Analysis of the intergranular cracking process inside polycrystalline heat-resistant materials under creep-fatigue conditions

Naoya Tada; Weisheng Zhou; Takayuki Kitamura; Ryuichi Ohtani

Analysis of the intergranular cracking process inside polycrystalline heat-resistant materials under creep-fatigue conditions

Naoya Tada, Weisheng Zhou, Takayuki Kitamura, Ryuichi Ohtani

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

Abstract

In order to investigate the intergranular failure process in polycrystalline materials under creep-dominant fatigue, numerical simulation of inner small cracks was conducted on the basis of a simple probabilistic model. Although the simulation condition is determined from experimental observation of the cross section of specimens interrupted at different fatigue cycles, the simulation is carried out continuously and reproduces inner cracking behavior throughout the fatigue life. This enables us not only to extract the spatial distribution of inner cracks at arbitrary creep-fatigue cycles, but also to calculate the propagation rate of each inner crack.

Original language	English
Pages (from-to)	87-101
Number of pages	15
Journal	ASTM Special Technical Publication
Volume	1297
Publication status	Published - Jan 1 1997
Externally published	Yes

Keywords

Creep-fatigue
Inner cracking
Numerical simulation
Probabilistic model

ASJC Scopus subject areas

Engineering(all)

Cite this

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title = "Analysis of the intergranular cracking process inside polycrystalline heat-resistant materials under creep-fatigue conditions",

abstract = "In order to investigate the intergranular failure process in polycrystalline materials under creep-dominant fatigue, numerical simulation of inner small cracks was conducted on the basis of a simple probabilistic model. Although the simulation condition is determined from experimental observation of the cross section of specimens interrupted at different fatigue cycles, the simulation is carried out continuously and reproduces inner cracking behavior throughout the fatigue life. This enables us not only to extract the spatial distribution of inner cracks at arbitrary creep-fatigue cycles, but also to calculate the propagation rate of each inner crack.",

keywords = "Creep-fatigue, Inner cracking, Numerical simulation, Probabilistic model",

author = "Naoya Tada and Weisheng Zhou and Takayuki Kitamura and Ryuichi Ohtani",

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AU - Tada, Naoya

AU - Zhou, Weisheng

AU - Kitamura, Takayuki

AU - Ohtani, Ryuichi

PY - 1997/1/1

Y1 - 1997/1/1

N2 - In order to investigate the intergranular failure process in polycrystalline materials under creep-dominant fatigue, numerical simulation of inner small cracks was conducted on the basis of a simple probabilistic model. Although the simulation condition is determined from experimental observation of the cross section of specimens interrupted at different fatigue cycles, the simulation is carried out continuously and reproduces inner cracking behavior throughout the fatigue life. This enables us not only to extract the spatial distribution of inner cracks at arbitrary creep-fatigue cycles, but also to calculate the propagation rate of each inner crack.

AB - In order to investigate the intergranular failure process in polycrystalline materials under creep-dominant fatigue, numerical simulation of inner small cracks was conducted on the basis of a simple probabilistic model. Although the simulation condition is determined from experimental observation of the cross section of specimens interrupted at different fatigue cycles, the simulation is carried out continuously and reproduces inner cracking behavior throughout the fatigue life. This enables us not only to extract the spatial distribution of inner cracks at arbitrary creep-fatigue cycles, but also to calculate the propagation rate of each inner crack.

KW - Creep-fatigue

KW - Inner cracking

KW - Numerical simulation

KW - Probabilistic model

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M3 - Article

AN - SCOPUS:0030783479

SN - 0066-0558

VL - 1297

SP - 87

EP - 101

JO - ASTM Special Technical Publication

JF - ASTM Special Technical Publication

ER -

Analysis of the intergranular cracking process inside polycrystalline heat-resistant materials under creep-fatigue conditions

Abstract

Keywords

ASJC Scopus subject areas

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