01091nam 2200337 n 450 99638547920331620221108053121.0(CKB)1000000000603224(EEBO)2248513912(UnM)99872198(EXLCZ)99100000000060322419850403d1644 uy |engurbn||||a|bb|Sir Simon D'Ewes his 9th speech in the House of Commons upon Saturday July 27 1644[electronic resource][London? s.n.1644][8] pMS copy.Variant of Wing D1254.reproduction of the original in the British Library.eebo-0018Great BritainHistoryCivil War, 1642-1649Early works to 1800D'Ewes SimondsSir,1602-1650.1003586Cu-RivESCu-RivESCStRLINWaOLNBOOK996385479203316Sir Simon D'Ewes his 9th speech in the House of Commons upon Saturday July 27 16442306087UNISA05424nam 2200673Ia 450 991081318940332120240514070136.01-283-40120-797866134012051-118-16280-31-118-16279-X1-118-16285-4(CKB)2670000000138107(EBL)818501(OCoLC)769342422(SSID)ssj0000576116(PQKBManifestationID)11349261(PQKBTitleCode)TC0000576116(PQKBWorkID)10553713(PQKB)11601586(MiAaPQ)EBC818501(Au-PeEL)EBL818501(CaPaEBR)ebr10523232(CaONFJC)MIL340120(EXLCZ)99267000000013810720110720d2011 uy 0engur|n|---|||||txtccrRadiation processing of polymer materials and its industrial applications /Keizou Makuuchi, Song Cheng1st ed.Hoboken, N.J. Wiley20111 online resource (445 p.)Description based upon print version of record.0-470-58769-5 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: Throughput1.4.4: 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 Crosslinking2.2.2.2: 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: Copolymer2.4.2.8: 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: Plasticizer3.3.4: 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 Temperature4.2.1.1: Mechanical PropertiesUp-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 PolymersEffect of radiation onRadiation chemistryIndustrial applicationsPolymersEffect of radiation on.Radiation chemistryIndustrial applications.620.1/9204228Makuuchi Keizou1702536Cheng Song1702537MiAaPQMiAaPQMiAaPQBOOK9910813189403321Radiation processing of polymer materials and its industrial applications4087113UNINA