Process Optimisation and Tribological Behaviour Studies on Surface Modified Al 6061-T6 Alloy Deposited with WS2 Solid Lubricant Layer Through Electrical Discharge Approach

Rajeshshyam, R.; Venkatraman, R.; Raghuraman, S.

doi:10.1007/s13369-021-05908-w

Cited by 10 publications

(5 citation statements)

References 23 publications

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“…The maximum value obtained is in agreement with mean value of experimental data of EDD in air [14]. Fm= q (v0 x B) = q vp B sin α [N], (7) where: q is the electric charge [C]; vp -particle velocity [m/s]; B -magnetic flux density [T]; α -the angle between vp and B vectors directions. The localization of released particles (Np) after passing through magnetic field is represented by Poincaré maps in correspondence with the three cut planes previously defined -Fig.…”

Section: Results Provided By Numerical Simulationssupporting

confidence: 85%

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Numerical Simulation of the Coating Process of some Metals by Electrical Discharge Deposition

Ghiculescu,

Iuga,

Dumitru

2023

KEM

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The paper deals with research on a hybrid technique of coating by Electrical Discharge Deposition (EDD) which has the advantage of lower costs than the other similar methods. This is due to the possibility of using a usual electrical discharge machine, with common tooling, aided by electromagnetic coils that increase the precision and the quality of deposed layers. Some metallic materials like W, Al, Ni, and Ti of high purity are used for EDD, which could be taken from available wires providers. Numerical simulation of the EDD process, using the metals mentioned above was achieved in Comsol Multiphysics. Two connected modules (physics) were used: Magnetic Fields that produced the magnetic force that actuated each of these four categories of ions and Charged Particle Tracing that highlighted the distribution of particles on different cut planes – Poincare maps. Based on these results provided by numerical simulation, it was possible to evaluate the ions behavior, in comparison to electrons, during EDD that is influenced by their atomic mass and the charge number.

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Section: Results Provided By Numerical Simulationssupporting

confidence: 85%

“…For example, WS2 was deposited on an aluminum alloy (Al 6061-T6). The results pointed out that by coating, the friction coefficient was reduced, and the wear resistance was improved [7]. Another example was WC-Cu coating from powder compacted electrode on Mg alloy (AZ31B Mg) that improved the friction coefficient and the wear resistance.…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation of the Coating Process of some Metals by Electrical Discharge Deposition

Ghiculescu,

Iuga,

Dumitru

2023

KEM

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“…WS 2 was deposited on an Al 6061-T6 surface to conduct the tribological study. The selected deposition criteria are 8.7 g/L of WS 2 concentration, 72 µs of spark-on time, and 23 V of gap voltage, as determined by previous research [21]. The macroscopic view of Al 6061-T6 sample before and after WS 2 deposition is shown in Figure 2 (b,c).…”

Section: Ws 2 Deposition Through Eddmentioning

confidence: 99%

Wear characteristics and sustainability of WS₂ solid lubricant deposited layer on Al 6061-T6 substrate under the dry sliding conditions

Rajeshshyam

Venkatraman

Raghuraman

et al. 2023

Tribology - Materials, Surfaces & Interfaces

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This research investigates the tribological characteristics and sustainability of WS 2 deposited Al 6061-T6 surface under dry sliding conditions and optimizes the wear parameters to enhance the tribological behaviour and discuss its sustainability. The experiment used the Box-Behnken design, which examines the effective interaction between dry sliding parameters and specific wear rate (SWR) and friction coefficient (COF). By varying the load (L), sliding velocity (V) and distance (D), the wear behaviour of WS 2 deposition against EN 31 steel was examined through the pin-on-disc experiment. Grooving, debris formation, polishing, tribolayer, ploughing, transfer material, smearing, delamination and pitting are observed through scanning electron microscope (SEM) analysis. For optimum conditions, SEM with energy dispersive spectroscopy was utilized to characterize the worn surface, and X-Ray diffraction (XRD) patterns confirmed the phases of W, WO

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“…They reported surface defects, existence elements, phase recognition and surface roughness of coated layer. Rajeshshyam R et al [105] developed a solid lubricant coating on aluminium alloy by powder mixed EDC and powder concentration influence on coat layer thickness and it ranges from 35 μm to 55 μm. Arun I et al [106] developed a powder mixed EDC of silicon powder on a steel substrate and reported that the coated layer thickness increases with increase of powder concentration.…”

Section: Layer Thicknessmentioning

confidence: 99%

Electric discharge coating process: a critical review with potential application

Kumaran

Muralidharan²

2023

Eng. Res. Express

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Electric discharge coating (EDC) process is a competitive surface coating technology that alters the desired surface characteristics. EDC process deposits the material on the substrates from the sacrificial electrode by spark erosion process with the potential advantage of depositing any materials. This paper extensively reviews the work carried out in the EDC process and suggests areas of improvement for easy adaptability in industrial applications. Here, the variants of the EDC process, the route map for process parameter selection, the advantage over conventional methods, and coating characterization are discussed. The review sequentially presents the fundamental process, detailed analysis of tool and workpiece materials used, process parameters, and applications. EDC process has continued to be a key solution for many industrial needs, with the critical advantage of enhancing the substrate's serviceability and protecting against corrosion, thermal stress, and other adverse environmental conditions. The scope of the work is discussed in detail, with potential industrial and biomedical applications suggesting avenues for researchers and industrialists.

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Process Optimisation and Tribological Behaviour Studies on Surface Modified Al 6061-T6 Alloy Deposited with WS2 Solid Lubricant Layer Through Electrical Discharge Approach

Cited by 10 publications

References 23 publications

Numerical Simulation of the Coating Process of some Metals by Electrical Discharge Deposition

Numerical Simulation of the Coating Process of some Metals by Electrical Discharge Deposition

Wear characteristics and sustainability of WS₂ solid lubricant deposited layer on Al 6061-T6 substrate under the dry sliding conditions

Electric discharge coating process: a critical review with potential application

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Process Optimisation and Tribological Behaviour Studies on Surface Modified Al 6061-T6 Alloy Deposited with WS2 Solid Lubricant Layer Through Electrical Discharge Approach

Cited by 10 publications

References 23 publications

Numerical Simulation of the Coating Process of some Metals by Electrical Discharge Deposition

Numerical Simulation of the Coating Process of some Metals by Electrical Discharge Deposition

Wear characteristics and sustainability of WS2 solid lubricant deposited layer on Al 6061-T6 substrate under the dry sliding conditions

Electric discharge coating process: a critical review with potential application

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Product

Resources

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Wear characteristics and sustainability of WS₂ solid lubricant deposited layer on Al 6061-T6 substrate under the dry sliding conditions