Name: کتاب Chemical Engineering Principles and Applications
Rating: 5.0 (4 reviews)
ISBN: 9783031278785

توضیحاتی در مورد کتاب Chemical Engineering Principles and Applications

نام کتاب : Chemical Engineering Principles and Applications
عنوان ترجمه شده به فارسی : اصول و کاربردهای مهندسی شیمی
سری :
نویسندگان : Nuggenhalli S. Nandagopal
ناشر : Springer
سال نشر : 2023
تعداد صفحات : [510]
ISBN (شابک) : 9783031278785 , 9783031278792
زبان کتاب : English
فرمت کتاب : pdf
حجم کتاب : 18 Mb

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فهرست مطالب :

Preface Contents Chapter 1: Mass and Energy Balances 1.1 Introduction 1.2 Mass Balances 1.2.1 Fundamental Mass Balance Equation 1.2.2 Mass Balances for Steady-State, Non-reactive Systems 1.2.3 Mass Balances for Steady-State, Reactive Systems 1.2.3.1 Limiting and Excess Reactants 1.2.3.2 Multiple Reactions - Conversion, Extent of Reaction, Selectivity, and Yield 1.2.4 Mass Balances for Systems with Recycle 1.2.5 Mass Balances for Systems with Bypass 1.2.6 Mass Balances for Non-reactive Unsteady-State Systems 1.3 Energy Balances 1.3.1 Energy Balance for Closed Systems - First Law of Thermodynamics 1.3.2 Fundamental Energy Balance Equation 1.3.2.1 Steady-State Energy Balance 1.3.3 Energy Balances for Reactive Processes 1.3.3.1 Definitions of Thermochemical Data 1.3.3.2 Hess´s Law 1.3.3.3 General Procedure for Energy Balances for Reactive Processes 1.4 Mass and Energy Balances for Combustion Reactions 1.4.1 Introduction 1.4.2 Heating Value of Fuels 1.4.3 Stoichiometry of Combustion Reactions, Theoretical and Excess Air 1.4.4 Analysis of Combustion Products - Flue Gas Analysis 1.4.5 Dew Point of Combustion Products 1.4.6 Combustion of Coal - Use of Gravimetric Analysis of Coal Practice Problems Practice Problem 1.1 Practice Problem 1.2 Practice Problem 1.3 Practice Problem 1.4 Practice Problem 1.5 Practice Problem 1.6 Practice Problem 1.7 Practice Problem 1.8 Practice Problem 1.9 Practice Problem 1.10 Solutions to Practice Problems Practice Problem 1.1 Solution Practice Problem 1.2 Solution Practice Problem 1.3 Solution Practice Problem 1.4 Solution Practice Problem 1.5 Solution Practice Problem 1.6 Solution Practice Problem 1.7 Solution Practice Problem 1.8 Solution Practice Problem 1.9 Solution Practice Problem 1.10 Solution References Chapter 2: Chemical Thermodynamics 2.1 Introduction 2.2 Equations of State 2.2.1 Ideal Gas Equation 2.2.2 Real Gas Equations of State 2.2.2.1 Van Der Waals Equation 2.2.2.2 Redlich-Kwong Equation 2.2.3 Generalized Compressibility Chart - Compressibility Factor 2.2.4 Ideal Gas Mixtures 2.2.4.1 Definitions and Laws for Ideal Gas Mixtures 2.3 Thermodynamic Property Tables 2.3.1 Steam Tables 2.3.1.1 Saturated Steam Tables 2.3.1.2 Superheated Steam Tables 2.3.2 Phase Diagram for Water 2.3.3 Properties of Liquid-Vapor Mixtures 2.3.4 Properties of Compressed Liquid 2.4 Thermodynamic Charts 2.4.1 Mollier Diagram 2.4.2 Pressure-Enthalpy (P-h) Phase Diagram 2.5 Vapor-Liquid Equilibrium (VLE) 2.5.1 VLE Relationships for Ideal Solutions 2.5.1.1 Raoult´s Law 2.5.1.2 Henry´s Law 2.5.2 VLE Relationships for Non-ideal Systems 2.5.3 Distribution Coefficients for VLE Involving Multicomponent Systems 2.5.4 Generating VLE Curve Using Relative Volatility Data 2.5.5 Bubble Point and Dew Point Calculations 2.5.6 Azeotropic Mixtures 2.6 Gibbs Free Energy Change and Phase Transitions 2.6.1 Clausius-Clapeyron Equation for Phase Transition 2.7 Chemical Equilibrium 2.7.1 Characteristics of Chemical Equilibrium 2.7.2 Position of Equilibrium - Equilibrium Constant 2.7.3 Equilibrium Calculations 2.7.3.1 Calculation of the Equilibrium Constant, KC, and Unknown Concentrations 2.7.3.2 Equilibrium Constant Based on Partial Pressures KP, and the Relationship Between KP and KC 2.7.4 Disruptions to Equilibrium State - Le Chatelier´s Principle 2.7.4.1 Responses to Changes in Concentration of a Species 2.7.4.2 Responses to Changes in Temperature of the System 2.7.4.3 Responses to Changes in Pressure of the System 2.7.5 Gibbs Free Energy Change and Chemical Equilibrium 2.7.6 Temperature Dependence of Equilibrium Constant - The Van´t-Hoff Equation Practice Problems Practice Problem 2.1 Practice Problem 2.2 Practice Problem 2.3 Practice Problem 2.4 Practice Problem 2.5 Practice Problem 2.6 Practice Problem 2.7 Practice Problem 2.8 Practice Problem 2.9 Practice Problem 2.10 Practice Problem 2.11 Practice Problem 2.12 Practice Problem 2.13 Practice Problem 2.14 Practice Problem 2.15 Practice Problem 2.16 Practice Problem 2.17 Practice Problem 2.18 Practice Problem 2.19 Solutions to Practice Problems Practice Problem 2.1 Solution Practice Problem 2.2 Solution Practice Problem 2.3 Solution Practice Problem 2.4 Solution Practice Problem 2.5 Solution Practice Problem 2.6 Solution Practice Problem 2.7 Solution Practice Problem 2.8 Solution Practice Problem 2.9 Solution Practice Problem 2.10 Solution Practice Problem 2.11 Solution Practice Problem 2.12 Solution Practice Problem 2.13 Solution Practice Problem 2.14 Solution Practice Problem 2.15 Solution Practice Problem 2.16 Solution Practice Problem 2.17 Solution Practice Problem 2.18 Solution Practice Problem 2.19 Solution References Chapter 3: Fluid Mechanics and Momentum Transfer 3.1 Role of Fluid Mechanics in Chemical Engineering 3.2 Fluid Properties and Fundamentals 3.3 Fluid Statics and Manometers 3.3.1 Static Pressure and Pressure Head 3.3.2 Differential Manometers 3.4 Fluid Dynamics 3.4.1 Conservation of Mass - Continuity Equation 3.4.2 Laminar Flow and Turbulent Flow Through Pipes 3.4.3 Reynolds Number 3.4.4 Friction Head Loss and Pressure Drop for Fluid Flow in Pipes 3.5 Calculating the Friction Head Loss for Pipe Flow 3.5.1 Fanning Friction Factor 3.5.2 Equations for Calculating Friction Factors 3.5.3 Hagen-Poiseuille Equation 3.6 Flow Through Non-circular Cross Sections 3.7 Flow Through Pipe Networks 3.8 Head Loss Through Fittings and Valves - Minor Losses 3.8.1 Velocity Head Method 3.8.2 Equivalent Length Method 3.8.3 Other, Miscellaneous Minor Losses - Pipe Entrance, Pipe Exit, Change in Pipe Cross Section 3.9 The Mechanical Energy Equation 3.9.1 Bernoulli´s Equation 3.9.2 Pump Power Equation 3.9.3 Pump Performance Parameters 3.10 Flow Measurement 3.10.1 Introduction 3.10.2 Pitot Tube 3.10.3 Orifice Meter 3.10.4 Venturi Meter 3.10.5 Orifice Meter and Venturi Meter Comparison 3.10.5.1 Calculation of Permanent Pressure Loss in an Orifice Meter 3.11 Flow Through Packed Beds 3.11.1 Calculation of Pressure Drop in Packed Columns 3.11.2 Operation of Packed Columns - Generalized Pressure Drop Correlations and Flooding 3.11.2.1 Generalized Pressure Drop Correlations 3.11.2.2 Flooding in Packed Columns 3.12 Fluidized Beds 3.13 Compressible Flow 3.13.1 Introduction 3.13.2 Continuity Equation for Compressible Flow 3.13.3 Mach Number and Its Significance in Compressible Flow 3.13.4 Isentropic Gas Flow 3.13.5 Application of the Steady Flow Energy Equation for Isentropic Flows 3.13.6 Stagnation - Static Relationships 3.13.7 Isentropic Flow with Area Changes 3.13.8 Adiabatic Compressible Flow with Friction Loss Practice Problems Practice Problem 3.1 Practice Problem 3.2 Practice Problem 3.3 Practice Problem 3.4 Practice Problem 3.5 Practice Problem 3.6 Practice Problem 3.7 Practice Problem 3.8 Practice Problem 3.9 Practice Problem 3.10 Practice Problem 3.11 Practice Problem 3.12 Solutions to Practice Problems Practice Problem 3.1 Solution Practice Problem 3.2 Solution Practice Problem 3.3 Solution Practice Problem 3.4 Solution Practice Problem 3.5 Solution Practice Problem 3.6 Solution Practice Problem 3.7 Solution Practice Problem 3.8 Solution Practice Problem 3.9 Solution Practice Problem 3.10 Solution Practice Problem 3.11 Solution Practice Problem 3.12 Solution References Chapter 4: Heat Transfer 4.1 Introduction 4.1.1 General Equation for Modeling of Heat Transfer 4.1.2 Heat Transfer Modes 4.2 Conduction Heat Transfer 4.2.1 Conduction Through a Rectangular Slab 4.2.1.1 Multilayer Conduction 4.2.2 Conduction Through a Cylindrical Wall 4.2.3 Conduction Through a Spherical Wall 4.3 Convection Heat Transfer 4.3.1 Convection Heat Transfer Resistance 4.3.2 Dimensionless Parameters Used in Heat Transfer 4.3.3 Correlations Used in Calculating Convection Heat Transfer Coefficients 4.3.4 Typical Range of Convection Heat Transfer Coefficients 4.3.5 Overall Heat Transfer Coefficients in Conduction-Convection Systems 4.3.6 Order of Magnitude Analysis to Determine the Value of Overall Heat Transfer Coefficients 4.4 Heat Exchangers 4.4.1 Heat Balance 4.4.2 Log Mean Temperature Difference (LMTD) 4.4.3 Overall Heat Transfer Coefficient for Heat Exchangers 4.4.4 Heat Exchanger Design Equation 4.4.5 LMTD Correction Factors 4.4.6 Heat Exchanger Effectiveness 4.4.7 Effectiveness-NTU Method 4.5 Radiation 4.5.1 Stefan-Boltzmann´s Law of Thermal Radiation 4.5.2 Non-Ideal Radiators - Gray Bodies 4.5.3 Absorptivity, Transmissivity, and Reflectivity 4.5.4 Radiation View Factor 4.5.5 View Factor Relationships 4.5.6 Calculation of Net Radiation Heat Transfer 4.5.7 Radiation Heat Transfer from a Small Object to an Enclosure, Both Being Gray Bodies 4.5.8 Correction for Thermocouple Readings Practice Problems Practice Problem 4.1 Practice Problem 4.2 Practice Problem 4.3 Practice Problem 4.4 Practice Problem 4.5 Solutions to Practice Problems Practice Problem 4.1 Solution Practice Problem 4.2 Solution Practice Problem 4.3 Solution Practice Problem 4.4 Solution Practice Problem 4.5 Solution References Chapter 5: Mass Transfer 5.1 Introduction 5.2 Molecular Diffusion 5.3 Mass Transfer Coefficients and Interphase Mass Transfer 5.3.1 Interphase Mass Transfer 5.4 Gas Absorption and Stripping 5.4.1 Process Design of Absorption Columns 5.4.1.1 Height of Packing Required, Height of a Transfer Unit (HTU), and Number of Transfer Units (NTU) for Gas Absorption Col... 5.5 Distillation 5.5.1 Batch Distillation 5.5.2 Continuous Distillation 5.5.2.1 McCabe-Thiele Method for Determining Theoretical Stages 5.5.2.2 q Line and Feed Condition 5.5.2.3 Reflux Ratio Range and Optimum Reflux Ratio 5.5.2.4 Construction of McCabe-Thiele Diagram 5.5.2.5 Determining Minimum Number of Theoretical Stages Using Fenske Equation 5.6 Psychrometrics and Psychrometric Chart 5.6.1 Moist Air Properties and Definitions 5.6.2 Finding Moist Air Properties from Psychrometric Chart 5.7 Cooling Towers 5.8 Drying 5.8.1 Drying Mechanism and Rate of Drying 5.8.1.1 Determining the Time Required for Drying 5.8.2 Adiabatic Drying and Adiabatic Saturation Process 5.9 Liquid-Liquid Extraction 5.9.1 Ternary Phase Diagrams 5.9.2 Lever Rule 5.9.3 Multistage Extractions 5.9.3.1 Finding the Number of Transfer Units Required in Counterflow Multistage Extraction 5.9.3.2 Finding the Number of Theoretical Stages Required Using Extraction Factor and Distribution Coefficient 5.10 Leaching 5.10.1 Batch Leaching Process 5.10.2 Single-Stage Continuous Counterflow Leaching Process 5.10.3 Multistage Continuous Counterflow Leaching 5.10.4 Determining Number of Stages Required Using the R-Factor 5.11 Adsorption Process 5.11.1 Adsorption Equilibrium 5.11.2 Continuous Multistage Counterflow Adsorption 5.12 Crystallization 5.12.1 Crystallization Process Calculations 5.13 Evaporation 5.13.1 Single-Effect Evaporator 5.13.2 Multiple-Effect Evaporator Practice Problems Practice Problem 5.1 Practice Problem 5.2 Practice Problem 5.3 Practice Problem 5.4 Practice Problem 5.5 Practice Problem 5.6 Practice Problem 5.7 Practice Problem 5.8 Practice Problem 5.9 Solutions to Practice Problems Practice Problem 5.1 Solution Practice Problem 5.2 Solution Practice Problem 5.3 Solution Practice Problem 5.4 Solution Practice Problem 5.5 Solution Practice Problem 5.6 Solution Practice Problem 5.7 Solution Practice Problem 5.8 Solution Practice Problem 5.9 Solution References Chapter 6: Chemical Reaction Engineering and Kinetics 6.1 Introduction 6.2 Key Definitions in Chemical Reaction Engineering 6.3 Arrhenius Equation - Effect of Temperature on the Rate Constant 6.4 Constant Volume and Variable Volume Systems 6.5 List of Useful Integrals in Reactor Design 6.6 Reactor Types, Design Equations, and Applications 6.6.1 Batch Reactor 6.6.1.1 Design (or Performance) Equation for a Batch Reactor 6.6.2 Mixed Flow Reactor 6.6.2.1 Design Equation for a Mixed Flow Reactor 6.6.3 Plug Flow Reactor 6.6.3.1 Design Equation for Plug Flow Reactor 6.6.4 Comparison of Volumes of Mixed Flow Reactor and Plug Flow Reactor 6.6.5 CSTRs in Series Practice Problems Practice Problem 6.1 Practice Problem 6.2 Practice Problem 6.3 Practice Problem 6.4 Practice Problem 6.5 Practice Problem 6.6 Solutions to Practice Problems Practice Problem 6.1 Solution Practice Problem 6.2 Solution Practice Problem 6.3 Solution Practice Problem 6.4 Solution Practice Problem 6.5 Solution Practice Problem 6.6 Solution References Chapter 7: Transport Phenomenon 7.1 Introduction 7.2 Mass Transfer Correlations 7.3 Analogies Between Momentum, Heat, and Mass Transfer 7.3.1 Stanton Number for Heat Transfer 7.3.2 Colburn Factor for Heat Transfer 7.3.3 Stanton Number for Mass Transfer 7.3.4 Colburn Factor for Mass Transfer 7.3.5 Chilton-Colburn Analogy Between Momentum, Heat, and Mass Transfer References Index

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