共查询到17条相似文献,搜索用时 93 毫秒
1.
法向承力锚是一种新型的拖曳嵌入式系泊基础.这种锚的工程应用仅有10 a时间.国内在此项技术上尚属空白.通过实验系统的设计,介绍了针对这种新型拖曳锚展开模型实验研究的实验平台.利用一些新型传感器和巧妙的机件设计,不仅实现了实验量测方法的创新,而且达到了经济实用的目的.实验结果也验证了整个系统设计的可靠性. 相似文献
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拖曳锚由于其承载性能和深水中便于安装被广泛应用于海洋工程系泊系统中,如:适用于悬链式系泊系统的传统拖曳锚和适用于绷紧式系泊系统的法向承力锚。拖曳锚安装过程中涉及诸多运动特性:锚板运动方向、系缆点处拖曳力和拖曳角及运动轨迹。基于大变形有限元分析技术耦合的欧拉-拉格朗日法,并引入缆绳方程,建立起锚-缆绳-海床土耦合作用的有限元分析模型;模拟了拖曳锚在均质和线性强度黏土中的嵌入安装过程,研究了锚板运动方向、系缆点处拖曳力和拖曳角及运动轨迹等运动特性;通过与已有的有限元分析方法及理论方法进行对比,验证了该分析模型的有效性;与已有的有限元分析方法相比,提出的分析模型有效地提高了计算效率。 相似文献
3.
法向承力锚(VLA)--一种适用于深海工程的新型系泊基础 总被引:2,自引:0,他引:2
深水系泊基础是深水系泊系统的重要组成,随着海洋油气资源开发的加速发展,深水系泊系统的关键技术成为国际海洋油气资源开发的重要研究领域.法向承力锚(VLA)是一种崭新的适用于深海油气资源开发的系泊基础形式,论文对其应用、性能特点、工作原理、安装与回收以及计算分析方法等进行了全面介绍,以期对科研人员进一步认识深水系泊系统的关键技术有所帮助,并对国内深水系泊系统的研发起到一定的借鉴作用. 相似文献
4.
法向承力锚(Vertically Loaded Plate Anchor,VLA)是一种适用于深水的新型系泊基础,它的拖曳安装过程直接决定了其系泊定位的精度和锚体的最终承载能力。综合考虑VLA锚体、锚泊线和上部船体的运动,建立了一种新的准静力整体分析模型。模型包括不断贯入海床的锚体、锚泊线(土中反悬链段和水中悬链段)和安装船体三部分,针对确定的锚泊线长度,安装船运动张紧锚泊线进行安装的过程,计算了此过程中锚体的运动轨迹、锚泊线形态和作用在船体上的锚泊线张力矢量的变化,重点分析了不同抛链长度和海床土体的参数对安装过程控制的影响,发现链长与水深之比达到5时,接近极限贯入深度。 相似文献
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相比于已有动力锚(鱼雷锚、多向受荷锚等),新型轻质动力安装锚借助助推器安装,具有质量轻、埋深大、承载效率高、在海床中下潜容易等特点。良好的水动力学特性(较小的拖曳阻力系数及稳定的下落垂直度)是确保动力安装锚准确、有效地安装到指定地点并贯入到设计深度的前提。通过4组10个工况的模型试验,研究了轻质动力安装锚的终端速度和拖曳阻力系数,及轻质动力安装锚和助推器的组合锚在水中自由下落时的方向稳定性。试验结果表明:优化后轻质动力安装锚的拖曳阻力系数为0.51~0.55,这有助于提高组合锚在水中的下落速度,从而提升组合锚的沉贯深度;增大助推器尾翼展弦比和选用轻质材料制作尾翼能减小组合锚的下落偏角,提高组合锚的方向稳定性。 相似文献
6.
深水锚是深水系泊系统的核心组成,随着新概念和新技术在深水系泊领域的不断涌现和发展,深水锚在海床中的动力行为变得更为复杂,这给既有的分析方法带来极大的挑战。将深水锚的复杂动力行为视为拔出、旋转、嵌入三种典型行为的组合,分别给出明确定义并建立力学模型。提出最小力准则以确定锚的拔出、嵌入方向和旋转中心,该准则同时可作为拔出、旋转、嵌入行为是否发生的判定条件,从而建立起可以描述深水锚在海床中复杂动力行为的分析模型。为检验所提出的分析模型,将其应用于预测拖曳锚在海床中的嵌入运动轨迹,并与已有分析方法和离心机试验结果进行对比,验证了该分析模型的有效性。 相似文献
7.
新型深水系缆非线性动力特性研究进展 总被引:1,自引:0,他引:1
随着海洋油气资源开采逐渐向深海发展,新型绷紧式系泊系统正替代传统悬链式系泊系统广泛应用于深水平台的系泊中.作为一种采用合成纤维材料系缆的新型系泊系统,系缆复杂的力学特性是其工程应用需要首先认识并解决的关键技术问题.介绍了在复杂海洋环境条件下合成纤维系缆的非线性动力特性,包括动刚度、绷紧-松弛、蠕变、应力松弛以及疲劳破坏等特性,总结和评述了针对这些特性开展的国内外相关研究,也对今后需要继续深化的研究进行了展望,以期为国内在此方向开展的数值模拟和实验研究提供重要参考. 相似文献
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深海吸力锚基础的极限承载能力是海洋工程锚固系统的一个关键问题。基于Coulomb摩擦接触对原理,给出一种模拟吸力锚承载能力的有限元模型。在该数值模型基础上,利用通用有限元分析软件ABAQUS,研究系泊点位置、吸力锚长径比对极限承载力的影响,并给出深海吸力锚失稳模式。结果表明,系泊点位置极大地影响着吸力锚的极限承载力与稳定性,系泊点位置的变化会导致吸力锚出现前倾转动、平移滑动和后仰转动失稳模式,同时吸力锚失稳模式受长径比的影响。为工程实际和理论分析提供了技术支持和理论指导。 相似文献
10.
针对应用于中国南海的新型深水Spar钻井生产储卸油平台进行了涡激运动特性与影响的研究。对该平台进行涡激运动拖曳试验,根据规范和动力学分析得出平台的拖曳力系数和升力系数,通过比较南海流速分布情况与平台涡激运动与流速关系发现:该平台在一般海况下即可发生幅值为10 m左右的涡激运动;对平台进行水池模型试验,进一步验证涡激运动拖曳试验结果并分析平台运动性能,对平台受到的脉冲拖曳力和升力载荷进行了初步校验。通过模型试验对平台涡激运动特性有了初步认识,发现在百年一遇条件下,平台脉动拖曳力载荷与升力载荷比为1∶3;一年一遇条件下,平台脉动拖曳力载荷与升力载荷比为1∶1。根据试验结果对数值模型进行了修正并与试验值进行比较,比较结果表明经过修正后的计算结果与试验结果取得了良好的一致性。比较了全尺度下涡激运动对于平台系泊系统和平台水平位移的影响,结果表明:涡激运动的存在使得Inline方向系泊张力增加5%,并使得系泊缆受力分布产生变化,位移增加27%;Between line方向张力增加15%,位移增加2.5%。涡激运动对于平台极限张力以及极限漂移出现方向还有待进一步研究。涡激运动对于平台系泊系统疲劳寿命的影响还需进一步研究。 相似文献
11.
Attributed to good performance in the seabed, drag anchors are adopted as an effective anchoring solution in deepwater mooring systems. This type of anchors is drag installed, companying with comprehensive behaviors during movement of the anchor in the seabed, which make the anchor trajectory and therefore the final embedment position difficult to be predicted. On the basis of the mechanical model and analytical procedure, an analytical method is proposed for exploring comprehensive behaviors of drag anchors in both clay and sand. The anchor behaviors are classified as keying, pulling out and diving. The bearing capacity and the trajectory of the anchor can be predicted through the combination of the three behaviors. By comparing analytical predictions with experimental data and other predictions, the efficiency and veracity of the theoretical model are validated. A parametric study is also performed to investigate the effects of different parameters, and to further understand the comprehensive anchor behaviors in the seabed. The present work provides an efficient theoretical tool for analyzing comprehensive behaviors of drag anchors in either clayey or sandy seabed. 相似文献
12.
With the application of innovative anchor concepts and advanced technologies in deepwater moorings, anchor behaviors in the seabed are becoming more complicated and pose a great challenge to the analytical methods. In the present work, a large deformation finite element (FE) analysis employing the coupled Eulerian–Lagrangian technique is performed to simulate the installation/mooring line, and then is applied to analyzing comprehensive anchor behaviors in the seabed. By connecting cylindrical units with each other using connector elements, the installation/mooring line is constructed. With the constructed installation/mooring line, FE simulations are carried out to investigate comprehensive anchor behaviors in the seabed, including long-distance penetration of drag anchors, keying of suction embedded plate anchors and non-catastrophic behavior of gravity-installed anchors. Through comparative studies, the accuracy of the proposed method is well examined. A parametric study is also undertaken to quantify the effects of the frictional coefficient, initial embedment depth, and soil weight on the profile of the embedded anchor line and the shackle load. The present work demonstrates that the proposed FE model, which incorporates the installation/mooring line and the anchor, is effective in analyzing the comprehensive anchor behaviors in the seabed. 相似文献
13.
With the application of innovative anchor concepts and advanced technologies in deepwater moorings, anchor behaviors in the seabed are becoming more complicated and significantly affected by the anchor line. Based on the coupled Eulerian–Lagrangian (CEL) method, a numerical approach incorporating anchor line effects is developed to investigate comprehensive anchor behaviors in the soil, including penetration of drag anchors, keying of suction embedded plate anchors and diving of gravity installed anchors. Compared to the method directly incorporating the anchor line into the CEL analysis, the proposed method is computationally efficient. To examine the robustness and accuracy of the proposed method, numerical probe tests and then comparative studies are carried out. It is found that the penetration (or diving) and keying behaviors of anchors can be well simulated. A parametric study is also undertaken to quantify the effects of various factors on the behavior of OMNI-Max anchors, whose mechanisms are not yet fully understood. The maximum embedment loss of OMNI-Max anchors during keying is not influenced by the initial anchor embedment depth, whereas significantly increases with increasing drag angle at the embedment point. With decreasing initial anchor embedment depth or increasing soil strength gradient, drag angle at the embedment point and diameter of the anchor line, the behavior of OMNI-Max anchors could change from diving to pullout, which is undesirable in offshore engineering practice. If the drag angle increases over a certain limit, the anchor will fail similar to a suction anchor. 相似文献
14.
Positioning drag anchors in seabed soils are strongly influenced not only by the properties of the anchor and soil,but also by the characteristics of the installation line.The investigation on the previous prediction methods related to anchor positioning demonstrates that the prediction of the anchor position during dragging has inevitably introduced some key and unsubstantiated hypotheses and the applicability of these methods is limited.In the present study,the interactional system between the drag anchor and installation line is firstly introduced for the analysis of anchor positioning.Based on the two mechanical models for embedded lines and drag anchors,the positioning equations for drag anchors have been derived both for cohesive and noncohesive soils.Since the drag angle at the shackle is the most important parameter in the positioning equations,a novel analytical method that can predict both the variation and the exact value of the drag angle at the shackle is proposed.The analytical method for positioning drag anchors which combines the interactional system between the drag anchor and the installation line has provided a reasonable theoretic approach to investigate the anchor behaviors in soils.By comparing with the model flume experiments,the sensitivity,effectiveness and veracity of the positioning method are well verified. 相似文献
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Drag anchor is one of the most commonly used anchorage foundation types. The prediction of embedded trajectory in the process of drag anchor installation is of great importance to the safety design of mooring system. In this paper, the ultimate anchor holding capacity in the seabed soil is calculated through the established finite element model, and then the embedded motion trajectory is predicted applying the incremental calculation method. Firstly, the drag anchor initial embedded depth and inclination angle are assumed, which are regarded as the start embedded point. Secondly, in each incremental step, the incremental displacement of drag anchor is added along the parallel direction of anchor plate, so the displacement increment of drag anchor in the horizontal and vertical directions can be calculated. Thirdly, the finite element model of anchor is established considering the seabed soil and anchor interaction, and the ultimate drag anchor holding capacity at new position can be obtained. Fourthly, the angle between inverse catenary mooring line and horizontal plane at the attachment point at this increment step can be calculated through the inverse catenary equation. Finally, the incremental step is ended until the angle of drag anchor and seabed soil is zero as the ultimate embedded state condition, thus, the whole embedded trajectory of drag anchor is obtained. Meanwhile, the influences of initial parameter changes on the embedded trajectory are considered. Based on the proposed method, the prediction of drag anchor trajectory and the holding capacity of mooring position system can be provided. 相似文献
16.
ABSTRACTThe OMNI-Max anchors are newly developed dynamically installed anchors for deep water mooring systems. After installation, the anchor is keyed to a new orientation and position by tensing the attached mooring chain, which is known as the “keying process”. This study conducted 1g model tests to study the trajectories and capacity developments of OMNI-Max anchors in homogeneous and lightly overconsolidated (LOC) clays. A testing arrangement was designed to simulate the anchor keying process with a constant pullout angle at the mudline. A half model anchor which could move against the box glass was used to determine the anchor trajectory in the soil. The effects of padeye offset angle, uplift angle at the mudline, anchor fluke thickness, anchor initial embedment depth, and soil strength on the anchor trajectory and capacity were systematically investigated. Moreover, the critical uplift angle at the padeye and the anchor critical initial embedment depth were discussed. The results indicate that the anchor can dive both in homogeneous and LOC clays under certain conditions. A padeye offset angle of 24–30° is recommended for the OMNI-Max anchor to maintain high capacity and diving trend simultaneously. Besides, the anchor diving trend can be improved with small uplift angles at the mudline and with thick anchor flukes. A critical initial embedment depth of 1.3 times the anchor length is recommended to preclude the anchor from being pulled out. 相似文献
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基于三维频域势流理论,计算船体的水动力参数;采用动态耦合方法分析了深海半潜式生产平台各系统之间的相互作用特征,研究了立管系统对锚泊系统定位能力的影响。计算结果表明,立管系统在一定程度上增加了整个系统的刚度,其所受的附加质量和阻尼可降低平台的低频响应,从而降低平台的偏移和系泊缆的张力;海流将增大立管上的拖曳力,使平台偏移更远,锚索上的张力更大;立管系统对锚泊系统定位性能的最终影响需综合考虑多种因素的叠加。对目标平台而言,由于服役海域的流速较大,对立管的拖曳作用较为明显。因此,为确保平台的安全性,当服役海域流速较大时,带有多立管的平台,其锚泊系统的设计应考虑立管的影响。 相似文献