Making the Connection for Well Control on Floaters: Evolving Design Rationales for BOP Control Systems

IF 1.6 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Scientific Drilling Pub Date : 2018-10-31 DOI:10.5772/INTECHOPEN.77998

P. A. Potter

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Abstract

In this chapter, a broad technical overview is offered to illustrate the technological advancements that have made the original direct hydraulic system reach those system design features that are shown in figure overleaf, which is a modern general arrangement of the “multiplexing” type of the BOP control system. Behind each discrete advancement, it goes without saying, there was a lot of design work, influenced by the radically differ - ent conditions in the subsea marine environment than those that we experience on land. Each step of this enabling technology is reviewed with in-depth reasoning explaining the “whys” and “wherefores” of each particular development. Let us start, as the drilling industry did for the development of BOP designs, at the beginning of the industry’s step offshore around 60 years ago. Not least, it should be emphasized that the ways in which the systems’ architecture has evolved have, in large part, been “driven” by the statutes laid out by the American Petroleum Institute (API) and later by other class societies that govern design compliance within the industry. The learning objectives of this chapter are to provide factual insights into evolving BOP control system designs as the indus try moved from onshore to offshore and subsequently from bottom-supported drilling installations to floating drilling installations. This technology also forms the basis of the underpinning principles of hydraulic/electro and multiplexing subsea control systems that are currently used in the control of all kinds of production trees, subsea production centers, subsea distribution, and pipe line end manifolds (PLEMs). This chapter can be considered as a foundation and introductory overview for the development of control systems used in the subsea environment and those engineering challenges and obstacles that have been successfully surmounted, resulting in the technology basis in use today in the manufacture of subsea control systems.

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浮子的井控连接:BOP控制系统设计原理的演变

在本章中，提供了一个广泛的技术概述来说明技术进步，这些技术进步使原始的直接液压系统达到了背页图所示的系统设计特征，这是“多路复用”型防喷器控制系统的现代总体安排。毋庸置疑，在每一个独立的进步背后，都有大量的设计工作，这些工作受到海底海洋环境与陆地环境截然不同的影响。通过深入的推理来解释每个特定开发的“原因”和“原因”，对该支持技术的每个步骤进行了回顾。让我们从60年前开始，就像钻井行业开始开发防喷器设计一样。值得强调的是，系统架构发展的方式在很大程度上是由美国石油协会(API)制定的法规以及后来由行业内管理设计遵从性的其他阶级协会所“驱动”的。本章的学习目标是，随着行业从陆上转向海上，以及随后从底部支撑式钻井装置转向浮式钻井装置，为不断发展的防喷器控制系统设计提供实际见解。该技术还构成了液压/电子和多路复用水下控制系统的基础原理，这些系统目前用于控制各种采油树、海底生产中心、海底配电和管道端歧管(PLEMs)。本章可以被视为海底环境中使用的控制系统开发的基础和介绍性概述，以及那些已经成功克服的工程挑战和障碍，从而形成了今天在海底控制系统制造中使用的技术基础。

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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