10.22190/FUME151120001P

97

106

Complex nature of machining processes requires the use of different methods and techniques for process optimization. Over the past few years a number of different optimization methods have been proposed for solving continuous machining optimization problems. In manufacturing environment, engineers are also facing a number of discrete machining optimization problems. In order to help decision makers in solving this type of optimization problems a number of multi criteria decision making (MCDM) methods have been proposed. This paper introduces the use of an almost unexplored MCDM method, i.e. performance selection index (PSI) method for solving machining MCDM problems. The main motivation for using the PSI method is that it is not necessary to determine criteria weights as in other MCDM methods. Applicability and effectiveness of the PSI method have been demonstrated while solving two case studies dealing with machinability of materials and selection of the most suitable cutting fluid for the given machining application. The obtained rankings have good correlation with those derived by the past researchers using other MCDM methods which validate the usefulness of this method for solving machining MCDM problems.

Multi Criteria Decision Making, Performance Selection Index, Machining, Optimization, Machinability, Cutting Fluid

Rao, R. V., 2007, Decision Making in the Manufacturing Environment: using graph theory and fuzzy multiple attribute decision making methods, Springer-Verlag London.

Radovanović M., Madić, M., 2010, Methodology of neural network based modeling of machining processes, International Journal of Modern Manufacturing Technologies, 2(2), pp. 77-82.

Rao, R.V., 2006, Machinability evaluation of work materials using a combined multiple attribute decision making method, International Journal of Advanced Manufacturing Technology, 28(3–4), pp. 221–227.

Chakraborty, S., Zavadskas, E.K., 2014, Applications of WASPAS Method in Manufacturing Decision Making, Informatica, 25(1), pp. 1–20.

Petković, D., Madić, M., Radenković, G., 2015, Selection of the Most Suitable Non-Conventional Machining Processes for Ceramics Machining by Using MCDMs, Science of Sintering, 47, pp. 229-235.

Rao, R.V., Patel, B.K., 2010, Decision making in the manufacturing environment using an improved PROMETHEE method, International Journal of Production Research, 48(16), pp. 4665–4682.

Enache, S., Strajescu, E., Opran, C., Minciu, C., Zamfirache, M., 1995, Mathematical model for the establishment of the materials machinability, CIRP Annals, 44, pp. 79–82.

Maniya, K., Bhatt, M.G., 2010, A selection of material using a novel type decision-making method: Preference selection index method, Materials and Design, 31, pp. 1785–1789.

Singh T., Patnaik A, Gangil B., Chauhan R., 2015, Optimization of tribo-performance of brake friction materials: effect of nano filler, Wear, 324-325, pp. 10-16.

Khorshidi R., Hassani A., 2013, Comparative analysis between TOPSIS and PSI methods of materials selection to achieve a desirable combination of strength and workability in Al/SiC composite, Materials and Design, 52, pp. 999–1010.

Vahdani, B., Zandieh, M., Tavakkoli-Moghaddam, R., 2011, Two novel FMCDM methods for alternative-fuel buses selection, Applied Mathematical Modelling, 35, pp. 1396–1412.

Rao, R.V., Gandhi, O.P., 2002, Digraph and matrix methods for the machinability evaluation of work materials, International Journal of Machine Tools and Manufacture, 42(3), pp. 320–330.