Publication detail

Effect of Surface Velocity Directions on Elastohydrodynamic Film Shape

OMASTA, M. KŘUPKA, I. HARTL, M.

Original Title

Effect of Surface Velocity Directions on Elastohydrodynamic Film Shape

English Title

Effect of Surface Velocity Directions on Elastohydrodynamic Film Shape

Type

journal article in Web of Science

Language

en

Original Abstract

This article is focused on the effects of the angle between lubricant entrainment velocity and sliding velocity on elastohydrodynamic film thickness distribution. Thin-film colorimetric interferometry was used to evaluate the film thickness distribution in smooth glass–steel contacts to provide basic data on the effects of the slide–roll ratio and the direction of sliding with respect to entrainment velocity.

English abstract

This article is focused on the effects of the angle between lubricant entrainment velocity and sliding velocity on elastohydrodynamic film thickness distribution. Thin-film colorimetric interferometry was used to evaluate the film thickness distribution in smooth glass–steel contacts to provide basic data on the effects of the slide–roll ratio and the direction of sliding with respect to entrainment velocity.

Keywords

Elastohydrodynamic Lubrication; Velocity Direction; Rolling–Sliding

RIV year

2013

Released

27.02.2013

Publisher

Taylor & Francis

Location

USA

Pages from

301

Pages to

309

Pages count

9

Documents

BibTex


@article{BUT99252,
  author="Milan {Omasta} and Ivan {Křupka} and Martin {Hartl}",
  title="Effect of Surface Velocity Directions on Elastohydrodynamic Film Shape",
  annote="This article is focused on the effects of the angle between lubricant entrainment velocity and sliding velocity on elastohydrodynamic film thickness distribution. Thin-film colorimetric interferometry was used to evaluate the film thickness distribution in smooth glass–steel contacts to provide basic data on the effects of the slide–roll ratio and the direction of sliding with respect to entrainment velocity.",
  address="Taylor & Francis",
  chapter="99252",
  doi="10.1080/10402004.2012.750024",
  institution="Taylor & Francis",
  number="2",
  volume="56",
  year="2013",
  month="february",
  pages="301--309",
  publisher="Taylor & Francis",
  type="journal article in Web of Science"
}