Characteristics of dimple structure on aluminium silicon alloy fabricated using turning machine

Purpose This research aims to present the characteristics of dimple structure which was fabricated using a turning machine, where the characteristics include sizes, shapes, area ratio and aspect ratio. This research aims at filling the gap in the machining parameters of previous research in producin...

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Bibliographic Details
Published in:Industrial lubrication and tribology 2022-04, Vol.74 (4), p.421-430
Main Authors: Mohd Nasir, Faarih Farhan, A. Ghani, Jaharah, Kasim, Mohd Shahir, W. Zamri, Wan Fathul Hakim
Format: Article
Language:English
Subjects:
Aluminum base alloys
Aspect ratio
Bearing strength
Carbide tools
Coefficient of friction
Cutting parameters
Cutting speed
Dimpling
Feed rate
Friction
Friction reduction
Geometry
Lathes
Load
Load carrying capacity
Lubricants & lubrication
Machine tools
Mass production
Mechanical components
Optical microscopes
Orthogonal arrays
Process parameters
Profilometers
Rake angle
Silicon
Surface roughness
Taguchi methods
Tooling
Tribology
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Summary:Purpose This research aims to present the characteristics of dimple structure which was fabricated using a turning machine, where the characteristics include sizes, shapes, area ratio and aspect ratio. This research aims at filling the gap in the machining parameters of previous research in producing dimple by using turning process with the aid of dynamic assisted tooling for turning (DATT). In producing dimple, a carbide insert grade H1 was used on a hypereutectic aluminium silicon alloy (A390) material. Dimple has many advantages such as for reducing friction coefficient, load-carrying capacity and trap wear debris for sliding mechanical components. Design/methodology/approach There are seven machining parameters (cutting speed, feed rate, depth of cut, frequency, amplitude, rake angle, relief angle and nose radius) which have an influence on dimple produced. Taguchi method (orthogonal arrays L8) was used to conduct the experiment systematically and efficiently for these seven parameters. A carbide insert grade H1 was used as a cutting tool on a turning machine with the aid of DATT. The dimple structure was fabricated on a cylindrical rod hypereutectic aluminium silicon alloy (A390). A profilometer 3D Alicona infinite focus and an optical microscope equipped with Vis software were used to analyse the fabricated dimple structure. Findings Various shapes and sizes of ellipse dimples were produced in this research, including short and long drops with lengths in the range of 517.03–3,927.61 µm, widths of 565.15–1,039.19 µm, depths of 14.46–124.87 µm, area ratios of 5.05–25.65% and aspect ratios of 0.007%–0.111%. There were four experiments within the optimal area ratio range of 10%–20%, i.e. the second, third, seventh and eighth experiments. The width of these dimples was 895.95, 961.39, 787.27 and 829.22 µm, length was 826.26, 3163.13, 885.98 and 1026.65 µm, depth was 83.67, 84.19, 87.05 and 110.70 µm and area ratio was 15.12%, 13.14%, 14.79% and 12.70%. The surface roughness of textured surface was below 1 µm. In this research, the results obtained were similar with that of previous researchers on dimple structure related to tribology performance. Originality/value There exists machining parameters, namely, cutting speed and frequency, that were not used by previous research in producing dimple. These machining parameters (cutting speed and frequency) were used in this research to produce dimple via turning process with the aid of DATT using carbide insert
ISSN:0036-8792
1758-5775
DOI:10.1108/ILT-08-2020-0310