Modelling for Creep Cavitation Damage and Life of Three Metallic Materials

Rami Pohja; Pertti Auerkari; Pedro Vilaça

doi:10.1080/09603409.2021.2024420

Modelling for Creep Cavitation Damage and Life of Three Metallic Materials

Rami Pohja^*
, Pertti Auerkari
, Pedro Vilaça

^*Corresponding author for this work

Department of Energy and Mechanical Engineering

VTT Technical Research Centre of Finland

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

5 Citations (Scopus)

355 Downloads (Pure)

Abstract

Metallic structures operating at high temperatures can have creep as a life-limiting mechanism. The limit can arise by nucleation and growth of creep cavities that eventually merge becoming the leading damage of the fracture mechanisms. Understanding and modelling for creep cavitation can therefore help in prediction of structural safety and condition of such structures. The present paper will introduce a new model to predict creep cavitation damage so that the associated creep strain is also modelled out of the predictive expression without losing accuracy in the time to critical damage and corresponding residual life. The model was verified for OFHC copper, low-alloy 0.5CMV steel and higher-alloy X20 steel, to cover a wide range of polycrystalline metals and their microstructures. The new model performed as well as or better than the classical approach which requires access to measured strain. The model was applied to predict creep cavitation damage from time, stress and temperature as predictive variables.

Original language	English
Pages (from-to)	86-96
Number of pages	11
Journal	Materials at High Temperatures
Volume	39
Issue number	1
DOIs	https://doi.org/10.1080/09603409.2021.2024420
Publication status	Published - 2 Jan 2022
MoE publication type	A1 Journal article-refereed

Funding

The authors wish to acknowledge the financial support of the Academy of Finland, via the EARLY project No. 325108, and Finnish Research Programme on Nuclear Waste Management, via the CRYCO project No. KYT15/2020.

Keywords

cavitation
Creep
damage
life
metal
model

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10.1080/09603409.2021.2024420Licence: CC BY-NC-ND

Modelling for Creep Cavitation Damage and Life of Three Metallic MaterialsFinal published version, 5.49 MBLicence: CC BY-NC-ND

Cite this

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title = "Modelling for Creep Cavitation Damage and Life of Three Metallic Materials",

abstract = "Metallic structures operating at high temperatures can have creep as a life-limiting mechanism. The limit can arise by nucleation and growth of creep cavities that eventually merge becoming the leading damage of the fracture mechanisms. Understanding and modelling for creep cavitation can therefore help in prediction of structural safety and condition of such structures. The present paper will introduce a new model to predict creep cavitation damage so that the associated creep strain is also modelled out of the predictive expression without losing accuracy in the time to critical damage and corresponding residual life. The model was verified for OFHC copper, low-alloy 0.5CMV steel and higher-alloy X20 steel, to cover a wide range of polycrystalline metals and their microstructures. The new model performed as well as or better than the classical approach which requires access to measured strain. The model was applied to predict creep cavitation damage from time, stress and temperature as predictive variables.",

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author = "Rami Pohja and Pertti Auerkari and Pedro Vila{\c c}a",

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AU - Vilaça, Pedro

N1 - Funding Information: The authors wish to acknowledge the financial support of the Academy of Finland, via the EARLY project No. 325108, and Finnish Research Programme on Nuclear Waste Management, via the CRYCO project No. KYT15/2020. Publisher Copyright: © 2022 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.

PY - 2022/1/2

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N2 - Metallic structures operating at high temperatures can have creep as a life-limiting mechanism. The limit can arise by nucleation and growth of creep cavities that eventually merge becoming the leading damage of the fracture mechanisms. Understanding and modelling for creep cavitation can therefore help in prediction of structural safety and condition of such structures. The present paper will introduce a new model to predict creep cavitation damage so that the associated creep strain is also modelled out of the predictive expression without losing accuracy in the time to critical damage and corresponding residual life. The model was verified for OFHC copper, low-alloy 0.5CMV steel and higher-alloy X20 steel, to cover a wide range of polycrystalline metals and their microstructures. The new model performed as well as or better than the classical approach which requires access to measured strain. The model was applied to predict creep cavitation damage from time, stress and temperature as predictive variables.

AB - Metallic structures operating at high temperatures can have creep as a life-limiting mechanism. The limit can arise by nucleation and growth of creep cavities that eventually merge becoming the leading damage of the fracture mechanisms. Understanding and modelling for creep cavitation can therefore help in prediction of structural safety and condition of such structures. The present paper will introduce a new model to predict creep cavitation damage so that the associated creep strain is also modelled out of the predictive expression without losing accuracy in the time to critical damage and corresponding residual life. The model was verified for OFHC copper, low-alloy 0.5CMV steel and higher-alloy X20 steel, to cover a wide range of polycrystalline metals and their microstructures. The new model performed as well as or better than the classical approach which requires access to measured strain. The model was applied to predict creep cavitation damage from time, stress and temperature as predictive variables.

KW - cavitation

KW - Creep

KW - damage

KW - life

KW - metal

KW - model

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DO - 10.1080/09603409.2021.2024420

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AN - SCOPUS:85122471995

SN - 0960-3409

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SP - 86

EP - 96

JO - Materials at High Temperatures

JF - Materials at High Temperatures

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Modelling for Creep Cavitation Damage and Life of Three Metallic Materials

Abstract

Funding

Keywords

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EARLY/Vilaca: New high-resolution non-destructive methods for assessment of early damage in advanced welded steels for high-temperature applications with extended life

Cite this

Modelling for Creep Cavitation Damage and Life of Three Metallic Materials

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Projects

EARLY/Vilaca: New high-resolution non-destructive methods for assessment of early damage in advanced welded steels for high-temperature applications with extended life

Cite this