Transport processes and separation process principles : (Includes unit operations) / Christie John Geankoplis
Publisher: Estados Unidos : Pearson Education, ©2003Edition: 4th edDescription: xiii, 1026 páginas : ilustraciones, tablas ; 24 cmContent type: texto Media type: no mediado Carrier type: volumenISBN: 9780131013674Subject(s): Procesos de separación | Transferencia de calorDDC classification: 660.2842Item type | Current location | Collection | Call number | Vol info | Copy number | Status | Date due | Barcode | Item holds |
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B. Campus los Cerros En carrito para ordenar en estante | Colección general | 660.2842 G292 (Browse shelf) | 4th ed. 2003 | 1 | Available | 0000052481 |
Enhanced descriptions from Syndetics:
In Transport Processes and Separation Process Principles, Fourth Edition , author Christie John Geankoplis offers a unified and fully updated treatment of momentum transfer, heat transfer, mass transfer, and separation processes. Enhancements to this edition include a more thorough coverage of transport processes, plus new or expanded coverage of separation process applications, fluidized beds, non-Newtonian fluids, membrane separation processes and gas-membrane theory, and much more. The book contains 240+ example problems and 550+ homework problems.
Includes contents, appendix, index. -- Appendix A.1. Fundamental constans and conversion factors. -- A.2. Physical propertiesof water. -- A.3. Physical properties of inorganic and organic compounds. -- A.4. Physical properties of foods and biological materials. -- A.5. Properties of pipes, tubes, and scrrens.
Introduction to engineering principles and units. -- Principles of momentum transfer and overall balances. -- Principles of momentum transfer and applicationd. -- Principles of steady - state heat transfer. -- Principles of unsteady - state heat transfer. -- Principles of mass transfer. -- Principles of unsteady - state and convective mass transder. -- Evaporation. -- Drying of process materials. -- Stage and continuous gas - liquid separation processes. -- Vapor - liquid separation processes. -- Liquid - liquid and fluid - solid separation processes. -- Membrane separation processes. -- Mechanical - physical seperation processes.
Today, chemical engineering professionals need a thorough understanding of momentum, heat, and mass transfer processes, as well as separation processes. this book offers a unified and up - to - date treatment of all these topics. thoroughy updated to reflect the field´s latest methods and applications, it covers both fundamental principles and practical applications.
Table of contents provided by Syndetics
- Preface
- I Transport Processes: Momentum, Heat, and Mass
- 1 Introduction to Engineering Principles and Units
- Classification of Transport Processes and Separation Processes (Unit Operations)
- SI System of Basic Units Used in This Text and Other Systems
- Methods of Expressing Temperatures and Compositions
- Gas Laws and Vapor Pressure
- Conservation of Mass and Material Balances
- Energy and Heat Units
- Conservation of Energy and Heat Balances
- Numerical Methods for Integration
- 2 Principles of Momentum Transfer and Overall Balances
- Introduction
- Fluid Statics
- General Molecular Transport Equation for Momentum, Heat, and Mass Transfer
- Viscosity of Fluids
- Types of Fluid Flow and Reynolds Number
- Overall Mass Balance and Continuity Equation
- Overall Energy Balance
- Overall Momentum Balance
- Shell Momentum Balance and Velocity Profile in Laminar Flow
- Design Equations for Laminar and Turbulent Flow in Pipes
- Compressible Flow of Gases
- 3 Principles of Momentum Transfer and Applications
- Flow Past Immersed Objects and Packed and Fluidized Beds
- Measurement of Flow of Fluids
- Pumps and Gas-Moving Equipment
- Agitation and Mixing of Fluids and Power Requirements
- Non-Newtonian Fluids
- Differential Equations of Continuity
- Differential Equations of Momentum Transfer or Motion
- Use of Differential Equations of Continuity and Motion
- Other Methods for Solution of Differential Equations of Motion
- Boundary-Layer Flow and Turbulence
- Dimensional Analysis in Momentum Transfer
- Conduction Through Solids in Series
- 4 Principles of Steady-State Heat Transfer
- Introduction and Mechanisms of Heat Transfer
- Conduction Heat Transfer
- Steady-State Conduction and Shape Factors
- Forced Convection Heat Transfer Inside Pipes
- Heat Transfer Outside Various Geometries in Forced Convection
- Natural Convection Heat Transfer
- Boiling and Condensation
- Heat Exchangers
- Introduction to Radiation Heat Transfer
- Advanced Radiation Heat-Transfer Principles
- Heat Transfer of Non-Newtonian Fluids
- Special Heat-Transfer Coefficients
- Dimensional Analysis in Heat Transfer
- Numerical Methods for Steady-State Conduction in Two Dimensions
- 5 Principles of Unsteady-State Heat Transfer
- Derivation of Basic Equation
- Simplified Case for Systems with Negligible Internal Resistance
- Unsteady-State Heat Conduction in Various Geometries
- Numerical Finite-Difference Methods for Unsteady-State Conduction
- Chilling and Freezing of Food and Biological Materials
- Differential Equation of Energy Change
- Boundary-Layer Flow and Turbulence in Heat Transfer
- 6 Principles of Mass Transfer
- Introduction to Mass Transfer and Diffusion
- Molecular Diffusion in Gases
- Molecular Diffusion in Liquids Molecular Diffusion in Biological Solutions and Gels
- Molecular Diffusion in Solids
- Numerical Methods for Steady-State Molecular Diffusion in Two Dimensions
- 7 Principles of Unsteady-State and Convective Mass Transfer
- Unsteady-State Diffusion
- Convective Mass-Transfer Coefficients
- Mass-Transfer Coefficients for Various Geometries
- Mass Transfer to Suspensions of Small Particles
- Dimensional Analysis in Mass Transfer
- Molecular Diffusion Plus Convection and Chemical Reaction
- Diffusion of Gases in Porous Solids and Capillaries
- Numerical Methods for Unsteady-State Molecular Diffusion
- Boundary-Layer Flow and Turbulence
Excerpt provided by Syndetics
Author notes provided by Syndetics
CHRISTIE JOHN GEANKOPLIS is a Professor of Chemical Engineering and Materials Science at the University of Minnesota. His current research interests involve transport processes, biochemical reactor engineering, mass transfer in liquid solutions, and diffusion and/or reaction in porous solids. He holds a Ph.D. in Chemical Engineering from the University of Pennsylvania.
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