Overview
- Authors:
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John Happel
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Department of Chemical Engineering and Applied Chemistry, Columbia University, New York, USA
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Howard Brenner
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Department of Chemical Engineering, Cambridge, USA
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Table of contents (9 chapters)
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- John Happel, Howard Brenner
Pages 1-22
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- John Happel, Howard Brenner
Pages 23-57
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- John Happel, Howard Brenner
Pages 58-95
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- John Happel, Howard Brenner
Pages 96-158
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- John Happel, Howard Brenner
Pages 159-234
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- John Happel, Howard Brenner
Pages 235-285
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- John Happel, Howard Brenner
Pages 286-357
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- John Happel, Howard Brenner
Pages 358-430
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- John Happel, Howard Brenner
Pages 431-473
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Back Matter
Pages 474-553
About this book
One studying the motion of fluids relative to particulate systems is soon impressed by the dichotomy which exists between books covering theoretical and practical aspects. Classical hydrodynamics is largely concerned with perfect fluids which unfortunately exert no forces on the particles past which they move. Practical approaches to subjects like fluidization, sedimentation, and flow through porous media abound in much useful but uncorrelated empirical information. The present book represents an attempt to bridge this gap by providing at least the beginnings of a rational approach to fluid particle dynamics, based on first principles. From the pedagogic viewpoint it seems worthwhile to show that the Navier-Stokes equations, which form the basis of all systematic texts, can be employed for useful practical applications beyond the elementary problems of laminar flow in pipes and Stokes law for the motion of a single particle. Although a suspension may often be viewed as a continuum for practical purposes, it really consists of a discrete collection of particles immersed in an essentially continuous fluid. Consideration of the actual detailed boundary value problems posed by this viewpoint may serve to call attention to the limitation of idealizations which apply to the overall transport properties of a mixture of fluid and solid particles.
Authors and Affiliations
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Department of Chemical Engineering and Applied Chemistry, Columbia University, New York, USA
John Happel
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Department of Chemical Engineering, Cambridge, USA
Howard Brenner