[1]王 淼,盖长城,何海燕,等.复杂断块油藏建库圈闭密封性综合评价技术[J].复杂油气藏,2022,15(03):94-99.[doi:10.16181/j.cnki.fzyqc.2022.03.017]
 WANG Miao,GAI Changcheng,HE Haiyan,et al.Comprehensive evaluation technology of trap sealing performance in complex fault block reservoir construction[J].Complex Hydrocarbon Reservoirs,2022,15(03):94-99.[doi:10.16181/j.cnki.fzyqc.2022.03.017]
点击复制

复杂断块油藏建库圈闭密封性综合评价技术()
分享到:

《复杂油气藏》[ISSN:1674-4667/CN:31-2019/TQ]

卷:
15卷
期数:
2022年03期
页码:
94-99
栏目:
油气开发
出版日期:
2022-10-25

文章信息/Info

Title:
Comprehensive evaluation technology of trap sealing performance in complex fault block reservoir construction
作者:
王 淼盖长城何海燕辛春彦段 彬
中国石油冀东油田公司勘探开发研究院,河北 唐山 063004
Author(s):
WANG MiaoGAI ChangchengHE HaiyanXIN ChunyanDUAN Bin
Exploration and Development Research Institute of Jidong Oilfield Company,PetroChina, Tangshan 063004,China
关键词:
复杂断块储气库盖层密封性断层密封性圈闭密封性
Keywords:
complex fault-blockgas storagecaprock sealing propertyfault sealing propertytrap sealing property
分类号:
TE822
DOI:
10.16181/j.cnki.fzyqc.2022.03.017
文献标志码:
A
摘要:
以M储气库为例,通过室内实验与理论分析,从盖层和断层综合评价圈闭密封性。从宏观、微观和力学评价盖层密封强度,从侧向、垂向和动态评价断层密封能力,落实圈闭密封极限压力。研究结果表明:盖层岩性以泥岩为主,厚度大,岩石致密、孔喉细小、排替压力大,岩石力学性质优良。主控断层两盘砂泥对接为主,断层泥岩比率(SGR)均较高,断层开启系数低,断层断面正压力大于7.5 MPa,断层岩排替压力大于储层岩排替压力,示踪剂等动态资料证实断层两侧不连通。综合评价M储气库圈闭密封性良好。由圈闭气体散逸、盖层毛细管密封失效、拉张和剪切破坏及断层剪切滑移失稳条件下盖层和断层的承压极限,综合确定圈闭密封上限压力为44.6 MPa。形成的复杂断块油藏圈闭密封性综合评价技术对同类油藏的密封性评价具有一定推广意义。
Abstract:
Taking M Gas storage as an example,indoor tests and theoretical analysis are used to thoroughly assess the trap sealing performance from caprocks and faults. The fault sealing capacity is evaluated from the lateral,vertical,and dynamic views,the sealing strength of the caprock is evaluated from the macroscopic,microscopic,and mechanical perspectives,and the ultimate pressure of the trap seal is calculated. The results show that mudstone comprises the majority of the caprock’s lithology and that it possesses excellent mechanical capabilities as well as a large thickness,compact physical characteristics,narrow pore throat,and high displacement pressure. Sand and mud are primarily used to connect the two sides of the primary control fault,which also has a greater SGR and a lower opening coefficient. The two sides of the fault are not connected because the positive pressure of the fault section is larger than 7.5 MPa,the displacement pressure of the fault rock is greater than that of the reservoir rock,and this is proved by dynamic data such as tracers,etc. A comprehensive analysis indicates that M Gas storage has effective trap sealing. The upper limit pressure of the trap seal is determined to be 44.6 MPa based on the pressure limit of the caprock and fault under the conditions of trap gas escape,capillary seal failure,tensile and shear failure,and fault shear slip instability. A certain promotion relevance exists for the comprehensive sealing assessment technology of complex fault-block reservoirs formed in the sealing evaluation of related oil reservoirs.

参考文献/References:

[1]陈章明,吕延防.泥岩盖层封闭性的确定及其与源岩排气史的匹配[J].大庆石油学院学报,1990,14(2):1-6.
[2]邓祖佑,王少昌,姜正龙,等.天然气封盖层的突破压力[J].石油与天然气地质,2000,21(2):136-138.
[3]马新华,郑得文,申瑞臣,等.中国复杂地质条件气藏型储气库建库关键技术与实践[J].石油勘探与开发,2018,45(3):489-499.
[4]张立宽,罗晓容,宋国奇,等.油气运移过程中断层启闭性的量化表征参数评价[J].石油学报,2013,34(1):92-100.
[5]徐珂,戴俊生,商琳,等.南堡凹陷现今地应力特征及影响因素[J].中国矿业大学学报,2019,48(3):570-583.
[6]吕延防,沙子萱,付晓飞,等.断层垂向封闭性定量评价方法及其应用[J].石油学报,2007,28(5):34-38.
[7]胡欣蕾,吕延防,付广,等.南堡凹陷1号构造断层垂向封闭能力定量评价[J].地球科学,2019,44(11):3882-3893.
[8]赵树栋,王皆明.天然气地下储气库注采技术[M].北京:石油工业出版社,2000.
[9]魏国齐,丁国生,何刚.储气库地质与气藏工程[M].北京:石油工业出版社,2020.
[10]廖伟,刘国良,陈如鹤,等.气藏型地下储气库动态密封性评价——以新疆H地下储气库为例[J].天然气工业,2021,41(3):133-141.

相似文献/References:

[1]朱煜华,张晓亮,刘盛阳,等.南阳凹陷魏岗地区井震一体化构造重构与滚动勘探实践[J].复杂油气藏,2021,14(01):27.[doi:10.16181/j.cnki.fzyqc.2021.01.005]
 ZHU Yuhua,ZHANG Xiaoliang,LIU Shengyang,et al.Well-seismic integrated structure reconstruction and rolling exploration practice in Weigang area,Nanyang Sag[J].Complex Hydrocarbon Reservoirs,2021,14(03):27.[doi:10.16181/j.cnki.fzyqc.2021.01.005]
[2]孙秀会,黄 飞,盖广点,等.断层精细描述在老油田剩余油挖潜中的应用[J].复杂油气藏,2021,14(01):45.[doi:10.16181/j.cnki.fzyqc.2021.01.009]
 SUN Xiuhui,HUANG Fei,GAI Guangdian,et al.Application of fine fault description in tapping the potential of remainingoil in old oilfields[J].Complex Hydrocarbon Reservoirs,2021,14(03):45.[doi:10.16181/j.cnki.fzyqc.2021.01.009]
[3]奥立德,林 波.朱家墩储气库密封性评价[J].复杂油气藏,2021,14(03):86.[doi:10.16181/j.cnki.fzyqc.2021.03.016]
 AO Lide,LIN Bo.Sealability evaluation of Zhujiadun underground gas storage[J].Complex Hydrocarbon Reservoirs,2021,14(03):86.[doi:10.16181/j.cnki.fzyqc.2021.03.016]
[4]申春生,胡治华,徐中波,等.复杂断块油田薄互储层精细描述方法及应用——以渤海P油田馆陶组为例[J].复杂油气藏,2022,15(02):45.[doi:10.16181/j.cnki.fzyqc.2022.02.008]
 SHEN Chunsheng,HU Zhihua,XU Zhongbo,et al.Fine description method and application of thin interbed reservoir in complex fault-block oilfield: A case study of Guantao Formation in P Oilfield, Bohai Sea[J].Complex Hydrocarbon Reservoirs,2022,15(03):45.[doi:10.16181/j.cnki.fzyqc.2022.02.008]
[5]尤启东,王智林,奥立德,等.枯竭层状砂岩气藏改建储气库注采能力评价——以Z气藏为例[J].复杂油气藏,2022,15(04):76.[doi:10.16181/j.cnki.fzyqc.2022.04.014]
 YOU Qidong,WANG Zhilin,AO lide,et al.Evaluation of the injection-production capacity of reconstructed gas storage in depleted stratified sandstone gas reservoirs: A case study of Z gas reservoir[J].Complex Hydrocarbon Reservoirs,2022,15(03):76.[doi:10.16181/j.cnki.fzyqc.2022.04.014]
[6]周静毅,潘新朋,李振伟.混合速度建模技术在东海西湖凹陷复杂断块解释中的应用[J].复杂油气藏,2023,16(03):289.[doi:10.16181/j.cnki.fzyqc.2023.03.007]
 ZHOU Jingyi,PAN Xinpeng,LI Zhenwei.Application of hybird velocity modeling technique in the interpretation of complex fault blocks in Xihu Depression in the East China Sea[J].Complex Hydrocarbon Reservoirs,2023,16(03):289.[doi:10.16181/j.cnki.fzyqc.2023.03.007]

备注/Memo

备注/Memo:
收稿日期:2021-12-20;改回日期:2022-01-14。
第一作者简介:王淼(1988—),女,硕士,工程师,现主要从事油气田开发工作。E-mail: wangmiao2013@petrochina.com.cn 。
更新日期/Last Update: 2023-08-28