Verfügbarkeit: Rheology in polymer processing

Rheology in polymer processing: modeling and simulation

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Bibliographische Detailangaben
1. Verfasser:	Wilczyński, Krzysztof (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Munich ; Cincinnati, Ohio Hanser [2021]
Schlagworte:	Kunststoffverarbeitung Computersimulation Rheologie Polymere Viskosimetrie Mathematisches Modell Computer modeling Extrusion Injection molding Melt flow Plastic melt Plastics Polymer engineering Polymer melt Polymer processing Polymers Rheological Rheometry FBKTCHEM: Chemie/Physik der Kunststoffe FBKTVEAL: Verarbeitung allgemein PLAS2021
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	XIII, 377 Seiten Illustrationen, Diagramme
ISBN:	9781569906606 1569906602

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Datensatz im Suchindex

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adam_text	PREFACE ...................................................................................................... VII 1 RHEOLOGY ......................................................................................... 1 1.1 FUNDAMENTALS OF CONTINUUM MECHANICS ...................................... 1 1.1.1 STRESS .................................................................................. 1 1.1.2 RATE OF STRAIN ...................................................................... 5 1.1.3 THE CONSERVATION LAWS ...................................................... 8 1.1.3.1 CONSERVATION OF MASS ........................................ 8 1.1.3.2 CONSERVATION OF MOMENTUM ............................ 11 1.1.3.3 CONSERVATION OF ENERGY .................................... 16 1.1.4 CONSTITUTIVE EQUATIONS ...................................................... 21 1.1.5 THE BASIC PROBLEM OF FLUID MECHANICS ............................ 22 1.2 VISCOSITY 23 1.2.1 THE CONCEPT OF VISCOSITY .................................................... 23 1.2.2 NEWTONIAN AND NON-NEWTONIAN FLUIDS ............................ 25 1.2.3 VISCOSITY OF POLYMERS ........................................................ 28 1.2.3.1 EFFECT OF TEMPERATURE ON VISCOSITY ................... 35 1.2.3.2 EFFECT OF PRESSURE ON VISCOSITY ......................... 37 1.2.3.3 EFFECT OF MOLECULAR WEIGHT ON VISCOSITY ........... 38 1.2.3.4 EFFECT OF TIME OF DEFORMATION ON VISCOSITY ... 39 1.2.3.5 EFFECT OF CROSSLINKING ON VISCOSITY ................... 40 1.2.4 RHEOLOGICAL MODELS OF VISCOUS FLUIDS .............................. 40 1.2.4.1 NEWTONIAN FLUID ................................................. 40 1.2.4.2 GENERALIZED NEWTONIAN FLUIDS ........................ 47 1.2.5 MULTIPHASE SYSTEMS OF POLYMERS ...................................... 53 1.3 VISCOELASTICITY .................................................................................. 55 1.3.1 THE CONCEPT OF VISCOELASTICITY .......................................... 55 1.3.2 CHARACTERISTIC PHENOMENA OF VISCOELASTICITY ................... 57 1.3.3 LINEAR VISCOELASTICITY ........................................................ 59 1.3.3.1 THE CONCEPT OF LINEAR VISCOELASTICITY ............... 59 1.3.3.2 MECHANICAL RHEOLOGICAL MODELS ........................ 61 1.3.3.3 TIME EFFECTS OF VISCOELASTICITY .......................... 66 1.3.3.4 THE GENERAL DIFFERENTIAL MODEL OF LINEAR VISCOELASTICITY .................................................... 75 1.3.4 NONLINEAR VISCOELASTICITY .................................................. 76 1.3.4.1 THE CONCEPT OF NONLINEAR VISCOELASTICITY ........ 76 1.3.4.2 NORMAL STRESS DIFFERENCES ................................ 77 1.3.4.3 NORMAL STRESS EFFECTS ........................................ 79 1.3.5 RHEOLOGICAL MODELS OF VISCOELASTIC LIQUIDS .................... 83 1.3.5.1 THE RIVLIN-ERICKSEN MODEL OF SECOND ORDER .. 84 1.3.5.2 THE CRIMINALE-ERICKSEN-FILBEY MODEL ............. 86 1.3.5.3 THE MAXWELL CONVECTIVE MODEL ...................... 86 1.3.5.4 THE WHITE-METZNER MODEL ................................. 86 2 RHEOMETRY ....................................................................................... 89 2.1 THE CONCEPT OF RHEOMETRY .............................................................. 89 2.2 CLASSIFICATION OF RHEOMETRIC METHODS .......................................... 90 2.3 SINGLE-POINT METHODS ...................................................................... 95 2.3.1 MELT FLOW INDEX .................................................................. 95 2.3.2 THE SINGLE-POINT METHOD OF DETERMINATION OF VISCOSITY CURVE .................................................................. 98 2.4 CAPILLARY RHEOMETERS ...................................................................... 99 2.4.1 PRINCIPLE OF OPERATION ........................................................ 99 2.4.2 THEORETICAL BASICS .............................................................. 99 2.4.3 ERRORS OF CAPILLARY RHEOMETRY ........................................... 106 2.4.4 DETERMINATION OF VISCOSITY ................................................ 112 2.4.5 DETERMINATION OF EXTENSIONAL VISCOSITY .......................... 115 2.4.6 DETERMINATION OF NORMAL STRESSES .................................... 116 2.5 CONE-PLATE RHEOMETERS .................................................................... 117 2.5.1 PRINCIPLE OF OPERATION ........................................................ 117 2.5.2 THEORETICAL BASICS .............................................................. 118 2.6 EXTENSIONAL RHEOMETERS .................................................................. 123 2.6.1 PRINCIPLE OF OPERATION ........................................................ 123 2.6.2 THEORETICAL BASICS .............................................................. 124 3 POLYMER PROCESSING ....................................................................... 129 3.1 EXTRUSION .......................................................................................... 129 3.1.1 INTRODUCTION ........................................................................ 129 3.1.2 SINGLE SCREW EXTRUSION ...................................................... 133 3.1.3 TWIN SCREW EXTRUSION ........................................................ 138 3.1.3.1 CO-ROTATING TWIN SCREW EXTRUSION .................. 139 3.1.3.2 COUNTER-ROTATING TWIN SCREW EXTRUSION ........ 140 3.1.4 EXTRUSION DIES ..................................................................... 142 3.2 INJECTION MOLDING ............................................................................ 149 3.2.1 INTRODUCTION ........................................................................ 149 3.2.2 INJECTION MOLDING PROCESS ................................................ 150 3.2.3 INJECTION MOLDS .................................................................. 153 3.2.4 SPECIAL INJECTION MOLDING PROCESSES ................................ 156 3.3 BLOW MOLDING .................................................................................... 157 3.3.1 INTRODUCTION ........................................................................ 157 3.3.2 FILM BLOWING ...................................................................... 158 3.3.3 EXTRUSION BLOW MOLDING .................................................... 159 3.3.4 INJECTION BLOW MOLDING ...................................................... 160 3.4 THERMOFORMING ................................................................................ 161 3.4.1 INTRODUCTION ........................................................................ 161 3.4.2 NEGATIVE THERMOFORMING .................................................. 162 3.4.3 POSITIVE THERMOFORMING .................................................... 163 3.5 CALENDERING ...................................................................................... 164 3.6 COMPRESSION MOLDING ...................................................................... 166 4 PROCESS MODELING .......................................................................... 171 4.1 INTRODUCTION .................................................................................... 171 4.2 SIMPLE FLOWS .................................................................................... 172 4.2.1 PRESSURE FLOWS .................................................................... 172 4.2.1.1 FLOW BETWEEN PARALLEL PLATES .......................... 173 4.2.1.2 FLOW THROUGH A CIRCULAR TUBE .......................... 184 4.2.1.3 FLOW THROUGH A TAPERED CHANNEL .................... 192 4.2.1.4 FLOW THROUGH A CONE ........................................ 193 4.2.1.5 FLOW THROUGH AN ANNULUS ................................ 194 4.2.1.6 DISK FLOW ............................................................ 199 4.2.1.7 HELE-SHAW FLOW .................................................. 204 4.2.2 DRAG FLOWS .......................................................................... 207 4.2.2.1 ISOTHERMAL FLOW BETWEEN PARALLEL PLATES ........ 208 4.2.2.2 NON-ISOTHERMAL FLOW BETWEEN PARALLEL PLATES . 210 4.2.3 PRESSURE-DRAG FLOW BETWEEN PARALLEL PLATES .................... 212 4.3 NUMERICAL METHODS .......................................................................... 214 4.3.1 INTRODUCTION ........................................................................ 214 4.3.2 FINITE DIFFERENCE METHOD .................................................. 215 4.3.2.1 BASIC FORMULATIONS ............................................ 215 4.3.2.2 EXAMPLE OF COMPUTATIONS ................................ 217 5 MODELING OF EXTRUSION ................................................................... 223 5.1 INTRODUCTION ...................................................................................... 223 5.2 SINGLE SCREW EXTRUSION .................................................................. 224 5.2.1 PHYSICAL MODEL OF EXTRUSION .............................................. 224 5.2.2 BASIC ASSUMPTIONS OF EXTRUSION THEORY ........................ 225 5.2.3 SOLID CONVEYING .................................................................. 228 5.2.3.1 SOLID CONVEYING MECHANISM ........................... 228 5.2.3.2 FLOW RATE ............................................................ 230 5.2.3.3 PRESSURE DEVELOPMENT .................................... 231 5.2.4 PLASTICATING .......................................................................... 234 5.2.4.1 PRE-MELTING ........................................................ 234 5.2.4.2 MELTING ................................................................ 236 5.2.5 MELT CONVEYING IN CONVENTIONAL SCREWS .......................... 245 5.2.5.1 CLASSIFICATION OF MODELS ................................... 245 5.2.5.2 NEWTONIAN MODEL ............................................... 246 5.2.5.3 NON-NEWTONIAN MODEL ....................................... 255 5.2.6 MELT CONVEYING IN NON-CONVENTIONAL SCREWS ................... 257 5.2.6.1 DISPERSIVE MIXING ELEMENTS ............................. 257 5.2.6.2 DISTRIBUTIVE MIXING ELEMENTS ........................ 260 5.2.7 CHARACTERISTICS OF EXTRUDER OPERATION .............................. 262 5.3 EXTRUSION DIES .................................................................................. 265 5.3.1 CLASSIFICATION OF DIES .......................................................... 265 5.3.2 METHODOLOGY OF MODELING .................................................. 266 5.3.2.1 GENERAL ASSUMPTIONS ......................................... 266 5.3.2.2 NEWTONIAN MODEL .............................................. 268 5.3.2.3 NON-NEWTONIAN MODEL ....................................... 270 5.3.2.4 THE CONCEPT OF REPRESENTATIVE VISCOSITY .... 271 5.3.3 CIRCULAR DIES ...................................................................... 273 5.3.4 SLIT DIES .............................................................................. 273 5.3.5 ANNULAR DIES ...................................................................... 278 5.3.5.1 CENTER FED MANDREL DIES ................................. 279 5.3.5.2 SIDE FED MANDREL DIES ...................................... 279 5.3.6 PROFILE DIES .......................................................................... 286 5.3.6.1 COMPUTATION BY CROSS-SECTION DIVISION .......... 286 5.3.6.2 COMPUTATION BY SHAPE CORRECTION ................... 289 5.4 GLOBAL MODELING .............................................................................. 292 6 COMPUTER MODELING FOR POLYMER PROCESSING ........................... 295 6.1 OVERVIEW OF COMPUTER MODELING SOFTWARE .................................... 295 6.2 CFD MODELING .................................................................................. 297 CO-AUTHORED BY ADRIAN LEWANDOWSKI 6.2.1 ANSYS POLYFLOW - PROGRAM OVERVIEW .............................. 297 6.2.2 MODELING PROCEDURE .......................................................... 298 6.2.3 EXAMPLES OF MODELING ........................................................ 300 6.2.3.1 PRESSURE FLOW .................................................... 300 6.2.3.2 EXTRUDATE SWELL .................................................. 317 6.2.3.3 EXTRUDATE SWELL INVERSE PROBLEM .................... 321 6.2.3.4 SINGLE SCREW EXTRUSION .................................... 325 6.2.3.5 CO-ROTATING TWIN SCREW EXTRUSION .................. 332 6.2.3.6 COUNTER-ROTATING TWIN SCREW EXTRUSION ........ 339 6.3 INJECTION MOLDING ............................................................................ 348 CO-AUTHORED BY KRZYSZTOF J. WILCZYNSKI 6.3.1 AUTODESK MOLDFLOW - PROGRAM OVERVIEW ........................ 348 6.3.2 MODELING PROCEDURE .......................................................... 349 6.3.3 EXAMPLES OF MODELING ........................................................ 350 6.3.3.1 GATE LOCATION ...................................................... 350 6.3.3.2 FILLING ANALYSIS .................................................. 351 6.3.3.3 FLOW BALANCING .................................................. 352 6.3.3.4 MELT FLIPPER ........................................................ 354 6.4 EXTRUSION .......................................................................................... 359 CO-AUTHORED BY ANDRZEJ NASTAJ 6AA MULTI-SCREW SYSTEM - PROGRAM OVERVIEW ................... 359 6.4.2 MODELING PROCEDURE .......................................................... 361 6.4.3 EXAMPLES OF MODELING ........................................................ 361 6.4.3.1 SINGLE SCREW EXTRUSION .................................... 361 6.4.3.2 TWIN SCREW EXTRUSION ...................................... 368 INDEX .......................................................................................................... 373
adam_txt	PREFACE . VII 1 RHEOLOGY . 1 1.1 FUNDAMENTALS OF CONTINUUM MECHANICS . 1 1.1.1 STRESS . 1 1.1.2 RATE OF STRAIN . 5 1.1.3 THE CONSERVATION LAWS . 8 1.1.3.1 CONSERVATION OF MASS . 8 1.1.3.2 CONSERVATION OF MOMENTUM . 11 1.1.3.3 CONSERVATION OF ENERGY . 16 1.1.4 CONSTITUTIVE EQUATIONS . 21 1.1.5 THE BASIC PROBLEM OF FLUID MECHANICS . 22 1.2 VISCOSITY 23 1.2.1 THE CONCEPT OF VISCOSITY . 23 1.2.2 NEWTONIAN AND NON-NEWTONIAN FLUIDS . 25 1.2.3 VISCOSITY OF POLYMERS . 28 1.2.3.1 EFFECT OF TEMPERATURE ON VISCOSITY . 35 1.2.3.2 EFFECT OF PRESSURE ON VISCOSITY . 37 1.2.3.3 EFFECT OF MOLECULAR WEIGHT ON VISCOSITY . 38 1.2.3.4 EFFECT OF TIME OF DEFORMATION ON VISCOSITY . 39 1.2.3.5 EFFECT OF CROSSLINKING ON VISCOSITY . 40 1.2.4 RHEOLOGICAL MODELS OF VISCOUS FLUIDS . 40 1.2.4.1 NEWTONIAN FLUID . 40 1.2.4.2 GENERALIZED NEWTONIAN FLUIDS . 47 1.2.5 MULTIPHASE SYSTEMS OF POLYMERS . 53 1.3 VISCOELASTICITY . 55 1.3.1 THE CONCEPT OF VISCOELASTICITY . 55 1.3.2 CHARACTERISTIC PHENOMENA OF VISCOELASTICITY . 57 1.3.3 LINEAR VISCOELASTICITY . 59 1.3.3.1 THE CONCEPT OF LINEAR VISCOELASTICITY . 59 1.3.3.2 MECHANICAL RHEOLOGICAL MODELS . 61 1.3.3.3 TIME EFFECTS OF VISCOELASTICITY . 66 1.3.3.4 THE GENERAL DIFFERENTIAL MODEL OF LINEAR VISCOELASTICITY . 75 1.3.4 NONLINEAR VISCOELASTICITY . 76 1.3.4.1 THE CONCEPT OF NONLINEAR VISCOELASTICITY . 76 1.3.4.2 NORMAL STRESS DIFFERENCES . 77 1.3.4.3 NORMAL STRESS EFFECTS . 79 1.3.5 RHEOLOGICAL MODELS OF VISCOELASTIC LIQUIDS . 83 1.3.5.1 THE RIVLIN-ERICKSEN MODEL OF SECOND ORDER . 84 1.3.5.2 THE CRIMINALE-ERICKSEN-FILBEY MODEL . 86 1.3.5.3 THE MAXWELL CONVECTIVE MODEL . 86 1.3.5.4 THE WHITE-METZNER MODEL . 86 2 RHEOMETRY . 89 2.1 THE CONCEPT OF RHEOMETRY . 89 2.2 CLASSIFICATION OF RHEOMETRIC METHODS . 90 2.3 SINGLE-POINT METHODS . 95 2.3.1 MELT FLOW INDEX . 95 2.3.2 THE SINGLE-POINT METHOD OF DETERMINATION OF VISCOSITY CURVE . 98 2.4 CAPILLARY RHEOMETERS . 99 2.4.1 PRINCIPLE OF OPERATION . 99 2.4.2 THEORETICAL BASICS . 99 2.4.3 ERRORS OF CAPILLARY RHEOMETRY . 106 2.4.4 DETERMINATION OF VISCOSITY . 112 2.4.5 DETERMINATION OF EXTENSIONAL VISCOSITY . 115 2.4.6 DETERMINATION OF NORMAL STRESSES . 116 2.5 CONE-PLATE RHEOMETERS . 117 2.5.1 PRINCIPLE OF OPERATION . 117 2.5.2 THEORETICAL BASICS . 118 2.6 EXTENSIONAL RHEOMETERS . 123 2.6.1 PRINCIPLE OF OPERATION . 123 2.6.2 THEORETICAL BASICS . 124 3 POLYMER PROCESSING . 129 3.1 EXTRUSION . 129 3.1.1 INTRODUCTION . 129 3.1.2 SINGLE SCREW EXTRUSION . 133 3.1.3 TWIN SCREW EXTRUSION . 138 3.1.3.1 CO-ROTATING TWIN SCREW EXTRUSION . 139 3.1.3.2 COUNTER-ROTATING TWIN SCREW EXTRUSION . 140 3.1.4 EXTRUSION DIES . 142 3.2 INJECTION MOLDING . 149 3.2.1 INTRODUCTION . 149 3.2.2 INJECTION MOLDING PROCESS . 150 3.2.3 INJECTION MOLDS . 153 3.2.4 SPECIAL INJECTION MOLDING PROCESSES . 156 3.3 BLOW MOLDING . 157 3.3.1 INTRODUCTION . 157 3.3.2 FILM BLOWING . 158 3.3.3 EXTRUSION BLOW MOLDING . 159 3.3.4 INJECTION BLOW MOLDING . 160 3.4 THERMOFORMING . 161 3.4.1 INTRODUCTION . 161 3.4.2 NEGATIVE THERMOFORMING . 162 3.4.3 POSITIVE THERMOFORMING . 163 3.5 CALENDERING . 164 3.6 COMPRESSION MOLDING . 166 4 PROCESS MODELING . 171 4.1 INTRODUCTION . 171 4.2 SIMPLE FLOWS . 172 4.2.1 PRESSURE FLOWS . 172 4.2.1.1 FLOW BETWEEN PARALLEL PLATES . 173 4.2.1.2 FLOW THROUGH A CIRCULAR TUBE . 184 4.2.1.3 FLOW THROUGH A TAPERED CHANNEL . 192 4.2.1.4 FLOW THROUGH A CONE . 193 4.2.1.5 FLOW THROUGH AN ANNULUS . 194 4.2.1.6 DISK FLOW . 199 4.2.1.7 HELE-SHAW FLOW . 204 4.2.2 DRAG FLOWS . 207 4.2.2.1 ISOTHERMAL FLOW BETWEEN PARALLEL PLATES . 208 4.2.2.2 NON-ISOTHERMAL FLOW BETWEEN PARALLEL PLATES . 210 4.2.3 PRESSURE-DRAG FLOW BETWEEN PARALLEL PLATES . 212 4.3 NUMERICAL METHODS . 214 4.3.1 INTRODUCTION . 214 4.3.2 FINITE DIFFERENCE METHOD . 215 4.3.2.1 BASIC FORMULATIONS . 215 4.3.2.2 EXAMPLE OF COMPUTATIONS . 217 5 MODELING OF EXTRUSION . 223 5.1 INTRODUCTION . 223 5.2 SINGLE SCREW EXTRUSION . 224 5.2.1 PHYSICAL MODEL OF EXTRUSION . 224 5.2.2 BASIC ASSUMPTIONS OF EXTRUSION THEORY . 225 5.2.3 SOLID CONVEYING . 228 5.2.3.1 SOLID CONVEYING MECHANISM . 228 5.2.3.2 FLOW RATE . 230 5.2.3.3 PRESSURE DEVELOPMENT . 231 5.2.4 PLASTICATING . 234 5.2.4.1 PRE-MELTING . 234 5.2.4.2 MELTING . 236 5.2.5 MELT CONVEYING IN CONVENTIONAL SCREWS . 245 5.2.5.1 CLASSIFICATION OF MODELS . 245 5.2.5.2 NEWTONIAN MODEL . 246 5.2.5.3 NON-NEWTONIAN MODEL . 255 5.2.6 MELT CONVEYING IN NON-CONVENTIONAL SCREWS . 257 5.2.6.1 DISPERSIVE MIXING ELEMENTS . 257 5.2.6.2 DISTRIBUTIVE MIXING ELEMENTS . 260 5.2.7 CHARACTERISTICS OF EXTRUDER OPERATION . 262 5.3 EXTRUSION DIES . 265 5.3.1 CLASSIFICATION OF DIES . 265 5.3.2 METHODOLOGY OF MODELING . 266 5.3.2.1 GENERAL ASSUMPTIONS . 266 5.3.2.2 NEWTONIAN MODEL . 268 5.3.2.3 NON-NEWTONIAN MODEL . 270 5.3.2.4 THE CONCEPT OF REPRESENTATIVE VISCOSITY . 271 5.3.3 CIRCULAR DIES . 273 5.3.4 SLIT DIES . 273 5.3.5 ANNULAR DIES . 278 5.3.5.1 CENTER FED MANDREL DIES . 279 5.3.5.2 SIDE FED MANDREL DIES . 279 5.3.6 PROFILE DIES . 286 5.3.6.1 COMPUTATION BY CROSS-SECTION DIVISION . 286 5.3.6.2 COMPUTATION BY SHAPE CORRECTION . 289 5.4 GLOBAL MODELING . 292 6 COMPUTER MODELING FOR POLYMER PROCESSING . 295 6.1 OVERVIEW OF COMPUTER MODELING SOFTWARE . 295 6.2 CFD MODELING . 297 CO-AUTHORED BY ADRIAN LEWANDOWSKI 6.2.1 ANSYS POLYFLOW - PROGRAM OVERVIEW . 297 6.2.2 MODELING PROCEDURE . 298 6.2.3 EXAMPLES OF MODELING . 300 6.2.3.1 PRESSURE FLOW . 300 6.2.3.2 EXTRUDATE SWELL . 317 6.2.3.3 EXTRUDATE SWELL INVERSE PROBLEM . 321 6.2.3.4 SINGLE SCREW EXTRUSION . 325 6.2.3.5 CO-ROTATING TWIN SCREW EXTRUSION . 332 6.2.3.6 COUNTER-ROTATING TWIN SCREW EXTRUSION . 339 6.3 INJECTION MOLDING . 348 CO-AUTHORED BY KRZYSZTOF J. WILCZYNSKI 6.3.1 AUTODESK MOLDFLOW - PROGRAM OVERVIEW . 348 6.3.2 MODELING PROCEDURE . 349 6.3.3 EXAMPLES OF MODELING . 350 6.3.3.1 GATE LOCATION . 350 6.3.3.2 FILLING ANALYSIS . 351 6.3.3.3 FLOW BALANCING . 352 6.3.3.4 MELT FLIPPER . 354 6.4 EXTRUSION . 359 CO-AUTHORED BY ANDRZEJ NASTAJ 6AA MULTI-SCREW SYSTEM - PROGRAM OVERVIEW . 359 6.4.2 MODELING PROCEDURE . 361 6.4.3 EXAMPLES OF MODELING . 361 6.4.3.1 SINGLE SCREW EXTRUSION . 361 6.4.3.2 TWIN SCREW EXTRUSION . 368 INDEX . 373
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id	DE-604.BV047065292
illustrated	Illustrated
index_date	2024-07-03T16:12:28Z
indexdate	2024-07-10T09:01:36Z
institution	BVB
institution_GND	(DE-588)1064064051
isbn	9781569906606 1569906602
language	English
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-032472398
oclc_num	1227508163
open_access_boolean
owner	DE-210 DE-91 DE-BY-TUM DE-12 DE-703
owner_facet	DE-210 DE-91 DE-BY-TUM DE-12 DE-703
physical	XIII, 377 Seiten Illustrationen, Diagramme
publishDate	2021
publishDateSearch	2021
publishDateSort	2021
publisher	Hanser
record_format	marc
spelling	Wilczyński, Krzysztof Verfasser (DE-588)1226112145 aut Rheology in polymer processing modeling and simulation Krzysztof Wilczyński Munich ; Cincinnati, Ohio Hanser [2021] © 2021 XIII, 377 Seiten Illustrationen, Diagramme txt rdacontent n rdamedia nc rdacarrier Kunststoffverarbeitung (DE-588)4114335-8 gnd rswk-swf Computersimulation (DE-588)4148259-1 gnd rswk-swf Rheologie (DE-588)4049828-1 gnd rswk-swf Polymere (DE-588)4046699-1 gnd rswk-swf Viskosimetrie (DE-588)4188415-2 gnd rswk-swf Mathematisches Modell (DE-588)4114528-8 gnd rswk-swf Computer modeling Extrusion Injection molding Melt flow Plastic melt Plastics Polymer engineering Polymer melt Polymer processing Polymers Rheological Rheologie Rheometry FBKTCHEM: Chemie/Physik der Kunststoffe FBKTVEAL: Verarbeitung allgemein PLAS2021 Polymere (DE-588)4046699-1 s Kunststoffverarbeitung (DE-588)4114335-8 s Rheologie (DE-588)4049828-1 s Viskosimetrie (DE-588)4188415-2 s Mathematisches Modell (DE-588)4114528-8 s Computersimulation (DE-588)4148259-1 s DE-604 Hanser Publications (DE-588)1064064051 pbl Erscheint auch als Online-Ausgabe 978-1-56990-661-3 DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=032472398&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p vlb 20201111 DE-101 https://d-nb.info/provenance/plan#vlb
spellingShingle	Wilczyński, Krzysztof Rheology in polymer processing modeling and simulation Kunststoffverarbeitung (DE-588)4114335-8 gnd Computersimulation (DE-588)4148259-1 gnd Rheologie (DE-588)4049828-1 gnd Polymere (DE-588)4046699-1 gnd Viskosimetrie (DE-588)4188415-2 gnd Mathematisches Modell (DE-588)4114528-8 gnd
subject_GND	(DE-588)4114335-8 (DE-588)4148259-1 (DE-588)4049828-1 (DE-588)4046699-1 (DE-588)4188415-2 (DE-588)4114528-8
title	Rheology in polymer processing modeling and simulation
title_auth	Rheology in polymer processing modeling and simulation
title_exact_search	Rheology in polymer processing modeling and simulation
title_exact_search_txtP	Rheology in polymer processing modeling and simulation
title_full	Rheology in polymer processing modeling and simulation Krzysztof Wilczyński
title_fullStr	Rheology in polymer processing modeling and simulation Krzysztof Wilczyński
title_full_unstemmed	Rheology in polymer processing modeling and simulation Krzysztof Wilczyński
title_short	Rheology in polymer processing
title_sort	rheology in polymer processing modeling and simulation
title_sub	modeling and simulation
topic	Kunststoffverarbeitung (DE-588)4114335-8 gnd Computersimulation (DE-588)4148259-1 gnd Rheologie (DE-588)4049828-1 gnd Polymere (DE-588)4046699-1 gnd Viskosimetrie (DE-588)4188415-2 gnd Mathematisches Modell (DE-588)4114528-8 gnd
topic_facet	Kunststoffverarbeitung Computersimulation Rheologie Polymere Viskosimetrie Mathematisches Modell
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=032472398&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT wilczynskikrzysztof rheologyinpolymerprocessingmodelingandsimulation AT hanserpublications rheologyinpolymerprocessingmodelingandsimulation

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