Authors: Afzeri, R. Muhida, Darmawan, A. N. Berahim

Abstract:

Sharing the manufacturing facility through remote operation and monitoring of a machining process is challenge for effective use the production facility. Several automation tools in term of hardware and software are necessary for successfully remote operation of a machine. This paper presents a prototype of workpiece holding attachment for remote operation of milling process by self configuration the workpiece setup. The prototype is designed with mechanism to reorient the work surface into machining spindle direction with high positioning accuracy. Variety of parts geometry is hold by attachment to perform single setup machining. Pin type with array pattern additionally clamps the workpiece surface from two opposite directions for increasing the machining rigidity. Optimum pins configuration for conforming the workpiece geometry with minimum deformation is determined through hybrid algorithms, Genetic Algorithms (GA) and Particle Swarm Optimization (PSO). Prototype with intelligent optimization technique enables to hold several variety of workpiece geometry which is suitable for machining low of repetitive production in remote operation.

Keywords: Optimization, Remote machining, GeneticAlgorithms, Machining Fixture.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1061613

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2585

References:

[1] H. Yang, D. Xue, Recent research on developing Web-based manufacturing systems: a review, Int. journal. prod. res., 2003, vol. 41, no. 15, 3601-3629.
[2] Qiang, L., Zhang, Y. F. and Nee, A. Y. C., 2001, A distributive and collaborative concurrent product design system through the WWW/Internet. International Journal of Advanced Manufacturing Technology, 17, 315-322.
[3] Kim, Y., Choi, Y. and Yoo, S. B., 2001, Brokering and 3D collaborative viewing of mechanical part modelson the Web. International Journal of Computer Integrated Manufacturing, 14, 28-40.
[4] J.H. Yeh, F.W. Liou, 1999, Contact condition modelling for machining fixture setup processes, Int. J. Mach. Tools Manuf. 39 787-803.
[5] R.O. Mittal, P.H. Cohen, B.J. Gilmore, 199, Dynamic modelling of the fixture-workpiece system, Robot. Comput.-Integr. Manuf. 8 (4) 204- 2171.
[6] Shane P. Siebenaler, Shreyes N. Melkote, Prediction of workpiece deformation in a fixture system using the finite element method, International Journal of Machine Tools & Manufacture 4651-58, 2006.
[7] R.J. Menassa, W.R. DeVries, 1991, Optimization methods applied to selecting support positions in fixture design, ASME Journal of Engineering for Industry 113 412-418.
[8] N. Amaral, J.J. Rencis, Y. Rong, 2004, Development of a finite element analysis tool for fixture design integrity verification and optimisation, International Journal of Advanced Manufacturing Technology 21 411- 419.
[9] E.Y.T. Tan, A.S. Kumar, J.Y.H. Fuh, A.Y.C. Nee, 2004, Modeling, analysis and verification of optimal fixturing design, IEEE Transactions on Automation Science and Engineering 1 (2) 121-132.
[10] Necmettin, K. , 2006, Machining fixture locating and clamping position optimization using genetic algorithms, Computers in Industry 57 112- 120.
[11] A.S. Kumar, V. Subramaniam, K.C. Seow, 1999, Conceptual design of fixtures using genetic algorithms, International Journal of Advanced Manufacturing Technology 15, pp 79-84.
[12] Afzeri, A.G. E. Sutjipto, A.K.M. Nurul Amin, Riza Muhida, 2005, Determination of pin configuration for clamping fixture by means of solid model contact analysis, Proceedings of the International Conference on Mechanical Engineering (ICME), Dhaka, Bangladesh.