Author(s)

Alexis Mouangué Nanimina^1*, Nandiguim Lamaï¹, Djimako Bongo^1,2, Togdjim Jonas¹, Bonaventure Danoumbé¹, Ahmad Majdi Abdul-Rani³

¹Mechanical Engineering Department, Higher National Institute of Sciences and Techniques of Abéché (INSTA), Abéché, Ouaddai, Chad.
²Higher Normal School of Technology of Sarh, Moyen-Chari, Chad.
³Mechanical Engineering Department, Universiti Teknologi PETRONAS (UTP), Perak, Darul Ridzuan, Malaysia.

The objective of this work research is to investigate the potential of using metallic powder mixed with electrical discharge machining (EDM) dielectric when machining hard electrically conductive materials. Nowadays, the development of industries requires hard materials for various applications. Machining the hard materials using the traditional processes lead to tool break and poor machined product. Even when the conventional EDM can machine hard material as long as it is electrically conductive materials, the machined parts still present drawbacks. Metallic powder mixed with EDM dielectric (PMEDM) was hypothesized to improve the machined part. The presence of metallic powder ensures uniform distribution of spark and the electrical density of the spark decreases which reduces craters, cracks and voids on machined surface. The transfer and deposit of alloying elements during powder mixed electrical discharge machining improve the machined surface properties particularly micro-hardness and fatigue. Discharge current (IP), gap voltage (GapV), ON-time (ON) and aluminum powder are selected as machined variable parameters and the output responses are fatigue performance, micro-hardness and surface topography. The workpiece material selected is molybdenum high speed steel. Micro-hardness was determined using micro-hardness tester device. The fatigue performance was determined using empirical equation. Analysis of material transfer was done using energy dispersive spectroscopy (EDS) attached to FESEM. EDS analysis involves the generation of an X-ray spectrum from the entire scan area of the SEM. The use of PMEDM improved the fatigue, the micro-harness and the machined surface morphology as the above-mentioned parameters increased.

PMEDM, Fatigue, Micro-Hardness, Discharge Current, Gap Voltage, ON-Time

Mouangué Nanimina, A. , Lamaï, N. , Bongo, D. , Jonas, T. , Danoumbé, B. and Abdul-Rani, A. (2020) Analysis of Fatigue and Microhardness in Metallic Powder Mixed EDM. Open Journal of Applied Sciences, 10, 613-624. doi: 10.4236/ojapps.2020.1010043.