Although hand prostheses with a cosmetic covering are commercially available for disabled people, the operating effort due to the stiffness of the mechanism is high. This results in high power requirements. This paper aims to present a new concept of mechanisms for the compensation of the nonlinear stiffness of hand prostheses by using statically balanced mechanisms with a nonlinear behavior. This concept was based on a combination of stability phases of snap-through buckling in bistable spring mechanisms to create the nonlinear balancing force. To demonstrate the efficiency of the concept, an optimized design for a case study of a child-sized hand prosthesis is also presented. A pattern search method was applied for the optimization. As a result, the calculated stiffness and, thereby, the operating effort was reduced by 96%. It can be concluded from the conceptual and numerical results that the presented concept provides a highly efficient solution to the discussed problem.
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Stiffness Compensation in Hand Prostheses With Cosmetic Coverings Using Statically Balanced Mechanisms
Ali Asadi Nikooyan,
Ali Asadi Nikooyan
Delft University of Technology
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Dick Plettenburg,
Dick Plettenburg
Delft University of Technology
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Just Herder
Just Herder
Delft University of Technology
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Nima Tolou
Delft University of Technology
Gerwin Smit
Delft University of Technology
Ali Asadi Nikooyan
Delft University of Technology
Dick Plettenburg
Delft University of Technology
Just Herder
Delft University of Technology
J. Med. Devices. Jun 2010, 4(2): 027527 (1 pages)
Published Online: August 10, 2010
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Published:
August 10, 2010
Citation
Tolou, N., Smit, G., Nikooyan, A. A., Plettenburg, D., and Herder, J. (August 10, 2010). "Stiffness Compensation in Hand Prostheses With Cosmetic Coverings Using Statically Balanced Mechanisms." ASME. J. Med. Devices. June 2010; 4(2): 027527. https://doi.org/10.1115/1.3443321
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