Prototyping a robotic dental testing simulator

Abstract A parallel robot based on the Stewart platform is being developed to simulate jaw motion and investigate its effect on jaw function to test the wearing away of dental components such as individual teeth, crowns, bridges, full set of dentures, and implant-supported over-dentures by controlli...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine Journal of engineering in medicine, 2007-05, Vol.221 (4), p.385-396
Main Authors: Alemzadeh, K, Hyde, R A, Gao, J
Format: Article
Language:English
Subjects:
Actuators
Algorithms
Assembly
Bite Force
CAD
Carrying capacity
Chewing
Circuits
Computer aided design
Computer aided testing
Computer programs
Computer simulation
Construction
Control algorithms
Dental bridges
Dental Stress Analysis - instrumentation
Dental Stress Analysis - methods
Dentures
Design analysis
Environments
Equipment Design
Equipment Failure Analysis
Humans
Integration
Jaw
Jaw - physiology
Kinematics
Load carrying capacity
Machining
Mandible
Mastication
Mastication - physiology
Mathematical models
Maxilla
Modulation
Numerical controls
Occlusion
Physical Stimulation - instrumentation
Physical Stimulation - methods
Pilot Projects
Product development
Rigidity
Robotics - instrumentation
Robotics - methods
Simplification
Skull
Software
Teeth
Transducers
Wire
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Summary:Abstract A parallel robot based on the Stewart platform is being developed to simulate jaw motion and investigate its effect on jaw function to test the wearing away of dental components such as individual teeth, crowns, bridges, full set of dentures, and implant-supported over-dentures by controlling chewing motion. The current paper only describes the comparison between an alternative configuration proposed by Xu and the Stewart platform configuration. The Stewart platform was chosen as an ideal structure for simulating human mastication as it is easily assembled, has high rigidity, high load-carrying capacity, and accurate positioning capability. The kinematics and singularities of the Stewart platform have been analysed and software developed to (a) test the control algorithms/strategy of muscle movement for the six degree of freedom of mastication cycle and (b) simulate and observe various design options to be able to make the best judgement in product development. The human replica skull has been analysed and reverse engineered with further simplification before integration with the Stewart platform computer-aided design (CAD) to develop the robotic dental testing simulator. Assembly modelling of the reproduced skull was critically analysed for good occlusion in CAD environment. A pulse-width modulation (PWM) circuit plus interface was built to control position and speed of the chosen actuators. A computer numerical control (CNC) machine and wire-electro-discharge machining (wire EDM) were used to manufacture the critical parts such as lower mandible, upper maxilla, and universal joints.
ISSN:0954-4119
2041-3033
DOI:10.1243/09544119JEIM145