Objective: To investigate the stress distribution and fracture mechanism of proximal femur under impact loads. Methods : The image data of one male' s femur were collected by the Lightspeed multi-lay spiral comput...Objective: To investigate the stress distribution and fracture mechanism of proximal femur under impact loads. Methods : The image data of one male' s femur were collected by the Lightspeed multi-lay spiral computed tomography. A 3D finite element model of the femur was established by employing the finite element software ANSYS, which mainly concentrated on the effects of the directions of the impact loads arising from intense movements and the parenchyma on the hip joint as well as those of the femur material properties on the distribution of the Mises equivalent stress in the femur after impact. Results: The numerical results about the effects of the angle δ of the impact loads to the anterior direction and the angle γ of the impact loads to the femur shaft on the bone fracture were given. The angle δ had larger effect on the stress distribution than the angle γ, which mainly represented the fracture of the upper femur including the femoral neck fracture when the posterolateral femur was impacted. This result was consistent with the clinical one. The parenchyma on the hip joint has relatively large relaxation effect on the impact loads. Conclusions : A 3D finite element analysis model of the femoral hip joint under dynamic loads is successfully established by using the impact dynamic theory.展开更多
文摘Objective: To investigate the stress distribution and fracture mechanism of proximal femur under impact loads. Methods : The image data of one male' s femur were collected by the Lightspeed multi-lay spiral computed tomography. A 3D finite element model of the femur was established by employing the finite element software ANSYS, which mainly concentrated on the effects of the directions of the impact loads arising from intense movements and the parenchyma on the hip joint as well as those of the femur material properties on the distribution of the Mises equivalent stress in the femur after impact. Results: The numerical results about the effects of the angle δ of the impact loads to the anterior direction and the angle γ of the impact loads to the femur shaft on the bone fracture were given. The angle δ had larger effect on the stress distribution than the angle γ, which mainly represented the fracture of the upper femur including the femoral neck fracture when the posterolateral femur was impacted. This result was consistent with the clinical one. The parenchyma on the hip joint has relatively large relaxation effect on the impact loads. Conclusions : A 3D finite element analysis model of the femoral hip joint under dynamic loads is successfully established by using the impact dynamic theory.
