Thermal Deformation in a Static Pressure Dry Gas Seal

Wei Bing Zhu; Sheng Ren Zhou; He Shun Wang

doi:10.4028/www.scientific.net/AMM.217-219.2406

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 217-219Thermal Deformation in a Static Pressure Dry Gas...

Thermal Deformation in a Static Pressure Dry Gas Seal

Abstract:

Based on the basic principles of heat transfer, the two-dimensional stable state cylindrical coordinate solid heat conduction differential equation having no inner heat source is established. Use the ANSYS software to establish the temperature field finite element analysis model of rotating and stationary rings and carry on the solution to the temperature field. The temperature distributing rules of rotating and stationary rings are obtained at the same time. According to thermo-elastic deformation theory, numerical analysis method and separation method are applied to resolve and analyze thermal-structural coupling deformation of rotating and stationary rings.

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Periodical:

Applied Mechanics and Materials (Volumes 217-219)

Pages:

2406-2409

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.217-219.2406

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Online since:

November 2012

Authors:

Wei Bing Zhu*, Sheng Ren Zhou, He Shun Wang

Keywords:

Finite Element Method (FEM), Static Pressure Dry Gas Seal, Temperature Field, Thermal Deformation

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References

[1] H. S. Wang: Research on working stablity of dry gas seal (Southwest Traffic University, Chengdu 2006), in Chinese.

Google Scholar

[2] S. Fujiwara, and T. Fuse: Advanced aerostatic dry gas seal, 16th International Conference on Fluid sealing, BHR Group 2000 Fluid Sealing (2000), pp.483-499.

Google Scholar

[3] T. A. Stolarski, and Y. Xue: Performance study of a back-depression mechanical dry gas seal, Proc Instn Mech Engrs, Part J Vol. 212 (1998), pp.279-290.

DOI: 10.1243/1350650981542092

Google Scholar

[4] F. Liu: The research of aerostatic gas seal (Xihua University, Chengdu 2010), in Chinese.

Google Scholar

[5] J. P. Yu: Research on characteristic of aerostatic gas lubricating mechanical seal (Kunming University of Science and Technology, Kunming 2008), in Chinese.

Google Scholar

[6] K. Tadashi, and F. Takuya: The hydrostatic gas noncontact seal, ASLE Transactions Vol. 29 (1985), pp.505-514.

Google Scholar

[7] S. R. Zhou, W. B. Zhu, H. S. Wang: Lubrication Engineering Vol. 11 (2010), pp.69-73, in Chinese.

Google Scholar

[8] L. Jia: Higher heat transfer theory (Higher Education Press, Beijing 2003), in Chinese.

Google Scholar

[9] W. B. Zhu, S. R. Zhou, and H. S. Wang: Journal of Xihua University (Natural Science Edition) Vol. 6 (2010), pp.1-3, in Chinese.

Google Scholar