High Temperature Deformation Mechanism of a High-Purity Fe–50 mass% Cr Alloy

Isozaki, S.; Takaki, S.; Abiko, K.

doi:10.1002/(sici)1521-396x(199806)167:2<471::aid-pssa471>3.0.co;2-m

Cited by 14 publications

(10 citation statements)

References 9 publications

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“…Figure 1 shows the tensile strength and the reduction in area of 60Cr-Fe-4W (I) after Gleeble testing at temperatures between 1273 K and 1573 K, together with the data of 50Cr-Fe and 60Cr-Fe. 3,4) The data of 50Cr-Fe-5W and 50Cr-Fe-8W alloys 5) were also shown in the same Figure. It was found from the present investigation that the tensile strength of 60Cr-Fe increases by the addition of tungsten at temperatures between 1273 K and 1573 K. The reduction in area of 50Cr-Fe increases by the addition of tungsten; however, the Effect of Tungsten on Mechanical Properties of High-Purity 60 mass%Cr-Fe Alloys 143 and Fig. 4(b).…”

Section: Tensile Testmentioning

confidence: 67%

“…6, the nominal stress gradually decreases until fracture after the stress drop at the end of the elastic deformation. Isozaki et al and Kano et al discussed the deformation mechanism of high-purity 50Cr-Fe and 60Cr-Fe between 873 K and 1073 K, respectively, 4,5) that is, the stress drop after yield is due to grain boundary sliding. The gradual stress decreases after the stress drop is due to uniform dislocation slip through the specimen.…”

Section: Effect Of W On Tensile Properties and Microstructurementioning

confidence: 99%

“…Isozaki et al found that the addition of tungsten to high purity 50 mass%Cr-Fe alloys was effective in improving strength and ductility at high temperatures. 5,6) Kako et al reported that the amount of twinning increased with the addition of tungsten.…”

Section: Introductionmentioning

confidence: 99%

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Effect of Tungsten on Mechanical Properties of High-Purity 60 mass%Cr-Fe Alloys

et al. 2002

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The effect of the tungsten addition on the mechanical properties of high-purity 60 mass%Cr-Fe alloy was investigated. High-purity 60 mass%Cr-Fe-4 mass%W alloy ingots were prepared by melting in a newly designed high-frequency induction furnace equipped with a cold copper crucible. The purity of the ingots were higher than 99.98 mass% after the analysis of 21 elements. The deformability at temperatures of 1273 to 1573 K and the tensile properties between 293 K and 1073 K were measured by Gleeble test and tensile test. It was found that the tensile strength of 60 mass%Cr-Fe-4 mass%W alloy is higher than that of 60 mass%Cr-Fe alloy, and the addition of tungsten is effective in improving tensile properties of a 60 mass%Cr-Fe alloy.

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Section: Tensile Testmentioning

confidence: 67%

Section: Effect Of W On Tensile Properties and Microstructurementioning

confidence: 99%

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Effect of Tungsten on Mechanical Properties of High-Purity 60 mass%Cr-Fe Alloys

et al. 2002

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“…These high-purity alloys were prepared from high-purity metals of 99.995 mass% iron, 99.98 mass% chromium, and 99.98 mass% tungsten in a high vacuum of 10 À6 Torr in a high-frequency induction furnace. Further details of the preparation may be found elsewhere [7,8,12,13]. The ingots were heated at 1323 K for 1.8 Â 10 3 s in a high-purity argon atmosphere, then forged and rolled to sheets of 7 mm thickness.…”

Section: Methodsmentioning

confidence: 99%

“…No precipitation formation of the s-phase was observed in the matrix or even at grain boundaries during the heat treatment in the Fe-50Cr alloys aged at 973 K for 5000 h [6]. Kako et al [7] and Isozaki et al [8] investigated the effect of tungsten atoms in the Fe-50Cr alloys on the tensile properties. The tensile strength increased with tungsten content, and the ductility of the Fe-50Cr-8W alloy was better than that of the Fe-50Cr alloy at above 673 K. phys.…”

Section: Introductionmentioning

confidence: 99%

Effects of Radiation on Tensile Properties and Damage: Microstructures in High-Purity Fe-(9-70)Cr Alloys

Wakai

Hishinuma

Asahina

et al. 2002

phys. stat. sol. (a)

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Tensile properties of high-purity Fe-50Cr and Fe-50Cr-8W alloys irradiated by neutrons have been investigated. The behavior of precipitate formation on dislocation loops in high-purity Fe-(9-70)Cr alloys has been examined during 1 MeV electron irradiation in a high voltage electron microscope. The neutron irradiation was performed at 673, 773 and 873 K in the Modified Japan Research Reactor-3 (JRR-3M) to about 0.4 dpa. In the Fe-50Cr and Fe-50Cr-8W alloys irradiated at 673 K, no elongation was observed in the test performed at 673 K. The elongations were observed to recover in the tensile test at 873 K. They also recovered largely after a heat treatment at 873 K for 10 h. However, heat treatment at 873 K for 10 h hardly improved the ductility for the Fe-50Cr alloy irradiated at 873 K. The defect clusters formed at 873 K by the irradiation were relatively stable. Moiré fringe contrast due to the precipitate formation on dislocation loops was observed in the Fe-(9-70)Cr alloys irradiated by electrons at temperatures lower than about 773 K. The precipitates were identified as a 0 -phase in the Fe-(9-30)Cr alloys, but as aphase in the Fe-70Cr alloy. The loops formed in Fe-(9-70)Cr alloys were of two types: either on {100} planes with Burgers vector b ¼ ah100i or on {111} planes with b ¼ ða=2Þh111i. Their number density decreased with irradiation temperature.

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Properties of a High-Purity Fe–mass% Cr Alloy

Abiko¹,

Kato²

1998

phys. stat. sol. (a)

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Since Fe–Cr alloys containing more than 30 mass% chromium are potentially useful for many industrial applications, the properties of a high‐purity Fe–50 mass% Cr alloy were investigated to see whether the purification improves properties. Both mechanical and physical properties were investigated: mechanical properties such as tensile properties and deformability, and physical properties such as density, Young's modulus, thermal expansion rate, specific heat, thermal conductivity, heat transfer rate, specific electrical resistivity, and magnetic properties. It is concluded that a high‐purity Fe–50 mass% alloy is deformable, while maintaining high strength, at temperatures between 293 and 1523 K. Also, it possesses several desiable physical properties for high‐temperature services such as low thermal expansion coefficient and high thermal conductivity, compared to type 304 stainless steel.

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High Temperature Deformation Mechanism of a High-Purity Fe–50 mass% Cr Alloy

Cited by 14 publications

References 9 publications

Effect of Tungsten on Mechanical Properties of High-Purity 60 mass%Cr-Fe Alloys

Effect of Tungsten on Mechanical Properties of High-Purity 60 mass%Cr-Fe Alloys

Effects of Radiation on Tensile Properties and Damage: Microstructures in High-Purity Fe-(9-70)Cr Alloys

Properties of a High-Purity Fe–mass% Cr Alloy

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