Engineering

Designed for undergraduate and first-year courses in Fluid Mechanics, this is a revision of the best selling fluid mechanics book for chemical engineers.  It is a comprehensive text that offers an understanding of fluid mechanics essential for the chemical engineer. Thorough and clearly written, this book gives the undergraduate and first-year graduate student a complete overview of this essential topic by providing numerous real-world examples and problems of increasing detail and complexity. It also covers all the material necessary to pass the fluid mechanics portion of the Professional Engineer's exam.

Offers a comprehensive understanding of fluid mechanics essential for the chemical engineer and upper level students.

° A revision of the best selling fluid mechanics book for chemical engineers.

° Covers all the material necessary to pass the fluid mechanics portion of the Professional Engineer's exam.

° Includes software to facilitate an understanding of the important but difficult subject of turbulence.

The second edition will have perhaps 15% - 20% of reworked or additional material, for example, (a) weed out non-essential problems and text, and clarifying those places that need it; (b) include conversion factors on the inside front cover; (c) give a road map as to the contents of the book; (d) major reworking of Chapter 9 on turbulence; (e) additions to Chapter 10 on bubble motion and fluidization to include pneumatic conveying of solids ("saltation") and atomization and spray formation; (f) amplification of Chapter 11 on non-Newtonian fluids, also to include experimental data to back up non-Newtonian models;  (g) the addition of some 40 pages in Chapter 12 (Computational Fluid Dynamics) on the scope of Fluent and details of how to solve two or three representative problems; and (h) the inclusion of graphical Fluent output in 12 - 15 representative cases, scattered throughout the book.

Preface.

I. MACROSCOPIC FLUID MECHANICS.

1. Introduction to Fluid Mechanics.

    1.1 Fluid Mechanics in Chemical Engineering

    1.2 General Concepts of a Fluid

    1.3 Stresses, Pressure, Velocity, and the Basic Laws

    1.4 Physical Properties - Density, Viscosity, and Surface Tension

    1.5 Units and Systems of Units

      Example 1.1 - Units Conversion

      Example 1.2 - Mass of Air in a Room

    1.6 Hydrostatics

      Example 1.3 - Pressure in an Oil Storage Tank

      Example 1.4 - Multiple Fluid Hydrostatics

      Example 1.5 - Pressure Variations in a Gas

      Example 1.6 - Hydrostatic Force on a Curved Surface

      Example 1.7 - Application of Archimedes?f Law

    1.7 Pressure Change Caused by Rotation

      Example 1.8 - Overflow from a Spinning Container

    Problems for Chapter 1

2. Mass, Energy, and Momentum Balances.

    2.1 General Conservation Laws

    2.2 Mass Balances

      Example 2.1 - Mass Balance for Tank Evacuation

    2.3 Energy Balances

      Example 2.2 - Pumping n-Pentane

    2.4 Bernoulli’s Equation

    2.5 Applications of Bernoulli?fs Equation

      Example 2.3 - Tank Filling

    2.6 Momentum Balances

      Example 2.4 - Impinging Jet of Water

      Example 2.5 - Velocity of Wave on Water

      Example 2.6 - Flow Measurement by a Rotameter

    2.7 Pressure, Velocity, and Flow Rate Measurement

    Problems for Chapter

3. Fluid Friction in Pipes.

    3.1 Introduction

    3.2 Laminar Flow

      Example 3.1 - Polymer Flow in a Pipeline

    3.3 Models for Shear Stress

    3.4 Piping and Pumping Problems

      Example 3.2 - Unloading Oil from a Tanker

      Specified Flow Rate and Diameter

      Example 3.3 - Unloading Oil from a Tanker

      Specified Diameter and Pressure Drop

      Example 3.4 - Unloading Oil from a Tanker

      Specified Flow Rate and Pressure Drop

      Example 3.5 - Unloading Oil from a Tanker

      Miscellaneous Additional Calculations

    3.5 Flow in Noncircular Ducts

      Example 3.6 - Flow in an Irrigation Ditch

    3.6 Compressible Gas Flow in Pipelines

    3.7 Compressible Flow in Nozzles

    3.8 Complex Piping Systems

      Example 3.7 - Solution of a Piping/Pumping Problem

    Problems for Chapter 3

4. Flow in Chemical Engineering Equipment.

    4.1 Introduction

    4.2 Pumps and Compressors

      Example 4.1 - Pumps in Series and Parallel

    4.3 Drag Force on Solid Particles in Fluids

      Example 4.2 - Manufacture of Lead Shot

    4.4 Flow Through Packed Beds

      Example 4.3 - Pressure Drop in a Packed-Bed Reactor

    4.5 Filtration

    4.6 Fluidization

    4.7 Dynamics of a Bubble-Cap Distillation Column

    4.8 Cyclone Separators

    4.9 Sedimentation

    4.10 Dimensional Analysis

      Example 4.4 - Thickness of the Laminar Sublayer

    Problems for Chapter 4

II. MICROSCOPIC FLUID MECHANICS.

5. Differential Equations of Fluid Mechanics.

    5.1 Introduction to Vector Analysis

    5.2 Vector Operations

      Example 5.1 - The Gradient of a Scalar

      Example 5.2 - The Divergence of a Vector

      Example 5.3 - An Alternative to the Differential Element

      Example 5.4 - The Curl of a Vector

      Example 5.5 - The Laplacian of a Scalar

    5.3 Other Coordinate Systems

    5.4 The Convective Derivative

    5.5 Differential Mass Balance

      Example 5.6 - Physical Interpretation of the Net Rate of Mass Outflow

      Example 5.7 - Alternative Derivation of the Continuity Equation

    5.6 Differential Momentum Balances

    5.7 Newtonian Stress Components in Cartesian Coordinates

      Example 5.8 - Constant-Viscosity Momentum Balances in Terms of Velocity Gradients

    Example 5.9 - Vector Form of Variable-Viscosity Momentum Balance

    Problems for Chapter 5

6. Solution of Viscous-Flow Problems.

    6.1 Introduction

    6.2 Solution of the Equations of Motion in Rectangular Coordinates

      Example 6.1 - Flow Between Parallel Plates

    6.3 Alternative Solution Using a Shell Balance

      Example 6.2 - Shell Balance for Flow Between Parallel Plates

      Example 6.3 - Film Flow on a Moving Substrate

      Example 6.4 - Transient Viscous Diffusion of Momentum (FEMLAB)

    6.4 Poiseuille and Couette Flows in Polymer Processing

      Example 6.5 - The Single-Screw Extruder

      Example 6.6 - Flow Patterns in a Screw Extruder (FEMLAB)

    6.5 Solution of the Equations of Motion in Cylindrical x Table of Contents Coordinates

      Example 6.7 - Flow Through an Annular Die

      Example 6.8 - Spinning a Polymeric Fiber

    6.6 Solution of the Equations of Motion in Spherical Coordinates

      Example 6.9 - Analysis of a Cone-and-Plate Rheometer

    Problems for Chapter 6

7. Laplace’s Equation, Irrotational and Porous-Media Flows.

    7.1 Introduction

    7.2 Rotational and Irrotational Flows

      Example 7.1 - Forced and Free Vortices

    7.3 Steady Two-Dimensional Irrotational Flow

    7.4 Physical Interpretation of the Stream Function

    7.5 Examples of Planar Irrotational Flow

      Example 7.2 - Stagnation Flow

      Example 7.3 - Combination of a Uniform Stream and a Line Sink (C)

      Example 7.4 - Flow Patterns in a Lake (FEMLAB)

    7.6 Axially Symmetric Irrotational Flow

    7.7 Uniform Streams and Point Sources

    7.8 Doublets and Flow Past a Sphere

    7.9 Single-Phase Flow in a Porous Medium

      Example 7.5 - Underground Flow of Water

    7.10 Two-Phase Flow in Porous Media

    7.11 Wave Motion in Deep Water

    Problems for Chapter 7

8. Boundary-Layer Aand Other Nearly Unidirectional Flows.

    8.1 Introduction

    8.2 Simplified Treatment of Laminar Flow Past a Flat Plate

      Example 8.1 - Flow in an Air Intake

    8.3 Simplification of the Equations of Motion

    8.4 Blasius Solution for Boundary-Layer Flow

    8.5 Turbulent Boundary Layers

      Example 8.2 - Laminar and Turbulent Boundary Layers Compared

    8.6 Dimensional Analysis of the Boundary-Layer Problem

    8.7 Boundary-Layer Separation

      Example 8.3 - Boundary-Layer Flow Between Parallel Plates (FEMLAB Library)

      Example 8.4 - Entrance Region for Laminar Flow Between Flat Plates

    8.8 The Lubrication Approximation

      Example 8.5 - Flow in a Lubricated Bearing (FEMLAB)

    8.9 Polymer Processing by Calendering

      Example 8.6 - Pressure Distribution in a Calendered Sheet

    8.10 Thin Films and Surface Tension

    Problems for Chapter 8

9. Turbulent Flow.

    9.1 Introduction

      Example 9.1 - Numerical Illustration of a Reynolds Stress Term

    9.2 Physical Interpretation of the Reynolds Stresse

    9.3 Mixing-Length Theory

    9.4 Determination of Eddy Kinematic Viscosity and Mixing Length

    9.5 Velocity Profiles Based on Mixing Length Theory 486

      Example 9.2 - Investigation of the von K?Larm?Lan Hypothesis

    9.6 The Universal Velocity Profile for Smooth Pipes

    9.7 Friction Factor in Terms of Reynolds Number for Smooth Pipes

      Example 9.3 - Expression for the Mean Velocity

    9.8 Thickness of the Laminar Sublayer

    9.9 Velocity Profiles and Friction Factor for Rough Pipe

    9.10 Blasius-Type Law and the Power-Law Velocity Profile

    9.11 A Correlation for the Reynolds Stresses

    9.12 Computation of Turbulence by the k/? Method

      Example 9.4 - Flow Through an Orifice Plate (FEMLAB)

      Example 9.5 - Turbulent Jet Flow (FEMLAB)

    9.13 Analogies Between Momentum and Heat Transfer

      Example 9.6 - Evaluation of the Momentum/Heat-Transfer Analogies

    9.14 Turbulent Jets

      Problems for Chapter 9

10. Bubble Motion, Two-Phase Flow, and Fluidization.

    10.1 Introduction

    10.2 Rise of Bubbles in Unconfined Liquids

      Example 10.1 - Rise Velocity of Single Bubbles

    10.3 Pressure Drop and Void Fraction in Horizontal Pipes

      Example 10.2 - Two-Phase Flow in a Horizontal Pipe

    10.4 Two-Phase Flow in Vertical Pipes

      Example 10.3 - Limits of Bubble Flow

      Example 10.4 - Performance of a Gas-Lift Pump

      Example 10.5 - Two-Phase Flow in a Vertical Pipe

    10.5 Flooding

    10.6 Introduction to Fluidization

    10.7 Bubble Mechanics

    10.8 Bubbles in Aggregatively Fluidized Beds

      Example 10.6 - Fluidized Bed with Reaction (C)

    Problems for Chapter 10

11. Non-Newtonian Fluids.

    11.1 Introduction

    11.2 Classification of Non-Newtonian Fluids

    11.3 Constitutive Equations for Inelastic Viscous Fluids

      Example 11.1 - Pipe Flow of a Power-Law Fluid

      Example 11.2 - Pipe Flow of a Bingham Plastic

      Example 11.3 - Non-Newtonian Flow in a Die (FEMLAB Library)

    11.4 Constitutive Equations for Viscoelastic Fluids

    11.5 Response to Oscillatory Shear

    11.6 Characterization of the Rheological Properties of Fluids

      Example 11.4 - Proof of the Rabinowitsch Equation

      Example 11.5 - Working Equation for a Coaxial Cylinder Rheometer: Newtonian Fluid

    Problems for Chapter 11

12. Microfluidics and Electrokinetic Flow Effects.

    12.1 Introduction

    12.2 Physics of Microscale Fluid Mechanics

    12.3 Pressure-driven Flow Through Microscale Tubes

      Example 12.1 - Calculation of Reynolds Numbers

    12.4 Mixing, Transport, and Dispersion

    12.5 Species, Energy, and Charge Transport

    12.6 The Electrical Double Layer and Electrokinetic Phenomena

      Example 12.2 - Relative Magnitudes of Electroosmotic and Pressure-driven Flow

      Example 12.3 - Electroosmotic Flow Around a Particle

      Example 12.4 - Electroosmosis in a Microchannel (FEMLAB)

      Example 12.5 - Electroosmotic Switching in a Branched Microchannel (FEMLAB)

    12.7 Measuring the Zeta Potential

      Example 12.6 - Magnitude of Typical Streaming Potentials

    12.8 Electroviscosity

    12.9 Particle and Macromolecule Motion in Microfluidic Channels

      Example 12.7 - Gravitational and Magnetic Settling of Assay Beads

    Problems for Chapter 12

13. An Introduction to Computational Fluid Dynamics and Flowlab.

    13.1 Introduction and Motivation

    13.2 Numerical Methods

    13.3 Learning CFD by Using FlowLab

    13.4 Practical CFD Examples

      Example 13.1 - Developing Flow in a Pipe Entrance Region (FlowLab)

      Example 13.2 - Pipe Flow Through a Sudden Expansion (FlowLab)

      Example 13.3 - A Two-Dimensional Mixing Junction (FlowLab)

      Example 13.4 - Flow Over a Cylinder (FlowLab)

    References for Chapter 13

14. Femlab for Solving Fluid Mechanics Problems.

    14.1 Introduction to FEMLAB

    14.2 How to Run FEMLAB

      Example 14.1 - Flow in a Porous Medium with an Obstruction (FEMLAB)

    14.3 Draw Mode

    14.4 Solution and Related Modes

    14.5 Fluid Mechanics Problems Solvable by FEMLAB

    Problems for Chapter 14

Appendix A: Useful Mathematical Relationships.

Appendix B: Answers to the True/False Assertions.

Appendix C: Some Vector and Tensor Operations.

Index.

Chemical Fluid Mechanics [PTG: PRENTICE HALL PROFESSIONAL] (Chemical Engineering)

Designed for undergraduate and first-year courses in Fluid Mechanics, this text consists of two parts—four chapters on macroscopic or relatively large-scale phenomena, followed by eight chapters on microscopic or relatively small-scale phenomena.

• Fluid Mechanics for Chemical Engineers
  Wilkes
  © 1999 | Prentice Hall | Paper; 624 pages | Instock
  ISBN-10: 0137398972 | ISBN-13: 9780137398973
  Brief Description | Buy from myPearsonStore
  

James O. Wilkes is Professor Emeritus of Chemical Engineering at the University of Michigan, where he served as department chairman and assistant dean for admissions. From 1989 to 1992, he was an Arthur F. Thurnau Professor. Wilkes coauthored Applied Numerical Methods (Wiley, 1969) and Digital Computing and Numerical Methods (Wiley, 1973). He received his bachelors degree from the University of Cambridge and his M.S. and Ph.D. in chemical engineering from the University of Michigan. His research interests involve numerical methods for solving a wide variety of engineering problems.

The Chemical Engineer's Practical Guide to Contemporary Fluid Mechanics

Since most chemical processing applications are conducted either partially or totally in the fluid phase, chemical engineers need a strong understanding of fluid mechanics. Such knowledge is especially valuable for solving problems in the biochemical, chemical, energy, fermentation, materials, mining, petroleum, pharmaceuticals, polymer, and waste-processing industries.

Fluid Mechanics for Chemical Engineers, Second Edition, with Microfluidics and CFD, systematically introduces fluid mechanics from the perspective of the chemical engineer who must understand actual physical behavior and solve real-world problems. Building on a first edition that earned Choice Magazine's Outstanding Academic Title award, this edition has been thoroughly updated to reflect the field's latest advances.

This second edition contains extensive new coverage of both microfluidics and computational fluid dynamics, systematically demonstrating CFD through detailed examples using FlowLab and COMSOL Multiphysics. The chapter on turbulence has been extensively revised to address more complex and realistic challenges, including turbulent mixing and recirculating flows.

Part I offers a clear, succinct, easy-to-follow introduction to macroscopic fluid mechanics, including physical properties; hydrostatics; basic rate laws for mass, energy, and momentum; and the fundamental principles of flow through pumps, pipes, and other equipment. Part II turns to microscopic fluid mechanics, which covers

• Differential equations of fluid mechanics
• Viscous-flow problems, some including polymer processing
• Laplace's equation, irrotational, and porous-media flows
• Nearly unidirectional flows, from boundary layers to lubrication, calendering, and thin-film applications
• Turbulent flows, showing how the k/ε method extends conventional mixing-length theory
• Bubble motion, two-phase flow, and fluidization
• Non-Newtonian fluids, including inelastic and viscoelastic fluids
• Microfluidics and electrokinetic flow effects including electroosmosis, electrophoresis, streaming potentials, and electroosmotic switching
• Computational fluid mechanics with FlowLab and COMSOL Multiphysics

Fluid Mechanics for Chemical Engineers, Second Edition, with Microfluidics and CFD, includes 83 completely worked practical examples, several of which involve FlowLab and COMSOL Multiphysics. There are also 330 end-of-chapter problems of varying complexity, including several from the University of Cambridge chemical engineering examinations. The author covers all the material needed for the fluid mechanics portion of the Professional Engineer's examination.

The author's Web site, www.engin.umich.edu/~fmche/, provides additional notes on individual chapters, problem-solving tips, errata, and more.

View a Sample Chapter PDF:

Pearson Higher Education offers special pricing when you choose to package your text with other student resources. If you're interested in creating a cost-saving package for your students, contact your Pearson Higher Education representative for pricing and ordering information.

This title is a member of the Prentice Hall International Series in the Physical and Chemical Engineering Sciences, which also contains the titles below . You can also visit the Prentice Hall International Series in the Physical and Chemical Engineering Sciences page.

• Analysis, Synthesis and Design of Chemical Processes, 3/E
  Turton, Bailie, Whiting & Shaeiwitz
  © 2009 | Prentice Hall | Cloth; 1040 pages | Estimated Availability: 12/19/2008
  ISBN-10: 0135129664 | ISBN-13: 9780135129661
  
  
  
• Analysis, Synthesis and Design of Chemical Processes, Safari, 3/E
  Turton, Bailie, Whiting & Shaeiwitz
  © 2009 | Prentice Hall | On-line Supplement; 1040 pages | Estimated Availability: 12/05/2008
  ISBN-10: 0135072913 | ISBN-13: 9780135072912
  URL: http://safari.informit.com
  
  
  



Appropriate for all courses in chemical engineering process design.

Analysis, Synthesis and Design of Chemical Processes, Second Edition moves chemical engineering students beyond neatly delineated classroom exercises and into the world of solving the open-ended process problems they will see in practice. The authors accomplish this by emphasizing design synthesis of the entire process—from equipment sizing to optimization, finances to operation. Drawing on over 30 years of teaching chemical engineering process design, they present design as a creative process that integrates the big picture with the small details, and relies on knowing which to stress, and why. They show students how to apply key process design techniques to every aspect of the discipline, from the conceptual design of a plant to improving an existing process. This edition has been updated throughout, and contains extensive new coverage of environmental, health, and safety issues, green engineering, and engineering ethics. Coverage also includes: evolution and generation of multiple process configurations; estimating capital investment, manufacturing cost, and other economic factors; synthesis and optimization of chemical processes; performance analysis of existing processes and equipment; and more. The authors provide suggested curricula for both single-semester and year-long design courses, case studies and design projects with practical applications, and appendices with current equipment cost data and preliminary design information for four chemical processes. The accompanying CD-ROM contains powerful tools for helping students master chemical process design, including a thoroughly revised version of CAPCOST for evaluating fixed capital investments and full process economics; HENSAD for planning temperatures and heat exchange; a virtual plant tour of a simple chemical process; and additional student design projects.

• Analysis, Synthesis, and Design of Chemical Processes, 2/E
  Turton, Bailie, Whiting & Shaeiwitz
  © 2003 | Prentice Hall | Cloth Bound w/CD-ROM; 987 pages | Instock
  ISBN-10: 0130647926 | ISBN-13: 9780130647924
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Approprirate for all introductory courses in chemical engineering.

Basic Principles and Calculations in Chemical Engineering, Seventh Edition is a complete, practical, and student-friendly introduction to the principles and techniques of contemporary chemical, petroleum, and environmental engineering. Throughout, the authors introduce efficient and consistent methods for analyzing material and energy balance problems, organizing solutions, and calculating answers. The authors thoroughly address the behavior of gases, liquids, and solids: ideal/real gases, single component two-phase systems, gas-liquid systems, and more. This edition presents extensive new coverage, including new chapters on degrees of freedom, process simulation, and unsteady state materials. It brings together more examples and problems treating topics pertaining to the environment, safety, semiconductor processing, nanotechnology, biology and biotechnology. Recast into 29 modular chapters, it offers students and faculty members an exceptionally flexible approach to learning. The CD-ROM includes new Polymath software, a convenient physical property database, 200 supplementary problems, animations of working process equipment, and checklists designed to simplify learning and accelerate mastery.

• Basic Principles and Calculations in Chemical Engineering, 7/E
  Himmelblau & Riggs
  © 2004 | Prentice Hall | Cloth Bound w/CD-ROM; 1072 pages | Instock
  ISBN-10: 0131406345 | ISBN-13: 9780131406346
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For Senior-level and graduate courses in Biochemical Engineering, and for programs in Agricultural and Biological Engineering or Bioengineering.

This concise yet comprehensive text introduces the essential concepts of bioprocessing—internal structure and functions of different types of microorganisms, major metabolic pathways, enzymes, microbial genetics, kinetics and stoichiometry of growth and product information—to traditional chemical engineers and those in related disciplines. It explores the engineering principles necessary for bioprocess synthesis and design, and illustrates the application of these principles to modern biotechnology for production of pharmaceuticals and biologics, solution of environmental problems, production of commodities, and medical applications.

• Bioprocess Engineering: Basic Concepts, 2/E
  Shuler & Kargi
  © 2002 | Prentice Hall | Cloth; 576 pages | Instock
  ISBN-10: 0130819085 | ISBN-13: 9780130819086
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Chemical Thermodynamics unified around energy, entropy and equilibrium.

• Chemical Engineering Thermodynamics
  Balzhiser, Samuels & Eliassen
  © 1972 | Prentice Hall | Paper; 696 pages | Instock
  ISBN-10: 013128603X | ISBN-13: 9780131286030
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A thorough overview of all aspects of chemical process control — process modeling, dynamic analyses of processing systems, a large variety of control schemes, synthesis of multivariable control configurations for single units and complete chemical plants, analysis and design of digital computer control systems.

• Chemical Process Control: An Introduction to Theory and Practice
  Stephanopoulos
  © 1984 | Prentice Hall | Paper; 704 pages | Instock
  ISBN-10: 0131286293 | ISBN-13: 9780131286290
  Brief Description | Buy from myPearsonStore
  
  



For upper level undergraduate or graduate level Chemical or Mechanical Engineering courses in chemical process safety, as well as for chemical and mechanical engineers in the beginning of their careers who are interested in improving chemical process safety. It can also serve as a guide for anyone interested in learning about chemical process safety, including high school teachers, firemen, environmentalists, OSHA regulators, EPA regulators, and others.

The only book designed as a text for teaching chemical process safety, this book provides a comprehensive introduction to the essential technical fundamentals of chemical process safety. Its emphasis on fundamentals is intended to help both the student and the practicing scientist to understand the concepts and to apply them in an appropriate manner.

• Chemical Process Safety: Fundamentals with Applications, 2/E
  Crowl & Louvar
  © 2002 | Prentice Hall | Cloth; 656 pages | Instock
  ISBN-10: 0130181765 | ISBN-13: 9780130181763
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A description of the basic principles of electrochemical engineering and their application to energy storage, industrial electrolysis, and corrosion.

• Electrochemical Engineering Principles
  Prentice
  © 1991 | Prentice Hall | Paper; 320 pages | Instock
  ISBN-10: 0132490382 | ISBN-13: 9780132490382
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The book presents in a clear and concise manner the fundamentals of chemical reaction engineering. The structure of the book allows the student to solve reaction engineering problems through reasoning rather than through memorization and recall of numerous equations, restrictions, and conditions under which each equation applies. The fourth edition contains more industrial chemistry with real reactors and real engineering and extends the wide range of applications to which chemical reaction engineering principles can be applied (i.e., cobra bites, medications, ecological engineering)
• Elements of Chemical Reaction Engineering, 4/E
  Fogler
  © 2006 | Prentice Hall | Cloth Bound w/CD-ROM; 1120 pages | Instock
  ISBN-10: 0130473944 | ISBN-13: 9780130473943
  Brief Description | Buy from myPearsonStore
  
  



Designed for undergraduate and first-year courses in Fluid Mechanics, this text consists of two parts—four chapters on macroscopic or relatively large-scale phenomena, followed by eight chapters on microscopic or relatively small-scale phenomena.

• Fluid Mechanics for Chemical Engineers
  Wilkes
  © 1999 | Prentice Hall | Paper; 624 pages | Instock
  ISBN-10: 0137398972 | ISBN-13: 9780137398973
  Brief Description | Buy from myPearsonStore
  
  



Designed for undergraduate and first-year courses in Fluid Mechanics, this is a revision of the best selling fluid mechanics book for chemical engineers.  It is a comprehensive text that offers an understanding of fluid mechanics essential for the chemical engineer. Thorough and clearly written, this book gives the undergraduate and first-year graduate student a complete overview of this essential topic by providing numerous real-world examples and problems of increasing detail and complexity. It also covers all the material necessary to pass the fluid mechanics portion of the Professional Engineer's exam.
• Fluid Mechanics for Chemical Engineers with Microfluidics and CFD, 2/E
  Wilkes
  © 2006 | Prentice Hall | Cloth; 784 pages | Instock
  ISBN-10: 0131482122 | ISBN-13: 9780131482128
  Brief Description | Buy from myPearsonStore
  
  



For undergraduate courses in Applied Thermodynamics.

Written in a style and at a level that is accessible to undergraduates, this introduction to applied thermodynamics covers the first and second law for process applications, molecular concepts, equations of state, activity models, and reaction equilibria—all in a tightly integrated, pedagogical progression of topics. It addresses the on-going evolution in applied thermodynamics and computer technology, and integrates several widely-accessible computational tools to allow exploration of model behavior— e.g., programs for HP and TI calculators, Microsoft Excel spreadsheets, and PC's. Includes background and comparison on many of the popular thermodynamic models.

• Introductory Chemical Engineering Thermodynamics
  Elliott & Lira
  © 1999 | Prentice Hall | Cloth; 560 pages | Instock
  ISBN-10: 0130113867 | ISBN-13: 9780130113863
  Brief Description | Buy from myPearsonStore
  
  



A thorough introduction to the fundamentals and applications of microscopic and macroscopic mass transfer.

• Mass Transfer: Fundamentals and Applications
  Hines & Maddox
  © 1985 | Prentice Hall | Paper; 600 pages | Instock
  ISBN-10: 0135596092 | ISBN-13: 9780135596098
  Brief Description | Buy from myPearsonStore
  
  



Appropriate for chemical engineering students, Molecular Thermodynamics of Fluid-Phase Equilibria presents a broad introduction to the thermodynamics of phase equilibria in chemical engineering design, especially in separation operations.

• Molecular Thermodynamics of Fluid-Phase Equilibria, 3/E
  Prausnitz, Lichtenthaler & de Azevedo
  © 1999 | Prentice Hall | Paper; 864 pages | Instock
  ISBN-10: 0139777458 | ISBN-13: 9780139777455
  Brief Description | Buy from myPearsonStore
  
  



For junior/senior/graduate-level courses in Numerical Methods in departments of Chemical and Biochemical Engineering.

Designed for multi-level use, this text explores in detail the derivation of a variety of numerical methods and their application to the solution of engineering problems—with special attention to problems in chemical engineering. It uses MATLAB^® extensively throughout (for the WINDOWS, Macintosh, and Unix environments)—but focuses clearly on teaching students numerical methods and problem solving skills. It is not a MATLAB manual for simple number-crunching. The companion web site at informit.com/title/9780130138514 contains the MATLAB scripts used throughout the text.

• Numerical Methods for Chemical Engineers with MATLAB Applications
  Constantinides & Mostoufi
  © 1999 | Prentice Hall | Paper; 608 pages | Instock
  ISBN-10: 0130138517 | ISBN-13: 9780130138514
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A companion textbook for core courses in chemical engineering or in computational methods. This book takes a “nuts and bolts” approach to interactive problem solving, offering solved, partially solved, and unsolved problems in the core subject areas of chemical engineering where standard numerical methods are illustrated and where numerical solutions are typically required.

The numerical techniques for problem solving discussed in the book allow students to use widely available mathematical software packages (such as POLYMATH™, Matlab™, Mathematica™, Maple™, MathCAD™) to solve realistic chemical engineering problems much more conveniently, faster, and more accurately than with traditional problem solving techniques.

• Problem Solving in Chemical Engineering with Numerical Methods
  Cutlip & Shacham
  © 1999 | Prentice Hall | Paper; 464 pages | Instock
  ISBN-10: 0138625662 | ISBN-13: 9780138625665
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This book provides extensive problem-solving instruction and suggestions, numerous examples, and many complete and partial solutions in the main subect areas of chemical and biochmeical engineering and related disciplines. It is intended for students in chemical and biochemical engineering.
• Problem Solving in Chemical and Biochemical Engineering with POLYMATH, Excel, and MATLAB, 2/E
  Cutlip & Shacham
  © 2008 | Prentice Hall | Paper; 752 pages | Instock
  ISBN-10: 0131482041 | ISBN-13: 9780131482043
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For junior or senior-level undergraduate Chemical Engineering courses in process dynamics and control, as well as a reference for professionals seeking the latest simulation tools and advanced control strategies.

This is the first book to offer a fully integrated introduction of the fundamental topics of process dynamics with MATLAB software tools that allow students to learn the material interactively through computer-based simulation exercises. Process Control: Modeling, Design and Simulation presents realistic problems and provides the software tools for students to simulate processes and solve practical, real-world problems. Ultimately, the book will teach students to analyze dynamic chemical processes and develop automatic control strategies to operate them safely and economically.

• Process Control: Modeling, Design and Simulation
  Bequette
  © 2003 | Prentice Hall | Cloth; 800 pages | Instock
  ISBN-10: 0133536408 | ISBN-13: 9780133536409
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This edition is suitable as a text for Chemical Process Dynamics or Introductory Chemical Process Control courses at the junior/senior level. Also, for Numerical Methods courses in chemical engineering.

The goal of this book is to provide an introduction to the modeling, analysis, and simulation of the dynamic behavior of chemical processes.

• Process Dynamics: Modeling, Analysis and Simulation
  Bequette
  © 1998 | Prentice Hall | Paper; 640 pages | Instock
  ISBN-10: 0132068893 | ISBN-13: 9780132068895
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An applications-oriented introduction to process fluid mechanics. Provides an orderly treatment of the essentials of both the macro and micro problems of fluid mechanics.

• Process Fluid Mechanics
  Denn
  © 1980 | Prentice Hall | Paper; 383 pages | Instock
  ISBN-10: 0137231636 | ISBN-13: 9780137231638
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• Solutions Manual, 4/E
  Vicente, Nori & Fogler
  © 2006 | Prentice Hall | Paper Bound w/CD-ROM; 896 pages | Instock
  ISBN-10: 0131863835 | ISBN-13: 9780131863835
  
  
  



At the undergraduate level, this book is intended to be a textbook for the Senior Design Course. This text can also be used for a graduate course in Process Synthesis.

The book presents a systematic approach to design, starting from an elementary treatment that is suitable for the undergraduate level, working toward advanced topics prepared for graduate level courses. This edition provides a comprehensive and modern treatment to process design of continuous and batch processes.

• Systematic Methods of Chemical Process Design
  Biegler, Grossmann & Westerberg
  © 1997 | Prentice Hall | Paper; 700 pages | Instock
  ISBN-10: 0134924223 | ISBN-13: 9780134924229
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A comprehensive introduction to the concepts, techniques, and applications of model-based process control that presents the process control problem as a subset of overall plant operations problem rather than as a separate discipline. In addition, the approaches presented in the book are motivated by their use in solving practical problems, thus emphasizing methods rather than theory. The examples used to illustrate these methods and the MATLAB software that is included are further intended to assist the reader in the design and tuning of actual control systems.

• Techniques of Model-Based Control
  Brosilow & Joseph
  © 2002 | Prentice Hall | Paper; 704 pages | Instock
  ISBN-10: 013028078X | ISBN-13: 9780130280787
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For two-semester, graduate-level courses in Chemical Thermodynamics.

Rigorous and comprehensive in approach, this text explores the theory, concepts and applications of classical thermodynamics and introduces a molecular-level perspective of constitutive property models for both electrolyte and non-electrolyte mixtures. Extensive examples and problems provide ample opportunities for connecting theory with applications.

• Thermodynamics and Its Applications, 3/E
  Tester & Modell
  © 1997 | Prentice Hall | Paper; 960 pages | Out of Stock
  ISBN-10: 013915356X | ISBN-13: 9780139153563
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