Yuanlong Chen , Jianfeng Li , Pengpeng Ni , Zhiwang Lu
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引用次数: 0
Abstract
Bell-spigot jointed ductile iron pipelines are increasingly used, which are highly susceptible to permanent ground deformation. It is necessary to predict their responses under normal fault conditions. This investigation presents an analytical approach that simplifies the pipeline as a beam-type structure resting on discrete Winkler foundation comprising discrete springs, connected by shear and torsional springs at the bell-spigot joints, which is solved by the finite difference method. Comparisons of pipe deflection and joint rotation with the results from two full-scale experiments confirm the effectiveness of this method. Parametric analysis is conducted with respect to soil modulus, location of peak curvature, burial condition, pipe diameter, and joint rotational stiffness. It is found that increase in soil modulus can deteriorate the deformation of pipe bodies. Concentration of shear zones intensifies the responses of both pipeline segments and bell-spigot joints. For deeply buried jointed pipelines, less compacted backfills can reduce the soil-pipe interaction forces, mitigating the detrimental impact of fault rupture. A concept of relative joint-pipe stiffness ratio, R, is introduced to describe different joint rotational stiffness, identifying the threshold of R = 10 % for transition between jointed and continuous pipelines. Considering different failure limits, joint rotation failure always occurs earlier than pipe bending failure.
Bell-spigot 接头球墨铸铁管道的应用越来越广泛,这种管道极易受到永久性地面变形的影响。有必要预测其在正常故障条件下的响应。本研究提出了一种分析方法,将管道简化为由离散弹簧组成的梁式结构,支撑在离散的温克勒地基上,在钟形插销接头处由剪切和扭转弹簧连接,并采用有限差分法求解。管道挠度和接头旋转与两个全尺寸实验结果的比较证实了该方法的有效性。对土壤模量、峰值曲率位置、埋设条件、管道直径和接头旋转刚度进行了参数分析。结果发现,土壤模量的增加会使管体变形恶化。剪切区的集中会加剧管道段和钟形插销接头的响应。对于深埋的连接管道,较少压实的回填土可减少土壤与管道之间的相互作用力,从而减轻断层破裂的不利影响。引入了接头-管道相对刚度比 R 的概念来描述不同的接头旋转刚度,并确定 R = 10 % 为接头管道和连续管道之间的过渡阈值。考虑到不同的失效极限,接头旋转失效总是早于管道弯曲失效。
期刊介绍:
The journal aims to encourage and enhance the role of mechanics and other disciplines as they relate to earthquake engineering by providing opportunities for the publication of the work of applied mathematicians, engineers and other applied scientists involved in solving problems closely related to the field of earthquake engineering and geotechnical earthquake engineering.
Emphasis is placed on new concepts and techniques, but case histories will also be published if they enhance the presentation and understanding of new technical concepts.