Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process. Concept Introduction: The entropy change by appropriate generalized correlations is Δ S = ∫ T 1 T 2 C P i g d T T − R ln P 2 P 1 + S 2 R − S 1 R ....(2)

Question

Want to see more full solutions like this?

Answer 1

Question

Chapter 6, Problem 6.60P

Interpretation Introduction

Interpretation:

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process.

Concept Introduction:

The entropy change by appropriate generalized correlations is

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

Expert Solution & Answer

Answer to Problem 6.60P

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Explanation of Solution

Given information:

It is given that n-butane gas compressed isentropically from 1 bar and 323.15 K to 7.8 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 n-butane, the properties can be written down using Appendix B, Table B.1

ω=0.2, Tc=425.1 K, Pc=37.96 bar, ZC=0.276

Tr=T1TcTr=323.15 K425.1 K=0.7602

Pr=P1PcPr=1 bar37.96 bar=0.0263

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=0.76 lies between reduced temperatures Tr=0.75 and Tr=0.8 and Pr=0.026 lies in between reduced pressures Pr=0.01 and Pr=0.05 .

At Tr=0.75 and Pr=0.01

( H R)RTC0=−0.017, ( S R)R0=−0.015

At Tr=0.75 and Pr=0.05

( H R)RTC0=−0.088, ( S R)R0=−0.078

At Tr=0.8 and Pr=0.01

( H R)RTC0=−0.015, ( S R)R0=−0.013

At Tr=0.8 and Pr=0.05

( H R)RTC0=−0.078, ( S R)R0=−0.064

And

At Tr=0.75 and Pr=0.01

( H R)RTC1=−0.027, ( S R)R1=−0.029

At Tr=0.75 and Pr=0.05

( H R)RTC1=−0.142, ( S R)R1=−0.156

At Tr=0.8 and Pr=0.01

( H R)RTC1=−0.021, ( S R)R1=−0.022

At Tr=0.8 and Pr=0.05

( H R)RTC1=−0.11, ( S R)R1=−0.116

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=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC0=[( 0.05−0.026 0.05−0.01)×−0.017+( 0.026−0.01 0.05−0.01)×−0.088] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.76−0.750.8−0.75( H R )RTC0=−0.04436

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R0=[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.013+( 0.026−0.01 0.05−0.01)×−0.064] ×0.76−0.750.8−0.75( S R )R0=−0.03884

And

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC1=[( 0.05−0.026 0.05−0.01)×−0.027+( 0.026−0.01 0.05−0.01)×−0.142] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.021+( 0.026−0.01 0.05−0.01)×−0.110] ×0.76−0.750.8−0.75( H R )RTC1=−0.06972

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R1=[( 0.05−0.026 0.05−0.01)×−0.029+( 0.026−0.01 0.05−0.01)×−0.156] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.022+( 0.026−0.01 0.05−0.01)×−0.116] ×0.76−0.750.8−0.75( S R )R1=−0.07576

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R )0RTC+ω( H 1 R )1RTCH1RRTC=−0.04436+0.2×−0.06972H1RRTC=−0.058304H1R=−0.058304×8.314 Jmol K×425.1 KH1R=−206.063 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R )0R+ω( S 1 R )1RS1RR=−0.03884+0.2×−0.07576S1RR=−0.053992S1R=−0.053992×8.314 Jmol KS1R=−0.4489 Jmol K

Considering at final state gas is an ideal gas.

Hence, H2R=0 and S2R=0

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CP igRdTT=ln7.81−0+(−0.4489 Jmol K)8.314 Jmol K∫T1T2CPigRdTT=2

Hence,

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

τ=TT0

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

i A 103B 106 C 10−5Dn−butane 1.935 36.915 −11.402 0

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152+0 τ 2× 323.15 2)(τ+12)}(τ−1lnτ)]×lnτ2=[1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152)(τ+12)}(τ−1lnτ)]×lnττ=1.18

τ=TT01.18=T323.15KT=381.317 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 =1.935×323.15×(1.18−1)+36.915×10−32×323.152×(1.182−1)+−11.402×10−63×323.153(1.183−1)∫T0TΔC∘PRdT=−786.41 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−786.41 K+0−(−206.063 Jmol)W=−6332.15 Jmol

Conclusion

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Students have asked these similar questions

Chemical Engineering Use the psychrometric chart and demonstrate the linear interpolation method to obtain -0.52 KJ/KgDA. This is the enthalpy deviation. The exercise is uploaded below.

Chemical Engineering Use the psychrometric chart. The remaining curves on the psychrometric chart are almost vertical and convex to the left, with labeled values (on Figure 8.4-1) of 0.05, 0.1, 0.2, and so on. (The units of these numbers arekJ/kg DA). Thesecurves are usedto determine theenthalpyof humid air that is not saturated. The procedure is as follows: (a) locate the point on the chart corresponding to air at its specified condition; (b) interpolate to estimate the enthalpy deviation at this point; (c) follow the constant wet-bulb temperature line to the enthalpy scale above the saturation curve, read the value on that scale, and add the enthalpy deviation to it. Also, you will see the exercise on the piece of paper.

Calculate the permeability of the bed of ion-exchange particles in Example 11.1.

Answer 2

Question

Chapter 6, Problem 6.60P

Interpretation Introduction

Interpretation:

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process.

Concept Introduction:

The entropy change by appropriate generalized correlations is

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

Expert Solution & Answer

Answer to Problem 6.60P

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Explanation of Solution

Given information:

It is given that n-butane gas compressed isentropically from 1 bar and 323.15 K to 7.8 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 n-butane, the properties can be written down using Appendix B, Table B.1

ω=0.2, Tc=425.1 K, Pc=37.96 bar, ZC=0.276

Tr=T1TcTr=323.15 K425.1 K=0.7602

Pr=P1PcPr=1 bar37.96 bar=0.0263

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=0.76 lies between reduced temperatures Tr=0.75 and Tr=0.8 and Pr=0.026 lies in between reduced pressures Pr=0.01 and Pr=0.05 .

At Tr=0.75 and Pr=0.01

( H R)RTC0=−0.017, ( S R)R0=−0.015

At Tr=0.75 and Pr=0.05

( H R)RTC0=−0.088, ( S R)R0=−0.078

At Tr=0.8 and Pr=0.01

( H R)RTC0=−0.015, ( S R)R0=−0.013

At Tr=0.8 and Pr=0.05

( H R)RTC0=−0.078, ( S R)R0=−0.064

And

At Tr=0.75 and Pr=0.01

( H R)RTC1=−0.027, ( S R)R1=−0.029

At Tr=0.75 and Pr=0.05

( H R)RTC1=−0.142, ( S R)R1=−0.156

At Tr=0.8 and Pr=0.01

( H R)RTC1=−0.021, ( S R)R1=−0.022

At Tr=0.8 and Pr=0.05

( H R)RTC1=−0.11, ( S R)R1=−0.116

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=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC0=[( 0.05−0.026 0.05−0.01)×−0.017+( 0.026−0.01 0.05−0.01)×−0.088] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.76−0.750.8−0.75( H R )RTC0=−0.04436

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R0=[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.013+( 0.026−0.01 0.05−0.01)×−0.064] ×0.76−0.750.8−0.75( S R )R0=−0.03884

And

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC1=[( 0.05−0.026 0.05−0.01)×−0.027+( 0.026−0.01 0.05−0.01)×−0.142] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.021+( 0.026−0.01 0.05−0.01)×−0.110] ×0.76−0.750.8−0.75( H R )RTC1=−0.06972

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R1=[( 0.05−0.026 0.05−0.01)×−0.029+( 0.026−0.01 0.05−0.01)×−0.156] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.022+( 0.026−0.01 0.05−0.01)×−0.116] ×0.76−0.750.8−0.75( S R )R1=−0.07576

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R )0RTC+ω( H 1 R )1RTCH1RRTC=−0.04436+0.2×−0.06972H1RRTC=−0.058304H1R=−0.058304×8.314 Jmol K×425.1 KH1R=−206.063 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R )0R+ω( S 1 R )1RS1RR=−0.03884+0.2×−0.07576S1RR=−0.053992S1R=−0.053992×8.314 Jmol KS1R=−0.4489 Jmol K

Considering at final state gas is an ideal gas.

Hence, H2R=0 and S2R=0

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CP igRdTT=ln7.81−0+(−0.4489 Jmol K)8.314 Jmol K∫T1T2CPigRdTT=2

Hence,

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

τ=TT0

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

i A 103B 106 C 10−5Dn−butane 1.935 36.915 −11.402 0

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152+0 τ 2× 323.15 2)(τ+12)}(τ−1lnτ)]×lnτ2=[1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152)(τ+12)}(τ−1lnτ)]×lnττ=1.18

τ=TT01.18=T323.15KT=381.317 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 =1.935×323.15×(1.18−1)+36.915×10−32×323.152×(1.182−1)+−11.402×10−63×323.153(1.183−1)∫T0TΔC∘PRdT=−786.41 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−786.41 K+0−(−206.063 Jmol)W=−6332.15 Jmol

Conclusion

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Question

Chapter 6, Problem 6.60P

Interpretation Introduction

Interpretation:

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process.

Concept Introduction:

The entropy change by appropriate generalized correlations is

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

Expert Solution & Answer

Answer to Problem 6.60P

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Explanation of Solution

Given information:

It is given that n-butane gas compressed isentropically from 1 bar and 323.15 K to 7.8 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 n-butane, the properties can be written down using Appendix B, Table B.1

ω=0.2, Tc=425.1 K, Pc=37.96 bar, ZC=0.276

Tr=T1TcTr=323.15 K425.1 K=0.7602

Pr=P1PcPr=1 bar37.96 bar=0.0263

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=0.76 lies between reduced temperatures Tr=0.75 and Tr=0.8 and Pr=0.026 lies in between reduced pressures Pr=0.01 and Pr=0.05 .

At Tr=0.75 and Pr=0.01

( H R)RTC0=−0.017, ( S R)R0=−0.015

At Tr=0.75 and Pr=0.05

( H R)RTC0=−0.088, ( S R)R0=−0.078

At Tr=0.8 and Pr=0.01

( H R)RTC0=−0.015, ( S R)R0=−0.013

At Tr=0.8 and Pr=0.05

( H R)RTC0=−0.078, ( S R)R0=−0.064

And

At Tr=0.75 and Pr=0.01

( H R)RTC1=−0.027, ( S R)R1=−0.029

At Tr=0.75 and Pr=0.05

( H R)RTC1=−0.142, ( S R)R1=−0.156

At Tr=0.8 and Pr=0.01

( H R)RTC1=−0.021, ( S R)R1=−0.022

At Tr=0.8 and Pr=0.05

( H R)RTC1=−0.11, ( S R)R1=−0.116

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=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC0=[( 0.05−0.026 0.05−0.01)×−0.017+( 0.026−0.01 0.05−0.01)×−0.088] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.76−0.750.8−0.75( H R )RTC0=−0.04436

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R0=[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.013+( 0.026−0.01 0.05−0.01)×−0.064] ×0.76−0.750.8−0.75( S R )R0=−0.03884

And

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC1=[( 0.05−0.026 0.05−0.01)×−0.027+( 0.026−0.01 0.05−0.01)×−0.142] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.021+( 0.026−0.01 0.05−0.01)×−0.110] ×0.76−0.750.8−0.75( H R )RTC1=−0.06972

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R1=[( 0.05−0.026 0.05−0.01)×−0.029+( 0.026−0.01 0.05−0.01)×−0.156] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.022+( 0.026−0.01 0.05−0.01)×−0.116] ×0.76−0.750.8−0.75( S R )R1=−0.07576

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R )0RTC+ω( H 1 R )1RTCH1RRTC=−0.04436+0.2×−0.06972H1RRTC=−0.058304H1R=−0.058304×8.314 Jmol K×425.1 KH1R=−206.063 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R )0R+ω( S 1 R )1RS1RR=−0.03884+0.2×−0.07576S1RR=−0.053992S1R=−0.053992×8.314 Jmol KS1R=−0.4489 Jmol K

Considering at final state gas is an ideal gas.

Hence, H2R=0 and S2R=0

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CP igRdTT=ln7.81−0+(−0.4489 Jmol K)8.314 Jmol K∫T1T2CPigRdTT=2

Hence,

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

τ=TT0

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

i A 103B 106 C 10−5Dn−butane 1.935 36.915 −11.402 0

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152+0 τ 2× 323.15 2)(τ+12)}(τ−1lnτ)]×lnτ2=[1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152)(τ+12)}(τ−1lnτ)]×lnττ=1.18

τ=TT01.18=T323.15KT=381.317 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 =1.935×323.15×(1.18−1)+36.915×10−32×323.152×(1.182−1)+−11.402×10−63×323.153(1.183−1)∫T0TΔC∘PRdT=−786.41 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−786.41 K+0−(−206.063 Jmol)W=−6332.15 Jmol

Conclusion

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Question

Chapter 6, Problem 6.60P

Interpretation Introduction

Interpretation:

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process.

Concept Introduction:

The entropy change by appropriate generalized correlations is

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

Expert Solution & Answer

Answer to Problem 6.60P

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Explanation of Solution

Given information:

It is given that n-butane gas compressed isentropically from 1 bar and 323.15 K to 7.8 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 n-butane, the properties can be written down using Appendix B, Table B.1

ω=0.2, Tc=425.1 K, Pc=37.96 bar, ZC=0.276

Tr=T1TcTr=323.15 K425.1 K=0.7602

Pr=P1PcPr=1 bar37.96 bar=0.0263

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=0.76 lies between reduced temperatures Tr=0.75 and Tr=0.8 and Pr=0.026 lies in between reduced pressures Pr=0.01 and Pr=0.05 .

At Tr=0.75 and Pr=0.01

( H R)RTC0=−0.017, ( S R)R0=−0.015

At Tr=0.75 and Pr=0.05

( H R)RTC0=−0.088, ( S R)R0=−0.078

At Tr=0.8 and Pr=0.01

( H R)RTC0=−0.015, ( S R)R0=−0.013

At Tr=0.8 and Pr=0.05

( H R)RTC0=−0.078, ( S R)R0=−0.064

And

At Tr=0.75 and Pr=0.01

( H R)RTC1=−0.027, ( S R)R1=−0.029

At Tr=0.75 and Pr=0.05

( H R)RTC1=−0.142, ( S R)R1=−0.156

At Tr=0.8 and Pr=0.01

( H R)RTC1=−0.021, ( S R)R1=−0.022

At Tr=0.8 and Pr=0.05

( H R)RTC1=−0.11, ( S R)R1=−0.116

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=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC0=[( 0.05−0.026 0.05−0.01)×−0.017+( 0.026−0.01 0.05−0.01)×−0.088] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.76−0.750.8−0.75( H R )RTC0=−0.04436

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R0=[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.013+( 0.026−0.01 0.05−0.01)×−0.064] ×0.76−0.750.8−0.75( S R )R0=−0.03884

And

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC1=[( 0.05−0.026 0.05−0.01)×−0.027+( 0.026−0.01 0.05−0.01)×−0.142] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.021+( 0.026−0.01 0.05−0.01)×−0.110] ×0.76−0.750.8−0.75( H R )RTC1=−0.06972

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R1=[( 0.05−0.026 0.05−0.01)×−0.029+( 0.026−0.01 0.05−0.01)×−0.156] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.022+( 0.026−0.01 0.05−0.01)×−0.116] ×0.76−0.750.8−0.75( S R )R1=−0.07576

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R )0RTC+ω( H 1 R )1RTCH1RRTC=−0.04436+0.2×−0.06972H1RRTC=−0.058304H1R=−0.058304×8.314 Jmol K×425.1 KH1R=−206.063 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R )0R+ω( S 1 R )1RS1RR=−0.03884+0.2×−0.07576S1RR=−0.053992S1R=−0.053992×8.314 Jmol KS1R=−0.4489 Jmol K

Considering at final state gas is an ideal gas.

Hence, H2R=0 and S2R=0

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CP igRdTT=ln7.81−0+(−0.4489 Jmol K)8.314 Jmol K∫T1T2CPigRdTT=2

Hence,

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

τ=TT0

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

i A 103B 106 C 10−5Dn−butane 1.935 36.915 −11.402 0

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152+0 τ 2× 323.15 2)(τ+12)}(τ−1lnτ)]×lnτ2=[1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152)(τ+12)}(τ−1lnτ)]×lnττ=1.18

τ=TT01.18=T323.15KT=381.317 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 =1.935×323.15×(1.18−1)+36.915×10−32×323.152×(1.182−1)+−11.402×10−63×323.153(1.183−1)∫T0TΔC∘PRdT=−786.41 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−786.41 K+0−(−206.063 Jmol)W=−6332.15 Jmol

Conclusion

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Chapter 6, Problem 6.60P

Interpretation Introduction

Interpretation:

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process.

Concept Introduction:

The entropy change by appropriate generalized correlations is

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

Expert Solution & Answer

Answer to Problem 6.60P

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Explanation of Solution

Given information:

It is given that n-butane gas compressed isentropically from 1 bar and 323.15 K to 7.8 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 n-butane, the properties can be written down using Appendix B, Table B.1

ω=0.2, Tc=425.1 K, Pc=37.96 bar, ZC=0.276

Tr=T1TcTr=323.15 K425.1 K=0.7602

Pr=P1PcPr=1 bar37.96 bar=0.0263

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=0.76 lies between reduced temperatures Tr=0.75 and Tr=0.8 and Pr=0.026 lies in between reduced pressures Pr=0.01 and Pr=0.05 .

At Tr=0.75 and Pr=0.01

( H R)RTC0=−0.017, ( S R)R0=−0.015

At Tr=0.75 and Pr=0.05

( H R)RTC0=−0.088, ( S R)R0=−0.078

At Tr=0.8 and Pr=0.01

( H R)RTC0=−0.015, ( S R)R0=−0.013

At Tr=0.8 and Pr=0.05

( H R)RTC0=−0.078, ( S R)R0=−0.064

And

At Tr=0.75 and Pr=0.01

( H R)RTC1=−0.027, ( S R)R1=−0.029

At Tr=0.75 and Pr=0.05

( H R)RTC1=−0.142, ( S R)R1=−0.156

At Tr=0.8 and Pr=0.01

( H R)RTC1=−0.021, ( S R)R1=−0.022

At Tr=0.8 and Pr=0.05

( H R)RTC1=−0.11, ( S R)R1=−0.116

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=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC0=[( 0.05−0.026 0.05−0.01)×−0.017+( 0.026−0.01 0.05−0.01)×−0.088] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.76−0.750.8−0.75( H R )RTC0=−0.04436

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R0=[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.013+( 0.026−0.01 0.05−0.01)×−0.064] ×0.76−0.750.8−0.75( S R )R0=−0.03884

And

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC1=[( 0.05−0.026 0.05−0.01)×−0.027+( 0.026−0.01 0.05−0.01)×−0.142] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.021+( 0.026−0.01 0.05−0.01)×−0.110] ×0.76−0.750.8−0.75( H R )RTC1=−0.06972

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R1=[( 0.05−0.026 0.05−0.01)×−0.029+( 0.026−0.01 0.05−0.01)×−0.156] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.022+( 0.026−0.01 0.05−0.01)×−0.116] ×0.76−0.750.8−0.75( S R )R1=−0.07576

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R )0RTC+ω( H 1 R )1RTCH1RRTC=−0.04436+0.2×−0.06972H1RRTC=−0.058304H1R=−0.058304×8.314 Jmol K×425.1 KH1R=−206.063 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R )0R+ω( S 1 R )1RS1RR=−0.03884+0.2×−0.07576S1RR=−0.053992S1R=−0.053992×8.314 Jmol KS1R=−0.4489 Jmol K

Considering at final state gas is an ideal gas.

Hence, H2R=0 and S2R=0

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CP igRdTT=ln7.81−0+(−0.4489 Jmol K)8.314 Jmol K∫T1T2CPigRdTT=2

Hence,

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

τ=TT0

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

i A 103B 106 C 10−5Dn−butane 1.935 36.915 −11.402 0

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152+0 τ 2× 323.15 2)(τ+12)}(τ−1lnτ)]×lnτ2=[1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152)(τ+12)}(τ−1lnτ)]×lnττ=1.18

τ=TT01.18=T323.15KT=381.317 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 =1.935×323.15×(1.18−1)+36.915×10−32×323.152×(1.182−1)+−11.402×10−63×323.153(1.183−1)∫T0TΔC∘PRdT=−786.41 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−786.41 K+0−(−206.063 Jmol)W=−6332.15 Jmol

Conclusion

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Answer 6

Chapter 6, Problem 6.60P

Interpretation Introduction

Interpretation:

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process.

Concept Introduction:

The entropy change by appropriate generalized correlations is

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

Expert Solution & Answer

Answer to Problem 6.60P

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Explanation of Solution

Given information:

It is given that n-butane gas compressed isentropically from 1 bar and 323.15 K to 7.8 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 n-butane, the properties can be written down using Appendix B, Table B.1

ω=0.2, Tc=425.1 K, Pc=37.96 bar, ZC=0.276

Tr=T1TcTr=323.15 K425.1 K=0.7602

Pr=P1PcPr=1 bar37.96 bar=0.0263

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=0.76 lies between reduced temperatures Tr=0.75 and Tr=0.8 and Pr=0.026 lies in between reduced pressures Pr=0.01 and Pr=0.05 .

At Tr=0.75 and Pr=0.01

( H R)RTC0=−0.017, ( S R)R0=−0.015

At Tr=0.75 and Pr=0.05

( H R)RTC0=−0.088, ( S R)R0=−0.078

At Tr=0.8 and Pr=0.01

( H R)RTC0=−0.015, ( S R)R0=−0.013

At Tr=0.8 and Pr=0.05

( H R)RTC0=−0.078, ( S R)R0=−0.064

And

At Tr=0.75 and Pr=0.01

( H R)RTC1=−0.027, ( S R)R1=−0.029

At Tr=0.75 and Pr=0.05

( H R)RTC1=−0.142, ( S R)R1=−0.156

At Tr=0.8 and Pr=0.01

( H R)RTC1=−0.021, ( S R)R1=−0.022

At Tr=0.8 and Pr=0.05

( H R)RTC1=−0.11, ( S R)R1=−0.116

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=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC0=[( 0.05−0.026 0.05−0.01)×−0.017+( 0.026−0.01 0.05−0.01)×−0.088] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.76−0.750.8−0.75( H R )RTC0=−0.04436

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R0=[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.013+( 0.026−0.01 0.05−0.01)×−0.064] ×0.76−0.750.8−0.75( S R )R0=−0.03884

And

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC1=[( 0.05−0.026 0.05−0.01)×−0.027+( 0.026−0.01 0.05−0.01)×−0.142] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.021+( 0.026−0.01 0.05−0.01)×−0.110] ×0.76−0.750.8−0.75( H R )RTC1=−0.06972

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R1=[( 0.05−0.026 0.05−0.01)×−0.029+( 0.026−0.01 0.05−0.01)×−0.156] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.022+( 0.026−0.01 0.05−0.01)×−0.116] ×0.76−0.750.8−0.75( S R )R1=−0.07576

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R )0RTC+ω( H 1 R )1RTCH1RRTC=−0.04436+0.2×−0.06972H1RRTC=−0.058304H1R=−0.058304×8.314 Jmol K×425.1 KH1R=−206.063 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R )0R+ω( S 1 R )1RS1RR=−0.03884+0.2×−0.07576S1RR=−0.053992S1R=−0.053992×8.314 Jmol KS1R=−0.4489 Jmol K

Considering at final state gas is an ideal gas.

Hence, H2R=0 and S2R=0

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CP igRdTT=ln7.81−0+(−0.4489 Jmol K)8.314 Jmol K∫T1T2CPigRdTT=2

Hence,

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

τ=TT0

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

i A 103B 106 C 10−5Dn−butane 1.935 36.915 −11.402 0

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152+0 τ 2× 323.15 2)(τ+12)}(τ−1lnτ)]×lnτ2=[1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152)(τ+12)}(τ−1lnτ)]×lnττ=1.18

τ=TT01.18=T323.15KT=381.317 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 =1.935×323.15×(1.18−1)+36.915×10−32×323.152×(1.182−1)+−11.402×10−63×323.153(1.183−1)∫T0TΔC∘PRdT=−786.41 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−786.41 K+0−(−206.063 Jmol)W=−6332.15 Jmol

Conclusion

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Answer 7

Chapter 6, Problem 6.60P

Interpretation Introduction

Interpretation:

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process.

Concept Introduction:

The entropy change by appropriate generalized correlations is

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

Answer 8

Expert Solution & Answer

Answer to Problem 6.60P

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given information:

It is given that n-butane gas compressed isentropically from 1 bar and 323.15 K to 7.8 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 n-butane, the properties can be written down using Appendix B, Table B.1

ω=0.2, Tc=425.1 K, Pc=37.96 bar, ZC=0.276

Tr=T1TcTr=323.15 K425.1 K=0.7602

Pr=P1PcPr=1 bar37.96 bar=0.0263

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=0.76 lies between reduced temperatures Tr=0.75 and Tr=0.8 and Pr=0.026 lies in between reduced pressures Pr=0.01 and Pr=0.05 .

At Tr=0.75 and Pr=0.01

( H R)RTC0=−0.017, ( S R)R0=−0.015

At Tr=0.75 and Pr=0.05

( H R)RTC0=−0.088, ( S R)R0=−0.078

At Tr=0.8 and Pr=0.01

( H R)RTC0=−0.015, ( S R)R0=−0.013

At Tr=0.8 and Pr=0.05

( H R)RTC0=−0.078, ( S R)R0=−0.064

And

At Tr=0.75 and Pr=0.01

( H R)RTC1=−0.027, ( S R)R1=−0.029

At Tr=0.75 and Pr=0.05

( H R)RTC1=−0.142, ( S R)R1=−0.156

At Tr=0.8 and Pr=0.01

( H R)RTC1=−0.021, ( S R)R1=−0.022

At Tr=0.8 and Pr=0.05

( H R)RTC1=−0.11, ( S R)R1=−0.116

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=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC0=[( 0.05−0.026 0.05−0.01)×−0.017+( 0.026−0.01 0.05−0.01)×−0.088] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.76−0.750.8−0.75( H R )RTC0=−0.04436

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R0=[( 0.05−0.026 0.05−0.01)×−0.015+( 0.026−0.01 0.05−0.01)×−0.078] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.013+( 0.026−0.01 0.05−0.01)×−0.064] ×0.76−0.750.8−0.75( S R )R0=−0.03884

And

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( H R )RTC1=[( 0.05−0.026 0.05−0.01)×−0.027+( 0.026−0.01 0.05−0.01)×−0.142] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.021+( 0.026−0.01 0.05−0.01)×−0.110] ×0.76−0.750.8−0.75( H R )RTC1=−0.06972

M=[( X 2 −X X 2 − X 1 )M1,1+( X− X 1 X 2 − X 1 )M1,2]Y2−YY2−Y1 +[( X 2 −X X 2 − X 1 )M2,1+( X− X 1 X 2 − X 1 )M2,2]Y−Y1Y2−Y1( S R )R1=[( 0.05−0.026 0.05−0.01)×−0.029+( 0.026−0.01 0.05−0.01)×−0.156] ×0.8−0.760.8−0.75 +[( 0.05−0.026 0.05−0.01)×−0.022+( 0.026−0.01 0.05−0.01)×−0.116] ×0.76−0.750.8−0.75( S R )R1=−0.07576

Now, from equation,

H1R=(H1R)0+ω(H1R)1

Or

H1RRTC=( H 1 R )0RTC+ω( H 1 R )1RTCH1RRTC=−0.04436+0.2×−0.06972H1RRTC=−0.058304H1R=−0.058304×8.314 Jmol K×425.1 KH1R=−206.063 Jmol

And

S1R=(S1R)0+ω(S1R)1

Or

S1RR=( S 1 R )0R+ω( S 1 R )1RS1RR=−0.03884+0.2×−0.07576S1RR=−0.053992S1R=−0.053992×8.314 Jmol KS1R=−0.4489 Jmol K

Considering at final state gas is an ideal gas.

Hence, H2R=0 and S2R=0

Now,

∫T1T2 C P igRdTT=ln P 2 P 1−S2RR+S1RR∫T1T2CP igRdTT=ln7.81−0+(−0.4489 Jmol K)8.314 Jmol K∫T1T2CPigRdTT=2

Hence,

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

τ=TT0

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

i A 103B 106 C 10−5Dn−butane 1.935 36.915 −11.402 0

τ=TT0

∫T1T2 C P igRdTT=[A+{BT0+(CT02+D τ 2 T 0 2 )( τ+12)}(τ−1lnτ)]×lnτ∫T1T2CP igRdTT= [1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152+0 τ 2× 323.15 2)(τ+12)}(τ−1lnτ)]×lnτ2=[1.935+{36.915×10−3×323.15+(−11.402×10−6×323.152)(τ+12)}(τ−1lnτ)]×lnττ=1.18

τ=TT01.18=T323.15KT=381.317 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 =1.935×323.15×(1.18−1)+36.915×10−32×323.152×(1.182−1)+−11.402×10−63×323.153(1.183−1)∫T0TΔC∘PRdT=−786.41 K

Hence,

W=ΔH=R∫T1T2 C P igRdT+H2R−H1RW=8.314 Jmol K×−786.41 K+0−(−206.063 Jmol)W=−6332.15 Jmol

Answer 12

Conclusion

Temperature is

T=381.317 K

Work done is

W=−6332.15 Jmol

Answer 13

Ch. 6 - Prob. 6.1P Ch. 6 - Prob. 6.2P Ch. 6 - Prob. 6.3P Ch. 6 - Prob. 6.4P Ch. 6 - Prob. 6.5P Ch. 6 - Prob. 6.6P Ch. 6 - Prob. 6.7P Ch. 6 - Prob. 6.8P Ch. 6 - Prob. 6.9P Ch. 6 - Prob. 6.10P

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process. Concept Introduction: The entropy change by appropriate generalized correlations is Δ S = ∫ T 1 T 2 C P i g d T T − R ln P 2 P 1 + S 2 R − S 1 R ....(2)

Interpretation: Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process. Concept Introduction: The entropy change by appropriate generalized correlations is ΔS=∫T1T2CPigdTT−RlnP2P1+S2R−S1R....(2)

Answer to Problem 6.60P

Explanation of Solution

Want to see more full solutions like this?

Chapter 6 Solutions

Interpretation:

Determine the final temperature and work produced of the compressedn-butane gas, compressed isentropically in a steady state process.

Concept Introduction:

The entropy change by appropriate generalized correlations is

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