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Efeito da radiação ionizante nos revestimentos de cateteres de poliuretano com nanopartículas de prata / Effect of ionizing radiation in polyurethane catheters coatings with silver nanoparticlesHEILMAN, SONIA 03 February 2016 (has links)
Submitted by Claudinei Pracidelli (cpracide@ipen.br) on 2016-02-03T12:13:54Z
No. of bitstreams: 0 / Made available in DSpace on 2016-02-03T12:13:54Z (GMT). No. of bitstreams: 0 / O presente trabalho teve a finalidade de estudar a utilização da radiação ionizante para revestimento de nanopartículas de prata em Cateteres Venosos Centrais de Poliuretano, proporcionando redução de infecções associadas à contaminação de cateteres introduzidos na corrente sanguínea. A espectroscopia de absorção no infravermelho por transformada de Fourier (FTIR) possibilitou a identificação de grupos funcionais na estrutura das macromoléculas, como o poli(eteruretano). Um estudo do comportamento térmico dos cateteres de poliuretano, antes e após a radiação ionizante, foi realizado com a finalidade de caracterização do material polimérico desses cateteres. A DSC e a TG, foram empregadas na observação das alterações das propriedades do material antes e depois da degradação. A curva DSC permitiu a caracterização das propriedades térmicas, como Tm e Tg dos copolímeros, assim como, evidenciar os principais eventos térmicos. As nanopartículas de prata possuem propriedades físicas, químicas e biológicas quando comparadas ao metal em escala macroscópica, e têm sido utilizadas na área médica, em razão de sua atividade antimicrobiana excelente. As nanopartículas de dióxido de titânio, obtidas pelo método sol-gel, foram utilizadas como revestimento dos cateteres para posterior impregnação de nanopartículas de prata por radiação ionizante na dose de 25 kGy. A espectrometria Raman foi utilizada na identificação do polimorfo de óxido de titânio, rutilo. Em ensaios com (ICP OES) foram avaliadas as quantidades de titânio e prata nos cateteres revestidos com óxido de titânio e de prata. A avaliação comparativa realizada entre os cateteres antes e após a irradiação, por FTIR, Raman e DSC, possibilitou a utilização da radiação ionizante como agente de esterilização e impregnação de nanopartículas de prata. / Tese (Doutorado em Tecnologia Nuclear) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP
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Lignopoliuretanos: preparação, caracterização e aplicação em compósitos de sisal / Lignopolyurethanes: preparation, characterization and application in sisal compositesFernando de Oliveira 31 October 2014 (has links)
A valorização racional da lignina e seus derivados é um dos maiores desafios ligado às biorrefinarias em que estas macromoléculas são geradas como subprodutos. Os lignossulfonatos, obtidos através do processo de polpação sulfito da madeira, são produzidos em larga escala e pouco utilizados como reagentes na preparação de compostos macromoleculares. A presença de grupos OH em sua estrutura permite o seu uso como macromonômero na obtenção de poliuretanos (PUs). O presente estudo teve como meta a obtenção de lignopoliuretanos e de compósitos baseados principalmente em matérias primas obtidas a partir de fontes renováveis. O óleo de mamona (OM) e lignossulfonato de sódio (NaLS), ambos oriundos de matérias primas renováveis, foram utilizados, em composições variadas, como substitutos de polióis convencionais, juntamente com difenilmetano diisocianato (MDI), na reação de obtenção de PUs. Inicialmente, PUs foram preparados a partir de NaLS e outros polióis, como dietilenoglicol (DEG), polietilenoglicol (PEG) e OM, assim como a partir destes reagentes, exceto NaLS (amostras controles). Visando aumentar a reatividade das hidroxilas do NaLS frente aos grupos isocianatos na síntese dos lignopoliuretanos, o NaLS foi oxipropilado (reação com óxido de propileno, gerando LS-Oxi) e hidroxialquilado (reações com glutaraldeído e formaldeído, gerando NaLS-Glu e NaLS-For, respectivamente). O uso de aldeídos na modificação do NaLS, até onde se tenha conhecimento, foi uma abordagem inédita no que se refere à síntese de lignopoliuretanos. Os produtos, (LS-Oxi, NaLS-Glu, NaLS-Glu) foram caracterizados por espectroscopia na região do infravermelho (IV) e, associados ou não com OM, foram usados na preparação de lignopoliuretanos (também caracterizados por IV). Fibras lignocelulósicas extraídas de sisal (Agave sisalana), cujo maior produtor mundial é o Brasil, foram utilizadas como reforço dos lignopoliuretanos preparados. Os compósitos lignopoliuretânicos, bem como os lignopoliuretanos não reforçados, foram caracterizados por análise termogravimétrica (TG), resistência ao impacto, resistência à flexão, microscopia eletrônica de varredura (MEV) e análise térmica dinâmico-mecânica (DMA). Os resultados mostraram que as fibras de sisal aumentaram consideravelmente a resistência ao impacto de todos os lignopoliuretanos. Entre os compósitos baseados em NaLS não modificado (Grupo 1), o DEG/NaLS/MDI/Sisal foi o que apresentou melhor resistência ao impacto (472 J m-1) e melhor resistência à flexão (47 MPa). Quando o NaLS oxipropilado foi utilizado (Grupo 2), o compósito LS-Oxi/MDI/Sisal apresentou resistência ao impacto de 459 J m-1 e resistência à flexão de 43 MPa, enquanto que o compósito NaLS-Glu/MDI/Sisal, preparado à partir do NaLS hidroxialquilado (Grupo 3), apresentou resistência ao impacto de 945 J m-1 e resistência à flexão de 23 MPa. As imagens de MEV da superfície de fratura pós-ensaio de impacto revelaram uma forte adesão na interface fibra/matriz, como consequência da presença de ligações hidrogênio entre os grupos uretanos da matriz e os grupos hidroxila das fibras, além das interações entre os domínios hidrofóbicos de ambos, fibra e matriz. Materiais com grau de entrecruzamento diversificados, com características entre elastomérica a termorrígidos, foram obtidos a partir do uso do NaLS e do OM, o que faz com que eles se tornem atrativos para diferentes aplicações, como em partes automotivas e painéis de uso arquitetônico. Neste sentido, e atendendo às expectativas atuais, materiais com excelentes propriedades e com elevada proporção de matérias-primas obtidas de fontes renováveis foram desenvolvidos. / The rational valuing of lignin and its derivatives is one of the major challenges in the biorefinery context where these macromolecules are generated as byproducts. Lignosulfonates obtained through the wood sulfite pulping process are produced on a large scale. However, they are rarely used as reagents in the preparation of macromolecular compounds. The presence of OH groups in their structure allows their use as a macromonomer to obtain polyurethanes (PU). This study aimed at obtaining lignopolyurethanes and composites based mainly on raw materials obtained from renewable sources. Castor oil (CO) and sodium lignosulfonate (NaLS), both derived from renewable raw materials, were used in different compositions as replacements for conventional polyols along with diphenylmethane diisocyanate (MDI) in the PU synthesis. Initially, polyurethanes were prepared from NaLS and other polyols such as diethylene glycol (DEG), polyethylene glycol (PEG), and OM, as well as by using these reagents, except for NaLS (control samples). In order to increase the reactivity of the OH groups of NaLS against isocyanates in the lignopolyurethanes synthesis, NaLS was oxypropylated (reaction with propylene oxide, generating LS-Oxy) and hydroxyalkylated (reaction with formaldehyde and glutaraldehyde, generating NaLS-Glu-For NaLS, respectively). The use of aldehydes in the NaLS modification, as far as we know, is a novel approach with regard to the lignopolyurethane synthesis. The products (LS-Oxy, NaLS-Glu, and NaLS-For) were characterized by infrared spectroscopy (IR) and associated or not with CO were also used in lignopolyurethanes preparation (also characterized by IR). Lignocellulosic fibers extracted from sisal (Agave sisalana), which has Brazil as its largest producer in the world, were used as reinforcement for the prepared lignopolyurethanes. Lignopolyurethanic composites and the non-reinforced lignopolyurethanes were characterized by thermogravimetric analysis (TG), impact test, flexural strength, scanning electron microscopy (SEM) and dynamic mechanical analysis (DMA). Results showed that sisal fibers substantially increased the impact strength of all lignopolyurethanes. Among the composites based on unmodified NaLS (Group 1), DEG/NaLS/MDI/Sisal showed the best impact strength (472 J m-1) and the best flexural strength (47 MPa). When the oxypropylated NaLS was used (Group 2), the composite <br /> LS-Oxy/MDI/Sisal showed impact strength of 459 J m-1 and flexural strength of 43 MPa, while the composite NaLS-Glu/MDI/Sisal prepared from the hydroxyalkylated NaLS (Group 3) showed impact strength of 945 J m-1 and flexural strength of 23 MPa. The SEM images of the fracture surface after the impact test revealed a strong adhesion in the fiber/matrix interface as a consequence of the presence of hydrogen bonds between the urethane groups of the matrix and the hydroxyl groups of the fibers, in addition to the interactions between the hydrophobic domains of both fiber and matrix. Materials with different degrees of crosslinking and characteristics from elastomeric to thermoset were obtained from the use of NaLS and CO, which makes them attractive for different applications such as automotive parts and panels for architectural use. In general, materials with excellent properties and prepared with a high proportion of renewable raw materials were developed, thus meeting the current expectations concerning biobased materials.
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Increasing Effective Thermal Resistance of Building Envelope's Insulation Using Polyurethane Foam Incorporated with Phase Change MaterialHoul, Yassine 05 1900 (has links)
Incorporating insulation material with phase change materials (PCMs) could help enhance the insulation capability for further building energy savings by reducing the HVAC loadings. During the phase change process between the solid and liquid states, heat is being absorbed or released by PCMs depending on the surrounding temperature. This research explores the benefits of a polyurethane (PU)-PCM composite insulation material through infiltrating paraffin wax as PCM into PU open cell foam. The new PU-PCM composite provides extra shielding from the exterior hot temperatures for buildings. Through this study, it was demonstrated that PU-PCM composite insulation could potentially help building energy savings through reducing the loads on the HVAC systems based on the building energy modeling using EnergyPlus. The Zero Energy Lab (ZØE) at the University of North Texas was modeled and studied in the EnergyPlus. It is a detached building with all wall facades exposed to the ambient. It was determined that the new PU-PCM insulation material could provide 14% total energy saving per year and reduce the electricity use due to cooling only by around 30%.
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RATIONAL DESIGN AND SYNTHESIS OF FUNCTIONAL POLYMERS FOR ANTIMICROBIAL, ANTI-FOULING AND ANTI-ADHESIVE BIOMATERIAL APPLICATIONSNikam, Shantanu P. 05 May 2021 (has links)
No description available.
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Hyperbranched polyesters for polyurethane coatings: their preparation, structure and crosslinking with polyisocyanatesPavlova, Ewa 18 October 2006 (has links)
In this work, hyperbranched aromatic polyesters-polyphenols based on 4,4-bis(4’ hydroxy¬phenyl)pentanoic acid (BHPPA) were prepared and, according to the authors knowledge, for the first time tested as precursors for polyurethane bulk resins and coatings. Comparison of poly-BHPPA with competing products The materials prepared in this work show better properties than their aliphatic polyester-polyol analoga based on 2,2-bis-(hydroxymethyl)propanoic acid (BHMPA). Especially, the solubility of poly-BHPPA in organic solvents is better and poly-BHPPAs also do not tend to microphase separation during their reaction with isocyanates, in contrast to poly-BHMPAs. The poly-BHPPA and the polyurethane networks made from them display higher Tg values than analogous poly- BHMPA compounds. Because of the high Tg of the reacting and final systems, curing must occur at elevated temperatures (90°C) in order to avoid undercure. The lower reactivity of phenolic OH groups prevents the reaction from being too fast at that temperature. A drawback of the polyurethanes based on the aromatic polyesters-polyols prepared is the lower thermal stability of their urethane bonds, if compared to aliphatic urethanes. An interesting possibility for future investigations would be the modification of the BHPPA monomer in order to change the OH functionality from phenolic to aliphatic OH, e.g. by replacement of the phenolic OH by hydroxymethyl or hydroxyethyl groups (requires a strong modification of the monomer synthesis) or simpler by reacting the phenolic OH of BHPPA with a suitable reagent like oxirane, which would lead to groups like O-CH2-CH2-OH in the place of the phenolic OH. Such a BHPPA modification should in turn yield modified “poly-BHPPA” polycondensates, which would combine the advantages of poly-BHPPA with those of aliphatic OH precursors of polyurethanes. Poly-BHPPA synthesis Hyperbranched polymers of the 4,4-bis-(4’-hydroxyphenyl)pentanoic acid (BHPPA) were synthesized successfully by the catalyzed (by dibutyltin diacetate) polycondensation of BHPPA. The products obtained were oligomers with number average molecular weight ranging from 1800 to 3400 g/mol (polymerization degree of ca. 6 to 12), displaying a first moment of functionality in the range 7 to 14. Such products were good OH precursors for the preparation of polyurethane coatings, because higher functional polymers would gel at low conversions. The analysis of the functional groups (determination of acid and hydroxyl numbers) and the 1H-NMR and the 13C-NMR spectroscopy were found to be good methods for the determination of molecular weights. The polydispersity of the poly-BHPPA products was in the range 3.5 to 6. Their degree of branching was found to be in the range 0.36 to 0.47. Poly-BHPPA containing aliphatic polyols as core monomers were also prepared successfully. Difunctional and trifunctional core monomers usually reached a full conversion of their OH groups, while the tetra- and hexafunctional core monomers were converted only to 89%. In all these products however, a considerable amount, usually even a majority, of the polymer molecules were core free. The poly-BHPPA products prepared displayed relatively high glass transition temperatures, in the range of 84°C to 114°C, obviously due to interactions between the phenol groups and to hydrogen bridging. The thermal stability of these products was also high, with decomposition occurring near 350°C (at a heating rate of 10°C / min) Kinetics investigations of the poly-BHPPA reactivity towards isocyanates The poly-BHPPA are polyphenols and were expectedly found to react significantly slower with isocyanates than aliphatic alcohols. The reactivity of poly BHPPA was also found to be somewhat lower than that of the monofunctional, low molar-mass 4 ethylphenol. Hexamethylene diisocyanate trimer, Desmodur N3300, was found to be more reactive than hexamethylene diisocyanate (HDI) or butyl isocyanate in all experiments, possibly due to a substitution effect. The substitution effect can be explained by a change of microenvironment caused by conversion of isocyanate group and OH group into urethane groups. The reactions of low-molecular-mass alcohols or phenols with low molecular weight isocyanates followed well the 2nd order kinetics, while the reactions of poly-BHPPA with isocyanates show deviations from ideal 2nd order kinetics at higher conversions. All the kinetics experiments were carried out under catalysis by dibutyltin dilaurate. This catalyst inhibits the undesired reaction of isocyanate groups with moisture. It was also found that the catalysis was necessary to reach reasonable curing times for poly-BHPPA based polyurethane networks. The uncatalyzed systems reacted extremely slowly. Preparation of polyurethane networks from poly-BHPPA The poly BHPPA products prepared were used successfully as OH functional precursors of polyurethane networks. The networks prepared contained only very low sol fractions. Acetone and also ethylene diglycol dimethylether (diglyme) were found to be good swelling solvents for the networks prepared, while methyl propyl ketone was a much poorer solvent and aromatic compounds like toluene or xylene practically did not swell the poly BHPPA based polyurethanes. The networks prepared contain a relatively high amount of cyclic bonds, 40 to 50% in the finally cured state, which is an expected result for systems with precursors of high functionality and with small distances between the functional groups. The temperature of glass transition (Tg) of the networks prepared (ranging from 68°C to 126°C) depends of the poly BHPPA precursor used: it increases with increasing molecular mass and with increasing core functionality. The choice of the isocyanate crosslinker also influences Tg: the networks made from HDI show higher Tg values, than networks made from the same poly BHPPA but crosslinked with Desmodur N3300 (Tri HDI). The urethane bonds in the networks prepared start to decompose near 140°C. The easier degradation of PU with aromatic urethane bonds is a disadvantage in comparison with aliphatic polyurethanes, whose decomposition starts at 200°C. The surfaces of polyurethane coatings prepared are smooth, displaying a roughness of ca. 20-25 nm, and relatively hydrophilic: the contact angle with water was found to be near 80°. The prepared networks are also relatively hard, possessing the Shore D hardness of 70.
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Steric and Anchimeric Effects on the Hydrolysis of Oligoesters and their Influence on End-Use Polyurethane CoatingsRamirez-Huerta, Mayela Cristina 15 December 2009 (has links)
No description available.
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A Study of Various Parameters Affecting Adhesion of Coatings to Metal Substrates / En studie av olika parametrar som påverkar ytbeläggningars adhesion till metallsubstratPathanatecha, Worabhorn January 2019 (has links)
The adhesion of coatings is of high importance in the coating industry and a more thorough understanding of adhesion behavior is required. In this thesis work, seven parameters affecting adhesion of silane-modified poly(urethane urea) (PUSi) coatings on pretreated steel and aluminum substrates were studied. These parameters include substrate type, dry film thickness (20-30 and 60-70 μm), solid content (40, 60, and 70 wt%), resin ratio between two different types of PUSi (PUSi-A: PUSi-B = 70:30, 50:50, and 30:70 wt ratio), crosslinking density, additive, and curing condition. The different pretreatments of substrates include solvent wiping, sandblasting, phosphating, and galvanizing. A commercial paint product (‘yellow topcoat’) was used as a reference for the study of substrates and additives. Several formulations of clearcoat, prepared from the same PUSi resins as the commercial paint product, were mainly used in every experiment. The obtained coatings were tested for their adhesion properties using cross hatch adhesion test, bending test, and humidity resistance test. The film hardness and thermo-mechanical properties were evaluated with König pendulum hardness test and Dynamic Mechanical Analysis (DMA), respectively. Surface energies of all substrates were analyzed with Contact Angle Measurement (CAM). The PUSi-A and PUSi-B resins used in the coating formulations were characterized with Differential Scanning Calorimetry (DSC), Size-Exclusion Chromatography (SEC), and Fourier Transform Infrared Spectroscopy (FT-IR). The results showed a correlation between poor adhesion properties and the relatively low surface energies of some substrates, namely cold-rolled steel (CRS), industrial ACE aluminum, and standard Q aluminum. The use of silane-functional crosslinking agent and silane adhesion promoters in the coatings has greatly enhanced adhesion. The increase in film hardness via increased crosslinking density also did not hinder the adhesion due to the presence of silane groups in the crosslinker. Additionally, increased time and temperature during curing showed positive effects. However, the variation of resin ratio, solid content, and film thickness did not offer significant adhesion improvement in this study. / Adhesionsegenskaperna hos ytbeläggningar är av stor betydelse i färg- och lackindustrin och en djupare förståelse av vidhäftning är av stor betydelse. I detta uppsatsarbete studerades sju parametrar som påverkar vidhäftning av silanmodifierad poly(uretan-urea) (PUSi)-beläggningar på stål- och aluminiumsubstrat. Dessa parametrar inkluderar substrattyp, torr filmtjocklek (20-30 och 60-70 μm), torrhalt (40, 60 och 70 viktprocent), mängdförhållandet mellan två olika typer av PUSi (PUSi-A: PUSi-B = 70:30, 50:50 och 30:70 viktprocent), tvärbindningsdensitet, tillsatsmedel och härdningsbetingelser. Förbehandlingen av substraten inkluderar lösningsmedelsavtorkning, sandblästring, fosfatering och galvanisering. En kommersiell ytbehandlingsprodukt innehållandes gula pigment (gul topplack) användes som referens. Flera formuleringar av klarlack, framställda av samma PUSi-hartser som den kommersiella produkten, användes i det experimentella arbetet. Beläggningarna testades med avseende på deras vidhäftningsegenskaper med ’cross-hatch’-test, böjningstest och fuktbeständighetstest. Filmhårdhet och termomekaniska egenskaper utvärderades med König pendelhårdhetstest respektive Dynamisk Mekanisk Analys (DMA). Ytenergier för alla substrat analyserades med kontaktvinkelmätning (CAM). PUSi-A- och PUSi-B-hartserna som användes i ytbeläggningarna karaktäriserades med Differential Scanning Calorimetry (DSC), Size-Exclusion Chromatography (SEC) och Fourier Transform Infrared Spectroscopy (FT-IR). Resultaten visade en korrelation mellan dålig vidhäftning och låga ytenergier för vissa underlag, främst kallvalsat stål (CRS), industriellt ACE-aluminium och standard Q-aluminium. Användningen av silan-funktionell tvärbindare och en silan-baserad primer förbättrade vidhäftningen avsevärt. Ökningen i filmhårdhet genom högre tvärbindningsdensitet resulterade inte i sämre vidhäftning eftersom tvärbindaren innehåller silan-grupper vilket bidrog till att upprätthålla vidhäftningen. Längre tid och högre temperatur vid härdning gav generellt bättre vidhäftning, liksom tillsats av urea. Att variera mängden bindemedel, torrhalt eller filmtjocklek gav inte någon signifikant påverkan på vidhäftning i denna studie.
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Untersuchungen zum Einfluss unterschiedlicher Bedingungen auf die Degradation von MDI-basierenden Ether- und Ester-PolyurethanenScholz, Philipp 20 December 2021 (has links)
Polyurethane (PU) bilden eine wichtige Klasse von Kunststoffen, die in vielen technischen Anwendungen zum Einsatz kommen. Damit verbunden sind hohe Ansprüche an die Stabilität und Lebensdauer derartiger Polymere. Das Verständnis wichtiger Abbauprozesse stellt somit die Voraussetzung zur Optimierung deren Einsatzes dar. In dieser Arbeit wurde die Degradation von Ether und Ester Polyurethan-Probenkörpern zuerst durch eine kombinierte Bewitterung aus photochemischer, hydrolytischer und thermischer Beanspruchung simuliert und mit verschiedenen spektroskopischen, massenspektrometrischen und chromatographischen Methoden untersucht. Durch die Wahl zum Teil neuartiger konnten individuelle Prüfkörperhergestellt werden.
Analytischer Schwerpunkt der Untersuchungen stellte dabei die Gel-Permeations-Chromatographie (GPC) dar. Mit dieser Methode war es erstmals möglich, aus den zeitlichen Änderungen von Molmassen und Löslichkeiten während der Beanspruchung Rückschlüsse auf einzelne Degradationsmechanismen wie Kettenbruch, Vernetzung und Verzweigung zu ziehen. Kombiniert wurde diese Untersuchung mit spektroskopischen und massenspektrometrischen Verfahren.
Die in dieser Arbeit präsentierten Ergebnisse zeigen, dass die Degradation von Polyurethanen nahezu ausschließlich durch Temperaturerhöhung und UV-Strahlung induziert wurde, während die Feuchtigkeit allein keinen signifikanten Einfluss hatte. Die beobachteten Effekte ließen sich überwiegend durch Kettenbrüche und Verzweigung bzw. Vernetzungen erklären, wobei sich beide Prozesse überlagerten. Die Ergebnisse lassen auch darauf schließen, das Ester PU bei identischen Degradationsbedingungen grundsätzlich stabiler sind und weniger stark abgebaut wurden, als Ether PU.
Die Ergebnisse können dazu beitragen, die kombinierte Bewitterung, die einen natürlichen Abbau simulieren soll, besser zu verstehen und den Anteil der einzelnen Umweltfaktoren auf die Gesamtalterung der Materialen realistischer einzuordnen. / Polyurethanes (PU) are an important class of polymers that are used in many technical applications. Therefore, there are high demands regarding their stability and durability Thus, an understanding of important degradation processes is required for their optimized use. In this thesis, the degradation of ether and ester polyurethane samples was initially simulated by a combined weathering by photochemical, hydrolytic and thermal exposure and investigated with different spectroscopic and mass spectrometric methods. Using innovative manufacturing techniques (e.g. 3D printing, electrospinning) for the fabrication of specimens, individual samples from nano- to centimeter scale became available. Based on the results of the combined weathering, exposure scenarios were developed, which reduced the complexity of the degradation towards the investigation of individual parameters (temperature, UV radiation, humidity).
The analytical investigations were focused on gel permeation chromatography (GPC). For the first time, time-depending degradation mechanisms such as chain scission, crosslinking and branching were derived from changes of molecular masses and solubilities during exposure. This chromatographic investigation was combined with spectroscopic and mass spectrometric methods.
The results presented in this thesis show, that degradation of polyurethanes was induced almost exclusively by temperature and UV radiation, while moisture alone had no significant influence. The observed effects could mainly be explained by chain scission and branching/crosslinking affecting each other. The results also indicate that ester PU was more stable under identical degradation conditions and degraded less than ether PU.
These results might contribute to a better understanding of the combined weathering, which is intended to simulate natural degradation, and might serve for a realistic evaluation of the contribution of single degradation parameters.
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Synthesis and Characterization of Hydrophilic-Hydrophobic Poly (Arylene Ether Sulfone) Random and Segmented Copolymers for Membrane ApplicationsNebipasagil, Ali 26 January 2015 (has links)
Poly(arylene ether sulfone)s are high-performance engineering thermoplastics that have been investigated extensively over the past several decades due to their outstanding mechanical properties, high glass transition temperatures (Tg), solvent resistance and exceptional thermal, oxidative and hydrolytic stability. Their thermal and mechanical properties are highly suited to a variety of applications including membrane applications such as reverse osmosis, ultrafiltration, and gas separation. This dissertation covers structure-property-performance relationships of poly(arylene ether sulfone) and poly(ethylene oxide)-containing random and segmented copolymers for reverse osmosis and gas separation membranes.
The second chapter of this dissertation describes synthesis of disulfonated poly(arylene ether sulfone) random copolymers with oligomeric molecular weights that contain hydrophilic and hydrophobic segments for thin film composite (TFC) reverse osmosis membranes. These copolymers were synthesized and chemically modified to obtain novel crosslinkable poly(arylene ether sulfone) oligomers with acrylamide groups on both ends. The acrylamide-terminated oligomers were crosslinked with UV radiation in the presence of a multifunctional acrylate and a UV initiator. Transparent, dense films were obtained with high gel fractions. Mechanically robust TFC membranes were prepared from either aqueous or water-methanol solutions cast onto a commercial UDEL® foam support. This was the first example that utilized a water or alcohol solvent system and UV radiation to obtain reverse osmosis TFC membranes. The membranes were characterized with regard to composition, surface properties, and water uptake. Water and salt transport properties were elucidated at the department of chemical engineering at the University of Texas at Austin.
The gas separation membranes presented in chapter three were poly(arylene ether sulfone) and poly(ethylene oxide) (PEO)-containing polyurethanes. Poly(arylene ether sulfone) copolymers with controlled molecular weights were synthesized and chemically modified to obtain poly(arylene ether sulfone) polyols with aliphatic hydroxyethyl terminal functionality. The hydroxyethyl-terminated oligomers and α-ω-hydroxy-terminated PEO were chain extended with a diisocyanate to obtain polyurethanes. Compositions with high poly(arylene ether sulfone) content relative to the hydrophilic PEO blocks were of interest due to their mechanical integrity. The membranes were characterized to analyze their compositions, thermal and mechanical properties, water uptake, and molecular weights. These membranes were also evaluated by collaborators at the University of Texas at Austin to explore single gas transport properties. The results showed that both polymer and transport properties closely related to PEO-content. The CO2/CH4 gas selectivities of our membranes were improved from 25 to 34 and the CO2/N2 gas selectivity nearly doubled from 25 to 46 by increasing PEO-content from 0 to 30 wt.% in polyurethanes.
Chapter four also focuses on polymers for gas separation membranes. Disulfonated poly(arylene ether sulfone) and poly(ethylene oxide)-containing polyurethanes were synthesized for potential applications as gas separation membranes. Disulfonated polyols containing 20 and 40 mole percent of disulfonated repeat units with controlled molecular weights were synthesized. Poly(arylene ether sulfone) polyols and α,ω-hydroxy-terminated poly(ethylene oxide) were subsequently chain extended with a diisocyanate to obtain polyurethanes. Thermal and mechanical characterization revealed that the polyurethanes had a phase-mixed complex morphology. / Ph. D.
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Photo-Curing Through Single Apertures: The Phenomenon and Its Influence On PolymerizationMacPherson, Meoghan Elizabeth January 2013 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Reduction of the polymerization shrinkage stress inherent of dimethacrylate-based resin composites has been a work in progress since the phenomenon was first described by Dr. Rafael L. Bowen in 1967. Contemporary efforts to modify the composites or the curing protocols for polymerization have proven a challenging task with controversial results. Influenced by existing mathematical models relating exposure, curing time and depth of cure of resin composites, a novel method for the reduction of polymerization shrinkage stress is proposed. By polymerizing through a single aperture mask, a dental light curing unit is transformed from a planar light source to a point light source, and a fully cured, three-dimensional “bullet” shaped curing front is predicted for the cured resin below. So long as the edges of the bullet do not touch the cavity walls or floor, the shrinkage stress of the bullet is not transferred. Follow-up with an unmasked curing unit then fully polymerizes the restoration. By reducing the volume of uncured composite in contact with the cavity walls and floor, shrinkage stress of the restoration is also reduced.
The objective of the present study was to demonstrate this curing phenomenon with a model resin composite using masks with aperture diameters of 0.5, 0.4, and 0.25 mm and curing times of 10, 20, 30, and 40 seconds. The resulting curing front was evaluated quantitatively and qualitatively. From this, mathematical models of the curing front were derived. Selected combinations of aperture mask and curing time were then investigated to evaluate the influence of this phenomenon on the degree of conversion, Knoop hardness, and polymerization shrinkage stress of the same model resin composite. Group differences were analyzed using a one-way ANOVA at 5% significance.
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