准噶尔盆地腹部超压顶面附近深层砂岩碳酸盐胶结作用和次生溶蚀孔隙形成机理

何生; 杨智; 何治亮; 武恒志; 王芙蓉; 孟闲龙

准噶尔盆地腹部超压顶面附近深层砂岩碳酸盐胶结作用和次生溶蚀孔隙形成机理

何生^1,,
杨智^{1, 2, 5},
何治亮^{3, 5},
武恒志^{4, 5},
王芙蓉^{1, 5},
孟闲龙^{3, 5}

1.
中国地质大学构造与油气资源教育部重点实验室, 湖北武汉 430074
2.
中国石油勘探开发研究院, 北京 100083
3.
中国石化石油勘探开发研究院, 北京 100083
4.
中国石化西南油气分公司, 四川成都 610051
5.
中国石化石油勘探开发研究院西部分院, 新疆乌鲁木齐 830011

基金项目:

教育部高等学校博士学科点专项科研基金 20060491505

国家自然科学基金重点资助项目 40739904

国家科技重大专项项目 2008ZX05001

中国石油天然气股份有限公司科学研究与技术开发项目 2008B-0100

详细信息

作者简介:
何生(1956-), 男, 教授, 博士生导师, 从事油气地质方面的教学和科研工作.E-mail: shenghe@cug.edu.cn

中图分类号: P618
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出版历程
- 收稿日期: 2008-12-11
- 刊出日期: 2009-09-25

Mechanism of Carbonate Cementation and Secondary Dissolution Porosity Formation in Deep-Burial Sandstones near the Top Overpressured Surface in Central Part of Junggar Basin

HE Sheng^1
,,
YANG Zhi^{1, 2, 5},
HE Zhi-liang^{3, 5},
WU Heng-zhi^{4, 5},
WANG Fu-rong^{1, 5},
MENG Xian-long^{3, 5}

1.
Key Laboratory of Tectonics and Petroleum Resources, China University of Geosciences, Ministry of Education, Wuhan 430074, China
2.
Research Institute of Petroleum Exploration & Development, PetroChina, Beijing 100083, China
3.
Research Institute of Petroleum Exploration and Production, SINOPEC, Beijing 100083, China
4.
Southwest Branch Company, SINOPEC, Chengdu 610051, China
5.
West Branch, Research Institute of Petroleum Exploration and Production, SINOPEC, Urumqi 830011, China

摘要

摘要: 准噶尔盆地腹部深层超压顶面附近(现今埋深4400~6200m, 温度105~145℃) 砂岩中广泛出现的碳酸盐胶结作用和次生溶蚀孔隙与超压流体活动关系密切.由于超压封闭和释放引起其顶面附近砂岩中的孔隙压力和水化学环境的周期性变化可导致碳酸盐沉淀和易溶矿物溶解过程交替出现.根据腹部地区超压顶面附近深埋砂岩成岩作用、碳酸盐胶结物含量、储集物性、碳酸盐胶结物碳、氧同位素和烃源岩热演化模拟等资料的综合研究表明: 含铁碳酸盐胶结物是主要的胶结成分, 长石类成分的次生溶蚀孔隙是主要的储集空间类型, 纵向上深层砂岩碳酸盐胶结物出现15%~30%含量的地层厚度范围约在邻近超压顶面之下100m至之上大于450m, 碳酸盐胶结物出现大于25%含量高值带分布在靠近超压顶面向上的250~300m的地层厚度范围, 超压顶面附近砂岩中碳酸盐胶结物含量高值的深度范围也是次生溶蚀孔隙(孔隙度10%~20%) 发育带的范围; 因晚白垩世以来深部侏罗纪煤系有机质生烃增压作用, 导致在超压顶面附近砂岩晚成岩作用阶段深部富含碳酸盐的超压流体频繁活动, 所形成的碳酸盐胶结物受到了明显的与深部生烃增压有关的超压热流体和有机脱羧作用的影响; 超压流体多次通过超压顶面排放, 使得超压顶面附近砂岩遭受了多期酸性流体溶蚀作用过程, 形成了次生溶蚀孔隙发育带.
- 碳酸盐胶结作用 /
- 次生溶蚀孔隙 /
- 超压顶面 /
- 流体-岩石相互作用 /
- 准噶尔盆地腹部
Abstract: The carbonate cementation and secondary dissolution porosity in the deep-burial sandstones near the top overpressured surface (present-day depths: 4 400-6 200 m and temperatures: 105-145 ℃) in the central part of Junggar Basin are intimately related to the overpressured fluid activities.Periodic decreases of pore pressures and changes of formation hydrochemical conditions as sealing and releasing of overpressures along the top overpressured surface can result the processes of carbonate precipitation and aluminosilicate dissolving in the sandstones.Based on the data of diagenesis, carbonate cement content, sandstone property, carbon and oxygen isotope of carbonate cement, thermal maturity modeling of source rocks and so on, integrated studies indicate as fellows: The ferroan carbonate cements are the dominated cements formed in the late diagenesis stage, and the feldspar-related secondary dissolved pores are the most important pore types in the deep-burial sandstone reservoirs.The thickness scopes are more than 550 m, occurring 100 m below the top overpressured surface and over 450 m above the surface, while the carbonate cement contents reach or exceed the values of 15% to 30%.The thickness intervals are 250-300 m above the top overpressured surface while the carbonate cement contents reach or exceed the values of 25%.The depth intervals of up to 10%-20% secondary dissolving porosity are concomitant with the depth ranges of relative high carbonate cement contents.Since the late Cretaceous, the carbonate-riched fluid flows have been produced frequently as the development of hydrocarbon generation pressures from the deep Jurassic coal-bearing strata, and the carbonate cements have been influenced evidently by the overpressured and thermal fluids, implying that the late-stage ferroan calcite carbon is partly originated from the organic-matter thermal degradation.The secondary porosity zones in the deep-burial sandstones near the top overpressured surface have been formed during the processes of acid-fluid expulsion and migration due to upward releases of overpressures along the diagenetic barrier associated with the top carbonate mineralization zones.
- carbonate cementation /
- secondary dissolution porosity /
- top overpressured surface /
- fluid-rock interaction /
- central part of Junggar basin

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图 1 准噶尔盆地腹部超压顶面深度等值线以及典型钻井井位图

Fig. 1. A contour map of top overpressured surface and typical well locations in the central part of Junggar basin

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图 2 准噶尔盆地腹部砂岩碳酸盐胶结成岩作用显微照片

a.Y1井, 5 877.34 m, J₂t, 孔隙全貌, 主要发育粒间溶蚀孔隙, 铸体片, 10×4 (-); b.Y1井, 5 882 m, J₂t, 长石溶蚀残余, 铸体片, 10×20 (-); c.Y1井, 5 876 m, J₂t, 连晶方解石占据孔隙和喉道, 10×10 (+); d.Y1井, 5 877.8 m, J₂t, 方解石溶孔, 10×10 (-); e.ZHG3井, 5 109.56 m, J₁s, 多期含铁方解石胶结物, 阴极发光片, ×40;f.Y2井, 5 966 m, J₂t, 溶蚀孔隙为含铁方解石充填, 铁白云石交代含铁方解石, 孔隙周缘为沥青, 铸体片, 10×4 (-)

Fig. 2. Diagenesis micrograph of carbonate cements in sandstone in central part of Junggar basin

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图 3 准噶尔盆地腹部不同井区超压顶面附近砂岩面孔率和碳酸盐胶结物含量以及泥岩碳酸钙含量图

Fig. 3. Graphs of mean porosities and carbonate cement contents in sandstones for the different well areas and calcium carbonate contents in mudstones for the well ZH1, near the top overpressured surface in the central part of Junggar basin

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图 4 准噶尔盆地腹部超压顶面附近砂岩碳酸盐胶结物碳氧同位素特征图

Fig. 4. Characteristics of carbon-oxygen isotopic composition for carbonate cements in sandstones near the top overpressured surface in the central part of Junggar basin

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图 5 准噶尔盆地腹部煤系地层埋藏热演化、孔隙演化、酸性流体演化以及超压发育史图

Fig. 5. Diagrams for the histories of source rock burial and thermal maturity, evolutions of sandstone porosity, organic acid and CO₂ generation and overpressure in the coal-bearing strata of the central part of Junggar basin

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