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��1�� MOLE BALANCES
Ħ������ 1
1.1 The Rate of Reaction����rA
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1.2 The General Mole Balance Equation (GMBE)
ͨ��Ħ�����㷽�̣�GMBE������8
1.3 Batch Reactors (BRs)
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1.4 Continuous-Flow Reactors
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1.4.1��Continuous-Stirred Tank Reactor (CSTR)
ȫ�츪��CSTR������12
1.4.2��Tubular Reactor
��ʽ����(y��ng)������14
1.4.3��Packed-Bed Reactor (PBR)
��䴲����(y��ng)����PBR�� ����18
1.4.4��Well-Mixed “Fluidized” Catalytic Bed Reactor
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1.5 Industrial Reactors
���I(y��)����(y��ng)������24
1.6 And Now… A Word from Our Sponsor—Safety1 (AWFOS-S1 Safety)
��ȫ����1——�W(xu��)��(x��)�^�̰�ȫ����Ҫ�ԡ���25
1.6.1��What Is Chemical Process Safety
ʲô�ǻ��W(xu��)�^�̰�ȫ����25
1.6.2��Why Study Process Safety
��ʲô�о��^�̰�ȫ����25

��2�� CONVERSION AND REACTOR SIZING
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2.1 Definition of Conversion
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2.2 Batch Reactor Design Equations
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2.3 Design Equations for Flow Reactors
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2.3.1��CSTR (Also Known as a Backmix Reactor or a Vat)
ȫ�츪��CSTR��һ�N�����ʽ����(y��ng)��������40
2.3.2��Tubular Flow Reactor (PFR)
��ʽ����(y��ng)����PFR�� ����40
2.3.3��Packed-Bed Reactor (PBR)
��䴲����(y��ng)����PBR������41
2.4 Sizing Continuous-Flow Reactors
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2.5 Reactors in Series
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2.5.1��CSTRs in Series
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2.5.2��PFRs in Series
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2.5.3��Combinations of CSTRs and PFRs in Series
ȫ�츪��ƽ��������(y��ng)����“(li��n)����57
2.5.4��Comparing the CSTR and PFR Volumes and Reactor Sequencing
���^ȫ�츪��ƽ��������(y��ng)���ijߴ��Լ�����(y��ng)����򡡡�61
2.6 Some Further Definitions
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2.6.1��Space Time
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2.6.2��Space Velocity
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2.7 And Now… A Word from Our Sponsor—Safety 2(AWFOS-S2 The NFPA Diamond)
��ȫ����2——NFPA��(bi��o)������66

��3�� RATE LAWS
���ʷ��� 75
3.1 Basic Definitions
�������x����76
3.1.1��Relative Rates of Reaction
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3.2 The Rate Law
���ʷ��̡���78
3.2.1��Power Law Models and Elementary Rate Laws
�纯��(sh��)ģ�ͺͻ�Ԫ����(y��ng)���ʷ��̡���79
3.2.2��Nonelementary Rate Laws
�ǻ�Ԫ����(y��ng)���ʷ��̡���82
3.2.3��Reversible Reactions
���淴��(y��ng)����86
3.3 The Reaction-Rate Constant
����(y��ng)���ʳ���(sh��)����89
3.3.1��The Rate Constant k and Its Temperature Dependence
���ʳ���(sh��)k�͜ض�Ч��(y��ng)����89
3.3.2��Interpretation of the Activation Energy
��ܵĽ�ጡ���90
3.3.3��The Arrhenius Plot
�������˹��ʽ����96
3.4 Molecular Simulations
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3.4.1��Historical Perspective
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3.4.2��Stochastic Modeling of Reactions
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3.5 Present Status of Our Approach to Reactor Sizing and Design
����(y��ng)���ߴ�Ӌ(j��)����O(sh��)Ӌ(j��)�ķ�������103
3.6 And Now… A Word from Our Sponsor—Safety 3(AWFOS-S3 The GHS Diamond)
��ȫ����3——GHS��(bi��o)������104

��4�� STOICHIOMETRY
���W(xu��)Ӌ(j��)���P(gu��n)ϵ 117
4.1 Batch Reactors (BRs)
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4.1.1��Batch Concentrations for the Generic Reaction, Equation (2-2)
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4.2 Flow Systems
����(d��ng)ϵ�y(t��ng)����125
4.2.1��Equations for Concentrations in Flow Systems
����(d��ng)ϵ�y(t��ng)��ȷ��̡���126
4.2.2��Liquid-Phase Concentrations
Һ����ȡ���126
4.2.3��Gas-Phase Concentrations
������ȡ���127
4.3 Reversible Reactions and Equilibrium Conversion
���淴��(y��ng)��ƽ���D(zhu��n)���ʡ���138
4.4 And Now… A Word from Our Sponsor—Safety 4(AWFOS-S4 The Swiss Cheese Model)
��ȫ����4——��ʿ����ģ�͡���143

��5�� ISOTHERMAL REACTOR DESIGN: CONVERSION
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5.1 Design Structure for Isothermal Reactors
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5.2 Batch Reactors (BRs)
�g����(y��ng)����BRs������160
5.2.1��Batch Reaction Times
�g����(y��ng)������(y��ng)�r(sh��)�g����161
5.3 Continuous-Stirred Tank Reactors (CSTRs)
ȫ�츪��CSTRs������168
5.3.1��A Single CSTR
�΂�(g��)ȫ�츪����168
5.3.2��CSTRs in Series
ȫ�츪��“(li��n)����171
5.4 Tubular Reactors
��ʽ����(y��ng)������178
5.4.1��Liquid-Phase Reactions in a PFR υ = υ0
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5.4.2��Gas-Phase Reactions in a PFR [υ = υ0 (1 εX) (T/T0)(P0/P)]
ƽ��������(y��ng)���еĚ��෴��(y��ng) [υ = υ0 (1 εX) (T/T0)(P0/P)] ����180
5.4.3��Effect of ε on Conversion
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5.5 Pressure Drop in Reactors
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5.5.1��Pressure Drop and the Rate Law
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5.5.2��Flow Through a Packed Bed
��䴲�е�����(d��ng)����187
5.5.3��Pressure Drop in Pipes
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5.5.4��Analytical Solution for Reaction with Pressure Drop
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5.5.5��Robert the Worrier Wonders: What If…
Robert��֪��������l����׃��(hu��)�l(f��)��ʲô����198
5.6 Synthesizing the Design of a Chemical Plant
�����S�O(sh��)Ӌ(j��)����208
5.7 And Now… A Word from Our Sponsor—Safety 5 (AWFOS-S5 A Safety Analysis of the Incident Algorithm)
��ȫ����5——�¹ʰ�ȫ�����㷨����210

��6�� ISOTHERMAL REACTOR DESIGN: MOLES AND MOLAR FLOW RATES
�Ȝط���(y��ng)���O(sh��)Ӌ(j��)�����|(zh��)������Ħ������ 229
6.1 The Moles and Molar Flow Rate Balance Algorithms
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6.2 Mole Balances on CSTRs, PFRs, PBRs, and Batch Reactors
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6.2.1��Liquid Phase
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6.2.2��Gas Phase
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6.3 Application of the PFR Molar Flow Rate Algorithm to a Microreactor
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6.4 Membrane Reactors
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6.5 Unsteady-State Operation of Stirred Reactors
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6.6 Semibatch Reactors
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6.6.1��Motivation for Using a Semibatch Reactor
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6.6.2��Semibatch Reactor Mole Balances
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6.6.3��Equilibrium Conversion
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6.7 And Now… A Word from Our Sponsor—Safety 6 (AWFOS-S6 The BowTie Diagram)
��ȫ����6——�I(l��ng)�Y(ji��)�D����256

��7�� COLLECTION AND ANALYSIS OF RATE DATA
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7.1 The Algorithm for Data Analysis
��(sh��)��(j��)�����㷨����270
7.2 Determining the Reaction Order for Each of Two Reactants Using the Method of Excess
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7.3 Integral Method
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7.4 Differential Method of Analysis
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7.4.1��Graphical Differentiation Method
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7.4.2��Numerical Method
��(sh��)ֵ��������278
7.4.3��Finding the Rate-Law Parameters
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7.5 Nonlinear Regression
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7.5.1��Concentration-Time Data
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7.5.2��Model Discrimination
ģ�ͱ�e����290
7.6 Reaction-Rate Data from Differential Reactors
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7.7 Experimental Planning
��(sh��)�(y��n)Ӌ(j��)������297
7.8 And Now… A Word from Our Sponsor—Safety 7 (AWFOS-S7 Laboratory Safety)
��ȫ����7——��(sh��)�(y��n)�Ұ�ȫ����298

��8�� MULTIPLE REACTIONS
��(f��)�Ϸ���(y��ng) 309
8.1 Definitions
���x����310
8.1.1��Types of Reactions
����(y��ng)��͡���310
8.1.2��Selectivity
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8.1.3��Yield
���ʡ���312
8.1.4��Conversion
�D(zhu��n)���ʡ���313
8.2 Algorithm for Multiple Reactions
��(f��)�Ϸ���(y��ng)���㷨����313
8.2.1��Modifications to the Chapter 6 CRE Algorithm for Multiple Reactions
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8.3 Parallel Reactions
ƽ�з���(y��ng)����316
8.3.1��Selectivity
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8.3.2��Maximizing the Desired Product for One Reactant
��һ����(y��ng)���wϵĿ��(bi��o)�a(ch��n)�ﻯ����316
8.3.3��Reactor Selection and Operating Conditions
����(y��ng)���x�ͺͲ����l������322
8.4 Reactions in Series
�B������(y��ng)����325
8.5 Complex Reactions
��(f��)�s����(y��ng)����335
8.5.1��Complex Gas-Phase Reactions in a PBR
��䴲����(y��ng)���еď�(f��)�s���෴��(y��ng)����335
8.5.2��Complex Liquid-Phase Reactions in a CSTR
ȫ�츪�еď�(f��)�sҺ�෴��(y��ng)����339
8.5.3��Complex Liquid-Phase Reactions in a Semibatch Reactor
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8.6 Membrane Reactors to Improve Selectivity in Multiple Reactions
����Ĥ����(y��ng)����ߏ�(f��)�Ϸ���(y��ng)���x���ԡ���343
8.7 Sorting It All Out
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8.8 The Fun Part
��Ȥ�IJ��֡���348
8.9 And Now… A Word from Our Sponsor—Safety 8 (AWFOS-S8 The Fire Triangle)
��ȫ����8——�����ǡ���349
8.9.1��The Fire Triangle
�����ǡ���350
8.9.2��Defining Some Important Terms
���xһЩ��Ҫ���g(sh��)�Z����350
8.9.3��Ways to Prevent Fires
�A(y��)�����(z��i)�ķ�������350
8.9.4��Ways to Protect from Fires
���(z��i)���o(h��)��������351

��9�� REACTION MECHANISMS, PATHWAYS, BIOREACTIONS, AND BIOREACTORS
����(y��ng)�C(j��)����·�������ﷴ��(y��ng)�����ﷴ��(y��ng)�� 367
9.1 Active Intermediates and Nonelementary Rate Laws
�������g�w�ͷǻ�Ԫ����(y��ng)���ʷ��̡���368
9.1.1��Pseudo-Steady-State Hypothesis (PSSH)
�M��(w��n)�B(t��i)���O(sh��)��PSSH������369
9.1.2��If Two Molecules Must Collide, How Can the Rate Law Be First Order
����ɂ�(g��)���ӱ����ײ�����ʹ�����ʷ��̼�(j��)��(sh��)��һ��(j��)����372
9.1.3��Searching for a Mechanism
���ҙC(j��)������373
9.1.4��Chain Reactions
朷���(y��ng)����377
9.2 Enzymatic Reaction Fundamentals
ø����(y��ng)���A(ch��)����377
9.2.1��Enzyme-Substrate Complex
ø-�����(f��)�����378
9.2.2��Mechanisms
�C(j��)������380
9.2.3��Michaelis-Menten Equation
���Ϸ��̡���383
9.2.4��Batch Reactor Calculations for Enzyme Reactions
ø����(y��ng)���gЪ����(y��ng)��Ӌ(j��)�㡡��389
9.3 Inhibition of Enzyme Reactions
ø����(y��ng)�����ơ���391
9.3.1��Competitive Inhibition
��(j��ng)��(zh��ng)�����ơ���392
9.3.2��Uncompetitive Inhibition
����(j��ng)��(zh��ng)�����ơ���394
9.3.3��Noncompetitive Inhibition (Mixed Inhibition)
�Ǹ�(j��ng)��(zh��ng)�����ƣ�������ƣ�����396
9.3.4��Substrate Inhibition
�������ơ���398
9.4 Bioreactors and Biosynthesis
���ﷴ��(y��ng)��������ϳɡ���399
9.4.1��Cell Growth
��(x��)�����L(zh��ng)����403
9.4.2��Rate Laws
���ʷ��̡���404
9.4.3��Stoichiometry
���W(xu��)Ӌ(j��)���P(gu��n)ϵ����407
9.4.4��Mass Balances
���Ϻ��㡡��413
9.4.5��Chemostats
�㻯������418
9.4.6��CSTR Bioreactor Operation
ȫ�츪���ﷴ��(y��ng)����������418
9.4.7��Washout
��(x��)��ϴÓ����419
9.5 And Now… A Word from Our Sponsor—Safety 9 (AWFOS-S9 Process Safety Triangle)
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9.5.1��Levels of the Process Safety Triangle
�^�̰�ȫ�����ε�ˮƽ����422
9.5.2��Application to Process Safety
�^�̰�ȫ�đ�(y��ng)�á���423
9.5.3��Examples of Process Safety Triangle
�^�̰�ȫ�����εİ�������424

��10�� CATALYSIS AND CATALYTIC REACTORS
�߻��ʹ߻�����(y��ng)�� 441
10.1 Catalysts
�߻�������441
10.1.1��Definitions
���x����442
10.1.2��Catalyst Properties
�߻��������|(zh��)����443
10.1.3��Catalytic Gas-Solid Interactions
�����߻�����445
10.1.4��Classification of Catalysts
�߻����ķ����446
10.2 Steps in a Catalytic Reaction
�߻�����(y��ng)���E����447
10.2.1��Mass Transfer Step 1: Diffusion from the Bulk to the External Surface of the Catalyst—An Overview
���|(zh��)���������w����߻��������ĔU(ku��)ɢ——��������450
10.2.2��Mass Transfer Step 2: Internal Diffusion—An Overview
���|(zh��)�ڶ�������(n��i)�U(ku��)ɢ——��������451
10.2.3��Adsorption Isotherms
�����Ȝؾ�����452
10.2.4��Surface Reaction
���淴��(y��ng)����458
10.2.5��Desorption
������460
10.2.6��The Rate-Limiting Step
���ʿ��Ʋ��E����461
10.3 Synthesizing a Rate Law, Mechanism, and Rate-Limiting Step
���ʷ������C(j��)�������ʿ��Ʋ��C�Ϸ�������463
10.3.1��Is the Adsorption of Cumene Rate-Limiting
�����������������ʿ��Ʋ�����466
10.3.2��Is the Surface Reaction Rate-Limiting
���淴��(y��ng)�����ʿ��Ʋ�����470
10.3.3��Is the Desorption of Benzene the Rate-Limiting Step (RLS)
��Ó�������ʿ��Ʋ�����471
10.3.4��Summary of the Cumene Decomposition
���������ֽ⿂�Y(ji��)����473
10.3.5��Reforming Catalysts
�߻�����������474
10.3.6��Rate Laws Derived from the Pseudo-Steady-State Hypothesis (PSSH)
���ڔM��(w��n)�B(t��i)���O(sh��)��PSSH�������ʷ��̡���478
10.3.7��Temperature Dependence of the Rate Law
���ʷ��̵Ĝض�Ч��(y��ng)����479
10.4 Heterogeneous Data Analysis for Reactor Design
����(y��ng)���O(sh��)Ӌ(j��)�ķǾ�����(sh��)��(j��)��������479
10.4.1��Deducing a Rate Law from the Experimental Data
���ڌ�(sh��)�(y��n)��(sh��)��(j��)�ƌ�(d��o)���ʷ��̡���481
10.4.2��Finding a Mechanism Consistent with Experimental Observations
̽���c��(sh��)�(y��n)�F(xi��n)��һ�µęC(j��)������482
10.4.3��Evaluation of the Rate-Law Parameters
���ʷ��̅���(sh��)�u(p��ng)�r(ji��)����484
10.4.4��Reactor Design
����(y��ng)���O(sh��)Ӌ(j��)����486
10.5 Reaction Engineering in Microelectronic Fabrication
΢��������еķ���(y��ng)���̡���490
10.5.1��Overview
��������490
10.5.2��Chemical Vapor Deposition (CVD)
���W(xu��)������e��CVD������490
10.6 Model Discrimination
ģ�ͱ�e����493
10.7 Catalyst Deactivation
�߻���ʧ���496
10.7.1��Types of Catalyst Deactivation
�߻���ʧ�����͡���498
10.7.2��Decay in Packed-Bed Reactors
��䴲����(y��ng)���е�ʧ���505
10.8 Reactors That Can Be Used to Help Offset Catalyst Decay
�a(b��)���߻���ʧ��Ч��(y��ng)�ķ���(y��ng)������507
10.8.1��Temperature-Time Trajectories
�ض�-�r(sh��)�g܉�E����508
10.8.2��Moving-Bed Reactors
�Ƅ�(d��ng)������(y��ng)������510
10.8.3��Straight-Through Transport Reactors (STTR)
ֱͨݔ�ͷ���(y��ng)����STTR������515
10.9 And Now… A Word from Our Sponsor—Safety 10 [AWFOS-S10 Exxon Mobil Torrance Refinery Explosion Involving a Straight-Through Transport Reactor (STTR)]
��ȫ����10——����ɭ�����Ђ�˹ֱͨݔ�ͷ���(y��ng)�����l(f��)�ğ��͏S��ը����519

��11�� NONISOTHERMAL REACTOR DESIGN: THE STEADY-STATE ENERGY BALANCE AND ADIABATIC PFR APPLICATIONS
�ǵȜط���(y��ng)���O(sh��)Ӌ(j��)����(w��n)�B(t��i)��������ͽ^��ƽ��������(y��ng)����(y��ng)�� 541
11.1 Rationale
����ԭ������542
11.2 The Energy Balance
�������㡡��543
11.2.1��First Law of Thermodynamics
�����W(xu��)���ɡ���543
11.2.2��Evaluating the Work Term
�u(p��ng)�r(ji��)�����(xi��ng)����544
11.2.3��Overview of Energy Balances
���������������546
11.3 The User-Friendly Energy Balance Equations
�Ñ��Ѻõ��������㷽�̡���551
11.3.1��Dissecting the Steady-State Molar Flow Rates to Obtain the Heat of Reaction
������(w��n)�B(t��i)Ħ�����ʫ@�÷���(y��ng)��ķ�������551
11.3.2��Dissecting the Enthalpies
�����ʡ���553
11.3.3��Relating ?HRx (T), ?H°Rx (TR), and ?CP
�P(gu��n)“(li��n)?HRx (T)��?H°Rx (TR)��?CP����554
11.4 Adiabatic Operation = 0
�^����� = 0����557
11.4.1��Adiabatic Energy Balance
�^���������㡡��557
11.4.2��Adiabatic Tubular Reactor
�^���ʽ����(y��ng)������558
11.5 Adiabatic Equilibrium Conversion
�^��ƽ���D(zhu��n)���ʡ���566
11.5.1��Equilibrium Conversion
ƽ���D(zhu��n)���ʡ���566
11.6 Reactor Staging with Interstage Cooling or Heating
���м�(j��)�g��s��ӟ�Ķ༉(j��)����(y��ng)������571
11.6.1��Exothermic Reactions
�şᷴ��(y��ng)����571
11.6.2��Endothermic Reactions
���ᷴ��(y��ng)����571
11.7 Optimum Feed Temperature
�M(j��n)�Ϝضȡ���575
11.8 And Now… A Word from Our Sponsor—Safety 11(AWFOS-S11 Acronyms)
��ȫ����11——�¹ʈ�(b��o)���еij�Ҋ�s���~����579

��12�� STEADY-STATE NONISOTHERMAL REACTOR DESIGN:
FLOW REACTORS WITH HEAT EXCHANGE
��(w��n)�B(t��i)�ǵȜط���(y��ng)���O(sh��)Ӌ(j��)�����ГQ�������(d��ng)����(y��ng)�� 591
12.1 Steady-State Tubular Reactor with Heat Exchange
���ГQ��ķ�(w��n)�B(t��i)��ʽ����(y��ng)������592
12.1.1��Deriving the Energy Balance for a PFR
�ƌ�(d��o)ƽ��������(y��ng)�����������㷽�̡���592
12.1.2��Applying the Algorithm to Flow Reactors with Heat Exchange
��(y��ng)���㷨�������ГQ�������(d��ng)����(y��ng)������594
12.2 Balance on the Heat-Transfer Fluid
�Q�����w�������㡡��595
12.2.1��Co-Current Flow
��������595
12.2.2��Countercurrent Flow
��������597
12.3 Examples of the Algorithm for PFR/PBR Design with Heat Effects
���П�Ч��(y��ng)��ƽ����/��䴲����(y��ng)���㷨��������598
12.3.1��Applying the Algorithm to an Exothermic Reaction
��(y��ng)���㷨�����şᷴ��(y��ng)����603
12.3.2��Applying the Algorithm to an Endothermic Reaction
��(y��ng)���㷨�������ᷴ��(y��ng)����610
12.4 CSTR with Heat Effects
���П�Ч��(y��ng)��ȫ�츪��CSTR������619
12.4.1��Heat Added to the Reactor
���뷴��(y��ng)���ğ��� ����620
12.5 Multiple Steady States (MSS)
�ව(w��n)�B(t��i)��MSS������630
12.5.1��Heat-Removed Term R (T)
�����Ƴ��(xi��ng)R (T)����632
12.5.2��Heat-Generated Term G (T)
�����a(ch��n)���(xi��ng)G (T)����633
12.5.3��Ignition-Extinction Curve
�c(di��n)��-Ϩ����������634
12.6 Nonisothermal Multiple Chemical Reactions
�ǵȜ؏�(f��)�Ϸ���(y��ng)����637
12.6.1��Energy Balance for Multiple Reactions in Plug-Flow Reactors
ƽ��������(y��ng)���Џ�(f��)�Ϸ���(y��ng)���������㡡��637
12.6.2��Energy Balance for Multiple Reactions in a CSTR
ȫ�츪����(y��ng)���Џ�(f��)�Ϸ���(y��ng)���������㡡��642
12.6.3��Series Reactions in a CSTR
ȫ�츪����(y��ng)���е��B������(y��ng)����642
12.6.4��Complex Reactions in a PFR
ƽ��������(y��ng)���еď�(f��)�s����(y��ng)����645
12.7 Radial and Axial Temperature Variations in a Tubular Reactor
��ʽ����(y��ng)���еď�����S��ض�׃������652
12.8 And Now… A Word from Our Sponsor—Safety 12(AWFOS-S12 Safety Statistics)
��ȫ����12——��ȫ�y(t��ng)Ӌ(j��)����652
12.8.1 The Process Safety Across the Chemical Engineering Curriculum Web site
�c���W(xu��)�����n�����P(gu��n)���^�̰�ȫ����652
12.8.2 Safety Statistics
��ȫ�y(t��ng)Ӌ(j��)����653
12.8.3 Additional Resources CCPS and SAChE
�����YԴCCPS��SAChE����654

��13�� UNSTEADY-STATE NONISOTHERMAL REACTOR DESIGN
�Ƿ�(w��n)�B(t��i)�ǵȜط���(y��ng)���O(sh��)Ӌ(j��) 681
13.1 The Unsteady-State Energy Balance
�Ƿ�(w��n)�B(t��i)�������㡡��682
13.2 Energy Balance on Batch Reactors (BRs)
�gЪ����(y��ng)�����������㡡��684
13.2.1��Adiabatic Operation of a Batch Reactor
�gЪ����(y��ng)���Ľ^���������686
13.2.2 Case History of a Batch Reactor with Interrupted Isothermal Operation Causing a Runaway Reaction
�Д�Ȝز����a(ch��n)��ʧ�ط���(y��ng)���gЪ����(y��ng)���İ����vʷ����693
13.3 Batch and Semibatch Reactors with a Heat Exchanger
���ГQ�������gЪ�Ͱ��gЪ����(y��ng)������700
13.3.1 Startup of a CSTR
ȫ�츪��CSTR���Ć���(d��ng)����702
13.3.2 Semibatch Operation
���g��������707
13.4 Nonisothermal Multiple Reactions
�ǵȜ؏�(f��)�Ϸ���(y��ng)����711
13.5 And Now... A Word from Our Sponsor—Safety 13(AWFOS-S13 Safety Analysis of the T2 Laboratories Incident)
��ȫ����13——T2��(sh��)�(y��n)���¹ʵİ�ȫ��������723

��14�� MASS TRANSFER LIMITATIONS IN REACTING SYSTEMS
����(y��ng)ϵ�y(t��ng)�Ă��|(zh��)���� 739
14.1 Diffusion Fundamentals
�U(ku��)ɢ���A(ch��)����740
14.1.1 Definitions
���x����741
14.1.2 Molar Flux WA
Ħ��ͨ��WA����742
14.1.3 Fick’s First Law
�M(f��i)�˶��ɡ���743
14.2 Binary Diffusion
��Ԫ�U(ku��)ɢ����744
14.2.1 Evaluating the Molar Flux
�u(p��ng)�r(ji��)Ħ��ͨ������744
14.2.2 Diffusion and Convective Transport
�U(ku��)ɢ�͌�(du��)��ݔ�\(y��n)����744
14.2.3 Boundary Conditions
߅��l������746
14.2.4 Temperature and Pressure Dependence of DAB
DAB�Ĝض�������Ч��(y��ng)����746
14.3 Modeling Diffusion with Chemical Reaction
���л��W(xu��)����(y��ng)�ĔU(ku��)ɢģ�͡���748
14.3.1��Diffusion through a Stagnant Film to a Particle
ͨ�^�w�������oֹ��Ĥ�ĔU(ku��)ɢ����748
14.4 The Mass Transfer Coefficient
���|(zh��)ϵ��(sh��)����750
14.5 Mass Transfer to a Single Particle
���һ�w���Ă��|(zh��)����752
14.5.1��First-Order Rate Laws
һ��(j��)���ʷ��̡���752
14.5.2��Limiting Regimes
���Ʒ�ʽ����754
14.6 The Shrinking Core Model
�s��ģ�͡���758
14.6.1��Dust Explosions, Particle Dissolution, and Catalyst Regeneration
�ۉm��ը���w���ܽ⼰�߻�����������758
14.7 Mass Transfer-Limited Reactions in Packed Beds
��䴲�еĂ��|(zh��)���޷���(y��ng)����763
14.8 Robert the Worrier
�n�]��Robert����766
14.9 What If …? (Parameter Sensitivity)
���……��(hu��)�l(f��)��ʲô������(sh��)�����ԣ�����770
14.10 And Now… A Word from Our Sponsor—Safety 14(AWFOS-S14 Sugar Dust Explosion)
��ȫ����14——�Ƿۉm��ը����778

��15�� DIFFUSION AND REACTION
�U(ku��)ɢ�ͷ���(y��ng) 791
15.1 Diffusion and Reactions in Homogeneous Systems
�����wϵ�еĔU(ku��)ɢ�ͷ���(y��ng)����792
15.2 Diffusion and Reactions in Spherical Catalyst Pellets
���δ߻����w���еĔU(ku��)ɢ�ͷ���(y��ng)����793
15.2.1��Effective Diffusivity
��Ч�U(ku��)ɢϵ��(sh��)����793
15.2.2��Derivation of the Differential Equation Describing Diffusion and Reaction in a Single Spherical Catalyst Pellet
�����΂�(g��)���δ߻����w����(n��i)�U(ku��)ɢ�ͷ���(y��ng)��΢�ַ��̡���795
15.2.3��Writing the Diffusion with the Catalytic Reaction Equation in Dimensionless Form
�ԟo���V��ʽ���_(d��)�߻�����(y��ng)���̵ĔU(ku��)ɢ����798
15.2.4��Solution to the Differential Equation for a First-Order Reaction
һ��(j��)����(y��ng)΢�ַ��̵Ľ⡡��801
15.3 The Internal Effectiveness Factor
��(n��i)��Ч�����ӡ���802
15.3.1��Isothermal First-Order Catalytic Reactions
�Ȝ�һ��(j��)�߻�����(y��ng)����802
15.3.2��Effectiveness Factors with Volume Change with Reaction
�����w�e׃���Ļ��W(xu��)����(y��ng)��Ч�����ӡ���806
15.3.3��Internal-Diffusion-Limited Reactions Other Than First Order
��һ��(j��)����(y��ng)�ă�(n��i)�U(ku��)ɢ���ơ���806
15.3.4��Weisz-Prater Criterion for Internal Diffusion Limitations
��(n��i)�U(ku��)ɢ���Ƶ�Weisz-Prater��(zh��n)�t����807
15.4 Falsified Kinetics
�΄�(d��ng)���W(xu��)����809
15.5 Overall Effectiveness Factor
��Ч�����ӡ���811
15.6 Estimation of Diffusion- and Reaction-Limited Regimes
�U(ku��)ɢ-����(y��ng)���ƙC(j��)����������816
15.6.1��Mears Criterion for External Diffusion Limitations
��U(ku��)ɢ���Ƶ�Mears��(zh��n)�t����816
15.7 Mass Transfer and Reaction in a Packed Bed
��䴲�еĂ��|(zh��)�ͷ���(y��ng)����817
15.8 Determination of Limiting Situations from Reaction-Rate Data
���ڷ���(y��ng)���ʔ�(sh��)��(j��)�Д�������r����823
15.9 Multiphase Reactors in the Professional Reference Shelf
���I(y��)�������еĶ��෴��(y��ng)������824
15.9.1��Slurry Reactors
�{�B(t��i)������(y��ng)������825
15.9.2��Trickle Bed Reactors
����������(y��ng)������826
15.10 Fluidized Bed Reactors
����������(y��ng)������826
15.11 Chemical Vapor Deposition (CVD)
���W(xu��)������e��CVD������826
15.12 And Now… A Word from Our Sponsor—Safety 15(AWFOS-S15 Critical Thinking Questions Applied to Safety)
��ȫ����15——��ȫ�е������Ԇ��}����826

��16�� RESIDENCE TIME DISTRIBUTIONS OF CHEMICAL REACTORS
���W(xu��)����(y��ng)����ͣ���r(sh��)�g�ֲ� 843
16.1 General Considerations
���t����844
16.1.1��Residence Time Distribution (RTD) Function
ͣ���r(sh��)�g�ֲ���RTD������(sh��)����845
16.2 Measurement of the RTD
RTD�y(c��)������846
16.2.1��Pulse Input Experiment
�}�_ע�댍(sh��)�(y��n)����847
16.2.2��Step Tracer Experiment
�A�Sע�댍(sh��)�(y��n)����852
16.3 Characteristics of the RTD
RTD�����|(zh��)����853
16.3.1��Integral Relationships
�e���P(gu��n)ϵ����853
16.3.2��Mean Residence Time
ƽ��ͣ���r(sh��)�g����854
16.3.3��Other Moments of the RTD
RTD�������A�ع�Ӌ(j��)����855
16.3.4��Normalized RTD Function E(?)
�wһ����RTD����(sh��)E(?)����859
16.3.5��Internal-Age Distribution I(?)
��(n��i)�����g�ֲ�I(?)����859
16.4 RTD in Ideal Reactors
���뷴��(y��ng)����RTD����860
16.4.1��RTDs in Batch and Plug-Flow Reactors
�gЪ��ƽ��������(y��ng)���е�RTD����860
16.4.2��Single-CSTR RTD
�΂�(g��)CSTR��RTD����861
16.4.3��Laminar-Flow Reactor (LFR)
��������(y��ng)����LFR������863
16.5 PFR/CSTR Series RTD
ƽ����/ȫ�츪����(y��ng)����“(li��n)��RTD����866
16.6 Diagnostics and Troubleshooting
�\����{(di��o)ԇ����869
16.6.1��General Comments
һ�����u(p��ng)�r(ji��)����869
16.6.2��Simple Diagnostics and Troubleshooting Using the RTD for Ideal Reactors
ʹ��RTD��(du��)���뷴��(y��ng)���M(j��n)�к�(ji��n)�ε��\����{(di��o)ԇ����870
16.7 And Now… A Word from Our Sponsor—Safety 16 (AWFOS-S16 Critical Thinking Actions)
��ȫ����16——������˼�S�Ĉ�(zh��)�С���876

��17�� PREDICTING CONVERSION DIRECTLY FROM THE RESIDENCE TIME DISTRIBUTION
��RTDֱ���A(y��)�y(c��)�D(zhu��n)���� 887
17.1 Modeling Nonideal Reactors Using the RTD
����RTD���������뷴��(y��ng)��ģ�͡���888
17.1.1��Modeling and Mixing Overview
ģ�ͺͻ�ϸ�������888
17.1.2��Mixing
��ϡ���888
17.2 Zero Adjustable Parameter Models
�o���{(di��o)����(sh��)ģ�͡���890
17.2.1��Segregation Model
�x����ģ�͡���890
17.2.2��Maximum Mixedness Model
���ģ�͡���900
17.3 Using Software Packages Such as Polymath to Find Maximum Mixedness Conversion
ʹ��Polymathܛ����Ӌ(j��)����ģ�͵��D(zhu��n)���ʡ���907
17.3.1��Comparing Segregation and Maximum Mixedness Predictions
���^�x����ģ�ͺͻ��ģ�͡���909
17.4 Tanks-in-Series One Parameter Model n
�ส��“(li��n)�΅���(sh��)ģ��n����910
17.4.1��Find the Number of T-I-S to Model the Real Reactor
�öส��“(li��n)��(g��)��(sh��)������(sh��)�H����(y��ng)��ģ�͡���911
17.4.2��Calculating Conversion for the T-I-S Model
Ӌ(j��)��ส��“(li��n)ģ�͵��D(zhu��n)���ʡ���912
17.4.3��Tanks-in-Series versus Segregation for a First-Order Reaction
��(du��)��һ��(j��)����(y��ng)�Ķส��“(li��n)���x����ģ�͡���912
17.5 RTD and Multiple Reactions
RTD�͏�(f��)�Ϸ���(y��ng)����912
17.5.1��Segregation Model
�x����ģ�͡���912
17.5.2��Maximum Mixedness
��ϡ���913
17.6 And Now… A Word from Our Sponsor—Safety 17 (AWFOS-S17 Brief Case History on an Air Preheater)
��ȫ����17——�՚��A(y��)�����ĺ�(ji��n)Ҫ�����vʷ����917

��18�� MODELS FOR NONIDEAL REACTORS
�����뷴��(y��ng)��ģ�� 929
18.1 Some Guidelines for Developing Models
��ģ��Ҏ(gu��)�t����930
18.1.1��One-Parameter Models
�΅���(sh��)ģ�͡���932
18.1.2��Two-Parameter Models
�p����(sh��)ģ�͡���932
18.2 Flow and Axial Dispersion of Inert Tracers in Isothermal Reactors
�Ȝط���(y��ng)���ж���ʾۙ��������(d��ng)���S��U(ku��)ɢ����933
18.2.1��Balances on Inert Tracers
����ʾۙ�����Ϻ��㡡��933
18.2.2��Boundary Conditions for Flow and Reaction
����(d��ng)�ͷ���(y��ng)��߅��l������935
18.3 Flow, Reaction, and Axial Dispersion
����(d��ng)������(y��ng)���S��U(ku��)ɢ����937
18.3.1��Balance Equations
���㷽�̡���937
18.3.2��Solution for a Closed-Closed System
���]ϵ�y(t��ng)�Ľ⡡��938
18.4 Flow, Reaction, and Axial Dispersion in Isothermal Laminar-Flow Reactors and Finding Meno
�Ȝ،�������(y��ng)����(n��i)������(d��ng)������(y��ng)���S��U(ku��)ɢ������ Meno����941
18.4.1��Determine the Dispersion Coefficient (Da) and the Péclet Number (Per)
�_���U(ku��)ɢϵ��(sh��)��Da��������R��(sh��)��Per������941
18.4.2��Correlations for Da
Da���P(gu��n)“(li��n)ʽ����944
18.4.3��Dispersion in Packed Beds
��䴲��(n��i)�ĔU(ku��)ɢ����944
18.4.4��Experimental Determination of Da
��(sh��)�(y��n)�����y(c��)��Da����944
18.5 Tanks-in-Series Model versus Dispersion Model
���^�ส��“(li��n)ģ�ͺ͔U(ku��)ɢģ�͡���951
18.6 Numerical Solutions to Flows with Dispersion and Reaction
���ДU(ku��)ɢ�ͷ���(y��ng)������(d��ng)�^�̵Ĕ�(sh��)ֵ�⡡��952
18.7 Nonisothermal Flow with Radial and Axial Variations in a Tubular Reactor
��ʽ����(y��ng)���Ў��Џ������S��׃���ķǵȜ�����(d��ng)����956
18.7.1��Molar Flux
Ħ��ͨ������956
18.7.2��Energy Flux
����ͨ������958
18.7.3��Energy Balance
�������㡡��958
18.8 Two-Parameter Models—Modeling Real Reactors with Combinations of Ideal Reactors
�p����(sh��)ģ��——�������뷴��(y��ng)���Č�(sh��)�H����(y��ng)��ģ�͡���964
18.8.1��Real CSTR Modeled Using Bypassing and Dead Space
���]��·�����^(q��)�Č�(sh��)�H�B�m(x��)���踪����(y��ng)��ģ�͡���965
18.8.2��Real CSTR Modeled as Two CSTRs with Interchange
���н��Q�ăɂ�(g��)CSTRģ�M��(sh��)�H�B�m(x��)���踪����(y��ng)��ģ�͡���968
18.8.3��Other Models of Nonideal Reactors Using CSTRs and PFRs
ʹ��CSTR��PFRģ�M��(sh��)�H����(y��ng)����������������972
18.8.4��Applications to Pharmacokinetic Modeling
��ˎ�^��ģ�ͻ��đ�(y��ng)�á���973
18.9 And Now…A Word from Our Sponsor—Safety 18 [AWFOS-S18 An Algorithm for Management of Change (MoC)]
��ȫ����18——׃�������㷨��MoC������974

APPENDIX
��� 991
���A NUMERICAL TECHNIQUES
��(sh��)ֵ���g(sh��)����991
A.1 Useful Integrals in Chemical Reactor Design
���W(xu��)����(y��ng)���O(sh��)Ӌ(j��)�еķe�ֹ�ʽ����991
A.2 Equal-Area Graphical Differentiation
����e�Dʾ΢�֡���992
A.3 Solutions to Differential Equations
΢�ַ��̵Ľ⡡��994
A.4 Numerical Evaluation of Integrals
�e�ֵĔ�(sh��)ֵ�u(p��ng)�r(ji��)����995
A.5 Semi-Log Graphs
�댦(du��)��(sh��)�D����997
A.6 Software Packages
ܛ��������997
���B IDEAL GAS CONSTANT AND CONVERSION FACTORS
������w����(sh��)���D(zhu��n)�����ӡ���998
���C THERMODYNAMIC RELATIONSHIPS INVOLVING THE EQUILIBRIUM CONSTANT
�漰ƽ�ⳣ��(sh��)�ğ����W(xu��)�P(gu��n)ϵ����1001
���D SOFTWARE PACKAGES
ܛ��������1007
D.1 Polymath����1007
D.2 Wolfram����1008
D.3 Python����1009
D.4 MATLAB����1009
D.5 Excel����1009
D.6 COMSOL����1010
D.7 Aspen����1011
D.8 Visual Encyclopedia of Equipment—Reactors Section
�O(sh��)��Ŀ�ҕ���ٿ�ȫ��——����(y��ng)�����֡���1011
D.9 Reactor Lab����1011
���E RATE-LAW DATA
����(y��ng)���ʷ��̔�(sh��)��(j��)����1012
���F NOMENCLATURE
��̖(h��o)������1013
���G OPEN-ENDED PROBLEMS
�_���Ԇ��}����1016
G.1 Chem-E Car����1016
G.2 Effective Lubricant Design
��Ч�������O(sh��)Ӌ(j��)����1016
G.3 Peach Bottom Nuclear Reactor
�һ��Ⱥ˷���(y��ng)������1016
G.4 Underground Wet Oxidation
����ʽ��������1017
G.5 Hydrodesulfurization Reactor Design
�Ӛ�Ó�򷴑�(y��ng)���O(sh��)Ӌ(j��)����1017
G.6 Continuous Bioprocessing
�B�m(x��)�����^�̡���1017
G.7 Methanol Synthesis
�״��ϳɡ���1017
G.8 Cajun Seafood Gumbo
Cajun���r�✫����1017
G.9 Alcohol Metabolism
�ƾ����x����1018
G.10 Methanol Poisoning
�״��ж�����1019
G.11 Safety
��ȫ����1019
���H USE OF COMPUTATIONAL CHEMISTRY SOFTWARE PACKAGES
Ӌ(j��)�㻯�W(xu��)ܛ������ʹ�á���1020
H.1 Computational Chemical Reaction Engineering
Ӌ(j��)�㻯�W(xu��)����(y��ng)���̡���1020
���I HOW TO USE THE CRE WEB RESOURCES
���ʹ��CRE�W(w��ng)�j(lu��)�YԴ����1021

INDEX
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