En este artículo se presenta un rehabilitador de hombro de movimiento pasivo continuo. El diseño del rehabilitador de hombro se basa en un sistema de mesa XY para ofrecer movimientos en el eje horizontal (X) y vertical (Y), así como, la combinación de ambos para proporcionar movimientos complejos, como lo son los arcos o circulares y que son requeridos en la rehabilitación de hombro. Se propone un control tipo PID para el seguimiento de trayectorias suaves, basadas en polinomios de Bezier. Se presentan resultados bajo el ambiente del software MSC Adams View en co-simulación con Simulink-MatLab que muestran el buen desempeño del controlador propuesto. Con la automatización de este rehabilitador se puede ofrecer movimientos personalizados a las necesidades de cada paciente, de tal manera que sean más naturales.

Palabra(s) Clave: Diseño mecatrónico, prototipo virtual, sistema de rehabilitación, movimiento pasivo continúo.

Abstract

In this paper a shoulder rehabilitator with continuous passive movement is presented. The design of the shoulder rehabilitation machine is based on an XY table system to offer movements on the horizontal (X) and vertical (Y) axis, as well as the combination of both to provide complex movements, such as arcs or circular and which are required in shoulder rehabilitation. A PID-type control is proposed for smooth trajectory tracking, based on Bezier polynomials. Simulation results under the MSC Adams View software environment in co-simulation with Simulink-MatLab showing the good performance of the proposed controller are presented. By automating this rehabilitator, personalized movement to the needs of each patient can be offered, so that more natural.

Keywords: Mechatronic design, virtual prototype, rehabilitation system, continuous passive motion.

Angulo Carrere, M.T., Álvarez Méndez, A., Fuentes Peñaranda, Y., Biomecánica clínica. Biomecánica de la Extremidad Superior. Exploración del Hombro. Reduca (Enfermería, Fisioterapia y Podología). Serie Biomecánica clínica. 3 (4): 104-123, 2011.

Ball, S. J.; Brown, I. E., Scott, S. H., MEDARM: a rehabilitation robot with 5DOF at the shoulder complex, 2007 IEEE/ASME international conference on advanced intelligent mechatronics, Zurich, pp. 1-6. 2007.

Dehez, B., Sapin, J., ShouldeRO, An alignment-free two-DOF rehabilitation robot for the shoulder complex, 2011 IEEE International Conference on Rehabilitation Robotics, Zurich, pp. 1-8. 2011.

Hogan, N., Krebs, H. I., Charnnarong, J., Srikrishna, P., Sharon, A., MIT-MANUS: a workstation for manual therapy and training. I, Proceedings IEEE International Workshop on Robot and Human Communication, Tokyo, Japan, pp. 161-165. 1992.

Lee, K., Park, J., Park, H., Compact design of a robotic device for shoulder rehabilitation, 2017 14th International Conference on Ubiquitous Robots and Ambient Intelligence (URAI), Jeju, pp. 679-682. 2017.

Niyetkaliyev, A. S., Hussain, S., Ghayesh, M. H., Alici, G., Review on Design and Control Aspects of Robotic Shoulder Rehabilitation Orthoses, in IEEE Transactions on Human-Machine Systems, vol. 47, no. 6, pp. 1134-1145, Dec. 2017.

O’Discoll S. W., Giori, N. J. Continuous Passive Motion (CPM): Theory and principles of applications. Journal of Rehabilitation Research and Development. Vol. 32(2). pp.179-188. 2000.

Park, J., Lee, K., Park, H., Development of low-end robot system for comprehensive shoulder rehabilitation, 2016 13th International Conference on Ubiquitous Robots and Ambient Intelligence (URAI), Xi'an, pp. 297-297. 2016.

Salter R. B., Field P. The effects of continuous compression on living articular cartilage. An experimental investigation, Journal of Bone and Joint Surgery; vol. 42(1). pp. 31-49. 1960.

Santana Camilo, J. A., Blanco-Ortega, A., Antúnez Leyva, E., Magadán Salazar, A., Gómez Becerra, F.A., Control numérico en una máquina de rehabilitación para tobillos. Pistas Educativas, No. 125, pp. 592-610. México. 2017.

Song W., Song, J., Improvement of upper extremity rehabilitation Robotic Exoskeleton, NREX, 2017 14th International Conference on Ubiquitous Robots and Ambient Intelligence (URAI), Jeju, pp. 580-582. 2017.

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