AN EXPERIMENTAL STUDY ON THIRD-BODY PARTICLE TRANSPORT IN SLIDING CONTACT

Qiang Li, Iakov A. Lyashenko, Jasminka Starcevic

DOI Number
10.22190/FUME201211016L
First page
001
Last page
005

Abstract


An experiment is designed to study the third-body particle transport in a rough contact. To study the influence of particles in a pure form, it is assured that the first bodies have no contact and the sliding is very slow, so that the process can be considered as quasistatic. An example of sliding contact of a 3D printed “rough body” on small spheres artificially located on a rubber layer is presented. The trajectory of particles during the sliding is captured for studying their movement and the correlation to the fluctuation of normal and tangential force.

Keywords

Third-body, Particle transport, Friction, Experiment

Full Text:

PDF

References


Vakis, A.I. Yastrebov, V.A., Schreibert, J., et al., 2018, Modeling and simulation in tribology across scales: An overview, Tribology International, 125, pp. 169–199.

Dienwiebel, M., Verhoeven, G.S., Pradeep, N., Frenken, J.W.M., Heimberg, J.A., Zandbergen, H.W., 2004, Superlubricity of Graphite, Physical Review Letters, 92, 126101.

Zhang, Y., Kovalev A., Meng, Y., 2018, Combined effect of boundary layer formation and surface smoothing on friction and wear rate of lubricated point contacts during normal running-in processes, Friction, 6, pp. 274–288.

Aghababaei, R., Warner, D.H., Molinari, J.F., 2016, Critical length scale controls adhesive wear mechanisms, Nature Communication, 7, 11816.

Popov, V.L., Pohrt, R., 2018, Adhesive wear and particle emission: Numerical approach based on asperity-free formulation of Rabinowicz criterion, Friction, 6, pp. 260-273.

Ostermeyer, G.P., Brumme, S., Recke, B., 2017, The wear debris investigator – a new device for studying the formation of particles in the contact area, Proc. Eurobrake, Dresden, EB2017-VDT-019.

Ostermeyer, G.P., 2003, On the dynamics of the friction coefficient, Wear, 254, pp. 852–858.

Deng, F., Tsekenis, G., Rubinstein, S.M., 2019, Simple law for third-body friction, Physical Review Letters, 122, 135503.

Lyashenko, I.A., Pohrt, R., 2020, Adhesion between rigid indenter and soft rubber layer: Influence of roughness, Frontiers in Mechanical Engineering. Section Tribology, 6, 49.

Lyashenko, I.A., Popov, V.L., 2020, The effect of contact duration and indentation depth on adhesion strength: experiment and numerical simulation, Technical Physics, 65(10), pp. 1695–1707.

Li, Q., Lyashenko, I.A., Starcevic, J., 2021, An experimental study on third-body particle transport in sliding contact (video of experiment), supplementary video. https://doi.org/10.13140/RG.2.2.31164.67206

De Payrebrune, K.M., Kröger, M., 2015, Kinematic analysis of particles in three-body contact, Tribology International, 81, pp. 240–247.

Li, Q., 2020, Simulation of a single third-body particle in frictional contact, Facta Universitatis-Series Mechanical Engineering, 18(4), pp. 537–544.

Rey, V., Anciaux, G., Molinari, J.F., 2017, Normal adhesive contact on rough surfaces: efficient algorithm for FFT-based BEM resolution, Computational Mechanics, 60, pp. 69–81.


Refbacks

  • There are currently no refbacks.


ISSN: 0354-2025 (Print)

ISSN: 2335-0164 (Online)

COBISS.SR-ID 98732551

ZDB-ID: 2766459-4