利用地震岩石物理模拟预测三湖地区生物气成藏单元

doi:10.3969/j.issn.1673-8926.2010.04.004

Lithologic Reservoirs ›› 2010, Vol. 22 ›› Issue (4): 20-24.doi: 10.3969/j.issn.1673-8926.2010.04.004

Previous Articles Next Articles

Using seismic rock physics modeling to predict accumulation unit of biogenetic gas in Sanhu area

ZHENG Hongjun¹， CAO Zhenglin¹， YAN Cunfeng¹， XU Ziyuan²， SUN Songling¹

1. Research Institute of Petroleum Exploration & Development-Northwest（NWGI）， PetroChina， Lanzhou 730020， China； 2. Research Institute of Exploration and Development， Qinghai Oilfield Company， PetroChina， Dunhuang 736200， China

Online:2010-12-15 Published:2010-12-15

Abstract

Abstract:

Aimed at the Quaternary thin interbed of loose sand and shale in Sanhu area, the exploration of biogenetic gas is analyzed. It pointed out that to quantitatively predict the gas reservoir accumulation unit and the heterogeneity of the controlling factors is the key for looking for lowsaturation lithologic gas reservoir in the eight major slope areas. Based on the seismic data, combined with logging, geology and testing data, as well as making the two dimensional seismic data gridding, the variogram analysis and sequential indicator stochastic simulation method are applied to establish 3D petrophysical stochastic model, and the petrophysical properties body is obtained which is more sensitive to gas-bearing abnormal. The most sensitive gas threshold range of petrophysical properties body is analyzed so as to build up the gas and water identification model, and carry out the fluid substitution for the 3D model of petrophysical properties. The grid cell distribution model and seismic reservoir unit are obtained and finally the possible 3D spatial distribution characteristics of biogenetic gas reservoir can be acquired. The drilling result shows that the S wave petrophysical simulation method guided by seismic-petroleum accumulation science can predict the 3D distribution of natural gas reservoir, and good application effects are obtained.

Key words: slope, tectonic quiet zone, triangle zone of denudation, paleogeomorphology, TarimBasin

ZHENG Hongjun， CAO Zhenglin， YAN Cunfeng， XU Ziyuan， SUN Songling. Using seismic rock physics modeling to predict accumulation unit of biogenetic gas in Sanhu area[J].Lithologic Reservoirs, 2010, 22(4): 20-24.

References

［1］杨杰，卫平生，李相博.石油地震地质学的基本概念、内容和研究方法［J］.岩性油气藏，2010，22（1）：1-6.
［2］卫平生，潘建国，张虎权，等.地震储层学的概念、方法和技术［J］.岩性油气藏，2010，22（2）：1-6.
［3］朱如凯，毛治国，郭宏莉，等.火山岩油气储层地质学———思考与建议［J］.岩性油气藏，2010，22（2）：7-13.
［4］张虎权，卫平生，潘建国，等.碳酸盐岩地震储层学［J］.岩性油气藏，2010，22（2）：14-17.
［5］张子枢，吴邦辉.国内外火山岩油气藏研究现状及勘探技术调研［J］.天然气勘探与开发，1994，16（1）：1-26.
［6］罗静兰，邵红梅，张成立，等.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.
［7］伊培荣，彭峰，韩芸，等.国外火山岩油气藏特征及其勘探方法［J］.特种油气藏，1998，15（2）：69-70.
［8］陈建文.一门新兴的边缘科学———火山岩储层地质学［J］.海洋地质动态，2002，18（4）：19-22.
［9］孙善平，刘永顺，钟蓉，等.火山碎屑岩分类评述及火山沉积学研究展望［J］.岩石矿物学杂志，2001，20（3）：313-317.
［10］赵海玲，刘振文，李剑，等.火成岩油气储层的岩石学特征及研究方向［J］.石油与天然气地质，2004，25（6）：609-613.
［11］黄亮，彭军，周康，等.火山岩储层形成机制研究综述［J］.特种油气藏，2009，16（1）：1-5.
［12］杨仁超.储层地质学研究新进展［J］.特种油气藏，2006，13（4）：1-5.
［13］谢家莹，蓝善先，张德宝，等.运用火山地质学理论研究竹田头火山机构［J］.火山地质与矿产，2000，21（2）：87-95.
［14］王拥军，李志平，冉启全，等.火山岩储层微裂缝研究［J］.国外测井技术，2006，21（3）：27-30.
［15］陈庆春，朱东亚，胡文暄，等.试论火山岩储层的类型及其成因［J］.地质论评，2003，49（3）：286-291.
［16］潘保芝，张丽华，单刚义，等.裂缝和孔洞型储层孔隙模型的理论进展［J］.地球物理学进展，2006，21（4）：1 232-1 237.
［17］王芙蓉，陈振林，田继军，等.火山岩储集性研究［J］.重庆石油高等专科学校学报，2003，（5）：44-47.
［18］赵澄林.火山岩储层储集空间形成机理及含油气性［J］.地质论评，1996，42（增刊）：37-43.
［19］王全柱.火成岩储层研究［J］.西安石油大学学报：自然科学版，2004，19（2）：13-16.
［20］李长山，陈建文，游俊，等.火山岩储层建模初探［J］.地学前缘，2000，7（4）：381-389.
［21］于兴河，李剑峰.油气储层研究所面临的挑战与新动向［J］.地学前缘，1995，2（3/4）：213-220.
［22］侯贵卿，孙萍.油气储层研究新动向［J］.海洋石油，2000，103（1）：8-14.
［23］刘宪斌，林金逞，韩春明，等.地震储层研究的现状及展望［J］.地球学报，2002，23（1）：73-78.
［24］祖振杰，叶松.纵观近代岩矿测试分析技术［J］.地学前缘，1994，1（1/2）：188-192.
［25］操应长，姜在兴.沉积学实验方法和技术［M］.北京：石油工业出版社，2003：54-65.
［26］袁云峰，秦启荣，肖风学，等.火山岩岩性识别技术发展现状研究［J］.内蒙古石油化工，2007，5：270-272.
［27］王廷光. 储层地震反演方法及应用中的关键问题与对策［J］.石油物探，2002，41（3）：299-303.
［28］李长宝.模型正演和波阻抗反演技术储层识别研究［J］.胜利油田职工大学学报，2007，21（4）：56-57.
［29］刘军迎，雍学善，高建虎.模型正演技术在碳酸盐岩油气藏地震资料解释中的应用［J］.岩性油气藏，2007，19（1）：109-112.
［30］陆基孟.地震勘探原理［M］.东营：石油大学出版社，1993：340-341.
［31］郭华军，刘庆成.地震属性技术的历史、现状及发展趋势［J］.物探与化探，2008，32（1）：19-22.
［32］卫平生，张虎权，王宏斌，等.塔中地区缝洞碳酸盐岩储层的地球物理预测方法［J］.天然气工业，2009，29（3）：38-40.
［33］罗振丽，张爱敏，丁在宇.相干体技术和图像处理技术在检测断层中的应用［J］.中国煤田地质，2004，16（3）：48-50.
［34］李玉新.地震相干技术在断层与沉积相解释中的应用［J］.沉积与特提斯地质，2006，26（3）：67-71.
［35］许多年，蒋春玲，潘建国，等.Epos3.0 地震解释系统在准噶尔盆地车排子地区火山岩油气勘探中的应用［J］.岩性油气藏，2009，21（1）：112-114.
［36］王玉学，韩大匡，刘文岭，等.相干体技术在火山岩预测中的应用［J］.石油物探，2006，45（2）：192-196.
［37］龚洪林，潘建国，王宏斌，等.塔中碳酸盐岩综合预测技术及应用［J］.天然气工业，2008，26（6）：31-33.
［38］王瑞英，汤新啼，宋承文.烃类检测技术在吐哈盆地油气勘探中的应用［J］.吐哈油气，2002，7（3）：235-237.
［39］徐怀民，刘泽容，许敬.综合烃类检测技术及其在早期油藏描述中的应用［J］.地质论评，1993，39（4）：308-314.
［40］殷八斤.AVO 技术的理论与实践［M］.北京：石油工业出版社，1995：76-77.
［41］胡贤根，尚新民，石林光，等.基于叠前时间偏移资料的AVO处理技术［J］.石油物探，2002，41（3）：343-346.
［42］陈建阳，于兴河.储层地质建模在油藏描述中的应用［J］.大庆石油地质与开发，2005，24（3）：17-18.
［43］张婷，徐守业.储层地质建模技术研究与展望［J］.长春理工大学学报，2009，41（4）：191-192.

Related Articles 15

[1]	YU Qixiang, LUO Yu, DUAN Tiejun, LI Yong, SONG Zaichao, WEI Qingliang. Reservoir forming conditions and exploration prospect of Jurassic coalbed methane encircling Dongdaohaizi sag，Junggar Basin [J]. Lithologic Reservoirs, 2024, 36(6): 45-55.
[2]	HE Wenyuan, CHEN Keyang. Prediction method for lithologic reservoirs in Doshan slope zone of South Turgai Basin，Kazakhstan [J]. Lithologic Reservoirs, 2024, 36(4): 1-11.
[3]	BAO Hanyong, ZHAO Shuai, ZHANG Li, LIU Haotian. Exploration achievements and prospects for shale gas of Middle-Upper Permian in Hongxing area，eastern Sichuan Basin [J]. Lithologic Reservoirs, 2024, 36(4): 12-24.
[4]	WANG Tongchuan, CHEN Haoru, WEN Longbin, QIAN Yugui, LI Yuzhuo, WEN Huaguo. Identification and reservoir significance of Carboniferous karst paleogeomorphology in Wubaiti area，eastern Sichuan Basin [J]. Lithologic Reservoirs, 2024, 36(4): 109-121.
[5]	TIAN Ya, LI Junhui, CHEN Fangju, LI Yue, LIU Huaye, ZOU Yue, ZHANG Xiaoyang. Tight reservoir characteristics and favorable areas prediction of Lower Cretaceous Nantun Formation in central fault depression zone of Hailar Basin [J]. Lithologic Reservoirs, 2024, 36(4): 136-146.
[6]	LU Keliang, WU Kangjun, LI Zhijun, SUN Yonghe, XU Shaohua, LIANG Feng, LIU Lu, LI Shuang. Characteristics and evolution model of hydrocarbon accumulation of Cambrian Longwangmiao Formation in the north slope of central Sichuan paleo-uplift [J]. Lithologic Reservoirs, 2024, 36(4): 159-168.
[7]	NIU Chengmin, HUI Guanzhou, DU Xiaofeng, GUAN Dayong, WANG Bingjie, WANG Qiming, ZHANG Hongguo. Sedimentary model of sublacustrine fan of the third member of Paleogene Dongying Formation and large-scale oilfield discovered in western slope of Liaozhong Sag [J]. Lithologic Reservoirs, 2024, 36(2): 33-42.
[8]	WANG Tianhai, XU Duonian, WU Tao, GUAN Xin, XIE Zaibo, TAO Huifei. Sedimentary facies distribution characteristics and sedimentary model of Triassic Baikouquan Formation in Shawan Sag，Junggar Basin [J]. Lithologic Reservoirs, 2024, 36(1): 98-110.
[9]	LONG Shengfang, HOU Yunchao, YANG Chao, GUO Yixuan, ZHANG Jie, ZENG Yali, GAO Nan, LI Shanghong. Sequence stratigraphy and evolution of Triassic Chang 7 to Chang 3 mebers in Qingcheng area，southwestern Ordos Basin [J]. Lithologic Reservoirs, 2024, 36(1): 145-156.
[10]	SUN Hanxiao, XING Fengcun, XIE Wuren, QIAN Hongshan. Lithofacies paleogeography evolution of Late Ordovician in Sichuan Basin and its surrounding areas [J]. Lithologic Reservoirs, 2024, 36(1): 121-135.
[11]	DENG Yuan, CHEN Xuan, QIN Jianhua, LI Yingyan, HE Jixiang, TAO Xin, YIN Taiju, GAO Yang. Paleogeomorphology and favorable reservior distribution of the first member of Permian Lucaogou Formation in Jimsar Sag [J]. Lithologic Reservoirs, 2024, 36(1): 136-144.
[12]	LIU Jiguo, ZHOU Hongpu, QIN Yanqun, ZOU Quan, ZHENG Fengyun, LI Zaohong, XIAO Gaojie. Exploration potential of lithologic reservoirs of Cretaceous AG Formation in Fula Sag,Muglad Basin,Africa [J]. Lithologic Reservoirs, 2023, 35(6): 82-91.
[13]	LUO Beiwei, YIN Jiquan, HU Guangcheng, CHEN Hua, KANG Jingcheng, XIAO Meng, ZHU Qiuying, DUAN Haigang. Characteristics and controlling factors of high porosity and permeability limestone reservoirs of Cretaceous Cenomanian in the western United Arab Emirates [J]. Lithologic Reservoirs, 2023, 35(6): 63-71.
[14]	MA Wenjie, WAGN Jingchun, TIAN Zuoji, MA Zhongzhen, WAN Xuepeng, LIN Jincheng, XU Xianglin, ZHOU Yubing. Accumulation model and favorable area prediction of structural-lithologic composite reservoirs in block W,the slope zone of Oriente Basin,South America [J]. Lithologic Reservoirs, 2023, 35(6): 29-36.
[15]	PAN Shuxin, XU Duonian, TANG Yong, QU Yongqiang, WANG Guodong, DONG Xuemei, HU Tingting, MA Yongping. Discovery of Liushugou river depositional system in Shawan Sag of Junggar Basin and its petroleum geological significance [J]. Lithologic Reservoirs, 2023, 35(5): 26-36.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 10

[1]	PANG Xiongqi,CHEN Dongxia, ZHANG Jun. Concept and categorize of subtle reservoir and problems in its application[J]. Lithologic Reservoirs, 2007, 19(1): 1 -8 .
[2]	LEI Bianjun, ZHANG Ji,WANG Caili,WANG Xiaorong, LI Shilin, LIU Bin. Control of high r esolution sequence str atigr aphy on microfacies and reservoir s: A case from the upper Ma 5 member in Tong 5 wellblock, Jingbian Gas Field[J]. Lithologic Reservoirs, 2008, 20(1): 1 -7 .
[3]	YANG Jie，WEI Pingsheng， LI Xiangbo. Basic concept, content and research method of petroleum seismogeology[J]. Lithologic Reservoirs, 2010, 22(1): 1 -6 .
[4]	WANG Yan-qi1，HU Min-yi1，LIU Fu-yan1，WANG Hui1，HU Zhi-hua1,2. [J]. LITHOLOGIC RESERVOIRS, 2008, 20(3): 44 -48 .
[5]	DAI Liming, LI Jianping, ZHOU Xinhuai, CUI Zhongguo, CHENG Jianchun. Depositional system of the Neogene shallow water delta in Bohai Sea area[J]. Lithologic Reservoirs, 2007, 19(4): 75 -81 .
[6]	DUAN Youxiang, CAO Jing, SUN Qifeng. Application of auto-adaptive dip-steering technique to fault recognition[J]. Lithologic Reservoirs, 2017, 29(4): 101 -107 .
[7]	HUANG Long, TIAN Jingchun, XIAO Ling, WANG Feng. Characteristics and evaluation of Chang 6 sandstone reservoir of Upper Triassic in Fuxian area, Ordos Basin[J]. Lithologic Reservoirs, 2008, 20(1): 83 -88 .
[8]	YANG Shiwei, LI Jianming. Characteristics and geological significance of seismites[J]. Lithologic Reservoirs, 2008, 20(1): 89 -94 .
[9]	LI Chuanliang, TU Xingwan. Two types of stress sensitivity mechanisms for reservoir rocks:Being favorable for oil recovery[J]. Lithologic Reservoirs, 2008, 20(1): 111 -113 .
[10]	LI Jun, HUANG Zhilong, LI Jia, LIU Bo. The pool-forming pattern in the condition of arching in the southeast uplift in Songliao Basin[J]. Lithologic Reservoirs, 2007, 19(1): 57 -61 .

TRENDMD: