立管机器人检测-降低安全风险,同时提高效率和有效性

Neré J. Mabile, Alessandro Vagata
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引用次数: 0

摘要

完整性管理是一个持续的生命周期过程,用于确保海上油气生产系统(包括立管)的安全运行和适合服务。立管提供了一种在海底油井和主平台之间输送流体的手段,通过飞溅区,这可能是腐蚀和暴露于外部损害的最关键区域。此外,由于它们靠近平台上的人员和上层设备,因此被认为是安全关键,因此,在对结果进行工程评估之后,需要进行计划检查。本文讨论了开发和实施一种基于创新机器人平台的新型、具有成本效益的防溅区立管检测方法的动机和业务驱动因素。概述了该机器人的技术特点和性能。传统上,隔水管的检查是由绳索接触技术人员和潜水员或水下机器人进行的,使用传统技术,如现场超声厚度测量、传统射线摄影和视觉评估。这种类型的检查是基于第一次视觉评估,然后只有在发现一些发现时才进行NDE测试。内部缺陷或涂层下的缺陷,例如飞溅,很容易被忽视,从而影响整个评估过程。此外,此类活动通常受到可达性、天气和船上人员(POB)住宿的限制,但主要是涉及检查员的安全风险。所提出的方法的核心是使用机器人履带,它具有自主检查立管的关键优势,可以通过夹子和支撑物等障碍物。该机器人可以携带各种有效载荷进行视觉检查、表面轮廓分析和无损检测,能够扫描有或没有涂层的大型表面,并检测内部和外部缺陷。它可以在立管的上部、飞溅区和海底部分运行。检查数据被实时处理,以便对资产的完整性进行即时评估。举例说明了传统检测方法与机器人自主检测方法的比较,证明了检测效果和效率的提高。本文还讨论了未来发展的潜在领域,包括人工智能(AI)算法,以进一步自动化立管检测和数据分析的过程和方法。
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Riser Robotic Inspection - Reducing Safety Risk While Improving Efficiency and Effectiveness
Integrity management is an ongoing lifecycle process for ensuring safe operation and fitness for service of offshore oil and gas production systems, including risers. Risers offer a means of transporting fluids between subsea wells and the host platform crossing the splash zone that is probably the most critical region for corrosion and exposure to external damages. Furthermore, with their proximity to the personnel on the platform and to the topside equipment, risers are considered safety critical, and are therefore, subject to planned inspections followed by an engineering assessment of the findings. This paper discusses the motivation and business driver for developing and implementing a new and cost effective risers’ inspection methodology in the splash zone based on innovative robotic platforms. The technical features and the capabilities of the robot are outlined. Traditionally, risers’ inspections are carried out by rope access technicians and divers or ROV below the water line using conventional technologies as spot ultrasonic thickness measurements, traditional radiography and visual assessment. This type of inspection is based on a first visual assessment followed by NDE testing only if some finding is spotted. Internal defects or defect under coating, e.g. splashtron, can be easily overlooked, compromising the entire assessment process. Additionally such activities are often limited by accessibility, weather, and Personnel On-Board (POB) accommodations, but primarily they involve risks to inspector's safety. Backbone of the presented methodology is the use of a robotic crawler that has the key advantage to inspect autonomously the risers, navigating over obstacles like clamps and supports. The robot can carry a variety of payloads for visual inspections, surface profiling, and NDE examinations with the ability to scan large surfaces with or without coating and detect internal and external defects. It can operate in the topside, splash zone and subsea sections of the riser. The inspection data are processed in real time for an immediate assessment of the integrity of the asset. Examples are presented and comparison is made between traditional inspection methodologies and robotic autonomous methodologies to demonstrate the improvement of inspection effectiveness and efficiency. The paper also discusses the potential areas of future development, which include Artificial Intelligence (AI) algorithms to further automatize the process and methodologies of risers’ inspection and data analysis.
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