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 16, Problem 16.1P
Interpretation Introduction

(a)

Interpretation:

To interpret the value of ideal power required5 (W˙ideal) for the process.

Concept Introduction:

The initial stage contains liquid water at 21°C . The final stage contains ice at 0°C . Heat of fusion of water is 333.5kJkg and ice is producing at a rate of 0.5kgs .

Expert Solution
Check Mark

Answer to Problem 16.1P

The ideal power required (W˙ideal) for the process is 13.15 kW .

Explanation of Solution

At initial stage,

  Hi=88.5043 kJkgSi=0.31216 kJkg-K

At final stage,

  Hf=333.5kJkgSf=1.22 kJkg-K

The value of Tσ is Tσ=294.15

The flowsheet of the given process is as follows,

EBK INTRODUCTION TO CHEMICAL ENGINEERIN, Chapter 16, Problem 16.1P , additional homework tip  1

The various positions in the flowsheet are described as follows,

Point A: saturated vapor at 0°C .

Point B: Superheated vapor at P=5.84atm and the entropy of Point A.

Point C: saturated liquid at 21°C.P=5.84atm .

Point D: Mixture of saturated liquid & saturated vapor at 0°C with the enthalpy of Point C.

Data for Points A, C, & D from Table 9.1. Data for Point B from Fig. G.2. For reference, Table 9.1 and Figure G.2 are below.

EBK INTRODUCTION TO CHEMICAL ENGINEERIN, Chapter 16, Problem 16.1P , additional homework tip  2

EBK INTRODUCTION TO CHEMICAL ENGINEERIN, Chapter 16, Problem 16.1P , additional homework tip  3

The equation to calculate the ideal work done (Wideal) is Wideal=HfHiTσ(SfSi) .

Upon substituting the values,

  Wideal=HfHiTσ(SfSi)=(333.5)(88.5043)(294.15(1.22.31216))Wideal=29.22KJKg|Wideal|=29.22KJKg

Let the mass flow rate be m˙=0.45Kgs

So, the ideal power required is W˙ideal=m˙×Wideal

  W˙ideal=m˙×Wideal(Kgs×KJKg)=0.45×29.22KJs=13.15KW (Js=W)

So, the ideal power required is W˙ideal=13.145KW

Interpretation Introduction

(b)

Interpretation:

To calculate the ideal power required (W˙ideal) for a single Carnot Heat Pump operated between 273.15K(0°C)&294.15K(21°C) and its thermodynamic efficiency.

Concept Introduction:

A single Carnot heat pump is operated between sink and source at 273.15K(0°C)&294.15K(21°C) respectively.

Expert Solution
Check Mark

Answer to Problem 16.1P

The ideal power required (W˙ideal) for given single Carnot Heat Pump is 14.6 kW and thermodynamic efficiency ηt=0.9 .

Explanation of Solution

For the Carnot heat pump, heat equal to the enthalpy change of the water is extracted from a cold reservoir at 0°C, with heat rejection to the surroundings at 21°C .

The given data is as follows,

  TH=21°C(orTσ)TC=0°CHi=88.5043kJkgHf=333.5kJkgηT=ThermodynamicEfficiency

The heat removed is QC=HfHi .

  QC=HfHi=333.588.5043QC=422KJKg

The work done can be calculated as W=|QC|(THTCTC)

  W=|QC|( T H T C T C)=|422|(( 21+273.15)( 0+273.15)( 0+273.15))=|422|(21273.15)W=32.44KJKg

The power required is W˙=m˙×W .

  W˙=m˙×W (kgs×kJkg)=0.45×32.44 kJsW˙=14.6 kW (Js=W)

The thermodynamic efficiency is ηT=W˙idealW˙

  ηT=W˙idealW˙=13.1514.6ηT=0.9

Interpretation Introduction

©

Interpretation:

To interpret the power requirement of an ideal tetrafluoroethane vapor-compression refrigeration cycle and thermodynamic efficiency of the process.

Concept Introduction:

Vapor-compression refrigeration cycle is operated using tetrafluoroethane. Ideal condition implies Isentropic Compression, Infinite cooling water rate in the condenser and minimum heat transfer driving forces in evaporator and condenser.

Expert Solution
Check Mark

Answer to Problem 16.1P

The power requirement of an ideal tetrafluoroethane vapor-compression refrigeration cycle is 16.67 kW . Thermodynamic efficiency of the process is ηt=0.788 .

Explanation of Solution

Conventional refrigeration cycle under ideal conditions of operation: Isentropic compression, infinite flow rate of cooling water, & minimum temperature difference for heat transfer = 0.

The data is as follows,

For saturated liquid and vapor at 0°C,

  HA=250.28kJkgSA=0.93kJkgK

For saturated liquid at 18°C,

  HC=79.735kJkgHD=HC

For superheated vapor at 5.84atm and S=0.93kJkgK,

  HB=265.164kJkg

Refrigeration Circulation Rate:

  m˙=( H f H i)×0.45KgsHAHDW˙=m˙×(HBHA)ηA=W˙idealW˙

Substitute the values in the above equations,

  m˙=( H f H i)×0.45kgsHAHD=(333.588.5043)×0.45(250.2879.735)m˙=1.12kgsW˙=m˙×(HBHA)=1.12×(265.164250.28)W˙=16.67ηt=W˙idealW˙=13.1516.67ηt=0.788

Interpretation Introduction

(d)

Interpretation:

To interpret the power requirement (W˙ideal) of a tetrafluoroethane vapor-compression cycle for which the compressor efficiency is 75% .

Concept Introduction:

Vapor-compression refrigeration cycle is operated using tetrafluoroethane. The thermodynamic efficiency is 75% . Ideal condition implies Isentropic Compression, Infinite cooling water rate in the condenser and minimum heat transfer driving forces in evaporator and condenser.

Expert Solution
Check Mark

Answer to Problem 16.1P

The power requirement (W˙ideal) of a tetrafluoroethane vapor-compression cycle for which the compressor efficiency of 75% is 46.8 kW and the thermodynamic efficiency is ηt=0.281

Explanation of Solution

Given, efficiency is η=0.75

The practical cycle has 4 major points,

Point A: Saturated vapor at 5°C .

Point B: Superheated vapor at 9.17atm .

Point C: Saturated Liquid at 10°C .

Point D: Mix of saturated liquid and saturated vapor at 5°C with H of point C,

For saturated liquid and vapor at 5°C,

  Hliq=45.54kJkgSliq=0.18kJkgKHvap=247.67kJkg=HASvap=0.914kJkgK=SA

For saturated liquid at 10°C,

  HC=102.9kJkgSC=0.38kJkgK

For isentropic compression, the entropy of Point B is SB=0.934kJkgK at P=9.17atm .

  HB=274.47KJKg (FromFig.G2)HB=HA+HBHAηHB=247.67+274.47247.670.75HB=283.4kJkg

  xD=HDHliqHvapHliq=102.945.54247.6745.54xD=0.284

Entropy at point D can be calculated as

\n

  SD=Sliq+xD(SvapSliq)=0.18+(0.284(0.9140.18))SD=0.388kJkgK

Refrigerant circulation rate can be calculated as

\n

  m˙=( H f H i)×0.45kgsHAHD=(333.588.5043)×0.45(247.67102.9)m˙=1.31kgsW˙=m˙×(HBHA)=1.31×(283.4247.67)W˙=46.8ηt=W˙idealW˙=13.1546.8ηt=0.281

Thermodynamic Analysis

\n

Here Tσ=21°C,

  W˙ideal=13.15KWW˙LostCompressor=m˙Tσ(SBSA)=1.31×294.15×(0.9340.914)W˙LostCompressor=8.305 kWQ˙Condenser=m˙(HCHB)=1.31×(102.9283.4)Q˙Condenser=236.455W˙LostCondenser=m˙Tσ(SCSB)Q˙Condenser=1.31×294.15(0.380.934)(236.455)W˙LostCondenser=14.178 kWW˙Throttle=m˙Tσ(SDSC)=1.31×294.15(0.3880.377)W˙Throttle=4.24 kW

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