海上平台桶基负压沉贯阻力与土体稳定数值计算研究

用有限元分析方法对桶形基础负压沉贯过程中流场进行动态模拟,提出桶形基础沉贯阻力计算方法和土体稳定有限计算方法,提出桶内土体稳定性判断准则,计算结果表明所提方法是合理的,并具有工程实用性。     

筒型基础沉贯阻力估算方法

系统地总结国外有代表性工程实践对筒型基础沉贯阻力的研究 ,并将各种方法综合起来 ,提出了加权综合估算法 ,供今后的研究和工程实践参考     

桶形基础采油平台负压沉贯特性分析

进行了桶形基础负压沉贯的室内试验、中间试验和现场沉贯.对负压沉贯的机理进行了初步分析,结合CB20B桶形基础计量平台的现场测试数据,研究了负压对桶形基础沉贯阻力的影响及对土壤特性的影响,同时对负压、沉贯深度、沉贯速度之间的关系进行了总结.在此基础上,提出了改进的计算沉贯阻力的经验公式.     

海上平台桶形基础模型压力压贯与负压沉贯试验研究

介绍了海上平台桶形基础模型（模型桶）压力压贯和负压沉贯的试验概况,对比分析了两者贯入力的巨大差异和产生的原因,给出了模型桶压力压贯中贯入深度与压力的关系,负压没贯负压与贯入深度,抽吸泵流量,基土渗流量,桶内土塞隆起之间的关系,试验结果表明,负压沉贯可以大大降低以砂质粉土为基土的土抗力,为在胜利油田类似基土海域海上平台应用桶形基础提供了试验依据,为海上现场导管架桶形基础平台的安装就位施工和控制提供了     

桶形基础采油平台负压沉贯特性分析

进行了桶形基础负压沉贯的室内试验、中间试验和现场沉贯。对负压沉贯的机理进行了初步分析,结合ＣＢ２０Ｂ桶形基础计量平台的现场测试数据,研究了负压对桶形基础沉贯阻力的影响及土壤特性的影响,同时对负压、沉南深度、沉贯速度之间的关系进行了总结。在此基础上,提出了改进的计算沉贯阻力的经验公式。     

桶形基础负压沉贯海上试验研究与应用

海上现场试验对于桶形基础平台的沉贯安装十分重要。论述了桶形基础平台原型单桶模型在海上现场负压沉贯的方案、方法和过程,得出了试验结论,并将试验成果成功应用于ＣＢ２０Ｂ采油工艺平台的海上沉贯安装,对浅水区桶形基础平台的现场施工具有指导意义。     

海上平台桶形基础模型负压沉贯试验数据处理与分析

海上平台桶形基础是一种新型海洋石油开发技术,其特点是利用负压将桶形基础贯入海底。本文介绍了单模型和四桶模型平台负压沉贯试验数据处理方法,对负压作用下桶形基础的沉贯过程进行了分析,探索出桶形基础平台机理现场条件下的沉贯方法。     

海上平台桶形基础负压沉贯技术的模拟试验研究方案

对海上平台桶形基础负压沉贯技术的模拟试验研究提出了初步方案,可作为本单位此项技术训端性研究工作的参考。     

桶基平台负压沉贯施工机具的研究与应用

桶形基础采用负压沉贯方法施工,初始入泥和倾斜控制成为制约桶形基础平台应用于浅水区的重要环节。通过分析沉贯、倾斜调整机理,设计了１种负压沉贯施工机具,并成功应用于ＣＢ２０Ｂ桶形基础平台的海上安装,对浅水区桶形基础平台施工机具研究开发具有指导意义。     

桶基平台负压沉贯施工中监测数据的处理构思

桶基平台负压沉贯必须在严格监控下进行。“８６３－８２０－１０－０１”项目在施工中使用了２６个监测器,控制系统根据这些监测数据判断沉贯的姿态和趋势并由工探机的专家系统决策,以实施必要的控制。软件是监控系统的神经中枢,桶基平台负压沉贯施工中监测数据的处理构思是关键。     

Finite element analysis of suction penetration seepage field of bucket foundation platform with application to offshore oilfield development

The seepage field generated by suction penetration of a bucket foundation into sea floor is numerically simulated with a finite element method. The water head and its gradient on both sides of the bucket wall in the seepage field are computed and the results are applied to the calculation of penetration resistance versus penetration depth. Also, allowable suction pressures with various penetration depths are provided for platform installation. The engineering parameters given in this paper were adopted in the design of the first platform (CB20B) with suction-penetrated buckets as foundations in China. This platform has successfully been launched into operation for the offshore oilfield development at the Yellow River Submersed Delta.     

复合加载下桶形基础循环承载性能数值分析

作为一种新型基础形式,吸力式桶形基础除了承受海洋平台结构及自身重量等竖向荷载的长期作用之外,往往还遭受波浪等所产生的水平荷载及其力矩等其它荷载分量的瞬时或循环作用。对复合加载模式下软土地基中桶形基础及其结构的循环承载性能尚缺乏合理的分析与计算方法。应用Andersen等对重力式平台基础及地基所建议的分析方法,基于软黏土的循环强度概念,在大型通用有限元分析软件ABAQUS平台上,通过二次开发,将软土的循环强度与Mises屈服准则结合,针对吸力式桶形基础,基于拟静力分析建立了复合加载模式下循环承载性能的计算模型,并与复合加载作用下极限承载性能进行了对比。由此表明,与极限承载力相比,桶形基础的循环承载力显著降低。     

Investigating the monotonic behaviour of hybrid tripod suction bucket foundations for offshore wind towers in sand

Existing tripod suction bucket foundations, utilised for offshore wind turbines, are required to resist significant lateral loads and overturning moments generated by wind and currents. This paper presents an innovative type of tripod bucket foundation, ‘hybrid tripod bucket foundation’, for foundations of offshore wind turbines, which has the ability to provide a larger overturning capacity compared with conventional tripod buckets. The proposed foundation consists of a conventional tripod bucket combined with three large circular mats attached to each bucket. A series of experiments were conducted on small-scale models of the proposed foundation subjected to overturning moment under 1g conditions in loose sand. Different circular mat diameter sizes with various bucket spacings were considered and the results were compared with conventional tripod bucket foundation. Finite element models of the proposed foundation were developed and validated using experimental results and were used to conduct a parametric study to understand the behaviour of the hybrid tripod bucket foundation. The results showed that there is a significant increase in overturning capacity provided by the novel foundation. The results of this work can significantly improve lowering the costs associated with installation of foundations to support offshore wind turbines.     

海上桶形基础平台负压沉贯渗流场有限元分析

讨论了浅海桶形基础平台负压沉贯渗流场有限元分析方法.通过模型实验结果与有限元分析结果的对比,验证有限元法的可靠性.将有限元法用于桶形基础平台负压沉贯渗流场的计算,得到沉贯过程中许用负压随插深的变化,用于指导平台就位施工时的负压控制.不同插深时,相应许用负压下的桶内、外壁渗流水头和水头梯度分布的计算结果,用于沉贯阻力的计算.     

海上平台桶基沉贯渗流场的有限元法数值模拟

桶形基础平台是一种新型的海洋平台,这种型式的平台与传统的导管架式平台的主要区别在于采用桶形基础代替打下桩基础,桶形基础的负压沉贯过程是一个复杂的水动力过程,其关键在于主动脉施加的桶内外压力差产生渗流场,渗流场的形成与发展对于负压沉贯有决定性的影响。本文用有限元分析方法对桶形基础负压沉贯流流场进行动态模拟,建立了桶形基础负压沉贯过程中渗流场的有限元分析模型,模型试验的结果与按有限元分析计算模型得一的     

Calculation of Hydro-Dynamic Stability of the Soil Inside Bucket in the Process of Bucket Foundation Penetration

—The offshore platform with bucket foundations is a new type of offshore platform that distin-guishes from traditional template platforms by replacing driven piles with bucket foundations.The suctionpenentration of bucket foundation is a complicated hydro-dynamic process.The key of this process is theseepage field caused by the difference of pressure applied on purpose inside and outside the bucket.The ap-pearance and developement of seepage field has a decisive influence on the suction penetration process.Inthis study,the finite element analysis method is applied to the dynamic simulation of the seepage field ofsuction penetration of bucket foundation.A criterion is suggested to distinguish the hydro-dynamic stabili-ty of the soil inside the bucket according to the critical hydraulic gradient method.The reliability of themodel and its applicability to engineering practice have been proved through comparison between the re-sults of model test and finite element calculation.     

单向荷载作用下海上风机多桶基础承载特性数值分析

作为一种新型的深水海上基础型式,桶形基础在海上风机设施设计与建设中逐步得到了发展和应用。以三桶基础为例,采用大型有限元软件ABAQUS对海上风机多桶基础的承载特性进行了三维有限元数值分析。根据海上风机的荷载受力特点,分别探讨了三桶基础在竖向荷载、水平荷载和力矩作用下的极限承载力,得出荷载作用方向及桶间距对极限承载力的影响程度,研究成果为复合加载模式下海上风机多桶基础的承载特性分析奠定了基础。     

Experimental study on wide-shallow composite bucket foundation for offshore wind turbine under cyclic loading

As an appropriate type of foundation for offshore wind turbines (OWTs), wide-shallow composite bucket foundation (WSCBF) is cost-competitive, and it has a unique and special substructure that comprises seven internal rooms arranged in a honeycomb-like structure. In this study, the cyclic behavior of WSCBF for OWTs embedded in saturated clay was investigated using a large-scale model subjected to lateral cyclic loading. The responses of foundation under constant- and various-amplitude cyclic loadings were recorded in terms of displacements, rotations, and bending moments. The variations in stiffness and damping were obtained, and a collaborative bearing mechanical model between the bucket and soil was considered, which was beneficial for improving the stiffness of the whole structure. Accumulative deformation was found to have little effect on the bearing capacity of the foundation. Dynamic analysis in frequency domain was further performed on both moment and rotation data, and the complex, frequency-dependent impedance was also studied.     

海上风机斜壁桶形基础承载特性研究

基于验证的三维有限元方法,考察了斜壁桶形基础的承载特性,得到了变形网格、位移增量分布、位移等值面分布等结果,探讨了斜壁倾角与各极限承载力之间的定量关系。计算表明,桶形基础发生竖向位移时,主要是桶体内部和桶基正下方的土体发生沉降,而桶侧的土体基本不发生沉降。桶形基础受到水平荷载发生转动时,转动中心轴大致位于桶基底面内,桶基水平承载力主要由桶内土体和桶基外侧中上部受压侧土体产生的抵抗反力构成。桶基因受到较大竖直向上荷载而失效时,桶内土体和桶基外侧靠近海床面附近土体产生了较大的向上位移。桶壁倾角β每增加1°,竖向抗压极限承载力、竖向抗拔极限承载力、水平极限承载力分别提高12%、17.4%及3.8%。     

Evaluation of cyclic and monotonic loading behavior of bucket foundations used for offshore wind turbines

Suction caissons are considered as an alternative foundation solution for offshore wind turbines. In the present study, three-dimensional finite element (FE) analyses are performed to assess the behavior of a bucket foundation and soil supporting the bucket under cyclic and monotonic loading conditions. A parametric study is also performed for a wide range of bucket geometries and two different soil densities. The results indicate that bucket geometry and soil properties significantly affect the foundation response due to cyclic loading conditions. The bucket with the smallest geometry installed in medium dense soil exhibits the lowest stiffness in initial loading and then with the progress of cyclic loads experiences lower stiffness compared to the caissons with larger geometries. The sensitivity of the foundation response to the soil density is higher than its geometry. The bucket under the lowest vertical load experiences the lowest stiffness in both virgin loading and during the progress of cyclic loads. The highest soil displacement is observed near the lid at the interior of the bucket. Stresses caused by cyclic loading belong to certain ranges. Additionally, increases in the skirt length result in increases in the stress ranges and shift the range to the right side. With respect to the monotonic loading conditions, normalized diagrams are proposed that can be used for the preliminary design of suction bucket foundations.