Introduction to polymeric composites with rice hulls:
Gespeichert in:
| 1. Verfasser: | |
|---|---|
| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Shropshire, England
Smithers Rapra
2014
|
| Schlagworte: | |
| Online-Zugang: | FAW01 FAW02 |
| Beschreibung: | Includes index Description based on online resource; title from PDF title page (ebrary, viewed December 18, 2014) |
| Beschreibung: | 1 online resource (208 pages) |
| ISBN: | 9781909030800 1909030805 9781909030794 |
Internformat
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| 082 | 0 | |a 620.192 |2 23 | |
| 100 | 1 | |a Defonseka, Chris |e Verfasser |4 aut | |
| 245 | 1 | 0 | |a Introduction to polymeric composites with rice hulls |c Chris Defonseka |
| 264 | 1 | |a Shropshire, England |b Smithers Rapra |c 2014 | |
| 264 | 4 | |c © 2014 | |
| 300 | |a 1 online resource (208 pages) | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b c |2 rdamedia | ||
| 338 | |b cr |2 rdacarrier | ||
| 500 | |a Includes index | ||
| 500 | |a Description based on online resource; title from PDF title page (ebrary, viewed December 18, 2014) | ||
| 505 | 8 | |a Preface; Contents; Acknowledgments; A Note on Sources; 1 Introduction; 1.1 History of Composite Materials; 1.2 What are Composite Materials?; 1.2.1 Engineered Composites; 1.3 Types of Composites; 1.3.1 Composite Resins with Rice Hulls; 1.3.2 Composite Profiles with Rice Hulls; 1.3.3 Wood Polymer Composites; 1.3.4 High-density Polyethylene Resin Composites with Rice Hulls; 1.3.5 Polymer Composites with Recycled Plastics; 1.3.6 Fibre-reinforced Polymers; 1.3.7 Concrete; 1.3.8 Shape-polymer Composites; 1.3.9 Metal Fibre Composites; 1.3.10 Thermoplastic Composites with Metal Powders | |
| 505 | 8 | |a 1.3.11 Structured Composites1.3.12 Natural Composite -- Wood; 1.4 Uses for Composites; 1.4.1 Polymeric Composite Resins in Injection Moulding; 1.4.2 Polymeric Composite Resins in Extrusion; 1.4.3 Polymeric Composites in Compression Moulding; 1.4.4 Some widely used Applications for Composites; 1.5 Why use Thermoplastic Bio-composites?; 2 Basic Technology of Plastics; 2.1 Introduction to Plastics; 2.2 Chemistry of Plastics; 2.2.1 The Atom; 2.2.2 Molecular Weight (Mass); 2.2.3 Polymeric Molecules; 2.2.4 Polymers; 2.2.5 Polymerisation; 2.2.6 Polymer Structures; 2.2.7 Morphological Structures | |
| 505 | 8 | |a 2.2.8 Polymer Blends2.2.9 Filled Polymers; 2.2.10 Modified Polymers; 2.2.11 Polymer Groups; 2.3 Properties of Plastics; 2.3.1 Compatibility of Material Properties; 2.3.2 Mechanical Properties; 2.3.3 Friction and Wear; 2.3.4 Environmental Effects; 2.3.5 Water Absorption; 2.3.6 Weathering Effects; 2.4 Moulding Process for Plastics; 2.5 Recycling of Plastics; 3 Composite Technology; 3.1 Principles of Composites; 3.1.1 Principles of Polymeric Composite Resins; 3.1.2 Principles of Polymeric Composite Extruded Profiles; 3.1.3 Principles of Polymeric Composites in Injection Moulding | |
| 505 | 8 | |a 3.1.4 Principles of Polymeric Composites in Compression Moulding3.2 Formation of Composites; 3.2.1 Extrusion; 3.2.2 Matched Die; 3.2.3 Hand Layup Processing; 3.2.4 Spray-up Processing; 3.2.5 Rigid Vacuum Forming; 3.2.6 Vacuum-bag Process; 3.2.7 Pressure-bag Processing; 3.2.8 Filament Winding Process; 3.2.9 Centrifugal Reinforcing; 3.2.10 Pultrusion; 3.2.11 Cold Stamp Forming; 3.3 General Properties of Composites; 3.3.1 Density; 3.3.2 Compressive Strength; 3.3.3 Impact Strength; 3.3.4 Permeability and Sorption; 3.3.5 Weathering; 3.3.6 Water Absorption; 3.3.7 Friction and Wear; 3.3.8 Fatigue | |
| 505 | 8 | |a 3.3.9 Aesthetic Properties4 Common Polymers and Additives used for Processing; 4.1 Polyethylene; 4.1.1 Physical Properties; 4.1.2 Chemical Properties; 4.1.3 Classifications; 4.2 Polypropylene; 4.2.1 Chemical and Physical Properties; 4.3 Polyvinyl Chloride; 4.3.1 Production; 4.3.2 Additives for Polymers; 4.3.3 Plasticisers; 4.3.4 Important Properties; 4.4 Polystyrene; 4.4.1 Structure of Polystyrene; 4.4.2 Polymerisation; 4.5 High-density Polyethylene; 4.5.1 Properties; 4.6 Acrylonitrile-butadiene-styrene; 4.6.1 Properties; 4.7 Polymer Additives; 4.7.1 Anti-blocking Agents; 4.7.2 Slip Additives | |
| 505 | 8 | |a There are many types of materials being used for composites, but polymers have played a major part as composite materials due to their versatility and seemingly endless possibilities. Constant research and development has enabled polymers to establish themselves as an essential part of daily life by replacing traditional materials over the years. Polymer composites with biomasses have been the trend for some time now, with wood plastic composites (WPC) probably the most common. However, a new and exciting field of polymer composites are opening up: polymeric composites with rice hulls. These c | |
| 650 | 4 | |a Polymers / Industrial applications | |
| 650 | 4 | |a Polymers | |
| 650 | 4 | |a Textile fibers, Synthetic | |
| 650 | 7 | |a TECHNOLOGY & ENGINEERING / Engineering (General) |2 bisacsh | |
| 650 | 7 | |a TECHNOLOGY & ENGINEERING / Reference |2 bisacsh | |
| 650 | 7 | |a Polymers |2 fast | |
| 650 | 7 | |a Polymers / Industrial applications |2 fast | |
| 650 | 7 | |a Textile fibers, Synthetic |2 fast | |
| 650 | 4 | |a Polymers |x Industrial applications |a Textile fibers, Synthetic |a Polymers | |
| 776 | 0 | 8 | |i Erscheint auch als |n Druck-Ausgabe |a Introduction to polymeric composites with rice hulls |
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Datensatz im Suchindex
| _version_ | 1804176616284225536 |
|---|---|
| any_adam_object | |
| author | Defonseka, Chris |
| author_facet | Defonseka, Chris |
| author_role | aut |
| author_sort | Defonseka, Chris |
| author_variant | c d cd |
| building | Verbundindex |
| bvnumber | BV043783976 |
| collection | ZDB-4-EBA |
| contents | Preface; Contents; Acknowledgments; A Note on Sources; 1 Introduction; 1.1 History of Composite Materials; 1.2 What are Composite Materials?; 1.2.1 Engineered Composites; 1.3 Types of Composites; 1.3.1 Composite Resins with Rice Hulls; 1.3.2 Composite Profiles with Rice Hulls; 1.3.3 Wood Polymer Composites; 1.3.4 High-density Polyethylene Resin Composites with Rice Hulls; 1.3.5 Polymer Composites with Recycled Plastics; 1.3.6 Fibre-reinforced Polymers; 1.3.7 Concrete; 1.3.8 Shape-polymer Composites; 1.3.9 Metal Fibre Composites; 1.3.10 Thermoplastic Composites with Metal Powders 1.3.11 Structured Composites1.3.12 Natural Composite -- Wood; 1.4 Uses for Composites; 1.4.1 Polymeric Composite Resins in Injection Moulding; 1.4.2 Polymeric Composite Resins in Extrusion; 1.4.3 Polymeric Composites in Compression Moulding; 1.4.4 Some widely used Applications for Composites; 1.5 Why use Thermoplastic Bio-composites?; 2 Basic Technology of Plastics; 2.1 Introduction to Plastics; 2.2 Chemistry of Plastics; 2.2.1 The Atom; 2.2.2 Molecular Weight (Mass); 2.2.3 Polymeric Molecules; 2.2.4 Polymers; 2.2.5 Polymerisation; 2.2.6 Polymer Structures; 2.2.7 Morphological Structures 2.2.8 Polymer Blends2.2.9 Filled Polymers; 2.2.10 Modified Polymers; 2.2.11 Polymer Groups; 2.3 Properties of Plastics; 2.3.1 Compatibility of Material Properties; 2.3.2 Mechanical Properties; 2.3.3 Friction and Wear; 2.3.4 Environmental Effects; 2.3.5 Water Absorption; 2.3.6 Weathering Effects; 2.4 Moulding Process for Plastics; 2.5 Recycling of Plastics; 3 Composite Technology; 3.1 Principles of Composites; 3.1.1 Principles of Polymeric Composite Resins; 3.1.2 Principles of Polymeric Composite Extruded Profiles; 3.1.3 Principles of Polymeric Composites in Injection Moulding 3.1.4 Principles of Polymeric Composites in Compression Moulding3.2 Formation of Composites; 3.2.1 Extrusion; 3.2.2 Matched Die; 3.2.3 Hand Layup Processing; 3.2.4 Spray-up Processing; 3.2.5 Rigid Vacuum Forming; 3.2.6 Vacuum-bag Process; 3.2.7 Pressure-bag Processing; 3.2.8 Filament Winding Process; 3.2.9 Centrifugal Reinforcing; 3.2.10 Pultrusion; 3.2.11 Cold Stamp Forming; 3.3 General Properties of Composites; 3.3.1 Density; 3.3.2 Compressive Strength; 3.3.3 Impact Strength; 3.3.4 Permeability and Sorption; 3.3.5 Weathering; 3.3.6 Water Absorption; 3.3.7 Friction and Wear; 3.3.8 Fatigue 3.3.9 Aesthetic Properties4 Common Polymers and Additives used for Processing; 4.1 Polyethylene; 4.1.1 Physical Properties; 4.1.2 Chemical Properties; 4.1.3 Classifications; 4.2 Polypropylene; 4.2.1 Chemical and Physical Properties; 4.3 Polyvinyl Chloride; 4.3.1 Production; 4.3.2 Additives for Polymers; 4.3.3 Plasticisers; 4.3.4 Important Properties; 4.4 Polystyrene; 4.4.1 Structure of Polystyrene; 4.4.2 Polymerisation; 4.5 High-density Polyethylene; 4.5.1 Properties; 4.6 Acrylonitrile-butadiene-styrene; 4.6.1 Properties; 4.7 Polymer Additives; 4.7.1 Anti-blocking Agents; 4.7.2 Slip Additives There are many types of materials being used for composites, but polymers have played a major part as composite materials due to their versatility and seemingly endless possibilities. Constant research and development has enabled polymers to establish themselves as an essential part of daily life by replacing traditional materials over the years. Polymer composites with biomasses have been the trend for some time now, with wood plastic composites (WPC) probably the most common. However, a new and exciting field of polymer composites are opening up: polymeric composites with rice hulls. These c |
| ctrlnum | (ZDB-4-EBA)ocn900885852 (ZDB-4-ENC)ocn900885852 (OCoLC)900885852 (DE-599)BVBBV043783976 |
| dewey-full | 620.192 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 620 - Engineering and allied operations |
| dewey-raw | 620.192 |
| dewey-search | 620.192 |
| dewey-sort | 3620.192 |
| dewey-tens | 620 - Engineering and allied operations |
| format | Electronic eBook |
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| id | DE-604.BV043783976 |
| illustrated | Not Illustrated |
| indexdate | 2024-07-10T07:35:01Z |
| institution | BVB |
| isbn | 9781909030800 1909030805 9781909030794 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-029195036 |
| oclc_num | 900885852 |
| open_access_boolean | |
| owner | DE-1046 DE-1047 |
| owner_facet | DE-1046 DE-1047 |
| physical | 1 online resource (208 pages) |
| psigel | ZDB-4-EBA ZDB-4-EBA FAW_PDA_EBA |
| publishDate | 2014 |
| publishDateSearch | 2014 |
| publishDateSort | 2014 |
| publisher | Smithers Rapra |
| record_format | marc |
| spelling | Defonseka, Chris Verfasser aut Introduction to polymeric composites with rice hulls Chris Defonseka Shropshire, England Smithers Rapra 2014 © 2014 1 online resource (208 pages) txt rdacontent c rdamedia cr rdacarrier Includes index Description based on online resource; title from PDF title page (ebrary, viewed December 18, 2014) Preface; Contents; Acknowledgments; A Note on Sources; 1 Introduction; 1.1 History of Composite Materials; 1.2 What are Composite Materials?; 1.2.1 Engineered Composites; 1.3 Types of Composites; 1.3.1 Composite Resins with Rice Hulls; 1.3.2 Composite Profiles with Rice Hulls; 1.3.3 Wood Polymer Composites; 1.3.4 High-density Polyethylene Resin Composites with Rice Hulls; 1.3.5 Polymer Composites with Recycled Plastics; 1.3.6 Fibre-reinforced Polymers; 1.3.7 Concrete; 1.3.8 Shape-polymer Composites; 1.3.9 Metal Fibre Composites; 1.3.10 Thermoplastic Composites with Metal Powders 1.3.11 Structured Composites1.3.12 Natural Composite -- Wood; 1.4 Uses for Composites; 1.4.1 Polymeric Composite Resins in Injection Moulding; 1.4.2 Polymeric Composite Resins in Extrusion; 1.4.3 Polymeric Composites in Compression Moulding; 1.4.4 Some widely used Applications for Composites; 1.5 Why use Thermoplastic Bio-composites?; 2 Basic Technology of Plastics; 2.1 Introduction to Plastics; 2.2 Chemistry of Plastics; 2.2.1 The Atom; 2.2.2 Molecular Weight (Mass); 2.2.3 Polymeric Molecules; 2.2.4 Polymers; 2.2.5 Polymerisation; 2.2.6 Polymer Structures; 2.2.7 Morphological Structures 2.2.8 Polymer Blends2.2.9 Filled Polymers; 2.2.10 Modified Polymers; 2.2.11 Polymer Groups; 2.3 Properties of Plastics; 2.3.1 Compatibility of Material Properties; 2.3.2 Mechanical Properties; 2.3.3 Friction and Wear; 2.3.4 Environmental Effects; 2.3.5 Water Absorption; 2.3.6 Weathering Effects; 2.4 Moulding Process for Plastics; 2.5 Recycling of Plastics; 3 Composite Technology; 3.1 Principles of Composites; 3.1.1 Principles of Polymeric Composite Resins; 3.1.2 Principles of Polymeric Composite Extruded Profiles; 3.1.3 Principles of Polymeric Composites in Injection Moulding 3.1.4 Principles of Polymeric Composites in Compression Moulding3.2 Formation of Composites; 3.2.1 Extrusion; 3.2.2 Matched Die; 3.2.3 Hand Layup Processing; 3.2.4 Spray-up Processing; 3.2.5 Rigid Vacuum Forming; 3.2.6 Vacuum-bag Process; 3.2.7 Pressure-bag Processing; 3.2.8 Filament Winding Process; 3.2.9 Centrifugal Reinforcing; 3.2.10 Pultrusion; 3.2.11 Cold Stamp Forming; 3.3 General Properties of Composites; 3.3.1 Density; 3.3.2 Compressive Strength; 3.3.3 Impact Strength; 3.3.4 Permeability and Sorption; 3.3.5 Weathering; 3.3.6 Water Absorption; 3.3.7 Friction and Wear; 3.3.8 Fatigue 3.3.9 Aesthetic Properties4 Common Polymers and Additives used for Processing; 4.1 Polyethylene; 4.1.1 Physical Properties; 4.1.2 Chemical Properties; 4.1.3 Classifications; 4.2 Polypropylene; 4.2.1 Chemical and Physical Properties; 4.3 Polyvinyl Chloride; 4.3.1 Production; 4.3.2 Additives for Polymers; 4.3.3 Plasticisers; 4.3.4 Important Properties; 4.4 Polystyrene; 4.4.1 Structure of Polystyrene; 4.4.2 Polymerisation; 4.5 High-density Polyethylene; 4.5.1 Properties; 4.6 Acrylonitrile-butadiene-styrene; 4.6.1 Properties; 4.7 Polymer Additives; 4.7.1 Anti-blocking Agents; 4.7.2 Slip Additives There are many types of materials being used for composites, but polymers have played a major part as composite materials due to their versatility and seemingly endless possibilities. Constant research and development has enabled polymers to establish themselves as an essential part of daily life by replacing traditional materials over the years. Polymer composites with biomasses have been the trend for some time now, with wood plastic composites (WPC) probably the most common. However, a new and exciting field of polymer composites are opening up: polymeric composites with rice hulls. These c Polymers / Industrial applications Polymers Textile fibers, Synthetic TECHNOLOGY & ENGINEERING / Engineering (General) bisacsh TECHNOLOGY & ENGINEERING / Reference bisacsh Polymers fast Polymers / Industrial applications fast Textile fibers, Synthetic fast Polymers Industrial applications Textile fibers, Synthetic Polymers Erscheint auch als Druck-Ausgabe Introduction to polymeric composites with rice hulls |
| spellingShingle | Defonseka, Chris Introduction to polymeric composites with rice hulls Preface; Contents; Acknowledgments; A Note on Sources; 1 Introduction; 1.1 History of Composite Materials; 1.2 What are Composite Materials?; 1.2.1 Engineered Composites; 1.3 Types of Composites; 1.3.1 Composite Resins with Rice Hulls; 1.3.2 Composite Profiles with Rice Hulls; 1.3.3 Wood Polymer Composites; 1.3.4 High-density Polyethylene Resin Composites with Rice Hulls; 1.3.5 Polymer Composites with Recycled Plastics; 1.3.6 Fibre-reinforced Polymers; 1.3.7 Concrete; 1.3.8 Shape-polymer Composites; 1.3.9 Metal Fibre Composites; 1.3.10 Thermoplastic Composites with Metal Powders 1.3.11 Structured Composites1.3.12 Natural Composite -- Wood; 1.4 Uses for Composites; 1.4.1 Polymeric Composite Resins in Injection Moulding; 1.4.2 Polymeric Composite Resins in Extrusion; 1.4.3 Polymeric Composites in Compression Moulding; 1.4.4 Some widely used Applications for Composites; 1.5 Why use Thermoplastic Bio-composites?; 2 Basic Technology of Plastics; 2.1 Introduction to Plastics; 2.2 Chemistry of Plastics; 2.2.1 The Atom; 2.2.2 Molecular Weight (Mass); 2.2.3 Polymeric Molecules; 2.2.4 Polymers; 2.2.5 Polymerisation; 2.2.6 Polymer Structures; 2.2.7 Morphological Structures 2.2.8 Polymer Blends2.2.9 Filled Polymers; 2.2.10 Modified Polymers; 2.2.11 Polymer Groups; 2.3 Properties of Plastics; 2.3.1 Compatibility of Material Properties; 2.3.2 Mechanical Properties; 2.3.3 Friction and Wear; 2.3.4 Environmental Effects; 2.3.5 Water Absorption; 2.3.6 Weathering Effects; 2.4 Moulding Process for Plastics; 2.5 Recycling of Plastics; 3 Composite Technology; 3.1 Principles of Composites; 3.1.1 Principles of Polymeric Composite Resins; 3.1.2 Principles of Polymeric Composite Extruded Profiles; 3.1.3 Principles of Polymeric Composites in Injection Moulding 3.1.4 Principles of Polymeric Composites in Compression Moulding3.2 Formation of Composites; 3.2.1 Extrusion; 3.2.2 Matched Die; 3.2.3 Hand Layup Processing; 3.2.4 Spray-up Processing; 3.2.5 Rigid Vacuum Forming; 3.2.6 Vacuum-bag Process; 3.2.7 Pressure-bag Processing; 3.2.8 Filament Winding Process; 3.2.9 Centrifugal Reinforcing; 3.2.10 Pultrusion; 3.2.11 Cold Stamp Forming; 3.3 General Properties of Composites; 3.3.1 Density; 3.3.2 Compressive Strength; 3.3.3 Impact Strength; 3.3.4 Permeability and Sorption; 3.3.5 Weathering; 3.3.6 Water Absorption; 3.3.7 Friction and Wear; 3.3.8 Fatigue 3.3.9 Aesthetic Properties4 Common Polymers and Additives used for Processing; 4.1 Polyethylene; 4.1.1 Physical Properties; 4.1.2 Chemical Properties; 4.1.3 Classifications; 4.2 Polypropylene; 4.2.1 Chemical and Physical Properties; 4.3 Polyvinyl Chloride; 4.3.1 Production; 4.3.2 Additives for Polymers; 4.3.3 Plasticisers; 4.3.4 Important Properties; 4.4 Polystyrene; 4.4.1 Structure of Polystyrene; 4.4.2 Polymerisation; 4.5 High-density Polyethylene; 4.5.1 Properties; 4.6 Acrylonitrile-butadiene-styrene; 4.6.1 Properties; 4.7 Polymer Additives; 4.7.1 Anti-blocking Agents; 4.7.2 Slip Additives There are many types of materials being used for composites, but polymers have played a major part as composite materials due to their versatility and seemingly endless possibilities. Constant research and development has enabled polymers to establish themselves as an essential part of daily life by replacing traditional materials over the years. Polymer composites with biomasses have been the trend for some time now, with wood plastic composites (WPC) probably the most common. However, a new and exciting field of polymer composites are opening up: polymeric composites with rice hulls. These c Polymers / Industrial applications Polymers Textile fibers, Synthetic TECHNOLOGY & ENGINEERING / Engineering (General) bisacsh TECHNOLOGY & ENGINEERING / Reference bisacsh Polymers fast Polymers / Industrial applications fast Textile fibers, Synthetic fast Polymers Industrial applications Textile fibers, Synthetic Polymers |
| title | Introduction to polymeric composites with rice hulls |
| title_auth | Introduction to polymeric composites with rice hulls |
| title_exact_search | Introduction to polymeric composites with rice hulls |
| title_full | Introduction to polymeric composites with rice hulls Chris Defonseka |
| title_fullStr | Introduction to polymeric composites with rice hulls Chris Defonseka |
| title_full_unstemmed | Introduction to polymeric composites with rice hulls Chris Defonseka |
| title_short | Introduction to polymeric composites with rice hulls |
| title_sort | introduction to polymeric composites with rice hulls |
| topic | Polymers / Industrial applications Polymers Textile fibers, Synthetic TECHNOLOGY & ENGINEERING / Engineering (General) bisacsh TECHNOLOGY & ENGINEERING / Reference bisacsh Polymers fast Polymers / Industrial applications fast Textile fibers, Synthetic fast Polymers Industrial applications Textile fibers, Synthetic Polymers |
| topic_facet | Polymers / Industrial applications Polymers Textile fibers, Synthetic TECHNOLOGY & ENGINEERING / Engineering (General) TECHNOLOGY & ENGINEERING / Reference Polymers Industrial applications Textile fibers, Synthetic Polymers |
| work_keys_str_mv | AT defonsekachris introductiontopolymericcompositeswithricehulls |