Excess Coalbed Methane Production Mechanism in the Process of Coal Tectonic Deformation ()
1. Propose a Question
Coalbed methane (i.e. coal mine gas), which mainly consists of methane, is one kind of gaseous geological body that is generated and reserved mainly by adsorption in coalbed. It is a clean and efficient energy, and yet it is a major mine hazard. Research demonstrates that coal and gas outburst has a close relationship with tectonic deformation.
Roughly, almost all coal and gas outbursts around the world occurs in intense tectonic deformation coals, meanwhile, the amount of gas outburst is generally several to hundreds of times higher than the max-adsorption of coal, which cannot be reasonably explained only as absorbed gas in wall rocks. Peng Lishi et al. (1988) [1], Hou Quanlin et al. (1995) [2], Ju et al. (2002, 2005) [3] [4], Cao et al. (1996, 2006) [5] [6] and Wang Zhirong et al. (2006) [7] research the Bedding sliding structure of coal control to the gas outburst and point out that the strong tectonic shear, especially in coal seam shear zone, often have gas outburst areas, such as Baijiao coal mine in Sichuan.
2092 face seam shear zone in Baijiao have seven gas outburst one after another (Figure 1). Li Peking on the basis of analysis of the Chongqing area of coal and gas prominent feature, pointed out that the geological structure is the main factors affecting the coal and gas outburst [8] [9].
According to incomplete statistics, almost all of the world’s coal gas outburst occurred in transformation coal transformed by intensive tectonic movement, although not all of tectonic coal occurrence of coal and gas outburst, Generally tectonic coal is not necessarily for gas outburst, non-deformed coal certain not gas outburst, gas outburst must be constructed coal. So, what kind of tectonic coals are more prone to gas outburst?
The above discussion objectively raises an important question for coalfield geology and structural geology: is there a relationship between the excess coalbed methane and coal deformation, and if it is related, what is the relationship. Without any doubt, the better understanding of this issue will play a significant role in understanding the mechanism of coal and gas outburst and coalbed methane exploration. Sub-high-temperature and sub- high-pressure deformation experiments on middle-rank coals were designed in our work, combined with gas composition analysis, quantitative analysis of hydrogen and carbon elements, and Fourier transform infrared spectrometer (FTIR). Based on our achievements, this dissertation presents whether middle rank coal can generate methane during the deformation process and if and how the chemical structure will change during this process.
2. Excess CBM Possible Source
We designed an experiment to study the gas generation during deformation. To exclude the impact of pyrolysis
Figure 1. Baijiao coal mine in Sichuan 2092 Face of Outburst with flat and sections.
gas, the experimental temperatures were only 70˚C and 100˚C, which are far below the pyrolysis temperature of sample coals [10]. Meanwhile, we eliminated the impact of residual gas in coals to the greatest extent, in order to test the gas during deformation precisely. Results show that, the experiment is feasible in studying whether coals can generate gas during the deformation process. During the deformation of middle-rank coals new methane will be generated and gas generation is affected both by the experimental temperature and differential stress and the latter outweighs. The gas shows an increasing trend with the reinforcement of differential stress. By contrast, the temperature affects the amount of gas by affecting the deformation behavior of coal since it can improve the ductile deformation and thus facilitates gas generation.
Quantitative analysis of hydrogen and carbon elements is performed on samples before and after the deformation. The results reveal that hydrogen and carbon elements of all samples decline in some degree after the deformation experiments and the reduction of hydrogen and carbon shows a good corresponding relationship with the deformation and the new generated methane. When the experimental temperature is the highest and the differential stress is the biggest, the decline is the max and the gas is the most. The result on the one hand explains that the gas collected in the experiments is neither residual gas nor from small inclusions, but comes from coals’ chemical structure, on the other hand demonstrate that the deformation under tectonic stress can not only change the physical structure of coal, but also change its chemical structure, and thus contributes to the generation of methane.
Evidence provided by Fourier transform infrared spectrometer (FTIR) shows that the content of aliphatic groups decreases [11]-[14], while the aromatic and naphthenic groups stay steady. Methyl is very sensitive to differential stress, and the specific performance is that even a small differential stress will result a large loss of methyl. The decrease of methyl shows a good corresponding relationship with the methane. The peak area of G which belongs to the total number of aromatic rings increases both with the differential stress and the temperature, but it is more sensitive with the differential [15]. The peak area of D which relates with structural imperfection of coal molecular is very sensitive to ductile deformation, since when the experimental condition is in favor of ductile deformation, the peak area of D increases markedly. The feature of Raman spectra proves the dynamic metamorphism of coals, that is to say, the deformation can change the chemical structure of coals, improve the degree of coalification, promote the loss of side chain and functional groups, thus facilitates the molecule structure to be aromatic.
3. Discussion
In the end, we discuss the controlling mechanism of ductile deformation to coal chemical structures and gas generation. Under brittle deformation conditions, samples deform with the characteristics of fracture and grinding, forming obviously sliding advantage failure surface and the change of chemical structure is caused by kinetic energy, which is transformed primarily by mechanical friction between fractures. Along with enhanced deformation, thermal energy is accumulated and the molecular activity within coals is increased which cause functional groups and aromatic chain to pyrolyze and shed successively on the basis of the bond energy, companying with small quantity of methane emission. On the other hand aromatic nuclei grow up and polycondensation is enhanced. However, the chemical structure of coal is still in the steady state, so it is not prone to outburst. Under ductile deformation mechanism, effect of tectonic stress on coals mainly converts into strain energy which can promote coal molecular units to deform, break and bring about dislocation and creep of coal interior nucleus. This process, on the one hand, results in the increase of structural imperfection and the decrease of polycondensation, on the other hand, causes the aromatic chain to shed along with gas generation. The gas as well as unsteady strain energy is stored in the imperfect structure. When the equivalent condition is broken, enormous strain energy and excess coalbed methane will be generated from the structural imperfection. This may be the dynamic process of coal and gas outburst.