Disintegration of Oil Films Emerging From Radial Holes in a Rotating Cylinder

Author:

Glahn A.1,Blair M. F.1,Allard K. L.2,Busam S.3,Scha¨fer O.3,Wittig S.3

Affiliation:

1. United Technologies Research Center, 411 Silver Lane, M/S 129-19, East Hartford, CT 06108

2. Pratt & Whitney, 400 Main Street, East Hartford, CT 06108

3. Institut fu¨r Thermische Stro¨mungsmaschinen, Universita¨t Karlsruhe, Kaiserstr. 12, Karlsruhe 76128, Germany

Abstract

A fundamental study has been performed to examine the disintegration of oil films emerging from radial holes in a rotating hollow cylinder. The configuration investigated is an abstraction of one of the droplet generation sources in an aeroengine bearing compartment; similar configurations may also occur inside gearboxes. The paper aims to contribute to both the determination of directly applicable droplet characteristics and the establishment of a database that can be used for the development of droplet generation models. Similar to a prior paper on droplet generation processes at the rim of a rotating disk (Glahn, A. et al., 2000, “Droplet Generation by Disintegration of Oil Films at the Rim of a Rotating Disk,” ASME Paper No. 2000-GT-0279.) the near-term objectives of the study are (i) to determine droplet sizes under relevant aeroengine bearing compartment operating conditions, and (ii) to measure individual droplet diameter/velocity relationships. The long-term objective is to incorporate this information into advanced CFD-based design tools. Therefore, special emphasis has been directed towards a correlation of test results that enables determination of boundary conditions for a two-phase (oil droplets/air) simulation of lubrication system components. Based on the results of the present paper, droplet flow boundary conditions in terms of mean diameter, standard deviation of the diameter distribution, starting velocity, and flow angle are available for oil droplets generated by disintegration of oil films emerging from rotating radial holes and rotating disks.

Publisher

ASME International

Subject

Mechanical Engineering,Energy Engineering and Power Technology,Aerospace Engineering,Fuel Technology,Nuclear Energy and Engineering

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