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Influence of the Groove Width on the Aerostatic Dry Gas Seal

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Abstract:

Aerostatic dry gas seal has attracted more and more attention because of its advantages with low friction loss, low heat generation, large opening force and high gas film stiffness at low-speed operation situation. The influence of the radial groove width ratio, Bw, on the performance of the aerostatic dry gas seal has been investigated by an analytical method by solving the N-S equation in order to understand the performance of the seal further more. The results show that the effect of the radial groove width ratio, Bw, on the opening force and on the gas film stiffness is obvious. The opening force decreases with the radial groove width ratio, Bw, increasing at the same gas film thickness. The situation of the gas film stiffness is complex. When the gas film thickness is smaller than a critical value, about 6μm as to the example presented in this paper, the gas film stiffness increases with the Bw increasing, but the gas film stiffness decreases with the Bw increasing when thickness is larger than the critical value. With the increasing of Bw, the leakage to the atmosphere, Q2, increases, but the leakage to the process fluid, Q1, reduces.

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Periodical:

Applied Mechanics and Materials (Volumes 365-366)

Pages:

318-322

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.365-366.318

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Online since:

August 2013

Authors:

Heng Jie Xu, Peng Yun Song

Keywords:

Aerostatic, Dry Gas Seal, Groove, Mechanical Seal

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© 2013 Trans Tech Publications Ltd. All Rights Reserved

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