黎 伟^1*， 陈 曦¹， 夏 杨¹， 李玉民²， 张 建³， 肖 勇⁴

1. 石油天然气装备教育部重点实验室(西南石油大学)，四川 成都 6105002. 中石化中原石油工程有限公司管具公司，河南 濮阳 4573003. 中国石油辽河油田分公司钻采工艺研究院油井防砂中心，辽宁 盘锦 1240104. 中国石油集团川庆钻探工程有限公司井下作业公司，四川 成都 610051

收稿日期:2019-04-24修回日期:2019-06-05出版日期:2020-02-22发布日期:2020-02-19
通讯作者:陈曦

基金资助:双梯度钻井套管内压力梯度隔断封隔器研究

Finite element analysis of anti-extrusion strength of machined hole casing

Wei LI^1*, Xi CHEN¹, Yang XIA¹, Yumin LI², Jian ZHANG³, Yong XIAO⁴

1. Key Laboratory of Oil and Gas Equipment, Ministry of Education, Southwest Petroleum University, Chengdu, Sichuan 610500, China2. Drilling Tubes & Tools Service Company of Zhongyuan Oilfield Service Corporation of Sinopec, Puyang, Henan 457300, China3. Drilling and Production Technology Research Institute of Liaohe Oilfield, Panjin, Liaoning 124010, China4. Downhole Service Company, CNPC Chuanqing Drilling Engineering Company Limited, Chengdu, Sichuan 610051, China

Received:2019-04-24Revised:2019-06-05Online:2020-02-22Published:2020-02-19

摘要/Abstract

摘要： 套管屈服强度直接影响套管抗挤压性能，套管在加工孔过程中可能诱发孔眼附近材料发生金属相变，导致套管屈服强度不再均匀分布，进而影响套管抗挤压强度。在相同工况下，对比了P110完整套管和机加工孔套管的抗挤压强度，以此为参照组分析了相变区域面积和相变区域屈服强度对机加工孔套管抗挤压强度的影响。结果表明，机加工孔会改变材料屈服强度，进而影响套管抗挤压性能。随金属相变区域屈服强度减小，机加工孔套管抗挤压强度减弱；当金属相变区域屈服强度增大时，机加工孔套管抗挤压强度增强。且机加工孔套管相变区域面积对机加工孔套管抗挤压强度的影响随相变区域屈服强度增加而逐渐削弱。

引用本文

黎伟 陈曦 夏杨 李玉民 张建 肖勇. 机加工孔套管抗挤压强度有限元分析[J]. 过程工程学报, 2020, 20(2): 189-196.
Wei LI Xi CHEN Yang XIA Yumin LI Jian ZHANG Yong XIAO. Finite element analysis of anti-extrusion strength of machined hole casing[J]. Chin. J. Process Eng., 2020, 20(2): 189-196.

使用本文

0
/ / 推荐
导出引用管理器 EndNote|Ris|BibTeX
链接本文:http://www.jproeng.com/CN/10.12034/j.issn.1009-606X.219186
http://www.jproeng.com/CN/Y2020/V20/I2/189

参考文献

[1] 贾曦雨,王树山,马峰,唐凯,陈华彬,马小强,潘德凯.射孔冲击相变对射孔套管抗挤性能的影响[J].石油学报,2017,38(03):348-355. Jia Yuyu, Wang Shushan, Ma Feng, Tang Kai, Chen Huabin, Ma Xiaoqiang, Pan Dekai.Influence of perforation impact phase change on the anti-squeezing performance of perforated casing[J].Acta Petrolei Sinica,2017,38(03):348-355. [2] 张立民.冀东油田出砂井射孔套管变形分析[J].石油钻采工艺,2013,35(05):71-73. Zhang Limin.Analysis of the deformation of perforated casing in sand production well in Jidong Oilfield[J].Oil Drilling & Production Technology,2013,35(05):71-73. [3] 许爱荣,邹云,杨向同,窦益华.内压作用下含裂纹射孔套管临界开裂应力分析[J].石油机械,2012,40(04):22-25. Xu Airong,Zou Yun,Yang Xiangtong,Dou Yihua.Analysis of critical cracking stress of perforated casing with crack under internal pressure[J].Petroleum Machinery,2012,40(04):22-25. [4] 丁祖鹏,罗艳艳,韩彬,邓彩凤.射孔对套管抗挤强度的影响分析与试验[J].钻采工艺,2016,39(04):15-18+2. Ding Zupeng,Luo Yanyan,Han Bin,Deng Caifeng.Analysis and Experiment of Influence of Perforation on Squeezing Strength of Casing[J].Drilling & Production Technology,2016,39(04):15-18+2. [5] 佟光军,胡知辉,于莉,唐彪.深水海底管道屈曲扩展非线性有限元分析[J].石油工程建设,2018,44(05):11-15+65. Shu Guangjun,Hu Zhihui,Yu Li,Tang Wei.Nonlinear finite element analysis of buckling expansion of deepwater submarine pipeline[J].Petroleum Engineering Construction,2018,44(05):11-15+65. [6] Roberto Casado-Vara,Pablo Chamoso,Fernando De la Prieta,Javier Prieto,Juan M. Corchado. Non-linear adaptive closed-loop control system for improved efficiency in IoT-blockchain management[J]. Information Fusion,2019,49. [7] Elsayed M.E. Zayed,Abdul-Ghani Al-Nowehy,Reham M.A. Shohib. New sub-equation method to construct solitons and other solutions for perturbed nonlinear Schr?dinger equation with Kerr law nonlinearity in optical fiber materials[J]. Journal of Ocean Engineering and Science,2018. [8] 李彬. 薄壁构件稳定性分析[D].大连理工大学,2016. [9] 罗天洋. 浅水域钢管式栈桥平台结构设计研究[D].合肥工业大学,2016. [10] 王骁峰,段毅,袁锐之.薄壁硬壳式圆筒结构的屈曲分析[J].兵器装备工程学报,2018,39(07):166-170. Wang Yifeng,Duan Yi,Yuan Ruizhi.Buckling Analysis of Thin-walled Hard-shell Cylinder Structure[J].Journal of Ordnance Equipment Engineering,2018,39(07):166-170. [11] 王欣,范雯霖,高顺德.基于弧长法的臂架非线性稳定性分析[J].起重运输机械,2018(11):127-132. Wang Xin, Fan Wenlin, Gao Shunde.Analysis of Nonlinear Stability of Boom Based on Arc Length Method[J].Lifting and Transport Machinery,2018(11):127-132. [12] 魏鹏,李建光,李延强,陈超.从一实例分析看弧长法与牛顿—拉普森法[J].科技与创新,2018(24):5-6+12. Wei Peng, Li Jianguang, Li Yanqiang, Chen Chao. A case study of arc length method and Newton-Raphson method [J]. Science, Technology and Innovation, 2018 (24): 5 / 612.

相关文章 1

[1]	宁安刚毛文文郭汉杰陈希春. H13钢淬火态碳化物的析出行为及沉淀强化[J]. , 2014, 14(6): 1041-1046.

PDF全文下载地址:

http://www.jproeng.com/CN/article/downloadArticleFile.do?attachType=PDF&id=3390