Methodology for Obtaining Optimal Sleeve Friction and Friction Ratio Estimates from CPT Data

Cone penetration testing (CPT) is a cost effective and popular tool for geotechnical site characterization. CPT consists of pushing at a constant rate an electronic penetrometer into penetrable soils and recording cone bearing (qc), sleeve friction (fc) and dynamic pore pressure (u) with depth. The measured qc, fs and u values are utilized to estimate soil type and associated soil properties. A popular method to estimate soil type from CPT measurements is the Soil Behavior Type (SBT) chart. The SBT plots cone resistance vs friction ratio, Rf [where: Rf = (fs/qc)100%]. There are distortions in the CPT measurements which can result in erroneous SBT plots. Cone bearing measurements at a specific depth are blurred or averaged due to qc values being strongly influenced by soils within 10 to 30 cone diameters from the cone tip. The qcHMM algorithm was developed to address the qc blurring/averaging limitation. This paper describes the distortions which occur when obtaining sleeve friction measurements which can in association with qc blurring result in significant errors in the calculated Rf values. This paper outlines a novel and highly effective algorithm for obtaining accurate sleeve friction and friction ratio estimates. The fc optimal filter estimation technique is referred to as the OSFE-IFM algorithm. The mathematical details of the OSFE-IFM algorithm are outlined in this paper along with the results from a challenging test bed simulation. The test bed simulation demonstrates that the OSFE-IFM algorithm derives accurate estimates of sleeve friction from measured values. Optimal estimates of cone bearing and sleeve friction result in accurate Rf values and subsequent accurate estimates of soil behavior type.

Change of the mode of failure by interface friction and width-to-height ratio of coal specimens

Bumps in coal mines have been recognized as a major hazard for many years. These sudden and violent failures around mine openings have compromised safety, ventilation and access to mine workings.Previous studies showed that the violence of coal specimen failure depends on both the interface friction and width-to-height（W/H） ratio of coal specimen. The mode of failure for a uniaxially loaded coal specimen or a coal pillar is a combination of both shear failure along the interface and compressive failure in the coal. The shear failure along the interface triggered the compressive failure in coal. The compressive failure of a coal specimen or a coal pillar can be controlled by changing its W/H ratio. As the W/H ratio increases, the ultimate strength increases. Hence, with a proper combination of interface friction and the W/H ratio of pillar or coal specimen, the mode of failure will change from sudden violent failure which is brittle failure to non-violent failure which is ductile failure. The main objective of this paper is to determine at what W/H ratio and interface friction the mode of failure changes from violent to non-violent. In this research, coal specimens of W/H ratio ranging from 1 to 10 were uniaxially tested under two interface frictions of 0.1 and 0.25, and the results are presented and discussed.

Identification of Maximum Road Friction Coefficient and Optimal Slip Ratio Based on Road Type Recognition

The identification of maximum road friction coefficient and optimal slip ratio is crucial to vehicle dynamics and control.However,it is always not easy to identify the maximum road friction coefficient with high robustness and good adaptability to various vehicle operating conditions.The existing investigations on robust identification of maximum road friction coefficient are unsatisfactory.In this paper,an identification approach based on road type recognition is proposed for the robust identification of maximum road friction coefficient and optimal slip ratio.The instantaneous road friction coefficient is estimated through the recursive least square with a forgetting factor method based on the single wheel model,and the estimated road friction coefficient and slip ratio are grouped in a set of samples in a small time interval before the current time,which are updated with time progressing.The current road type is recognized by comparing the samples of the estimated road friction coefficient with the standard road friction coefficient of each typical road,and the minimum statistical error is used as the recognition principle to improve identification robustness.Once the road type is recognized,the maximum road friction coefficient and optimal slip ratio are determined.The numerical simulation tests are conducted on two typical road friction conditions（single-friction and joint-friction）by using CarSim software.The test results show that there is little identification error between the identified maximum road friction coefficient and the pre-set value in CarSim.The proposed identification method has good robustness performance to external disturbances and good adaptability to various vehicle operating conditions and road variations,and the identification results can be used for the adjustment of vehicle active safety control strategies.

The Relation between the Coefficient of Friction and Pressure Drop by Using the Different Reynolds Number in a Circular Tube

This study explains the relationship between friction coefficient and pressure change at a range of Reynolds (21,056 - 28,574) and (0 - 1.4) solid loading ratio of two-phase flow (gas-solid) inside a circular copper pipe by using laboratory apparatus and solving the equations mathematically. An experimentally relationship of friction coefficient and pressure change with Reynolds number and flow velocity obtained also the relationship between the Solid loading ratio with friction coefficient and pressure change has been done for a Limit range of Reynolds number. It was noticed that the increase in friction coefficient and pressure change for two-phase flow was occurred when solid loading ratio increased. Also the relationship between pressure change and Reynolds number was direct proportion while the relationship between friction coefficient and Reynolds Number was inversely related.

上软下硬复合地层盾构隧道开挖面稳定性分析

针对上软下硬复合地层条件下盾构隧道开挖面的稳定性问题,依托深惠城际2标实际工况,分析不同软硬比及土体参数对开挖面极限支护压力的影响。利用颗粒流数值模拟分析土体的失稳模式,借助极限分析法建立符合开挖面失稳轮廓的理论计算模型,将理论计算结果与既往文献及实际工程进行比较分析。结果表明:当隧道开挖面主动失稳时,变形主要集中在软土层,硬岩层的变形较少;随着开挖面软硬比的增大,隧道开挖面的极限支护压力也增大;开挖面的极限支护压力与隧道埋深比无关,与土体内摩擦角成反比。

抗拔桩承载能力影响因素与群桩变形规律试验研究

利用自主研发的桩基室内抗拔测试装置,结合数值模拟技术对抗拔桩的承载破坏过程及影响因素、群桩的协同工作特征展开了深入研究。结果表明:抗拔桩的承载破坏经历4个阶段,承载初期,桩顶侧摩阻力最先发挥作用,桩顶土体发生塑性破坏;随上拔荷载不断增大,桩体产生相对位移,桩周土体由于桩身侧摩阻力产生塑性破坏;当桩身轴力自桩顶传递至桩底时,桩身底端产生抗拔“吸附力”,并伴随局部土体塑性破坏;随着桩周土体塑性区的拓展、连通,抗拔桩承载能力达到极限;桩身长径比、桩-土界面摩擦因数、桩侧土体压力与其承载极限呈正相关关系,其中桩身长径比对桩端“吸附力”具有重要影响;群桩抗拔过程中,角桩侧摩阻力发挥最充分,桩身位移量最小,极限承载力最大,中心桩桩身位移最大,极限承载力最低;距径比影响抗拔桩的群桩效应,当距径比从2增大至8时,桩身侧摩阻力提高30%,将距径比8作为群桩工程的推荐值,6~10作为群桩距径比的推荐范围。

疏浚管道粗砂输送特性及最佳流态研究

在疏浚管道输送粗砂砾石等粗大颗粒时,由于粒径构成复杂、浓度和局部阻力波动较大等因素,容易造成输送效率低、淤积堵塞和施工操作困难等问题。为实现粗大颗粒物料的安全高效输送,以中值粒径0.82 mm的粗砂为研究对象,在不同浓度和流速下进行管道输送试验,对粗砂的流态、沿程阻力损失、临界流速和滑移比(输送效率)等特性进行研究,根据疏浚施工要求确定输送时的最佳流态及对应的流速区间,该流态具有不易堵塞、输送稳定性高、输送效率高和磨损较小等优点。泥沙输送特性研究成果及最佳流态确定方法对粗大颗粒的安全、稳定、高效输送具有一定的理论参考和实际应用价值。

井底压力下牙轮钻头浮动套轴承性能分析

为了探究井底压力下215.9 mm牙轮钻头浮动套轴承的平衡转速比、摩擦学性能、油膜压力分布随内外间隙比的变化规律,修正了考虑浮动套轴承实际井下环境压力和牙轮钻头密封压差的Reynolds边界条件,利用MATLAB中的PDE Toolbox对浮动套轴承Reynolds方程进行数值求解,分析内外间隙比对浮动套轴承平衡转速比、油膜压力及摩擦因数的影响规律,结果表明:当环境压力为60 MPa、密封压差为20 MPa时,随内外间隙比增加,浮动套平衡转速比呈现先增大后减小的趋势;以轴承的摩擦因数和油膜压力作为综合评价指标,钻头浮动套轴承内外间隙比为2.0时,轴承的摩擦因数较小,油膜压力较高,其轴承综合性能较优;而当浮动套轴承内外间隙比为2.0时,随着环境压力的升高,浮动套轴承的摩擦扭矩和摩擦因数增加,从而加剧轴承的磨损。该研究为牙轮钻头浮动套轴承的结构参数优化及性能提升提供了基础理论支撑。

汽车线控转向系统自适应变增益传动比设计

转向传动比是影响车辆主动安全性及操纵稳定性的重要因素。为改善线控转向车辆在低附着系数路面下的转向特性,设计了随路面附着系数和车速变化而自适应调整的变增益传动比。建立汽车二自由度模型,分析影响横摆角速度增益的因素,并通过仿真得到影响因素与增益之间的数据关系。采用Min-Max归一化方法,将影响因素与横摆角速度增益之间的数据进行预处理,构建神经网络数据集;设计蛇算法优化的BP神经网络(SO-BP),利用预处理后的数据集对SO-BP神经网络进行训练,由此动态获取变横摆角速度增益。采用变横摆角速度增益与侧向加速度增益按比例综合的策略,设计线控转向变增益传动比。利用Simulink-CarSim搭建线控转向整车模型,分别在高附着系数路面双移线工况和低附着系数路面角阶跃工况下,将所设计的变增益传动比与传统定增益传动比进行对比分析。结果表明:高附着系数路面条件下,两种传动比车辆的行驶轨迹误差保持在3%以内,而变增益传动比车辆的转向盘转角峰值降低了9.1%;低附着系数路面条件下,变增益传动比车辆在中低车速下的横摆角速度稳态值降低了22.3%、峰值降低了24.6%,中高车速下的横摆角速度稳态值降低了6.6%、峰值降低了10.8%。变增益传动比不仅可以提高车辆在高附着系数路面上的转向灵敏度,也改善了在低附着系数路面上行驶的安全性与操纵性。

磁控溅射时长对复合羟基磷灰石涂层性能的影响

采用射频磁控溅射技术在Ti-6Al-4V基体沉积复合羟基磷灰石(HA,Ca_(10)(PO_(4))_(6)(OH)_(2))涂层,研究掺杂Ti和TiN在不同HA溅射时长下对HA复合涂层微观结构、摩擦学性能、钙磷比(Ca/P)及电化学的影响。结果表明:复合HA涂层随着HA溅射时长增加,涂层表面的半球形颗粒状结晶体更明显,对细胞附着生长及生物相容性有重要影响;复合涂层主要由HA相、Ti相和TiN相组成,溅射时间越长的复合HA涂层物相更接近标准值,且涂层Ca/P随着溅射时间的增加逐渐接近标准值;摩擦系数随溅射时长的增加逐渐趋于稳定,涂层的摩擦磨损情况随溅射时间增加而逐渐减小;溅射时长最长的涂层获得了最低的腐蚀电流密度和最大的腐蚀电位。

摩擦阻尼器组合支座的隔震优化对比

为解决一种摩擦阻尼器组合隔震支座的有效性及计算方法的问题,研究了用于结构设计有限元建模的组合元件计算模型,包括水平向、竖向刚度和滞回模型。使用有限元软件SAP2000,对比研究了布置有该组合支座的优化隔震方案和传统橡胶支座的隔震优化方案在高宽比不同的高层框架剪力墙筒体结构的抗震性能。结果表明:与传统隔震支座方案相比,组合隔震支座隔震方案可适当延长结构自振周期,减小隔震层侧移,有效降低支座拉应力,提高支座的抗倾覆能力和支座耗能,还可有效降低上部结构的层间剪力及侧移等地震响应,证明组合隔震支座方案较传统隔震支座方案综合性收效明显。

不同溶洞条件下穿越溶洞桩基础竖向荷载传递机制

穿越溶洞桩基础竖向荷载传递机制是特殊岩溶发育地区桥梁基础设计的核心问题.依托新建沪渝蓉高速铁路马河特大桥24#号墩岩溶桥基工程,开展区域地层(上覆粉质黏土层,下部风化灰岩)中桩基础竖向受荷现场试验.结合有限元数值模拟方法,研究有无溶洞、不同溶洞直径和不同溶洞位置等因素对穿越溶洞桩基础竖向荷载传递机制的影响规律.研究结果表明:(1)相比于无溶洞条件,溶洞存在导致桩基竖向承载力降低,溶洞以上的桩侧摩阻力减小,溶洞以下的桩侧摩阻力增大,桩身压缩量增加;此外,溶洞存在降低了桩身侧阻的荷载分担比,有利于发挥端阻.(2)在不同地层中,溶洞直径变化对桩侧摩阻力的影响有所不同.下部岩层中桩侧摩阻力随着溶洞直径的增大而增大,而上覆土层中变化不明显;整体看来,桩侧摩阻力的荷载分担比随溶洞直径的增大而减小,端阻力占比随之增大.(3)随着溶洞深度的增大,溶洞以上岩层中桩侧摩阻力减小,溶洞以下在1倍溶洞直径范围内桩侧摩阻力增大,桩身压缩量和桩身荷载分配的变化不明显.

单室与四室井筒式地下连续墙竖向承载特性研究

以井筒式地下连续墙为研究对象,采用数值模拟的研究方法,应用弹性本构模型,考虑墙土界面的参数影响,对单室和四室井筒式地下连续墙基础的沉降特性、内外侧摩阻力、端阻力、土芯顶部反力及其荷载分担比进行分析和研究。研究表明:外摩阻力主要由墙身深度范围内的外侧下部土体提供,内摩阻力主要由土芯下部土体提供;外摩阻力自上而下发挥作用,而内摩阻力自下而上发挥作用。随着荷载的增加,单室井筒式地下连续墙的外侧摩阻力的荷载分担比逐渐减小,而端承反力、内侧摩阻力和土芯顶反力的荷载分担比都在增加,而四室井筒式地下连续墙的外侧摩阻力、墙端反力、土芯顶反力都在减小,仅有内摩阻力的荷载分担比在增加。

非金融企业宏观杠杆率波动与货币政策传导路径

文章基于2000—2020年中国非金融企业部门宏观杠杆率和上市公司数据,在识别数量型货币政策外生冲击的基础上,采用局部状态依赖投影等方法,从宏观、微观角度研究了企业债务负担对货币政策传导的影响。结果表明,当宏观杠杆率处于高杠杆期时,宽松的货币政策对国有企业投资的促进作用比民营企业更大,对实际GDP、实际投资的促进作用也更大,并且更容易引发通胀;相对于高杠杆企业的金融加速器效应,低杠杆企业投资的预期收益效应更大;异质性分析发现,规模较小、更年轻、现金持有更少的企业对货币政策冲击的反应更强烈。

大屯锡矿尾砂膏体环管管输数值模拟研究

膏体管输沿程阻力是影响管道设计与采场充填质量的关键因素之一,采用Fluent建立与实际环管实验系统一样的管道输送的几何模型,分析得到不同管线沿程阻力损失之间的关系以及膏体配比参数对沿程阻力损失的影响规律。研究表明:膏体在管道中弯管处的速度和压力都发生急剧的变化,弯管外侧压力和速度明显大于弯管内侧,有着明显的梯度。在水平管段速度和压力在管道径向上存在明显的梯度,呈结构流的特点,分为柱塞流动区和边界层区域。在膏体管道输送中管道内膏体的速度和压力均存在着边界效应,随着流速的增大,管输阻力增大;随着膏体质量浓度增加,沿程管道阻力损失变大;随着屈服应力与塑性黏度的增加,沿程阻力损失也增大,获得了不同物料组成、管道内径、管流流速下水平段膏体压力损失,为大屯锡矿最终输送泵、充填管道选型提供了依据。

考虑支点摩擦和试样长宽比影响的压实黏土SENB试样的I型断裂参数研究

利用有限元软件ABAQUS对不同长宽比条件下单边切槽梁(SENB)试样I型应力强度因子进行了数值模拟,探讨了支点摩擦作用对试样无量纲应力强度因子Y_(Ⅰ)及无量纲T应力T^(*)的影响规律。结果表明,试件长宽比增大会导致Y_(Ⅰ)和T^(*)的值逐渐增大,摩擦系数增大会导致Y_(Ⅰ)减小;长宽比较小的试样经支点摩擦作用后,T^(*)会减小并使断裂轨迹更加稳定。通过压实黏土I型断裂试验,对比了考虑和不考虑支点摩擦效应的试验结果,验证了数值模拟的准确性。

限量供油条件下氧化石墨烯的润滑增效

为了研究在限量供油条件下氧化石墨烯(GO)对润滑增效的影响,利用球-盘点接触油膜润滑测量系统对PAO10(聚α-烯烃)和添加质量分数0.03%GO的PAO10进行膜厚和摩擦因数研究,分析卷吸速度、供油量、滑滚比、载荷等对GO润滑性能的影响。结果表明:在供油量较少及低速工况下,加入GO后摩擦因数下降最明显,并且能在一定程度上缓解乏油状况;随着卷吸速度的增大,加入GO前后摩擦因数和膜厚差别减小;当卷吸速度一定时,随着滑滚比的增大,乏油宽度增大,乏油更严重;当滑滚比一定,加入GO后乏油程度得到一定程度的改善;GO的润滑增效随供油量的增加而变弱;随着滑滚比的增加,油膜受到的剪切应力增大,导致GO的润滑增效降低;相比于低载条件,在高载条件下GO的润滑增效更加明显。

采空区顶板垮落摩擦诱发瓦斯爆炸试验研究

大采高工作面采空区顶板垮落时岩体相互撞击摩擦产生火花已成为诱发采空区瓦斯爆炸事故的主要隐患。为研究砂岩摩擦速度、摩擦力、瓦斯体积分数、SiO_(2)含量等因素对砂岩摩擦诱发瓦斯爆炸的机制,采用岩石摩擦效应引燃瓦斯试验系统对各因素进行定量试验研究。结果表明:瓦斯体积分数为7.0%~11.5%时,砂岩摩擦诱发瓦斯爆炸时间随瓦斯体积分数增加先缩短后延长;砂岩摩擦高温热表面是诱发瓦斯爆炸的主要原因;摩擦诱发瓦斯爆炸分为砂岩摩擦面燃烧瓦斯与瓦斯爆炸扩散2个阶段;摩擦诱发瓦斯爆炸时间随摩擦力增大而缩短,随砂岩中SiO_(2)含量增大而缩短;摩擦低于最低临界速度不会诱发瓦斯爆炸,高于最低临界速度且低于最高临界速度时最大摩擦速度与摩擦诱发瓦斯爆炸时间呈负相关。

微生物加固粉土的强度特性及加固机理研究

针对华北地区广泛分布的黄河冲积粉土级配差、强度低的问题,采用微生物诱导碳酸钙沉淀(MICP)技术对其进行加固。通过三轴试验研究加固粉土的强度特性,通过微观结构测试分析其微观机理;结合宏观现象和微观机理揭示强度加固机理。结果表明:MICP加固后粉土的强度得到了大幅提升;其黏聚力和内摩擦角均随加固轮数、胶结液浓度的增加而增大,且增长速率呈现出先快后慢的趋势;在胶结液浓度为0.5 mol/L、加固两轮时加固效率更高。就微观结构而言,土样中的孔隙随胶结液浓度和加固轮数的增大而逐渐减少;土样截面的平均非孔隙面积比随加固轮数、胶结液浓度的增加而增大;黏聚力、内摩擦角与平均非孔隙面积比之间均符合先快后慢的双线性增加关系。黏聚力与内摩擦角提升原因在于MICP加固生成的碳酸钙通过粘结粉土颗粒,填充堵塞颗粒间孔隙,使平均非孔隙面积比增大,进而提升土体强度。

弹簧-坡面变摩擦阻尼器参数研究

本文是针对变摩擦阻尼器无系统研究方法及具体规范的支撑。通过理论推导得出单自由度体系在谐振激励下结构位移、耗能比计算公式并确定摩擦系数、坡面长度、坡度和碟簧刚度等为影响弹簧-坡面变摩擦阻尼器力学性能的重要参数,采用自编程序对弹簧-坡面变摩擦阻尼器进行参数分析,研究结果发现:(1)弹簧-坡面变摩擦阻尼器摩擦系数宜取0.5以上;(2)宜适当增加坡面长度且平面段长度宜小于结构屈服位移;(3)当弹簧-坡面变摩擦阻尼器耗能不足时,宜优先考虑增大坡度;(4)当增大坡度仍无法满足弹簧-坡面变摩擦阻尼器耗能需求时,可考虑增大碟簧刚度。研究结果为实际工程应用中弹簧-坡面变摩擦阻尼器参数确定提供参考。