[1]于伟强,赵洪涛,房鑫磊,等. 基于快速傅里叶变换的海上油气井试井解释潮汐效应消除方法[J].油气井测试,2020,29(06):1-7.[doi:10.19680/j.cnki.1004-4388.2020.06.001]
 YU Weiqiang,ZHAO Hongtao,FANG Xinlei,et al. Elimination of tidal effect in well test interpretation of offshore oil and gas wells based on fast Fourier transform[J].Well Testing,2020,29(06):1-7.[doi:10.19680/j.cnki.1004-4388.2020.06.001]
点击复制

 基于快速傅里叶变换的海上油气井试井解释潮汐效应消除方法()
分享到:

《油气井测试》[ISSN:1006-6977/CN:61-1281/TN]

卷:
29卷
期数:
2020年06期
页码:
1-7
栏目:
出版日期:
2020-12-25

文章信息/Info

Title:
 Elimination of tidal effect in well test interpretation of offshore oil and gas wells based on fast Fourier transform
文章编号:
1004-4388(2020)06-0001-07
作者:
 于伟强赵洪涛房鑫磊李大亮
 中法渤海地质服务有限公司 天津 300457
Author(s):
 YU Weiqiang ZHAO Hongtao FANG Xinlei LI Daliang
 ChinaFrance Bohai Geoservices Co., Ltd., Tianjin 300457, China
关键词:
 不稳定试井试井解释潮汐效应快速傅里叶变换快速傅里叶反变换频率幅值
Keywords:
 transient pressure test well test interpretation tidal effect fast Fourier transform inverse fast Fourier transform frequency amplitude
分类号:
TE353
DOI:
10.19680/j.cnki.1004-4388.2020.06.001
文献标志码:
A
摘要:
针对不稳定试井中压力数据存在潮汐影响,且干扰模型判断和储层物性参数解释的问题,利用快速傅里叶变换方法识别并去除潮汐效应。将含有潮汐影响的压力数据进行规整化处理和快速傅里叶变换,使信号由时间域变换到频率域,各个潮汐分量在频率域表现为固定值,判断并识别出其频率,将各分潮所对应频率的幅值进行插值降幅处理,再经过快速傅里叶反变换和逆规整转换,得到处理后的压力数据。结果表明,原始数据经过快速傅里叶变换,噪声等信号会出现在相对高频区域;储层压力响应信息出现在相对低频区域;各潮汐分潮在频率域中以固定频率形式出现而被准确识别,插值降幅处理后压力的周期性波动得到抑制,压力导数径向流段和后期特征能够准确判断。该方法在处理原始压力数据的过程中不需要最优化拟合,避免了结果的多解性和繁杂的计算量,为含有潮汐效应压力数据的矫正提供了一种有效手段。
Abstract:
 Tidal influence of pressure data in unstable well testing influencing model judgment and reservoir physical parameter interpretation. The fast Fourier transform method is used to identify and remove the tidal effect. The pressure data with tidal influence is processed by regularization and fast Fourier transform, so that the signal is transformed from time domain to frequency domain. Each tidal component is represented as a fixed value in frequency domain. Its frequency can be determined and identified. The amplitude of frequency corresponding to each tidal component can be interpolated and reduced, and then the processed pressure can be obtained through inverse fast Fourier transform and inverse regularization transformation. The results show that after FFT, noise and other signals will appear in the relatively high frequency region; the reservoir pressure response information appears in the relatively low frequency region; each tidal component appears in the frequency domain in the form of fixed frequency and is accurately identified; after interpolation and amplitude reduction, 〖HJ*4〗the periodic pressure fluctuation is suppressed, and the radial flow section and later characteristics of pressure derivative can be accurately determined. During the processing the original pressure data, the method does not need to optimize the fitting, which avoids the multi solution and complex calculation of the results and provides an effective means for the correction of pressure data with tidal effect.

相似文献/References:

[1]马奎前,张宏友,王月杰,等.压力测试技术在海上深层湖相碳酸盐岩油藏中的应用[J].油气井测试,2013,22(05):0.
[2]曹银萍,黄宇曦,于凯强,等. 基于ANSYS Workbench完井管柱流固耦合振动固有频率分析[J].油气井测试,2018,27(01):1.[doi:10.19680/j.cnki.1004-4388.2018.01.001]
 CAO Yinping,HUANG Yuxi,YU Kaiqiang,et al. Natural frequency analysis for fluidsolid coupling vibration of completion string based on ANSYS workbench[J].Well Testing,2018,27(06):1.[doi:10.19680/j.cnki.1004-4388.2018.01.001]
[3]高 超,艾 昆,高 辉,等. 基于施工压力曲线的综合滤失系数测试方法及压裂参数优化[J].油气井测试,2018,27(01):8.[doi:10.19680/j.cnki.1004-4388.2018.01.002]
 GAO Chao,AI Kun,GAO Hui,et al.Test method of total leak-off coefficient and optimization of fracturing parameters based on operation pressure curves[J].Well Testing,2018,27(06):8.[doi:10.19680/j.cnki.1004-4388.2018.01.002]
[4]周小林,高志华,张 冲.龙凤山气田大通径免钻桥塞分段压裂先导试验[J].油气井测试,2018,27(01):62.[doi:10.19680/j.cnki.1004-4388.2018.01.010]
 ZHOU Xiaolin,GAO Zhihua,ZHANG Chong. Pilot tests of staged fracturing involving largediameter drillfree bridge plugs in the Longfengshan gas field[J].Well Testing,2018,27(06):62.[doi:10.19680/j.cnki.1004-4388.2018.01.010]
[5]魏 聪,陈宝新,刘 敏,等. 基于反褶积技术的S气井不稳定试井解释[J].油气井测试,2018,27(01):73.[doi:10.19680/j.cnki.1004-4388.2018.01.012]
 WEI Cong,CHEN Baoxin,LIU Min,et al. Interpretation of pressure transient well testing data of S gas well based on deconvolution technique[J].Well Testing,2018,27(06):73.[doi:10.19680/j.cnki.1004-4388.2018.01.012]
[6]张中宝.塔河油田深抽杆式泵一体化管柱工艺[J].油气井测试,2018,27(02):27.[doi:10.19680/j.cnki.1004-4388.2018.02.005]
 ZHANG Zhongbao.Deep integrated rod pumping string applied in Tahe Oilfield[J].Well Testing,2018,27(06):27.[doi:10.19680/j.cnki.1004-4388.2018.02.005]
[7]李军贤.地层出砂井测试工艺优化[J].油气井测试,2018,27(02):47.[doi:10.19680/j.cnki.1004-4388.2018.02.008]
 LI Junxian.Optimization of testing techniques for wells with formation sand production[J].Well Testing,2018,27(06):47.[doi:10.19680/j.cnki.1004-4388.2018.02.008]
[8]田向东,康 露,杨 志,等.海上油气井快速诱喷测试技术[J].油气井测试,2018,27(02):41.[doi:10.19680/j.cnki.1004-4388.2018.02.007]
 TIAN Xiangdong,KANG Lu,YANG Zhi,et al.Fast testing of induced flows in offshore oil/gas wells[J].Well Testing,2018,27(06):41.[doi:10.19680/j.cnki.1004-4388.2018.02.007]
[9]张 毅,于丽敏,任勇强,等.一种新型可降解压裂封隔器坐封球[J].油气井测试,2018,27(02):53.[doi:10.19680/j.cnki.1004-4388.2018.02.009]
 ZHANG Yi,YU Limin,REN Yongqiang,et al.A new type of degradable setting ball for fracturing packers[J].Well Testing,2018,27(06):53.[doi:10.19680/j.cnki.1004-4388.2018.02.009]
[10]褚春波,郭 权,黄小云,等.有限元分析径向水力压裂裂缝扩展影响因素[J].油气井测试,2018,27(02):59.[doi:10.19680/j.cnki.1004-4388.2018.02.010]
 CHU Chunbo,GUO Quan,HUANG Xiaoyun,et al.Finiteelement analysis on influencing factors for propagation of fractures induced in radial jet hydraulic fracturing[J].Well Testing,2018,27(06):59.[doi:10.19680/j.cnki.1004-4388.2018.02.010]
[11]于伟强,劳文韬,李纪智,等.基于TMD工具箱海上油气井试井解释潮汐效应消除方法[J].油气井测试,2022,31(01):62.[doi:10.19680/j.cnki.1004-4388.2022.1.011]
 YU Weiqiang,LAO Wentao,LI Jizhi,et al. Tidal effect elimination method in well testing interpretation of offshore oil and gas wells based on TMD toolbox[J].Well Testing,2022,31(06):62.[doi:10.19680/j.cnki.1004-4388.2022.1.011]
[12]李超. 低渗透油藏压前不稳定试井数据与压裂效果的关系分析[J].油气井测试,2023,32(01):74.[doi:10. 19680/ j. cnki. 1004-4388. 2023. 01. 013]
 [J].Well Testing,2023,32(06):74.[doi:10. 19680/ j. cnki. 1004-4388. 2023. 01. 013]
[13]王海兵,陶静,彭丽. 压裂后不稳定试井早期恢复压力拟合重建方法[J].油气井测试,2023,32(04):68.[doi:10.19680/j.cnki.1004-4388.2023.04.012]
 [J].Well Testing,2023,32(06):68.[doi:10.19680/j.cnki.1004-4388.2023.04.012]

备注/Memo

备注/Memo:
 2020-05-07收稿,2020-10-23修回,2020-11-01接受,2020-12-20 网络版发表
于伟强,男,1987年出生,硕士,工程师,2014年毕业于中国石油大学(华东)油气田开发工程专业,现主要从事井下压力测试数据解释和研究工作。电话:022-65310731,18366269007;Email:yuwq@cfbgc.com。通信地址:天津经济技术开发区信环西路19号天河科技园1号楼3层中法渤海地质服务有限公司,邮政编码:300457。
更新日期/Last Update: 2021-01-07