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1.
海上自升式钻井平台以其造价低廉、便于移动和安装的优势被广泛应用于海洋地质勘察、风电安装和油气开采等领域,其基础类型多为桩靴基础。为了保证平台能在恶劣的海洋环境中安全作业,桩靴基础需要贯入海床以下一定深度以获得足够的承载力。然而,当桩靴基础在上硬下软土层中贯入时可能发生穿刺破坏导致平台损坏甚至倾覆。已有的桩靴穿刺破坏分析方法基于预设的地层参数预测穿刺荷载,由于无法考虑海床中地层及土性的不确定性,其准确性有待提高。将桩靴基础贯入过程中的监测数据与穿刺破坏机理相结合,通过66组离心机模型试验结果表征土体不确定性的影响,发展贝叶斯预测模型,实现了峰值阻力和穿刺深度的实时预测。基于规范推荐的荷载扩展分析法和冲剪系数分析法,建立了适用于规范法的概率模型,采用该模型对上砂下黏土层中桩靴基础的穿刺行为进行了预测,结果表明所提方法的预测精度随着监测数据的增加而提高,预测得到的峰值阻力误差在10%以内。 相似文献
2.
在自升式平台的预压载过程中,桩靴在层状地基上较易发生“穿刺”现象,很大程度上影响着平台的安全运行。准确地分析桩靴峰值阻力,避免平台桩靴发生“穿刺”是非常重要的。采用极限分析上限定理,合理构建运动许可速度场,从理论上推导了层状地基上桩靴峰值阻力的上限解答。为了进一步验证峰值阻力理论解答的准确性,采用ABAQUS有限元软件构建了“桩靴—弹塑性海床”的三维数值模型,对桩靴贯入海床的过程进行了数值模拟,分析桩靴周围土体的塑性变形演变规律,研究土体的破坏机理。研究结果表明:推导的桩靴峰值阻力上限解答,能够较好地计算层状地基极限承载能力,通过与离心机试验和数值结果对比,计算误差在18%以内;给出的运动许可速度场能够较好地反映桩靴周围土体破坏模式;桩靴阻力达到峰值时,下层软土中的土塞高度约为桩靴直径的0.2倍。 相似文献
3.
复杂土层中自升式平台桩靴安装穿刺预测 总被引:1,自引:1,他引:0
由于复杂海洋工程地质条件的普遍性,自升式平台在安装过程中穿刺事故频发,近年来涌现出大量针对自升式平台桩靴基础在复杂土层中穿刺预测方法的研究。为了方便工程设计人员的理解和使用,首先简单介绍这些研究中所采用的技术手段,总结现行规范ISO 19905-1建议的桩靴在复杂土层中贯入阻力的预测方法以及最新文献中提出的新的设计方法,并对规范方法和新方法的优缺点进行了评价。所总结的设计方法针对国内外常见的含穿刺风险的海洋地基形式,包括双层"砂—黏"、三层"硬—软—硬"黏性土、三层"软—硬—软"黏性土、三层"黏—砂—黏"地层以及四层"黏—砂—黏—硬层土"地层。通过对离心机模型试验的预测,对规范方法和新方法的预测精度进行了比较,对比结果显示新方法对桩靴穿刺破坏的预测更为合理精确。 相似文献
4.
为研究钻井船插桩对邻近平台群桩相互作用的影响,采用耦合欧拉拉格朗日(CEL)方法对桩靴贯入黏土层时邻近群桩中各桩荷载分担比、桩头附加位移及两桩相互作用系数进行了分析。首先通过对缩尺模型试验的数值分析,验证了CEL方法的可行性;然后进一步分析了桩靴贯入黏土层时对邻近群桩相互作用的影响;最后探讨了净间距、桩间距对群桩相互作用的影响。结果表明,在桩靴贯入中,前桩的荷载分担比大于后桩,且桩靴贯入至一定深度后,当净间距越小或桩间距越大时,前桩的荷载分担比越大、后桩的荷载分担比越小,但各桩的荷载分担比随桩靴贯入深度增加时的变化规律不变;净间距越大,桩头附加位移及相互作用系数越小;在桩靴贯入时,由于受群桩遮拦效应的影响,桩头附加位移及相互作用系数随桩间距的变化规律同插桩前有所不同,当桩间距大于3倍桩径时,随桩间距的增加而减小,当桩间距小于3倍桩径时,随桩间距的增加而增大。 相似文献
5.
自升式平台作业前需对桩靴基础进行预压安装,使桩靴具备抵抗竖向-水平-弯矩复合荷载的能力。安装过程中,桩靴上部将形成一定深度的孔洞。弱超固结黏土地基中,土体强度较高,桩靴最终贯入深度较浅,而形成的上部孔洞较深,因此孔洞将对桩靴就位后的承载力产生影响。通过有限元分析,研究弱超固结黏土中桩靴上部孔洞对承载力的影响,结果表明:1)与无孔洞的情况相比,孔洞的存在对桩靴的单向和复合承载力有削弱作用; 2)当桩靴与孔洞底部距离大于桩靴直径时,承载力不再受上部孔洞的影响; 3)当桩靴埋深小于等于0.75倍桩靴直径时,无论桩靴上部有无孔洞,现有预测公式都不能较为合理地预测弱超固结黏土地基的复合承载力,为此提出了考虑孔洞影响的桩靴复合承载力包络面预测公式。 相似文献
6.
在海洋工程中,移动钻井平台在作业结束后需要转场时,经常会遇到拔桩困难的问题,桩靴底部的吸附力是上拔力的重要组成部分,明确其产生机理及发展规律对于上拔力计算与缓解上拔困难问题有重要意义。通过室内模型试验研究了黏土中桩靴底部真空度对桩靴吸附力产生机理的影响,试验结果表明,桩靴底部真空度的变化对上拔力的影响显著,而桩靴贯入深度和上拔速率会对真空度产生影响。当真空度达到峰值时,桩靴底部吸附力与上拔力几乎同时达到峰值,因此可以通过减小桩靴底部真空度的措施来减小上拔力。根据试验结果,提出了运用真空吸盘理论来计算桩靴底部吸附力的计算公式。所述吸附力计算方法与试验结果进行对比,其误差较小,对工程实践具有一定的参考意义。 相似文献
7.
《中国海洋大学学报(自然科学版)》2015,(7)
在分析桩靴式钻井平台插桩过程中地基土的破坏形式的基础上,将桩靴下土体破坏面假定为锥形面,根据极限平衡理论,推导出了均匀、双层地基土中基于被动土压力的插桩阻力计算公式。通过插桩实例对所推导的公式进行了验证,分析比较了极限承载力与插桩阻力的异同,讨论了插桩阻力计算公式推导过程中土体假设为锥形破坏面的合理性,认为本文推导的插桩阻力计算公式作为桩靴式钻井平台插桩深度预测方法更接近实际插桩结果。 相似文献
8.
自升式平台穿刺过程结构响应研究 总被引:1,自引:0,他引:1
为减少自升式平台穿刺造成的损失,需要对自升式平台穿刺过程中的结构响应进行研究。根据某典型平台图纸,使用有限元法建立细化模型。在穿刺过程中采用CONNECTOR单元及非线性弹簧模拟自升式平台围阱区的齿轮齿条接触及桩土作用。考虑到模型中包含的高度非连续过程,穿刺过程采用显式动力学方法求解。通过分析模型穿刺后的结构形态,危险点分布,穿刺速度对结构的影响及预压载值的变化,探讨自升式平台穿刺过程中的结构响应特征。结果表明:平台导向板附近桩腿结构最容易在穿刺中损坏;穿刺速度对与桩靴相连的桩腿结构影响很大;为减少穿刺对结构的影响,可以考虑主动刺穿或减少气隙进行单桩预压载等措施。 相似文献
9.
自升式钻井平台在海洋石油开采中得到了广泛的应用。桩腿的刺穿安全性分析是钻井平台插桩分析的重点。随着钻井平台建造越来越大,压载过程中,桩靴对土层的破坏模式也发生了改变,一种新的土层破坏模式(土塞破坏模式)在大直径桩靴压载过程中经常发生。分析了在复杂地层下,常规破坏模式和土塞破坏模式发生的机理,并对土塞破坏模式下计算桩靴入泥深度的基本公式进行了介绍。根据多次工程实践以及案例分析表明,土塞破坏分析模式能够较为准确地预测大型钻井平台在复杂地层下的桩靴入泥深度,为钻井平台操作者提供可靠的资料和安全分析。 相似文献
10.
针对粉土中吸力桶在吸力沉贯中的两个关键性问题——沉贯阻力和内部土体稳定性,在自行研制的试验平台上进行了一系列吸力桶沉贯模型试验。试验结果表明,粉土中吸力沉贯时,Andersen所提供的基于CPT锥尖强度的阻力计算公式能较好预测阻力发展趋势,但计算结果偏小;而修正的承载力公式预测结果在沉贯前期与实测值较吻合,沉贯后期预测偏大。吸力沉贯前期,贯入阻力随深度稳步增长,直到贯入深度达到某个临界值后,阻力增长缓慢甚至保持不变。桶内粉土在吸力作用下的失稳机理与黏土或砂土不同,在渗透力作用下表现为从土层表面开始的自上而下管涌或渗流侵蚀。沉贯后期,端部土体在较高水头差下发生失稳并向桶内流动,造成了桶内土体密度降低,端阻力与内壁摩阻力降低,总贯入阻力主要由外壁摩阻力提供。并结合有限元模拟对上述实验现象的内在机理进行了解释。 相似文献
11.
This paper presents a finite element approach to calculate the full resistance profile of a spudcan deeply penetrating in dense sand overlying clay, in which a potential for an installing spudcan to experience a sudden uncontrolled punch-through failure exists. A modified Mohr-Coulomb model characterized by incorporating a four-phase variation of the mobilized strength and dilation parameters with an equivalent accumulated plastic strain is developed and tested for the overlying dense silica sand. An extended Tresca model is used for the strain softening of the underlying clay. A series of large deformation finite-element (LDFE) analyses are carried out, varying the strength and dilation parameters as well as the spudcan geometries. A fairly good performance of the present approach is verified by validating against groups of centrifuge tests data, allowing the numerical study to be extended parametrically. The four-phase variation of the mobilized strength and dilation parameters involved in the progressive failure of the upper dense sand is parametrically studied and extended to cover the range of sand relative densities that are of practical interest. Additionally, comparisons with the typical existing LDFE analyses using both simple and sophisticated constitutive models are carried out. It shows that the present approach performs fairly well to calculate the full resistance profile of a spudcan deeply penetration in both thin and thick dense sand overlying clay, especially the peak and post-peak resistance, within around 5% of the corresponding centrifuge tests results. 相似文献
12.
The behaviour of spudcan foundations during the installation and preloading in two-layer sand sediments was investigated through large deformation finite element (LDFE) analyses. The LDFE analyses were carried out using the coupled Eulerian-Lagrangian approach, modifying Mohr-Coulomb soil model to capture hardening and subsequent softening effects of sand. Parametric analyses were undertaken varying the top layer thickness, relative density of sand and spudcan diameter. Both loose to medium dense-over-dense and dense-over-loose to medium dense sand deposits were explored. The results showed that, for the investigated relatively thin top layer thickness of ≤ 5 m, spudcan behaviour was dictated by the bottom sand layer with a minimal influence of the top layer. For assessing the penetration resistance profile in two-layer sands, the performance of the ISO, SNAME, InSafeJIP, and other existing theoretical design methods were evaluated. 相似文献
13.
Spudcan may experience punch-through failure on strong over weak layered soils, such as sand overlying clay. A large deformation finite element method (LDFE) is used to simulate the penetration process of spudcan into sand overlying clay. The sand is simulated by smoothed hyperbolic Mohr-Coulomb model, and the clay is simulated by a simple elasto-plastic model which obeys Tresca yield criterion. According to the LDFE results of a large amount of cases, the effects of the strength, unit weight and thickness of the top sand layer, as well as the effect of the strength of the underlying clay on the spudcan punch-through behavior, are investigated. The critical depth occurring punch-through and the critical bearing capacity are presented in charts. Fitting equations to calculate the critical punch-through depth and the critical bearing capacity are proposed for the convenience of engineering practice. 相似文献
14.
The mechanisms of soil structure interaction have drawn much attention in the past years in the installation and operation of jack-up platform. A bionic spudcan produced by biomimetic of egg and snail shell is proposed, and the performance of the penetration and extraction are analyzed by numerical method. The geometric contour of egg and snail shell is measured, and its mathematical model is established respectively. According to the structure of existing spudcan of jack-up platform, three kinds of typical biomimetic spudcan are designed. Furthermore, numerical analysis models of biomimetic spudcan are established respectively to study the soil structure interaction mechanism in the process of penetration and extraction, and contrastive analysis of resistance characteristics are carried out. To conclude, the results show that the biomimetic spudcan facilitates the platform installation, and it is also beneficial to the improvement of the bearing capacity of spudcan. 相似文献
15.
Jack-up platforms of the Ocean engineering structures always withstand the vertical gravity loads which are applied to the seabed by spudcan, so it is important to determine the bearing capacity and the penetration depth of the spudcan for its geometry. In fact, it is up to the deformation law and the failure modes of soil surrounding the spudcan which can calculate the ultimate bearing capacity of the spudcan foundation on the soil seabed. By using the finite element analysis software Abaqus, the deformation law of soil around the spudcan is analyzed in detail, and the failure modes of soil surrounding the spudcan foundation are achieved. At the same time, based on the limit equilibrium theory, by use of static permissible slip-line field, the ultimate bearing capacity of the spudcan foundation is analyzed and the lower limit solution is derived theoretically, and the effect of the spudcan angle on the ultimate bearing capacity is investigated. The numerical results are compared with those obtained by the theoretical formulas deduced in this paper. On the basis of the lower limit solutions in this paper, the effect of the spudcan angle on the ultimate bearing capacity is revealed, and a practical bearing capacity formula is given to take the effect of the spudcan angle into consideration. 相似文献