Abstract
Machined surface quality and integrity affect the corrosion performance of AZ31 magnesium composites. These novel materials are preferred for temporary orthopedic and vascular implants. In this paper, the drilling performance of AZ31-magnesium reinforced with hollow alumina microsphere syntactic foam under LN2 cryogenic, dry, and Almag® Oil is presented. Cutting tests were conducted using TiAlN physical vapor deposition (PVD) coated multilayer carbide and K10 uncoated carbide twist drills. AZ31 magnesium matrices were reinforced with hollow alumina ceramic microspheres with varying volume fractions (5%, 10%, 15%) and average bubble sizes. Experimental results showed that the drilling thrust forces increased by 250% with increasing feed rate (0.05 to 0.6 mm/tooth) and 46% with the increasing volume fraction of alumina microspheres (5% to 15%). Cryogenic machining generated 45% higher thrust forces compared to dry and wet machining. The higher the volume fraction and the finer the average size of hollow microspheres, the higher were the thrust forces. Cryogenic machining (0.42 µm) produced a 75% improvement in surface roughness (Ra) values compared to wet machining (1.84 µm) with minimal subsurface machining-induced defects. Surface quality deteriorated by 129% with an increasing volume fraction of alumina microspheres (0.61 µm to 1.4 µm). Burr height reduction of 53% was achieved with cryogenic machining (60 µm) compared to dry machining (130 µm). Overall, compared to dry and wet machining methods, cryogenic drilling can be employed for the machining of AZ31 magnesium syntactic foams to achieve good surface quality and integrity.
Highlights
Magnesium being the lightest metal, is commercially available with enhanced mechanical properties [1]
The effect of process parameters on test results shows that the variation in cutting speed and feed/tooth has an important influence on the magnitude of generated thrust force
An increase cutting speed from 40 m/min to m/min decreases force by 46% (150 N to 80 N). This is primarily attributed to the softening of the AZ31 matrix due to an and abrasion of the hollow ceramic microsphere on the tool are the main causes of tool wear during the thrust force by 46% (150 N to 80 N)
Summary
Magnesium being the lightest metal, is commercially available with enhanced mechanical properties [1]. Magnesium-based closed cell syntactic foams possess great potential in important sectors such as biomedical, automotive, and marine applications to design lightweight products [2]. Due to their excellent biocompatibility, magnesium-based alloys are potential candidates for temporary biodegradable medical implants [3,4,5]. The coarser the average size of hollow reinforcements is, the lower the hardness of the magnesium closed-cell foam [11,12]. The mechanical properties of aluminum-based syntactic foam are shown to be comparable to the base alloy under cryogenic conditions [8]
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