考虑全局和局部影响的井口疲劳分析

Filipe A. Rezende, G. Lopes, F. Sousa, J. Sousa, C. E. Fonseca, J. Percy
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引用次数: 1

摘要

在钻井作业期间,井口系统和顶孔套管的设计应能够承受从连接的隔水管到防喷器组/LMRP的动态载荷。由于动态运动与应力变化有关,疲劳成为设计师关注的主要问题。井口和邻近区域的损害累积取决于几个方面,例如立管组件、土壤-导体和导体-地面套管的相互作用,当然还有环境条件。因此,疲劳分析涉及复杂的数值模型,需要模拟大量的载荷情况。本文的目的是估计顶井套管和井口关键部件的疲劳损伤。研究了两种不同的方法。首先在时域(TD)上分析全局模型,并采用雨流循环计数法计算疲劳损伤;全局模型包括钻井隔水管、井口、套管、部件之间以及与土壤的相互作用。其次,对同一模型进行频域分析,采用Dirlik方法计算疲劳损伤;此外,为了更好地评估复杂几何区域的应力,使用TD方法获得的力和力矩与通过局部模型和符号回归(SR)分析定义的载荷-应力传递函数相结合。局部模型包括压力外壳的详细3D模型,以及土壤与外壳的相互作用。所得结果表明,压力外壳对疲劳不敏感,并且所进行的分析是可行的,有助于降低井口疲劳评估的计算成本。
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Wellhead Fatigue Analysis Considering Global and Local Effects
During drilling operations, the wellhead system and top hole casings shall be designed to support dynamic loads from the connected riser through the BOP stack/LMRP. As dynamic motions are associated to stress variations, fatigue becomes a major concern for designers. The accumulation of damage at the wellhead and close regions is dependent on several aspects, such as the riser components, the interactions soil-conductor and conductor-surface casing, and of course the environmental conditions. Consequently, fatigue analysis involves complex numerical models and requires the simulation of a huge number of loading cases. The present paper aims to estimate the fatigue damage at critical components of the top hole casings and at the wellhead. Two different approaches were investigated. In the first, a global model is analyzed in the time domain (TD), and the Rainflow cycle counting method is used to calculate fatigue damage. The global model includes the drilling riser, wellhead, casings, and interactions between components and with soil. In the second, the same model is analyzed in the frequency domain (FD), and the Dirlik method is used to calculate fatigue damage. Additionally, to allow a better evaluation of stresses at complex geometry regions, forces and moments obtained using the TD methodology were combined with load-to-stress transfer functions, defined by means of a local model and symbolic regression (SR) analysis. The local model includes a detailed 3D model of the pressure housings, and soil-to-casing interaction. The obtained results indicate that the pressure housings are not sensitive to fatigue, and also that the analyses performed are feasible, contributing to reduce computational costs in wellhead fatigue assessments.
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