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基于管体变形实时监测的挠性接管寿命评估方法
Research on the evaluation method of the filament-wound flexible pipe's life based on the real-time monitoring the deformation of the pipe body

DOI:
作者:
范宇琦1,2, 吕志强1,2, 卜文俊1,2
FAN Yu-qi1,2, LV Zhi-qiang1,2, BU Wen-jun1,2
作者单位:
1. 海军工程大学 船舶振动噪声重点实验室,湖北 武汉 430033;
2. 海军工程大学 振动与噪声研究所,湖北 武汉 430033
1. National Key Laboratory on Ship Vibration and Noise, Naval University of Engineering, Wuhan 430033, China;
2. Institute of Noise and Vibration, Naval University of Engineering, Wuhan 430033, China
关键词:
凯夫拉纤维增强型挠性接管;电阻感应原理;光纤光栅传感原理;有限元仿真;特征阈值
filament-wound flexible pipe; the principle of resistance induction; the principle of fiber bragg grating sensing; finite element simulation; characteristic threshold
摘要:
针对凯夫拉纤维增强型挠性接管(FW-FP)管体发生局部异常变形而导致管体破裂失效的问题,提出一种基于管体变形实时监测的挠性接管寿命评估方法。融合电阻感应原理和光纤光栅(FBG)传感原理,在建立管体结构模型的基础上,采用数值计算和有限元仿真方法,对管体轴向变形、径向变形、充压变形及局部异常变形特性进行分析,提取出区分管体正常变形和局部异常变形的特征阈值。该方法能够有效识别管体的局部异常变形,实时评估挠性接管的工作寿命。
Aiming at the problem of the failure of the pipe body by the local abnormal deformation of the filament-wound flexible pipe (FW-FP). an evaluation method of the FW-FP's life based on the real-time monitoring the deformation of the pipe body is proposed. the principle of resistance induction and the principle of fiber Bragg grating sensing are fused, on the basis of establishing the model of the FW-FP's structure, numerical calculation and finite element simulation are used, the axial deformation, radial deformation, compaction deformation and local abnormal deformations’ characteristics of the pipe body are analyzed, the characteristic threshold of normal deformation and local abnormal deformation is extracted. The method can effectively identity the FW-FP's local abnormal deformation, and the FW-FP's service life can be real-time judged.
2020,42(5): 120-126 收稿日期:2018-10-18
DOI:10.3404/j.issn.1672-7649.2020.05.023
分类号:U662
基金项目:国家自然科学基金资助项目(51209214);海军工程大学科研发展基金资助项目(425517K031)
作者简介:范宇琦(1994-),男,硕士研究生,研究方向为噪声与振动
参考文献:
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