Modeling the water-modified microstructure and viscoelasticity of epoxy resins and their composites /

The application of epoxy resin composites in the marine

Bibliographic Details
Main Author: Simon, Philip Parayil, 1959-
Format: Thesis Book
Language:English
Published: [Place of publication not identified] : [publisher not identified] ; 1995.
Subjects:
Online Access:Link to OAKTrust copy
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Description
Summary:The application of epoxy resin composites in the marine
environment is hindered by long-term modulus changes and
unpredictable structural failure due to wate-induced internal
damage. Water modifies the viscoelastic behavior of the
epoxy resin matrix as well as the microstructure of the
composite. One of the macroscopic observations of the effect
of water is the water-induced co-transition in an isochrone
of the dynamic modulus. Because this transition is linked to
water sorption and internal damage within the composite,
identification of its cause is important. This work
hypothesizes, with supporting modeling, a possible mechanism
for the co-transition. The hypothesis states that a
heterogeneous distribution of water within the resin is the
source of the transition. The validity of the hypothesis is
tested by qualitatively comparing the transitions observed in
the predicted dynamic moduli to the experimental moduli. In
order to predict the dynamic moduli of the heterogeneous
material, the properties of the individual phases, including
the viscoelastic moduli of the un-measurable water-rich epoxy
resin phase, are necessary. A molecular-level model,
developed to account for the interaction of time,
temperature, and diluents on the viscoelastic properties of
crosslinked polymers, predicts the properties of a model
epoxy resin with various water contents. The volume-averaged
dynamic moduli of the heterogeneous resins and composites
with the hypothesized water-rich phase are calculated using
micromechanical averaging techniques. The appearance of
transitions in the predicted dynamic moduli similar to
experimental co-transitions supports the proposed hypothesis.
The molecular-level model not only provides a functional
form-n to fit the experimental isochrone data of the resin
and a predictive equation for the isothermal frequency
response, but also aids in the study of time-temperature
superposition and its validity in the presence of water.
Item Description:Vita.
"Major Subject: Chemical Engineering".
Physical Description:xiv, 174 leaves : illustrations ; 28 cm.
Issued also on microfiche from University Microfilms Inc.
Bibliography:Includes bibliographical references.