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ASTM Selected Technical Papers
Fretting Fatigue: Current Technology and Practices
By
DW Hoeppner, Ph.D.,
DW Hoeppner, Ph.D.
P.E.
1
University of Utah
?Symposium Chairman, Co-chairmen, and STP Editors
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V Chandrasekaran, Ph.D.,
V Chandrasekaran, Ph.D.
1
University of Utah
?Symposium Chairman, Co-chairmen, and STP Editors
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C Elliott, III, Ph.D. III
C Elliott, III, Ph.D. III
P.E.
1
University of Utah
?Symposium Chairman, Co-chairmen, and STP Editors
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ISBN-10:
0-8031-2851-7
ISBN:
978-0-8031-2851-4
No. of Pages:
571
Publisher:
ASTM International
Publication date:
2000
eBook Chapter
Stage II Crack Propagation Direction Determination Under Fretting Fatigue Loading: a New Approach in Accordance with Experimental Observations
By
MC Dubourg
,
MC Dubourg
1.
Research Scientist and Doctor
, respectively, Laboratoire de Mécanique des Contacts, UMR-CNRS 5514, INSA
, 20, Av A. Einstein, 69621 Villeurbanne
Cédex, France
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V Lamacq
V Lamacq
1.
Research Scientist and Doctor
, respectively, Laboratoire de Mécanique des Contacts, UMR-CNRS 5514, INSA
, 20, Av A. Einstein, 69621 Villeurbanne
Cédex, France
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Page Count:
15
-
Published:2000
Citation
Dubourg, M, & Lamacq, V. "Stage II Crack Propagation Direction Determination Under Fretting Fatigue Loading: a New Approach in Accordance with Experimental Observations." Fretting Fatigue: Current Technology and Practices. Ed. Hoeppner, D, Chandrasekaran, V, & Elliott, C, III. 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959 : ASTM International, 2000.
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Cracking is a dangerous degradation mode under fretting loading and the understanding of crack initiation and propagation is thus a necessity. A double experimental and theoretical approach has been undertaken to deal with crack initiation during Stage I [1,2], Stage I/Stage II transition and Stage II propagation. The work presented here is related to the latter point and aims at determining the direction and the propagation mode of cracks. A new approach is proposed here to account for non-proportional mixed mode conditions such as those encountered under fretting conditions at crack tips. Propagation directions during Stage II are derived from Δσθθ*max, the maximum effective amplitude of the tangential stress perpendicular to the crack trajectory. They correlate well with experimental data. The stress field analysis shows that the trajectory of cracks borders the tensile-compressive and the tensile zones existing around the crack tip over a loading cycle.
References
1.
Reybet Degat
, P.
, Lamacq
, V.
, Dubourg
, M. C.
, Zhou
, Z. R.
, Vincent
, L.
, “Experimental and Theoretical Approach to Fretting Crack Nucleation on Pre-stressed Aluminum Alloy
”, ECF 11, Mechanisms and Mechanics of Damage and Failure
, 1996
, pp 1443–1445.2.
Lamacq
, V.
, Dubourg
, M. C.
, Vincent
, L.
, “A Theoretical Model for the Prediction of Fretting Fatigue Crack Initial Growth Angles and Sites
”, Tribology International
, Vol. 30
, n∘ 6
, 1997
, pp. 391–400.3.
Vincent
, L.
, Berthier
, Y.
, Dubourg
, M. C.
and Godet
, M.
, “Mechanics and Materials in Fretting
”, Wear
0043-1648, Vol. 153
, 1992
, pp. 135–148.4.
Vincent
L.
, Berthier
Y.
and Godet
M.
, “Testing Methods in Fretting Fatigue: A Critical Appraisal
”, ASTM-STP 1159, 1992
, pp. 33–485.
Fouvry
, S.
, Kapsa
, P.
, Vincent
, L.
, “Quantification of Fretting Damage
”, Wear
0043-1648 200
, 1996
, pp. 186–205.6.
Reybet Degat
, P.
, Zhou
, Z. R.
, Vincent
, L.
, “Fretting Behavior on Pre-stressed Aluminum Alloy Specimen
”, Tribology International
, Vol. 30
, n∘3
, 1996
, pp 711–720.7.
Zhou
, Z., R.
, Vincent
, L.
, “Mixed Fretting Regime
”, Wear
0043-1648 181–183
, 1995
, pp. 531–536.8.
Nowells
, D.
, Hills
, D.A.
, “Crack Initiation Criteria in Fretting Fatigue
”, Wear
0043-1648, Vol. 135
, 1990
, pp. 329–343.9.
Yamashita
, N.
and Mura
, T.
, “Contact Fatigue Crack Initiation under Repeated Oblique Force
”, Wear
0043-1648, 91
, 1983
, pp. 235–250.10.
Tanaka
, N.
, Mura
, T.
, “A Dislocation Model For Fatigue Crack Initiation
”, Journal of Applied Mechanics
, 47
, 1981
, pp. 111–113.11.
Mura
, T.
, Nakasone
, Y.
, “A Theory of Fatigue Crack Initiation in Solids
”, Journal of Applied Mechanics
, Vol. 57
, 1990
, pp 1–6.12.
Hourlier
, F.
, Pineau
, A.
, “Fatigue Crack Path Behavior under Complex Mode Loading
”, in Advances in Fracture Research, Proceedings 5th International Conference on Fracture
, Pergamon
, Oxford
, Vol. 4
, 1981
, pp. 1841–1849.13.
Lamacq
, V.
, “Amorçage et Propagation de Fissures de Fatigue sous Conditions de Fretting
”, Thèse: Doctorat, INSA
, 1997
,251 p.14.
Bower
, A., F.
, “The influence of Crack Face Friction and Trapped Fluid on Surface Initiated Rolling Contact Fatigue Cracks
”, Journal of Tribology
, Transaction of the ASME, 110
, 1988
, pp. 704–711.15.
Dubourg
, M. C.
, Villechaise
, B.
, “Analysis of Multiple Cracks — Part I: Theory
”, ASME, Journal of Tribology
, Vol. 114
, 1992
, pp 455–461.16.
Dubourg
, M. C.
, Godet
, M.
, Villechaise
, B.
, “Analysis of Multiple Cracks — Part II: Results
”, ASME, Journal of Tribology
, Vol. 114
, 1992
, pp. 462–468.17.
Dubourg
, M. C.
, Villechaise
, B.
, “Stress Intensity Factors in a Bent Crack: a Model
”, European Journal of Mechanics, A/Solids
, 11
, n∘2
, 1992
, pp. 169–179.18.
Amestoy
, M.
, Bui
H. D.
, Dang Van
K.
, “Déviation Infinitésimale d'une Fissure dans une Direction Arbitraire
”, Compte Rendu Académie des Sciences Paris
, t. 289
, Série B, 1979
, pp. 99–102
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