海上风电装配式多桩承台基础结构研究

文章针对海上风电多桩承台基础,从桩基结构和上部承台结构两方面进行优化,提出了带预应力锚杆的装配式全直桩承台新结构。结合国华东台海上风电项目,采用Abaqus软件建立模型,模拟装配式承台结构的实际受力,研究装配式承台的结构应力和桩身水平度等设计参数。计算结果表明:装配式承台结构应力和位移满足规范要求,具备施工可行性,有一定的应用前景。     

海上风电场高桩承台群桩基础平台的设计研究

针对国内海上风电基础设计没有统一的规范及标准,为提升海上风电基础设计建设的水平,通过对东南沿海某海域海上风电基础的设计进行了有限元计算分析论证,验证了群桩高承台结构设计方案的设计方法和设计参数。分析结果表明该设计的最大应力主要发生在塔筒底座与承台接触部位及钢管桩与承台连接段,应在连接部位加强措施处理;基础竖直位移较小,水平位移相对较大;分界部位应力较集中,刚度不能顺畅过渡,可考虑填充碎石土等方法加强。本研究对海上风电基础设计技术的研究与探索,可为将来制定中国海上风电行业标准提供可靠的依据,对中国未来大批量的海上风电能源的开发有着重要意义。     

海上风电机组高承台群桩基础设计特点及关键力学问题

海上风电机组高承台群桩基础是我国首次提出并获得广泛应用的新型海上风电机组基础结构型式,该基础由桩基、混凝土承台、基础预埋环、连接件和靠泊构件等组成。在阐述基础结构总体布置及其特点的基础上,从高耸结构、大型动力设备基础和海洋工程的角度,分析了基础的工程特性和载荷分配传递体系。从水动力载荷、系统整体载荷仿真、桩基岩土力学和承台结构分析等方面,提炼出基础设计的若干关键力学问题,包括:大直径承台结构尺度和群桩影响下的承台波浪载荷分析、基于CFD技术和Bladed软件的海上风电机组-塔架-高承台群桩基础载荷分析、大直径超长钢管桩土塞效应对承载力的影响、地基基础对系统整体频率影响和承台钢筋混凝土非线性有限元分析等。     

钢筋砼海洋采油平台的受力分析和配筋设计

由于钢筋砼采油平台结构的复杂性,目前国内的设计者大部分仍按线弹性力学计算结构的内力,再按强度极限状态配置钢筋.但由于砼材料具有明显的非线性性质,且在较低的拉应力作用下就会出现裂缝.以至引起应力重分布,所以上述简化的内力分析方法对于低应力状态下的钢筋砼结构是合理的,而对高应力状态,特别是对研究强度极限状态是不合理的,必须采用非线性有限元分析方法来分析结构的应力状态,为配筋设计提供可靠的依据,并据此进行配筋设计.     

海上风机高桩承台基础船舶碰撞动力分析

为研究海上风机高桩承台基础受到船舶碰撞作用的动力响应,本文运用非线性分析软件LS-DYNA,结合我国东南某海上风电场实际情况,通过建立风机高桩承台基础与船舶碰撞的有限元模型,研究了船舶在撞击过程中的撞击力时程分布以及高桩承台基础在撞击作用下的响应,分析了船舶碰撞对于风机基础结构的动力影响,对于橡胶护舷对于基础结构的保护作用进行了分析。研究结果表明,船舶撞击速度对于风机基础结构的位移影响显著,需要严格控制船舶靠泊速度。同时,橡胶护舷对于结构起到了良好的保护作用。     

洋山深水港区接岸结构稳定性三维数值分析

洋山深水港区工程是我国目前唯一一座建在远离陆地外海岛礁上的现代化集装箱港区,接岸形式采用斜顶桩板桩承台新型结构,由于无现成经验和规范可借鉴,运用大型非线性有限元分析软件对其施工过程进行了三维数值模拟.重点对不同施工工况中承台位移,斜顶桩、板桩与支撑桩的受力,以及地层的施工位移变化进行了模拟分析,计算结果表明接岸结构在起挡土作用的同时,能够保持稳定.计算结果可为洋山后续工程的优化提供了参考.     

海底管道抗压溃分析的理论适用性研究

本文以研究压溃理论的适用性为目的,以有椭圆度的钢管为研究对象,采用理论、有限元、实验相结合的方式,进行均匀外压作用下管道结构压溃失效的研究。整理了目前运用较为广泛的三种压溃理论模型,分别为弹性压溃理论、塑性压溃理论与规范经验公式。并基于ABAQUS软件,建立有椭圆度的钢管模型进行外压压溃模拟,得到不同径厚比D/T钢管的极限压溃值,并进行实验验证了有限元模型的正确性。对比不同压溃理论模型的计算值与有限元结果确定不同理论模型的适用性,获得以下结论:弹性压溃理论适用于径厚比D/T≥40的情况;塑性压溃理论的计算结果偏于保守,计算值均小于有限元结果;DNVGL-ST-F101规范适用适用径厚比D/T≥15的压溃值预测,是目前适用范围最广的公式。本文可为海底管道的抗压溃分析的理论研究提供参考。     

深水港斜顶桩驳岸结构后高回填桩土相互作用研究

斜顶桩驳岸结构是一种深水高桩码头接岸结构型式,驳岸结构后进行高回填将是一个复杂的被动桩与土相互作用的问题。采用平面有限元方法,分别建立了后支撑和前支撑斜顶桩驳岸结构的桩一土相互作用模型,桩基采用梁单元模拟,桩一土界面采用接触对进行模拟,进行了高回填施工过程的仿真分析。将承台侧向位移的数值计算结果与原型观测值进行了比较,吻合较好,并对桩身侧向位移、板桩前后土压力以及位移场进行了分析。结果表明：结构的变形随着施工过程进行而变化,承台最大侧向位移发生在施工过程中;不同驳岸结构的被动土压力分布相似,而主动土压力由于支撑桩的位置不同而有所差别;后支撑桩的桩身挠度相对较大。研究结论可为此类结构的设计及计算提供参考,也可为深水港结构型式的优化提供建议。     

深潜器大开口球形耐压操纵舱结构模型的力学性能

结合模型试验和数值计算对大潜深、带大开口的球形耐压结构静态力学性能进行了研究。研究中考虑到材料非线性、非弹性的因素,通过对材料拉伸试验曲线的分析,得到了材料应力-应变的近似表达式;并且利用超声测厚仪对结构模型的几何缺陷进行了测量。同时基于参数化设计语言建立了有随机几何缺陷的有限元模型,并利用接触单元考虑了大开口观察窗与耐压结构的联系。试验验证表明论文提出的利用有限元软件分析大潜深、大开口耐压壳体力学性能的计算方法和计算策略是准确可靠的,所获得的结果可供设计使用。     

海上风电大直径单桩基础结构在渤海海冰环境下的抗冰性能研究

文章以大连庄河临近的渤海海域为例,基于SACS模型研究大直径单桩基础结构在渤海海冰环境下的抗冰性能。研究结果表明：在静冰力方面,根据不同规范推荐公式设计的大直径单桩基础材料的用量可相差约10%;在动冰力方面,在不同冰速和冰厚的组合工况下,低冰速和大冰厚作用下的大直径单桩基础结构更易产生持续振动。     

海上风电钢管桩自平衡法现场试验研究

一种新型钢管桩预装荷载箱法被研发出用于自平衡法海上风电钢管桩基检测试验,并通过现场自平衡试验研究探究了海上打入桩桩基础特性。该方法首次成功应用于海外某海上风电场直径1.4 m的超长大直径钢管桩承载力检测,用于探究其承载特性和桩侧桩端阻力发挥规律。现场试验显示,该新型检测方法达到了预期的测试效果和经济效益,与现有钢管桩自平衡法相比,对土的影响更小,可靠度更高,为类似土层和直径的超长钢管桩承载力试验提供了新的途径。     

压力注浆螺旋钢管桩抗拔承载性能试验研究

针对海相软土地区螺旋钢管桩承载力低与腐蚀问题,提出一种新型压力注浆螺旋钢管桩,并设计5根足尺试验桩,进行现场抗拔承载性能试验,研究螺旋叶片直径与排布方式对成桩直径与桩基抗拔承载性能的影响.结果表明,成桩直径与螺旋叶片直径呈正相关,在每节延长段钢管末端设置螺旋叶片利于提高水泥土柱完整性,使成桩直径更为饱满,提高桩基的抗拔承载性能.将试验结果和现行规范抗拔极限承载力计算结果进行对比,计算结果约为实测平均值的94％,在此基础上提出压力注浆螺旋钢管桩抗拔承载力计算参数修正建议,为后续的设计提供参考.     

潮间带钢管斜桩吊打导向装置与沉桩参数研究

钢管斜桩是潮间带风电的常用基础形式,常采用吊打沉桩的方式。文章针对潮间带吊打沉桩方式的难点开发吊打导向装置,并总结沉桩参数的确定方法。该导向装置包括定位桩、定位架和调向限位架,总体平面布局为六边形,可一次定位并完成整个风电基础的基桩施工,既能可靠保证桩的施工精度,又能极大地提高施工效率和降低安全风险;在应用该施工关键装备时,采用GRLWEAP打桩分析功能确定桩顶动荷载,采用有限元软件建立导向装置有限元模型,对导向装置和沉桩参数进行分析,从而实现斜桩顺利沉桩的目的。该装置和方法已成功应用于越南朔庄一期海上风电场项目,为潮间带风电钢管斜桩吊打施工提供沉桩装备和方法经验。     

Reinforcement and Arching Effect of Geogrid-Reinforced and Pile-Supported Embankment on Marine Soft Ground

The effectiveness of constructing a geogrid-reinforced and pile supported embankment on soft ground to reduce differential settlement has been studied by pilot scale field tests and numerical analysis. Three-by-three pile groups with varying pile spacing were driven into a layer of soft ground, and a layer of geogrid was used as reinforcement over each pile group. Further, a 2-D numerical analysis has been conducted using the computer program FLAC 2D. The mechanisms of load transfer can be considered as a combination of embankment soil arching, geogrid tension, and stress transfer due to the difference in stiffness between pile and soft ground. Based on the pilot scale field tests and results of numerical analysis, we find that the geosynthetic reinforcement slightly interferes with soil arching, and helps reduce differential settlement of the soft ground. Also, the most effective load transfer and vertical stress reduction at the midspan between piles occurs when the pile cap spacing index D/b (D: pile cap spacing, b: diameter of pile) is 3.0.     

黏土中防沉板—桩复合基础地震反应特性研究

为了研究海底防沉板—桩复合基础在地震荷载作用下的动力反应特性,以我国南海深水工程实例为研究对象,利用Flac3D有限差分仿真软件建立了计算模型,土体采用Mohr-Coulomb本构模型,模型底部输入EL Centro地震波,对不同桩长的复合基础进行分析计算.在该特定工程背景下,研究结果表明:随着桩长的增加,防沉板顶部加速度放大系数呈减小趋势;地震荷载下,复合基础发生震陷,沉降量在地震波加速度峰值过后趋于稳定;当桩长为6m时,复合基础的水平振动程度和震陷量最小;由于桩基础把震动能量传输到深部土层中,复合基础周围土体的加速度响应值小于远场土体.在动力时域内,防沉板与桩连接处弯矩最大,需要在此处增设加固装置.     

Reinforcement and Arching Effect of Geogrid-Reinforced and Pile-Supported Embankment on Marine Soft Ground

The effectiveness of constructing a geogrid-reinforced and pile supported embankment on soft ground to reduce differential settlement has been studied by pilot scale field tests and numerical analysis. Three-by-three pile groups with varying pile spacing were driven into a layer of soft ground, and a layer of geogrid was used as reinforcement over each pile group. Further, a 2-D numerical analysis has been conducted using the computer program FLAC 2D. The mechanisms of load transfer can be considered as a combination of embankment soil arching, geogrid tension, and stress transfer due to the difference in stiffness between pile and soft ground. Based on the pilot scale field tests and results of numerical analysis, we find that the geosynthetic reinforcement slightly interferes with soil arching, and helps reduce differential settlement of the soft ground. Also, the most effective load transfer and vertical stress reduction at the midspan between piles occurs when the pile cap spacing index D/b (D: pile cap spacing, b: diameter of pile) is 3.0.     

Longitudinal dynamic impedance of a static drill rooted nodular pile embedded in layered soil

The static drill rooted nodular (SDRN) pile is a new type of precast pipe pile with equally spaced nodes distributed along the shaft and wrapped by the surrounding cemented soil. In this paper, the longitudinal dynamic response of the SDRN pile embedded in layered soil is investigated with respect to the complexity of the pile body structure and the pile–soil contact condition. First, the shear complex stiffness transfer model is used to simulate the radial inhomogeneity of the surrounding soil. Then, the governing Equations of the pile–soil system subjected to longitudinal dynamic loading are established. The analytical solution for the dynamic response at the pile head is obtained by the shear complex stiffness transfer method and the impedance function transfer method. The degenerate case of the present solution is compared with the published solution to verify its reliability, and the complex impedance of the SDRN pile is compared with that of the precast pipe pile and the bored pile. Finally, a parametric study is conducted to investigate the influence of pile–soil parameters on the complex impedance at the pile head within the low frequency range concerned in the design of the dynamic foundation.     

多层砂土地基扩底桩单桩抗压模型试验及颗粒流模拟研究

利用室内半模试验和颗粒流数值模拟,揭示多层砂土地基扩底桩单桩抗压承载特性及变形特征。结果表明,通过对比分析极限承载力与H_h/D(持力层厚度与扩大头直径之比)的关系可以看出,单桩的抗压极限承载力随H_h/D逐渐增加,当H_h/D超过2.0时,极限承载力基本不再增加,此时的单桩抗压极限承载力稳定在300.01~303.25 N,是H_h/D=0.5时极限承载力(183.83 N)的1.65倍。扩大头下部土体发生局部压缩-剪切破坏,破坏面从扩大头底面边缘向斜下方扩展,在水平方向影响范围达到最大后逐渐向桩内侧收缩;荷载作用越大,地基破坏区域越大,相应的极限抗压承载力也越大;持力层厚度增加,扩大头分担的荷载比例增大,分担的荷载达到稳定需要的桩顶位移也越大,H_h=0.5 D试验扩大头分担的荷载比例稳定时为60%,对应的桩顶位移约为29 mm;桩顶位移达到33 mm后,H_h=1.0~3.0 D试验稳定在63%~65%之间;通过细观颗粒流理论对砂土移动特性的研究发现,持力层厚度从0.5 D增大至2.0 D,破坏面的起始扩展角度从31°增大至42°。数值模拟研究结果与模型试验数据吻合效果良好,证明该方法分析多层砂土地基扩底桩单桩抗压荷载传递机理是可行的。     

Study of the Bearing Capacity at the Variable Cross-Section of A Riser-Surface Casing Composite Pile

Reducing the cost of offshore platform construction is an urgent issue for marginal oilfield development.The offshore oil well structure includes a riser and a surface casing.The riser,surface casing and oil well cement can be considered special variable cross-section piles.Replacing or partially replacing the steel pipe pile foundation with a variable cross-section pile to provide the required bearing capacity for an offshore oil platform can reduce the cost of foundation construction and improve the economic efficiency of production.In this paper,the finite element analysis method is used to investigate the variable cross-section bearing mode of composite piles composed of a riser and a surface casing in saturated clay under a vertical load.The calculation formula of the bearing capacity at the variable section is derived based on the theory of spherical cavity expansion,the influencing factors of the bearing capacity coefficient N_c are revealed,and the calculation method of N_c is proposed.By comparing the calculation results with the results of the centrifuge test,the accuracy and applicability of the calculation method are verified.The results show that the riser composite pile has a rigid core in the soil under the variable cross-section,which increases the bearing capacity at the variable cross-section.     

Experimental Study on the Interaction Mechanism of Cap—Pile Group—Soil

Static load tests on pile group with prototype size were carried out in order to study the behavior and the working properties of the cap—pile group—soil interaction in the pile group foundation. The soil resistance under the cap, the pile shaft resistance and the tip resistance were measured by installing various measuring gauges. Based on these test results, the cap—pile group—soil interaction characteristics were analyzed. The regulations of the soil reaction on the cap, the shaft resistance and the tip resistance of pile, the mechanism of load transfer have been discussed with comparison to the result of the single pile tests. The bearing capacity of pile group is greater than the sum of the bearing capacity of the single pile obtained from testing in the same site in pile group foundation in the case presented here.