共查询到18条相似文献,搜索用时 140 毫秒
1.
《中国海洋大学学报(自然科学版)》2017,(3)
采用三维非线性动态有限元方法对抛锚撞击海底管道进行模拟。建立霍尔锚模型,考虑管土相互作用,研究不同撞击能量下抛锚撞击管道的机械损伤(最大凹陷)变化规律。对不同防护措施的防护效果进行探讨,包括埋深、混凝土配重层、加大径厚比等措施。数值模拟结果与试验结果进行对比,两者结果吻合较好。结果表明:当锚与管道接触面积越小时,锚对管道的撞击凹陷越大;加大埋深对抛锚撞击管道有很好防护的作用;管道内压对抛锚撞击管道有一定的抵抗作用;混凝土配重层对防护抛锚撞击管道的防护作用不明显;增加管道壁厚是防护抛锚撞击管道的有效措施之一,也应考虑经济性。本文研究结果为实际工程中降低抛锚撞击管道机械损伤后果提供参考。 相似文献
2.
以往的海底管道落锚撞击防护数值模拟主要为单一保护层模型,这里则针对块石+混凝土排垫复合方案建立模型并开展防护性能研究。基于ABAQUS建立有限元数值模型,模拟了落锚、海底管道、海床土体、块石层和混凝土排垫组成的复杂系统相互作用,研究了管道壁厚、内压,落锚质量和撞击速度等因素对管道应变极值和管体凹陷变形的影响。与单纯块石层保护方案相比,采用的块石+混凝土排垫方案具有更优良的防护效果。研究结果表明:在撞击点处,管道的轴向应变和环向应变均达到最大值,且随着与撞击点距离的增加沿管道轴向逐渐减小;撞击结束后,管道上仍然残留一定的塑性应变。随着管道壁厚的增加,管道的最大应变和凹陷深度也随之减小;随着内压的增加,管道上最大拉伸应变变大,而最大压缩应变和凹陷深度减小。随着落锚速度或者质量的增加,管道上最大应变和凹痕深度均变大;在相同动能情况下,管道上的最大应变和凹陷值基本相同,也表明落锚动能是影响管道变形响应的控制因素。本文研究成果可为海底管道防护方案设计提供科学依据。 相似文献
3.
航船应急抛锚时锚板贯入土体可能会影响河床或海床中的结构物甚者造成破坏,因此在通航频繁的航道,结构物埋深的设计需要充分考虑应急抛锚时锚板的贯入深度。本文通过缩尺模型试验模拟了霍尔锚在中等密实度粉细砂中的抛锚贯入过程,研究了不同抛锚速度(1.15~4.4 m/s)及粉细砂相对密实度(0.45~0.65)对抛锚贯入深度的影响;基于太沙基极限承载力理论和能量守恒定律,推导出霍尔锚在粉细砂土中贯入深度的表达式,与模型试验结果对比显示理论计算结果偏于保守。基于试验结果提出修正系数,修正后的理论公式能够较好地快速预测霍尔锚在中等密实度粉细砂中的贯入深度。研究结果为粉细砂土河床或海床中的结构物埋深设计提供了一定的技术参考。 相似文献
4.
5.
河床或海床中会布设光缆、管线、隧洞等结构物,如果该水域上有船只抛锚,就要考虑抛锚对结构物安全的影响。通过模型试验探究了霍尔锚在黏土中的抛锚深度,研究了贯入速度、锚重以及土强度对抛锚深度的影响。在模型试验中,用MEMS加速度传感器捕捉锚在土中运动时的加速度,并由加速度积分得到锚的下落速度及对应的下落位移。模型试验结果表明:当霍尔锚以极限速度贯入软黏土中时,17.8 t锚在强度为7.5 k Pa土中的贯入深度为4.0 m; 42 t锚在强度为8.3 k Pa的土中贯入深度为6.7 m。根据试验结果建立了霍尔锚在土中动力贯入时的运动微分方程,分析了作用在锚上的各项受力,并预测了抛锚深度。此外,根据模型试验结果,建立了抛锚深度和锚的总能量之间的经验公式。 相似文献
6.
为探索海底管道在锚击作用下的损伤规律,通过海底管道损伤试验和数值模拟,研究了坠物质量、坠落高度和坠物形状对海底管道机械损伤的影响,并结合试验结果修正了Ellinas-Wallker公式。研究结果表明:管道的凹陷损伤随坠物质量和坠落高度的增大而变大;在相同质量的立方体、球体和模型锚三种形状坠物作用下,球体坠物对管道的损伤最严重;EllinasWallker公式计算结果偏于保守,修正后计算结果与试验和数值模拟结果吻合良好。研究结果可以为海底管道的工程设计及应用提供一定的参考。 相似文献
7.
8.
板翼动力锚是依靠自重完成安装并靠自重和海床土的抗力来锚固的新型动力锚。板翼动力锚高速(15~25 m/s)贯入地基过程中涉及到高应变率、流固耦合、土体软化和大变形等难题,模型试验可避免上述计算困难,能直接得出不同的贯入速度所对应的沉贯深度。本文首先推导了模型相似关系,然后在常规重力条件下,进行了两组26个工况的板翼动力锚在均质黏土中动力安装过程的模型试验,根据试验结果确定了率效应参数的取值范围,并研究了每一项受力对沉贯深度的影响。最后提出了在均质黏土中预测板翼动力锚沉贯深度的经验公式。 相似文献
9.
坠锚事故容易对海底管道造成撞击损伤,引起环境污染及经济损失。为保证管道在运行期间的安全,有必要对其进行风险分析。基于可靠度理论,在DNV规范(DNV-RP-F107)推荐方法的基础上,本文提出了一种失效概率的计算方法,该方法可考虑船锚质量、尺寸及管道尺寸、材料强度等因素对失效概率的影响,与实际情况更相符。结合工程实例,对船锚撞击作用下的海底管道进行了风险分析。考虑随机变量的变异性,探讨了管道失效概率对各变量的敏感性。分析结果可为降低海底管道损伤风险及采取合理的防护措施提供技术参考。 相似文献
10.
11.
Because of the complex geological conditions of the seabed, submarine pipelines buried beneath the ocean floor become suspended over the seabed under the long-term scour of waves eroding the surrounding sediment. Further, most oil fields were built in offshore areas while the country was developing. This gives the waves seen in shallow water obvious nonlinear features, and the abnormal characteristics of these waves must be considered when calculating their hydrodynamic forces. Particularly under such conditions, these suspended spans of submarine pipelines are prone to damage caused by the action of the external environment load. Such damages and eventual failures may result not only in great property losses but also pollution of the marine environment. The span length of these areas is a key predictive factor in pipeline damages. Therefore, determining the allowable span length for these submarine pipelines will allow future projects to avoid or prevent damage from excessive suspended span lengths. Expressions of the hydrodynamic loads placed on suspended spans of pipeline were developed in this work based on the first-order approximate cnoidal wave theory and Morison equation. The formula for the allowable free span length was derived for the common forms of free spanning submarine pipeline based on the point where maximum bending stresses remain less than the material’s allowable stress. Finally, the allowable free span length of real-world pipelines was calculated for a subsea pipeline project in Bohai Bay. This research shows that, with consideration for the complicated marine environment, existing suspended spans are within allowable length limitations. However, continuing to limit the length of these submarine pipeline spans in the Nanpu oil field will require ongoing attention. 相似文献
12.
海底滑坡作为常见的海洋地质灾害,对海洋油气工程安全产生巨大威胁。海床土体失稳引起滑坡体滑动,会对海底管道产生拖曳作用。基于计算流体动力学方法(CFD)建立海底滑坡体对管道作用的评估模型,采用H-B模型描述块状滑坡体并与试验比较验证,分析不同海床倾斜度滑坡对管道的作用并拟合表达式;研究了海底管道在滑坡作用下的力学响应,并采用极限状态方法开展海底滑坡作用下管道结构极限安全分析,探讨了管道埋地状态时的极限安全界限,建立滑坡作用下管道结构安全分析方法。研究表明:滑坡对管道作用力与海床倾角呈现正相关,而覆土层厚度对作用力影响较小;随着不排水抗剪强度的减小,允许的滑坡宽度和速度均增加,表明土体不排水抗剪强度与引起的拖曳力呈正相关;滑坡土体宽度对极限安全速度影响较大。 相似文献
13.
14.
Experimental investigation on the wave-induced pore pressure around shallowly embedded pipelines 总被引:1,自引:1,他引:0
A series of regular wave experiments have been done in a large-scale wave flume to investigate the wave-induced pore pressure around the submarine shallowly embedded pipelines.The model pipelines are buried in three kinds of soils,including gravel,sand and silt with different burial depth.The input waves change with height and period.The results show that the amplitudes of wave-induced pore pressure increase as the wave period increase,and decay from the surface to the bottom of seabed.Higher pore pressures are recorded at the pipeline top and the lower pore pressures at the bottom,especially in the sand seabed.The normalized pressure around pipeline decreases as the relative water depth,burial depth or scattering parameters increase.For the silt seabed,the wavelet transform has been successfully used to analyze the signals of wave-induced pore pressure,and the oscillatory and residual pore pressure can be extracted by wavelet analysis.Higher oscillatory pressures are recorded at the bottom and the lower pressures at the top of the pipeline.However,higher residual pressures are recorded at the top and the lower pressures at the bottom of the pipeline. 相似文献
15.
With the development of marine energy in full swing, an increasing number of pipelines are being installed in deep-sea areas, which inevitably pass through extremely complex topographic conditions, to form natural sections of suspension over submarine canyons. The seabed is easily eroded and shaped by active deep-sea bottom currents and watercourses, resulting in different span heights for pipelines originally laid on the seabed. In particularly, deep-sea geological hazards frequently occur, and submarine landslides seriously threaten the safe operation of the pipelines. To address these problems, an improved numerical analysis method combined with low-temperature rheological models of landslides and the optimization design method of the geometric model, is developed to simulate the landslides’ impacts on pipelines. Based on these, the effect of the span heights on the pipelines’ impact forces induced by deep-sea landslides is systematically investigated, and three modes of the forces on pipelines under the impact of landslides and related mechanism are proposed. Further, the span height ratio is put forward, and four formulas for evaluating the forces on pipeline are established. Through the analysis of calculation results, the lift force coefficient even increases nearly 20 times considering different span heights. This research provides a theoretical basis for the design and protection of deep-sea pipelines. 相似文献
16.
The stability of submarine pipelines has been extensively studied by coastal engineers in recent years. Seismic-induced pore pressure and effective stresses in the saturated porous seabed and pipeline are the main important factors in the analysis of foundation stability around submarine pipelines. The majority research of the seismic-induced dynamic response around an offshore pipeline has been limited to two-dimension cases. In this paper, a three-dimensional finite element model including buried pipeline is established by extending DYNE3WAC. Based on the proposed numerical model, a parametric study is conducted to examine the effects of soil characteristics and pipeline configurations on the seismic-induced soil response around offshore pipelines. 相似文献
17.
海底管道的位置与埋深测量通常采用浅地层剖面仪等声学手段来实现,由于海管与地层之间的声阻抗差异,会以绕射弧的形态出现在声学剖面中。但当海管埋设于管沟中时,管沟中断棱的绕射与海管绕射易于混淆,给声学剖面图的解译和识别带来困难。基于地震勘探原理,结合浅地层剖面仪的性能、挖沟作业对地层的扰动等,分析了管沟绕射弧的类型与特点、挖沟作业扰动的声学特征等,提出了管沟中海管绕射弧的识别方法。结果表明,正确认识不同类型管沟的绕射、施工扰动产生的绕射等声学特征,才能辨识出海管的绕射现象。实际工作中应根据测量海区的水深、土质、海管属性等多种要素,选用适宜的仪器类型及测量参数。 相似文献