控制水下跳桥的流激振动

R. Naik, Y. Urthaler, S. McNeill, Rafik Boubenider
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引用次数: 1

摘要

水下跳线的某些设计特点和操作条件可能会导致水下跳线的流动诱发振动(FIV)。在跳线使用寿命结束之前,过多的FIV会导致允许疲劳损伤的累积。因此,在墨西哥湾(GOM)发现FIV的大型开发项目中,实施了广泛的FIV管理计划。该程序由现场测量、建模和分析组成。选定的井和管线跳线都配备了水下仪器,用于专门的振动测试。为每个跳线建立了有限元模型,并对其进行了细化,以匹配从测量数据中提取的动态特性。然后使用改进的有限元模型和实测响应数据进行疲劳分析。如果分析结果得到保证,则采取措施减轻FIV的有害影响。关于建模和数据分析的详细内容见[5]。在此,我们将重点放在项目期间的总体发现和经验教训上。详细讨论了该计划的以下主题:1。2.现场振动测量整体振动随流量变化趋势,且FIV与流量强度(rho-v平方)缺乏相关性;3.。管线跳隔器与井跳隔器的振动和疲劳性能疲劳分析的保守性依赖于筛选计算或预测有限元分析可能导致过于保守的操作限制或在易受FIV影响的条件下的高度疲劳寿命不确定性。建议采用现场振动测量,然后根据运行条件对测量数据进行分析,这是获得水下跳线完整性的最佳实践,以确保水下系统安全可靠地运行。FIV管理项目的研究结果为水下行业提供了宝贵的见解,特别是在现役水下跳桥的完整性管理领域;现场仪器和振动测量以及与跳线FIV预测分析相关的限制。如果将这些经验反馈到水下设备的设计、分析和监测指南中,那么与目前的行业实践相比,FIV的理解和管理将大大提高。
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Managing Flow Induced Vibration in Subsea Jumpers
Certain subsea jumper design features coupled with operating conditions can lead to Flow Induced Vibration (FIV) of subsea jumpers. Excessive FIV can result in accumulation of allowable fatigue damage prior to the end of jumper service life. For this reason, an extensive FIV management program was instated for a large development in the Gulf of Mexico (GOM) where FIV had been observed. The program consisted of in-situ measurement, modeling and analysis. Selected well and flowline jumpers were outfitted with subsea instrumentation for dedicated vibration testing. Finite Element (FE) models were developed for each jumper and refined to match the dynamic properties extracted from the measured data. Fatigue analysis was then carried out using the refined FE model and measured response data. If warranted by the analysis results, action was taken to mitigate the deleterious effects of FIV. Details on modeling and data analysis were published in [5]. Herein, we focus on the overall findings and lessons learned over the duration of the program. The following topics from the program are discussed in detail: 1. In-situ vibration measurement 2. Overall vibration trends with flow rate and lack of correlation of FIV to flow intensity (rho-v-squared); 3. Vibration and fatigue performance of flowline jumpers vs. well jumpers 4. Fatigue analysis conservatism Reliance on screening calculations or predictive FE analysis could lead to overly conservative operational limits or a high degree of fatigue life uncertainty in conditions vulnerable to FIV. It is proposed that in-situ vibration measurements followed by analysis of the measured data in alignment with operating conditions is the best practice to obtain a realistic understanding of subsea jumper integrity to ensure safe and reliable operation of the subsea system. The findings from the FIV management program provide valuable insight for the subsea industry, particularly in the areas of integrity management of in-service subsea jumpers; in-situ instrumentation and vibration measurements and limitations associated with predictive analysis of jumper FIV. If learnings, such as those discussed here, are fed back into design, analysis and monitoring guidelines for subsea equipment, the understanding and management of FIV could be dramatically enhanced compared to the current industry practice.
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