Transport Phenomena for Chemical Reactor Design

Transport Phenomena for Chemical Reactor Design
by: Laurence A. Belfiore


Description:

Laurence Belfiore’s unique treatment meshes two mainstream subject areas in chemical engineering: transport phenomena and chemical reactor design. Expressly intended as an extension of Bird, Stewart, and Lightfoot’s classic Transport Phenomena, and Froment and Bischoff’s Chemical Reactor Analysis and Design, Second Edition, Belfiore’s unprecedented text explores the synthesis of these two disciplines in a manner the upper undergraduate or graduate reader can readily grasp.

Transport Phenomena for Chemical Reactor Design approaches the design of chemical reactors from microscopic heat and mass transfer principles. It includes simultaneous consideration of kinetics and heat transfer, both critical to the performance of real chemical reactors. Complementary topics in transport phenomena and thermodynamics that provide support for chemical reactor analysis are covered, including:
Fluid dynamics in the creeping and potential flow regimes around solid spheres and gas bubbles
The corresponding mass transfer problems that employ velocity profiles, derived in the book’s fluid dynamics chapter, to calculate interphase heat and mass transfer coefficients
Heat capacities of ideal gases via statistical thermodynamics to calculate Prandtl numbers
Thermodynamic stability criteria for homogeneous mixtures that reveal that binary molecular diffusion coefficients must be positive

In addition to its comprehensive treatment, the text also contains 484 problems and ninety-six detailed solutions to assist in the exploration of the subject. Graduate and advanced undergraduate chemical engineering students, professors, and researchers will appreciate the vision, innovation, and practical application of Laurence Belfiore’s Transport Phenomena for Chemical Reactor Design.

Transport Phenomena

Transport Phenomena, 2nd Edition
by: R. Byron Bird


Description

Transport Phenomenon by Bird, Stewart and Lightfoot is one of the most useful chemical engineering textbook ever written. For nearly five decades now, many chemical engineers have lived by what they learned first through this book. The revised edition makes the book current, though 1960 edition is great introduction to the mass, heat and energy and/or momentum transfer problems.

The basis idea of the book is simple: list the equations useful for a system of problems, say in mass transfer; provide set of assumptions used to arrive at those; suggest possible solutions to the differential equations for practical industry conditions; use correlations derived by researchers where real time data is unavailable and lastly, learn how to adapt solutions for different set of conditions. The book attempts to make problem solving into a set of instructions to be followed, and by sticking to the fundamental assumptions and equations allows one to attack a range of problems relevant to fields as diverse as diffusion transport, biochemical processes, condensation problems for atmospheric physics, chemical kinetics, heat conduction, petroleum extraction and flow of fluids relevant to many processing industries.

We often hailed it as the Bible of Chemical Engineering. Every now and then, (nearly a decade after we first read it) I still hear people say: this problem, or something like it, was in BSL, (the acronym awarded to the book after its authors). Be it Transport texts by Deen or Middleman typically used for graduate school courses, or Incompressible Flow by Patton, the recourse to understanding problems first hand through BSL is always rewarding.

The book comes with a number of solved and unsolved problems. There is no short-cut to becoming a good chemical engineer, except by mastering the art and science of attacking problems. By going through the book meticulously right in your first course, (for in most cases, this is the first chemical engineering text encountered), you can ensure that you will do well in your whole education as chemical engineer.

Recommended reference for all chemical engineers.

Conservation Equations and Modeling of Chemical and Biochemical Processes

Conservation Equations and Modeling of Chemical and Biochemical Processes (Chemical Industries)
by: Said S.E.H. Elnashaie Parag Garhyan

Description

Presenting strategies in control policies, this text uses a systems theory approach to predict, simulate and streamline plant operation, conserve fuel and resources, and increase workplace safety in the manufacturing, chemical, petrochemical, petroleum, biochemical and energy industries. Topics of discussion include system theory and chemical/biochemical engineering systems, steady state, unsteady state, and thermodynamic equilibrium, modeling of systems, fundamental laws governing the processes in terms of the state variables, different classifications of physical models, the story of chemical engineering in relation to system theory and mathematical modeling, overall heat balance with single and multiple chemical reactions and single and multiple reactions.

Table of Contents
Preface
1 System Theory and Chemical/Biochemical Engineering Systems 1
2 Material and Energy Balances 41
3 Mathematical Modeling (I): Homogeneous Lumped Systems 167
4 Mathematical Modeling (II): Homogeneous Distributed Systems and Unsteady-State Behavior 265
5 Process Dynamics and Control 317
6 Heterogeneous Systems 433
7 Practical Relevance of Bifurcation, Instability, and Chaos in Chemical and Biochemical Systems 515
8 Novel Designs for Industrial Chemical/Biochemical Systems 545
App. A Matrices and Matrix Algebra 567
App. B Numerical Methods 589
App. C Analytical Solution of Differential Equations 607
App. D Table of Laplace Transform of Some Common Functions 615
App. E Orthogonal Collocation Technique 619
App. F Some Software and Programming Environments 627
Index 631

Packed Bed Columns

Packed Bed Columns: For absorption, desorption, rectification and direct heat transferby: Nikolai Kolev
Part-1

Packed Bed Columns: For absorption, desorption, rectification and direct heat transferby: Nikolai Kolev
Part-2

Book Description:

Packed bed columns are largely employed for absorption, desorption, rectification and direct heat transfer processes in chemical and food industry, environmental protection and also processes in thermal power stations like water purification, flue gas heat utilization and SO2 removal.
These Separation processes, are estimated to account for 40%-70% of capital and operating costs in process industry. Packed bed columns are widely employed in this area. Their usage also for direct heat transfer between gas and liquid, enlarge their importance. They are the best apparatuses, from thermodynamical point of view, for mass and heat transfer processes between gas and liquid phase.
Their wide spreading is due to low capital investments and operating costs. Since 1995 there has not been published a specialised book in this area, and this is a period of quick development of packed columns. Packed Bed Columns reflects the state of this field including the author's experience on creating and investigating of new packings, column internals and industrial columns.

* Considers the theories of mass transfer processes and shows how they help the construction of highly effective packings
* Complete information about the performance characteristics of different modern types of highly effective packings
* Considers the models for calculation and areas of their application

Mass Transfer: From Fundamentals to Modern Industrial Applications

Mass Transfer: From Fundamentals to Modern Industrial Applications
by: Kenichi Asano

Description

This didactic approach to the principles and modeling of mass transfer as it is needed in modern industrial processes is unique in combining a step–by–step introduction to all important fundamentals with the most recent applications. Based upon the renowned author′s successful new modeling method as used for the O–18 process, the exemplary exercises included in the text are fact–proven, taken directly from existing chemical plants.
Fascinating reading for chemists, graduate students, chemical and process engineers, as well as thermodynamics physicists.