Abstract
Surface modification is given vital importance in the biomedical industry to cope with surface tissue growth problems. Conventionally, basic surface treatment methods are used which include physical and chemical deposition. The major drawbacks associated with these methods are excessive cost and poor adhesion of coating with implant material. To generate a bioactive surface on an implant, electric discharge machining (EDM) is a promising and emerging technology which simultaneously serves as machining and surface modification technique. Besides the surface topology, implant material plays a very important role in surgical applications. From various implant materials, titanium (Ti6Al4V ELI) alloy is the best choice for long-term hard body tissue replacement due to its superior engineering, excellent biocompatibility and antibacterial properties. In this research, EDM’s surface characteristics are explored using Si powder mixed in dielectric on Ti6Al4V ELI. The effect of powder concentration (5 g/L, 10 g/L and 20 g/L) along with pulse current and pulse on time is investigated on micro and nanoscale surface topography. Optimized process parameters having a 5 g/L powder concentration result in 2.76 μm surface roughness and 13.80 μm recast layer thickness. Furthermore, a nano-structured (50–200 nm) biocompatible surface is fabricated on the surface for better cell attachment and growth. A highly favourable carbon enriched surface is confirmed through EDS which increases adhesion and proliferation of human osteoblasts.
Highlights
Titanium and its alloys are being used in automotive, aeronautical, biomedical and a number of other industries due to their exceptional properties
The study resulted in 57.98% and 129.17% improvements in the surface finish and microhardness of powder mixed electric discharge machining (PMEDM), respectively, as compared to EDM
The present study investigates surface quality along with machining characteristics to modify the surface without compromising on machining efficiency
Summary
Titanium and its alloys are being used in automotive, aeronautical, biomedical and a number of other industries due to their exceptional properties. The mixing of powder, surfactant and different type of gasses in the dielectric to enhance properties of dielectric or to deposit a specific required layer on the surface in EDM is called additive mixed electric discharge machining. The attention of researchers has been drawn towards the fabrication of a biomedically active surface using additive mixed electric discharge machining It significantly improves corrosion and wear resistance, fatigue life and biomedical properties of artificial human body components (implant). The study resulted in 57.98% and 129.17% improvements in the surface finish and microhardness of powder mixed electric discharge machining (PMEDM), respectively, as compared to EDM Another researcher carried out similar study with titanium powder mixed dielectric and using pulse on:off time, current, polarity, and copper electrode as variables to evaluate surface characteristics (topography, recast layer thickness) [24]. In the present research work, silicon particle mixed dielectric fluid in EDM with different concentrations is evaluated to enhance biocompatibility by producing favourable surface characteristics
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