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Dynamic Mechanical Analysis of E-Beam and Thermally Curable IPN Thermosets

Interpenetrating polymer network (IPN) materials possess unique properties that can be exploited for multicomponent composite armor systems, including toughness and thermal stability. E-beam curing of composites and adhesives offers advantages, such as reduced cure shrinkages, over traditional autoc...

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Main Authors:	Jensen, Robert E, Palmese, Giuseppe R, McKnight, Steven H
Format:	Report
Language:	English
Subjects:	ADHESIVES ARMOR AUTOCLAVES BEHAVIOR COMPOSITE MATERIALS COMPOSITE STRUCTURES CURING ELECTRON BEAMS Laminates and Composite Materials MECHANICAL PROPERTIES NETWORKS POLYMERS PROCESSING THERMAL PROPERTIES THERMAL STABILITY Thermodynamics THICKNESS TOUGHNESS VISCOELASTICITY WEAPON SYSTEMS
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creator	Jensen, Robert E Palmese, Giuseppe R McKnight, Steven H
description	Interpenetrating polymer network (IPN) materials possess unique properties that can be exploited for multicomponent composite armor systems, including toughness and thermal stability. E-beam curing of composites and adhesives offers advantages, such as reduced cure shrinkages, over traditional autoclave processing by curing multiple resins through the thickness for thick-section composites in a single step. Because of the complexity and thickness of composite integral armor structures, e-beam curing is an attractive processing method for Future Combat System applications, and the development of these new resins permits this approach. This research seeks to discern the differences in viscoelastic behavior between traditional thermal and e-beam curing in IPN resins, as these viscoelastic characteristics may prove important for composite integral armor applications.
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E-beam curing of composites and adhesives offers advantages, such as reduced cure shrinkages, over traditional autoclave processing by curing multiple resins through the thickness for thick-section composites in a single step. Because of the complexity and thickness of composite integral armor structures, e-beam curing is an attractive processing method for Future Combat System applications, and the development of these new resins permits this approach. 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source	DTIC Technical Reports
subjects	ADHESIVES ARMOR AUTOCLAVES BEHAVIOR COMPOSITE MATERIALS COMPOSITE STRUCTURES CURING ELECTRON BEAMS Laminates and Composite Materials MECHANICAL PROPERTIES NETWORKS POLYMERS PROCESSING THERMAL PROPERTIES THERMAL STABILITY Thermodynamics THICKNESS TOUGHNESS VISCOELASTICITY WEAPON SYSTEMS
title	Dynamic Mechanical Analysis of E-Beam and Thermally Curable IPN Thermosets
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