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Recycling of polyurethane foams / edited by Sabu Thomas [and four others].
- Format:
- Book
- Series:
- Plastics Design Library
- Language:
- English
- Subjects (All):
- Plastics--Recycling.
- Plastics.
- Polyurethanes.
- Physical Description:
- 1 online resource (147 pages)
- Edition:
- 1st ed.
- Place of Publication:
- Oxford, United Kingdom ; Cambridge, MA : William Andrew is an imprint of Elsevier, [2018]
- Summary:
- Recycling of Polyurethane Foams introduces the main degradation/depolymerization processes and pathways of polyurethane foam materials, focusing on industrial case studies and academic reviews from recent research and development projects.
- Contents:
- Front Cover
- Recycling of Polyurethane Foams
- Copyright Page
- Contents
- List of Contributors
- 1 Introduction to Polymer and Their Recycling Techniques
- 1.1 Introduction of Plastics and Their Classification
- 1.2 Classification of Polymers
- 1.3 Recycling of Thermoplastics Is Possible but not With Thermosets. Why?
- 1.4 Polymerization Reactions
- 1.5 Economic and Environmental Impact of Plastic Waste
- 1.6 Economic Issues Relating to Recycling
- 1.7 Various Thermoplastics and Their Applications
- 1.7.1 Polyolefins
- 1.7.2 Vinyl Polymers
- 1.7.3 Polystyrenes
- 1.7.4 Acrylate and Methacrylate Polymers
- 1.7.5 Polyamide (i.e., Nylons)
- 1.7.6 Polycarbonates
- 1.7.7 Celluloid
- 1.7.8 Linear Polyester
- 1.7.9 Polyfluorethane
- 1.7.10 Polyacetals
- 1.7.11 Polysulfones
- 1.7.12 Polyphenylene Sulfide
- 1.7.13 Modified Polyphenylene Oxide (PPO)
- 1.8 Various Thermosetting Plastics
- 1.8.1 Unsaturated Polyester
- 1.8.2 Phenol Formaldehyde Resins
- 1.8.3 Melamine Resins
- 1.8.4 Polyepoxides
- 1.8.5 Polyimide
- 1.8.6 Polyurethane
- 1.8.7 Polyorganosiloxanes
- 1.9 Systems for Plastic Recycling
- 1.10 Recycling of Thermoplastics
- 1.10.1 Size Reduction and Cleaning
- 1.10.2 Further Separation
- 1.10.3 Processing/Remelting to Make Products
- 1.11 PET Bottle/Container Recycling Process
- 1.12 PU Recycling Processes
- 1.12.1 Mechanical Recycling
- 1.12.2 Chemical Recycling
- 1.13 Recycling of Thermoset Plastics
- 1.14 Recycling and Reuse of Elastomeric Materials
- 1.14.1 Incineration
- 1.14.2 Pyrolysis
- 1.14.3 Grinding of Vulcanized Rubber Waste
- 1.14.4 Devulcanization
- 1.14.5 Applications of Waste Rubber
- 1.15 Challenges and Opportunities for Improving Plastic Recycling
- 1.16 Conclusions
- References
- Further Reading
- 2 Polyurethane Foam Chemistry
- 2.1 History
- 2.2 Raw Materials.
- 2.3 Isocyanates
- 2.4 Polyols
- 2.5 PU Foams
- 2.5.1 Flexible Slabstock
- 2.5.2 Flexible Cold Cure Molding
- 2.5.3 Rigid Foams
- 2.5.4 Microcellular or Footwear Foams
- 2.5.5 Elastomeric Applications
- 2.6 Blowing Agents
- 2.6.1 Physical Blowing Agents
- 2.6.2 Chemical Blowing Agents
- 2.6.3 Mixed Physical/Chemical Blowing Agents
- 2.7 Manufacturing of PU Foams
- 2.7.1 Slabstock Method
- 2.7.2 Molding Method
- 2.8 Properties of PU Foams
- 2.8.1 Foam Is a Good Air Sealant
- 2.8.2 Closed-Cell Foam Has Very High Resistance Toward Water Vapor Permeation
- 2.8.3 Closed-Cell Foam Resists Damages From Short-Term Wet Conditions
- 2.8.4 Binding Strength of Foam
- 2.8.5 Structural Advantages of Foams
- 2.9 Thermal Conductivity
- 2.9.1 Thermal Conductivity and Thermal Resistance of Insulating Materials
- 2.9.2 Thermal Conductivity of Rigid PU Foam (PUR/PIR)
- 2.10 The R-Value of PU Foam Is Higher Than Other Types of Insulations
- 2.11 Mechanical Properties of PU Foams
- 2.11.1 Density
- 2.11.2 Compressive strength σ·m
- 2.11.3 Continuous Compressive Stress σ c (Compressive Creep)
- 2.11.4 Tensile Strength Perpendicular to Faces σmt, Shear Strength, and Bending Strength σb
- 2.11.5 Flammability of PU Foams
- 2.11.6 PU Foam Manufacturers in India
- 2.12 Conclusion
- 2.12.1 Mechanical Recycling
- 2.12.2 Chemical Recycling
- 3 Degradability of Polymers
- 3.1 Thermal Degradation
- 3.1.1 Initiation
- 3.1.2 Propagation
- 3.1.3 Termination
- 3.2 Chemical Degradation
- 3.2.1 Hydrolysis
- 3.2.2 Alcoholysis
- 3.2.3 Acidolysis Process
- 3.2.4 Glycolysis Process
- 3.2.5 Aminolysis
- 3.3 Mechanical Degradation
- 3.3.1 Regrinding
- 3.3.2 Adhesive Pressing
- 3.3.3 Compression Molding
- 3.3.4 Injection Molding
- 3.4 Photodegradation
- 3.5 Biodegradation
- 3.5.1 High-energy radiation degradation.
- 3.5.2 Ultrasonic Wave Degradation
- 3.6 Conclusion
- 4 Introduction to Mechanical Recycling and Chemical Depolymerization
- 4.1 Mechanical Depolymerization
- 4.2 Chemical Depolymerization
- 4.3 Summary
- 5 Mechanical Recycling via Regrinding, Rebonding, Adhesive Pressing, and Molding
- 5.1 Introduction
- 5.2 Mechanical Recycling of PU Foams
- 5.2.1 Grinding and Powdering
- 5.2.2 Rebonding
- 5.2.3 Adhesive Pressing
- 5.2.4 Compression Molding, Injection Molding, and Extrusion
- 5.3 Summary
- 6 Chemical Depolymerization of Polyurethane Foams via Glycolysis and Hydrolysis
- 6.1 Introduction
- 6.2 Glycolysis of Rigid and Flexible PU Foams
- 6.2.1 Double Recovery Method
- 6.2.2 Microwave-Assisted Techniques
- 6.3 Glycolysis Technology
- 6.3.1 Analytical Techniques
- 6.4 Applications
- 6.5 Comparison of Glycolysis With Hydrolysis
- 6.5.1 Hydrolysis
- 6.6 Conclusion
- 7 Chemical Depolymerization of Polyurethane Foam via Ammonolysis and Aminolysis
- 7.1 Introduction
- 7.2 Aminolysis of PU Foam
- 7.3 Ammonolysis of PU Foam
- 7.4 Conclusion
- 8 Chemical Depolymerization of Polyurethane Foams via Combined Chemolysis Methods
- 8.1 Introduction
- 8.1.1 Physical Recycling
- 8.1.2 Chemolysis of PU Foam
- 8.1.2.1 Hydrolysis of PU Foam
- 8.1.2.2 Alcoholysis of PU Foam
- 8.1.2.3 Acidolysis of PU Foam
- 8.1.2.4 Aminolysis of PU Foam
- 8.1.2.5 Glycolysis of PU Foam
- 8.2 Combined Chemolysis of PU Foam
- 8.2.1 Hydroglycolysis
- 8.2.1.1 Mechanism for Hydroglycolysis Reaction
- 8.2.2 Glycolysis-Aminolysis
- 8.2.3 Aminolysis-Hydrolysis
- 8.3 Advantages and Disadvantages of Combined Chemolysis
- 8.4 Combined Chemolysis in Comparison to Other Recycling Methods of PU Foams
- 8.4.1 Physical Recycling
- 8.4.1.1 Regrind or Powdering.
- 8.4.1.2 Adhesive Pressing/Particle Bonding
- 8.4.1.3 Pyrolysis
- 8.4.2 Chemical Recycling
- 8.4.2.1 Glycolysis
- 8.4.2.2 Methanolysis
- 8.4.2.3 Aminolysis
- 8.4.2.4 Hydrolysis
- 8.4.3 Combined Chemolysis
- 8.5 Comparison Between Combined Chemolysis and Conventional Chemolysis
- 8.6 Conclusions
- 9 Life Cycle Analysis of Polyurethane Foam Wastes
- 9.1 Introduction-Theoretical Background
- 9.1.1 Life Cycle Assessment-Introduction
- 9.1.2 Procedural Steps of LCA
- 9.1.3 Use of LCA in Business and Policy-Making
- 9.1.4 Resources Inside of the EU to Help With LCA
- 9.2 LCA of Polyurethane Foam-Previous Studies
- 9.2.1 Comparative Assessment of LCA Scope Definition of Previous Studies
- 9.2.2 Comparative Assessment of LCI of Previous Studies
- 9.3 LCIA and Interpretation of Results of Previous LCA Studies
- 9.3.1 Environmental Impact Breakdown of PU Production Processes
- 9.3.2 Improvement of Environmental Performance of PU Production
- 9.4 Environmental Assessment of PU Recycling Routes
- 9.4.1 LCA of PU Recycling Routes
- 9.4.2 Conditions for Environmental Payback of PU Recycling
- 10 Construction Applications of Polyurethane Foam Wastes
- 10.1 Introduction
- 10.2 PU Foam Wastes
- 10.2.1 Recycled Lightweight PU Plaster Materials
- 10.2.2 Recycled Lightweight PU Mortar Materials
- 10.2.3 Recycled Lightweight PU Asphalt Materials
- 10.3 Eco-Friendly PU Coatings
- 10.4 Eco-Friendly PU Adhesives
- 10.5 Conclusions
- Index
- Back Cover.
- Notes:
- Description based on print version record.
- Description based on publisher supplied metadata and other sources.
- ISBN:
- 9780323511346
- 0323511341
- 9780323511339
- 0323511333
- OCLC:
- 1039718511
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