Relationship of Fault with Hydrocarbon Migration and Accumulation in Longfengshan Area, Changling Faulted Depression
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摘要: 长岭断陷龙凤山地区具有“下生上储、他源成藏”特征,明确断裂与油气运聚的关系对指导其油气勘探具有重要意义.在分析断裂静态特征的基础上,分别定量评价断裂的活动性、封闭性以及断-盖配置关系,并提出了评价断-盖配置有效性的“SGR下限”法(SGR全称是Shale Gouge Ratio),结合油气藏静态分布特征,探讨了断裂对油气差异聚集的控制作用.研究结果表明,第1期油气成藏早中期,断裂可大规模输导油气;第1期晚期及第2期油气成藏时,主干反向断裂形成的封闭“走廊”空间为油气提供聚集场所.应用“SGR下限”法,认为营Ⅲ砂组断-盖配置关系较好,为油气提供良好的保存条件.断裂控烃作用体现在3个方面,断裂的活动性控制了油气不同时期的垂向运移规模,断裂的封闭差异性控制了油气富集程度,断-盖配置关系控制了油气的富集层系.Abstract: Reservoirs in Longfengshan area are characterized by "other-source, generation in lower part, storage and accumulation in the upper part". It faclitates the hydrocarbon exploration by determining the fault control to hydrocarbon migration and accumulation. Based on precise illustration of the static characteristics of faults, fault activity, sealing capacity and fault-caprock configuration are evaluated quantitatively in this study. In addition, a method of SGR (Shale Gouge Ratio) lower limit for assessing fault-caprock configuration effectiveness is proposed. Combined with hydrocarbon distribution, the controlling effect on the differential accumulation of hydrocarbon is discussed. The study shows that hydrocarbon can migrate vertically through faults on a large scale at the early and middle stages of the first accumulation period. At the end of the first and the second accumulation periods, sealing corridor space formed by two faults is the main hydrocarbon accumulation site. Application of the SGR lower limit method indicates that fault-caprock configuration of K1yc3 is good enough to provide favourable conditions for hydrocarbon conservation. Consequently, the effect of faults controlling on hydrocarbon migration and accumulation can be summarized into following three aspects. This is fault activity controls the hydrocarbon vertical migration scale in different stages; fault sealing capacity controls the horizontal enrichment degree of hydrocarbon, and fault-caprock configuration controls petroliferous reservoir.
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图 1 龙凤山地区区域构造图顶(K1yc)及地层综合柱状图
Fig. 1. Regional structural map (the top of K1yc) and strata histogram of Longfengshan area
图 2 龙凤山地区各时期断层活动速率直方图
Fig. 2. The histogram of fault active rate in different stages in Longfengshan area
图 3 不同构造带断裂活动期与成藏期匹配图
Fig. 3. The configuration of accumulation period and fault active stage in different structural belts
图 4 第1期油气成藏时断裂类型分布图(K1yc3顶)
Fig. 4. The distribution of different type faults in the first period of hydrocarbon accumulation in Longfengshan area (top of K1yc3)
图 6 F5断裂不同部位泥岩涂抹特征图
Fig. 6. Clay smear oharacteristics in different positions of F5 fault
图 8 平行F4断裂下降盘波阻抗反演剖面(剖面M)及其上升盘油气藏剖面(剖面N)对比
Fig. 8. Comparison of wave impedance inversion section (Section M) of downthrown side and hydrocarbon accumulation section (Section N) of uplifted side paralleled to F4 fault
图 9 F10断层封闭性及其与油气的关系
Fig. 9. F10 fault sealing characteristic and its relationship with hydrocarbon distribution
图 10 龙凤山地区营Ⅲ砂组断-盖配置评价测点位置
Fig. 10. Measure point location for assessing fault-caprock configuration in K1yc3 Formation in Longfengshan area
图 11 龙凤山地区地层岩石排替压力与其埋深、泥质含量乘积之间的关系
Fig. 11. Relation among displacement pressure and product of buried depth and mudstone content in Longfengshan area
表 1 龙凤山地区断层岩与储层排替压力计算参数
Table 1. The current calculation parameters for fault rock and reservoir displacement pressure in Longfengshan area
断
层测
点埋
深
(m)储层泥
质含量
(%)储层排
替压力
(MPa)断层成
岩时间
(Ma)围岩成
岩时间
(Ma)cosθ SGR 断层成
岩深度
(m)断层岩排
替压力
(MPa)排替压
力差
(MPa)断-盖配置有
效性的SGR
下限值最大油
柱高度
(m)F4 1 2 826 12.2 0.729 106.125 113.64 0.813 0.46 1 294.013 0.961 0.231 0.266 118.05 2 2 675 13.7 0.747 105.4 113.64 0.800 0.45 1 196.833 0.903 0.156 0.306 79.44 3 2 560 13.8 0.736 106.125 113.64 0.782 0.47 1 128.149 0.894 0.158 0.313 80.72 4 2 496 12.5 0.704 108 113.64 0.595 0.54 851.196 0.828 0.124 0.367 63.30 5 2 240 12.5 0.679 105.4 113.64 0.554 0.49 694.717 0.726 0.047 0.403 23.81 F5 6 2 975 9.3 0.677 106.125 113.64 0.831 0.56 1 392.57 1.177 0.500 0.199 255.28 7 2 810 13.6 0.760 106.125 113.64 0.940 0.42 1 487.154 0.992 0.232 0.257 118.52 8 2 700 13.6 0.748 102.5 113.64 0.890 0.48 1 307.329 0.995 0.247 0.281 126.47 9 2 550 14.5 0.750 108 113.64 0.826 0.52 1 207.737 0.996 0.246 0.306 125.68 F2 10 2 000 16.6 0.719 106.125 113.64 0.893 0.67 1 005.997 1.048 0.219 0.330 111.62 F9 11 3 000 8.9 0.670 105.4 113.64 0.554 0.52 930.425 0.850 0.180 0.287 92.02 F10 12 3 500 13.1 0.857 99 113.64 0.558 0.58 1 026.271 0.961 0.134 0.447 68.46 F15 13 3 950 14.4 0.897 105.4 113.64 0.605 0.40 1 252.498 0.866 -0.031 0.425 / F19 14 3 700 16.9 1.040 108 113.64 0.447 0.53 1 012.087 0.901 -0.140 0.660 / F11 15 2 388 15.8 0.756 103.95 113.64 0.750 0.38 988.171 0.754 -0.002 0.382 / 
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[1] Carolyn, L., Song, G.Q., Cong, L.Z., et al., 2012.Fault Control on Hydrocarbon Migration and Accumulation in the Tertiary Dongying Depression, Bohai Basin, China.AAPG Bulletin, 96(6):983-1000. doi: 10.1306/11031109023 [2] Childs, C., Sylta, Ø., Moriya, S., et al., 2009.Calibrating Fault Seal Using a Hydrocarbon Migration Model of the Oseberg Syd Area, Viking Graben.Marine & Petroleum Geology, 14(2):764-774. http://linkinghub.elsevier.com/retrieve/pii/S0264817208001001 [3] Doughty, P.T., 2003.Clay Smear Seals and Fault Sealing Potential of an Exhumed Growth Fault, Rio Grande Rift, New Mexico.AAPG Bulletin, 87(3):427-444. doi: 10.1306/10010201130 [4] Fu, G., Xu, B.L., Li, N., 2016.A Method of Judging Lateral Sealing of Fault by Mudstone Content of Fault Rock and Its Application.Lithologic Reservoirs, 28(2):101-106 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-YANX201602016.htm [5] Fu, G., Wang, H.R., Hu, X.L., 2015.Prediction Method and Application of Caprock Faulted-Contact Thickness Lower Limit for Oil-Gas Sealing in Fault Zone.Journal of China University of Petroleum (Edition of Natural Sciences), 39(3):30-37 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-SYDX201503004.htm [6] Fu, G., Yang, J.B., 2013.Sealing of Matching between Fault and Caprock to Oil-Gas Migration along Faults:An Example from Middle and Shallow Strata in Nanpu Depression.Earth Science, 38(4):783-791 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-DQKX201304012.htm [7] Fu, X.F., Jia, R., Wang, H.X., et al., 2015.Quantitative Evaluation of Fault-Caprock Sealing Capacity:A Case from Dabei-Kelasu Structural Belt in Kuqa Depression, Tarim Basin, NW China.Petroleum Exploration and Development, 42(3):300-309 (in Chinese with English abstract). http://www.sciencedirect.com/science/article/pii/S1876380415300239 [8] Gui, L.L., Liu, K.Y., Liu, S.B., et al., 2015.Hydrocarbon Charge History of Yingdong Oilfield, Western Qaidam Basin.Earth Science, 40(5):890-899 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTotal-DQKX201505012.htm [9] Hao, F., Zou, H.Y., Gong, Z.S., et al., 2006.The Material and Energy Effects of Neotectonics/Late-Stage Tectonics and Petroleum Accumulation.Acta Geologica Sinica, 80(3):424-431 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-DZXE200603015.htm [10] Jiang, Y.L., Liu, H., 2010.Fault Asphalt Zone and Its Significance in Petroleum Geology.Acta Petrolei Sinica, 31(1):36-41. http://en.cnki.com.cn/Article_en/CJFDTOTAL-SYXB201001008.htm [11] Jiang, Y.L., Liu, P., Liu, H., et al., 2014.Difference of Reservoir Forming Conditions of Different Depressions and Accumulation Models of Neogene Hydrocarbon in Bohai Bay Basin.Journal of China University of Petroleum (Natural Science Edition), 38(1):14-21. http://en.cnki.com.cn/Article_en/CJFDTOTAL-SYDX201401004.htm [12] Jiang, Y.L., Liu, P., Song, G.Q., et al., 2015.Late Cenozoic Faulting Activities and Their Influence upon Hydrocarbon Accumulations in the Neogene in Bohai Bay Basin.Oil & Gas Geology, 36(4):525-533 (in Chinese with English abstract). [13] Jin, Z.J., Yuan, Y.S., Sun, D.S., et al., 2014.Models for Dynamic Evaluation of Mudstone/Shale Cap Rocks and Their Applications in the Lower Paleozoic Sequences, Sichuan Basin, SW China.Marine & Petroleum Geology, 49(49):121-128. http://www.sciencedirect.com/science/article/pii/S0264817213002444 [14] Li, F., Jiang Z.X., Li, Z., et al., 2015.Enriched Mechanism of Natural Gas of Lower Jurassic in Dibei Area, Kuqa Depression.Earth Science, 40(9):1538-1548 (in Chinese with English abstract). [15] Lu, J.L., Wang, G.S., Cai, J.G., et al., 2007.An Analysis of Exploration Potential of Volcanic Gas Pools in Changling Fault Depression.Natural Gas Industry, 27(8):13-15 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-TRQG200708008.htm [16] Luo, Q., 2010.Concept, Principle, Model and Significance of the Fault Controlling Hydrocarbon Theory.Petroleum Exploration and Development, 37(3):316-324 (in Chinese with English abstract). doi: 10.1016/S1876-3804(10)60035-3 [17] Lü, Y.F., Wan, J., Sha, Z.X., et al., 2008.Evaluation Method for Seal Ability of Cap Rock Destructed by Faulting and Its Application.Chinese Journal of Geology, 43(1):162-174 (in Chinese with English abstract). [18] Pang, X.Q., Luo, Q., Jiang, Z.X., et al., 2003.Accumulating Diversity and Its Mechanism between Hanging and Lower Walls of Fault in Superimposed Basin.Chinese Journal of Geology, 38(3):297-306 (in Chinese with English abstract). [19] Peng, H.J., Pang, X.Q., Li, H.B., et al., 2016.Quantitative Evaluation of Control of Faults on Hydrocarbon Accumulation and Play Fairway Prediction in Zhu Ⅰ Depression of Pearl River Mouth Basin.Geoscience, 30(6):1318-1328 (in Chinese with English abstract). [20] Qiao, H.S., Niu, J.Y., Wang, M.M., 1999.The Principle and Exploration Practice of Hydrocarbon Accumulation Sealed by Backward Faults in Deep Formation of Eastern China.Petroleum Exploration and Development, 26(6):10-13 (in Chinese with English abstract). [21] Qin, D., Huang, G.X., Li, R.L., et al., 2016.Main Controlling Factors for Gas Accumulation in Clastic Rocks in Fault Depression, Southern Songliao Basin:A Case Study on Longfengshan Sub-Sag, Changling Fault Depression.China Petroleum Exploration, 21(3):52-61 (in Chinese with English abstract). [22] Reilly, C., Nicol, A., Walsh, J.J., et al., 2015.Temporal Changes of Fault Seal and Early Charge of the Maui Gas-Condensate Field, Taranaki Basin, New Zealand.Marine & Petroleum Geology, 70:237-250. http://www.sciencedirect.com/science/article/pii/S0264817215301410?via=sd [23] Shi, J.J., Li, L.L., Fu, G., et al., 2012.Quantitative Evalution Method and Application of Vertical Sealing Property of Faults in Caprock.Journal of Jilin University (Earth Science Edition), 42(Suppl.2):162-170 (in Chinese with English abstract). http://www.sciencedirect.com/science/article/pii/S1876380416300404 [24] Teng, C.Y., Zou, H.Y., Hao, F., 2014.Control of Differential Tectonic Evolution on Petroleum Occurrence in Bohai Bay Basin.Science China Earth Sciences, 57(5):1117-1128. doi: 10.1007/s11430-013-4771-6 [25] Wan, T., Jiang, Y.L., Dong, Y.X., et al., 2012.Relationship between Fault Activity and Hydrocarbon Accumulation and Enrichment in Nanpu Depression.Journal of China University of Petroleum (Edition of Natural Sciences), 36(2):60-67 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-SYDX201202009.htm [26] Wan, T., Jiang, Y.L., Dong, Y.X., et al., 2013.Reconstructed and Traced Pathways of Hydrocarbon Migration in Nanpu Depression, Bohai Bay Basin.Earth Science, 38(1):173-180 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-DQKX201301022.htm [27] Wang, H.J., Wu, Y.Y., 2011.Distribution Patterns and Controlling Factors of Volcanic Gas Pools in the Changling Fault Depression, the Songliao Basin.Oil & Gas Geology, 32(3):360-367 (in Chinese with English abstract). http://en.cnki.com.cn/Article_en/CJFDTOTAL-SYYT201103011.htm [28] Wei, D.N., Fu, G., 2016.Quantitative Explanation of Mechanism about Lower Wall of Antithetic Faults Accumulating More Oil-Gasthan Upper Wall of Consequent Faults.Journal of Jilin University (Earth Science Edition), 46(3): 702-710 (in Chinese with English abstract). [29] Yielding, G., 2012.Using Probabilistic Shale Smear Modelling to Relate SGR Predictions of Column Height to Fault-Zone Heterogeneity.Petroleum Geoscience, 18(1):33-42. doi: 10.1144/1354-079311-013 [30] Zhang, Y.F., Wang, G.Q., Fu, B.L., et al., 2011.The Diagenesis and the Origin of Abnormal High Porosity Zone in the Deep Classtic Reservoir in Changling Fault Depression.Journal of Jilin University (Earth Science Edition), 41(2):372-376, 454 (in Chinese with English abstract). [31] Zhou, Z.M., Wang, B.H., Zhu T.X., et al., 2011.Source Rock Features and Exploration Potential of Huoshiling Formation, Changling Fault Depression.Petroleum Geology & Experiment, 33(6):613-616, 623 (in Chinese with English abstract). [32] 付广, 宿碧霖, 历娜, 2016.一种利用断层岩泥质含量判断断层侧向封闭性的方法及其应用.岩性油气藏, 28(2): 101-106. http://www.cnki.com.cn/Article/CJFDTOTAL-YANX201602016.htm [33] 付广, 王浩然, 胡欣蕾, 2015.断裂带盖层油气封盖断接厚度下限的预测方法及应用.中国石油大学学报(自然科学版), 39(3): 30-37. http://www.cnki.com.cn/Article/CJFDTOTAL-SYDX201503004.htm [34] 付广, 杨敬博, 2013.断盖配置对沿断裂运移油气的封闭作用:以南堡凹陷中浅层为例.地球科学, 38(4): 783-791. http://www.earth-science.net/WebPage/Article.aspx?id=2753 [35] 付晓飞, 贾茹, 王海学, 等, 2015.断层-盖层封闭性定量评价——以塔里木盆地库车坳陷大北-克拉苏构造带为例.石油勘探与开发, 42(3): 300-309. http://www.cnki.com.cn/Article/CJFDTOTAL-SKYK201503007.htm [36] 桂丽黎, 刘可禹, 柳少波, 等, 2015.柴达木盆地西部英东地区油气成藏过程.地球科学, 40(5): 890-899. http://www.earth-science.net/WebPage/Article.aspx?id=3081 [37] 郝芳, 邹华耀, 龚再升, 等, 2006.新(晚期)构造运动的物质、能量效应与油气成藏.地质学报, 80(3): 424-431. http://www.cnki.com.cn/Article/CJFDTOTAL-DZXE200603015.htm [38] 蒋有录, 刘华, 2010.断裂沥青带及其油气地质意义.石油学报, 31(1): 36-41. doi: 10.7623/syxb201001006 [39] 蒋有录, 刘培, 刘华, 等, 2014.渤海湾盆地不同凹陷新近系油气成藏条件差异性及聚集模式.中国石油大学学报:自然科学版, 38(1): 14-21. http://www.cnki.com.cn/Article/CJFDTOTAL-SYDX201401004.htm [40] 蒋有录, 刘培, 宋国奇, 等, 2015.渤海湾盆地新生代晚期断层活动与新近系油气富集关系.石油与天然气地质, 36(4): 525-533. doi: 10.11743/ogg20150401 [41] 李峰, 姜振学, 李卓, 等, 2015.库车坳陷迪北地区下侏罗统天然气富集机制.地球科学, 40(9): 1538-1548. http://www.earth-science.net/WebPage/Article.aspx?id=3157 [42] 陆建林, 王果寿, 蔡进功, 等, 2007.长岭断陷火山岩气藏勘探潜力.天然气工业, 27(8): 13-15. http://www.cnki.com.cn/Article/CJFDTOTAL-TRQG200708008.htm [43] 罗群, 2010.断裂控烃理论的概念、原理、模式与意义.石油勘探与开发, 37(3): 316-324. http://www.cnki.com.cn/Article/CJFDTOTAL-SKYK201003010.htm [44] 吕延防, 万军, 沙子萱, 等, 2008.被断裂破坏的盖层封闭能力评价方法及其应用.地质科学, 43(1): 162-174. http://www.cnki.com.cn/Article/CJFDTOTAL-DZKX200801014.htm [45] 庞雄奇, 罗群, 姜振学, 等, 2003.叠合盆地断裂上、下盘油气差异聚集效应及成因机理.地质科学, 38(3): 297-306. http://www.cnki.com.cn/Article/CJFDTOTAL-DZKX200303003.htm [46] 彭辉界, 庞雄奇, 李洪博, 等, 2016.珠江口盆地珠一坳陷断裂控藏定量表征与有利勘探区预测.现代地质, 30(6): 1318-1328. http://www.cnki.com.cn/Article/CJFDTOTAL-XDDZ201606014.htm [47] 谯汉生, 牛嘉玉, 王明明, 1999.中国东部深部层系反向断层遮挡聚油原理与勘探实践.石油勘探与开发, 26(6): 10-13. http://www.cnki.com.cn/Article/CJFDTOTAL-SKYK199906003.htm [48] 秦都, 黄桂雄, 李瑞磊, 等, 2016.松辽盆地南部断陷层碎屑岩天然气成藏主控因素分析——以长岭断陷龙凤山次凹为例.中国石油勘探, 21(3): 52-61. http://www.cnki.com.cn/Article/CJFDTOTAL-KTSY201603005.htm [49] 史集建, 李丽丽, 付广, 等, 2012.盖层内断层垂向封闭性定量评价方法及应用.吉林大学学报(地球科学版), 42(S2): 162-170. http://www.cnki.com.cn/Article/CJFDTOTAL-CCDZ2012S2020.htm [50] 万涛, 蒋有录, 董月霞, 等, 2012.南堡凹陷断层活动与油气成藏和富集的关系.中国石油大学学报(自然科学版), 36(2): 60-67. http://www.cnki.com.cn/Article/CJFDTOTAL-SYDX201202009.htm [51] 万涛, 蒋有录, 董月霞, 等, 2013.渤海湾盆地南堡凹陷油气运移路径模拟及示踪.地球科学, 38(1): 173-180. http://www.earth-science.net/WebPage/Article.aspx?id=2354 [52] 王洪江, 吴聿元, 2011.松辽盆地长岭断陷火山岩天然气藏分布规律与控制因素.石油与天然气地质, 32(3): 360-367. doi: 10.11743/ogg20110307 [53] 韦丹宁, 付广, 2016.反向断裂下盘较顺向断裂上盘更易富集油气机理的定量解释.吉林大学学报(地球科学版), 46(3): 702-710. http://www.cnki.com.cn/Article/CJFDTOTAL-CCDZ201603008.htm [54] 张云峰, 王国强, 付宝利, 等, 2011.长岭断陷深层碎屑岩储层成岩作用及异常高孔带成因.吉林大学学报(地球科学版), 41(2): 372-376, 454. http://www.cnki.com.cn/Article/CJFDTOTAL-CCDZ201102008.htm [55] 周卓明, 王保华, 朱廷祥, 等, 2011.长岭断陷火石岭组烃源岩特征及勘探远景分析.石油实验地质, 33(6): 613-616, 623. doi: 10.11781/sysydz201106613 -
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