Lubrication for Moving Mechanical Systems Used in Spacecraft

Sathyan Krishnan

doi:10.4028/www.scientific.net/AMM.772.446

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 772Lubrication for Moving Mechanical Systems Used in...

Lubrication for Moving Mechanical Systems Used in Spacecraft

Abstract:

Spacecraft, irrespective of their mission’s purpose, contain a number of moving mechanical assemblies such as control moment gyros, momentum/ reaction wheels, gyroscopes, scanners, solar array drives, etc. Most problems encountered with these moving systems are related to tribology and, specifically, lubrication. Lubrication problems result from the loss of lubricant from the working zone by evaporation, surface migration, etc. Therefore, to ensure long-term uninterrupted performance of these systems, an efficient lubricant replenishment system is essential. This article describes various lubricating methods and lubrication systems used for the successful operation of some of these systems for the entire mission periods.

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Periodical:

Applied Mechanics and Materials (Volume 772)

Pages:

446-452

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.772.446

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Online since:

July 2015

Authors:

Sathyan Krishnan*

Keywords:

Centrifugal Lubricators, Lubrication, Momentum Wheels, Space Tribology

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* - Corresponding Author

References

[1] Fusaro RL. Tribology needs for future space and aeronautical systems. In: NASA technical memorandum 104525; December (1991).

Google Scholar

[2] Rowntree, R A., Tribological Design Criteria and Standards for Spacecraft Mechanisms. In Tribological Research and Design for Engineering Systems. D. Dowson et al. (Editors), Elsevier, pp.197-203. (2003).

DOI: 10.1016/s0167-8922(03)80132-3

Google Scholar

[3] Robertson, B., Stoneking, E. Satellite GN&C Anomaly Trends. NASA Goddard Space Flight Centre, AAS 03-071. http: /klabs. org/DEI/ lessons_learned/satellite_anomaly-. br. pdf.

Google Scholar

[4] Chronology of satellite failures. http: /sat-nd. com/failures/index. html.

Google Scholar

[5] Burt, R. R., Loffi, R. W. Failure Analysis of International Space Station Control Moment Gyro. Proceedings, 10th European Space Mechanisms and Tribology Symposium, (2003), pp-13 – 25.

Google Scholar

[6] Sathyan, K. Gopinath, K., Lee, S.H., Hsu, H.Y. Bearing Retainer Designs and Retainer Instability Failures in Spacecrafts. Tribology Transactions, 55: 503-511, (2012).

DOI: 10.1080/10402004.2012.675118

Google Scholar

[7] Sathyan, K., Long Term Lubrication of Momentum Wheels Used in Spacecrafts, MS Thesis in Applied Mechanics. September 2003, Indian Institute of Technology, Madras: India.

Google Scholar

[8] Sathyan,K., Hsu, H.Y., Lee, S.H., Gopinath K. Lubrication of Attitude Control Systems. In Advances in Spacecraft Technologies. Edited by: Dr Jason Hall, 54: 75-98, (2011).

Google Scholar

[9] Smith D W, Hooper FL. Positive lubrication system. In: Proceedings of the 24th aerospace mechanisms symposium. NASA conference publication, vol. 3062, 1990. p.243–58.

Google Scholar

[10] James G E. Positive commandable oiler for satellite bearing lubrication. In: Proceedings of the 11th aerospace mechanisms symposium. NASA CP-2038; 1977. p.87–95.

Google Scholar

[11] Sathyan,K., Hsu, H.Y., Lee, S.H., Gopinath K. Development of a Centrifugal Oil Lubricator for Long-Term Lubrication of Spacecraft Attitude Control Systems- Design and Theory. Tribology Transactions, 54: 770-778, (2011).

DOI: 10.1080/10402004.2011.599509

Google Scholar

[12] Hashimoto.F. Ooze Flow Bearing. United State Patent, Patent no: 6290397, September. 18, (2001).

Google Scholar

[13] Sathyan, K.; Gopinath, K.; Hsu, H. Y.; Lee S. H. (2010). Development of a positive lubrication system for space application. Tribology Online, 5, 1, 2010, 40-45. ISSN: 1881-2198.

DOI: 10.2474/trol.5.40

Google Scholar

[14] C.J. Fernando, A.B. Ettore. Development of a Dynamically Tuned Gyroscope DTG. Proceedings ABCM symposium in mechatronics, Vol-1, pp.470-478. (2004).

Google Scholar