Global ETD Search

1	Charpy Impact Testing of Twinning Induced Plasticity and Transformation Induced Plasticity High Entropy Alloys Zellner, Samantha R 08 1900 (has links) High entropy alloys (HEAs) are a new class of solid solution alloys that contain multiple principal elements and possess excellent mechanical properties, from corrosion resistance to fatigue and wear resistance. Even more recently, twinning induced plasticity (TWIP) and transformation induced plasticity (TRIP) non-equiatomic high entropy alloys have been engineered, promising increased strength and ductility as compared to their equiatomic counterparts. However, impact and fracture resistance of these HEAs has not been studied as much as their other mechanical properties. In this thesis, the hardness, tensile properties, and Charpy impact energy of Al0.3CoCrFeNi, a TWIP HEA, and 50Fe-30Mn-10Co-10Cr (at.%), a TRIP HEA, was explored. First, three processing conditions, (1) as-received, (2) recrystallized, and (3) peak hardness, were chosen for each alloy and verified with Vickers microhardness measurements. Next, the tensile properties of each alloy and condition were investigated. Charpy impact specimen size was then selected based on the final plate thickness, and the machined samples were tested. Plastic zone size and change in sample thickness in the deformed region of each condition after testing was measured. Post-impact test inspection of the samples in all conditions showed that the samples were in tension near the V-notch root and in compression at the impact surface. Plastic zone size is seen to change as a function of distance from the V-notch root moving towards the impact surface in conditions that exhibited higher ductility. Overall, the TWIP alloy displayed high fracture resistance, and further microstructural optimization will likely increase the fracture resistance of these alloys. HEAs Charpy impact testing
2	none Li, Dong-Ming 16 July 2003 (has links) none charpy impact 2340duplex stainless steel
3	Understanding Low temperature Impact Toughness of 2.25Cr-1Mo steel Submerged Arc Welds Mohan, Soumya 20 May 2015 (has links) No description available. Engineering Submerged arc welds Charpy Impact Toughness Granular Bainite Precipitate Evolution Slag Metal reactions Phase Transformations
4	Caracterização mecânica e metalúrgica de um elo de corrente de amarra em aço para aplicação naval na indústria do petróleo Santos, Rafael Eugenio dos January 2017 (has links) As amarras de correntes de aço para aplicação naval utilizadas na indústria de óleo e gás são fabricadas para atender elevadas exigências operacionais. Com a prospecção de petróleo em águas profundas e ultraprofundas o conhecimento de suas propriedades torna-se relevante. Frente a essa necessidade foi realizado o estudo das propriedades mecânicas e metalúrgicas de um elo de corrente de amarra naval na indústria do petróleo proveniente de operação. Esse estudo teve como objetivo principal identificar e avaliar as propriedades mecânicas e metalúrgicas das regiões resultante do processo de soldagem por centelhamento frente ao material de base. Como objetivo secundário foi classificado o material de acordo com algumas propriedades mecânicas recomendadas pela IACS UR W22. Para isso foram realizados ensaios de tração, microdureza, tenacidade ao impacto Charpy e à fratura CTOD, com avaliações metalúrgicas no material de base e região de união por centelhamento. Como resultado foi verificado que o processo de soldagem por centelhamento produziu zonas de extensões reduzidas e com menores valores de tenacidade à fratura e ao impacto. O processo de centelhamento produziu união com espessura de 0,375 mm, com uma zona de solda revelada por ataque químico e duas zonas afetadas pelo calor caracterizadas apenas por perfil de microdureza, com 0,150 mm e 0,300 mm, respectivamente. Os menores valores de tenacidade ao impacto Charpy e à fratura CTOD foram medidos nos corpos de prova posicionados na zona afetada pelo calor. Os resultados obtidos em todos os ensaios foram comparados com as recomendações técnicas IACS UR W22, onde caracterizou o elo como grau R4. / Mooring chains of offshore systems anchors are design to be used under extreme environment operation. New fields of exploration have been operated in deep water and ultra-deep water, wherefore, require more knowledge of the mechanical and metallurgical properties. Hence a study of a studless link of offshore chain from the operating service component was carried out. The main goal of this work was to determine and evaluate the properties of the base material and the zones produced by Flash Butt Welding Process. Furthermore, the material was characterized by the IACS UR W22 standard recommendation. In this study tests of tensile test, microhardness, Charpy and CTOD toughness, mechanical and metallurgical evaluation were performed in the base material and welding zones. The results showed small welding zones with reduced impact and fracture toughness. The lowest values were seen in specimens from the heat affect zone. The weld zone thickness observed by chemical etching extend 0,375 mm and the microhardness profile indicated a Heat Affected Zone (HAZ) with 0,150 and 0,300 mm. The lowest Charpy and CTOD toughness tests were measured in the HAZ specimens. These results were compared with IACS UR W22 standard recommendation and the link chain was characterized as R4 grade. Corrente de amarra Soldagem Resistência mecânica Fracture Toughness Flash Butt Welding Heat Affect Zone Microhardness Charpy Impact CTOD
5	Caracterização mecânica e metalúrgica de um elo de corrente de amarra em aço para aplicação naval na indústria do petróleo Santos, Rafael Eugenio dos January 2017 (has links) As amarras de correntes de aço para aplicação naval utilizadas na indústria de óleo e gás são fabricadas para atender elevadas exigências operacionais. Com a prospecção de petróleo em águas profundas e ultraprofundas o conhecimento de suas propriedades torna-se relevante. Frente a essa necessidade foi realizado o estudo das propriedades mecânicas e metalúrgicas de um elo de corrente de amarra naval na indústria do petróleo proveniente de operação. Esse estudo teve como objetivo principal identificar e avaliar as propriedades mecânicas e metalúrgicas das regiões resultante do processo de soldagem por centelhamento frente ao material de base. Como objetivo secundário foi classificado o material de acordo com algumas propriedades mecânicas recomendadas pela IACS UR W22. Para isso foram realizados ensaios de tração, microdureza, tenacidade ao impacto Charpy e à fratura CTOD, com avaliações metalúrgicas no material de base e região de união por centelhamento. Como resultado foi verificado que o processo de soldagem por centelhamento produziu zonas de extensões reduzidas e com menores valores de tenacidade à fratura e ao impacto. O processo de centelhamento produziu união com espessura de 0,375 mm, com uma zona de solda revelada por ataque químico e duas zonas afetadas pelo calor caracterizadas apenas por perfil de microdureza, com 0,150 mm e 0,300 mm, respectivamente. Os menores valores de tenacidade ao impacto Charpy e à fratura CTOD foram medidos nos corpos de prova posicionados na zona afetada pelo calor. Os resultados obtidos em todos os ensaios foram comparados com as recomendações técnicas IACS UR W22, onde caracterizou o elo como grau R4. / Mooring chains of offshore systems anchors are design to be used under extreme environment operation. New fields of exploration have been operated in deep water and ultra-deep water, wherefore, require more knowledge of the mechanical and metallurgical properties. Hence a study of a studless link of offshore chain from the operating service component was carried out. The main goal of this work was to determine and evaluate the properties of the base material and the zones produced by Flash Butt Welding Process. Furthermore, the material was characterized by the IACS UR W22 standard recommendation. In this study tests of tensile test, microhardness, Charpy and CTOD toughness, mechanical and metallurgical evaluation were performed in the base material and welding zones. The results showed small welding zones with reduced impact and fracture toughness. The lowest values were seen in specimens from the heat affect zone. The weld zone thickness observed by chemical etching extend 0,375 mm and the microhardness profile indicated a Heat Affected Zone (HAZ) with 0,150 and 0,300 mm. The lowest Charpy and CTOD toughness tests were measured in the HAZ specimens. These results were compared with IACS UR W22 standard recommendation and the link chain was characterized as R4 grade. Corrente de amarra Soldagem Resistência mecânica Fracture Toughness Flash Butt Welding Heat Affect Zone Microhardness Charpy Impact CTOD
6	Caracterização mecânica e metalúrgica de um elo de corrente de amarra em aço para aplicação naval na indústria do petróleo Santos, Rafael Eugenio dos January 2017 (has links) As amarras de correntes de aço para aplicação naval utilizadas na indústria de óleo e gás são fabricadas para atender elevadas exigências operacionais. Com a prospecção de petróleo em águas profundas e ultraprofundas o conhecimento de suas propriedades torna-se relevante. Frente a essa necessidade foi realizado o estudo das propriedades mecânicas e metalúrgicas de um elo de corrente de amarra naval na indústria do petróleo proveniente de operação. Esse estudo teve como objetivo principal identificar e avaliar as propriedades mecânicas e metalúrgicas das regiões resultante do processo de soldagem por centelhamento frente ao material de base. Como objetivo secundário foi classificado o material de acordo com algumas propriedades mecânicas recomendadas pela IACS UR W22. Para isso foram realizados ensaios de tração, microdureza, tenacidade ao impacto Charpy e à fratura CTOD, com avaliações metalúrgicas no material de base e região de união por centelhamento. Como resultado foi verificado que o processo de soldagem por centelhamento produziu zonas de extensões reduzidas e com menores valores de tenacidade à fratura e ao impacto. O processo de centelhamento produziu união com espessura de 0,375 mm, com uma zona de solda revelada por ataque químico e duas zonas afetadas pelo calor caracterizadas apenas por perfil de microdureza, com 0,150 mm e 0,300 mm, respectivamente. Os menores valores de tenacidade ao impacto Charpy e à fratura CTOD foram medidos nos corpos de prova posicionados na zona afetada pelo calor. Os resultados obtidos em todos os ensaios foram comparados com as recomendações técnicas IACS UR W22, onde caracterizou o elo como grau R4. / Mooring chains of offshore systems anchors are design to be used under extreme environment operation. New fields of exploration have been operated in deep water and ultra-deep water, wherefore, require more knowledge of the mechanical and metallurgical properties. Hence a study of a studless link of offshore chain from the operating service component was carried out. The main goal of this work was to determine and evaluate the properties of the base material and the zones produced by Flash Butt Welding Process. Furthermore, the material was characterized by the IACS UR W22 standard recommendation. In this study tests of tensile test, microhardness, Charpy and CTOD toughness, mechanical and metallurgical evaluation were performed in the base material and welding zones. The results showed small welding zones with reduced impact and fracture toughness. The lowest values were seen in specimens from the heat affect zone. The weld zone thickness observed by chemical etching extend 0,375 mm and the microhardness profile indicated a Heat Affected Zone (HAZ) with 0,150 and 0,300 mm. The lowest Charpy and CTOD toughness tests were measured in the HAZ specimens. These results were compared with IACS UR W22 standard recommendation and the link chain was characterized as R4 grade. Corrente de amarra Soldagem Resistência mecânica Fracture Toughness Flash Butt Welding Heat Affect Zone Microhardness Charpy Impact CTOD
7	Hydrogen Effects on X80 Steel Mechanical Properties Measured by Tensile and Impact Testing Li, Xuan 24 March 2016 (has links) The effect of hydrogen charging current density and tensile strain rate on the mechanical properties of X80 pipeline steel were investigated by slow strain rate test (SSRT), Charpy impact test, and scanning electron microscopy (SEM) in this thesis. The results show that both the ultimate tensile strength and elongation to failure of X80 steel were deteriorated significantly after charging with hydrogen. With a strain rate of 5 x 10-5 s-1, the relative tensile strength and plasticity loss of X80 steel had no significant change within the range of assumed hydrogen partial pressures at room temperature. At room temperature, X80 steel had no apparent variation in ultimate tensile strength and elongation, except at the strain rate of 10-6 s-1. Specimens obtained the greatest relative tensile strength loss and plasticity loss when strained at 10-6 s-1 with a current density of 4.6 mA/cm2. The fracture morphology of two test groups of X80 steel exhibited significant brittle rupture when tested with dynamic hydrogen charging. The impact energy of X80 was not affected by hydrogen charging. Different current density also had no influence on the results of the impact test. Hydrogen permeation Cathodic charging Hydrogen embrittlement Slow strain rate tensile (SSRT) test Charpy impact test Materials Science and Engineering Mechanical Engineering
8	An Investigation of Friction Stir Welding Parameter Effects on Post Weld Mechanical Properties in 7075 AA Dickson, Steven B. 01 March 2015 (has links) (PDF) The effects of weld temperature, travel speed, and backing plate thermal diffusivity on themechanical properties of a weld have been studied. A face centered cubic experiment of designwas completed in which the response variables were yield strength, minimum hardness in the HAZ, and charpy impact toughness. Three models were created from the data gathered usinga stepwise regression in order to see the effects of each parameter. For the yield strength andminimum hardness it was found that only travel speed and backing plate thermal diffusivities werestatistically significant to the properties. The charpy impact toughness saw that all three parameterswere statistically significant to its value. In all three models the travel speed had the greatest affecton the material properties. friction stir weldiing 7075 aluminum parameter effects analysis yield strength minimum hardness charpy impact test Mechanical Engineering
9	Effect of welding thermal cycles on the heat affected zone microstructure and toughness of multi-pass welded pipeline steels Nuruddin, Ibrahim K. January 2012 (has links) This research is aimed at understanding the effect of thermal cycles on the metallurgical and microstructural characteristics of the heat affected zone of a multi-pass pipeline weld. Continuous Cooling Transformation (CCT) diagrams of the pipeline steel grades studied (X65, X70 and X100) were generated using a thermo mechanical simulator (Gleeble 3500) and 10 mm diameter by 100 mm length samples. The volume change during phase transformation was studied by a dilatometer, this is to understand the thermodynamics and kinetics of phase formation when subjected to such varying cooling rates. Samples were heated rapidly at a rate of 400°C/s and the cooling rates were varied between t8/5 of 5.34°C/s to 1000°C/s. The transformation lines were identified using the dilatometric data, metallographic analysis and the micro hardness of the heat treated samples. Two welding processes, submerged arc welding (SAW) and tandem Metal Inert Gas (MIG) Welding, with vastly different heat inputs were studied. An API-5L grades X65, X70 and X100 pipeline steels with a narrow groove bevel were experimented with both welding processes. The welding thermal cycles during multi-pass welding were recorded using thermocouples. The microstructural characteristics and metallurgical phase formation was studied and correlated with the fracture toughness behaviour as determined through the Crack Tip Opening Displacement (CTOD) tests on the welded specimens. It was observed that SAW process is more susceptible to generate undesirable martensite-austenite (M-A) phase which induce formation of localised brittle zones (LBZ) which can adversely affect the CTOD performance. Superimposition of the multiple thermal cycles, measured in-situ from the different welding processes on the derived CCTs, helped in understanding the mechanism of formation of localised brittle zones. Charpy impact samples were machined from the two X65 and X70 grades, for use in thermal simulation experiments using thermo mechanical simulator (Gleeble). The real thermal cycles recorded from the HAZ of the SAW were used for the thermal simulations, in terms of heating and cooling rates. This is to reproduce the microstructures of the welds HAZ in bulk on a charpy impact sample which was used for impact toughness testing, hardness and metallurgical characterisation. The three materials used were showing different response in terms of the applied thermal cycles and the corresponding toughness behaviours. The X65 (a) i.e. the seamless pipe was showing a complete loss of toughness when subjected to the single, double and triple thermal cycles, while the X65 (b), which is a TMCP material was showing excellent toughness in most cases when subjected to the same thermal cycles at different test temperatures. The X70 TMCP as well was showing a loss of toughness as compared to the X65 (b). From the continuous cooling transformation diagrams and the thermally simulated samples results it could be established that different materials subjected to similar thermal cycle can produce different metallurgical phases depending on the composition, processing route and the starting microstructure.
10	Influência do tempo de imersão em solução aquosa contendo H2S sobre a tenacidade de tubo API 5L X65 sour avaliada a partir de ensaio Charpy / Influence of immersion time in water solution containing H2S opn the toughness of pipe API 5L X65 Sour evaluated from Charpy test. Brandão, Bryane Prando 13 November 2015 (has links) Com o decorrer dos anos o consumo de petróleo e seus derivados aumentou significativamente e com isso houve a necessidade de se investir em pesquisas para descobertas de novas jazidas de petróleo como o pré-sal. Porém, não apenas a localização dessas jazidas deve ser estudada, mas, também, sua forma de exploração. Essa exploração e extração, na maioria das vezes, se dão em ambientes altamente corrosivos e o transporte do produto extraído é realizado através de tubulações de aço de alta resistência e baixa liga (ARBL). Aços ARBL expostos a ambientes contendo H2S e CO2 (sour gas) sofrem corrosão generalizada que promovem a entrada de hidrogênio atômico no metal, podendo diminuir sua tenacidade e causar falha induzida pela presença de hidrogênio (Hydrogen Induced Cracking HIC), gerando falhas graves no material. Tais falhas podem ser desastrosas para o meio ambiente e para a sociedade. O objetivo deste trabalho é estudar a tenacidade, utilizando ensaio Charpy, de um tubo API 5L X65 sour após diferentes tempos de imersão em uma solução saturada com H2S. O eletrólito empregado foi a solução A (ácido acético contendo cloreto de sódio) da norma NACE TM0284 (2011), fazendo-se desaeração com injeção de N2, seguida de injeções de H2S. Os materiais foram submetidos a: ensaios de resistência a HIC segundo a norma NACE TM0284 (2011) e exames em microscópio óptico e eletrônico de varredura para caracterização microestrutural, de inclusões e trincas. As amostras foram submetidas a imersão em solução A durante 96h e 360h, sendo que, após doze dias do término da imersão, foram realizados os ensaios Charpy e exames fractográficos. Foram aplicados dois métodos: o de energia absorvida e o da expansão lateral, conforme recomendações da norma ASTM E23 (2012). As curvas obtidas, em função da temperatura de impacto, foram ajustadas pelo método da tangente hiperbólica. Esses procedimentos foram realizados nas duas seções do tubo (transversal e longitudinal) e permitiram a obtenção dos seguintes parâmetros: energias absorvidas e expansão lateral nos patamares superior e inferior e temperaturas de transição dúctil-frágil (TTDF) em suas diferentes definições, ou seja, TTDFEA, TTDFEA-DN, TTDFEA-FN, TTDFEL, TTDFEL-DN e TTDFEL-FN (identificação no item Lista de Abreviaturas e Siglas). No exame fractográfico observou-se que o material comportou-se conforme o previsto, ou seja, em temperaturas mais altas ocorreu fratura dúctil, em temperaturas próximas a TTDF obteve-se fratura mista e nas temperaturas mais baixas observou-se o aparecimento de fratura frágil. Os resultados mostraram que quanto maior o tempo de imersão na solução A, menor é a energia absorvida e a expansão lateral no patamar superior, o que pode ser explicado pelo (esperado) aumento do teor de hidrogênio em solução sólida com o tempo de imersão. Por sua vez, os resultados mostraram que há tendência à diminuição da temperatura de transição dúctil-frágil com o aumento do tempo de imersão, particularmente, as TTDFEA-DN e TTDFEL-DN das duas seções do tubo (longitudinal e transversal). Esse comportamento controverso, que pode ser denominado de tenacificação com o decorrer do tempo de imersão na solução A, foi explicado pelo aparecimento de trincas secundárias durante o impacto (Charpy). Isso indica uma limitação do ensaio Charpy para a avaliação precisa de materiais hidrogenados. / Over the years the consumption of crude oil and its derivatives increased significantly, creating the necessity to invest in research to discover new sources of pre-salt crude oil. However, not only the location of these deposits should be studied, but also its extraction. This exploration and extraction, in most cases, occur in highly corrosive environments and the transport of the extracted product is performed by high strength low alloy steel pipes (HSLA). HSLA steels exposed to environments containing CO2 and H2S (sour gas) suffer general corrosion that promotes the diffusion of atomic hydrogen into the metal structure, which may decrease its toughness and induce cracks by the presence of hydrogen (Hydrogen Induced Cracking - HIC), leading the material to severe failures. Such events can be disastrous for the environment and the society. The objective of this work is to study the toughness using Charpy Impact Tests on an API 5L X65 sour service steel pipe, submitted to different immersion times in a H2S saturated solution. The used electrolyte was the NACE TM0284 (2011) solution A (acetic acid containing sodium chloride), with deaeration by N2 injection followed by H2S injection. The materials were submitted to HIC resistance tests according to NACE TM0284 (2011) standard and examination by optical microscopy and scanning electron microscopy for microstructural inclusions and cracks characterization. The samples were immersed in the solution for 96h and 360h and after twelve days of immersion, Charpy tests and fracture analysis were performed. Two analytical methods were applied to Charpy tests results: the energy absorbed and lateral expansion, as recommended by the ASTM E23 (2012). The obtained curves, that are a function of impact temperature, were adjusted by the hyperbolic tangent method. This procedure was performed in two different orientations in the pipe (transverse and longitudinal) and allowed the determination of the following parameters: energy absorbed and lateral expansion in the upper and lower levels and ductile-to-brittle transition temperatures (DBTT) in its different definitions: DBTTAE, DBTTAE-DN, DBTTAE-FN, DBTTLE, DBTTLE-DN e DBTTLE-FN. Fracture analysis revealed that the material behaved as expected, meaning that at higher temperatures ductile fracture occurred, at temperatures near DBTT it was obtained a mixed fracture and at lower temperatures it was observed the presence of brittle fracture. Results showed that when the immersion time in the solution was higher, the energy absorbed in upper shelf decreases, and also lateral expansion in upper shelf decreases, which may be explained by the (expected) increase of hydrogen level in solid solution, induced by the immersion time. It was found that there is a tendency of the ductile-to-brittle transition temperature to be lower with the increase of immersion time, particularly the DBTTAE-DN and DBTTLE-DN of the two pipe sections (longitudinal and transversal). This controversial behavior, which may be defined as the toughening by the increase of immersion time in the solution A, was explained by the appearance of secondary cracks during impact test (Charpy). This indicates a limitation of the Charpy test for the accurate characterization of hydrogenated materials, concerning toughness. Ácido sulfídrico Aço microligado Charpy impact test Ensaio Charpy Fractografia Fragilização por hidrogênio HSLA steels Hydrogen embrittlement Hydrogen sulfide Temperatura de transição. Tenacidade dos materiais Toughness Transition temperature.

Search results