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Experimental – Numerical Analysis of Stress State in Front of the Crack Tip of Modified and Unmodified G17CrMo5-5 Cast Steel by Rare Earth Metals in a Brittle-Ductile Transition Region

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EN
Abstrakty
EN
In the paper presented experimental data and numerical analysis of stress distribution in front of the crack of two melts of low-alloy G17CrMo5-5 cast steel-modified (M) by rare earth metals and original, unmodified (UM) in the temperature range, according to the brittle-ductile transition region. Experimental tests include determination of the tensile properties and fracture toughness characteristics for the UM and M cast steel. Numerical analysis includes determination of stress distribution in front of the crack at the initial moment of the crack extension. In the numerical computations, experimentally tested specimens SEN(B) were modeled. The true stress-strain curves for the UM and M cast steel were used in the calculation. It was shown that the maximum of the opening stresses at the initial moment of the crack extension occurs in the axis of the specimens and reaches similar level of about 3.5σ0 for both UM and M cast steel. However, the length of the critical distance, measured for stress level equal 3σ0, is great for the M in comparison to the UM cast steel. Also was shown that the UM cast steel increased the level of the stress state triaxiality parameters that resulted in a decrease of fracture toughness.
Twórcy
autor
  • Kielce University of Technology, 7th Tysiaclecia P. P. Av. 25-314 Kielce, Poland
autor
  • Kielce University of Technology, 7th Tysiąclecia P. P. Av. 25-314 Kielce, Poland
autor
  • Kielce University of Technology, 7th Tysiąclecia P. P. Av. 25-314 Kielce, Poland
Bibliografia
  • [1] Long-Mei Wang, at al., Study of application of rare elements in advanced low alloy steels, Journal of Alloys and Compounds 451, 534-537 (2008).
  • [2] Heon Young Ha, Chan Jin Park, Hyuk Sang Kwon. Effect of misch metal on the formation of non-metallic inclusions in 25% Cr duplex stainless steels, Scripta Materialia 55, 991-994 (2006).
  • [3] M. Gajewski, J. Kasinska, Rare earth metals influence on mechanical properties and crack resistance of GP240GH and G17CrMo5-5 cast steels, Archives of Foundry Engineering 9, 37-44 (2009).
  • [4] K. Bolanowski, Structure and properties of MA-steel with rare earth elements addition, Archives of Metallurgy and Materials 50, 327-332 (2005).
  • [5] V. V. Luniov, Non metallic inclusions and properties of cast steels, Foundry Journals of the Polish Foundrymen’s Association 53, 9, 299-304 (2003) (in Polish).
  • [6] J. Kasinska, Wide-ranging influence of mischmetal on properties of G17CrMo5-5 cast steel, Metallurgija 54, 1, 135-138 (2015).
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  • [9] A. Seweryn, Brittle Fracture criterion for structures with sharp notches, Engineering Fracture Mechanics 45(5), 673-681 (1994).
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  • [13] I. Dzioba, The influence of the microstructural components on fracture toughness of 13HMF steel, Materials Science, 47 (5), 357-364 (2011).
  • [14] ASTM E1737-96. Standard Test Method for J-Integral Characterization of Fracture Toughness.
  • [15] ASTM E1820-09. Standard Test Method for Measurement of Fracture Toughness, Annual book of ASTM standards 03.01, 1070-1118 (2011).
  • [16] ASTM E1921-10. Standard Test Method for Determination of Reference Temperature, T0, for Ferritic Steels in the Transition Range, Annual book of ASTM standards 03.01, 1177-1198, (2011).
  • [17] I. Dzioba, P. Furmanczyk, J. Kasinska, Fractographic study of G17CrMo5-5 cast steel fracture in a transition brittle-ductile region. XLIII School of Materials Engineering, ed. by J. Pacyna, AGH, Krakow-Rytro, 27-30.09.2015, 65-68 (in Polish).
  • [18] C. Berdin, Damage evolution laws and fracture criteria. In Local Approach to Fracture, ed. by J. Besson, Paris, 147-174 (2004).
  • [19] A. Neimitz, I. Dzioba, The influence of the out-of- and in-plane constraint on fracture toughness of high strength steel in the ductile to brittle transition temperature range, Engineering Fracture Mechanics 147(10), 431-448 (2015).
  • [20] J. R. Rice, D. M. Tracey, On the ductile enlargement of voids in triaxial stress fields, Journal of the Mechanics and Physics of Solids 17, 201-217 (1969).
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Uwagi
EN
Financial support of the Polish MSHE contracts 01.0.08.00/2.01.01.01.0035 and 01.0.08.00/2.01.01.02.0016 and NCTA contract PBS1B5 13/2012 is gratefully acknowledged. Figure 2 made by Piotr Furmanczyk. Sincere thanks for sharing these photographs.
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Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę
Typ dokumentu
Bibliografia
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bwmeta1.element.baztech-5bb4df22-a162-4d8e-b08e-a8469ac79a2d
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