Análise da influência das temperaturas de preaquecimento e TTPS na microestrutura e propriedades mecânicas da ZAC do aço AISI 4130 soldado por SAW / Analysis of the influence of the preheating temperature and PWHT on microstructure and mechanical properties of HAZ of steel AISI 4130 welded by SAW

Silva, Fernando Fernandes da

04 January 2019

Atualmente, há a necessidade de se desenvolver aços com alta resistência à propagação de trincas, especialmente em condições de carregamentos cíclicos, ou seja, resistentes à fadiga, na qual sua aplicabilidade se da em função de suas propriedades mecânicas. No presente trabalho estudou-se o efeito do preaquecimento na zona afetada pelo calor do aço AISI/SAE 4130 com composição química modificada, com altos teores de Mo, comparando as propriedades mecânicas e microestruturais nas condições como soldada, tratada termicamente e aplicando a técnica de Metodologia do Preaquecimento Combinado (MPC) com otimização de ciclos térmicos através da combinação do preaquecimento entre o 1º e 3º passe da 1º e 2º camada, respectivamente. A fim de avaliar as propriedades mecânicas, foram realizados ensaios de microdureza, mapeamento de dureza e ensaio de tenacidade ao impacto charpy. Para análise microestrutural, foi realizado microscopia ótica e microscópio eletrônico de varredura (MEV) para analisar as regiões de grãos grosseiros, fino e as intersecções entre as regiões da Zona Afetada pelo Calor (ZAC), quando aplicado o MPC. Como resultado, observa-se que preaquecimento é uma forma efetiva de redução de dureza, chegando a uma redução máxima de 71 HV0,1, quando comparado às temperaturas de preaquecimento entre 150 e 400 ºC. No entanto há um severo efeito deletério na tenacidade, podendo chegar a uma queda de 71% da energia absorvida. O tratamento térmico pós soldagem (TTPS) se mostrou eficiente apenas para amostra soldada com temperaturas de preaquecimento de 150 ºC, para as demais temperaturas não houve benefício, tanto em redução de dureza, quanto na restauração da tenacidade. No entanto, para temperatura de preaquecimento de 230 ºC também foi observado o acréscimo de dureza após o TTPS devido ao efeito de endurecimento secundário por precipitação de carbonetos metálicos (MC). A técnica MPC se mostrou muito eficiente em redução da dureza e restauração da tenacidade, e este fenômeno está associado à capacidade de solubilizar os carbonetos que precipitam durante a soldagem, fenômeno que não ocorre com a aplicação do TTPS. / Currently, it is necessary to develop materials with high resistance to crack propagation, especially under conditions of cyclic loading condition such as fatigue resistant, in which its applicability is due to its mechanical properties. In the present work the effect of preheating in the heat-affected zone of the AISI / SAE 4130 steel with modified chemical composition (High Mo) was compared, regarding its mechanical and microstructural properties of each welding condition, As weld, post weld heat treated and applying the Methodology of combined preheating (MCP) with optimization of thermal cycles by combining the preheating between the 1st pass of 1st layer and the 3rd pass of 2nd layer. In order to evaluate the mechanical properties, microhardness tests, hardness mapping and charpy V notch tests were performed. For microstructural analysis, optical and scanning electron microscopy (SEM) were used to analyze the coarse grained regions and the intersections between the Heat Affected Zones (HAZ) regions, when applied to the MPC. As a result, it is observed that preheating is an effective form of reduction of hardness, reaching a maximum reduction of 71 HV0,1, when compared to the preheating temperatures between 150 and 400ºC, however there is a severe deleterious effect in the toughness, dropping up to 71% of the absorbed energy. The post weld heat treatment (PWHT) is efficient only for welded sample with preheating temperatures of 150 ºC, for the other temperatures there was no benefit, either in reduction of hardness or restoration of toughness. However, for the preheating temperature of 230 °C it was observed the increase of hardness after the PWHT due to the effect of secondary hardening by precipitation of metal carbides (MC). The MPC technique proved to be very efficient in decreasing hardness and restoring toughness, and this phenomenon is associated with the ability to solubilize the carbides that precipitate during welding, which is not observed while PWHT is applied.

Bead on pipe

Endurecimento secundário

Higuchi methodology

Metodologia de Higuchi

Post weld heat treatment (PWHT)

Preaquecimento

Preheating

Secondary hardening

Soldagem sobre tubo

Tratamento térmico pós-soldagem

Soldagem de chapas grossas em aço baixa liga temperado e revenido ASTM A514 com aço carbono ASTM A36 pelo processo arame tubular / Welding of ASTM A514 quenched and tempered low alloy steel thick plates with ASTM A36 carbon steel by FCAW process

Marcello Ferrari

09 December 2016

Neste trabalho foram determinadas as condições para a soldagem de chapas grossas de aço carbono ASTM A36 com aço baixo-liga temperado e revenido ASTM A514 Grau Q empregando-se o processo arame tubular. Para tanto foram soldadas diversas peças de testes com o intuito de se avaliar as condições mais adequadas de preparação e soldagem de juntas dissimilares destes materiais. A preparação foi realizada por meio de corte térmico. A temperatura de preaquecimento foi determinada através de modelos matemáticos, pelas recomendações das normas AWS D1.1 e DIN EN 1011-2 sendo posteriormente avaliada por intermédio do teste de soldabilidade tipo CTS Controlled Thermal Severity. Os parâmetros de soldagem foram determinados a partir da qualificação de um procedimento de soldagem, conforme a norma AWS D1.1. Foram avaliadas as consequências do emprego do tratamento térmico de alívio de tensões após soldagem (TTAT), pelos testes de dureza Vickers e impacto Charpy. A caracterização microestrutural foi realizada por meio de microscopia óptica e microscopia eletrônica de varredura. A caracterização das superfícies oxicortadas evidenciou os efeitos da descarbonetação e também da carbonetação. A temperatura de pré-aquecimento de 160°C determinada por meio da metodologia recomendada pelas normas AWS D1.1 e DIN EN 1011-2 mostrou-se satisfatória nos testes de soldabilidade. Foi possível a qualificação do procedimento de soldagem (EPS) com requisitos de impacto na condição \"como soldado\", porém na condição \"após TTAT\", os baixos valores de tenacidade obtidos no metal de solda, inferiores a 27J, não permitiram a qualificação de uma EPS com requisitos de impacto. Foi observada a ausência de trincas intergranulares tanto na zona afetada pelo calor quanto no metal de base ASTM A514, porém foi revelada a presença de microfases frágeis no metal de solda na condição \"como soldado\", especificamente na região da raiz, intensificadas pelo efeito da diluição. O aumento do teor de carbono na raiz, a presença de microfases frágeis, a grande fração de grãos colunares e de ferrita proeutetóide combinados com a baixa fração de ferrita acicular no metal de solda contribuíram para os baixos valores de tenacidade encontrados na condição \"como soldado\". Após o TTAT observou-se uma queda acentuada da tenacidade, inferior a 27J, do metal de solda devido à fragilização provocada pela precipitação e coalescimento de carbonetos de ferro. / In this work it was determined the conditions for welding thick plate of ASTM A36 carbon steel with quenched and tempered low-alloy steel ASTM A514 Grade Q employing the Flux Cored Arc Welding (FCAW) process. For that several coupons of tests were welded in order to evaluate the most appropriate conditions for preparation and welding of these dissimilar materials. The preparation was carried out by means of thermal cutting. The preheat temperature was determined by mathematical models, the recommendations of standards AWS D1.1 and DIN EN 1011-2 being further evaluated using the CTS type weldability test - Controlled Thermal Severity. The welding parameters were determined by qualifying a welding procedure (WPS), according to AWS D1.1. The effects of post weld heat treatment (PWHT) were evaluated by Vickers hardness tests and Charpy. Microstructural characterization was performed by optical microscopy and scanning electron microscopy. The characterization of oxi-fuel cut surfaces showed the effects of decarburization and also carburization. The preheating temperature of 160 °C determined by calculation and the methodology recommended by the standards was satisfactory in weldability tests. It was possible qualification of welding procedure (WPS) with impact requirements in the condition \"as welded\" but the condition \"after PWHT\" low toughness values obtained in the weld metal, less than 27J, did not allow to qualify a WPS with toughness requirements. The absence of intergranular cracking was observed in both the heat affected zone as the base metal ASTM A514, but the presence of fragile microphase in the weld metal was revealed in the weld metal in the condition \"as welded\" specifically in the root region, intensified by the effect of dilution. The carbon increase at root, the presence of fragile microphase, the large fraction of columnar grains and proeutectoid ferrite combined with the low fraction of acicular ferrite in the weld metal contributed to the low toughness values found in the condition \"as welded \". After PWHT there was a sharp drop in toughness, less than 27J, in the weld metal due to embrittlement caused by precipitation and coarsening of iron carbides.

ASTM A514

juntas de aços dissimilares

soldagem de chapas grossas

ASTM A514

dissimilar steels welded joints

post weld heat treatment

thick plates welding

Microstructure and properties of welds in the lean duplex stainless steel LDX 2101

Westin, Elin M.

January 2010

Duplex stainless steels can be very attractive alternatives to austenitic grades due to their almost double strength at equal pitting corrosion resistance. When welding, the duplex alloys normally require addition of filler metal, while the commodity austenitic grades can often be welded autogenously. Over-alloyed consumables are used to counteract segregation of important alloying elements and to balance the two phases, ferrite and austenite, in the duplex weld metal. This work focuses on the weldability of the recently-developed lean duplex stainless steel LDX 2101® (EN 1.4162, UNS S32101). The pitting corrosion resistance of this grade is better than that of austenitic AISI 304 (EN 1.4307) and can reach the level of AISI 316L (EN 1.4404). The austenite formation is rapid in LDX 2101 compared to older duplex grades. Pitting resistance tests performed show that 1-2.5 mm thick laser and gas tungsten arc (GTA) welded LDX 2101 can have good corrosion properties even when welding autogenously. Additions of filler metal, nitrogen in the shielding gas, nitrogen-based backing gas and use of laser hybrid welding methods, however, increase the austenite formation. The pitting resistance may also be increased by suppressing formation of chromium nitrides in the weld metal and heat affected zone (HAZ). After thorough post-weld cleaning (pickling), pitting primarily occurred 1-3 mm from the fusion line, in the parent metal rather than in the HAZ. Neither the chromium nitride precipitates found in the HAZ, nor the element depletion along the fusion line that was revealed by electron probe microanalysis (EPMA) were found to locally decrease the pitting resistance. The preferential pitting location is suggested to be controlled by the residual weld oxide composition that varies over the surface. The composition and thickness of weld oxide formed on LDX 2101 and 2304 (EN 1.4362, UNS S32304) were determined using X-ray photoelectron spectroscopy (XPS). The heat tint on these lean duplex grades proved to contain significantly more manganese than what has been reported for standard austenitic stainless steels in the AISI 300 series. A new approach to heat tint formation is presented; whereby evaporation of material from the weld metal and subsequent deposition on the already-formed weld oxide are suggested to contribute to weld oxide formation. This is consistent with manganese loss from the weld metal, and nitrogen additions to the GTA shielding gas enhance the evaporation. The segregation of all elements apart from nitrogen is low in autogenously welded LDX 2101. This means that filler wire additions may not be required as for other duplex grades assuming that there is no large nitrogen loss that could cause excessive ferrite contents. As the nitrogen appears to be controlling the austenite formation, it becomes essential to avoid losing nitrogen during welding by choosing nitrogen-containing shielding and backing gas. / QC 20101213

Duplex stainless steel

welding

HAZ

nitrogen

manganese

microstructure

austenite formation

phase balance

precipitates

element distribution

segregation

depletion

solidification

pitting corrosion resistance

solidification

element loss

evaporation

deposition

weld oxide

thermo-mechanical simulation

thermodynamic modelling

EPMA

XPS

post-weld cleaning

pickling

Welds in the lean duplex stainless steel LDX 2101 : effect of microstructure and weld oxide on corrosion properties

Westin, Elin M.

January 2008

<p>Duplex stainless steels are a very attractive alternative to austenitic grades due to their higher strength and good corrosion performance. The austenitic grades can often be welded autogenously, while the duplex grades normally require addition of filler metal. This is to counteract segregation of important alloying elements and to give sufficient austenite formation to prevent precipitation of chromium nitrides that could have a negative effect on impact toughness and pitting resistance. The corrosion performance of the recently-developed lean duplex stainless steel LDX 2101 is higher than that of 304 and can reach the level of 316. This thesis summarises pitting resistance tests performed on laser and gas tungsten arc (GTA) welded LDX 2101. It is shown here that this material can be autogenously welded, but additions of filler metal, nitrogen in the shielding gas and use of hybrid methods increases the austenite formation and the pitting resistance by further suppressing formation of chromium nitride precipitates in the weld metal. If the weld metal austenite formation is sufficient, the chromium nitride precipitates in the heat-affected zone (HAZ) could cause local pitting, however, this was not seen in this work. Instead, pitting occurred 1–3 mm from the fusion line, in the parent metal rather than in the high temperature HAZ (HTHAZ). This is suggested here to be controlled by the heat tint, and the effect of residual weld oxides on the pitting resistance is studied. The composition and the thickness of weld oxide formed on LDX 2101 and 2304 were determined using X-ray photoelectron spectroscopy (XPS). The heat tint on these lean duplex grades proved to contain significantly more manganese than what has been reported for standard austenitic stainless steels in the 300 series. A new approach on heat tint formation is consequently presented. Evaporation of material from the weld metal and subsequent deposition on the weld oxide are suggested to contribute to weld oxide formation. This is supported by element loss in LDX 2101 weld metal, and nitrogen additions to the GTA shielding gas further increase the evaporation.</p><p> </p>

Duplex stainless steel

welding

weld metal

HAZ

nitrogen

manganese

austenite formation

phase balance

precipitates

pitting resistance

heat input

solidification

element loss

evaporation

deposition

weld oxides

discoloration

mechanical properties

thermo-mechanical simulation

Geeble

GTA

laser

LOM

SEM

EDS

TEM

Leco

EPMA

ferroxyl test

XPS

post weld cleaning

pickling

Materials science

Teknisk materialvetenskap

Heat Affected Zone Cracking of Allvac 718Plus Superalloy during High Power Beam Welding and Post-weld Heat Treatment

Idowu, Oluwaseun Ayodeji

08 April 2010

The present dissertation reports the findings of a study of cracking behavior of a newly developed superalloy, Allvac 718Plus during high power beam welding and post-weld heat treatment. Microstructures of the base alloy, heat affected zone (HAZ) and fusion zone (FZ) of welded and post-weld heat treated (PWHT) coupons were examined by the use of standard metallographic techniques involving optical microscopy, analytical scanning electron microscopy (SEM) and analytical transmission electron microscopy. Moreover, grain boundary segregation behavior of boron atoms during pre-weld heat treatments was evaluated using secondary ion mass spectroscopic system. In the first phase of the research, 718Plus was welded using a low and high heat input CO2 laser to assess its weld cracking response. Detailed examination of the welds by analytical electron microscopic technique revealed the occurrence of cracking in the HAZ of low heat input welds, while their FZ was crack free. However, both the FZ and HAZ of high heat input welds were crack-free. Resolidified constituents were observed along the cracked grain boundaries of the lower heat input welds, which indicated that HAZ cracking in this newly developed superalloy was associated with grain boundary liquation. However, despite a more extensive liquation of grain boundaries and grain interior in the HAZ of high heat input welds, no cracking occurred. This was attributed to the combination of lower welding stresses generated during cooling, and relaxation of these stresses by thick intergranular liquid. Although HAZ cracking was prevented by welding with a high heat input laser, it resulted in a significant damage to the parent microstructure through its extensive liquation. Thus, the use of low heat input welding is desirable. However, this resulted in HAZ cracking which needs to be minimized or eliminated. Therefore, during the second phase of this research, the effects of pre-weld thermal processing on the cracking response of 718Plus were investigated. Results from the quantification of the cracking of the alloy showed that HAZ cracking may be significantly reduced or eliminated through an adequate selection of pre-weld thermal cycle. In the third stage of this research, crack-free welds of 718Plus were post-weld heat treated using standard thermal schedules. A significant solid state cracking of the alloy occurred during the PWHT. The cracking was attributed to the presence of embrittling phases on HAZ grain boundaries, coupled with aging contraction stresses that are generated by a considerable precipitation of gamma prime phase during aging.

Allvac 718Plus

Inconel 718

Superalloy

Boron

Grain boundary segregation

SIMS

Welding

Heat affected zone cracking

Microstructural analysis

Heat treatment

Electron beam welding

Laser beam welding

Post weld heat treatment cracking

Constitutional liquation

Grain size

Weld heat input

Gamma prime

Liquid film migration

HAZ cracking

Heat Affected Zone Cracking of Allvac 718Plus Superalloy during High Power Beam Welding and Post-weld Heat Treatment

Idowu, Oluwaseun Ayodeji

08 April 2010

The present dissertation reports the findings of a study of cracking behavior of a newly developed superalloy, Allvac 718Plus during high power beam welding and post-weld heat treatment. Microstructures of the base alloy, heat affected zone (HAZ) and fusion zone (FZ) of welded and post-weld heat treated (PWHT) coupons were examined by the use of standard metallographic techniques involving optical microscopy, analytical scanning electron microscopy (SEM) and analytical transmission electron microscopy. Moreover, grain boundary segregation behavior of boron atoms during pre-weld heat treatments was evaluated using secondary ion mass spectroscopic system. In the first phase of the research, 718Plus was welded using a low and high heat input CO2 laser to assess its weld cracking response. Detailed examination of the welds by analytical electron microscopic technique revealed the occurrence of cracking in the HAZ of low heat input welds, while their FZ was crack free. However, both the FZ and HAZ of high heat input welds were crack-free. Resolidified constituents were observed along the cracked grain boundaries of the lower heat input welds, which indicated that HAZ cracking in this newly developed superalloy was associated with grain boundary liquation. However, despite a more extensive liquation of grain boundaries and grain interior in the HAZ of high heat input welds, no cracking occurred. This was attributed to the combination of lower welding stresses generated during cooling, and relaxation of these stresses by thick intergranular liquid. Although HAZ cracking was prevented by welding with a high heat input laser, it resulted in a significant damage to the parent microstructure through its extensive liquation. Thus, the use of low heat input welding is desirable. However, this resulted in HAZ cracking which needs to be minimized or eliminated. Therefore, during the second phase of this research, the effects of pre-weld thermal processing on the cracking response of 718Plus were investigated. Results from the quantification of the cracking of the alloy showed that HAZ cracking may be significantly reduced or eliminated through an adequate selection of pre-weld thermal cycle. In the third stage of this research, crack-free welds of 718Plus were post-weld heat treated using standard thermal schedules. A significant solid state cracking of the alloy occurred during the PWHT. The cracking was attributed to the presence of embrittling phases on HAZ grain boundaries, coupled with aging contraction stresses that are generated by a considerable precipitation of gamma prime phase during aging.

Allvac 718Plus

Inconel 718

Superalloy

Boron

Grain boundary segregation

SIMS

Welding

Heat affected zone cracking

Microstructural analysis

Heat treatment

Electron beam welding

Laser beam welding

Post weld heat treatment cracking

Constitutional liquation

Grain size

Weld heat input

Gamma prime

Liquid film migration

HAZ cracking

Welds in the lean duplex stainless steel LDX 2101 : effect of microstructure and weld oxides on corrosion properties

Westin, Elin M.

January 2008

Duplex stainless steels are a very attractive alternative to austenitic grades due to their higher strength and good corrosion performance. The austenitic grades can often be welded autogenously, while the duplex grades normally require addition of filler metal. This is to counteract segregation of important alloying elements and to give sufficient austenite formation to prevent precipitation of chromium nitrides that could have a negative effect on impact toughness and pitting resistance. The corrosion performance of the recently-developed lean duplex stainless steel LDX 2101 is higher than that of 304 and can reach the level of 316. This thesis summarises pitting resistance tests performed on laser and gas tungsten arc (GTA) welded LDX 2101. It is shown here that this material can be autogenously welded, but additions of filler metal, nitrogen in the shielding gas and use of hybrid methods increases the austenite formation and the pitting resistance by further suppressing formation of chromium nitride precipitates in the weld metal. If the weld metal austenite formation is sufficient, the chromium nitride precipitates in the heat-affected zone (HAZ) could cause local pitting, however, this was not seen in this work. Instead, pitting occurred 1–3 mm from the fusion line, in the parent metal rather than in the high temperature HAZ (HTHAZ). This is suggested here to be controlled by the heat tint, and the effect of residual weld oxides on the pitting resistance is studied. The composition and the thickness of weld oxide formed on LDX 2101 and 2304 were determined using X-ray photoelectron spectroscopy (XPS). The heat tint on these lean duplex grades proved to contain significantly more manganese than what has been reported for standard austenitic stainless steels in the 300 series. A new approach on heat tint formation is consequently presented. Evaporation of material from the weld metal and subsequent deposition on the weld oxide are suggested to contribute to weld oxide formation. This is supported by element loss in LDX 2101 weld metal, and nitrogen additions to the GTA shielding gas further increase the evaporation. / QC 20101126

Duplex stainless steel

welding

weld metal

HAZ

nitrogen

manganese

austenite formation

phase balance

precipitates

pitting resistance

heat input

solidification

element loss

evaporation

deposition

weld oxides

discoloration

mechanical properties

thermo-mechanical simulation

Geeble

GTA

laser

LOM

SEM

EDS

TEM

Leco

EPMA

ferroxyl test

XPS

post weld cleaning

pickling

Materials Engineering

Materialteknik