胜利油田稠油未动用储量评价及动用对策

doi:10.3969/j.issn.1006-6535.2021.02.009

摘要/Abstract

摘要： 胜利油田稠油资源丰富,经过多年技术攻关和开发建设,仍有近3.20×10⁸t探明储量未得到有效动用。为实现不同类型稠油未动用储量的有效开发,系统分析了储量特点及开发难点,将其划分为敏感稠油、深层低渗稠油、特超稠油、边底水稠油和超薄层稠油5种类型,综合应用物理模拟、数值模拟、室内实验等方法,制订了不同类型未动用储量的开发对策。研究表明:敏感稠油油藏可采用适度出砂、稠油降黏冷采、火烧油层等技术,深层低渗稠油油藏可采用压裂辅助增溶降黏、降黏引驱技术开发,特超稠油油藏可采用E-SAGD、HECS强化采油技术提高原油流动性,边底水稠油油藏可通过底水蒸汽驱、降黏冷采、微生物采油技术减少边底水对开发的影响,薄层稠油油藏主要考虑短半径水平井、压裂+降黏冷采技术增加单井控制储量。研究形成的技术与认识对国内外相似储量的动用有一定的指导和借鉴意义。

关键词: 稠油油藏, 未动用储量, 储量评价, 动用对策, 地下改质, 胜利油田

Abstract: Shengli Oilfield, rich in heavy oil resources, still has nearly 3.20×10⁸t proven reserves that have not been effectively developed after years of technical research and development. In order to realize the effective development of nonproducing reserves of different types of heavy oil reservoirs, the reserves characteristics and development difficulties were systematically analyzed, the heavy oil reservoirs were divided into five types, namely sensitive heavy oil, deep low-permeability heavy oil, super heavy oil, edge-bottom water heavy oil and ultra-thin layer, and development countermeasures were prepared for different types of nonproducing reserves with comprehensive application of physical modeling, numerical simulation, laboratory testing, and other methods. It was found in the study that sensitive heavy oil reservoirs could be developed with technologies such as moderate sand production, heavy oil viscosity reduction and cold recovery, and oil layer combustion; deep low-permeability heavy oil reservoirs could be developed with technologies of fracturing assisted solubilization and viscosity reduction, and viscosity reduction and displacement; super heavy oil reservoirs could be developed with E-SAGD, HECS and other EOR technologies to improve the fluidity of crude oil; edge-bottom water heavy oil reservoirs could be developed with bottom-water steam flooding, viscosity reduction and cold recovery, and microbial oil recovery to reduce the effect of edge-bottom water on development; the thin heavy oil reservoirs could be developed mainly with short-radius horizontal well, and fracturing + viscosity reduction and cold recovery to increase the controlled reserves of single well. The technologies and findings obtained in the study are of great significance in guidance and reference for the development of similar reserves at home and abroad.

Key words: heavy oil reservoirs, nonproducing reserves, reserves evaluation, development countermeasures, in-situ upgrading, Shengli Oilfield

中图分类号:

TE345

李伟忠. 胜利油田稠油未动用储量评价及动用对策[J]. 特种油气藏, 2021, 28(2): 63-71.

Li Weizhong. Evaluation and Development Countermeasures for Nonproducing Reserves of Heavy Oil Reservoirs in Shengli Oilfield[J]. Special Oil & Gas Reservoirs, 2021, 28(2): 63-71.

参考文献

[1] 孙建芳.氮气及降黏剂辅助水平井热采开发浅薄层超稠油油藏[J].油气地质与采收率,2012,19(2):47-49,53,114.
SUN Jianfang.Nitrogen and viscosity reducers assisted horizontal well thermal recovery technology for developing shallow, thin and super-heavy oil reservoirs[J].Petroleum Geology and Recovery Efficiency,2012,19(2):47-49,53,114.
[2] 袁明琦.王庄油田强水敏性稠油油藏开发方式研究[J].大庆石油地质与开发,2006,25(6):56-58,122-123.
YUAN Mingqi.Study on development pattern optimization for high water sensitivity heavy oil reservoir in Wangzhuang Oilfield[J].Petroleum Geology & Oilfield Development in Daqing,2006,25(6):56-58,122-123.
[3] 田刚,唐洪明,王春华.疏松砂岩稠油油藏适度出砂开采方式研究[J].新疆石油地质,2007,28(2):197-199.
TIAN Gang,TANG Hongming,WANG Chunhua.Study on reasonable sand producing process for unconsolidated sandstone heavy oil reservoir[J].Xinjiang Petroleum Geology,2007,28(2):197-199.
[4] 李伟忠.金家油田低渗敏感稠油油藏适度出砂室内评价[J].断块油气田,2019,26(6):810-815.
LI Weizhong.Laboratory evaluation on reasonable sand production of low permeability sensitive heavy oil reservoir in Jinjia Oilfield[J]. Fault-Block Oil & Gas Field,2019,26(6):810-815.
[5] 曹嫣镔,于田田,林吉生,等.热复合化学方法改善极强敏感性稠油油藏开发效果机理[J].石油学报,2013,34(1):128-132.
CAO Yanbin,YU Tiantian,LIN Jisheng,et al.A study on a thermal compound chemical method for improving development efficiency of heavy-oil reservoirs with strong sensitivity[J].Acta Petrolei Sinica,2013,34(1):128-132.
[6] 蔡文斌,李友平,李淑兰,等.胜利油田火烧油层现场试验[J].特种油气藏,2007,14(3):88-90,110.
CAI Wenbin,LI Youping,LI Shulan,et al.Field test of in situ combustion in Shengli Oilfield[J].Special Oil & Gas Reservoirs,2007,14(3):88-90,110.
[7] 邓宏伟.超深层低渗透稠油CO₂增溶降黏体系研发与应用[J].油气地质与采收率,2020,27(1):81-88.
DENG Hongwei.Development and application of CO₂ solubilizing and viscosity reducing system for ultra-deep and low-permeability heavy oil reservoirs[J].Petroleum Geology and Recovery Efficiency,2020,27(1):81-88.
[8] 何金钢,王洪卫.三类油层压裂驱油技术设计及效果研究[J].西南石油大学学报(自然科学版),2018,40(5):95-104.
HE Jingang,WANG Hongwei.The study on effect and design of fracture-flooding in Class Ⅲ oil reservoirs[J].Journal of Southwest Petroleum University (Science & Technology Edition),2018,40(5):95-104.
[9] 王传飞,吴光焕,韦涛,等.薄层特超稠油油藏氮气与降黏剂联合蒸汽辅助重力泄油物理模拟实验[J].油气地质与采收率,2017,24(1):80-85.
WANG Chuanfei,WU Guanghuan,WEI Tao,et al.Physical simulation experiment of nitrogen gas and dissolve solvent aided SAGD for thin formation and extra-super heavy oil reservoir[J].Petroleum Geology and Recovery Efficiency,2017,24(1):80-85.
[10] 余华杰,朱国金,田冀.海上强边底水油帽稠油油藏注CO₂提高采收率[J].大庆石油地质与开发,2013,32(5):137-142.
YU Huajie,ZHU Guojin,TIAN Ji.EOR by CO₂ injection into offshore heavy oil-cap reservpor with strong edge and bottom waters[J].Petroleum Geology & Oilfield Development in Daqing,2013,32(5):137-142.
[11] 刘祖鹏.边底水稠油油藏水溶性降黏剂吞吐技术研究[J].特种油气藏,2020,27(3):99-104.
LIU Zupeng.Water-soluble viscosity reducer stimulation in the heavy-oil reservoir with bottom-edge aquifer[J].Special Oil & Gas Reservoirs,2020,27(3):99-104.
[12] 魏超平,李伟忠,吴光焕,等.稠油降黏剂驱提高采收率机理[J].油气地质与采收率,2020,27(2):131-136.
WEI Chaoping,LI Weizhong,WU Guanghuan,et al.EOR mechanism of viscosity reducer flooding in heavy oil reservoirs[J].Petroleum Geology and Recovery Efficiency,2020,27(2):131-136.
[13] 汪卫东.我国微生物采油技术现状及发展前景[J].石油勘探与开发,2002,29(6):87-90,102.
WANG Weidong.Present study situation and development prospects of microbiological recovery technology in China[J].Petroleum Exploration and Development,2002,29(6):87-90,102.
[14] 王新,陈若铭.哈萨克斯坦浅层稠油井侧钻短半径水平井技术[J].新疆石油科技,2006,16(2):1-5,47.
WANG Xin,CHEN Ruoming.Sidetracking and short-radius horizontal well drilling technology for shallow heavy oil wells in Kazakhstan[J].Xinjiang Petroleum Science & Technology,2006,16(2):1-5,47.
[15] 倪益民,袁永嵩,赵金海,等.胜利油田两口超短半径侧钻水平井的设计与施工[J].石油钻探技术,2007,35(6):57-59.
NI Yimin,YUAN Yongsong,ZHAO Jinhai,et al.Design and implementation of two ultra-short radius sidetracking horizontal wells in Shengli Oilfield[J].Petroleum Drilling Technology,2007,35(6):57-59.
[16] 石芳,吴景春,赵博,等.Janus微纳米胶囊的结构表征与驱油性能[J].硅酸盐学报,2019,47(11):1677-1682.
SHI Fang,WU Jingchun,ZHAO Bo,et al.Structure and oil displacement performance of Janus microcapsules[J].Journal of the Chinese Ceramic Society,2019,47(11):1677-1682.
[17] 杨艳,王祥程,王涛.中国稠油开发技术现状与建议[J].自然科学,2019,7(6):471-477.
YANG Yan,WANG Xiangcheng,WANG Tao.China's heavy-oil development technology: status and recommendations[J].Open Journal of Nature Science, 2019,7(6):471-477.