Verfügbarkeit: Materials science of polymers for engineers

Materials science of polymers for engineers:

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Bibliographische Detailangaben
1. Verfasser:	Osswald, Tim A. 1958- (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Munich Hanser [u.a.] 2003
Ausgabe:	2. ed.
Schlagworte:	Matières plastiques Polymères Plastics Polymers Stoffeigenschaft Kunststoff Werkstoffkunde Polymere Lehrbuch
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	XVIII, 622 S. graph. Darst.
ISBN:	1569903484 3446224645

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Datensatz im Suchindex

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adam_text	Table of Contents Part I Basic Principles ....................................................................................... 1 1 Introduction to Polymers .................................................................................. З 1.1 General Properties ............................................................................. З 1.2 Identification of Polymers ................................................................10 Problems .......................................................................................13 References .......................................................................................13 2. Historical Background .......................................................................................15 2.1 From Natural to Synthetic Rubber .................................................15 2.2 Cellulose and the $10,000 Idea .........................................................21 2.3 Galalith - The Milk Stone ..................................................................24 2.4 Leo Baekeland and the Plastic Industry .........................................25 2.5 Herman Mark and the American Polymer Education .................27 2.6 Wallace Hume Carothers and Synthetic Polymers ......................31 2.7 Polyethylene - A Product of Brain and Brawn ..............................34 2.8 The Super Fiber and the Woman who Invented it .......................37 2.9 One last Word - Plastics ....................................................................38 References .......................................................................................41 3 Structure of Polymers .......................................................................................43 3.1 Macromolecular Structure of Polymers .........................................43 3.2 Molecular Bonds and Inter-Molecular Attraction ........................45 3.3 Molecular Weight ..............................................................................45 3.4 Conformation and Configuration of Polymer Molecules ..........51 3.5 Arrangement of Polymer Molecules ..............................................55 3.5.1 Thermoplastic Polymers .......................................................55 3.5.2 Amorphous Thermoplastics .................................................56 3.5.3 Semi-Crystalline Thermoplastics ........................................58 3.5.4 Thermosets and Cross-Linked Elastomers ........................67 3.6 Copolymers and Polymer Blends ...................................................68 3.7 Polymer Additves ..............................................................................71 3.7.1 Flame Retardants ...................................................................71 3.7.2 Stabilizers ................................................................................73 3.7.3 Antistatic Agents ....................................................................74 3.7.4 Fillers .......................................................................................74 3.7.5 Blowing Agents ......................................................................75 3.8 Viscoelastic Behavior of Polymers .................................................76 3.8.1 Stress Relaxation Test ............................................................76 3.8.2 Time-Temperature Superposition (WLF-Equationa) .......78 3.8.3 The Boltzmann Superposition Principle ............................80 xii Table of Contents 3.8.4 Applying Linear Viscoelasticity to Describe the behavior of Polymers ............................................................81 Examples .......................................................................................88 Problems .......................................................................................91 References .......................................................................................94 Thermal Properties of Polymers .....................................................................97 4.1 Material Properties ..........................................................................100 4.1.1 Thermal Conductivity .........................................................100 4.1.2 Specific Heat ..........................................................................107 4.1.3 Density ...................................................................................109 4.1.4 Thermal Diffusivity .............................................................112 4.1.5 Linear Coefficient of Thermal Expansion ........................113 4.1.6 Thermal Penetration ............................................................115 4.1.7 Glass Transition Temperature ...........................................115 4.1.8 Melting Temperature ..........................................................116 4.2 Measuring Thermal Data ................................................................116 4.2.1 Differential Thermal Analysis (DTA) ...............................117 4.2.2 Differential Scanning Calorimeter (DSC) ........................118 4.2.3 Thermomechanical Analysis (TMA) .................................120 4.2.4 Thermogravimetry (TGA) ..................................................121 4.2.5 Density Measurements ........................................................122 Examples .....................................................................................123 Problems .....................................................................................124 References .....................................................................................128 Rheology of Polymer Melts ...........................................................................129 5.1 Introduction .....................................................................................129 5.1.1 Continuum Mechanics ........................................................129 5.1.2 The Generalized Newtonian Fluid ...................................131 5.1.3 Normal Stresses in Shear Flow ..........................................133 5.1.4 Deborah Number .................................................................134 5.2 Viscous Flow Models ......................................................................137 5.2.1 The Power Law Model ........................................................137 5.2.2 The Bird-Carreau-Yasuda Model .....................................139 5.2.3 The Bingham Fluid ..............................................................140 5.2.4 Elongational Viscosity ........................................................140 5.2.5 Rheology of Curing Thermosets .......................................142 5.2.6 Suspension Rheology ..........................................................146 5.3 Simplified Flow Models Common in Polymer Processing .....147 5.3.1 Simple Shear Flow ...............................................................148 5.3.2 Pressure Flow Through a Slit .............................................148 5.3.3 Pressure Flow Through a Tube - Hagen-Poiseuille Flow .....................................................................................149 Table of Contents xiii 5.3.4 Couette Flow ........................................................................150 5.4 Viscoelastic Flow Models ...............................................................151 5.4.1 Differential Viscoelastic Models .......................................151 5.4.2 Integral Viscoelastic Models ..............................................154 5.5 Rheometry .....................................................................................159 5.5.1 The Melt Flow Indexer ........................................................159 5.5.2 The Capillary Viscometer ..................................................159 5.5.3 Computing Viscosity Using the Bagley and ............. Weissenberg-Rabinowitsch Equations .............................162 5.5.4 Viscosity Approximation Using the Representative .... Viscosity Method .................................................................163 5.5.5 The Cone-Plate Rheometer ................................................164 5.5.6 The Couette Rheometer ......................................................166 5.5.7 Extensional Rheometry .......................................................167 5.6 Surface Tension .................................................................................170 Examples .....................................................................................174 Problems .....................................................................................179 References .....................................................................................180 Part II Influence of Processing on Properties ...............................................183 6 Introduction to Processing ..............................................................................185 6.1 Extrusion .....................................................................................185 6.1.1 The Plasticating Extruder ....................................................188 6.1.1.1 The Solids Conveying Zone ...................................191 6.1.1.2 The Melting Zone .....................................................195 6.1.1.3 The Metering Zone ..................................................197 6.1.2 Extrusion Dies .......................................................................199 6.1.2.1 Sheeting Dies ............................................................199 6.1.2.2 Tubular Dies ..............................................................201 6.2 Mixing Processes ..............................................................................202 6.2.1 Distributive Mixing .............................................................204 6.2.1.1 Effect of Orientation ................................................205 6.2.2 Dispersive Mixing ................................................................208 6.2.2.1 Break-Up of Particulate Agglomerates ................208 6.2.2.2 Break-Up of Fluid Droplets ....................................211 6.2.3 Mixing Devices .....................................................................214 6.2.3.1 Static Mixers ..............................................................215 6.2.3.2 Banbury Mixer ..........................................................216 6.2.3.3 Mixing in Single Screw Extruders .........................218 6.2.3.4 Cokneader .................................................................220 6.2.3.5 Twin Screw Extruders ..............................................221 6.2.4 Energy Consumption During Mixing ..............................224 6.2.5 Mixing Quality and Efficiency ...........................................225 xiv Table of Contents 6.2.6 Plasticization .........................................................................227 6.3 Injection Molding .............................................................................233 6.3.1 The Injection Molding Cycle ..............................................234 6.3.2 The Injection Molding Machine .........................................238 6.3.2.1 The Plasticating and Injection Unit .......................238 6.3.2.2 The Clamping Unit ..................................................239 6.3.2.3 The Mold Cavity...................................................... 241 6.3.3 Related Injection Molding Processes ................................243 6.4 Secondary Shaping ...........................................................................245 6.4.1 Fiber Spinning ......................................................................245 6.4.2 Film Production ...................................................................246 6.4.2.1 Cast Film Extrusion .................................................246 6.5.2.2 Film Blowing ............................................................247 6.4.3 Blow Molding .......................................................................249 6.4.3.1 Extrusion Blow Molding .........................................249 6.4.3.2 Injection Blow Molding ..........................................251 6.4.3.3 Thermoforming ........................................................253 6.5 Calendering .....................................................................................255 6.6 Coating .....................................................................................257 6.7 Compression Molding ....................................................................260 6.8 Foaming .....................................................................................262 6.9 Rotational Molding .........................................................................264 Examples .....................................................................................266 Problems .....................................................................................275 References .....................................................................................279 Anisotropy Development During Processing ............................................283 7.1 Orientation in the Final Part ..........................................................283 7.1.1 Processing Thermoplastic Polymers ................................283 7.1.2 Processing Thermoset Polymers .......................................292 7.2 Predicting Orientation in the Final Part ......................................297 7.2.1 Planar Orientation Distribution Function .......................298 7.2.2 Single Particle Motion .........................................................300 7.2.3 Jeffery s Model ......................................................................302 7.2.4 Folgar-Tucker Model ..........................................................303 7.2.5 Tensor Representation of Fiber Orientation ...................304 7.2.5.1 Predicting Orientation in Complex Parts Using Computer Simulation .............................................306 7.3 Fiber Damage ...................................................................................312 Examples .....................................................................................314 Problems .....................................................................................316 References .....................................................................................318 Table of Contents xv 8 Solidification of Polymers .............................................................................321 8.1 Solidification of Thermoplastics ...................................................321 8.1.1 Thermodynamics During Cooling ...................................321 8.1.2 Morphological Structure .....................................................325 8.1.3 Crystallization ......................................................................326 8.1.4 Heat Transfer During Solidification .................................329 8.2 Solidification of Thermosets ..........................................................334 8.2.1 Curing Reaction ...................................................................334 8.2.2 Cure Kinetics ........................................................................336 8.2.3 Heat Transfer During Cure ................................................340 8.3 Residual Stresses and Warpage of Polymeric Parts ...................343 8.3.1 Residual Stress Models ........................................................346 8.3.1.1 Residual Stress Model Without Phase Change Effects .........................................................................349 8.3.1.2 Model to Predict Residual Stresses with Phase .. Change Effects ..........................................................350 8.3.2 Other Simple Models to Predict Residual Stresses and Warpage .................................................................................353 8.3.2.1 Uneven Mold Temperature ....................................354 8.3.2.2 Residual Stress in a Thin Thermoset Part ............355 8.3.2.3 Anisotropy Induced Curvature Change ..............357 8.3.3 Predicting Warpage in Actual Parts ..................................358 Examples .....................................................................................362 Problems .....................................................................................364 References .....................................................................................366 Part III Engineering Design Properties ...........................................................369 9 Mechanical Behavior of Polymers ................................................................371 9.1 Basic Concepts of Stress and Strain ...............................................371 9.1.1 Plane Stress ............................................................................372 9.1.2 Plane Strain ...........................................................................373 9.2 The Short-Term Tensile Test ..........................................................373 9.2.1 Rubber Elasticity ..................................................................373 9.2.2 The Tensile Test and Thermoplastic Polymers ...............379 9.3 Long-Term Tests ...............................................................................388 9.3.1 Isochronous and Isometric Creep Plots ...........................391 9.4 Dynamic Mechanical Tests .............................................................393 9.4.1 Torsion Pendulum ...............................................................393 9.4.2 Sinusoidal Oscillatory Test .................................................397 9.5 Viscoelastic Behavior of Polymers ...............................................398 9.5.1 Kelvin Model ........................................................................399 9.5.1.1 Kelvin Model Creep Response ..............................400 9.5.1.2 Kelvin Model Stress Relaxation ............................400 xvi Table of Contents 9.5.1.3 Kelvin Model Strain Recovery ..............................401 9.5.1.4 Kelvin Model Dynamic Response .........................401 9.5.2 Jeffrey Model ........................................................................401 9.5.2.1 Jeffrey Model Creep Response ..............................402 9.5.2.2 Jeffrey Model Stress Relaxation .............................403 9.5.2.3 Jeffrey Model Strain Recovery ...............................403 9.5.3 Standard Linear Solid Model .............................................403 9.5.3.1 Standard Linear Solid Model Creep Response... 404 9.5.3.2 Standard Linear Solid Model Stress Relaxation. .405 9.5.4 Maxwell-Wiechert Model ...................................................405 9.5.4.1 Maxwell-Wiechert Model Stress Relaxation .......406 9.5.4.2 Maxwell-Wiechert Model Dynamic Response.... 407 9.6 Effects of Structure and Composition on Mechanical Properties .....................................................................................407 9.6.1 Amorphous Thermoplastics ...............................................409 9.6.2 Semi-Crystalline Thermoplastics ......................................410 9.6.3 Oriented Thermoplastics ....................................................412 9.6.4 Cross-Linked Polymers ......................................................418 9.7 Mechanical Behavior of Filled and Reinforced Polymers ..........420 9.7.1 Anisotropie Strain-Stress Relation ....................................422 9.7.2 Aligned Fiber Reinforced Composite Laminates ..........423 9.7.3 Transformation of Fiber Reinforced Composite Laminate Properties ............................................................426 9.7.4 Reinforced Composite Laminates with a Fiber Orientation Distribution Function ....................................429 9.8 Strength Stability Under Heat .........................................................429 Examples .....................................................................................431 Problems .....................................................................................440 References .....................................................................................444 10 Failure and Damage of Polymers .................................................................447 10.1 Fracture Mechanics ..........................................................................447 10.1.1 Fracture Predictions Based on the Stress Intensity Factor .....................................................................................448 10.1.2 Fracture Predictions Based on an Energy Balance ..........450 10.1.3 Linear Viscoelastic Fracture Predictions Based on J-Integrals ..............................................................................453 10.2 Short-Term Tensile Strength ..........................................................455 10.2.1 Brittle Failure ........................................................................456 10.2.2 Ductile Failure ......................................................................459 10.2.3 Failure of Highly Filled Systems or Composites ..........464 10.3 Impact Strength ................................................................................467 10.3.1 Impact Test Methods ............................................................473 10.3.2 Fracture Mechanics Analysis of Impact Failure ..............478 Table of Contents xvii 10.4 Creep Rupture ..................................................................................483 10.4.1 Creep Rupture Tests ............................................................484 10.4.2 Fracture Mechanics Analysis of Creep Rupture .............487 10.5 Fatigue .....................................................................................488 10.5.1 Fatigue Test Methods ..........................................................488 10.5.2 Fracture Mechanics Analysis of Fatigue Failure ............498 10.6 Friction and Wear ............................................................................499 10.7 Stability of Polymer Structures .....................................................503 10.8 Environmental Effects on Polymer Failure .................................505 10.8.1 Weathering ............................................................................505 10.8.2 Chemical Degradation ........................................................511 10.8.3 Thermal Degradation of Polymers ...................................513 Examples .....................................................................................515 Problems .....................................................................................517 References .....................................................................................518 11 Electrical Properties of Polymers ..................................................................521 11.1 Dielectric Behavior ..........................................................................521 11.1.1 Dielectric Coefficient ...........................................................521 11.1.2 Mechanisms of Dielectrical Polarization .........................524 11.1.3 Dielectric Dissipation Factor ..............................................528 11.1.4 Implications of Electrical and Thermal Loss in a Dielectric ................................................................................532 11.2 Electric Conductivity .......................................................................532 11.2.1 Electric Resistance ................................................................532 11.2.2 Physical Causes of Volume Conductivity .......................534 11.3 Application Problems .....................................................................537 11.3.1 Electric Breakdown ..............................................................537 11.3.2 Electrostatic Charge .............................................................540 11.3.3 Electrets ..................................................................................542 11.3.4 Electromagnetic Interference Shielding (EMI Shielding) ....................................................................542 11.4 Magnetic Properties .........................................................................543 11.4.1 Magnetizability ....................................................................543 11.4.2 Magnetic Resonance ............................................................543 References .....................................................................................544 12 Optical Properties of Polytmers ....................................................................545 12.1 Index of Refraction ...........................................................................545 12.2 Photoelasticity and Birefringence .................................................548 12.3 Transparency, Reflection, Absorption, and Transmittance ......553 12.4 Gloss .....................................................................................559 12.5 Color .....................................................................................560 12.6 Infrared Spectroscopy ......................................................................563 xviii Table of Contents 12.7 Infrared Pyrometry ..........................................................................565 12.8 Heating with Infrared Radiation ...................................................567 References .....................................................................................569 13 Permeability Properties of Polymers ...........................................................571 13.1 Sorption .....................................................................................571 13.2 Diffusion and Permeation ..............................................................573 13.3 Measuring S, D and Ρ .......................................................................579 13.4 Corrosion of Polymers and Cracking ..........................................580 13.5 Diffusion of Polymer Molecules and Self-Diffusion ..................583 References .....................................................................................584 14 Acoustic Properties of Polymers ...................................................................585 14.1 Speed of Sound .................................................................................585 14.2 Sound Reflection ..............................................................................587 14.3 Sound Absorption ............................................................................589 References .....................................................................................590 Appendix .....................................................................................591 Subject Index .....................................................................................611 Author Index .....................................................................................618
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genre	(DE-588)4123623-3 Lehrbuch gnd-content
genre_facet	Lehrbuch
id	DE-604.BV017072892
illustrated	Illustrated
indexdate	2024-07-09T19:13:27Z
institution	BVB
isbn	1569903484 3446224645
language	English
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-010300230
oclc_num	51969004
open_access_boolean
owner	DE-12 DE-210 DE-91G DE-BY-TUM DE-29T DE-703 DE-1050 DE-1102 DE-1043 DE-1051 DE-83
owner_facet	DE-12 DE-210 DE-91G DE-BY-TUM DE-29T DE-703 DE-1050 DE-1102 DE-1043 DE-1051 DE-83
physical	XVIII, 622 S. graph. Darst.
publishDate	2003
publishDateSearch	2003
publishDateSort	2003
publisher	Hanser [u.a.]
record_format	marc
spelling	Osswald, Tim A. 1958- Verfasser (DE-588)1062689453 aut Materials science of polymers for engineers Tim A. Osswald ; Georg Menges 2. ed. Munich Hanser [u.a.] 2003 XVIII, 622 S. graph. Darst. txt rdacontent n rdamedia nc rdacarrier Matières plastiques ram Polymères ram Plastics Polymers Stoffeigenschaft (DE-588)4192147-1 gnd rswk-swf Kunststoff (DE-588)4033676-1 gnd rswk-swf Werkstoffkunde (DE-588)4079184-1 gnd rswk-swf Polymere (DE-588)4046699-1 gnd rswk-swf (DE-588)4123623-3 Lehrbuch gnd-content Kunststoff (DE-588)4033676-1 s Werkstoffkunde (DE-588)4079184-1 s DE-604 Polymere (DE-588)4046699-1 s Stoffeigenschaft (DE-588)4192147-1 s 1\p DE-604 Menges, Georg Sonstige oth Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=010300230&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk
spellingShingle	Osswald, Tim A. 1958- Materials science of polymers for engineers Matières plastiques ram Polymères ram Plastics Polymers Stoffeigenschaft (DE-588)4192147-1 gnd Kunststoff (DE-588)4033676-1 gnd Werkstoffkunde (DE-588)4079184-1 gnd Polymere (DE-588)4046699-1 gnd
subject_GND	(DE-588)4192147-1 (DE-588)4033676-1 (DE-588)4079184-1 (DE-588)4046699-1 (DE-588)4123623-3
title	Materials science of polymers for engineers
title_auth	Materials science of polymers for engineers
title_exact_search	Materials science of polymers for engineers
title_full	Materials science of polymers for engineers Tim A. Osswald ; Georg Menges
title_fullStr	Materials science of polymers for engineers Tim A. Osswald ; Georg Menges
title_full_unstemmed	Materials science of polymers for engineers Tim A. Osswald ; Georg Menges
title_short	Materials science of polymers for engineers
title_sort	materials science of polymers for engineers
topic	Matières plastiques ram Polymères ram Plastics Polymers Stoffeigenschaft (DE-588)4192147-1 gnd Kunststoff (DE-588)4033676-1 gnd Werkstoffkunde (DE-588)4079184-1 gnd Polymere (DE-588)4046699-1 gnd
topic_facet	Matières plastiques Polymères Plastics Polymers Stoffeigenschaft Kunststoff Werkstoffkunde Polymere Lehrbuch
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=010300230&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT osswaldtima materialsscienceofpolymersforengineers AT mengesgeorg materialsscienceofpolymersforengineers

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