不同岩相泥页岩数字岩心构建方法研究——以东营凹陷为例

摘要/Abstract

摘要：

针对泥页岩储层低孔特低渗、结构致密、非均质性强的特点,多采用三维数字岩心来直观显示各组分空间分布和表征微观结构。物理数字岩心虽更真实准确,但往往局限于特定岩石样品物性特征,因此需构建具有一定普适性、受多参数约束的、代表某一类岩性或岩相的简约数字岩心。同时,目前的图像分割方法难以对综合多样品特征、代表某类岩相样品进行组分划分。提出一种基于图像像素点累计分布函数,结合各组分百分含量及灰度序列进行阈值分割的方法,并基于X射线CT扫描成像,综合运用扫描电镜成像及能谱分析等手段,结合东营凹陷不同岩相泥页岩矿物组分及孔隙度特征,构建不同岩相(包括富长英质、长英质、富钙质、钙质和富泥质)泥页岩数字岩心。结果显示,东营凹陷泥页岩储层组分按灰度值由小到大依次为孔裂隙、有机质、黏土矿物、长英质矿物、钙质矿物、铁质矿物;基于不同岩相各组分体积百分含量及灰度分布序列,以CT灰度图像像素点累计分布函数表征不同岩相各组分体积百分含量分布函数,可依次划分各组分阈值,该方法可以实现其他分割方法难以完成的针对某一岩相进行阈值划分;采用先构建单组分数字岩心再嵌套组合的方法可构建具有一定普适性、受矿物组分和孔隙度等参数约束的泥页岩数字岩心。

关键词: 泥页岩, 数字岩心, X射线CT, 扫描电镜, 阈值分割

Abstract:

Shale is a complex porous medium with low porosity, super-low permeability, tight and heterogeneity pore structure. The distribution of each component within shale can be visually revealed by the three-dimensional digital cores. Moreover, microscopic structural characterization and seepage simulation experiments of shale can also be carried out repeatedly and nondestructively using digital core. Therefore, the digital core is a more effective and convenient method than the conventional physics experiment methods for shale. The digital core constructed by the physical construction method is more accurate, however, which can only reveal the physical properties of a particular rock sample, and is generally effected by the contradiction between the field of view and resolution. Thus, it is necessary to construct the simple digital core models with a certain universality, which is constrained by some parameters, and can represent the characteristics of a kind of lithology or lithofacies. In the meantime, the current image segmentation methods are difficult to synthesize the multi-sample characteristics, which represent the characteristics of a kind of lithology or lithofacies. In this paper, we propose a method about threshold segmentation. It segmentalizes CT images based on the cumulative distribution function of image pixels, combined with the percentage of each component groups and the gray level distribution sequence. The volume relative content and gray level distribution sequence of mineral compositions and porosity of different lithofacies shale in Dongying depression are obtained by means of scanning electron microscopy (SEM) and energy-dispersive X-ray spectroscopy (EDX). And then the digital core models of different lithofacies shale, including rich felsic, felsic, rich calcareous, calcareous and rich argillaceous lithofacies shale, are constructed based on the X-ray computed tomography (CT) imaging. The results show that: (1) According to the grey value, the six component groups of shale reservoirs in Dongying depression from low to high,are followed by pore-fractures, organic matter, clay minerals, felsic minerals, calcium minerals and iron minerals, respectively;(2) Cumulative distribution function of pixels in CT gray image is represented cumulative distribution function of volume relative content of different lithofacies sample component groups. Based on volume relative content and gray level distribution sequence of different lithofacies shale sample components, threshold of each component group can be obtained in turn. This method is more suitable for threshold segmentation of specific lithofacies, while other segmentation methods cannot achieve; (3) The simple standard digital core models can be constructed by a superposition method. Firstly, the single-component digital cores are constructed based on CT images and thresholds of various petrographic component groups. And then these digital cores are superimposed together and the complete simple digital core is reconstructed, which is constrained by the parameters, such as mineral components and porosity. The simple standard digital core models, which have a certain universality, can represent the characteristics of a kind of lithology or lithofacies.

Key words: shale, digital core, X-ray computed tomography (CT), scanning electron microscopy (SEM), threshold segmentation

中图分类号:

TE132.2

陈晨, 卢双舫, 李俊乾, 张鹏飞, 张萍. 不同岩相泥页岩数字岩心构建方法研究——以东营凹陷为例[J]. 现代地质, 2017, 31(05): 1069-1078.

CHEN Chen, LU Shuangfang, LI Junqian, ZHANG Pengfei, ZHANG Ping. Digital Core Modeling Construction of Different Lithofacies Shale: A Case Study of Dongying Depression[J]. Geoscience, 2017, 31(05): 1069-1078.

图/表 14

参考文献 29

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样品编号	岩相	矿物组成/%								TOC/ %	孔隙度/ %
样品编号	岩相	石英	钾长石	斜长石	方解石	白云石	菱铁矿	黄铁矿	黏土矿物	TOC/ %	孔隙度/ %
L752-1	富钙质页岩	8	2	5	5	1	3	4	13	2.5	4
F41-2	富长英质泥岩	38.7	5.8	18.5	11.2	6.6	3.7	0.5	14	0.27	6.366
L76-1	富长英质泥岩	37.7	4.8	10.5	2.3	8.3	1.8		32.1	0.13	2.135
L76-2	富长英质泥岩	40	2.8	14.2	1.8	8.9	1.5		28.9	0.16	7.206
N5-3	富长英质泥岩	43	5.1	16.8	14.7	14			2.6	0.12	5.949
H88-1	富泥质泥岩	30.8	2.1	7.9	3.6		1	1	55.5	2.66	0.978
F41-1	钙质泥岩	17.5	0.9	3.1	26.5	1.8	5.1	4.5	40.7	1.1	0.469
Y556-2	钙质泥岩	19.8	1.8	3	25.6	6.9	5.3	4.6	32.8	2.58	8.743
LX884-1	钙质页岩	26	0.2	2.7	18.7	17.5	0.4	3.7	30	1.74	5.926
Y556-1	钙质页岩	20	1.7	2.5	31.6	2.6	2.4	2.2	37	2.86	9.572
Y556-3	钙质页岩	22.3	1.7	5.7	19.9	15.7	2.4	4.7	27.6	2.39	1.598
Y556-4	钙质页岩	19.8	1.6	2.2	26.6	6.8		4.5	38.5	2.87	5.885
F169-2	长英质泥岩	24.1	1.5	10.1	16.7	5.9		5.1	36.7	0.25	0.336
F169-1	长英质页岩	30.8	1.8	11.1	6.1	10.3			39.8	0.37	0.874

样品编号	岩相	矿物组成/%								TOC/ %	孔隙度/ %
样品编号	岩相	石英	钾长石	斜长石	方解石	白云石	菱铁矿	黄铁矿	黏土矿物	TOC/ %	孔隙度/ %
L752-1	富钙质页岩	8	2	5	5	1	3	4	13	2.5	4
F41-2	富长英质泥岩	38.7	5.8	18.5	11.2	6.6	3.7	0.5	14	0.27	6.366
L76-1	富长英质泥岩	37.7	4.8	10.5	2.3	8.3	1.8		32.1	0.13	2.135
L76-2	富长英质泥岩	40	2.8	14.2	1.8	8.9	1.5		28.9	0.16	7.206
N5-3	富长英质泥岩	43	5.1	16.8	14.7	14			2.6	0.12	5.949
H88-1	富泥质泥岩	30.8	2.1	7.9	3.6		1	1	55.5	2.66	0.978
F41-1	钙质泥岩	17.5	0.9	3.1	26.5	1.8	5.1	4.5	40.7	1.1	0.469
Y556-2	钙质泥岩	19.8	1.8	3	25.6	6.9	5.3	4.6	32.8	2.58	8.743
LX884-1	钙质页岩	26	0.2	2.7	18.7	17.5	0.4	3.7	30	1.74	5.926
Y556-1	钙质页岩	20	1.7	2.5	31.6	2.6	2.4	2.2	37	2.86	9.572
Y556-3	钙质页岩	22.3	1.7	5.7	19.9	15.7	2.4	4.7	27.6	2.39	1.598
Y556-4	钙质页岩	19.8	1.6	2.2	26.6	6.8		4.5	38.5	2.87	5.885
F169-2	长英质泥岩	24.1	1.5	10.1	16.7	5.9		5.1	36.7	0.25	0.336
F169-1	长英质页岩	30.8	1.8	11.1	6.1	10.3			39.8	0.37	0.874

岩相	矿物组成/%								TOC/ %	孔隙度/ %
岩相	石英	钾长石	斜长石	方解石	白云石	菱铁矿	黄铁矿	黏土矿物	TOC/ %	孔隙度/ %
富长英质泥页岩	39.85	4.63	15.00	7.50	9.45	2.33	0.50	19.40	0.17	5.41
富泥质泥页岩	30.80	2.10	7.90	3.60		1.00	1.00	55.50	2.66	0.98
富钙质泥页岩	8.00	2.00	5.00	50.00	15.00	3.00	4.00	13.00	2.50	4.00
长英质泥页岩	27.45	1.65	10.60	11.40	8.10		5.10	38.25	0.31	0.61
钙质泥页岩	20.90	1.32	3.20	24.82	8.25	3.12	4.03	34.43	2.26	5.37

岩相	矿物组成/%								TOC/ %	孔隙度/ %
岩相	石英	钾长石	斜长石	方解石	白云石	菱铁矿	黄铁矿	黏土矿物	TOC/ %	孔隙度/ %
富长英质泥页岩	39.85	4.63	15.00	7.50	9.45	2.33	0.50	19.40	0.17	5.41
富泥质泥页岩	30.80	2.10	7.90	3.60		1.00	1.00	55.50	2.66	0.98
富钙质泥页岩	8.00	2.00	5.00	50.00	15.00	3.00	4.00	13.00	2.50	4.00
长英质泥页岩	27.45	1.65	10.60	11.40	8.10		5.10	38.25	0.31	0.61
钙质泥页岩	20.90	1.32	3.20	24.82	8.25	3.12	4.03	34.43	2.26	5.37

岩相	矿物组成/%								TOC/ %	孔隙度/ %
岩相	石英	钾长石	斜长石	方解石	白云石	菱铁矿	黄铁矿	黏土矿物	TOC/ %	孔隙度/ %
富长英质泥页岩	38.54	4.56	14.62	7.09	8.50	1.51	0.26	19.12	0.39	5.41
富泥质泥页岩	28.04	1.95	7.25	3.20	0.00	0.61	0.48	51.49	6.01	0.98
富钙质泥页岩	7.58	1.93	4.77	46.30	13.21	1.90	2.01	12.55	5.76	4.00
长英质泥页岩	27.03	1.66	10.52	10.98	7.42	0.00	2.66	38.39	0.74	0.61
钙质泥页岩	19.30	1.24	2.98	22.41	7.34	1.93	1.97	32.40	5.07	5.37