Introduction to Polymer Rheology
ISBN: 9780470388440 | 0470388447
Edition: 1stFormat: Hardcover
Publisher: Wiley
Pub. Date: 1/3/2012
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Providing new students and practitioners with an easy-to-understand introduction to the theory and practice an often complicated subject, Introduction to Polymer Rheology incorporates worked problems and problems with appended answers to provide opportunities for review and further learning of more advanced concepts.
An introduction to the rheology of polymers, with simple math Designed for practicing scientists and engineers interested in polymer rheology science, education, consulting, or research and development... MORE
An introduction to the rheology of polymers, with simple math Designed for practicing scientists and engineers interested in polymer rheology science, education, consulting, or research and development... MORE
| Introduction | p. 1 |
| Polymers and the importance of rheology | p. 1 |
| Rheology in its simplest form | p. 9 |
| Problems | p. 12 |
| Suggested references, with commentary | p. 13 |
| Stress | p. 15 |
| Stress and pressure | p. 16 |
| Organization of the stress components | p. 30 |
| Coping with subscripts | p. 31 |
| Typical stress tensors | p. 32 | ... MORE
| Compilation of equations of motion (ssc) | p. 38 |
| Equations of motion-curvilinear quick list (ssc) | p. 40 |
| Problems | p. 40 |
| References | p. 44 |
| Velocity, Velocity Gradient and Rate of Deformation | p. 45 |
| Why velocity is simpler than location-Speedometers vs. GPS | p. 45 |
| Velocity gradients | p. 46 |
| Rate of deformation | p. 48 |
| Components of the rate-of-deformation tensor | p. 52 |
| Components of the continuity equation | p. 53 |
| Nomenclature and sign conventions used in popular rheology texts | p. 53 |
| Problems | p. 54 |
| References | p. 57 |
| Relationship Between Stress and Rate of Deformation: The Newtonian Fluid | p. 59 |
| Material idealizations in rheology | p. 59 |
| The Newtonian fluid | p. 63 |
| Problems | p. 68 |
| References | p. 70 |
| Generalized Newtonian Fluids-A Small But Important Step Toward a Description of Real Behavior for Polymers | p. 71 |
| Reasons for inventing generalized Newtonian fluids-behavior of polymer melts | p. 72 |
| Generalizing the GNF to three dimensions | p. 77 |
| Inventing relationships for viscosity vs. shear rate | p. 82 |
| Short primer on finding GNF parameters from data | p. 86 |
| Summary of GNF characteristics | p. 90 |
| Fitting data with ExcelŽ | p. 90 |
| Problems | p. 92 |
| References | p. 96 |
| Normal Stresses-Ordinary Behavior for Polymers | p. 97 |
| Introduction | p. 97 |
| What are normal stresses? | p. 98 |
| Origin of normal stresses in simple shear | p. 99 |
| The second normal-stress difference | p. 102 |
| Normal-stress coefficients and empirical findings | p. 103 |
| Transient rheological functions | p. 107 |
| Temperature effects and superposition of steady-flow data | p. 109 |
| Problems | p. 116 |
| References | p. 122 |
| Experimental Methods | p. 125 |
| Measurement of viscosity | p. 126 |
| Normal stresses from shearing flows | p. 149 |
| Extensional rheology | p. 155 |
| Specialized geometries | p. 162 |
| Flow visualization and other rheo-optical methods | p. 165 |
| Micro and nano rheology | p. 171 |
| Numerical derivatives | p. 174 |
| Velocity-profile correction for non-Newtonian fluids | p. 176 |
| Incorporation of slip into the velocity-profile correction-the Mooney correction | p. 179 |
| Normal stresses using the cone-and-plate geometry | p. 180 |
| Desktop rheo-optical experiment | p. 184 |
| Problems | p. 186 |
| References | p. 193 |
| Strain, Small and Large | p. 197 |
| Displacement | p. 197 |
| Infinitesimal strain | p. 201 |
| Hookean solids | p. 208 |
| Finite strain | p. 210 |
| The Lodge elastic fluid and variants | p. 214 |
| The Cauchy strain measure | p. 219 |
| Fixing up integral equations based on C and C-1 | p. 222 |
| The relaxation function | p. 226 |
| Constant-rate extension of the LEF | p. 227 |
| Problems | p. 233 |
| References | p. 238 |
| Molecular Origins of Rheological Behavior | p. 239 |
| Description of polymer molecules | p. 239 |
| The Rouse chain-a limited description of polymer behavior | p. 241 |
| Other chain-like models | p. 242 |
| Dealing with entanglements | p. 248 |
| Summary of predictions of molecular theory | p. 255 |
| Problems | p. 256 |
| References | p. 259 |
| Elementary Polymer Processing Concepts | p. 261 |
| Simple laboratory processing methods | p. 261 |
| Elementary extrusion concepts | p. 271 |
| A downstream process-spinning | p. 281 |
| Summary | p. 284 |
| Densities of melts at elevated temperatures | p. 284 |
| Problems | p. 286 |
| References | p. 290 |
| Quality-Control Rheology | p. 291 |
| Examples of methods used by various industries | p. 292 |
| Test precision | p. 297 |
| ASTM tests methods for rheological characterization | p. 302 |
| Problems | p. 305 |
| References | p. 308 |
| Flow of Modified Polymers and Polymers with Supermolecular Structure | p. 311 |
| Polymers filled with particulates | p. 311 |
| Liquid crystallinity and rheology | p. 321 |
| Polymers with microphase separation in melts or solutions | p. 323 |
| Covalent crosslinking of polymers | p. 327 |
| Van't Hoff equation applied to gelation | p. 329 |
| Problems | p. 330 |
| References | p. 335 |
| Answers to Selected Problems | p. 337 |
| p. 337 | |
| p. 339 | |
| p. 342 | |
| p. 345 | |
| p. 350 | |
| p. 352 | |
| p. 357 | |
| p. 362 | |
| p. 371 | |
| p. 372 | |
| p. 375 | |
| p. 377 | |
| p. 381 | |
| p. 382 | |
| Author Index | p. 385 |
| Subject Index | p. 391 |
| Table of Contents provided by Ingram. All Rights Reserved. |
Montgomery T. Shaw, PhD, is the DiBenedetto Distinguished Professor Emeritus at the University of Connecticut in Storrs, Connecticut. He is a coauthor of Introduction to Polymer Viscoelasticity, Third Edition, also published by Wiley.
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