Fracture surface morphology in thermosets modified with hollow microspheres

Kim, Ho Sung

Title: Fracture surface morphology in thermosets modified with hollow microspheres
Creator: Kim, Ho Sung
Relation: Journal of Applied Polymer Science Vol. 105, Issue 6, p. 3287-3294
Publisher Link: http://dx.doi.org/10.1002/app.26596
Publisher: John Wiley & Sons
Resource Type: journal article
Date: 2007
Description: Fracture surface morphology in relation with toughening of thermosets modified with hollow microspheres was studied. Two different toughening methods were employed - one was with (MEH) and the other without (ME) compressive residual stresses around microspheres, respectively. The compressive residual stresses were to increase effective stress intensity factor. Various conditions arising from toughening method, properties of constituent materials, bonding between matrix and microspheres, relativity between bonding and microsphere strengths, and plane stress/strain were derived for part of generalization of fracture surface morphology. Mohr circle representations were employed for relative stress components analysis. New deformation mechanisms contributing to toughening were proposed. A major difference in toughening mechanism between ME and MEH methods was found to be in the location of plastic deformation under plane strain. The plastic deformation of ME was dominantly in matrix and appeared in the form of matrix cavitation. In the case of MEH, it was dominantly in microspheres. It was suggested that compressive residual stress promotes plastic deformation of microspheres caused by extrusion effect. The microsphere deformation in MEH was found also under plane stress although it was not as much as under plane strain. Matrix cavitation in ME under plane stress, however, was not found.
Subject: thermosets; composites; fracture; toughness; stress
Identifier: http://hdl.handle.net/1959.13/33981
Identifier: uon:3438
Identifier: ISSN:0021-8995
Language: eng
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