共查询到19条相似文献,搜索用时 358 毫秒
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筒型基础安装过程中,筒内的负压作用会导致土塞现象的出现。以试验模型为基础建立可变形离散元计算模型,通过VC++编制的程序SPSAⅡ对筒型基础负压沉贯中土塞的生成过程进行可视化模拟计算。考虑渗流力、筒壁内外摩擦阻力和筒内负压吸力作为土塞产生的主要外荷载,分别模拟渤海地区3种典型土(黏土、粉土和砂土)的情况。其中,粉土情况下。程序的收敛速度最快,黏土情况下,土塞的计算高度最接近试验测量值,数值计算结果表明该计算方法作为筒型基础施工前筒内土塞高度的预测方法是可行的。 相似文献
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射流作为流体运动的一种特殊形式,在工程中具有非常广泛的应用。其中,卷吸和掺混效应是射流的两大重要特征,其影响贯穿射流发展的整个过程。长期以来研究人员从理论分析、实验测量和数值模拟等几个方面对射流的卷吸、掺混性能进行了大量的研究工作,并探索出多种提高射流卷吸、掺混性能的方法。文中从喷嘴形状,喷嘴数目,喷嘴间距,喷嘴矩形截面宽高比和射流流速比等几个方面,对增强射流卷吸、掺混性能的研究方法、研究现状和研究结果进行了整理、分析,讨论了该领域存在的问题,并对该领域的研究方向进行了展望。 相似文献
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针对振动沉管碎石桩水上施工应用少、合适船机设备少、桩身质量控制难等问题,通过改造施工船机设备,优化关键技术参数和施工工艺,依托具体工程开展现场研究。采用三管式碎石桩船,研发了大开度活瓣钢桩靴,配置沉桩定位及视频监控系统实现施工过程的可视化;碎石添加采用干法填料、管身开孔润料、提升过程不留振的工艺,可顺利拔管成桩;采用皮带机供料、计量斗计量、提升斗运输的一体化加料工艺,碎石填料可精确控制。结果表明:通过将桩间距2.3 m 分别调整为桩间距2.4 m、排间距2.18 m 和桩间距2.1 m、排间距2.5 m,整个桩身分为三段,并控制平均拔管速度为1.5 m/min,充盈系数采用1.38,合理分批次加料、干法填料,两次留振时间分别控制在20 s和60 s等措施,经重型动力触探法检测,表层2 m 锤击数平均值为8.3,2 m 以下锤击数平均值为11.2,满足表层2 m 的碎石桩重型动力触探锤击数达到7击以上,2 m 以下贯入10 cm 锤击数不小于10击的设计要求。 相似文献
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大直径钢管桩土塞效应的判断和沉桩过程分析 总被引:5,自引:0,他引:5
港口工程和海洋工程中出现了越来越多的大直径超长钢管桩。由于这种桩直径较大,土塞的形成对桩的可打入性和承载力有较大的影响。鉴于此,根据大直径和超大直径钢管桩土塞性状的特殊性,考虑了桩直径对侧壁摩阻力、端阻力的影响,引入了尺寸效应系数,重新建立了土塞微分体的静力平衡方程,提出了采用改进的静力平衡法进行土塞效应判断,同时采用波动方程法近似模拟土塞与桩管内壁的相互作用,建立了简化的土塞与桩壁相互作用模型,并用该方法进行实际工程的打桩分析,分析结果表明该方法对土塞效应的判断、打桩过程的预测等与工程实测数据吻合较好。 相似文献
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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
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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
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开发了一种新型平台桩靴,可通过活动板转动实现自升式平台不同阶段桩靴受力面积的灵活变化。基于大变形有限元方法,模拟新型桩靴基础在“砂-黏”地层中的贯入过程,分析了活动板转角、砂层厚度比、摩擦角和黏土层不排水抗剪强度对新型桩靴贯入阻力的影响,并与普通桩靴的贯入响应比较。数值分析中,上覆砂土和下层黏土分别采用摩尔库伦模型和修正Tresca模型进行模拟。结果表明:新型桩靴穿刺时,土层参数对峰值阻力的影响规律与普通桩靴相同,但其峰值阻力随活动板转角的变化而变化,无法直接使用具有等效面积普通桩靴的穿刺预测方法。考虑各项关键影响因素,结合穿刺破坏时的地基破坏模式,基于数值模拟结果提出了适用于新型桩靴的贯入阻力预测公式。 相似文献
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筒型基础负压沉贯就位后,筒内表面土的沉降会使土层上部产生一层水膜。严重的水膜现象会影响到筒基平台的正常使用,为此专门设计本项试验来模拟筒内水膜形成的机理,并且提出了向筒内灌浆的方法解决水膜问题的方案。该试验通过配土、设计模型筒基、负压沉贯和筒内灌浆等操作过程,设置土槽、安装孔压传感器等实验手段,从土体破坏的角度,寻求负压沉贯过程中沉贯负压、沉贯阻力及孔隙水压力等因素对水膜形成的影响,试图探询水膜形成的规律,并且通过不同泥浆的灌浆试验来寻找有效解决水膜现象的方法。 相似文献
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近壁圆柱绕流水动力特性数值模拟与实验研究 总被引:3,自引:0,他引:3
通过数值模拟和物理模型实验,对距壁面一定高度的圆柱绕流水动力特性进行了研究。数值模拟采用有限体积法对标准k-ε模式方程进行离散,采用SIMPLE算法进行求解,模拟绕流流场。在物理模型实验中,将PVC圆管制作的实验模型安放在水槽内,在圆管的跨中沿表面周向均匀布置水下压力传感器,用于测量绕流圆柱体表面动水压力分布。通过改变Re数和间隙比来分析它们对近壁圆柱绕流水动力特性的影响。基于数值流动显示技术,给出了近壁绕流流场的尾流流态分析。通过数值结果与实验结果的对比,对近壁绕流圆柱体的升力系数及其表面动水压力分布进行了研究,对比结果显示了较好的一致性。 相似文献
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大直径超长桩的可打入分析是海洋平台打桩施工顺利进行的重要保障,土塞是否闭合的判断对于桩基可打入性分析具有较大的影响,因此,合理准确的土塞判断结果对提高桩的可打入分析的准确性具有重要的意义。以现场静力触探(CPTU)试验数据为依据,采用孔扩张理论推导了基于CPTU测试结果的桩端土的极限承载力计算公式;在求解桩端土体承载力时考虑了管桩与土体的刚度差异,同时考虑到打桩过程中的土体扰动。采用Randolph推荐的方法得到了土塞阻力,将两者进行比较,进而判断土塞的状态。通过实际工程的实测数据,对各个土层的土塞状况进行了判别,并根据判别情况采用波动方程的方法对桩基的可打入性进行了分析,将预测结果和现场的打桩记录进行了比较。计算结果显示,提出的方法与实测结果更为接近,有效地提高了桩的可打入性的预测精度。 相似文献
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Calibration chamber tests were conducted on open‐ended model piles driven into dried siliceous sands with different soil conditions in order to clarify the effect of soil conditions on load transfer mechanism in the soil plug. The model pile used in the test series was devised so that the bearing capacity of an open‐ended pile could be measured as three components: outside shaft resistance, plug resistance, and tip resistance. Under the assumption that the unit shaft resistance due to pile‐soil plug interaction varies linearly near the pile tip, the plug resistance was estimated. The plug capacity, which was defined as the plug resistance at ultimate condition, is mainly dependent on the ambient lateral pressure and relative density. The length of wedged plug that transfers the load decreases with the decrease of relative density, but it is independent of the ambient pressure and penetration depth. Under several assumptions, the value of earth pressure coefficient in the soil plug can be calculated. It gradually reduces with increase in the longitudinal distance from the pile tip. At the bottom of the soil plug, it tends to decrease with increase in the penetration depth and relative density, and to increase with the increase of ambient pressure. This may be attributed to (1) the decrease of friction angle as a result of increase in the effective vertical stress, (2) the difference in the dilation degree of the soil plug during driving with ambient pressures, and (3) the difference in compaction degree of soil plug during driving with relative densities. Based on the test results, an empirical equation was suggested to compute the earth pressure coefficient to be used in the calculation of plug capacity using one‐dimensional analysis, and it produces proper plug capacities for all soil conditions. 相似文献
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Foundation piles of the offshore oil platforms in the Bohai Bay are usually longer than 100 m with a diameter larger than 2 m.Driving such long and large-sized piles into the ground is a difficult task.It needs a comprehensive consider ation of the pile dimensions,soil properties and the hammer energy.Thoughtful drivability analysis has to be performed in the design stage.It has been shown that judging whether the soil column inside the pile is fully plugged,which makes the pile behave as close-ended,strongly influences the accuracy of drivability analysis.Engineering practice repeatedly indicates that the current methods widely used for soil plug judgment often give incorrect results,leading the designers to make a wrong decision.It has been found that this problem is caused by the ignorance of the bearing capacity provided by the soil surrounding the pile.Based on the Terzaghi’s bearing capacity calculation method for deep foundation,a new approach for judging soil plug status is put forward,in which the surcharge effect has been considered and the dynamic effect coefficient is included.This approach has been applied to some practical engineering projects successfully,which may give more reasonable results than the currently used method does. 相似文献
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Long steel piles with large diameters have been more widely used in the field of ocean engineering.Owing to the pile with a large diameter,soil plug development during pile driving has great influences on pile driveability and beating capacity.The response of soil plug developed inside the open-ended pipe pile during the dynamic condition of pile-driving is different from the response under the static condition of loading during service.This paper addresses the former aspect.A numerical procedure for soil plng effect prediction and pile driveability analysis is proposed and described.By taking into consideration of the pile dimension effect on side and tip resistance,this approach introduces a dimensional coefficient to the conventional static equilibrium equations for the plug differential unit and proposes an improved static equity method for the plug effect prediction.At the same time,this approach introduces a simplified model by use of one-dimensional stress wave equation to simulate the interaction between soft ping and pile inner wall.The proposed approach has been applied in practical engineering analyses.Results show that the calculated plug effect and pile driveability based on the proposed approach agree well with the observed data. 相似文献
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近年来海上工程的规模越来越大,为了满足工程需要,桩基设计常常采用大直径,大长度的钢管桩。打桩过程是个相当复杂的过程,不仅涉及到几何非线性、材料非线性、边界非线性,而且是个动力过程。有限元法在处理打桩分析方面具有很强的优势,采用PLAXIS对不同条件下的打桩问题进行了动力模拟分析。分析显示在打桩过程中,桩端土体会产生较大的水平位移和竖向位移,桩端土体和靠近桩端的部分土塞内会产生较大的超孔隙水压力。在砂土中,停锤较短时间也会使孔压迅速消散,这也是打桩中间的停锤会造成后续打桩困难的主要原因。 相似文献
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AbstractIn this article, the drivability of stepped and tapered offshore piles with the same length and volume has been investigated under hammer blows. To justify the obtained results from field testing and numerical methods, this pile driving procedure has been analyzed and discussed with wave propagation mechanism. It will be shown that tapered pile can be confidently idealized as a number of prismatic segments connected rigidly to each other. This is an interesting finding that fully tapered or stepped piles have a better performance in pile driving and enable users to apply simple one dimensional numerical analysis for simulating pile drivability. 相似文献
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Liqiang Sun Yandi Wang Shuwang Yan Jian Chu Xiaoqiang Liu 《Marine Georesources & Geotechnology》2018,36(6):709-721
The super-long and large-diameter steel pipe piles are often adopted for the construction of offshore oil platforms in deep sea. One constructability issue related to driving heavy pipe piles is the pile running. The term pile running refers to the quick penetration of a pile into the seabed as a result of its high self-weight and low resistance from the seabed. The unexpected pile running can cause the steel wire of the hammer to break or even the loss of the hammer. A case study of pile running at an oil platform is introduced in this paper. A simplified theoretical method is proposed to explain the mechanisms of the pile running in this case. A factor of friction degradation is proposed to calculate the dynamic skin friction from the static ultimate skin friction of surrounding soil. The comparisons between the predictions to the case history show that the proposed simplified method can be used to predict the pile running condition. 相似文献
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Large monopiles are used as foundations for offshore wind turbines and are generally designed with a tapered section or conical shape. Some loss of driving energy is expected to occur during installation of these structures due to the submerged section of the tapered monopile. The current literature on this subject is limited and indicates rather large losses compared to field observations.A numerical model of the monopile–water–soil system was set up in the general-purpose finite element package Abaqus. By simulating the hammer impact and the resulting stress wave propagation through the monopile and water, the energy losses to be expected can be calculated accurately. The model was verified against independent finite element analyses and experimental data.A parametric study was performed and the effect of hammer characteristics, submerged monopile length and monopile geometry on the driving energy losses were quantified. The results enable a simple relationship between the energy losses and the monopile geometry to be proposed which increases linearly with pile diameter, taper angle, and submerged length. The losses are typically on the order of 0.15–0.3% per metre submerged length for large tapered monopiles. 相似文献
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In the water jet propulsion system with a positive displacement (PD) pump, the nozzle, which converts pressure energy into kinetic energy, is one of the key parts exerting great influence on the reactive thrust and the efficiency of the system due to its high working pressure and easily occurring cavitation characteristics. Based on the previous studies of the energy loss and the pressure distribution of different nozzles, a model of water jet reactive thrust, which fully takes the energy loss and the nozzle parameters into consideration, is developed to optimize the nozzle design. Experiments and simulations are carried out to investigate the reactive thrust and the conversion efficiency of cylindrical nozzles, conical nozzles and optimized nozzles. The results show that the optimized nozzles have the largest reactive thrust and the highest energy conversion efficiency under the same inlet conditions. The related methods and conclusions are extended to the study of other applications of the water jet, such as water jet cutting, water mist fire suppression, water injection molding. 相似文献