Theoretic Analysis of the Effect of Carbon Dioxide Real Gas on the Performance of the T-Groove Dry Gas Seal

Xiao Peng Hu; Peng Yun Song

doi:10.4028/www.scientific.net/AMR.634-638.3815

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 634-638Theoretic Analysis of the Effect of Carbon Dioxide...

Theoretic Analysis of the Effect of Carbon Dioxide Real Gas on the Performance of the T-Groove Dry Gas Seal

Abstract:

Dry gas seals have widely used in many centrifugal compressors and other rotating machinery. The gas performance of the dry gas seal is generally regarded as an ideal gas when the gas seal is investigated, designed, and operated. However some real gases performance may be quite different from the ideal gas when the gas pressure is high. In this paper, the carbon dioxide (CO2) was taken as an example in some T-groove dry gas seal, and the virial equation of state, which expresses the effect of real gas, was used, and the finite difference method (FDM) was adopted to solve the Reynolds equation of gas lubrication. The effects of real gas on the opening force (Fo) and radial leakage (Q) of the T-groove gas seal had been obtained. The results show that the seal performance (Fo, Q) will be underestimated when the real carbon dioxide is considered as an ideal gas. In calculation conditions, Fo and Q were maximum underestimated 4.16% and 19.25% respectively when Po was 5MPa and ns was variable and the real carbon dioxide was considered as an ideal gas; Fo and Q were maximum underestimated 7.48%, and 29.25% respectively, when ns was 3000r/min and Po was variable and the real carbon dioxide was considered as an ideal gas.

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Periodical:

Advanced Materials Research (Volumes 634-638)

Pages:

3815-3820

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.634-638.3815

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Online since:

January 2013

Authors:

Xiao Peng Hu, Peng Yun Song

Keywords:

Dry Gas Seal, Finite Difference Method (FDM), Real Gas, T-Groove

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References

[1] Li Na, Zhu Weibing, Wang Heshun, etc. Research on Distribution Law of Steady –state Temperature for the Rotating ring of T-shape Groove Dry Seal [J].Hydraulic and Pneumatic,2009(5):46-49.

Google Scholar

[2] Zhang Xuan and Song Pengyun: Theoretical Analysis of the Operating Characteristics of T-groove Dry Gas Seal at the Slow Speed Conditions. Lubrication Engineering. Vol. 35, No 10 (2010) pp.49-54 (in Chinese)

Google Scholar

[3] Hu Wenji Chen Xiuqin: Numerical Simulation of Face How Field on T-shape Groove Dry Gas Seal Lubrication Engineering. Vol. 33, No 11 (2008) pp.20-23 (in Chinese)

Google Scholar

[4] Alessandro Vetere. A Simple Modification of the Pitzer Method to Predict Second virial Coefficients. The Canadian Journal of Chemical Engineering, Volume 85, February 2007:118-121

DOI: 10.1002/cjce.5450850112

Google Scholar

[5] Song Pengyun: The Effect of Real Gas on the performance of the Spiral Groove Dry Gas Seal. 21st International Conference on Fluid Sealing, Milton Keynes, UK: 30 November- 1 December 2011, Published by BHR Group, The Fluid Engineering Centre.

Google Scholar

[6] Wang Bing and Zhang Huiqiang: Numerical Analysis of a Spiral-groove Dry-gas Seal Considering Micro-scale Effects. Chinese Journal of Mechanical Engineer. Vol.24. (2011)

DOI: 10.3901/cjme.2011.01.146

Google Scholar

[7] Basu, P. Analysis of a Radial Groove Gas Face Seal .TRIBOLOGYTRANSATION.1992, 35(1):11-20

Google Scholar