2 research outputs found
Effects of Incorporation of Organically Modified Montmorillonite on the Reaction Mechanism of Epoxy/Amine Cure
The aim of this study is to understand the effect of
nonmodified
or different organically modified montmorillonites on the reaction
mechanism of epoxy/amine cure.
The reference material consists of diglycidyl ether of bisphenol A
(DGEBA) and 1,3-phenylene diamine (<i>m</i>PDA) in stoichiometric
proportions. The reaction with various organically modified montmorillonites
(I28E, I34TCN, and MMTm) is compared to highlight the catalytic effect
of MMT water content and of the alkylammonium cations on the epoxy/amine
reaction mechanism. In the absence of <i>m</i>PDA curing
agent, DGEBA develops homopolymerization reactions with I28E, I34TCN,
and MMTm. Chemorheological kinetics and advanced isoconversional analysis
of epoxy cure are studied by rheometrical measurements and differential
scanning calorimetry (DSC). Molecular mobility of the system under
curing is modified in the presence of montmorillonites. Finally, the
study underlines the role of montmorillonites and the influence of
the change in reaction mechanisms on glass transition of the nanocomposites
Valorization of Biorefinery Side-Stream Products: Combination of Humins with Polyfurfuryl Alcohol for Composite Elaboration
A challenge
of today’s industry is to transform low-value
side products into more value-added materials. Humins, a byproduct
derived from sugar conversion processes, can be transformed into high
value-added products. Thermosetting furanic composites were elaborated
with cellulose filters. Large quantities of humins were included into
a polyfuranic thermosetting network. Comparisons were made with composites
generated with polyfurfuryl alcohol (PFA) and with PFA/lignin. It
was concluded that new chemical interactions were created between
the side-chain oxygen groups of the humins and the PFA network. Analysis
of the fracture surface of the composites containing humins lead to
the conclusion that higher interfacial bonding and more efficient
stress transfer between the matrix and the fibers is present. The
higher ductility of the humins-based matrix allows for a two-fold
higher tensile strength in comparison with other composites tested.
Incorporation of humins decreases the brittleness of the furanic composites,
which is one major drawback of the pure PFA composites