Etude des mécanismes de corrosion sous contrainte des aciers inoxydables supermartensitiques en milieu H2S / Study of stress corrosion mechanisms of supermartensitic stainless steels in sulphure hydrogen medium

Monnot, Martin

28 September 2017

Les aciers inoxydables super martensitiques sont très utilisés dans le secteur pétrochimique, mais ils présentent des ruptures en service en conditions sévères. L'objectif de cette étude est d'apporter une meilleure compréhension du mécanisme de corrosion sous contrainte de ces matériaux en milieu H$_2$S. Pour cela, des coulées laboratoires ont été élaborées avec différentes teneurs en molybdène, élément connu pour améliorer la résistance à la corrosion. Ces ajouts d'éléments d'alliage impliquent alors une caractérisation fine de la microstructure, pour bien appréhender par la suite les mécanismes de rupture. Une attention particulière a été apportée à l'évolution de la fraction d'austénite et de ferrite résiduelle avec les traitements thermiques d'hypertrempe et de revenus qui sont couramment pratiqués sur ces nuances. Puis, par des mesures électrochimiques sans contrainte mécanique, l'ajout de molybdène a été identifiée comme bénéfique pour renforcer la passivité de la nuance dans le milieu H$_2$S. Et pour des teneurs en molybdène inférieures à 2,25%, des produits de corrosion ont été identifiés, principalement des sulfures de nickel, qui sont des inhibiteurs de la recombinaison de l'hydrogène. Par la suite, des essais de corrosion sous contrainte sous charge statique et dynamique couplés à des mesures d'impédance électrochimique montrent un effet bénéfique du molybdène et de l'austénite résiduelle. Le molybdène permet notamment de réduire les défauts du film passif. Un modèle d'éléments finis permet de simuler les essais de traction lente en tenant compte de la fragilisation par hydrogène. Afin de l'alimenter avec des paramètres expérimentaux, une cellule de perméation électrochimique a été montée et a permis de mesurer le coefficient de diffusion de l'hydrogène au sein de nos différentes coulées. Le modèle présente alors une bonne adéquation avec les résultats expérimentaux et une étude paramétrique a été réalisée sur le coefficient de diffusion et sur la concentration interfaciale en hydrogène. Enfin, une synthèse permet la proposition d?un mécanisme de corrosion sous contrainte comportant deux étapes : la résistance du film passif pour limiter l'absorption de l?hydrogène dans la matrice et le piégeage de l'hydrogène par l'austénite résiduelle en fonction de la déformation. / Super martensitic stainless steels are widely used in the oil and gas industry, but failures occurred in service under severe conditions. The aim of this study is to provide a better understanding of the stress corrosion mechanism in H$_2$S medium. For this purpose, laboratory heats have been casted with different molybdenum contents, a component known to improve corrosion resistance. These additions of alloying elements then involve a fine characterization of the microstructure, in order to grasp the mechanisms of rupture. Particular attention has been paid to the evolution of the retained austenite and residual ferrite fraction with the heat treatments of quench and annealing which are commonly practiced on these grades. Then, by electrochemical measurements without mechanical stress, the addition of molybdenum was identified as beneficial for the passivity of the grade in the H$_2$S medium. And for 2.25% molybdenum contents, corrosion products have been identified as mainly nickel sulfides, which are inhibitors of hydrogen recombination. Subsequently, corrosion tests under static and dynamic load coupled to electrochemical impedance measurements show a beneficial effect of molybdenum and residual austenite. In particular, molybdenum reduces the defects of the passive film. A finite elements model simulates the slow strain rate traction tests taking into account the hydrogen embrittlement. In order to use experimental parameters, an electrochemical permeation cell was implemented and used to measure the hydrogen diffusion coefficient within our different heats. A good match with the experimental results was obtained with this model and a parametric study was carried out on the diffusion coefficient and the hydrogen interfacial concentration. Finally, a synthesis provides the proposal of a stress corrosion mechanism divided in two steps: the passive film resistance to limit the hydrogen absorption in the matrix and the trapping of the hydrogen by the residual austenite in function deformation.

Corrosion sous contrainte

Mécansime de corrosion

Sulfure d'hydrogène

Aciers martensitiques

Stress corrosion

Corrosion mechanism

Hydrogen sulphur

540

Degradation mechanisms of UN and UN–10U3Si2 pellets of varying microstructure by comparative steam oxidation experiments

Uygur, Selim

January 2016

During an extended LOCA in a LWR, the current UO2 fuel reaches very high temperatures and eventually melts, while the current Zircaloy fuel cladding oxidizes releasing hydrogen. These two consequences can lead to an unacceptable amount of radioactive release by presenting accident routes for containment failure. After such an accident at the Fukushima NPP in 2011, the development of Accident Tolerant Fuels LWRs gained additional momentum which aims to increase the margin to fuel melting, and to preserve cladding integrity as long as possible. Among the top ATF candidates compounds are UN and U3Si2, which have a high thermal conductivity and high uranium density. UN melts at 2850 °C on par with UO2, while U3Si2 melts at only 1665 °C. U3Si2 may serve as a second phase in UN–U3Si2 composites with better material properties than pure UN. Early studies on powders and dense samples, found the chemical UN corrosion by steam at all T,p pairs to generate a sandwiched UN/α‒U2N3+x/UO2 corrosion layer with inferior density. It was seen that dense polycrystalline UN would perform poorly due to an intergranular cracking mechanism due to the stresses caused by the growth of this layer. Due to the missing technological ability to control parameters like grain size and open porosity no work exist on the microstructure dependence of high density UN pellet corrosion in steam, and the intergranular cracking mechanism was never captured by imaging techniques. Also, as UN–U3Si2 composites are fairly new, the degradation mechanism of high density samples under steam is not known as no degradation study has yet been published. This work aimed at increasing understanding of the high pressure steam degradation mechanism of Spark Plasma sintered, microstructure controlled, UN and UN–10U3Si2 (wt %) composite samples, and to analyze the influence of grain size and density on the UN corrosion rate. A further goal was to image corrosion progress in the microstructure. For this, HPBAC steam exposure tests on UN and UN–10U3Si2 at 303 °C and 9 MPa were done. Durations were up to 1.5 hours. Samples were 96–99.9% of theoretical density and grain sizes were 6–24 µm. The corrosion in the microstructure of all samples is imaged by Light Optical Microscopy (LOM). Scanning Electron Microscopy/Energy Dispersive Spectroscopy (SEM/EDS) were used to track the change in chemical composition at the grain boundaries. Two continuous steam exposures in flowing Ar and N2 at 400 °C and 1 atm have been done to study the role of N2 and NH3 on the degradation. One TGA on the residue of one of the autoclave tests was done to confirm the final oxidation state. TGA confirms that at 303 °C and 9 MPa the final product is UO2, while Digerator results show that under N2 the corrosion is faster. LOM and SEM/EDS show that UN–pellets exposed to steam are breaking apart by intergranular cracks generated by a layered precipitation of U2N3+x/UO2 in the grain boundaries. As the density of the products differs greatly from that of UN, high intergranular stresses result in cracking. Cracking makes progressively more surfaces available to oxidation/hydrolysis. An increase in density and reduction of open porosity slows the corrosion process, while an increase in grain size accelerates the degradation. Consequently, all other considerations cast aside the most waterproofed microstructure of a pure polycrystalline UN sample will have maximized density, eliminated open porosity, while maintaining a small grain size. As clusters of UN grains are enveloped by the U3Si2 phase in UN–10%U3Si2, the cracking was seen to be predominantly intragranular. Irrespective of the quality of the microstructure polycrystalline UN will fail by intergranular corrosion. U3Si2 seems to react preferentially with the steam precipitating UO2, delaying the attack on the UN grains. The low degree of maximum weight gain and different corrosion progression in the microstructure of UN–10U3Si2 are strong indications that the composite may provide significantly higher steam tolerance than pure UN.

Uranium Mononitride

Uranium Silicide

Composite

Steam degradation

corrosion mechanism

Physical Sciences

Fysik

Thermodynamics and Kinetics of Carbon Dioxide Corrosion of Mild Steel at Elevated Temperatures

Tanupabrungsun, Tanaporn

January 2012

No description available.

Chemical Engineering

Engineering

CO2 corrosion mechanism

mild steel

elevation temperature

pourbaix diagram

thermodynamics

kinetics

Corrosion Mechanisms of Mild Steel in Weak Acids

Tran, Thu N. B.

24 September 2014

No description available.

Chemical Engineering

CO2 corrosion

acetic acid

carbonic acid

mild steel corrosion

weak acids

corrosion mechanism

buffering effect