Cinisello Balsamo : edizioni Paoline, 1991

8821522636

794 p. ; 22 cm

Classici del pensiero cristiano ; 7

Buzzi, Franco

Italiano

Hoboken, N.J., : Wiley, 2011

1-283-40120-7

9786613401205

1-118-16280-3

1-118-16279-X

1-118-16285-4

1 online resource (445 p.)

ChengSong

620.1/9204228

Polymers - Effect of radiation on

Radiation chemistry - Industrial applications

Inglese

Description based upon print version of record.

Includes bibliographical references.

Radiation Processing of Polymer Materials and its Industrial Applications; Contents; Preface; Abbreviations; 1: Basic Concepts of Radiation Processing; 1.1: Radiation Sources; 1.1.1: ?- Ray; 1.1.2: Electron Beam; 1.1.3: X-Ray; 1.2: Radiation Chemistry of Polymers; 1.2.1: Interactions of Ionizing Radiation with Polymers and Reactions Induced; 1.2.2: Different Responses to Radiation from Different Polymers; 1.3: Advantages and Disadvantages of Radiation Processing; 1.4: Engineering of Radiation Processing; 1.4.1: Materials Handling; 1.4.2: Radiation Dose and Dose Distribution; 1.4.3: Throughput

1.4.4: Temperature Rise1.4.5: Atmosphere; 1.4.6: Dose Rate; 1.4.7: Radiation Processing Cost; References; 2: Fundamentals of Radiation Crosslinking; 2.1: Radiation Chemistry of Crosslinking; 2.1.1: Types of Crosslinking; 2.1.2: Evidence of Crosslinking; 2.2: Crosslinking of Polymer; 2.2.1: Crosslinking of Semicrystalline Polymer; 2.2.1.1: Peroxide Crosslinking; 2.2.1.2: Silane Crosslinking; 2.2.1.3: Technical Comparison of Crosslinking Methods; 2.2.2: Crosslinking of Rubber; 2.2.2.1: Radiation Crosslinking Versus Sulfur Crosslinking

2.2.2.2: Radiation Crosslinking Versus Peroxide Crosslinking2.3: Estimation of G Value of Crosslinking; 2.3.1: Charlesby-Pinner Method; 2.3.2: Modification of Charlesby-Pinner Equation; 2.3.3: Swelling and Elasticity Methods; 2.4: Factors Affecting Radiation Crosslinking; 2.4.1: Physical Nature of Polymer; 2.4.1.1: Glass-Transition Temperature; 2.4.1.2: Crystallinity; 2.4.2: Chemical Composition of Polymer; 2.4.2.1: Bond Energy; 2.4.2.2: Unsaturation; 2.4.2.3: Methyl Group; 2.4.2.4: Halogen Atom; 2.4.2.5: Phenyl Group; 2.4.2.6: Ester and Ether Bond; 2.4.2.7: Copolymer

2.4.2.8: Ethylene Copolymer2.4.2.9: Fluoropolymer; 2.4.2.10: Silicone Rubber; 2.4.2.11: Branching; 2.4.3: Molecular Weight and Molecular Weight Distribution; 2.4.4: Configuration; 2.4.4.1: Structural Isomerism; 2.4.4.2: Stereoisomerism; References; 3: Enhancement of Radiation Crosslinking; 3.1: Concept of Enhancement of Radiation Crosslinking; 3.2: Increasing Number of Polymer Radicals; 3.2.1: Sensitizer; 3.2.2: Postirradiation Heat Treatment; 3.3: Increasing Recombination of Polymer Radicals; 3.3.1: Compression; 3.3.2: High-Temperature Irradiation; 3.3.3: Plasticizer

3.3.4: Polyfunctional Monomer3.4: Filler Effect; 3.4.1: Modification of Superstructure; 3.4.2: Direct Bonding to Amorphous Polymers; 3.5: Hybrid Crosslinking; 3.6: Selection of Antioxidant; 3.7: Advanced Radiation Crosslinking; References; 4: Properties of Radiation Crosslinked Polymers; 4.1: Radiation Crosslinked Rubbers; 4.1.1: Radiation Crosslinking of Rubbers; 4.1.2: Properties of Radiation Crosslinked Rubbers with PFM; 4.1.3: Silicone Rubber; 4.1.4: Fluoroelastomer; 4.2: Radiation Crosslinked Plastics; 4.2.1: Physical Properties of Crosslinked Polymers at Room Temperature

4.2.1.1: Mechanical Properties

Up-to-date, comprehensive coverage on radiation-processed polymer materials and their applications Offering a unique perspective of the industrial and commercial applications of the radiation processing of polymers, this insightful reference examines the fundamental scientific principles and cutting-edge developments advancing this diverse field. Through a variety of case studies, detailed examples, and economic feasibility analysis, Radiation Processing of Polymer Materials and Its Industrial Applications systematically explains the commercially viable ways to process and use