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[en] API X80 HAZ PHYSICAL SIMULATION AND MICROSTRUCTURAL AND MECHANICAL CHARACTERIZATION / [pt] CARACTERIZAÇÃO MICROESTRUTURAL, MECÂNICA E SIMULAÇÃO FÍSICA DA ZTA EM AÇO API X80JOSE LUIS MONTALVO ANDIA 24 July 2013 (has links)
[pt] Foram utilizados dois sistemas de aço API 5L X80, Nb-Cr e Nb-Cr-Mo,
para obter as diferentes regiões da ZTA pertencentes a uma soldagem
multipasse. Estas regiões são denominadas de: região de grãos grosseiros
inalterados (RGGI), região de grãos refinados reaquecidos supercriticamente
(RGRRS), região de grãos grosseiros reaquecidos intercriticamente (RGGRI),
região de grãos grosseiros reaquecidos subcriticamente (RGGRS). Estas regiões
foram obtidas para dois aportes de calor (1,2 e 2,5 kJ/mm) e a RGGRI por ser
considerada a região onde poderiam ser formadas zonas frágeis localizadas
(ZFL) foram utilizados também aportes de calor de 3,0 e 4,0 kJ/mm. Cada uma
das regiões obtidas pela simulação física foi submetida a ensaios mecânicos de
impacto Charpy e dureza, assim como a análises metalográficos por microscopia
ótica (MO) e microscopia eletrônica de varredura (MEV). Foi possível observar
que as microestruturas pertencentes a uma ZTA simulada obtidas com o
equipamento (GleebleR3800) se mostram compatíveis com aquelas pertencentes
a uma soldagem real. Este resultado comprova que as velocidades de
resfriamento obtidas pela simulação foram similares àquelas da soldagem real.
A adição de Mo ao sistema Nb-Cr-Mo não promoveu mudanças significativas
tanto a nível microestrutural, observado por MO e MEV, como em termos de
propriedades mecânicas. / [en] Two API 5L steels grade X80 of the systems Nb-Cr and Nb-Cr-Mo, were
submitted to physical simulation in order to obtain different regions of the HAZ
similar to those of a multipass welding, the coarse grained heat affected zone
(CGHAZ), supercritically coarse grained heat affected zone (SCCGHAZ),
intercritically coarse grained heat affected zone (ICCGHAZ), subcritically
coarse grained heat affected zone (SCGHAZ). The welding simulation was
carried out on a Gleeble R 3800 considering two thermal cycles and different
heat inputs 1.2, 2.5, 3.0 and 4,0 kJ/mm, typical of a girth weld. All HAZ zones
were simulated only for 1.2 and 2.5kJ/mm. Since the ICCGHAZ is the probable
weak link where a local brittle zone (LBZ) can occur, this region was simulated
for all heat inputs studied. All simulated regions were subjected to traditional
mechanical tests such as impact Charpy-V at -40 and -60C and microhardness
Hv1kg. Metallographic analysis by optical microscopy (OM) and scanning
electron microscopy (SEM) and fractography were also performed.
The microstructures obtained for the different regions of the HAZ, by simulation
were close to those of a real welding, however, the cooling rates obtained by
simulation were slower than that obtained in a real welding. The mechanical
properties and microstructure of the different regions of the HAZ for the systems
NbCr and NbCrMo indicate that the microstructural and mechanical behavior of
the intercritical region (ICCGHAZ) was considered to be similar to a local brittle
zone (LBZ) for all conditions studied.
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Precipitação de fases intermetálicas na Zona Afetada pelo Calor de Temperatura Baixa (ZACTB) na soldagem multipasse de aços inoxidáveis duplex. / Precipitation of intermetallics phases in the heat affected zone of low temperature (HAZLT) during duplex stainless steels multipasse welding.Serna Giraldo, Claudia Patricia 30 August 2001 (has links)
Os aços inoxidáveis duplex são ligas Cr-Fe-Ni-Mo, que possuem uma microestrutura balanceada austenita-ferrita, e com excelentes propriedades mecânicas e de resistência à corrosão. Estas características os fazem muito utilizados nas industrias química, petroquímica, de papel, alimentícia e farmacêutica. O processamento destes aços geralmente envolve processos de soldagem, os quais devem ser elaborados cuidadosamente. Durante os ciclos térmicos experimentados na soldagem na zona afetada pelo calor, dependo do tempo de permanência no intervalo de temperaturas entre 650°C-950°C, podem ser precipitadas fases intermetálicas, como a fase sigma, que prejudicam as propriedades mecânicas e de resistência à corrosão. Três ligas comerciais de aços inoxidáveis duplex (AID) e superduplex (AISD) de denominação UNS S32304(AID), UNS S32750(AISD) e UNS S32760(AISD) foram submetidos a soldagem multipasse e a simulações de ciclos de soldagem na zona afetada pelo calor de temperatura baixa (ZACTB). As simulações foram realizadas em um dilatômetro e em um equipamento Gleeble®. Foram feitas comparações entre as microestruturas obtidas nas soldas reais e nos corpos-de-prova simulados. As microestruturas foram analisadas através de microscopia ótica e microscopia eletrônica de varredura. Foram também analisadas as fases precipitadas através de difração de Raios-X de resíduos extraídos, química e eletroliticamente, das amostras simuladas. Realizaram-se ensaios de corrosão intergranular e de polarização cíclica, para determinar o comportamento dos materiais à corrosão após a soldagem. Achou-se um bom acordo entre as microestruturas das soldas reais e as microestruturas simuladas. Encontrou-se que o aço UNS S32304 não precipitou nenhuma fase. No entanto, nos aços UNS S32750 e UNS S32760 foram encontradas fases precipitadas nos contornos de grão ferrítico. Essas fases foram identificadas como sigma e Cr2N. Entre estes dois últimos achou-se que o aço mais susceptível à precipitação de fases é o UNS S32760, provavelmente pela presença do W. Quanto ao comportamento à corrosão, não se observou nenhuma variação nos potenciais de pite após a simulação, enquanto que os potenciais de proteção sofreram uma queda comparando-se aos materiais na condição como-recebidos. / Duplex stainless steels are Cr-Fe-Ni-Mo alloys. They possess balanced austenitic/ ferritic microstructure, excellent mechanical and corrosion resistance properties. Thus, these characteristics make them very used in chemical, petrochemical, cellulose, food and pharmaceutical industries. The processing of these steels generally involves welding processes, which should be carried out carefully. Depending on time from 650°C to 950°C temperature range during thermal cycles in heat affected zone, intermetallic phases can be precipitated, as sigma phase for instance. As a consequence, mechanical and corrosion resistance might be impaired. Three duplex (DSS) and superduplex (SDSS) stainless steel alloys, with denomination of UNS S32304 (DSS), UNS S32750 (SDSS), and UNS S32760 (SDSS), were submitted to real multipass welding and welding thermal cycles simulations of low temperature heat affected zone. The simulations were accomplished in a dilatometer and in a Gleeble® equipment. They were made comparisons among microstructures obtained in actual welds and simulated welding thermal cycles. Microstructures were analyzed by optical and electronic microscopy. X-ray diffraction analyses of extracted residues were studied. Tests of intergranular corrosion and cyclic potentiodynamic polarization were performed. Results indicated good agreement between actual welding and thermal cycles simulated microstructures. UNS S32304 steel did not precipitate any intermetallic phase. On the other hand, in UNS S32750 and UNS S32760 steels were found precipitated phases in the ferritic grain boundary. Those phases were identified as sigma and Cr2N. UNS S32760 were more susceptible phase precipitation, probably due to tungsten as an additional alloying element in this steel. Corrosion results indicated no observed variation in pitting potentials of simulated samples, meanwhile pitting protection potentials suffered a fall compared to materials in the as received condition.
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Precipitação de fases intermetálicas e austenita secundária na ZAC de soldagens multipasse de aços inoxidáveis duplex. / Intermetallic phases and secondary austenite precipitation at the multipass welding HAZ of duplex stainless steels.Ramírez Londoño, Antonio José 24 October 2001 (has links)
Os aços inoxidáveis duplex (AIDs) são materiais com um excelente desempenho tanto mecânico como à corrosão. Inúmeras pesquisas tem sido desenvolvidas para aprimorar a soldabilidade destas ligas. Algumas transformações de fase, que são passíveis de ocorrer durante o processo de soldagem, podem prejudicar seriamente o desempenho das juntas. Foram simuladas microestruturas da região da zona afetada pelo calor submetida a temperaturas elevadas (ZACTE), utilizando um modelo proposto de fluxo de calor. Abordaram-se aspectos fundamentais da precipitação de austenita secundária, de nitreto de cromo e as suas interações na ZACTE de soldas multipasse. Finalmente, foram realizados testes de tenacidade e de resistência à corrosão para avaliar o efeito das transformações de fase estudadas no desempenho das juntas soldadas. Os tratamento térmicos e simulações da ZACTE foram realizadas num equipamento GleebleÒ. As microestruturas foram analisadas mediante microscopia ótica e eletrônica de varredura e de transmissão. Junto com a microscopia eletrônica foram realizadas microanálises químicas das fases estudadas. Baseando-se nos resultados obtidos, verificou-se que nem todos os AIDs são susceptíveis de ferritizar. Este fato tem uma grande influência no comportamento metalúrgico e na soldabilidade destes aços. Quanto aos aspectos fundamentais da metalurgia destes aços, observou-se uma estreita interação entre a precipitação da austenita secundária e os nitretos de cromo, chegando-se a propor um mecanismo de nucleação da austenita secundária intragranular a partir dos nitretos. Por último, foi constatado que o efeito deletério da austenita secundária intragranular na resistência à corrosão pode ser evitado mediante a adequada elaboração do procedimento de soldagem. / Duplex stainless steels (DSS) have excellent mechanical and corrosion properties. Many researches have been developed regarding the weldability of these alloys. There are some phase transformations that take place during the welding process, which may impair the welded joint behavior. High temperature heat-affected zone (HTHAZ) microstructures were simulated using a proposed heat flow model. Fundamental aspects of the secondary austenite and chromium nitride precipitation, and its interactions in the HTHAZ of multipass welds, were studied. In addition, toughness and corrosion tests were done to evaluate the influence of the studied phase transformations on the weld behavior. A GleebleÒ system was used to do the heat treatments and HTHAZ simulations. The microstructures were analyzed by means of optic and electron microscopy. Along with the electron microscopy it was done chemical microanalysis of the studied phases. Based on results, it was verified that not all DSSs can be ferritized. This fact has a strong influence on metallurgical behavior and weldability of these alloys. Regarding to the metallurgical fundamental aspects of these steels, it was observed a remarkable interaction between secondary austenite and chromium nitride precipitation. Thus, it was proposed a mechanism of intragranular secondary austenite precipitation from chromium nitrides. It was also verified, how the deleterious effect of intragranular secondary austenite in the corrosion resistance can be avoided by means of appropriate welding procedures.
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AnÃlise Quantitativa da Fase FerrÃtica do AÃo inoxidÃvel Duplex UNS S3 1803 na CondiÃÃo Soldada / Quantitative Analysis of Phase Ferritic Duplex Stainless Steel UNS S3 1803 in Welded ConditionJohn Winston Abitibol Menezes 16 September 2005 (has links)
Em geral, os requisitos essenciais exigidos para uma liga metÃlica utilizada em
atividades ligadas à industria petroquÃmica sÃo resistÃncia mecÃnica, tendo em vista os diversos esforÃos aos quais os materiais serÃo submetidos, e resistÃncia à corrosÃo, devido a severidade ambiental ao qual os materiais serÃo expostos. O aÃo inoxidÃvel duplex (AID) vem conquistando cada vez mais espaÃo no setor petroquÃmico justamente por possuir tais requisitos citados acima. Atribuem-se suas altas resistÃncias à corrosÃo e mecÃnica à sua
microestrutura balanceada em aproximadamente 50% de ferrita e 50% de austenita. O presente trabalho estudou a influÃncia de diversas condiÃÃes de soldagem sobre o balanÃo de fases de um aÃo inoxidÃvel duplex UNS S31803. Para tanto quatro tÃcnicas de quantificaÃÃes foram utilizadas para medir a fraÃÃo volumÃtrica de ferrita para as diversas condiÃÃes empregadas. AlÃm disso, uma propriedade mecÃnica (dureza) e uma propriedade de resistÃncia à corrosÃo (corrosÃo intergranular) foram avaliadas em funÃÃo da energia de
soldagem empregada. Por fim, um estudo qualitativo acerca da precipitaÃÃo de compostos intermetÃlicos oriundos da soldagem foi realizado. Os resultados mostraram que o efeito da energia de soldagem sobre a fraÃÃo volumÃtrica de ferrita foi bem marcante no metal de solda, porÃm para a zona afetada pelo calor (ZAC) e o metal de base este efeito nÃo foi tÃo pronunciado. Ainda em relaÃÃo à fraÃÃo volumÃtrica de ferrita, foi constatado que esta à mais
afetado pela largura do corpo de prova que pelo meio de resfriamento pÃs-soldagem. Em geral, tanto a dureza como a resistÃncia à corrosÃo intergranular nÃo sofreram influÃncia quando as diversas condiÃÃes de soldagem foram comparadas. Por fim, apesar de ter ocorrido a precipitaÃÃo de compostos intermetÃlicos, contatou-se que esta foi de pequena intensidade. / In general, the essential requirements for a metal alloy used inactivities are linked to the petrochemical industry mechanical strength, in view of the many efforts to which the materials are subjected, and corrosion resistance due to severe environment to which the materials are exposed. The duplex stainless steel (AID) has been gaining more space in the petrochemical industry precisely because it has such requirements mentioned above. Are attributed to their high resistance to corrosion and its mechanical
balanced microstructure by approximately 50% to 50% ferrite and austenite. This work studied the influence of different welding conditions on the balance of phases of a duplex stainless steel UNS S31803. For both techniques of four measurements were used to measure the volume fraction of ferrite for the various conditions employed. Moreover, the mechanical properties (hardness) and corrosion resistance property (intergranular) were measured by the energy
welding employed. Finally, a qualitative study about the precipitation of intermetallic compounds derived welding was performed. The results showed that the effect of heat input on the volume fraction of ferrite was well marked in the weld metal, but for the heat-affected zone (HAZ) and base metal this effect was not as pronounced. Still on the volume fraction of ferrite, it was found that this is more
affected by the width of the body of evidence by means of cooling after welding. In general, both the hardness and resistance to intergranular corrosion when not influenced by the different welding conditions were compared. Finally, although there was precipitation of intermetallic compounds, is contacted to this was mild.
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Avaliação da tenacidade à fratura na zona termicamente afetada de soldas múltiplos passes em um aço ARBL / Evaluation of fracture toughness in heat affected zone of multiple pass welds in a high strength low alloy steelFalcão, César Augusto de Jesus 29 January 1997 (has links)
O presente trabalho avalia e compara os resultados da tenacidade à fratura da zona termicamente afetada (ZTA) de soldas múltiplos passes por meio de ensaios de CTOD. Para este estudo, foi utilizado um aço alta resistência e baixa liga (ARBL) resistente à corrosão ambiental. As soldas foram realizadas com insumo de calor de 30 e 50 kJ/cm em um chanfro 1/2 K. Os resultados dos ensaios de CTOD mostraram que a solda produzida com maior insumo de calor apresenta tenacidade à fratura mais elevada. A análise microestrutural revelou que as microestruturas de elevada dureza e baixa tenacidade, formadas na ZTA de granulação grosseira, para a condição de 30 kJ/cm, deram lugar às microestruturas de tenacidade mais elevada, para o insumo de calor de 50 kJ/cm. / In this work the fracture toughness results of the heat affected zone (HAZ) in a multiple pass welds using a crack tip opening displacement (CTOD) concept were evaluated and compared. It was used an ambiental resistent high strengh low alloy steel. The welds were carried out using a heat input of 30 and 50 kJ/cm in a bevel preparation 1/2 K. The results of CTOD testing showed that increasing heat input, caused an improvement in the weldments fracture toughness. Microstructural analysis revealed that the high hardness and low toughness microstructures formed at coarse grain HAZ, near fusion line, for welding condition 30 kJ/cm were changed to higher toughness microstructure using a heat input of 50 kJ/cm.
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Effects of Submerged Arc Weld (SAW) Parameters on Bead Geometry and Notch-Toughness for X70 and X80 Linepipe SteelsPepin, Joel Unknown Date
No description available.
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Microstructural Analysis of Linear Friction Welded Joint in Nickel-Base Inconel 738 SuperalloyOla, Oyedele Temitope 19 January 2011 (has links)
Inconel 738 (IN 738), like other precipitation-hardened nickel-base superalloys that contain a substantial amount of Al and Ti, is very difficult to weld due to its high susceptibility to heat-affected zone (HAZ) cracking during conventional fusion welding processes. The cause of this cracking, which is usually intergranular in nature, has been attributed to the liquation of various phases in the alloy, subsequent wetting of the grain boundaries by the liquid and decohesion along one of the solid-liquid interfaces due to on-cooling tensile stresses. To address the problem of liquation cracking in weldments, recent developments in welding research have resulted in supposedly exclusive solid-state friction joining processes, such as linear friction welding (LFW), for joining crack susceptible structural alloys. The objective of this work was therefore to investigate the weldability of the difficult-to-weld IN 738 superalloy by LFW and to analyze the resulting microstructural changes in the alloy due to the welding process. LFW was performed on Linear Friction Welding Process Development System (PDS) at the Aerospace Manufacturing Technology Centre of the Institute for Aerospace Research, National Research Council (NRC) of Canada. In order to study and decouple the effect of non-equilibrium thermal cycle and imposed compressive stress during the joining, physical simulation of the LFW process was performed by using Gleeble 1500-D Thermo-Mechanical Simulation System at the University of Manitoba. Detailed microstructural study of welded and Gleeble-simulated materials was carried out. Correlation between the simulated microstructure and that of the weldments was obtained, in that, a significant grain boundary liquation was observed in both the simulated specimens and actual weldments due to non-equilibrium reaction of second phase particles, including the strengthening gamma prime phase. These results show that in contrast to the general assumption of LFW being an exclusively solid-state joining process, intergranular liquation, caused by non-equilibrium phase reaction(s), occurred during the process. However, despite a significant occurrence of liquation in the alloy, no HAZ cracking was observed. Nevertheless, the result showed that crack-free welding by linear friction welding is not due to preclusion of grain boundary liquation as has been commonly assumed and reported. Instead, resistance to cracking can be related to the counter-crack-formation effect of the imposed strain and to a concept observed and reported for the first time in this work, which is strain-induced rapid solidification. Furthermore, microstructural evolution during joining cannot be understood without considering the concept of non-equilibrium liquation reaction and strain-induced rapid solidification of the metastable liquid, which are carefully elucidated in this thesis.
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Influence of weldiing modes to strength and residual of low carbon steel joints / Suvirinimo režimų įtaka mažaanglio plieno jungčių stiprumui ir liekamiesiems įtempimamsJohns Eyioma, Izuwah 17 June 2014 (has links)
In this study, microstructural, micro hardness evaluation and residual stress distribution, of low carbon steel after single pass gas metal arc welding technique (GMAW) were investigated. The goal of this investigation were to reveal the microstructures, micro hardness, residual stress distribution and tensile strength of welded joints by using welding current as varying parameter. In order to realize this objective, welded plate of low carbon steel with thickness of 2.5mm and 250mm long by 200mm wide were welded together with different welding current of 70A, 100A through MIG process. Four different parts of samples were tried. The first part of samples was annealed in a furnace to a temperature of 750 and allowed to cool in air before welding. While the second was not heated, third and fourth trials were heated to a temperature of 200˚C and 580˚C respectively after the welding and allowed cooling in air. Nikon optic microscope and CSM micro hardness testing instrument were used to determine the microstructure of the weld bead and HAZ of the samples, and hardness tests were carried out at different zones of welded joint.
Micro hardness behavior was observed by using CSM instrument using 20N load for indentation, which reveals the correlation between hardness, elasticity and plasticity on the heat affected zone (HAZ) and weld bead of the welded plates. The samples were subjected to tensile strength and the distribution of residual stress of the weld. Tensile strength test... [to full text] / Šiame darbe aprašomi mikrostruktūros, mikrokietumo nustatymo bei liekamųjų įtempimų pasiskirstymo tyrimai mažo anglingumo plienuose po lankinio suvirinimo. Tyrimo tiksla - nustatyti suvirintos jungties mikrostuktūros ir mikrokietųmo priklausomybę nuo suvirinimo srovės, kaip kintamo dydžio. Remiantis užduotimi buvo suvirintos 2.5 mm storio, 250 mm ilgio ir 200 mm pločio mažaanglio plieno plokštės, naudojant skirting dydžio (70A ir 100A) suvirininant apsauginių dujų aplinkoje (MIG) srovę. Buvo paruoštos keturios partijos bandinių. Pirmoji partija, proies suvirinant, buvo atkaitinta 750°C temperatųroje, ir ataušintas ore. Tuo tarpu antroji partija nebuvo apdorojama, o trečioji ir ketvirtoji atleista 200 C° ir 580°C temperatūroje ir atvėsinta ore. Suvirinimo vonelės ir erminio poveikio zonos mikrostruktūrai tirti bei mikrokietumui nustatyti buvo naudotas Nicon optinis mikroskopas bei CSM mikrokietumo bandymų įrenginys. Matuojant CSM įrenginiu, 20N įspaudimo apkrova, buvo pastebėtas įdomus kietuvo būvis, kuris atskleidė ryšį tarp kietumo, elastingumo ir plastiškumo esantį suvirintų plokštelių terminio poveikio zonoje bei suvirinimo vonelėje. Buvo matuojamas suvirintų bandinių stiprumas tempiant ir liekamųjų įtempimų pasiskirstymas. Tempimo stiprumo bandymų duomenys parodė ducharakteringus suirimo atvejus – plastiio-elastinio bei trapaus tipo. Liekamųjų įtempimų bandymų rezultati neparodė rėikšmingos liekamųjų įtempimų įtakos pasirinktomis sąlygomis suvirintuose bandiniuose.
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Microstructural Analysis of Linear Friction Welded Joint in Nickel-Base Inconel 738 SuperalloyOla, Oyedele Temitope 19 January 2011 (has links)
Inconel 738 (IN 738), like other precipitation-hardened nickel-base superalloys that contain a substantial amount of Al and Ti, is very difficult to weld due to its high susceptibility to heat-affected zone (HAZ) cracking during conventional fusion welding processes. The cause of this cracking, which is usually intergranular in nature, has been attributed to the liquation of various phases in the alloy, subsequent wetting of the grain boundaries by the liquid and decohesion along one of the solid-liquid interfaces due to on-cooling tensile stresses. To address the problem of liquation cracking in weldments, recent developments in welding research have resulted in supposedly exclusive solid-state friction joining processes, such as linear friction welding (LFW), for joining crack susceptible structural alloys. The objective of this work was therefore to investigate the weldability of the difficult-to-weld IN 738 superalloy by LFW and to analyze the resulting microstructural changes in the alloy due to the welding process. LFW was performed on Linear Friction Welding Process Development System (PDS) at the Aerospace Manufacturing Technology Centre of the Institute for Aerospace Research, National Research Council (NRC) of Canada. In order to study and decouple the effect of non-equilibrium thermal cycle and imposed compressive stress during the joining, physical simulation of the LFW process was performed by using Gleeble 1500-D Thermo-Mechanical Simulation System at the University of Manitoba. Detailed microstructural study of welded and Gleeble-simulated materials was carried out. Correlation between the simulated microstructure and that of the weldments was obtained, in that, a significant grain boundary liquation was observed in both the simulated specimens and actual weldments due to non-equilibrium reaction of second phase particles, including the strengthening gamma prime phase. These results show that in contrast to the general assumption of LFW being an exclusively solid-state joining process, intergranular liquation, caused by non-equilibrium phase reaction(s), occurred during the process. However, despite a significant occurrence of liquation in the alloy, no HAZ cracking was observed. Nevertheless, the result showed that crack-free welding by linear friction welding is not due to preclusion of grain boundary liquation as has been commonly assumed and reported. Instead, resistance to cracking can be related to the counter-crack-formation effect of the imposed strain and to a concept observed and reported for the first time in this work, which is strain-induced rapid solidification. Furthermore, microstructural evolution during joining cannot be understood without considering the concept of non-equilibrium liquation reaction and strain-induced rapid solidification of the metastable liquid, which are carefully elucidated in this thesis.
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Effects of Submerged Arc Weld (SAW) Parameters on Bead Geometry and Notch-Toughness for X70 and X80 Linepipe SteelsPepin, Joel 11 1900 (has links)
For the manufacture of higher strength pipelines to be feasible, a better understanding of the effects of welding on toughness is necessary. Bevel submerged arc welds were performed on X80 grade steel. The subsequent Charpy V-notch (CVN) test results indicated that the notch placement in the various heat affected zone regions, and hence the bead geometry, affected the test results. A series of bead-on-plate (BOP) submerged arc welds then were performed on X70 grade steel plate to determine the effects of current, voltage, heat input, polarity, and waveform manipulation (i.e., balance, offset, and frequency) on both single and tandem weld bead geometry. A new bead profile characteristic, the SP ratio, is proposed to describe weld bead geometry, and its relationship with welding parameters is discussed. Sub-size CVN specimens, pulled from many of the BOP weld coupons, were then tested. The greatest subsize CVN fracture energies were achieved when the bead was produced using lower heat input, and when the bead profile possessed a greater SP ratio. / Materials Engineering
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