Experimental Study of Assembly Stress Based on Manufacturing Characteristics

Jian Feng Chen; Xin Jin; Zhi Jing Zhang

doi:10.4028/www.scientific.net/AMR.820.141

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 820Experimental Study of Assembly Stress Based on...

Experimental Study of Assembly Stress Based on Manufacturing Characteristics

Abstract:

Assembly stress exists in mechanical equipment and instrumentation widely. Especially for precision mechanical systems, assembly stress may influence the system accuracy and performance. In this paper, taking form error and assembly force into account, the assembly stress and deformation were studied. By employing numerical simulation technology, the contact state of the part combining surface and additional deformational error were obtained, and an experiment was performed to verify the simulation calculation.

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Periodical:

Advanced Materials Research (Volume 820)

Pages:

141-146

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.820.141

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Online since:

September 2013

Authors:

Jian Feng Chen, Xin Jin, Zhi Jing Zhang

Keywords:

Assembly Stress, Manufacturing Characteristics, Non-Uniform Contact

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References

[1] Jin Xin, Zhang Zhijng. Manufacturing Characteristics Based Numerical Surface Model of Microminiatute Component [J]. Journal of Beijing Institute of Technology. 2005, 25(3): 189-193. In Chinese.

Google Scholar

[2] Lee K. and D.C. Gossard. A hierarchical data structure for representing assemblies: part 1. Computer-Aided Design, 1985, 17(1): 15-19.

DOI: 10.1016/0010-4485(85)90005-3

Google Scholar

[3] Clément A., A. Desrochers and A. Riviere. In: Theory and practice of 3-D tolerancing for assembly. 1991: École de technologie supérieure.

Google Scholar

[4] Komvopoulos K, Choi D H. Elastic finite element analysis of multi-asperity contacts[J]. Journal of tribology, 1992, 114(4): 823-831.

DOI: 10.1115/1.2920955

Google Scholar

[5] Zhang Guozhi, Zhang Zhijing. Study of Contact Prediction Method On Simulation of Random Rough Surface. Journal of System Simulation. 20 (22), 2008. 11. 6190-6192. In Chinese.

Google Scholar

[6] Jin Xin, Zhang Zhijing, Liu Kefei. Simulation model building and validation of microminiatute gear & shaft shrink fitting [J]. Machinery. 2004, 31(9): 1-3. In Chinese.

Google Scholar

[7] Zhang Guozhi, Zhang Zhijing, Zhao Ting, et al. Finite Element Simulation of Microminiature Clock Mechanism with Unturned Escapement Based on Manufacturing Characteristics [J]. Journal of Beijing Institute of Technology. 2006, 26(9): 781-784. In Chinese.

Google Scholar

[8] Liu Q, Wu W, Zhang Z, et al. A New Multilevel Contact Model between Rough Surfaces[C]. Digital Manufacturing and Automation (ICDMA), 2010 International Conference on. IEEE, 2010, 1: 71-74.

DOI: 10.1109/icdma.2010.190

Google Scholar