The Seal System in Aerostatic Journal Bearings for High Vacuum Chambers-Reference-Cited by-同舟云学术

The Seal System in Aerostatic Journal Bearings for High Vacuum Chambers

Published:2004-04-01 Issue:2 Volume:126 Page:310-315
ISSN:0742-4787
Container-title:Journal of Tribology
language:en
Short-container-title:

Author:

Yoshimoto S.¹,Yoshida Y.¹,Yagi K.¹

Affiliation:

1. Tokyo University of Science, Department of Mechanical Engineering, 1-3 Kagurazaka Shinjuku-ku, Tokyo 162-8601, Japan

Abstract

This paper investigates the performance of a seal system for an aerostatic journal bearing used in a high vacuum chamber. The seal system consists of axially spaced viscous seals and annular exhaust grooves that are located between the viscous seals. Each exhaust groove is coupled to a separate vacuum pump in order to achieve a vacuum chamber pressure of less than 10−3 Pa. The vacuum chamber pressure is affected by design parameters such as the number of viscous seal stages, seal length, seal gap, and exhaust tube conductance. The influence of these design parameters on the pressure distribution across seal regions and the vacuum chamber pressure are discussed theoretically. It is subsequently shown that an aerostatic journal bearing with three-stage seal system installed can obtain a reduction in the vacuum chamber pressure almost to the ultimate pressure of a vacuum pump, providing there is no leak or outgassing from materials.

Publisher

ASME International

Subject

Surfaces, Coatings and Films,Surfaces and Interfaces,Mechanical Engineering,Mechanics of Materials

Link

http://asmedigitalcollection.asme.org/tribology/article-pdf/126/2/310/5752344/310_1.pdf

Reference7 articles.

1. Pollock, J. D., 1988, “Linear Gas Bearing With Integral Vacuum Seal for Use in Serial Process Ion Implantation Equipment,” US Patent No. US 4,726,689.

2. Yokomatsu, T., 1988, “Static Pressure Bearing,” US Patent No. US 4,749,283.

3. Bisschops, T. H. J., Soemers, H. M. J. R., Vijfvinkel, J., Driessen, J. C., Renkens, M. M. J., and Bouwer, A. G., 2002, “Movable Support in a Vacuum Chamber and Its Application in Lithographic Projection Apparatus,” US Patent No. US 6,421,112 B1.

4. Gans, R. F. , 1985, “Lubrication Theory of Arbitrary Knudsen Number,” ASME J. Tribol., 107(3), p. 431431.

5. Fukui, S., and Kaneko, R., 1987, “Analysis of Ultra-Thin Gas Film Lubrication Based on Linearized Boltzmann Equation (1st Report, Derivation of Generalized Lubrication Equation),” Trans. JSME, 53(487), p. 829 829 (in Japanese).

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