ln2.630−(−0.1995 Jmol K)8.314 Jmol K+(−1.048 Jmol K)8.314 Jmol K∫T1T2CPigdTT=−2.5477

Hence,

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτ−2.5477= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.7352

τ=TT00.7352=T493.15KT=362.56 K

Now, for work produced

W=ΔH

And enthalpy change by generalized correlations is given by,

ΔH=∫T1T2CPigdT+H2R−H1R

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.735−1)+19.225×10−32×493.152×(0.7352−1)+−5.561×10−63×493.153(0.7353−1)∫T0TΔC∘PRdT=−1088.593 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−1088.593 K+(−102.561 Jmol)−(−669.97 Jmol)W=−8453.15 Jmol

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1425.78 KW=11853.93 Jmol

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Answer 2

Question

Chapter 6, Problem 6.59P

(a)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethane are calculated by equations for an ideal gas.

Concept Introduction:

The entropy change for an ideal gas is calculated by,

ΔS=∫T1T2CPigdTT−RlnP2P1. ...(1)

(a)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=367.4 K

Work done is

W=−8746.9 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (1)

ΔS=∫T1T2CPigdTT−Rln P 2 P 10=R∫T1T2CP igRdTT−RlnP2P1∫T1T2CPigRdTT=lnP2P1

wherE

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

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

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτlnP2P1=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτln2.630=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.745

τ=TT00.745=T493.15 KT=367.4 K

For work produced

W=ΔH for ideal gas

And for ideal gas

ΔH=∫T1T2CPigdTΔH=R∫T1T2CP igRdT

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.745−1)+19.225×10−32×493.152×(0.7452−1)+−5.561×10−63×493.153(0.7453−1)∫T0TΔC∘PRdT=−1052.07 K

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1052.07 KW=−8746.9 Jmol

(b)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethylene are calculated by appropriate generalized correlations.

Concept Introduction:

The entropy change by appropriate generalized correlations is

ΔS=∫T1T2CPigdTT−RlnP2P1+S2R−S1R. ...(2)

(b)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=362.56 K

Work done is

W=−8453.15 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (2),

ΔS=∫T1T2CPigdTT−Rln P 2 P 1+S2R−S1RR∫T1T2CP igRdTT−RlnP2P1+S2R−S1R=0R∫T1T2CPigRdTT=RlnP2P1−S2R+S1R

Initial statE

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

ω=0.1, Tc=305.3 K, Pc=48.72 bar, ZC=0.279

Tr=T1TcTr=493.15 K305.3 K=1.615

Pr=P1PcPr=30bar48.72 bar=0.61576

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=1.615 lies between reduced temperatures Tr=1.6and Tr=1.7 and Pr=0.61576 lies in between reduced pressures Pr=0.6 and Pr=0.8 .

At Tr=1.6 and Pr=0.6

( H R)RTC0=−0.261, ( S R)R0=−0.12

At Tr=1.6 and Pr=0.8

( H R)RTC0=−0.35, ( S R)R0=−0.162

At Tr=1.7 and Pr=0.6

( H R)RTC0=−0.231, ( S R)R0=−0.102

At Tr=1.7 and Pr=0.8

( H R)RTC0=−0.309, ( S R)R0=−0.137

And

At Tr=1.6 and Pr=0.6

( H R)RTC1=−0.013, ( S R)R1=−0.057

At Tr=1.6 and Pr=0.8

( H R)RTC1=−0.011, ( S R)R1=−0.073

At Tr=1.7 and Pr=0.6

( H R)RTC1=0.009, ( S R)R1=−0.044

At Tr=1.7 and Pr=0.8

( H R)RTC1=0.017, ( S R)R1=−0.056

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.8−0.61576 0.8−0.6)×−0.261+( 0.61576−0.6 0.8−0.6)×−0.35] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.231+( 0.61576−0.6 0.8−0.6)×−0.309] ×1.615−1.61.7−1.6( HR )RTC0=−0.263

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.8−0.61576 0.8−0.6)×−0.12+( 0.61576−0.6 0.8−0.6)×−0.162] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.102+( 0.61576−0.6 0.8−0.6)×−0.137] ×1.615−1.61.7−1.6( SR )R0=−0.1205

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.8−0.61576 0.8−0.6)×−0.013+( 0.61576−0.6 0.8−0.6)×−0.011] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×0.009+( 0.61576−0.6 0.8−0.6)×0.017] ×1.615−1.61.7−1.6( HR )RTC1=−0.0095

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.8−0.61576 0.8−0.6)×−0.057+( 0.61576−0.6 0.8−0.6)×−0.073] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.044+( 0.61576−0.6 0.8−0.6)×−0.056] ×1.615−1.61.7−1.6( SR )R1=−0.056

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R)0RTC+ω( H 1 R)1RTCH1RRTC=−0.263+0.1×−0.0095H1RRTC=−0.26395H1R=−0.26395×8.314 Jmol K×305.3 KH1R=−669.97 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R)0R+ω( S 1 R)1RS1RR=−0.1205+0.1×−0.056S1RR=−0.1261S1R=−0.1261×8.314 Jmol KS1R=−1.048 Jmol K

Final state

Final state temperature is calculated in part (a), T=367.4 K

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

Tr=T2TcTr=367.4 K305.3 K=1.204

Pr=P2PcPr=2.6 bar48.72 bar=0.0534

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=1.204 lies between reduced temperatures Tr=1.2and Tr=1.3 and Pr=0.0534 lies in between reduced pressures Pr=0.05 and Pr=0.1 .

At Tr=1.2 and Pr=0.05

( H R)RTC0=−0.036, ( S R)R0=−0.021

At Tr=1.2 and Pr=0.1

( H R)RTC0=−0.073, ( S R)R0=−0.042

At Tr=1.3 and Pr=0.05

( H R)RTC0=−0.031, ( S R)R0=−0.017

At Tr=1.3 and Pr=0.1

( H R)RTC0=−0.063, ( S R)R0=−0.033

And

At Tr=1.2 and Pr=0.05

( H R)RTC1=−0.02, ( S R)R1=−0.019

At Tr=1.2 and Pr=0.1

( H R)RTC1=−0.04, ( S R)R1=−0.037

At Tr=1.3 and Pr=0.05

( H R)RTC1=−0.013, ( S R)R1=−0.013

At Tr=1.3 and Pr=0.1

( H R)RTC1=−0.026, ( S R)R1=−0.026

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.1−0.0534 0.1−0.05)×−0.036+( 0.0534−0.05 0.1−0.05)×−0.073] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.031+( 0.0534−0.05 0.1−0.05)×−0.063]×1.204−1.21.3−1.2( HR )RTC0=−0.0383

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.1−0.0534 0.1−0.05)×−0.021+( 0.0534−0.05 0.1−0.05)×−0.042] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.017+( 0.0534−0.05 0.1−0.05)×−0.033]×1.204−1.21.3−1.2( SR )R0=−0.022

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.1−0.0534 0.1−0.05)×−0.02+( 0.0534−0.05 0.1−0.05)×−0.04] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( HR )RTC1=−0.02106

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.1−0.0534 0.1−0.05)×−0.019+( 0.0534−0.05 0.1−0.05)×−0.037] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( SR )R1=−0.02

Now, from equation,

H2R=(H2R)0+ω(H2R)1

Or

H2RRTC=( H 2 R)0RTC+ω( H 2 R)1RTCH2RRTC=−0.0383+0.1×−0.02106H2RRTC=−0.0404H2R=−0.0404×8.314 Jmol K×305.3 KH2R=−102.561 Jmol

And

S2R=(S2R)0+ω(S2R)1

Or

S2RR=( S 2 R)0R+ω( S 2 R)1RS2RR=−0.022+0.1×−0.02S2RR=−0.024S2R=−0.024×8.314 Jmol KS2R=−0.1995 Jmol K

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CPigdTT=ln2.630−(−0.1995 Jmol K)8.314 Jmol K+(−1.048 Jmol K)8.314 Jmol K∫T1T2CPigdTT=−2.5477

Hence,

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτ−2.5477= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.7352

τ=TT00.7352=T493.15KT=362.56 K

Now, for work produced

W=ΔH

And enthalpy change by generalized correlations is given by,

ΔH=∫T1T2CPigdT+H2R−H1R

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.735−1)+19.225×10−32×493.152×(0.7352−1)+−5.561×10−63×493.153(0.7353−1)∫T0TΔC∘PRdT=−1088.593 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−1088.593 K+(−102.561 Jmol)−(−669.97 Jmol)W=−8453.15 Jmol

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1425.78 KW=11853.93 Jmol

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Answer 3

Question

Chapter 6, Problem 6.59P

(a)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethane are calculated by equations for an ideal gas.

Concept Introduction:

The entropy change for an ideal gas is calculated by,

ΔS=∫T1T2CPigdTT−RlnP2P1. ...(1)

(a)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=367.4 K

Work done is

W=−8746.9 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (1)

ΔS=∫T1T2CPigdTT−Rln P 2 P 10=R∫T1T2CP igRdTT−RlnP2P1∫T1T2CPigRdTT=lnP2P1

wherE

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

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

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτlnP2P1=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτln2.630=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.745

τ=TT00.745=T493.15 KT=367.4 K

For work produced

W=ΔH for ideal gas

And for ideal gas

ΔH=∫T1T2CPigdTΔH=R∫T1T2CP igRdT

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.745−1)+19.225×10−32×493.152×(0.7452−1)+−5.561×10−63×493.153(0.7453−1)∫T0TΔC∘PRdT=−1052.07 K

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1052.07 KW=−8746.9 Jmol

(b)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethylene are calculated by appropriate generalized correlations.

Concept Introduction:

The entropy change by appropriate generalized correlations is

ΔS=∫T1T2CPigdTT−RlnP2P1+S2R−S1R. ...(2)

(b)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=362.56 K

Work done is

W=−8453.15 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (2),

ΔS=∫T1T2CPigdTT−Rln P 2 P 1+S2R−S1RR∫T1T2CP igRdTT−RlnP2P1+S2R−S1R=0R∫T1T2CPigRdTT=RlnP2P1−S2R+S1R

Initial statE

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

ω=0.1, Tc=305.3 K, Pc=48.72 bar, ZC=0.279

Tr=T1TcTr=493.15 K305.3 K=1.615

Pr=P1PcPr=30bar48.72 bar=0.61576

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=1.615 lies between reduced temperatures Tr=1.6and Tr=1.7 and Pr=0.61576 lies in between reduced pressures Pr=0.6 and Pr=0.8 .

At Tr=1.6 and Pr=0.6

( H R)RTC0=−0.261, ( S R)R0=−0.12

At Tr=1.6 and Pr=0.8

( H R)RTC0=−0.35, ( S R)R0=−0.162

At Tr=1.7 and Pr=0.6

( H R)RTC0=−0.231, ( S R)R0=−0.102

At Tr=1.7 and Pr=0.8

( H R)RTC0=−0.309, ( S R)R0=−0.137

And

At Tr=1.6 and Pr=0.6

( H R)RTC1=−0.013, ( S R)R1=−0.057

At Tr=1.6 and Pr=0.8

( H R)RTC1=−0.011, ( S R)R1=−0.073

At Tr=1.7 and Pr=0.6

( H R)RTC1=0.009, ( S R)R1=−0.044

At Tr=1.7 and Pr=0.8

( H R)RTC1=0.017, ( S R)R1=−0.056

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.8−0.61576 0.8−0.6)×−0.261+( 0.61576−0.6 0.8−0.6)×−0.35] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.231+( 0.61576−0.6 0.8−0.6)×−0.309] ×1.615−1.61.7−1.6( HR )RTC0=−0.263

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.8−0.61576 0.8−0.6)×−0.12+( 0.61576−0.6 0.8−0.6)×−0.162] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.102+( 0.61576−0.6 0.8−0.6)×−0.137] ×1.615−1.61.7−1.6( SR )R0=−0.1205

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.8−0.61576 0.8−0.6)×−0.013+( 0.61576−0.6 0.8−0.6)×−0.011] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×0.009+( 0.61576−0.6 0.8−0.6)×0.017] ×1.615−1.61.7−1.6( HR )RTC1=−0.0095

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.8−0.61576 0.8−0.6)×−0.057+( 0.61576−0.6 0.8−0.6)×−0.073] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.044+( 0.61576−0.6 0.8−0.6)×−0.056] ×1.615−1.61.7−1.6( SR )R1=−0.056

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R)0RTC+ω( H 1 R)1RTCH1RRTC=−0.263+0.1×−0.0095H1RRTC=−0.26395H1R=−0.26395×8.314 Jmol K×305.3 KH1R=−669.97 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R)0R+ω( S 1 R)1RS1RR=−0.1205+0.1×−0.056S1RR=−0.1261S1R=−0.1261×8.314 Jmol KS1R=−1.048 Jmol K

Final state

Final state temperature is calculated in part (a), T=367.4 K

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

Tr=T2TcTr=367.4 K305.3 K=1.204

Pr=P2PcPr=2.6 bar48.72 bar=0.0534

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=1.204 lies between reduced temperatures Tr=1.2and Tr=1.3 and Pr=0.0534 lies in between reduced pressures Pr=0.05 and Pr=0.1 .

At Tr=1.2 and Pr=0.05

( H R)RTC0=−0.036, ( S R)R0=−0.021

At Tr=1.2 and Pr=0.1

( H R)RTC0=−0.073, ( S R)R0=−0.042

At Tr=1.3 and Pr=0.05

( H R)RTC0=−0.031, ( S R)R0=−0.017

At Tr=1.3 and Pr=0.1

( H R)RTC0=−0.063, ( S R)R0=−0.033

And

At Tr=1.2 and Pr=0.05

( H R)RTC1=−0.02, ( S R)R1=−0.019

At Tr=1.2 and Pr=0.1

( H R)RTC1=−0.04, ( S R)R1=−0.037

At Tr=1.3 and Pr=0.05

( H R)RTC1=−0.013, ( S R)R1=−0.013

At Tr=1.3 and Pr=0.1

( H R)RTC1=−0.026, ( S R)R1=−0.026

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.1−0.0534 0.1−0.05)×−0.036+( 0.0534−0.05 0.1−0.05)×−0.073] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.031+( 0.0534−0.05 0.1−0.05)×−0.063]×1.204−1.21.3−1.2( HR )RTC0=−0.0383

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.1−0.0534 0.1−0.05)×−0.021+( 0.0534−0.05 0.1−0.05)×−0.042] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.017+( 0.0534−0.05 0.1−0.05)×−0.033]×1.204−1.21.3−1.2( SR )R0=−0.022

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.1−0.0534 0.1−0.05)×−0.02+( 0.0534−0.05 0.1−0.05)×−0.04] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( HR )RTC1=−0.02106

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.1−0.0534 0.1−0.05)×−0.019+( 0.0534−0.05 0.1−0.05)×−0.037] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( SR )R1=−0.02

Now, from equation,

H2R=(H2R)0+ω(H2R)1

Or

H2RRTC=( H 2 R)0RTC+ω( H 2 R)1RTCH2RRTC=−0.0383+0.1×−0.02106H2RRTC=−0.0404H2R=−0.0404×8.314 Jmol K×305.3 KH2R=−102.561 Jmol

And

S2R=(S2R)0+ω(S2R)1

Or

S2RR=( S 2 R)0R+ω( S 2 R)1RS2RR=−0.022+0.1×−0.02S2RR=−0.024S2R=−0.024×8.314 Jmol KS2R=−0.1995 Jmol K

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CPigdTT=ln2.630−(−0.1995 Jmol K)8.314 Jmol K+(−1.048 Jmol K)8.314 Jmol K∫T1T2CPigdTT=−2.5477

Hence,

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτ−2.5477= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.7352

τ=TT00.7352=T493.15KT=362.56 K

Now, for work produced

W=ΔH

And enthalpy change by generalized correlations is given by,

ΔH=∫T1T2CPigdT+H2R−H1R

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.735−1)+19.225×10−32×493.152×(0.7352−1)+−5.561×10−63×493.153(0.7353−1)∫T0TΔC∘PRdT=−1088.593 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−1088.593 K+(−102.561 Jmol)−(−669.97 Jmol)W=−8453.15 Jmol

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1425.78 KW=11853.93 Jmol

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Answer 4

Question

Chapter 6, Problem 6.59P

(a)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethane are calculated by equations for an ideal gas.

Concept Introduction:

The entropy change for an ideal gas is calculated by,

ΔS=∫T1T2CPigdTT−RlnP2P1. ...(1)

(a)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=367.4 K

Work done is

W=−8746.9 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (1)

ΔS=∫T1T2CPigdTT−Rln P 2 P 10=R∫T1T2CP igRdTT−RlnP2P1∫T1T2CPigRdTT=lnP2P1

wherE

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

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

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτlnP2P1=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτln2.630=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.745

τ=TT00.745=T493.15 KT=367.4 K

For work produced

W=ΔH for ideal gas

And for ideal gas

ΔH=∫T1T2CPigdTΔH=R∫T1T2CP igRdT

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.745−1)+19.225×10−32×493.152×(0.7452−1)+−5.561×10−63×493.153(0.7453−1)∫T0TΔC∘PRdT=−1052.07 K

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1052.07 KW=−8746.9 Jmol

(b)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethylene are calculated by appropriate generalized correlations.

Concept Introduction:

The entropy change by appropriate generalized correlations is

ΔS=∫T1T2CPigdTT−RlnP2P1+S2R−S1R. ...(2)

(b)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=362.56 K

Work done is

W=−8453.15 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (2),

ΔS=∫T1T2CPigdTT−Rln P 2 P 1+S2R−S1RR∫T1T2CP igRdTT−RlnP2P1+S2R−S1R=0R∫T1T2CPigRdTT=RlnP2P1−S2R+S1R

Initial statE

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

ω=0.1, Tc=305.3 K, Pc=48.72 bar, ZC=0.279

Tr=T1TcTr=493.15 K305.3 K=1.615

Pr=P1PcPr=30bar48.72 bar=0.61576

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=1.615 lies between reduced temperatures Tr=1.6and Tr=1.7 and Pr=0.61576 lies in between reduced pressures Pr=0.6 and Pr=0.8 .

At Tr=1.6 and Pr=0.6

( H R)RTC0=−0.261, ( S R)R0=−0.12

At Tr=1.6 and Pr=0.8

( H R)RTC0=−0.35, ( S R)R0=−0.162

At Tr=1.7 and Pr=0.6

( H R)RTC0=−0.231, ( S R)R0=−0.102

At Tr=1.7 and Pr=0.8

( H R)RTC0=−0.309, ( S R)R0=−0.137

And

At Tr=1.6 and Pr=0.6

( H R)RTC1=−0.013, ( S R)R1=−0.057

At Tr=1.6 and Pr=0.8

( H R)RTC1=−0.011, ( S R)R1=−0.073

At Tr=1.7 and Pr=0.6

( H R)RTC1=0.009, ( S R)R1=−0.044

At Tr=1.7 and Pr=0.8

( H R)RTC1=0.017, ( S R)R1=−0.056

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.8−0.61576 0.8−0.6)×−0.261+( 0.61576−0.6 0.8−0.6)×−0.35] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.231+( 0.61576−0.6 0.8−0.6)×−0.309] ×1.615−1.61.7−1.6( HR )RTC0=−0.263

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.8−0.61576 0.8−0.6)×−0.12+( 0.61576−0.6 0.8−0.6)×−0.162] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.102+( 0.61576−0.6 0.8−0.6)×−0.137] ×1.615−1.61.7−1.6( SR )R0=−0.1205

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.8−0.61576 0.8−0.6)×−0.013+( 0.61576−0.6 0.8−0.6)×−0.011] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×0.009+( 0.61576−0.6 0.8−0.6)×0.017] ×1.615−1.61.7−1.6( HR )RTC1=−0.0095

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.8−0.61576 0.8−0.6)×−0.057+( 0.61576−0.6 0.8−0.6)×−0.073] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.044+( 0.61576−0.6 0.8−0.6)×−0.056] ×1.615−1.61.7−1.6( SR )R1=−0.056

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R)0RTC+ω( H 1 R)1RTCH1RRTC=−0.263+0.1×−0.0095H1RRTC=−0.26395H1R=−0.26395×8.314 Jmol K×305.3 KH1R=−669.97 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R)0R+ω( S 1 R)1RS1RR=−0.1205+0.1×−0.056S1RR=−0.1261S1R=−0.1261×8.314 Jmol KS1R=−1.048 Jmol K

Final state

Final state temperature is calculated in part (a), T=367.4 K

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

Tr=T2TcTr=367.4 K305.3 K=1.204

Pr=P2PcPr=2.6 bar48.72 bar=0.0534

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=1.204 lies between reduced temperatures Tr=1.2and Tr=1.3 and Pr=0.0534 lies in between reduced pressures Pr=0.05 and Pr=0.1 .

At Tr=1.2 and Pr=0.05

( H R)RTC0=−0.036, ( S R)R0=−0.021

At Tr=1.2 and Pr=0.1

( H R)RTC0=−0.073, ( S R)R0=−0.042

At Tr=1.3 and Pr=0.05

( H R)RTC0=−0.031, ( S R)R0=−0.017

At Tr=1.3 and Pr=0.1

( H R)RTC0=−0.063, ( S R)R0=−0.033

And

At Tr=1.2 and Pr=0.05

( H R)RTC1=−0.02, ( S R)R1=−0.019

At Tr=1.2 and Pr=0.1

( H R)RTC1=−0.04, ( S R)R1=−0.037

At Tr=1.3 and Pr=0.05

( H R)RTC1=−0.013, ( S R)R1=−0.013

At Tr=1.3 and Pr=0.1

( H R)RTC1=−0.026, ( S R)R1=−0.026

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.1−0.0534 0.1−0.05)×−0.036+( 0.0534−0.05 0.1−0.05)×−0.073] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.031+( 0.0534−0.05 0.1−0.05)×−0.063]×1.204−1.21.3−1.2( HR )RTC0=−0.0383

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.1−0.0534 0.1−0.05)×−0.021+( 0.0534−0.05 0.1−0.05)×−0.042] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.017+( 0.0534−0.05 0.1−0.05)×−0.033]×1.204−1.21.3−1.2( SR )R0=−0.022

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.1−0.0534 0.1−0.05)×−0.02+( 0.0534−0.05 0.1−0.05)×−0.04] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( HR )RTC1=−0.02106

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.1−0.0534 0.1−0.05)×−0.019+( 0.0534−0.05 0.1−0.05)×−0.037] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( SR )R1=−0.02

Now, from equation,

H2R=(H2R)0+ω(H2R)1

Or

H2RRTC=( H 2 R)0RTC+ω( H 2 R)1RTCH2RRTC=−0.0383+0.1×−0.02106H2RRTC=−0.0404H2R=−0.0404×8.314 Jmol K×305.3 KH2R=−102.561 Jmol

And

S2R=(S2R)0+ω(S2R)1

Or

S2RR=( S 2 R)0R+ω( S 2 R)1RS2RR=−0.022+0.1×−0.02S2RR=−0.024S2R=−0.024×8.314 Jmol KS2R=−0.1995 Jmol K

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CPigdTT=ln2.630−(−0.1995 Jmol K)8.314 Jmol K+(−1.048 Jmol K)8.314 Jmol K∫T1T2CPigdTT=−2.5477

Hence,

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτ−2.5477= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.7352

τ=TT00.7352=T493.15KT=362.56 K

Now, for work produced

W=ΔH

And enthalpy change by generalized correlations is given by,

ΔH=∫T1T2CPigdT+H2R−H1R

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.735−1)+19.225×10−32×493.152×(0.7352−1)+−5.561×10−63×493.153(0.7353−1)∫T0TΔC∘PRdT=−1088.593 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−1088.593 K+(−102.561 Jmol)−(−669.97 Jmol)W=−8453.15 Jmol

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1425.78 KW=11853.93 Jmol

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Answer 5

Chapter 6, Problem 6.59P

(a)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethane are calculated by equations for an ideal gas.

Concept Introduction:

The entropy change for an ideal gas is calculated by,

ΔS=∫T1T2CPigdTT−RlnP2P1. ...(1)

(a)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=367.4 K

Work done is

W=−8746.9 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (1)

ΔS=∫T1T2CPigdTT−Rln P 2 P 10=R∫T1T2CP igRdTT−RlnP2P1∫T1T2CPigRdTT=lnP2P1

wherE

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

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

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτlnP2P1=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτln2.630=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.745

τ=TT00.745=T493.15 KT=367.4 K

For work produced

W=ΔH for ideal gas

And for ideal gas

ΔH=∫T1T2CPigdTΔH=R∫T1T2CP igRdT

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.745−1)+19.225×10−32×493.152×(0.7452−1)+−5.561×10−63×493.153(0.7453−1)∫T0TΔC∘PRdT=−1052.07 K

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1052.07 KW=−8746.9 Jmol

(b)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethylene are calculated by appropriate generalized correlations.

Concept Introduction:

The entropy change by appropriate generalized correlations is

ΔS=∫T1T2CPigdTT−RlnP2P1+S2R−S1R. ...(2)

(b)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=362.56 K

Work done is

W=−8453.15 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (2),

ΔS=∫T1T2CPigdTT−Rln P 2 P 1+S2R−S1RR∫T1T2CP igRdTT−RlnP2P1+S2R−S1R=0R∫T1T2CPigRdTT=RlnP2P1−S2R+S1R

Initial statE

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

ω=0.1, Tc=305.3 K, Pc=48.72 bar, ZC=0.279

Tr=T1TcTr=493.15 K305.3 K=1.615

Pr=P1PcPr=30bar48.72 bar=0.61576

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=1.615 lies between reduced temperatures Tr=1.6and Tr=1.7 and Pr=0.61576 lies in between reduced pressures Pr=0.6 and Pr=0.8 .

At Tr=1.6 and Pr=0.6

( H R)RTC0=−0.261, ( S R)R0=−0.12

At Tr=1.6 and Pr=0.8

( H R)RTC0=−0.35, ( S R)R0=−0.162

At Tr=1.7 and Pr=0.6

( H R)RTC0=−0.231, ( S R)R0=−0.102

At Tr=1.7 and Pr=0.8

( H R)RTC0=−0.309, ( S R)R0=−0.137

And

At Tr=1.6 and Pr=0.6

( H R)RTC1=−0.013, ( S R)R1=−0.057

At Tr=1.6 and Pr=0.8

( H R)RTC1=−0.011, ( S R)R1=−0.073

At Tr=1.7 and Pr=0.6

( H R)RTC1=0.009, ( S R)R1=−0.044

At Tr=1.7 and Pr=0.8

( H R)RTC1=0.017, ( S R)R1=−0.056

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.8−0.61576 0.8−0.6)×−0.261+( 0.61576−0.6 0.8−0.6)×−0.35] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.231+( 0.61576−0.6 0.8−0.6)×−0.309] ×1.615−1.61.7−1.6( HR )RTC0=−0.263

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.8−0.61576 0.8−0.6)×−0.12+( 0.61576−0.6 0.8−0.6)×−0.162] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.102+( 0.61576−0.6 0.8−0.6)×−0.137] ×1.615−1.61.7−1.6( SR )R0=−0.1205

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.8−0.61576 0.8−0.6)×−0.013+( 0.61576−0.6 0.8−0.6)×−0.011] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×0.009+( 0.61576−0.6 0.8−0.6)×0.017] ×1.615−1.61.7−1.6( HR )RTC1=−0.0095

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.8−0.61576 0.8−0.6)×−0.057+( 0.61576−0.6 0.8−0.6)×−0.073] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.044+( 0.61576−0.6 0.8−0.6)×−0.056] ×1.615−1.61.7−1.6( SR )R1=−0.056

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R)0RTC+ω( H 1 R)1RTCH1RRTC=−0.263+0.1×−0.0095H1RRTC=−0.26395H1R=−0.26395×8.314 Jmol K×305.3 KH1R=−669.97 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R)0R+ω( S 1 R)1RS1RR=−0.1205+0.1×−0.056S1RR=−0.1261S1R=−0.1261×8.314 Jmol KS1R=−1.048 Jmol K

Final state

Final state temperature is calculated in part (a), T=367.4 K

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

Tr=T2TcTr=367.4 K305.3 K=1.204

Pr=P2PcPr=2.6 bar48.72 bar=0.0534

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=1.204 lies between reduced temperatures Tr=1.2and Tr=1.3 and Pr=0.0534 lies in between reduced pressures Pr=0.05 and Pr=0.1 .

At Tr=1.2 and Pr=0.05

( H R)RTC0=−0.036, ( S R)R0=−0.021

At Tr=1.2 and Pr=0.1

( H R)RTC0=−0.073, ( S R)R0=−0.042

At Tr=1.3 and Pr=0.05

( H R)RTC0=−0.031, ( S R)R0=−0.017

At Tr=1.3 and Pr=0.1

( H R)RTC0=−0.063, ( S R)R0=−0.033

And

At Tr=1.2 and Pr=0.05

( H R)RTC1=−0.02, ( S R)R1=−0.019

At Tr=1.2 and Pr=0.1

( H R)RTC1=−0.04, ( S R)R1=−0.037

At Tr=1.3 and Pr=0.05

( H R)RTC1=−0.013, ( S R)R1=−0.013

At Tr=1.3 and Pr=0.1

( H R)RTC1=−0.026, ( S R)R1=−0.026

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.1−0.0534 0.1−0.05)×−0.036+( 0.0534−0.05 0.1−0.05)×−0.073] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.031+( 0.0534−0.05 0.1−0.05)×−0.063]×1.204−1.21.3−1.2( HR )RTC0=−0.0383

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.1−0.0534 0.1−0.05)×−0.021+( 0.0534−0.05 0.1−0.05)×−0.042] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.017+( 0.0534−0.05 0.1−0.05)×−0.033]×1.204−1.21.3−1.2( SR )R0=−0.022

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.1−0.0534 0.1−0.05)×−0.02+( 0.0534−0.05 0.1−0.05)×−0.04] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( HR )RTC1=−0.02106

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.1−0.0534 0.1−0.05)×−0.019+( 0.0534−0.05 0.1−0.05)×−0.037] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( SR )R1=−0.02

Now, from equation,

H2R=(H2R)0+ω(H2R)1

Or

H2RRTC=( H 2 R)0RTC+ω( H 2 R)1RTCH2RRTC=−0.0383+0.1×−0.02106H2RRTC=−0.0404H2R=−0.0404×8.314 Jmol K×305.3 KH2R=−102.561 Jmol

And

S2R=(S2R)0+ω(S2R)1

Or

S2RR=( S 2 R)0R+ω( S 2 R)1RS2RR=−0.022+0.1×−0.02S2RR=−0.024S2R=−0.024×8.314 Jmol KS2R=−0.1995 Jmol K

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CPigdTT=ln2.630−(−0.1995 Jmol K)8.314 Jmol K+(−1.048 Jmol K)8.314 Jmol K∫T1T2CPigdTT=−2.5477

Hence,

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτ−2.5477= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.7352

τ=TT00.7352=T493.15KT=362.56 K

Now, for work produced

W=ΔH

And enthalpy change by generalized correlations is given by,

ΔH=∫T1T2CPigdT+H2R−H1R

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.735−1)+19.225×10−32×493.152×(0.7352−1)+−5.561×10−63×493.153(0.7353−1)∫T0TΔC∘PRdT=−1088.593 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−1088.593 K+(−102.561 Jmol)−(−669.97 Jmol)W=−8453.15 Jmol

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1425.78 KW=11853.93 Jmol

Answer 6

Chapter 6, Problem 6.59P

(a)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethane are calculated by equations for an ideal gas.

Concept Introduction:

The entropy change for an ideal gas is calculated by,

ΔS=∫T1T2CPigdTT−RlnP2P1. ...(1)

(a)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=367.4 K

Work done is

W=−8746.9 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (1)

ΔS=∫T1T2CPigdTT−Rln P 2 P 10=R∫T1T2CP igRdTT−RlnP2P1∫T1T2CPigRdTT=lnP2P1

wherE

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

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

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτlnP2P1=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτln2.630=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.745

τ=TT00.745=T493.15 KT=367.4 K

For work produced

W=ΔH for ideal gas

And for ideal gas

ΔH=∫T1T2CPigdTΔH=R∫T1T2CP igRdT

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.745−1)+19.225×10−32×493.152×(0.7452−1)+−5.561×10−63×493.153(0.7453−1)∫T0TΔC∘PRdT=−1052.07 K

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1052.07 KW=−8746.9 Jmol

Answer 7

Chapter 6, Problem 6.59P

(a)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethane are calculated by equations for an ideal gas.

Concept Introduction:

The entropy change for an ideal gas is calculated by,

ΔS=∫T1T2CPigdTT−RlnP2P1. ...(1)

Answer 8

(a)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=367.4 K

Work done is

W=−8746.9 Jmol

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (1)

ΔS=∫T1T2CPigdTT−Rln P 2 P 10=R∫T1T2CP igRdTT−RlnP2P1∫T1T2CPigRdTT=lnP2P1

wherE

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

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

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτlnP2P1=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτln2.630=[1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.745

τ=TT00.745=T493.15 KT=367.4 K

For work produced

W=ΔH for ideal gas

And for ideal gas

ΔH=∫T1T2CPigdTΔH=R∫T1T2CP igRdT

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.745−1)+19.225×10−32×493.152×(0.7452−1)+−5.561×10−63×493.153(0.7453−1)∫T0TΔC∘PRdT=−1052.07 K

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1052.07 KW=−8746.9 Jmol

Answer 13

(b)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethylene are calculated by appropriate generalized correlations.

Concept Introduction:

The entropy change by appropriate generalized correlations is

ΔS=∫T1T2CPigdTT−RlnP2P1+S2R−S1R. ...(2)

(b)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=362.56 K

Work done is

W=−8453.15 Jmol

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (2),

ΔS=∫T1T2CPigdTT−Rln P 2 P 1+S2R−S1RR∫T1T2CP igRdTT−RlnP2P1+S2R−S1R=0R∫T1T2CPigRdTT=RlnP2P1−S2R+S1R

Initial statE

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

ω=0.1, Tc=305.3 K, Pc=48.72 bar, ZC=0.279

Tr=T1TcTr=493.15 K305.3 K=1.615

Pr=P1PcPr=30bar48.72 bar=0.61576

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=1.615 lies between reduced temperatures Tr=1.6and Tr=1.7 and Pr=0.61576 lies in between reduced pressures Pr=0.6 and Pr=0.8 .

At Tr=1.6 and Pr=0.6

( H R)RTC0=−0.261, ( S R)R0=−0.12

At Tr=1.6 and Pr=0.8

( H R)RTC0=−0.35, ( S R)R0=−0.162

At Tr=1.7 and Pr=0.6

( H R)RTC0=−0.231, ( S R)R0=−0.102

At Tr=1.7 and Pr=0.8

( H R)RTC0=−0.309, ( S R)R0=−0.137

And

At Tr=1.6 and Pr=0.6

( H R)RTC1=−0.013, ( S R)R1=−0.057

At Tr=1.6 and Pr=0.8

( H R)RTC1=−0.011, ( S R)R1=−0.073

At Tr=1.7 and Pr=0.6

( H R)RTC1=0.009, ( S R)R1=−0.044

At Tr=1.7 and Pr=0.8

( H R)RTC1=0.017, ( S R)R1=−0.056

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.8−0.61576 0.8−0.6)×−0.261+( 0.61576−0.6 0.8−0.6)×−0.35] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.231+( 0.61576−0.6 0.8−0.6)×−0.309] ×1.615−1.61.7−1.6( HR )RTC0=−0.263

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.8−0.61576 0.8−0.6)×−0.12+( 0.61576−0.6 0.8−0.6)×−0.162] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.102+( 0.61576−0.6 0.8−0.6)×−0.137] ×1.615−1.61.7−1.6( SR )R0=−0.1205

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.8−0.61576 0.8−0.6)×−0.013+( 0.61576−0.6 0.8−0.6)×−0.011] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×0.009+( 0.61576−0.6 0.8−0.6)×0.017] ×1.615−1.61.7−1.6( HR )RTC1=−0.0095

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.8−0.61576 0.8−0.6)×−0.057+( 0.61576−0.6 0.8−0.6)×−0.073] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.044+( 0.61576−0.6 0.8−0.6)×−0.056] ×1.615−1.61.7−1.6( SR )R1=−0.056

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R)0RTC+ω( H 1 R)1RTCH1RRTC=−0.263+0.1×−0.0095H1RRTC=−0.26395H1R=−0.26395×8.314 Jmol K×305.3 KH1R=−669.97 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R)0R+ω( S 1 R)1RS1RR=−0.1205+0.1×−0.056S1RR=−0.1261S1R=−0.1261×8.314 Jmol KS1R=−1.048 Jmol K

Final state

Final state temperature is calculated in part (a), T=367.4 K

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

Tr=T2TcTr=367.4 K305.3 K=1.204

Pr=P2PcPr=2.6 bar48.72 bar=0.0534

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=1.204 lies between reduced temperatures Tr=1.2and Tr=1.3 and Pr=0.0534 lies in between reduced pressures Pr=0.05 and Pr=0.1 .

At Tr=1.2 and Pr=0.05

( H R)RTC0=−0.036, ( S R)R0=−0.021

At Tr=1.2 and Pr=0.1

( H R)RTC0=−0.073, ( S R)R0=−0.042

At Tr=1.3 and Pr=0.05

( H R)RTC0=−0.031, ( S R)R0=−0.017

At Tr=1.3 and Pr=0.1

( H R)RTC0=−0.063, ( S R)R0=−0.033

And

At Tr=1.2 and Pr=0.05

( H R)RTC1=−0.02, ( S R)R1=−0.019

At Tr=1.2 and Pr=0.1

( H R)RTC1=−0.04, ( S R)R1=−0.037

At Tr=1.3 and Pr=0.05

( H R)RTC1=−0.013, ( S R)R1=−0.013

At Tr=1.3 and Pr=0.1

( H R)RTC1=−0.026, ( S R)R1=−0.026

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.1−0.0534 0.1−0.05)×−0.036+( 0.0534−0.05 0.1−0.05)×−0.073] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.031+( 0.0534−0.05 0.1−0.05)×−0.063]×1.204−1.21.3−1.2( HR )RTC0=−0.0383

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.1−0.0534 0.1−0.05)×−0.021+( 0.0534−0.05 0.1−0.05)×−0.042] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.017+( 0.0534−0.05 0.1−0.05)×−0.033]×1.204−1.21.3−1.2( SR )R0=−0.022

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.1−0.0534 0.1−0.05)×−0.02+( 0.0534−0.05 0.1−0.05)×−0.04] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( HR )RTC1=−0.02106

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.1−0.0534 0.1−0.05)×−0.019+( 0.0534−0.05 0.1−0.05)×−0.037] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( SR )R1=−0.02

Now, from equation,

H2R=(H2R)0+ω(H2R)1

Or

H2RRTC=( H 2 R)0RTC+ω( H 2 R)1RTCH2RRTC=−0.0383+0.1×−0.02106H2RRTC=−0.0404H2R=−0.0404×8.314 Jmol K×305.3 KH2R=−102.561 Jmol

And

S2R=(S2R)0+ω(S2R)1

Or

S2RR=( S 2 R)0R+ω( S 2 R)1RS2RR=−0.022+0.1×−0.02S2RR=−0.024S2R=−0.024×8.314 Jmol KS2R=−0.1995 Jmol K

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CPigdTT=ln2.630−(−0.1995 Jmol K)8.314 Jmol K+(−1.048 Jmol K)8.314 Jmol K∫T1T2CPigdTT=−2.5477

Hence,

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτ−2.5477= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.7352

τ=TT00.7352=T493.15KT=362.56 K

Now, for work produced

W=ΔH

And enthalpy change by generalized correlations is given by,

ΔH=∫T1T2CPigdT+H2R−H1R

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.735−1)+19.225×10−32×493.152×(0.7352−1)+−5.561×10−63×493.153(0.7353−1)∫T0TΔC∘PRdT=−1088.593 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−1088.593 K+(−102.561 Jmol)−(−669.97 Jmol)W=−8453.15 Jmol

Hence,

W=ΔH=R∫T1T2 C P igRdTW=8.314 Jmol K×−1425.78 KW=11853.93 Jmol

Answer 14

(b)

Interpretation Introduction

Interpretation:

Determine the temperature of the expanded ethane gas, expands isentropically in a turbine and work produced if properties of ethylene are calculated by appropriate generalized correlations.

Concept Introduction:

The entropy change by appropriate generalized correlations is

ΔS=∫T1T2CPigdTT−RlnP2P1+S2R−S1R. ...(2)

Answer 15

(b)

Expert Solution

Answer to Problem 6.59P

Temperature is

T=362.56 K

Work done is

W=−8453.15 Jmol

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Given information:

It is given that ethane expands isentropically from 30 bar and 493.15 Kto 2.6 bar .

Process is isentropically, so ΔS=0

From equation (2),

ΔS=∫T1T2CPigdTT−Rln P 2 P 1+S2R−S1RR∫T1T2CP igRdTT−RlnP2P1+S2R−S1R=0R∫T1T2CPigRdTT=RlnP2P1−S2R+S1R

Initial statE

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

ω=0.1, Tc=305.3 K, Pc=48.72 bar, ZC=0.279

Tr=T1TcTr=493.15 K305.3 K=1.615

Pr=P1PcPr=30bar48.72 bar=0.61576

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=1.615 lies between reduced temperatures Tr=1.6and Tr=1.7 and Pr=0.61576 lies in between reduced pressures Pr=0.6 and Pr=0.8 .

At Tr=1.6 and Pr=0.6

( H R)RTC0=−0.261, ( S R)R0=−0.12

At Tr=1.6 and Pr=0.8

( H R)RTC0=−0.35, ( S R)R0=−0.162

At Tr=1.7 and Pr=0.6

( H R)RTC0=−0.231, ( S R)R0=−0.102

At Tr=1.7 and Pr=0.8

( H R)RTC0=−0.309, ( S R)R0=−0.137

And

At Tr=1.6 and Pr=0.6

( H R)RTC1=−0.013, ( S R)R1=−0.057

At Tr=1.6 and Pr=0.8

( H R)RTC1=−0.011, ( S R)R1=−0.073

At Tr=1.7 and Pr=0.6

( H R)RTC1=0.009, ( S R)R1=−0.044

At Tr=1.7 and Pr=0.8

( H R)RTC1=0.017, ( S R)R1=−0.056

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.8−0.61576 0.8−0.6)×−0.261+( 0.61576−0.6 0.8−0.6)×−0.35] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.231+( 0.61576−0.6 0.8−0.6)×−0.309] ×1.615−1.61.7−1.6( HR )RTC0=−0.263

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.8−0.61576 0.8−0.6)×−0.12+( 0.61576−0.6 0.8−0.6)×−0.162] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.102+( 0.61576−0.6 0.8−0.6)×−0.137] ×1.615−1.61.7−1.6( SR )R0=−0.1205

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.8−0.61576 0.8−0.6)×−0.013+( 0.61576−0.6 0.8−0.6)×−0.011] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×0.009+( 0.61576−0.6 0.8−0.6)×0.017] ×1.615−1.61.7−1.6( HR )RTC1=−0.0095

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.8−0.61576 0.8−0.6)×−0.057+( 0.61576−0.6 0.8−0.6)×−0.073] ×1.7−1.6151.7−1.6 +[( 0.8−0.61576 0.8−0.6)×−0.044+( 0.61576−0.6 0.8−0.6)×−0.056] ×1.615−1.61.7−1.6( SR )R1=−0.056

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R)0RTC+ω( H 1 R)1RTCH1RRTC=−0.263+0.1×−0.0095H1RRTC=−0.26395H1R=−0.26395×8.314 Jmol K×305.3 KH1R=−669.97 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R)0R+ω( S 1 R)1RS1RR=−0.1205+0.1×−0.056S1RR=−0.1261S1R=−0.1261×8.314 Jmol KS1R=−1.048 Jmol K

Final state

Final state temperature is calculated in part (a), T=367.4 K

i A 103B 106 C 10−5DEthane 1.131 19.225 −5.561 0

Tr=T2TcTr=367.4 K305.3 K=1.204

Pr=P2PcPr=2.6 bar48.72 bar=0.0534

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=1.204 lies between reduced temperatures Tr=1.2and Tr=1.3 and Pr=0.0534 lies in between reduced pressures Pr=0.05 and Pr=0.1 .

At Tr=1.2 and Pr=0.05

( H R)RTC0=−0.036, ( S R)R0=−0.021

At Tr=1.2 and Pr=0.1

( H R)RTC0=−0.073, ( S R)R0=−0.042

At Tr=1.3 and Pr=0.05

( H R)RTC0=−0.031, ( S R)R0=−0.017

At Tr=1.3 and Pr=0.1

( H R)RTC0=−0.063, ( S R)R0=−0.033

And

At Tr=1.2 and Pr=0.05

( H R)RTC1=−0.02, ( S R)R1=−0.019

At Tr=1.2 and Pr=0.1

( H R)RTC1=−0.04, ( S R)R1=−0.037

At Tr=1.3 and Pr=0.05

( H R)RTC1=−0.013, ( S R)R1=−0.013

At Tr=1.3 and Pr=0.1

( H R)RTC1=−0.026, ( S R)R1=−0.026

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:

X1 X X2Y1 M1,1 M1,2Y M=? Y2 M2,1 M2,2

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC0=[( 0.1−0.0534 0.1−0.05)×−0.036+( 0.0534−0.05 0.1−0.05)×−0.073] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.031+( 0.0534−0.05 0.1−0.05)×−0.063]×1.204−1.21.3−1.2( HR )RTC0=−0.0383

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R0=[( 0.1−0.0534 0.1−0.05)×−0.021+( 0.0534−0.05 0.1−0.05)×−0.042] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.017+( 0.0534−0.05 0.1−0.05)×−0.033]×1.204−1.21.3−1.2( SR )R0=−0.022

And

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( HR )RTC1=[( 0.1−0.0534 0.1−0.05)×−0.02+( 0.0534−0.05 0.1−0.05)×−0.04] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( HR )RTC1=−0.02106

M=[( X2 −X X2 −X1 )M1,1+( X−X1 X2 −X1 )M1,2]Y2−YY2−Y1 +[( X2 −X X2 −X1 )M2,1+( X−X1 X2 −X1 )M2,2]Y−Y1Y2−Y1( SR )R1=[( 0.1−0.0534 0.1−0.05)×−0.019+( 0.0534−0.05 0.1−0.05)×−0.037] ×1.3−1.2041.3−1.2 +[( 0.1−0.0534 0.1−0.05)×−0.013+( 0.0534−0.05 0.1−0.05)×−0.026]×1.204−1.21.3−1.2( SR )R1=−0.02

Now, from equation,

H2R=(H2R)0+ω(H2R)1

Or

H2RRTC=( H 2 R)0RTC+ω( H 2 R)1RTCH2RRTC=−0.0383+0.1×−0.02106H2RRTC=−0.0404H2R=−0.0404×8.314 Jmol K×305.3 KH2R=−102.561 Jmol

And

S2R=(S2R)0+ω(S2R)1

Or

S2RR=( S 2 R)0R+ω( S 2 R)1RS2RR=−0.022+0.1×−0.02S2RR=−0.024S2R=−0.024×8.314 Jmol KS2R=−0.1995 Jmol K

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CPigdTT=ln2.630−(−0.1995 Jmol K)8.314 Jmol K+(−1.048 Jmol K)8.314 Jmol K∫T1T2CPigdTT=−2.5477

Hence,

∫T1T2CPigRdTT=[A+{BT0+(CT02+Dτ2T02)(τ+12)}(τ−1lnτ)]×lnτ

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ2 T0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152+0 τ 2× 493.15 2)(τ+12)}(τ−1lnτ)]×lnτ−2.5477= [1.131+{19.225×10−3×493.15+(−5.561×10−6×493.152)(τ+12)}(τ−1lnτ)]×lnττ=0.7352

τ=TT00.7352=T493.15KT=362.56 K

Now, for work produced

W=ΔH

And enthalpy change by generalized correlations is given by,

ΔH=∫T1T2CPigdT+H2R−H1R

∫T0TΔC∘PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)

Where τ=TT0

∫T0TΔ C ∘ PRdT=AT0(τ−1)+B2T02(τ2−1)+C3T03(τ3−1)+DT0(τ−1τ)∫T0TΔC∘PRdT =1.131×493.15×(0.735−1)+19.225×10−32×493.152×(0.7352−1)+−5.561×10−63×493.153(0.7353−1)∫T0TΔC∘PRdT=−1088.593 K