Residual stresses exist intrinsically in any manufactured or processed material, significantly influencing its mechanical properties. Shot peening enhances fatigue life by introducing compressive residual stresses at the surface, however, the beneficial effects may be reduced under external loads. This study investigates the behavior of surface residual stresses induced by shot peening in API 5L X80 steel. Specimens underwent tensile monotonic loading cycles below the yield strength, incrementally increasing the load until reaching the yield limit. Residual stresses were measured using the X-ray diffraction by sin2ψ method, revealing a progressive stress relief of compressive residual stresses field induced by shot peening. The development of tensile residual stresses was observed following the monotonic tests. Loads below yield stress were able to completely reverse compressive stresses to tensile stresses. A correlation was observed between residual stresses and magnetic Barkhausen noise, suggesting it as a potential method for analyzing residual stress behavior qualitatively in shoot peened steel samples. material properties however loads L X X8 strength limit Xray ray sinψ sin ψ tests noise samples

Resumo A soldagem em operação de um duto de distribuição de gás natural é uma operação crítica. O processo de soldagem com eletrodo revestido, embora simples e barato, encontra limitações quanto à espessura do duto. O processo TIG exige soldadores mais treinados e equipamentos de maior custo, mas o controle do aporte de calor permite soldar menores espessuras. Neste trabalho, os dois processos foram comparados para a soldagem de um tubo de aço API 5L grau B frequentemente utilizado nas linhas de distribuição. Os resultados mostraram que os dois processos forneceram resultados satisfatórios de propriedades mecânicas, a resistência à tração mínima foi de 430 MPa em ambos os processos, dentro do intervalo esperado de 415 a 760 MPa. A tenacidade também ao impacto foi de 50 e 48 J para as juntas por TIG e eletrodo revestido, respectivamente. Comparativamente, a solda pelo processo TIG apresentou mais regiões de grãos refinados. A dureza da ZTA com eletrodo revestido foi em torno de 220 HV, quanto para o TIG o valor foi ligeiramente menor, 180 HV. Nos dois processos, foi superior ao metal base, porém muito abaixo do valor limite de 350 HV considerado crítico para fissuração por hidrogênio (trinca a frio). crítica barato custo espessuras trabalho L mecânicas 43 41 76 5 4 respectivamente Comparativamente refinados 22 menor 18 base 35 trinca frio. frio . frio) 7 2 1 3

Abstract The in-service welding of natural gas distribution pipes is a critical operation. The shield metal arc welding (SMAW) process has low cost and is very simple, but it has limitations in the minimum pipe thickness. Gas tungsten inert arc welding (GTAW) employs more qualified operators and expensive welding machines and accessories. However, it can weld thinner pipes. In this work, both processes were tested and compared for the welding of an API 5L grade B pipe, often used in the distribution lines of Rio de Janeiro State. The results obtained showed that both processes gave satisfactory results. The minimum tensile strength was 430 MPa for both methods, under the standard range of 415 to 760 MPa. The impact toughness was 50 and 48 J for GTAW and SMAW, respectively. The GTAW showed more fine grains than the SMAW process. The hardness values in the SMAW HAZ was around 220 HV, while the GTAW HAZ was slightly lower, at 180 HV. For both processes, the hardness measured in the heat affected zone (HAZ) was superior to the base metal (BM), but much lower than the limit of 350 HV considered critical for hydrogen induced cold cracking. inservice service operation (SMAW simple thickness (GTAW accessories However work L State 43 methods 41 76 5 4 respectively 22 18 (HAZ BM, BM , (BM) 35 cracking 7 2 1 (BM 3

Austenitic-ferritic stainless steels are alloys with controlled additions of Cr, Ni, Mo and N which, after a suitable thermomechanical treatment, results in a balanced microstructure with similar proportions of ferrite (δ) and austenite (γ). Thus, it is possible to obtain good combinations of high mechanical properties and corrosion resistance through microstructural refinement, which also leads to a relatively good Pitting Resistance Equivalent value (PRE) at both phases. However, inadequate heat treatment and/or welding processes might result in the precipitation of deleterious phases, leading to poor mechanical properties and/or corrosion resistance. In this sense, the use of non-destructive microstructural characterization techniques becomes a valuable resource to access such alterations. Therefore, this work evaluates the precipitation of deleterious phase’s in welded thermal aged joints by portable Double Loop Electrochemical Polarization Reactivation (DL-EPR) taking into account a preliminary metallographic replica characterization. The results show that the proposed portable method can detect even a small percentage of deleterious phases, in addition to having a strong potential to be a non-destructive microstructural characterization technique.

Abstract This work evaluates microstructural changes and residual stresses on surface samples of AISI 201LN and 304L subjected to shot peening. The residual stresses were measured by X‑ray diffraction and magnetic Barkhausen noise (MBN) in different shot-peened conditions. The results showed that the 201LN steel presented more martensite than the 304L steel in the initial condition, but with lower δ‑ferrite contents. These ferromagnetic phases were present in a low amount with high tensile residual stresses due to brush cleaning and light cold‑rolling in the final stage of the fabrication process. The shot peening process promoted compressive residual stresses mainly in the δ‑ferrite. However, some “fresh” martensite exhibited tensile residual stress represented by higher and thinner peaks, which together with the low-intensity amplitude in the neighborhood, represented all formed martensite. Thus, small microstructural changes provoked high residual stresses behavior, which can be detected in ferromagnetic phases by MBN.

This work studies the application of a Non-Destructive Inspection Technique (NDIT), based on the Magnetic Barkhausen Noise (MBN), for the detection of non-homogeneous regions in carbon steel plates. It presents the advances in the development of a variant of a new non-destructive magnetic test technique, called Continuous Scanning Magnetic Barkhausen Noise (CSMBN). The non-homogeneous or damaged regions were produced by plastic deformations in rolled and annealed sheets of SAE 1060 and 1070 steels. MBN is generated by abrupt changes in the magnetization of materials when subjected to alteration. The sensitivity of the MBN signals in the detection of plastic deformations was analyzed varying parameters such as excitation magnetic field frequency and the speed of movement of the probe. The behavior of the root mean square of magnetic Barkhausen Noise signal (RMSMBN) parameter was correlated with the position of the nonhomogeneous regions detected in the samples. An evaluation of the technique applied to the measurement was made, comparing the results obtained with the Static Magnetic Barkhausen Noise (SMBN) technique, which is a method already established in the literature. The results showed that in all cases studied it was possible to detect the position of the damage, due to variation of the magnetic field. These changes are affected by the presence and distribution of elastic stresses (compression and traction), plastic deformation and microstructure modification. The results of CSMBN were similar to the SBMN with the advantage of being a continuous and more productive procedure. This new technique increases the spectrum of NDIT solutions for problems not contemplated by existing techniques.

Resumo O presente trabalho avalia a influência de adições entre 10 e 25% de CO2 como gases de proteção a base de argônio (Ar) nas propriedades mecânicas e resistência à corrosão de juntas soldadas pelo processo FCAW no aço inoxidável duplex (AID) UNS S31803 fazendo uso de arame eletrodo E2209T1-4. Sob estas condições o efeito da participação de 2% de oxigênio (O2) na mistura foi também levado em consideração. Ensaios mecânicos de tração e impacto Charpy, assim como de microdureza nas fases austenita e ferrita foram realizados em diversos locais das juntas assim produzidas. Paralelamente foram efetuados ensaios de corrosão para determinação da temperatura critica de pites (CPT) e perda de massa por unidade de área baseando-se nas especificações das normas ASTM G150 e G48, respectivamente. O estudo foi complementado com análises metalográficas mediante o emprego de diversos reagentes quantificando-se as fases presentes, assim como revelando características microestruturais nas condições supracitadas. Os valores das propriedades mecânicas obtidos nas juntas analisadas foram satisfatórios quando comparadas com valores normativos assim como de trabalhos publicados recentemente. Contudo, constatou-se ainda um aumento da CPT nas juntas soldadas com o emprego de gases com teores crescentes de CO 2. Finalmente observou-se, que dentre as juntas soldadas estudadas, aquelas obtidas utilizando-se a mistura com composição de 73%Ar+25%CO2 +2%O2, apresentou o melhor desempenho, tanto no que tange às propriedades mecânicas, quanto na resistência à corrosão. Os resultados obtidos permitem considerar a utilização de outras misturas gasosas na soldagem destes aços inoxidáveis com o processo FCAW, atém das indicadas normativamente, visando a grande demanda na construção e montagem de diversos componentes desta família de aço inoxidáveis na indústria offshore.

Abstract The present work evaluates the influence of additions between 10 and 25% of CO2 in argon-based shielded gases on the mechanical properties and corrosion resistance of welded joints by the FCAW process in duplex stainless steel (DSS) UNS S31803 using electrode wire E2209T1-4. Under these conditions the effect of the 2% O2 addition in the mixture was also taken into account. Mechanical tensile test, Charpy toughness and microhardness in the austenite and ferrite phases were carried out in several places of the joints thus produced. Besides, corrosion tests were carried out to determine the critical pitting temperature (CPT) and mass loss per unit area based on the specifications of ASTM G150 and G48, respectively. The study was complemented with metallographic analyzes using several reagents, quantifying the present phases, as well as revealing microstructural characteristics in the studied conditions. The mechanical properties values obtained in the analyzed joints were satisfactory when compared with normative values as well in recently published works. However, it was also observed a CPT increase value in the joints welded with the use of gases with higher levels of CO2. Finally, it was observed that, among the welded joints studied, those obtained using the mixture with composition of 73% Ar + 25% CO2 + 2% O2, presented the best performance, both with regard to mechanical properties and the corrosion resistance. The results allow determinates the use of other gaseous mixtures in the welding of DSS with the FCAW process, in addition to the normative one, in view of the great demand in the construction and assembly of several components of this stainless steel family in the offshore industry.

Duplex stainless steels (DSS) are Fe-Cr-Ni-Mo alloys, with low carbon content, which have a favorable combination of mechanical properties and corrosion resistance. These characteristics are mainly attributed to a dual phase and refined microstructure, typical of these alloys, consisting of similar amounts of ferrite and austenite. For this reason, DSS are widely used in various segments of industry, especially in offshore applications. However, DSS components may have a decrease of their properties when they are exposed high temperatures, often due to incorrect manufacturing processes. Intermetallic phases may precipitate causing embrittlement and corrosion resistance decrease. This work presents the effects of short time aging at 475 °C on the mechanical properties and localized corrosion resistance of a cast DSS. The results show that mechanical properties, such as toughness and hardness, are more susceptible to aging, having already been affected during the first 4 hours of heat treatment, while the corrosion was affected in 12 h of aging.

Superduplex stainless steels (SDSS) are frequently employed in the petrochemical industries where is required high mechanical strength, toughness, and corrosion resistance. However, these properties can be affected by deleterious phases formation due thermomechanical processes applied in the field during pipes and vessels construction. This work propose the nondestructive microstructural characterization of deleterious phases precipitated in SDSS isothermally treated in 800 and 850ºC using portable double loop electrochemical polarization reactivation tests (DL-EPR). The results obtained in this nondestructive test are quite close to those obtained by conventional test, and can be correlated with the amount of deleterious phases precipitated. It can be concluded that the microstructural degradation of superduplex stainless steel can be evaluated by portable DL-EPR test with slow sweep rates, using a special cell and a proper electrolyte at room temperature.

Maraging steels with 18wt%Ni and 10wt%Co are precipitation hardenable steels selected for special applications. These steels are quenched and aged in the 480 - 600ºC range. Ti and Mo are added to precipitate during aging as fine Ni3(Ti,Mo) and Fe2Mo particles. Aging at high temperatures causes overaging due to coarsening of particles and austenite formation. SAE 4340 is a typical low alloy medium carbon steel for quenching and tempering. The best combination of mechanical properties is attained by quenching and tempering in the 650 - 670ºC range. These two steels are selected for services where an optimum combination of mechanical strength, toughness and fatigue resistance is required. In this work, the austenitizing temperature in the quenching treatment was varied in order to evaluate the effects on microstructure and mechanical properties of both steels. The results showed that the effect of previous austenite grain size on the toughness was different in the two steels analyzed.

Austenitic stainless steels are high corrosion resistant alloys widely used in many industrial fields. Among this family of steels, AISI 317L stands out due to its higher localized corrosion resistance when compared to the traditional grades AISI 304L and AISI 316L. In some applications in oil refineries, the AISI 317L is being specified for services at moderately high temperatures. At the same time as it is sought to use new stainless steels, is also desirable to apply and develop emerging welding processes, replacing conventional ones, in order to achieve better behavior in service. In this respect, this work studied the effects of thermal aging on the toughness and resistance to pitting corrosion of AISI 317L steel weld metals produced by the Gas Tungsten Arc Welding (GTAW) and Friction Stir Welding (FSW) joining processes. After prolonged exposures at 450°C, for 200h, 300h and 400h, the microstructural characterization by scanning electron microscopy (SEM), toughness evaluation and anodic polarization tests in 3.5% NaCl solution were performed. The results showed that the increase of the exposure time in both weld metals caused a toughness decrease. The pitting potentials measured in the polarization tests also decreased with the aging at 450ºC.

The AISI 317L grade is an austenitic stainless steel with high Mo content (3.0 wt% min.). Due to the higher pitting resistance, this grade has replaced AISI 316L steel in many applications where the corrosion resistance is a critical property. However, the high Mo can induce phase transformations in high temperature services. In modern oil refinaries and petrochemical industries AISI 317L has been selected for temperatures as high as 550 °C. The goal of this work was to analyze the microstructural evolution and corrosion resistance of base and weld metal of AISI 317L stainless steel. The welded joints were produced by friction stir welding (FSW). The effect of prolonged exposure at 550 °C was investigated in specimens aged for 200h, 300h and 400h. After each aging treatment microstructural characterization was performed by scanning electron microscopy (SEM). Double loop electrochemical polarization reactivation tests (DL-EPR) were performed to evaluate the degree of sensitization of the samples. The results indicated that the increase of the exposure time at 550 °C promotes the formation of intermetallic phases, which causes corrosion decay of the weld metal.

This work investigates the influence of deleterious phases precipitation on the corrosion resistance of two wrought superduplex stainless steels UNS S32750 with similar composition, but different grain sizes. Isothermal treatments were carried out to introduce different amounts of deleterious phases, such as chi (χ), sigma (σ) and secondary austenite (γ2). The specimens were tested by double loop electrochemical potentiodynamic reactivation test (DL-EPR). The kinetics of precipitation in the two steels was different due to the difference of the grain sizes. The results show a correlation between the sensitization degrees, measured by DL-EPR, with the amount of deleterious phases precipitated.

The knowledge of residual stress arising from the welding processes is extremely important because the mechanical properties of the welded components are not only determined by the microstructures present in the joint, but also by the heterogeneous residual stresses introduced during the thermal cycle in welding processes. The aim of this work is the characterization of ASTM P91 steel-pipe welded by Metal Cored Arc Welding &Flux Cored Arc Welding (MCAW/FCAW) processes, through the residual stresses evaluation associated with welding and post-weld heat treatment (PWHT). Residual stresses were analysed by X-ray diffraction technique with sin2ψ method, presenting tensile behaviour with higher magnitude at the weld metal of root region. The PWHT promoted the relief of the residual stresses in the both regions. High Vickers microhardness values were observed in the weld metal region before the PWHT, which was very efficient to reduce them.

A influência da precipitação de fases deletérias na resistência à corrosão em dois aços inoxidáveis superduplex (AISD) UNS S32750 com diferentes tamanhos de grão foi investigada. Foram realizados tratamentos isotérmicos de modo a introduzir na microestrutura diversas quantidades de fases deletérias, tais como chi, sigma, austenita secundária e nitretos de cromo. Nestas condições foram efetuados ensaios de corrosão por polarização anódica cíclica. Estudos por microscopias ótica (MO) e eletrônica de varredura (MEV) foram realizados para caracterizar as fases precipitadas e a sua cinética de precipitação. Os resultados permitem correlacionar os valores obtidos pelos ensaios de polarização com o percentual de fases deletérias precipitadas para diferentes condições de tratamento em AISD com composições similares, mas com diferentes tamanhos de grão. Observou-se ainda que o tamanho de grão e a temperatura de envelhecimento influem na cinética de precipitação, na morfologia e no tamanho das fases deletérias precipitadas, incidindo na resistência à corrosão por pites dos AISD.

The influence of deleterious phases precipitation in corrosion resistance was investigated in two superduplex stainless steel (SDSS) UNS S32750 with different grain sizes. Isothermal treatments were performed in order to introduce various quantities of deleterious phases, such as chi, sigma, secondary austenite and chromium nitrides. Under these conditions corrosion tests were carried out by cyclic anodic polarization method. Studies by light optical microscopy (LOM) and scanning electron microscopy (SEM) were performed to characterize the precipitated phases and the precipitation kinetics. The results allow to correlate the values obtained by polarization tests with the percentage of deleterious phases precipitates to the different conditions of treatments of SDSS with similar compositions, but with different grain sizes. It was observed that the grain sizes and aging temperature influence the kinetics of precipitation, morphology and size of deleterious phases. These features affect the corrosion resistance of SDSS.

Os aços inoxidáveis superduplex (AISD) são ligas extensamente utilizadas nas atividades de exploração e produção de petróleo naval e offshore em componentes tais como, trocadores de calor, cabos umbilicais, linhas de injeção de água salgada e em diversos equipamentos que requeiram uma elevada resistência à corrosão com altos valores de resistência mecânica. Estas características são devidas à sua fina microestrutura bifásica composta por proporções semelhantes de austenita e ferrita e aos elementos de liga Cr, Ni, Mo, N e W. Entretanto, durante a soldagem, tal como nas fases de fabricação e montagem de tubulações, podem ocorrer a formação de defeitos, sendo necessários procedimentos de reparos das juntas soldadas. Deste modo, o presente trabalho pretendeu caracterizar a microestrutura, propriedades mecânicas, teor de nitrogênio e a temperatura crítica de pites (CPT) em determinadas regiões de uma junta soldada de AISD UNS S32760 efetuada através do processo GTAW com dois reparos sequenciais. Os resultados exibem um decréscimo do valor da CPT na raiz da solda, apesar de não se manifestar variações tão acentuadas nas propriedades mecânicas analisadas.

Superduplex stainless steels (SDSS) are alloys widely used in the exploration and production of oil. They are used in marine and offshore components such as heat exchangers, umbilicals, seawater injection lines and various other equipment that require high corrosion resistance with elevated mechanical strength values. These characteristics are due to its fine two-phase microstructure composed of similar proportions of austenite and ferrite and the alloying elements of Cr, Ni, Mo, N and W. However, during welding, and also in the stages of fabrication and pipe assembly, the presence of defects may occur that requires the need for repair procedures to be carried out on the welded joint. This study aims to characterize the microstructure, mechanical properties, nitrogen content and critical pitting temperature (CPT) of a SDSS pipe, UNS S32760, in certain regions of a welded joint, where the GTAW welding process was performed, with the completion of two sequential repair procedures. The results show that there is a decrease in the value of the critical pitting temperature at the root of the weld, though there aren't substantial variations in the mechanical properties analyzed.