Design Challenges of SCRs in Deepwater and Ultra Deepwater

Yongming Cheng, Chen Yu, Hao Song
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Abstract

A riser is a fluid conduit connecting from a subsea well to a surface floating production vessel such as a spar, TLP, or a semi-submersible. It is a key component for transporting produced oil and gas from the subsea wells to the surface production vessel. Through nearly 30 years of design and implementation, Steel Catenary Risers (SCRs) have been found to have the advantages of relatively low manufacturing cost and good adaptability to floating platform’s motion. Thus, SCRs are widely used in GoM and Brazilian water. This paper investigates design challenges of SCRs used for a semi-submersible in deepwater and ultra deepwater. As the application moves to deepwater and ultra deepwater, challenges of a conventional SCRs increase significantly in terms of global performance, fabrication, and installation. This paper first introduces an SCR system used for a semi-submersible platform. One of the challenges is the harsh environmental condition such as hurricanes or tropical cyclones. Severe motions of a semi-submersible platform may cause significant compression loads on SCRs at the Touch Down Zone (TDZ). It is challenging to design the SCRs to meet API RP 2RD requirement for the riser dynamic strength. Multiple seeds of random motion simulations for irregular wave are necessary for the evaluation. The new riser design code of API STD 2RD can also be used to assess riser strength, especially under 1000-yr survival environmental conditions. It is challenging to design SCRs to meet a design life of 30 years and beyond. The fatigue assessment of the SCRs considers the damage contributions from the semi wave motions, riser Vortex-Induced Vibration (VIV) due to ambient current, and Vortex-Induced Motion (VIM) of a semi-submersible platform. Fatigue contribution from installation is also considered and included in the combined fatigue damage calculation. The long term combined factored fatigue life is computed to ensure that the SCRs meet the requirement of design life. This paper further investigates intermittent Vortex-Induced Vibration (VIV) caused by heave motions of a semi-submersible platform. This VIV phenomenon has an impact on SCR strength due to the drag amplification as well as fatigue damage. The installation concerns come from riser pipe size, installation method and capacity of an installation vessel. Examples are provided for illustrations of the design challenges. In addition, this paper explores likely solutions to meet SCR design challenges for the applications in deepwater and ultra deepwater.
深水和超深水scr的设计挑战
立管是一种流体管道,将海底油井连接到水面浮式生产船(如桅杆、张力腿平台或半潜式作业船)。它是将产出的石油和天然气从海底井输送到地面生产船的关键部件。通过近30年的设计与实施,发现钢链链立管具有制造成本相对较低、对浮式平台运动适应性较好的优点。因此,scr在墨西哥湾和巴西水域得到了广泛的应用。本文研究了用于深水和超深水半潜式平台的scr的设计挑战。随着应用向深水和超深水领域发展,传统scr在全球性能、制造和安装方面面临的挑战显著增加。本文首先介绍了一种用于半潜式平台的可控硅系统。其中一个挑战是恶劣的环境条件,如飓风或热带气旋。半潜式平台的剧烈运动可能会对触地区(TDZ)的scr造成巨大的压缩载荷。设计scr以满足API RP 2RD对立管动态强度的要求是一项挑战。对不规则波进行多种子随机运动模拟是评估的必要条件。新的立管设计规范API STD 2RD也可用于评估立管强度,特别是在1000年的生存环境条件下。设计scr以满足30年及以上的设计寿命是一项挑战。scr的疲劳评估考虑了半波运动、环境电流引起的隔水管涡激振动(VIV)和半潜式平台涡激运动(VIM)的损伤贡献。在组合疲劳损伤计算中也考虑了安装对疲劳的贡献。计算了scr的长期组合疲劳寿命,保证了scr满足设计寿命要求。本文进一步研究了半潜式平台升沉运动引起的间歇涡激振动。由于阻力放大和疲劳损伤,这种涡激振动现象对可燃硅的强度产生影响。安装问题来自立管尺寸、安装方法和安装船的容量。举例说明了设计挑战。此外,本文还探讨了在深水和超深水应用中应对SCR设计挑战的可能解决方案。
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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