3) An intramedullary implant has the geometry as shown where the diameters are di-0.7mm and d2-1.65mm. The ends are inserted into the intramedullary space of a bone defect and the midie section f...
3) An intramedullary implant has the geometry as shown where the diameters are di-0.7mm and d2-1.65mm. The ends are inserted into the intramedullary space of a bone defect and the midie section fills the defect space. In this configuration, the bone places an axial compressive torce uniformly on the exposed end surfaces as shown (think carefully about the loading geometry you should use). The material is made from PEEK with E 3.6 GPa and will rupture under a compressive strain of 0.002. Determine the maximum axial load to which itmay be subjected. di Force is distributed evenly over this surface on both sides (stress)
3) An intramedullary implant has the geometry as shown where the diameters are di-0.7mm and d2-1.65mm. The ends are inserted into the intramedullary space of a bone defect and the midie section fills the defect space. In this configuration, the bone places an axial compressive torce uniformly on the exposed end surfaces as shown (think carefully about the loading geometry you should use). The material is made from PEEK with E 3.6 GPa and will rupture under a compressive strain of 0.002. Determine the maximum axial load to which itmay be subjected. di Force is distributed evenly over this surface on both sides (stress)