In this study, Castigliano’s second theorem is applied to predict the force and moment system produced by orthodontics T-spring. The developed analytical formulas include all spring design parameters (material, geometrical shape and wire cross section, type and position of spring end mounting system, and direction and magnitude of the activation forces). The analytical results are compared with those obtained by nonlinear finite element formulation with nonlinear capabilities as a large deflection and showed an acceptable agreement for the current application. The reliability of the proposed model is successfully tested to predict the effect of some design parameters on spring stiffness. The developed analytic force system formulas are used as an objective function for solving a multi-objective optimization problem to produce the required force and moment at spring ends. A new genetic algorithm scheme is developed to obtain optimal spring design parameters according to design objectives and constraints. The results show that depending on the above methodology we can make a good estimation of the required design parameters of the T-spring for a specific application.
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December 2009
Research Papers
Multi-Objective Optimization for the Force System of Orthodontic Retraction Spring Using Genetic Algorithms
Bahaa I. Kazem
Bahaa I. Kazem
Department of Mechatronics Engineering, College of Engineering,
e-mail: bahaak@mit.edu
University of Baghdad
, Iraq
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Bahaa I. Kazem
Department of Mechatronics Engineering, College of Engineering,
University of Baghdad
, Iraqe-mail: bahaak@mit.edu
J. Med. Devices. Dec 2009, 3(4): 041006 (8 pages)
Published Online: November 20, 2009
Article history
Received:
May 11, 2009
Revised:
October 12, 2009
Online:
November 20, 2009
Published:
November 20, 2009
Citation
Kazem, B. I. (November 20, 2009). "Multi-Objective Optimization for the Force System of Orthodontic Retraction Spring Using Genetic Algorithms." ASME. J. Med. Devices. December 2009; 3(4): 041006. https://doi.org/10.1115/1.4000494
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