Experimental Study of the Pore Structure and Gas Desorption Characteristics of a Low-Rank Coal: Impact of Moisture

Mingyi Chen; Xiaoyun Chen; Xuejie Zhang; Fuchao Tian; Weili Sun; Yumeng Yang; Tonghao Zhang

doi:10.1021/acsomega.2c03805

Experimental Study of the Pore Structure and Gas Desorption Characteristics of a Low-Rank Coal: Impact of Moisture

ACS Omega. 2022 Oct 14;7(42):37293-37303. doi: 10.1021/acsomega.2c03805. eCollection 2022 Oct 25.

Authors

Mingyi Chen^{1

2

3}, Xiaoyun Chen¹, Xuejie Zhang^{1

3}, Fuchao Tian⁴, Weili Sun⁴, Yumeng Yang^{1

2

3}, Tonghao Zhang¹

Affiliations

¹ School of Safety Engineering and Emergency Management, Shijiazhuang Tiedao University, Shijiazhuang050043, China.
² Hebei Province Technical Innovation Center of Safe and Effective Mining of Metal Mines, Shijiazhuang Tiedao University, Shijiazhuang050043, China.
³ Key Laboratory of Roads and Railway Engineering Safety Control, Shijiazhuang Tiedao University, Ministry of Education, Shijiazhuang050043, China.
⁴ State Key Laboratory of Coal Mine Safety Technology, China Coal Technology & Engineering Group, Shenyang Research Institute, Shenfu Demonstration Zone113122, China.

Abstract

Coal-water interactions have a prominent impact on the prediction of coal mine gas disasters and coalbed methane extraction. The change of characteristics in the microscopic pores of coal caused by the existence of water is an important factor affecting the diffusion and migration of gas in coal. The low-pressure nitrogen adsorption experiments and gas desorption experiments of a low-rank coal with different equilibrium moisture contents were conducted. The results show that both the specific surface area and pore volume decrease significantly as the moisture content increases, and the micropores (pore diameter <10 nm) are most affected by the water adsorbed by coal. In particular, for a water-equilibrated coal sample at 98% relative humidity, micropores with pore sizes smaller than 4 nm as determined by the density functional theory model almost disappear, probably due to the blocking effects of water clusters and capillary water. In this case, micropores with a diameter less than 10 nm still contribute most of the specific surface area for gas adsorption in coal. Furthermore, the fractal dimensions at relative pressures of 0-0.5 (D ₁) and 0.5-1 (D ₂) calculated by the Frenkel-Halsey-Hill model indicate that when the moisture content is less than 4.74%, D ₁ decreases rapidly, whereas D ₂ shows a slight reduction as the moisture content increased. In contrast, when the moisture content exceeds 4.74%, further increases in the moisture content cause D ₂ to decrease significantly, while there is nearly no change for D ₁. The correlation analyses show that the ultimate desorption volume and initial desorption rate are closely related to the fractal dimension D ₁, while the desorption constant (K _t) mainly depends on the fractal dimension D ₂. Therefore, the gas desorption performances of coal have a close association with the pore properties of coal under water-containing conditions, which indicate that the fluctuation in moisture content should be carefully considered in the evaluation of gas diffusion and migration performances of in situ coal seams.