Assessing manual wheelchair caster design for mobility in winter conditions

Berthelette, Michele

12 September 2016

Manual wheelchair users who live in cold climates are faced with daily difficulties related to personal independence and societal inclusion, as their assistive devices are unable to overcome the physical barriers created by snow. Packed snow on sidewalks creates a barrier for wheelchair users as the small caster wheels become embedded in the snow-pack, this leads to upper body fatigue as well as wheelchair tipping, and falling. The purpose of this thesis was to develop a method by which the best design could be determined of a group of four commercially available manual wheelchair casters. This method was developed based on the HAAT model of assistive technology design. It was confirmed that snow-packed surfaces, as well as increased inclines, had a significant detrimental effect on the recorded human factors determinants, as well as conventional engineering determinants. / October 2016

Manual wheelchair

Winter mobility

Wheelchair design

Wheelchair caster

Understanding and Modelling Manual Wheelchair Propulsion and Strength Characteristics in People with C5-C7 Tetraplegia

Hollingsworth, Laura Jean

January 2010

Spinal Cord Injuries (SCIs) are debilitating injuries where damage to the spinal cord causes a loss of mobility and feeling in muscles innervated below the injury point. Tetraplegia refers to an SCI in the cervical region of the spinal cord that impacts on the functionality of all four limbs. ‘Complete’ tetraplegia results in complete paralysis of the legs, partial or complete paralysis of the arms and trunk, and in the most severe cases, the neck. The independence of people living with tetraplegia is heavily dependent on assistive and mobility devices. Understanding the strength characteristics of people with tetraplegia is crucially important for the suitable and effective design of mobility and rehabilitative devices such as wheelchairs. A study using a stationary dynamometer and video capture measured kinetic and kinematic characteristics of wheelchair propulsion for 15 subjects with C5-C7 tetraplegia. This study differentiated between subjects with different injuries, at two different test resistances, and was more comprehensive than other reported studies on MWC propulsion. Some of the subjects in the study with C5-C6 injuries had no elbow extension capability, while others had undergone a deltoids-to-triceps tendon transfer procedure called TROIDS, which restores some elbow extension capability. No differences were found in any of the push phase metrics between those who had undergone the TROIDs procedure, and those who had not, suggesting that TROIDs provides no significant benefit for mobility. As expected, subjects with C7 tetraplegia recorded velocity and power outputs significantly higher than those for subjects with C5-C6 tetraplegia. To better understand the strength characteristics over the full range of motion in the sagittal plane, and thus potentially modify the design of mobility devices to better suit these characteristics, a novel method for gathering strength data in multiple directions and positions was developed. This method had advantages over other commonly used methods. In particular, it was inclusive of complex muscle and joint interactions that would otherwise be very difficult to build into a model. Sagittal horizontal push strength was measured using this method for 8 able bodied and 4 tetraplegic subjects. There were clear trends in the data from the able-bodied subjects, and a fourth order polynomial (R-squared = 0.8) was fitted to the data for modelling purposes. Data for the tetraplegic subjects varied significantly from the able-bodied data, but inter-individual variation was such that no model would provide a satisfactory fit to the data indicating a very high degree of patient-specific behaviour. One multi-directional data set, consisting 1584 measurements in the sagittal plane, was gathered for an able-bodied subject. The main trends in this measured data were successfully captured by a model consisting of twelve fourth-order polynomials. Building on these measurements, and employing a human model in the constraint modelling environment, SWORDS, this thesis develops a conceptual design tool for comparing the effectiveness of different hand force paths. Initial simulations using hypothetical hand paths indicated that the proposed method for predicting the direction of the applied force needs to be verified, and likely refined, for hand paths that differ significantly from the traditional wheelchair push-rim path. This proposed procedure has the potential to be a powerful tool for optimising and modifying the design of wheelchairs or human powered devices to utilise previously untapped abilities for any given population.

Spinal Cord Injuries

tetraplegia

wheelchair propulsion

wheelchair design

upper body strength

Development of dynamic seating system for high-tone extensor thrust

Patrangenaru, Vlad Petru

12 January 2006

High-tone extensor thrusts, or involuntary muscle contractions experienced by many children with cerebral palsy, can cause problems that are not addressed by current seating systems. This thesis is concerned with the development of a dynamic seating system to better accommodate individuals who exhibit high-tone extensor thrusts. The first part of the thesis is focused on obtaining a general understanding of extensor thrusts from a mechanical perspective. To achieve this goal, an analytical dynamic model of a human subject undergoing an extensor thrust on a rigid chair is created. This model is validated experimentally, and inferences about the nature of extensor thrusts are made from the simulation and experimental results. A Dynamic-Hingeback Seating System which allows the occupant to lean back during an uncontrolled extensor thrust is developed. This system is capable of maintaining seatback rigidity during an intentionally-induced episode, thereby enabling the occupant to communicate or interact with his/her environment. The design of this system is influenced by the results obtained from the rigid seat study, as well as by numerical simulation results gathered with a commercial dynamic simulation software package (Working Model 2D). The improved seatback performance is characterized through experimentation. Alternative dynamic seating systems are considered. The important features of each of these systems are identified, and the desired motion of the system occupant during an extensor thrust is verified through Working Model simulations.

Dynamic seating

Inverse dynamics

Extensor thrust

Wheelchair design

Wheelchairs Design and construction

Biomechanics

Muscle contraction