A pressure-adaptive seal is developed to meet the demands of quick assembling and disassembling for an individual protection equipment in aerospace. The analysis model, which reflects the main characteristics of the seal structure, is built based on the finite element method and the Roth’s theory of rubber seal, and verified by the prototype test. The influences of precompression ratio, hardness of the sealing ring rubber, and friction coefficient on the sealing performance are investigated by variable parameter method. Results show that the model can describe the essential characteristics of the pressure-adaptive seal structure, which has good follow-up to the cavity pressure to achieve the purpose of pressure self-adaptive. The leakage rate correlates negatively with the precompression ratio of the sealing ring and the hardness of the sealing ring material, while is positively related to the friction coefficient between the sealing ring and the sealing edge. The maximum contact stress on sealing surface has negative correlation with the precompression ratio of the sealing ring, and positive correlation with the hardness of the seal ring material. The damage risk of the sealing ring increases with the increases of the precompression ratio of sealing ring, hardness of sealing ring material, and friction coefficient.
LI Yuanfeng (李元丰), WANG Yiling (王怡灵), ZHANG Wanxin∗ (张万欣), LIU Jinian (刘冀念), MA Jialu (马加炉)
. Sealing Performance of Pressure-Adaptive Seal[J]. Journal of Shanghai Jiaotong University(Science), 2022
, 27(6)
: 747
-756
.
DOI: 10.1007/s12204-022-2510-x
[1] MCPHEE, JANCY C, JOHN B. Human health and performance risks of space exploration missions: Evidence reviewed by the NASA human research program [M]. Houston: NASA, 2010.
[2] ZHANG W X, LI T Q, SHANG K, et al. Developments and conceptions of pressure protection technology in spacesuit [J]. Space Medicine & Medical Engineering, 2018, 31(2): 121-130 (in Chinese).
[3] THOMSA K S, MCMANN H J. US spacesuits [M]. Chichester: Praxis Publishing, 2006.
[4] LUTZ C C, STUTESMAN H L, CARSON M A, et al. Apollo experience report: Development of the extravehicular mobility unit [R]. Houston: NASA, 1975.
[5] US NASA. Apollo operations handbook: Extravehicular mobility unit [R]. Houston: NASA, 1971.
[6] GRAZIOSI D, FERL J, SPLAWN K. An examination of spacesuit entry types and the effect on suit architechure [C]//Space 2004 Conference and Exhibit. San Diego: AIAA, 2004: 5969.
[7] BOYLE R, MITCHELL K, ALLTON C, et al. Suit�port feasibility - development and test of a suitport and space suit for human pressurized space suit donning tests [C]//42nd International Conference on Environmental Systems. San Diego: AIAA, 2012: 3631.
[8] HU D Y, WANG R Q, REN Q B, et al. Finite element analysis of O-ring seal structure [J]. Journal of Beijing University of Aeronautics and Astronautics, 2005, 31(2): 255-260 (in Chinese).
[9] LI S X, CAI J N, ZHANG Q X, et al. Performance analysis of O-ring used in compensatory confifiguration of mechanical seal [J]. Tribology, 2010, 30(3): 308-314 (in Chinese).
[10] KLAMECKI B E, SEFKOW R B, MACIEJEWSKI N J. Design of O-rings as an example of passive adaptive structures [C]//Smart Materials, Adaptive Structures and Intelligent Systems. Ellicott City: ASMEDC, 2008: 439-445.
[11] MACIEJEWSKI N J, SEFKOW R B, KLAMECKI B E. Composite structure design of O-rings using material behavior to decrease strain energy and permanent deformation [J]. Journal of Tribology, 2009, 131(4): 042202.
[12] ZHAO X Y, LIU Y, GAO Z, et al. Sealing performance of adaptive contacting mechanical seal [J]. Journal of Mechanical Engineering, 2015, 51(15): 9-19 (in Chinese).
[13] ROTH A. Vacuum technology [M]. Amsterdam: Elsevier, 1976.
[14] WANG B, JIAO G Q, LAI D F, et al. Applying Roth theory to calculating leak rate of rubber gasket of structure in vacuum at 23 °C, 70 °C and ? 70 °C [J]. Journal of Northwestern Polytechnical University, 2010, 28(1): 129-133 (in Chinese).
[15] LI B, LIU Y K. Calculation of leak rate for inner pressurized seal in vacuum with double rubber gaskets [J]. Vacuum and Cryogenics, 2000, 6(1): 48-53 (in Chinese).
[16] TASORA A, PRATI E, MARIN T. A method for the characterization of static elastomeric lip seal deformation [J]. Tribology International, 2013, 60: 119-126.
[17] ZHENG J P, SHEN M X, MENG X K, et al. Fretting characteristics of the rubber O-ring for a mechanical seal [J]. Journal of Shanghai Jiao Tong University, 2014, 48(6): 856-862 (in Chinese).
[18] GENT A N. Engineering with rubber: How to design rubber components [M]. 2nd ed. Cincinnati: Hanser Gardner Publications Inc., 2001.
[19] CAO J F, SHI Y P. Frequently asked question of ABAQUS finite element analysis [M]. Beijing: Machine
Press, 2009 (in Chinese).
[20] LI T Q. Development of Feitian spacesuit [J]. Manned Spaceflight, 2008(4): 8-18 (in Chinese).
[21] DA D A. Vacuum design manual [M]. 3rd ed. Beijing: National Defense Industry Press, 2004 (in Chinese).
[22] WEN S T, HUANG P, TIAN Y, et al. Principles of tribology [M]. 5th ed. Beijing: Tsinghua University Press, 2018 (in Chinese).
