Advanced search
Publication Cover
Powder Metallurgy Volume 66, 2023 - Issue 2
Journal homepage
841
Views
0
CrossRef citations to date
0
Altmetric
Articles

Crack initiation and early propagation in case hardened sintered PM steels under cyclic load

Anders HolmbergMaterials Science and Engineering, Applied Materials Science, Uppsala University, Uppsala, SwedenCorrespondence[email protected]
View further author information
,
Urban WiklundMaterials Science and Engineering, Applied Materials Science, Uppsala University, Uppsala, SwedenView further author information
,
Per IsakssonMaterials Science and Engineering, Applied Materials Science, Uppsala University, Uppsala, SwedenView further author information
&
Åsa Kassman RudolphiMaterials Science and Engineering, Applied Materials Science, Uppsala University, Uppsala, SwedenView further author information
Pages 164-175 | Received 12 May 2022, Accepted 24 Jun 2022, Published online: 12 Jul 2022

References

  • Sosa MJ, Björklund S, Sellgren U. Gear web design with focus on powder metal sound characteristics and web design. International conference on Gears: Europe Invites the World;2; 2013. p. 1199–1208.
  • Flodin A. Powder metal gear technology: A review of the state of the art. Am. Gear manuf. assoc. fall tech. meet. 2015, AGMA FTM 2015, no. March; 2015. p. 67–77
  • Beiss P. Mechanische Eigenschaften von Sinterstählen. Tagungsband zum Symp. für Pulvermetallurgie Mater. Hagen. 2003;27:3–24.
  • Dlapka M, Danninger H, Gierl C, et al. Defining the pores in PM components. Met Powder Rep 2010;65:30–33.
  • Dobrzański LA, Brytan Z, Grande MA, et al. Influence of sintering parameters on the properties of duplex stainless steel. J Achievements in Mater Manuf Eng. 2007;20(2):231–234.
  • Sevostianov I, Kushch V. Effect of pore distribution on the statistics of peak stress and overall properties of porous material. Int J Solids Struct 2009;46(25–26):4419–4429.
  • Wendel J, Manchili SK, Hryha E, et al. Sintering behaviour of compacted water-atomised iron powder: effect of initial state and processing conditions. Powder Metall 2020;63(5):338–348.
  • German RM. Microstructure coarsening. In: RM German, editor. Sintering: from empirical observations to scientific principles, pp. 227–246. Waltham, MA: Elsevier; 2014.
  • Höganäs AB. Höganäs Handbook for Sintered Components Power of Powder ® Production of Sintered Components 2; 2013.
  • Dlapka M, Strobl S, Danninger H, et al. Austenite grain size in sinter hardened powder metallurgy steels. Prakt Metallogr Metallogr. 2010;47(12):686–699.
  • Carter CB, Norton MG. Ceramic Materials: Science and Engineering. New York, NY: Springer; 2013.
  • Murakami Y. Metal fatigue: effects of small defects and nonmetallic inclusions. Oxford: Elsevier; 2002.
  • Andersson M, Larsson M. Linking pore size and structure to the fatigue performance of sintered steels. Proceedings of the World powder metallurgy congress and exhibition, World PM 2010; 3; 2010. p. 1–8.
  • Morris J. “The Influence of Grain Size on the Mechanical Properties of Steel,” 2001.
  • Simm T, Sun L, McAdam S, et al. The influence of lath, block and prior austenite grain (PAG) size on the tensile, creep and fatigue properties of novel maraging steel. Materials. 2017;10(7):730. DOI:10.3390/ma10070730
  • Deng X, Piotrowski G, Chawla N, et al. Fatigue crack growth behavior of hybrid and prealloyed sintered steels. part II. fatigue behavior. Mater Sci Eng A. 2008;491(1–2):28–38.
  • Kabatova M, Dudrova E, Wronski AS. Microcrack nucleation, growth, coalescence and propagation in the fatigue failure of a powder metallurgy steel. Fatigue Fract Eng Mater Struct 2009;32(3):214–222.
  • Wright SI, De Kloe R, Nowell MM. EBSD analysis of crack propagation : A case study. In. ICOTOM; 2017. p. 1–2.
  • Salvati E, O’Connor S, Sui T, et al. A study of overload effect on fatigue crack propagation using EBSD, FIB–DIC and FEM methods. Eng Fract Mech 2016;167:210–223.
  • Laureys A, Depover T, Petrov R, et al. Microstructural characterization of hydrogen induced cracking in TRIP-assisted steel by EBSD. Mater Charact 2016;112(January):169–179.
  • Berger M, Hogmark S. Tribological properties of selected PVD coatings when slid against ductile materials. Wear. 2002;252(7–8):557–565.
  • Holmberg A, Rudolphi ÅK. Rolling fatigue life of PM steel – Influence of sintering temperature and powder particle size. Euro PM 2019 congress and exhibition, 2019
  • Hertz H. Über die berührung fester elastischer körper. J für die Reine und Angew Math. 1881;92:156–171.
  • Guesnier A. Preparation of ferrous metals for electron backscatter diffraction application notes. Oxford Instruments NanoAnalysis. 2010: 12.
  • Holmberg A, Andersson M, Rudolphi ÅK. Rolling fatigue life of PM steel with different porosity and surface finish. Wear. 2019;426–427.
  • Janitzky TLM. Einfluss von Dichte und Schlupf auf die Wälzfestigkeit einsatzgehärteter Sinterstähle. In Von der Fakultät für Maschinenwesen der Rheinisch-Westfälischen Technischen Hochschule Aachen zur Erlangung des akademischen Grades eines Doktors der Ingenieurwissenschaften genehmigte Dissertation; 2014.
  • Mekonone ST, Pahl W, Molinari A. Influence of the microstructure on the subsurface and surface damage during lubricated rolling – sliding wear of sintered steel : theoretical analysis and experimental investigation. Powder Metall 2018;0(0):1–10.
  • Lu Y, Yu H, Sisson RD. The effect of carbon content on the c/a ratio of as-quenched martensite in Fe-C alloys. Mater Sci Eng A. 2017;700(April):592–597.
  • Shabanov AP. Under compressive external stresses. J Appl Mech Tech Phys 2005;46(6):861–866.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.