High shear stress induces atherosclerotic vulnerable plaque formation through angiogenesis

Rupture of atherosclerotic plaques causing thrombosis is the main cause of acute coronary syndrome and ischemic strokes.Inhibition of thrombosis is one of the important tasks developing biomedical materials such as intravascular stents and vascular grafts.Shear stress(SS)influences the formation and development of atherosclerosis.The current review focuses on the vulnerable plaques observed in the high shear stress(HSS)regions,which localizes at the proximal region of the plaque intruding into the lumen.The vascular outward remodelling occurs in the HSS region for vascular compensation and that angiogenesis is a critical factor for HSS which induces atherosclerotic vulnerable plaque formation.These results greatly challenge the established belief that low shear stress is important for expansive remodelling,which provides a new perspective for preventing the transition of stable plaques to high-risk atherosclerotic lesions.

Shear behavior of coarse aggregates for dam construction under varied stress paths

Coarse aggregates are the major infrastructure materials of concrete-faced rock-fill dams and are consolidated to bear upper and lateral loads. With the increase of dam height, high confining pressure and complex stress states complicate the shear behavfor of coarse aggregates, and thus impede the high dam＇s proper construction, operation and maintenance. An experimental program was conducted to study the shear behavior of dam coarse aggregates using a large-scale triaxial shear apparatus. Through triaxial shear tests, the strain-stress behaviors of aggregates were observed under constant confining pressures： 300 kPa, 600 kPa 900 kPa and 1200 kPa. Shear strengths and aggregate breakage characteristics associated with high pressure shear processes are discussed. Stress path tests were conducted to observe and analyze coarse aggregate response under complex stress states. In triaxial shear tests, it was found that peak deviator stresses increase along with confining pressures, whereas the peak principal stress ratios decrease as confining pressures increase With increasing confining pressures, the dilation decreases and the contraction eventually prevails. Initial strength parameters （Poisson＇s ratio and tangent modulus） show a nonlinear relationship with confining pressures when the pressures are relatively low. Shear strength parameters decrease with increasing confining pressures. The failure envelope lines are convex curves, with clear curvature under low confining pressures. Under moderate confining pressures, dilation is offset by particle breakage. Under high confining pressures, dilation disappears.

Friction Shear Stress on the Surface of Iron-Based Coating/HSS during Sliding Wear of Pin Disk

With the increasing demand for lightweight and lower fuel consumption and safety of automobile industry, lightweight materials of high strength steel (HSS) are more and more widely used. The hot stamping technology, which is determined by the inherent mechanical properties of high strength steel, makes molds prone to wear failure in the harsh service environments. In this paper, a finite element model is proposed for analyzing the value and distributions law of friction shear stress of contact surface of the pin disk. Through the simulation process of sliding wear, two kinds of different cladding materials of the pin specimens including H13 and Fe65, were experimented under three different loads by using the software ABAQUS. And then the pin-on- disk wear test at elevated temperature was conducted to verify the effectiveness of the simula-tion results. The results showed that the friction shear stress of pin with iron-based cladding and H13 steel was different under different loads, but the distribution was basically the same;the normal friction shear stress increased gradually along the direction of the pin movement, and the tangential shear stress increased gradually from the center of the pin to the outside of the circle;the value of the friction shear stress of the normal joints on the contact surface was periodically fluctuating in the whole dynamic analysis step, while it was basically stable in the tangential direction.

滑膜细胞及软骨细胞释放HMGB1流体力学阈值的研究

目的探究流体流动剪切力(fluid flow shear stress,FFSS)下,滑膜细胞及软骨细胞释放高迁移率族蛋白1(high⁃mobility group box 1,HMGB1)时流体力学的阈值;阐明异常机械力刺激下,滑膜细胞及软骨细胞破坏的先后顺序,为了解颞下颌关节骨关节炎的发病机制及病理研究提供实验基础。方法获得医院动物实验伦理委员会的审批,于SD大鼠膝关节获取滑膜组织及软骨组织块,消化培养获得滑膜细胞及软骨细胞,取3~4代滑膜细胞及软骨细胞,通过流体剪切力学装置对软骨及滑膜细胞施加FFSS,根据不同大小的FFSS值分组,分别采用1、3、5、10 dyn/cm^(2)的FFSS刺激滑膜细胞1 h,采用4、8、12、16 dyn/cm^(2)的FFSS刺激软骨细胞1 h,静息培养(0 dyn/cm^(2))作为对照组,观察细胞的形态学变化、免疫组化检测HMGB1及白细胞介素⁃1β(interleu⁃kin⁃1β,IL⁃1β)的细胞表达分布,ELISA检测上清液中HMGB1与IL⁃1β的水平;Western blot检测细胞HMGB1与IL⁃1β蛋白表达水平。结果随着FFSS负载的增大,滑膜细胞及软骨细胞逐渐肿胀,破裂,且细胞数量减少。随着FFSS负载的增大,HMGB1与IL⁃1β的表达由胞核逐渐转移至胞浆。在滑膜细胞中,与对照组相比,1、3、5、10 dyn/cm^(2)干预组中的HMGB1和IL⁃1β在上清液及细胞内的表达水平明显升高(P<0.01)。在软骨细胞中,与对照组相比,4、12、16 dyn/cm^(2) FFSS干预组中HMGB1在上清液中的表达水平增加(P<0.05),细胞HMGB1蛋白表达水平明显增加(P<0.01);而在8 dyn/cm^(2) FFSS干预组中HMGB1在上清液中的表达水平明显增加(P<0.01),但细胞HMGB1蛋白表达减少(P<0.01);与对照组相比,4、8、12、16 dyn/cm^(2) FFSS干预组中IL⁃1β在上清液中表达水平逐渐增加(P<0.01);除4 dyn/cm^(2)组外,随着FFSS负载增大,细胞中IL⁃1β的蛋白表达水平逐渐升高。结论滑膜细胞及软骨细胞随FFSS负载增大出现溶胀破裂,释放HMGB1流体力学阈值分别接近于1 dyn/cm^(2)和8 dyn/cm^(2);即在受到机械力刺激时,滑膜细胞先于软骨细胞损伤。

高应力状态下两河口堆石料蠕变特性试验研究

堆石料是土石坝的主要填筑材料,其蠕变特性直接决定着土石坝工后变形的大小。对两河口水电站砾石土心墙堆石坝的两种筑坝堆石料,开展室内大型三轴蠕变试验,结果表明:①在低应力水平下,试验侧向应变为正;在高应力水平下,试验侧向应变为负;②采用幂函数外推30 a对应的试验值,将其作为堆石料蠕变试验的极限应变,所得剩余蠕变与时间呈良好的幂函数关系;③最终剪切蠕变与剪应力呈倍数关系,轴向蠕变衰减幂指数与剪切蠕变衰减幂指数基本相等,最终轴向蠕变是最终剪切蠕变的1.5倍。最后,提出了更简洁的两参数幂函数蠕变模型,模型参数物理含义明确,便于在工程中使用。研究可为土石坝工后变形的初步估算提供参考。

浅谈氢含量对圆棒端部开裂的影响

宝武杰富意特钢有限公司中棒未过RH的200方45钢放量生产的圆棒,经过冷剪分段后打捆入库,在库内堆放2~3 d后,出现批量性45钢端部开裂现象。端部开裂的圆棒返修处理,修磨后的圆棒出现二次、三次开裂现象,端部裂纹深度0.1~5 mm,存在较大的质量管控风险。通过对45钢炼钢工艺分析,发现过RH的45钢在任何温度下剪切均不开裂,不过RH的45钢在200~300℃下剪切端部存在开裂缺陷;通过对比圆棒各规格剪切残留应力分布情况,发现大规格剪切后端部残留应力大,端部开裂率偏高,由此得出,圆棒端部开裂受残留氢量及残留应力影响。为了解决圆棒端部开裂问题,采用高温剪切方式对圆棒进行分段,高温剪切圆棒硬度小,可大幅度降低圆棒所受的剪切应力,且高温剪切后圆棒存在一个缓冷过程,能将残留氢去除,有效解决未过RH的45钢端部开裂问题。

含水量对膨胀土高填方渠堤土体剪切特性的影响研究

通过不同含水量下南水北调中线工程高填方渠堤的改性土、膨胀土和渠基土的直剪试验,研究含水量对3种土体剪应力-剪切位移以及抗剪强度的影响规律。结果表明:3种土体的基质吸力随着含水量增加而显著减小;当含水量较低时,剪应力-剪切位移曲线呈剪切软化型;而随含水量的增加,剪应力-剪切位移曲线转化为剪切硬化型。不同土体的抗剪强度随含水量增加均呈现先增大后减小的变化规律,且含水量达到土体的塑性含水量以后,抗剪强度降低较小。含水量对改性土、回填膨胀土和渠基土的黏聚力及内摩擦角存在着显著影响,黏聚力与含水量满足二次多项式关系;土体的内摩擦角随着土体含水量的增加呈现出非线性减小的变化规律,且渠堤改性土内摩擦角随含水量的降低幅度较渠堤膨胀土和渠基土大。

广州某超限高层住宅楼结构设计

某工程位于广州市黄埔区,为剪力墙结构超限高层住宅,高度为140.45m,主体结构为高度超限且存在凹凸不规则、扭转不规则等不规则项。为分析结构的抗震性能,通过进行合理的结构布置,采用多种软件进行结构分析,并针对结构细节进行专项设计,提出相应的构造加强措施。分析结果表明,结构各项指标均满足要求,能达到相应的性能目标要求,结构方案可行且安全;通过拉应力分析加强剪力墙边缘构件配筋,通过压弯分析保证一字型剪力墙承载力满足要求,通过顶板高差处理、全混凝土外墙设计保证地震力较好传递。

聚丙烯纤维混凝土纤维增强作用机理研究

为分析混凝土添加聚丙烯纤维后的应用效果,以水泥、粉煤灰等为材料,掺杂0.05%、0.10%、0.15%添加量的网状聚丙烯纤维,制备聚丙烯纤维混凝土试件。试验结果表明,添加聚丙烯纤维后混凝土的抗压、抗折、抗剪强度均得到不同程度的提升;添加0.10%纤维含量的试件在收缩时的裂缝面积、最大缝宽以及失水速率均低于普通混凝土试件;当试件经过拉伸试验后,添加聚丙烯纤维含量为0.10%的混凝土试件拉伸应力最高;在不同高温环境下,聚丙烯纤维混凝土试件的强度、质量损失率均低于普通混凝土试件,0.10%含量混凝土试件抗渗性最高。综合试验各方面分析可知,0.10%聚丙烯纤维含量的混凝土性能最佳。

An approach to measure infill matric suction of irregular infilled rock joints under constant normal stiffness shearing

Rock joints infilled with sediments can strongly influence the strength of rock mass. As infilled joints often exist under unsaturated condition, this study investigated the influence of matric suction of infill on the overall joint shear strength. A novel technique that allows direct measurement of matric suction of infill using high capacity tensiometers(HCTs) during direct shear of infilled joints under constant normal stiffness(CNS) is described. The CNS apparatus was modified to accommodate the HCT and the procedure is explained in detail. Joint specimens were simulated by gypsum plaster using threedimensional(3D) printed surface moulds, and filled with kaolin and sand mixture prepared at different water contents. Shear behaviours of both planar infilled joints and rough joints having joint roughness coefficients(JRCs) of 8-10 and 18-20 with the ratios of infill thickness to asperity height(t/a)equal to 0.5 were investigated. Matric suction shows predominantly unimodal behaviour during shearing of both planar and rough joints, which is closely associated with the variation of unloading rate and volumetric changes of the infill material. As expected, two-peak behaviour was observed for the rough joints and both peaks increased with the increase of infill matric suction. The results suggest that the contribution of matric suction of infill on the joint peak normalised shear stress is relatively independent of the joint roughness.

考虑孔周应力集中的摩擦型高强度螺栓抗滑移性能分析与设计方法研究

抗滑移性能是摩擦型高强度螺栓受剪连接的重要力学性能之一。为研究抗滑移性能的影响因素,设计并完成了单个高强度螺栓抗滑移性能试验和高强度螺栓群抗滑移性能试验,连接试件均为双面剪切且表面进行了抛丸处理。基于试验结果,建立了准确、可靠的有限元验证模型,据此对高强度螺栓受剪连接进行了参数分析,主要研究参数包括:螺栓预紧次序、连接板件厚度、垂直于内力方向的螺栓间距与边距以及顺内力方向的螺栓间距与边距。分析结果表明:连接板件最危险截面的塑性区分布对摩擦型高强度螺栓的抗滑移性能有着显著影响,设计时应考虑孔周应力集中现象对抗滑移承载力的折减;不同的截面受力情况对应的孔周应力集中系数存在明显差异。通过计算分析给出了螺栓抗滑移承载力折减系数建议值。相关研究成果可为摩擦型高强度螺栓受剪连接的设计提供改进思路。

用高阶剪切理论研究层合圆管弯曲时力学特性

采用高阶剪切理论研究了层合圆管弯曲时的力学行为,建立了层合圆管弯曲微分方程,推导了外荷载作用下层合圆管的挠曲线方程及正应力、剪应力公式。有关算例证明,该方法计算精度很高。计算分析表明,剪切变形对层合圆管弯曲有较大影响,实际工程中层合圆管的设计不能忽略剪切变形的影响。

高剪跨比榫卯连接装配整体式剪力墙受力性能数值分析

采用ABAQUS建立了高剪跨比榫卯剪力墙的精细化数值分析模型,对比了高剪跨比榫卯剪力墙试验结果与有限元模拟结果,从水平力-位移骨架曲线和墙体破坏形态两方面进行了分析。结果表明:采用库仑-摩擦模型能够准确计算高剪跨比榫卯剪力墙中新旧混凝土结合面间的相互作用,且有限元模拟骨架曲线与试验结果吻合较好,模型破坏特征与试验现象基本一致,可用于参数分析研究。

约束应力下UHPC直剪性能试验及有限元验证

通过使用3个“Z”型推出试件和有限元模拟来研究超高性能混凝土(UHPC)的直接剪切行为。使用约束应力作为测试变量,对剪切行为的荷载-相对滑移曲线、初裂强度、直接剪切强度、破坏模式等进行了试验和有限元模拟验证。试验结果表明:约束应力为0、4、7MPa的UHPC,其直剪强度分别为19.17、25.21、28.46MPa。用模拟对比试验的极限剪切强度,两者比值的平均值为0.981,标准差为0.018,模拟结果非常吻合。由于约束应力的作用,UHPC的剪切刚度、剪切滑移量及残余承载能力会相应增大,但约束应力的增大对残余承载能力的提升并不明显,这与失效时释放的能量有关。

高剪切应力诱导引发马来酸酐官能化三元乙丙橡胶

在熔融挤出过程中,采用提高双螺杆挤出机螺杆转速所产生的高剪切应力诱导引发的方法及添加引发剂与提高螺杆转速的复合引发方法,研究了三元乙丙橡胶(EPDM)与马来酸酐(MAH)的官能化反应。结果表明,双螺杆挤出机的高螺杆转速所产生的高剪切应力作用可诱导EPDM的断链反应,引起官能化产物黏均相对分子质量的明显减小及接枝率与熔体流动速率的明显增大;在适量过氧化物类引发剂存在的条件下,此种高剪切应力作用可抑制EPDM官能化过程中的交联副反应,使产物的凝胶含量明显下降,接枝率及熔体流动速率明显增大;此种官能化反应过程易于控制,可制得接枝率0.80%～1.13%、熔体流动速率0.11～0.28g/min及凝胶质量分数不大于1.0%的MAH官能化EPDM。

层流状态下高、低切应力对动脉重构及血管细胞粘附分子-1表达的影响

目的制备小鼠腹主动脉狭窄模型,探讨近似层流状态下高、低切应力对动脉重构及VCAM-1表达的影响。方法 20只小鼠随机平均分为狭窄1 d组、7 d组、14 d组和假手术对照组,用动脉银夹建立腹主动脉局部狭窄模型,超声检测狭窄近心端和狭窄处血流动力学参数,计算切应力值;血管标本行HE染色和内皮血管细胞粘附分子-1(VCAM-1)免疫组织化学染色,定量分析动脉病理结构的改变及内皮VCAM-1表达的强度。结果狭窄动脉近心端和狭窄处分别形成低、高切应力血流区,与对照组比较,随着作用时间的增加,狭窄近心端动脉内中膜逐渐增厚、内皮VCAM-1表达逐渐增强,而狭窄处动脉无明显结构改变及内皮VCAM-1表达。结论血流动力学改变,尤其是低切应力可较早引起动脉重构,可能通过内皮VCAM-1的介导作用导致动脉粥样硬化的发生、发展,而高切应力则可能有抗动脉粥样硬化作用。

动脉粥样硬化病变在颈总动脉分叉处分布特征

为探讨动脉粥样硬化的始动机理,对58例尸体颈动脉分叉标本通过大体及辅以苏丹Ⅲ、Ⅳ染色后观察,采用Mitchell点计数法,以动脉粥样硬化病损频率、面积及粥样化指数为参数得到结论是颈动脉叉处动脉粥样硬化病损以分叉处内、后侧壁高切应力区为好发部位,文内并对切应力作用进行了讨论.

轮胎胶应力诱导脱硫及共混丁苯橡胶力学性能

采用在熔融挤出过程中提高双螺杆挤出机螺杆转速的高剪切应力诱导方法,研究了双螺杆挤出机的螺杆转速和挤出反应温度对脱硫轮胎胶共混物(DGTR-EPDM)凝胶含量、溶液特性黏数和溶胶红外吸收光谱的影响.研究了脱硫工艺条件对丁苯橡胶-脱硫轮胎胶共混物(SBR-DGTR-EPDM)再硫化共混材料力学性能的影响.实验结果表明:双螺杆挤出机的高剪切应力作用,可诱发废旧轮胎胶粒(GTR)中交联网络的断链反应和氧化降解作用,引起脱硫共混物(DGTR-EPDM)中凝胶含量的下降、溶液特性黏数的减小和溶胶分子链中含氧基团和亚磺酸酯基团的明显增加.挤出机螺杆转速越快,挤出反应温度越高,其所得SBR-DGTR-EPDM再硫化共混材料中未脱硫凝胶颗粒尺寸即越小.在最佳脱硫反应条件下,所得DGTR-EPDM-SBR再硫化共混材料的拉伸强度和断裂伸长率分别达到19.5 MPa和400%.

简谐运动膜分离过程及其强化机理

提出了一种新型的膜分离强化方式,即通过膜自身做简谐运动来达到以高剪切方式强化膜分离过程的目的.在层流状态下简化纳维-斯托克斯方程并推导出该强化方式所产生的流场及压力场的解析式;通过对流场分析,论证了该强化方式的膜运动的角速度和膜表面受到的黏性剪应力之间具有不同步性,该方式可以产生优异的自净性能,使强化能的消耗具有空间上的针对性;论证了该强化方式产生的流场具有不稳定性,容易转化为湍流;通过对压力场的分析,论证了该强化方式可产生脉冲性.

高应力下剪切速率对砂土抗剪强度影响研究

应用DRS-1型高压直剪仪,进行了16组法向应力水平、5种剪切速率条件下福建标准砂的抗剪强度试验,试验结果表明,高应力下砂土的抗剪强度受法向应力和剪切速率的共同影响。法向应力和剪切速率通过影响颗粒破碎和颗粒重排列程度等试样的细观参数,决定了砂土宏观上抗剪强度的发挥。当法向应力较小时,砂土抗剪强度与剪切速率基本无关;但是当法向应力较大时,较快剪切速率条件下的砂土抗剪强度变小,且其摩尔强度包线出现了"下弯-上扬"循环波动,因此不可以忽略剪切速率对砂土抗剪强度的影响。