高拱坝多效应量改进型D-S证据理论融合模型

针对目前高拱坝监测资料分析中单效应量分析方法存在的不足,将数据融合技术中的D-S证据理论引入到高拱坝多效应量融合建模之中,提出了一种适合于高拱坝D-S证据融合评价的新的融合系数运算公式,建立了基于改进型证据理论的高拱坝多效应量融合模型。工程实例分析表明,该方法合理、可行,并可降低高拱坝安全评价中的不确定性与未知性。     

薄壁桥台嵌岩桩基础斜桩与直桩设计方案的比较

结合莫桑比克Nampula—Cuamba道路升级改造项目第二标段Monapo桥基础桩基工程,采用Prokon2．5结构分析软件对薄壁桥台嵌岩斜桩和直桩在不同台高和不同桩长的受力和配筋情况分别进行计算分析,从而为设计中根据不同地层条件和不同台高选择合理的桩基形式提供依据。     

桥台地基附加竖向压应力通用计算公式

台后路堤及锥体将在桥台地基中产生附加竖向压应力,它是桥台设计中计算桥台不均匀沉降、桥台前移、桥台桩基侧压力和挠度的关键参数。根据有关力学原理,推导了任一宽度台后路基及锥体引起桥台地基附加竖向压应力的计算公式,解决了现有规范中计算桥台基底附加竖向压力方法只适用于单线铁路路基和查表内插易产生误差的缺点,并易于利用计算机编制程序进行计算。     

一种基于安全因子判据的坝肩裂隙岩体动力抗滑稳定分析方法

基于某混凝土拱坝,结合现行拱坝设计规范,研究提出了一种基于安全因子判据的坝肩岩体动力抗滑稳定安全度分析方法。该方法综合利用有限元和（刚体）极限平衡两种方法的优点,考虑了凝聚力和摩擦力是不同的抗力,其不确定性具有较大差异性,定义了抗滑稳定安全因子,据此来判别坝肩岩体的抗滑稳定安全度,安全因子随着凝聚力与摩擦力所占权重不同而变化,这种方法既考虑了坝肩岩体与坝体的联动作用,又能够反映拱坝体系真实的工作性态。通过某混凝土高拱坝工程实例,分析了坝肩裂隙岩体的抗震稳定性,结果表明,该方法具有较高的实用价值。     

渤海海域沙垒田凸起西北部奥陶系碳酸盐岩储层发育主控因素与分布预测

基于岩心、薄片观察以及同位素、稀土元素等分析资料,明确了渤海海域沙垒田凸起西北部奥陶系碳酸盐岩潜山储层岩性主要为白云岩,储集空间包括溶蚀孔、洞、缝,储层类型为裂缝-孔隙型,裂缝是沟通孔洞的重要通道。储层演化机制上,碳酸盐岩白云石化作用、岩溶作用和构造作用是储层发育的主控因素:白云石化作用是储层发育的基础,岩溶作用是储层发育的重要保障,构造作用是储层发育的关键。地震地质储层综合预测表明研究区西南部为风化壳岩溶储层发育的有利地区。     

Mechanism and countermeasures of preceding tunnel distortion induced by succeeding EPBS tunnelling in close proximity

Twin tunnels are frequently used to address the increasing transportation demands in large cities. To ensure the safety of twin tunnels in close proximity, it is often necessary to take protective measures that have not been well studied. Field monitoring was conducted for a project of twin earth pressure balance shield (EPBS) tunnels in typical soft ground. The preceding tunnel was reinforced by various measures, including trailer bracing, compensation grouting, artificial freezing and scaffold bracing. The entire deformation of the reinforced tunnel was recorded during the succeeding tunnelling process. A three dimensional finite-element method (FEM) model was established to simulate the entire process of twin EPBS tunnelling, particularly the reinforcement measures. The computed deformations of the reinforced tunnel were consistent with the measured data. Furthermore, the stress history and pore pressure of the surrounding soil were analysed to investigate the deformation mechanism of the tunnel. Both the measured and computed results indicate that although the face pressure of the succeeding tunnel was smaller than the earth pressure at rest, the preceding tunnel could still experience an inward horizontal convergence and a deflection away from the succeeding tunnel. These distortion modes were caused by the squeezing effect of the horizontal soil arch in front of the succeeding tunnel face. Finally, convergence and deflection indices were proposed to quantify and assess the effectiveness of the reinforcement measures. The trailer bracing, as an “in-tunnel” reinforcement technique, was found to be the most effective method for controlling tunnel convergence. However, artificial freezing as an “out-tunnel” reinforcement technique led to the largest reductions in tunnel deflection. A combination of both “in-tunnel” and “out-tunnel” reinforcements was recommended.     

整体桥高性能混凝土桩−土相互作用试验研究

高性能混凝土（高性能复合水泥基材料engineered cementitious composite,简称ECC与超高性能混凝土ultra-high performance concrete pile,简称UHPC）桩基具有良好的抗开裂性能和较高的承载能力,能较好地满足整体桥纵桥向变形。开展了砂土中高性能混凝土桩低周往复拟静力试验,得到了桩基的破坏特点、抗开裂能力以及极限承载力,分析了其桩身变形、桩侧土抗力以及桩身应变等分布规律,并与钢筋混凝土（RC）桩进行了比较。在此基础上,讨论了几种常用规范的适用性。试验结果表明,ECC、UHPC材料能有效减轻桩基的破坏程度、提高桩基的抗开裂能力以及水平承载力;相比RC桩基,高性能混凝土桩基的破坏位置更深,桩基的有效桩长更大,抗震性能更好;其中,ECC桩基的抗开裂能力最强,开裂荷载可达5.8 kN,开裂位移可达15 mm。试验结果还表明,高性能混凝土桩基的变形沿埋深方向不断的减小,埋深1.5 m以下位置基本为0;桩侧土抗力先增大后减小,桩底土抗力和变形量为0;桩身应变分布较为对称,且呈“橄榄”形,在埋深4D～6D（D为桩径）区间内桩身应变较大。分析计算表明,当桩顶位移在10 mm以内时,“m”法与API新规范法均能较好地计算高性能混凝土桩的桩身变形;当位移超过10 mm后,“m”法与实际数值相差较大。“m”法与API新规范法均不能较好地计算桩身弯矩,适用性不高;桩侧土抗力建议采用API新规范法。     

Study on Structure of Arched Longitudinal Beams of Deep-Water Wharf

High-pile and beam-slab quays have been widely used after several years development.They are mature enough to be one of the most important structural types of wharves in China coastal areas. In order to accommodate large tonnage vessels, wharves should be constructed in deep water gradually. However, conventional high-pileand beam-slab structures are hard to meet the requirements of large deep-water wharf.According to arch''s stresscharacteristics, a new type of wharf with catenary arched longitudinal beams is presented in this paper. The new wharf structure can make full use of arch''s overhead crossing and reinforced concrete compression resistance, improve the interval between transverse bents greatly, and decrease underwater construction quantity. Thus, the construction cost cab be reduced. Take the third phase project of the Yangshan Deep-water Port for example, comparative analysis on catenary arched longitudinal beams and conventional longitudinal beams has been made. The result shows that with the same wharf length and width, the same loads and same longitudinal beam moment, catenary arch structure can improve the interval between bents up to 28 m, decrease the number of piles and underwater construction quantity.     

多点激励下大跨度连续钢桁架柔性拱桥空间地震响应分析

基于多自由度空间结构体系地震响应分析的基本理论,利用ANSYS建立空间有限元模型,采用动力时程分析法分析某大跨度连续钢桁架柔性拱桥在一致和非一致激励作用不同地震工况下的空间地震响应。研究结果表明:非一致激励作用下,拱肋轴力、主桁弯矩峰值出现在拱脚和边墩附近;地震波组合输入较其单向输入拱脚轴力和面内弯矩最大分别可达1.28和8.32倍;非一致输入较一致激励作用拱脚轴力和面内弯矩分别可达2.5和8.4倍;地震波横向输入较纵向输入横向位移峰值比可达2.4倍,纵向输入较横向输入纵向位移峰值比可达2.6倍;结构的支座形式对结构构件地震响应结果也有一定影响;建议大跨度钢桁拱桥抗震设计应充分考虑地震波的空间和时间效应。     

Seismic analysis of a curved bridge considering deck‐abutment pounding interaction: an analytical investigation on the post‐impact response

Horizontal curved bridges are very common at intersections and at the changing angle of bridge alignment. Almost in every previous earthquake report, it can be seen that the columns of a curved segment experience torsional damage, and the curved decks are unseated from the abutment support. The main reason behind that phenomenon is the in‐plane deck rotation which results because of the complex dynamic coupling between two longitudinal directional vibrations. The curved decks are susceptible to deck rotation because in a curved segment, the centre of mass and the centre of stiffness generally lie outside the bridge deck and are not located at the same point. The pounding with the abutment often increases the rotational tendency of the deck. In this paper, a classical mechanics‐based approach is adopted to analytically estimate the deck rotation potential of curved bridge considering the deck‐abutment pounding interaction. The deck‐abutment pounding is modelled using non‐smooth techniques considering the Newton's impact law in the normal and Coulomb's friction in the tangential direction. Within the scope of this paper, a parametric study is performed to get the ideal combination of the column and bent arrangement and the gap distance. Copyright © 2016 John Wiley & Sons, Ltd.