A temporal multiscale modelling applied to fatigue damage evolution in cortical bone is presented. Microdamage accumulation in cortical bone, ensued from daily activities, leads to impaired mechanical properties, in particular by reducing the bone stiffness and inducing fatigue. However, bone damage is also known as a stimulus to bone remodelling, whose aim is to repair and generate new bone, adapted to its environment. This biological process by removing fatigue damage seems essential to the skeleton lifetime. As daily activities induce high frequency cycles (about 10,000 cycles a day), identifying two-time scale is very fruitful: a fast one connected with the high frequency cyclic loading and a slow one related to a quasi-static loading. A scaling parameter is defined between the intrinsic time (bone lifetime of several years) and the high frequency loading (few seconds). An asymptotic approach allows to decouple the two scales and to take into account history effects (Guennouni and Aubry in CR Acad Sci Paris Ser II 20:1765–1767, 1986). The method is here applied to a simple case of fatigue damage and a real cortical bone microstructure. A significant reduction in the amount of computation time in addition to a small computational error between time homogenized and non homogenized models are obtained. This method seems thus to give new perspectives to assess fatigue damage and, with regard to bone, to give a better understanding of bone remodelling.
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机译:提出了一种适用于皮质骨疲劳损伤演化的时间多尺度模型。日常活动引起的皮质骨中的微损伤积累会导致机械性能受损,特别是通过降低骨骼刚度并引起疲劳。但是,骨骼损伤也被称为对骨骼重塑的刺激,骨骼修复的目的是修复并生成适应其环境的新骨骼。这种消除疲劳损伤的生物过程似乎对骨骼寿命至关重要。由于日常活动会诱发高频周期(每天约10,000个周期),因此确定两次刻度是非常有益的:快速的高频周期负载与准静态的负载相关。在固有时间(几年的骨骼寿命)和高频负载(几秒钟)之间定义了缩放参数。渐近方法允许将两个音阶解耦并考虑历史影响(Guennouni和Aubry在CR Acad Sci Paris Ser II 20:1765-1767,1986)。该方法在此适用于简单的疲劳损伤情况和真实的皮质骨微观结构。除了时间均质化模型与非均质化模型之间的小的计算误差外,还可以显着减少计算时间。因此,这种方法似乎为评估疲劳损伤提供了新的视角,并且就骨骼而言,可以更好地了解骨骼的重塑。
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