Modified teaching learning based optimization for maximization of MRR in wire-cut EDM of Ti6Al4V alloy for sustainable production
Citations Over Time
Abstract
Wire-cut electrical discharge machining (WEDM) has emerged as prominent advanced machining process to machine electrically conductive difficult-to-machine materials to any intricate shape and size. Amongst Ti-alloys, Ti6Al4V is extensively used in diverse engineering applications and is popularly researched. In this work, maximization of material removal rate (MRR) is addressed as economic aspect of sustainable production during WEDM of Ti6Al4V alloy employing modified teaching-learning based optimization (M-TLBO) algorithm. A novel method for fitness curve fitting is illustrated to obtain global optima for maximization of MRR. Taguchi L16 OA is employed to perform WEDM experiments. It is observed that MRR at optimal cutting conditions improved by 27.51% as compared to its initial maximum value. The fitness curve constructed in the optimal search domain resulted in smooth U-shape curve. ANOVA result showed that current (56.58%) and pulse-off-time (23.57%) are highly dominant process parameters influencing MRR followed by pulse on time (11.66%) and wire speed (7.20%). Machined surface morphology is studied using SEM images. The proposed M-TLBO algorithm is found highly accurate and consistent during several runs conducted and converged faster taking less than ten iterations. Also, proposed novel approach for fitness curve fitting can be effectively applied in any optimization problem.
Related Papers
- → A NEW METHOD FOR MACHINING OF ELECTRICALLY NONCONDUCTIVE WORKPIECES USING ELECTRIC DISCHARGE MACHINING TECHNIQUE(2010)66 cited
- → Electrical Discharge Machining Technology and its Latest Application(2012)5 cited
- → Experimental investigation of Wire Electrical Discharge Machining (WEDM) Process Parameters on SS304 using Taguchi method(2018)2 cited
- → Study of the Machining Shape Monitor in Wire EDM(2009)
- → Experimental Study of Kerf Machined by Micro-WEDM(2009)