Design and development of an assistive walking system
This report aims to present the development of a powered orthosis, the Assistive Walking System (AWS). This system provides patients the muscular strength necessary for ambulation and provides lumbar and postural support required for proper balance during walking. Traditionally, patients...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2010
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/40032 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This report aims to present the development of a powered orthosis, the Assistive
Walking System (AWS). This system provides patients the muscular strength
necessary for ambulation and provides lumbar and postural support required for
proper balance during walking.
Traditionally, patients with walking disabilities would subscribe to a regimental
program at the gait rehabilitation clinic. In the recent years, gait rehabilitation via
robot technology has advanced to assist and complement the work by gait therapists.
Such robotic systems have moved away from the stationary gait trainers, such as the
Lokomat [1] and the AutoAmbulator [2] to portable devices like the ReWalkTM [3]
and the HAL [4] exoskeleton. These portable offerings allow patients to achieve a
more natural walking gait and undergo effective gait rehabilitation in an environment
closer to home at their own pace. The design and development of an assistive
walking system can provide instantaneous benefits and positive influences on the
patient’s quality of life.
This report will present the initial analysis of a patient volunteer’s condition and the
analysis of portable gait devices which are found to not suitable for paraplegics at all
stages of gait rehabilitation and does not provide postural and weight balance
support. An initial conceptual idea was developed through the findings and design
requirements. Suitable mechanical components are then selected and improved
through clinical trials embodiment design, leading to the development of the current
AWS prototype. The detailed design of the AWS can be found in this report.
Finally, a control and operation strategy for the AWS is proposed and the relevant
testing was conducted and found to be largely effective but more testing and
configuration must be done for the AWS operation after the prototype has been
fabricated and assembled. |
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