Etude des premiers instants d'oxydation d'un acier ferrito-martensitique FE-12CR dans le CO2 / Study of the first stages of oxidation of a ferritic-martensitic steel FE-12CR in CO2

Bouhieda, Soraya

16 October 2012

Dans le cadre du développement des réacteurs nucléaires de 4ème génération et plus particulièrement du réacteur à neutrons rapides refroidi au sodium (SFR), le CO2 supercritique, dans un cycle de Brayton, a été identifié comme fluide potentiel en remplacement de la vapeur d'eau dans le cycle de conversion de l'énergie. Les aciers ferrito-martensitiques contenant 9 à 12 % en poids de Cr sont de bons candidats pour la réalisation d'échangeurs thermiques car ils présentent de bonnes propriétés mécaniques jusqu'à une température de 600°C, une forte conductivité thermique, un faible coefficient d'expansion thermique ainsi qu'un coût plus faible que celui des aciers austénitiques. Cependant, il a été montré que ces aciers forment une couche d’oxyde à croissance rapide et carburent fortement dans les conditions du circuit de conversion d'énergie (550°C, 250 bar).Cette étude a pour objectif d’étudier l’influence de différents paramètres (les impuretés présentes dans le CO2, les vitesses de rampe thermique ainsi que l’état de surface) sur le mécanisme d’oxydation d’un acier Fe-12Cr dans le CO2 à 550°C. Il est montré qu’en fonction de la valeur de ces paramètres, il est possible de former une couche d’oxyde fine protectrice en surface sans carburation. Un modèle permettant de rendre compte de l’ensemble des résultats expérimentaux est proposé. / In the framework of the development of Sodium Fast Reactors in France, supercritical carbon dioxide integrated in the Brayton cycle is proposed as new cycle energy conversion system to replace current steam generators. Ferritic-Martensitic steels with 9-12 wt% Cr are good candidates for heat exchanger application because they have good mechanical properties up to a temperature of 600°C, a high thermal conductivity, a low coefficient of thermal expansion and a lower cost than that of austenitic steels. However, it has been found that these steels present a high parabolic oxide growth rate and a strong carburization in the temperature and pressure conditions of the SC-CO2 cycle (550°C, 250 bar).This study aims to investigate the influence of different parameters (impurities present in CO2, thermal ramp rate and surface state) on the oxidation mechanism of a Fe-12 Cr steel in CO2 at 550°C. It has been shown that depending on these parameters, a thin protective oxide scale without any strong carburization can be obtained. A model is proposed to explain the experimental results.

CO2 supercritique

Aciers ferrito-martensitiques

Oxydation

Impuretés

Supercritical CO2

Ferritic-martensitic steels

Oxidation

Impurity

Caracterização microestrutural do aço ODS Eurofer recozido isotermicamente até 1350oC / Microstructural characterization of ODS Eurofer steel isothermally annealed up to 1350°C

Bredda, Eduardo Henrique

24 March 2015

O aço ferrítico-martensítico ODS Eurofer com 9%pCr (ODS - do inglês oxide dispersion strengthened), objeto de estudo dessa dissertação, é um potencial candidato para fins estruturais em reatores de fusão nuclear. Este material foi produzido via metalurgia do pó e consolidado por prensagem isostática. Em seguida sofreu laminação cruzada a quente e revenimento em 750°C por 2h. Esta foi a condição como recebida desse aço, o qual foi cedido pelo KIT (Karlsruher Institut für Technologie - Alemanha). Este aço possui 0,3%p de partículas de ítria (Y2O3) com diâmetro entre 10 e 30 nm. Uma das finalidades dessa dispersão de partículas de óxido é impedir a livre movimentação de contornos de grão no material, de modo a garantir a estabilidade microestrutural do mesmo sob recozimento. O aço ODS Eurofer como recebido foi laminado a frio com reduções de 20, 40, 60 e 80% da espessura e, posteriormente, foi recozido em diversas temperaturas entre 300 e 1350°C por 1h. Como o enfoque desse trabalho é sobre o aço ODS Eurofer recozido em altas temperaturas, para as temperaturas de 1250, 1300 e 1350°C foram feitos recozimentos adicionais (para o material com 80% de redução) variando-se o tempo de recozimento de 1 a 8 h. Para todos os recozimentos, com exceção dos realizados em 1350°C, o resfriamento das amostras se deu ao ar. Para a temperatura de 1350°C isso não foi possível e o resfriamento das amostras se deu no interior do forno. As amostras foram caracterizadas utilizando-se de medidas de dureza, medidas magnéticas e microscopia eletrônica de varredura (MEV). Amostras representativas também foram analisadas utilizando-se de difração de elétrons retroespalhados (EBSD) e espectroscopia por energia dispersiva (EDS). Para recozimentos em temperaturas acima de 800°C seguidos de resfriamento ao ar o material sofreu uma transformação martensítica. Na faixa de temperatura entre 800°C e 1300°C verificou-se um ligeiro decréscimo na dureza do material. Para as amostras com 80% de redução e recozidas em 1250 e 1300°C por diversos tempos até 8 h, seguido de resfriamento ao ar, não ocorreu uma variação significativa tanto nos valores de dureza e de campo coercivo das amostras com o tempo de recozimento. Estes valores se mantiveram em um patamar bem superior ao verificado para as amostras sem recozimento. Para as amostras recozidas em 1350°C, devido às características do resfriamento a microestrutura resultou em grãos ferríticos, aproximadamente equiaxiais e com tamanho de grão médio da ordem de 15 ?m. Observou-se uma notável queda tanto no valor de dureza como de campo coercivo dessas amostras. A observação mais importante nesse caso foi a observação de partículas da ordem de 100 nm ricas em ítrio no interior dos grãos, uma evidência de que ocorre o engrossamento das partículas de ítria nessa temperatura. Em virtude disso, a capacidade dessa dispersão de óxidos em impedir a livre movimentação de contornos de grãos no material fica prejudicada em 1350°C. / The object of this study is Eurofer 9% Cr Oxide Dispersion Strengthened (ODS) steel. This ferritic/martensitic steel is a potential candidate for structural applications in nuclear fusion reactors. It is produced through powder metallurgy and consolidated by hot isostatic pressing. The material undergoes hot cross lamination and is tempered at 760 °C. This was the condition of the steel as received, which was provided by KIT (Karlsruher Institut für Technologie, Germany). This steel contains 0.3 wt% yttria particles (Y2O3) with a diameter in the range 10-30nm. The main purpose of this oxide particle dispersion is to prevent the free movement of the grain boundaries in the material, so as to ensure stability of the microstructure during annealing. The material as received was cold rolled to reduce thickness by 20, 40, 60 and 80%. It was annealed at different temperatures from 300 to 1350 °C for 1 h. The focus of this study is the effects of high temperature annealing on the microstructure of ODS Eurofer. For this purpose, additional heat treatments were carried out on the steel that had been rolled to reduce thickness by 80% at temperatures of 1250, 1300 and 1350 °C. Annealing time varied between 15 min and 8 h. For all annealing conditions, except those carried out at 1350 °C, the samples were air cooled. For the temperature of 1350 °C, this was not possible. These samples were cooled in the oven. The samples were characterized using hardness testing, magnetic testing, and scanning electron microscopy (SEM). Representative samples were also analyzed using electron backscatter diffraction (EBSD) and energy dispersive spectroscopy (EDS). For annealing at temperatures above 800 °C, the material underwent a martensitic transformation after air cooling. Between 800 and 1300 °C, there was a slight decrease in the hardness of the material. For samples with 80% reduction annealed at 1250 and 1300 °C followed by air cooling, annealing time up to 8h didn\'t lead to a significant variation in either the hardness or the coercive field. Both hardness and coercive field of these samples were at a level well above the samples without annealing. For samples annealed at 1350 °C, due to the cooling characteristics of the samples, the microstructure took on a ferritic matrix with equiaxed grains with an average grain size of 15 um. There was a remarkable decrease in hardness and coercive field values of these samples. The most important result in this case was the observation of yttria-rich particles of the order of 100nm inside the grains. This is an evidence of the coarsening of the yttria particles at this temperature. As a result, the capacity of oxide dispersion to prevent the free movement of grain boundaries in the material is impaired at 1350°C.

Aços ferrítico-martensíticos

Campo coercivo

Coercive field

Dureza

Ferritic/martensitic steels

Hardness

Microestrutura

Microstructure

Caracterização microestrutural do aço ODS Eurofer recozido isotermicamente até 1350oC / Microstructural characterization of ODS Eurofer steel isothermally annealed up to 1350°C

Eduardo Henrique Bredda

24 March 2015

O aço ferrítico-martensítico ODS Eurofer com 9%pCr (ODS - do inglês oxide dispersion strengthened), objeto de estudo dessa dissertação, é um potencial candidato para fins estruturais em reatores de fusão nuclear. Este material foi produzido via metalurgia do pó e consolidado por prensagem isostática. Em seguida sofreu laminação cruzada a quente e revenimento em 750°C por 2h. Esta foi a condição como recebida desse aço, o qual foi cedido pelo KIT (Karlsruher Institut für Technologie - Alemanha). Este aço possui 0,3%p de partículas de ítria (Y2O3) com diâmetro entre 10 e 30 nm. Uma das finalidades dessa dispersão de partículas de óxido é impedir a livre movimentação de contornos de grão no material, de modo a garantir a estabilidade microestrutural do mesmo sob recozimento. O aço ODS Eurofer como recebido foi laminado a frio com reduções de 20, 40, 60 e 80% da espessura e, posteriormente, foi recozido em diversas temperaturas entre 300 e 1350°C por 1h. Como o enfoque desse trabalho é sobre o aço ODS Eurofer recozido em altas temperaturas, para as temperaturas de 1250, 1300 e 1350°C foram feitos recozimentos adicionais (para o material com 80% de redução) variando-se o tempo de recozimento de 1 a 8 h. Para todos os recozimentos, com exceção dos realizados em 1350°C, o resfriamento das amostras se deu ao ar. Para a temperatura de 1350°C isso não foi possível e o resfriamento das amostras se deu no interior do forno. As amostras foram caracterizadas utilizando-se de medidas de dureza, medidas magnéticas e microscopia eletrônica de varredura (MEV). Amostras representativas também foram analisadas utilizando-se de difração de elétrons retroespalhados (EBSD) e espectroscopia por energia dispersiva (EDS). Para recozimentos em temperaturas acima de 800°C seguidos de resfriamento ao ar o material sofreu uma transformação martensítica. Na faixa de temperatura entre 800°C e 1300°C verificou-se um ligeiro decréscimo na dureza do material. Para as amostras com 80% de redução e recozidas em 1250 e 1300°C por diversos tempos até 8 h, seguido de resfriamento ao ar, não ocorreu uma variação significativa tanto nos valores de dureza e de campo coercivo das amostras com o tempo de recozimento. Estes valores se mantiveram em um patamar bem superior ao verificado para as amostras sem recozimento. Para as amostras recozidas em 1350°C, devido às características do resfriamento a microestrutura resultou em grãos ferríticos, aproximadamente equiaxiais e com tamanho de grão médio da ordem de 15 ?m. Observou-se uma notável queda tanto no valor de dureza como de campo coercivo dessas amostras. A observação mais importante nesse caso foi a observação de partículas da ordem de 100 nm ricas em ítrio no interior dos grãos, uma evidência de que ocorre o engrossamento das partículas de ítria nessa temperatura. Em virtude disso, a capacidade dessa dispersão de óxidos em impedir a livre movimentação de contornos de grãos no material fica prejudicada em 1350°C. / The object of this study is Eurofer 9% Cr Oxide Dispersion Strengthened (ODS) steel. This ferritic/martensitic steel is a potential candidate for structural applications in nuclear fusion reactors. It is produced through powder metallurgy and consolidated by hot isostatic pressing. The material undergoes hot cross lamination and is tempered at 760 °C. This was the condition of the steel as received, which was provided by KIT (Karlsruher Institut für Technologie, Germany). This steel contains 0.3 wt% yttria particles (Y2O3) with a diameter in the range 10-30nm. The main purpose of this oxide particle dispersion is to prevent the free movement of the grain boundaries in the material, so as to ensure stability of the microstructure during annealing. The material as received was cold rolled to reduce thickness by 20, 40, 60 and 80%. It was annealed at different temperatures from 300 to 1350 °C for 1 h. The focus of this study is the effects of high temperature annealing on the microstructure of ODS Eurofer. For this purpose, additional heat treatments were carried out on the steel that had been rolled to reduce thickness by 80% at temperatures of 1250, 1300 and 1350 °C. Annealing time varied between 15 min and 8 h. For all annealing conditions, except those carried out at 1350 °C, the samples were air cooled. For the temperature of 1350 °C, this was not possible. These samples were cooled in the oven. The samples were characterized using hardness testing, magnetic testing, and scanning electron microscopy (SEM). Representative samples were also analyzed using electron backscatter diffraction (EBSD) and energy dispersive spectroscopy (EDS). For annealing at temperatures above 800 °C, the material underwent a martensitic transformation after air cooling. Between 800 and 1300 °C, there was a slight decrease in the hardness of the material. For samples with 80% reduction annealed at 1250 and 1300 °C followed by air cooling, annealing time up to 8h didn\'t lead to a significant variation in either the hardness or the coercive field. Both hardness and coercive field of these samples were at a level well above the samples without annealing. For samples annealed at 1350 °C, due to the cooling characteristics of the samples, the microstructure took on a ferritic matrix with equiaxed grains with an average grain size of 15 um. There was a remarkable decrease in hardness and coercive field values of these samples. The most important result in this case was the observation of yttria-rich particles of the order of 100nm inside the grains. This is an evidence of the coarsening of the yttria particles at this temperature. As a result, the capacity of oxide dispersion to prevent the free movement of grain boundaries in the material is impaired at 1350°C.

Aços ferrítico-martensíticos

Campo coercivo

Dureza

Microestrutura

Coercive field

Ferritic/martensitic steels

Hardness

Microstructure

INITIAL STAGE OF DEFECT STRUCTURAL EVOLUTION IN F82H AND ITS MODEL ALLOYS BY IRRADIATION DAMAGE / F82H及びそのモデル合金鋼の照射損傷初期における欠陥構造発達過程

Huang, Shaosong

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第18266号 / 工博第3858号 / 新制||工||1592(附属図書館) / 31124 / 京都大学大学院工学研究科機械理工学専攻 / (主査)教授 福永 俊晴, 教授 白井 泰治, 准教授 徐 蛟 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

Ferritic/martensitic steels

Defects evolution

Irridation damage

Void swelling resistance

500

Thermodynamic Evaluation and Modeling of Grade 91 Alloy and its Secondary Phases through CALPHAD Approach

Smith, Andrew Logan, Mr.

07 May 2018

Grade 91 (Gr.91) is a common structural material used in boiler applications and is favored due to its high temperature creep strength and oxidation resistance. Under cyclic stresses, the material will experience creep deformation eventually causing the propagation of type IV cracks within its heat-affected-zone (HAZ) which can be a major problem under short-term and long-term applications. In this study, we aim to improve this premature failure by performing a computational thermodynamic study through the Calculation of Phase Diagram (CALPHAD) approach. Under this approach, we have provided a baseline study as well as simulations based on additional alloying elements such as manganese (Mn), nickel (Ni), and titanium (Ti). Our simulation results have concluded that high concentrations of Mn and Ni had destabilized M23C6 for short-term creep failure, while Ti had increased the beneficial MX phase, and low concentrations of nitrogen (N) had successfully destabilized Z-phase formation for long-term creep failure.

Grade 91 steel

Creep resistance

Ferritic-Martensitic steels

Welding microstructure

Computational thermodynamics

Secondary phase

Alloy composition

Computational Engineering

Structural Materials

Strukturní stabilita žárupevných ocelí a jejich svarů / Structural Stability of Creep-Resistant Steels and their Weldmets

Šohaj, Pavel

January 2009

The structural stability of creep-resistant steels P22, P91 and Eurofer´97 and structural stability of weld joint P22/P91 have been studied. The microstructural changes during annealing at temperatures of 500 – 900°C were examined. The state of equilibrium have been simulated using the ThermoCalc software. The computed results were compared with published data. A good agreement between the simulation and the published data was observed.

Creep and Creep-fatigue Deformation Studies in 22V and P91 Creep-strength EnhancedFerritic Steels

Whitt, Harrison Collin

11 July 2019

No description available.

Materials Science

ferritic-martensitic steels

CSEFS

22V

P91

FCAW

CMT

creep

creep-fatigue

type IV failure

anelastic backflow

polarity

SAW

subgrains

carbides

cr-mo steels

dislocation density

MECHANICAL PROPERTIES AND RADIATION RESPONSE OF NANOSTRUCTURED FERRITIC-MARTENSITIC STEELS

Zhongxia Shang (9171533)

17 November 2022

<p>Structural metallic materials exposed to energetic particle bombardments often experience various types of irradiation-induced microstructural damage, thus degrading the mechanical properties of the materials in form of irradiation hardening and embrittlement. Nanostructured materials have shown better radiation resistance than their coarse-grained (CG) counterparts due to the existence of abundant defect sinks, such as grain boundaries, twin boundaries, and phase boundaries. However, recently developed nanocrystalline (NC) steels show limited room-temperature tensile ductility (< 1%), which may become a concern for their future application for nuclear reactors. The focus of this thesis is to explore the strength-ductility dilemma in modified 9Cr1Mo (T91) ferritic/martensitic (F/M) steel processed by thermomechanical treatment (TMT) and surface severe plastic deformation (SSPD) with an attempt to fabricate strong, ductile and radiation resistant F/M steels. </p> <p><b>Carbon partitioning</b> between the quenched martensite and the other phases (bainitic ferrite or retained austenite) is critical for enhancing the strength and ductility of T91 steel. The tensile properties of partially tempered (PT) T91 steel can be tailored through introducing bainitic ferrite with high-density nanoscale transition carbides and refined lath martensite. In addition, retained austenite was introduced by increasing the carbon concentration of T91 steel to 0.6 wt.%. The carbon-modified steel processed by quenching partitioning (Q-P) treatment exhibits an ultrahigh strength, ~ 2 GPa, with a uniform strain of ~ 5% due to the existence of coherent carbides, ultrafine martensite and retained austenite. </p> <p>Meanwhile, surface mechanical grinding treatment (SMGT) on T91 steel reveals that introducing <b>gradient structures</b> on the sample surface contributes to a higher strength and an improved plasticity than its homogeneously structured counterpart. The deformation mechanism of the gradient structures was investigated with the assistance of quasi <i>in situ</i> crystal orientation analyses. Furthermore, <i>ex situ</i> He ion irradiation on the gradient T91 steel indicates that radiation-induced damage, such as bubble-induced swelling and irradiation hardening, were gradually mitigated by grain refinement from the sample surface to the center, resulting in superior radiation resistance. The results obtained from this thesis may facilitate the design and fabrication of strong, ductile and radiation-tolerant F/M steels.</p>

Metals and alloy materials

Nanomaterials

Ferritic-martensitic steels

thermomechanical treatment (TMT) process

surface severe plastic deformation

mechanical properties

radiation damages

Metals and Alloy Materials

Nanomaterials