Caracterização metalúrgica de juntas de aço inoxidável superduplex soldadas por processo TIG autógeno / Characterization of metallurgical stell joints welded stainles superduplex autogenous TIG process

Samuel Amora Alves Neto

28 March 2011

Os aços inoxidáveis do tipo duplex possuem grande importância na indústria, principalmente na do petróleo e gás natural, por apresentarem elevada resistência mecânica e excelente resistência à corrosão. Caracterizam-se por apresentar estrutura bifásica, constituída de proporções praticamente iguais de ferrita e austenita. O presente trabalho caracterizou juntas soldadas por TIG autógeno de aço inoxidável duplex UNS S32760. Foram confeccionados quatro grupos de amostras, provenientes da variação da corrente de soldagem e consequentemente do aporte térmico (corrente de pico: 25A e 40A - aporte térmico: 0,12KJ/mm e 0,19KJ/mm) e da composição do gás de proteção (argônio puro ou argônio contendo 2,5% nitrogênio). Foram utilizadas técnicas de caracterização por metalografia colorida, análise e processamento digital de imagens, ensaios de microdureza Vickers. Para avaliar a resistência à corrosão foram realizados ensaios de potencial em circuito aberto com solução de cloreto férrico (FeCl3) e eletrodo de referência de calomelano saturado. A análise quantitativa das fases ferrita e austenita presentes nas juntas soldadas mostrou que a adição de nitrogênio no gás de proteção favoreceu a formação da fase austenita, variando de 11% (sem nitrogênio) para 26% (com nitrogênio) a quantidade desta fase. Em uma análise qualitativa a variação do aporte térmico: 0,12KJ/mm para 0,19KJ/mm resultou no aumento do tamanho de grãos da fase ferrita. / The duplex stainless steels are of great importance in industry, mainly in oil and natural gas due to their high mechanical strength and excellent corrosion resistance. They are characterized by having biphasic structure, consisting of nearly equal proportions of ferrite and austenite. The present work characterized welded joints by autogenous TIG process of duplex stainless UNS S32760. Four groups of samples were prepared, from the variation of welding current and consequently of heat input (20A and 40A - heat input: 0.12KJ/mm and 0.19KJ/mm) and the composition of shielding gas (pure argon or argon containing 2.5% nitrogen). Techniques of characterization by colored metallography, analysis and digital image processing and Vickers microhardness tests techniques were used. To evaluate the corrosion resistance, tests were performed at open circuit potential with a solution of ferric chloride (FeCl3) and reference electrode of saturated calomel. The quantitative analysis of ferrite and austenite phases present in the welded joints showed that the addition of nitrogen in shielding gas favored the formation of austenite phase, ranging from 11% (without nitrogen) to 26% (with nitrogen) the amount of this phase In a qualitative analysis the variation of heat input (0.12KJ/mm and 0.19KJ/mm) resulted in an increase of the ferrite phases grain size.

Soldagem TIG Autógena

Superduplex

Corrosão

Aço inoxidável

Autogenous TIG welding

Superduplex

Corrosion

Analysis and digital image processing

ENGENHARIA MECANICA

Caracterização metalúrgica de juntas de aço inoxidável superduplex soldadas por processo TIG autógeno / Characterization of metallurgical stell joints welded stainles superduplex autogenous TIG process

Samuel Amora Alves Neto

28 March 2011

Os aços inoxidáveis do tipo duplex possuem grande importância na indústria, principalmente na do petróleo e gás natural, por apresentarem elevada resistência mecânica e excelente resistência à corrosão. Caracterizam-se por apresentar estrutura bifásica, constituída de proporções praticamente iguais de ferrita e austenita. O presente trabalho caracterizou juntas soldadas por TIG autógeno de aço inoxidável duplex UNS S32760. Foram confeccionados quatro grupos de amostras, provenientes da variação da corrente de soldagem e consequentemente do aporte térmico (corrente de pico: 25A e 40A - aporte térmico: 0,12KJ/mm e 0,19KJ/mm) e da composição do gás de proteção (argônio puro ou argônio contendo 2,5% nitrogênio). Foram utilizadas técnicas de caracterização por metalografia colorida, análise e processamento digital de imagens, ensaios de microdureza Vickers. Para avaliar a resistência à corrosão foram realizados ensaios de potencial em circuito aberto com solução de cloreto férrico (FeCl3) e eletrodo de referência de calomelano saturado. A análise quantitativa das fases ferrita e austenita presentes nas juntas soldadas mostrou que a adição de nitrogênio no gás de proteção favoreceu a formação da fase austenita, variando de 11% (sem nitrogênio) para 26% (com nitrogênio) a quantidade desta fase. Em uma análise qualitativa a variação do aporte térmico: 0,12KJ/mm para 0,19KJ/mm resultou no aumento do tamanho de grãos da fase ferrita. / The duplex stainless steels are of great importance in industry, mainly in oil and natural gas due to their high mechanical strength and excellent corrosion resistance. They are characterized by having biphasic structure, consisting of nearly equal proportions of ferrite and austenite. The present work characterized welded joints by autogenous TIG process of duplex stainless UNS S32760. Four groups of samples were prepared, from the variation of welding current and consequently of heat input (20A and 40A - heat input: 0.12KJ/mm and 0.19KJ/mm) and the composition of shielding gas (pure argon or argon containing 2.5% nitrogen). Techniques of characterization by colored metallography, analysis and digital image processing and Vickers microhardness tests techniques were used. To evaluate the corrosion resistance, tests were performed at open circuit potential with a solution of ferric chloride (FeCl3) and reference electrode of saturated calomel. The quantitative analysis of ferrite and austenite phases present in the welded joints showed that the addition of nitrogen in shielding gas favored the formation of austenite phase, ranging from 11% (without nitrogen) to 26% (with nitrogen) the amount of this phase In a qualitative analysis the variation of heat input (0.12KJ/mm and 0.19KJ/mm) resulted in an increase of the ferrite phases grain size.

Soldagem TIG Autógena

Superduplex

Corrosão

Aço inoxidável

Autogenous TIG welding

Superduplex

Corrosion

Analysis and digital image processing

ENGENHARIA MECANICA

Influence of multiple welding cycles on microstructure and corrosion resistance of a super duplex stainless steel

Hosseini, Vahid

January 2016

Super duplex stainless steel (SDSS) has found a wide use in demanding applications such as offshore, chemical and petrochemical industries thanks to its excellent combination of mechanical properties and corrosion resistance. Welding of SDSS, however, is associated with the risk of precipitation of secondary phases and formation of excessive amounts of ferrite in the weld metal and heat affected zone. The present study was therefore aimed at gaining knowledge about the effect of multiple welding thermal cycles on the microstructure and possible sensitization to corrosion of welds in SDSS.Controlled and repeatable thermal cycles were produced by robotic welding. Oneto four autogenous TIG-remelting passes were applied on 2507 type SDSS plates using low or high heat inputs with pure argon as shielding gas. Thermal cycles were recorded using several thermocouples attached to the plates. Thermodynamic calculations and temperature field modelling were performed in order to understand the microstructural development and to predict the pitting corrosion resistance. Etching revealed the formation of different zones with characteristic microstructures: the fused weld zone (WZ) and the heat affected zone composed of the fusion boundary zone (FBZ), next to the fusion boundary, and further out Zone 1 (Z1) and Zone 2 (Z2). The WZ had a high content of ferrite and often nitrides which increased with increasing number of passes and decreasing heati nput. Nitrogen content of the WZ decreased from 0.28 wt.% to 0.17 wt.% after four passes of low heat input and to 0.10 wt.% after four passes of high heatinput. The FBZ was reheated to high peak temperatures (near melting point) and contained equiaxed ferrite grains with austenite and nitrides. Zone 1 was free from precipitates and the ferrite content was similar to that of the unaffected base material. Sigma phase precipitated only in zone 2, which was heated to peak temperatures in the range of approximately 828°C to 1028°C. The content of sigma phase increased with the number of passes and increasing heat input.  All locations, except Z1, were susceptible to local corrosion after multiplere heating. Thermodynamic calculations predicted that a post weld heat treatment could restore the corrosion resistance of the FBZ and Z2. However, the pitting resistance of the WZ cannot be improved significantly due to the nitrogen loss. Steady state and linear fitting approaches were therefore employed to predict nitrogen loss in autogenous TIG welding with argon as shielding gas. Two practical formulas were derived giving nitrogen loss as functions of initial nitrogen content and arc energy both predicting a larger loss for higher heat input and higher base material nitrogen content. A practical recommendation based on the present study is that it is beneficial to perform welding with a minimum number of passes even if this results in a higherheat input as multiple reheating strongly promotes formation of deleterious phases.

Super duplex stainless steel

autogenous TIG welding

multiple welding thermal cycles

sensitization

nitrogen loss

sigma phase

ferrite content

production technology

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