Research on Transmission Line Tower Tilting and Foundation State Monitoring Technology Based onMulti-Sensor Cooperative Detection and Correction

The transmission line tower will be affected by bad weather and artificial subsidence caused by the foundation and other factors in the power transmission.The tower’s tilt and severe deformation will cause the building to collapse.Many small changes caused the tower’s collapse,but the early staff often could not intuitively notice the changes in the tower’s state.In the current tower online monitoring system,terminal equipment often needs to replace batteries frequently due to premature exhaustion of power.According to the need for real-time measurement of power line tower,this research designed a real-time monitoring device monitoring the transmission tower attitude tilting and foundation state based on the inertial sensor,the acceleration of 3 axis inertial sensor and angular velocity raw data to pole average filtering pre-processing,and then through the complementary filtering algorithm for comprehensive calculation of tilt angle,the system meets the demand for inclined online monitoring of power line poles and towers regarding measurement accuracy,with low cost and power consumption.The optimization multi-sensor cooperative detection and correction measured tilt angle result relative accuracy can reach 1.03%,which has specific promotion and application value since the system has the advantages of unattended and efficient calculation.

The changing process and trend of ground temperature around tower foundations of Qinghai-Tibet Power Transmission line

After the construction of Qinghai-Tibet Highway and Railway, the Qinghai-Tibet Power Transmission(QTPT) line is another major permafrost engineering project with new types of engineering structures. The changing process and trend of ground temperature around tower foundations are crucial for the stability of QTPT. We analyzed the change characteristics and tendencies of the ground temperature based on field monitoring data from 2010 to 2014. The results reveal that soil around the tower foundations froze and connected with the artificial permafrost induced during the construction of footings after the first freezing period, and the soil below the original permafrost table kept freezing in subsequent thawing periods. The ground temperature lowered to that of natural fields, fast or slowly for tower foundations with thermosyphons,while for tower foundations without thermosyphons, the increase in ground temperature resulted in higher temperature than that of natural fields. Also, the permafrost temperature and ice content are significant factors that influence the ground temperature around tower foundations. Specifically, the ground temperature around tower foundations in warm and ice-rich permafrost regions decreased slowly, while that in cold and ice poor permafrost regions cooled faster. Moreover, foundations types impacted the ground temperature, which consisted of different technical processes during construction and variant of tower footing structures. The revealed changing process and trend of the ground temperature is beneficial for evaluating the thermal regime evolution around tower foundations in the context of climate change.

Limits to foundation displacement of an extra high voltage transmission tower in a mining subsidence area

Given the background of a transmission tower erected on a particular mining subsidence area,we used finite element modeling to analyze the anti-deformation performance of transmission towers under a number of different load conditions,including horizontal foundation displacement,uneven vertical downward displacement,wind loads and icing conditions.The results show that the failure in stability of a single steel angle iron represents the limit of the tower given ground deformation.We calculated the corresponding limits of foundation displacements.The results indicate that compression displacement of the foundation is more dangerous than tension displacement.Under complex foundation displacement conditions,horizontal foundation displacement is a key factor leading to failure in the stability of towers.Under conditions of compression or tension displacement of the foundation,wind load becomes the key factor.Towers do not fail when foundation displacements are smaller than 1% (under tension) or 0.5% (under horizontal compression or single foundation subsidence) of the distance between two supports.

Dynamic Responses of Long-Span Transmission Tower-Line System Subjected to Broken Wires

A macroscopic finite element modeling approach was proposed to calculate the vibration of a tower-line system subjected to broken wires with software ANSYS/LS-DYNA. In the finite element model, not only the nonlinearity of wires and suspension insulators are considered, but also the support towers are included. The incremental and iterative approaches are combined by applying the unbalanced loads incrementally during each iteration cycle. The approach was illustrated with an example of a Hanjiang- River long-span transmission line system subjected to a shield wire and a conductor failure, respectively. The analysis results showed that the proposed dynamic simulation approach can demonstrate the kinetic process of the tower-line system subjected to wire ruptures： The frequencies of line components were lower and densely distributed, but the frequencies of tower components were higher and sparsely distributed. Anyhow, the dynamic effects of wire ruptures on tower-line system could not be ignored in analysis of tower-line system subjected wire failures.

土-岩组合地基变截面锚杆承载性能与机制研究

以山区输电线路工程为背景,针对实践中广泛遇到的上土下岩二元层状地基,提出了一种变截面锚杆技术,其原理为通过增大上覆土层中锚杆的截面积,达到充分利用上覆土层和下部岩层承载力的目的。为检验变截面锚杆的性能,采用现场真型试验和数值模拟相结合的手段,探讨了其承载力提升机制,分析了不同因素对承载特性的影响规律。研究表明,较等截面锚杆,变截面锚杆的上拔、下压以及水平承载力均有所提升。其中,水平承载性能提升效果最显著。场地覆土层厚度对锚杆上拔承载力影响较大,对下压和水平承载性能影响较小。场地地形坡度对锚杆水平承载性能有较大影响,二者呈负相关。此外,“上拔荷载+水平荷载”模式下,变截面群锚基础的承载性能优于等截面群锚基础和传统复合基础,且具有土方开挖量小以及更适用于斜坡地形的优点。研究成果可为该新型基础的推广应用提供技术支撑。

软岩地基斜锚-短桩复合基础水平承载性能研究

针对山区输电线路岩石地基斜锚-短桩复合基础这一新型基础型式,采用有限元方法构建并验证计算模型,并进一步以短桩的桩径及其嵌岩深度、斜锚长度、斜锚连接节点距地表深度为参数,开展嵌岩短桩及斜锚-短桩复合基础抗水平承载性能对比研究。基于斜锚-短桩复合基础水平荷载-位移曲线初始弹性段、弹塑性过渡段和直线破坏段的三阶段变化特征,确定了各基础相应阶段的水平承载力。研究岩体及桩身截面混凝土应力分布特征、斜锚与短桩连接节点位置对斜锚-短桩复合基础抗水平承载性能的影响规律,结果表明:斜锚与岩体间的黏结锚固作用可将基顶水平力转化为斜锚拉力,使水平荷载传递至斜锚周围及短桩桩端以下的岩体,进而有效提高斜锚-短桩复合基础水平承载性能。通过优化斜锚连接节点距地表深度,可减小桩径及其嵌岩深度同时满足相应基础抗水平承载力设计要求,从而有效降低基础施工难度,提高基础安全性。

输电铁塔基础水平位移对杆件内力变化的影响

为求解基础水平位移对铁塔主材内力变化和铁塔底部斜材内力变化的影响,对主材在横隔面上的刚度进行等效,并基于矩阵位移法和最小二乘法,给出了塔腿主材弯矩变化和铁塔底部斜材轴力变化与基础水平位移的计算式,2个计算式都包含了铁塔的主材坡度和高宽比的效应。结果表明:铁塔在基础水平位移作用下塔腿主材弯矩变化与铁塔横隔面的结构形式无关;铁塔在基础水平位移作用下底部斜材轴力变化仅与沿铁塔横截面对角线方向的相对位移有关;基础水平位移作用下的输电铁塔有限元仿真结果与2个计算式结果相吻合。

基于PFC2D的岩溶土洞对输电杆塔基础稳定性影响分析

岩溶土洞是岩溶区域常见的隐伏不良地质条件,随着我国经济发展对电力需求的不断增加,输电工程建设越来越多,由于输电线路的特殊性,在选址时常会跨越岩溶地区,若设计施工不当,则导致输电杆塔基础产生不均匀沉降、变形以及地基整体破坏,严重威胁输电杆塔线路的安全运行。依托宁夏—湖南±800 kV特高压直流输电工程,采用离散元PFC2D软件,分析岩溶土洞对输电杆塔基础稳定的影响,研究洞体尺寸、埋深以及洞体水平位置等因素的影响;并结合数值模拟结果,对洞体安全位置影响范围进行探讨,得到洞体安全位置预测模型,该模型可用于判定场地岩溶土洞地质条件下输电杆塔地基的安全稳定。

输电线路工程不同类型塔基边坡径流产沙特征

[目的]探究输电线路工程塔基边坡水土流失特征,为输电线路工程水土流失治理提供理论依据。[方法]以黄土丘陵区输电线路工程为研究对象,通过野外调查及模拟降雨试验,分析输电线路工程各侵蚀单元水土流失特征及不同类型塔基边坡径流的产沙特征。[结果](1)输电线路工程各侵蚀单元水土流失量占项目总水土流失量的大小依次为塔基区>施工便道>牵张场区>跨越施工场地。塔基区水土流失量占项目总水土流失量的60%以上;(2)与原地面相比,修建塔基边坡增加了地表产流,各类型塔基边坡径流率是原地面的1.8~8.7倍。与偏土质塔基边坡相比,偏石质塔基边坡径流率下降4%~35%,植草的塔基边坡减少20%~48%的径流率;(3)与原地面相比,修建塔基边坡下垫面的径流含沙量增大了0.5~345倍,偏土质塔基边坡增加最大。偏石质比偏土质塔基边坡减少39%~92%径流含沙量,植草可减少83%~98%的含沙量。[结论]输电线路工程建设过程中塔基区是水土流失最大的侵蚀单元,种植草被可以显著减少塔基边坡产沙量,塔基边坡修建后应及时进行植被恢复。

±800 kV特高压输电塔动力特性分析

针对在输电塔杆塔结构设计和动力特性的研究中难以通过理论分析和数值模拟准确获得塔身动力响应的问题,基于±800kV特高压直流输电工程直线塔,建立塔-线-基础体系有限元模型,采用p-y曲线法建立离散非线性弹簧模拟土体对结构的影响,对比分析了单塔、三塔两线、塔-线-基础体系等不同计算模型的特高压输电塔的动力特性,并与现场试验结果进行对比。结果表明,输电线的质量和刚度对输电塔的动力特性有一定的影响,塔线耦合作用不可忽略。考虑桩-土相互作用使输电塔自振频率降低。与单塔模型相比,塔-线-基础体系模型计算得到的频率相对较小,与实际测试频率更为接近,验证了塔-线-基础体系模型的合理性。

输电线路铁塔混凝土基础老化研究

输电线路在长时间运行后,由于环境、荷载等因素影响,铁塔混凝土基础会产生不同程度的老化,导致铁塔基础的性能和使用寿命下降,为输电线路的安全稳定运行埋下隐患。文章针对某市内在运的典型输电线路铁塔混凝土基础开展检测,分析了铁塔基础老化的原因及机理,比较了基础地上和地下部分性能的差异,为铁塔混凝土基础的施工和运维人员的巡检提供了经验和方法。

220kV同塔双回输电线路杆塔电场分布特性研究

随着我国高压交流输电技术的快速发展,高压交流电网已然成为我国电网的主要网架,高压输电线路工频电场不可避免地会对近地面的人类活动产生一定影响,因此有必要对输电线路产生的电磁场进行计算。本文以220kV同塔双回输电线路为研究对象,采用COMSOL有限元仿真软件,模拟同塔双回线鼓形排列条件下杆塔及导线周边的电场,研究分析相序配置、杆塔结构、导线粗细与分裂间距选择,以及导线对地高度等因素对电场分布的影响。结果显示,逆相序排布可显著降低地面电场强度,而导线粗细对电场分布的影响较小,合理的分裂间距有助于控制电场强度,输电线路对地高度是影响地面电场的最关键因素。以上研究结果可为220kV输电线路电场优化提供参考,有助于提升系统的环境兼容性和安全性。

输电线路基础作用力取值探讨

通过搜集历年来相关规程规范、文献的规定,梳理了基础作用力的历史沿革,结合风洞试验结果,针对输电线路基础作用力取值开展了研究。结果表明,行业中设计人员习惯描述的“杆塔作用力”与“基础作用力”两者并没有区别。因此建议不再提“基础作用力”的概念,统一为“杆塔作用力”,并对基础安全系数进行调整,调整前后维持基础的安全度水平基本不变。

陕北砂黄土地区输电线路塔基边坡问题治理对策研究

陕北砂黄土具有其特殊的物理力学性质,砂黄土边坡呈现一种特殊的变形破坏方式。通过综合分析陕北砂黄土变形破坏机制及输电线路塔基边坡的治理经验,得出陕北砂黄土地区输电线路砂黄土塔基边坡问题治理的对策及建议,并给出相关的工程实例予以论证分析。

软土地区基坑开挖对线路杆塔影响分析与加固措施优化研究

为研究软土地区基坑开挖对线路杆塔的影响,结合实际工程案例,应用MIDAS GTS NX有限元分析软件,建立三维有限元模型。对比分析正常工况和渗漏水工况,并采用理论分析验证数值模拟的可靠性。结果表明:现有输电线路技术规程的变形控制允许值不够完善,充分考虑杆塔已有变形,对比现有监测技术规范,对于采用桩基础的线路杆塔桩顶水平位移允许值建议取10 mm。止水帷幕失效时,桩侧土体将产生负摩阻力。相较于正常工况,桩顶水平位移增大71.9%,在软土地区止水质量是基坑开挖的关键环节。

架空输电线路铁塔的基础设计

本文从架空输电线路铁塔的塔型选择着手,分析了铁塔基础类型及设计要点,并采用案例分析法讨论了细节,对实际工作具有一定的指导与借鉴意义。

500 kV直流输电线路下方施工设备及人体感应电研究

针对500 kV同塔双回直流输电线路下方感应电相较于交流线路难以准确分析的问题,研究了同塔双回直流输电线路下方基础施工设备感应电分布规律及施工人员感应电防护措施。采用Solid Works和Ansoft Maxwell混合建模技术,分析了灌注桩基础设备感应电特性、工程施工装备对电场畸变的影响特性和线路下方施工人员位于不同位置时人体周围及体表的电场强度分布,结果表明:灌注桩钢筋笼和基础施工设备的存在会使线路下方的电场发生畸变,且越靠近杆塔畸变率越高,最大电场畸变率分别为75.54%和107.67%;人体体表及周围电场强度与杆塔距离相关,最大可达3830.01 mV/m。

关于猫头型直线塔的下曲臂构造计算分析

猫头塔广泛应用于单回路交流输电线路中,其塔头构造相对复杂,下曲臂部分的构造对整个杆塔尤为重要。本文采用三维铁塔计算软件对110 kV电压等级某系列直线杆塔进行建模并对计算结果展开深入分析。分析结果表明,经过典型设计修编工作验证,合理规划猫头塔下曲臂构造,能有效降低下曲臂外部主材角钢规格、减少分段、连接斜材、节点板及螺栓数量,进而有效减低杆塔整体重量,值得在今后的杆塔设计工作中借鉴采用。

110kV输电线路复合材料杆塔特性试验研究

为了研究110 kV复合材料杆塔特性,对2种不同接地方式下的110 kV单杆双回复合材料杆塔进行了相地操作冲击、雷电冲击、工频污闪等电气特性的试验研究,并对3种结构形式的110 kV复合材料杆塔进行了6种典型工况下的结构荷载试验。根据复合材料杆塔试验结果得出:110 kV复合材料杆塔在合适的接地方式下,杆塔的绝缘水平有大幅的提高;复合材料杆塔的强度满足线路荷载要求,但其挠度要大于铁塔。从运行性能的分析得出,采用复合材料绝缘杆塔可减少运行中风偏、污闪、冰闪、雷击跳闸等故障。

特高压直流输电线路岩石锚杆群锚基础试验

针对山区特高压直流输电线路荷载大、杆塔基础全方位铁塔长短腿和高低主柱基础配合方案的工程实际需求,提出了一种新型的山区特高压直流输电线路承台嵌岩式岩石锚杆群锚基础型式,并在现场完成了不同锚杆埋深和承台嵌岩深度的3个2×2承台式群锚基础的抗拔试验、3个3×3承台式(8根锚杆布置)群锚基础的上拔与水平力组合荷载工况试验。试验结果表明:水平力明显降低了承台嵌岩式岩石锚杆群锚基础的抗拔承载性能,适当增加锚杆长度及承台嵌岩深度可有效提高承台嵌岩式岩石锚杆群锚基础的抗拔承载性能。