黔西地区煤层埋深与地应力对其渗透性控制机制

徐宏杰; 桑树勋; 易同生; 赵霞; 刘会虎; 李林

doi:10.3799/dqkx.2014.143

黔西地区煤层埋深与地应力对其渗透性控制机制

doi: 10.3799/dqkx.2014.143

徐宏杰^{1, 2,},
桑树勋^3, ,,
易同生²,
赵霞²,
刘会虎¹,
李林⁴

1.
安徽理工大学地球与环境学院, 安徽淮南 232001
2.
贵州省煤层气页岩气工程技术研究中心, 贵州贵阳 550008
3.
中国矿业大学资源与地球科学学院, 江苏徐州 221008
4.
中煤科工集团西安研究院, 陕西西安 710054

基金项目:

国家自然科学基金项目 41330638

国家自然科学基金项目 41272154

国家自然科学基金项目 41402140

国家自然科学基金项目 41302129

贵州省重大科技专项 [2014]6002

安徽省自然科学基金项目 1408085QE88

安徽理工大学青年科学研究基金项目 QN201307

山西省煤层气联合研究基金项目 2012012008

详细信息

作者简介:
徐宏杰(1981-), 男, 讲师, 主要从事煤层气、瓦斯开发地质方面的研究与教学工作.E-mail: xiaonzm@163.com

通讯作者:
桑树勋, E-mail: shuxunsang@163.com

中图分类号: P618.111
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出版历程
- 收稿日期: 2013-12-18
- 刊出日期: 2014-11-01

Control Mechanism of Buried Depth and In-Situ Stress for Coal Reservoir Permeability in Western Guizhou

Xu Hongjie^{1, 2
,},
Sang Shuxun^{3
, ,},
Yi Tongsheng²,
Zhao Xia²,
Liu Huihu¹,
Li Lin⁴

1.
School of Earth Sciences and Environmental Studies, Anhui University of Science & Technology, Huainan 232001, China
2.
Research Center of Guizhou Coalbed Methane and Shale Gas Engineering, Guiyang 550008, China
3.
School of Resources and Geosciences, China University of Mining and Technology, Xuzhou 221008, China
4.
Xi'an Branch, China Coal Research Institute, Xi'an 710054, China

摘要

摘要: 基于黔西六盘水煤田和织纳煤田16口井36层次的试井资料, 采用地质统计分析等方法, 探讨了黔西地区煤储层渗透性的展布规律与地应力特征, 论证了煤层埋深与地应力对其渗透性的控制机制.研究表明, 研究区煤储层以特低渗-低渗透率储层(＜0.1×10^-9m²)为主, 中渗透率储层(0.1×10^-9~1.0×10^-9m²)也占有相当大比例; 应力场类型在浅部表现为大地动力场型, 一定深度可能转化为准静水压力状态.煤储层渗透率及其埋深的负幂指数关系较为离散, 但在不同深度渗透率转折点与地应力场类型转变一致; 单井煤储层试井渗透率差异较大, 随地应力增大和埋深增加而降低, 平面展布受地应力强度控制由SW-NE具"低-高-低"发育规律.埋深对渗透率的控制实质是地应力的控制, 区域构造位置及其所处高应力场作用下的煤体形变与破碎致使孔裂隙压缩或闭合是该区渗透性差异的主要控制机制.
- 黔西地区 /
- 煤储层 /
- 渗透性 /
- 埋深 /
- 地应力 /
- 控制机制 /
- 能源地质
Abstract: Based on geological analysis of data of 16 testing wells in the Liupanshui and Zhina coalfields, the spatial distribution of coal reservoir permeability and characteristics of in-situ stress in the western Guizhou are discussed, and the control mechanism of buried depth and in-situ stress for coal reservoir permeability is obtained in this study. It is shown that the coal reservoirs have the characteristic of ultra-low and low permeability (< 0.1×10^-9m²), and the permeability of coal reservoir with 0.1×10^-9-1.0×10^-9m² has considerably large proportion. The type of in-situ stress field is gradually undergoing a possible change from dynamic field in shallow layer to hydrostatic pressure field in deep layer. It has a negative power exponent relationship of coal reservoir permeability and buried depth, but the change of permeability is in accordance with in-situ stress field changed. The permeability of coal reservoir varies in different testing wells, decreasing with the increased in-situ stress and depth, and its spatial distribution has a law of "low-high-low" from SW to NE for the intensity of the stress controlled. The role of coal depth to permeability is supposed to be the in-situ stress in action essentially. The main control mechanism of coal permeability difference is that the pore and fracture tend to compress or close caused by the deformation and fragmentation of coal reservoirs under the influence of high in-situ stress in regional tectonic location of study area.
- western Guizhou /
- coal reservoir /
- permeability /
- buried depth /
- in-situ stress /
- control mechanism /
- energy geology

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图 1 黔西地区构造纲要图(据贵州省煤田地质局，2010修改)

Fig. 1. Structure outline in western Guizhou

下载: 全尺寸图片幻灯片

图 2 黔西地区平均水平应力与垂直应力之比与埋深关系

Fig. 2. The relationship of ε and depth of the coal seam

下载: 全尺寸图片幻灯片

图 3 黔西地区应力随煤层深度变化趋势

a.六盘水煤田；b.织纳煤田，其中2个数据姜永东，2011

Fig. 3. Trend of in-situ stress variation with increased coal seam depth in western Guizhou

下载: 全尺寸图片幻灯片

图 4 煤储层渗透率与其埋藏深度关系

Fig. 4. Distribution of permeability and stress gradient on permeability

下载: 全尺寸图片幻灯片

图 5 煤储层压力与埋深之间关系

Fig. 5. Effect of minimum horizontal stress on permeability

下载: 全尺寸图片幻灯片

图 6 煤储层试井渗透率与储层压力之间关系

Fig. 6. Distribution of permeability and stress gradient

下载: 全尺寸图片幻灯片

图 7 煤储层试井渗透率与地应力的关系

a.渗透率与最小水平主应力；b.渗透率与最大水平主应力；c.渗透率与有效应力

Fig. 7. Effect of horizontal stress on permeability

下载: 全尺寸图片幻灯片

图 8 煤储层试井渗透率与最小地应力梯度关系及其平面位置

Fig. 8. Relationship of permeability and stress gradient and the well location map

下载: 全尺寸图片幻灯片

表 1 水力压裂试验结果分区统计

Table 1. Parameter statistics of hydraulic fracturing test in western Guizhou

地区	煤层埋深(m)	渗透率(10^-9m²)	闭合压力(MPa)	闭压梯度(MPa/10²m)	σ_H/σ_v	σ_H/σ_h	σ_h/σ_v	探测半径(m)
亮山	1062.0~1243.6/ 1139.6	0.0004~0.0096/ 0.0035	23.76~27.36/ 25.57	2.1~2.4/ 2.2	1.03~1.32/ 1.14	1.26~1.49/ 1.39	0.78~0.89/ 0.55	-
金竹坪	359.09~554.24/ 440.62	0.0044~0.4260/ 0.1492	10.40~15.68/ 13.14	2.84~3.28/ 3.02	1.52~1.64/ 1.59	1.34~1.53/ 1.44	1.05~1.21/ 1.11	-
青山	292.33~771.73/ 568.70	0.000173~0.48/ 0.0549	6.28~20.65/ 11.27	1.16~2.86/ 2.35	0.45~1.51/ 0.96	0.98~1.55/ 1.28	0.40~1.03/ 0.76	0.13~8.64/ 2.64
都格	807.89~869.48/ 838.69	0.0459~0.0434/ 0.0447	9.56~13.33/ 11.45	1.20~1.55/ 1.38	0.52~0.82/ 0.67	1.19~1.44/ 1.32	0.44~0.57/ 0.50	2.90~8.30/ 5.60
化乐	464.04~577.76/ 517.52	0.1074~0.5002/ 0.2797	8.09~11.75/ 9.36	1.76~2.06/ 1.83	0.85~1.08/ 0.97	1.34~1.56/ 1.45	0.63~0.75/ 0.67	11.40~42.20/ 29.80
洞口	431.38~736.98/ 516.02	0.000164~0.0179/ 0.0062	8.01~17.56/ 13.72	2.10~3.64/ 2.71	1.01~2.26/ 1.54	1.30~1.69/ 1.50	0.78~1.34/ 1.00	1.23~1.82/ 1.53
织金	135.90~142.78/ 139.34	1.3103~1.5621/ 1.4362	2.14~2.40/ 2.27	1.69~1.75/ 1.72	0.76~0.81/ 0.78	1.30~1.31/ 1.31	0.58~0.62/ 0.60	9.40~10.70/ 10.05
注：σ_H/σ_v，水平最大主应力与垂直主应力比值；σ_H/σ_h，水平最大主应力与最小主应力比值；σ_h/σ_v，水平最小主应力与垂直主应力比值；1062.0~1243.6/1139.6，最大值~最小值/平均值；亮山，金竹坪数据引自贵州省煤田地质局内部报告，2011.

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