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管土摩擦和管径对埋地管道破坏的影响分析 总被引:8,自引:0,他引:8
如何分析管土摩擦和管径对埋地管道地震破坏的影响,是城市地下管道建设中面临的突出问题。采用AD INA软件的定义体操作来选择体类型,并应用布尔操作实现了管道与土体和断层之间的融合,得到地下管道破坏分析的几何模型。通过模型参数选择,确定了岩土性质、管道特性、断层等模型参数,定义了管土摩擦、地震荷载时间函数、断层位移荷载。依据计算结果,分析了管土摩擦和管径对地下管道地震破坏的影响,找出了提高埋地管道抵抗破坏能力的摩擦系数和管径最优值,给出了几点工程建议。 相似文献
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PCCP(预应力钢筒混凝土管)因其优良性能被广泛应用于我国水利水电及市政给排水等生命线工程的建设中。现有研究多为静力分析,少有学者对PCCP管内流体的动力相互作用开展研究。本文利用ABAQUS对PCCP结构及其管内流体在地震荷载下的双向流固耦合作用进行分析,开展了考虑流固耦合与未耦合条件下管道各个结构层的动力响应。进一步计算了考虑内水压力、地震荷载大小和管内水流速度等条件变化对管道受力变形特性的影响。结果表明:流固耦合模型能更加真实地还原和模拟在役PCCP的工作状态;内水压力显著影响管道的受力状态,PCCP结构随着输水压力的增大逐步由受压状态向受拉过渡,且受拉区域和拉应力峰值逐渐增大;管内水流速对应力场影响很微弱。 相似文献
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砂土液化是埋地管道遭受地震破坏的主要原因之一。液化土对管道产生上浮力,使管道发生上浮反应,它是随地震发生时间而变化的动态过程。将地震载荷作用下的液化区埋土管道模拟成两端弹性支承的直梁模型,考虑管-土间的相互作用和管内流体与管道之间的流固耦合作用,采用模态叠加法对液化区埋地管道进行地震响应的动态分析,探讨了管道和液化土参数对管道动态上浮反应的影响。通过数值仿真得到了管内流体的流速、流体压力、流体密度、管截面轴向力,管道黏弹系数、液化土容重和相对弹簧系数、地震加速度幅值等因素对管道上浮位移的影响情况。 相似文献
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基于ABAQUS软件平台,建立穿越断层的管道、有压液体及周围土体的三维有限元模型,分别在静力荷载作用和地震作用下,对不同运动形式断层(走滑断层、正断层、逆断层)中的管道进行模拟,并对管道内有无有压液体进行对比分析。分别得到管道在静力荷载作用下和地震作用下空管道与有压管道的变形特征,将其进行对比分析,得到管道内液体的质量和压力在静力荷载作用及地震荷载作用下对管道的不同影响。结果表明:在静力荷载作用下管道内液体的质量和压力提高了管道的抗变形能力,使管道更安全;而在地震作用下管道内液体的质量和压力削弱了管道的抗变形能力,使管道更容易被破坏。 相似文献
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跨越断层埋地管道屈曲分析 总被引:19,自引:7,他引:19
考虑埋地管道与土介质的相互作用,分析了管道作为薄壳结构的断层位错反应。管道模型化为四结点薄壳单元结构,土介质简化为弹塑性弹簧,建立了管土相互作用的有限元分析模型。计算中,考虑了管道与土介质的材料非线性,管道几何参数,断层类型及破碎带宽,断层滑移角,埋深,内压,温度应力等因素的影响,根据计算结果描绘出管道控制点位移,应力及应变时空分布曲线;比较不同参数下管道的反应特征,总结管道反应的变化规律。最终得到结论:在大位移断层运动作用下,埋地管道反应存在明显的非线性效应,断层类型,管道埋深等因素不能忽略。 相似文献
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为了提高铁路房屋的抗震能力,分析地震动竖向分量对铁路房屋的地震响应性能,提出基于荷载—变形关系联合评估的地震动竖向分量对铁路房屋的地震响应评估模型。构建地震动竖向分量的力学响应评估模型,识别铁路房屋的地震屈服响应参数,采用荷载—变形关系和极限荷载结合的方法进行铁路房屋的地震屈服响应应力评估,分析地震动竖向分量对铁路房屋的响应。建立动量平衡方程和弯矩平衡方程,构建铁路房屋的地震响应的三阶段荷载—变形模式,实现地震动竖向分量对铁路房屋的地震响应性能评估模型的优化设计。测试结果表明,采用该模型能有效分析地震动竖向分量对铁路房屋的地震响应性能影响,Simulink仿真结果和有限元模拟结果的准确性较高,力学参数辨识性能优越,计算结果准确可靠。 相似文献
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合理有效的工程场地自由场分析是开展地下结构地震反应计算、发展地下结构实用抗震分析方法的前提。目前常用的自由场分析方法多局限于单向地震动输入,难以考虑多向地震动共同作用时的非线性耦合效应。鉴于此,提出一种考虑水平和竖向地震动及重力荷载共同作用的土层地震反应分析力学模型,该模型采用捆绑约束条件作为侧面边界条件,采用基于黏性边界的地震动输入方法将输入地震动转化为等效地震荷载,可实现自由场计算中水平和竖向地震动以及重力荷载的同时施加,简化了计算步骤,减少了计算成本。此外,该方法考虑了水平和竖向地震荷载的叠加效应,对于考虑材料非线性及大变形影响的土层场地地震反应分析具有更为良好的计算精度与适用性。 相似文献
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地震断层作用下的埋地管道等效分析模型 总被引:2,自引:0,他引:2
地震作用下,活动断层附近的埋地管道易发生强度屈服、局部屈曲或整体失稳等形式的破坏,建立准确、高效的埋地管道在断层作用下的计算模型,对管道的抗震设计和震后安全状态评估具有重要的实用价值。本文采用非线性弹簧模拟远离断层处埋地管道的反应,基于管土之间小变形段管道处于强化阶段,提出一种改进的管土等效分析模型,进一步减小了管土之间大变形段的分析长度,从而提高了有限元分析效率。该模型采用ALA推荐的方法计算管土间的滑动摩擦力,可以考虑土体种类的影响;用Kennedy方法确定管道的计算长度。通过与精确模型比较,验证了管土等效模型的合理性和有效性。 相似文献
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Pipelines buried in saturated sand deposits, during earthquake loading could damage from resulting uplift due to excess pore water pressure generation. Several studies have been made to better understand the uplift mechanism and evaluate the effectiveness of mitigating techniques through experiment, but little numerical works have been done to assess the influence of soil properties and field conditions in pipeline floatation. Especially for previously buried pipelines, in order to set the priority for seismic retrofit, evaluating the risk of floatation in each region could be a concern. In this paper, effects of several parameters including dilatancy angle and density ratio of natural soil, diameter and burial depth of pipe, underground water table and thickness of the saturated soil layer on uplift of pipe have been investigated. Results show the prominent role of burial depth in pipe response and that there exits an optimum level for drop of water table to reduce floatation. 相似文献
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The response of buried pipelines to random excitation by earthquake forces is obtained using a lumped mass model. The earthquake is considered as a stationary random process characterized by a power spectral density function (PSDF). The cross spectral density function between two random inputs along the length of the pipe is defined with the help of the local earthquake PSDF which is the same for all points, and a frequency dependent exponentially decaying (with distance) function. Soil resistance to dynamic excitation along the pipelength is obtained in an approximate manner with the help of frequency independent impedance functions derived from half-space analysis and Mindlin's static stresses within the soil due to point loads. The proposed method has the advantage that it can take into consideration the cross terms in soil stiffness and damping matrices and can consider any boundary condition that needs to be satisfied at the ends of the pipe. A parametric study is also made to show the influence of cross terms in the soil stiffness and damping matrices on the response of the pipe. 相似文献
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This paper describes a laboratory model test carried out on high-density polyethylene (HDPE), small diameter pipes buried in trenches, which subjected to repeated loadings to simulate the vehicle loads. Deformation of the pipe was recorded at eight points on the circumference of the tested pipes to measure the radial deformations and detect cross-sectional pipe profiles. Also settlement of the soil surface during the test up to 1000 cycles of loadings was recorded, until its value become stable or the excessive settlement was happened. The parameters varied in the testing program include height of buried depth, relative density of the sand and intensity of stress on the soil surface. The influence of various repeated loads (with magnitude of 250, 400 and 550 kPa) at relative densities of 42%, 57% and 72% in different embedded depth of 1.5–3 times of pipe diameter were investigated. Based on the results, in medium and dense sand relative density, the pipe embedded in depth of 3.0D and 2.0D, respectively, mostly remained undamaged (the maximum value of VDS is less than 5%) and increased the safety of buried pipes under different magnitude of repeated loads. The records of the pipe deformation and settlement of the soil surface due to the repeated loads have been compared in different conditions. These values increase rapidly during the initial loading cycles by a rate decreasing significantly as the number of cycles increase. The influence of the first cycle was also found to be one of the main behavioral characteristics of buried pipes under repeated loads. The ratio of deformation of pipe at first cycle to last cycle changes from 0.60 to 0.85 in different of tests. Finally for the obtained results, a non-linear power model has been developed to estimate the vertical diametral strain of buried pipe and settlement of the soil surface based on the model test data. It should be noted that only one type of pipe and one type of sand are used in laboratory tests. 相似文献