Contribution à l'effet des éléments d'alliage sur la résistance à la corrosion de nuances duplex exposées à des environnements simulant leur marché d'application par le biais d'approches locales / Contribution to the effect of alloying elements on the corrosion duplex grades exposed to environments simulating their application using local probes

Ba, Djiby

15 December 2014

Les aciers inoxydables duplex (DSS) sont caractérisés par une structure biphasée comprenant un mélange de ferrite et d’austénite. La proportion entre les deux phases est d'habitude environ 50 %. Ils sont de plus en plus employés dans les industries chimiques, pétrochimiques, nucléaires, marines et de papier, principalement en raison de leurs excellentes propriétés mécaniques couplées à une bonne résistance à la corrosion par piqûre (basse teneur en nickel et molybdène). L’austénite ayant une composition chimique différente de celle de la ferrite, un film hétérogène se forme à la surface des aciers inoxydable duplex. Par ailleurs, les deux phases métalliques ayant des propriétés mécaniques différentes, un champ de contrainte hétérogène est généré dans les grains. Sous certaines conditions, l’existence de gradients de contraintes peut conduire à des hétérogénéités du film passif. Dans ce travail , on étudie l’effet des éléments d’alliages sur les propriétés physico-chimiques du film passif et le comportement en corrosion par piqures avant et après vieillissement en milieu chlorurés, pour une surface de référence respectant certains critères à savoir une surface lisse exempt de tout défauts (pas de couche écrouie, rugosité faible..). Les propriétés physico- chimiques du film sont étudiés à l’aide des analyses Auger et XPS à l’échelle locale et globale. Le comportement en corrosion des alliages duplex a été ensuite déterminé à partir d’essais TCP (détermination de la température critique de piqûration). Les résultats avant vieillissement ont montré que le film passif est homogène à l’échelle macroscopique et que l’amorçage des piqûres semblent être liée à la taille des grains et à la texture cristallographique décrit par le GOS. Après vieillissement de longue durée en milieu représentatif, les analyses de surface montrent un renforcement de la passivité par un épaississement du film passif, une augmentation significative du rapport Cr/Fe ce qui ont pour effet d’améliorer le comportement en corrosion par piqures des alliages. Des critères métallurgiques ont été proposés pour expliquer l’amorçage de piqûres pour ces alliages. / Duplex stainless steels (DSS) are characterized by a two-phase structure comprising a mixture of ferrite and austenite. The proportion between the two phases is usually about 50%. They are increasingly used in the chemical, petrochemical, nuclear, marine and paper, mainly because of their excellent mechanical properties coupled with good resistance to pitting corrosion (low grade nickel and molybdenum). The austenite having a different chemical composition than the ferrite, a heterogeneous film is formed on the surface of duplex stainless steels. Furthermore, the two metallic phases having different mechanical properties, a field of heterogeneous stress is generated in the grains. Under certain conditions, these differences may also yield formation of a heterogeneous passive film. In this work, we study the effect of alloying elements on the physico-chemical properties of the passive film and behavior pitting corrosion before and after ageing in chloride media for a reference surface that meet certain criteria ie a smooth surface free from any defects (no hardened layer .. low roughness). The physicochemical properties of the film are studied using Auger and XPS analysis at the microscale. The corrosion behavior of duplex alloys was then determined from CPT tests (determination of the Critical Pitting Temperature). The results before ageing have shown that the passive film is homogeneous on a macroscopic scale and that pitting corrosion appear to be related to the grain size and crystallographic texture described by GOS. After ageing, surface analysis shows a strengthening of passivity by thickening of the passive film and the ratio Cr/Fe are significantly increased which has the effect of improving behavior pitting alloys. Metallurgical criteria for pitting were proposed.

Aciers inoxydables duplex

Chlorures

Analyse de surface

Corrosion par piqûres

Microcellule

Température Critique de Piqûre (TCP)

EBSD

Duplex stainless steel

Chlorides

Surface Analysis

Pitting corrosion

Microcell

Critical pitting temperature (CPT)

EBSD

530

540

Vliv chemického složení a tepelného zpracování na strukturu a vlastnosti dvoufázových austeniticko-feritických korozivzdorných ocelí / Influence of chemical composition and heat treatment on structure and properties of two-phase austenitic-ferritic stainless steels

Stejskal, Marek

January 2018

This thesis focused on austenitic-ferritic (duplex) stainless steels and their mechanical and technological properties. The theoretical part includes introduction to chemical composition, structure, heat treatment and properties of these steels. The practical part focuses on influence of casting temperature on technological properties of ASTM A890 Gr4A stainless duplex steel. Furthermore, there is evaluated influence of chemical composition and heat treatment on structure and mechanical properties of different duplex stainless steels.

Influence des éléments d'alliage sur la cinétique de vieillissement de la ferrite d'aciers inoxydables austéno-ferritiques moulés / Influence of alloying elements on the aging kinetics of cast austenitic ferritic stainless steel ferrite

Badyka, Romain

06 December 2018

Les aciers inoxydables austéno-ferritiques moulés sont utilisés pour certains composants ducircuit primaire des centrales nucléaires de génération II. Aux températures de service (285 °C -325 °C), des modifications de propriétés mécaniques sont observées. Elles sont imputables auxtransformations de phases au sein de la ferrite de ces aciers : la décomposition spinodale (DS) en phaseα (riche en Fe) et α’ (riche en Cr) et la précipitation de la phase G aux interfaces α/α'. S'il est admisque la composition de l’acier influe sur l’évolution des transformations de phase de la ferrite (lesaciers moins riches en Ni et Mo sont moins sensibles au vieillissement), aucune étude, à ce jour, n'apermis de mettre en évidence l'influence du Ni, Mo, Mn et des synergies éventuelles sur levieillissement des aciers ni de déterminer la contribution de la phase G à l'évolution des propriétésmécaniques. Dans cette étude, les cinétiques des transformations de phase de la ferrite d'aciers inoxydable austéno-ferritiques pauvres en Mo et riches en Mo ainsi que de celle d'alliages modèles decomposition ciblée ont été étudiées par sonde atomique tomographique (SAT) et par mesure demicrodureté. Les travaux ont répondu aux trois questions suivantes : - Quantification de la contribution des différentes phases au durcissement : L'utilisation conjointe de modèles de durcissement et des données obtenues par la sonde a montré que, contrairement à ce qui était dit dans la littérature, la phase G est le contributeur majoritaire au durcissement pour les aciers avec Mo. Ce n'est qu'aux temps longs, lorsque la coalescence des particules de phase G intervient et que la DS est plus développée que la contribution de la DS devient prépondérante. Ceci est dû à la forte densité de particules de phase G dans ces aciers. Dans le cas des aciers sans Mo qui contiennent dix fois moins de particules en début de cinétique, la phase G et la DS ont des contributions équivalentes. – Influence du Ni, Mo et Mn : L’étude d’alliage modèles de compositions ciblées a montré que seul le Ni accélère la décomposition spinodale et que le Mn a un rôle prépondérant dans la formation des particules de phase G aux interfaces α/α’. - Efficacité d'un traitement thermique de régénération à 550 °C: Une alternative au remplacement des composants les plus vieillis pourrait être un traitement thermique dit de régénération. Les recuits à 550 °C permettent de restaurer entièrement les aciers sans Mo et partiellement les aciers avec Mo. Ceci est dû au fait que les particules de phase G ne sont pas entièrement dissoutes dans le cas des aciers avec Mo, induisant un durcissement résiduel. Dans tous les cas, la DS est entièrement dissoute. / Cast austenitic-ferritic stainless steels are used in primary circuit of 2nd generation nuclearpower plants. At operating temperature (285 °C - 325 °C), evolution of mechanical properties isobserved due to the phase transformations occurring within the ferrite: spinodal decomposition (SD)leading to the formation on a Fe rich phase (α) and a Cr rich phase (α ') and the precipitation of the G-phase at α/α' interfaces. This evolution of the mechanical properties can be prohibitive for thecomponents. If it is well known that the steel composition plays an important role on the evolution ofthe properties (steels less rich in Ni and Mo are less sensitive to aging), the role of solute elements asNi, Mo and Mn on the aging kinetics is not yet known so as the contribution of the G-phase on thehardening during the thermal aging. In this study, the aging kinetics of the ferrite of some austenitic-ferritic stainless steels with or without Mo and model alloys with tuned compositions have been studied by atom probe tomography (APT) and by micro hardness measurements. This works answered the three following questions: - Quantification of the contribution of both spinodal decomposition and G-phase precipitation on hardening of the ferrite: combination of hardening models and data obtained with APT permitted to show that G-phase precipitation is clearly the main contributor to ferrite hardness increase at early stage of ageing in Mo-bearing steels. This is due to the high number density of G-phase particles. In Mo-free steels which have ten times less G-phase particles, contributions of both spinodal decomposition and G-phase precipitation are similar. In both cases, when coarsening of G-phase particles occurs and SD is well developed, SD contribution becomes larger. - Influence of Ni, Mo and Mn on aging kinetics: The study of model alloys with tuned composition has shown that only Ni plays a role on SD by enhancing the decomposition. Mn is a key element for the precipitation of G-phase particles at α/α' interfaces. - Efficiency of regeneration heat treatment at 550 °C: an alternative to component replacement is to perform a heat treatment at higher temperature in order to restore the properties of the components. The heat treatments performed permitted to entirely restore the mechanical properties of Mo free steels and partially the properties of Mo bearing ones. This is due to the presence of undissolved G-phase particles in the case of Mo bearing alloys. In each case, SD was totally dissolved.

Aciers inoxydables austéno-ferritiques

Vieillissement thermique

Décomposition spinodale

Phase G

Sonde atomique tomographique

Transformations de phases

Durcissement

Duplex stainless steel

Thermal ageing

Spinodal decomposition

G phase

Atom probe tomography

Phase transformations

Hardening

620.112

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

Westin, Elin M.

January 2010

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

Duplex stainless steel

welding

HAZ

nitrogen

manganese

microstructure

austenite formation

phase balance

precipitates

element distribution

segregation

depletion

solidification

pitting corrosion resistance

solidification

element loss

evaporation

deposition

weld oxide

thermo-mechanical simulation

thermodynamic modelling

EPMA

XPS

post-weld cleaning

pickling

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

Westin, Elin M.

January 2008

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

Duplex stainless steel

welding

weld metal

HAZ

nitrogen

manganese

austenite formation

phase balance

precipitates

pitting resistance

heat input

solidification

element loss

evaporation

deposition

weld oxides

discoloration

mechanical properties

thermo-mechanical simulation

Geeble

GTA

laser

LOM

SEM

EDS

TEM

Leco

EPMA

ferroxyl test

XPS

post weld cleaning

pickling

Materials science

Teknisk materialvetenskap

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

Westin, Elin M.

January 2008

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

Duplex stainless steel

welding

weld metal

HAZ

nitrogen

manganese

austenite formation

phase balance

precipitates

pitting resistance

heat input

solidification

element loss

evaporation

deposition

weld oxides

discoloration

mechanical properties

thermo-mechanical simulation

Geeble

GTA

laser

LOM

SEM

EDS

TEM

Leco

EPMA

ferroxyl test

XPS

post weld cleaning

pickling

Materials Engineering

Materialteknik

Performance characterisation of duplex stainless steel in nuclear waste storage environment

Ornek, Cem

January 2016

The majority of UK’s intermediate level radioactive waste is currently stored in 316L and 304L austenitic stainless steel containers in interim storage facilities for permanent disposal until a geological disposal facility has become available. The structural integrity of stainless steel canisters is required to persevere against environmental degradation for up to 500 years to assure a safe storage and disposal scheme. Hitherto existing severe localised corrosion observances on real waste storage containers after 10 years of exposure to an ambient atmosphere in an in-land warehouse in Culham at Oxfordshire, however, questioned the likelihood occurrence of stress corrosion cracking that may harm the canister’s functionality during long-term storage. The more corrosion resistant duplex stainless steel grade 2205, therefore, has been started to be manufactured as a replacement for the austenitic grades. Over decades, the threshold stress corrosion cracking temperature of austenitic stainless steels has been believed to be 50-60°C, but lab- and field-based research has shown that 304L and 316L may suffer from atmospheric stress corrosion cracking at ambient temperatures. Such an issue has not been reported to occur for the 2205 duplex steel, and its atmospheric stress corrosion cracking behaviour at low temperatures (40-50°C) has been sparsely studied which requires detailed investigations in this respect. Low temperature atmospheric stress corrosion cracking investigations on 2205 duplex stainless steel formed the framework of this PhD thesis with respect to the waste storage context. Long-term surface magnesium chloride deposition exposures at 50°C and 30% relative humidity for up to 15 months exhibited the occurrence of stress corrosion cracks, showing stress corrosion susceptibility of 2205 duplex stainless steel at 50°C.The amount of cold work increased the cracking susceptibility, with bending deformation being the most critical type of deformation mode among tensile and rolling type of cold work. The orientation of the microstructure deformation direction, i.e. whether the deformation occurred in transverse or rolling direction, played vital role in corrosion and cracking behaviour, as such that bending in transverse direction showed almost 3-times larger corrosion and stress corrosion cracking propensity. Welding simulation treatments by ageing processes at 750°C and 475°C exhibited substantial influences on the corrosion properties. It was shown that sensitisation ageing at 750°C can render the material enhanced susceptible to stress corrosion cracking at even low chloride deposition densities of ≤145 µm/cm². However, it could be shown that short-term heat treatments at 475°C can decrease corrosion and stress corrosion cracking susceptibility which may be used to improve the materials performance. Mechanistic understanding of stress corrosion cracking phenomena in light of a comprehensive microstructure characterisation was the main focus of this thesis.

620.1