不同温度下孔隙压力对煤岩渗流特性的影响机制

李波波; 杨康; 袁梅; 许江; 杜育芹

doi:10.3799/dqkx.2017.107

不同温度下孔隙压力对煤岩渗流特性的影响机制

doi: 10.3799/dqkx.2017.107

李波波^1,2,3,,
杨康¹,
袁梅^1,2,3,
许江⁴,
杜育芹¹

1.
贵州大学矿业学院, 贵州贵阳 550025
2.
贵州大学喀斯特山区优势矿产资源高效利用国家地方联合工程实验室, 贵州贵阳 550025
3.
贵州省非金属矿产资源综合利用重点实验室, 贵州贵阳 550025
4.
重庆大学煤矿灾害动力学与控制国家重点实验室, 重庆 400044

基金项目:

贵州省科技厅、贵州大学联合资金计划项目黔科合LH字[2014]7654

贵州大学引进人才科研基金资助项目贵大人基合字（2015）30号

贵州省科学技术基金项目黔科合J字[2015]2049号

贵州大学引进人才科研基金资助项目贵大人基合字（2014）57号

国家科技重大专项 2016ZX05044

详细信息

作者简介:
李波波(1985-), 男, 讲师, 主要从事岩石力学与工程、煤层气渗流等方面的研究

中图分类号: P554
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出版历程
- 收稿日期: 2017-03-22
- 刊出日期: 2017-08-15

Effect of Pore Pressure on Seepage Characteristics of Coal and Rock at Different Temperatures

Li Bobo^{1,2,3
,},
Yang Kang¹,
Yuan Mei^1,2,3,
Xu Jiang⁴,
Du Yuqin¹

1.
College of Mining, Guizhou University, Guiyang 550025, China
2.
National & Local Joint Laboratory of Engineering for Effective Utilization of Regional Mineral Resources from Karst Areas, Guizhou University, Guiyang 550025, China
3.
Guizhou Key Laboratory of Comprehensive Utilization of Non-Metallic Mineral Resources, Guiyang 550025, China
4.
State Key Laboratory of Coal Mine Disaster Dynamics and Control, Chongqing University, Chongqing 400044, China

摘要

摘要: 在深部煤层瓦斯抽采过程中，地温较高且孔隙压力逐渐降低，而目前综合考虑温度和孔隙压力对煤岩渗透特性耦合作用的研究较少.利用自主研发的出口端压力可调的三轴渗流装置，以贵州矿区原煤试件为研究对象，进行不同温度下改变孔隙压力的渗流试验，并建立了考虑温度的渗透率匹配模型.研究表明，煤岩渗透率随孔隙压力增大按指数函数减小；煤岩渗透率随压差的增大而减小，随温度的升高而降低，在不同的温度状态下，渗透率的下降速率和变化幅度有所不同.在模拟瓦斯开发的物理试验中，压差应尽量小，减少其误差，为建立不同边界条件的渗透率模型提供帮助；随温度的升高，温度突变系数呈增大的趋势；随孔隙压力的增大，温度突变系数呈减小的趋势.温度突变系数在整个阶段不为常数，且割理压缩系数可变，这两个特征更能真实地匹配模型，反映瓦斯的开发过程.
- 煤岩 /
- 渗透率 /
- 孔隙压力 /
- 有效应力 /
- 温度 /
- 压差
Abstract: The ground temperature is higher and the pore pressure gradually decreases in the process of gas extraction in deep coal seams, however there are few studies on the coupling effect of temperature and pore pressure on the permeability of coal. Seepage experiments on the raw coal from Guizhou mining area are carried out by the self-developed triaxial seepage equipment with an adjustable outlet pressure to study the influence of pore pressure and temperature on the permeability. A permeability matching model with temperature effect is also developed in this study. An exponential relationship between the permeability and pore pressure is found and presented. The results show that the permeability decreases with increasing pore pressure, and it decreases as the differential pressure increases. Also, the permeability of coal seam decreases with increased temperature, and the decreasing rate and magnitude of permeability are different under different temperatures. Therefore, the differential pressure should be as small as possible to reduce the error and help develop the permeability model with different boundary conditions in the physical simulation experiments of coalbed methane (CBM) extraction. As the temperature increases, the mutation coefficient of temperature increases. While, the mutation coefficient of temperature decreases as pore pressure increases. It has been found these two characteristics that the mutation coefficient of temperature is not a constant in the whole stage and the realistic model matching with a variable cleat compressibility coefficient can reflect the development process of CBM.
- coal and rock /
- permeability /
- pore pressure /
- effective stress /
- temperature /
- differential pressure

HTML全文

图 1 原煤试件

Fig. 1. Raw coal samples

下载: 全尺寸图片幻灯片

图 2 出口端正压的三轴渗流装置原理

Fig. 2. The sketch of traixial seepage device with positive pressure at outlet

下载: 全尺寸图片幻灯片

图 3 理想化煤岩双孔隙度模型

据Wang et al.(2014)

Fig. 3. Dual porosity model of idealized coal

下载: 全尺寸图片幻灯片

图 4 不同温度状态下煤岩渗透率与孔隙压力变化关系

a.压差Δp=0.1 MPa；b.压差Δp=0.3 MPa；c.压差Δp=0.5 MPa

Fig. 4. Relationship between permeability and pore pressure of coal under different temperature

下载: 全尺寸图片幻灯片

图 5 不同压差状态下煤岩渗透率与孔隙压力变化关系

Fig. 5. Variation relationship between pore pressure and permeability of coal under different pressure difference

a.T=30 ℃; b.T=50 ℃; c.T=70 ℃

下载: 全尺寸图片幻灯片

图 6 不同温度状态下温度突变系数与孔隙压力变化关系

Fig. 6. The relationship between temperature mutation coefficient and pore pressure at different temperatures

a.Δp=0.1 MPa; b.Δp=0.3 MPa; c.Δp=0.5 MPa

下载: 全尺寸图片幻灯片

表 1 林华9号煤层原煤基本力学参数

Table 1. Basic mechanical parameters of raw coal in No.9 coal seam of Lin Hua

围压(MPa)	与层理面关系	σ_c(MPa)	E(MPa)	ν
3.0	⊥	38.28	1 905.04	0.125 9
3.0	//	39.55	2 114.45	0.114 5

下载: 导出CSV

表 2 煤岩数据匹配的模型参数

Table 2. Model parameters of coal about data matching

△p(MPa)	T(℃)	c_f0(MPa^-1)	a(MPa^-1)
0.1	30	-0.006 4	4.002 0
	50	-0.004 2	3.994 2
	70	-0.006 4	4.004 3
0.3	30	-0.006 2	4.002 1
	50	-0.006 1	3.995 1
	70	-0.007 5	4.023 5
0.5	30	-0.006 8	4.018 8
	50	-0.008 4	3.995 1
	70	-0.006 3	4.399 7

下载: 导出CSV

表 3 不同温度条件下的弹性模量

Table 3. Values of elastic modulus under different temperature conditions

温度(℃)	25	30	50	70
弹性模量(MPa)	181.46	178.88	168.72	160.00

下载: 导出CSV

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