苏北盆地注CO2提高采收率技术面临的挑战与对策

doi:10.13809/j.cnki.cn32-1825/te.2020.03.009

Abstract

Abstract:

CO₂ injection for enhanced oil recovery（EOR） has gone though 4 stages of technical improvements in North Jiangsu Basin. During the current low oil price period, three challenges are exiting: the high cost of CO₂ flooding makes it difficult to realize benefit development, the minimum miscible pressure（MMP） is too high to enhance oil recovery substantially, and the heterogeneity is too strong for expanding CO₂ swept volume. Therefore, three main countermeasures is put forward. Firstly, the optimization of scheme is the key. By full advantage of the old wells to reduce investment for new wells, optimization of injection mode to reduce injection volume, use of current equipment to reduce recycling cost, and overall plan for the pipe network to reduce gas cost, the cost of CO₂ flooding is reduced, thus, the equilibrium oil price of 60 % of the CO₂ flooding project will be kept below ＄60/bbl. Secondly, screening and evaluation of additives to reduce MMP are carried out. Meanwhile, the miscible condition was improved and the recovery rate of CO₂ flooding was increased by the injection in advance to increase the formation pressure. Tiredly, the swept volume of CO₂ is improved by means of injection at the high parts, water alternating gas injection（WAG）, and profile modification to mitigate gas channeling. The research and practice offer reference and examples for the beneficial development of CO₂ flooding in similar reservoirs under low oil price.

Key words: CO₂ flooding, EOR, North Jiangsu Basin, reducing minimum miscible pressure, mitigate gas channeling

CLC Number:

TE357

Zuhua CHEN. Challenges and countermeasures of EOR by CO₂ injection in North Jiangsu Basin[J]. Reservoir Evaluation and Development, 2020, 10(3): 60-67.

Figures/Tables 9

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References 20

[1]	秦积舜, 韩海水, 刘晓蕾. 美国CO₂驱油技术应用及启示[J]. 石油勘探与开发, 2015,42(2):209-216.
	QIN J S, HAN H S, LIU X L. Application and enlightenment of carbon dioxide flooding in the United States of America[J]. Petroleum Exploration and Development, 2015,42(2):209-216.
[2]	MOHAN H, CAROLUS M, BIGLARBIGI K. The potential for additional carbon dioxide flooding projects in the United States[C]// paper SPE-113975-MS presented at the SPE Symposium on Improved Oil Recovery, 20-23 April 2008, Tulsa, Oklahoma, USA.
[3]	JABLONOWSKI C, SINGH A. A survey of CO₂-EOR and CO₂ storage project costs[C]// paper SPE-139669-MS presented at the SPE International Conference on CO₂ Capture, Storage, and Utilization, 10-12 November 2010, New Orleans, Louisiana, USA.
[4]	李阳. 低渗透油藏CO₂驱提高采收率技术进展及展望[J]. 油气地质与采收率, 2020,27(1):1-10.
	LI Y. Technical advancement and prospect for CO₂ flooding enhanced oil recovery in low permeability reservoirs[J]. Petroleum Geology and Recovery Efficiency, 2020,27(1):1-10.
[5]	俞凯, 刘伟, 陈祖华, 等. 陆相低渗透油藏CO2混相驱技术[M]. 北京: 中国石化出版社, 2015.
	YU K, LIU W, CHEN Z H, et al. CO2 miscible flooding technology in continental low permeability reservoir[M]. Beijing: China Petrochemical Press, 2015.
[6]	陈祖华, 吴公益, 钱卫明, 等. 苏北盆地复杂小断块油藏注CO₂提高采收率技术及应用[J]. 油气地质与采收率, 2020,27(1):152-162.
	CHEN Z H, WU G Y, QIAN W M, et al. EOR technology and application of CO₂ injection for small complex fault block reservoirs in Subei Basin[J]. Petroleum Geology and Recovery Efficiency, 2020,27(1):152-162.
[7]	王海妹. CO₂驱油技术适应性分析及在不同类型油藏的应用——以华东油气分公司为例[J]. 石油地质与工程, 2018,32(5):63-65.
	WANG H M. Adaptive analysis of CO₂ flooding technology and its application in different types of reservoirs[J]. Petroleum Geology & Engineering, 2018,32(5):63-65.
[8]	陈祖华, 孙雷, 杨正茂, 等. 苏北低渗透油藏CO₂驱油开发模式探讨[EB/OL]. （2020-05-25）[2020-06-02]. https://kns.cnki.net/KCMS/detail/51.1718.TE.20200524.2247.020.html.
	CHEN Z H, SUN L, YANG Z M, et al. Discussion on the Development Model of CO₂ Flooding in Low Permeability Reservoir in North Jiangsu[EB/OL]. （2020-05-25）[2020-06-02]. https://kns.cnki.net/KCMS/detail/51.1718.TE.20200524.2247.020.html.
[9]	陈祖华. 低渗透油藏CO₂驱油开发方式与应用[J]. 现代地质, 2015,29(4):950-957.
	CHEN Z H. Application and utilization of CO₂ flooding in low-permeability reservoir[J]. Geoscience, 2015,29(4):950-957.
[10]	陈祖华, 蒲敏, 杨春红, 等. CS油田CT复杂断块低渗透油藏CO₂驱动态调整研究[J]. 石油天然气学报, 2012,34(1):132-135.
	CHEN Z H, PU M, YANG C H, et al. Study on dynamic adjustment of CO₂ flooding in low permeability reservoirs of a complex fault block[J]. Journal of Oil and Gas Technology, 2012,34(1):118-122.
[11]	陈祖华, 汤勇, 王海妹, 等. CO₂驱开发后期防气窜综合治理方法研究[J]. 岩性油气藏, 2014,26(5):102-106.
	CHEN Z H, TANG Y, WANG H M, et al. Comprehensive treatment of gas channeling at the later stage of CO₂ flooding[J]. Lithologic Rservoir, 2014,26(5):102-106.
[12]	GUI X, WANG W, GAO Q, et al. Measurement and correlation of high pressure phase equilibria for CO₂ + alkanes and CO₂ + crude oil systems[J]. Journal of Chemical Engineering data, 2017,62(11):3807-3822. doi: 10.1021/acs.jced.7b00517
[13]	王世璐, 王玉霞, 贾凯锋. 低渗透油藏岩心注CO₂驱油效率物理模拟[J]. 非常规油气, 2019,6(2):85-90.
	WANG S L, WANGY X, JIA K F. Physical simulation of CO₂ flooding efficiency in low permeability reservoir core[J]. Unconventional Oil & Gas, 2019,6(2):85-90.
[14]	贾凯锋, 计董超, 高金栋, 等. 低渗透油藏CO₂驱油提高原油采收率研究现状[J]. 非常规油气, 2019,6(1):107-114.
	JIA K F, JI D C, GAO J D, et al. The exisiting state of enhanced oil recovery by CO₂ flooding in low permeability reservoirs[J]. Unconventional Oil & Gas, 2019,6(1):107-114.
[15]	陈祖华. ZJD油田阜宁组大倾角油藏注CO₂方式探讨[J]. 西南石油大学学报:自然科学版, 2014,36(6):83-87.
	CHEN Z H. Studies on CO₂ injection scenarios for large dip angle reservoir of Funing group in ZJD Oilfield[J]. Journal of Southwest Petroleum University(Science & Technology Edition), 2014,36(6):83-87.
[16]	邓瑞健, 田巍, 李中超, 等. 二氧化碳驱动用储层微观界限研究[J]. 特种油气藏, 2019,26(3):133-137.
	DENG R J, TIAN W, LI Z C, et al. Microscopic limits of reservoir producing for carbon dioxide flooding[J]. Special Oil & Gas Reservoirs, 2019,26(3):133-137.
[17]	李承龙. 特低渗透油藏二氧化碳驱气窜影响因素及规律[J]. 特种油气藏, 2018,25(3):82-86.
	LI C L. Gas channeling influencing factors and patterns of CO₂-flooding in ultra-low permeability oil reservoir[J]. Special Oil & Gas Reservoirs, 2018,25(3):82-86.
[18]	牛保伦. 边底水气藏注二氧化碳泡沫控水技术研究[J]. 特种油气藏, 2018,25(3):126-129.
	NIU B L. Water control in the CO₂ foal-flooding gas reservoir with bottom-edge aquifer[J]. Special Oil & Gas Reservoirs, 2018,25(3):126-129.
[19]	张世明. 低渗透油藏CO₂驱气窜通道识别方法[J]. 油气地质与采收率, 2020,27(1):101-106.
	ZHANG S M. Study on identification method for gas channeling of CO₂ flooding in low permeability reservoirs[J]. Petroleum Geology and Recovery Efficiency, 2020,27(1):101-106.
[20]	陈祖华, 俞凯, 刘伟. CO₂混相驱注采特征及开发效果初探——以苏北草舍油田为例[J]. 油气藏评价与开发, 2011,1(1-2):37-41.
	CHEN Z H, YU K, LIU W, et al. CO₂ miscible flooding and production characteristics and preliminary discussion about the development effects-taking Caoshe oilfield in northern Jiangsu area as an example[J]. Progress in Exploration Geophysics, 2011,1(1-2):37-41.

油藏类型	区块	层系	渗透率/10^-3 μm²	埋藏深度/m	原始地层压力/MPa	最小混相压力/MPa	混相状况
低渗透油藏	草舍	Et	24.8	2 827	32.40	29.3	混相
	草中	Ef³	9.95	3 080	32.90	26.6	混相
	华庄	Ef³	6.10	2 800	31.40	32.1	近混相
	金南I号	Ef²	1.20	2 136	22.34	24.1	近混相
	帅垛	Ef³	4.37	2 844	27.99	26.7	混相
	张家垛	Ef³	5.20	3 100	37.40	29.5	混相
	台南	Ef³	50.50	2 521	26.28	22.1	混相
	鹤5	Ef³	93.70	2 494	24.60	22.2	混相
中高渗油藏	洲城	Es¹	866.00	1 650	15.74	45.3	非混相
	草中	Ed¹	158.30	2 260	24.50	34.1	非混相
	溪南庄	Es¹	1 318.00	2 350	22.26	33.2	非混相

注气井	对应油井	注气时机	见效时间	日产油/t
注气井	对应油井	注气时机	见效时间	见效前	见效后	差值
CZ1-2	CZ1-7	超前一年注气	投产见效	0	5.4	5.4
CZ1-2	CZ1-3	同步注气	8个月后	3.1	4.8	1.7
T10	CQK-118	超前半年注气	投产自喷	0	5.2	5.2
CZ1-10	CZ2	滞后注气	6个月后	2.3	3.6	1.3

注气部位	注气井井号	对应油井井号	见效时间	见效有效期	日产油/t			增油倍比	含水率/%
注气部位	注气井井号	对应油井井号	见效时间	见效有效期	见效前	见效后	差值	增油倍比	见效前	见效后	差值
高部位注气	C23	QK-26	1年半后	3年	6.29	13.59	7.3	2.16	34.95	4.6	-30.4
低部位注气	C5	C18	10个月后	2年半	2.6	5.31	2.7	2.04	81.48	51.6	-29.9

Challenges and countermeasures of EOR by CO₂ injection in North Jiangsu Basin

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Challenges and countermeasures of EOR by CO2 injection in North Jiangsu Basin

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Challenges and countermeasures of EOR by CO₂ injection in North Jiangsu Basin