Effects of crystallographic orientation and grain morphology on crack tip stress state and plasticity

M. E. Kartal; M. A. Cuddihy; F. P. E. Dunne

doi:10.1016/j.ijfatigue.2013.11.022

Effects of crystallographic orientation and grain morphology on crack tip stress state and plasticity

M. E. Kartal, M. A. Cuddihy, F. P. E. Dunne

Engineering

Imperial College London

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

19 Citations (Scopus)

Abstract

The Sih, Paris and Irwin analytical solution for cracks in anisotropic elastic media has been developed for an hcp Ti single crystal and shown to lead to crack tip normal stresses which are independent of crystal orientation but other stress components which are dependent. Detailed finite element studies confirm that the stress intensity remains independent of crystal orientation but ceases to do so in an edge-cracked bi-crystal.

The incorporation of crystallographic slip demonstrates that single-crystal crack tip stresses largely remain independent of crystal orientation but that the plastic zone size and shape depends greatly upon it. Significant differences result in both the magnitude and extent of the plasticity at the crack tip with crystallographic orientation which can be quite different to that predicted using Mises plasticity. For an edge crack terminating in a bi-crystal, the slip fields which result depend upon both crystal mis-orientation and morphology.

Original language	English
Pages (from-to)	46-58
Number of pages	13
Journal	International journal of fatigue
Volume	61
Issue number	46-58
Early online date	6 Dec 2013
DOIs	https://doi.org/10.1016/j.ijfatigue.2013.11.022
Publication status	Published - Apr 2014

Bibliographical note

Acknowledgements
We are grateful to the Engineering and Physical Sciences Research Council (EP/G004676/1), and Rolls-Royce plc for financial support.

Keywords

stress intensity factor
crystal plasticity
anisotropy
titanium alloys
cold dwell fatigue

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10.1016/j.ijfatigue.2013.11.022

Cite this

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title = "Effects of crystallographic orientation and grain morphology on crack tip stress state and plasticity",

abstract = "The Sih, Paris and Irwin analytical solution for cracks in anisotropic elastic media has been developed for an hcp Ti single crystal and shown to lead to crack tip normal stresses which are independent of crystal orientation but other stress components which are dependent. Detailed finite element studies confirm that the stress intensity remains independent of crystal orientation but ceases to do so in an edge-cracked bi-crystal.The incorporation of crystallographic slip demonstrates that single-crystal crack tip stresses largely remain independent of crystal orientation but that the plastic zone size and shape depends greatly upon it. Significant differences result in both the magnitude and extent of the plasticity at the crack tip with crystallographic orientation which can be quite different to that predicted using Mises plasticity. For an edge crack terminating in a bi-crystal, the slip fields which result depend upon both crystal mis-orientation and morphology.",

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author = "Kartal, {M. E.} and Cuddihy, {M. A.} and Dunne, {F. P. E.}",

note = "Acknowledgements We are grateful to the Engineering and Physical Sciences Research Council (EP/G004676/1), and Rolls-Royce plc for financial support.",

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TY - JOUR

T1 - Effects of crystallographic orientation and grain morphology on crack tip stress state and plasticity

AU - Kartal, M. E.

AU - Cuddihy, M. A.

AU - Dunne, F. P. E.

N1 - Acknowledgements We are grateful to the Engineering and Physical Sciences Research Council (EP/G004676/1), and Rolls-Royce plc for financial support.

PY - 2014/4

Y1 - 2014/4

N2 - The Sih, Paris and Irwin analytical solution for cracks in anisotropic elastic media has been developed for an hcp Ti single crystal and shown to lead to crack tip normal stresses which are independent of crystal orientation but other stress components which are dependent. Detailed finite element studies confirm that the stress intensity remains independent of crystal orientation but ceases to do so in an edge-cracked bi-crystal.The incorporation of crystallographic slip demonstrates that single-crystal crack tip stresses largely remain independent of crystal orientation but that the plastic zone size and shape depends greatly upon it. Significant differences result in both the magnitude and extent of the plasticity at the crack tip with crystallographic orientation which can be quite different to that predicted using Mises plasticity. For an edge crack terminating in a bi-crystal, the slip fields which result depend upon both crystal mis-orientation and morphology.

AB - The Sih, Paris and Irwin analytical solution for cracks in anisotropic elastic media has been developed for an hcp Ti single crystal and shown to lead to crack tip normal stresses which are independent of crystal orientation but other stress components which are dependent. Detailed finite element studies confirm that the stress intensity remains independent of crystal orientation but ceases to do so in an edge-cracked bi-crystal.The incorporation of crystallographic slip demonstrates that single-crystal crack tip stresses largely remain independent of crystal orientation but that the plastic zone size and shape depends greatly upon it. Significant differences result in both the magnitude and extent of the plasticity at the crack tip with crystallographic orientation which can be quite different to that predicted using Mises plasticity. For an edge crack terminating in a bi-crystal, the slip fields which result depend upon both crystal mis-orientation and morphology.

KW - stress intensity factor

KW - crystal plasticity

KW - anisotropy

KW - titanium alloys

KW - cold dwell fatigue

U2 - 10.1016/j.ijfatigue.2013.11.022

DO - 10.1016/j.ijfatigue.2013.11.022

M3 - Article

SN - 0142-1123

VL - 61

SP - 46

EP - 58

JO - International journal of fatigue

JF - International journal of fatigue

IS - 46-58

ER -

Effects of crystallographic orientation and grain morphology on crack tip stress state and plasticity

Abstract

Bibliographical note

Keywords

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