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Powder Metallurgy Volume 56, 2013 - Issue 5
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Original Articles

Modelling and experimental study of fatigue of powder metal steel (FC-0205)

P. G. AllisonUS Army ERDC, 3909 Halls Ferry Road, Vicksburg, MS 39180, USACorrespondence[email protected]
,
Y. HammiCenter for Advanced Vehicular Systems, Mississippi State University, PO Box 5405, Mississippi State, MS 39762, USA
,
J. B. JordonDepartment of Mechanical EngineeringUniversity of Alabama, PO Box 870276, Tuscaloosa, AL 35487, USA
&
M. F. HorstemeyerDepartment of Mechanical Engineering, Mississippi State University, PO Box ME, Mississippi State, MS 39762, USA
Pages 388-396 | Received 10 Jun 2013, Accepted 30 Jun 2013, Published online: 06 Dec 2013

References

  • Hammi Y., Stone T. Y. and Horstemeyer M. F.: ‘Constitutive modeling of metal powder behavior during compaction’, SAE Trans. J. Mater. Manuf., 2006, 293–299.
  • Christian K. D. and German R. M.: ‘Relation between pore structure and fatigue behavior in sintered iron–copper–carbon’, Int. J. Powder Metall., 1995, 31, 51–62.
  • Klumpp S., Eifler D., Vohringer O. and Macherauch E.: ‘Cyclic deformation behaviour of sintered pure and alloyed iron’, Met. Powder Rep., 1992, 47, 48.
  • Jordon J. B., Horstemeyer M. F., Yang N., Major J. F., Gall K. A., Fan J. and McDowell D. L.: ‘Microstructural inclusion influence on fatigue of a cast A356 aluminum alloy’, Metall. Trans. A, 2010, 41A, 356–363.
  • Major J. F.: ‘Porosity control and the fatigue behavior in A356-T61 aluminum alloy’, AFS Trans., 1998, 901–906.
  • Zhang B., Poirier D. R. and Chen W.: ‘Microstructural effets on high-cycle fatigue-crack initiation in A356·2 casting alloy’, Metall. Trans. A, 1999, 30A, 2659–2666.
  • Chawla N. and Deng X.: ‘Microstructure and mechanical behavior of porous sintered steels’, Mater. Sci. Eng. A, 2005, A390, 98–112.
  • Sudhakar K. V.: ‘Fatigue behavior of a high density powder metallurgy steel’, Int. J. Fatigue, 2000, 22, 729–734.
  • Chawla N., Murphy T. F., Narasimhan K. S., Koopman M. and Chawla K. K.: ‘Axial fatigue behavior of binder-treated versus diffusion alloyed powder metallurgy steels’, Mater. Sci. Eng. A, 2001, A308, 180–188.
  • Lindstedt U., Karlsson B. and Masini R.: ‘Influence of porosity on deformation and fatigue behavior of PM austenitic stainless steel’, Int. J. Powder Metall., 1997, 33, 49–61.
  • Poland D. D., Stephens R. I. and Prucher T.: ‘Influence of density and sintering temperature on smooth, notched, and cracked variable amplitude fatigue behaviour of FL4405 high strength PM steel’, Powder Metall., 1998, 41, 274–280.
  • Engler-Pinto CC Jr, Lasecki J. V., Frisch RJ Sr, DeJack M. A. and Allison J. E.: ‘Statistical approaches applied to fatigue data analysis’, SAE Trans. J. Mater. Manuf., 2006, 114, 422–431.
  • Lin S.-K, Lee Y.-L and Lu M.-W: ‘Evaluation of the staircase and the accelerated test methods for fatigue limit distributions’, Int. J. Fatigue, 2001, 23, 75–83.
  • Williams C. R., Lee Y.-L and Rilly J. T.: ‘A practical method for statistical analysis of strain–life fatigue data’, Int. J. Fatigue, 2003, 25, 427–436.
  • Iacoviello F., Iacoviello D. and Cavallini M.: ‘Analysis of stress ratio effects on fatigue propagation in a sintered duplex steel by experimentation and artificial neural network approaches’, Int. J. Fatigue, 2004, 26, 819–828.
  • Torres Y., Rodriguez S., Mateo A., Anglada M. and Llanes L.: ‘Fatigue behavior of powder metallurgy high-speed steels: fatigue limit prediction using a crack growth threshold-based approach’, Mater. Sci. Eng. A, 2004, A387–A389, 501–504.
  • Yan X.-J, Li H.-Y and Nie J.-X: ‘A probabilistic model for prediction of LCF life of PM alloys’, Aircraft Eng. Aerosp. Technol., 2004, 76, 286–292.
  • McDowell D. L., Gall K., Horstemeyer M. F. and Fan J.: ‘Microstructure-based fatigue modeling of cast A356-T6 alloy’, Eng. Fract. Mech., 2003, 70, 49–80.
  • Xue Y., McDowell D. L., Horstemeyer M. F., Dale M. and Jordon J. B.: ‘Microstructure-based multistage fatigue modeling of aluminum alloy 7075-T651’, Eng. Fract. Mech., 2007, 74, 2810–2823.
  • Xue Y., Burton C. L., Horstemeyer M. F., McDowell D. L. and Berry J. T.: ‘Multistage fatigue modeling of cast A356-T6 and A380-F aluminum alloys’, Metall. Trans. B, 2007, 38B, 601–606.
  • Jordon J. B., Gibson J. B., Horstemeyer M. F., El Kadiri H., Baird J. C. and Luo A. A.: ‘Effect of twinning, slip, and inclusions on the fatigue anisotropy of extrusion-textured AZ61 magnesium alloy’, Mater. Sci. Eng. A, 2011, A528, 6860–6871.
  • ‘Metaldyne, FC-0205 powder metal production’, http://metaldyne.com, 2007.
  • Allison P. G., Horstemeyer M. F. and Brown H. R.: ‘Modulus dependence on large scale porosity of powder metallurgy steel’, J. Mater. Eng. Perform., 2012, 21, 1422–1425.
  • ASTM E606-04e1, ‘Standard practice for strain controlled fatigue testing’, 2004.
  • Horstemeyer M. F.: ‘Mapping failure by microstructure–property modeling’, JOM, 2001, 53, 24–27.
  • El Kadiri H., Xue Y., Horstemeyer M. F., Jordon J. B. and Wang P. T.: ‘Identification and modeling of fatigue crack growth mechanisims in a die-cast AM50 magnesium alloy’, Acta Mater., 2006, 54, 5061–5076.
  • Fan J., McDowell D. L., Horstemeyer M. F. and Gall K. A.: ‘Computational micromechanics analysis of cyclic crack-tip behavior for microstructurally small cracks in dual-phase Al–Si alloys’, Eng. Fract. Mech., 2001, 68, 1687–1706.
  • Gall K. A. and Horstemeyer M. F.: ‘Integration of basic materials research into the design of cast components by a multi-scale methodology’, J. Eng. Mater. Technol., 2000, 122, 355–362.
  • Gokhale A. M., Dighe M. D. and Horstemeyer M. F.: ‘Effect of temperature on silicon particle damage in A356 alloy’, Metall. Trans. A, 1998, 29A, 905–907.
  • Gall K. A., Yang N., Horstemeyer M. F., McDowell D. L. and Fan J.: ‘The debonding and fracture of Si particles during the fatigue of a cast Al–Si alloy’, Metall. Trans. A, 1999, 30A, 3079–3088.
  • Xue Y., El Kadiri H., Horstemeyer M. F., Jordon J. B. and Weiland H.: ‘Micromechanisms of multistage fatigue crack growth in a high-strength aluminum alloy’, Acta Mater., 2007, 55, 1975–1984.
  • Nisitani H., Goto M. and Miyagawa H.: ‘Effect of pre-strain on the fatigue life of 0·34% C steel plain specimens’, JSME Int. J., 1987, 53, 378–386.
  • Shiozawa K., Tohda Y. and Sun S. M.: ‘Crack initiation and small fatigue crack growth behavior of squeeze-cast Al–Si aluminum alloys’, Fatigue Fract. Eng. Mater. Struct., 1997, 20, 237–247.
  • Newman J. C., Wu X. R., Venneri S. L. and Li G. G.: ‘Small-crack effects on high strength aluminum alloys’, in Report No. A, NASA/CAE Cooperative Program, NASA Reference Publication no. 1309, 1994.
  • Stephens R. I., Fatemi A., Stephens R. R. and Fuchs H. O.: ‘Metal fatigue in engineering’, 2nd edn; 2001, New York, John Wiley & Sons Inc.
  • Allison P. G., Horstemeyer M. F., Hammi Y., Brown H. R., Tucker M. T. and Hwang Y-K: ‘Microstructure–property relations of a powder metallurgy steel (FC-0205) under varying temperatures, strain rates, and stress states’, Mater. Sci. Eng. A, 2011, A529, 335–344.
  • Jordon J. B., Horstemeyer M. F., Solanki K., Bernard J. D., Berry J. T. and Williams T. N.: ‘Damage characterization and modeling of a 7075-T651 aluminum plate’, Mater. Sci. Eng. A, 2009, A527, 167–178.

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