Polydimethylsiloxane Modification of Segmented Thermoplastic Polyurethanes and Polyureas

Wang, Feng

31 August 1998

This thesis addresses the systematic modification of poly(tetramethylene oxide) (PTMO), polyether based segmented thermoplastic polyurethane with a secondary aminoalkyl functional polydimethylsiloxane (PDMS), which was intended to improve the fire resistance of polyurethane systems. The PDMS oligomer was successfully incorporated into the polyurethane backbone via one step solution polymerization. The effect of PDMS content on thermal stability, morphology, surface composition, mechanical properties, and fire resistance of polyurethane was investigated. These polymers displayed a complex two phase morphology and composition-dependant mechanical properties. The PDMS segment microphase separated from other polyurethane segments and varying microphase separation morphologies were observed with differing PDMS content. Spherical dispersed complex phases and co-continuous phases occurred when the PDMS content was 15wt% and 55wt%, respectively. Similar thermal stability was observed for both the polyurethane control and the PDMS modified polyurethanes, but the later displayed increased char yield in air with increased PDMS concentration. Quantitative measurements of the fire resistance of the modified polyurethanes by cone calorimetry showed that the peak heat release rate of the 15wt% siloxane modified samples dropped 67wt%, compared with the polyurethane control. However, the peak heat release rate did not further change with increasing siloxane content. Excellent mechanical properties, in terms of tensile strength and elongation, were found for the modified polyurethane with 15wt% of PDMS. Higher PDMS levels did reduce tensile strength, probably because of the reduction in strain crystallizing PTMO content. The PDMS modification, which resulted in improved fire resistance and excellent mechanical properties, is attributed to the low surface energy of the PDMS segment that tended to migrate to the surface of the polymer. It could be oxidized into a partially silicate-like material upon heating in air. In addition, the syntheses of primary and secondary aminoalkyl functional PDMS based segmented polyureas are described herein. Two-phase morphology was observed for all the polyurea samples, even when the hard segment concentration was as low as 6wt%. All these polyureas formed clear transparent films that exhibited good mechanical properties even with very high PDMS content, up to 94wt%. They also demonstrated similar thermal stability, independent of the PDMS end group. However, the nature of the end group, i.e. primary or secondary aminoalkyl, had a dramatic effect on mechanical and morphological properties of these PDMS based polyureas, which was interpreted in terms of the level of hydrogen bonding. / Ph. D.

fire resistancy

polydimethylsiloxane

polyurea

polyurethane

segmented copolymer

SMD Publikuotų straipsnių apžvalga: Lietuvos zoologijos sodo kukurūzinių žalčių, karališkųjų gyvačių, stepinių vėžlių burnos mikrofloros tyrimas ir atsparumo antimikrobinėms medžiagoms nustatymas / SMD Review of thesis presented at student science conference: Lithuanian zoo’s corn snakes, royal snakes, lesser turtles mouths flora’s study and antimicrobial resistancy determination

Neverauskas, Donatas

05 March 2014

Stomatitas yra dažna roplių burnos infekcinė liga. Didėjant namie auginamų roplių skaičiui, daugės ir klinikinių atvejų veterinarijos gydyklose. Svarbu identifikuoti sukėlėjus ir paskirti tikslingą antimikrobinę terapiją. Tyrimui burnos gleivinės tepinėliai paimti iš: 8 kukurūzinių žalčių, 2 karališkųjų gyvačių ir 13 stepinių vėžlių, auginamų Lietuvos zoologijos sode. Išskirta burnos mikroflora: kukurūzinių žalčių-Staphylococcus spp., Streptococcus spp., Pseudomonas spp., Bacillus spp.; karališkųjų gyvačių: Staphylococcus spp., Streptoccocus spp.; stepinių vėžlių: Staphylococcus spp., Pseudomonas spp., Bacillus spp., Klebsiella spp. padermės. Jų atsparumui antimikrobinėms medžiagoms nustatyti atliktas testas pagal modifikuotą Kirby-Bauer (indikatorinių diskų) metodą. Panaudotos antimikrobinės medžiagos buvo: penicilinų, cefalosporinų, aminoglikozidų, sulfonamidų grupių. Atlikus sveikų kukurūzinių žalčių burnos mikrofloros tyrimus, nustatytas atsparumas antimikrobinėms medžiagoms- atspariausia sulfonamidui. Sergančio kukurūzinio žalčio išskirta burnos mikroflora atspari cefaklorui, oksitetraciklinui, amoksicilinui. Atlikus sveikų stepinių vėžlių burnos mėginių mikrofloros tyrimą, nustatytas atsparumas antimikrobinėms medžiagoms, atspariausia amoksicilinui ir klavulano rūgščiai. / Stomatitis (mouth infection) is common disease in reptiles. The number of reptiles kept as house pets is increasing so it is likely that clinical cases in veterinary clinics will also increase. It is necessary to identify infective agents and start optimal antimicrobial therapy. In this study microflora was isolated from reptiles kept at Lithuanian zoo: 8 corn snakes, 2 royal snakes, 13 russian tortoises. Isolated microflora was: corn snakes- Staphylococcus spp., Streptococcus spp., Pseudomonas spp., Bacillus spp.; royal snakes: Staphylococcus spp., Streptoccocus spp.; russian tortoises: Staphylococcus spp., Pseudomonas spp., Bacillus spp., Klebsiella spp. Resistance to antimicrobial substances was identified using modified Kirby-Bauer (indicatory discs) method. Antimicrobial substances were: penicillins, cephalosporins, aminoglycosides, sulphonamides. Resistance to antimicrobial substances of healthy corn snakes mouth microflora was: highest resistance to sulphonamides. Mouth microflora of corn snake with stomatitis was most resistive to cephaclor, oxitetracyclin, amoxicillin. Russian tortoise mouth microflora was most resistive to amoxicillin and clavulanic acid.

Veterinary Medicine

Ropliai

Mikroflora

Atsparumas

Antimikrobinės medžiagos

Reptiles

Microflora

Resistancy

Antimicrobial substances