唐古项目:考虑土壤特性和海底流动性等主要不确定性因素的海上管道在役屈曲设计

S. Bughi, Luigi Foschi, Lorenzo Marchionni, R. Vichi, Yansa Zulkarnain
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引用次数: 0

摘要

本文基于最近在印度尼西亚完成的一条海上管道的设计和安装过程中的经验,该管道在设计过程中发现一条24英寸海底生产管道(长16公里,水深70米)容易发生侧向屈曲。屈曲是一种众所周知的现象。然而,该项目具有主要不确定性,主要受土壤特性、土壤区带性、土壤-管道相互作用、海底流动性和海底液化的影响。这些不确定性对在役屈曲设计起到了关键作用。特别是,从完全暴露到完全覆盖(由于自然输沙)的极端管道埋置场景对土-管相互作用产生了重大影响。为了在验收标准范围内限制过度应变的发展,采用了一种基于相互作用的计划屈曲的缓解策略,在管道路线沿线安装了三个屈曲启动器(BI)。在设计过程中,为了证明所提出的解决方案的鲁棒性,已经付出了巨大的努力。利用ABAQUS软件进行了三维有限元模拟,考虑了管道的路线曲线和海底剖面,以及扣环起爆器的主要几何形状。所有的不确定性都是按照确定性方法来考虑的。由于潜在的拖网渔具相互作用,环境和意外载荷的影响也进行了评估。此外,还分析了沿沙波区域的管道对横向和/或剧变屈曲的敏感性,以评估在使用寿命期间采取适当的缓解措施以冻结管道配置的必要性。最后,在建立横向屈曲设计理念后,评估管道的循环膨胀和行走行为,以验证管道在屈曲处的结构完整性,路线曲线拉出和管道在阀芯处的累积膨胀。本文介绍了管道设计过程中面临的主要工程问题和管道安装后现场的初步反馈。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Tangguh Project: In-Service Buckling Design of Offshore Pipelines With Major Uncertainties on Soil Characterization and Seabed Mobility
This paper is based on the experience made during the design and installation of an offshore pipeline recently completed in Indonesia, where a 24” subsea production pipeline (16km long in 70m water depth) was found susceptible during design to lateral buckling. Buckling is a well understood phenomenon. However, this project was characterized by major uncertainties mainly driven by soil characterization, soil zonation, soil-pipe interaction, seabed mobility and seabed liquefaction. These uncertainties have played a key role in the in-service buckling design. In particular, extreme pipeline embedment scenarios ranging from fully exposed to fully covered (due to natural sand transportation) were accounted with a significant impact on soil-pipe interaction. To limit the development of excessive strain within the acceptance criteria, a mitigation strategy based on interacting planned buckles has been adopted installing three Buckle Initiators (BI) along the pipeline route. During design great efforts have been spent with the aim to demonstrate the robustness of the proposed solution. 3-D FEM simulations with ABAQUS have been performed taking into account the pipeline route including route curves and the sea bottom profile and the buckle initiators with their main geometries. All uncertainties have been considered following a deterministic approach. The impact of environmental and accidental loads due to a potential trawl-gear interaction were assessed as well. The pipeline susceptibility to lateral and/or upheaval buckling along the sandwave areas has been analyzed as well in order to evaluate the need of mitigation measures suitable to freeze the pipeline configuration during the operating life. Finally, once the lateral buckling design philosophy was established, the cyclic expansion and walking behavior of the pipeline were assessed to verify the pipeline structural integrity at buckles, route curve pull-out and the accumulative pipeline expansion at spools. This paper presents all main engineering aspects faced during design and first feedbacks from field after the pipeline installation.
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