| 该模型考虑了水泥石在不同围压下反映出来的脆性、脆塑性转换以及塑性特征,把水泥基材料普遍具有的损伤准则、剪切塑性准则和孔隙材料在高应力状态具有的孔隙塑性准则相互关联,并充分考虑了围压对材料力学特征的影响。本文中提出的多次方形式的剪切塑性屈服函数可以适应不同材料的屈服特征,比通常采用的线性和二次方形式的屈服函数适用性更广;同时,采用与围压应力状态相关联的破坏准则可以有效解释不同应力状态下的水泥石脆性-塑性转换特征。与试验结果比较表明,在不同围压情况该本构模型都能较好的反映水泥石主要力学特征。尽管模型参数较多,但是可以通过常规的静水压力试验和三轴试验获得;同时,该模型中采用了多次方形式的剪切塑性屈服准则,存在破坏面形式的多样性。剪切塑性、孔隙塑性以及损伤准则的共同作用使该本构模型具有广泛的适应性,适用于具有准脆性力学特征和较高孔隙率特征的水泥基材料和岩石材料。
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意见答复:
(1)参数过多,模型复杂。 4/5 首页 上一页 2 3 4 5 下一页 尾页 |
