巴晶1,,,
马汝鹏1,
陈天胜2,
张琳1,
庞孟强1,
谢剑勇1
1. 河海大学地球科学与工程学院地球探测研究所, 南京 211100
2. 中国石化石油勘探开发研究院油气地球物理中心, 北京 100083
基金项目: 国家自然科学基金项目(41704109),中央高校基本科研业务费项目(2016B13114),"江苏****"计划,中国科学院测量与地球物理研究所大地测量与地球动力学国家重点实验室开放基金(SKLGED2017-5-2-E)资助
详细信息
作者简介: 郭梦秋, 女, 1979年生, 博士, 河海大学博士后, 主要从事地震衰减特征分析、岩石物理实验规律研究.E-mail:guomq@hhu.edu.cn
通讯作者: 巴晶, 男, 1980年生, 博士, 河海大学教授, 主要从事孔隙介质波传播理论、岩石物理学、储层流体地震检测方法研究.E-mail:jba@hhu.edu.cn
中图分类号: P313;P631收稿日期:2017-11-02
修回日期:2017-12-13
上线日期:2018-03-05
P-wave velocity dispersion and attenuation in fluid-saturated tight sandstones: Characteristics analysis based on a double double-porosity structure model description
GUO MengQiu1,,BA Jing1,,,
MA RuPeng1,
CHEN TianSheng2,
ZHANG Lin1,
PANG MengQiang1,
XIE JianYong1
1. Institute of Earth Probe, School of Earth Sciences and Engineering, Hohai University, Nanjing 211100, China
2. Center of Oil/gas Geophysics, Petroleum Exploration and Production Research Institute, SINOPEC, Beijing 100083, China
More Information
Corresponding author: BA Jing,E-mail:jba@hhu.edu.cn
MSC: P313;P631--> Received Date: 02 November 2017
Revised Date: 13 December 2017
Available Online: 05 March 2018
摘要
摘要:致密砂岩普遍具有低孔、低渗及微裂缝发育的地质特征,并且呈现出很强的非均匀性.致密砂岩储层与常规砂岩储层比较,具有明显的岩石物理性质、渗流力学性质方面的差异.致密砂岩内部的非均匀性对弹性波频散、衰减有显著影响,其中包括孔隙结构的非均匀性,即岩石内部孔隙参数的不均一性,以及孔隙内部不相混溶流体的非均匀分布;此外,非均匀性的尺度也决定了波出现显著频散与衰减的频段.综合考虑致密砂岩孔隙结构非均匀性及流体斑块状饱和的非均匀性,本文采用双双重孔隙介质结构模拟了致密砂岩的弹性波响应,分析了同时具备两类非均质性岩石中的波传播特征.调查分析了两组分别来自中国鄂尔多斯盆地苏里格气田及四川盆地广安气田的不同类型致密砂岩储层的岩芯超声波实验数据,给出了岩石样本的弹性波速度频散与衰减曲线.结果显示理论模型预测结果与完全饱和、部分饱和岩石的实验数据吻合良好.对两个地区致密砂岩岩芯数据进行对比分析,苏里格致密砂岩样本总体上比广安致密砂岩渗透率高,在各孔隙度范围内,特征模拟显示苏里格样本的裂隙尺寸明显大于广安样本.广安致密砂岩在低孔隙度范围内发育了更多、更小的颗粒裂隙/接触.致密砂岩的速度频散与衰减结果受流体黏度、晶体破裂及流体斑块状饱和的共同影响.此外,孔隙度越大,部分饱和岩石中斑块状饱和机制对总衰减的贡献越低,与之相对,结构非均质性所占的比重则有所增强.
关键词: 致密砂岩/
非均质性/
部分饱和/
纵波频散和衰减/
双重双重孔隙介质模型
Abstract:Tight sandstones have general geological characteristics of low porosity, low permeability and development of micro-crack systems, which present strong heterogeneity. There are obvious differences of rock physical and percolation mechanical properties between the tight sandstone reservoirs and the conventional sandstone reservoirs. The heterogeneity inside tight sandstones, including fabric heterogeneity (the inhomogeneity of pore properties within rock matrix) and the heterogeneous distribution of immiscible fluid mixtures inside pores, has a significant effect on elastic wave velocity dispersion and attenuation. Furthermore, the scale of heterogeneity determines the characteristic frequency bands of wave dispersion and attenuation. In a comprehensive analysis of the heterogeneities of pore structure and fluid patchy-saturation in tight sandstones, this paper adopts a double double-porosity structure to model elastic wave response features, and investigates the wave propagation characteristics in the rocks simultaneously containing the two types of heterogeneities. We analyzed the two different sets of ultrasonic measurement data of tight sandstones, one from the Sulige gas field of Ordos Basin, Northwest China and the other from the Guang'an gas field of Sichuan Basin, Southwest China, and presented the elastic wave velocity dispersion and attenuation curves for the corresponding rock specimens. The theoretical prediction results are shown to be in well agreement with the rock experimental data at the full-saturation and partial-saturation states. Comparative analysis on the core data of tight sandstones from the two gas fields shows that the Sulige specimens generally have higher permeability than Guang'an specimens. In each different porosity range, characteristics analysis shows that the micro-crack sizes of Sulige specimens are larger than those of Guang'an specimens. More grain contacts/cracks with smaller sizes are found to be developed in Guang'an tight sandstones in the low-porosity range. The velocity dispersion and attenuation in tight sandstones are impacted by a combined effect of fluid viscosity, grain cracks and fluid patchy-saturation. It is also deduced in the partially-saturated rocks that the contribution of the mechanism of patchy-saturation to the total attenuation will decline as rock porosity increase, while on the other hand, the proportion of attenuation caused by the mechanism of fabric heterogeneity increases.
Key words:Tight sandstone/
Heterogeneity/
Partial saturation/
P-wave velocity dispersion and attenuation/
Double double-porosity media model
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