基于SPE—PRMS准则下的3P储量含油气边界确定方法探讨

doi:10.3969/j.issn.1673-8926.2013.04.002

Lithologic Reservoirs ›› 2013, Vol. 25 ›› Issue (4): 6-10.doi: 10.3969/j.issn.1673-8926.2013.04.002

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Determination method of oil—bearing area boundary of the 3P reserves based on SPE—PRM S standard

LI Hongying,SUN Jing

1．Key Laboratory for Shale Gas Resource&Exploration，Ministry of Land and Resources，Chongqing 400042，China：2．Chongqing Engineering Research Center for Shale Gas Resource＆Exploration，Chongqing 400042， China；3．Research Institute ofExploration and Development，PetroChina Daqing Oilfield Company Ltd．，Daqing 163712， China

Online:2013-10-08 Published:2013-10-08

Abstract

Abstract:

The basis for the determination of oil bearing area is not clear when use SPE．PRMS standard t0 evaluate 3Preserves．By the comprehensive application of the data of production testing，testing for oil，well logging and reservoir characteristics，combined with the evaluation resuh of 3P reserves in international cooperative block． this paper studied the determination method of oil．bearing area boundary of 3P reserves of different types of reservoirs based on SPE—PRMS standard．The results show that the evaluation method according to the reservoir types to determine oil．bearing area can further improve the credibility of reserves evaluation results，and effectively reduce the risk 0f devel0Dment 0f oil and gas production．

Key words: seismic attributes, cluster analysis, interbeds genesis, interbeds identification, Bozhong 26 oifield

LI Hongying,SUN Jing. Determination method of oil—bearing area boundary of the 3P reserves based on SPE—PRM S standard[J].Lithologic Reservoirs, 2013, 25(4): 6-10.

References

［1］ Corcoran D. Petroleum Resources Management System （PRMS）［DB/OL］. http：//www.spe.org/industry/reserves/docs/Petroleum_Resources_ Management_System 2007.pdf，2007.
［2］ Purewal S，Ross J G，Rodriguez J M，et al. Guidelines for Application of the Petroleum Resources Management System［DB/OL］. http：//www.spe.org/industry/docs/PRMS_Guidelines_Nov2011.pdf，2011.
［3］王永祥，段晓文.美国油储新规影响何在［J］.中国石油石化，2008（15）：54-55.
［4］王永祥，张君峰，段晓文.中国油气资源/储量分类与管理体系［J］.石油学报，2011，32（4）：645-651.
［5］赵文智，李建忠，王永祥，等.SEC 标准确定证实储量边界的方法［J］.石油勘探与开发，2006，33（6）：754-758.
［6］胡允栋，萧德铭，王永祥.按SEC 标准进行油气证实储量评估的基本原则［J］.石油学报，2004，25（2）：19-24.
［7］毕海滨，王永祥，胡允栋.浅析SPE 储量分类中三级储量的相互关系［J］.新疆石油地质，2004，25（4）：420-422.
［8］刘鹏超，唐海，吕栋梁，等.利用压力恢复曲线求取油井控制储量的新方法［J］.岩性油气藏，2010，22（3）：106-109.
［9］李红英，杨耀坤，孙静，等.国际合作区断块油藏SPE 准则2P、3P 储量评估方法研究［C］//中国石油天然气股份公司勘探与生产分公司编.美国SEC 准则油气储量评估论文集.北京：石油工业出版社，2012，175-189.
［10］闫博，吕晓辉.塔南凹陷储层孔隙特征及其发育成因［J］.岩性油气藏，2012，24（1）：26-29.
［11］吴国干，胡允栋，王永祥，等.油气储量评估与油气藏圈闭成因的主控因素［J］.石油学报，2008，29（6）：804-808.

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