Design, Manufacture, and Testing of An Affordable External Bone Fixator Taylor Spatial Frame
Broken bones are injuries that often occur. Fracture is often caused by traffic accident. For some cases, compound fractures are quite complex requiring taylor spatial frame as bone fixation tool. Taylor spatial frame has 6 degrees of freedom. However, taylor spatial frame is hard to obtain in I...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/43692 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Broken bones are injuries that often occur. Fracture is often caused by traffic accident.
For some cases, compound fractures are quite complex requiring taylor spatial frame as bone
fixation tool. Taylor spatial frame has 6 degrees of freedom. However, taylor spatial frame
is hard to obtain in Indonesia and cost ineffective. Therefore, it is required to develop low
cost taylor spatial frame.
In design process, several design criteria were reviewed and then one design concept
was chosen. Taylor spatial frame consists of two rings and six struts. Static analysis using
numerical method on ANSYS was used to ensure whether the design is strong enough to
withstand applied load. Based on static analysis, the design continuously iterated to get the
optimum design.
Machining processes are used to manufacture taylor spatial frame from raw materials.
Some components directly use common component from the market and some going through
a little modification beforehand. Taylor spatial frame is made of AA7075 T6 and SS304.
Lastly, kinematic tests were performed to test whether taylor spatial frame could work
properly. Nylon rod was used to model broken bones and mounted on taylor spatial frame on
deformed condition. Bone deformation parameters were measured using marker tracking
form the anteroposterior, lateral, and axial view. The parameters are then used as software
input, and the output were length of each strut. The length of the struts was set to follow the
data from the software and then nylon was measured to show how big the error was. Taylor
spatial frame was successfully made at a cost of 2,778,800.00 IDR with 1 – 3 mm error.
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