Global ETD Search

51	Estudo da transformação da austenita retida em martensita induzida por deformação plástica em aços multifásicos Del Sant, Ricardo [UNESP] 13 April 2010 (has links) (PDF) Made available in DSpace on 2014-06-11T19:32:50Z (GMT). No. of bitstreams: 0 Previous issue date: 2010-04-13Bitstream added on 2014-06-13T20:24:12Z : No. of bitstreams: 1 delsant_r_dr_guara.pdf: 3721030 bytes, checksum: 88232a756e66c084fa98967c48ab9853 (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Os aços multifásicos constituídos de ferrita, bainita, austenita retida e martensita apresentam combinações muito atrativas de resistência e tenacidade. Há ainda um potencial adicional de melhorias de propriedades mecânicas quando a fração de austenita retida for alta, conferindo alta conformabilidade pelo efeito TRIP. Neste contexto, é fundamental a análise qualitativa e quantitativa das fases, especialmente de austenita retida e sua transformação em martensita induzida por deformação. Este trabalho enfoca a transformação da austenita retida em martensita por deformação em tração monotônica em um aço AISI 4340 com estrutura multifásica. Os resultados confirmam a transformação da austenita retida em martensita atingindo cerca de 80% de transformação. As frações volumétricas de austenita retida antes e após a deformação foram estimadas por duas técnicas. A primeira foi feita por análise de imagens em microscopia óptica e a segunda por magnetização de saturação, tendo em vista o caráter paramagnético desta fase. As frações estimadas pelas duas técnicas foram comparadas, concluindo-se que o método magnético deve ser reavaliado, tendo sido proposto um fator de correção na equação básica deste processo e presenta na literatura. / The multiphase steels made of ferrite, bainite, retained austenite and martensite present very attractive combinations and toughness. There is still an additional potential of improvement of the mechanical properties when the fraction of retained austenite is high allowing high conformability by the TRIP effect. In this context the qualitative and quantitative analysis of the phases is essentual specially from retained austenite and its transformation in martensite induced by deformation. This work focus on the transformation of retained austenite in martensite by the deformation in monotonic traction in one steel AISI 4340 with multiphasic structure. The results confirm the transformation of retained in martensite reaching about 80% of transformation. The volumetric of retained austenite before and after the deformation were estimated by two technique: the first was made by the anllysis of images in optic microscopy and the second by magnetization of saturation taking into consideration the paramagnetica character of this phase. The estimated fraction by the two technique were compared leading to the conclusion that the magnetic method must be evaluated again using a proposed factor of correction in the basic equation of this process and present in the literature. Ação Católica Operária (Brasil) Austenita Aço multifásico Multiphase steels Austenite
52	Desenvolvimento de ligas inoxidaveis com efeito de memoria de forma: elaboracao e caracterizacao OTUBO, JORGE 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:41:11Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:08:35Z (GMT). No. of bitstreams: 1 04051.pdf: 13566851 bytes, checksum: 00f45b4ba82c60e068d8fd10c9aba717 (MD5) / Tese (Doutoramento) / IPEN/T / Universidade Estadual de Campinas - UNICAMP/SP stainless steels alloys shape memory effect martensite austenite
53	Têmpera e partição em ferros fundidos nodulares. / Quenching & partitioning of ductile cast Irons. Anderson José Saretta Tomaz da Silva 15 August 2013 (has links) Um novo ciclo de tratamento térmico denominado como têmpera e partição vem sendo desenvolvido em aços com elevados teores de silício, como rota para obtenção de estruturas com frações consideráveis de austenia retida. Essa rota de tratamento m térmico consiste em realizar uma têmpera temperaturas intermediárias entre Ms e Mf, seguido de um reaquecimento com manutenção em patamares isotérmicos por certos intervalos de tempo, objetivando estabilizar a austenita remanescente através da partição do carbono a partir da martensita supersaturada. No presente trabalho, duas ligas de ferros fundidos nodulares convencionais, com diferentes teores de silício e manganês, foram submetidas a ciclos de têmpera e partição. As amostras foram austenitizadas a 900°C por duas horas. Uma das ligas foi temperada em óleo a 160°C e a outra a 170°C por 2 minutos. Imediatamente após a têmpera as amostras foram reaquecidas em temperaturas entre 300 e 450°C por intervalos de tempo que variaram entre 2 e 180 minutos. A caracterização microestrutural foi realizada através de microscopia eletrônica de varredura (MEV) e difração de raios x. A caracterização mecânica foi feita através de ensaios de energia absorvida ao impacto, dureza HRC e ensaios de tração. A caracterização microestrutural evidenciou que os ciclos de têmpera e partição são viáveis na obtenção de frações consideráveis de austenita retida nos ferros fundidos nodulares. A caracterização mecânica evidenciou que foi possível obter boas combinações de energia absorvida ao impacto, resistência à tração e alongamento. Em todas as condições testadas é possível perceber uma janela de processo bem definida caracterizada por valores crescentes das propriedades mecânicas nos primeiros minutos do ciclo de partição e que decrescem após certo intervalo de tempo. O conjunto de propriedades mecânicas obtidas através dessa rota de tratamentos térmicos indica que os ferros fundidos nodulares submetidos ao ciclo de têmpera e partição podem se constituir como alternativa tecnológica para aplicações comerciais nas quais os ferros fundidos nodulares austemperados já são materiais consolidados. / A new heat treatment cycle known as quenching and partitioning has been developed in commercial steel alloys containing silicon as a way to obtain structures with controlled fractions of retained austenite. This heat treatment cycle consists in performing a quenching in temperatures between Ms and Mf, followed by a reheating with isothermal holding by different time intervals. The aim of this cycle is to achieve the austenite stabilization by diffusion of carbon from the supersaturated plates of martensite. In this work, two conventional ductile cast iron alloys, with two different contents of silicon and manganese were heat-treated in quenching and partitioning cycle. The samples were austenitized at 900°C for two hours, followed by quenching in oil at 160° C and 170° C for two minutes. Immediately after quenching, the samples were reheated at temperatures between 300 and 450°C for time intervals between 2 and 180 minutes. The microstructural characterization was performed using electronic microscopy (SEM) and x-ray diffraction. The mechanical characterization was performed using impact tests, hardness and tensile strength tests. The microstructural characterization showed that the cycles of quenching and partitioning are viable to obtain considerable fractions of retained austenite in nodular cast by this heat treatment route. The mechanical characterization showed that it was possible to obtain good combinations of energy absorbed in the impact, tensile strength and elongation. In all tested conditions was possible to perceive a well-defined process window characterized by increasing values of mechanical properties in the first minutes of the partitioning step, and decrease after certain time intervals. The set of mechanical properties obtained by this route of heat treatments indicates that nodular cast iron subjected to tempering and partitioning cycle can be constituted as an alternative technology for commercial applications in which austempered ductile irons are already consolidated materials. Austenita Ferro nodular Têmpera e partição Austenite Ductile iron Quenching and partitioning
54	Desenvolvimento de ligas inoxidaveis com efeito de memoria de forma: elaboracao e caracterizacao OTUBO, JORGE 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:41:11Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:08:35Z (GMT). No. of bitstreams: 1 04051.pdf: 13566851 bytes, checksum: 00f45b4ba82c60e068d8fd10c9aba717 (MD5) / Tese (Doutoramento) / IPEN/T / Universidade Estadual de Campinas - UNICAMP/SP stainless steels alloys shape memory effect martensite austenite
55	InfluÃncia do Resfriamento sub-zero apÃs o Envelhecimento na FormaÃÃo de Austenita Revertida em um AÃo Maraging 350 / Influence of sub-zero cooling after the formation of austenite on Aging Reversed in a maraging steel 350 Henrique Thiago Freire de Menezes 29 September 2008 (has links) FundaÃÃo de Amparo Ã Pesquisa do Estado do CearÃ / Os aÃos maraging sÃo materiais de ultra-alta resistÃncia sendo composto principalmente por uma base quaternÃria Ni-Co-Mo-Ti que possuem excelente tenacidade aliada com alta resistÃncia mecÃnica sendo utilizadas na indÃstria bÃlica, nuclear, componentes aeronÃuticos, vasos de pressÃo atÃ indÃstria esportiva. Uma de suas importantes aplicaÃÃes Ã na utilizaÃÃo nos motores de histerese os quais necessitam de materiais com caracterÃsticas de materiais magneticamente macios e elevada resistÃncia mecÃnica. Foram realizados ensaios de microdueza para determinar propriedades mecÃnicas nas diversas condiÃÃes de tratamento de envelhecimento e meios de resfriamento. Com o objetivo de descobrir as fases presentes no material nas diversas condiÃÃes de tratamento foram realizadas ensaios por difraÃÃo de raios-X bem como analisar a macrotextura atravÃs de FDOC`s. A microtextura foi analisada atravÃs da tÃcnica de EBSD (Electron Backscatterig Diffraction) com o intuito de estudar a influÃncia da textura da austenita na martensita nas determinadas condiÃÃes de envelhecimento e meios de resfriamento. Esta dissertaÃÃo Ã de grande relevÃncia para o desenvolvimento de novos produtos utilizando aÃos maraging, pois determina as condiÃÃes que oferecem as propriedades mecÃnicas, bem como as fases e textura presentes no material nas condiÃÃes de tratamento requeridas. / Maraging steels are materials of ultra high strength mainly composed of a base quaternary Ni-Co-Mo-Ti which have excellent toughness combined with high mechanical strength being used in war industry, nuclear, aircraft components, pressure vessels up to the sports industry . One of its important applications is in use in hysteresis motors which require materials with characteristics of magnetically soft materials and high mechanical strength. Microdueza tests were performed to determine mechanical properties in different treatment conditions of aging and cooling media. In order to discover the phases present in the material conditions in the various treatment trials were performed by X-ray diffraction as well as analyze the macrotexture through FDOC `s. The microtexture was examined using the technique of EBSD (Electron Diffraction Backscatterig) in order to study the influence of the texture of the austenite in the martensite aging in certain conditions and means of cooling. This thesis is of great importance for the development of new products using maraging steel, because it determines the conditions that provide the mechanical properties as well as the phases and texture present in the material conditions of treatment required. Austenita AÃo Maranging Austenite reversed maraging 350 ENGENHARIA DE MATERIAIS E METALURGICA
56	Development and processing of low carbon bainitic steels Suikkanen, P. (Pasi) 20 October 2009 (has links) Abstract The aim of this work was to study systematically the effects of composition and processing on austenite grain growth and static recrystallization (SRX) kinetics, austenite decomposition under controlled cooling as well as microstructures, mechanical properties and weldability of hot rolled low carbon bainitic (LCB) steels. The results showed that the coarsening of austenite grain structure is influenced by the chemical composition. Steels with Nb-Ti alloying exhibited fine and uniform austenite grain size up to 1125 °C, whereas higher temperatures led to formation of the bimodal grain structures. However, with Nb-Ti-B microalloying, the abnormal grain growth was already observed at 1050 °C. SRX rate at roughing temperatures, determined by the stress relaxation method, was found to be retarded markedly by Mo, Nb and B alloying. For the test conditions investigated, the decomposition of austenite started in the temperature range from 780 °C to below 550 °C. All alloying elements with the exception of Nb (0.04–0.10 wt-%) decreased the phase transformation temperatures and increased the hardness of dilatometric specimens. Detailed microstructural examinations enabled the identification of 4 different ferrite morphologies: polygonal ferrite, quasi-polygonal ferrite (QF), granular bainitic ferrite (GB) and bainitic ferrite (BF), generally as a mixed microstructure consisting of 2–3 types morphologies. Consistent with the microstructures detected in dilatometric experiments, the microstructures of rolled plates comprise various combinations of low C ferrite morphologies. These microstructure types provided the yield strengths from 500 MPa up to 850 MPa in hot rolled condition and from 500 MPa to 950 MPa in heat-treated condition (600 °C/1h). The yield strengths from 500 MPa to 570 MPa were mainly related to QF microstructures in as-rolled condition, while the steels with the yield strength from 570 to 700 MPa had GB-QF microstructures. Steels with the yield strengths above 700 MPa consisted of BF. The most effective alloying element regarding the strength properties is B. Also C, Mn, Cr, Mo and Ni have strong influences, but Nb in the range of 0.05–0.10 wt-% is ineffective. Strengthening with B and Mo was detrimental to toughness. Alloying with Ni and Mn is beneficial to good strength and toughness combination. Mn, Mo, Nb and B contents mainly dictate CGHAZ toughness. austenite decomposition bainite microalloying physical simulation static recrystallization
57	The effect of austenitising and tempering parameters on the microstructure and hardness of martensitic stainless steel AISI 420 Barlow, Lilian Debra 26 November 2009 (has links) The effect of austenitising and tempering practice on the microstructure and mechanical properties of two martensitic stainless steels was examined with the aim of supplying heat treatment guidelines to the consumer or fabricator that, if followed, would result in a martensitic structure with minimal retained austenite, evenly dispersed carbides and a hardness of between 610 HV and 740 HV (hardness on the Vickers scale) after quenching and tempering. The steels examined during the course of this examination conform in composition to medium-carbon AISI type 420 martensitic stainless steel, except for the addition of 0.13% vanadium and 0.62% molybdenum to one of the alloys. The effect of various austenitising and tempering heat treatments was examined. Steel samples were austenitised at temperatures between 1000°C and 1200°C, followed by quenching in oil. The as-quenched microstructures were found to range from almost fully martensitic structures to martensite with up to 35% retained austenite after quenching, with varying amounts of carbide precipitates. The influence of tempering, double tempering, and sub-zero treatment was investigated. Optical and scanning electron microscopy was used to characterise the as-quenched microstructures, and X-ray diffraction analysis was employed to identify the carbide present in the as-quenched structures and to quantify the retained austenite contents. Hardness tests were performed to determine the effect of heat treatment on mechanical properties. As-quenched hardness values ranged from 700 HV to 270 HV, depending on the amount of retained austenite. Thermodynamic predictions (using the CALPHAD™ model) were used to explain these microstructures based on the solubility of the carbide particles in the matrix at various austenitising temperatures. The carbide particles were found to be mainly in the form of M7C3 at elevated temperatures, transforming to M23C6 on cooling. / Dissertation (MSc)--University of Pretoria, 2010. / Materials Science and Metallurgical Engineering / unrestricted M23c6 M7c3 Retained austenite Stainless Martensitic Carbide Austenitising temperature UCTD
58	Characterization of Phase Transformation and Twin Formation in Automotive Sheet Metal Alloys to Quantify and Understand Their Impact on Ductility Chelladurai, Isaac 01 July 2019 (has links) The motivation to use lightweight materials in the construction of the automotive structure is the resultant increased fuel efficiency. However, these materials possess certain drawbacks that make it challenging to adopt them into current automobile manufacturing processes. In this dissertation the microstructural response observed in a magnesium alloy, AZ31, and an advanced high strength steel alloy, QP1180, to uniaxial deformation is analyzed and the results are presented. In AZ31 the required slip modes are not activated at room temperature leading to its low ductility at room temperature. The resulting activity of these twins in response to uniaxial tension is analyzed and its correlations with the microstructure features is reported. Additionally, a neighborhood viscoplastic self-consistent model is developed that will allow more accurate simulation of twin response to outside deformation. Furthermore, activity of slip modes that are usually observed at high temperatures (>200°C) are also observed at lower temperatures (<125°C) and they are compared to the relative twin activity at these temperatures. It is observed that larger grains, with high schmid factors, longer grain boundaries and have misorientation with its neighboring grain greater than 27° are more favorable for twin formation and transmission in the AZ31 microstructure in response to uniaxial tension. The nature of retained austenite (RA) transformation into martensite that gives QP1180 its enhanced ductility, is not clearly understood primarily because of challenges present in characterization of these metastable RA. Further, a 2 dimensional characterization method does not provide the complete information of the RA grain. These challenges are overcome by characterization of a 3 dimensional volume element using serial sectioning and EBSD followed by reconstruction using DREAM3D. The influence of 3d morphology and orientation direction on RA transformation is studied using as-is and uniaxially deformed samples. A novel shear affinity factor is introduced as a metric to describe the ease of RA transformation under uniaxial tension. The 3d nature of the information collected allows a new classification of disk shape in addition to globular and lamellar shapes for RA. It is found that RA that are low volume laths and have low shear affinity factor transform later compared to disk shaped RA’s. Through these guidelines the preparation of a microstructure that is conducive to RA transformation under uniaxial tension is possible. magnesium QP1180 EBSD retained austenite DIC VPSC twinning AZ31
59	STUDY OF PHASE TRANSITION AND MAGNNETOCALORIC EFFECT FOR THE SYSTEM Ni-Mn-In-Bi Oli, Abhiyan 01 December 2023 (has links) (PDF) AN ABSTRACT OF THE THESIS OFABHIYAN OLI, for the Master of Science degree in Applied Physics, presented on August 10, 2023 at Southern Illinois University Carbondale. TITLE: STUDY OF PHASE TRANSITION AND MAGNNETOCALORIC EFFECT FOR THE SYSTEM Ni-Mn-In-Bi MAJOR PROFESSOR: Dr. Saikat Talapatra We experimentally investigate the Heusler alloys Ni50Mn35In12Bi3 and Ni47Mn35In15Bi3 on their different magnetic properties: structural, magnetic, magnetocaloric and magnetotransport properties by using room-temperature X-ray diffraction (XRD), and magnetization measurements in the temperature interval of 10 -380K and field up to 5T. This alloys shows both high temperature austenite phase (AP) and martensite phase (MP). The alloy Ni47Bi3Mn35In15 crystallize in primitive Cubic structure with space group Fm-3m and Ni50Mn35In12Bi3 with the crystal structure of Tetragonal L21 type with space group I4-3m. Alloy Ni47Bi3Mn35In15 show two phase transition FOPT from Ferrimagnetic/AFM to FM and SOPT from FM to PM towards higher temperature and its result will be discussed here mainly. The martensitic transition (TM) takes place around 200K and Curie temperature (TC) 313K in presence of 100Oe field. The saturation magnetization (Ms) at 10K was found to be increasing at lower field and stabilized at higher field indicating ferromagnetic behavior. The Ni47Bi3Mn35In15 shows high magnetocaloric effects (ΔSM = -47.36 Jkg-1K-1) and Relative Cooling Power (RCP = 222.12 J/Kg) in the vicinity of its Curie temperature (TC =313K). Magnetotransport measurement is done by using a standard four-probe method from 10-380 K temperature in presence of zero field and 50 kOe field. austenite phase Heusler alloys Magnetotransport MAGNNETOCALORIC EFFECT martensite phase
60	Interactions between austenite grain boundaries and aluminum nitride precipitates Dogan, Omer Nihat January 1990 (has links) No description available. Engineering, Materials Science austenite grain boundaries aluminum nitride precipitates

Search results