Cathodic Protection Design Consideration for an Offshore Flexible Riser Connected to an Impressed Current System

Thierry Dequin, C. Weldon, M. Hense
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Abstract

Flexible risers are regularly used to produce oil and gas in subsea production systems and by nature interconnect the subsea production system to the floating or fixed host facilities. Unbonded flexible pipes are made of a combination of metallic and non-metallic layers, each layer being individually terminated at each extremity by complex end fittings. Mostly submerged in seawater, the metallic parts require careful material selection and cathodic protection (CP) to survive the expected service life. Design engineers must determine whether the flexible pipe risers should be electrically connected to the host in order to receive cathodic protection current or be electrically isolated. If the host structure is equipped with a sacrificial anode system, then electrical continuity between the riser and the host structure is generally preferred. The exception is often when the riser and host structure are operated by separate organizations, in which case electrical isolation may be preferred simply to provide delineation of ownership between the two CP systems. The paper discusses these interface issues between hull and subsea where the hull is equipped with an impressed current cathodic protection (ICCP) system, and provides guidance for addressing them during flexible pipe CP design, operation, and monitoring. Specifically, CP design philosophies for flexible risers will be addressed with respect to manufacturing, installation and interface with the host structure’s Impressed Current Cathodic Protection (ICCP) system. The discussion will emphasize the importance of early coordination between the host structure ICCP system designers and the subsea SACP system designers, and will include recommendations for CP system computer modeling, CP system design operation and CP system monitoring. One of the challenges is to understand what to consider for the exposed surfaces in the flexible pipes and its multiple layers, and also the evaluation of the linear resistance of each riser segment. The linear resistance of the riser is a major determinant with respect to potential attenuation, which in turn largely determines the extent of current drain between the subsea sacrificial anode system and the hull ICCP system. To model the flexible riser CP system behavior for self-protection, linear resistance may be maximized, however the use of a realistic linear resistance is recommended for evaluation of the interaction between the host structure and subsea system. Realistic flexible linear resistance would also reduce conservatism in the CP design, potentially save time during the offshore campaign by reducing anode quantities, and also providing correct evaluation of drain current and stray currents.
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连接外加电流系统的海上柔性立管阴极保护设计考虑
柔性立管通常用于海底生产系统中的油气生产,并将海底生产系统与浮式或固定主机设施连接起来。无粘结柔性管由金属层和非金属层组合而成,每一层通过复杂的端件分别在两端端接。金属部件大多浸没在海水中,需要仔细的材料选择和阴极保护(CP)来维持预期的使用寿命。设计工程师必须确定软管立管是否与主机电连接,以便接收阴极保护电流或进行电隔离。如果主机结构配有牺牲阳极系统,那么立管与主机结构之间的电气连续性一般是首选的。例外情况通常是当立管和主机结构由不同的组织操作时,在这种情况下,电气隔离可能只是为了在两个CP系统之间提供所有权的描述。本文讨论了船体与海底之间的接口问题,并为柔性管CP设计、操作和监控过程中解决这些问题提供了指导。具体来说,柔性立管的CP设计理念将涉及到制造、安装以及与主机结构的外加电流阴极保护(ICCP)系统的接口。讨论将强调主机结构ICCP系统设计人员与海底SACP系统设计人员之间早期协调的重要性,并将包括CP系统计算机建模、CP系统设计操作和CP系统监控的建议。其中一个挑战是要了解如何考虑柔性管及其多层的暴露表面,以及评估每个立管段的线性阻力。立管的线性电阻是电位衰减的主要决定因素,这反过来又在很大程度上决定了海底牺牲阳极系统和船体ICCP系统之间的电流泄漏程度。为了模拟柔性立管CP系统的自我保护行为,可以最大化线性电阻,但建议使用实际的线性电阻来评估主机结构与海底系统之间的相互作用。现实的柔性线性电阻还可以减少CP设计的保守性,通过减少阳极数量,可能节省海上作业期间的时间,并且还可以正确评估漏极电流和杂散电流。
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