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Informationen zum Autor LOUIS THEODORE, ENG SCD, is a professor in the Chemical Engineering Department at Manhattan College in Bronx, New York, and the recipient of the prestigious Ripperton Award from the International Air and Waste Management Association's and the American Society for Engineering Education's AT&T Foundation Award for "excellence in the instruction of engineering students." Professor Theodore is a contributor to Perry's Chemical Engineers' Handbook, the coeditor of Handbook of Chemical and Environmental Engineering Calculations (Wiley), the coauthor of Thermodynamics for the Practicing Engineer (Wiley), and the author of Fluid Flow for the Practicing Chemical Engineer and Air Pollution Control Equipment Calculations, also from Wiley. FRANCESCO RICCI is the recipient of numerous academic awards and scholarships. Aside from academic research, Mr. Ricci's industrial experience includes short tenures at Air Products and Chemicals, Inc. and Bristol-Myers Squibb. He has lectured at the undergraduate level on chemical engineering thermodynamics as well as on reactor design. Mr. Ricci is the coauthor of Thermodynamics for the Practicing Engineer (Wiley), the author of the solutions manual for said text, and a contributing author to the 2009 title Introduction to Environmental Management. Klappentext An invaluable guide for problem solving in mass transfer operationsThis book takes a highly pragmatic approach to providing the principles and applications of mass transfer operations by offering a valuable, easily accessible guide to solving engineering problems. Both traditional and novel mass transfer processes receive treatment. As with all of the books in this series, emphasis is placed on an example-based approach to illustrating key engineering concepts.The book is divided into two major parts. It starts with the principles underlying engineering problems-showing readers how to apply general engineering principles to the topic of mass transfer operations. It then goes on to provide step-by-step guidance for traditional mass transfer operations, including distillation, absorption and stripping, and adsorption, plus novel mass transfer processes. Essential topics for professional engineering exams are also covered.Geared towards chemical, environmental, civil, and mechanical engineers working on real-world industrial applications, Mass Transfer Operations for the Practicing Engineer features:* Numerous sample problems and solutions with real-world applications* Clear, precise explanations on how to carry out the basic calculations associated with mass transfer operations* Coverage of topics from the ground up for readers without prior knowledge of the subject* Overview of topics relevant to the ABET (Accreditation Board for Engineering and Technology) for those taking the Professional Engineering (PE) exams* Appendix containing relevant mass transfer operation charts and tables Zusammenfassung * Part of the Essential Engineering Calculations Series, this book presents step-by-step solutions of the basic principles of mass transfer operations. * Covers specific mass transfer operations such as distillation, absorption and stripping, and adsorption. Inhaltsverzeichnis Preface. Part One Introduction. 1. History of Chemical Engineering and Mass Transfer Operations. References. 2. Transport Phenomena vs Unit Operations Approach. References. 3. Basic Calculations. Introduction. Units and Dimensions. Conversion of Units. The Gravitational Constant gc. Significant Figures and Scientific Notation. References. 4. Process Variables. Introduction. Temperature. Pressure. Moles and Molecular Weight. Mass, Volume, and Density. Viscosity. Reynolds Number. pH. Vapor Pressure. I...
Sommario
Preface.
Part One Introduction.
1. History of Chemical Engineering and Mass Transfer Operations.
References.
2. Transport Phenomena vs Unit Operations Approach.
References.
3. Basic Calculations.
Introduction.
Units and Dimensions.
Conversion of Units.
The Gravitational Constant gc.
Significant Figures and Scientific Notation.
References.
4. Process Variables.
Introduction.
Temperature.
Pressure.
Moles and Molecular Weight.
Mass, Volume, and Density.
Viscosity.
Reynolds Number.
pH.
Vapor Pressure.
Ideal Gas Law.
References.
5. Equilibrium vs Rate Considerations.
Introduction.
Equilibrium.
Rate.
Chemical Reactions.
References.
6. Phase Equilibrium Principles.
Introduction.
Gibb's Phase Rule.
Raoult's Law.
Henry's Law.
Raoult's Law vs Henry's Law.
Vapor-Liquid Equilibrium in Nonideal Solutions.
Vapor-Solid Equilibrium.
Liquid-Solid Equilibrium.
References.
7. Rate Principles.
Introduction.
The Operating Line.
Fick's Law.
Diffusion in Gases.
Diffusion in Liquids.
Mass Transfer Coefficients.
Individual Mass Transfer Coefficients.
Equimolar Counterdiffusion.
Diffusion of Component A Through Non-diffusing Component B.
Overall Mass Transfer Coefficients.
Equimolar Counterdiffusion and/or Diffusion in Dilute Solutions.
Gas Phase Resistance Controlling.
Liquid Phase Resistance Controlling.
Experimental Mass Transfer Coefficients.
References.
Part Two Applications: Component and Phase Separation Processes.
8. Introduction to Mass Transfer Operations.
Introduction.
Classification of Mass Transfer Operations.
Contact of Immiscible Phases.
Miscible Phases Separated by a Membrane.
Direct Contact of Miscible Phases.
Mass Transfer Equipment.
Distillation.
Absorption.
Adsorption.
Extraction.
Humidification and Drying.
Other Mass Transfer Unit Operations.
The Selection Decision.
Characteristics of Mass Transfer Operations.
Unsteady-State vs Steady-State Operation.
Flow Pattern.
Stagewise vs Continuous Operation.
References.
9. Distillation.
Introduction.
Flash Distillation.
Batch Distillation.
Continuous Distillation with Reflux.
Equipment and Operation.
Equilibrium Considerations.
Binary Distillation Design: McCabe-Thiele Graphical Method.
Multicomponent Distillation: Fenske-Underwood-Gilliland (FUG) Method.
Packed Column Distillation.
References.
10. Absorption and Stripping.
Introduction.
Description of Equipment.
Packed Columns.
Plate Columns.
Design and Performance Equations?Packed Columns.
Liquid Rate.
Column Diameter.
Column Height.
Pressure Drop.
Design and Performance Equations-Plate Columns.
Stripping.
Packed vs Plate Tower Comparison.
Summary of Key Equations.
References.
11. Adsorption.
Introduction.
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