Nova Publishers
My Account Nova Publishers Shopping Cart
HomeBooksSeriesJournalsReference CollectionseBooksInformationSalesImprintsFor Authors
  Top » Catalog » Books » Biology » Biotechnology and Genetic Engineering » My Account  |  Cart Contents  |  Checkout   
Quick Find
Use keywords to find the product you are looking for.
Advanced Search
What's New? more
Doxycycline: Medical Uses and Effects
Shopping Cart more
0 items
Shipping & Returns
Privacy Notice
Conditions of Use
Contact Us
01.Bioengineering: Principles, Methodologies and Applications
02.Genome Research Advances
03.Histones: Class, Structure and Function
04.Focus on Food Engineering Research and Developments
05.Cellulose: Structure and Properties, Derivatives and Industrial Uses
06.Genome and Proteome in Oncology
07.Biotechnology in Agriculture and the Food Industry
08.Biotechnology: Research, Technology and Applications
09.Food Microbiology Research Trends
10.Governing Risk in the 21st Century: Lessons from the World of Biotechnology
Notifications more
NotificationsNotify me of updates to Computational Techniques: The Multiphase CFD Approach to Fluidization and Green Energy Technologies (includes CD-ROM)
Tell A Friend
Tell someone you know about this product.
Computational Techniques: The Multiphase CFD Approach to Fluidization and Green Energy Technologies (includes CD-ROM)
Retail Price: $395.00
10% Online Discount
You Pay:

Authors: Dimitri Gidaspow (Ilinois Inst. of Technology, Chicago, IL); Veeraya Jiradilok (GreatPoint Energy, Ilinois Inst. of Technology, Chicago, IL) 
Book Description:
This text has been used in the form of class notes taught to graduate and senior undergraduate students in chemical and mechanical engineering at Illinois Institute of Technology for the last three decades. The computer codes, particularly the Navier-Stokes equation solvers, have been continually updated by several Ph.D. students over the last decade.The theory of fluidization and multiphase flow is based on the new paradigm that emerged in the 1980s as granular flow. Commercial CFD codes, such as FLUENT, already use this theory. However, this theory is not yet complete. Hence the programs described in this text can be easily updated as new theory is developed. For example, the codes can be extended to anisotropic and multi-size particle flow based on the emerging kinetic theories. Hence this book should be useful to research engineers in industry, to graduate students and to professors teaching a first course in computational techniques. In this book the authors illustrate how their code as well as the commercial codes can be used for the design of green energy technology processes.

Table of Contents:
Part I: Numerical methods

Chapter 1: Iteration, pp. 1-30
1.1 Introduction
1.2 Iteration
1.2.1 Algebraic equations
1.2.2 Improved Iteration
1.2.3 Newton-Raphson method Newton-Raphson method graphical interpretation
1.2.4 The Secant method and the method of false position
1.2.5 Improved the Newton-Raphlson method
1.2.6 Example & Computer program
1.3 Linear system
1.3.1 Methods of solution
1.3.2 The row-sum criteria for convergence by total steps
1.4 Algebraic equations
1.4.1 Iteration for algebraic system
1.4.2 Newton-Raphson method for a system of algebraic equations
1.4.3 Numerical example: system of two nonlinear equations

Chapter 2: Interpolation, Differentiation & Integration, pp. 31-46
2.1 Finite differences
2.1.1 Newton’s formula for forward interpolation
2.1.2 Newton’s formula for backward Interpolation
2.1.3 Inverse interpolation
2.1.4 Numerical Differentiation & Integration
2.2 Integration
2.2.1 Simpson’s rule
2.2.2 Quadrature: error analysis - Trapezoidal rule
2.2.3 Product integration
2.3 Finite difference approximations by Taylor expansions

Chapter 3: Ordinary Differential Equations, pp. 47-115
3.1 Initial value problems pp.519-632
3.1.1 Existence and uniqueness: Contraction mapping
3.1.2 Euler’s method (FORTRAN program)
3.1.3 Unstable central difference solution (FORTRAN program)
3.1.4 Error analysis for finite difference (Solution to differential equations)
3.1.5 Truncation error
3.1.6 Stability analysis for a non-linear ordinary differential equation
3.1.7 Finite difference formula with higher order truncation errors
3.1.8 Stability
3.1.9 Consistency, convergence and stability theory
3.1.10 Equivalence of convergence and stability for a consistent scheme
3.1.11 Stability of second difference equation
3.1.12 Nonlinear spring problem
3.1.13 Stability of the nonlinear spring problem
3.1.14 Instability of Patankar’s scheme
3.1.15 Accurate, stable finite difference schemes
3.1.16 Runge-Kutta method
3.1.17 Runge-Kutta for simultaneous equations
3.1.18 Stiff differential equations
3.2 Boundary value problems
3.2.1 Introduction
3.2.2 Illustration of a solution by finite differences
3.2.3 A non-linear boundary value problem
3.2.4 Solution of boundary value problems by Runge-Kutta and Newton-Raphson Methods
3.2.5 Quasilinearization Solution of the Blasius problem-laminar flow over a flat plate Solution by superposition and initial value techniques The Thomas method: tridiagonal matrix inversion
Appendix A: Adiabatic Humidification in Boundary Layer Flow for Nonlinear Boundary Value Problems by Runge-Kutta and Newton-Raphson methods.
Appendix B: Difference Equations

Chapter 4: Numerical Solution of Partial Differential Equations (Solution by finite differences), pp. 117-143
4.1 Solution of the diffusion equation by finite differences
4.1.1 An explicit computational method
4.1.2 Schmidt method
4.1.3 Restriction on the ratio “R” example
4.1.4 Consistency & Errors
4.1.5 Explicit molecule – Stability - Von Neumann Method
4.1.6 Stability of explicit scheme (Alternative method)
4.1.7 An implicit method
4.1.8 Explicit methods using more than two grids
4.1.9 The Crank – Nicolson method – implicit
4.1.10 ADI-method for heat equation
4.1.11 Conditional consistency for Du Fort-Frankel scheme
4.2 Stability theory: System of diffusion equations
4.3 Stability of Navier-Stokes equations
4.3.1 Free convective in a 2-D cavity by finite differences
4.3.2 Finite difference form of the parabolic equations – explicit form
4.3.3 Von Neumann stability for simultaneous PDE

Chapter 5. - Numerical Solution of Partial Differential Equations: Hyperbolic Partial Differential Equations: The Theory of Characteristics, pp. 145-223
5.1 First order partial differential equation
5.1.1 Integration theory
5.1.2 Unsteady plug flow reactor
5.1.3 Separation in a chromatographic column
5.1.4 Linear isotherm: Henry’s law
5.1.5 Dispersion
5.1.6 Shock formation
5.1.7 General first order partial differential equation by characteristics
5.2 Numerical solution of a hyperbolic system of first order partial differential equations
5.2.1 Decoupling of quasi-linear first order PDE
5.2.2 Transient pipe flow
5.2.3 Dimensionless representation of pipe flow
5.2.4 Frictionless flow example
5.2.5 Numerical solution by characteristics
5.2.6 Uniqueness of solution and boundary conditions
5.3 Relation of characteristics to stability
5.4 Partial differential equations theory
5.4.1 Well-posedness of the system
5.4.2 Lax’s equivalence theorem
5.4.3 Relationship between characteristics and stability
5.4.4 Two-step Lax-Wendroff method
5.5 Hyperbolic systems: classical approach
5.5.1 Method of characteristic –finite differences
5.5.2 Classification of a second order partial differential equation-quasi linear
5.5.3 An introduction to the theory of characteristics & classification of PDE
5.6 System of hyperbolic partial differential equations in more than two independent variables
Appendix A: First order partial differential equation
Appendix B: Wave equation
Appendix C: Decoupling method example

Part II Computational Fluidization and Reactor Design

Chapter 1: Experimental Foundation, pp. 227-277
Chapter 2: Elementary Multiphase Kinetic Theory, pp. 279-306
Chapter 3: Multiphase Kinetic Theory of Mixtures, pp. 307-322
Chapter 4: Computation of Flow Regimes for Fluidization, pp. 323-349
Chapter 5: Finite Volume Method for Navier-Stokes Equations, pp. 351-380
Chapter 6: Manual for Computer Programs and Tutorial, pp. 381-469
Chapter 7: Efficient Coal Gasifier-Fuel Cell with CO2 Sequestration, pp. 471-494
Chapter 8: Computation of Mass Transfer Coefficients with Reactions, pp. 495-516

Part III Green’s Functions and Functional Analysis

Chapter 1 : Green’s Functions for Ordinary Differential Equations, pp. 519-546
Chapter 2 : Nonlinear Integral Equations, pp. 547-583
Chapter 3 : Green’s functions for the Laplace’s equation, pp. 585-608
Chapter 4 : Green’s Functions for the diffusion equation, pp. 609-632


      Energy Science, Engineering and Technology
   Binding: Hardcover
   Pub. Date: 2009
   Pages: pp.642
   ISBN: 978-1-60876-024-4
   Status: AV
Status Code Description
AN Announcing
FM Formatting
PP Page Proofs
FP Final Production
EP Editorial Production
PR At Prepress
AP At Press
AV Available
Customers who bought this product also purchased
Computational Techniques: The Multiphase CFD Approach to Fluidization and Green Energy Technologies (includes CD-ROM)
Computational Techniques: The Multiphase CFD Approach to Fluidization and Green Energy Technologies (includes CD-ROM)
Special Focus Titles
01.Violent Communication and Bullying in Early Childhood Education
02.Cultural Considerations in Intervention with Women and Children Exposed to Intimate Partner Violence
03.Chronic Disease and Disability: The Pediatric Lung
04.Fruit and Vegetable Consumption and Health: New Research
05.Fire and the Sword: Understanding the Impact and Challenge of Organized Islamism. Volume 2

Nova Science Publishers
© Copyright 2004 - 2021

Computational Techniques: The Multiphase CFD Approach to Fluidization and Green Energy Technologies (includes CD-ROM)