Design of a Pneumatic Artificial Muscle for Powered Lower Limb Prostheses

Murillo, Jaime

January 2013

Ideal prostheses are defined as artificial limbs that would permit physically impaired individuals freedom of movement and independence rather than a life of disability and dependence. Current lower limb prostheses range from a single mechanical revolute joint to advanced microprocessor controlled mechanisms. Despite the advancement in technology and medicine, current lower limb prostheses are still lacking an actuation element, which prohibits patients from regaining their original mobility and improving their quality of life. This thesis aims to design and test a Pneumatic Artificial Muscle that would actuate lower limb prostheses. This would offer patients the ability to ascend and descend stairs as well as standing up from a sitting position. A comprehensive study of knee biomechanics is first accomplished to characterize the actuation requirement, and subsequently a Pneumatic Artificial Muscle design is proposed. A novel design of muscle end fixtures is presented which would allow the muscle to operate at a gage pressure surpassing 2.76 MPa (i.e. 400 psi) and yield a muscle force that is at least 3 times greater than that produced by any existing equivalent Pneumatic Artificial Muscle. Finally, the proposed Pneumatic Artificial Muscle is tested and validated to verify that it meets the size, weight, kinetic and kinematic requirements of human knee articulation.

PAM

Pneumatic Artificial Muscle

High power density actuator

Powered lower limb prostheses actuator

Actuators for robotics and automation

Biorobotics

Light and powerful actuator

Pneumatic actuator in aerospace industry

Powered prostheses

McKibben muscle

Lightweight actuator

Compliance

Actuator

Pneumatic

Legged robots

Rehabilitation

Gait

Exoskeleton

Locomotion

Aerospace actuator

Bipedal walking robot