Study on the Effect of Soft and Hard Coal Pore Structure on Gas Adsorption Characteristics

In order to grasp the effect of soft and hard coal pore structure on gas adsorption characteristics, based on fractal geometry theory, low-temperature nitrogen adsorption and constant temperature adsorption test methods are used to test the pore structure characteristics of soft coal and its influence on gas adsorption characteristics. We used box dimension algorithm to measure the fractal dimension and distribution of coal sample microstructure. +e research results show that the initial nitrogen adsorption capacity of soft coal is greater than that of hard coal, and the adsorption hysteresis loop of soft coal is more obvious than that of hard coal. And the adsorption curve rises faster in the high relative pressure section. +e specific surface area and pore volume of soft coal are larger than those of hard coal. +e number of pores is much larger than that of hard coal. In particular, the superposition of the adsorption force field in the micropores and the diffusion in the mesopores enhance the adsorption potential of soft coal. Introducing the concept of adsorption residence time, it is concluded that more adsorption sites on the surface of soft coal make the adsorption and residence time of gas on the surface of soft coal longer. Fractal characteristics of the soft coal surface are more obvious. +e saturated adsorption capacity of soft coal and the rate of reaching saturation adsorption are both greater than those of hard coal. +e research results of this manuscript will provide a theoretical basis for in-depth analysis of the adsorption/desorption mechanism of coalbed methane in soft coal seams and the formulation of practical coalbed methane control measures.


Introduction
Coal is a kind of porous solid medium with developed pore structure. e abundant pore structure in the coal body is not only a place for gas storage, but also a channel for gas production. e adsorption state of gas in coal makes the mechanical properties of gas-containing coal different from non-adsorption media. Gas-containing coal is a multi-phase porous medium with temporal and spatial variability, which is composed of pore fluid, matrix pores and micro-fractures. e distribution and connectivity of coal pore directly affect the migration and diffusion of gas. In the process of coal seam mining or gas drainage, the coal seamstress field, fissure field, and gas seepage field change. Fracture expansion and penetration of coal and rock mass caused by mining unloading will change the interaction between coal and gas. e natural pore and fissure structural characteristics of coal determine that coal has good gas adsorption capacity and storage performance. In recent years, scholars have conducted a lot of research on coal pore structure and gas adsorption characteristics. Bing et al. [1] studied the pore structure and adsorption characteristics of outburst coal and found that micropores with a pore size of 3-5 nm in outburst coal are the main gas adsorption space. Xue et al. [2] used a variety of test methods to study and found that for the same coal grade, as the degree of structural deformation increases, open pores gradually transform into fine bottleneck pores, and the adsorption capacity increases, but the coal porosity decreases. Yuan et al. [3,4] used nitrogen adsorption method and mercury injection method to study the pore structure of coal and obtained the pore characteristics of coal adsorption and migration; Sitprasert et al. [5] used multiscale methods to study physical adsorption in micropores; Rigby et al. [6] studied the gas adsorption law of irregular meshes. Zhang et al. [7] used the low-temperature liquid nitrogen method to study the influence of structural deformation on the nano-scale pore structure of coal and found that ductile deformed coal has more complex pore structure and a higher fractal dimension than brittle deformed coal. An et al. [8] conducted a fractal study on the pore characteristics of high coal rank coals and found that the pore fractal dimension is negatively correlated with coal metamorphism, porosity, macropore content, and volume median pore size, and has a negative correlation with mesopore content and adsorption pore content. Mercury removal efficiency and ash yield are positively correlated. Jiang et al. [9] used the mercury intrusion method to determine the characteristic parameters of the ultrafine pore structure of coal and found that as the hardness of the coal increases, the fractal dimension of pores continues to decrease. Wang et al. [10] used small-angle rays combined with scanning electron microscopy to find that coal pores are mostly spheres at low coal ranks, and generally ellipsoids with high coal ranks. Klimenko et al. [11] used the conditional moment model to study the fractal characteristics of the transportation, storage, and adsorption processes in the pores of CO 2 porous media. However, there are relatively few systematic studies on the pore characteristics of soft coal bodies. A large number of studies have shown that the pore distribution of porous media satisfies self-similarity and conforms to the fractal law [12,13]. Harpalant et al. [14][15][16][17][18] showed that the coal body will produce expansion stress and deformation after adsorbing gas. ere are few systematic research results on the influence of soft coal pore structure on gas adsorption performance.
A typical soft coal body has a smaller consolidation coefficient and a larger initial dispersion rate. is manuscript takes typical soft coal seams and contrasting hard coals as the research objects. Using scanning electron microscope, low-temperature nitrogen adsorption test and isothermal adsorption test, combined with fractal geometry theory, the pore structure characteristics of soft coal and hard coal and their influence on gas adsorption characteristics are studied. In order to quantitatively characterize the pore distribution characteristics of soft coal and hard coal, the mechanical properties of soft coal and the gas flow law in soft coal are studied. e research results of this manuscript will provide a theoretical basis for in-depth analysis of the adsorption/ desorption mechanism of coalbed methane in soft coal seams and the formulation of practical coalbed methane control measures.

Experimental Apparatus.
e self-developed high/lowtemperature pressure swing adsorption-desorption experimental system is shown in Figure 1. e experimental equipment mainly consists of an adsorption system, a gas desorption system, a refrigeration system, an electrical control system, and a computer data acquisition and processing system. e gas adsorption experiment adopts the pressure range is 0-8 MPa.
e working temperature is 0-40°C. e low-temperature nitrogen adsorption test uses the ASAP-2020 specific surface and pore size analyzer produced by Mircromeritics. e pore volume is less than 0.0001 cm 3 / g, the pore size analysis range is 0.35 to 500 nm, and the specific surface area analysis range is 0.0005 to 5000 m 2 /g. e pore size classification method defined by the International Union of Pure and Applied Chemistry (referred to as IUPAC) is used. Using the ΣIGMA scanning electron microscope produced by Zeiss, the acceleration voltage range of the instrument is 0.1-30 kV, and the magnification range is 12-500 kX. It can analyze the microstructure of powder, block, and film samples.

Sample Preparations.
e soft coal sample used in the test was taken from the Lvtang Coal Mine (LT) in Bijie District, Guizhou, China, and the hard coal used was taken from the Quanlun Coal Mine (QL) in Qinglong County, Xingyi City. e geographical location of the LT and QL is shown in Figure 2.
Each coal sample is not less than 1 kg. According to the China Coal Industry Standard [19] to prepare the coal sample for proximate analysis and gas adsorption experiment, the humidification process for coal samples is shown in Figure 3. e data of proximate analysis of coal samples, coal hardiness coefficient, and initial gas diffusion velocity of coal are shown in Table 1. Select a small coal sample with a flat cross section with a particle size of 1 to 2 cm 3 for low-temperature nitrogen adsorption test. It should be handled with care during operation. Table 1 data display that the firmness coefficient of soft coal is significantly lower than that of hard coal, and the initial rate of dispersal is greater than that of hard coal.

Experimental Methods.
Coal sample gas desorption process simulation was conducted by employing the experimental device shown in Figure 3. e gas desorption environment of the sample was always maintained at a temperature of 30 ± 1°C and a gas outlet pressure of 0.1 MPa during the measurement process, and gas desorption of the coal sample could be considered to be an isothermal and isostatic desorption process. e experiment is conducted following the steps: (1) e experimental coal sample is loaded into the coal sample tank. (2) e coal sample tank and the reference tank are fully degassed using a vacuum pump. (3) When the vacuum in the experimental system reaches 25 kPa, gas is introduced into the reference tank. When the gas pressure is stable, the coal sample tank and the reference tank are connected to conduct gas adsorption.
2 Advances in Civil Engineering (4) As gas adsorption balance in the coal sample is reached, the gas inlet valve is first closed, and the gas outlet valve is opened second to conduct the gas desorption experiment.
(5) After the experiment is completed, the measured gas desorption amount is converted into volume in the standard state.

Pore Microstructure
Analyses. e coal sample from the Lvtang coal mine showed a microscopic breccia structure when observed under a microscope, as shown in Figure 4(a). Its characteristic is that the coal body is broken into particles of different sizes, some of which have more obvious edges and corners. e particles on the coal surface are mostly     Mad is moisture content on air-dry (ad) basis, %; Aad is ash content on air-dry (ad) basis, %; Vdaf is volatile matter content on dry-ash-free (daf ) basis, %; f is coal hardiness coefficient, dimensionless; ΔP is the initial gas diffusion velocity of coal, mmHg. fissure penetrates the entire coal surface in the visible range, as shown in Figure 4(b). e surface of the coal sample is distributed with some inorganic components such as pointlike and pile-like clay materials. On the one hand, the presence of inorganic components increases the strength of the coal and acts as the skeleton of the coal; on the other hand, it destroys the uniformity of the coal and softens when exposed to water, which directly reduces the anti-destructive ability of the coal body itself.

Specific Surface Areas and Pore Volume Characteristics.
Two sets of soft coal experiment coal samples from LT and two sets of hard coal experiment coal samples from QL were selected, and a total of 4 sets of nitrogen adsorption tests were carried out. e pore volume characterization method adopts the BJH method, and the specific surface area characterization method adopts the BET method and the Langmuir method. e pore structure characteristics of the soft and hard coal surface are analyzed from different angles. e results of the low-temperature nitrogen adsorption test are shown in Table 2.
It can be seen from Table 2 that the BET specific surface area values of soft and hard coal are all smaller than the corresponding Langmuir specific surface area values. is is because the calculation methods of the two models are different. e Langmuir model assumes that the gas adsorption on the coal surface is limited to a single layer, while the BET model believes that the gas adsorption on the coal surface can be multilayer adsorption. at is, when the gas reaches the saturated adsorption capacity, the adsorption capacity of the BET model is greater than that of the Langmuir model. In addition, single-layer adsorption capacity referred to by Langmuir theory is the saturated adsorption capacity, while the single-layer adsorption capacity referred to by the BET theory is only a theoretical value. e Langmuir saturated adsorption capacity is not equal to the maximum adsorption capacity, but corresponds to the closed point of the adsorption loop on the adsorption isotherm. e appearance of adsorption loops on the adsorption isotherm indicates that there are mesopores or microporous pores in the test object. However, the adsorption in the mesopores appears as capillary condensation. According to theory of Langmuir, it is an adsorbate liquefaction process and cannot be regarded as an adsorption process. erefore, the Langmuir theoretical model is not suitable for explaining the adsorption behavior of the adsorbate in the mesopores. For porous media, especially materials with more micropores and mesopores, the BET model is more suitable for characterizing the specific surface area. e BET specific surface area of soft coal ranges from 10.4158 to 14.3245 m 2 /g, and the BJH pore volume ranges from 0.006117 to 0.008416 cm 3 /g. e specific surface area and pore volume of soft coal are 2.33 times and 1.79 times larger than those of hard coal, respectively. Specific surface area and pore volume are important indicators to characterize the ability of coal to absorb gas. e larger the value, the larger the gas absorption volume of coal. e average pore diameter of soft coal is smaller than that of hard coal, indicating that the inner surface area of the pores of soft coal is larger in unit volume, so that the pore surface provides more gas adsorption sites.

Relationship between Adsorption/Desorption Curve and Pore Structure Characteristics.
e shape of the different relative pressure sections of the adsorption isotherm reflects the physical characteristics of the coal surface and the relationship between the coal and gas. e relative pressure can evaluate the performance of the coal reservoir, especially the permeability of the coal. e low-temperature nitrogen adsorption/desorption curve of a typical soft and hard coal sample is shown in Figure 5.
It can be seen from Figure 5 that when the relative pressure is zero, the nitrogen adsorption capacity of soft and hard coal is greater than zero. It shows that a certain volume of nitrogen has been adsorbed in the micropores, and the adsorption capacity of soft coal at the starting point is greater than that of hard coal. It can be seen that soft coal has a larger micropore area than hard coal. is is because the gas is preferentially adsorbed in the micropores of the coal. e more micropores contained in the coal, the stronger the superposition of the adsorption potential energy in the micropores. As a result, nitrogen adsorption capacity increases faster. When the relative pressure is between 0 and 0.2, the adsorption curve shows an upward convex trend. It shows that the force between the surface of the coal body and the nitrogen molecules is strong [20]. When the relative pressure is between 0.5 and 1, soft and hard coal have different adsorption hysteresis loops. And the hysteresis range of soft coal is larger than that of hard coal. e size of the hysteresis ring reflects the connectivity of coal pores. It shows that the pore connectivity of soft coal is better than that of hard coal [21]. Compared with hard coal, the hysteresis loop of soft coal is more obvious in the desorption process. is shows that it is very likely that a large amount of gas will escape in a short time when mining soft coal seams. Major outburst prevention and stress control measures should be taken to mine and ease the pressure during mining. When the relative pressure is higher than 0.9, the adsorption curve rises sharply, and the rise rate of the soft coal adsorption curve is obviously greater than that of the hard coal adsorption curve. e opening degree of coal pores is related to the rate of rise of the adsorption line. e faster the rise, the greater the opening degree of the pores.

Fractal Geometric Characteristics of Coal Surface.
e fractal dimension can be used to characterize the fractal characteristics of the pore surface of coal, and its numerical value can be obtained from low-temperature nitrogen adsorption test data. Calculating and analyzing from different angles, taking the adsorption capacity at the inspection point, the relationship between fractal dimension and adsorption capacity is as follows [22]: where P is nitrogen partial pressure, MPa; Q is the adsorption capacity when the equilibrium pressure is P, cm 3 /g;

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P 0 is saturated vapor pressure of gas adsorption, MPa; D f is fractal dimension, which characterizes the fractal characteristics of coal pore surface, dimensionless; and C is constant, dimensionless. Taking the specific surface area of coal as an investigation point, the relationship between fractal dimension and specific surface area is as follows [23]: where A is specific surface area of coal surface, m 2 /g; other parameter symbols have the same meaning as above.
In the low-temperature nitrogen adsorption experiment, a straight line can be obtained by plotting LnQ and LnA against Ln(LnP 0 /P), and the fractal dimension can be obtained from the slope of the straight line. According to formula (1) and (2), the size of the fractal dimension of the coal sample surface can be calculated, and the calculation results are shown in Table 3.
e data in Table 3 shows that the calculation results of formula (1) and (2) are slightly different, and the calculation result of formula (1) is slightly larger than that of formula (2).
is difference may be due to the micropores or mesopores in the coal. e difference in the pore size of the micropores or mesopores results in the difference in the adsorption potential of the micropores for nitrogen, so that nitrogen molecules cannot completely and effectively fill all mesopores. e scoring dimension results of the two calculation formulas reflect the characteristics of coal pore structure to a certain extent. It can be seen from Table 3 that the calculation results of the surface fractal dimension of soft coal are between 2.12 and 2.35, the calculation results of the surface fractal dimension of hard coal are between 1.43 and 1.62, and the average surface fractal dimension of soft coal is 1.47 times that of hard coal. e larger the fractal dimension, the rougher the surface and the larger the specific surface area of coal pores. is also reflects that soft coal has more developed pores than hard coal.

Characteristics of Coal Gas Adsorption.
Constant temperature adsorption experimental data of soft and hard coal are shown in Table 4, and the constant temperature adsorption test curve is shown in Figure 6.
Comprehensive analysis of Table 4 and Figure 6 can be drawn that, under the same experimental conditions, the soft coal adsorption constants a and b are both larger than the hard coal adsorption constants. Soft coal has a larger saturated adsorption capacity than hard coal, and at the same time soft coal reaches the saturated adsorption capacity faster. It shows that the gas adsorbs and stays on the pore surface of the soft coal for a long time, the gas coverage is high, and the soft coal has a stronger ability to adsorb gas.

e Superposition of Adsorption Potential Energy in the
Micropores. e abundant pore structure in the coal body is not only a place for gas storage, but also a channel for gas migration and diffusion. In particular, the presence of micropores greatly increases the surface area of the coal body. Since the size of the micropores is similar to the size of the gas molecules, the gas molecules are surrounded by the micropores. e adsorption force field in the micropores produces a superposition effect, so that the adsorption potential energy is greatly enhanced compared with the adsorption potential energy on the flat pore wall surface. Under low relative pressure, it has stronger adsorption attraction for gas molecules. Studies have shown that the adsorption potential is greatly enhanced in circular pores less than six molecular diameters and in slit pores less than two molecular diameters. e relationship between micropore adsorption volume and adsorption potential energy can be expressed as [24] φ � φ 0 · e − Kε 2 , where φ is adsorption volume, cm 3 ; φ 0 is maximum adsorption volume, cm 3 ; K is constant related to the micropore structure, dimensionless; and ε is adsorption potential energy, J. In formula (3), ε 2 reflects the superposition of the adsorption potential field on the micropore wall.

Diffusion in Mesopores.
e analysis of mesopores is closely related to the nitrogen adsorption/desorption curve, and the specific form of the adsorption hysteresis ring corresponds to different mesopore structures. e large range of the hysteresis ring indicates that the corresponding pores are smooth and the pores have high air permeability, which is conducive to the migration and diffusion of gas. e diffusion of gas in mesopores satisfy Fick diffusion, and the diffusion rate can be expressed as where dQ/dt is gas diffusion rate, kg/s; D 0 is gas diffusion coefficient, m 2 /s; A g is the gas diffusion area in the channel, m 2 ; and dc/dx is gas concentration gradient, kg/(m 3 ·m).
In formula (4), "−" means that the direction of gas diffusion in the channel is opposite to the direction of the gas concentration gradient.

e Effect of Adsorption Residence Time on Gas Adsorption.
e time from when the gas molecules hit the surface of the coal body to when they leave the surface and return to the gas phase is called the adsorption residence time. If the adsorption residence time is much longer than   (1 + bP)). Here, a is the value reflects the maximum adsorption capacity of the coal, cm 3 /g; b is the value represents the rate at which the coal reaches its saturated adsorption capacity, MPa −1 ; Q is gas adsorption capacity under a certain pressure, cm 3 ; P is the gas pressure of the coal seam, MPa. the molecular vibration period, it can be considered that adsorption has occurred. e inner surface area of the pores of soft coal is larger, it provides more gas adsorption sites, and the adsorption site gas coverage is high. Soft coal has a stronger adsorption potential for gas, and the adsorption residence time of gas on the surface of soft coal is longer than that of hard coal, so the amount of gas adsorption is greater. e gas coverage of coal pore surface can be expressed as where θ is the gas coverage on the surface of coal pores, (°); a is the number of gas molecules adsorbed on the coal surface, unit; and a m is the number of gas molecules covering the monolayer of 1 cm 2 coal surface, unit. e relationship between the number of gas molecules and the adsorption residence time τ can be expressed as where n is the number of gas molecules that collide on the surface of the coal body in a unit time, unit; N A is Avogadro's constant, which is 6.02 × 10 23 mol −1 ; P is gas pressure, MPa; M is the relative molecular mass of adsorption, dimensionless; R is the ideal gas constant, which is 8.314 J/(mol·K); T is the thermodynamic temperature, K; and τ is adsorption residence time, S.

e Influence of Fractal Characteristics on Gas Adsorption.
e difference in the fractal characteristics of the coal surface reflects the change of the coal pore structure. e pore size of the soft coal gradually decreases with the increase of the fractal dimension of the coal surface. e change curve of the calculation result using formula (1) is shown in Figure 7. e larger the fractal dimension, the higher the surface roughness of the coal and the increase of pores per unit volume. e radius of the pore channel decreases, which increases the pore volume and specific surface area. e gas adsorption sites provided by the pore surface of the coal increase, and the gas adsorption capacity is enhanced.
According to the theory of fractal geometry, there is the following relationship between the pore radius and the cumulative number in coal [25]: where N is the total number of pores per unit volume of coal, unit; r is the radius of the pores in the coal, nm; A f is does not significantly include the proportional coefficient of D f ; r m is maximum radius of the pore, nm; r 0 is minimum radius of pore, nm; and λ is the ratio of the minimum and maximum pore radius. From formula (7), the distribution density function of the pore radius in the coal body can be obtained: From formula (8), the average radius of pores in the coal body can be obtained as Analyzing formula (9), it can be obtained that the average radius of coal pores depends entirely on the fractal dimension D f of the coal, the upper and lower limits r m and r 0 of the pore distribution in the coal, and the total number of pores in the porous medium per unit volume N.
In addition, upper and lower limits r m and r 0 of the pore distribution in the coal body and the total number N of pores per unit volume of porous media are constant. en, the average radius r of the pore gradually decreases with the increase of the fractal dimension D f .

Conclusion
In this paper, a self-developed adsorption/desorption device is used to test the gas adsorption and desorption performance of soft coal and hard coal under low-temperature conditions, combined with scanning electron microscope and low-temperature nitrogen adsorption experiment to test the pore characteristics of experimental soft coal and hard coal. Analyze the microscopic pore and fracture structure and connectivity of typical soft coal, use the box dimension algorithm to measure the fractal dimension of the microstructure of the coal sample, and compare and analyze the relevant characteristics of hard coal. And we got the following conclusions:  (1) e results of the low-temperature nitrogen adsorption test calculated that the BET specific surface area of soft coal ranges from 10.4158 to 14.3245 m 2 /g, and the BJH pore volume ranges from 0.006117 to 0.008416 cm 3 /g, both of which are larger than those of hard coal. It shows that soft coal has more pores than hard coal, and the inner surface of the pores is larger. Particularly, the number of micropores and the superposition of the adsorption potential energy existing in the micropores make the adsorption potential energy of soft coal to gas greater. (2) According to the nitrogen adsorption test data, the fractal characteristics of the pore surface of soft and hard coal are calculated, and the average fractal dimension of the surface of soft coal is more than double that of hard coal. It shows that the surface roughness of soft coal is high, there are many pores per unit volume, and the inner surface of the pores can provide more adsorption sites. e gas adsorption site coverage on the surface of the soft coal body is high, and the adsorption residence time is long. erefore, soft coal has a stronger ability to absorb gas than hard coal.
(3) Compared with hard coal, soft coal exhibits a larger adsorption hysteresis loop in the nitrogen adsorption test. It shows that the pore connectivity of coal is better than that of hard coal. When mining soft coal seams, it is more likely to cause a large amount of gas escape in a short time. When mining, the main prevention and control measures should be taken to extract and relieve pressure [26].

Data Availability
All the data generated or published during the study are included within the article; no other data were used to support this study.

Conflicts of Interest
e authors declare that they have no conflicts of interest regarding the publication of this paper.