1) critical cyclic stress ratio
临界循环应力比
1.
Analysis on critical cyclic stress ratio and permanent deformation of composite foundation improved by cement-soil piles under cyclic loading;
循环荷载作用下水泥土桩复合地基的临界循环应力比和永久变形分析
2.
There exists critical cyclic stress ratio Sthwhen lightweight sand-EPS beads soil(LSES) is subjected to cyclic loading.
循环荷载下,砂土与EPS颗粒混合的轻质土(LSES)存在临界循环应力比Sth,将割线弹性模量衰减系数δ与循环次数的关系曲线能保持平缓的最大循环应力比定义为Sth,它是结构稳定与破坏两种状态的界限指标,根据动三轴试验结果,认为影响Sth的主要因素有围压、水泥掺量和EPS颗粒含量。
2) general critical cyclic stress ratio
广义临界循环应力比
3) supercritical pressure cycle
超临界压力循环
4) cyclic stress ratio
循环应力比
1.
In addition,in laboratory tests using dynamic triaxial test machine with stress controlled,definite dynamic stress frequency and different cyclic stress ratio were adopted to simulate the traffic load,and the axial strain,pore water pressure and axial strain softening under cyclic load were studied.
并且通过应力控制的室内动三轴试验,采用一定的动应力频率、不同的循环应力比来模拟交通荷载,研究了在循环荷载作用下,连盐高速公路饱和软粘土的轴向累计应变、孔隙水压力和轴向周期应变软化的变化规律。
2.
According to the dynamics triaxial test on the eolian sand,the strain property under cyclic loading is mainly affected by the compaction water content,cyclic stress ratio and ambient stress.
通过动三轴试验 ,得到了影响循环荷载下风积沙变形特性的主要因素为压实含水量、循环应力比和围
3.
Based on the test results, it concluded that the cyclic stress ratio and confining pressure are the mainly factors which affected the deformation property of the studied Ger ermu sand under cyclic loading, and the suggestion about the embankment construction is advanced.
通过对格尔木地区砾石砂的动三轴试验 ,得到了影响循环荷载作用下砾石砂变形特性的主要因素为循环应力比和围压 ,并根据试验结果对路基施工方法提出了建
5) critical cycle
临界循环
1.
So the co-efficiency of critical cycle is high than the traditional cycle.
通过构造一个逆劳伦兹循环来作为临界循环热泵的理想循环 ,以HFC12 5为例计算临界循环热泵的各部分不可逆损失 ,并与常规热泵进行了比较。
6) critical cyclic shear stress ratio
临界动剪应力比
1.
Discussion on computing effective reinforcement depth of soft soil foundation by dynamic compaction based on critical cyclic shear stress ratio;
临界动剪应力比法求解强夯加固软土地基有效加固深度的探讨
补充资料:临界分切应力
临界分切应力
eritical resolved shear stress
积为A/cos癸,滑移方向与拉伸轴的夹角为尺,如图所示。因此,F在此滑移面沿滑移方向的分切应力r为: r~Jeos职eos穴式中的cospcos只称为取向因子。对于面心立方晶格而言,有12个等同的滑移系统。晶体在拉伸过程中,究竟在哪一个系统上滑移取决于取向因子。取向因子最大的,优先滑移。当甲一90’时,即拉伸轴平行于滑移面时,或当穴一90a,即拉伸轴垂直于滑移面时,取向因子均为零,滑移不能进行。当沪和只处于同一平面且均为45。时,可以得到最大的取向因子和切应力。 l沾界分切应力定律的实质是:作用于单位长度位错线上促使位错滑移的力,决定于沿滑移面的切应力在滑移方向上的分量。当此切应力分量达到一定的临界值时,位错开始滑移。 l愉界分切应力而对于杂质、温度和形变速率相当敏感。材料的纯度愈高,即杂质愈少,而愈低;而少量杂质,不论在基体溶解与否,都会使而大幅度提高。低温时,肠随着温度的升高而显著降低,超过一定温度时变化不太显著,趋于稳定值。形变速率愈大,T0也愈高。(周浩孔庆平)临界分切应力eritical晶体中滑移要素的取向resolved shear stress外 力在晶体某一滑移面和滑 移方向上的分解切应力, 达到使晶体开始产生滑移 时的临界值。单晶体的拉 伸实验表明,一个滑移系 统只有当受到一定大小的 切应力时,它才能开始滑 移。这就是施密特 (Schlllid)的临界分切应 力定律。 设F为沿着拉伸轴方 向的拉力,A为试样的横 截面积,拉伸应力J一 F/A,滑移面法线与拉 伸轴的夹角为p,滑移面
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