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221	Avaliação da corrosão da junta dissimilar sobreposta das ligas AA7050-T76511 e AA2024-T3 soldadas por fricção linear com mistura Bertoncello, João Carlos Brancher January 2014 (has links) As ligas de alumínio AA2024 e AA7050 tradicionalmente são utilizadas na fabricação de estruturas da fuselagem e da asa de aeronaves. Normalmente, a união dos componentes dessas estruturas é realizada por rebites, já que processos de soldagem com fusão produziriam defeitos indesejáveis. O processo de soldagem por fricção linear com mistura ou Friction Stir Welding (FSW) é uma alternativa à união de chapas de ligas de alumínio por rebites haja vista que não há fusão do material durante a união. No presente trabalho estudou-se o comportamento eletroquímico e a caracterização microestrutural de uma junta sobreposta, composta por um perfil extrudado da liga AA7050-T76511 e uma chapa da liga AA2024-T3, ambos previamente anodizados, soldada por fricção linear com mistura. O comportamento eletroquímico foi avaliado através da utilização da Técnica de Varredura com Eletrodo Vibratório (SVET), medidas do potencial de corrosão e curvas de voltametria cíclica em solução de 0,1 M de NaCl. Correntes anódicas mais intensas foram medidas na região da solda e ainda verificou-se que esta possui menores potenciais de pite e corrosão do que ambas as ligas. Também foi constatada a presença de corrosão intercristalina em ambas as ligas e na região da solda, porém com maior severidade na liga AA2024-T3. / AA2024 and AA7050 aluminum alloys are traditionally used in the manufacture of fuselage structures and aircrafts wings. Usually, the component union of these structures is made using rivets since weld process with melting will produce unwanted defects. The Friction Stir Welding (FSW) process is an alternative way to replace the traditional rivet union of aluminum alloys in the aeronautical and aerospace industries since the material does not melt during the joint. In the present work it has been studied the electrochemical behavior and microstructural characterization of a lap joint composed of an extruded profile of AA7050-T76511 alloy and a sheet of AA2024-T3 alloy, both of them previously anodized and jointed by friction stir welding. The electrochemical behavior was evaluated by means of Scanning Vibrating Electrode Technique (SVET), measurements of the corrosion potential and cyclic voltammetry in 0,1 M NaCl. Higher anodic currents were found in the weld region, moreover this region has the lowest pit and corrosion potential. Intercrystalline corrosion was found in both alloys and in the weld region, with the highest intensity in the AA2024-T3 alloy. Ligas de alumínio Soldagem por fricção Comportamento eletroquímico Friction stir welding Corrosion Aluminum alloys AA2024-T3 AA7050- T76511 SVET
222	Estudo da união por fricção e mistura mecânica entre aço austenítico alto Mn com efeito TRIP e aço automotivo ARBL / Study union friction and mechanical mixing between austenitic high Mn TRIP effect and automotive steel HSLA Brianda Rangel Francisco 06 March 2014 (has links) A crescente escassez dos recursos energéticos renováveis, bem como o contínuo aumento dos seus custos tem requerido nas últimas décadas uma redução drástica no consumo de energia utilizada para o transporte de cargas e passageiros. A indústria siderúrgica pode contribuir decisivamente neste contexto, disponibilizando no mercado aços de maior resistência mecânica, os quais podem ser utilizados em estruturas mais esbeltas. Os aços com elevados teores de Mn (15-30%) representam um desenvolvimento muito recente de ligas ferrosas puramente austeníticas, que reúnem resistência mecânica elevada e grande ductilidade. Além disso, trata-se de ligas de baixo custo devido à eliminação dos elevados teores de Ni necessários para a estabilização da austenita e ao reduzido tempo de processamento, que dispensa tratamentos térmicos e processamentos termomecânicos controlados. Por outro lado, a redução de peso estrutural no setor automobilístico requer não somente a pesquisa de novos aços, mas também a utilização de componentes híbridos, resultantes, entre outros, da união dos aços austeníticos alto Mn com aços comerciais estruturais de alta resistência e baixa liga (ARBL). Nesta dissertação, estudou-se, portanto, a soldabilidade pelo processo de fricção e mistura mecânica (SFMM) de aço austenítico alto Mn com efeito TRIP (plasticidade induzida por transformação martensítica) com aço ARBL processado termomecanicamente tipo XABO500 (ThyssenKrupp Steel, limite de escoamento > 460 MPa). As placas de aço TRIP foram fabricadas na EESC-USP com composição Fe-22.5% Mn-0.4% C através de fundição sob atmosfera protetora de argônio, tratamento térmico de homogenização e laminação a quente a 1150°C. As juntas dissimilares TRIP-ARBL foram produzidas com chapas de 3.5 mm de espessura. Os ensaios de soldagem SFMM foram conduzidos com ferramenta de compósito PCBN-WRe. O aporte térmico de soldagem foi variado através do uso de três velocidades de rotação da ferramenta: 300, 400 e 500 rpm, e o avanço foi de 100 mm/min. Dois deslocamentos (offsets) da ferramenta foram investigados: +1.0 e +2.0 mm em direção ao aço TRIP. Os resultados revelaram um acabamento superficial satisfatório das juntas soldadas com 300 e 400 rpm. A penetração de soldagem aumentou com a velocidade de rotação da ferramenta e com um maior deslocamento da ferramenta em direção ao aço TRIP devido ao crescimento do aporte térmico. A SFMM produziu em ambos os lados das juntas dissimilares uma microestrutura caracterizada apenas por zona de mistura (ZM) e zona termicamente afetada (ZTA), não sendo observada a formação de zonas termomecanicamente afetadas (ZTMA). Na ZM do aço ARBL, a SFMM produziu uma microestrutura polifásica, contendo misturas de ferrita acicular, bainita e martensita. O lado TRIP da ZM não exibiu sinais de transformação martensítica induzida por deformação e sofreu recristalização dinâmica com a formação de uma austenita refinada em comparação com o metal de base. A junta produzida com menor aporte térmico (300 RPM e Offset +1) apresentou os maiores picos de dureza na ZM do aço TRIP devido à maior taxa de resfriamento e, consequentemente, a microestrutura mais fina. Apesar dos maiores picos de dureza, a junta produzida com 300 RPM e Offset +1 apresentou o melhor desempenho no ensaio de tração, atingindo o maior percentual de alongamento a fratura e rompendo no metal de base ARBL. Isso se deve provavelmente à formação de ferrita acicular mais fina na ZM do aço ARBL com microestrutura entrelaçada e de maior tenacidade, se comparado com o metal de base ARBL. / The increasing scarcity of renewable energy resources and their continuously rising costs have required in the last decades a drastic reduction in the energy consumption for the transportation of goods and passengers. The steel industry can decisively contribute in this context by providing the market with steel grades of increased mechanical strength, which can be incorporated into light-weight structures. Steels with high Mn contents (15-30%) represent a recent development of austenitic ferrous alloys that combine elevated mechanical strength with high ductility. In addition, those steel grades correspond to low cost alloys due to the replacement of the high Ni contents necessary to stabilize the austenite as well as the reduced manufacturing time that does not involve subsequent heat treatments or controlled thermo-mechanical processing. On the other hand, the reduction of structural weight in the automotive sector does not only require the research on novel steels, but also the use of hybrid components that result among others from joining austenitic high-Mn steels to commercial structural high-strength low-alloyed (HSLA) steel grades. In this work, we studied therefore the friction stir weldability of an austenitic high-Mn steel with TRIP (transformation induced plasticity) effect to the thermomechanically processed HSLA XABO500 steel grade (ThyssenKrupp Steel, yield strength > 460 MPa). High-Mn TRIP steel plates were produced at the EESC-USP with the chemical composition of Fe-22.5% Mn-0.4% C by casting under protective argon atmosphere, followed by homogenization treatment and hot rolling at 1150°C. The dissimilar TRIP-HSLA joints were produced using 3.5 mm thick plates. The friction stir welding (FSW) experiments were carried out with a tool made of a PCBN-WRe composite. The heat input was varied by using three tool rotational speeds: 300, 400 and 500 rpm. The welding speed was set to 100 mm/min. Two different tool offsets were investigated: +1.0 and +2.0 mm towards the high-Mn TRIP steel. The results revealed that a satisfactory surface finishing is achieved for the butt-joints produced with 300 and 400 rpm. The welding penetration increased for higher tool rotational speeds and larger tool offsets towards the TRIP steel because of an increased heat input. FSW produced at both sides of the dissimilar joints a microstructure characterized by only stir zone (SZ) and heat-affected zone (HAZ). Thermo-mechanical affected zones (TMAZ) could not be observed. In the SZ of the HSLA steel, FSW produced a multiphase microstructure that contains a mixture of acicular ferrite, bainite and martensite. The TRIP side of the SZ did not exhibit traces of strain induced martensitic transformation and underwent dynamic recrystallization with the formation of a fine-grained austenite in comparison to the base material. The butt-joint produced with the lowest heat input (300 RPM and Offset +1) developed the highest hardness peaks in the SZ of the TRIP steel because of the increased cooling rate and, consequently, the more refined microstructure. In spite of the hardest zones, the butt-joint produced with 300 RPM and offset +1 achieved the best performance in the tensile tests by reaching the largest elongation to fracture and having the failure in the HSLA base material. This is likely promoted by the formation of a more refined acicular ferrite in the SZ of the HSLA steel with interpenetrated microstructure and enhanced toughness in comparison to the HSLA base material. Aços ARBL Microestrutura Propriedades mecânicas TRIP Friction stir welding HSLA Mechanical properties Microestructure Steels TRIP
223	Aplikace svařování třením v leteckých konstrukcích / Application of Friction Stir Welding in Aircraft Structures Šrubař, Martin January 2009 (has links) Slitiny hliníku řad 2XXX a 7XXX nejsou shledávány jako svařitelné s použitím tradičních metod svařování. Jsou však široce používány v leteckých a kosmických konstrukcích. Obvyklý způsob jejich spojování je pomocí nýtování. Nově vznikající technologie lineárního svařování třením rotujícím nástrojem (Friction Stir Welding - FSW) již ukázala slibné výsledky při svařování těchto slitin. V této práci jsme prozkoumali aplikace technologie FSW v leteckých konstrukcích zejména jako náhradu nýtování na panelech vyztužených stringery. Sestavili jsme výrobní postup pro daný panel a navrhli další kroky k jeho optimalizaci. Dále jsme sestavili znalostní bázi základních svařovacích parametrů a porovnali jsme nýtování a FSW na jednoduchém modelu využitím metody konečných prvků a s cílem identifikovat rozdíly v charakteru rozložení napětí v těchto vzorcích.
224	Modeling of Fracture Toughness of Magnesium Alloy WE43 Before and After Friction Stir Processing Lipscomb, Celena Andrea 12 1900 (has links) Magnesium alloys are a popular research topic for structural applications because they have a lower density than conventional structural materials, including steel, titanium, and aluminum; however, the reliability and safety of their mechanical properties must be further proven. An important mechanical property for this purpose is fracture toughness, which is the measure of the material's resistance to crack propagation. In this study, a model of an experiment to investigate the fracture toughness of a magnesium alloy WE43 before and after friction stir processing (FSP) is developed, and the results are compared to those produced by a digital image correlation (DIC) system during an experiment from another paper. The model results of the material before FSP matched well with the DIC results, but the model of the material after FSP only partially matches the DIC results. In addition, a theoretical approach to calculating the standard fracture toughness value, KIc, from the modeling results is proposed, and is found to be a conservative approach. Friction stir processing Mg alloy FEM Kahn-type tear test DIC plastic deformation Engineering, Materials Science Engineering, Mechanical
225	Casting repair and Surface Modification of Aluminum Alloys using Friction Stir Processing (FSP) Bates, William January 2021 (has links) This thesis investigates using friction stir welding to repair common surface defects found in aluminum-silicon sand castings. Wherein, the effect of welding parameters: weld RPM, weld speed, and number of weld passes, were evaluated using hardness, porosity density, welding temperature, microstructure refinement as metrics. Therefrom, the results strongly suggest friction stir welding: reduces porosity size, reduces porosity density in a specific area, increases average hardness, improves hardness uniformity, increases surface roughness, redistributes microstructure features in a manner that theoretically improves strength, and maintains a welding temperature less than 660 degrees Celsius. Friction Stir FSP Aluminium Alloys Casting Repair Mechanical Engineering Maskinteknik
226	Dissimilar Joining of Al (AA2139) – Mg (WE43) Alloys Using Friction Stir Welding Poudel, Amir 12 1900 (has links) This research demonstrates the use of friction stir welding (FSW) to join dissimilar (Al-Mg) metal alloys. The main challenges in joining different, dissimilar metal alloys is the formation of brittle intermetallic compounds (IMCs) in the stir zone affecting mechanical properties of joint significantly. In this present study, FSW joining process is used to join aluminum alloy AA2139 and magnesium alloy WE43. The 9.5 mm thick plates of AA2139 and WE43 were friction stir butt welded. Different processing parameters were used to optimize processing parameters. Also, various weldings showed a crack at interface due to formation of IMCs caused by liquation during FSW. A good strength sound weld was obtained using processing parameter of 1200 rev/min rotational speed; 76.2 mm/min traverse speed; 1.5 degree tilt and 0.13 mm offsets towards aluminum. The crack faded away as the tool was offset towards advancing side aluminum. Mostly, the research was focused on developing high strength joint through microstructural control to reduce IMCs thickness in Al-Mg dissimilar weld joint with optimized processing parameter and appropriate tool offset. FSW (Friction Stir Welding) Al (Aluminum) Mg (Magnesium) IMCs (Intermetallic compounds) AA2139 (Aluminum Alloy) WE43 (Magnesium Alloy)
227	Nekonveční metody svařování tvářených slitin hořčíku / Unconventional methods of welding of wrought magnesium alloys Klimčáková, Kateřina January 2011 (has links) Master's thesis deals with consideration possibility of conventional and unconvetional welding methods of wrought magnesium alloys. Methods of Friction Stir Welding, Pulsed Nd:YAG laser and Continuous Fiber laser was used to join magnesium alloy sheets AZ31, AZ61, ZE10 and ZE41. For studying influence of processing parameters on microstructure and mechanical properties were used methods of light microscopy, scanning electron microscopy, tensile tests and microhardness measurements. The results of tensile tests show that from the point of view of keeping ultimate tensile strength is the best methods for welding magnesium alloys Friction Stir Welding. Compared with Nd:YAG laser, fiber laser give better properties of welds. From comparing microstructure and mechanical properties . It wasn't found publications about Friction Stir Welding of magnesium ZE alloys or about FSW sheets with thickness only 0,8 mm and 1,6 mm.
228	Exceptional Properties in Friction Stir Processed Beta Titanium Alloys and an Ultra High Strength Steel Tungala, Vedavyas 05 1900 (has links) The penchant towards development of high performance materials for light weighting engineering systems through various thermomechanical processing routes has been soaring vigorously. Friction stir processing (FSP) - a relatively new thermomechanical processing route had shown an excellent promise towards microstructural modification in many Al and Mg alloy systems. Nevertheless, the expansion of this process to high temperature materials like titanium alloys and steels is restricted by the limited availability of tool materials. Despite it challenges, the current thesis sets a tone for the usage of FSP to tailor the mechanical properties in titanium alloys and steels. FSP was carried out on three near beta titanium alloys, namely Ti6246, Ti185 and Tiβc with increasing β stability index, using various tool rotation rates and at a constant tool traverse speed. Microstructure and mechanical property relationship was studied using experimental techniques such as SEM, TEM, mini tensile testing and synchrotron x-ray diffraction. Two step aging on Ti6246 had resulted in an UTS of 2.2GPa and a specific strength around 500 MPa m3/mg, which is about 40% greater than any commercially available metallic material. Similarly, FSP on an ultra-high strength steel―Eglin steel had resulted in a strength greater than 2GPa with a ductility close to 10% at around 4mm from the top surface of stir zone (SZ). Experimental techniques such as microhardness, mini-tensile testing and SEM were used to correlate the microstructure and properties observed inside SZ and HAZ's of the processed region. A 3D temperature modeling was used to predict the peak temperature and cooling rates during FSP. The exceptional strength ductility combinations inside the SZ is believed to be because of mixed microstructure comprised of various volume fractions of phases such as martensite, bainite and retained austenite. FSP Beta titanium alloys Eglin steel Mechanical properties Microstructural characterization Titanium alloys. Steel, High strength. Friction stir welding.
229	Experimental and Numerical Study of High-Speed Friction Stir Spot Welding of Advanced High-Strength Steel Karki, Utsab 01 March 2015 (has links) (PDF) With the desire to lighten the frame while keeping or increasing the strength, Advanced High-Strength Steels (AHSS) have been developed for use in the automotive industry. AHSS meet many vehicle functional requirements because of their excellent strength and acceptable ductility. But joining AHSS is a challenge, because weldability is lower than that of mild steels. Friction stir spot welding (FSSW) is a solid state joining process that can provide a solution to the weldability issues in AHSS, but FSSW has not been studied in great detail for this application. In this work, Si3N4 tools were used for FSSW experiments on DP 980 steel with 1.2mm thickness. Joint strength was measured by lap shear tension testing, while thermocouples were used for the temperature measurements. A finite element model was developed in order to predict material flow and temperatures associated with FSSW. Since a 3D model of the process is very time consuming, a novel 2D model was developed for this study. An updated Lagrangian scheme was employed to predict the flow of sheet material, subjected to the boundary conditions of the fixed backing plate and descending rotating tool. Heat generation by friction was computed by including the rotational velocity component from the tool in the thermal boundary conditions. Material flow was calculated from a velocity field while an isotropic, viscoplastic Norton-Hoff law was used to compute the material flow stress as a function of temperature, strain and strain rate. Shear stress at the tool/sheet interface was computed using the viscoplastic friction law. The model predicted welding temperatures to within 4% of the experiments. The welding loads were significantly over predicted. Comparison with a 3D model of FSSW showed that frictional heating and the proportion of total heat generated by friction were similar. The position of the joint interface was reasonably well predicted compared to experiment. Utsab Karki high speed friction stir spot welding simulation DP 980 Si3N4 tool advanced high strength steel Industrial Engineering
230	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

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