Maria J. Gerschutz

Characterisation of a phenomenological model for commercial pneumatic muscle actuators

This study focuses on the parameter characterisation of a three-element phenomenological model for commercially available pneumatic muscle actuators (PMAs). This model consists of a spring, damping and contractile element arranged in parallel. Data collected from static loading, contraction and relaxation experiments were fitted to theoretical solutions of the governing equation for the three-element model resulting in prediction profiles for the spring, damping and contractile force coefficient. For the spring coefficient, K N/mm, the following relationships were found: K = 32.7 − 0.0321P for 150 ≤ P ≤ 314 kPa and K = 17 + 0.0179P for 314 ≤ P ≤ 550 kPa. For the damping coefficient, B Ns/mm, the following relationship was found during contraction: B = 2.90 for 150 ≤ P ≤ 550 kPa. During relaxation, B = 1.57 for 150 ≤ P ≤ 372 kPa and B = 0.311 + 0.00338P for 372 ≤ P ≤ 550. The following relationship for the contractile force coefficient, F ce N, was also determined: F ce = 2.91P+44.6 for 150 ≤ P ≤ 550 kPa. The model was then validated by reasonably predicting the response of the PMA to a triangular wave input in pressure under a constant load on a dynamic test station.

A computational simulated control system for a high-force pneumatic muscle actuator: system definition and application as an augmented orthosis

High-force pneumatic muscle actuators (PMAs) are used for force assistance with minimal displacement applications. However, poor control due to dynamic nonlinearities has limited PMA applications. A simulated control system is developed consisting of: (1) a controller relating an input position angle to an output proportional pressure regulator voltage, (2) a phenomenological model of the PMA with an internal dynamic force loop (system time constant information), (3) a physical model of a human sit-to-stand task and (4) an external position angle feed-back loop. The results indicate that PMA assistance regarding the human sit-to-stand task is feasible within a specified PMA operational pressure range.

A Vacuum Suspension Measurement Tool for Use in Prosthetic Research and Clinical Outcomes: Validation and Analysis of Vacuum Pressure in a Prosthetic Socket

The use of vacuum suspension (VS) in the prosthetic field has increased dramatically. However, knowledge regarding the mechanics of VS, the loading responses on the soft tissue, the short-term effects on perfusion, and the long-term effects on the residual limb are limited. In addition, little is known about what level of vacuum should be considered sufficient. Currently, there are no tools available to monitor the vacuum in a socket, how it varies with time, or the actual patient usage. This article presents a tool, the LimbLogic VS Communicator (The Ohio Willow Wood Company, Mt. Sterling, OH), that allows these types of studies to be performed in a nonintrusive manner, with the intent of facilitating the understanding and appropriate usage of VS systems. In this article, the accuracy of the LimbLogic VS Communicator is verified to the same standards as the LimbLogic VS System (accuracy: ±1 in Hg [±3.39 kPa]). The average accuracy of the LimbLogic VS Communicator, which is dependent on the VS pressure setting, is determined to be ±0.5 in Hg (±1.69 kPa). In addition, a study on the distribution of vacuum levels in a socket is presented. This VS measurement tool may simplify many possible future experiments in the prosthetic field.

Pneumatic Muscle Actuator for Resistive Exercise in Microgravity: Test with a Leg Model

INTRODUCTION A proof-of-concept demonstration is described in which a DC servomotor (simulating the quadriceps of a human operator) rotated a pulley 90 degrees (simulating knee extension). A pneumatic muscle actuator (PMA) generated an opposing force (antagonist) to the rotating pulley. One application of such a device is for use in microgravity environments because the PMA is compact, simple, and of relatively small mass (283 g). In addition, the operator can set a computer-controlled force-level range in response to individual user changes in exercise conditioning over time. METHODS A PMA was used in this study and interacted with a DC servomotor. For each trial, the PMA contracted in response to internal pressure. An input voltage profile activated the DC servomotor, resulting in the following three phases: an isokinetic counterclockwise pulley rotation of 90 degrees over 5 s (Phase I), the position was held for 5 s (Phase II), and an isokinetic clockwise rotation of 90 degrees over 5 s (Phase III). Root mean square error (RMSE) values were used to evaluate the pulley rotation. RESULTS For Phase I, when the PMA pressures (in kPa) were 300, 450, and 575, the percent RMSE, respectively, were 5.24, 6.23, and 4.59. For Phase II, the percent RMSE were 2.81, 2.57, and 5.63, respectively. For Phase III, the percent RMSE were 5.69, 2.63, and 3.30, respectively. DISCUSSION This study presents a demonstration of a PMA device that can enhance exercise by providing a wide range of resistive loads.

Strength evaluation of prosthetic check sockets, copolymer sockets, and definitive laminated sockets.

A prosthesis encounters loading through forces and torques exerted by the person with amputation. International Organization for Standardization (ISO) standard 10328 was designed to test most lower-limb prosthetic components. However, this standard does not include prosthetic sockets. We measured static failure loads of prosthetic sockets using a modified ISO 10328 and then compared them with the criteria set by this standard for other components. Check socket (CS) strengths were influenced by thickness, material choice, and fabrication method. Copolymer socket (CP) strengths depended on thickness and fabrication methods. A majority of the CSs and all of the CPs failed to pass the ISO 10328 ductile loading criterion. In contrast, the strengths of definitive laminated sockets (DLs) were influenced more by construction material and technique. A majority of the DLs failed to pass the ISO 10328 brittle loading criterion. Analyzing prosthetic sockets from a variety of facilities demonstrated that socket performance varies considerably between and within facilities. The results from this article provide a foundation for understanding the quality of prosthetic sockets, some insight into possible routes for improving the current care delivered to patients, and a comparative basis for future technology.