The graphite dust, produced by friction of fuel pebbles, is a significant concern in potential accidents of HTGR because the graphite dust is closely coupled with radioactive fission product. The study of graphite particle-wall impaction is important to accurately estimate deposition rate of graphite dust. In this paper, both the spherical and non-spherical particle-wall impaction process are discussed based on FEM. By combining derived adhesion force with FEM. the results agree well with JKR model. The damping dissipation is employed to describe the energy loss, corresponding dimensionless damping coefficient is defined to establish the relation between damping coefficient and material properties. Meanwhile, the results of non-spherical particle impaction are also well predicted by dimensionless damping coefficient. It is also shown both adhesion force and damping dissipation are important at low incident velocity, while the effect of adhesion force is negligible and the dissipation is the dominant mechanism at high incident velocity. Besides, the contact area remains perfectly elastic deformation and never gets into failure when the incident velocity is lower than 20 m/s due to size effect. The results provide a possible approach for non-spherical particle-wall impaction, which can be combined with computational fluid dynamics (CFD) to estimate the deposition rate of graphite dust in HTGR.
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机译:由燃料小石的摩擦产生的石墨粉尘是高温气冷堆潜在事故的重要关注点,因为石墨粉尘与放射性裂变产物紧密结合。对石墨颗粒-壁碰撞的研究对于准确估计石墨粉尘的沉积速率具有重要意义。本文基于有限元方法对球形和非球形粒子壁碰撞过程进行了讨论。通过将导出的附着力与FEM相结合。结果与JKR模型非常吻合。利用阻尼耗散来描述能量损失,定义相应的无量纲阻尼系数以建立阻尼系数与材料性能之间的关系。同时,通过无量纲的阻尼系数也可以很好地预测非球形粒子撞击的结果。还表明,在低入射速度下,粘附力和阻尼耗散都很重要,而在高入射速度下,粘附力的影响可忽略不计,耗散是主要机理。此外,当入射速度低于20 m / s时,由于尺寸效应,接触区域保持完美的弹性变形,并且永不失效。结果为非球形粒子壁碰撞提供了一种可能的方法,该方法可以与计算流体动力学(CFD)结合以估计HTGR中石墨粉尘的沉积速率。
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