EBK INTRODUCTION TO CHEMICAL ENGINEERIN
EBK INTRODUCTION TO CHEMICAL ENGINEERIN
8th Edition
ISBN: 9781259878091
Author: SMITH
Publisher: MCGRAW HILL BOOK COMPANY
Question
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Chapter 5, Problem 5.49P

(a)

Interpretation Introduction

Interpretation:

Calculate the lost work of given process in(kJ)(mole)1 of the flue gas.

Concept Introduction:

The lost work of any process is calculated by following formula:

  Wlost=TσSG    ....(1)

(a)

Expert Solution
Check Mark

Answer to Problem 5.49P

  Wlost=14.8208kJmol 

Explanation of Solution

Given information:

The process is given as a flue gas is cooled from1100C to150C, heat is used to generate saturated steam at100C in a boiler.

The heat capacity of flue gas is given as,

  CPR=3.83+0.000551T/(K)

Latent heat of vaporization of water to generate steam is given asΔHV=2256.9kJkg and water enters the boiler at100C and surrounding temperature is given as25C .

  T0=1100C+273.15=1373.15K

  T=150C+273.15=423.15K

  Tσ=25C+273.15=298.15K

  Tsteam=100C+273.15=373.15K

For rate of entropy generation, the total entropy generation in boiler is the sum of the entropy generation during the heating of water in order to generate steam and entropy generation during the cooling of gas which are find out by entropy balance of the open system equation.

  SG=SGas+SSteam

Entropy generation during cooling of gas is

  (ΔSgasn)=SGas

The entropy change of gas is

  dS=CPTdTΔSgas=RT0TCPTdTRΔSgas=RT0T3.83+0.000551TTdTΔSgas=R[3.83×ln423.15K1373.15K+0.000551(423.15K1373.15K)]ΔSgas=8.314Jmol K×5.03ΔSgas=41.83Jmol K

And

Entropy generation during vaporization of water is

  (ΔSsteamm)=Ssteam

The entropy change of water is

  ΔSsteam=ΔHVTsteamΔSsteam=2256.9kJkg373.15K=6.048kJkg K

Now for the calculations of mass and molar flow rates, applying the steady state energy balance across the boiler

  nT0TCPdT+mΔHV=0mn=T0TCPdTΔHV=RT0TCPRdTΔHVmn=T0TCPdTΔHV=8.314Jmol K×T0T(3.83+0.000551T)dT970.3Btulbmmn=8.314Jmol K×[3.83×(TT0)+0.000551×T220.000551×T022]2256.9kJkgmn=8.314Jmol K×[3.83×(423.15K1373.15K)+0.000551×423.15220.000551×1373.1522]2256.9kJkgmn=34159.205Jmol×1kJ1000J2256.9kJkg×1kg1000gmn=15.14gmmol

Hence

  SG=SGas+SSteamSG=(ΔSgasn)+(ΔSsteamm)SGn=mnΔSsteam+ΔSgasSGn=15.14gmmol×6.048Jgm K+(41.83Jmol K)SGn=49.709Jmol K

Hence the lost work in(kJ)(mole)1 is

  Wlost=TσSGWlost=298.15K×49.709Jmol KWlost=14820.805Jmol ×1kJ1000JWlost=14.8208kJmol 

(b)

Interpretation Introduction

Interpretation:

Calculate the maximum work of given process in(kJ)(mole)1 of the flue gas that can be accomplished by the saturated steam if it condenses only and does not subcool.

Concept Introduction:

The maximum work of any process is ideal work and calculated by following formula:

  Wideal=ΔHTσΔS

    ....(1)

(b)

Expert Solution
Check Mark

Answer to Problem 5.49P

  Wideal=6.867kJkmol

Explanation of Solution

Given information:

Latent heat of vaporization of water to generate steam is given asΔHV=2256.9kJkg and water enters the boiler at100C and surrounding temperature is given as25C .

  Tσ=25C+273.15=298.15K

  Tsteam=100C+273.15=373.15K

The maximum work of flue gas if it condenses only and does not subcoolis same as ideal work done by water to vaporize. Hence

  Wideal=ΔHsteamTσΔSsteam

AndΔHsteam=ΔHV=2256.9kJkg

From the part (a), we found that

  ΔSsteam=ΔHVTsteamΔSsteam=2256.9kJkg373.15K=6.048kJkg K

Hence

  Wideal=ΔHVTσΔSsteamWideal=2256.9Jgm298.15K×6.048kJkg KWideal=453.62kJkg

The maximum work in terms of(kJ)(mole)1 is

From the part (a), we found that

  mn=15.14gmmol

Hence

  Wideal×mn=453.62kJkg×15.14gmmol×1kg1000gmWideal=6.867kJkmol

(c)

Interpretation Introduction

Interpretation:

Compare the results of part (b) with the theoretical value of maximum work done by flue gas itself.

Concept Introduction:

The maximum work of any process is ideal work and calculated by following formula:

  Wideal=ΔHTσΔS

    ....(1)

(c)

Expert Solution
Check Mark

Answer to Problem 5.49P

  Wideal=21.687kJmol

Explanation of Solution

The maximum work of flue gas is same as ideal work done by flue gas. Hence

  Wideal=ΔHgasTσΔSgas

  ΔHgas=T0TCPdTΔHgas=RT0TCPRdTΔHgas=8.314Jmol K×T0T(3.83+0.000551T)dTΔHgas=8.314Jmol K×[3.83×(423.15K1373.15K)+0.000551×423.15220.000551×1373.1522]ΔHgas=34159.205Jmol×1kJ1000JΔHgas=34.159kJmol

From the part (a), we found that

  ΔSgas=41.83Jmol K

Hence

  Wideal=ΔHgasTσΔSgasWideal=34159.205Jmol298.15K×41.83Jmol KWideal=21687.59Jmol×1kJ1000JWideal=21.687kJmol

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