Optimization of Frequency Domain Fatigue Analysis for Unbonded Flexible Risers

Jiabei Yuan, Yucheng Hou, Z. Tan
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Abstract

Fatigue analysis of flexible risers is a demanding task in terms of time and computational resources. The traditional time domain approach may take weeks of time in global simulation, local modelling and post-processing of riser responses to get fatigue results. Baker Hughes developed a fast hybrid approach, which is based on a frequency domain technique. The new approach was first implemented at the end fitting region and then to all other regions of the riser. Studies showed that the hybrid approach achieved convenient and conservative results in a significant shorter period of time. To improve the accuracy and reduce conservatism of the method, Baker Hughes has further optimized the analysis procedure to seek better results approaching true solutions. Several methods were proposed and studied. The duration of representative cases and noncritical cases have been extended. The steps to predict stress spectrum based on transfer functions have also been updated. From previous studies, only one transfer function was built for fatigue load cases with similar response spectra. This assumption linearizes the system response and produces certain level of discrepancy against true time domain solution. In this study, multiple ways of spectrum prediction are evaluated and compared. The paper summarizes several techniques to further optimize the hybrid frequency domain approach. The updated fatigue results are found to be more accurate. The optimized approach therefore gives more flexibility to engineers to approach the true solutions, which were originally acquired from full 3-hr time domain simulations. The approach requires less analysis time and reduces iterations in pipe structure and riser configuration design, which leads to faster project execution and potential cost reduction.
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无粘结柔性隔水管频域疲劳分析优化
柔性立管的疲劳分析在时间和计算资源方面要求很高。传统的时域方法可能需要数周的时间进行全局模拟、局部建模和隔水管响应的后处理,才能得到疲劳结果。贝克休斯开发了一种基于频域技术的快速混合方法。新方法首先在末端拟合区域实施,然后在立管的所有其他区域实施。研究表明,混合方法在较短的时间内获得了方便和保守的结果。为了提高方法的准确性和降低保守性,贝克休斯进一步优化了分析程序,寻求更接近真解的结果。提出并研究了几种方法。代表性案例和非关键案例的持续时间有所延长。基于传递函数预测应力谱的步骤也进行了更新。从以往的研究来看,对于具有相似响应谱的疲劳载荷情况,只建立了一个传递函数。这种假设使系统响应线性化,并与真实的时域解产生一定程度的差异。本研究对多种频谱预测方法进行了评价和比较。本文总结了进一步优化混合频域方法的几种技术。更新后的疲劳计算结果更为准确。因此,优化的方法为工程师提供了更大的灵活性,以接近真正的解决方案,这些解决方案最初是从完整的3小时时域模拟中获得的。该方法需要更少的分析时间,减少了管道结构和立管配置设计的迭代,从而加快了项目的执行速度,降低了潜在的成本。
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