深孔保压取样球阀热-应力耦合仿真分析

doi:10.19388/j.zgdzdc.2024.237

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摘要随着钻孔深度的不断加大,钻孔内的温度和压力也会越来越高,保压取样作为一种能够有效获取地下岩心原位赋存状态的技术方法,在高温高压的环境下能否有效实现原位保压成为检验保压取样可靠性的关键标志之一。为此,选取保压取样的关键机构球阀,开展热-应力耦合仿真分析,重点研究了球阀在[15,30] MPa、[0,250] ℃环境参数内的应力和变形规律。从仿真模拟结果可以看出: ①对比316L、42CrMo和Inconel718这3种材料在[15,30] MPa静压力作用下的最大等效应力与最大变形,同时考虑加工成本,优选42CrMo作为球阀制作材料; ②当温度从0 ℃增加到250 ℃时,球阀的最大变形也在增加,但增长率仅为1.05%,最大等效应力虽然有小的波动,但整体呈现增加趋势,最大波动幅度为12.76 MPa,处于球阀有效密封的允许范围内。仿真模拟结果可为保压球阀在深孔中的可靠密封提供理论数据。

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	王瑛俪
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关键词 ：保压取样, 球阀, 高温高压, 热-应力耦合, 等效应力

Abstract：The temperature and pressure inside the borehole are higher and higher with the increasing depth of the borehole. As a technical method to effectively obtain the in situ state of the underground core, the effective realization of the in situ pressure retention under the high temperature and pressure environment has become one of the key signs to test the reliability of pressure retention sampling. Thus, ball valves were selected as key devices for pressure retention sampling and simulation analysis of thermal-stress coupling, and the stress and deformation law of ball valves in the environmental parameters of [15,30] MPa and [0,250] ℃ were analyzed. The results of numerical simulation are as follows. ① The maximum equivalent stress and deformation values of three materials of 316L, 42CrMo and Inconel718 under the action of static pressure from 15 to 30 MPa were compared, and the 42CrMo was preferred as a material for the fabrication of ball valves, considering the cost of processing. ② The maximum deformation values of ball valves is increasing when the temperature is increasing from 0 ℃ to 250 ℃, but the growth rate is only 1.05%. The maximum equivalent force is increasing with slight fluctuation, showing an increasing overall trend. The maximum fluctuation is 12.76 MPa, which is in the effective sealing range of ball valves. The simulation results could provide theoretical data for the reliable sealing of pressure retention ball valves in the deep hole.

Key words： pressure retention sampling ball valves high temperature and high pressure thermal-stress coupling equivalent stress

收稿日期: 2024-06-20

中图分类号:

P634

基金资助:国家自然科学基金项目“海洋天然气水合物保压取样球阀密封失效机理及优化设计研究(编号: 42102352)”与国家重点研发计划项目“精准勘探定向钻进连续取心前沿技术研发(编号: 2021YFC2900200)”联合资助

通讯作者: 李小洋(1988—),男,高级工程师,主要从事深部钻探取心技术研究。Email: Lixy0692@163.com。

作者简介: 王瑛俪(2001—),女,硕士在读,主要从事深部钻探取心技术研究。Email: wyl05202023@163.com。

引用本文:

王瑛俪, 李小洋, 李冰, 施山山, 吴纪修. 深孔保压取样球阀热-应力耦合仿真分析[J]. 中国地质调查, 2024, 11(5): 153-160.
WANG Yingli,LI Xiaoyang,LI Bing,SHI Shanshan,WU Jixiu. Simulation analysis of thermal-stress coupling for deep hole pressure retention sampling ball valves. , 2024, 11(5): 153-160.

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http://journal25.magtechjournal.com/Jwk_dzdc/CN/10.19388/j.zgdzdc.2024.237 或 http://journal25.magtechjournal.com/Jwk_dzdc/CN/Y2024/V11/I5/153

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