Details

Subject(s)

• Separation (Technology)—Textbooks [Browse]

Related name

• EBSCOhost [Browse]

Author

• Henley, Ernest J. [Browse]
• Roper, D. Keith [Browse]

Bibliographic references

Includes bibliographical references and index.

Reproduction note

Electronic reproduction. Ipswich, MA Available via World Wide Web.

Source of description

Online resource; title from digital title page (viewed on June 28, 2018).

Contents

• Cover
• Conversion Factors
• Title Page
• Copyright
• Contents
• About the Authors
• Preface to the Fourth Edition
• General Nomenclature
• Dimensions and Units
• Chapter 1 Separation Processes
• 1.0 Instructional Objectives
• 1.1 Industrial Chemical Processes
• 1.2 Basic Separation Techniques
• 1.3 Separations by Phase Creation
• 1.4 Separations by Phase Addition
• 1.5 Separations by Barrier
• 1.6 Separations by an Applied External Field or Gradient
• 1.7 Brief Comparison of Common Separation Operations
• 1.8 Separation Processes, Product Purity, Component Recovery, and Separation Sequences
• 1.8.1 Purity and Composition Designations
• 1.8.2 Alternative Separation Sequences
• References
• Study Questions
• Exercises
• Chapter 2 Thermodynamics of Separation Operations
• 2.0 Instructional Objectives
• 2.1 Phase Equilibria
• 2.1.1 Fugacities and Activity Coefficients
• 2.1.2 Definitions of K-Values
• 2.1.3 Rigorous K-Value Formulations
• 2.2 Ideal-Gas, Ideal-Liquid-Solution Model
• 2.3 Graphical Representation of Thermodynamic Properties
• 2.4 Nonideal Thermodynamic Property Models
• 2.4.1 Reference State (Datum) for Enthalpy
• 2.5 P-v-T Equation-of-State (EOS) Models
• 2.5.1 The Redlich-Kwong (RK) Model
• 2.5.2 The Soave-Redlich-Kwong (SRK) Model
• 2.5.3 The Peng-Robinson (PR) Model
• 2.5.4 Derived Thermodynamic Properties from EOS Models
• 2.6 Highly Nonideal Liquid Solutions
• 2.7 Gibbs Excess Free-Energy (gE) Models
• 2.7.1 The Local-Composition Concept and the Wilson Model
• 2.7.2 The NRTL Model
• 2.7.3 The UNIQUAC Model
• 2.7.4 Excess Thermodynamic Functions
• 2.8 Predictive Models
• 2.8.1 The UNIFAC Model
• 2.8.2 The Predictive Soave-Redlich-Kwong (PSRK) Model
• 2.8.3 Predictive Peng-Robinson UNIFAC Models
• 2.9 Electrolyte Solution Models
• 2.10 Polymer Solution Models
• 2.11 K-Value Methods in Process Simulators
• 2.11.1 Selecting an Appropriate Model
• 2.12 Exergy and Second-Law Analysis
• Summary
• Chapter 3 Mass Transfer and Diffusion
• 3.0 Instructional Objectives
• 3.1 Steady-State, Ordinary Molecular Diffusion
• 3.1.1 Fick's Law of Diffusion
• 3.1.2 Species Velocities in Diffusion
• 3.1.3 Equimolar Counter Diffusion (EMD)
• 3.1.4 Unimolecular Diffusion (UMD)
• 3.2 Diffusion Coefficients (Diffusivities)
• 3.2.1 Diffusivity in Gas Mixtures
• 3.2.2 Diffusivity in Nonelectrolyte Liquid Mixtures
• 3.2.3 Diffusivities of Electrolytes
• 3.2.4 Diffusivity in Solids
• 3.3 Steady-State and Unsteady-State Mass Transfer Through Stationary Media
• 3.3.1 Steady-State Diffusion
• 3.3.2 Unsteady-State Diffusion
• 3.3.3 Diffusion in a Semi-infinite Medium
• 3.4 Mass Transfer in Laminar Flow
• 3.4.1 Falling Laminar, Liquid Film
• 3.4.2 Mass-Transfer Coefficients

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ISBN

• 9781119141303 ((electronic book))
• 1119141303 ((electronic book))
• 9781119141297 ((electronic book))
• 111914129X ((electronic book))

LCCN

2015022980

OCLC

910936407

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