Life prediction of oxide dispersion-strengthened platinum–rhodium alloy subjected to high-temperature bending fatigue under axial stress

A. Niwa; Y. Akita; J. Arakawa; H. Akebono; A. Sugeta

doi:10.1016/j.ijfatigue.2020.105808

Life prediction of oxide dispersion-strengthened platinum–rhodium alloy subjected to high-temperature bending fatigue under axial stress

A. Niwa, Y. Akita, J. Arakawa, H. Akebono, A. Sugeta

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

In this study, the bending fatigue properties of an oxide dispersion-strengthened platinum–rhodium alloy subjected to axial stress at 1400 °C were evaluated, and the effects of the axial stress and life prediction methods were examined. When the axial stress increased, the fracture mechanism changed from fatigue fracture to creep fracture, thus reducing the fracture time. The creep rupture time due to the stress generated at the center of the thickness direction was compared with the fatigue failure time due to the stress amplitude of the surface; the shorter one corresponded to the main fracture mechanism. Creep rupture was the main factor affecting the stress levels of the actual equipment, and its life should be predicted according to the creep rupture time.

Original language	English
Article number	105808
Journal	International Journal of Fatigue
Volume	140
DOIs	https://doi.org/10.1016/j.ijfatigue.2020.105808
Publication status	Published - Nov 2020
Externally published	Yes

Keywords

Creep fracture
High temperature fatigue
Platinum alloy

ASJC Scopus subject areas

Modelling and Simulation
Materials Science(all)
Mechanics of Materials
Mechanical Engineering
Industrial and Manufacturing Engineering

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10.1016/j.ijfatigue.2020.105808

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title = "Life prediction of oxide dispersion-strengthened platinum–rhodium alloy subjected to high-temperature bending fatigue under axial stress",

abstract = "In this study, the bending fatigue properties of an oxide dispersion-strengthened platinum–rhodium alloy subjected to axial stress at 1400 °C were evaluated, and the effects of the axial stress and life prediction methods were examined. When the axial stress increased, the fracture mechanism changed from fatigue fracture to creep fracture, thus reducing the fracture time. The creep rupture time due to the stress generated at the center of the thickness direction was compared with the fatigue failure time due to the stress amplitude of the surface; the shorter one corresponded to the main fracture mechanism. Creep rupture was the main factor affecting the stress levels of the actual equipment, and its life should be predicted according to the creep rupture time.",

keywords = "Creep fracture, High temperature fatigue, Platinum alloy",

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T1 - Life prediction of oxide dispersion-strengthened platinum–rhodium alloy subjected to high-temperature bending fatigue under axial stress

AU - Niwa, A.

AU - Akita, Y.

AU - Arakawa, J.

AU - Akebono, H.

AU - Sugeta, A.

PY - 2020/11

Y1 - 2020/11

N2 - In this study, the bending fatigue properties of an oxide dispersion-strengthened platinum–rhodium alloy subjected to axial stress at 1400 °C were evaluated, and the effects of the axial stress and life prediction methods were examined. When the axial stress increased, the fracture mechanism changed from fatigue fracture to creep fracture, thus reducing the fracture time. The creep rupture time due to the stress generated at the center of the thickness direction was compared with the fatigue failure time due to the stress amplitude of the surface; the shorter one corresponded to the main fracture mechanism. Creep rupture was the main factor affecting the stress levels of the actual equipment, and its life should be predicted according to the creep rupture time.

AB - In this study, the bending fatigue properties of an oxide dispersion-strengthened platinum–rhodium alloy subjected to axial stress at 1400 °C were evaluated, and the effects of the axial stress and life prediction methods were examined. When the axial stress increased, the fracture mechanism changed from fatigue fracture to creep fracture, thus reducing the fracture time. The creep rupture time due to the stress generated at the center of the thickness direction was compared with the fatigue failure time due to the stress amplitude of the surface; the shorter one corresponded to the main fracture mechanism. Creep rupture was the main factor affecting the stress levels of the actual equipment, and its life should be predicted according to the creep rupture time.

KW - Creep fracture

KW - High temperature fatigue

KW - Platinum alloy

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Life prediction of oxide dispersion-strengthened platinum–rhodium alloy subjected to high-temperature bending fatigue under axial stress

Abstract

Keywords

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