Compósitos processados via RTM em molde de aço carbono e de liga de alumínio: efeito da condutividade térmica nas propriedades mecânicas e térmicas / Processed composites via RTM in carbon steel and aluminum alloy mold: effect of thermal conductivity in mechanical and thermal properties

Majewski, Marcelo [UNESP]

06 February 2017

Submitted by MARCELO MAJEWSKI null (marcelomajewski@bol.com.br) on 2017-03-20T20:40:04Z No. of bitstreams: 1 Marcelo [v13-03-2017vFINAL].pdf: 3845690 bytes, checksum: c51d5240a6bf0ae87ee09592959712cc (MD5) / Rejected by Juliano Benedito Ferreira (julianoferreira@reitoria.unesp.br), reason: Solicitamos que realize uma nova submissão seguindo as orientações abaixo: No campo “Versão a ser disponibilizada online imediatamente” foi informado que seria disponibilizado o texto completo porém no campo “Data para a disponibilização do texto completo” foi informado que o texto completo deverá ser disponibilizado apenas 6 meses após a defesa. Caso opte pela disponibilização do texto completo apenas 6 meses após a defesa selecione no campo “Versão a ser disponibilizada online imediatamente” a opção “Texto parcial”. 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Agradecemos a compreensão. on 2017-03-22T13:50:06Z (GMT) / Submitted by MARCELO MAJEWSKI null (marcelomajewski@bol.com.br) on 2017-03-23T01:46:44Z No. of bitstreams: 1 Marcelo [v13-03-2017vFINAL].pdf: 3845690 bytes, checksum: c51d5240a6bf0ae87ee09592959712cc (MD5) / Approved for entry into archive by Luiz Galeffi (luizgaleffi@gmail.com) on 2017-03-23T16:39:23Z (GMT) No. of bitstreams: 1 majewski_m_me_guara.pdf: 3845690 bytes, checksum: c51d5240a6bf0ae87ee09592959712cc (MD5) / Made available in DSpace on 2017-03-23T16:39:23Z (GMT). No. of bitstreams: 1 majewski_m_me_guara.pdf: 3845690 bytes, checksum: c51d5240a6bf0ae87ee09592959712cc (MD5) Previous issue date: 2017-02-06 / O aumento do uso de compósitos estruturais tem levado a uma preocupação constante com a confiabilidade destes materiais. Em particular, o processo de cura das resinas na fabricação é citado como um dos problemas mais significativos no processamento de compósitos estruturais. Assim, para que essa classe de materiais possa ser economicamente viável e atender às exigências dos padrões de qualidade do setor aeronáutico, tecnologias de processamento automatizado e novas formas de matéria-prima estão sendo desenvolvidas e implantadas na fabricação. Desta forma, o objetivo da presente pesquisa foi estudar a influência das propriedades térmicas dos materiais de moldes, utilizados no processamento de compósitos via RTM, nas propriedades finais dos laminados. Foram processadas três placas de compósitos com reforço não dobrável (NCF-non-crimp fabric) biaxial [+45°/-45°] via RTM: em molde de aço 1020, laminado 1; e em liga de alumínio 5052-F, laminados 2 e 3. Para verificar a influência dos materiais dos moldes nas propriedades finais, foram analisadas a tenacidade à fratura interlaminar em modo I e investigação das superfícies de fratura pelo Microscópio Eletronico de Varredura (MEV). O comportamento térmico estudado via análise térmica dinâmico-mecânica (DMA), que avaliou as diferenças no grau de cura dos laminados 1, 2 e 3 com a análise da Tg. Nos processamentos, evidenciou-se que o molde de alumínio apresentou maior controle e estabilidade térmica, enquanto que o molde de aço apresentou maior estabilidade dimensional. Pelo modo I, observou-se maior energia de iniciação de trinca (GIc) para o laminado 1 em relação aos laminados 2 e 3. Nas imagens de fratura no MEV constatou-se a influência da fração volumétrica de fibras e a quantidade de fiber bridging. No laminado 1, observou-se mechas de fibra sobre a costura e fibras rompidas originadas do fiber bridging, que foram responsáveis pela energia adicional exigida na propagação da trinca (GI). No laminado 2 observou-se acúmulo de resina e menor quantidade de fiber bridging, consequentemente, valores intermediários de GI, já no laminado 3 notou-se a ausência de fiber bridging, o que proporcionou a propagação da trinca no domínio da matriz, apresentando o menor valor GI entre os laminados. Nos dois últimos laminados a diminuição de GIc foi atribuida ao grau de cura da resina. Na qual observou-se as transições vítreas (Tg) próximas entre os laminados 1 e 3, e para o laminado 2 a Tg foi inferior, o que demonstrou efetiva correlação entre as características térmicas dos moldes com as propriedades físicas e mecânicas finais dos laminados compósitos obtidos via RTM. / The increase use of structural composites has led to a constant concern on the reliability of these materials. In particular, curing process of resins during manufacturing are cited as one of the most significant problems in the structural composites. Therefore, in order to this class of materials can be economically viable and meet the requirements of quality in the aeronautic industry standards, automated processing technologies and new materials have been developed and implemented in manufacturing sector. Thus, this research aimed to investigate the influence of thermal properties of the mold, which was used in the processing of composites via RTM, on the final properties of the laminates. Three composite plates comprised with NCF (non-crimp fabric) reinforcement, which has biaxial [+45°/-45°] configuration, and epoxy matrix. Two molds were employed for this investigation: steel 1020, for laminate 1, and aluminum alloy 5052-F, for laminates 2 and 3, all laminates with the same fiber stacking sequence. The influence of the materials of the molds in the final properties were verified with interlaminar fracture toughness in mode I (GIc), and their images of the fractured surfaces investigated by Scanning Electron Microscope (SEM). The thermal analysis conducted with Dynamic Mechanical Thermal Analysis (DMA), which evaluated the differences in the degree of cure of laminate 1, 2 and 3 by vitreous temperature transitions (Tg). It was evidenced that the aluminium mold showed better thermal conductivity and temperature stability, while the steel mold showed higher dimensional stability. Mode I showed higher energy crack initiation (GIc) for laminate 1 than for laminates 2 and 3. In the SEM images, it was verified a change in fiber volume fraction and the amount of fiber bridging. Laminate 1 showed fiber tows on the stitch regions and ruptured fibers originated from the fiber bridging, which were responsible for the additional energy of propagation (GI). Laminate 2 showed resin accumulation and less loose fibers, and consequently, intermediate values of GI, Laminate 3 no fiber bridging occured, which showed the propagation of the crack in the matrix domain, presenting the lowest GI value between the laminates. In laminates 2 and 3, the decrease in GIc can be attributed to the degree of cure, in which correlated to the glass transitions (Tg) results. Overall, the tests demonstrated a good correlation between the thermal characteristics of the molds with the final physical and mechanical properties of the laminates obtained via RTM.

Processamento RTM

Fibra de carbono

Tenacidade à fratura

DMA

RTM processing

Carbon fiber

Fracture toughness

Compósito de resina poliuretano derivada de óleo de mamona e fibras vegetais / Composite based on polyurethane resin derived from castor oil and vegetable fibers

Rosana Vilarim da Silva

27 June 2003

O novo paradigma de se preservar o meio ambiente e de se utilizar produtos naturais vem contribuindo para um maior interesse na utilização de materiais derivados da biomassa. Neste sentido, os compósitos poliméricos com fibras vegetais surgem como uma boa alternativa no campo dos materiais para aplicações de engenharia. Os principais objetivos deste trabalho foram o processamento e a caracterização do compósito formado por uma resina poliuretano derivada do óleo de mamona e fibras de sisal e coco. O processamento foi realizado utilizando-se a técnica de moldagem por compressão. As fibras foram utilizadas em diferentes formas como fibras curtas, fibras longas, tecido e fios contínuos. A caracterização foi realizada através dos seguintes ensaios: tração, flexão, impacto, tenacidade à fratura, absorção d’água e DMTA. Foi também avaliado o efeito do tratamento com hidróxido de sódio (10%), nas fibras de sisal e coco, nas análises realizadas. O resultados mostraram que o desempenho dos compósitos com fibras de coco foi inferior aos compósitos com fibras de sisal, e mesmo ao poliuretano. Nos ensaios de tração e flexão, as fibras longas de sisal apresentaram o melhor efeito de reforçamento, seguido dos fios contínuos, fibras curtas e tecido. Nos ensaios de impacto e tenacidade à fratura, o melhor desempenho foi dos compósitos com tecido de sisal. O efeito do tratamento alcalino variou em função do tipo de ensaio e da geometria do reforço. Nos ensaios de tração e flexão, o seu efeito foi positivo para os compósitos com fibras longas e curtas, e negativo para os compósitos com tecido e fios, devido à deterioração da estrutura dos fios. Nos ensaios de tenacidade e impacto foi prejudicial, pois ao melhorar a aderência na interface, reduziu os principais mecanismos de absorção de energia, que são, a extração de fibras e o descolamento na interface. Com relação às medidas de absorção d’água, foi observado aumento no nível de absorção dos compósitos com o aumento da fração volumétrica de fibras. O máximo percentual de absorção foi de 17%, para os compósitos com fibras curtas de coco não tratadas. Este percentual diminuiu com o tratamento alcalino das fibras. Na análise térmica dinâmico mecânica, de uma forma geral, os compósitos mostraram acréscimo do módulo de armazenamento e decréscimo do amortecimento e da temperatura de transição vítrea, Tg, em relação ao poliuretano. Este comportamento foi proporcional ao aumento da fração volumétrica de fibras. / The new paradigm in preserving the environment and the use of natural products has contributed to increase the interest in the development and use of derived biomass materials. In this sense, the polymeric composites with natural fibers appear to be a good alternative for engineering applications. The main targets of this work were the processing and characterization of composites obtained by a polyurethane resin derived from castor oil and sisal and coir fibers. The compression moulding technique was used to process the composite. The fibers were employed in different forms such as: short fibers, long fibers, biaxial weave and continuos yarns. Tension, bend, impact, fracture toughness, water absorption and DMTA tests were used to characterize the composites. The sodium hidroxide (10%) treatment effect on the sisal and coir fibers was also evaluated. The results showed, in general, that the coir fibers composites performance were inferior to the sisal fibers composites, and even to the polyurethane matrix. Under tension and bending conditions, the long sisal fibers presented the best reinforcement effect, followed by the continuous yarns, short fibers, and the biaxial weave. Under impact and fracture toughness tests, the best performance was enhanced by sisal weave composites. The alkaline treatment effect varied in accordance with test type and reinforcement geometry. In tension and bending tests, its effect was positive for composites with short and long fibers and negative for composites with weave and yarns. This late was due to deterioration of the yarn structure. In the impact and toughness tests, the alkaline treatment effect was harmful, because when adherence is improved at the interface, the main energy absorption mechanisms are reduced, that mean, the fibers are pulled out and interface is debonded. Water absorption measurements showed an increase in the absorption level for the composites with higher volumetric fraction of fibers. The maximum water absorption was 17% for composites with non-treated coir short fibers. This percentage decreased for composites with treated fibers. In the dynamic mechanical thermal analysis (DMTA) the composites showed an increased storage modulus and a decreased glass transition temperature, Tg, when compared to polyurethane matrix. This behaviour was proportional to the increase of the fibers volumetric fraction.

compósito

fibras vegetais

óleo de mamona

poliuretano

tenacidade à fratura

castor oil

composite

fracture toughness

polyurethane

vegetable fibers

Avaliação da tenacidade de juntas soldadas por fricção com pino consumível em aço para amarras

Buzzatti, Diogo Trento

January 2017

Nas últimas décadas a soldagem em estado sólido vem demonstrando ser uma ótima alternativa frente aos métodos convencionais de união mais utilizados na indústria, dos quais a grande maioria consiste na soldagem por fusão dos materiais. O presente trabalho consiste na utilização do processo denominado como soldagem por fricção com pino consumível (Friction Hydro Pillar Processing – FHPP). Este trabalho visou avaliar a aplicação do processo FHPP em um aço utilizado para a fabricação de componentes de amarras de uso offshore, para esses aços o surgimento de defeitos durante operação ou fabricação trazem elevados custos operacionais, o reparo por soldagem a arco é não recomendado por normas técnicas devido às propriedades destes materiais e as condições de operação dos componentes produzidos com os mesmos. Esta avaliação se deu através da análise dos melhores parâmetros de processo (força axial, velocidade de rotação, consumo do pino e geometria de pinos e furos usinados) visando juntas soldadas livres de defeitos, avaliadas através de análises macrográficas, análises micrográficas e perfis de microdureza que por sua vez foram realizados visando a melhor caracterização das regiões que compõem a junta soldada Por fim, para a avaliação da tenacidade das juntas soldadas, ensaios de impacto Charpy e tenacidade à fratura (CTOD), seguidos de análises fractográficas em lupa e MEV (microscópio eletrônico de varredura), foram realizados com base em recomendações normativas visando uma avaliação precisa da tenacidade da região de união dos materiais soldados. As juntas soldadas apresentaram valores de CTOD de aproximadamente 40% dos valores obtidos em corpos de prova extraídos do material base. O desempenho das juntas soldadas nos ensaios de tenacidade foi claramente prejudicado pela presença de inclusões, observadas ainda no material base, que acabaram por concentrar-se nas interfaces de união das soldas devido às características do processo FHPP. / In the last few years the solid state welding has been a great alternative compared to the most common processes used in industry, which usually consists in fusion of the employed materials. The present study wants to evaluate the application of Friction Hydro-Pillar Processing (FHPP). This work aims to analyze the application of FHPP in steel used to manufacturing offshore mooring components where the incidence of defects during the operation and manufacturing result in elevated operational costs. In addition the repair of these components is not recommended by technical stand arts duo to properties of materials and operational conditions of components. The analyses was carried out by the optimization of process parameters (axial force, rotational speed, rod burn off, geometry of rod and machined hole) aiming, in the first step, free defects and sufficient heat input welded joints through analyses of macrographs. A subsequently detailed analysis of micrographs and micro hardness profile was made aiming a better characterization of all welding regions. Finally, Charpy impact tests and Crack Tip Opening Displacement (CTOD) tests were carried out, to toughness evaluation of welding joints Followed by fractography in scanning electron microscopy (SEM) was made based in recommended technical standards aiming more accurate about the toughness in bonding line regions of welded joints. The welded joints presented a CTOD tests result that where about 40% of the values obtained for the base material. The specimen performance in toughness tests was clearly adversely affected by the presence of inclusions in the bonding lines. Observed in material base during the first analyses, these inclusions have been found in large quantity on bonding lines of welds because a characteristic of FHPP to concentrate it in this region.

Soldagem por fricção

Resistência à fratura

Juntas soldadas

Friction welding

Mooring steel

Fracture toughness

FHPP

[en] EXPERIMENTAL STUDY OF FRACTURE TOUGHNESS OF GNEISS ROCKS IN DIFFERENT WEATHERING CLASSES / [pt] ESTUDO EXPERIMENTAL DA TENACIDADE DE ROCHAS GNÁISSICAS PARA DIFERENTES GRAUS DE ALTERAÇÃO

BRUNO PINHEIRO PIRES

29 April 2019

[pt] O estudo da mecânica da fratura aplicada às rochas vem se desenvolvendo desde os anos 60. Seu principal parâmetro, a tenacidade à fratura, quantifica a capacidade que a rocha possui para absorver energia até atingir a ruptura. Seu conhecimento é muito importante em diversas áreas da engenharia de rochas, como análise de estabilidade de taludes rochosos, processos de desmonte de rochas, escavações na mineração, fraturamento hidráulico, mecânica de terremotos, dentre outros. O presente estudo apresenta e analisa a influência do grau de alteração na tenacidade à fratura, no modo I de propagação, através de ensaio CCNDB (corpo de prova em forma de disco brasileiro com entalhe em chevron), de rochas gnáissicas da cidade do Rio de Janeiro. Amostras de diferentes graus de alteração foram caracterizadas quanto às suas propriedades mineralógicas, físicas (porosidade e peso específico) e mecânicas (resistência à compressão puntiforme, resistência à compressão uniaxial e resistência à tração). Nos resultados obtidos, são discutidas e realizadas correlações da tenacidade com as propriedades analisadas. Foi possível verificar que o grau de alteração é diretamente proporcional à porosidade e inversamente proporcional às resistências (compressão uniaxial e tração). Sendo assim, a rocha alterada apresenta maior porosidade e menor resistência, quando comparada com rochas menos alteradas (sãs e medianamente alteradas). A tenacidade à fratura para rochas medianamente alteradas é 45,9 por cento menor do que para rochas sãs, e 86,7 por cento menor para rochas alteradas. Assim sendo, o grau de alteração das rochas influencia, de maneira significativa, todas as propriedades analisadas. / [en] The study of fracture mechanics applied to rocks has been developed since 1960. The main parameter, fracture toughness, quantifies the rock ability to absorb energy until it ruptures. This knowledge is very important in several areas of rock engineering, such as stability analysis of rocky slopes, rock clearing processes, mining excavations, hydraulic fracturing, earthquake mechanic, among others. The study presents and analyzes the influence of the weathering class in the mode I fracture toughness of gneiss rocks in the city of Rio de Janeiro, using Cracked Chevron Noched Brazilian Disc (CCNDB). Samples of different classes were characterized for their mineralogical, physical (porosity and dry specific weight) and mechanical properties (point load strength, uniaxial compressive strength and tensile strength). The obtained results allowed correlations to be made between toughness and the other analyzed properties. By doing this, it was possible to verify that the weathering class of a rock is directly proportional to the porosity and inversely proportional to the strengths (uniaxial compressive and tensile). Thus, the highly weathered rock presents higher porosity and lower strength when compared to less weathered rocks (sound and moderated). The fracture toughness for moderately weathered rocks is 45,9 percent lower than sound rocks, and 86,7 percent smaller for highly weathered rocks. Therefore, the class of weathering rocks influences all the analyzed properties in a significant way.

[pt] TENACIDADE A FRATURA

[en] FRACTURE TOUGHNESS

[pt] GRAU DE ALTERACAO

[en] WEATHERING CLASS

[pt] GNAISSE

[en] GNEISS

Mechanical Properties of Silicon Carbide (SiC) Thin Films

Deva Reddy, Jayadeep

08 November 2007

There is a technological need for hard thin films with high elastic modulus. Silicon Carbide (SiC) fulfills such requirements with a variety of applications in high temperature and MEMS devices. A detailed study of SiC thin films mechanical properties was performed by means of nanoindentation. The report is on the comparative studies of the mechanical properties of epitaxially grown cubic (3C) single crystalline and polycrystalline SiC thin films on Si substrates. The thickness of both the Single and polycrystalline SiC samples were around 1-2 µm. Under indentation loads below 500 µ-Newton both films exhibit Elastic contact without plastic deformation. Based on the nanoindentation results polycrystalline SiC thin films have an elastic modulus and hardness of 422 plus or minus 16 GPa and 32.69 plus or minus 3.218 GPa respectively, while single crystalline SiC films elastic modulus and hardness of 410 plus or minus 3.18 Gpa and 30 plus or minus 2.8 Gpa respectively. Fracture toughness experiments were also carried out using the nanoindentation technique and values were measured to be 1.48 plus or minus 0.6 GPa for polycrystalline SiC and 1.58 plus or minus 0.5 GPa for single crystal SiC, respectively. These results show that both polycrystalline SiC thin films and single crystal SiC more or less have similar properties. Hence both single crystal and polycrystalline SiC thin films have the capability of becoming strong contenders for MEMS applications, as well as hard and protective coatings for cutting tools and coatings for MEMS devices.

Nanoindentation

Hardness

Elastic modulus

Fracture toughness

Hertzian contact theory

American Studies

Arts and Humanities

Fracture toughness determination and micromechanics of rock under Mode I and Mode II loading

Backers, Tobias

January 2004

This thesis work describes a new experimental method for the determination of Mode II (shear) fracture toughness, KIIC of rock and compares the outcome to results from Mode I (tensile) fracture toughness, KIC, testing using the International Society of Rock Mechanics Chevron-Bend method.<br><br>Critical Mode I fracture growth at ambient conditions was studied by carrying out a series of experiments on a sandstone at different loading rates. The mechanical and microstructural data show that time- and loading rate dependent crack growth occurs in the test material at constant energy requirement.<br><br>The newly developed set-up for determination of the Mode II fracture toughness is called the Punch-Through Shear test. Notches were drilled to the end surfaces of core samples. An axial load punches down the central cylinder introducing a shear load in the remaining rock bridge. To the mantle of the cores a confining pressure may be applied. The application of confining pressure favours the growth of Mode II fractures as large pressures suppress the growth of tensile cracks.<br><br>Variation of geometrical parameters leads to an optimisation of the PTS- geometry. Increase of normal load on the shear zone increases KIIC bi-linear. High slope is observed at low confining pressures; at pressures above 30 MPa low slope increase is evident. The maximum confining pressure applied is 70 MPa. The evolution of fracturing and its change with confining pressure is described.<br><br>The existence of Mode II fracture in rock is a matter of debate in the literature. Comparison of the results from Mode I and Mode II testing, mainly regarding the resulting fracture pattern, and correlation analysis of KIC and KIIC to physico-mechanical parameters emphasised the differences between the response of rock to Mode I and Mode II loading. On the microscale, neither the fractures resulting from Mode I the Mode II loading are pure mode fractures. On macroscopic scale, Mode I and Mode II do exist. / Diese Arbeit beschreibt eine neue experimentelle Methode zur Bestimmung der Modus II (Schub) Bruchzähigkeit, KIIC, von Gestein und vergleicht die Ergebnisse mit Resultaten aus Versuchen zur Bestimmung der Modus I (Zug) Bruchzähigkeit, KIC.<br><br>An einer Serie von Versuchen mit verschiedenen Belastungsraten wurde das kritische Modus I Rißwachstum eines Sandsteines untersucht. Die mechanischen Daten zeigen, daß zeit- und belastungsratenabhängiges Rißwachstum in dem Material bei konstantem Energieverbrauch stattfindet. <br><br>Der neu entwickelte Versuchsaufbau zur Ermittlung der Modus II Bruchzähigkeit wurde Punch- Through Shear Test genannt. Die Proben werden aus Bohrkernen hergestellt in deren Endflächen Nuten eingebracht werden. Eine Last auf den Innenzylinder induziert eine Schubspannung. Auf die Mantelfläche der Proben kann ein Umlagerungsdruck aufgebracht werden. Da durch Normalspannungen das Modus I Rißwachstum unterdrückt wird, wird das Modus II Rißwachstum gefördert.<br><br>Die PTS- Probengeometrie wurde bezüglich Nutentiefe, -durchmessers, -breite und des Probendurchmessers optimiert. KIIC steigt bi-linear mit Zunahme des Umlagerungsdruckes an. Ein starker Anstieg ist bis zu Umlagerungsdrücken von etwa 30 MPa zu beobachten, oberhalb ist die Steigung geringer. Bisher wurden Umlagerungsdrücke bis maximal 70 MPa aufgebracht. Die Entwicklung der entstehenden Risse und deren Variation mit Umlagerungsdruck wird beschrieben.<br><br>Ob die Entstehung eines Modus II Risses in Gestein möglich ist, wurde vielfach in der Literatur diskutiert. Der Vergleich der Ergebnisse der Modus I und II Experimente, insbesondere bezüglich der Rißmuster und der Korrelationsanalysen von KIC und KIIC zu physiko-mechanischen Parametern, zeigt die Unterschiede der Reaktion auf Modus I und Modus II Belastung auf. Mikroskopisch gesehen wachsen die Risse weder unter Modus I noch unter Modus II Belastung in einem reinen Modus. Allerdings existieren Modus I und Modus II Risse auf der makroskopischen Betrachtungsebene.

-

Earth sciences

Fracture toughness properties of duplex stainless steels

Sieurin, Henrik

January 2006

Good toughness properties in base and weld material enable the use of duplex stainless steels (DSS) in critical applications. DSS offer high strength compared to common austenitic stainless steels. The high strength can be utilized to reduce the wall thickness and accordingly accomplish reduction of cost, welding time and transportation weight, contributing to ecological and energy savings. Although DSS have been used successfully in many applications the last decades, the full utilisation in pressure vessels has been restricted due to conservative design rules. The consequences of failure in a pressure vessel are often very severe and it is accordingly important to verify a high ductility and fracture toughness. In this study fracture toughness data has been generated that has been used to analyse the brittle failure model in the European pressure vessel code EN 13445. The evaluation of the results has been made successfully by the master curve analysis, previously applied to ferritic steels. The master curve analysis includes calculation of a reference temperature, which can be correlated to an impact toughness transition temperature. A correlation between fracture and impact toughness results is necessary for a practically applicable design code. The heat distribution and austenite reformation have been modelled to verify satisfactory toughness properties in the heat affected zone. A similar model was used to evaluate the nucleation and diffusional growth of sigma phase during isothermal heat treatment or continuous cooling. For future stainless steel development, the availability of satisfactory correlations between composition, microstructure and mechanical properties are essential to optimize alloy design. Stainless steel data has been analysed to find approximate relations between mechanical properties and the chemical composition, grain size, ferrite content, product thickness and solution hardening size misfit parameter. The solution hardening effect was successfully predicted by the Labusch-Nabarro relation and multiple regression analyses were used to evaluate hardening equations for stainless steel. / QC 20100920

duplex stainless steel

fracture toughness

austenite reformation

sigma phase

material optimisation

Materials science

Teknisk materialvetenskap

Experimental investigation of the interfacial fracture toughness in organic photovoltaics

Kim, Yongjin

01 April 2013

The development of organic photovoltaics (OPVs) has attracted a lot of attention due to their potential to create a low cost flexible solar cell platform. In general, an OPV is comprised of a number of layers of thin films that include the electrodes, active layers and barrier films. Thus, with all of the interfaces within OPV devices, the potential for failure exists in numerous locations if adhesion at the interface between layers is inherently low or if a loss of adhesion due to device aging is encountered. To date, few studies have focused on the basic properties of adhesion in organic photovoltaics and its implications on device reliability. In this dissertation, we investigated the adhesion between interfaces for a model multilayer barrier film (SiNx/PMMA) used to encapsulate OPVs. The barrier films were manufactured using plasma enhanced chemical vapor deposition (PECVD) and the interfacial fracture toughness (Gc, J/m2) between the SiNx and PMMA were quantified. The fundamentals of the adhesion at these interfaces and methods to increase the adhesion were investigated. In addition, we investigated the adhesive/cohesive behavior of inverted OPVs with different electrode materials and interface treatments. Inverted OPVs were fabricated incorporating different interface modification techniques to understand their impact on adhesion determined through the interfacial fracture toughness (Gc, J/m2). Overall, the goal of this study is to quantify the adhesion at typical interfaces used in inverted OPVs and barrier films, to understand methods that influence the adhesion, and to determine methods to improve the adhesion for the long term mechanical reliability of OPV devices.

Photovoltaics

Adhesion

Interfacial fracture toughness

Organic solar cells

Photovoltaic power generation

Organic semiconductors

Photovoltaic cells

Adhesion

Mechanical Properties of Sodium and Potassium Activated Metakaolin-Based Geopolymers

Kim, Hyunsoo

2010 August 1900

Geopolymers (GPs) are a new class of inorganic polymers that have been considered as good candidate materials for many applications, including fire resistant and refractory panels, adhesives, and coatings, waste encapsulation material, etc. The aim of this study is to establish relationship between structural and mechanical properties of geopolymers with different chemical compositions. The metakaolin-based geopolymers were prepared by mechanically mixing metakaolin and alkaline silicate aqueous solutions to obtain samples with SiO2/Al2O3 molar ratio that ranges from 2.5 to 5, and Na/Al or K/Al atomic ratios equal to 1. Geopolymer samples were cured in a laboratory oven at 80°C and ambient pressure for different times in the sealed containers. Structural characterization of the samples with different chemical compositions was carried out using X-Ray Diffraction (XRD), Fourier Transform Infrared (FTIR) spectroscopy, Nuclear Magnetic-Resonance (NMR) spectroscopy and Scanning Electron Microscopy (SEM) with Energy Dispersive Spectroscopy (EDS). The mechanical characterization included Micro-indentation, Vickers indentation and fracture toughness measurement, as well as compressive testing. It was found that structure and mechanical properties of GPs depend on their chemical composition. The Na-GPs with ratio 3 have a highest compressive strength and Young‘s modulus of 39 MPa and 7.9 GPa, respectively. The results of mechanical testing are discussed in more detail in this thesis and linked to structural properties of processed geopolymers.

Geopolymer

metakaolin

mechanical properties

compressive strength

Young's modulus

hardness

fracture toughness

NMR

FTIR

XRD

Effects Of Specimen Height And Loading Span On The Fracture Toughness Of Disc Type Rock Specimens Under Three Point Bending

Tez, Burkay Yasar

01 May 2008

A relatively new fracture toughness testing method called Straight Notched Disc Bending (SNDB) was used before for fracture testing of Ankara Andesite and Afyon Marble cores. In this work to investigate the applicability of the new method to other rock types. With a preliminary notch of 10 mm, straight notched disc type specimens with a diameter of 75 mm were loaded by three-point bending loads. Investigation of effect of specimen height on the stress intensity factor and fracture toughness was carried out. Specimen heights (B) between 18 &ndash / 67 mm were tried for andesite and marble cylindrical specimens. Loading span, that is span/radius (S/R) ratio was changed between 0.6 - 0.9 for andesite specimens. Stress intensity factor for specimens was computed with ABAQUS program. Stress intensity factor was found to increase with increasing specimen diameter for a fixed span/radius ratio. Stress intensity factor decreased with increasing specimen height. Changing span was found to have no significant effect on fracture toughness of andesite. Fracture toughness was significantly lower for specimens with smaller height. The suggested testing height interval for this type of specimens was between height/diameter ratios of 0.49 &ndash / 0.64. Results were compared to the results obtained by a well-known specimen geometry named semi-circular bend specimens (SCB) under three-point bending. SCB tests produced lower values for fracture toughness for both rock types. Fracture toughness was 0.99 MPa&amp / #8730 / m for Ankara Andesite and 0.70 MPa&amp / #8730 / m for Afyon Marble.

QE General 1-350.62