The mathematical model of motion trajectory of wear particle between textured surfaces

V. Marchuk; M. Kindrachuk; Ya Krysak; O. Tisov; O. Dukhota; Y. Gradiskiy

doi:10.24874/ti.1001.11.20.03

The mathematical model of motion trajectory of wear particle between textured surfaces

V. Marchuk
, M. Kindrachuk
, Ya Krysak
, O. Tisov
, O. Dukhota
, Y. Gradiskiy

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

An effort was made to obtain a simplified mathematical model of wear particle motion in a magnetic field formed between flat and dimpled surfaces during the friction process. The magnetic field’s experimental values on the dimple edge and inside the dimple for several materials are presented. As a direct result of the internal magnetic field’s excitation at the edges of indentations, debris falls into the dimple. This reduces the wear rate by decreasing the number of abrasives in the friction interface. Apparent results expand ideas about the phenomena that naturally occur during the friction of textured surfaces.

Original language	English
Article number	1001
Pages (from-to)	241-246
Number of pages	6
Journal	Tribology in Industry
Volume	43
Issue number	2
DOIs	https://doi.org/10.24874/ti.1001.11.20.03
State	Published - 2021
Externally published	Yes

Keywords

Dimple
Indentation
Internal magnetic field
Mathematical model
Textured surface
Trajectory of motion
Wear particle

Access to Document

10.24874/ti.1001.11.20.03

Cite this

@article{be2bb325106540f28ebced1a34bb3c65,

title = "The mathematical model of motion trajectory of wear particle between textured surfaces",

abstract = "An effort was made to obtain a simplified mathematical model of wear particle motion in a magnetic field formed between flat and dimpled surfaces during the friction process. The magnetic field{\textquoteright}s experimental values on the dimple edge and inside the dimple for several materials are presented. As a direct result of the internal magnetic field{\textquoteright}s excitation at the edges of indentations, debris falls into the dimple. This reduces the wear rate by decreasing the number of abrasives in the friction interface. Apparent results expand ideas about the phenomena that naturally occur during the friction of textured surfaces.",

keywords = "Dimple, Indentation, Internal magnetic field, Mathematical model, Textured surface, Trajectory of motion, Wear particle",

author = "V. Marchuk and M. Kindrachuk and Ya Krysak and O. Tisov and O. Dukhota and Y. Gradiskiy",

note = "Publisher Copyright: {\textcopyright} 2021 Published by Faculty of Engineering.",

year = "2021",

doi = "10.24874/ti.1001.11.20.03",

language = "英语",

volume = "43",

pages = "241--246",

journal = "Tribology in Industry",

issn = "0354-8996",

publisher = "Masinski Fakultet - Kragujevac",

number = "2",

}

TY - JOUR

T1 - The mathematical model of motion trajectory of wear particle between textured surfaces

AU - Marchuk, V.

AU - Kindrachuk, M.

AU - Krysak, Ya

AU - Tisov, O.

AU - Dukhota, O.

AU - Gradiskiy, Y.

PY - 2021

Y1 - 2021

N2 - An effort was made to obtain a simplified mathematical model of wear particle motion in a magnetic field formed between flat and dimpled surfaces during the friction process. The magnetic field’s experimental values on the dimple edge and inside the dimple for several materials are presented. As a direct result of the internal magnetic field’s excitation at the edges of indentations, debris falls into the dimple. This reduces the wear rate by decreasing the number of abrasives in the friction interface. Apparent results expand ideas about the phenomena that naturally occur during the friction of textured surfaces.

AB - An effort was made to obtain a simplified mathematical model of wear particle motion in a magnetic field formed between flat and dimpled surfaces during the friction process. The magnetic field’s experimental values on the dimple edge and inside the dimple for several materials are presented. As a direct result of the internal magnetic field’s excitation at the edges of indentations, debris falls into the dimple. This reduces the wear rate by decreasing the number of abrasives in the friction interface. Apparent results expand ideas about the phenomena that naturally occur during the friction of textured surfaces.

KW - Dimple

KW - Indentation

KW - Internal magnetic field

KW - Mathematical model

KW - Textured surface

KW - Trajectory of motion

KW - Wear particle

UR - https://www.scopus.com/pages/publications/85108861573

U2 - 10.24874/ti.1001.11.20.03

DO - 10.24874/ti.1001.11.20.03

M3 - 文章

AN - SCOPUS:85108861573

SN - 0354-8996

VL - 43

SP - 241

EP - 246

JO - Tribology in Industry

JF - Tribology in Industry

IS - 2

M1 - 1001

ER -

The mathematical model of motion trajectory of wear particle between textured surfaces

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this