Creep failure analysis of directionally solidified CM247LC superalloy

Müge Akdemir; Hüseyin Aydln; Havva Kazdal Zeytin; Hüseyin Çimenoǧlu

doi:10.1515/mt-2024-0223

Creep failure analysis of directionally solidified CM247LC superalloy

Müge Akdemir, Hüseyin Aydln, Havva Kazdal Zeytin, Hüseyin Çimenoǧlu^*

^*Corresponding author for this work

Department of Metallurgical and Materials Engineering

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

Abstract

This study investigates the behavior of an in-house cast directionally solidified nickel-based superalloy (i.e. CM247LC grade alloy) at low and high temperatures (760 and 982 °C, respectively). For this purpose, creep and tensile tests were conducted on the alloy after the heat treatment consisted of solutionizing and double aging. Following creep and tensile tests, microstructural examinations were made on the fracture surface and cross-sections of samples by using optical, digital, and electron microscopes. The results showed that the dominant creep mechanism of the CM247LC alloy was dislocation creep at both temperatures. However, the higher temperature accelerated creep failure via de-binding at the matrix/carbide interface and caused severe structural degradation.

Original language	English
Pages (from-to)	612-619
Number of pages	8
Journal	Materialpruefung/Materials Testing
Volume	67
Issue number	4
DOIs	https://doi.org/10.1515/mt-2024-0223
Publication status	Published - 1 Apr 2025

Bibliographical note

Publisher Copyright:
© 2025 Walter de Gruyter GmbH, Berlin/Boston.

Keywords

creep
directional solidification
high temperature
microstructure
superalloy

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10.1515/mt-2024-0223

Cite this

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abstract = "This study investigates the behavior of an in-house cast directionally solidified nickel-based superalloy (i.e. CM247LC grade alloy) at low and high temperatures (760 and 982 °C, respectively). For this purpose, creep and tensile tests were conducted on the alloy after the heat treatment consisted of solutionizing and double aging. Following creep and tensile tests, microstructural examinations were made on the fracture surface and cross-sections of samples by using optical, digital, and electron microscopes. The results showed that the dominant creep mechanism of the CM247LC alloy was dislocation creep at both temperatures. However, the higher temperature accelerated creep failure via de-binding at the matrix/carbide interface and caused severe structural degradation.",

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AU - Akdemir, Müge

AU - Aydln, Hüseyin

AU - Kazdal Zeytin, Havva

AU - Çimenoǧlu, Hüseyin

PY - 2025/4/1

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N2 - This study investigates the behavior of an in-house cast directionally solidified nickel-based superalloy (i.e. CM247LC grade alloy) at low and high temperatures (760 and 982 °C, respectively). For this purpose, creep and tensile tests were conducted on the alloy after the heat treatment consisted of solutionizing and double aging. Following creep and tensile tests, microstructural examinations were made on the fracture surface and cross-sections of samples by using optical, digital, and electron microscopes. The results showed that the dominant creep mechanism of the CM247LC alloy was dislocation creep at both temperatures. However, the higher temperature accelerated creep failure via de-binding at the matrix/carbide interface and caused severe structural degradation.

AB - This study investigates the behavior of an in-house cast directionally solidified nickel-based superalloy (i.e. CM247LC grade alloy) at low and high temperatures (760 and 982 °C, respectively). For this purpose, creep and tensile tests were conducted on the alloy after the heat treatment consisted of solutionizing and double aging. Following creep and tensile tests, microstructural examinations were made on the fracture surface and cross-sections of samples by using optical, digital, and electron microscopes. The results showed that the dominant creep mechanism of the CM247LC alloy was dislocation creep at both temperatures. However, the higher temperature accelerated creep failure via de-binding at the matrix/carbide interface and caused severe structural degradation.

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KW - directional solidification

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Creep failure analysis of directionally solidified CM247LC superalloy

Abstract

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Keywords

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