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On the driving force for fatique crack formation from inclusion and voids in a cast A356 aluminum alloy

Publication ,  Journal Article
Gall, K; Horstemeyer, MF; Degner, BW; McDowell, DL; Fan, J
Published in: International Journal of Fracture
January 1, 2001

Monotonic and cyclic finite element simulations are conducted on linear-elastic inclusions and voids embedded in an elasto-plastic matrix material. The elasto-plastic material is modeled with both kinematic and isotropic hardening laws cast in a hardening minus recovery format. Three loading amplitudes (Δε/2 = 0.10%, 0.15, 0.20%) and three load ratios (R=-1, 0, 0.5) are considered. From a continuum standpoint, the primary driving force for fatigue crack formation is assumed to be the local maximum plastic shear strain range. Δγmax, with respect to all possible shear strain planes. For certain inhomogeneities, the Δγmax was as high as ten times the far field strains. Bonded inclusions have Δγmax values two orders of magnitude smaller than voids, cracked, or debonded inclusions. A cracked inclusion facilitates extremely large local stresses in the broken particle halves, which will invariably facilitate the debonding of a cracked particle. Based on these two observations, debonded inclusions and voids are asserted to be the critical inhomogeneities for fatigue crack formation. Furthermore, for voids and debonded inclusions, shape has a negligible effect on fatigue crack formation compared to other significant effects such as inhomogeneity size and reserved loading conditions (R ratio). Increasing the size of an inclusion by a factor of four increases Δγmax by about a factor of two. At low R ratios (-1) equivalent sized voids and debonded inclusions have comparable Δγmax values. At higher R ratios (0, 0.5) debonded inclusions have Δγmax values twice that of voids.

Duke Scholars

Published In

International Journal of Fracture

DOI

ISSN

0376-9429

Publication Date

January 1, 2001

Volume

108

Issue

3

Start / End Page

207 / 233

Related Subject Headings

  • Mechanical Engineering & Transports
  • 4017 Mechanical engineering
  • 4016 Materials engineering
  • 4005 Civil engineering
  • 0913 Mechanical Engineering
  • 0912 Materials Engineering
  • 0905 Civil Engineering
 

Citation

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Gall, K., Horstemeyer, M. F., Degner, B. W., McDowell, D. L., & Fan, J. (2001). On the driving force for fatique crack formation from inclusion and voids in a cast A356 aluminum alloy. International Journal of Fracture, 108(3), 207–233. https://doi.org/10.1023/A:1011033304600
Gall, K., M. F. Horstemeyer, B. W. Degner, D. L. McDowell, and J. Fan. “On the driving force for fatique crack formation from inclusion and voids in a cast A356 aluminum alloy.” International Journal of Fracture 108, no. 3 (January 1, 2001): 207–33. https://doi.org/10.1023/A:1011033304600.
Gall K, Horstemeyer MF, Degner BW, McDowell DL, Fan J. On the driving force for fatique crack formation from inclusion and voids in a cast A356 aluminum alloy. International Journal of Fracture. 2001 Jan 1;108(3):207–33.
Gall, K., et al. “On the driving force for fatique crack formation from inclusion and voids in a cast A356 aluminum alloy.” International Journal of Fracture, vol. 108, no. 3, Jan. 2001, pp. 207–33. Scopus, doi:10.1023/A:1011033304600.
Gall K, Horstemeyer MF, Degner BW, McDowell DL, Fan J. On the driving force for fatique crack formation from inclusion and voids in a cast A356 aluminum alloy. International Journal of Fracture. 2001 Jan 1;108(3):207–233.
Journal cover image

Published In

International Journal of Fracture

DOI

ISSN

0376-9429

Publication Date

January 1, 2001

Volume

108

Issue

3

Start / End Page

207 / 233

Related Subject Headings

  • Mechanical Engineering & Transports
  • 4017 Mechanical engineering
  • 4016 Materials engineering
  • 4005 Civil engineering
  • 0913 Mechanical Engineering
  • 0912 Materials Engineering
  • 0905 Civil Engineering