STUDY ON BALL END MILLING PROCESS USING TWO DIMENSIONAL FINITE ELEMENT METHOD

Authors

  • Ahmad Shahir Jamaludin Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak
  • Abdullah Yassin Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak
  • Mohd. Shahril Osman Department of Mechanical and Manufacturing Engineering, Faculty of Engineering, Universiti Malaysia Sarawak, 94300 Kota Samarahan, Sarawak

Keywords:

Finite element method (FEM), 2D orthogonal end milling, cutting force prediction, cutting temperature prediction, friction model

Abstract

In this paper, finite element analysis on laser sintered material machining with predicted cutting force and temperature distribution is explained. The process involved 2D orthogonal down-cut milling with the application of two dimension thermo mechanical plane strain model. The updated Lagrangian formulation was used whereas cutting simulation does not involved element separation but automatic remesh when element distorted critically. AISI 1055 mild steel properties were used as comparison. Various types of friction models were adopted in obtaining precise results. Predicted cutting force and cutting edge temperature are validated against corresponding experimental values by previous researches. From the simulation results, the shear friction model of 0.8 is the optimum friction model whereas 5-15% errors were obtained for increasing machining radial depth for AISI 1055. Lower cutting force predicted for laser sintered materials as compared to AISI 1055 due to lower Young modulus value. Cutting edge temperature predicted for laser sintered materials is higher due to its low thermal conductivity as compared to AISI 1055.

References

Dewes R. C. and Aspinwall D. K., A review of ultra high speed milling of hardened steels. Journal of Materials Processing Technology, 1997. 69(1-3): p. 1-17.

King D. and Tansy T., Rapid tooling: Selective laser sintering injection tooling. Journal of Materials Processing Technology, 2003. 132(1-3): p. 42-48.

Ramada S. and Dickens P., Rapid tooling analysis of Stereolithography injection mould tooling. International Journal of Machine Tools and Manufacture, 2007. 47 (5): p. 740-747.

Kalpakjian S. and Schmidt S.R., Manufacturing engineering and technology. 4thed., 2000. Prentice Hall International.

Guzzle B. U. and Lazuli I., An enhanced force model for sculptured surface machining. Machining Science and Technology, 2004. 8(3): p. 431-448.

Abe S., Higashi Y., Few I., Yoshida N., and Onekama T., Milling-combined laser metal sintering system and production of injection molds with sophisticated function. Proceeding of 11th International Conference on Precision Engineering, 2006. Tokyo, Japan.

Abe S., Study on Development of Milling-Combined Laser Metal Sintering System and Production of Injection Molds. Doctoral Thesis, Department of Mechanical System Engineering, Kanazawa University, Kanazawa, 2008. Ishikawa, Japan.

Armoring, E. J. A., Shi G., and Veers S., Modeling the basic cutting action and machining performance of sintered metallic materials. Machining Science and Technology, 2001. 5(3): p. 353-373.

Hamiuddin M. and Mustafa Q., Machinability of phosphorous containing sintered steels. Materials Chemistry and Physics, 2001. 67(1-3): p. 78-84.

Filice L., Micari F., Rizzuti S., Umbrello D., Dependence Of Machining Simulation effectiveness On Material And Friction Modelling. Machining Science and Technology, 2008. 12(3): p. 370-389.

Ozel T., The Influence of Friction Models On Finite Element Simulations ofMachining, Int. Journal of Tools and Manufacturing, 2006. 46: p. 518-530.

Usui E. and Shirakashi T., Mechanics of Machining from Descriptive to Predictive Theory. The Art of Cutting Metals- 75 Years Later- ASME PED, 1982. 7: p. 13-55.

Strenkowski J. S., and Carroll J. T., A Finite Element Model of Orthogonal Metal Cutting. Trans. ASME Journal of Engineering for Industry, 1985. 107: p. 346-354.

Davim J. P., and Maranhao C., A Study of Plastic Strain and Plastic Strain Rate in Machining of Steel AISI 1045 Using FEM Analysis. Materials and Design, 2009. 30: p. 160-165.

Davim J. P., Maranhao C., Jackson M. J., Cabral G., Gracio J., FEM analysis in high speed machining of aluminium alloy (Al7075-0) using polycrystalline diamond (PCD) and cemented carbide (K10) cutting tools. International Journal of Advanced Manufacturing Technology, 2008. 39: p. 1093-1100

Umbrello D., Finite element simulations of conventional and high speed machining of Ti6Al4V alloy. Journal of Materials Processing Technology, 2008. 196(1-3): p. 79-87.

Ozel T., Altan T., Process simulation using finite element method - prediction of cutting forces, tool stresses and temperature in high speed flat end milling. International Journal of Machine Tools & Manufacturing, 2000. 40: p. 713-718.

Furumoto T., Ueda T., Abdul Aziz M. S., Hosokawa A., Tanaka R., Study on reduction of residual stress induced during rapid tooling process – influence of heating conditions on residual stress. Key Engineering Materials, 2010. 447-448: p. 785-789.

Yassin A., Ueda T., Furumoto T., Hosokawa A., Tanaka R., Abe S., Experimental investigation on cutting mechanism of laser sintered material using small ball end mill. Journal of Materials Processing Technology, 2009. 209: p. 5680-5689.

Ergatoudis I., Irons B. M. and Zienkiewics O. C., Curved, isoparametic ‘Quadrilateral’ element for finite element analysis. International Journal of Solids Structures, 1968. 4, p. 31-42.

Kato S., Yamaguchi K., Yamada M., Stress distribution at the interface between tool and chip in machining. Trans. ASME Journals of Engineering for Industry, 1972. 94: p. 683-689.

Abukhshim N. A., Mativenga P. T., Sheikh M.A., Heat generation and temperature prediction in metal cutting: review and implications for high speed machining. International Journal of Machine Tools & Manufacture, 2006. 46: p. 782-800.

Coelho R. T., Ng E. G. , Elbestawi M. A., Tool wear when turning hardened AISI 4340 with coated PCBN tools using finishing cutting conditions. International Journal of Machine Tools and Manufacture, 2007. 47(2): p. 263-272.

Abukhshim N. A., Mativenga P. T., Sheikh M. A., Investigation of heat partition in high speed turning of high strength alloy steel. International Journal of Machine Tools & Manufacture, 2005. 45: p. 1687-1695.

Hosokawa A., Zhou Z. P., Yamada K. and Ueda T., Studies on High-speed Milling with Small Ball End Mill: Temperature Distribution on Flank Face of Cutting Tool. Journal of Japanese Society Precision Engineering, 2010. 70(12): p. 1527-1532.

Sutter G., Chip geometries during high-speed machining for orthogonal cutting conditions. International Journal of Machine Tools & Manufacture, 2005. 45: p. 719-726.

Trent E., Wright P., Metal Cutting, 4th ed., 2000. Butterworth Heinemann, US.

Newby G., Venkatachalan S., Liang S. Y., Empirical analysis of cutting force constants in micro-end-milling operations. Journal of Materials Processing Technology, 2007. 192-193: p. 41-47.

Downloads

Published

2018-04-02

How to Cite

Jamaludin, A. S., Yassin, A., & Osman, M. S. (2018). STUDY ON BALL END MILLING PROCESS USING TWO DIMENSIONAL FINITE ELEMENT METHOD. Jurnal Mekanikal, 34(1). Retrieved from https://jurnalmekanikal.utm.my/index.php/jurnalmekanikal/article/view/75

Issue

Section

Mechanical

Similar Articles

<< < 17 18 19 20 21 22 23 24 25 26 > >> 

You may also start an advanced similarity search for this article.