海底智能电气控制单元,用于建造更智能、更便宜的海底硬件

M. York, Ben Alexander, Todd Holtz, A. J. Schroeder, J. Chitwood
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引用次数: 0

摘要

海底生产系统和过程通常使用液压控制,最近使用电液控制。这些系统的部署变得复杂且昂贵,特别是随着回接长度的增加、深水安装的增加和环境的挑战。电动和控制设备已经成为陆上和海上设备的标准。开发一种模块化且易于封装的海底电气控制单元,对于将电气监测和控制的优势发挥到海底生产系统和过程中,以及许多其他干预应用(如海底化学储存和注入)是不可或缺的。除了简化和降低这些系统的成本外,该装置还能够识别终端组件的健康状况和状态,从而为现场调整或修改操作提供机会,在某些情况下,还可以实时提供其他好处。正在开发由高级分析和人工智能(AI)驱动的新分析技术,以更详细地检查受控制设备的运行状态,推断其当前健康状态,甚至预测未来性能和维护/维修需求。随着收集和分析的数据越来越多,分析和预测的可预见性和准确性也越来越高。将本文中介绍的新开发的全电动海底控制器单元与先进的数据分析相结合,将降低海底系统的操作成本和风险。根据多年来在API RP 17H 2级扭矩设备和变速海底泵方面的经验,该系统被设计成一种简单、坚固、可靠的设备。它利用具有位置限制的串行通信,具有闭环速度/位置控制,转矩控制和实时转矩限制。分析功能有助于建立阀门和泵的状态、功能和健康监测。该工具非常适合在水下应用10,000 fsw,适用于任何需要250 ft -lbs的应用。具有位置和变速控制。借鉴核工业及其监管机构的经验,这种“无弹簧”装置包括一个“智能电池”(锂离子)备用选项,用于指定的故障安全定位和监测。技术规范由运营商客户驱动。制定了一整套功能设计规范(FDS)以及检验和测试质量计划(ITP)。在可行的情况下,验收标准从API、ASME和其他行业指南中得到借鉴。一个全尺寸的原型装置已经建成,经过了超过100万次的循环测试和合格。该单元能够从一个或多个终端设备和一个或多个控制端点收集感测到的运行数据,计算和执行分析,并报告一个或多个终端设备和一个或多个控制端点的运行状况和状态。目前,它被应用于一个常见的工业水下球阀,集成到水下化学储存和注入系统中,以及变速水下化学注入泵的驱动器中。美国监管机构已被纳入资格见证。
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Subsea Smart Electric Control Unit for Building Smarter and Cheaper Subsea Hardware
Subsea production systems and processes are generally conducted using hydraulic and more recently electro-hydraulic controls. These systems have become complex and expensive to deploy, especially with increasing length of tie-backs, more deepwater installations and challenging environments. Electrically powered and controlled equipment has become the standard for onshore and topsides equipment. Developing a subsea electric control unit that is modular and easily packaged is integral to leveraging the benefits of electric monitoring and control into subsea production systems and processes, as well as many other intervention applications such as subsea chemical storage and injection. In addition to simplifying and reducing costs of these systems, the unit will be able to discern an end component's health and status providing an opportunity to adjust or modify the operation in-situ, and in some instances real-time as well as provide other benefits. New analytical techniques powered by advanced analytics and artificial intelligence (AI) are being developed to examine in greater detail the controlled equipment's operational status, infer its current state of health and even predict future performance and maintenance/repair needs. As more and more data are collected and analyzed, the predictability and accuracy of the analysis and prediction improves. Coupling the newly developed all electric subsea controller unit described in this paper with advanced data analytics will lower operator costs and risks in subsea systems. the system presented herein has been designed as a simple, rugged and reliable piece of equipment based on years of experience with API RP 17H Class 2 torque equipment and variable speed subsea pumps. It utilizes serial communications with position limiting and has a closed loop speed/position control, torque control, and real-time torque limiting. The profiling feature helps establish valve and pump status, functionality and health monitoring. The tool is ideally suited for subsea application to 10,000 fsw for any application requiring up to 250 ft.-lbs. with position and variable speed control. Leveraging learnings from the nuclear industry and their regulators, this ‘spring-less’ unit includes an option for a ‘smart battery’ (Lithium ion) back-up for specified fail-safe positioning and monitoring. Technical specifications were driven by operator customers. A full set of Functional Design Specs (FDS) were developed as well as an Inspection and Test Quality Plan (ITP). Where practical, acceptance criteria were leveraged from API, ASME and other industry guidance. A full-scale prototype unit has been built, tested and qualified with over 1 million cycles. The unit enables collecting sensed operating data from one or more end devices and one or more control end points, calculating and performing analytics, and reporting health and status of the one or more end devices and one or more control end points. It is currently being utilized on a common industry subsea ball valve, integrated into a subsea chemical storage and injection system as well as a drive for a variable speed subsea chemical injection pump. Regulator authorities in the U.S. have been included in the qualification witnessing.
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