Study on Surface Properties of Big Tilling Depth Rotary Blade for Laser Shock Peening

Xiao Bo Xi; Hong Miao; De Qing Tao; Li Zhao; Rui Hong Zhang; Zai Xiang Zheng

doi:10.4028/www.scientific.net/AMM.395-396.973

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 395-396Study on Surface Properties of Big Tilling Depth...

Study on Surface Properties of Big Tilling Depth Rotary Blade for Laser Shock Peening

Abstract:

A stress concentration area of big tilling depth rotary blade with 350 mm turning radius is found by ANSYS, and is strengthened by laser shock peening (LSP). The surface properties of rotary blade for LSP, included residual stress, surface micrograph, microstructure and hardness, are researched in this article. The results show that microstructure density is higher after LSP, and the layer is smoother, then the stress concentration is decreased. Meanwhile, the hardness and residual stress of rotary blade surface layer are significantly increased. The average residual stress reaches 390.7 MPa, and the average Rockwell hardness number achieves 45.1 HRC. Measuring results of residual stress, surface micrograph, microstructure and hardness after LSP indicate that LSP can significantly improve the surface properties of rotary blade, and it provides a new basis for further mending surface quality and fatigue property of big tilling depth rotary blade.

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Periodical:

Applied Mechanics and Materials (Volumes 395-396)

Pages:

973-978

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.395-396.973

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Online since:

September 2013

Authors:

Xiao Bo Xi*, Hong Miao, De Qing Tao, Li Zhao, Rui Hong Zhang, Zai Xiang Zheng

Keywords:

Big Tilling Depth Rotary Blade, Laser Shock Peening, Microstructure, Residual Stress

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* - Corresponding Author

References

[1] T.M. Agbede, and S.O. Ojeniyi: Soil and Tillage Research. Vol. 104(2009), p.80.

Google Scholar

[2] J.W. Zhong, J.Z. Lu, K.Y. Luo, and C.J. Yang: Chinese J. Lasers. Vol. 39(2012), pp.103001-2 (in Chinese).

Google Scholar

[3] Y. Kuramitsu, Y. Sakawa, T. Morita, and C.D. Gregory: High Energy Density Physics. Vol. 9(2013), p.223.

Google Scholar

[4] Y. Tan, G. Wu, and J.M. Yang: Fatigue and Fracture of Engineering Materials and Structures. Vol. 27(2004), p.650.

Google Scholar

[5] Lavender Curt A., S.T. Hong, and Smith Mark T.: Journal of Materials Processing Technology. Vol. 204(2008), p.490.

Google Scholar

[6] Y.K. Zhang, C.L. Hu, and L. Cai: Appl. Phys. A. Vol. 72(2001), p.113.

Google Scholar

[7] Charles S. Montross, W. Tao, and Y. Lin: International J. Fatigue. A. Vol. 24(2002), p.1022.

Google Scholar

[8] Hemmat, A.R. Binandeh, J. Ghaisari, and A. Khorsandi: Sensors and Actuators A. Physical Vol. 198(2013), p.64.

Google Scholar

[9] J. Zhao: Agricultural Mechanical Analysis and Synthesis (China Machine Press, Beijing 2009) (in Chinese).

Google Scholar

[10] B.F. Li: Agricultural Mechanics (China Agriculture Press, Beijing 2003) (in Chinese).

Google Scholar

[11] Y.K. Zhang, J.F. Chen, and R.J. Xu: Chinese J. Lasers. Vol. 35(2008), p.1070 (in Chinese).

Google Scholar

[12] R.B. Gou, Y.L. Zhang, X.D. Xu, L. Sun, and Y. Yang: NDT & E International. Vol. 44(2011), p.388.

Google Scholar

[13] H. Miao, D.W. Zuo, M. Wang, R.H. Zhang, and H.F. Wang: Chinese J. Mechanical Engineering. Vol. 24(2011), p.442.

Google Scholar