The effect of temperature on the properties of permanent magnet alloys of the NdFeBCo system

Coulson, I. M.

January 1987

No description available.

669

Cobalt alloy magnetic study

Effect of Heat Treatment on Magnetic and Mechanical Properties of an Iron-Cobalt-Vanadium-Niobium Alloy

Hailer, Benjamin Thomas

21 May 2002

Iron-cobalt-vanadium alloys can be processed to have excellent soft magnetic properties for use in high performance power generation applications such as the rotors and stators of aircraft integrated power units. These soft magnetic properties are, however, developed at the expense of mechanical strength and toughness. Small additions of niobium are reported to increase the strength of these Fe-Co-V alloys. This study evaluates the effects of heat treatment on the mechanical and magnetic properties of heavily cold work strip of a 48 wt.% iron-48 wt.% cobalt-2 wt.% vanadium alloy with a 0.3 wt.% addition of niobium. For heat treatments between 640 and 740°C for 1 hour the tensile and yield strengths and ductility of the alloy were all found to be superior to a similar alloy found in the literature without the addition of Nb and processed in a similar manner. Magnetic permeability, remnant induction, saturation induction, coercivity and core loss were only slightly degraded at all annealing temperatures when compared with the non-niobium containing alloy. All properties were shown to depend primarily on degree of recrystallization of the sample, which was found to fully recrystallize between 720 and 740 °C for 1 hour anneals. No significant change in measured properties were found when annealing time was increased to 2 hours. Full recrystallization was observed for samples annealed for as short of times as 10 minutes at 800 °C. / Master of Science

Hiperco 50HS

magnetic

Iron Cobalt alloy

mechanical

Growth and characterization of advanced layered thin film structures : Amorphous SmCo thin film alloys

Roos, Andreas

January 2012

This report describes the growth and characterization of thin amorphous samarium-cobalt alloy films. The samarium-cobalt alloy was grown by DC magnetron sputtering in the presence of an external magnetic field parallel to the thin film. The external magnetic field induces a uniaxial in-plane magnetic anisotropy in the samarium-cobalt alloy. The thin films were characterized with x-ray scattering, and the magnetic anisotropy was characterized with the magneto optic Kerr effect. The measurements showed a uniaxial in-plane magnetic anisotropy in the samarium-cobalt alloy films. It is not clear how amorphous the samples really are, but there are indications of crystalline and amorphous areas in the alloys.

uniaxial magnetic anisotropy

samarium Cobalt alloy

amorphous thin film

DC magnetron sputtering

magneto optic Kerr effect

x-ray scattering

Recrystallization of L-605 cobalt superalloy during hot-working process

Favre, Julien

25 September 2012

Co-20Cr-15W-10Ni alloy (L-605) is a cobalt-based superalloy combining high strength with keeping high ductility, biocompatible and corrosion resistant. It has been used successfully for heart valves for its chemical inertia, and this alloy is a good candidate for stent elaboration. Control of grain size distribution can lead to significant improvement of mechanical properties: in one hand grain refinement enhance the material strength, and on the other hand large grains provide the ductility necessary to avoid the rupture in use. Therefore, tailoring the grain size distribution is a promising way to adapt the mechanical properties to the targeted applications. The grain size can be properly controlled by dynamic recrystallization during the forging process. Therefore, the comprehension of the recrystallization mechanism and its dependence on forging parameters is a key point of microstructure design approach. The optimal conditions for the occurrence of dynamic recrystallization are determined, and correlation between microstructure evolution and mechanical behavior is investigated. Compression tests are carried out at high-temperature on Thermec-master Z and Gleeble forging devices, followed by gas or water quench. Mechanical behavior of the material at high temperature is analyzed in detail, and innovative methods are proposed to determine the metallurgical mechanisms at stake during the deformation process. Mechanical properties of the material after hot-working and annealing treatments are investigated. The grain growth kinetics of L-605 alloy is determined, and experimental results are compared with the static recrystallization process. Microstructures after hot deformation are evaluated using SEM-EBSD and TEM. Significant grain refinement occurs by dynamic recrystallization for high temperature and low strain rate (T≥1100 ◦ C, strain rate < 0.1s−1), and at high strain rate (strain rate > 10s−1). Dynamic recrystallization is discontinuous and takes place from the grain boundaries, leading to a necklace structure. The nucleation mechanism is most likely to be bulging from grain boundaries and twin boundaries. A new insight of the modeling of dynamic recrystallization taking as a starting point the experimental data is proposed. By combining the results from the mechanical behavior study and microstructure observation, the recrystallization at steady-state is thoroughly analyzed and provides the mobility of grain boundaries. The nucleation criterion for the bulging from grain boundaries is reformulated to a more general expression suitable for any initial grain size. Nucleation frequency can be deduced from experimental data at steady-state through modeling, and is extrapolated to any deformation condition. From this point, a complete analytical model of the dynamic recrystallization is established, and provides a fair prediction on the mechanical behavior and the microstructure evolution during the hot-working process.

[SPI:OTHER] Engineering Sciences/Other

Cobalt alloy

Superalloy

Biocompatible material

Recrystallization

Hot working

Mechanical properties

Microstructure

EBSD - Electron BackScatter Diffraction

TEM - Transmission electronic microscopy

Analytical modeling

Recrystallization of L-605 cobalt superalloy during hot-working process / Recristallisation du superalliage base cobalt L-605 pendant la déformation à chaud

Favre, Julien

25 September 2012

L’alliage L-605 est un superalliage base cobalt combinant une haute résistance et une bonne ductilité, de plus il est biocompatible et présente une bonne résistance a la corrosion. Dû a son inertie chimique dans le corps humain, ce matériau a été utilise avec succès pour fabriquer des valves cardiaques et des stents. Le contrôle de la microstructure peut influencer grandement les propriétés mécaniques : notamment un raffinement des grains est susceptible d’augmenter d’avantage la résistance et serait intéressant pour permettre de fabriquer des stents selon une architecture plus fine. L’ajustement de la distribution de taille de grains à travers le phénomène de recristallisation lors de la déformation à chaud apparait comme une solution pratique pour ajuster les propriétés mécaniques du matériau. Pour contrôler la microstructure et choisir les conditions de procédé optimales, les mécanismes mis en jeu lors de la recristallisation dynamique et l’effet des conditions de déformation sur la taille de grain doivent être compris et prévisibles par des outils théorique. Les propriétés mécaniques du matériau à haute température sont déterminées par des essais de compression à chaud. L’évolution microstructurale du matériau lors de la compression est analysée par microscopie optique et électronique (EBSD, TEM). Le phénomène de recristallisation dynamique continue est mis en évidence, et procède par nucléation de nouveaux grains aux joints de grain. La corrélation entre le comportement mécanique à chaud et l’évolution microstructurale est déterminée expérimentalement. Les conditions optimales de déformation impliquant la recristallisation dynamique sont déterminées, et la microstructure résultante est étudiée en détail. De nouveaux outils théoriques permettant de prévoir les conditions de recristallisation et d’extraire les paramètres physiques du matériau a partir des données expérimentales sont proposés. Enfin, la recristallisation dynamique est modélisée analytiquement, et permet de prédire le comportement mécanique et l’évolution de la taille de grain lors de la déformation. / Co-20Cr-15W-10Ni alloy (L-605) is a cobalt-based superalloy combining high strength with keeping high ductility, biocompatible and corrosion resistant. It has been used successfully for heart valves for its chemical inertia, and this alloy is a good candidate for stent elaboration. Control of grain size distribution can lead to significant improvement of mechanical properties: in one hand grain refinement enhance the material strength, and on the other hand large grains provide the ductility necessary to avoid the rupture in use. Therefore, tailoring the grain size distribution is a promising way to adapt the mechanical properties to the targeted applications. The grain size can be properly controlled by dynamic recrystallization during the forging process. Therefore, the comprehension of the recrystallization mechanism and its dependence on forging parameters is a key point of microstructure design approach. The optimal conditions for the occurrence of dynamic recrystallization are determined, and correlation between microstructure evolution and mechanical behavior is investigated. Compression tests are carried out at high-temperature on Thermec-master Z and Gleeble forging devices, followed by gas or water quench. Mechanical behavior of the material at high temperature is analyzed in detail, and innovative methods are proposed to determine the metallurgical mechanisms at stake during the deformation process. Mechanical properties of the material after hot-working and annealing treatments are investigated. The grain growth kinetics of L-605 alloy is determined, and experimental results are compared with the static recrystallization process. Microstructures after hot deformation are evaluated using SEM-EBSD and TEM. Significant grain refinement occurs by dynamic recrystallization for high temperature and low strain rate (T≥1100 ◦ C, strain rate < 0.1s−1), and at high strain rate (strain rate > 10s−1). Dynamic recrystallization is discontinuous and takes place from the grain boundaries, leading to a necklace structure. The nucleation mechanism is most likely to be bulging from grain boundaries and twin boundaries. A new insight of the modeling of dynamic recrystallization taking as a starting point the experimental data is proposed. By combining the results from the mechanical behavior study and microstructure observation, the recrystallization at steady-state is thoroughly analyzed and provides the mobility of grain boundaries. The nucleation criterion for the bulging from grain boundaries is reformulated to a more general expression suitable for any initial grain size. Nucleation frequency can be deduced from experimental data at steady-state through modeling, and is extrapolated to any deformation condition. From this point, a complete analytical model of the dynamic recrystallization is established, and provides a fair prediction on the mechanical behavior and the microstructure evolution during the hot-working process.

Alliage de cobalt

Superalliage

Matériau biocompatible

Recristallisation

Déformation à chaud

Propriété mécanique

Microstructure

Modélisation analytique

Cobalt alloy

Superalloy

Biocompatible material

Recrystallization

Hot working

Mechanical properties

Microstructure

EBSD - Electron BackScatter Diffraction

TEM - Transmission electronic microscopy

Analytical modeling

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