ABSTRACT:The shape memory behavior of a series of polycaprolactone/methane diisocyanate/ butanediol ( PCL /MDI /BDO) segmented polyurethanes of different composition was studied. The molecular weight of PCL diols was in the range of 1600 -7000, and the hard segment content varied from 7.8 to 27% by weight. Film specimens for shape memory measurements were prepared by drawing at temperatures above the melting temperature of the soft segment crystals and subsequent quick cooling to room temperature under constrained conditions. The shape memory process was observed and recorded in a heating process. Parameters describing the recovery temperature, ability, and speed were used to study the influence of structure and processing conditions on the shape memory behavior of the sample. It was found that the high crystallinity of the soft segment regions at room temperature and the formation of stable hard segment domains acting as physical crosslinks in the temperature range above the melting temperature of the soft segment crystals are the two necessary conditions for a segmented copolymer with shape memory behavior. The response temperature of shape memory is dependent on the melting temperature of the soft segment crystals. The final recovery rate and the recovery speed are mainly related to the stability of the hard segment domains under stretching and are dependent on the hard segment content of the copolymers.
The cationic copolymerization of regular soybean oil, low-saturation soybean oil (LoSatSoy oil), or conjugated LoSatSoy oil with styrene and divinylbenzene initiated by boron trifluoride diethyl etherate (BF 3 ⅐OEt 2 ) or related modified initiators provides viable polymers ranging from soft rubbers to hard, tough, or brittle plastics. The gelation time of the reaction varies from 1 ϫ 10 2 to 2 ϫ 10 5 s at room temperature. The yields of bulk polymers are essentially quantitative. The amount of crosslinked polymer remaining after Soxhlet extraction ranges from 80 to 92%, depending on the stoichiometry and the type of oil used. Proton nuclear magnetic resonance spectroscopy and Soxhlet extraction data indicate that the structure of the resulting bulk polymer is a crosslinked polymer network interpenetrated with some linear or less-crosslinked triglyceride oil-styrene-divinylbenzene copolymers, a small amount of low molecular weight free oil, and minor amounts of initiator fragments. The bulk polymers possess glass-transition temperatures ranging from approximately 0 to 105°C, which are comparable to those of commercially available rubbery materials and conventional plastics. Thermogravimetric analysis (TGA) indicates that these copolymers are thermally stable under 200°C, with temperatures at 10% weight loss in air (T 10 ) ranging from 312 to 434°C, and temperatures at 50% weight loss in air (T 50 ) ranging from 445 to 480°C. Of the various polymeric materials, the conjugated LoSatSoy oil polymers have the highest glass-transition temperatures (T g ) and thermal stabilities (T 10 ). The preceding properties that suggest that these soybean oil polymers may prove useful where petroleumbased polymeric materials have found widespread utility.
A variety of new polymers ranging from rubbery materials to tough and rigid plastics have been prepared by the thermal copolymerization of tung oil, styrene, and divinylbenzene. The thermal copolymerization is performed in the temperature range of 85-160 degrees C with variations in the stoichiometry, oxygen uptake, peroxides, and metallic catalysts used. Gelation of the reactants typically occurs at temperatures higher than 140 degrees C, and fully cured thermosets are obtained after post-curing at 160 degrees C. The fully cured thermosets are determined by Soxhlet extraction to contain approximately 90-100% cross-linked materials, and (1)H NMR and FTIR spectroscopy indicates that the cross-linked materials are random copolymers. The new bulk polymeric materials obtained are light yellow and transparent with glossy surfaces, and possess glass transition temperatures of -2 to +116 degrees C, cross-link densities of 1.0 x 10(3)-2.5 x 10(4) mol/m(3), coefficients of linear thermal expansion of 2.3 x 10(-4)-4.4 x 10(-4) per degrees C, compressive moduli of 0.02-1.12 GPa, and compressive strengths of 8-144 MPa. These materials are thermally stable below 300 degrees C and exhibit a major thermal degradation with a maximum degradation rate at 493-506 degrees C.
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