Global ETD Search

31	Synthesis, Characterization and Thermal Decomposition of Hybrid and Reverse Fluorosilicones Conrad, Michael Perry Cyrus 18 February 2010 (has links) Traditional fluorosilicones contain a siloxane backbone and pendant fluorinated group leading to low temperature ductility and excellent thermal stability. However, acidic or basic catalysts can reduce the thermal stability from a potential 350 °C to 150 °C. The predominant decomposition mechanism is through chain scission and it is hypothesized that preventing this will result in polymers with higher thermal stability. Three approaches were taken to prevent chain scission. First, a series of hybrid fluorosilicones based on (trifluorovinyl)benzene were synthesized through condensation polymerization with initial decomposition temperatures of approximately 240 °C. These were compared to similar aromatic polyethers and removal of the ether oxygen lowered the initial decomposition temperature by approximately 190 °C demonstrating the importance of this oxygen to the stability of polyethers. Second, reverse fluorosilicone (fluorinated backbone and pendant siloxane) terpolymers of chlorotrifluoroethylene (CTFE), vinyl acetate (VAc) and methacryloxypropyl-terminated polydimethylsiloxane (PDMSMA) were synthesized in supercritical CO2 (scCO2) or by emulsion polymerization. Chain scission was prevented as initial decomposition occurred between 231 and 278 °C. In both the emulsion and scCO2 cases, VAc was essential in facilitating cross-propagation between CTFE and PDMSMA and the branching was similar suggesting polymerization media does not affect polymer structure. Emulsion-based polymers had higher molar masses and thermal stability whereas comparable scCO2 polymers had higher yields and incorporated more PDMSMA. Third, a series of homo-, co-, and terpolymers of CTFE, VAc and methacryloxypropyl-terminated silsesquioxane (POSSMA) were synthesized representing the first synthesis of POSSMA containing polymers in scCO2 and demonstrating reverse fluorosilicones can be synthesized without VAc. Chain scission was prevented as initial decomposition occurred from 244 to 296 °C with thermal stability increasing with CTFE content to a limit. Decomposition of the polymers was examined and mechanism elucidated. In air, the copolymers give 40 to 47 wt% char since the silsesquioxane oxidizes to SiO2 while in N2, no residue is seen. In contrast, the terpolymers give a carbonaceous residue of approximately 20 wt% in N2. The flammability and surface properties of the polymers were examined with the terpolymers having flammability similar to p(CTFE) and surface properties comparable to p(POSSMA) giving a low-flammability, hydrophobic polymer. fluorosilicone decomposition polymer synthesis fluoropolymer supercritical carbon dioxide chlorotrifluoroethylene vinyl acetate polyhedral oligomeric silsesquioxane flammability thermal thermo-oxidative 0542
32	Synthesis, Characterization and Thermal Decomposition of Hybrid and Reverse Fluorosilicones Conrad, Michael Perry Cyrus 18 February 2010 (has links) Traditional fluorosilicones contain a siloxane backbone and pendant fluorinated group leading to low temperature ductility and excellent thermal stability. However, acidic or basic catalysts can reduce the thermal stability from a potential 350 °C to 150 °C. The predominant decomposition mechanism is through chain scission and it is hypothesized that preventing this will result in polymers with higher thermal stability. Three approaches were taken to prevent chain scission. First, a series of hybrid fluorosilicones based on (trifluorovinyl)benzene were synthesized through condensation polymerization with initial decomposition temperatures of approximately 240 °C. These were compared to similar aromatic polyethers and removal of the ether oxygen lowered the initial decomposition temperature by approximately 190 °C demonstrating the importance of this oxygen to the stability of polyethers. Second, reverse fluorosilicone (fluorinated backbone and pendant siloxane) terpolymers of chlorotrifluoroethylene (CTFE), vinyl acetate (VAc) and methacryloxypropyl-terminated polydimethylsiloxane (PDMSMA) were synthesized in supercritical CO2 (scCO2) or by emulsion polymerization. Chain scission was prevented as initial decomposition occurred between 231 and 278 °C. In both the emulsion and scCO2 cases, VAc was essential in facilitating cross-propagation between CTFE and PDMSMA and the branching was similar suggesting polymerization media does not affect polymer structure. Emulsion-based polymers had higher molar masses and thermal stability whereas comparable scCO2 polymers had higher yields and incorporated more PDMSMA. Third, a series of homo-, co-, and terpolymers of CTFE, VAc and methacryloxypropyl-terminated silsesquioxane (POSSMA) were synthesized representing the first synthesis of POSSMA containing polymers in scCO2 and demonstrating reverse fluorosilicones can be synthesized without VAc. Chain scission was prevented as initial decomposition occurred from 244 to 296 °C with thermal stability increasing with CTFE content to a limit. Decomposition of the polymers was examined and mechanism elucidated. In air, the copolymers give 40 to 47 wt% char since the silsesquioxane oxidizes to SiO2 while in N2, no residue is seen. In contrast, the terpolymers give a carbonaceous residue of approximately 20 wt% in N2. The flammability and surface properties of the polymers were examined with the terpolymers having flammability similar to p(CTFE) and surface properties comparable to p(POSSMA) giving a low-flammability, hydrophobic polymer. fluorosilicone decomposition polymer synthesis fluoropolymer supercritical carbon dioxide chlorotrifluoroethylene vinyl acetate polyhedral oligomeric silsesquioxane flammability thermal thermo-oxidative 0542
33	Wood Nanocellulose Materials and Effects from Surface Modification of Nanoparticles Salajkova, Michaela January 2013 (has links) Nanocellulose is an interesting natural material thatis gaining interest in the field of materials science, particularly nanocomposites. Depending on the disintegration route, nanocellulose can be isolated either in the form of long and flexible fibres (nanofibrillated cellulose, NFC), or stiff, rod-like crystals (cellulose nanocrystals, CNC). Nanocellulose can be utilized in nanocomposites either as a reinforcement element or as a network matrix due to its ability to form a strong network. In this thesis, nanocellulose based materials are prepared by evaporation of a liquid medium. The key step in this processing route is a good dispersion of the nanoparticles in the selected matrix. Therefore the importance of surface modification in order to ensure favourable nanocellulose dispersion is clarified in avariety of materials systems. In Paper I, poly(methyl methacrylate) (PMMA) based fibres prepared by electrospinning were reinforced with nanofibrillated cellulose. Native NFC appeared to show a good compatibility with PMMA matrix in the electrospinning solution and resulting fibres. Furthermore, a new method for mechanical testing of mats with random fibre orientation as well as aligned fibres was developed. In Paper II, commingled nanopaper structures with carbon nanotubes (CNTs) were prepared. Several surfactants were used to disperse hydrophobic CNTs in water. A nonylphenol phosphate ester (NPPE) was found to work well for both dispersing CNTs in water and providing compatibility with NFC through electrostatic repulsion between the phosphate ester groups of the surfactant and the carboxylate groups of NFC. In Paper III, a new water based route for functionalization of cellulose nanocrystals was developed. In this approach, inspired by organo-modified layered silicates, quaternary ammonium salts were adsorbed. It was demonstrated that different functionalities (alkyl, phenyl, glycidylor diallyl) can be introduced onto the cellulose and the dispersibility in organic solvents was studied. Subsequently, in Paper IV, nanocomposites with poly(vinyl acetate) (PVAc)were prepared. The effect of modification on the degree of dispersion of the CNC within the matrix was studied as well as the strong effects on the properties of the resulting nanocomposites. In Paper V, taking advantage of the entangled NFC network and the possibility to tailor the pore size and surface chemistry, lubricant-infused slippery films and coatings based on NFC were prepared for the first time. / <p>QC 20131016</p> Nanocellulose nanoc omposite dispersion surface modification surfa ctant poly(methyl methacrylate) poly(vinyl acetate) carbon nanotubes electrospinning lubricant - infused surfaces
34	Acylation des nanocelluloses en milieu aqueux par transestérification des esters de vinyle et utilisation comme charge dans le caoutchouc naturel / Acylation of nanocelluloses in aqueous media by transesterification of vinyl esters and utilization as filler in natural rubber Dhuiège, Benjamin 11 July 2017 (has links) Ce travail de thèse a pour objectif d’élaborer de nouveaux matériaux composites (élastomères, adhésifs) en utilisant les nanocelluloses (NCC et NFC) comme renforts mécaniques biosourcés. Une méthode de fonctionnalisation des nanocelluloses en conditions aqueuses a d’abord été développée, dans le but ultime d’améliorer leur compatibilité avec les matrices polymères. La réaction, basée sur la transestérification des esters de vinyle, a été optimisée à partir de l’acétate de vinyle utilisé comme réactif modèle. Le greffage en conditions basiques s’est avéré efficace, mais a également conduit à la formation de poly(acétate de vinyle) (PVAc) comme produit secondaire. Pour pallier à ce problème, un deuxième protocole en conditions neutres a également été développé, mais des rendements moins bons ont été obtenus dans ce cas. Les nanocelluloses non modifiées et acétylées ont ensuite été dispersés dans une matrice caoutchouc naturel (NR) afin d’étudier l’impact de cette charge sur les performances thermomécaniques du matériau cru ou vulcanisé. Une amélioration des propriétés mécaniques a pu être observée en présence de NCC ou NFC, mais l’acétylation des nanoparticules n’a pas conduit à de meilleures performances. Enfin, une valorisation du PVAc produit lors de l’acétylation des nanocelluloses en conditions aqueuses basiques a été proposée. La dispersion des NCC acétylés dans le PVAc polymérisé in-situ a en effet permis de produire des composites aux propriétés améliorées. L’utilisation ultérieure de ces composites comme charge (mélange-maître) dans des matrices NR ou EVA a été discutée. / The objective of this research work consists in the elaboration of novel composite materials (elastomers, adhesives) using nanocelluloses (CNC and NFC) as biobased reinforcing fillers. A method allowing the functionalization of nanocelluloses in aqueous conditions was first developed, with the aim of ultimately improving their compatibility with polymer matrices. The reaction, based on the transesterification of vinyl esters, was optimized with vinyl acetate selected as model reactant. The grafting performed in basic aqueous conditions was efficient, but also led to the formation of poly(vinyl acetate) as a by-product. To limit this problem, a second protocol in neutral aqueous conditions was also developed, but lower yields were obtained in that case. The unmodified and acetylated nanocelluloses were then dispersed in a natural rubber matrix (NR), to study the impact of this filler on the thermomechanical performances of the crude and vulcanized material. An improvement of the mechanical properties was observed in the presence of NCC or NFC, but the acetylation of the nanoparticles did not enhance further the performances. Finally, a valorization of the PVAc produced during the acetylation of the nanocelluloses in basic aqueous conditions was proposed. The dispersion of the acetylated NCC in the PVAc polymerized in-situ indeed led to the production of composites with improved properties. The subsequent utilization of these composites as filler (master batch) in NR or EVA matrices was discussed. Nanocelluloses Fonctionnalisation Acétate de vinyle Milieu aqueux Nanocomposites Caoutchouc naturel PVAc Nanocelluloses Functionalization Vinyl acetate Aqueous medium Nanocomposites Natural rubber PVAc.
35	Estudo das propriedades do cimento asfÃltico de petrÃleo modificado por copolÃmero de etileno e acetato de vinila(eva) / Study of the asphaltic cement of petroleum modified for copolymers of ethylene vinyl acetate(EVA) Ana Ellen Valentim de Alencar 13 July 2005 (has links) CoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superior / Cimento AsfÃltico de PetrÃleo (CAP), caracterizado como CAP 50/60, oriundo do Campo Fazenda Alegre, no estado do EspÃrito Santo, foi modificado por adiÃÃo de CopolÃmero de Etileno e Acetato de Vinila (EVA). Na modificaÃÃo foram incorporadas amostras do copolÃmero EVA puro e proveniente do resÃduo da indÃstria de calÃados (EVAR). Os CAPS, polÃmeros e CAPS modificados, foram inicialmente caracterizados por espectroscopia no infravermelho (FTIR) e ressonÃncia magnÃtica nuclear (RMN). AnÃlise tÃrmica, como a termogravimetria (TG) e caloria exploratÃria diferencial (DSC), foi utilizada para o estudo da decomposiÃÃo tÃrmica, bem como para avaliar a estabilidade termoxidativa das amostras. Testes empÃricos como penetraÃÃo, ponto de amolecimento, susceptibilidade tÃrmica e retorno elÃstico, alÃm de viscosidade, tambÃm foram realizados para caracterizaÃÃo dos materiais. Os resultados indicaram que CAPS modificados apresentaram maior estabilidade em atmosfera oxidativa do que em atmosfera inerte. A anÃlise das curvas DSC revelou que os CAPS modificados mostraram-se mais resistentes Ã trincas tÃrmicas, quando submetidos a temperaturas mais baixas, que o CAP convencional. Os CAPS modificados foram mais resistentes Ã decomposiÃÃo oxidativa, quando foram submetidos ao envelhecimento simulado. A viscosidade do ligante modificado por adiÃÃo do polÃmero foi aumentada em relaÃÃo ao ligante puro. Diferentemente do CAP convencional, o CAP modificado por EVAR apresentou comportamento nÃo Newtoniano. Os ensaios empÃricos, relativos Ã penetraÃÃo, ponto de amolecimento, susceptibilidade tÃrmica e retorno elÃstico, mostraram que os CAPS modificados com EVAR, tiveram uma melhoria nas suas propriedades fÃsicas, em relaÃÃo aos CAPS nÃo modificados. / The Petroleum Asphaltic Cement characterized as CAP 50/60, produced at the state of EspÃrito Santo (Fazenda Alegre), was modified by addition of copolymers of ethylene vinyl acetate (EVA) and EVA from the footwearâs industry residue (EVAR). The original and modified CAPS were characterized by infrared spectroscopy (FTIR) and nuclear magnetic resonance (RMN). Thermal analysis,as thermogravimetry (TG) and differential scanning calorimetry (DSC), was used to evaluate the thermal stability of the samples. The characterization was also performed with empirical tests such as penetration, softening point, elastic recovery and viscosity. The main results indicated that polymer modified CAPS presented larger thermal stability in oxidative atmosphere than in inert atmosphere. The analysis of DSC curves revealed that modified CAPS, when submitted to lower temperatures, were more resistant to the thermal cracks than conventional CAP. Also modified CAPS showed to be more resistant to the thermal oxidative decomposition, when submitted to a simulated aging process. The viscosity of the polymer modified binder was increased in relation to the original binder. Polymer modified CAP EVAR presented non-Newtonian behavior, whereas Newtonian behavior was observed for unmodified CAP. It was observed that modifying the asphalt binder with a copolymer EVAR leads to an improvement in the physical properties in relation to the penetration, softening point, thermal susceptibility and elastic recovery Cimento asfÃltico petrÃleo modificado copolÃmero de etileno acetato de vinila asphaltic cement petroleum modifield copolymers of ethylene vinyl acetate QUIMICA
36	Oxidative Copolymerization Of Vinylmonomers : Studies On The Microstructure And Reactivities Of The Copolyperoxides Jayanthi, S 04 1900 (has links) (PDF) No description available. Copolymerization Polyvinyls - Monomers Copolyperoxides Oxidative Polymerization Styrene Methyl Methacrylate Polyperoxides Poly(Vinyl Acetate Peroxide) Vinyl Monomers Organic Chemistry
37	Vliv okolních podmínek na recyklaci solárních modulů / The influence of environmental conditions of the recycling of solar modules Langer, Filip January 2021 (has links) This thesis is focused on experiments, goal of which is to separate protective glass apart from thin layer solar panel. This could lead to less expensive and more efficient recycling. We try to achieve the separation of the glass by thawing ethylene vinyl acetate layer, which serves as insulant and bonding material. Experiments are concluded in high temperature dryer and high temperature vacuum oven on samples of thin layer solar panel, which is for the purposes of experiments cut into same pieces by water jet cutting machine. The initiatory experiments in dryer and oven are to determine value of ethylene vinyl acetate thaw point in tested samples of panel. The thaw point is determined to be 340 °C. When exposed to this temperature, the ethylene vinyl acetate thaws enough for glass to be able to be extracted with minimal physical strength. The process is accompanied by fire destruction of tedlar layer and creation of exhaust gases. Following experiments in vacuum and nitrogen environment are to test their influence on thawing process. Exposing sample to temperature of 340 °C in vacuum led to no new results. Exposing sample to temperature of 340 °C in nitrogen environment prevented fire and achieved same level of thawing of ethylene vinyl acetate while creating less exhaust gases. Even though the fire was prevented, tedlar layer was still destroyed by the high temperature. Furthermore, particles of evaporated ethylene vinyl acetate condensed on surface of module in form of dust. Following experiments studied absorption of panel and influence of accessible solvents on thawing process. It was determined that panel is able to absorb approximately 2 % of acetone, 0,4 % of isopropyl alcohol and 0,11 % of distilled water in its own weight. Experiments with modules soaked in these solvents proved no new results in thawing process. By observing samples of ethylene vinyl acetate taken from module, thawed out of module after experiment in vacuum oven and dust condensed on surface of module after experiment in nitrogen environment, it was proven that the condensed dust is indeed ethylene vinyl acetate.
38	Krystalizace dvousložkových směsí polylaktidu a jejich morfologie / Crystallization of binary polylactide blends and their morphology Debnáriková, Michaela January 2021 (has links) Master thesis deals with the influence of polyvinylacetate, polycaprolactone, poly(butylene-adipate-co-terephtalate) and talc, ethylenevinylacetate, polyethylene glycol and monosodium citrate on the flow properties, mechanical properties and crystallization ability of PLA. The flow properties were studied using the melt flow index and mechanical properties were studied using a tensile test. The crystallinity was studied by differential scanning calorimetry and on a polarization optical microscope equipped with hot stage. Isothermal crystallization was performed at 95 and 105 °C for 3 h and non-isothermal crystallization was performed with a calorimeter at two cooling rates (1 and 10 °C/min). Upon the isothermal crystallization at 95 °C, the formation of denser crystalline structure was observed and the content of crystalline phase increased in most of the samples. The formation of spherulitic structure was observed at 105 °C in samples with 30 % PVAc, 30 % EVA and PEG. Reducing the cooling rate to 1 °C/min at non-isothermal crystallization had nearly no effect on the crystallization process of the most samples; the content of crystalline phase increased in the samples containing PBAT and PEG, which revealed double melting peak during subsequent heating. The crystalline fraction was the most significantly affected by the addition of PEG. All added polymers except PVAc affected the mechanical properties; PBAT, PCL, EVA and PEG increased the strain and decreased the strength and modulus of elasticity. The samples containing monosodium citrate showed unsatisfactory mechanical properties and could not be measured. The samples containing higher concentration of EVA copolymer showed the phase separation.
39	Studium účinnosti polymerní přísady EVA v závislosti na ošetřovacích podmínkách malty / Study of the Effectiveness of Copolymer EVA Depending on Storage Conditions of Mortar Hlawiczka, Jakub January 2016 (has links) The Diploma thesis is adressing the issue of polymer-modified mortars (PMM) and theirs properties in dependence on curing conditions. The reasons of using polymer additives and some selected applications of PMM are described in theoretical part of this work. Cementitious composite (mortar) hardening is especially focused on mechanism of formation co-matrix system based on cement hydration products and polymer film in dependence on curing conditions. The knowledge of interaction of cement and ethylene-vinyl acetate (EVA) copolymer is presented in the latest paragraphs of theoretical work. Following practical part presents influence of EVA to physical and mechanic properties of PMM in dependence of dosage polymer additive and exogenous factors. The study of microstructure was investigated by scanning electron microscope and high-pressure mercury porosimetry. Tests and investigations are described and evaluated.
40	Effects of Molecular Architecture on Crystallization Behavior of Pol(lactic Acid) and Ethylene-Vinyl Acetate Kalish, Jeffrey Paul 01 September 2011 (has links) The relationship between polymer chain architecture, crystallization behavior, and morphology formation was investigated. The structures formed are highly dependent on chain configuration and crystallization kinetics. Poly(lactic acid) (PLA) and Poly(ethylene-co-vinyl acetate) (EVA) random copolymers were studied. Sample characterization was performed using a variety of techniques, including spectroscopy, scattering, and calorimetry. In PLA, structural differences between α’ and α crystalline phases were analyzed using cryogenic infrared and Raman spectroscopy. Compared to the  crystal, the ’ crystal has slightly looser packing and weaker intermolecular interactions involving carbonyl and methyl functional groups. Simulations in conjunction with Raman scattering analyzed the conformational distortion of the α’ phase. The conformation of an α’ chain was determined to have tg’t-103 conformation with tg’t-31 units randomly distributed along the chain. Departure of the O-C α dihedral angle was also confirmed. The structural disorder leads to different thermal properties for α’ and α crystalline forms, which was quantified by measuring the enthalpic change at melting for both crystals ( = 57 ± 3 J/g and =9 6 ± 3 J/g). The transformation from α’ to α and the mechanism of order formation in PLA were also elucidated. The relationship between chain configuration of EVA random copolymers and crystallization behavior was established. For three different EVA samples, the distribution of methylene sequences was calculated and compared to a distribution of crystallite sizes formed. This comparison revealed that only a small fraction of the total methylene segments present actually crystallized. Cocrystallization with highly mobile oligomers was explored to enhance the crystallization of EVA copolymers. When blended, EVA28 (28 weight percentage) cocrystallizes with C36H74 n-alkane resulting in faster crystallization kinetics and a higher degree of crystallinity. The observed increase in degree of crystallinity was directly related to the chain configuration. Compositional mapping using Raman spectroscopy provided evidence for oligomer nucleation. The cocrystallization kinetics and morphology of EVA and n-alkane blends was found to depend on the chain length of oligomer. In both systems studied, crystallization kinetics determines the morphologies formed, which are undoubtedly related to the details of molecular architecture. crystallization poly(ethylene-co-vinyl acetate) poly(lactic acid) polymer structure polymorphism thermal properties Materials Science and Engineering

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