shale gas, mineral components, CT scanning, fractal characteristics, ImageJ software,"/> Genesis of low resistivity oil layer and evaluation of water saturation of the first member of Zhujiang Formation in Wenchang area, Pearl River Mouth Basin

Lithologic Reservoirs ›› 2014, Vol. 26 ›› Issue (5): 97-101.doi: 10.3969/j.issn.1673-8926.2014.05.018

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Genesis of low resistivity oil layer and evaluation of water saturation of the first member of Zhujiang Formation in Wenchang area, Pearl River Mouth Basin

CHEN Rong1LI K ui2HE Shenglin1HU X iangyang1L UO Wei1
  

  1. 1. Zhanjiang Branch of CNOOC Ltd., Zhanjiang 524057, Guangdong, China; 2. Well Logging Company, CNPC Great Wall Drilling Company, Panjin 124000, Liaoning, China
  • Online:2014-10-20 Published:2014-10-20

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Abstract:

 The reservoir of the first member of Zhujiang Formation in Wenchang area of Pearl River Mouth Basin is characterized by high content of shale, and the difference of resistivity between oil layer and water layer is little. So it is difficult to identify the oil-bearing reservoir and water-bearing reservoir by well logging interpretation. Based on the analysis of reservoir lithology, imaging data of thin interbed and litho-electric experiment in various salinity conditions, this paper studied the impact of different factors on the formation resistivity. The results show that the main causes of low resistivity oil layer are fine lithology, high content of shale, high content of irreducible water saturation and middle formation water salinity. Based on the genesis of low resistivity, tri-water model was used to evaluate the water saturation of low resistivity oil layer in the study area. The calculation results are consistent with the sealed coring results.

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[1]郑雷清.综合识别方法在低阻油气层勘探中的应用[J].岩性油气藏,2007,19(2):71-75.
[2]雍世和,张超谟.测井数据处理与综合解释[M].北京:石油大学出版社,1996.
[3]张丽华,潘保芝,李宁,等.基于三水模型的储层分类方法评价低孔隙度低渗透率储层[J].测井技术,2011,35(1):31-35.
[4]赵留运,陈清华,刘强.低电阻率油层研究现状[J].油气地质与采收率,2007,14(1):22-25.
[5]莫修文,贺铎华,李舟波,等.三水导电模型及其在低阻储层解释中的应用[J] .长春科技大学学报,2001,31(1):92-95.
[6]赵杏媛.粘土矿物与油气[J].新疆石油地质,2009,30(4):533-536.
[7]周康,刘佳庆,段国英,等.吴起地区长 61 油层黏土矿物对油层低电阻率化的影响[J].岩性油气藏,2012,24(2):26-30.
[8]王博,赵军,王淼,等.断块低阻油层测井识别与评价[J].岩性油气藏,2012,24(6):110-114.
[9]潘和平,黄坚,樊政军,等.低电阻率油气层测井评价[J].勘探地球物理进展,2002,25(6):11-17.
[10]莫修文,王宏建,许淑梅,等.用测井资料确定储层三孔隙组分的理论与方法[J].吉林大学学报:地球科学版,2005,35(专辑):80-83.
[11]卞应时,张凤敏,高祝军,等.大港油田中浅层低阻油气层成因分析及评价[J].特种油气藏,2002,9(2):26-28.
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