Influence of inclusion on stress and strain fields in ultra-high strength steel

HOU Jie; DONG Jian-xin; YAO Zhi-hao

doi:10.13374/j.issn2095-9389.2017.07.007

Volume 39 Issue 7

Jul. 2017

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HOU Jie, DONG Jian-xin, YAO Zhi-hao. Influence of inclusion on stress and strain fields in ultra-high strength steel[J]. Chinese Journal of Engineering, 2017, 39(7): 1027-1035. doi: 10.13374/j.issn2095-9389.2017.07.007

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HOU Jie, DONG Jian-xin, YAO Zhi-hao. Influence of inclusion on stress and strain fields in ultra-high strength steel[J]. Chinese Journal of Engineering, 2017, 39(7): 1027-1035. doi: 10.13374/j.issn2095-9389.2017.07.007

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Influence of inclusion on stress and strain fields in ultra-high strength steel

doi: 10.13374/j.issn2095-9389.2017.07.007

School of Materials Science and Technology, University of Science and Technology Beijing, Beijing 100083, China

Received Date: 2016-10-04

Abstract

Abstract

The influence of non-metallic inclusion on the performance of steels is closely related to the characteristic parameters. The in-situ scanning electron microscope (SEM) observation results of the crack initiation induced by TiN inclusion under tensile and fatigue loads in the ultra-high strength steel were analyzed. The stress fields of the inclusions and nearby matrix were then calculated using the MSC Marc finite element analysis software. Subsequently, the stress and strain fields of the TiN inclusions with different characteristic parameters and the nearby matrix were simulated. The results show that the mechanical behavior of the inclusions and the nearby matrix can be explained and predicted by finite element method. The maximum stress concentration is located around the sharp angle of a triangle inclusion. The position of the high-stress region in a rectangle inclusion is affected by the angle between the inclusion and the load direction. The position of the maximum stress in the matrix changes from the outer-inclusion region to the inter-inclusion region with the increase of the inter-inclusion distance. The high-stress region near the free surface results from the sub-surface inclusions, and the position of the maximum stress is affected by the distance from the inclusion to the free surface and the inclusion size.
- ultra-high strength steel,
- inclusion,
- stress and strain fields,
- crack initiation,
- FEM

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References(11)

References

[3]	Chen X C, Shi C B, Guo H J, et al. Investigation of oxide inclusions and primary carbonitrides in Inconel 718 superalloy refined through electroslag remelting process. Metall Mater Trans B, 2012, 43(6):1596
[7]	Texier D, Cormier J, Villechaise P, et al. Crack initiation sensitivity of wrought direct aged alloy 718 in the very high cycle fatigue regime:the role of non-metallic inclusions. Mater Sci Eng A, 2016, 678:122
[8]	Krewerth D, Lippmann T, Weidner A, et al. Influence of nonmetallic inclusions on fatigue life in the very high cycle fatigue regime. Int J Fatigue, 2016, 84:40
[9]	Jiang J, Yang J, Zhang T T, et al. On the mechanistic basis of fatigue crack nucleation in Ni superalloy containing inclusions using high resolution electron backscatter diffraction. Acta Mater, 2015, 97:367
[10]	Zhang T T, Jiang J, Shollock B A, et al. Slip localization and fatigue crack nucleation near a non-metallic inclusion in polycrystalline nickel-based superalloy. Mater Sci Eng A, 2015, 641:328
[11]	Tan J B, Wu X Q, Han E H, et al. Role of TiN inclusion on corrosion fatigue behavior of alloy 690 steam generator tubes in borated and lithiated high temperature water. Corros Sci, 2014, 88:349
[13]	Paul S K. Numerical models to determine the effect of soft and hard inclusions on different plastic zones of a fatigue crack in a C(T) specimen. Eng Fract Mech, 2016, 159:90
[14]	Spriestersbach D, Grad P, Kerscher E. Influence of different non-metallic inclusion types on the crack initiation in highstrength steels in the VHCF regime. Int J Fatigue, 2014, 64:114
[16]	Melander A. A finite element study of short cracks with different inclusion types under rolling contact fatigue load. Int J Fatigue, 1997, 19(1):13
[17]	Prasannavenkatesan R, Zhang J X, McDowell D L, et al. 3D modeling of subsurface fatigue crack nucleation potency of primary inclusions in heat treated and shot peened martensitic gear steels. Int J Fatigue, 2009, 31(7):1176
[18]	Shamblen C E, Chang D R. Effect of inclusions on LCF life of HIP plus heat treated powder metal rené 95. Metall Trans B, 1985, 16(4):775