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1	High Strain Rate Characterization of Advanced High Strength Steels Thompson, Alan January 2006 (has links) The current research has considered the characterization of the high strain rate constitutive response of three steels: a drawing quality steel (DDQ), a high strength low alloy steel (HSLA350), and a dual phase steel (DP600). The stress-strain response of these steels were measured at seven strain rates between 0. 003 s<sup>-1</sup> and 1500 s<sup>-1</sup> (0. 003, 0. 1, 30, 100, 500, 1000, and 1500 s<sup>-1</sup>) and temperatures of 21, 150, and 300 ??C. In addition, the steels were tested in both the undeformed sheet condition and the as-formed tube condition, so that tube forming effects could be identified. After the experiments were performed, the parameters of the Johnson-Cook and Zerilli-Armstrong constitutive models were fit to the results. <br /><br /> In order to determine the response of the steels at strain rates of 30 and 100 s<sup>-1</sup>, an intermediate rate tensile experiment was developed as part of this research using an instrumented falling weight impact facility (IFWI). An Instron tensile apparatus was used to perform the experiments at lower strain rates and a tensile split-Hopkinson bar was used to perform the experiments at strain rates above 500 s<sup>-1</sup> <br /><br /> A positive strain rate sensitivity was observed for each of the steels. It was found that, as the nominal strength of the steel increased, the strain rate sensitivity decreased. For an increase in strain rate from 0. 003 to 100 s<sup>-1</sup>, the corresponding increase in strength at 10% strain was found to be approximately 170, 130, and 110 MPa for DDQ, HSLA350, and DP600, respectively. <br /><br /> The thermal sensitivity was obtained for each steel as well, however no correlation was seen between strength and thermal sensitivity. For a rise in temperature from 21 to 300 ??C, the loss in strength at 10% strain was found to be 200, 225, and 195 MPa for DDQ, HSLA350, and DP600, respectively for the 6 o?clock tube specimens. <br /><br /> For all of the alloys, a difference in the stress ? strain behaviour was seen between the sheet and tube specimens due to the plastic work that was imparted during forming of the tube. For the DP600, the plastic work only affected the work-hardening response. <br /><br /> It was found that both the HSLA350 and DDQ sheet specimens exhibited an upper/lower yield stress that was amplified as the strain rate increased. Consequently the actual strength at 30 and 100 s<sup>-1</sup> was obscured and the data at strain rates above 500 s<sup>-1</sup> to be unusable for constitutive modeling. This effect was not observed in any of the tube specimens or the DP600 sheet specimens <br /><br /> For each of the steels, both the Johnson-Cook and Zerilli-Armstrong models fit the experimental data well; however, the Zerilli-Armstrong fit was slightly more accurate. Numerical models of the IFWI and the TSHB tests were created to assess whether the experimental results could be reproduced using the constitutive fits. Both numerical models confirmed that the constitutive fits were applied correctly. Mechanical Engineering strain rate steel dual phase high strength low alloy characterization
2	Estudo comparativo do efeito de diferentes arames de adição em juntas soldadas de aços de fase dupla no comportamento em fadiga por flexão Mezzomo, Tiago January 2015 (has links) Atualmente, no setor de máquinas agrícolas o uso de aços de alta resistência está começando a ganhar espaço e cada vez mais lembrado nos projetos estruturais; para atender as necessidades citadas acima e também para redução de emissão de poluentes. A utilização dos aços de alta resistência na indústria de implementos agrícolas está focada nos aços DP (Dual Phase), sendo este o objeto de estudo desta presente pesquisa. Este trabalho visa analisar o comportamento mecânico, priorizando a análise de resistência à fadiga em flexão de uniões soldadas através do processo de soldagem de metal de gás ativo (GMAW) utilizando dois tipos de arames como material de adição. Neste estudo foram utilizadas chapas metálicas de aços de alta resistência da marca DOCOL 1000 fabricado pela SSAB e os arames de adição fornecidos pela ESAB, sendo um usado largamente na indústria de maquinas agrícolas e o outro um fio especial desenvolvido para soldagem de aços de alta resistência e baixa liga. O processo de solda robotizada foi adotado para assegurar a homogeneidade dos cordões das juntas durante a obtenção das amostras. Para a análise das características mecânicas das amostras foi realizado o ensaio de flexão estático, caracterização macroestrutural, perfil de microdureza e ensaios de fadiga de flexão em quatro pontos. Os resultados mostraram que a vida em fadiga, por flexão em quatro pontos, nas juntas soldadas com o material de adição para aço carbono comum obteve uma melhor resposta em relação ao material de adição especial para soldagem de aços de alta resistência, porém pode-se verificar que ambas as curvas de fadiga respeitaram a curva de projeto conforme norma. / Nowadays, in the agricultural industry the use of high strength steels is being used each day more and more as well and increasingly coming in our mind in structural designs, to meet the requirements mentioned above and also to reduce the emission of pollutants. The highstrength steels application in the agricultural machinery industry is focused on the DP steels (Dual Phase), which is the subject of this present study. The focus of this work is analyze the mechanical behavior, prioritizing the deflection fatigue strength analysis on welded joints by Gas Metal Arc Welding (GMAW) process using two welding wire types. In this study it was used high strength steels sheet metal called DOCOL 1000, manufactured by SSAB and solder wires supplied by ESAB, and one widely used in the agricultural machinery industry for carbon steel welding and other a special wire developed for high strength. The robotic welding process was used to ensure the homogeneity of the weld bead on the samples manufacture process. For the mechanical characteristics analysis was done the static bending test, macrography, microhardness profile and deflection fatigue tests by four points. The results showed that the fatigue life, four-point bending, at welded joint used welding wire to carbon steel achieved a better result regarding a special welding wire to high strength steel, however, both fatigue curve respected project curve as British Standard. Aço de alta resistência Ensaios de fadiga Juntas soldadas High strength low alloy steel DP steel Welding Fatigue
3	Sulfide stress cracking resistance of API-X100 high strength low alloy steel in H2S environments Almansour, Mansour A. 05 1900 (has links) Sulfide Stress Cracking (SSC) resistance of the newly developed API-X100 High Strength Low Alloy (HSLA) steel was investigated in the NACE TM0177 "A" solution. The NACE TM0177 "A" solution is a hydrogen sulfide (H2S) saturated solution containing 5.0 wt.% sodium chloride (NaC1) and 0.5 wt.% acetic acid (CH3COOH). The aim of this thesis was to study the effect of microstructure, non-metallic inclusions and alloying elements of the X100 on H2S corrosion and SSC susceptibility. The study was conducted by means of electrochemical polarization techniques and constant load (proof ring) testing. Microstructural analysis and electrochemical polarization results for X100were compared with those for X80, an older generation HSLA steel. Uniaxial constant load SSC testing was conducted using X100 samples and the results were compared with those reported for older generation HSLA steels. Addition of H2S to the NACE TM0177 "A" solution increased the corrosion rate of X100from 51.6 to 96.7 mpy. The effect of H2S on the corrosion rate was similar for X80. The corrosion rate for X80 increased from 45.2 to 80.2 mpy when H2S was added to the test solution. Addition of H2S enhanced the anodic kinetics by forming a catalyst (FeHSads) on the metal surface and as a result, shifted the anodic polarization curve to more current densities. Moreover, the cathodic half cell potential increased due to the decrease in pH, from 2.9 to 2.7, which shifted the cathodic polarization curve to more current densities. The increase in both the anodic and cathodic currents, after H2S addition, caused the rise in the corrosion current density. In H2S saturated NACE TM-0177 "A" solution, the X100 steel corrosion rate was higher than the X80 steel by 20%. Longer phase boundaries and larger nonmetallic inclusions in the X100 microstructure generated more areas with dissimilar corrosion potentials and therefore, a stronger driving force for corrosion. Higher density of second phase regions and larger nonmetallic inclusions acted as an increased cathode area on the X100 surface which increased the cathodic current density and consequently, increased the corrosion current density. Proof ring tests on the X100 gave a threshold stress value, C5th, of 46% YS, 343.1 MPa(49.7 ksi). The main failure was caused by SSC cracking. SSC nucleated at corrosion pits on the metal surface and microcracks in the metal body and propagated perpendicular to the applied stress. Hydrogen Induced Cracking (HIC) was observed in the X100. HIC cracks nucleated at banded martensite-ferrite interfaces and propagated along the rolling direction parallel to the applied tensile stress through the softer ferrite phase. When compared to older HSLA grades, the X100 tested in this study had a high SSC susceptibility and therefore, is not be recommended for H2S service applications. The high X100 SSC susceptibility was caused by the material high corrosion rates in H2Smedia which formed corrosion pits that acted as crack initiation sites on the metal surface and provided more hydrogen that migrated into the steel. In addition, the X100 inhomogeneous microstructure provided a high density of hydrogen traps in front of the main crack tip which promoted SSC microcrack formation inside the metal. Microcracks in the metal body connected with the main crack tip that originated from corrosion pits which assisted SSC propagation. sulfide stress cracking SSC high strength low alloy microcrack microstructure non-metallic inclusions
4	High Strain Rate Characterization of Advanced High Strength Steels Thompson, Alan January 2006 (has links) The current research has considered the characterization of the high strain rate constitutive response of three steels: a drawing quality steel (DDQ), a high strength low alloy steel (HSLA350), and a dual phase steel (DP600). The stress-strain response of these steels were measured at seven strain rates between 0. 003 s<sup>-1</sup> and 1500 s<sup>-1</sup> (0. 003, 0. 1, 30, 100, 500, 1000, and 1500 s<sup>-1</sup>) and temperatures of 21, 150, and 300 °C. In addition, the steels were tested in both the undeformed sheet condition and the as-formed tube condition, so that tube forming effects could be identified. After the experiments were performed, the parameters of the Johnson-Cook and Zerilli-Armstrong constitutive models were fit to the results. <br /><br /> In order to determine the response of the steels at strain rates of 30 and 100 s<sup>-1</sup>, an intermediate rate tensile experiment was developed as part of this research using an instrumented falling weight impact facility (IFWI). An Instron tensile apparatus was used to perform the experiments at lower strain rates and a tensile split-Hopkinson bar was used to perform the experiments at strain rates above 500 s<sup>-1</sup> <br /><br /> A positive strain rate sensitivity was observed for each of the steels. It was found that, as the nominal strength of the steel increased, the strain rate sensitivity decreased. For an increase in strain rate from 0. 003 to 100 s<sup>-1</sup>, the corresponding increase in strength at 10% strain was found to be approximately 170, 130, and 110 MPa for DDQ, HSLA350, and DP600, respectively. <br /><br /> The thermal sensitivity was obtained for each steel as well, however no correlation was seen between strength and thermal sensitivity. For a rise in temperature from 21 to 300 °C, the loss in strength at 10% strain was found to be 200, 225, and 195 MPa for DDQ, HSLA350, and DP600, respectively for the 6 o?clock tube specimens. <br /><br /> For all of the alloys, a difference in the stress ? strain behaviour was seen between the sheet and tube specimens due to the plastic work that was imparted during forming of the tube. For the DP600, the plastic work only affected the work-hardening response. <br /><br /> It was found that both the HSLA350 and DDQ sheet specimens exhibited an upper/lower yield stress that was amplified as the strain rate increased. Consequently the actual strength at 30 and 100 s<sup>-1</sup> was obscured and the data at strain rates above 500 s<sup>-1</sup> to be unusable for constitutive modeling. This effect was not observed in any of the tube specimens or the DP600 sheet specimens <br /><br /> For each of the steels, both the Johnson-Cook and Zerilli-Armstrong models fit the experimental data well; however, the Zerilli-Armstrong fit was slightly more accurate. Numerical models of the IFWI and the TSHB tests were created to assess whether the experimental results could be reproduced using the constitutive fits. Both numerical models confirmed that the constitutive fits were applied correctly. Mechanical Engineering strain rate steel dual phase high strength low alloy characterization
5	Sulfide stress cracking resistance of API-X100 high strength low alloy steel in H2S environments Almansour, Mansour A. 05 1900 (has links) Sulfide Stress Cracking (SSC) resistance of the newly developed API-X100 High Strength Low Alloy (HSLA) steel was investigated in the NACE TM0177 "A" solution. The NACE TM0177 "A" solution is a hydrogen sulfide (H2S) saturated solution containing 5.0 wt.% sodium chloride (NaC1) and 0.5 wt.% acetic acid (CH3COOH). The aim of this thesis was to study the effect of microstructure, non-metallic inclusions and alloying elements of the X100 on H2S corrosion and SSC susceptibility. The study was conducted by means of electrochemical polarization techniques and constant load (proof ring) testing. Microstructural analysis and electrochemical polarization results for X100were compared with those for X80, an older generation HSLA steel. Uniaxial constant load SSC testing was conducted using X100 samples and the results were compared with those reported for older generation HSLA steels. Addition of H2S to the NACE TM0177 "A" solution increased the corrosion rate of X100from 51.6 to 96.7 mpy. The effect of H2S on the corrosion rate was similar for X80. The corrosion rate for X80 increased from 45.2 to 80.2 mpy when H2S was added to the test solution. Addition of H2S enhanced the anodic kinetics by forming a catalyst (FeHSads) on the metal surface and as a result, shifted the anodic polarization curve to more current densities. Moreover, the cathodic half cell potential increased due to the decrease in pH, from 2.9 to 2.7, which shifted the cathodic polarization curve to more current densities. The increase in both the anodic and cathodic currents, after H2S addition, caused the rise in the corrosion current density. In H2S saturated NACE TM-0177 "A" solution, the X100 steel corrosion rate was higher than the X80 steel by 20%. Longer phase boundaries and larger nonmetallic inclusions in the X100 microstructure generated more areas with dissimilar corrosion potentials and therefore, a stronger driving force for corrosion. Higher density of second phase regions and larger nonmetallic inclusions acted as an increased cathode area on the X100 surface which increased the cathodic current density and consequently, increased the corrosion current density. Proof ring tests on the X100 gave a threshold stress value, C5th, of 46% YS, 343.1 MPa(49.7 ksi). The main failure was caused by SSC cracking. SSC nucleated at corrosion pits on the metal surface and microcracks in the metal body and propagated perpendicular to the applied stress. Hydrogen Induced Cracking (HIC) was observed in the X100. HIC cracks nucleated at banded martensite-ferrite interfaces and propagated along the rolling direction parallel to the applied tensile stress through the softer ferrite phase. When compared to older HSLA grades, the X100 tested in this study had a high SSC susceptibility and therefore, is not be recommended for H2S service applications. The high X100 SSC susceptibility was caused by the material high corrosion rates in H2Smedia which formed corrosion pits that acted as crack initiation sites on the metal surface and provided more hydrogen that migrated into the steel. In addition, the X100 inhomogeneous microstructure provided a high density of hydrogen traps in front of the main crack tip which promoted SSC microcrack formation inside the metal. Microcracks in the metal body connected with the main crack tip that originated from corrosion pits which assisted SSC propagation. sulfide stress cracking SSC high strength low alloy microcrack microstructure non-metallic inclusions
6	Estudo comparativo do efeito de diferentes arames de adição em juntas soldadas de aços de fase dupla no comportamento em fadiga por flexão Mezzomo, Tiago January 2015 (has links) Atualmente, no setor de máquinas agrícolas o uso de aços de alta resistência está começando a ganhar espaço e cada vez mais lembrado nos projetos estruturais; para atender as necessidades citadas acima e também para redução de emissão de poluentes. A utilização dos aços de alta resistência na indústria de implementos agrícolas está focada nos aços DP (Dual Phase), sendo este o objeto de estudo desta presente pesquisa. Este trabalho visa analisar o comportamento mecânico, priorizando a análise de resistência à fadiga em flexão de uniões soldadas através do processo de soldagem de metal de gás ativo (GMAW) utilizando dois tipos de arames como material de adição. Neste estudo foram utilizadas chapas metálicas de aços de alta resistência da marca DOCOL 1000 fabricado pela SSAB e os arames de adição fornecidos pela ESAB, sendo um usado largamente na indústria de maquinas agrícolas e o outro um fio especial desenvolvido para soldagem de aços de alta resistência e baixa liga. O processo de solda robotizada foi adotado para assegurar a homogeneidade dos cordões das juntas durante a obtenção das amostras. Para a análise das características mecânicas das amostras foi realizado o ensaio de flexão estático, caracterização macroestrutural, perfil de microdureza e ensaios de fadiga de flexão em quatro pontos. Os resultados mostraram que a vida em fadiga, por flexão em quatro pontos, nas juntas soldadas com o material de adição para aço carbono comum obteve uma melhor resposta em relação ao material de adição especial para soldagem de aços de alta resistência, porém pode-se verificar que ambas as curvas de fadiga respeitaram a curva de projeto conforme norma. / Nowadays, in the agricultural industry the use of high strength steels is being used each day more and more as well and increasingly coming in our mind in structural designs, to meet the requirements mentioned above and also to reduce the emission of pollutants. The highstrength steels application in the agricultural machinery industry is focused on the DP steels (Dual Phase), which is the subject of this present study. The focus of this work is analyze the mechanical behavior, prioritizing the deflection fatigue strength analysis on welded joints by Gas Metal Arc Welding (GMAW) process using two welding wire types. In this study it was used high strength steels sheet metal called DOCOL 1000, manufactured by SSAB and solder wires supplied by ESAB, and one widely used in the agricultural machinery industry for carbon steel welding and other a special wire developed for high strength. The robotic welding process was used to ensure the homogeneity of the weld bead on the samples manufacture process. For the mechanical characteristics analysis was done the static bending test, macrography, microhardness profile and deflection fatigue tests by four points. The results showed that the fatigue life, four-point bending, at welded joint used welding wire to carbon steel achieved a better result regarding a special welding wire to high strength steel, however, both fatigue curve respected project curve as British Standard. Aço de alta resistência Ensaios de fadiga Juntas soldadas High strength low alloy steel DP steel Welding Fatigue
7	Estudo comparativo do efeito de diferentes arames de adição em juntas soldadas de aços de fase dupla no comportamento em fadiga por flexão Mezzomo, Tiago January 2015 (has links) Atualmente, no setor de máquinas agrícolas o uso de aços de alta resistência está começando a ganhar espaço e cada vez mais lembrado nos projetos estruturais; para atender as necessidades citadas acima e também para redução de emissão de poluentes. A utilização dos aços de alta resistência na indústria de implementos agrícolas está focada nos aços DP (Dual Phase), sendo este o objeto de estudo desta presente pesquisa. Este trabalho visa analisar o comportamento mecânico, priorizando a análise de resistência à fadiga em flexão de uniões soldadas através do processo de soldagem de metal de gás ativo (GMAW) utilizando dois tipos de arames como material de adição. Neste estudo foram utilizadas chapas metálicas de aços de alta resistência da marca DOCOL 1000 fabricado pela SSAB e os arames de adição fornecidos pela ESAB, sendo um usado largamente na indústria de maquinas agrícolas e o outro um fio especial desenvolvido para soldagem de aços de alta resistência e baixa liga. O processo de solda robotizada foi adotado para assegurar a homogeneidade dos cordões das juntas durante a obtenção das amostras. Para a análise das características mecânicas das amostras foi realizado o ensaio de flexão estático, caracterização macroestrutural, perfil de microdureza e ensaios de fadiga de flexão em quatro pontos. Os resultados mostraram que a vida em fadiga, por flexão em quatro pontos, nas juntas soldadas com o material de adição para aço carbono comum obteve uma melhor resposta em relação ao material de adição especial para soldagem de aços de alta resistência, porém pode-se verificar que ambas as curvas de fadiga respeitaram a curva de projeto conforme norma. / Nowadays, in the agricultural industry the use of high strength steels is being used each day more and more as well and increasingly coming in our mind in structural designs, to meet the requirements mentioned above and also to reduce the emission of pollutants. The highstrength steels application in the agricultural machinery industry is focused on the DP steels (Dual Phase), which is the subject of this present study. The focus of this work is analyze the mechanical behavior, prioritizing the deflection fatigue strength analysis on welded joints by Gas Metal Arc Welding (GMAW) process using two welding wire types. In this study it was used high strength steels sheet metal called DOCOL 1000, manufactured by SSAB and solder wires supplied by ESAB, and one widely used in the agricultural machinery industry for carbon steel welding and other a special wire developed for high strength. The robotic welding process was used to ensure the homogeneity of the weld bead on the samples manufacture process. For the mechanical characteristics analysis was done the static bending test, macrography, microhardness profile and deflection fatigue tests by four points. The results showed that the fatigue life, four-point bending, at welded joint used welding wire to carbon steel achieved a better result regarding a special welding wire to high strength steel, however, both fatigue curve respected project curve as British Standard. Aço de alta resistência Ensaios de fadiga Juntas soldadas High strength low alloy steel DP steel Welding Fatigue
8	Sulfide stress cracking resistance of API-X100 high strength low alloy steel in H2S environments Almansour, Mansour A. 05 1900 (has links) Sulfide Stress Cracking (SSC) resistance of the newly developed API-X100 High Strength Low Alloy (HSLA) steel was investigated in the NACE TM0177 "A" solution. The NACE TM0177 "A" solution is a hydrogen sulfide (H2S) saturated solution containing 5.0 wt.% sodium chloride (NaC1) and 0.5 wt.% acetic acid (CH3COOH). The aim of this thesis was to study the effect of microstructure, non-metallic inclusions and alloying elements of the X100 on H2S corrosion and SSC susceptibility. The study was conducted by means of electrochemical polarization techniques and constant load (proof ring) testing. Microstructural analysis and electrochemical polarization results for X100were compared with those for X80, an older generation HSLA steel. Uniaxial constant load SSC testing was conducted using X100 samples and the results were compared with those reported for older generation HSLA steels. Addition of H2S to the NACE TM0177 "A" solution increased the corrosion rate of X100from 51.6 to 96.7 mpy. The effect of H2S on the corrosion rate was similar for X80. The corrosion rate for X80 increased from 45.2 to 80.2 mpy when H2S was added to the test solution. Addition of H2S enhanced the anodic kinetics by forming a catalyst (FeHSads) on the metal surface and as a result, shifted the anodic polarization curve to more current densities. Moreover, the cathodic half cell potential increased due to the decrease in pH, from 2.9 to 2.7, which shifted the cathodic polarization curve to more current densities. The increase in both the anodic and cathodic currents, after H2S addition, caused the rise in the corrosion current density. In H2S saturated NACE TM-0177 "A" solution, the X100 steel corrosion rate was higher than the X80 steel by 20%. Longer phase boundaries and larger nonmetallic inclusions in the X100 microstructure generated more areas with dissimilar corrosion potentials and therefore, a stronger driving force for corrosion. Higher density of second phase regions and larger nonmetallic inclusions acted as an increased cathode area on the X100 surface which increased the cathodic current density and consequently, increased the corrosion current density. Proof ring tests on the X100 gave a threshold stress value, C5th, of 46% YS, 343.1 MPa(49.7 ksi). The main failure was caused by SSC cracking. SSC nucleated at corrosion pits on the metal surface and microcracks in the metal body and propagated perpendicular to the applied stress. Hydrogen Induced Cracking (HIC) was observed in the X100. HIC cracks nucleated at banded martensite-ferrite interfaces and propagated along the rolling direction parallel to the applied tensile stress through the softer ferrite phase. When compared to older HSLA grades, the X100 tested in this study had a high SSC susceptibility and therefore, is not be recommended for H2S service applications. The high X100 SSC susceptibility was caused by the material high corrosion rates in H2Smedia which formed corrosion pits that acted as crack initiation sites on the metal surface and provided more hydrogen that migrated into the steel. In addition, the X100 inhomogeneous microstructure provided a high density of hydrogen traps in front of the main crack tip which promoted SSC microcrack formation inside the metal. Microcracks in the metal body connected with the main crack tip that originated from corrosion pits which assisted SSC propagation. / Applied Science, Faculty of / Materials Engineering, Department of / Graduate sulfide stress cracking SSC high strength low alloy microcrack microstructure non-metallic inclusions
9	Influence of Fine-scale Niobium Carbonitride Precipitates on Hydrogen-Induced Cracking of X70 Pipeline Steel Wojnas, Caroline Theresa January 2021 (has links) The microstructure of steel is well known to affect hydrogen-induced cracking (HIC) susceptibility by having certain heterogeneities serving as effective hydrogen trap sites. A consensus on whether or not fine-scale niobium carbide (NbC), nitride (NbN) and carbonitride (Nb(C,N)) precipitates can behave as effective hydrogen traps has yet to be established. The H-trapping capacity of Nb precipitates in a Fe-C-Mn-Nb model steel was investigated with the goal of minimizing embrittlement effects and improving the design of X70 pipeline grade steel for sour service oil and gas applications. First, a heat treatment was applied to the model steel to change the Nb-based precipitate size distribution, which was subsequently characterized via transmission electron microscopy, electron energy loss spectroscopy, and atom probe tomography. The experimental heat treatment increased the number of fine-scale precipitates (<15 nm) that are ideal for APT characterization. NbN and NbC precipitates of various stoichiometries were confirmed within the steel. Further, a custom electrolytic H-charging device was designed, fabricated, and validated using thermal desorption spectroscopy. Additionally, the extent of galvanic corrosion between NbC and NbN and the steel matrix was determined using custom scaled-up particle matrix specimens. Potentiodynamic polarizations conducted using active and passivating electrolytes revealed the relative nobility of the materials. Both NbC and NbN particles were more noble than the steel matrix; thus, possessing driving force for galvanic corrosion, with the particles serving as cathodes. Future studies involving electrolytic charging of the steel in a D-based electrolyte coupled with atom probe tomography will facilitate the direct observation of H-trapping sites relative to various Nb-based precipitates and contribute to an improved understanding of the mechanisms governing HIC. / Thesis / Master of Science in Materials Science and Engineering (MSMSE) Corrosion resistance Hydrogen-induced cracking (HIC) High strength low alloy (HSLA) Nb content
10	Estudo do comportamento mecânico de juntas soldadas de um aço de alta resistência mecânica Carlesso, Rodrigo January 2017 (has links) A aplicação de aços de alta resistência está fortemente difundida na indústria mecânica, principalmente em aplicações onde a redução de peso é importante, como por exemplo, a indústria de implementos rodoviários e maquinários agrícolas. Esta dissertação visa analisar a influência de diferentes aportes térmicos no comportamento microestrutural e mecânico de juntas soldadas através do processo MAG de modo a obter juntas com propriedades otimizadas. Para este estudo foram utilizadas chapas metálicas com espessura de 3 mm do aço de alta resistência e baixa liga USI LNE700. Os parâmetros nominais de energia de soldagem foram variados de acordo com os valores descritos pelo fornecedor SSAB. O processo de soldagem foi realizado com o auxílio de um sistema robotizado para manter a homogeneidade ao longo da junta, distância e posicionamento correto no comprimento total da junta soldada. Os ensaios para verificação do comportamento microestrutural e mecânico foram realizados com auxílio de microscopia ótica, perfis de microdureza e ensaios de tração. Buscaram-se utilizar aportes térmicos reduzidos para minimizar os efeitos de revenimento da martensita presente no metal de base, um dos principais responsáveis pela redução das propriedades mecânicas da junta soldada. Os resultados não mostraram significativa variações na microestrutura e propriedades de tração do material, porém o preenchimento da junta soldada formada apresenta um comportamento diretamente proporcional à energia de soldagem. / The application of high strength steels is strongly diffused in the engineering industry, especially in applications where weight reduction is important, such as the industry of agricultural machines and trailers industry. This investigation aims to analyze the influence of different heat inputs on microstructural and mechanical behavior of joint welded by GMAW in order to obtain joints with optimized properties. Sheet metal with a thickness of 3 mm high strength low alloy steel LNE700 (supplier Usiminas) were used. The welding energy was varied around the nominal value informed by the steel supplier SSAB for this study. The welding process was made using robotic system to maintain homogeneity along the joint, right distance and position during the total weld joint length. The microstructural and mechanical behaviors were performed with the optical microscope, microhardness profile and traction test. We attempted to use lower heat inputs to minimize the effects of tempering of martensite present in the base metal, a major contributor to the reduction of the mechanical properties of the welded joint. The results did not show significant microestructural and tensile properties variation, however, when the welding energy is increased, the welded joint penetration formed was increased as well. Soldagem MIG/MAG Chapas de aço Aço de alta resistência Welding GMAW High strength low alloy steel Tensile test Micro hardness profile

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