Analysis of Helical Torsion Spring for Epicyclic Traction Drive

Geza Nemeth

doi:10.4028/www.scientific.net/SSP.261.408

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HomeSolid State PhenomenaSolid State Phenomena Vol. 261Analysis of Helical Torsion Spring for Epicyclic...

Analysis of Helical Torsion Spring for Epicyclic Traction Drive

Abstract:

Let us consider a simple epicyclic traction drive containing a sun wheel, an annular wheel, planetary wheels and a planet carrier. The annular wheel is substituted by a helical torsion spring with rectangular cross section. The spring has initial tensioning, tightened to the planetary wheels. When the number of coils is z and the number of planet wheels is N, there are zN piece of concentrated forces acting to the spring from inside towards outside. The main load of the spring is bending, it is computable along the spring wire. The bending moment is limited by the spring material and the cross section of spring. The radial forces acting to the spring are governed by the constraint of stress equality, the deflections of the contacting parts are determined by the radial (and slightly the tangential) forces. An initial shape of the spring that assures the proper operation of the drive after the assembly, is calculated by elementary mechanical calculation methods. The main goal is the developing of a traction drive in which the clamping force is proportional to the torque which should be transmitted, for the sake of the favourable life rating and the efficiency.

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Periodical:

Solid State Phenomena (Volume 261)

Pages:

408-415

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.261.408

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Online since:

August 2017

Authors:

Geza Nemeth*

Keywords:

Epicyclic Traction Drive, Helical Torsion Spring

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References

[1] E. Horvath, inventor, Otto Bock Orthopadische Industrie Besitz-Und Werwaltungs-KG, Assignee, Planetary Friction Drive, U.S. Patent 5, 046, 996, filed Jul. 18, 1989, and issued Sep. 10, (1991).

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[2] Y. Deyuan, G. Jingjing, Z. Xiaohong, New Symmetrically Loading Epicyclic Traction Drive Reducer (in Chinese). Journal of Bejing University of Astronautics, 1999. Vol. 25 Issue 2 p.229–231.

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[3] G. Németh, J. Péter, Á. Döbröczöni, N. Németh, A new type of epicyclic traction drive, Advances in Mechanical Engineering, 1: (1) pp.137-142. (2013).

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[4] G. Németh, J. Péter, Á. Döbröczöni, N. Németh, (2012) Helical Torsion Spring Improvement for Epicyclic Traction Drive in Gép, LXIII (12): pp.85-88.

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