Feasibility study on a composite material construction technique for highly stressed components in reciprocal walking orthoses for paraplegic patients

Citation
Pj. Woollam et al., Feasibility study on a composite material construction technique for highly stressed components in reciprocal walking orthoses for paraplegic patients, P I MEC E H, 213(H4), 1999, pp. 355-360
Citations number
33
Categorie Soggetti
Mechanical Engineering
Journal title
PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART H-JOURNAL OF ENGINEERING IN MEDICINE
ISSN journal
09544119 → ACNP
Volume
213
Issue
H4
Year of publication
1999
Pages
355 - 360
Database
ISI
SICI code
0954-4119(1999)213:H4<355:FSOACM>2.0.ZU;2-C
Abstract
Reciprocal walking for thoracic level paraplegic patients using reciprocal walking orthoses has become a routine treatment option. Two general design options are currently deployed within an overall treatment regime. Research has shown that one has better walking efficiency but is cosmetically less acceptable to the patient. Design analysis and experimental data have shown that a major factor in improved walking efficiency is the lateral stiffnes s of the body brace section of the orthosis. This is the area where problem s of cosmesis in the more efficient orthosis are perceived because of the e mployment of metallic structures. The use of composite material structures to achieve shapes which are more c losely conforming to the patient is an attractive option. However the britt le nature of these materials makes it unlikely that the requirement for the ductile failure mode will be achieved from a straightforward moulding. A n ew construction technique has been devised which has the potential to provi de a safe failure mode with greater stiffness and lighter weight. This feas ibility study has been undertaken to demonstrate its potential so that furt her work can be justified which will provide sufficient evidence to support a patent application. The successful outcome of the study, in which stiffness was increased by 60 per cent with a weight reduction of 50 per cent and a failure mode compara ble with the original metal structure, suggests that further work will enab le the dilemma in the choice of orthosis to be resolved.