Force analysis and kinematic optimization of a fluid valve driven by shape memory alloys

Authors

  • Todor Todorov Department of Theory of Mechanisms, Mechanical Engineering Faculty, Technical University of Sofia, Bulgaria
  • Rosen Mitrev Department of Logistics Engineering, Faculty of Industrial Technology, Technical University of Sofia, Bulgaria
  • Ivailo Penev Department of Theory of Mechanisms and Machines, Faculty of Industrial Technology, Technical University of Sofia, Bulgaria

DOI:

https://doi.org/10.31181/rme200101061t

Keywords:

Bistable mechanism Shape Memory Alloys Force analysis Parametric optimization

Abstract

The paper describes the design and performs a force analysis of a novel mechanism with bistable action, driven by Shape Memory Alloys (SMA). Based on this analysis, the parameters of the links are determined to minimize the energy costs. The kinematics of the mechanism is described in detail and the moments and forces of the elastic and SMA links acting in the mechanism are determined. The influence of the wire forces is determined by the static equilibrium conditions at the end positions and the driving capabilities. Based on the pre-calculated loads, the choice of materials and the design features, the influence of friction forces have been studied. Parametric optimization of the mechanism was performed using the obtained results.

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Published

2020-09-24

How to Cite

Todorov, T., Mitrev, R., & Penev, I. (2020). Force analysis and kinematic optimization of a fluid valve driven by shape memory alloys. Reports in Mechanical Engineering, 1(1), 61–76. https://doi.org/10.31181/rme200101061t