Completely rewritten to enhance clarity, this third edition provides engineers with a strong understanding of the field. With the help of an additional co-author, the text presents new information on bioseparations throughout the chapters.
About The Book: Updated to reflect advances in the field, the second edition of this highly respected text examines rate-based and equilibrium-based approaches to separation operations. Today, chemical engineering students need a thorough understanding of momentum, heat, mass transfer and separation processes.
This volume offers a unified and up-to-date treatment of all these topics. This edition's extensive updates and enhancements include: A more thorough coverage of momentum, heat, and mass transport processes Detailed new coverage of separation process applications Greatly expanded coverage of momentum transfer, The third edition has been completely rewritten to enhance clarity Provides a comprehensive treatment of the major separation operations in the chemical industry Contains examples, homework exercises, and more that 1, references.
This edition provides New chapter objectives and summaries throughout Better linkages between coverage of heat and mass transfer More coverage of heat exchanger design New problems based on emerging topics such as biotechnology, This much-needed book presents a clear and very practice-oriented overview of thermal separation processes.
Coverage includes: Essential engineering principles and units Principles of momentum transfer, overall balances, and application Heat transfer, steady-state conduction, unsteady-state heat transfer, convection, heat exchangers, and Cram Just the FACTS studyguides gives all of the outlines, highlights, and quizzes for your textbook with optional online comprehensive practice tests.
Only Cram is Textbook Specific. Accompanies: This second edition reflects these changes. Author : J. Covers the key topics in computer organization and embedded systems. The 3rd edition focuses on using process simulators to design separation processes and prepares readers for professional practice. A new chapter on mechanical separations covers settling, filtration and centrifugation including mechanical separations in biotechnology and cell lysis.
Boxes help highlight fundamental equations. Numerous new examples and exercises are integrated throughout as well. It describes the fundamentals of all separation operations of commercial interest, and includes theory and application examples in each chapter, as well as over exercises.
This edition-reorganized and modularized for better readability and to align with modern chemical engineering curricula-covers both fundamental principles and practical applications, and is a key resource for chemical engineering students and professionals alike. This edition provides New chapter objectives and summaries throughout Better linkages between coverage of heat and mass transfer More coverage of heat exchanger design New problems based on emerging topics such as biotechnology, nanotechnology, and green engineering New instructor resources: additional homework problems, exam questions, problem-solving videos, computational projects, and more Part 1 thoroughly covers the fundamental principles of transport phenomena, organized into three sections: fluid mechanics, heat transfer, and mass transfer.
Part 2 focuses on key separation processes, including absorption, stripping, humidification, filtration, membrane separation, gaseous membranes, distillation, liquid--liquid extraction, adsorption, ion exchange, crystallization and particle-size reduction, settling, sedimentation, centrifugation, leaching, evaporation, and drying.
The authors conclude with convenient appendices on the properties of water, compounds, foods, biological materials, pipes, tubes, and screens. The companion website trine. First semester covers fluid mechanics, heat and mass transfer; second semester covers separation process principles includes unit operations. This was done because the term Unit Operations has been largely superseded by the term Separation Processes which better reflects the present modern nomenclature being used.
The main objectives and the format of the Fourth Edition remain the same. The sections on momentum transfer have been greatly expanded, especially in the sections on fluidized beds, flow meters, mixing, and non-Newtonian fluids. Material has been added to the chapter on mass transfer.
The chapters on absorption, distillation, and liquid-liquid extraction have also been enlarged. More new material has been added to the sections on ion exchange and crystallization. The chapter on membrane separation processes has been greatly expanded especially for gas-membrane theory.
With the help of an additional co—author, the text presents new information on bioseparations throughout the chapters. A new chapter on mechanical separations covers settling, filtration, and centrifugation, including mechanical separations in biotechnology and cell lysis. In addition, frequent references are made to the software products and simulators that will help engineers find the solutions they need.
An extensive introduction elucidates the physical and physicochemical fundamentals of different unit operations used to separate homogenous mixtures. This is followed by a concise text with numerous explanatory figures and tables referring to process and design, flowsheets, basic engineering and examples of separation process applications. Very helpful guidance in the form of process descriptions, calculation models and operation data is presented in an easy-to- understand manner thereby assisting the practicing engineer in the choosing and evaluation of separation processes and facilitating the modeling and design of innovative equipment.
A comprehensive reference list provides further opportunity for the following up of special separation problems. Chemical and mechanical engineers, chemists, physicists and biotechnologists in research and development, plant design and environmental protection, as well as students in chemical engineering and natural sciences will find this all-embracing reference guide of tremendous value and practical use.
This edition—reorganized and modularized for better readability and to align with modern chemical engineering curricula—covers both fundamental principles and practical applications, and is a key resource for chemical engineering students and professionals alike.
Part 2 focuses on key separation processes, including absorption, stripping, humidification, filtration, membrane separation, gaseous membranes, distillation, liquid—liquid extraction, adsorption, ion exchange, crystallization and particle-size reduction, settling, sedimentation, centrifugation, leaching, evaporation, and drying.
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