Evaluation of tensile static, dynamic, and cyclic fatigue behavior for a HIPed silicon nitride at elevated temperatures

Chih Kuang Jack Lin; Michael G. Jenkins; Mattison K. Ferber

Evaluation of tensile static, dynamic, and cyclic fatigue behavior for a HIPed silicon nitride at elevated temperatures

Chih Kuang Jack Lin, Michael G. Jenkins, Mattison K. Ferber

機械工程學系

研究成果: 書貢獻/報告類型 › 會議論文篇章 › 同行評審

2 引文斯高帕斯（Scopus）

摘要

Tensile fatigue behavior of a hot-isostatically-pressed (HIPed) silicon nitride was investigated over ranges of constant stresses, constant stress rates, and cyclic loading at 1150-1370°C. At 1150°C, static and dynamic failures were governed by a slow crack growth mechanism. Creep rupture was the dominant failure mechanism in static fatigue at 1260 and 1370°C. A transition of failure mechanism from slow crack growth to creep rupture appeared at stress rates ≤10^-2 MPa/s for dynamic fatigue at 1260 and 1370°C. At 1150-1370°C, cyclic loading appeared to be less damaging than static loading as cyclic fatigue specimens displayed greater failure times than static fatigue specimens under the same maximum stresses.

原文	???core.languages.en_GB???
主出版物標題	Silicon Nitride Ceramics, Scientific and Technological Advances
發行者	Publ by Materials Research Society
頁面	455-460
頁數	6
ISBN（列印）	1558991824
出版狀態	已出版 - 1993
事件	Materials Research Society Fall Meeting - Boston, MA, USA 持續時間: 1 12月 1992 → 3 12月 1992

出版系列

名字	Materials Research Society Symposium Proceedings
卷	287
ISSN（列印）	0272-9172

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???event.eventtypes.event.conference???	Materials Research Society Fall Meeting
城市	Boston, MA, USA
期間	1/12/92 → 3/12/92

引用此

@inproceedings{91912e36f0c544e9b7d6176c3f897df3,

title = "Evaluation of tensile static, dynamic, and cyclic fatigue behavior for a HIPed silicon nitride at elevated temperatures",

abstract = "Tensile fatigue behavior of a hot-isostatically-pressed (HIPed) silicon nitride was investigated over ranges of constant stresses, constant stress rates, and cyclic loading at 1150-1370°C. At 1150°C, static and dynamic failures were governed by a slow crack growth mechanism. Creep rupture was the dominant failure mechanism in static fatigue at 1260 and 1370°C. A transition of failure mechanism from slow crack growth to creep rupture appeared at stress rates ≤10-2 MPa/s for dynamic fatigue at 1260 and 1370°C. At 1150-1370°C, cyclic loading appeared to be less damaging than static loading as cyclic fatigue specimens displayed greater failure times than static fatigue specimens under the same maximum stresses.",

author = "Lin, {Chih Kuang Jack} and Jenkins, {Michael G.} and Ferber, {Mattison K.}",

year = "1993",

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isbn = "1558991824",

series = "Materials Research Society Symposium Proceedings",

publisher = "Publ by Materials Research Society",

pages = "455--460",

booktitle = "Silicon Nitride Ceramics, Scientific and Technological Advances",

note = "Materials Research Society Fall Meeting ; Conference date: 01-12-1992 Through 03-12-1992",

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Lin, CKJ, Jenkins, MG & Ferber, MK 1993, Evaluation of tensile static, dynamic, and cyclic fatigue behavior for a HIPed silicon nitride at elevated temperatures. 於 Silicon Nitride Ceramics, Scientific and Technological Advances. Materials Research Society Symposium Proceedings, 卷 287, Publ by Materials Research Society, 頁 455-460, Materials Research Society Fall Meeting, Boston, MA, USA, 1/12/92.

Evaluation of tensile static, dynamic, and cyclic fatigue behavior for a HIPed silicon nitride at elevated temperatures. / Lin, Chih Kuang Jack; Jenkins, Michael G.; Ferber, Mattison K.
Silicon Nitride Ceramics, Scientific and Technological Advances. Publ by Materials Research Society, 1993. p. 455-460 (Materials Research Society Symposium Proceedings; 卷 287).

研究成果: 書貢獻/報告類型 › 會議論文篇章 › 同行評審

TY - GEN

T1 - Evaluation of tensile static, dynamic, and cyclic fatigue behavior for a HIPed silicon nitride at elevated temperatures

AU - Lin, Chih Kuang Jack

AU - Jenkins, Michael G.

AU - Ferber, Mattison K.

PY - 1993

Y1 - 1993

N2 - Tensile fatigue behavior of a hot-isostatically-pressed (HIPed) silicon nitride was investigated over ranges of constant stresses, constant stress rates, and cyclic loading at 1150-1370°C. At 1150°C, static and dynamic failures were governed by a slow crack growth mechanism. Creep rupture was the dominant failure mechanism in static fatigue at 1260 and 1370°C. A transition of failure mechanism from slow crack growth to creep rupture appeared at stress rates ≤10-2 MPa/s for dynamic fatigue at 1260 and 1370°C. At 1150-1370°C, cyclic loading appeared to be less damaging than static loading as cyclic fatigue specimens displayed greater failure times than static fatigue specimens under the same maximum stresses.

AB - Tensile fatigue behavior of a hot-isostatically-pressed (HIPed) silicon nitride was investigated over ranges of constant stresses, constant stress rates, and cyclic loading at 1150-1370°C. At 1150°C, static and dynamic failures were governed by a slow crack growth mechanism. Creep rupture was the dominant failure mechanism in static fatigue at 1260 and 1370°C. A transition of failure mechanism from slow crack growth to creep rupture appeared at stress rates ≤10-2 MPa/s for dynamic fatigue at 1260 and 1370°C. At 1150-1370°C, cyclic loading appeared to be less damaging than static loading as cyclic fatigue specimens displayed greater failure times than static fatigue specimens under the same maximum stresses.

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M3 - 會議論文篇章

AN - SCOPUS:0027206634

SN - 1558991824

T3 - Materials Research Society Symposium Proceedings

SP - 455

EP - 460

BT - Silicon Nitride Ceramics, Scientific and Technological Advances

PB - Publ by Materials Research Society

T2 - Materials Research Society Fall Meeting

Y2 - 1 December 1992 through 3 December 1992

ER -

Evaluation of tensile static, dynamic, and cyclic fatigue behavior for a HIPed silicon nitride at elevated temperatures

摘要

出版系列

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