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References (13)
-
(2006)
Process equipment sealing technology -
(2011)
Analysis of performance and interface structure of cylindrical film seal -
(2017)
Analysis on steady fluid dynamics of cylindrical gas seal by CFD -
Hidehiko Nakane, A. Maekawa, Eiji Akita, K. Akagi, T. Nakano, Shin Nishimoto, S. Hashimoto, T. Shinohara, H. Uehara (2004)
The Development of High-Performance Leaf SealsJournal of Engineering for Gas Turbines and Power-transactions of The Asme, 126
-
(2004)
Computational fluid dynamics analysis: principle and application of CFD software. Beijing -
Shen Xinmin (2013)
Numerical Calculation of Dynamic Coefficients for Gas Film Cylinder SealJournal of Mechanical Engineering
-
(2018)
Numerical analysis of CFD for flexible support cylindrical sealing -
(2016)
Numerical simulation and parameter optimization of seal property of bidirectional rotating cylindrical gas film -
(2001)
Prospect of aero engine power transmission system in the 21st century -
(2014)
Optimum design of the rotor of cylindrical gas seal based on the multivariate linear regression method -
(2007)
Design and analysis for spiral grooved cylindrical gas seal structural parameter -
(2016)
CFD numerical simulation of cylindrical gas film seal properties -
(2010)
Quasi - dynamic analysis of gas - film seal of flexible support floating ring cylindrical
- Publisher
- SAGE
- Copyright
- Copyright © 2022 by SAGE Publications Ltd
- ISSN
- 2633-366X
- eISSN
- 2633-366X
- DOI
- 10.1177/0963693519864373
- Publisher site
- See Article on Publisher Site
Abstract
Cylindrical gas film sealing technology is a new type of dry gas sealing technology. Compared with the face gas film sealing technology, the cylindrical gas film seal presents a strong floating property, which can reduce the vibration and thermal deformation of the rotor system. In this article, the effect of operating parameters such as speed, pressure difference and viscosity on the T-groove gas cylindrical film seal performance are studied in detail by the method of control variable in computational fluid dynamics software, and pressure distribution, gas film stiffness, leakage, leakage stiffness ratio and hydrodynamic force are analysed. Results show that with the increase of the rotational speed, static pressure, hydrodynamic force and film stiffness increase, but leakage decreases first and then increases. Furthermore, the results indicate that with the increase of pressure difference, the static pressure, leakage and hydrodynamic force increase. In addition, the simulations show that when the viscosity increases, the maximum pressure and film stiffness increase, but the leakage decreases. This indicates that as the rotational speed increases, the hydrodynamic effect and the amount of gas overflow in the axial direction increase, resulting in an increase of leakage. Lastly, the results also show that when the pressure difference increases, both the radial and axial gas flow rates increase, resulting in an increase in both the film stiffness and the leakage. With the increase of viscosity, the viscous shear force and fluid hydrodynamic force increase, resulting in the increase of the gas film stiffness. This study can provide a theoretical basis in industrial applications for setting the operating parameters and serving as a reference.
Journal
Advanced Composites Letters – SAGE
Published: Jul 18, 2019
Keywords: cylindrical gas film seal; T-groove; operating parameters; sealing performance; computational fluid dynamics