Finite Element Analysis for Vibration Mechanical Behavior of Tubing String in Gas Wells under Extreme Conditions

Xinjiang Oil & Gas ›› 2021, Vol. 17 ›› Issue (3): 59-66.

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Finite Element Analysis for Vibration Mechanical Behavior of Tubing String in Gas Wells under Extreme Conditions

LIAN Zhanghua, MOU Yisheng, ZHANG Qiang

State Key Laboratory of Oil & Gas Reservoir Geology and Exploitation,Southwest Petroleum University,Chengdu 610500,Sichuan,China

Online:2021-09-10 Published:2021-09-10

极端条件下气井油管柱振动力学行为的有限元分析

练章华, 牟易升, 张强

西南石油大学油气藏地质及开发工程国家重点实验室,四川成都 610500

通讯作者: 牟易升（1992-）,2018年毕业于西南石油大学石油工程专业,硕士学位,现在该校读油气井工程博士学位,主要研究方向为油气井管柱力学、钻柱疲劳损伤与控制等。（Tel）15928758120（E-mail） 479824223@qq.com
作者简介:练章华（1964-）,1994年毕业于西南石油学院机械工程专业,博士学位,教授,博士生导师,主要从事CAD/CAE/CFD、套管损坏机理、管柱力学及射孔完井等教学与科研工作。（Tel）13308072813（E-mail）cwctlzh@swpu.edu.cn
基金资助:
国家自然科学2020-2023年“极端条件下气井管柱耦联振动力学行为与控制基础理论研究”（编号：51974271）

Abstract

Abstract: In order to systematically and quantitatively analyze the vibration mechanical behavior of tubing string in gas wells under extreme conditions,two finite element mechanical models were established according to the tubing string structures and sizes of an oilfield in Xinjiang for the vibration of tubing string with packers under the said conditions using finite element method. APDL finite element program was compiled,by which the vibration problems of such tubing string were systematically analyzed and studied. Study findings show that ① After comparing the first 15th modes and frequencies of two string structures,it was found that the improved structure could mitigate the damage of vibration to tubing string. ② In respect of transient dynamic response,the improved structure made the average stress in high-risk string section (4 200-5 500 m) reduce by about 104 MPa,and the neutral point moved down by 231 m,which are conducive to improving the safety and fatigue life of string. It is concluded that the established model can be used to analyze the string vibration mode,inherent frequency,and stress,velocity and displacement that change with time,providing quantitative basis for the fatigue life prediction,neutral point change and vibration mechanical mechanism of tubing string in gas wells under extreme conditions,as well as theoretical basis for tubing string design of new wells.

Key words: ultra-deep well, tubing string, vibration mechanics, finite element method, mode, fatigue life, transient dynamics

摘要： 为了系统地、定量地分析极端条件下气井油管柱振动力学行为,根据新疆某油田油管柱结构尺寸,基于有限元法,建立了两种结构带封隔器的极端条件气井油管柱振动有限元力学模型,编写了极端条件下气井油管柱的振动动力学行为分析的APDL有限元程序,对该极端条件下气井管柱振动问题开展了系统分析和研究。研究表明：①对比改进前后管柱结构的前15阶模态和频率,改进后油管柱均有利于减缓振动对油管柱的损伤;②在瞬态动力响应方面,改进后的结构对事故高发（4 200~5 500 m）油管段内平均应力降低了约104 MPa,同时中和点也下移了231 m,均有利于提高极端条件下气井油管柱安全性及其疲劳寿命。结论表明,建立的模型可分析油管柱的振型,固有频率以及随时间历程变化的应力、速度、位移等,为极端条件下气井油管柱疲劳寿命预测、中和点变化以及油管柱在采气期间的振动力学机理提供定量的数据,同时为新井管柱设计提供了理论依据。

关键词: 超深井, 油管柱, 振动力学, 有限元法, 模态, 疲劳寿命, 瞬态动力学

CLC Number:

TE319

LIAN Zhanghua, MOU Yisheng, ZHANG Qiang. Finite Element Analysis for Vibration Mechanical Behavior of Tubing String in Gas Wells under Extreme Conditions[J]. Xinjiang Oil & Gas, 2021, 17(3): 59-66.

练章华, 牟易升, 张强. 极端条件下气井油管柱振动力学行为的有限元分析[J]. 新疆石油天然气, 2021, 17(3): 59-66.

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Finite Element Analysis for Vibration Mechanical Behavior of Tubing String in Gas Wells under Extreme Conditions

极端条件下气井油管柱振动力学行为的有限元分析

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