EBANO油田裂缝-孔隙型灰岩稠油油藏特征及油气富集规律

doi:10.11743/ogg20200217

摘要/Abstract

摘要：

墨西哥EBANO油田地质特征复杂、油气分布预测难度大，油田开发效果差。利用岩心、测井、地震、生产动态等多方面数据，对油藏特征及油气主控因素开展系统研究。研究表明，上白垩统Ksf和Kan两组灰岩地层是EBANO油田的主力层；断裂系统受区域构造运动影响，南北差异大，北部断裂级别小、断距小、切割层位少、延伸距离短，南部断裂级别大、断距大、切割层位多、延伸距离长；储集空间主要为基质孔隙和裂缝，基质含油非均质性强，断裂附近含油性较好；EBANO油田油气富集主要受断层、构造、裂缝和基质有效厚度控制。基于新认识，实现井位部署由北部高构造向南部低构造的战略转移，平均初产是前期井的2.1倍，开发效果明显改善，为油田高效开发奠定了基础。

关键词: 油藏特征, 油气富集规律, 裂缝型灰岩, 孔隙型灰岩, 稠油, 上白垩统, EBANO油田, 墨西哥

Abstract:

The geology feature of EBANO oilfield in Mexico is complex, leading to difficulty in predicting hydrocarbon distribution, and poor development results.Based on the core description, well logging and seismic data, and well production performance data, we studied the reservoir characteristics and the main factors controlling hydrocarbon accumulation in a systematic way.The results show that the limestone KSF and Kan strata of the Upper Cretaceous are the major pay zones of EBANO oilfield.Due to regional tectonic movement, the fault system shows large difference between the northern and southern parts, with of smaller rank in the north:shorter fault displacement, fewer horizons getting incised and shorter extension distance in the north, and larger rank ones to the south.The reservoir space is dominated by both matrix pores and fractures:the oil-bearing matrix is strong in heterogeneity, and the oil content surrounding faults is high.The hydrocarbon enrichment in EBANO oilfield is controlled mainly by fault, structure, fracture and effective thickness of matrix.Given the above-mentioned new understandings, we implemented a strategic transfer of well emplacement from the higher structures in the north to the lower structures in the south.The development results is obviously improved with the average initial production of new wells 2.1 times that of the old ones, laying a foundation for the successful development of the oilfield.

Key words: reservoir characteristics, hydrocarbon accumulation pattern, limestone of fracture type, limestone of pore type, heavy oil, Upper Cretaceous, EBANO oilfield, Mexico

中图分类号:

TE122.1

王希贤. EBANO油田裂缝-孔隙型灰岩稠油油藏特征及油气富集规律[J]. 石油与天然气地质, 2020, 41(2): 416-422. doi: 10.11743/ogg20200217 Xixian Wang. Characteristics and hydrocarbon accumulation pattern of heavy oil reservoir of fracture-pore limestone in EBANO oilfield, Mexico[J]. Oil & Gas Geology, 2020, 41(2): 416-422. doi: 10.11743/ogg20200217

图/表 6

图1

表1

图2

图3

图4

图5

参考文献 20

1	Akbar M , Vissapragada B , Alghamdi AH , et al. A snapshot of carbonate reservoir evaluation[J]. Oilfield Review, 2000, 12 (4): 20- 21.
2	Huang J P , Li Z C , Kong X , et al. A study of least-squares migration imaging method for fractured-type carbonate reservoir[J]. Chinese Journal of Geophysics-Chinese Edition, 2013, 56 (5): 1716- 1725.
3	Kurtzman D , El Azzi J A , Lucia F J , et al. Improving fractured carbonate-reservoir characterization with remote sensing of beds, fractures, and vugs[J]. Geosphere, 2009, 5 (2): 126- 139. doi: 10.1130/GES00205.1
4	王鸣川, 段太忠, 杜秀娟, 等. 沉积相耦合岩石物理类型的孔隙型碳酸盐岩油藏建模方法[J]. 石油实验地质, 2018, 40 (2): 253- 259.
	Wang Mingchuan , Duan Taizhong , Du Xiujuan , et al. Geological modeling method based on sedimentary facies coupled rock type for porous carbonate reservoirs[J]. Petroleum Geology & Experiment, 2018, 40 (2): 253- 259.
5	柏松章, 唐飞. 裂缝性潜山基岩油藏开发模式[M]. 北京: 石油工业出版社, 1997: 127- 133.
	Bo Songzhang , Tang Fei . Development model of fractured buried hill bedrock reservoir[M]. Beijing: Petroleum Industry Press, 1997: 127- 133.
6	袁士义, 宋新民, 冉启全. 裂缝性油藏开发技术[M]. 北京: 石油工业出版社, 2004: 299- 322.
	Yuan Shiyi , Song Xinmin , Yan Qiyou . Fractured reservoir development technology[M]. Beijing: Petroleum Industry Press, 2004: 299- 322.
7	T.D.范高尔夫一拉特(法).裂缝性油藏工程[M].北京:石油工业出版社, 1989: 377-392. T.D.
	Fan Golf-Latt (France).Fractured reservoir engineering[M]. Beijing: Petroleum Industry Press, 1989: 377-392.
8	李阳, 康志江, 薛兆杰, 等. 中国碳酸盐岩油气藏开发理论与实践[J]. 石油勘探与开发, 2018, 45 (04): 669- 678.
	Li Yang , Kang Zhijiang , Xue Zhaojie , et al. Theories and practices of carbonate reservoirs development in China[J]. Petroleum Exploration and Development, 2018, 45 (04): 669- 678.
9	张继标, 张仲培, 汪必峰, 等. 塔里木盆地顺南地区走滑断裂派生裂缝发育规律及预测[J]. 石油与天然气地质, 2018, 39 (5): 955- 963.
	Zhang Jibiao , Zhang Zhongpei , Wang Bifeng , et al. Development pattern and prediction of induced fractures from strike-slip faults in Shunnan area, Tarim Basin[J]. Oil & Gas Geology, 2018, 39 (5): 955- 963.
10	赫俊民, 王小垚, 孙建芳, 等. 塔里木盆地塔河地区中-下奥陶统碳酸盐岩储层天然裂缝发育特征及主控因素[J]. 石油与天然气地质, 2019, 40 (5): 1022- 1030.
	Hao Junmin , Wang Xiaoyao , Sun Jianfang , et al. Characteristics and main controlling factors of natural fractures in the Lower-to-Middle Ordovician carbonate reservoirs in Tahe area, Northern Tarim Basin[J]. Oil & Gas Geology, 2019, 40 (5): 1022- 1030.
11	高振南, 霍春亮, 罗成栋, 等. 双模迭代技术在裂缝性碳酸盐岩油藏中的应用[J]. 特种油气藏, 2018, 25 (3): 108- 112. doi: 10.3969/j.issn.1006-6535.2018.03.021
	Gao Zhennan , Huo Chunliang , Luo Chengdong , et al. Appliciation of Dual-Mode Iterative Technology in Fractured Cabonate Reservoir[J]. Special Oil & Gas Reservoirs, 2018, 25 (3): 108- 112. doi: 10.3969/j.issn.1006-6535.2018.03.021
12	郑松青, 姚志良. 离散裂缝网络随机建模方法[J]. 石油天然气学报, 2009, 31 (4): 106- 110. doi: 10.3969/j.issn.1000-9752.2009.04.025
	Zheng Songqing , Yao Zhiliang . Discrete fracture network stochastic modeling[J]. Journal of Oil and Gas Technology, 2009, 31 (4): 106- 110. doi: 10.3969/j.issn.1000-9752.2009.04.025
13	Hu X Y , Quan L S , Hou J G , et al. New technology of two step modeling controlled by karst facies of multiscale fractured-cavity carbonate reservoir[J]. Science & Technology Review, 2013, 31 (24): 42- 46.
14	Guo X , Zhao H , HuG L , et al. Ultra-deep wells in fractured-vuggy reservoir nitrogen injection EOR technology[J]. Oil Drilling & Production Technology, 2013, 35 (6): 98- 101.
15	刘中春,李江龙.塔河碳酸盐岩油藏提高采收率方法初探[C]//中国石油学会三次采油技术研讨会.2005.
	Liu Zhongchun, Li Jianglong.A preliminary study on the EOR method of Tahe carbonate reservoir[C]//The Third Oil Recovery Technical Seminar of the Petroleum Society of China.2005.
16	Ren G W , Nguyen Q P , Lau H C . Laboratory investigation of oil recovery by CO₂ foam in a fractured carbonate reservoir using CO₂-Soluble surfactants[J]. Journal of Petroleum Science & Engineering, 2018, 169, 277- 296.
17	郑松青, 杨敏, 康志江, 等. 塔河油田缝洞型碳酸盐岩油藏水驱后剩余油分布主控因素与提高采收率途径[J]. 石油勘探与开发, 2019, 46 (04): 746- 754.
	Zheng Songqing , Yang Min , Kang Zhijiang , et al. Controlling factors of remaining oil distribution after water flooding and enhanced oil recovery methods for fracture-cavity carbonate reservoirs in Tahe Oilfield[J]. Petroleum Exploration and Development, 2019, 46 (04): 746- 754.
18	张正涛, 林畅松, 李慧勇, 等. 渤海湾盆地沙垒田地区新近纪走滑断裂发育特征及其对油气富集的控制作用[J]. 石油与天然气地质, 2019, 40 (4): 778- 788.
	Zhang Zhengtao , Lin Changsong , Li Huiyong , et al. Characteristics of the Neogene strike slip faults and their controls on hydrocarbon accumulation in Shaleitian uplift, Bohai Bay Basin[J]. Oil & Gas Geology, 2019, 40 (4): 778- 788.
19	梅丹, 胡勇, 王倩. 裂缝对气藏储层渗透率及气井产能的贡献[J]. 石油实验地质, 2019, 41 (5): 769- 772.
	Mei Dan , Hu Yong , Wang Qian . Experimental study on fracture contribution to gas reservoir permeability and well capacity[J]. Petroleum Geology & Experiment, 2019, 41 (5): 769- 772.
20	郭臣, 解慧, 聂延波, 等. 塔河碳酸盐岩缝洞型油藏超稠油注氮气实验研究[J]. 油气藏评价与开发, 2017, 7 (4): 22- 26. doi: 10.3969/j.issn.2095-1426.2017.04.005
	Guo Chen , Xie Hui , Nie Yanbo , et al. Research on nitrogen gas injection in super heavy oil of Tahe carbonate fracture-cave type reservoir[J]. Reservoir Evaluation and Development, 2017, 7 (4): 22- 26. doi: 10.3969/j.issn.2095-1426.2017.04.005

界	系	统	阶	层位	组
新生界	古近系	始新统		Brecha	Ebr
新生界	古近系	古新统		Velasco	Pev
中生界	白垩系	上白垩统	Maastrichtiano Campaniano Santoniano Coniaciano	Mendez San Felipe	KmKsf
		中白垩统	Turoniano	Agua Nueva	Kan
			Cenomaniano	Tamaulipas	Kts
			Albiano	Superior	Kts
		下白垩统	Aptiano	Otates	Kto
			Barremiano	Otates	Kto
			Hauteriviano	Tamaulipas Inferior	Kti
			Valanginiano
			Berriasiano
			Tithoniano	Pimienta	Jp
	侏罗系	上侏罗统	Kimmeridiano	Taman/Chipoco/SanAndres	Jt/Jch/Jsa
		上侏罗统	Oxfordiano	santiago/zuloaga	Jsg/Jz
		中侏罗统		Tepexic	Jtx
		中侏罗统		Cahuasas	Jcs
		下侏罗统		Rosary Huayacocotla	JrJhy
		上三叠统		Huizachal	Th
	三叠系	中三叠统
		下三叠统
古生界				Basement	Bas

[1]	侯佳凯, 张志遥, 师生宝, 朱光有. 全二维气相色谱技术在石油地球化学中的应用进展[J]. 石油与天然气地质, 2024, 45(2): 565-580.
[2]	张莉. 中国石化东部老油田提高采收率技术进展及攻关方向[J]. 石油与天然气地质, 2022, 43(3): 717-723.
[3]	孙焕泉. 薄储层超稠油热化学复合采油方法与技术[J]. 石油与天然气地质, 2020, 41(5): 1100-1106.
[4]	汤国民, 王飞龙, 王清斌, 万琳, 燕歌. 渤海海域莱州湾凹陷高硫稠油成因及其成藏模式[J]. 石油与天然气地质, 2019, 40(2): 284-293.
[5]	付金刚, 杜殿发, 郑洋, 巴忠臣, 李冬冬. 超稠油油藏蒸汽驱动态预测模型[J]. 石油与天然气地质, 2018, 39(1): 192-197.
[6]	张淑霞, 刘帆, 沐宝泉. 蒸汽驱及化学辅助蒸汽驱提高稠油采收率实验[J]. 石油与天然气地质, 2017, 38(5): 1000-1004.
[7]	孙晓飞, 张艳玉, 段学苇, 赵春燕, 李星民. 稠油注气二次泡沫油形成机理及数值模拟[J]. 石油与天然气地质, 2017, 38(2): 391-399.
[8]	王冰洁, 徐长贵, 吴奎, 彭靖淞, 刘丰. 渤海海域辽西凹陷陡坡带LX构造特稠油藏内部油品品质分布及成因[J]. 石油与天然气地质, 2017, 38(1): 79-89.
[9]	王昱翔, 周文, 郭睿, 伏美燕, 沈忠民, 赵丽敏, 陈文玲. 伊拉克哈勒法耶油田中、上白垩统碳酸盐岩储层岩石类型及特征[J]. 石油与天然气地质, 2016, 37(5): 764-772.
[10]	计秉玉, 王友启, 聂俊, 张莉, 于洪敏, 何应付. 中国石化提高采收率技术研究进展与应用[J]. 石油与天然气地质, 2016, 37(4): 572-576.
[11]	宋传真, 刘传喜, 徐婷, 曹丽丽, 丁一萍, 杨森. 低渗孔隙型碳酸盐岩稠油油藏开发对策——以叙利亚O油田为例[J]. 石油与天然气地质, 2015, 36(2): 297-305.
[12]	刘宗堡, 索苏, 潘龙, 付晓飞, 申家年. 松辽盆地大庆长垣南部浅层气富集规律及潜力评价[J]. 石油与天然气地质, 2014, 35(4): 463-472.
[13]	席伟军, 张枝焕, 徐新宇, 史翠娥. 流体包裹体技术在春风油田特超稠油成藏研究中的应用[J]. 石油与天然气地质, 2014, 35(3): 350-358.
[14]	吴义平, 潘校华, 田作基, 法贵方, 李富恒, 候平. 陆-陆碰撞对南亚地区油气的控制作用[J]. 石油与天然气地质, 2013, 34(2): 236-241.
[15]	王子强, 张代燕, 杨军, 寇根, 杨飞. 普通稠油油藏渗流特征实验研究——以新疆油田九₄区齐古组油藏为例[J]. 石油与天然气地质, 2012, 33(2): 302-306.