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ASTM Selected Technical Papers
Fatigue and Fracture Mechanics: 31st VolumeAvailable to Purchase
By
GR Halford,
GR Halford
1
NASA Glenn Research Center
at Lewis Field; Cleveland, OH
; Symposium Chairman and Editor
Search for other works by this author on:
JP Gallagher
JP Gallagher
2
University of Dayton Research Institute
, Dayton, OH
; Symposium Chairman and Editor
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ISBN-10:
0-8031-2868-1
ISBN:
978-0-8031-2868-2
No. of Pages:
560
Publisher:
ASTM International
Publication date:
2000
eBook Chapter
Fatigue Life Estimation Under Cumulative Cyclic Loading Conditions Available to Purchase
By
S Kalluri
,
S Kalluri
1
Senior research engineer
, Ohio Aerospace Institute
, Brookpark, OH
.
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MA McGaw
,
MA McGaw
2
President
, McGaw Technology, Inc.
, Lakewood, OH
.
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GR Halford
GR Halford
3
Senior scientific technologist
, Research and Technology Directorate, NASA Glenn Research Center
, Cleveland, OH
.
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Page Count:
16
-
Published:2000
Citation
Kalluri, S, McGaw, M, & Halford, G. "Fatigue Life Estimation Under Cumulative Cyclic Loading Conditions." Fatigue and Fracture Mechanics: 31st Volume. Ed. Halford, G, & Gallagher, J. 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959 : ASTM International, 2000.
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The cumulative fatigue behavior of a cobalt-base superalloy, Haynes 188, was investigated at 760°C in air. Initially, strain-controlled tests were conducted on solid cylindrical gage section specimens of Haynes 188 under fully reversed, tensile and compressive mean strain-controlled fatigue tests. Fatigue data from these tests were used to establish the baseline fatigue behavior of the alloy with (1) a total strain range type fatigue life relation and (2) the Smith-Watson-Topper (SWT) parameter. Subsequently, two load-level multi-block fatigue tests were conducted on similar specimens of Haynes 188 at the same temperature. Fatigue lives of the multi-block tests were estimated with (1) the linear damage rule (LDR) and (2) the non-linear damage curve approach (DCA) both with and without the consideration of mean stresses generated during the cumulative fatigue tests. Fatigue life predictions by the nonlinear DCA were much closer to the experimentally observed lives than those obtained by the LDR. In the presence of mean stresses, the SWT parameter estimated the fatigue lives more accurately under tensile conditions than under compressive conditions.
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