地学前缘 ›› 2018, Vol. 25 ›› Issue (2): 179-190.DOI: 10.13745/j.esf.yx.2017-6-4

• 致密储层形成机理与孔隙演化 • 上一篇    下一篇

致密砂岩储层成岩作用与孔隙演化:以川西南上三叠统为例

施振生,李熙喆,董大忠,邱振,卢斌,梁萍萍   

  1. 1. 中国石油勘探开发研究院,河北 廊坊 065007
    2. 国家能源页岩气研发(实验)中心,河北 廊坊 065007
  • 收稿日期:2017-09-01 修回日期:2017-10-12 出版日期:2018-03-15 发布日期:2018-03-15
  • 作者简介:施振生(1976—),男,博士,高级工程师,主要从事非常规沉积学基础地质理论研究及勘探生产实践等工作。E-mail:shizs69@petrochina.com.cn
  • 基金资助:
    国家自然科学基金项目(41572079)

Diagenesis and pore evolution of tight sandstone reservoir: a case study from the Upper Triassic reservoir of the southwest Sichuan Basin, China.

SHI Zhensheng,LI Xizhe,DONG Dazhong,QIU Zhen,LU Bin,LIANG Pingping   

  1. 1. Research Institute of Petroleum Exploration and Development, CNPC, Langfang 065007, China
    2. National Energy Shale Gas Research and Development (Experiment) Center, Langfang 065007, China
  • Received:2017-09-01 Revised:2017-10-12 Online:2018-03-15 Published:2018-03-15

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摘要: 致密砂岩储层成岩作用控制孔隙演化,并进一步决定相对优质储层分布。川西南上三叠统砂岩储层整体孔隙度小于6%,基质渗透率小于0.1×10-3 μm2,属于典型致密砂岩储层。铸体薄片和储层流体包裹体综合分析表明,砂岩储层经历了压实作用、胶结作用、溶蚀作用和交代作用,储集空间以粒内溶孔、铸模孔和粒间溶孔为主。综合各成岩矿物共生组合关系,结合储层流体包裹体均一化温度,确定各成岩事件和成岩矿物形成相对顺序:压实作用→第Ⅰ期裂缝→第Ⅰ期伊利石胶结→第Ⅰ期石英加大→第Ⅰ期方解石胶结→第Ⅱ期石英加大、硅质充填→长石、岩屑溶蚀→绿泥石胶结或者伊利石胶结→第Ⅱ期方解石胶结→长石溶蚀作用→第Ⅱ期破裂作用→第Ⅲ期石英加大、硅质充填→第Ⅲ期碳酸盐胶结→碳酸盐交代长石和石英→第Ⅲ期构造破碎→晚期方解石和石英胶结成岩。镜质体反射率(Ro)及砂岩储层流体包裹体均一温度表明砂岩储层目前已达到中成岩A2期至B期,压实作用是储层致密化的最主要原因,造成孔隙度损失约27.5%,硅质和碳酸盐胶结作用仅损失孔隙度约5.3%。

关键词: 致密砂岩储层, 成岩演化, 孔隙演化, 川西南部, 上三叠统

Abstract: Diagenesis of tight sandstone reservoir dominates pore evolution, and further controls the distribution of relatively highquality reservoirs. The Upper Triassic sandstone reservoir in the southwest Sichuan Basin, with overall porosity less than 6% and permeability less than 0.1×10-3 μm2, is a typical tight sandstone reservoir. In this study, a comprehensive analysis of cores, cast slices and fluid inclusion shows that the tight sandstone reservoirdominated by intragranular dissolved pore, intergranular dissolved pore and moldic poreexperienced compaction, cementation, dissolution and metasomatism. Paragenetic relationship and fluid inclusion homogenization temperatures reveal the succession of the Upper Triassic sandstone: compaction→first phase (sequentially) fracture, illite cementation, quartz overgrowth and calcite cementation→second phase quartz overgrowth and siliceous infill→dissolution of feldspar and debris→chlorite cementation or illite cementation→second phase calcite cementation→dissolution of feldspar and debris→second phase fracture→third phase quartz overgrowth and siliceous infill followed by carbonate cementation→carbonate replacement of feldspar and quartz→third phase fracture→late stage calcite and quartz cementation. The measured vitrinite reflectivity (Ro) value and homogenization temperature of fluid inclusions indicate the sandstone is currently in the A2 to B diagenetic stage, when compaction, the main factor of reservoir densification, causes roughly 27.5% porosity loss; while siliceous and carbonate cementation are responsible for only 5.3% porosity loss.

Key words: tight sandstone reservoir, diagenesis evolution, pore evolution, southwest Sichuan Basin, Upper Triassic

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