Verfügbarkeit: Recycling of plastics

Recycling of plastics:

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Bibliographische Detailangaben
Weitere Verfasser:	Niessner, Norbert (HerausgeberIn)
Format:	Buch
Sprache:	German
Veröffentlicht:	Munich Hanser [2022]
Schlagworte:	Recycling Kunststoffabfall Economic Recycling Recycling Technologies Sustainability FBKTRECY: Recycling
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	XXXIII, 836 Seiten Illustrationen, Diagramme 25 cm
ISBN:	9781569908563 1569908567

Internformat

MARC


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245	1	0	\|a Recycling of plastics \|c Norbert Niessner [editor]
264		1	\|a Munich \|b Hanser \|c [2022]
264		4	\|c © 2022
300			\|a XXXIII, 836 Seiten \|b Illustrationen, Diagramme \|c 25 cm
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653			\|a Economic Recycling
653			\|a Recycling Technologies
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776	0	8	\|i Erscheint auch als \|n Online-Ausgabe, EPUB \|z 978-1-56990-858-7
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Datensatz im Suchindex

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adam_text	CONTENTS PREFACE . V FOREWORD . VII FOREWORD 2 . IX THE AUTHORS . XI THE EDITOR . XI THE COAUTHORS . XII GLOSSARY . XV PART A: FUNDAMENTALS; LEGISLATIVE, ECONOMIC, AND POLITICAL CONSIDERATIONS; LCA . 1 1 INTRODUCTION . 3 NORBERT NIEFINER 1.1 INDUSTRIAL ASPECTS . 4 1.2 PLASTICS POLLUTION . 9 1.3 PLASTICS POLLUTION: BIO SOLUTION? . 12 1.4 RECYCLING METHODS: CLOSING THE LOOP . 20 1.5 SUMMARY . 22 2 INTRODUCTION TO MAJOR THERMOPLASTIC POLYMERS IN THE CONTEXT OF RECYCLING . 25 TRISTAN KOLB, ANDREAS SCHEDL, HANS-WERNER SCHMIDT 2.1 CHEMICAL STRUCTURE AND SYNTHESIS OF INDUSTRIAL POLYMERS . 26 2.1.1 POLYMER ARCHITECTURE . 26 2.1.2 POLYMERS IN THE SOLID STATE . 30 2.1.3 CATEGORIZATION OF POLYMERS . 31 2.1.4 POLYMERIZATION . 32 2.1.4.1 CHAIN-GROWTH POLYMERIZATION . 33 2.1.4.2 STEP-GROWTH POLYMERIZATION . 38 2.2 POLYMER DEGRADATION AND RECYCLING . 42 2.2.1 PHYSICAL AGING . 42 2.2.2 CHEMICAL AGING . 43 2.2.2.1 THERMAL AND THERMOMECHANICAL AGING . 44 2.2.2.2 OXIDATIVE AGING . 46 2.2.2.3 AGING BY HYDROLYSIS AND BIOLOGICAL PROCESSES . 48 2.3 THE WORLD OF THERMOPLASTIC INDUSTRIAL POLYMERS . 50 2.3.1 OVERVIEW OF POLYMER CLASSES AND USE . 50 2.3.2 PROFILES OF IMPORTANT COMMERCIAL POLYMERS . 53 2.3.2.1 POLYETHYLENE . 53 2.3.2.2 POLYPROPYLENE . 55 2.3.2.3 POLYVINYL CHLORIDE . 57 2.3.2.4 POLYSTYRENE . 58 2.3.2.5 POLYETHYLENE TEREPHTHALATE . 59 2.3.2.6 POLYAMIDE . 61 2.3.2.7 POLYCARBONATE . 64 2.3.2.8 POLY(METHYL METHACRYLATE) . 65 2.3.2.9 POLYTETRAFLUOROETHYLENE . 67 3 LEGISLATION . 71 MICHAEL ULBRICH, SOREN HORNICKE 3.1 A CATEGORIZATION OF REGULATORY APPROACHES TO PROMOTE RECYCLING . 72 3.1.1 LEGAL MEASURES . 73 3.1.2 FINANCIAL MEASURES . 77 3.2 APPROACHES IN VARIOUS WORLD REGIONS . 79 3.2.1 GLOBAL REGULATION . 79 3.2.2 EUROPE . 80 3.2.3 APAC . 84 3.2.4 NAFTA . 85 3.2.5 REST OF THE WORLD . 86 4 ECONOMICS . 91 MICHAEL ULBRICH, MARVIN STIEFERMANN 4.1 ECONOMIC CHALLENGES OF RECYCLING PLASTICS . 91 4.2 FRAMEWORK FOR RECYCLING BUSINESS CASES . 93 4.2.1 ILLUSTRATION 1: CHEMICAL RECYCLING OF POLYOLEFINS . 94 4.2.2 ILLUSTRATION 2: CHEMICAL RECYCLING OF PET . 96 4.2.3 ILLUSTRATION 3: MICROWAVE-ASSISTED DEPOLYMERIZATION OF STYRENE . 97 4.3 IMPLICATIONS AND OUTLOOK . 99 5 POLITICAL BOUNDARY CONDITIONS - PLASTICS WASTE MANAGEMENT 103 KLAUS WITTSTOCK, VICTORIA WESSOLOWSKI 5.1 PLASTICS RECYCLING AND ITS POLITICAL RELEVANCE . 103 5.2 OVERVIEW OF POLITICAL MEASURES RELATED TO PLASTIC WASTE MANAGEMENT 115 5.2.1 GLOBAL PLASTIC WASTE MANAGEMENT . 117 5.2.2 PLASTIC WASTE MANAGEMENT IN EUROPE . 121 5.2.3 PLASTIC WASTE MANAGEMENT IN GERMANY . 126 5.2.4 PLASTIC WASTE MANAGEMENT IN CHINA . 131 5.2.5 PLASTIC WASTE MANAGEMENT IN THE UNITED STATES OF AMERICA . 133 5.3 DEVELOPMENTS AND POLITICAL TRENDS IN PLASTIC WASTE MANAGEMENT . 136 5.3.1 HARMONIZATION OF LEGAL ASPECTS . 136 5.3.2 RESTRICTIONS ON MICROPLASTICS . 139 5.3.3 TRANSPARENCY ON CHEMICALS . 141 5.3.4 ECO-DESIGN, DESIGN FOR RECYCLING AND DESIGN FOR SUSTAINABILITY . 143 5.3.5 ECONOMIC INSTRUMENTS . 145 5.3.6 NEW RECYCLING TECHNOLOGIES . 150 5.3.7 REPLACEMENT OF VIRGIN BY RECYCLED CONTENT . 152 5.3.8 KEEPING CARBON IN THE LOOP . 153 5.3.9 CONCLUSION . 154 6 LIFE CYCLE ASSESSMENT (LCA) . 161 6.1 INTRODUCTION: WHAT IS LIFE CYCLE ASSESSMENT? . 161 PETER SALING 6.1.1 HISTORY AND GENERAL ASPECTS . 161 6.1.2 LCA PRINCIPLES DEFINED BY ISO STANDARDS . 162 6.1.2.1 DEFINITIONS . 162 6.1.2.2 GOAL AND SCOPE OF AN LCA STUDY . 163 6.1.2.3 LIFE CYCLE INVENTORIES . 166 6.1.2.4 PROCESSES WITH CO-PRODUCTS . 166 6.1.2.5 ALLOCATION IN RECYCLING PROCESSES . 167 6.1.3 IMPACT ASSESSMENT . 168 6.1.3.1 ENVIRONMENTAL FOOTPRINT OF THE EU . 169 6.1.3.2 IMPACT CATEGORIES USED BY BASF LCA METHODS . 174 6.1.4 INTERPRETATION . 175 6.1.5 EXAMPLES OF LCA STUDIES IN THE RECYCLING CONTEXT . 176 6.1.5.1 RECYCLING OF PET . 176 6.1.5.2 RECYCLING OF WEEE . 177 6.1.5.3 CHEMCYCLINGYY OF PLASTIC WASTE FROM PACKAGING . 179 6.1.5.4 ECO-EFFICIENCY ANALYSIS . 181 6.1.6 SUMMARY . 183 6.2 LIFE CYCLE ASSESSMENT FOR DIFFERENT RECYCLING ROUTES OF POLYSTYRENE . 189 REGINO WEBER, THOMAS NEUMEYER 6.2.1 BACKGROUND OF THE STUDY . 189 6.2.2 DIFFERENT RECYCLING TECHNOLOGIES FOR POLYSTYRENE WASTE . 190 6.2.3 GOAL AND SCOPE OF THE STUDY . 191 6.2.4 DATA FOR LIFE CYCLE INVENTORY (LCI) . 198 6.2.5 LIFE CYCLE IMPACT ASSESSMENT (LCIA) RESULTS . 202 6.2.6 ANALYSIS AND INTERPRETATION . 208 6.2.7 CONCLUSION . 210 6.3 LIFE CYCLE ASSESSMENT OF A NEW MONOMER RECYCLING PROCESS FOR PET . 212 MANDY PASCHETAG, HANNES SCHNEIDER, STEPHAN SCHOLL 6.3.1 THE REVOLPET PROCESS . 214 6.3.2 GOAL AND SCOPE OF THE STUDY . 214 6.3.3 DATA FOR LIFE CYCLE INVENTORY (LCI) . 221 6.3.4 RESULTS OF THE LIFE CYCLE IMPACT ASSESSMENT (LCIA) . 222 6.3.5 ANALYSIS AND INTERPRETATION . 232 PART B: MAJOR RECYCLING TECHNOLOGIES . 239 7 OVERVIEW OF MAJOR RECYCLING TECHNOLOGIES . 241 CHRISTIAN HOPMANN, RAINER DAHLMANN, MARTIN FACKLAM 7.1 INTRODUCTION . 241 7.2 MECHANICAL RECYCLING . 247 7.3 FEEDSTOCK RECYCLING . 252 7.3.1 CHEMICAL RECYCLING . 253 7.3.2 SOLVOLYTIC-BASED RECYCLING . 256 7.3.3 THERMOCHEMICAL PROCESSES . 261 7.3.4 BIODEGRADATION . 266 8 MECHANICAL RECYCLING . 275 8.1 BASIC PRINCIPLES . 275 ACHIM SCHMIEMANN 8.1.1 COARSE OR PRELIMINARY SHREDDING . 279 8.1.2 MEDIUM SIZE SHREDDING . 285 8.1.3 COMMINUTION OF BONDED MATERIALS . 287 8.1.4 CLASSIFYING AND SORTING . 290 8.1.5 EXTRUSION . 295 8.2 MECHANICAL RECYCLING OF POLYOLEFINS . 301 MARCO AMICI 8.2.1 INTRODUCTION - MARKET SIZE AND RECYCLING CHALLENGE . 301 8.2.2 MAIN PO APPLICATIONS . 301 8.2.3 COMMON PROCESSES FOR MECHANICAL RECYCLING OF PO . 302 8.2.4 MECHANICAL RECYCLING OF RIGID PO: PROCESSES AND PHYSICO-CHEMICAL CHANGES . 304 8.2.4.1 HIGH-DENSITY PE (HDPE) . 305 8.2.4.2 POLYPROPYLENE (PP) . 306 8.2.4.3 PE/PP BLENDS . 307 8.2.5 MECHANICAL RECYCLING OF FLEXIBLE PO: PROCESSES AND PHYSICO-CHEMICAL CHANGES . 313 8.2.5.1 INDUSTRIAL FILMS . 313 8.2.5.2 MULTILAYER FLEXIBLE PACKAGING . 314 8.2.6 FOOD CONTACT REGULATIONS FOR MECHANICALLY RECYCLED PO . 315 8.3 MECHANICAL RECYCLING OF PET . 317 THOMAS SCHRODER 8.3.1 INTRODUCTION . 318 8.3.2 MARKET OVERVIEW AND FIELDS OF APPLICATION . 320 8.3.3 CIRCULAR ECONOMY OF PET BOTTLES . 322 8.3.4 BOTTLE-TO-BOTTLE RECYCLING OF PET . 324 8.3.4.1 BOTTLE-TO-FLAKE PROCESSES . 324 8.3.4.2 DEEP CLEANING PROCESSES FOR PET FLAKES . 325 8.3.5 BARRIERS TO THE USE OF RECYCLED PET . 328 8.4 MECHANICAL RECYCLING OF STYRENICS . 331 8.4.1 MECHANICAL RECYCLING OF POLYSTYRENE . 331 HERMAN VAN ROOST 8.4.1.1 INTRODUCTION - QUALITY-DRIVEN CIRCULARITY . 331 8.4.1.2 ADEQUATE RECYCLATE QUALITY . 333 8.4.1.2.1 PRACTICAL QUALITY STANDARD . 333 8.4.1.2.2 VIRGIN EQUIVALENCY . 333 8.4.1.2.3 PURITY VS. POLYMER PROPERTIES . 335 8.4.1.3 THE IMPORTANCE OF FOOD CONTACT QUALITY FOR RECYCLATES . 341 8.4.1.3.1 FOOD CONTACT IN THE VIRGIN INDUSTRY CONTEXT . 341 8.4.1.3.2 THE PET BOTTLE RECYCLING REFERENCE . 343 8.4.1.3.3 MANY WAYS FOR A RECYCLATE TO BE NON-FOOD-CONTACT . 344 8.4.1.3.4 A VIRTUOUS CIRCLE TOWARDS PLASTICS CIRCULARITY . 346 8.4.1.4 FOOD CONTACT MECHANICAL RECYCLING PROCESS OF PS . 347 8.4.1.4.1 DEEP SORTING . 347 8.4.1.4.2 HOT WASHING . 349 8.4.1.4.3 FLAKE SORTING . 352 8.4.1.4.4 SUPER-CLEANING . 354 8.4.1.4.5 EXTRUSION AND MELT FILTRATION . 358 8.4.1.4.6 INDUSTRIAL BLUEPRINT FOR A HIGH-PURITY PS RECYCLING PLANT . 359 8.4.1.5 WASTE FEEDSTOCK FOR CIRCULAR PS . 361 8.4.1.5.1 PS PACKAGING IN EU WASTE STREAMS . 361 8.4.1.5.2 THE POTENTIAL OF PRE-INCINERATOR EXTRACTION . 363 8.4.1.6 CIRCULARITY OF POLYMERS - THE UNIQUE POSITION OF PS 365 8.4.1.6.1 OPEN LOOP VS. CLOSED LOOP: IS THAT REALLY THE QUESTION? . 365 8.4.1.6.2 A MATERIAL ' S CIRCULARITY AND CIRCULARITY MATRIX . 366 8.4.1.6.3 CIRCULAR UNIFICATION OF RIGID AND FOAMED PS . 370 8.4.1.7 CIRCULAR DESIGN OF PS PACKAGES . 371 8.4.1.7.1 DESIGN FOR INCREASED CIRCULAR YIELD . 371 8.4.1.7.2 GENERALIZED PACKAGING DESIGN FOR FOOD CONTACT . 373 8.4.2 MECHANICAL RECYCLING OF STYRENE COPOLYMERS . 375 EIKE JAHNKE 8.4.2.1 INTRODUCTION . 375 8.4.2.2 THE CHEMISTRY OF PS AND ABS DURING PRODUCTION, PROCESSING AND DURING THEIR LIFE CYCLES . 378 8.4.2.3 PROSPECTS, PREREQUISITES AND LIMITATIONS OF THE MECHANICAL RECYCLING OF STYRENICS . 384 8.4.2.4 MECHANICALLY RECYCLED PCR ABS - AN ECONOMIC CASE STUDY . 391 8.4.2.5 CONCLUSION . 394 8.4.3 MECHANICAL RECYCLING OF EXPANDABLE POLYSTYRENE (EPS) . 397 NORBERT NIEJINER 8.5 MECHANICAL RECYCLING OF ENGINEERING THERMOPLASTICS . 399 HANNAH MANGOLD, CAROLINE BEYER 8.5.1 MARKET SIZE AND RECYCLING CHALLENGE . 400 8.5.2 MAJOR APPLICATIONS AND RECYCLING PROCESS . 402 8.5.2.1 POLYAMIDES . 402 8.5.2.1.1 POLYAMIDE 6 . 402 8.5.2.1.2 POLYAMIDE 66 . 404 8.5.2.2 POLYURETHANES . 406 8.5.2.2.1 REBONDING WITH ADHESIVES . 406 8.5.2.2.2 MOLDING AND EXTRUSION . 406 8.5.2.2.3 REGRINDING AND POWDERING . 407 8.5.2.2.4 SOLVENT-BASED RECYCLING . 407 8.5.2.3 OTHER ENGINEERING PLASTICS . 407 8.5.3 MAJOR APPLICATIONS OF RECYCLED ENGINEERING PLASTICS . 408 8.6 MECHANICAL RECYCLING OF PVC . 411 JASON LEADBITTER 8.6.1 INTRODUCTION . 411 8.6.2 HOW IS PVC MANUFACTURED? . 412 8.6.3 PVC COMPOUNDING . 413 8.6.4 PVC APPLICATIONS IN USE . 413 8.6.5 WASTE HIERARCHY AND END-OF-LIFE OPTIONS . 414 8.6.6 HOW TO GO ABOUT RECYCLING OF PVC? . 417 8.6.7 THE DAWN OF A NEW INDUSTRY . 418 8.6.7.1 VINYLPLUS . 419 8.6.7.2 RECOVINYL . 419 8.6.7.3 SUCCESSES OF THE VINYLPLUS INITIATIVE - EUROPEAN RECYCLED PVC MARKET SIZE . 421 8.6.8 EUROPEAN MARKETS FOR RECYCLED PVC . 422 8.6.9 THE RECYCLABILITY OF PVC . 422 8.6.10 LEGACY ADDITIVES AND REGULATORY ISSUES . 424 8.6.10.1 LEAD STABILIZERS . 424 8.6.10.2 LOW MOLECULAR WEIGHT ORTHOPHTHALATE PLASTICIZERS . 425 8.6.11 BENEFITS OF PVC RECYCLING FROM A LIFE CYCLE PERSPECTIVE . 425 8.7 COMPATIBILIZATION OF BLENDS FOR MECHANICAL RECYCLING . 426 NORBERT NIEFINER, BIANCA WILHELMUS 8.7.1 CLASSIFICATION OF POLYMER BLENDS . 426 8.7.2 GENERAL PRINCIPLE OF COMPATIBILIZERS . 428 8.7.3 SELECTED EXAMPLES OF COMPATIBILIZED BLENDS . 429 8.7.4 COMPATIBILIZATION IN MECHANICAL RECYCLING . 431 9 CHEMICAL RECYCLING . 435 9.1 BASIC PRINCIPLES . 435 9.1.1 AN OVERVIEW OF MAJOR RECYCLING TECHNOLOGIES . 435 BIANCA WILHELMUS 9.1.1.1 INTRODUCTION . 435 9.1.1.2 TECHNOLOGIES . 438 9.1.1.3 HISTORICAL OVERVIEW OF THERMOLYTIC PROCESSES . 439 9.1.1.4 RECENT APPROACHES FOR PYROLYSIS AND GASIFICATION . 446 9.1.1.5 SOLVOLYTIC PROCESSES . 451 9.1.1.5.1 POLYETHYLENE TEREPHTHALATE . 451 9.1.1.5.2 POLYURETHANES . 454 9.1.1.5.3 POLYAMIDES . 455 9.1.1.5.4 POLYCARBONATE . 455 9.1.1.6 OUTLOOK . 455 9.1.2 PETROCHEMICAL FEEDSTOCK RECYCLING . 463 DIETER STAPF 9.1.2.1 WASTE & RECYCLING . 464 9.1.2.2 THE WASTE-TO-CHEMICALS PROCESS CHAIN . 468 9.1.2.3 UPGRADING AND USE OF PYROLYSIS OIL AS PETROCHEMICAL FEEDSTOCK . 470 9.1.2.4 DECENTRALIZED VERSUS CENTRALIZED CHEMICAL RECYCLING . 472 9.1.2.5 THE STATUS OF PETROCHEMICAL FEEDSTOCK RECYCLING . 473 9.1.3 PLASTIC RECYCLING BY DEPOLYMERIZATION . 474 ACHIM SCHMIDT-RODENKIRCHEN, STEPHAN ASCHAUER, THORSTEN GERDES, NORBERT NIEFINER 9.1.3.1 INTRODUCTION . 474 9.1.3.2 DESIGN ISSUES FOR FLUIDIZED-BED REACTORS . 476 9.1.3.2.1 THERMODYNAMICS . 476 9.1.3.2.2 KINETICS . 477 9.1.3.3 FLUIDIZED-BED REACTOR TECHNOLOGY . 479 9.1.3.3.1 PHYSICAL BASICS . 480 9.1.3.3.2 TECHNICAL DESIGN . 485 9.1.3.3.3 RAW GAS TREATMENT . 488 9.1.3.3.4 SCALE-UP . 492 9.1.3.3.5 INDUSTRIAL APPLICATIONS OF FLUIDIZED BEDS IN PLASTIC RECYCLING . 494 9.2 CHEMICAL RECYCLING OF POLYOLEFINS . 499 ADRIAN GRIFFITHS, ALEJANDRO SANCHEZ, STEPHANIE LOO 9.2.1 INTRODUCTION . 499 9.2.2 BASIC TECHNICAL PRINCIPLE . 500 9.2.3 EXAMPLES . 501 9.2.4 PRODUCTS: PYROLYSIS OILS . 503 9.2.5 APPLICATIONS . 510 9.2.6 MARKET . 512 9.2.6.1 CAPACITY . 512 9.2.6.2 COST . 514 9.2.6.3 COLLABORATORS . 517 9.2.6.4 CIRCULARITY . 518 9.2.6.5 CARBON REDUCTION . 520 9.2.7 CONCLUSION . 522 9.3 CHEMICAL RECYCLING OF PET . 525 CARSTEN EICHERT, VITALIJ SALIKOV, STEPHAN SCHOLL 9.3.1 INTRODUCTION . 525 9.3.2 OVERVIEW: OPTIONS FOR RECYCLING OF FEED MATERIALS . 526 9.3.3 CHEMICAL RECYCLING AND ITS RELEVANCE FOR PET . 529 9.3.3.1 PYROLYSIS . 529 9.3.3.2 CHEMICAL DEPOLYMERIZATION . 530 9.3.4 PET MONOMERS . 532 9.3.5 MONOMER RECYCLING OF PET . 534 9.3.5.1 METHANOLYSIS . 535 9.3.5.2 GLYCOLYSIS . 535 9.3.5.3 HYDROLYSIS . 536 9.4 CHEMICAL RECYCLING OF POLYSTYRENE . 544 NORBERT NIEFINER, ACHIM SCHMIDT-RODENKIRCHEN 9.4.1 INTRODUCTION . 544 9.4.2 OVERVIEW AND CHALLENGES . 544 9.4.3 LABORATORY PRE-TRIALS . 547 9.4.4 TRIALS IN THE FLUID BED REACTOR (INVERTEC) . 549 9.4.5 TRIALS WITH PS AND IMPURITIES . 552 9.4.6 CONCLUSION . 555 9.5 CHEMICAL RECYCLING OF ENGINEERING THERMOPLASTICS . 556 HANNAH MANGOLD, CAROLINE BEYER 9.5.1 INTRODUCTION: MARKET SIZE AND RECYCLING CHALLENGE . 556 9.5.2 OVERVIEW OF CHEMICAL RECYCLING PROCESSES . 558 9.5.2.1 POLYAMIDES (PA) . 558 9.5.2.1.1 POLYAMIDE 6 (PA6) . 558 9.5.2.1.2 POLYAMIDE 66 (PA66) . 562 9.5.2.2 POLYURETHANES (PUS) . 567 9.5.2.2.1 HYDROLYSIS AND ALCOHOLYSIS . 569 9.5.2.2.2 AMINOLYSIS . 569 9.5.2.2.3 PHOSPHOROLYSIS . 570 9.5.2.2.4 GLYCOLYSIS . 570 9.5.2.2.5 THERMOCHEMICAL RECYCLING . 571 9.5.2.3 POLYBUTYLENE TEREPHTHALATE (PBT) . 571 9.5.2.4 OTHER ENGINEERING PLASTICS . 572 9.5.3 APPLICATIONS OF MAJOR RECYCLED ENGINEERING PLASTICS . 572 9.6 CHEMICAL RECYCLING OF PTFE (AS A MODEL FOR OTHER POLYMERS) . 577 ACHIM SCHMIDT-RODENKIRCHEN, KLAUS HINTZER, THORSTEN GERDES 9.6 A INTRODUCTION . 577 9.6.2 MANUFACTURING PROCESS FOR PTFE AND OTHER PERFLUORINATED POLYMERS . 579 9.6.3 MECHANISM OF PTFE DEPOLYMERIZATION . 581 9.6.4 RECYCLING PTFE AND PERFLUORINATED POLYMER MATERIALS . 583 9.6.4.1 PTFE PRODUCTION WASTE . 583 9.6.4.2 PTFE COMPOSITES PRODUCTION WASTE . 584 9.6.4.3 PERFLUORINATED THERMOPLASTS PRODUCTION WASTE . 584 9.6.4.4 END-OF-LIFE (EOL) PTFE AND PERFLUORINATED MATERIALS 584 9.6.5 RECYCLING CONCEPTS FOR PERFLUORINATED MATERIALS . 585 9.6.5.1 THERMAL RECYCLING . 586 9.6.5.2 MECHANICAL RECYCLING . 586 9.6.5.3 CHEMICAL RECYCLING OF PERFLUORINATED POLYMERS . 587 9.6.6 ENVIRONMENTAL ASPECTS OF THE PRESENTED PROCESS . 591 10 DISSOLUTION . 595 ANDREAS MAURER, MARTIN SCHLUMMER 10.1 CLASSIFICATION OF POLYMER RECYCLING BY DISSOLUTION . 595 10.2 SOLVENT SELECTION . 596 10.3 UNIT OPERATIONS . 598 10.3.1 DISSOLUTION . 599 10.3.2 CLEANING . 600 10.3.3 PRECIPITATION . 601 10.3.4 DRYING AND SOLVENT RECOVERY . 601 10.4 DISSOLUTION TECHNOLOGIES IN CIRCULAR VALUE CHAINS . 602 10.4.1 WASTE STREAMS SUGGESTED FOR DISSOLUTION IN THE LITERATURE . 602 10.4.2 HIGH-LEVEL APPLICABILITY OF RECYCLED MATERIALS . 603 10.4.3 INDUSTRIAL-SCALE DISSOLUTION PROCESSES . 604 11 THERMOCHEMICAL PROCESSES . 609 DIETER STAPF 11.1 CHALLENGES AND APPROACHES . 610 11.1.1 PLASTIC WASTE . 610 11.1.2 PROCESS PARAMETERS . 612 11.1.3 FLEXIBLE THERMOCHEMICAL TECHNOLOGIES AND TECHNOLOGY READINESS . 612 11.2 GASIFICATION FOR CHEMICAL RECYCLING AS PETROCHEMICAL FEEDSTOCK . 614 11.2.1 PROCESS AND TECHNOLOGIES . 615 11.2.2 SYNGAS UPGRADING - CLEANING OF THE RAW SYNTHESIS GAS . 617 11.2.3 LARGE-SCALE, HIGH-TRL GASIFICATION APPLICATIONS FOR CHEMICAL RECYCLING . 618 11.2.4 BALANCING OF A GASIFICATION-BASED WASTE-TO-CHEMICALS PROCESS CHAIN . 620 11.3 PYROLYSIS FOR CHEMICAL RECYCLING AS PETROCHEMICAL FEEDSTOCK . 622 11.3.1 BALANCING OF A PYROLYSIS-BASED WASTE-TO-CHEMICALS PROCESS CHAIN . 622 11.3.2 PROCESS AND TECHNOLOGIES . 626 11.3.3 LARGE-SCALE HIGH-TRL PYROLYSIS APPLICATIONS FOR CHEMICAL RECYCLING . 629 11.4 OUTLOOK . 630 12 RECYCLING OF COMPOSITES . 633 MATHIAS MILHLBACHER, VOLKER ALTSTADT 12.1 INTRODUCTION TO COMPOSITES . 633 12.2 THE COMPOSITES MARKET . 636 12.3 COMPOSITE MANUFACTURING . 639 12.4 CHALLENGES AND AIMS FOR COMPOSITE RECYCLING . 642 12.5 ROUTES FOR COMPOSITE RECYCLING . 644 12.6 COMPOSITE RECYCLING FOR THE WIND ENERGY SECTOR . 647 12.7 COMPOSITE RECYCLING FOR AUTOMOTIVE . 649 PART C: VALUE CHAIN . 653 13 COMPARISON OF GLOBAL RECYCLING PROCESSES . 655 RAPHAEL KIESEL 13.1 EUROPE . 658 13.2 NORTH AMERICA . 663 13.2.1 USA . 664 13.2.2 CANADA . 667 13.3 ASIA . 669 13.3.1 CHINA . 669 13.3.2 INDIA . 673 13.3.3 JAPAN . 673 13.3.4 OTHER ASIAN COUNTRIES . 674 13.4 CONCLUSION & SUMMARY . 675 14 VALUE CHAIN EMEA - COLLECTING AND SORTING . 679 JIIRGEN EPHAN, ARNE KOHNE 14.1 WASTE: SOURCES AND ORIGINS . 679 14.2 COLLECTION AND SORTING . 686 14.3 RECYCLING . 689 15 RECYCLING VALUE CHAIN AND DETECTION/PURIFICATION TECHNOLOGIES . 697 JIIRGEN PRIESTERS 15.1 INTRODUCTION . 697 15.2 RECYCLING VALUE CHAIN . 697 15.3 MARINE LITTER . 699 15.4 WASTE MANAGEMENT SYSTEMS AND MATERIALS . 700 15.4.1 BULKY WASTE . 705 15.4.2 COMMERCIAL AND INDUSTRIAL WASTE . 706 15.4.3 MUNICIPAL WASTE . 707 15.4.4 ORGANIC WASTE . 709 15.4.5 PACKAGING WASTE . 710 15.4.6 PAPER RECOVERY . 712 15.4.7 POLYMER RECOVERY - UPGRADING AND RECYCLING . 712 15.5 THE TECHNOLOGIES . 717 15.6 EXAMPLE: ULTIMATE PURE SORTING OF POLYSTYRENE . 719 16 REUSE . 721 JOSEFA NIIJILEIN, THOMAS NEUMEYER 16.1 INTRODUCTION . 721 16.1.1 DEFINITION OF REUSE . 721 16.1.2 TYPES OF REUSE . 723 16.2 EXAMPLES . 724 16.2.1 LIFE CYCLE EXTENSION . 724 16.2.2 RELOCATION . 725 16.2.3 REMANUFACTURING . 727 16.2.4 COMPONENT REUSE . 731 16.2.5 ALTERNATIVE COMPONENT REUSE . 733 16.2.6 REFORM . 734 16.3 ENVIRONMENTAL IMPACT OF REUSE . 735 16.4 CONSUMER BEHAVIOR . 738 16.5 CONCLUSION . 740 PART D: DESIGN FOR RECYCLING . 745 17 DESIGN FOR RECYCLING . 747 ROBIN FACHTAN, VOLKER ALTSTADT 17.1 INTRODUCTION . 747 17.2 OVERVIEW OF DESIGN FOR RECYCLING . 752 17.3 GENERAL DESIGN STRATEGIES . 754 17.4 DESIGN FOR RECYCLING BY INDUSTRIAL SECTOR - STRATEGIES AND RECENT DEVELOPMENTS . 756 17.4.1 PACKAGING INDUSTRY . 756 17.4.2 TRANSPORTATION . 762 17.4.2.1 AUTOMOTIVE INDUSTRY . 762 17.4.2.2 AVIATION INDUSTRY . 770 17.4.3 ELECTRONICS . 772 17.4.4 BUILDING AND CONSTRUCTION . 776 17.5 CONCLUSION . 779 PART E: FUTURE TRENDS AND DEVELOPMENTS . 785 18 FUTURE TRENDS . 787 HOLGER RUCKDASCHEL, TOBIAS STANDAU 18.1 THINKING IN CLOSED LOOPS AT EVERY STAGE . 788 18.2 DESIGN AND MATERIAL SELECTION STAGE . 789 18.3 USAGE STAGE . 793 18.4 END-OF-LIFE STAGE . 796 18.5 RECYCLING STAGE . 798 18.6 CIRCULAR ECONOMY AND NEW BUSINESS MODELS . 799 19 FUTURE DEVELOPMENTS . 803 ACHIM SCHMIEMANN, ERIC HOMEY 19.1 THE THINNING EFFECT . 805 19.2 PREDICTION OF PROPERTIES . 807 19.3 DIGITIZATION IN PROCESSING TECHNOLOGY . 808 19.3.1 TRACER-BASED SORTING . 811 19.3.2 BLACK-BLACK SORTING . 812 19.3.3 MFI SORTING . 812 19.4 3D PRINTING . 814 INDEX . 825
adam_txt	CONTENTS PREFACE . V FOREWORD . VII FOREWORD 2 . IX THE AUTHORS . XI THE EDITOR . XI THE COAUTHORS . XII GLOSSARY . XV PART A: FUNDAMENTALS; LEGISLATIVE, ECONOMIC, AND POLITICAL CONSIDERATIONS; LCA . 1 1 INTRODUCTION . 3 NORBERT NIEFINER 1.1 INDUSTRIAL ASPECTS . 4 1.2 PLASTICS POLLUTION . 9 1.3 PLASTICS POLLUTION: BIO SOLUTION? . 12 1.4 RECYCLING METHODS: CLOSING THE LOOP . 20 1.5 SUMMARY . 22 2 INTRODUCTION TO MAJOR THERMOPLASTIC POLYMERS IN THE CONTEXT OF RECYCLING . 25 TRISTAN KOLB, ANDREAS SCHEDL, HANS-WERNER SCHMIDT 2.1 CHEMICAL STRUCTURE AND SYNTHESIS OF INDUSTRIAL POLYMERS . 26 2.1.1 POLYMER ARCHITECTURE . 26 2.1.2 POLYMERS IN THE SOLID STATE . 30 2.1.3 CATEGORIZATION OF POLYMERS . 31 2.1.4 POLYMERIZATION . 32 2.1.4.1 CHAIN-GROWTH POLYMERIZATION . 33 2.1.4.2 STEP-GROWTH POLYMERIZATION . 38 2.2 POLYMER DEGRADATION AND RECYCLING . 42 2.2.1 PHYSICAL AGING . 42 2.2.2 CHEMICAL AGING . 43 2.2.2.1 THERMAL AND THERMOMECHANICAL AGING . 44 2.2.2.2 OXIDATIVE AGING . 46 2.2.2.3 AGING BY HYDROLYSIS AND BIOLOGICAL PROCESSES . 48 2.3 THE WORLD OF THERMOPLASTIC INDUSTRIAL POLYMERS . 50 2.3.1 OVERVIEW OF POLYMER CLASSES AND USE . 50 2.3.2 PROFILES OF IMPORTANT COMMERCIAL POLYMERS . 53 2.3.2.1 POLYETHYLENE . 53 2.3.2.2 POLYPROPYLENE . 55 2.3.2.3 POLYVINYL CHLORIDE . 57 2.3.2.4 POLYSTYRENE . 58 2.3.2.5 POLYETHYLENE TEREPHTHALATE . 59 2.3.2.6 POLYAMIDE . 61 2.3.2.7 POLYCARBONATE . 64 2.3.2.8 POLY(METHYL METHACRYLATE) . 65 2.3.2.9 POLYTETRAFLUOROETHYLENE . 67 3 LEGISLATION . 71 MICHAEL ULBRICH, SOREN HORNICKE 3.1 A CATEGORIZATION OF REGULATORY APPROACHES TO PROMOTE RECYCLING . 72 3.1.1 LEGAL MEASURES . 73 3.1.2 FINANCIAL MEASURES . 77 3.2 APPROACHES IN VARIOUS WORLD REGIONS . 79 3.2.1 GLOBAL REGULATION . 79 3.2.2 EUROPE . 80 3.2.3 APAC . 84 3.2.4 NAFTA . 85 3.2.5 REST OF THE WORLD . 86 4 ECONOMICS . 91 MICHAEL ULBRICH, MARVIN STIEFERMANN 4.1 ECONOMIC CHALLENGES OF RECYCLING PLASTICS . 91 4.2 FRAMEWORK FOR RECYCLING BUSINESS CASES . 93 4.2.1 ILLUSTRATION 1: CHEMICAL RECYCLING OF POLYOLEFINS . 94 4.2.2 ILLUSTRATION 2: CHEMICAL RECYCLING OF PET . 96 4.2.3 ILLUSTRATION 3: MICROWAVE-ASSISTED DEPOLYMERIZATION OF STYRENE . 97 4.3 IMPLICATIONS AND OUTLOOK . 99 5 POLITICAL BOUNDARY CONDITIONS - PLASTICS WASTE MANAGEMENT 103 KLAUS WITTSTOCK, VICTORIA WESSOLOWSKI 5.1 PLASTICS RECYCLING AND ITS POLITICAL RELEVANCE . 103 5.2 OVERVIEW OF POLITICAL MEASURES RELATED TO PLASTIC WASTE MANAGEMENT 115 5.2.1 GLOBAL PLASTIC WASTE MANAGEMENT . 117 5.2.2 PLASTIC WASTE MANAGEMENT IN EUROPE . 121 5.2.3 PLASTIC WASTE MANAGEMENT IN GERMANY . 126 5.2.4 PLASTIC WASTE MANAGEMENT IN CHINA . 131 5.2.5 PLASTIC WASTE MANAGEMENT IN THE UNITED STATES OF AMERICA . 133 5.3 DEVELOPMENTS AND POLITICAL TRENDS IN PLASTIC WASTE MANAGEMENT . 136 5.3.1 HARMONIZATION OF LEGAL ASPECTS . 136 5.3.2 RESTRICTIONS ON MICROPLASTICS . 139 5.3.3 TRANSPARENCY ON CHEMICALS . 141 5.3.4 ECO-DESIGN, DESIGN FOR RECYCLING AND DESIGN FOR SUSTAINABILITY . 143 5.3.5 ECONOMIC INSTRUMENTS . 145 5.3.6 NEW RECYCLING TECHNOLOGIES . 150 5.3.7 REPLACEMENT OF VIRGIN BY RECYCLED CONTENT . 152 5.3.8 KEEPING CARBON IN THE LOOP . 153 5.3.9 CONCLUSION . 154 6 LIFE CYCLE ASSESSMENT (LCA) . 161 6.1 INTRODUCTION: WHAT IS LIFE CYCLE ASSESSMENT? . 161 PETER SALING 6.1.1 HISTORY AND GENERAL ASPECTS . 161 6.1.2 LCA PRINCIPLES DEFINED BY ISO STANDARDS . 162 6.1.2.1 DEFINITIONS . 162 6.1.2.2 GOAL AND SCOPE OF AN LCA STUDY . 163 6.1.2.3 LIFE CYCLE INVENTORIES . 166 6.1.2.4 PROCESSES WITH CO-PRODUCTS . 166 6.1.2.5 ALLOCATION IN RECYCLING PROCESSES . 167 6.1.3 IMPACT ASSESSMENT . 168 6.1.3.1 ENVIRONMENTAL FOOTPRINT OF THE EU . 169 6.1.3.2 IMPACT CATEGORIES USED BY BASF LCA METHODS . 174 6.1.4 INTERPRETATION . 175 6.1.5 EXAMPLES OF LCA STUDIES IN THE RECYCLING CONTEXT . 176 6.1.5.1 RECYCLING OF PET . 176 6.1.5.2 RECYCLING OF WEEE . 177 6.1.5.3 CHEMCYCLINGYY OF PLASTIC WASTE FROM PACKAGING . 179 6.1.5.4 ECO-EFFICIENCY ANALYSIS . 181 6.1.6 SUMMARY . 183 6.2 LIFE CYCLE ASSESSMENT FOR DIFFERENT RECYCLING ROUTES OF POLYSTYRENE . 189 REGINO WEBER, THOMAS NEUMEYER 6.2.1 BACKGROUND OF THE STUDY . 189 6.2.2 DIFFERENT RECYCLING TECHNOLOGIES FOR POLYSTYRENE WASTE . 190 6.2.3 GOAL AND SCOPE OF THE STUDY . 191 6.2.4 DATA FOR LIFE CYCLE INVENTORY (LCI) . 198 6.2.5 LIFE CYCLE IMPACT ASSESSMENT (LCIA) RESULTS . 202 6.2.6 ANALYSIS AND INTERPRETATION . 208 6.2.7 CONCLUSION . 210 6.3 LIFE CYCLE ASSESSMENT OF A NEW MONOMER RECYCLING PROCESS FOR PET . 212 MANDY PASCHETAG, HANNES SCHNEIDER, STEPHAN SCHOLL 6.3.1 THE REVOLPET PROCESS . 214 6.3.2 GOAL AND SCOPE OF THE STUDY . 214 6.3.3 DATA FOR LIFE CYCLE INVENTORY (LCI) . 221 6.3.4 RESULTS OF THE LIFE CYCLE IMPACT ASSESSMENT (LCIA) . 222 6.3.5 ANALYSIS AND INTERPRETATION . 232 PART B: MAJOR RECYCLING TECHNOLOGIES . 239 7 OVERVIEW OF MAJOR RECYCLING TECHNOLOGIES . 241 CHRISTIAN HOPMANN, RAINER DAHLMANN, MARTIN FACKLAM 7.1 INTRODUCTION . 241 7.2 MECHANICAL RECYCLING . 247 7.3 FEEDSTOCK RECYCLING . 252 7.3.1 CHEMICAL RECYCLING . 253 7.3.2 SOLVOLYTIC-BASED RECYCLING . 256 7.3.3 THERMOCHEMICAL PROCESSES . 261 7.3.4 BIODEGRADATION . 266 8 MECHANICAL RECYCLING . 275 8.1 BASIC PRINCIPLES . 275 ACHIM SCHMIEMANN 8.1.1 COARSE OR PRELIMINARY SHREDDING . 279 8.1.2 MEDIUM SIZE SHREDDING . 285 8.1.3 COMMINUTION OF BONDED MATERIALS . 287 8.1.4 CLASSIFYING AND SORTING . 290 8.1.5 EXTRUSION . 295 8.2 MECHANICAL RECYCLING OF POLYOLEFINS . 301 MARCO AMICI 8.2.1 INTRODUCTION - MARKET SIZE AND RECYCLING CHALLENGE . 301 8.2.2 MAIN PO APPLICATIONS . 301 8.2.3 COMMON PROCESSES FOR MECHANICAL RECYCLING OF PO . 302 8.2.4 MECHANICAL RECYCLING OF RIGID PO: PROCESSES AND PHYSICO-CHEMICAL CHANGES . 304 8.2.4.1 HIGH-DENSITY PE (HDPE) . 305 8.2.4.2 POLYPROPYLENE (PP) . 306 8.2.4.3 PE/PP BLENDS . 307 8.2.5 MECHANICAL RECYCLING OF FLEXIBLE PO: PROCESSES AND PHYSICO-CHEMICAL CHANGES . 313 8.2.5.1 INDUSTRIAL FILMS . 313 8.2.5.2 MULTILAYER FLEXIBLE PACKAGING . 314 8.2.6 FOOD CONTACT REGULATIONS FOR MECHANICALLY RECYCLED PO . 315 8.3 MECHANICAL RECYCLING OF PET . 317 THOMAS SCHRODER 8.3.1 INTRODUCTION . 318 8.3.2 MARKET OVERVIEW AND FIELDS OF APPLICATION . 320 8.3.3 CIRCULAR ECONOMY OF PET BOTTLES . 322 8.3.4 BOTTLE-TO-BOTTLE RECYCLING OF PET . 324 8.3.4.1 BOTTLE-TO-FLAKE PROCESSES . 324 8.3.4.2 DEEP CLEANING PROCESSES FOR PET FLAKES . 325 8.3.5 BARRIERS TO THE USE OF RECYCLED PET . 328 8.4 MECHANICAL RECYCLING OF STYRENICS . 331 8.4.1 MECHANICAL RECYCLING OF POLYSTYRENE . 331 HERMAN VAN ROOST 8.4.1.1 INTRODUCTION - QUALITY-DRIVEN CIRCULARITY . 331 8.4.1.2 ADEQUATE RECYCLATE QUALITY . 333 8.4.1.2.1 PRACTICAL QUALITY STANDARD . 333 8.4.1.2.2 VIRGIN EQUIVALENCY . 333 8.4.1.2.3 PURITY VS. POLYMER PROPERTIES . 335 8.4.1.3 THE IMPORTANCE OF FOOD CONTACT QUALITY FOR RECYCLATES . 341 8.4.1.3.1 FOOD CONTACT IN THE VIRGIN INDUSTRY CONTEXT . 341 8.4.1.3.2 THE PET BOTTLE RECYCLING REFERENCE . 343 8.4.1.3.3 MANY WAYS FOR A RECYCLATE TO BE NON-FOOD-CONTACT . 344 8.4.1.3.4 A VIRTUOUS CIRCLE TOWARDS PLASTICS CIRCULARITY . 346 8.4.1.4 FOOD CONTACT MECHANICAL RECYCLING PROCESS OF PS . 347 8.4.1.4.1 DEEP SORTING . 347 8.4.1.4.2 HOT WASHING . 349 8.4.1.4.3 FLAKE SORTING . 352 8.4.1.4.4 SUPER-CLEANING . 354 8.4.1.4.5 EXTRUSION AND MELT FILTRATION . 358 8.4.1.4.6 INDUSTRIAL BLUEPRINT FOR A HIGH-PURITY PS RECYCLING PLANT . 359 8.4.1.5 WASTE FEEDSTOCK FOR CIRCULAR PS . 361 8.4.1.5.1 PS PACKAGING IN EU WASTE STREAMS . 361 8.4.1.5.2 THE POTENTIAL OF PRE-INCINERATOR EXTRACTION . 363 8.4.1.6 CIRCULARITY OF POLYMERS - THE UNIQUE POSITION OF PS 365 8.4.1.6.1 OPEN LOOP VS. CLOSED LOOP: IS THAT REALLY THE QUESTION? . 365 8.4.1.6.2 A MATERIAL ' S CIRCULARITY AND CIRCULARITY MATRIX . 366 8.4.1.6.3 CIRCULAR UNIFICATION OF RIGID AND FOAMED PS . 370 8.4.1.7 CIRCULAR DESIGN OF PS PACKAGES . 371 8.4.1.7.1 DESIGN FOR INCREASED CIRCULAR YIELD . 371 8.4.1.7.2 GENERALIZED PACKAGING DESIGN FOR FOOD CONTACT . 373 8.4.2 MECHANICAL RECYCLING OF STYRENE COPOLYMERS . 375 EIKE JAHNKE 8.4.2.1 INTRODUCTION . 375 8.4.2.2 THE CHEMISTRY OF PS AND ABS DURING PRODUCTION, PROCESSING AND DURING THEIR LIFE CYCLES . 378 8.4.2.3 PROSPECTS, PREREQUISITES AND LIMITATIONS OF THE MECHANICAL RECYCLING OF STYRENICS . 384 8.4.2.4 MECHANICALLY RECYCLED PCR ABS - AN ECONOMIC CASE STUDY . 391 8.4.2.5 CONCLUSION . 394 8.4.3 MECHANICAL RECYCLING OF EXPANDABLE POLYSTYRENE (EPS) . 397 NORBERT NIEJINER 8.5 MECHANICAL RECYCLING OF ENGINEERING THERMOPLASTICS . 399 HANNAH MANGOLD, CAROLINE BEYER 8.5.1 MARKET SIZE AND RECYCLING CHALLENGE . 400 8.5.2 MAJOR APPLICATIONS AND RECYCLING PROCESS . 402 8.5.2.1 POLYAMIDES . 402 8.5.2.1.1 POLYAMIDE 6 . 402 8.5.2.1.2 POLYAMIDE 66 . 404 8.5.2.2 POLYURETHANES . 406 8.5.2.2.1 REBONDING WITH ADHESIVES . 406 8.5.2.2.2 MOLDING AND EXTRUSION . 406 8.5.2.2.3 REGRINDING AND POWDERING . 407 8.5.2.2.4 SOLVENT-BASED RECYCLING . 407 8.5.2.3 OTHER ENGINEERING PLASTICS . 407 8.5.3 MAJOR APPLICATIONS OF RECYCLED ENGINEERING PLASTICS . 408 8.6 MECHANICAL RECYCLING OF PVC . 411 JASON LEADBITTER 8.6.1 INTRODUCTION . 411 8.6.2 HOW IS PVC MANUFACTURED? . 412 8.6.3 PVC COMPOUNDING . 413 8.6.4 PVC APPLICATIONS IN USE . 413 8.6.5 WASTE HIERARCHY AND END-OF-LIFE OPTIONS . 414 8.6.6 HOW TO GO ABOUT RECYCLING OF PVC? . 417 8.6.7 THE DAWN OF A NEW INDUSTRY . 418 8.6.7.1 VINYLPLUS . 419 8.6.7.2 RECOVINYL . 419 8.6.7.3 SUCCESSES OF THE VINYLPLUS INITIATIVE - EUROPEAN RECYCLED PVC MARKET SIZE . 421 8.6.8 EUROPEAN MARKETS FOR RECYCLED PVC . 422 8.6.9 THE RECYCLABILITY OF PVC . 422 8.6.10 LEGACY ADDITIVES AND REGULATORY ISSUES . 424 8.6.10.1 LEAD STABILIZERS . 424 8.6.10.2 LOW MOLECULAR WEIGHT ORTHOPHTHALATE PLASTICIZERS . 425 8.6.11 BENEFITS OF PVC RECYCLING FROM A LIFE CYCLE PERSPECTIVE . 425 8.7 COMPATIBILIZATION OF BLENDS FOR MECHANICAL RECYCLING . 426 NORBERT NIEFINER, BIANCA WILHELMUS 8.7.1 CLASSIFICATION OF POLYMER BLENDS . 426 8.7.2 GENERAL PRINCIPLE OF COMPATIBILIZERS . 428 8.7.3 SELECTED EXAMPLES OF COMPATIBILIZED BLENDS . 429 8.7.4 COMPATIBILIZATION IN MECHANICAL RECYCLING . 431 9 CHEMICAL RECYCLING . 435 9.1 BASIC PRINCIPLES . 435 9.1.1 AN OVERVIEW OF MAJOR RECYCLING TECHNOLOGIES . 435 BIANCA WILHELMUS 9.1.1.1 INTRODUCTION . 435 9.1.1.2 TECHNOLOGIES . 438 9.1.1.3 HISTORICAL OVERVIEW OF THERMOLYTIC PROCESSES . 439 9.1.1.4 RECENT APPROACHES FOR PYROLYSIS AND GASIFICATION . 446 9.1.1.5 SOLVOLYTIC PROCESSES . 451 9.1.1.5.1 POLYETHYLENE TEREPHTHALATE . 451 9.1.1.5.2 POLYURETHANES . 454 9.1.1.5.3 POLYAMIDES . 455 9.1.1.5.4 POLYCARBONATE . 455 9.1.1.6 OUTLOOK . 455 9.1.2 PETROCHEMICAL FEEDSTOCK RECYCLING . 463 DIETER STAPF 9.1.2.1 WASTE & RECYCLING . 464 9.1.2.2 THE WASTE-TO-CHEMICALS PROCESS CHAIN . 468 9.1.2.3 UPGRADING AND USE OF PYROLYSIS OIL AS PETROCHEMICAL FEEDSTOCK . 470 9.1.2.4 DECENTRALIZED VERSUS CENTRALIZED CHEMICAL RECYCLING . 472 9.1.2.5 THE STATUS OF PETROCHEMICAL FEEDSTOCK RECYCLING . 473 9.1.3 PLASTIC RECYCLING BY DEPOLYMERIZATION . 474 ACHIM SCHMIDT-RODENKIRCHEN, STEPHAN ASCHAUER, THORSTEN GERDES, NORBERT NIEFINER 9.1.3.1 INTRODUCTION . 474 9.1.3.2 DESIGN ISSUES FOR FLUIDIZED-BED REACTORS . 476 9.1.3.2.1 THERMODYNAMICS . 476 9.1.3.2.2 KINETICS . 477 9.1.3.3 FLUIDIZED-BED REACTOR TECHNOLOGY . 479 9.1.3.3.1 PHYSICAL BASICS . 480 9.1.3.3.2 TECHNICAL DESIGN . 485 9.1.3.3.3 RAW GAS TREATMENT . 488 9.1.3.3.4 SCALE-UP . 492 9.1.3.3.5 INDUSTRIAL APPLICATIONS OF FLUIDIZED BEDS IN PLASTIC RECYCLING . 494 9.2 CHEMICAL RECYCLING OF POLYOLEFINS . 499 ADRIAN GRIFFITHS, ALEJANDRO SANCHEZ, STEPHANIE LOO 9.2.1 INTRODUCTION . 499 9.2.2 BASIC TECHNICAL PRINCIPLE . 500 9.2.3 EXAMPLES . 501 9.2.4 PRODUCTS: PYROLYSIS OILS . 503 9.2.5 APPLICATIONS . 510 9.2.6 MARKET . 512 9.2.6.1 CAPACITY . 512 9.2.6.2 COST . 514 9.2.6.3 COLLABORATORS . 517 9.2.6.4 CIRCULARITY . 518 9.2.6.5 CARBON REDUCTION . 520 9.2.7 CONCLUSION . 522 9.3 CHEMICAL RECYCLING OF PET . 525 CARSTEN EICHERT, VITALIJ SALIKOV, STEPHAN SCHOLL 9.3.1 INTRODUCTION . 525 9.3.2 OVERVIEW: OPTIONS FOR RECYCLING OF FEED MATERIALS . 526 9.3.3 CHEMICAL RECYCLING AND ITS RELEVANCE FOR PET . 529 9.3.3.1 PYROLYSIS . 529 9.3.3.2 CHEMICAL DEPOLYMERIZATION . 530 9.3.4 PET MONOMERS . 532 9.3.5 MONOMER RECYCLING OF PET . 534 9.3.5.1 METHANOLYSIS . 535 9.3.5.2 GLYCOLYSIS . 535 9.3.5.3 HYDROLYSIS . 536 9.4 CHEMICAL RECYCLING OF POLYSTYRENE . 544 NORBERT NIEFINER, ACHIM SCHMIDT-RODENKIRCHEN 9.4.1 INTRODUCTION . 544 9.4.2 OVERVIEW AND CHALLENGES . 544 9.4.3 LABORATORY PRE-TRIALS . 547 9.4.4 TRIALS IN THE FLUID BED REACTOR (INVERTEC) . 549 9.4.5 TRIALS WITH PS AND IMPURITIES . 552 9.4.6 CONCLUSION . 555 9.5 CHEMICAL RECYCLING OF ENGINEERING THERMOPLASTICS . 556 HANNAH MANGOLD, CAROLINE BEYER 9.5.1 INTRODUCTION: MARKET SIZE AND RECYCLING CHALLENGE . 556 9.5.2 OVERVIEW OF CHEMICAL RECYCLING PROCESSES . 558 9.5.2.1 POLYAMIDES (PA) . 558 9.5.2.1.1 POLYAMIDE 6 (PA6) . 558 9.5.2.1.2 POLYAMIDE 66 (PA66) . 562 9.5.2.2 POLYURETHANES (PUS) . 567 9.5.2.2.1 HYDROLYSIS AND ALCOHOLYSIS . 569 9.5.2.2.2 AMINOLYSIS . 569 9.5.2.2.3 PHOSPHOROLYSIS . 570 9.5.2.2.4 GLYCOLYSIS . 570 9.5.2.2.5 THERMOCHEMICAL RECYCLING . 571 9.5.2.3 POLYBUTYLENE TEREPHTHALATE (PBT) . 571 9.5.2.4 OTHER ENGINEERING PLASTICS . 572 9.5.3 APPLICATIONS OF MAJOR RECYCLED ENGINEERING PLASTICS . 572 9.6 CHEMICAL RECYCLING OF PTFE (AS A MODEL FOR OTHER POLYMERS) . 577 ACHIM SCHMIDT-RODENKIRCHEN, KLAUS HINTZER, THORSTEN GERDES 9.6 A INTRODUCTION . 577 9.6.2 MANUFACTURING PROCESS FOR PTFE AND OTHER PERFLUORINATED POLYMERS . 579 9.6.3 MECHANISM OF PTFE DEPOLYMERIZATION . 581 9.6.4 RECYCLING PTFE AND PERFLUORINATED POLYMER MATERIALS . 583 9.6.4.1 PTFE PRODUCTION WASTE . 583 9.6.4.2 PTFE COMPOSITES PRODUCTION WASTE . 584 9.6.4.3 PERFLUORINATED THERMOPLASTS PRODUCTION WASTE . 584 9.6.4.4 END-OF-LIFE (EOL) PTFE AND PERFLUORINATED MATERIALS 584 9.6.5 RECYCLING CONCEPTS FOR PERFLUORINATED MATERIALS . 585 9.6.5.1 THERMAL RECYCLING . 586 9.6.5.2 MECHANICAL RECYCLING . 586 9.6.5.3 CHEMICAL RECYCLING OF PERFLUORINATED POLYMERS . 587 9.6.6 ENVIRONMENTAL ASPECTS OF THE PRESENTED PROCESS . 591 10 DISSOLUTION . 595 ANDREAS MAURER, MARTIN SCHLUMMER 10.1 CLASSIFICATION OF POLYMER RECYCLING BY DISSOLUTION . 595 10.2 SOLVENT SELECTION . 596 10.3 UNIT OPERATIONS . 598 10.3.1 DISSOLUTION . 599 10.3.2 CLEANING . 600 10.3.3 PRECIPITATION . 601 10.3.4 DRYING AND SOLVENT RECOVERY . 601 10.4 DISSOLUTION TECHNOLOGIES IN CIRCULAR VALUE CHAINS . 602 10.4.1 WASTE STREAMS SUGGESTED FOR DISSOLUTION IN THE LITERATURE . 602 10.4.2 HIGH-LEVEL APPLICABILITY OF RECYCLED MATERIALS . 603 10.4.3 INDUSTRIAL-SCALE DISSOLUTION PROCESSES . 604 11 THERMOCHEMICAL PROCESSES . 609 DIETER STAPF 11.1 CHALLENGES AND APPROACHES . 610 11.1.1 PLASTIC WASTE . 610 11.1.2 PROCESS PARAMETERS . 612 11.1.3 FLEXIBLE THERMOCHEMICAL TECHNOLOGIES AND TECHNOLOGY READINESS . 612 11.2 GASIFICATION FOR CHEMICAL RECYCLING AS PETROCHEMICAL FEEDSTOCK . 614 11.2.1 PROCESS AND TECHNOLOGIES . 615 11.2.2 SYNGAS UPGRADING - CLEANING OF THE RAW SYNTHESIS GAS . 617 11.2.3 LARGE-SCALE, HIGH-TRL GASIFICATION APPLICATIONS FOR CHEMICAL RECYCLING . 618 11.2.4 BALANCING OF A GASIFICATION-BASED WASTE-TO-CHEMICALS PROCESS CHAIN . 620 11.3 PYROLYSIS FOR CHEMICAL RECYCLING AS PETROCHEMICAL FEEDSTOCK . 622 11.3.1 BALANCING OF A PYROLYSIS-BASED WASTE-TO-CHEMICALS PROCESS CHAIN . 622 11.3.2 PROCESS AND TECHNOLOGIES . 626 11.3.3 LARGE-SCALE HIGH-TRL PYROLYSIS APPLICATIONS FOR CHEMICAL RECYCLING . 629 11.4 OUTLOOK . 630 12 RECYCLING OF COMPOSITES . 633 MATHIAS MILHLBACHER, VOLKER ALTSTADT 12.1 INTRODUCTION TO COMPOSITES . 633 12.2 THE COMPOSITES MARKET . 636 12.3 COMPOSITE MANUFACTURING . 639 12.4 CHALLENGES AND AIMS FOR COMPOSITE RECYCLING . 642 12.5 ROUTES FOR COMPOSITE RECYCLING . 644 12.6 COMPOSITE RECYCLING FOR THE WIND ENERGY SECTOR . 647 12.7 COMPOSITE RECYCLING FOR AUTOMOTIVE . 649 PART C: VALUE CHAIN . 653 13 COMPARISON OF GLOBAL RECYCLING PROCESSES . 655 RAPHAEL KIESEL 13.1 EUROPE . 658 13.2 NORTH AMERICA . 663 13.2.1 USA . 664 13.2.2 CANADA . 667 13.3 ASIA . 669 13.3.1 CHINA . 669 13.3.2 INDIA . 673 13.3.3 JAPAN . 673 13.3.4 OTHER ASIAN COUNTRIES . 674 13.4 CONCLUSION & SUMMARY . 675 14 VALUE CHAIN EMEA - COLLECTING AND SORTING . 679 JIIRGEN EPHAN, ARNE KOHNE 14.1 WASTE: SOURCES AND ORIGINS . 679 14.2 COLLECTION AND SORTING . 686 14.3 RECYCLING . 689 15 RECYCLING VALUE CHAIN AND DETECTION/PURIFICATION TECHNOLOGIES . 697 JIIRGEN PRIESTERS 15.1 INTRODUCTION . 697 15.2 RECYCLING VALUE CHAIN . 697 15.3 MARINE LITTER . 699 15.4 WASTE MANAGEMENT SYSTEMS AND MATERIALS . 700 15.4.1 BULKY WASTE . 705 15.4.2 COMMERCIAL AND INDUSTRIAL WASTE . 706 15.4.3 MUNICIPAL WASTE . 707 15.4.4 ORGANIC WASTE . 709 15.4.5 PACKAGING WASTE . 710 15.4.6 PAPER RECOVERY . 712 15.4.7 POLYMER RECOVERY - UPGRADING AND RECYCLING . 712 15.5 THE TECHNOLOGIES . 717 15.6 EXAMPLE: ULTIMATE PURE SORTING OF POLYSTYRENE . 719 16 REUSE . 721 JOSEFA NIIJILEIN, THOMAS NEUMEYER 16.1 INTRODUCTION . 721 16.1.1 DEFINITION OF REUSE . 721 16.1.2 TYPES OF REUSE . 723 16.2 EXAMPLES . 724 16.2.1 LIFE CYCLE EXTENSION . 724 16.2.2 RELOCATION . 725 16.2.3 REMANUFACTURING . 727 16.2.4 COMPONENT REUSE . 731 16.2.5 ALTERNATIVE COMPONENT REUSE . 733 16.2.6 REFORM . 734 16.3 ENVIRONMENTAL IMPACT OF REUSE . 735 16.4 CONSUMER BEHAVIOR . 738 16.5 CONCLUSION . 740 PART D: DESIGN FOR RECYCLING . 745 17 DESIGN FOR RECYCLING . 747 ROBIN FACHTAN, VOLKER ALTSTADT 17.1 INTRODUCTION . 747 17.2 OVERVIEW OF DESIGN FOR RECYCLING . 752 17.3 GENERAL DESIGN STRATEGIES . 754 17.4 DESIGN FOR RECYCLING BY INDUSTRIAL SECTOR - STRATEGIES AND RECENT DEVELOPMENTS . 756 17.4.1 PACKAGING INDUSTRY . 756 17.4.2 TRANSPORTATION . 762 17.4.2.1 AUTOMOTIVE INDUSTRY . 762 17.4.2.2 AVIATION INDUSTRY . 770 17.4.3 ELECTRONICS . 772 17.4.4 BUILDING AND CONSTRUCTION . 776 17.5 CONCLUSION . 779 PART E: FUTURE TRENDS AND DEVELOPMENTS . 785 18 FUTURE TRENDS . 787 HOLGER RUCKDASCHEL, TOBIAS STANDAU 18.1 THINKING IN CLOSED LOOPS AT EVERY STAGE . 788 18.2 DESIGN AND MATERIAL SELECTION STAGE . 789 18.3 USAGE STAGE . 793 18.4 END-OF-LIFE STAGE . 796 18.5 RECYCLING STAGE . 798 18.6 CIRCULAR ECONOMY AND NEW BUSINESS MODELS . 799 19 FUTURE DEVELOPMENTS . 803 ACHIM SCHMIEMANN, ERIC HOMEY 19.1 THE THINNING EFFECT . 805 19.2 PREDICTION OF PROPERTIES . 807 19.3 DIGITIZATION IN PROCESSING TECHNOLOGY . 808 19.3.1 TRACER-BASED SORTING . 811 19.3.2 BLACK-BLACK SORTING . 812 19.3.3 MFI SORTING . 812 19.4 3D PRINTING . 814 INDEX . 825
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spelling	Recycling of plastics Norbert Niessner [editor] Munich Hanser [2022] © 2022 XXXIII, 836 Seiten Illustrationen, Diagramme 25 cm txt rdacontent n rdamedia nc rdacarrier Recycling (DE-588)4076573-8 gnd rswk-swf Kunststoffabfall (DE-588)4166051-1 gnd rswk-swf Economic Recycling Recycling Technologies Sustainability FBKTRECY: Recycling Kunststoffabfall (DE-588)4166051-1 s Recycling (DE-588)4076573-8 s DE-604 Niessner, Norbert (DE-588)1273388356 edt Hanser Publications (DE-588)1064064051 pbl Erscheint auch als Online-Ausgabe 978-1-56990-857-0 Erscheint auch als Online-Ausgabe, EPUB 978-1-56990-858-7 DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=033911235&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p dnb 20210512 DE-101 https://d-nb.info/provenance/plan#dnb
spellingShingle	Recycling of plastics Recycling (DE-588)4076573-8 gnd Kunststoffabfall (DE-588)4166051-1 gnd
subject_GND	(DE-588)4076573-8 (DE-588)4166051-1
title	Recycling of plastics
title_auth	Recycling of plastics
title_exact_search	Recycling of plastics
title_exact_search_txtP	Recycling of plastics
title_full	Recycling of plastics Norbert Niessner [editor]
title_fullStr	Recycling of plastics Norbert Niessner [editor]
title_full_unstemmed	Recycling of plastics Norbert Niessner [editor]
title_short	Recycling of plastics
title_sort	recycling of plastics
topic	Recycling (DE-588)4076573-8 gnd Kunststoffabfall (DE-588)4166051-1 gnd
topic_facet	Recycling Kunststoffabfall
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=033911235&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
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