Flexible Joint Stiffness Modelling Improving Ultra Deep Water Rigid Risers Fatigue Damage

G. Venero, Victor Gomes, Hugues Corrignan, D. Carneiro
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Abstract

Fatigue is one of the key governing conditions in the design of rigid risers, in particular those in ultra-deep water. One effective way of improving fatigue is to adopt a lazy wave configuration, rather than a simple catenary. Steel Lazy Wave Risers (SLWR) have been successfully used offshore Brazil (Hoffman et al. 2010, Oliveira et al. 2017) and in the Gulf of Mexico (Beattie et al. 2013), and have been considered for the North Sea (Felista et al. 2015) and offshore Australia (Vijayaraghavan et al. 2015). Yet, it is probably the most computational-intensive aspect of it. Fatigue analyses require a very large number of load cases to be run, on complex, non-linear models. Methods for simplifying aspects of the analysis are highly desirable, but they must be weighed to provide the required safety levels whilst not introducing uneconomical, overconservative assumptions. The top first weld is a crucial hotspot, in particular for production SLWRs (Senra et al. 2011). These typically adopt flexible joints (FJ) at the connection to the vessel/platform, and linearization of the FJ stiffness is one of these key simplifications that bring significant value in reducing analysis cost. This paper describes a method for estimating the characteristic angle used for the linearization, which results in significant stiffness reduction in contrast with the usual, simpler method. Non-linear FJ stiffness curves are usually available, and they provide stiffness associated to the FJ absolute angle. The FJ stiffness significantly reduces with the angle of rotation. The conventional method adopts the stiffness corresponding to the most likely riser angle – absolute value measured from the static configuration. Conversely, the proposed methodology for estimating the most likely change in angle. As the angles often turn up in alternate angles, the proposed method results in much higher characteristic angle, and hence much lower FJ stiffness. The outcome is significantly less conservative designs, whilst still meeting the same required safety margins.
柔性接头刚度建模改善超深水刚性隔水管疲劳损伤
疲劳是刚性隔水管设计的关键控制条件之一,特别是在超深水中。改善疲劳的一种有效方法是采用懒波结构,而不是简单的悬链线。钢制缓波立管(SLWR)已成功应用于巴西近海(Hoffman等人,2010年,Oliveira等人,2017年)和墨西哥湾(Beattie等人,2013年),并已被考虑用于北海(Felista等人,2015年)和澳大利亚近海(Vijayaraghavan等人,2015年)。然而,它可能是计算最密集的方面。疲劳分析需要在复杂的非线性模型上运行大量的载荷情况。简化分析方面的方法是非常可取的,但必须加以权衡,以提供所需的安全水平,同时不引入不经济、过度保守的假设。顶部第一个焊缝是一个关键的热点,特别是对于生产slwr (Senra et al. 2011)。这些方法通常采用柔性接头(FJ)连接容器/平台,而柔性接头刚度的线性化是这些关键简化方法之一,可以显著降低分析成本。本文描述了一种估计用于线性化的特征角的方法,与通常的、更简单的方法相比,该方法可以显著降低刚度。非线性FJ刚度曲线通常是可用的,它们提供了与FJ绝对角度相关的刚度。FJ刚度随旋转角度的增大而显著减小。传统的方法采用最可能的立管角所对应的刚度-从静态结构中测量的绝对值。相反,建议的方法估计最可能的角度变化。由于角度经常以交变角度出现,因此提出的方法可以获得更高的特征角,从而大大降低FJ刚度。其结果是明显不那么保守的设计,同时仍然满足相同的安全边际要求。
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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