静态和动态颗粒料RC筒仓侧压力

Kunpeng Guo, Changdong Zhou, Xiaoyang Zhang, L. Meng
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引用次数: 5

摘要

本文采用有限元法对钢筋混凝土筒仓在静、动两种工况下的材料侧压力进行了分析。在有限元软件ABAQUS中,混凝土材料采用混凝土损伤塑性模型进行建模,筒仓内储存材料采用欠塑性理论进行建模。在数值模型方面,模型筒仓壁和储料分别采用壳单元(S4R)和实体单元(C3D8)。利用ABAQUS提供的库仑摩擦模型和惩罚接触约束,模拟了筒仓壁与物料之间的相互作用。利用有限元法对数值计算结果与现有的实验数据进行了验证,得到了数值结果与实验数据较好的吻合。然后分别在静态和动态条件下对材料参数进行分析。通过分析可知,临界摩擦角、初始空隙比和最小空隙比对静侧压力的影响较为明显,而各材料参数对动侧压力的影响程度不同。此外,还分析了动态条件下筒仓壁弹塑性状态的差异。数值计算结果表明,筒仓壁进入塑性状态有助于提高动压。最后,讨论了沿筒壁不同高度的时程侧压力,分析结果表明,较大的加速度值对产生筒壁较高部分的最大侧压力起主要作用。
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Lateral pressure of RC silos with static and dynamic granular materials
This paper aims at analyzing material-induced lateral pressure of RC cylinder silo in both static and dynamic condition using the finite element method( FEM). In the finite element software ABAQUS,concrete material is modeled by concrete damaged plasticity model,and stored materials in silo is modeled by the hypoplastic theory.In terms of numerical model,shell elements( S4R) and solid elements( C3D8) are applied for model silo wall and stored materials respectively. The interaction between silo wall and stored materials is simulated by Coulomb friction model and penalty contact constrain provided by ABAQUS.The numerical results are verified with the existing experimental data that are designed to ensure the validation of such numerical model using FEM and it obtains good agreements between numerical results and experimental data. Then the material parameters are analyzed in both static and dynamic condition.According to the analysis,it is clear that critical friction angle,initial void ratio and minimum void ratio have an obvious effect on static lateral pressure while all the material parameters affect dynamic lateral pressure at different levels. In addition,differences of silo wall between elastic and plastic state are analyzed in dynamic condition. The numerical results show that it contributes to increasing dynamic pressure when silo wall enters into the plastic state. Finally,this paper discusses the time-history lateral pressure at different heights along silo wall,and analytical results indicate that larger acceleration values play main roles in producing the maximum lateral pressure at higher part of the silo wall.
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