Verfügbarkeit: Injection molding

Injection molding: technology and fundamentals

"A book about the fundamentals and applications of injection molding"--Provided by publisher.

Gespeichert in:

Bibliographische Detailangaben
Weitere Verfasser:	Kamal, Musa R. 1934- (HerausgeberIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Munich [u.a.] Hanser 2009
Schriftenreihe:	Progress in polymer processing
Schlagworte:	Spritzgießen Injection molding of metals Injection molding of plastics Injection molding of rubber
Online-Zugang:	Inhaltsverzeichnis
Zusammenfassung:	"A book about the fundamentals and applications of injection molding"--Provided by publisher.
Beschreibung:	Literaturangaben
Beschreibung:	XXVIII, 926 S. Ill., graph. Darst. 25 cm
ISBN:	9783446416857 9781569904343

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MARC


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245	1	0	\|a Injection molding \|b technology and fundamentals \|c Musa R. Kamal (ed.) ... With contributions by Jean-Francois Agassant ...
264		1	\|a Munich [u.a.] \|b Hanser \|c 2009
300			\|a XXVIII, 926 S. \|b Ill., graph. Darst. \|c 25 cm
336			\|b txt \|2 rdacontent
337			\|b n \|2 rdamedia
338			\|b nc \|2 rdacarrier
490	0		\|a Progress in polymer processing
500			\|a Literaturangaben
520	3		\|a "A book about the fundamentals and applications of injection molding"--Provided by publisher.
650		4	\|a Spritzgießen
650		4	\|a Injection molding of metals
650		4	\|a Injection molding of plastics
650		4	\|a Injection molding of rubber
650	0	7	\|a Spritzgießen \|0 (DE-588)4056561-0 \|2 gnd \|9 rswk-swf
689	0	0	\|a Spritzgießen \|0 (DE-588)4056561-0 \|D s
689	0		\|5 DE-604
700	1		\|a Kamal, Musa R. \|d 1934- \|0 (DE-588)133588033 \|4 edt
700	1		\|a Agassant, Jean-François \|e Sonstige \|0 (DE-588)112277837 \|4 oth
856	4	2	\|m DNB Datenaustausch \|q application/pdf \|u http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017598743&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA \|3 Inhaltsverzeichnis
999			\|a oai:aleph.bib-bvb.de:BVB01-017598743

Datensatz im Suchindex

_version_	1804139183625732097
adam_text	CONTENTS PREFACE V PART I: BACKGROUND AND OVERVIEW 1 1 INJECTION MOLDING: INTRODUCTION AND GENERAL BACKGROUND 3 MUSA R. KAMAL 1.1 SCOPE 3 1.2 INTRODUCTION 3 1.2.1 POLYMER PROCESSING 3 1.2.1.1 THE PLASTICS PROCESSING SYSTEM 4 1.2.1.2 PROCESSING PROPERTIES OF POLYMERS AND THEIR COMPOUNDS 5 1.2.2 INJECTION MOLDING 5 1.2.2.1 INTRODUCTION 5 1.2.2.2 GENERAL INJECTION MOLDING PROCESS SEQUENCE 6 1.3 INJECTION MOLDING PROCESS CHARACTERITICS 9 1.3.1 THE PLASTICATION STAGE 9 1.3.1.1 THE MELTING ZONE 11 1.3.1.2 TEMPERATURE DISTRIBUTION IN THE NOZZLE 13 1.3.2 THE FILLING STAGE 17 1.3.2.1 FLOW LINES AND WELD LINES 17 1.3.2.2 JETTING 19 1.3.2.3 FOUNTAIN FLOW 20 1.3.3 HEAT TRANSFER IN THE CAVITY 24 1.3.3.1 MEASUREMENT OF TEMPERATURE DISTRIBUTION IN THE CAVITY 24 1.3.3.2 NUMERICAL SIMULATION OF HEAT TRANSFER IN INJECTION MOLDING 28 1.3.3.3 CRYSTALLIZATION KINETICS 30 1.4 MICROSTRUCTURE OF INJECTION MOLDED PARTS 31 1.4.1 CRYSTALLINITY 32 1.4.1.1 EFFECT OF CRYSTALLINITY AND ORIENTATION ON BIREFRINGENCE AND TENSILE MODULUS 33 1.4.2 MORPHOLOGY 36 1.4.3 RESIDUAL STRESSES 40 1.4.3.1 CALCULATION OF RESIDUAL STRESSES 42 1.4.4 MICROSTRUCTURE OF FIBER REINFORCED THERMOPLASTICS 46 1.4.4.1 FIBER LENGTH AND CONCENTRATION DISTRIBUTIONS 46 1.4.4.2 MATRIX CRYSTALLINITY 47 1.4.4. BIBLIOGRAFISCHE INFORMATIONEN HTTP://D-NB.INFO/993612504 DIGITALISIERT DURCH VIII CONTENTS PART II: INJECTION MOLDING MACHINERY AND SYSTEMS 71 2 INJECTION MOLDING MACHINES, TOOLS, AND PROCESSES 73 TADAMOTO SAKAI AND KENJI KIKUGAWA 2.1 INJECTION MOLDING MACHINES 73 2.1.1 TYPES OF INJECTION MOLDING MACHINES 73 2.1.1.1 HORIZONTAL INJECTION MOLDING MACHINES 73 2.1.1.2 VERTICAL INJECTION MOLDING MACHINES 74 2.1.1.3 HYBRID INJECTION MOLDING MACHINE COMPOSED OF VERTICAL AND HORIZONTAL UNITS 75 2.1.2 SCREW AND BARREL UNIT 75 2.1.2.1 IN-LINE SCREW TYPE INJECTION MOLDING MACHINES 76 2.1.2.2 SCREW DESIGN FOR INJECTION MOLDING MACHINES 76 2.1.2.3 BARRELS FOR INJECTION MOLDING MACHINES 77 2.1.3 DRIVING PRINCIPLES 79 2.1.3.1 HYDRAULIC INJECTION MOLDING MACHINES 80 2.1.3.2 ELECTRIC INJECTION MOLDING MACHINES 80 2.1.3.2.1 CONTROL SYSTEMS FOR AN ELECTRIC INJECTION MOLDING MACHINE 81 2.1.3.2.2 INJECTION MECHANISM FOR AN ELECTRIC MACHINE 82 2.1.3.2.3 NOZZLE CONTACT MECHANISM FOR AN ELECTRIC INJECTION MOLDING MACHINE 83 2.1.3.2.4 ELECTRIC CLAMPING MECHANISM 83 2.1.3.2.5 ELECTRIC EJECTION MECHANISM 84 2.1.3.3 MAN-MACHINE INTERFACE AND COMMUNICATION CONTROL 84 2.1.3.3.1 MAN-MACHINE INTERFACE FOR AN INJECTION MOLDING MACHINE 84 2.1.3.3.2 COMMUNICATION CONTROL 86 2.1.4 PROCESS CONTROL 86 2.1.4.1 CONTROL OF THE FILLING PROCESS 87 2.1.4.2 CONTROL OF THE HOLD-PRESSURE SWITCHING PROCESS 87 2.1.4.3 CONTROL OF THE HOLD-PRESSURE PROCESS 88 2.1.4. CONTENTS IX 2.2.3.4 AIR VENTS 103 2.2.4 EJECTION MECHANISMS 103 2.2.4.1 EJECTOR PINS 104 2.2.4.2 SLEEVE AND A STRIPPER PLATE 104 2.2.4.3 AIR EJECTOR 104 2.2.5 MOLD COOLING 106 2.2.6 TEMPERATURE CONTROL METHODS AND MECHANISMS 106 2.2.6.1 LIQUID MEDIUM CONTROL 106 2.2.6.2 ELECTRIC HEATER CONTROL 107 2.3 INJECTION MOLDING PROCESSES 107 2.3.1 IN-MOLD BUILD-UP INJECTION MOLDING (DSI) 107 2.3.2 CONVENTIONAL PROCESSES 108 2.3.3 DSI MOLDING PROCESS 108 2.3.3.1 INJECTION WELDING MECHANISM 108 2.3.3.2 ADVANTAGES OF THE DSI MOLDING PROCESS 109 2.3.3.3 PRODUCT EXAMPLES OF THE DSI MOLDING PROCESS 110 2.3.4 MULTI-MATERIAL INJECTION MOLDING 111 2.3.4.1 MULTI-MATERIAL MOLDING TECHNIQUES 111 2.3.4.2 APPLICATION EXAMPLES FOR THE M-DSI MOLDING PROCESS 114 2.3.5 SUPER-HIGH SPEED INJECTION MOLDING 115 2.3.5.1 EFFECTS OF HIGH-SPEED INJECTION 115 2.3.5.2 HIGH-SPEED INJECTION MOLDING MACHINES 116 2.3.5.3 EXAMPLE OF ULTRA HIGH-SPEED INJECTION MOLDING 117 2.3.6 IN-MOLD COATING INJECTION MOLDING 117 2.3.6.1 SURFACE DECORATION TECHNIQUES 117 2.3.6.2 SIMULTANEOUS TRANSFER MOLDING 118 2.3.7 INSERT INJECTION MOLDING PROCESS 120 2.3.7.1 INSERT MOLDING MACHINES 121 2.3.8 SANDWICH INJECTION MOLDING 122 2.3.8.1 PROCESS OUTLINE 122 2.3.8.2 CONSTRUCTION OF SANDWICH NOZZLES 122 2.3.8.3 FEATURES OF SANDWICH MOLDING 124 2.3.9 PLASTIC MAGNET INJECTION MOLDING 125 2.3.9. CONTENTS 3 THE PLASTICATING SYSTEM FOR INJECTION MOLDING MACHINES 133 MARK A. SPALDING AND KUN SUP HYUN 3.1 INTRODUCTION 133 3.2 THE PLASTICATING SYSTEM 134 3.3 OPERATION OF PLASTICATING SCREW MACHINES 136 3.3.1 PROPER OPERATION 138 3.4 THE MELTING PROCESS 138 3.5 BASIC SCREW DESIGN 146 3.5.1 PS INJECTION MOLDING CASE STUDY 147 3.6 HIGH-PERFORMANCE SCREW DESIGNS 148 3.7 SECONDARY MIXING PROCESSES AND DEVICES 154 3.7.1 DYNAMIC MIXERS 161 3.8 SCREW DESIGN ISSUES CAUSING RESIN DEGRADATION 163 3.9 NON-RETURN VALVE 165 NOMENCLATURE 166 REFERENCES 168 4 NON-CONVENTIONAL INJECTION MOLDS 171 ANTONIO M. CUNHA, ANTONIO /. PONTES 4.1 INTRODUCTION 171 4.2 MOLDS FOR MULTI-MATERIAL MOLDING 173 4.2.1 CO-INJECTION 173 4.2.2 OVERMOLDING 176 4.3 INJECTION UNITS, LAYOUT, AND RUNNER SYSTEM 181 4.3.1 EQUIPMENT 181 4.3.2 HOT RUNNERS 183 4.3.3 MATERIAL INTERACTIONS 183 4.4 MOLDS FOR INJECTION-WELDING 184 4.5 MOLDS FOR BACKMOLDING 186 4.5.1 MOLDING OVER TEXTILES OR FABRICS 186 4.5.2 IN-MOLD LABELING 191 4.5.3 IN-MOLD DECORATION 192 REFERENCES 194 5 GAS ASSISTED INJECTION MOLDING 195 SHIH-JUNGLIU 5.1 INTRODUCTION 195 5.1. CONTENTS XI 5.2.4 PRESSURE DEVELOPMENT DURING THE MOLDING PROCESS 202 5.2.5 GAS PENETRATION BEHAVIOR IN MOLDED PARTS 203 5.2.6 GAS VENTING AND RECYCLING 205 5.2.7 MOLDABILITY DIAGRAM FOR GAIM 206 5.3 PROCESS MODELING 207 5.4 PART/MOLD DESIGNS AND MOLDING GUIDELINES 209 5.4.1 GAS CHANNEL GEOMETRY 209 5.4.2 GAS CHANNEL LAYOUT 211 5.4.3 EFFECT OF GRAVITY 211 5.4.4 RESIDUAL WALL THICKNESS DISTRIBUTION 212 5.4.5 GAS DISSOLUTION INTO THE POLYMER 213 5.4.6 GAS FINGERING 215 5.4.7 UNSTABLE GAS PENETRATIONS 216 5.4.8 WELD LINES CAUSED BY THE FLOW-LEAD EFFECT 217 5.4.9 MOLDING OF FIBER REINFORCED MATERIALS 218 5.5 CONCLUDING REMARKS 220 LIST OF SYMBOLS 220 REFERENCES 221 6 WATER INJECTION TECHNIQUES (WIT) 223 WALTER MICHAELI 6.1 INTRODUCTION 223 6.2 PROCESSING TECHNOLOGY 224 6.2.1 COURSE OF PROCESS 224 6.2.2 PROCESS VARIANTS 225 6.2.2.1 SHORT-SHOT PROCESS 226 6.2.2.2 FULL-SHOT PROCESS 226 6.2.2.3 FULL-SHOT PROCESS WITH OVERSPILL 226 6.2.2.4 MELT PUSH BACK PROCESS 226 6.2.2.5 CORE PULLING PROCESS 227 6.2.2.6 RINSING/FLUSHING PROCESS 227 6.2.3 COMPARISON BETWEEN GAIM AND WIT 228 6.2.3.1 LIMITATIONS OF GAIM 229 6.2.3.2 CYDE TIMES 229 6.2.3.3 PART PROPERTIES 230 6.2.3.3.1 RESIDUAL WALL THICKNESSES (RWT) 230 6.2.3.3.2 SHRINKAGE/WARPAGE 232 6.2.3.3. XII CONTENTS 6.3.3.1 OPERATING METHOD 239 6.3.3.2 OPERATING DIRECTION 241 6.3.3.3 ALIGNMENT IN THE MOLD 242 6.3.4 GENERAL DESIGN REMARKS FOR WIT INJECTORS 242 6.3.4.1 EXCELLENT PROCESS RELIABILITY 243 6.3.4.2 SPECIFIC CONTROLLABILITY 243 6.4 WIT COMPATIBLE PART DESIGN 243 6.4.1 INJECTOR EMBEDDING 243 6.4.2 GENERAL DESIGN GUIDELINES FOR WIT ARTIDES 244 6.4.3 TUBULAR ARTIDES 245 6.4.3.1 CROSS SECTIONS 245 6.4.3.2 ASPECT RATIO 246 6.4.3.3 CURVES AND REDIRECTIONS 246 6.4.3.4 CHANGE OF DIAMETER 247 6.4.4 COMPACT PARTS WITH INTEGRATED THICK-WALLED SECTIONS 248 LIST OF ABBREVIATIONS AND SYMBOLS 248 REFERENCES 249 PART III: INJECTION MOLDING OF COMPLEX MATERIALS 251 7 FLOW INDUCED FIBER MICRO-STRUCTURE IN INJECTION MOLDING OF FIBER REINFORCED MATERIALS 253 MICHEL VINCENT 7.1 INTRODUCTION 253 7.2 OBSERVATIONS 254 7.2.1 FIBER LENGTH DISTRIBUTION 254 7.2.2 FIBER CONCENTRATION 255 7.2.3 FIBER ORIENTATION 256 7.2.3.1 ORIENTATION MECHANISMS 256 7.2.3.2 QUALITATIVE OBSERVATIONS 256 7.2.3.3 QUANTIFICATION TOOLS: ORIENTATION DISTRIBUTION FUNCTION, ORIENTATION TENSORS 258 7.2.3.4 EXPERIMENTAL METHODS 258 7.2.3.5 RESULTS 260 7.3 CALCULATION OF FIBER ORIENTATION 261 7.3.1 ORIENTATION MODELS 261 7.3.1.1 THE STANDARD MODEL , 261 7.3.1. CONTENTS XIII 7.3.2.2 INTRODUCTION TO BEHAVIOR LAWS 267 7.4 CONCLUSIONS 268 LIST OF SYMBOLS 269 REFERENCES 270 8 INJECTION FOAM MOLDING 273 X. XU AND C. B. PARK 8.1 INTRODUCTION 273 8.2 INJECTION FOAM MOLDING TECHNOLOGIES: BACKGROUND 274 8.2.1 STRUCTURAL-FOAM MOLDING 274 8.2.1.1 LOW-PRESSURE FOAM MOLDING 274 8.2.2 HIGH-PRESSURE FOAM MOLDING 275 8.2.2.1 CO-INJECTION FOAM MOLDING 276 8.2.2.2 GAS COUNTER-PRESSURE FOAM MOLDING 277 8.2.2.3 SEQUENTIAL INJECTION FOAM MOLDING 278 8.2.3 MICROCELLULAR INJECTION FOAM MOLDING 279 8.2.3.1 BACKGROUND ON MICROCELLULAR FOAM PROCESSING 279 8.2.3.2 DEVELOPMENT OF MICROCELLULAR INJECTION FOAM MOLDING 280 8.2.3.2.1 BATCH MICROCELLULAR PROCESSING 280 8.2.3.2.2 SEMI-CONTINUOUS MICROCELLULAR PROCESSING 281 8.2.3.2.3 CONTINUOUS MICROCELLULAR PROCESSING 281 8.2.3.2.4 MICROCELLULAR INJECTION FOAM MOLDING 282 8.3 FUNDAMENTALS OF FOAM INJECTION MOLDING 284 8.3.1 FOAMING ADDITIVES 284 8.3.1.1 CELL-NUCLEATING AGENTS 284 8.3.1.2 BLOWING AGENTS 285 8.3.1.2.1 CHEMICAL BLOWING AGENTS 285 8.3.1.2.2 PHYSICAL BLOWING AGENTS 285 8.3.2 THERMOPHYSICAL AND RHEOLOGICAL PROPERTIES OF POLYMER/GAS MIXTURES 285 8.3.2.1 SOLUBILITY AND DIFFUSIVITY 285 8.3.2.1.1 SOLUBILITY 285 8.3.2.1.2 DIFFUSIVITY 288 8.3.2.2 VISCOSITY OF POLYMER/GAS MIXTURES 289 8.3.2.3 SURFACE TENSION OF POLYMER/GAS MIXTURES 291 8.3. XIV CONTENTS 8.3.5.1 GEOMETRIE SINGULARITY AND WELD LINES 299 8.3.5.2 VOID FRACTION CONTROL 299 8.3.5.3 CELL GROWTH IN A MOLD 299 8.4 FOAM MOLDING MACHINES AND APPLICATIONS 300 8.4.1 FOAM MOLDING MACHINES 300 8.4.2 APPLICATIONS 302 8.5 FUTURE DEVELOPMENTS 302 LIST OF SYMBOLS AND ABBREVIATION 303 REFERENCES 304 9 POWDER METAL INJECTION MOLDING 309 JAMES F. STEVENSON 9.1 OPPORTUNITY 309 9.2 PROCESS OVERVIEW 310 9.3 FEEDSTOCK 313 9.3.1 POWDERS 313 9.3.2 BINDERS 314 9.3.3 COMPOUNDS 316 9.4 PART AND TOOL DESIGN 317 9.4.1 PART DESIGN 317 9.4.2 MOLD DESIGN 319 9.5 MOLDING 322 9.5.1 EQUIPMENT 322 9.5.2 OPERATIONS 322 9.6 DEBINDING 323 9.7 SINTERING 324 9.7.1 FUNDAMENTALS 324 9.7.2 FUMACES 329 9.7.3 SETTERS 332 9.8 POST SINTERING TREATMENTS 333 9.8.1 HEAT TREATMENT 333 9.8.2 HOT ISOSTATIC PRESSING 335 9.8.3 SECONDARY OPERATIONS 335 9.9 MATERIAL PROPERTIES 336 LIST OF SYMBOLS 338 REFERENCES 338 ACKNOWLEDGEMENTS 339 10 MICRO INJECTION MOLDING 341 VOLKER PIOTTER, GUIDO FINNAH, THOMAS HANEMANN, ROBERT RUPRECHT 10.1 INTRODUCTION , 341 10.2 WHY IS POLYMER PROCESSING SO INTERESTING FOR MICROSYSTEMS ENGINEERING? .. 342 10.3 THE PROCESS SPECIALTIES OF MICRO INJECTION MOLDING 343 10.3. CONTENTS XV 10.3.2 MACHINE TECHNOLOGY FOR MICRO INJECTION MOLDING 346 10.3.3 FABRICATION OF MICROSTRUCTURED MOLD INSERTS FOR MICRO INJECTION MOLDING.. 349 10.3.4 SPECIAL TYPES OF MICRO INJECTION MOLDING 350 10.3.5 SIMULATION 351 10.4 MICRO REACTION INJECTION MOLDING 353 10.4.1 REACTIVE RESIN POLYMERIZATION METHODS 353 10.4.2 THERMALLY INITIATED REACTION INJECTION MOLDING OF LIGA-STRUCTURES 354 10.4.3 DEVELOPMENT OF LIGHT INDUCED REACTION MOLDING (PHOTOMOLDING) TECHNIQUES 356 10.4.4 UV-EMBOSSING OF PHOTOCURABLE SYSTEMS 358 10.4.5 PHOTOMOLDING OF COMPOSITES 360 10.5 MICRO POWDER INJECTION MOLDING (MICROPIM) 362 10.5.1 INTRODUCTION TO MICROPIM 362 10.5.2 METAL AND CERAMIC POWDERS FOR PIM 365 10.5.3 COMMERCIALLY AVAILABLE PIM FEEDSTOCKS AND BINDERS 366 10.5.4 BINDER SYSTEMS FOR MICROPIM 367 10.5.5 COMPOUNDING FEEDSTOCKS FOR MICROPIM 368 10.5.6 RHEOLOGY MEASUREMENTS OF PIM FEEDSTOCKS 369 10.5.7 MACHINERY FOR MICROPIM 371 10.5.8 MOLDING TOOLS FOR MICROPIM 371 10.5.9 PATTERNING PROCESS FOR PIM MICROPARTS 375 10.5.9.1 DEBINDING OF MICROPIM GREEN COMPACTS 376 10.5.9.2 SINTERING PROCESS FOR MICROPIM PARTS 378 10.5.10 MICROPIM RESEARCH 378 10.6 TWO-COMPONENT MICRO INJECTION MOLDING (2C-MICROPIM) 378 10.6.1 MACHINE TECHNOLOGY FOR MICRO TWO-COMPONENT INJECTION MOLDING 379 10.6.2 MOLD TECHNOLOGY FOR TWO-COMPONENT MICRO INJECTION MOLDING 381 10.6.3 CONTACT-STRENGTH FOR THE MULTI-COMPONENT INJECTION MOLDING 381 10.6. XVI CONTENTS PART IV: PROCESS VISUALIZATION, CONTROL, OPTIMIZATION, AND SIMULATION 395 11 INTERNAL VISUALIZATION OF MOLD CAVITY AND HEATING CYLINDER 397 HIDETOSHI YOKOI 11.1 INTRODUCTION 397 11.2 DYNAMIC VISUALIZATION TECHNIQUES FOR THE INSIDE OF THE MOLD CAVITY 397 11.2.1 OVERVIEW OF DYNAMIC VISUALIZATION TECHNIQUES 398 11.2.1.1 LIGHT TRANSMISSION METHOD 398 11.2.1.2 LIGHT REFLECTION METHOD 399 11.2.1.3 LIGHT-SECTION METHOD 401 11.2.2 GLASS-INSERTEDMOLD (2D, 3D) 401 11.2.3 BACK-LIGHTING MOLD 406 11.2.4 LASER-LIGHT-SHEET MOLD 408 11.2.5 RUNNER-EXCHANGING SYSTEM 411 11.2.6 AUTOMATIC TRACKING SYSTEM UNDER HIGH MAGNIFICATIONS 414 11.2.7 VISUALIZATION TECHNIQUE FOR ULTRA-HIGH-SPEED INJECTION MOLDING 416 11.3 STATIC VISUALIZATION TECHNIQUES FOR THE INSIDE OF A MOLD CAVITY. 418 11.3.1 OVERVIEW OF STATIC VISUALIZATION TECHNIQUES 418 11.3.1.1 PLUGGING OF COLORED MATERIALS 418 11.3.1.2 LAMINATION OF COLORED MATERIALS 419 11.3.2 RUNNER-EXCHANGING SYSTEM AND GATE-MAGNETIZATION METHOD 420 11.4 VISUALIZATION HEATING CYLINDER 424 11.4.1 OVERVIEW OF VISUALIZATION TECHNIQUES FOR THE INSIDE OF A HEATING CYLINDER.. 425 11.4.2 GLASS-INSERTED HEATING CYLINDER 428 11.4.3 VISUALIZATION UNIT INSIDE HOPPER THROAT, CHECK-RING, AND RESERVOIR AREAS. 431 11.4.4 IMAGE PROCESSING METHOD FOR LAMINATED SLIT IMAGES 434 REFERENCES 435 12 INJECTION MOLDING CONTROL 43 CONTENTS XVII 12.3.2.2 ADAPTIVE CONTROL BACKGROUND 450 12.3.2.3 RLS ESTIMATION 450 12.3.2.4 POLE PLACEMENT DESIGN 451 12.3.2.5 SOLVING THE DIOPHANTINE EQUATION 452 12.3.2.6 DIRECT IMPLEMENTATION OF ADAPTIVE POLE-PLACEMENT CONTROL 454 12.3.2.7 IMPROVEMENT I - ANTI-WINDUP ESTIMATION 454 12.3.2.8 IMPROVEMENT II - ADAPTIVE FEEDFORWARD CONTROL 457 12.3.2.9 IMPROVEMENT III - CYCLE-TO-CYCLE ADAPTATION 459 12.3.2.10 TEST OF DIFFERENT CONDITIONS 460 12.3.2.11 SUMMARY 461 12.3.3 MODEL PREDICTIVE CONTROL 462 12.3.3.1 MPC BACKGROUND 462 12.3.3.2 GPC DESIGN FOR INJECTION VELOCITY 464 12.3.3.3 STEP RESPONSE COMPARISON OF GPC AND POLE-PLACEMENT 465 12.3.3.4 ADAPTIVE GPC EXPERIMENTS WITH DIFFERENT CONDITIONS 465 12.3.3.5 SUMMARY 467 12.3.4 FUZZY MODEL BASED CONTROL [16] 468 12.3.4.1 FUZZY INFERENCE SYSTEM 468 12.3.4.2 FUZZY MULTI-MODEL AND APPLICATION TO INJECTION VELOCITY 469 12.3.4.3 FUZZY MULTI-MODEL PREDICTIVE CONTROL 474 12.3.4.4 ON-LINE IDENTIFICATION OF MODEL PARAMETERS OF RULE CONSEQUENTS 474 12.3.4.5 BATCH LEARNING OF MEMBERSHIP FUNCTION PARAMETERS OF RULE PREMISES 475 12.3.4.6 EXPERIMENTAL TEST OF FUZZY MULTI-MODEL BASED PREDICTIVE CONTROL 476 12.3.4.7 SUMMARY 481 12.3.5 ITERATIVE LEARNING CONTROL [18] 481 12.3.5.1 ITERATIVE LEARNING CONTROL BACKGROUND 482 12.3.5.2 P-TYPE LEARNING CONTROL ALGORITHM 483 12.3.5.3 OPTIMAL ITERATIVE LEARNING CONTROLLER 485 12.3.5.4 ROBUST AND CONVERGENCE ANALYSIS 488 12.3.5. XVIII CONTENTS 12.4.2.4 CLOSED-LOOP QUALITY CONTROL 507 12.4.2.5 PROCESS AND CONTROL PERFORMANCE MONITORING 507 REFERENCES 507 13 OPTIMAL DESIGN FOR INJECTION MOLDING 511 KALONJI K. KABANEMI, ABDESSALEM DERDOURI AND JEAN-FRANCOIS HETU 13.1 INTRODUCTION 511 13.2 BASIC EQUATIONS FOR THE MOLD FILLING PROBLEM 513 13.2.1 MATHEMATICAL MODEL: HELE-SHAW AND ENERGY EQUATIONS 513 13.2.2 BOUNDARY CONDITIONS 514 13.2.3 NUMERICAL DISCRETIZATION 515 13.3 OPTIMIZATION TECHNIQUES 516 13.3.1 OPTIMIZATION CONCEPT 516 13.3.2 OPTIMIZATION PROBLEMS 516 13.3.3 NUMERICAL SOLUTION OF OPTIMIZATION PROBLEMS 517 13.3.3.1 ZERO-ORDER METHODS 518 13.3.3.2 FIRST- AND SECOND-ORDER METHODS 519 13.3.3.3 COMBINATION OF ZERO-ORDER AND GRADIENT-BASED METHODS 520 13.4 GRADIENT-BASED METHODS AND SENSITIVITY ANALYSIS 521 13.4.1 DIRECT SENSITIVITY EQUATION METHOD 521 13.4.2 ADJOINT EQUATION METHOD 522 13.4.3 COMPARISON OF SOLUTION METHODS 524 13.4.4 CHOICE OF A METHOD 524 13.5 OPTIMAL DESIGN FOR INJECTION MOLDING 525 13.5.1 PROBLEM PARAMETERS 525 13.5.2 PROBLEM DEFINITION 525 13.5.3 DIRECT SENSITIVITY OF THE STATE EQUATIONS 526 13.5.4 SENSITIVITY FORMULATION OF THE OBJECTIVE FUNCTION 528 13.5.5 PARAMETERIZATION OF THE INJECTION PRESSURE AND SENSITIVITIES 528 13.5.6 SENSITIVITIES OF THE FUNCTION CONSTRAINTS 530 13.5.7 FLOW-FRONT TRACKING AND SENSITIVITIES 530 13.5. CONTENTS XIX 14.2 THE MOLDING PROCESS 553 14.3 THE PROBLEM 554 14.3.1 BASIC PHYSICS OF THE PROCESS 555 14.3.2 MATERIAL PROPERTIES 555 14.3.3 GEOMETRIE COMPLEXITY OF MOLD AND PART 556 14.3.4 PROCESS STABILITY 556 14.4 WHY SIMULATE INJECTION MOLDING? 556 14.5 EARLY ACADEMIC WORK ON SIMULATION 557 14.5.1 BOUNDARY CONDITIONS AND SOLIDIFICATION 558 14.6 EARLY COMMERCIAL SIMULATION 559 14.7 SIMULATION IN THE 1980S 561 14.8 ACADEMIC WORK IN THE 1980S 562 14.8.1 MOLD FILLING 562 14.8.2 MOLD COOLING 565 14.8.3 WARPAGE ANALYSIS 565 14.8.4 FIBER ORIENTATION 566 14.9 COMMERCIAL SIMULATION IN THE 1980S 568 14.9.1 CODES DEVELOPED BY LARGE INDUSTRIAIS AND NOT FOR SAELE 570 14.9.1.1 GENERAL ELECTRIC 570 14.9.1.2 PHILIPS/TECHNICAL UNIVERSITY OF EINDHOVEN 570 14.9.2 CODES DEVELOPED BY LARGE INDUSTRIAIS FOR SAELE IN THE MARKETPLACE 571 14.9.2.1 SDRC 571 14.9.2.2 GRAFTEK 571 14.9.3 COMPANIES DEVOTED TO DEVELOPING AND SELLING SIMULATION CODES 571 14.9.3.1 AC TECHNOLOGY 571 14.9.3.2 MOLDFLOW 572 14.9.3.3 SIMCON KUNSTSTOFFTECHNISCHE SOFTWARE GMBH 573 14.10 SIMULATION IN THE 1990S 573 14.11 ACADEMIC WORK IN THE 1990S 574 14.12 COMMERCIAL DEVELOPMENTS IN THE 1990S 575 14.12.1 SDRC 575 14.12.2 MOLDFLOW 576 14.12.3 ACTECHNOLOGY/C-MOLD 580 14.12.4 SIMCON 580 14.12.5 SIGMA ENGINEERING 580 14.12.6 TIMON 581 14.12. XX CONTENTS 14.16 CONDUSION 587 14.17 APPENDIX: 2.5D ANALYSIS 587 14.17.1 MATERIAL PROPERTIES 588 14.17.2 GEOMETRIE CONSIDERATIONS 589 14.17.3 SIMPLIFICATION BY MATHEMATICAL ANALYSIS 590 14.18 ACKNOWLEDGMENTS 592 REFERENCES 592 15 THREE-DIMENSIONAL INJECTION MOLDING SIMULATION 599 LUISA SILVA, JEAN-FRANCOIS AGASSANT AND THIERRY COUPEZ 15.1 INTRODUCTION 599 15.1.1 PROCESS BACKGROUND 599 15.1.2 HISTORICAL BACKGROUND ON 3D SIMULATION 600 15.1.3 GENERAL NUMERICAL TECHNIQUES FOR 3D INJECTION MOLDING SIMULATION 602 15.1.3.1 CONSTITUTIVE EQUATIONS 602 15.1.3.2 BOUNDARY CONDITIONS 605 15.1.4 NUMERICAL ISSUES IN 3D INJECTION MOLDING 606 15.2 TEMPERATURE INDEPENDENT FLOWS AND FINITE ELEMENT TECHNIQUES 607 15.2.1 GENERALIZED STOKES PROBLEM 607 15.2.1.1 MIXED FINITE ELEMENTS FOR NEWTONIAN FLOWS 607 15.2.1.2 MORE GENERAL VISCOUS RESOLUTION 611 15.2.2 EXTENSION TO WEAKLY ISOTHERMAL COMPRESSIBLE FLOWS 612 15.2.3 EXTENSION TO NAVIER AND STOKES EQUATIONS 614 15.2.4 EXTENSION TO VISCOELASTIC FLOWS 616 15.2.4.1 VISCOELASTICITY AND CONSTITUTIVE MODELS 617 15.2.4.2 FLOW DETERMINATION FOR VISCOELASTIC MATERIALS 618 15.3 FREE SURFACE DETERMINATION 622 15.3.1 TECHNIQUES TO DETERMINE THE INTERFACE 622 15.3.2 THE VOF (VOLUME OFFLUID METHOD) 623 15.3.2.1 RESOLUTION OF THE TRANSPORT EQUATION 623 15.3.2.2 ADVANTAGES AND DISADVANTAGES OF THE VOF METHOD 625 15.3. CONTENTS XXI 15.5.3 APPLICATION TO FILLING SIMULATION WITH MOLD COUPLING 639 15.6 APPLICATION TO A 3D PART 641 15.7 CONCLUSION 644 ACKNOWLEDGEMENTS 645 APPENDIXES 645 APPENDIX 15.1: VISCOSITY EQUATIONS 645 APPENDIX 15.2: TAIT EQUATION PARAMETERS 646 NOTATIONS 647 REFERENCES 650 16 VISCOELASTIC INSTABILITIES IN INJECTION MOLDING 653 G. W. M. PETERS, A. C. B. BOGAERDS 16.1 INTRODUCTION 653 16.2 BACKGROUND, LITERATURE REVIEW 654 16.3 EXPERIMENTAL MOTIVATION 656 16.4 ANALYSIS 658 16.5 NUMERICAL MODELLING: GOVERNING EQUATIONS 660 16.6 NUMERICAL MODELLING: FINITE ELEMENT ANALYSIS 662 16.7 DOMAIN PERTURBATION TECHNIQUE 668 16.8 RESULTS 672 16.8.1 STEADY STATE RESULTS 673 16.8.2 STABILITY RESULTS 677 16.9 DISCUSSION 678 SYMBOLS AND NOTATION 680 REFERENCES 682 PART V: MICROSTRUCTURE DEVELOPMENT, CHARACTERIZATION, AND PREDICTION 685 17 EVOLUTION OF STRUCTURAL HIERARCHY IN INJECTION MOLDED SEMKRYSTALLINE POLYMERS 687 M. CAKMAK AND B. YALCIN 17.1 INTRODUCTION 687 17.2 FUNDAMENTALS OF THE INJECTION MOLDING PROCESS 688 17.2.1 EXPERIENCES OF POLYMER CHAINS IN A TYPICAL INJECTION MOLDING MACHINE 688 17.2.2 FLOW BEHAVIOR INTO INJECTION MOLDING CAVITIES 689 17.3 STRUCTURE DEVELOPMENT IN INJECTION MOLDED FAST CRYSTALLIZING POLYMERS 693 17.3. XXII CONTENTS 17.4 STRUCTURE DEVELOPMENT IN INJECTION MOLDED SLOWLY CRYSTALLIZING POLYMERS . 709 17.4.1 GENERAL CHARACTERISTICS OF STRUCTURE DEVELOPMENT IN SLOW CRYSTALLIZING POLYMERS 710 17.4.2 POLY(PHYENYLENE SULFIDE) (PPS) 710 17.4.3 EFFECT OF MOLECULAR WEIGHT 713 17.4.4 POLY(ETHER ETHER KETONE) PEEK 16 17.4.5 SYNDIOTACTIC POLYSTYRENE (S-PS) 719 17.4.6 POLYETHYLENE NAPHTHALATE (PEN) 721 17.4.7 STRUCTURE CHARACTERISTICS OF INJECTION MOLDED SLOWLY CRYSTALLIZING POLYMERS - SUMMARY 722 17.5 SIMULATION OF THE STRUCTURE DEVELOPMENT DURING INJECTION MOLDING PROCESS 722 17.6 GENERAL SUMMARY 725 ABBREVIATIONS 726 REFERENCES 727 18 MODELING ASPECTS OF POST-FILLING STEPS IN INJECTION MOLDING 73 1 ROBERTO PANTANI AND GIUSEPPE TITOMANLIO 18.1 INTRODUCTION 731 18.1.1 THE POST-FILLING STAGES 732 18.1.2 STATE OF THE ART ON POST-FILLING MODELING 732 18.1.3 OUTLINE 735 18.2 UNDERSTANDING PRESSURE EVOLUTION 736 18.2.1 THE EVOLUTION OF PRESSURE CURVES DURING INJECTION MOLDING 736 18.2.1.1 THE FILLING STAGE 736 18.2.1.2 THE PACKING-HOLDING STAGE 737 18.2.1.3 THE COOLING STAGE 740 18.2.2 PRESSURE CURVES INSIDE THE RUNNERS DURING COOLING 744 18.3 A SUITABLE MODELING OF THE PROCESS 744 18.3.1 MODELING THE PACKING - HOLDING STAGE 746 18.3.2 MODELING THE COOLING STAGE 747 18.3.3 TIME-DEPENDING HEAT TRANSFER COEFFICIENT 747 18. CONTENTS XXIII 18.6.3 RESULTS OF MODELING FOR AMORPHOUS MATERIALS 762 18.7 SEMI-CRYSTALLINE POLYMERS 766 18.7.1 EFFECT OF CRYSTALLINITY ON MATERIAL PROPERTIES 767 18.7.1.1 EFFECT OF CRYSTALLINITY ON RHEOLOGY 767 18.7.1.2 EFFECT OF CRYSTALLINITY ON SPECIFIC VOLUME 769 18.8 MORPHOLOGY EVOLUTION DURING THE POST-FILLING STAGES 770 18.9 CONCLUDING REMARKS 773 NOMENCLATURE 774 REFERENCES 776 19 VOLUMETRIE AND ANISOTROPIE SHRINKAGE IN INJECTION MOLDINGS OF THERMOPLASTICS 779 A. I. ISAYEV AND KEEHAE KWON 19.1 INTRODUCTION 779 19.2 THEORETICAL ANALYSIS 780 19.2.1 VOLUMETRIE SHRINKAGE 780 19.2.2 ANISOTROPIE SHRINKAGE 782 19.3 COMPARISON BETWEEN SIMULATIONS AND EXPERIMENTS 789 19.3.1 VOLUMETRIE SHRINKAGE 789 19.3.2 ANISOTROPIE SHRINKAGE 793 19.4 CONCLUSIONS 804 19.5 ACKNOWLEDGEMENT 805 NOMENCLATURE 805 REFERENCES 807 20 THREE-DIMENSIONAL SIMULATION OF GAS-ASSISTED AND CO-INJECTION MOLDING PROCESSES 809 JEAN-FRANCOIS HETU, FLORIN LLINCA 20.1 INTRODUCTION 809 20.2 BACKGROUND 811 20.3 MATHEMATICAL MODELING AND FORMULATIONS 812 20.3.1 CONSERVATION OF MASS AND MOMENTUM 813 20.3.2 CONSERVATION OF ENERGY 814 20.3.3 BOUNDARY AND INITIAL CONDITIONS 814 20.3.4 THE COMPRESSIBILITY EFFECTS 815 20.4 FRONT CAPTURING METHODS FOR CO-INJECTION MOLDING 815 20.4. SUBJECT INDEX 917 XXIV CONTENTS 20.5.2 SOLUTION ALGORITHM 822 20.6 VALIDATION CASES AND APPLICATIONS 823 20.6.1 GAS-ASSISTED INJECTION MOLDING 824 20.6.1.1 GAS-ASSISTED INJECTION OF A PLATE WITH A FLOW CHANNEL 824 20.6.1.2 SECONDARY PENETRATION IN GAS-ASSISTED INJCCTION 828 20.6.1.3 GAS-ASSISTED INJECTION OF A THKK PART 829 20.6.2 CO-INJECTION MOLDING 830 20.6.2. L CO-INJECTION OF A SIDE GATCD RCCTANGULAR PLATE 830 20.6.2.2 CO-INJECTION OF A CENTER-GATED RECTANGULAR PLATE 833 20.6.2.3 CO-INJECTION OF A C-SHAPCD PLATE 837 20.6.3 SIMULATION OFBREAKTHROUGH INCO-INJCCTION MOLDING.... 838 20.7 CONCLUSIONS 845 LIST OF SYMBOLS AND ABBRCVIATIONS 846 REFERENCES. 848 21 CO-INJECTION MOLDING OF POLYMERS 851 A. I. ISUYEV AND NAM HYUNG KIM 21.1 INTRODUCTION 851 21.2 TECHNOLOGY 853 21.3 EXPERIMENTAL STUDIES 860 21.3.1 EFFECT OF PROCESS PARAMETERS ON SKIN-CORC STRUCTURE 860 21.3.2 BREAKTHROUGH PHENOMENON 867 21.3.3 INTERFACIAL INSTABILITY 874 21.3.4 MECHANICAL PROPERTIES 875 21.3.5 MICROSTRUCTURE 881 21.3.6 BIOMEDICA! APPLICATIONS 884 21.4 MODELING OF THE CO-INJECTION MOLDING PROCESS 884 21.4.1 SIMULATION APPROACHES 884 21.4.2 COMPARISON BETWEEN SIMULATION AND EXPERIMENT 898 21.5 CONCLUSIONS 909 NOMENCLATURE 909 REFERENCES. 912
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spelling	Injection molding technology and fundamentals Musa R. Kamal (ed.) ... With contributions by Jean-Francois Agassant ... Munich [u.a.] Hanser 2009 XXVIII, 926 S. Ill., graph. Darst. 25 cm txt rdacontent n rdamedia nc rdacarrier Progress in polymer processing Literaturangaben "A book about the fundamentals and applications of injection molding"--Provided by publisher. Spritzgießen Injection molding of metals Injection molding of plastics Injection molding of rubber Spritzgießen (DE-588)4056561-0 gnd rswk-swf Spritzgießen (DE-588)4056561-0 s DE-604 Kamal, Musa R. 1934- (DE-588)133588033 edt Agassant, Jean-François Sonstige (DE-588)112277837 oth DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017598743&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Injection molding technology and fundamentals Spritzgießen Injection molding of metals Injection molding of plastics Injection molding of rubber Spritzgießen (DE-588)4056561-0 gnd
subject_GND	(DE-588)4056561-0
title	Injection molding technology and fundamentals
title_auth	Injection molding technology and fundamentals
title_exact_search	Injection molding technology and fundamentals
title_full	Injection molding technology and fundamentals Musa R. Kamal (ed.) ... With contributions by Jean-Francois Agassant ...
title_fullStr	Injection molding technology and fundamentals Musa R. Kamal (ed.) ... With contributions by Jean-Francois Agassant ...
title_full_unstemmed	Injection molding technology and fundamentals Musa R. Kamal (ed.) ... With contributions by Jean-Francois Agassant ...
title_short	Injection molding
title_sort	injection molding technology and fundamentals
title_sub	technology and fundamentals
topic	Spritzgießen Injection molding of metals Injection molding of plastics Injection molding of rubber Spritzgießen (DE-588)4056561-0 gnd
topic_facet	Spritzgießen Injection molding of metals Injection molding of plastics Injection molding of rubber
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