Effect of Ball Burnishing on Surface Roughness and Wear of AISI 316L SS

Attabi, Selma; Himour, Abdelaziz; Laouar, L.; Motallebzadeh, Amir

doi:10.1007/s40735-020-00437-9

Cited by 22 publications

(19 citation statements)

References 38 publications

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“…This necessities the importance to study tangential misalignment angle between the shaft and burnishing tool head. Many authors have examined burnishing methods like ball or roller effect on material integrity [7,[12][13][14][15]. The effect of ultrasonic burnishing on microstructural mechanism for cylindrical workpiece with different tangential alignments has been understudied.…”

Section: Rotational Speedmentioning

confidence: 99%

Effect of Ultrasonic Burnishing Parameters on Burnished-Surface Quality of Stainless Steel After Heat Treatment

Ullah

Fangnon

Huuki

2022

Lecture Notes in Mechanical Engineering

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Ultrasonic burnishing induces beneficial compressive stresses and high surface quality in components with contact as a functional requirement. It was observed in previous work that some burnishing parameters can hinder burnishability of stainless steels. In this research tangential misalignment angles (TMA) for burnishing were varied considering as-supplied and heat-treated stainless steel. Properties such as surface hardness and surface roughness were measured after burnishing process. Electron Backscatter Diffraction was performed to characterize microstructure using Matlab (MTEX) to calculate average grain areas. By changing burnishing parameters, i.e., shaft rotational speed and burnishing tool diameter, it was observed that burnishing was less successful. Nevertheless, significant improvement in burnished surface quality was observed after heat-treatment process. In addition, grain size characterization revealed mean grain area reduction from 26 µm2 for unburnished to 11 µm2 and 3 µm2 for burnished and heat-treated samples respectively. Most importantly this work reveals the enhanced possibility of burnishing stainless steels after heat-treatment with varying tangential misalignment angles.

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Section: Rotational Speedmentioning

confidence: 99%

Effect of Ultrasonic Burnishing Parameters on Burnished-Surface Quality of Stainless Steel After Heat Treatment

Ullah

Fangnon

Huuki

2022

Lecture Notes in Mechanical Engineering

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“…It can be concluded that when the ball passes repeatedly over the surface of 316L, it deforms more asperities and produce smoother surface. However, this repetition should be limited 3 times to have the most improved surface, otherwise, surface flaking occurs due to excessive plastic deformation on the same surface layers [4].…”

Section: Effect Of Ball Burnishing On the Surface Topographymentioning

confidence: 99%

“…In almost engineering applications, an important interest is directed to the aspect of surface as it strongly influences the functional properties of mechanical parts such as their corrosion resistance, tribological behavior, and fatigue durability. Most failures of manufactured parts initiate from the outer layers which are exposed to the environmental conditions of service [4]. Mechanical, metallurgical, or chemical changes are the most common causes of the initiation of alterations in the surface [5].…”

Section: Introductionmentioning

confidence: 99%

“…The positive effect of this treatment in reducing the surface roughness [12][13][14][15][16] and raising the microhardness [12,[15][16][17][18] was widely reported. As a result, of these changes caused in surface characteristics, wear delamination was restricted as the interlocking movements of micro-irregularities were limited during friction [4,19]. Fatigue resistance, yield and tensile strength, and also corrosion resistance were improved [20,21].…”

Section: Introductionmentioning

confidence: 99%

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Surface Integrity of Ball Burnished 316L Stainless Steel

Attabi¹,

Himour²,

Laouar³

et al. 2022

Stainless Steels

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316L is a type of austenitic stainless steel that offers a good combination of mechanical properties, corrosion resistance, and biocompatibility. In some industrial applications, it is necessary to proceed to finish treatments to extend the lifetime of the mechanical parts. In the present chapter, ball burnishing treatment is applied to improve the surface integrity of 316L since the performance behavior of parts is directly dependant on the surface properties of the used material. Both surface topography and surface microhardness of 316L after subjection to ball burnishing are studied. The number of burnishing passes is varied by up to five to investigate its effect on the results. Optical profilometer and atomic force microscopy (AFM) were used to analyze the surface roughness and surface topography texture while measurements of microhardness Vickers were proceeded to investigate the changes in surface hardening.

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“…Revankar et al indicated that the specific wear rate and frictional coefficient of the burnished Ti-6Al-4V were decreased by 52.0% and 64.0%, respectively using the Taguchi method, as compared to the turned surface [10]. Attabi et al emphasized that the Ra and wear loss of the burnished AISI 316L could be enhanced by 93.4% and 53.4%, respectively with the support of the ball burnishing operation [11].…”

Section: Introductionmentioning

confidence: 99%

Multi-Response Optimization of Burnishing Variables for Minimizing Environmental Impacts

2023

Teh. vjesn.

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The purpose of this investigation is to optimize minimum quantity lubrication (MQL) variables, including the nozzle diameter (D), inclined angle (A), air pressure (P), oil quantity (F), and spraying distance (S) for decreasing the energy consumption in the burnishing time (EB) and particulate matter index (PI) of the interior burnishing process. The optimal adaptive neuro-based-fuzzy inference system (ANFIS) models of the performance measures were proposed in terms of the MQL variables with the aid of the Taguchi method. The non-dominated sorting genetic algorithm based on the grid partitioning (NSGA-G) and TOPSI were employed to produce feasible solutions and determine the best optimal point. The obtained results indicated that the optimal values of the D, A, P, F, and S are 1.0 mm, 35 deg., 3 Bar, 70 ml/h, and 10 mm, respectively, while the EB and PI are decreased by 8.0% and 15.7% at the optimal solution. The optimal ANFIS models were trustworthy and ensure accurate predictions. The optimization technique comprising the ANFIS, NSGA-G, and TOPSIS could be extensively utilized to determine the optimal outcomes instead of the trial-error and/or human experience. The outcomes could help to decrease environmental impacts in the practical burnishing process.

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Effect of Ball Burnishing on Surface Roughness and Wear of AISI 316L SS

Cited by 22 publications

References 38 publications

Effect of Ultrasonic Burnishing Parameters on Burnished-Surface Quality of Stainless Steel After Heat Treatment

Effect of Ultrasonic Burnishing Parameters on Burnished-Surface Quality of Stainless Steel After Heat Treatment

Surface Integrity of Ball Burnished 316L Stainless Steel

Multi-Response Optimization of Burnishing Variables for Minimizing Environmental Impacts

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