准噶尔盆地金龙油田二叠系佳木河组火山岩岩相组合及产能差异

doi:10.11743/ogg20250110

Abstract

Abstract:

Volcanic rocks in the Permian Jiamuhe Formation of the Jinlong oilfield in the Junggar Basin exhibit unclear lithofacies types and dominant reservoir distribution， which hinder the exploitation of the oil and gas resources therein. To address these challenges， we systematically analyze the volcanic facies types， reservoir physical properties， and storage space characteristics in the study area using data from core observations， log analysis， and laboratory tests. Accordingly， we establish lithofacies assemblage models， while clarifying their controlling effects on productivity. The results indicate that the volcanic rocks in the Jinlong oilfield in the Junggar Basin can be categorized into three facies： explosive， overflow， and volcanic sedimentary facies. The explosive facies， among others， consists primarily of welded volcaniclastic rocks and andesitic volcanic breccias， and exhibits an average porosity exceeding 10 %， forming dominant reservoirs. While the overflow facies is dominated by lavas， featuring an average porosity of below 6 %， and the volcanic sedimentary facies exhibits poor physical properties. In the volcanic reservoirs in the study area， vesicles， intra-amygdale pores， and dissolution pores predominate， with a minor presence of primary intergranular pores. Additionally， dissolution vugs are most developed at the top of the explosive and overflow facies. Fractures in the volcanic reservoirs are dominated by structural and dissolution fractures， with developmental degrees closely related to their distance from faults. The intermediate-acidic overflow facies mainly exhibits oblique and reticulate fractures， while the mafic overflow facies is dominated by high-angle， straight-split fractures. The study area exhibits four lithofacies assemblages： interbedded intermediate-acidic pyroclastic flow subfacies and intermediate-acidic overflow subfacies， frequently interbedded mafic pyroclastic flow subfacies and mafic overflow subfacies， interbedded neutral air-fall subfacies and neutral overflow subfacies， and interbedded neutral air-fall subfacies and intermediate-acidic pyroclastic flow subfacies. The interbedded neutral air-fall subfacies and intermediate-acidic pyroclastic flow subfacies exhibits the highest productivity， followed by interbedded intermediate-acidic pyroclastic flow subfacies and intermediate-acidic overflow subfacies and interbedded neutral air-fall subfacies and neutral overflow subfacies， and with the frequently interbedded mafic pyroclastic flow subfacies and mafic overflow subfacies coming at last in daily production. The productivity of the volcanic reservoirs is governed most significantly by the effective reservoir thickness and oil saturation， followed by porosity and formation pressure.

Key words: differential productivity, lithofacies assemblage, volcanic reservoir, Jiamuhe Formation, Jinlong oilfield, Junggar Basin

CLC Number:

TE122.2

Liyin BAO, Xiongqi PANG, Xinxuan CUI, Hongfei CHEN, Jun GAO, Liang ZOU, Zhencheng ZHAO, Chenxi WANG, Lei WANG, Wendong LI, Li LIU. Lithofacies assemblages and differential productivity of volcanic rocks in the Jiamuhe Formation， Jinlong oilfield， Junggar Basin[J]. Oil & Gas Geology, 2025, 46(1): 136-150.

Figures/Tables 14

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References 33

1	吴裕根，娄钰，门相勇. 油气是保障中国能源安全的重要基础［J］. 世界石油工业， 2022， 29（6）： 19-25.
	WU Yugen， LOU Yu， Xiangyong MEN. Oil and gas providing foundation for energy security in China［J］. World Petroleum Industry， 2022， 29（6）： 19-25.
2	李国欣，雷征东，董伟宏，等. 中国石油非常规油气开发进展、挑战与展望［J］. 中国石油勘探， 2022， 27（1）： 1-11.
	LI Guoxin， LEI Zhengdong， DONG Weihong， et al. Progress， challenges and prospects of unconventional oil and gas development of CNPC［J］. China Petroleum Exploration， 2022， 27（1）： 1-11.
3	王洛，李江海，师永民，等. 全球火山岩油气藏研究的历程与展望［J］. 中国地质， 2015， 42（5）： 1610-1620.
	WANG Luo， LI Jianghai， SHI Yongmin， et al. Review and prospect of global volcanic reservoirs［J］. Geology in China， 2015， 42（5）： 1610-1620.
4	侯连华，邹才能，匡立春，等. 准噶尔盆地西北缘克-百断裂带石炭系油气成藏控制因素新认识［J］. 石油学报， 2009， 30（4）： 513-517.
	HOU Lianhua， ZOU Caineng， KUANG Lichun， et al. Discussion on controlling factors for Carboniferous hydrocarbon accumulation in the Ke-Bai fractured zone of the northwestern margin in Junggar Basin［J］. Acta Petrolei Sinica， 2009， 30（4）： 513-517.
5	侯连华，邹才能，刘磊，等. 新疆北部石炭系火山岩风化壳油气地质条件［J］. 石油学报， 2012， 33（4）： 533-540.
	HOU Lianhua， ZOU Caineng， LIU Lei， et al. Geologic essential elements for hydrocarbon accumulation within Carboniferous volcanic weathered crusts in northern Xinjiang， China［J］. Acta Petrolei Sinica， 2012， 33（4）： 533-540.
6	SRUOGA P， RUBINSTEIN N. Processes controlling porosity and permeability in volcanic reservoirs from the Austral and Neuquén basins， Argentina［J］. AAPG Bulletin， 2007， 91（1）： 115-129.
7	罗静兰，侯连华，蒋宜勤，等. 陆东地区火成岩形成时代与构造背景及火山岩储层成因［J］. 石油学报， 2012， 33（3）： 351-360.
	LUO Jinglan， HOU Lianhua， JIANG Yiqin， et al. Chronology and tectonic settings of igneous rocks and origin of volcanic reservoirs in Ludong area， eastern Junggar Basin［J］. Acta Petrolei Sinica， 2012， 33（3）： 351-360.
8	罗静兰，林潼，杨知盛，等. 松辽盆地升平气田营城组火山岩岩相及其储集性能控制因素分析［J］. 石油与天然气地质， 2008， 29（6）： 748-757.
	LUO Jinglan， LIN Tong， YANG Zhisheng， et al. Lithofacies and reservoir quality control factors of volcanics in the Yingcheng Formation in the Shengping gas field in the Songliao Basin［J］. Oil & Gas Geology， 2008， 29（6）： 748-757.
9	罗静兰，曲志浩，孙卫，等. 风化店火山岩岩相、储集性与油气的关系［J］. 石油学报， 1996， 17（1）： 32-39.
	LUO Jinglan， QU Zhihao， SUN Wei， et al. The relations between lithofacies， reservoir lithology and oil and gas of volcanic rocks in Fenghuadian area［J］. Acta Petrolei Sinica， 1996， 17（1）： 32-39.
10	罗静兰，邵红梅，杨艳芳，等. 松辽盆地深层火山岩储层的埋藏-烃类充注-成岩时空演化过程［J］. 地学前缘， 2013， 20（5）： 175-187.
	LUO Jinglan， SHAO Hongmei， YANG Yanfang， et al. Temporal and spatial evolution of burial-hydrocarbon filling-diagenetic process of deep volcanic reservoir in Songliao Basin［J］. Earth Science Frontiers， 2013， 20（5）： 175-187.
11	罗静兰，邵红梅，张成立. 火山岩油气藏研究方法与勘探技术综述［J］. 石油学报， 2003， 24（1）： 31-38.
	LUO Jinglan， SHAO Hongmei， ZHANG Chengli. Summary of research methods and exploration technologies for volcanic reservoirs［J］. Acta Petrolei Sinica， 2003， 24（1）： 31-38.
12	WHITE J D L， ROSS P S. Volcanic processes and landforms in submarine settings： A review［J］. Geological Society of America Bulletin， 2011， 123（11/12）： 1243-1260.
13	MENZIES M A， XU Y G， et al. Volcanic rocks in the Earth’s interior： Composition， eruption， and formation［J］. Nature Reviews Earth & Environment， 2020， 1（4）： 243-256.
14	邹才能，杨智，张国生，等. 常规-非常规油气“有序聚集”理论认识及实践意义［J］. 石油勘探与开发， 2014， 41（1）： 14-25+27+26.
	ZOU Caineng， YANG Zhi， ZHANG Guosheng， et al. Geological concepts， characteristics， resource potential and key techniques of unconventional hydrocarbon： On unconventional petroleum geolog［J］. Petroleum Exploration and Development 2014， 41（1）： 14-25+27+26.
15	吴晓智，齐雪峰，唐勇，等. 东西准噶尔火山岩成因类型与油气勘探方向［J］. 中国石油勘探， 2009， 14（1）： 1-9.
	WU Xiaozhi， QI Xuefeng， TANG Yong， et al. Genetic types and hydrocarbon exploration directions of volcanic rocks in eastern and western Junggar［J］. China Petroleum Exploration， 2009， 14（1）： 1-9.
16	杨荣荣，周路，房涛，等. 准噶尔盆地金龙2地区佳木河组古地貌特征和油气藏分布关系研究［J］. 地球物理学进展， 2016， 31（5）： 2219-2225.
	YANG Rongrong， ZHOU Lu， FANG Tao， et al. Relationship between Jiamuhe paleogeomorphic features and hydrocarbon distribution of Jinlong-2 area in Junggar Basin［J］. Progress in Geophysics， 2016， 31（5）： 2219-2225.
17	何辉，李顺明，孔垂显，等. 准噶尔盆地西北缘二叠系佳木河组火山岩有效储层特征与定量评价［J］. 中国石油大学学报（自然科学版）， 2016， 40（2）： 1-12.
	HE Hui， LI Shunming， KONG Chuixian， et al. Characteristics and quantitative evaluation of volcanic effective reservoir in Jiamuhe Formation of Permian， northwestern margin of Junggar Basin［J］. Journal of China University of Petroleum （Edition of Natural Science）， 2016， 40（2）： 1-12.
18	李振华. 准噶尔盆地中拐地区佳木河组沉积特征与成岩环境研究［D］. 青岛：中国石油大学（华东）， 2014.
	LI Zhenhua. The research of sedimentary characteristics and diagenetic environment in Permian Jiamuhe Formation of Zhongguai area in the Junggar Basin‍［D］. Qingdao： China University of Petroleum （East China）， 2014.
19	蒋佳兵，陈如鹤，李小刚，等. 火山岩内幕型储层特征与主控因素——以准噶尔盆地滴南凸起滴水泉西断裂下盘为例［J］. 中国石油勘探， 2023， 28（2）： 119-132.
	JIANG Jiabing， CHEN Ruhe， LI Xiaogang， et al. Characteristics and main controlling factors of inner volcanic reservoir： A case study of the footwall of West Dishuiquan Fault in Dinan Bulge， Junggar Basin［J］. China Petroleum Exploration， 2023， 28（2）： 119-132.
20	魏周城. 准噶尔盆地金龙2井区火山岩岩性及裂缝识别与预测［D］. 北京：中国石油大学（北京）， 2019.
	WEI Zhoucheng. Identification and prediction of lithology and fracture of volcanic rocks in Jinlong 2 Well area， Junggar Basin［D］. Beijing： China University of Petroleum （Beijing）， 2019.
21	王德滋，周金城，刘昌实，等. 浙江桐庐自碎二长花岗斑岩的特征和成因［J］. 岩矿测试， 1982， 1（3）： 15-24， 8.
	WANG Dezi， ZHOU Jincheng， LIU Changshi， et al. The characteristics and the origin of the autoclastic monzonitic granite-porphyry， Tonglu， Zhejiang［J］. Rock and Mineral Analysis， 1982， 1（3）： 15-24， 8.
22	贺凯. 准噶尔盆地东部石炭系火山岩油气成藏规律研究［D］. 北京：中国地质大学（北京）， 2009.
	HE Kai. Study on the reservoir formation rule of volcanic rock of Carboniferous in the east of Junggar Basin［D］. Beijing： China University of Geosciences （Beijing）， 2009.
23	马尚伟. 准噶尔盆地东部西泉地区石炭系火山岩岩性岩相识别及储层主控因素研究［D］. 西安：西北大学， 2019.
	MA Shangwei. Identification of lithology and lithofacies and research on main controlling factors of the Carboniferous volcanic rocks reservoir， Xiquan area， Eastern Junggar Basin［D］. Xi’an： Northwest University， 2019.
24	潘虹，于庆森，李晓山，等. 准噶尔盆地红车断裂带石炭系重新认识及油气成藏特征［J］. 石油与天然气地质， 2024， 45（1）： 215-230.
	PAN Hong， YU Qingsen， LI Xiaoshan， et al. Recognition of the Carboniferous strata in the Hongche fault zone， Junggar Basin and its hydrocarbon accumulation characteristics［J］. Oil & Gas Geology， 2024， 45（1）： 215-230.
25	冯梓岩，殷文，钟云滔，等. 基于常规测井的火成岩岩性识别方法——以准噶尔盆地西北缘红车断裂带石炭系火成岩储层为例［J］. 东北石油大学学报， 2021， 45（5）： 95-108， 11-12.
	FENG Ziyan， YIN Wen， ZHONG Yuntao， et al. Lithologic identification of igneous rocks based on conventional log： A case study of Carboniferous igneous reservoir in Hongche Fault Zone in northwestern Junggar Basin［J］. Journal of Northeast Petroleum University， 2021， 45（5）： 95-108， 11-12.
26	毕力格. 准噶尔盆地西北缘佳木河组岩相古地理分析［D］. 北京：中国地质大学（北京）， 2021.
	BI Lige. Lithofacies and paleogeography analysis on the northwestern margin of the Junggar Basin［D］. Beijing： China University of Geosciences （Beijing）， 2021.
27	BOUMA A H. Sedimentology of some flysch deposits： A graphic approach to facies interpretation［M］. Amsterdam： Elsevier， 1962.
28	SCOTESE C R， SCHETTINO A. Chapter 3-Late Permian-Early Jurassic paleogeography of western Tethys and the world［M］//SOTO J I， FLINCH J F， TARI G. Permo-Triassic Salt Provinces of Europe， North Africa and the Atlantic Margins. Oxford： Elsevier， 2017： 57-95.
29	林向洋，苏玉平，郑建平，等. 准噶尔盆地克拉美丽气田复杂火山岩储层特征及控制因素［J］. 地质科技情报， 2011， 30（6）： 28-37.
	LIN Xiangyang， SU Yuping， ZHENG Jianping， et al. Characteristics and controlling factors of volcanic reservoir in Kelameili area of Jungger Basin［J］. Geological Science and Technology Information， 2011， 30（6）： 28-37.
30	李军，薛培华，张爱卿，等. 准噶尔盆地西北缘中段石炭系火山岩油藏储层特征及其控制因素［J］. 石油学报， 2008， 29（3）： 329-335.
	LI Jun， XUE Peihua， ZHANG Aiqing， et al. Characteristics and controlling factors of Carboniferous volcanic reservoir in the middle section of the northwestern margin of Junggar Basin［J］. Acta Petrolei Sinica， 2008， 29（3）： 329-335.
31	高嘉洪，金之钧，梁新平，等. 火山活动对鄂尔多斯盆地三叠系长7段淡水湖盆富营养化与沉积水体介质环境的影响［J］. 石油与天然气地质， 2023， 44（4）： 887-898.
	GAO Jiahong， JIN Zhijun， LIANG Xinping， et al. The impact of volcanism on eutrophication and water column in a freshwater lacustrine basin：A case study of Triassic Chang 7 Member in Ordos Basin［J］. Oil & Gas Geology， 2023， 44（4）： 887-898.
32	王宏博，马存飞，曹铮，等. 基于岩相的致密砂岩差异成岩作用及其储层物性响应［J］. 石油与天然气地质， 2023， 44（4）： 976-992.
	WANG Hongbo， MA Cunfei， CAO Zheng， et al. Differential diagenesis and reservoir physical property responses of tight sandstone based on lithofacies： A case study on the Lower Jurassic Sangonghe Formation in Moxizhuang area， Junggar Basin［J］. Oil & Gas Geology， 2023， 44（4）： 976-992.
33	韩豫，操应长，梁超，等. 川南地区五峰组—龙马溪组沉积环境演化及其对页岩发育的控制［J］. 中国石油大学学报（自然科学版）， 2024， 48（2）： 11-23.
	HAN Yu， CAO Yingchang， LIANG Chao， et al. Sedimentary environment evolution of Wufeng Formation-Longmaxi Formation and its control on shale deposition in the southern Sichuan Basin［J］. Journal of China University of Petroleum （Edition of Natural Science）， 2024， 48（2）： 11-23.

火山储集岩类型	孔隙度/%			渗透率/（10^-3μm²）
火山储集岩类型	最大值	最小值	平均值	最大值	最小值	平均值
流纹岩	10.14	0.81	4.42	0.11	0.01	0.06
英安岩	5.84	0.15	2.49	0.27	0.01	0.16
安山岩	10.01	0.66	6.64	0.27	0.01	0.08
玄武岩	13.08	1.19	6.59	0.67	0.01	0.22
流纹质熔结角砾岩	14.47	5.21	8.89	1.63	0.73	1.21
安山质熔结角砾岩	14.35	5.40	11.07	6.20	0.09	0.27
玄武质熔结角砾岩	19.85	8.21	12.87	17.42	0.13	3.12
安山质火山角砾岩	19.05	4.50	9.11	8.64	0.01	0.88

岩相组合	最低日产油气当量/t	最高日产油气当量/t	平均日产油气当量/t	井数/口
中性空落亚相-中-酸性热碎屑流亚相（D类）	36.15	64.10	50.13	2
中性热碎屑流亚相-中-酸性溢流相（A1类）	10.06	34.06	18.48	12
酸性热碎屑流亚相-中-酸性溢流相（A2类）	11.35	22.05	16.54	10
中性空落亚相-中性溢流亚相（C类）	14.47	18.47	16.47	2
基性热碎屑流亚相-基性溢流亚相（B类）	0.86	14.19	6.47	3

井号	试油段深度/m	岩相组合	爆发相有效储层厚度/m	有效储层测井解释平均孔隙度/%	有效储层测井解释平均含油饱和度/%	地层压力/MPa	平均日产当量/（t/d）
JL2008	4 242～4 268	D	23.4	14.76	67.9	52.96	64.10
JL2011	4 151～4 174	D	14.7	13.88	65.7	50.56	36.20
金214	4 128～4 144	A	10.4	12.80	52.3	51.00	16.80
金208	4 206～4 242	A	15.3	12.85	56.3	50.79	18.38
JL2107	4 121～4 151	B	17.1	12.42	34.8	49.95	2.41
JL2106	4 095～4 146	B	33.9	14.19	47.2	49.95	14.19
金209	4 234～4 247	C	9.0	13.53	55.1	52.11	14.10
金213	4 232～4 248	C	13.2	12.58	55.6	52.39	18.50

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Lithofacies assemblages and differential productivity of volcanic rocks in the Jiamuhe Formation， Jinlong oilfield， Junggar Basin

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