利用人工智能工具优化钢懒波立管

M. Lal, A. Sebastian, Feng Wang, Xiaohua Lu
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引用次数: 2

摘要

随着石油和天然气开发发生在更深的水域或世界上没有管道基础设施的地区,钢制懒波立管的使用也在增加。这些开发项目利用了具有卸载能力的FPSO。然而,由于与其他浮式平台相比,传统的悬链线形式的立管不适合这种发展,这就是需要钢制懒波立管(SLWR)的原因。与钢制悬链线立管相比,SLWRs具有更好的强度和疲劳性能,并且在悬挂处具有更低的张力。通过有针对性地放置定制配置的浮力部分,可以实现合适的悬链线立管的懒波形式。钢懒波立管的强度和疲劳性能受该浮力段起始长度、浮力段长度、悬挂角和浮力系数等参数的影响。实现SLWR的这些关键性能驱动因素需要在整个设计过程中进行多次迭代。本文将遗传算法作为一种人工智能优化工具,用于自动生成钢懒波立管的优化结构。这将使隔水管设计人员能够加快隔水管的设计过程,以实现浮力段的最佳位置、覆盖范围和尺寸。将遗传算法程序产生的结果与改变关键性能驱动因素的钢懒波立管参数化研究进行了比较。参数分析采用规则波时域分析,捕捉钢懒波参数变化对强度和疲劳性能的影响趋势。
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Steel Lazy Wave Riser Optimization Using Artificial Intelligence Tool
Use of steel lazy wave risers has increased as oil and gas developments are happening in deeper waters or in parts of the world with no pipeline infrastructure. These developments utilize FPSO’s with offloading capabilities necessary for these developments. However, due to more severe motions compared to other floating platforms, traditional catenary form of risers are unsuitable for such developments and this is the reason Steel lazy wave risers (SLWR) are required. SLWRs have shown to have better strength and fatigue performance and lower tensions at the hang-off compared to steel catenary risers. A suitable Lazy-Wave form of the catenary riser is achieved by targeted placement of a custom configured buoyancy section. The strength and fatigue performance of steel lazy wave risers are governed by parameters such as length to start of this buoyancy section, length of the buoyancy section, hang-off angle and the buoyancy factor. Achieving these key performance drivers for a SLWR takes several iterations throughout the design process. In this paper, genetic algorithm which is an artificial intelligence optimization tool has been used to automate the generation of an optimized configuration of a steel lazy wave riser. This will enable the riser designer to speed up the riser design process to achieve the best location, coverage and size of the buoyancy section. The results that the genetic algorithm routine produces is compared to a parametric study of steel lazy wave risers varying the key performance drivers. The parametric analysis uses a regular wave time domain analysis and captures trends of change in strength and fatigue performance with change in steel lazy wave parameters.
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