Turning Test and Simulation of Difficult to Cut Materials 300M in Aviation

Hui Ping Zhang; Yi Nan Lai; Chong Xun Wang; Xu Du

doi:10.4028/www.scientific.net/MSF.800-801.208

Paper Titles

Research on Fractal Characterization in Grinding of Monocrystal Sapphire
p.186

Experimental Study on Turning Nickel-Based Superalloy GH4033 with Coated Cemented Carbide Tools
p.191

Study Chip Breaking Experimental and Optimal Design of Tool for Machining Cylindrical Shell Material
p.197

Silicon Carbide Ceramic Turning Process Design and Parameter Analysis
p.203

Turning Test and Simulation of Difficult to Cut Materials 300M in Aviation
p.208

Cutting Performance and Wear Mechanism of Coated Silicon Nitride Cutting Tool in Turning of High Hardness Alloy Steel
p.214

Research of Dynamic Cutting Force in Hardened Steel Precision Turning Process
p.221

Changing Boundaries of Serrated Chip in Hard Cutting GCr15 Steel
p.227

Experiment Research of Milling Force in High Machining GH4169 Based on MatLab
p.232

HomeMaterials Science ForumMaterials Science Forum Vols. 800-801Turning Test and Simulation of Difficult to Cut...

Turning Test and Simulation of Difficult to Cut Materials 300M in Aviation

Abstract:

Turning process properties of difficult-to-cut materials used in aeronautics are often associated with the machining accuracy and surface quality of aerospace structural parts. This study presents the influence of cutting velocity, feed rate and back cutting depth on cutting force and cutting temperature during dry turning of ultra-high strength 300M steel, where the linear regression models of cutting forces and cutting temperature are constructed by using least square method, and the regression coefficients of these models are verified by significance tests. Meanwhile, the temperature distribution and chip in turning machining are also achieved by finite element analysis.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Materials Science Forum (Volumes 800-801)

Pages:

208-213

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.800-801.208

Citation:

Cite this paper

Online since:

July 2014

Authors:

Hui Ping Zhang*, Yi Nan Lai, Chong Xun Wang, Xu Du

Keywords:

Cutting Force, Difficult-to-Cut Material, Finite Element Analysis (FEA), Linear Regression Model

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Zhao,Z. Y. , Zhao,Y. T. , He,L. L. and Quan, H . S ., The Development of Structural Materials of Advanced Aircraft, Journal of Materials Engineering, Vol. 4, pp.4-11.

Google Scholar

[2] Zhang,B. G. , Chen,Z. T. , Xiong,X. Y., Li, X. D., and Jiang.L. K. Experimental Research on Tool Wear In Milling 300M with Coated Tool, Aviation Precision Manufacturing Technology, Vol. 2, pp.41-44.

Google Scholar

[3] Lee,E. H, Sha_er,B.W., The theory of plasticity applied to a problem of machining, ASME Journal Applied Mechanics, Vol. 18, pp.405-413.

Google Scholar

[4] Oxley P.L. B, Allowing for end cutting edge effects in predicting forces in bar turning with oblique machining conditions, Journal Title, Proc Inst MechEng, Vol. C3, pp.89-99.

Google Scholar

[5] Yen,Y. C. , Jain, A. and Altan,T., A finite element of orthogonal machining using different tool edge geometries, Journal of Materials Processing , Vol. 146, pp.72-81.

DOI: 10.1016/s0924-0136(03)00846-x

Google Scholar

[6] Hu,C. G. , Zhang,D. H., Ren,X. J., and Yang,L., An overview on cutting force modeling, Advances in Mechanics, Vol. 36, pp.564-570.

Google Scholar

[7] Chen,R. Y., 'Principles of Metal Cutting', China Machine Press, pp.60-66.

Google Scholar