Integrity Monitoring of Offshore Arctic Pipelines

Todd G. Cowin, G. Lanan, M. Paulin, D. Degeer
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Abstract

For safe and cost-efficient operations of new and existing offshore Arctic pipelines, monitoring of pipeline structural integrity is imperative. A well-founded pipeline integrity management program can optimize production output, extend the life of the pipeline, and serve as a tool for providing preventative maintenance information. Without the implementation of a routine integrity monitoring campaign, pipeline integrity degradation may go undetected until the point of failure. Arctic-specific offshore pipeline design and operational challenges, such as strudel scour, seabed ice gouge, pipeline upheaval buckling, permafrost thaw settlement, and remote location increase the risk and severity of a loss of pipeline integrity. These design cases can create abnormal conditions and ground deformations along sections of the pipeline which can be difficult to immediately detect through standard integrity monitoring systems and schedules. Many of the existing offshore pipelines in the Arctic are buried in remote locations under seasonal ice cover and the failure to detect pipeline damage in a timely manner could have severe safety, environmental, and economic consequences. An Arctic pipeline integrity monitoring philosophy can be implemented to provide further mitigation against loss of pipeline structural integrity by means of regular bathymetry surveys, In-Line Inspection (ILI) campaigns and Fiber Optic Cable (FOC) monitoring. This paper provides a guideline for buried offshore Arctic pipeline integrity monitoring. The guideline covers pipeline integrity assurance incorporated into the pipeline design, the surveys to be completed during installation, as-built assessment of the pipeline profile, the warm-up assessment/implementation needed before start-up, and the integrity inspections to be completed during operations.
北极近海管道完整性监测
为了安全和经济高效地运行新的和现有的北极海上管道,监测管道结构的完整性是必不可少的。一个完善的管道完整性管理程序可以优化生产产出,延长管道的使用寿命,并作为提供预防性维护信息的工具。如果没有实施常规的完整性监测活动,管道完整性的退化可能直到故障点才被发现。北极特定的海上管道设计和运营挑战,如结构冲刷、海底冰泥、管道隆起屈曲、永久冻土融化沉降和偏远位置,增加了管道完整性损失的风险和严重程度。这些设计案例可能会造成管道部分的异常情况和地面变形,而这些情况很难通过标准的完整性监测系统和时间表立即检测到。北极地区现有的许多海上管道都埋在季节性冰盖下的偏远地区,如果不能及时发现管道损坏,可能会造成严重的安全、环境和经济后果。可以实施北极管道完整性监测理念,通过定期测深测量、在线检查(ILI)活动和光纤电缆(FOC)监测,进一步缓解管道结构完整性的损失。本文为北极海上埋地管道完整性监测提供了指导。该指导方针涵盖了管道设计中的完整性保证、安装过程中需要完成的调查、管道外形的竣工评估、启动前需要的预热评估/实施,以及运行过程中需要完成的完整性检查。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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