Dissertations / Theses on the topic 'HIC ( Hydrogen Induced Cracking)'

Les installations pétrolières ou de gaz naturel peuvent être contaminées par H2S humide. Cet environnement est très agressif pour les aciers utilisés pour le transport ou les procédés liés à ces produits, car il peut provoquer l'absorption d'hydrogène par l'acier. En l'absence de contrainte, cet hydrogène peut causer une fissuration (Hydrogen Induced Cracking, HIC). En présence de contrainte appliquée ou résiduelle, une rupture peut se produire par un mécanisme dit de fissuration sous contrainte en présence d’hydrogène sulfuré (Sulphide Stress Cracking, SSC) ou de fissuration orientée induite par l'hydrogène (Stress Oriented Hydrogen Induced Cracking, SOHIC). La résistance des aciers est étroitement reliée aux caractéristiques microstructurales : inclusions non métalliques, constituants de phase dure, structure en bandes, etc. Cette thèse présente les résultats de tests de résistance à HIC et SCC d'aciers pour pipelines : deux aciers au carbone peu alliés (X52 et X 60) et un acier inoxydable 22-05 de type duplex (microstructure mixte d'austénite et ferrite). Ces matériaux ont été testés conformément aux normes NACE TM 0284 (HIC) et TM 0177, méthode A (SSC). Des essais de perméation électrochimique ont été réalisés pour compléter notre connaissance du comportement de ces matériaux en présence d'hydrogène (diffusivité, piégeage), et quelques essais de perméation ont été suivis de dosage de l'hydrogène piégé par dégazage sous vide à 600 °C. Les essais ont été réalisés en prenant en compte l'orientation des échantillons par rapport au sens de laminage, ainsi que l'état structural : état brut de réception (AR) et état après traitement thermique (HT)
Petroleum and natural gas systems can be contaminated with aqueous H2S. This environment is very aggressive to the steels used for the transport and processing of these products. Hydrogen absorption into steel may result, and provokes hydrogen induced cracking(HIC) in the absence of applied stress. In the presence of applied or residual stress, the failure process can occur by sulphide stress cracking (SSC) or stress oriented hydrogen induced cracking (SOHIC). The resistance of steels is closely related to the microstructure features: non-metallic inclusions, hard phase constituents, banded structures etc. This thesis summarizes results of HIC and SSC resistance of pipelines steels: two carbon micro alloyed steels (X52 and X60 according to API 5L Specification) and one 225 duplex stainless steel (austenite – ferrite microstructure). Materials have been tested according to NACE TM 0284 (HIC) and TM 0177 - Method A (SSC). To obtain detailed information about material behaviour in the presence of hydrogen, electrochemical permeation tests were performed as well. This method lets know the hydrogen diffusivity in these materialsand the hydrogen trapping. Some permeation tests were followed by vacuum outgasing at 600°C, to obtain information about irreversible trapping. The different tests have been achieved in as-received state (AR, after rolling) and after a laboratory heat treatment (HT, quenching and tempering). Influence of samples taking orientation has been also examined. Microstructure and fracture surfaces of broken SSC specimens analysis was performed by means of optical metallography and scanning electron microscopy

Atualmente a maior parte da energia consumida no mundo provém de fontes como carvão, petróleo e gás natural. Nas últimas décadas, o aumento na demanda por petróleo e gás natural teve como resultado um grande aumento no uso de tubos de aço para transportar estes produtos por longas distâncias. Os aços de alta resistência e baixa liga (ARBL) produzidos de acordo com a norma API 5L são atrativos para estas aplicações por apresentarem boas propriedades mecânicas e soldabilidade aliadas a baixos custos. Entretanto, nestas aplicações os materiais são expostos a meios corrosivos com altos teores de H2S, tornando-os susceptíveis aos danos provocados pelo hidrogênio. Dentre estes um dos mais importantes é o trincamento induzido pelo hidrogênio (hydrogen induced cracking - HIC). Neste trabalho a resistência à corrosão e ao HIC de dois aços API 5L X65, cujas composições diferem principalmente com relação aos teores de Mn e de Nb, e de um aço API 5L X80 comercial foi investigada na solução A da norma NACE TM0284-2011. A avaliação da resistência à corrosão foi realizada em solução naturalmente aerada ou desaerada sem e com saturação com H2S por meio de ensaios de potencial de circuito aberto, curvas de polarização potenciodinâmica e espectroscopia de impedância eletroquímica. Análises microestruturais por microscopia óptica (MO) e eletrônica de varredura (MEV) foram realizadas para correlacionar a microestrutura com os dois parâmetros investigados. As análises por MO e MEV mostraram que os dois aços API 5L X65 possuem inclusões uniformemente distribuídas em uma matriz ferrítica com ilhas de perlita degenerada e microconstituintes M/A (martensita/ austenita) nos contornos de grão da ferrita. Por sua vez, o aço API 5L X80 apresentou matriz ferrítica com microconstituintes M/A, e inclusões de formas arredondadas e irregulares em maior número e distribuídas de forma irregular. Os resultados dos ensaios eletroquímicos mostraram que, para os três aços, a resistência à corrosão diminui sensivelmente na presença de H2S. Por outro lado, os ensaios de impedância evidenciaram aumento da resistência à corrosão com o tempo de imersão em todos os meios, provavelmente associado à formação de produtos de corrosão insolúveis e que precipitam sobre a superfície dos aços. Todos os ensaios mostraram que os dois aços API 5L X65 são mais resistentes à corrosão que o aço API 5L X80. Os ensaios de HIC mostraram que os dois aços API 5L X65 não são suscetíveis a este tipo de falha, contrariamente ao aço API 5L X80. Neste último houve formação de trincas da parte central e inferior (interna) da amostra fornecida em forma de tubo. A análise do caminho de propagação da trinca mostrou a presença de inclusões ricas em Mn e S, indicando que elas têm um papel relevante no mecanismo de trincamento. Os resultados de todos os ensaios de corrosão mostraram que o aço experimental API 5L X65 produzido pela CBMM com baixos teores de Mn e altos teores de Nb apresentou resistência à corrosão ligeiramente superior ao aço API 5L X65 comercial, indicando ser esta composição promissora para aplicações em meios sour.
Currently most of the energy consumed in the world comes from sources such as coal, oil and natural gas. In recent decades the increase in demand for oil and natural gas has resulted in a large increase in the use of steel tubes to transport these products over long distances. High strength low alloy (HSLA) steels produced according to the API 5L standard are attractive for these applications because they have good mechanical properties and weldability combined with low costs. However, in these applications the materials are exposed to corrosive media with high levels of H2S, making them susceptible to damage caused by hydrogen. Among them, one of the most important is hydrogen-induced cracking (HIC). In this work the resistance to corrosion and HIC of two API 5L X65 steels, whose compositions differ mainly with respect to their Mn and Nb contents, and a commercial API 5L X80 steel were investigated in solution A of the NACE standard TM0284-2011. The evaluation of the corrosion resistance was carried out in naturally aerated or in deaerated solution without and with saturation with H2S by means of open circuit potential tests, potentiodynamic polarization curves and electrochemical impedance spectroscopy (EIS). Microstructural analysis by optical microscopy (OM) and scanning electron microscopy (SEM) were performed to correlate the microstructure with the two investigated parameters. OM and SEM analyzes showed that the two API 5L X65 steels have inclusions evenly distributed in a ferritic matrix with degenerated perlite islands and M/A (martensite/austenite) microconstituents at the perlite grain boundaries. In turn, the API 5L X80 steel presented a ferritic matrix with M/A microconstituents and round-shaped and irregular-shaped inclusions in greater number and irregularly distributed. The results of the electrochemical tests showed that, for all three steels, the corrosion resistance decreases significantly in the presence of H2S. On the other hand, the EIS tests showed an increase in corrosion resistance with immersion time in all media, which is probably due to the formation of insoluble corrosion products that precipitate on the steels surfaces. All assays showed that the two API 5L X65 steels are more resistant to corrosion than the API 5L X80 steel. The HIC assays showed that the two API 5L X65 steels are not susceptible to this type of failure, unlike the API 5L X80 steel. In the latter there was cracks formation in the central and lower (inner) part of the sample supplied as a tube. The analysis of the crack propagation path showed the presence of Mn and S-rich inclusions, indicating that they play a key role in the cracking mechanism. The results of all corrosion tests showed that the experimental steel API 5L X65 produced by CBMM with low Mn contents and high levels of Nb exhibited slightly higher corrosion resistance than the API 5L X65 commercial steel, indicating that this composition is promising for sour media applications.

A tecnologia dos aços microligados para transporte de gás natural e petróleo tem sido pressionada pelo descobrimento das novas jazidas e o aumento da demanda no mundo. As solicitações ambientais e de resistência mecânica são os parâmetros para o desenvolvimento de aços de alta resistência baixa liga para o transporte de gás e petróleo a menor custo e de forma segura. Neste contexto esta pesquisa investiga, em um aço microligado para tubos API 5L X80, o efeito das transformações de fase obtidas por resfriamentos controlados na fratura induzida por hidrogênio Hydrogen Induced Cracking-(HIC) e nas propriedades mecânicas. Os testes de HIC foram realizados no material como recebido, na espessura da chapa submetida a resfriamentos contínuos e em amostras do material tratadas de forma a simular as regiões de grão grosso da zona afetada pelo calor (GGZAC). Segundo o ciclo de resfriamento, os aços microligados têm microestruturas complexas, como é caso do aço microligado em estudo, onde sua microestrutura, estudada em trabalhos anteriores, é formada principalmente por ferrita, bainita, perlita e microconstituinte austenita/martensita (AM). A morfologia, tamanho, quantidade e distribuição dos produtos de transformação na chapa mudam as propriedades do aço. Esses fenômenos são de grande interesse tecnológico em aços microligados para a fabricação de tubos soldados para o transporte de gás e petróleo, tanto quando a solda é realizada em campo como também durante o encurvamento por indução; aqui as propriedades mecânicas do tubo decorrentes do processo de fabricação termomecânico podem ser degradadas pela ação do aquecimento e dos resfriamentos experimentados na zona afetada pelo calor (ZAC), principalmente na região de GGZAC. A simulação dos ciclos térmicos para o estudo da HIC na espessura da chapa foram realizados em CP austenitizados a 900ºC e submetidos a resfriamentos contínuos no dilatômetro de têmpera. Para simular os ciclos térmicos com resfriamentos controlados focados na GGZAC e a seguir obter CP de tamanho adequado para testes de tração e Charpy, foi necessário fazer os tratamentos térmicos a 1300ºC e resfriamentos contínuos em um simulador termomecânico e dilatômetro Gleeble. O maior tamanho da amostra tratada termicamente neste último equipamento permitiu extrair amostras para avaliar as propriedades mecânicas e a HIC do material, pois as diferentes regiões da ZAC em uma solda real são restritas e não permitem este tipo de ensaios em uma região específica da ZAC. Os resultados permitiram identificar a suscetibilidade de cada microestrutura produto da transformação da austenita na espessura da chapa, sendo a região central da chapa a mais sensível ao hidrogênio no aço como recebido e quando tratado a baixas taxas de resfriamento de 0,5°C/s após austenitizado a 900°C. As bandas grosseiras formadas por estruturas de maior dureza que a matriz na região central diminuíram a resistência à HIC. Da mesma forma nos corpos de prova que simulam a região GGZAC, a fratura induzida pelo hidrogênio foi localizada na região central da espessura embora apresente bainita e ferrita acicular. A falha possivelmente se deve aos elementos remanescentes segregados nesta região central e partição de carbono para os sub contornos de grão da bainita e ferrita que cresceram a partir a austenita primária. As inclusões e precipitados, segundo seu tipo, forma e localização na microestrutura, participam ou não da nucleação e propagação da trinca, sendo a posição mais crítica quando localizadas dentro das estruturas bandeadas. Não foi observada a nucleação de trincas na presença de hidrogênio em precipitados de Nb e Ti.
The technology of microalloyed steels for the transportation of natural gas and oil has been pressed by the discovery of new deposits and the increased demand in the world. Environmental requests for safety and ever increasing mechanical strength are the parameters for the development of high strength low alloy steels for transporting gas and oil at lower cost and safely. In this context, this research investigates, in a microalloyed steel pipe API 5L X80, the effect of phase transformations obtained by controlled cooling on the behavior when loaded with hydrogen - Hydrogen Induced Cracking - (HIC) and in the mechanical properties. HIC tests were performed on as-received material, on samples extracted from the thickness of the plate and subjected to continuous cooling and on samples of the material treated to simulate the coarse-grained regions of heat affected zone (CGHAZ). According to the cooling cycle, the microalloyed steels have complex microstructures: in the steel under evaluation its microstructure, studied in a previous work, consists mainly of ferrite, bainite, pearlite and austenite/martensite constituent (AM). The morphology, size, quantity and distribution of the products of transformation change the properties of plate steel. These phenomena are of great technological interest in microalloyed steels for the fabrication of welded tubes for the transport of gas and oil, when the welding is performed in the field as well as during hot bending; here the mechanical properties of the tube from the process of thermomechanical fabrication can be degraded by the action of heating and cooling experienced in the heat affected zone (HAZ), mainly in the region of CGHAZ. Simulations of thermal cycles for the study of HIC on sheet thickness were performed in coupons subjected to austenitization at 900ºC followed by continuous cooling in the dilatometer. To simulate the thermal cycles with controlled cooling, focused in the CGHAZ, and getting suitable sample sizes for tensile testing and Charpy, it was necessary to austenitize at 1300ºC followed by continuous cooling using the thermal and thermomechanical simulator in a Gleeble dilatometer. Samples heat treated in this equipment were suitable to evaluate the mechanical properties and the HIC of the material for different regions of HAZ, while a real weld would not have enough material to allow this type of testing on a specific region of HAZ. The results showed the susceptibility of each microstructure product of austenite transformation and of the position on the plate thickness. The central region of the plate was more sensitive to hydrogen in the steel as-received and when treated at low cooling rates of 0.5°C/s after austenitization at 900°C. The bands formed by coarse structures of greater hardness than the matrix in the central region decreased the resistance to HIC. Likewise in coupons that simulate the CGHAZ region, the fracture induced by hydrogen was located in the central thickness line, even when the microstructure were bainite and acicular ferrite. Failure there was possibly due to remnants of segregated elements in this central region and carbon partition to the subboundaries of the bainite and ferrite grain that grew from the primary austenite. Inclusions and precipitates, according to their type, shape and location in the microstructure, participating or not in the nucleation and propagation of the crack, were more critical when located within the banded structures; crack nucleation in the presence of hydrogen was not observed at Nb and Ti precipitates.

Testing of susceptibility to hydrogen induced stress cracking (HISC) in two 25% Cr Super Duplex Stainless Steels (SDSS) has been carried out. These were a forged material and a hot isostatically pressed (HIP) material with austenite spacing 51.5 µm and 12.9 µm, respectively. The tests were carried out on both smooth and notched samples by stepwise increasing load in Cortest proof rings on hydrogen pre-charged samples until fracture. The fracture surfaces were examined in scanning electron microscopes (SEM) and the hydrogen contents were measured. The microstructures of the materials were examined with the electron backscattered diffraction technique (EBSD) and assessed in relation to the results from the HISC testing.The results indicated that both SDSS materials are prone to HISC and that the HIP material has a higher threshold for HISC. The fracture surface on samples of both materials showed features indicating reduced ductility from HISC. The HIP samples indicated ductile fracture in the centre, implying that hydrogen influence was primarily in close proximity of the sample surfaces. This observation, and considerably higher hydrogen content measured in the forged material, indicates slower hydrogen diffusion in the HIP material than in the forged material.The results obtained were discussed against the literature reviewed and compared to the requirements in DNV-RP-F112. Indication of low temperature creep was observed on smooth samples by relaxation of the load determining ring deflection. The results from smooth samples indicated a threshold for HISC fracture (after one day of low temperature creep) at 112.6% ± 3.9% of yield strength (YS) and 104.8% ± 3.1% for HIP and forged material, respectively. No ring relaxation occurred for the notched samples. Therefore the results from these samples indicated higher threshold for HISC than the smooth samples, namely at 117.1% ± 2.2% and 113.8% ± 2.2\% of YS for HIP and forged samples, respectively.

Les viroles en acier microallié 18MND5, destinées aux générateurs de vapeur, présentent une composition hétérogène à plusieurs échelles. Un écart au procédé de fabrication ou une teneur en hydrogène excessive, peuvent conduire à la formation des Décohésions Dues à l’Hydrogène. Ces DDH résultent de la désorption de l’hydrogène interne lors du refroidissement jusqu’à température ambiante. La pression interne n’étant pas mesurables expérimentalement, une modélisation du phénomène est requise. Afin de préciser les mécanismes sous-jacents, il est proposé un scénario de formation de ces défauts s’appuyant conjointement sur une expertise et la modélisation des processus de diffusion-désorption-propagation. Les observations ont révélé une corrélation entre les DDH, les zones ségrégées et les amas de MnS (sites préférentiels d’initiation). Un modèle de diffusion dans un milieu hétérogène a été proposé afin d’évaluer la pression interne associée. La pression maximale excède ainsi 8600 bar en considérant une loi d’Abel-Noble optimisée du gaz réel. Le couplage de ce modèle avec la mécanique de la rupture a permis de quantifier l’évolution des paramètres relatifs à la propagation (pression interne, taille finale, vitesse, …). Un scénario de formation des DDH industriel a ainsi pu être formulé sur la base d’une étude paramétrique. Bien que les simulations préliminaires corroborent le retour d’expérience, le modèle raffiné et la prise en compte du gonflement de la DDH semblent sous-estimer la cinétique. Le caractère multi-fissuré des amas de MnS (homogénéisation des propriétés mécaniques) associé à un critère de rupture à l’échelle locale permettrait d’ajuster ce modèle
Heat generators are manufactured from ingots of 18MND5 (A508cl3) low alloy steel and present composition heterogeneities at different scales. Under specific conditions (non-respect of guidelines or high initial content of H), Hydrogen Induced Cracks (HIC) may result from diffusion-desorption of internal hydrogen during cooling down to room temperature. Since neither hydrogen redistribution nor its internal pressure within cavities could be measured by experimental techniques, quantitative investigation is based on the modelling of related physical phenomena. A scenario of HIC formation, based on industrial feedback and modelling, has been proposed. A correlation between these defects, segregated areas and clusters of MnS (preferred initiation sites) has been revealed by expertise of HIC. A model of diffusion in heterogeneous alloys has then been proposed to assess the maximal pressure of H2 in such HIC. Simulation has shown that internal pressures above 860MPa are reached by considering an optimized Abel-Noble real gas behavior. The previous model has then been coupled to a failure mechanics procedure to characterize and quantify the crack growth parameters. Based on a parametric study, a scenario of HIC formation during the cooling has been proposed regarding process. Although results from preliminary simulations matched with feedback, the refined model based on the pressure induced elastic deformation of HIC has been developed but provided an underestimated kinetic of crack growth. Consequently, the multi-cracked nature of MnS clusters (homogenization of mechanical properties) and the updated local failure criterion appear to be a viable path to adjust predictions

Hydrogen is the smallest element in the periodical table. It has been shown in several studies that hydrogen has a large influence on the corrosion and cracking behaviour of stainless steels. Hydrogen is involved in several of the most common cathode reactions during corrosion and can also cause embrittlement in many stainless steels. Some aspects of the effect of hydrogen on corrosion and hydrogen-induced stress cracking, HISC, of stainless steels were studied in this work. These aspects relate to activation of test specimens for uniform corrosion testing, modification of a test cell for dewpoint corrosion testing and the mechanism of hydrogen-induced stress cracking. The results from uniform corrosion testing of superduplex stainless steels indicated that there is a large difference between passive and activated surfaces in hydrochloric acid and in lower concentrations of sulphuric acid. Hence, initial activation of the test specimen until hydrogen evolution can have a large influence on the results. This may provide another explanation for the differences in iso-corrosion curves for superduplex stainless steels that have previously been attributed to alloying with copper and/or tungsten. In concentrated sulphuric acid, potential oscillations were observed; these oscillations activated the specimen spontaneously. Due to these potential oscillations the influence of activation was negligible in this acid. An experimental set-up was developed for testing dewpoint corrosion of stainless steels in a condensate containing 1 % hydrochloric acid. There was an existing experimental set-up that had to be modified in order to avoid azeotroping of the water and hydrogen chloride system. A separate flask with hydro chloric acid was included in the experimental set-up. The final set-up provided reasonably good agreement with field exposures in contrary to much higher corrosion rates in the original set-up. Relaxation and low temperature creep experiments have been performed with several stainless steels in this work. The aim was to understand how creep and relaxation relates to material properties and the relative ranking between the tested materials. For low temperature creep with a load generating stresses below the yield strength, as well relaxation at stress levels above and below the yield strength, the same ranking with respect to changes in mechanical properties of the steel grades was found. For low temperature creep with a load level above the yield strength, the same ranking was not obtained. This effect can most probably be explained by annihilation and generation of dislocations. During low temperature creep above the yield strength, dislocations were generated. In addition, low temperature creep experiments were performed forone superduplex stainless steel in two different product forms with differentaustenite spacing in the microstructure. The superduplex material experienced low temperature creep at a lower load level for the material with large austenite spacing compared to the one with smaller austenite spacing. Also this differenceis influenced by dislocations. In a material with small austenite spacing the dislocations have more obstacles that they can be locked up against. Studies of the fracture surfaces of hydrogen induced stress cracking, HISC, tested duplex stainless steels showed that HISC is a hydrogen-enhanced localised plasticity, HELP, mechanism. Here a mechanism that takes into account the inhomogeneous deformation of duplex stainless steels was proposed. This mechanism involves an interaction between hydrogen diffusion and plastic straining. Due to the different mechanical properties of the phases in a superduplex stainless steel, plastic straining due to low temperature creep can occur in the softer ferrite phase. A comparison between low temperature creep data showed that for the coarser grained material, HISC occurs at the load levelwhen creep starts. However, in the sample with small austenite spacing, HISC did not occur at this load level. Microhardness measurements indicated that the hydrogen level in the ferrite was not high enough to initiate cracking in the coarser material. The proposed mechanism shows that occurrence of HISC is an interaction between local plasticity and hydrogen diffusion.
QC20100618

The Hydrogen Induced Stress Cracking (HISC) susceptibility of Alloy 718 and Alloy 725 where examined and compared. Pre-charged samples of each alloy where stepwise loaded during polarization in Cortest Proof rings. A safe load was found from this stepwise loading. To confirm that these load levels were safe, pre-charged samples were loaded to this load for 30 days during cathodic polarization. After fracture the fracture surfaces were examined in scanning electron microscope and the hydrogen concentration were measured by hydrogen melt extraction. It was found that both alloy are severely embrittled by hydrogen. Both the ductility and stress at fracture were reduced by the same amount in both alloys. The constant load tests revealed a safe stress at 123,8 % of YS for Alloy 725 and 120,4 % of YS for Alloy 718. Based on this it was concluded that Alloy 725 is somewhat more resistant to HISC than Alloy 718.

In this work, Slow Strain Rate Test (SSRT) testing, Light Optical Microscopy (LOM) and Scanning Electron Microscopy (SEM) were used to study the effect of micro-structure, corrosive environments and cathodic polarisation on stress corrosion cracking (SCC) of two grades of high strength steels, Type A and Type B. Type A is manufactured by quench and tempered (Q&T) method. Type B, a normalize steel was used as reference. This study also supports electrochemical polarisation resistance method as an effective testing technique for measuring the uniform corrosion rate. SSRT samples were chosen from base metal, weld metal and Heat Affected Zone (HAZ). SSRT tests were performed at room temperature under free corrosion potential and cathodic polarisation using 4 mA/cm2 in 1 wt% and 3.5 wt% NaCl solutions. From the obtained corrosion rate measurements performed in 1 wt% and 3.5 wt% NaCl solutions it was observed that increased chloride concentration and dissolved oxygen content enhanced the uniform corrosion for all tested materials. Moreover, the obtained results from SSRT tests demonstrate that both Q&T and normalized steels were not susceptible to SCC in certain strain rate(1×10-6s-1) in 1 wt% and 3.5 wt% NaCl solutions under free corrosion potential. It was con-firmed by a ductile fracture mode and high reduction in area. The weld metal of Type A with acicular ferrite (AF), pro-eutectoid (PF) and bainite microstructure showed higher susceptibility to hydrogen assisted stress corrosion cracking compared to base metal and HAZ. In addition, typical brittle intergranular cracking with small reduction in area was observed on the fracture surface of the Type A due to hydrogen charging.

MASOUMI, M. Role of texture in hydrogen-induced cracking of steel API 5L X70 under various thermomechanical paths. 2017. 152 f. Tese (Doutorado em Ciência de Materiais)-Centro de Tecnologia, Universidade Federal do Ceará, Fortaleza, 2017.
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Pipeline steels are widely used to transport oil and natural gas in long distance in severe environments. Hydrogen-induced cracking (HIC) is one of the most important failure modes in sour environment. Atomic hydrogen produced during surface pipe corrosion diffuses into the steel and traps at defect sites such as inclusions, precipitations, phase interfaces, martensite islands, and grain boundaries. These hydrogen atoms recombine to form hydrogen molecules, leading to the creation of internal pressure within the metal. This reduces ductility, toughness and mechanical properties, leading to HIC nucleation and propagation. The main objective of this thesis was to find a correlation between a role of texture and grain boundary character distribution with HIC crack nucleation and propagation sites. Finally, proposed thermomechanical treatment produced favorable crystallographic textures and significantly increased HIC resistance which is of great interest to petroleum industry. In this thesis, API 5L X70 steel was subjected to thermomechanical processing with various finish rolling temperatures to produce a similar microstructure with different crystallographic textures. The microstructural and textural evolution was characterised by scanning electron microscopy (SEM), X-ray diffraction (XRD) and electron backscatter diffraction (EBSD). Then, HIC standard test and electrochemical hydrogen-charging experiments were used to induce HIC cracks in pipeline steels. Then EBSD analysis was carried out to show the HIC resistance improvement via appropriate thermomechanical processing. Present work revealed that significant improving of HIC resistance was obtained through engineering of crystallographic texture by isothermal rolling below non-recrystallisation temperature. The high resistance to HIC is highly important to oil and gas transportation. Electron backscatter diffraction (EBSD) measurements were done along the HIC crack in X70 steel after HIC test. The results showed that {001} grains which parallels to normal direction are weak against HIC propagation, and provide a preferred path to crack propagation. Whereas, grains which lied along {110} and {111} planes parallel to rolling plane showed higher resistance against HIC crack nucleation and propagation and improved HIC resistance. In addition, EBSD data revealed that the high amount of recrystallization fraction with no stored energy is one of the main reasons for a higher HIC resistance. Consequently, increasing the fraction of low angle and coincidence site lattice boundaries related to low {hkl} indexing and correspond to the dense planes is targeted in grain boundary engineering to improve HIC resistance. Increasing the number of {111} and {110} grains, with the goal of minimizing the number of {001} grains and HABs, leads to a reduction in crack nucleation and propagation. In overall, the key finding of this work revealed that significant improvement of HIC resistance was obtained through engineering of crystallographic texture by isothermal rolling at approximately 850°C. Although the rolling schedule suggested in the current study differs from the established industrial production, a significant improvement in HIC resistance by controlling of texture only was achieved. This can be a great motivation for development of an alternative thermomechanical treatment with lower finish rolling temperature
Aços de tubulação são amplamente utilizados para transporte de petróleo e gás natural em longa distância em ambientes agressivos. Trincas induzidas por hidrogênio (HIC) são um dos modos de falha mais importantes no ambiente em que se é usado. O hidrogênio atômico produzido durante a corrosão da superficial da tubulação difunde-se para o aço e as prende em locais de defeito, tais como inclusões, precipitações, interfaces de fase, ilhas martensíticas e contornos de grão. Estes átomos de hidrogênio se recombinam para formar moléculas de hidrogênio, levando à criação de pressão interna dentro do metal. Isso reduz a ductilidade, tenacidade e propriedades mecânicas, levando a nucleação e propagação do HIC. O objetivo principal desta tese foi encontrar uma correlação entre o papel da textura e a distribuição do caráter dos contornos de grãos com os núcleos de propagação e de nucleação das trincas. Finalmente, o tratamento termomecânico proposto produziu texturas cristalográficas favoráveis e aumentou significativamente a resistência ao HIC que é de grande interesse para a indústria petrolífera Nesta tese, o aço API 5L X70 foi submetido a processamento termomecânico com várias temperaturas finais de laminação para produzir uma microestrutura similar com diferentes texturas cristalográficas. A evolução microestrutural e de textura foi caracterizada por microscopia eletrônica de varredura (SEM), difração de raios X (XRD) e difração de retroespalhamento eletrônico (EBSD). Em seguida, utilizaram-se ensaios padrões de HIC e experimentos electroquímicos com bombardeamento de hidrogênio para induzir fissuras HIC em aços de tubulação. Em seguida, a análise de EBSD foi realizada para mostrar a melhoria da resistência HIC através de processo termomecânico apropriado. O presente trabalho revelou que a melhoria significativa da resistência HIC foi obtida através da engenharia da textura cristalográfica por laminação isotérmica abaixo da temperatura de recristalização. A alta resistência ao HIC é muito importante para o transporte de petróleo e gás. As medidas de difração de retroespalhamento de elétrons (EBSD) foram feitas ao longo da trinca HIC em aço X70 após o teste HIC. Os resultados mostraram que os grãos de planos {001} que são paralelos à direção de laminação são mais propensos a propagação de HIC, e proporcionam um caminho preferêncial para a propagação da trinca. Os grãos que estão ao longo dos planos {110} e {111} são paralelos ao plano de laminação e se mostraram mais resistentes a nucleação e propagação de trincas. Além disso, os dados do EBSD revelaram que a elevada quantidade de recristalização sem energia armazenada por deformação é uma das principais razões para uma maior resistência ao HIC. Consequentemente, o aumento da quantidade de contornos de baixo ângulo e coincident site lattice relacionados à baixa indexação {hkl} e que correspondem aos planos densos é direcionado à engenharia de contornos de grãos para melhorar a resistência a HIC. Em conclusão, aumentar o número de grãos em planos {111} e {110}, objetivando a minimização de grãos em planos {001} e contornos de alto ângulo, leva a uma redução na nucleação e propagação de trincas e a uma melhora de resistência a fragilização pelo hidrogênio. Em geral, a principal descoberta deste trabalho revelou que a melhoria significativa da resistência HIC foi obtida através da engenharia de textura cristalográfica por laminação isotérmica a aproximadamente 850°C. Embora o cronograma de laminação sugerido no presente estudo difira da produção industrial estabelecida, foi alcançada uma melhora significativa na resistência ao HIC somente pelo controle da textura. Isto pode ser uma grande motivação para o desenvolvimento de um tratamento termomecânico alternativo com temperatura de laminação de acabamento mais baixa.

In this study, hydrogen induced cracking (HIC) behavior of welded steels used in petroleum lines under sour petroleum environments was investigated. The testing environment in NACE TM0284-2003 standard was used in order to simulate sour petroleum environment. In order to investigate behavior of welding parameters, used in pipe production, on HIC, welds were done with different line energies. Two different API X-65 steels were used in welding operations. The specimens taken from welded zones were tested in testing environment. The specimens were examined metallographically. Crack lengths were measured with a computer program. The results obtained were discussed in view of metallurgical and welding parameters aspects. The result obtained from this investigation led to a general conclusion that, the metallurgical parameters of steels used in pipe production were more important than welding parameters regarding their effect on HIC. It was shown that the composition and microstructural grain size of steels were in direct relation to HIC.

Las condiciones ambientales de trabajo de los aceros estructurales y de conducciones en instalaciones energéticas y petrolíferas han puesto en evidencia la necesidad de encontrar una metodología de caracterización de su resistencia a la fisuración, tanto en régimen de dominio elástico como elastoplástico. Este trabajo recoge una metodología experimental y analítica adecuada para ser aplicada a los procesos de fisuración estudiados sobre probetas y estructuras, en particular a aquéllos asociados a la presencia de ambientes agresivos, como corrosión bajo tensión o fisuración inducida por hidrógeno de aceros microaleados. Una vez aplicada y validada, la metodología ofrece resultados de gran interés en la caracterización cuantitativa del comportamiento de fisuración y su correlación con los micromecanismos de rotura presentes. Esta tesis se ha mostrado eficaz en la caracterizacióny establecimiento de un modelo de comportamiento de aceros microaleados utilizados en condiciones de fisuración inducida por hidrógeno, como es el caso de las plataformas petrolíferas en alta mar (estructuras off-shore).
The environmental conditions of employment of structural steel and energy pipelines and oil facilities have highlighted the need to find a methodology for characterizing their resistance to cracking, both in the elastic and the elastoplastic regime. This work includes experimental and analytical methodologies that are appropriate to be applied to cracking processes studied on specimens and structures, in particular to those associated with the presence of aggressive environments, such as stress corrosion cracking or hydrogen induced cracking of microalloyed steels. Once applied and validated, the methodology provides results of great interest in the quantitative characterization of the cracking behavior and its correlation with the fracture micromechanisms taking place. This thesis has been shown to be effective in the characterization and establishment of a behavioral model of microalloyed steels used in conditions of hydrogen-induced cracking, such as oil platforms at sea (off-shore structures).

Componentes e equipamentos utilizados na indústria petroquímica estão suscetíveis a presença de descontinuidades e, por esta razão, diversas pesquisas são desenvolvidas com o intuito de aprimorar e criar novos métodos para evitar, remediar ou controlar estas, de forma a não causarem um dano à integridade estrutural. Neste trabalho é avaliado um conjunto de trincas induzidas pelo hidrogênio (TIH), através do método de elementos finitos, com a finalidade de verificar o fenômeno de união das suas extremidades formando uma trinca contínua do tipo SWC (Stepwise Cracking). Também se verifica a influência do conjunto de trincas à integridade da estrutura com base na metodologia Fitness for Service (FFS) através do uso dos diagramas de avaliação de falhas (FAD – Failure Assessment Diagram) indicados pelas normas API-579 / ASME FFS-1 e BS 7910 além do procedimento CEGB-R6. Os resultados mostram que o efeito de interação entre as extremidades é intenso quando estas se encontram próximas umas das outras, confirmando assim a tendência de união das fissuras. Também se constata que o fenômeno é fortemente influenciado pela pressão interna presente nas TIH, esta causada pela presença de hidrogênio. Em relação à aceitabilidade das descontinuidades, é observado que os resultados da avaliação são influenciados pela maneira como a descontinuidade é caracterizada.
Components and equipments of the petrochemical industry are susceptible to the presence of flaws and, for this reason, several studies are developed aiming to improve and create new methods to avoid, remedy and control these flaws in order they will not cause any integrity damage. In this work a cluster of Hydrogen Induced Crack (HIC) is assessed, using the finite element method, with the goal to verify the union phenomena in their tips forming a Stepwise Cracking (SWC) flaw. Also is verified the influence of the cluster to the integrity of the structure based on the Fitness for Service methodology, using the Failure Assessment Diagrams indicated by the Standards API-579 / ASME FFS-1 and BS 7910, also the CEGBR6 procedure. The results show that the interaction effect among the tip of the cracks is considerably intense when they are near to each other, confirming the tendency of union among them. Also this phenomenon is strongly influenced by the internal pressure in the HIC, caused by the presence of atomic Hydrogen diffused in the structure. In relation to the flaw assessment, it is observed that results are strongly influenced on how the flaw is characterized.

Com a descoberta de novas fontes de petróleo e gás, em regiões remotas e de difícil acesso, tem-se a necessidade do desenvolvimento de novas tecnologias para garantir a eficácia da exploração destes recursos. Essa exploração e extração muitas vezes se dão em ambientes altamente corrosivos e os equipamentos devem apresentar propriedades que garantam um fator de segurança em serviço. Os aços de alta resistência e baixa liga (ARBL) são utilizados em tubulações para o transporte de gás natural e petróleo. Estes estão constantemente expostos a ambientes ácidos os quais são compostos de umidade e sulfeto de hidrogênio (H2S), podendo causar falha induzida pela presença de hidrogênio (Hydrogen Induced Cracking HIC). Este tipo de falha é normalmente abordado na literatura através de ensaios em solução contendo ácido acético e/ou sais (cloreto de sódio, entre outros), sempre com a injeção de H2S. Há vários mecanismos propostos, no entanto, o assunto não está totalmente resolvido. As alterações de composição química dos aços, processos de refino do aço e processos de conformação mecânica são responsáveis pela microestrutura final e determinantes da resistência à fragilização por hidrogênio. O objetivo deste trabalho é analisar e comparar o comportamento quanto à resistência à corrosão e resistência à HIC de quatro materiais: tubo X65 sour, sua região de solda, tubo X65 não-sour e uma chapa destinada a confecção de tubo X65. Os eletrólitos empregados foram: solução A (ácido acético contendo cloreto de sódio) e a solução B (água do mar sintética), os quais correspondem às soluções recomendadas pela norma NACE TM0284-2003. Os materiais foram submetidos a: ensaios de polarização (Polarização Linear para determinação da Resistência de Polarização - Rp) e ensaios de resistência a HIC segundo a norma NACE TM0284-2003; exames em microscópio óptico e eletrônico de varredura para caracterização da morfologia da corrosão e do trincamento. Os ensaios de Rp revelaram que a solução A é mais agressiva do que a solução B, sendo isso explicado pela diferença de pH entre estas duas soluções. Os resultados mostraram ainda que a máxima resistência à corrosão sempre é obtida para o tubo sour, enquanto a mínima ocorreu para o tubo não-sour. Após o ensaio de resistência a HIC os exames em microscópio óptico revelaram que, em ambas as soluções, o tubo de X65 sour, e a sua solda não apresentaram trincas, bem como a chapa destinada a tubo X65; já o tubo de X65 não-sour apresentou trincamento principalmente na região central. Os exames das trincas revelaram que a presença de cementita intergranular e a estrutura bandeada foram as causas do trincamento. No caso do tubo sour, o bom desempenho foi discutido em termos da microestrutura de ferrita poligonal, acicular e microconstituinte M/A. Já o comportamento distinto encontrado para a chapa (para tubo X65), foi discutido levando-se em conta que esta chapa apresentou menor quantidade de cementita intergranular, uma vez que, sua microestrutura é bandeada e não foi encontrado trincamento. Os resultados também revelaram que a solução B, como no caso da resistência à corrosão, é uma solução menos agressiva, pois o trincamento obtido foi muito menor.
The discovery of new oil and gas reserves, at remote and hard to reach locations, makes imperative the development of new technologies to ensure effective exploitation of these resources. This exploitation is often performed at highly corrosive environments and equipment such as pipelines should have special mechanical and corrosion properties to guarantee safety levels in service. High-Strength Low Alloy (HSLA) steels are used in pipelines for transporting gas and oil. These steels are in constant exposure to acid environments containing hydrogen sulfide (H2S) and water, that can cause pipeline failures due to Hydrogen-Induced Cracking - HIC. The literature reports that Hydrogen-Induced Cracking in steels is normally tested in solutions containing acetic acid and/or, salts (sodium chloride and others) with addition of H2S. Chemical composition, steel refining processes and metal forming processes are responsible for the final microstructure of the steel and have effect on the hydrogen embrittlement resistance. The purpose of this work is to analyze and compare the corrosion resistance and HIC resistance, and compare of four materials: pipeline steel API 5L X65 for sour service, its welded junctions, pipeline steel API 5L X65 for non-sour service and pipeline steel plate API 5L X65. The materials were submitted to linear polarization test (Rp) and HIC resistance test according to NACE TM0284-2003 standard. Both tests were carried out with two different electrolytes: the solution A (acetic acid and sodium chloride) and solution B (synthetic seawater). Subsequently; the surface of the steels were evaluated by optical microscope and scanning electron microscopy in order to characterize the cracking modes and corrosion morphology. The Rp tests showed that the solution A is more aggressive than solution B, behavior attributed to the pH difference between solutions. Steel API 5L X65 for sour service had the highest corrosion resistance and pipeline steel API 5L X65 for non-sour service had the lowest. The HIC test and the surface examination revealed that in both solutions, pipeline steel API 5L X65 for sour service, the welded junctions and the pipeline steel plate API 5L X65 showed no cracks. On the other hand, pipeline steel API 5L X65 for non-sour service presented cracking mainly in the central region. The tests revealed that the cracks nucleated at the intergranular cementite in the banded structure. The good performance of the pipeline steel API 5L X65 for sour service was discussed in terms of the microstructure, formed by polygonal ferrite, acicular ferrite and M/A microconstituent. The performance of steel plate (for pipeline API 5L X65) was different. This material did not exhibit cracks in the matrix in spite of its banded microstructure. This result was discussed taking into account that the plate studied had a small amount of intergranular cementite. The results also showed that the solution B, as in the case of corrosion resistance tests, was less aggressive than solution A, because the cracks produced were smaller.

O objetivo deste trabalho é analisar e comparar o comportamento quanto à resistência à corrosão, permeabilidade de hidrogênio e sua relação com a susceptibilidade ao trincamento induzido por hidrogênio de aços ARBL, em ambientes contendo H2S, enfatizando a influência da microestrutura. Foram realizados tratamentos térmicos de normalização e têmpera (em água) de dois tipos de tubos API 5L X65 para aplicação sour service, obtendo-se três condições com diferentes microestruturas para cada tubo. Assim, as duas amostras tais como recebidas apresentavam microestruturas de: ferrita/perlita e, o outro, ferrita/ferrita acicular; após tratamento de normalização os dois tipos de amostras apresentaram microestrutura de ferrita/perlita; e, por último, os aços que passaram por têmpera constituíram-se de martensita. O eletrólito empregado foi a solução A (ácido acético contendo cloreto de sódio) da norma NACE TM0284-2011, saturado com H2S. Os materiais foram submetidos a: ensaios de polarização linear para determinação da Resistência de Polarização (Rp), ensaios de permeabilidade de hidrogênio - baseado na ASTM G148-2003 - e ensaios de resistência ao trincamento induzido por hidrogênio (HIC) segundo a norma NACE TM0284-2011; exames em microscópio óptico e eletrônico de varredura para caracterização microestrutural, da morfologia da corrosão e do trincamento. Após os ensaios de polarização linear, foi observada uma diferença pequena dos valores de Rp entre as diferentes amostras estudadas, entre 120 ?.cm2 e 210 ?.cm2; dentro desta faixa, as microestruturas de martensita (aços temperados) apresentaram a menor resistência à corrosão. Foi realizado o tratamento dos dados obtidos por polarização linear com a metodologia desenvolvida por Mansfeld (1973) para cálculo da taxa de corrosão, observando mudanças nos declives de Tafel evidenciando a formação de produtos de corrosão. Apesar da formação destes produtos a taxa de corrosão não foi afetada, já que estes produtos são dissolvidos na solução A, oferecendo uma baixa proteção contra à corrosão. Nos ensaios de permeabilidade de hidrogênio foi utilizada uma célula modificada tipo Devanathan-Stachurski, com a solução A, com injeção de H2S no lado de geração de hidrogênio e 0,2M NaOH no lado de detecção. Foi realizado o tratamento dos dados com o método tlag, calculando a difusividade aparente, concentração de hidrogênio no metal e quantidade de sítios de ancoramento de hidrogênio. Também foi utilizado um método de ajuste da curva experimental com a equação obtida a partir da segunda lei de Fick para calcular a difusividade aparente. Foram comparados os valores obtidos com os dois métodos, obtendo-se resultados similares de difusividade aparente. As amostras temperadas foram as que apresentaram menor difusividade aparente, maior concentração de hidrogênio e maior número de sítios de ancoramento. Após o ensaio de resistência ao trincamento induzido por hidrogênio os exames em microscópio óptico mostraram que as amostras de tubos API 5L X65 como recebidas e normalizadas não apresentaram trincamento, já as amostras que passaram por tratamento de têmpera apresentaram trincas. A realização dos ensaios e tratamento dos dados permitiram observar a relação entre a quantidade de interface e a taxa de corrosão: assim a microestrutura martensítica apresenta a maior taxa de corrosão devido a maior quantidade de interfaces. A difusividade de hidrogênio também é afetada por esta mesma microestrutura, por ter maior quantidade de interface e maior número de discordâncias, apresentando menor difusividade aparente, maior concentração de hidrogênio e maior quantidade de sítios de ancoramento, tem-se que a microestrutura de martensita apresenta maior susceptibilidade ao trincamento induzido por hidrogênio. A nucleação e propagação das trincas nesta microestrutura depende de vários mecanismos que atuam simultaneamente: (i) nucleação das microtrincas, (ii) formação de H2 nas microcavidades com aumento da pressão local e (iii) migração de átomos de hidrogênio até a ponta da trinca diminuindo a força coesiva do reticulado facilitando a propagação. No entanto, esta relação entre microestrutura e HIC não pode ser generalizada, pois a susceptibilidade ao trincamento depende tanto da quantidade de sítios de ancoramento, como de sua energia de ligação, localização microestrutural e tamanho destes sítios. Outro fator importante é a presença de regiões de pouca ductilidade onde as trincas nucleadas tenham maior facilidade para sua propagação. Este trabalho contribuiu para o melhor entendimento dos mecanismos que levam à fragilização e danos provocados pelo hidrogênio, mostrando a relação entre microestrutura, corrosão, difusão e trincamento. Permitiu ampliar o conhecimento sobre os testes utilizados para avaliar o desempenho de aços microligados para aplicações em ambientes severos.
Pipelines produced from High Strength Low Alloy steels (HSLA) are a safe and cheap way to transport large quantities of petroleum and gas. HSLA steels offers mechanical and economic advantages. When HSLA steels are exposed to environments containing hydrogen sulphide (H2S), the steel can corrode and generate atomic hydrogen in the surface wich can diffuse and trapped, leading loss of mechanical properties and subsequent failures. The infrastructure to transport oil and gas represent a high cost investment, in adittion, they must be free from degradation processes that can causes severe health and environmental impacts. For this reason, the development of materials with high performance in aggressive environments is required. The aim of this study is to analyze and compare the corrosion behavior, hydrogen permeability and its relation with the susceptibility to Hydrogen Induced Cracking (HIC) of HSLA steels in environments containing H2S, with emphasis on the influence of microstructure. Normalizing and quenching heat treatments were applied in two different API 5L X65 pipelines for sour service. Three conditions were obtained (as received, normalized and quenched). The as received has a microstructure of ferrite / pearlite and ferrite / acicular ferrite, respectively; the microstructure of normalized specimens consist of ferrite / pearlite and finally quenched steels presented a microstructure of martensite. Solution A (acetic acid containing sodium chloride), according to NACE TM0284-2011 standard and saturated with H2S was used. The materials were tested by linear polarization technique, hydrogen permeability and Hydrogen Induced Cracking test (HIC). HIC tests were performed according to NACE TM0284-2011 standard. Optical microscope and scanning electron microscope were used for microstructural, corrosion and cracking characterization. Rp values show a slight difference between the different samples studied (120 ?.cm2 e 210 ?.cm2); the martensite microstructure (quenched) showed the lower corrosion resistance. Mansfeld (1973) method was used to calculate the corrosion rates from polarization curves. The Tafel slopes are differents between samples making evident the formation of corrosion products. Despite the growth of those corrosion products, the corrosion rate was not affected, since these products are dissolved in the solution A, providing a low corrosion protection. A modified Devanathan-Stachurski cell was used for the hydrogen permeability tests. It was used the solution A, with injection of H2S in the charging cell, and 0.1M NaOH solution on the oxidation cell. The hydrogen effective diffusivity, sub-surface concentration of atomic hydrogen at the charging side and number of hydrogen-trap sites were calculate by tlag method. Moreover, the experimental data were fitted using an equation derived from Fick\'s second law, in order to determinate the diffusion coefficient. The diffusion coefficient obtained from both methods were compare showing similar results. The quenching samples showed the lower diffusion coefficient, higher hydrogen concentration and number of trap sites. The steels in the as received and normalized conditins did not show cracks in Hydrogen Induced Cracking test; in the other hand, quenched samples presents cracks. The results shoed the relationship between the amount of interface and the corrosion rate. Being the martensitic microstructure the one with the higher corrosion rate. The diffusion coefficient in the martensitic microstructure, is a result of the high amount of interfaces and high dislocation density, leading to a lower diffusion coefficient, higher hydrogen concentration and number of trap sites. In the Hydrogen induced Cracking test the martensitic microstructure has shown the lower resistance to crack. The nucleation and propagation of the cracks in martensite depend of mechanisms that may act simultaneously: (i) nucleation of micro-cracks in preferential sites, (ii) formation of H2 in micro-cavities, with increase the local pressure, and (iii) hydrogen migration to the tip of the crack, decreasing the cohesive force in the lattice. However, the relationship between microstructure and Hydrogen Induced Cracking can not be generalized, since the susceptibility to cracking depends of several factors, like number of trap sites, binding trap energy, microstructural distribution and trap sizes. In addition, the presence of regions of low ductility can result in easy cracks nucleation and propagation. This thesis contributed to the understanding of the mechanisms that lead to hydrogen embrittlement and hydrogen damage, showing the relationship between microstructure, corrosion rate, diffusion and cracking, I ncreasing the scientific knowledge about the standard tests actually used to evaluate the performance of microalloyed steels in sour environments.

Wasserstoff-induzierte Schäden sind ein verbreitetes Problem in verschiedenen Anwendungen von Metallen. In dieser Arbeit wurde Wasserstoff-induzierte Rissbildung in Eisen untersucht. Die Proben wurden elektrochemisch mit Wasserstoff beladen. Diese Beladung führt zu Rissen in den Eisenproben und Blistern auf deren Oberfläche, wenn Risse oberflächennah lokalisiert sind. Als Triebkraft der Rissbildung wurde der hohe Wasserstoffdruck in den Rissen gefolgert. Dieser Druck wurde durch eine Kombination aus Ausgasexperimenten und Dichtemessungen bestimmt. Die Mikrostruktur, die Risse und Blister umgibt, wurde mit Elektronenmikroskopie untersucht. Dafür wurden Rissflächen durch Zugversuche freigelegt. Oxidische Einschlüsse konnten als Ausgangspunkt für Risse ausgemacht werden. Mit Transmissionselektronenmikroskopie wurden duktile Merkmale in der Nähe von Rissen sichtbar. Ein Mechanismus für die Riss- und Blisterbildung wurde vorgeschlagen.

Pipeline steels that carry oil and natural gas in severe environments suffer from two important modes of failure: stress corrosion cracking (SCC) and hydrogen-induced cracking (HIC). The SCC has been studied extensively in the literature; however, HIC phenomenon in pipeline steels is less investigated by researchers. Nevertheless, HIC is recognized as the most important damage mode in sour environment. Hydrogen atoms produced due to surface corrosion of the steel diffuse into it through microstructural defects. When a critical amount of hydrogen is accumulated in such defects, HIC cracks initiate and propagate. The main objectives of this thesis are to find the HIC crack nucleation and propagation sites, evaluate a role of texture and grain boundary character distribution in crack growth and finally establish the effect of different microstructural parameters contributing to the HIC related failure in pipeline steel. In this thesis, HIC standard test and electrochemical hydrogen-charging experiments were used to induce HIC cracks in pipeline steels. HIC cracks at the cross section of tested samples were observed using scanning electron microscope (SEM). The SEM observations clearly indicate that the investigated X60 and X70 steels are susceptible to HIC while the X60SS steel showed a higher resistance to HIC. This experiment also proved that the X70 steel has higher susceptibility to HIC than the other investigated steel. Energy dispersive spectroscopic (EDS) analyses indicated that two types of inclusion namely manganese sulfide and carbonitiride precipitates serve as crack nucleation sites. HIC cracks were observed to propagate at the center of cross section where the segregation of some elements such as carbon and manganese occurred. Moreover, two other experiments were carried out in order to evaluate the capability of pipeline steels for hydrogen-trapping. The first test, hydrogen-permeation experiment, showed that all pipeline steel specimens, such as X70, X60 and X60SS steels, contain both reversible and irreversible hydrogen traps. However, the density of traps at the center of cross section was higher than other regions in all tested specimens. The hydrogen-discharging experiments also showed that all specimens keep a considerable amount of hydrogen inside their traps. The hydrogen traps, based on their binding energy with the metal matrix, are categorized as reversible (weak) and irreversible (strong) traps and the roles of each type of traps are explained. Electron backscatter diffraction (EBSD) measurements were done along the HIC crack in X70 steel after standard HIC test. The results showed that the {100} texture was strong while the {111} texture was weak. Some special texture components, such as the {110}, {332} and {112}, were observed after the HIC crack-stoppage. EBSD results also documented that fine grain colonies were prone to intergranular HIC crack propagation and IPF and PF, calculated in both sides of HIC cracks, showed the preferences of ND||<100> orientation. Both susceptible X60 and non-susceptible X60SS steel to HIC were compared based on the EBSD results. It was observed that the high amount of recrystallization fraction with no stored energy is one of the main reasons for a higher HIC resistance of X60SS steel to HIC. Moreover, Kernel Average Misorientation (KAM) data showed that the deformation is more concentrated in the as-received and HIC tested X60 specimens. The effect of hydrogen-charging during tensile/fatigue loading of X60SS steel was studied and it was observed that some HIC cracks at the cross section of X60SS steel were appeared after hydrogen-charging at stresses below the yield stress. Experiments were carried out to understand the effect of cold-rolling and annealing on HIC susceptibility in pipeline steels. The results documented that the {100} dominant texture is more pronounced in 50% and 90% cold-rolled and annealed specimens. The effect of different factors such as KAM degree and recrystallized fraction affecting HIC susceptibility on cold-rolled and annealed specimens was investigated. The obtained results showed that the cold-rolling and annealing process may not be considered as an effective method to increase HIC resistance in pipeline steels.

碩士
國立成功大學
材料科學及工程學系
107
The microstructure and mechanical properties of 17-4 precipitation hardening (PH) stainless steel (SS) can be modified by heat treatment associated with the precipitation of copper-rich particles in the matrix. Tempering at 480 ℃ for 1h resulted in an increase in hardness and tensile strength but at the expense of high susceptibility to hydrogen induced cracking (HIC). Hydrogen is likely to be absorbed and trapped in interstitial lattice sites, dislocation cores, grain boundaries and incoherent interfaces (commonly associated with inclusions), etc., which can possibly act as initiation sites for HIC but with different propensity. The results of thermal desorption spectroscopy (TDS) analysis showed that hydrogen trapping energy is relatively low after 480 ℃/1h aging treatment, revealing the diffusible nature of absorbed hydrogen. However, the higher susceptibility to HIC could probably attributed to the higher hydrogen content in the dislocation cores or interstitial lattice sites. Aging treatment at 580 ℃/1h caused an increase of the formation of incoherent interfaces, which normally became the irreversible hydrogen trapping sites. As a result, the lattice hydrogen concentration was lowered and a decrease in HIC susceptibility was observed. Spring load tensile testing results indicated that 17-4 PH SS became embrittled by revealing the transition from ductile to brittle fracture if it was cathodically charged with hydrogen, regardless of thermal treatment.

碩士
國立成功大學
材料科學及工程學系
107
In this study, the susceptibility to HIC of 17-4 PH stainless steel (SS) in various aqueous solution and under cathodic polarization was investigated. The experimental results showed that the amount of hydrogen absorbed strongly depended on solution pH under constant applied potential condition, which increased with decreasing solution pH. The addition of Na2S2O3 or NH4SCN caused a further increase in hydrogen absorption, where the former was more significant than the latter. The roles of the additives on hydrogen absorption were elucidated. The experimental results also showed that 17-4 PH SS was susceptible to hydrogen induced cracking (HIC) under loading-free condition, which was solution pH dependent. The initiation time for the occurrence of HIC was very short in sulfuric acid solution with the addition of NH4SCN under cathodic polarization. In neutral and alkaline solution with the presence of NH4SCN, however, 17-4 PH SS was immune to HIC at cathodic charging condition. The results of constant load tensile test at 80% UTS (597 Mpa) showed 17-4 PH SS suffered hydrogen assisted fracture (HAF) in acidic aqueous solution, and its sensitivity varied with applied potential. In neutral sodium sulfate solution, 17-4 PH SS was resistant to HAF at potentials higher than -0.6 VSCE. Fractographical examination showed that a transition from ductile to brittle fracture occurred when hydrogen was absorbed