压力型锚索力学机理现场试验研究

通过现场试验研究了岩质边坡中压力型锚索的受力和破坏机理。试验锚索采用130 mm孔径,6束标准钢绞线,符合实际工程的常用锚索规格。严格控制锚固段与非锚固段尺寸,设置了不同的锚固段长度用以研究锚索的抗拔力学性能。试验获得了岩质条件下足尺压力型锚索的荷载位移全曲线。用应变砖测试了锚固段注浆体在受力过程中的应变规律,测试结果与理论计算的结果吻合。对试验结果进行分析发现,在较软岩条件下,试验锚索的最佳锚固长度在2 m左右。压力型锚索的位移延性性能非常优秀,在锚索整体位移较大时还能维持较高的承载力,可以提供良好的破坏预警。根据实测的轴向应变发现,随着锚固长度的增加,应力传递长度也略有增加。提出压力型锚索的破坏要经历局部塑性,整体塑性两个阶段。     

预应力锚索在单桩竖向静载试验中的应用

在狭窄场地上进行大吨位单桩竖向静载试验时,需要解决的问题是在试验设备受场地限制无法增加的情况下如何提供足够大的反力荷载。根据此次试验场地地层中基岩埋藏丰富且深度较浅的情况,通过采用预应力锚索,进行加载反力装置设计,最终采用十字形加载反力装置,有效地解决了反力荷载不足的问题,从而为类似的试验提供了一种思路和选择。同时,通过对试验中出现的一些问题诸如锚固力、自由段变形等进行深入地分析和研究,提出了有关改进和完善反力装置现方案的建议。     

顺层岩质边坡预应力锚索抗震加固机制研究

将顺层岩质边坡的层面考虑为弱面,将其等效为等间距共线多节理的力学模型。预应力锚索加固边坡的锚固模型等效为平面有限宽度岩体节理问题。并将初始应力和地震荷载引起的附加动应力视为远场作用,锚固边坡的受力问题视为远场作用效果和节理面集中力作用效果的叠加。根据叠加原理计算地震荷载作用下裂纹端部应力强度因子,发现位于裂纹端部的预应力锚索能大幅度降低I型裂纹的应力强度因子。以应力强度因子作为岩体的压剪破坏判据解释顺层岩质边坡预应力锚索的抗震加固机制,能很好地解释汶川地震边坡破坏特点。     

新型锚索材料的试验研究

无锈蚀锚索是一种新型非金属锚索材料。通过对锚索索体、承压垫板、外锚具、附属零部件、张拉装置、锚索整体结构、锚索施工工艺的研究,以及两轮现场试验的结果表明,无锈蚀锚索以其独特的性能,在特殊锚固环境中锚固,比钢锚索更有效、更可靠,因此具有极大的市场潜力。     

基于感应电流测量的海峡水通量海底缆线观测系统设计

首先回顾了基于海底缆线的海峡水通量观测理论方法的发展历程,对基于电压测量的水通量反演方法进行了梳理,重点阐述了其中的关键观测要素和主要误差来源。为了提升系统可靠性、摒弃外界因素干扰,提出了一种基于感应电流测量的观测方法。对比传统方法,分析了本方法的优缺点,评估了基于本方法的海洋观测系统建设需求和可能性。最后应用本系统建立的一个理想海域——青岛胶州湾湾口各类海洋要素的典型取值范围,通过合理的特征尺度估算和量纲分析,估计了基于电流测量的观测系统中的各类设备的参数要求,其中关键测量器材——电流表至少应满足观测量程覆盖10~(–1)~10~1 m A,观测精度大于1μA,取样频率大于1/60 Hz。在电学测量仪器中,适应本系统要求的器材较普遍,可选择的测量仪器种类较丰富。     

基于三维GIS的地下电力管线管理系统的设计与实现

电力企业的输配电方式有架空线路和地下电力电缆及管线,它们负责为千家万户传送光明和能量,随着城市电缆化率的提升,地下电缆已变成电力公司重要的基础设施之一,是其赖以生存和发展的"生命线"。本文借助3S技术和传统测绘手段,采集地下电力管网基础数据,开发三维电力管线管理系统,对电缆数据录入建模、绘制各种专题图,实现地下电力管线从规划到建设、从运行到维护的全周期安全管理。     

滩海铺管敷缆船总体设计

针对胜利石油管理局“滩海铺管敷缆船”总体设计情况，分别从设计指标、基本功能、主要性能参数、关键技术和总体布置等几个方面进行了较详细的介绍。该装备具有性能指标先进、设备装备精良、工艺流程合理、安全可靠和注重环保的特点，适用于我国浅海油田及其它相同情况海域。     

On the motions of the underwater remotely operated vehicle with the umbilical cable effect

In this paper, a hydrodynamic model is developed to simulate the six degrees of freedom motions of the underwater remotely operated vehicle (ROV) including the umbilical cable effect. The corresponding hydrodynamic forces on the underwater vehicle are obtained by the planar motion mechanism test technique. With the relevant hydrodynamic coefficients, the 4th-order Runge–Kutta numerical method is then adopted to solve the equations of motions of the ROV and the configuration of the umbilical cable. The multi-step shooting method is also suggested to solve the two-end boundary-value problem on the umbilical cable with respect to a set of first-order ordinary differential equation system. All operation simulations for the ROV including forward moving, ascending, descending, sideward moving and turning motions can be analyzed, either with or without umbilical cable effect. The current effect is also taken into consideration. The present results reveal that the umbilical cable indeed significantly affects the motion of the ROV and should not be neglected in the simulation.     

Deep CTD Casts in the Challenger Deep,Mariana Trench

On 1 December 1992, CTD (conductivity-temperature-depth profiler) casts were made at three stations in a north-south section of the Challenger Deep to examine temperature and salinity profiles. The station in the Challenger Deep was located at 11°22.78′ N and 142°34.95′ E, and the CTD cast was made down to 11197 db or 10877 m, 7 m above the bottom by reeling out titanium cable of 10980 m length. The southern station was located at 11° 14.19′ N and 142°34.79′ E, 16.1 km from the central station, where water depth is 9012 m. CTD was lowered to 7014 db or 6872 m. The northern station was located at 11°31.47′ N and 142° 35.30′ E, 15.9 km from the central station, and CTD was lowered to 8536 db or 8336 m, 10 m above the bottom. Below the thermocline, potential temperature decreased monotonously down to 7300–7500 db beyond a sill depth between 5500 m and 6000 m, or between 5597 db and 6112 db, of the trench. Potential temperature increased from 7500 db to the bottom at a constant rate of 0.9 m°C/1000 db. Salinity increased down to 6020–6320 db, and then stayed almost constant down to around 9000 db. From 9500 db to the bottom, salinity increased up to 34.703 psu at 11197 db. Potential density referred to 8000 db increased monotonously down to about 6200 db, and it was almost constant from 6500 db to 9500 db. Potential density increased from 9500 db in accordance with the salinity increase. Geostrophic flows were calculated from the CTD data at three stations. Below an adopted reference level of 3000 db, the flow was westward in the north of Challenger Deep and eastward in the south, which suggests a cyclonic circulation over the Challenger Deep. Sound speed in Challenger Deep was estimated from the CTD data, and a relation among readout depth of the sonic depth recorder, true depth, and pressure was examined.     

电缆沉放深度对地震资料品质的影响

南海东北部陆坡深水区地质构造、地球物理特性复杂,进行地震资料采集时,如何获得中生界的高品质地震资料至关重要,而选择合适的地震采集参数是关键。7、10和12 m电缆沉放深度试验表明不论从频率分析,还是从子波特征、子波能量各方面均可发现7 m的沉放深度较优。