Observation of Internal Fatigue Cracks in Repeatedly Induction-Heated S45C Bearing Steel under Rotating Bending Fatigue

Shusuke Kita; Li Xiang; Takahiro Matsueda; Koshiro Mizobe; Katsuyuki Kida

doi:10.4028/p-t1mle1

Paper Titles

Research Progress of Ceramic and Metal Welding Technology
p.59

Effect of Line Width and Wall Count on the Compressive Strength of Single and Functionally Graded Additively Manufactured ABS Gyroid Structure
p.71

Predictive Modeling of Out-of-Plane Deviation for the Quality Improvement of Additive Manufacturing
p.79

Mechatronic Design of Two-Jaw Pleating End-Effector for Large-Scale Carbon Fibre Reinforced Polymer Manufacturing
p.85

Observation of Internal Fatigue Cracks in Repeatedly Induction-Heated S45C Bearing Steel under Rotating Bending Fatigue
p.93

Friction Coefficient during Five-Phased Start-Stop Tests of PEEK-PTFE Hybrid Radial Ball Bearings Reaching 50 c° under 487N at 600rpm in Air
p.99

Potassium Hydroxide Activation as an Adsorbent for Equilibrium Isotherms of Hexavalent Chromium Adsorptions onto Garcinia mangosteen Shell
p.107

Potassium Hydroxide Activation as an Adsorbent for Kinetic Models of Hexavalent Chromium Adsorptions onto Garcinia mangosteen Shell
p.115

Industrial Electrocatalytic Oxidation - The Future of «Green Chemistry»
p.125

HomeMaterials Science ForumMaterials Science Forum Vol. 1086Observation of Internal Fatigue Cracks in...

Observation of Internal Fatigue Cracks in Repeatedly Induction-Heated S45C Bearing Steel under Rotating Bending Fatigue

Abstract:

Induction-heated steel has hard and soft layers. These layers can cause an internal fatigue crack originating from the boundary of these layers when cyclic stress is applied. Repeated heating is known as a method for improving fatigue strength, and it was applied to induction heating method. Repeatedly induction-heated steel had high fatigue strength compared to single quenching. We performed rotating bending fatigue tests of low carbon steel (JIS-S45C) induction-heated three times, and observed the fracture surfaces and the microstructures of internal fatigue cracks. The internal fatigue cracks originated from the area around the boundary between soft and hard layers surrounding crack origin. Some pearlite and ferrite can be seen. There were pearlite and dimples on the soft layer of internal fatigue crack and clear grains on the hard layer of the crack. From chase-up observation, we revealed that internal fatigue crack originated from soft layer.

You might also be interested in these eBooks

The 5th International Conference on Mechanical Engineering and Applied Composite Materials

View Preview

Materials Research, Chemical and Petrochemical Production

View Preview

Info:

Periodical:

Materials Science Forum (Volume 1086)

Pages:

93-98

DOI:

https://doi.org/10.4028/p-t1mle1

Citation:

Cite this paper

Online since:

April 2023

Authors:

Shusuke Kita, Li Xiang, Takahiro Matsueda, Koshiro Mizobe*, Katsuyuki Kida

Keywords:

Fracture Surface, Induction Heating, Repeated Heating, Rotating Bending Fatigue, S45C Steel

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] P. H. Frith, Fatigue Tests on Rolled Alloy Steels Made in Electric and Open-Hearth Furnaces, Journal of The Iron and Steel Institute, Vol. 180, pp.26-33, (1955).

Google Scholar

[2] K. Shiozawa, Y. Morii, S. Nishino and L. Lu, Subsurface crack initiation and propagation mechanism in high-strength steel in a very high cycle fatigue regime, International Journal of Fatigue, 28, pp.1521-1532, (2006).

DOI: 10.1016/j.ijfatigue.2005.08.015

Google Scholar

[3] Y. Murakami, Metal fatigue: Effects of Defects and Nonmetallic Inclusions, Elsevier Science Ltd, UK, (2002).

Google Scholar

[4] T. Sakai, Y. Sato, Y. Nagano, M. Takeda and N. Oguma, Effect of stress ratio on long life fatigue behavior of high carbon chromium bearing steel under axial loading, International Journal of Fatigue, 28, pp.1547-1554, (2006).

DOI: 10.1016/j.ijfatigue.2005.04.018

Google Scholar

[5] R. A. Grange, E. R. Shackelford, U. S. Patent 3,178,324, (1965).

Google Scholar

[6] R. A. Grange, The Rapid Heat Treatment of Steel, Merallurgical Transactions, Vol. 2, pp.65-78, (1971).

Google Scholar

[7] C. Ooki, K. Maeda and H. Nakashima, Improving Rolling Contact Fatigue Life of Bearing Steels Through Refinement, NTN TECHNICAL REVIEW, No. 71, pp.2-7, (2004).

DOI: 10.4271/2004-01-0634

Google Scholar

[8] H. Koike, E.C. Santos, K. Kida T. Honda and J. Rozwadowska, Effect of repeated induction heating on fatigue crack propagation in SAE 52100 bearing steel, Advanced Materials Research, Vols. 217-218, pp.1266-1271, (2011).

DOI: 10.4028/www.scientific.net/amr.217-218.1266

Google Scholar

[9] K. Mizobe, E. C. Santos, T. Honda, H. Koike and K. Kida, Observation of non-metallic inclusions on repeatedly quenched SAE 52100 bearing steel fracture surfaces, International Jornal of Materials and Product Technology, Vol. 44, pp.227-239, (2012).

DOI: 10.1504/ijmpt.2012.050186

Google Scholar

[10] K. Tsuji, K. Mizobe, and K. Kida, Development of Surface Etching (FSE) Method around Non-Metallic Inclusion of SUJ2 Steel, Material Science Forum, Vol. 971, pp.65-69, (2019).

DOI: 10.4028/www.scientific.net/msf.971.65

Google Scholar

[11] I. Yoshida, K. Mizobe and K. Kida, Observation of Fracture Surface of Induction-Heated JIS SUJ2 Bearing Steel under Rotating Bending Fatigue, ISSN: 1662-9752, Vol. 904 pp.24-28, (2017).

DOI: 10.4028/www.scientific.net/msf.904.24

Google Scholar

[12] K. Mizobe, M. Matsushita, T. Shibukawa and K. Kida, Observation of Cracks Originating from Transition Area in Induction-Heated S45CShaft under Rotating Bending Fatigue, Key Engineering Materials, Vol. 832, pp.3-9, (2020).

DOI: 10.4028/www.scientific.net/kem.832.3

Google Scholar