Effects of Metamorphic Degree of Coal on Coal Dust Wettability and Dust-Suppression Efficiency via Spraying

Wang, Pengfei; Han, Han; Liu, Ronghua; Li, Yongjun; Tan, Xuanhao

doi:https://doi.org/10.1155/2020/4854391

Advances in Materials Science and Engineering

On this page

Abstract Introduction Experimental Results and Analysis Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2020 | Article ID 4854391 | https://doi.org/10.1155/2020/4854391

Effects of Metamorphic Degree of Coal on Coal Dust Wettability and Dust-Suppression Efficiency via Spraying

Pengfei Wang,^1,2,3Han Han,¹Ronghua Liu,¹Yongjun Li,¹and Xuanhao Tan¹

Academic Editor: Michael Aizenshtein

Received15 Oct 2019

Accepted24 Dec 2019

Published30 Mar 2020

Abstract

Currently, spraying is a main means for dust prevention and control in underground coal mines. The dust-suppression efficiency via spraying is highly correlated with the wettability of coal dusts. There are many factors affecting the wettability of coal dust, among which coal’s metamorphic degree has great influence. In order to gain in-depth knowledge of the effects of coal metamorphic degree on coal dust wettability and the dust-suppression efficiency via spraying, 6 coal dust samples with different metamorphic degrees were collected and used in the study. In the experiments, the microproperties, wetting performance, and dust-suppression efficiency via spraying were measured. According to the experimental results of coal’s microproperties, with the improvement of metamorphic degree, the content of hydrophilic oxygen-containing functional groups on the surface, the surface roughness, the specific surface area, and the interpore diameter all decreased. In addition, as coal’s metamorphic degree was enhanced from lignite to meager-lean coal, the wettability of the coal dust dropped. On the other hand, as the metamorphic degree of coal quality continued to be improved to anthracite, the wettability of the coal dust increased instead. The measured results revealed that the dust-suppression efficiency via spraying was highly correlated with the wettability of coal dust. The coal dust with better wettability exhibited higher dust-suppression efficiency via spraying. With the increase of water-supply pressure, the effect of coal dust wettability on the dust-suppression efficiency via spraying was weakened, and the difference of dust-suppression efficiency among different coal dust samples was narrowed.

1. Introduction

Coal is an important natural resource and plays a decisive role in the development of national economy [1–4]. During underground coal mining and transportation processes, a great amount of coal dust is produced [5–7]. Without effective control, coal dust not only threatens workers’ physical health but also causes serious threat to the safe production in coal mines [8–12]. According to China’s occupational disease report released by the National Health Commission in the People’s Republic of China, 23,497 occupational cases were reported in 2018, among which 19,468 patients suffered from pneumoconiosis, occupying 82.85% of total occupational cases [13]. In terms of industrial distribution of the occupational disease, the newly reported pneumoconiosis cases were mainly distributed in coal mining and nonferrous metal mining industries. In particular, the number of pneumoconiosis cases in coal mining industry accounts for 40% of the total number of the reported occupational cases. Therefore, it is extremely urgent to adopt high-efficiency dust-suppression and dust-control measures to reduce the dust concentration in coal production sites [14–18].

Currently, the main dust prevention methods in underground coal mine include preinjection of water into coal, ventilation, exhausting of dust, purification of air by dust remover, spraying, and dust isolation via enclosing [19–25]. Spraying has been extensively applied in underground mines for dedusting due to the low cost, convenient operation, and practicability [26–31]. The results in previous studies also revealed that the dust-suppression efficiency via spraying was closely related to the wettability of the coal dust. In general, spraying has higher dust-suppression performance on the coal dust with more favorable wettability. Hydrophobic coal dust can hardly be combined with the droplets in the air and can only be captured by a large number of droplets at high movement velocity [32–39]. Therefore, the in-depth knowledge of the wettability of coal dust and the dust-suppression efficiency via spraying has great guiding significance for the design of dust-suppression scheme via spraying and the prediction of dust-suppression efficiency in underground coal mines.

For the above reasons, researchers have performed many studies on the wettability of coal dust. Using Dataphysics DCAT21 surface interface tension meter, Dong et al. [40] measured the contact angles of 5 different types of ultrafine coal powders with different metamorphic degrees and found that the surface of coal dust became super-hydrophobic after ultrafine crushing. Wen et al. [41] adopted the software of MDI Jade 6.5 to analyze the inorganic mineral characteristics of the ashes in coal dust and investigate the effect of inorganic minerals on the dust wettability. From the results, quartz in coal dust ash can be used as the evaluation index of the hydrophily of coal dust. Chen et al. [42] examined the functional groups on the surface of coal dust using Fourier transform infrared (FTIR) spectrometer and pointed out that the wettability of the coal dust was affected by the transmittance of aromatic ring C-H stretching at 3050 cm⁻¹, the transmittance of S-O-Si anti-symmetric stretching at 1020–1100 cm⁻¹, and the content of Zhao et al. [43] investigated the relations of coal dust wettability with the quality parameters of coal and the functional groups on the surface of coal dust using experiments. In their study, a method was developed to measure and characterize the wettability of coal dust rapidly. Zhou et al. [44, 45] examined the carbon skeleton structures of coal dust particles with 6 different metamorphic degrees using magnetic resonance imaging (MRI) and revealed the variation patterns of the structural parameters for aromatic carbon and fat carbon with metamorphic degree. Luo et al. [46] investigated the influence of the chemical composition and internal structural parameters of the coal dust on the wettability. It was concluded that the chemical composition of coal dust played a dominant role in causing the difference in wettability. The carbon content and oxygen content played a significant role in the wettability of coal dust, while the average pore size and specific pore volume of the particles were less correlated with the wettability of coal dust. Huang et al. [47] conducted industrial analysis and elemental analysis on 13 types of coal dust with different metamorphic degrees. The wettability of each type of coal dust was measured using reverse osmosis experiment. On this basis, the optimal regression equation for the chemical composition of coal dust with the wettability of coal dust was established using both linear and nonlinear regression methods. The optimal regression equation can be used to determine the most significant influencing factors for the wettability of coal dust. In the study by Wang et al. [48], the functional group composition and wettability of five types of coal dust were obtained through infrared spectroscopy and contact angle experiments. The hydrophilic functional groups and hydrophobic functional groups on the surface of coal dust were determined. In addition, the coal dust with different degrees of metamorphism was evaluated to have different wettability.

Based on the relationship between the chemical composition and wettability of coal dust, Yang et al. [49, 50], Zhou et al. [51], and Wen and Liu [52] systematically investigated the effects of particle size of coal dust on the surface properties and wettability. The experimental methods included FTIR spectroscopy, X-ray photoelectron spectroscopy, and contact angle measurement. The results showed that the surface pore structure, chemical structure, and element composition of coal dust all changed with the reduction in the particle size of coal dust. In addition, as the particle size decreased, the wettability became weaker while the hydrophobicity became stronger. Some researchers have also investigated the effect of surface roughness of coal dust on the wettability. However, the obtained conclusions by these researchers on this topic were different and even contrary [53–56]. At present, regarding the influence of the surface roughness on the wettability of coal dust, the accepted conclusion is that as the surface of coal dust gets rougher, the wettability is better [57, 58].

Up to now, there has been a great progress in the studies on the wettability of coal dust, especially in the influence mechanism of the chemical composition and the metamorphic degree on the wettability of coal dust. However, there are two problems in the previous studies: (1) The method of determining the wettability of coal dust is relatively simple. Only a single index, i.e., contact angle or reverse osmosis moisture, was used to evaluate the wettability. Thus the accuracy of the conclusion needs to be further verified. (2) The studies only investigated the influence of the metamorphic degree of coal dust on the wettability. However, the correlation between the wettability and the dust-reduction efficiency via spraying was not analyzed. Thus the effect of the metamorphic degree on the dust-reduction efficiency of coal dust still needs to be determined. In this study, coal dust particles with 6 different metamorphic degrees were collected from the main coal production sites in China. In addition, infrared (IR) spectra, BET measurement, and scanning electron microscope (SEM) were used to analyze the microstructure of coal dust. Based on the combination of the contact angle and reserve osmosis experiments, the influence mechanism of the metamorphic degree on the wettability of coal dust was analyzed on a microscopic level. On this basis, the custom-developed dust-suppression experimental platform via spraying was used to investigate the dust-suppression efficiencies for the coal dust particles with different metamorphic degrees. The effect of the metamorphic degree of coal dust on the dust-suppression efficiency via spraying was evaluated. The results in this study can provide insightful reference and guidance for the design of spraying-based dust-suppression scheme and theoretical prediction of dust-suppression efficiency via spraying in underground coal mines.

2. Experimental Samples and Scheme

2.1. Experimental Samples

In order to obtain thorough knowledge about the influence of the metamorphic degree on the wettability of coal dust, coal dust particles with 6 different metamorphic degrees were collected from the main coal production sites in China. Specifically, the samples can be arranged in the following order according to the ascending of the metamorphic degree: lignite sample from Donghuai Coal Mine, Guangxi, gas coal sample from Baodian Coal Mine, Shandong, fat coal sample from Qianjiaying Coal Mine, Hebei, coking coal sample from Wanfeng Coal Mine, Shanxi, Meager-lean coal sample from Fa’er Coal Mine, Guizhou, and anthracite sample from Motian Coal Mine, Hunan. The industrial indexes and characteristic particle sizes of these 6 coal samples are listed in Table 1.

The collected coal samples were crushed by the grinder and sieved by standard industrial sifter with the pore diameter of 100 meshes. The sieved coal dust samples were labeled in the ascending order of metamorphic degree and placed in a vacuum drying oven for 480 minutes at 80°C. After being dried, the samples were placed in the sealing bag for further analysis. The particle size of coal dust was measured by LS13320 laser particle size analyzer. The measured results are shown in Figure 1.

(a)

(b)

(c)

(d)

(e)

(f)

2.2. Measurement of Basic Properties of Coal Dust

The basic properties of coal dust consisted of two parts, i.e., the microproperties and the wetting performance. The first group of experiments analyzed the microproperties of coal dust. Previous studies demonstrated that the wettability of coal dust was mainly affected by the important intrinsic parameters, including functional groups on the surface of coal dust, specific surface area, and mean internal pore diameter. The function groups on the surface of the moulded sample were analyzed using a Nicolet 6700 FT-IR spectrometer. Surface roughness of the coal sample was characterized by a new-generation high-resolution SEM (SU3500, Hitachi, Japan). Specific surface areas and mean pore diameters of the 6 coal dust samples were measured by the BET analyzer (ASAP2010, Micromeritics, America).

The second group of experiments investigated the wetting performance of coal dust. In this study, wetting performance of coal dust was evaluated by the contact angle and the reverse osmosis hygroscopic capacity. 400 mg coal powder was added to the mould and placed under a bench powder compressing machine. The moulding pressure with a magnitude of 50 MPa was applied and maintained for 1 minute to prepare the cylindrical test piece with the thickness of 2 mm. Three test pieces with smooth surfaces were prepared for each coal dust sample. The contact angle between distilled water and the test piece of coal dust was then measured by a CA100B contact angle meter. For each coal dust sample, the contact angle was measured from 3 test pieces and the average results were obtained. The hygroscopic properties of the prepared coal dust sample were measured using the custom-designed reserve osmosis device. Three grams of coal sample was placed in a glass tube with a diameter of 10 mm, and the tube was sealed by the filter paper and weighed. The glass tube was then inversed and placed into a water tank. Distilled water was added to the tank until it exactly submerged the orifice of the glass tube. After 10 minutes, the tube was taken out and weighed to calculate the water absorption capacity of the coal dust.

2.3. Measurement of Dust-Suppression Efficiency via Spraying

As shown in Figure 2, a dust-suppression experimental system via spraying was designed to simulate dust production, spraying, and ventilation conditions. The system mainly consisted of the tunnel model, a high-pressure water pump, a water tank, a control box, an aerosol generator, and the related pipes, valves, and measurement instruments. The tunnel model mainly included an inlet section, a measurement section, a spraying section, an axial flow fan, and an outlet section. The main section of the roadway model was 30 m, in which the length of the spraying section was 10 m. The section of the roadway was rectangular with the dimension of 60 cm × 60 cm. To facilitate the measurement of droplet size using the Malvern particle size analyzer, the main section of the tunnel model was made of the transparent organic glass with the thickness of 1 cm.

In this study, dust was generated by a dry-powder aerosol diffuser (AG420, Germany) at the rate of 13 g/min. Two antiexplosion dust samplers (FCC-25) were arranged in the measurement section. One sampler was placed in front of the spraying system and the other one was placed behind the spraying system. Dust particles at both measurement points were simultaneously collected under different operating conditions. Under each operating condition, the sampling was continuously conducted 3 times and the average value was calculated. The sampling time was set to 2 minutes and the sampling rate was set to 15 L/min. The mass concentration of dust was calculated from the weight measured by an electronic analytical balance. Before the test of dust-suppression efficiency via spraying, the airflow velocity in the tunnel model was set to 1.0 m/s. The dust-suppression efficiencies for 6 different types of coal dust samples were measured under 4 different water supply pressures, i.e., 0.5 MPa, 1.0 MPa, 1.5 MPa, and 2.0 MPa. A commonly used nozzle in mines, i.e., the spiral-apertured pressure nozzle with the outlet diameter of 0.8 mm, was used in the experiment. Figure 3 shows the structure of the spiral-apertured pressure nozzle. The water in the dust-reduction experiment via spraying was from the municipal pipe network. The droplet size parameters under 4 different water supply pressures were measured using Malvern particle size analyzer.

The horizontal droplet flow can be divided into a diffusion section, a direct-injection section, and an attenuating section. In the diffusion section, located near the exit of the nozzle, the droplets are dense and the particle size changes dramatically. Thus, in the diffusion section, the penetration of the transmitted laser from the Malvern droplet size analyzer is limited while the receiver has challenges to detect the signal and measure the droplet size. In the attenuation section, the droplet flow has an irregular shape and the distribution of the droplets is significantly affected by gravity. Therefore, in this study, the direct-injection section of the droplet flow is selected for the data acquisition to measure the parameters of droplets. The specific position for data acquisition was located at the center of the vertical cross section, which was 50 cm downstream of the nozzle.

3. Experimental Results and Analysis

3.1. Microproperties of Coal Dust

In order to illustrate the influence mechanism of the internal structure of coal dust on the wettability, many microcharacteristic parameters were acquired in the test, including surface functional groups, surface roughness degrees, specific surface areas, and internal pore diameters of coal dust samples with different metamorphic degrees.

3.1.1. Surface Functional Groups

Figure 4 shows the IR spectra of coal dust samples with 6 different metamorphic degrees in the study. In Figure 4, the absorption peaks can be clearly observed at 3400–3500 cm⁻¹, 2800–3000 cm⁻¹, 1600–1620 cm⁻¹, and 1020–1100 cm⁻¹. The above 4 absorption peaks are corresponding to the stretching radicals of aromatic hydroxyl, the absorption peak of C-H stretching radicals of aliphatic series, the absorption peak of C-H stretching radicals of aromatic ring, and the absorption peak of antisymmetrical stretching of Si-O-Si in quartz, respectively. Based on the results, despite of different metamorphic degrees, the 6 coal dust samples exhibited similar spectral pattern and almost identical characteristic peaks, which indicated that the coal dust samples had similar internal structure. Meanwhile, due to the differences in the metamorphic degree and the coal-formation condition, the characteristic absorptions of the 6 coal dust samples differed at the same wave length to a certain degree.

By comparing and analyzing IR spectra of different coal dust samples, the transmittances at the characteristic peaks were greatly different among the coal dust samples with different metamorphic degrees. Overall, the transmittance increased with the increase of metamorphic degree. Previous studies demonstrate that the wettability of coal dust was highly correlated with the oxygen-containing functional groups on the surface of coal dust, including aliphatic hydrocarbon and aromatic hydrocarbon [59, 60]. In general, the coal dust with a higher content of oxygen-containing functional groups is more hydrophilic and exhibits more favorable wettability. Therefore, the oxygen-containing functional groups corresponding to above 4 characteristic peaks were selected for in-depth analysis. The IR spectra were interpreted into absorbance based on Lambert-Beer Law. Then both heights and areas of the characteristic peaks of the oxygen-containing functional groups were quantitatively analyzed using OMNIC 8.0. The analysis results are shown in Figure 5.

(a)

(b)

(c)

As shown in Figure 5(a), the height of the characteristic peak decreased steadily with the increase of metamorphic degree, which suggested that the content of oxygen-containing functional groups gradually decreased with the coal-formation time and the environmental evolution. The coal sample with higher metamorphic degree contained a smaller content of oxygen-containing functional groups. The characteristic peaks of the oxygen-containing functional groups of lignite sample were highest while those of anthracite sample were lowest. From Figures 5(b) and 5(c), the areas at 4 characteristic peaks decreased steadily with the improvement of coal quality. The results further confirmed that, with the increase of the metamorphic degree, the oxygen-containing functional groups on the surface gradually fell off, resulting in the decrease of the content of oxygen-containing functional groups.

3.1.2. Surface Characteristics and Internal Pore Diameter of Coal Dust

Previous studies suggested that the roughness degree on the surface of the material affected the wettability to a certain degree. In general, for nonhydrophobic material with a contact angle of below 90°, a rougher surface is indicative of more favorable wetting performance [57, 58]. Figure 6 shows the SEM images of the 6 coal dust samples. From Figure 6, due to the differences in metamorphic degree and the coal formation condition, 6 coal samples exhibited different surface characteristics. To be specific, lignite sample and gas coal sample had rough surfaces with a great number of convex-concave points and pores. Fat coal sample, coking coal sample, and meager-lean coal sample had smooth surfaces but a lot of gullies. Anthracite sample had the smoothest surface without obvious voids and bumping points. Therefore, the coal sample with a better metamorphic degree exhibited a smoother surface.

After the coal sample was crushed into coal dust, the dust surface was irregular, rugged, and simultaneously containing many well-developed pores. The specific surface area of coal dust and internal pores had influence on the wetting performance. The specific surface areas and the pore diameter distributions of the 6 different types of coal dust particles were measured by nitrogen adsorption method. The measurement results are shown in Figure 7. Overall, the specific surface area of the coal dust decreased with the improvement of coal quality. Under same crushing conditions, in spite of roughly identical particle sizes, the coal sample with better quality had smoother surface, uniformly distributed surface patterns, and smaller specific surface area. This phenomenon was because of different hardness degrees and densities of the coal dust sample. In general, the wettability of the coal dust is worse when the surface of the coal dust is smoother, the morphology distribution is more uniform, and the specific surface area is smaller. Meanwhile, it can be easily observed that mean pore diameter of the coal sample also decreased with the enhancement of coal quality. Among the 6 tested samples, anthracite sample and lignite sample had smallest and greatest mean pore diameters, respectively. This was consistent with the results from SEM images. Since the anthracite coal had smooth surface and no obvious fractures, the mean pore diameter of the anthracite sample was small. By contrast, lignite sample was characterized by uneven surface and a great number of pores; thus a lot of new pores were produced after being crushed. Therefore, the mean internal pore diameter of the crushed lignite sample was great.

3.2. Measurement of Coal Dust Wettability

3.2.1. Contact Angle Test

When the droplet is in contact with the solid surface, a gas-solid-liquid interface is formed, and the intersection angle between solid-liquid interface and gas-liquid interface is called contact angle. Contact angle is an important index to characterize the wetting performance of solid materials. Due to the difference in metamorphic degree, both physical and chemical properties were different among different coal dust samples. The coal dust samples with different metamorphic degrees had different abilities combined with droplets. As a result, different coal dust samples exhibited different wetting performances. In this study, the contact angles between the distilled water and different test pieces of coal dust were measured by a CA100 B contact angle meter. The measured results are shown in Figure 8.

From Figure 8, lignite sample had the smallest contact angle, and the mean value of three measurements was 25.28°. The results proved that lignite sample had the best wettability. With the improvement of metamorphic degree, the contact angles of gas coal sample, fat coal sample, coking coal sample, and meager-lean coal increased gradually. The contact angle of meager-lean coal was the greatest, and the mean value of three measurements was over 80°. The results suggested that the wettability of coal dust decreased gradually with the improvement of the quality of coal. Figure 9 shows the projection of the contact angles of 6 types of coal dust samples, which indicated that all the coal dust samples exhibited similar variation trends. This phenomenon was due to the fact that, with the enhancement of metamorphic degree, although the content of fixed carbon in coal dust was increased, the content of oxygen-containing functional groups on the surface, the surface roughness, and the internal pore diameter were all decreased. For anthracite, since the quality of the coal was improved, the measured contact angle decreased. As a result, the wettability of the anthracite sample was improved. Although anthracite sample had a high coalification degree, it only contained a small number of oxygen-containing functional groups on the surface and the surface was smooth. However, as listed in Table 1 (industrial analysis results of coal samples), the ash content of anthracite was as high as 23.5%, which was significantly higher than that of the rest 5 coal dust samples. According to the results in the previous relevant studies, inorganic minerals in coal dust ash significantly affected the wettability [52]. Under the same conditions, the coal sample with higher ash content exhibited more favorable wettability. Therefore, because of greater ash content, the wettability of anthracite sample was remarkably improved. The contact angle of anthracite was smaller than that of meager-lean coal but was slightly greater than that of lignite. Thus in term of wettability, anthracite ranked second among the 6 coal samples. In conclusion, the wettability of coal dust was influenced by a lot of factors, including the content of fixed carbon, the content of oxygen-containing functional groups, the ash content, and the surface structural characteristics. In other words, the wettability of coal dust is the result of the combined actions by multiple factors.

(a)

(b)

(c)

(d)

(e)

(f)

In previous studies, it was demonstrated that there existed a certain relationship between the wettability of coal dust and the content of oxygen-containing functional groups when the ash content was fixed [44, 45]. As listed in Table 1, except the anthracite sample, the other 5 coal dust samples had similar ash contents. Therefore, these 5 anthracite coal dust samples were selected for further analysis. The relationship between the areas of the characteristic peaks corresponding to two representative oxygen-containing functional groups and the measured contact angle was fitted, as shown in Figure 10.

(a)

(b)

In Figure 10, the measured contact angle of coal dust decreased with the increase of the area of the characteristic peak corresponding to the oxygen-containing functional groups. A greater area of the characteristic peak corresponding to the oxygen-containing functional group was indicative of a smaller contact angle and more favorable wettability of coal dust. According to the fitted results, the areas of the characteristic peaks of the oxygen-containing functional group were linearly correlated with the measured contact angle. At both characteristic peaks, the correlation coefficients of the fitting curve were 0.9394 and 0.8369, respectively. Therefore, for coal dust samples with similar ash contents in industrial analysis indexes, the wettability can be qualitatively and quantitatively assessed by the areas of the characteristic peaks corresponding to the oxygen-containing functional groups on the surface.

3.2.2. Reverse Osmosis Test

Reverse osmosis is a conventional method to measure the wetting properties of powder materials based on the principle of capillary. In this study, the custom-designed reverse osmosis hygroscopic capacity measurement equipment was used to measure the hydroscopic capacities of the above 6 different types of coal dust samples within the prescribed time. The measurement results are shown in Figure 11.

In Figure 11, the lignite sample has the greatest hygroscopic capacity (680.10 mg), while the meager-lean coal sample and coking coal sample had the lowest hygroscopic capacities, which were 19.75 mg and 18.95 mg, respectively. According to the measured hydroscopic capacities in the reverse osmosis test, lignite with the lowest metamorphic degree exhibited the most favorable wettability, while meager-lean and coking coal samples with high metamorphic degrees had poor wettability. Due to the high ash content, the wettability of anthracite coal sample was improved, and the hygroscopic capacity of anthracite was second only to that of lignite. Thus, the hygroscopic capacity gradually decreased with the increase of the metamorphic degree of coal. As the rank of coal increased from lignite sample to meager-lean coal sample, the hygroscopic capacity gradually decreased, and the wettability of coal continuously decreased. As the quality of coal was enhanced to anthracite sample, the wettability was enhanced. The consistent results from both the contact angle and the hydroscopic capacity have proved that the conclusions on the wettability of coal dust are accurate and reliable.

3.3. Dust-Suppression Experiment via Spraying

3.3.1. Atomization Characteristics of the Nozzle

The dust-suppression efficiency via spraying is highly correlated with the atomization characteristics of the nozzle. In order to obtain the relationship between the wettability of coal dust and the dust-suppression efficiency via spraying, the atomization characteristics were measured under four different water-supply pressures. The measurement results are shown in Table 2.

Overall, with the increase of water-supply pressure, both the flow rate of the nozzle and the volume concentration of droplets increased steadily. As a result, the capacity of atomizing water in unit space was increased, which can improve the collection of dust particles. It can also be observed from Table 2 that all the characteristic particle sizes of droplets, i.e., D₁₀, D₅₀, D₉₀, D_{[3, 2]}, and D_{[4, 3]} decreased with the increase of water-supply pressure. At a water supply pressure of 0.50 MPa, D_{[3, 2]} was 145.8 μm; as water supply pressure increased to 1.0 MPa, 1.5 MPa, and 2.0 MPa, D_{[3, 2]} decreased to 132.6 μm, 117.6 μm, and 106.6 μm, respectively. Figure 12 shows the distribution of droplet particle sizes under four different water-supply pressures. From the histograms in the figure, with the increase of water-supply pressure, the peak of the volume frequency shifted towards the left, indicating the decreasing of droplet size. According to the cumulative volume fraction, the characteristic sizes of droplets, i.e., D₉₀, D₅₀, and D₁₀, all decreased with the increase of water supply pressure.

(a)

(b)

(c)

(d)

3.3.2. Dust-Suppression Efficiency via Spraying

Coal samples with different metamorphic degrees have different wettability of coal dust. In order to investigate the relationship between the wettability of coal dust and the dust-suppression efficiency via spraying, the dust-suppression experiment was conducted on coal dust samples with different metamorphic degrees. The experimental results are shown in Figure 13.

(a)

(b)

(c)

(d)

In Figure 13, under the same water-supply pressure, the dust-suppression efficiency via spraying decreases with the increase of the metamorphic degree of coal. As the quality of coal was enhanced to anthracite, the dust-suppression efficiency via spraying was enhanced. The measured dust-suppression efficiencies agreed well with the experimental results of the wettability of coal dust described in the above sections. Under similar spraying conditions, the dust-suppression efficiency for the coal dust particles with similar sizes was closely related to the wettability of the coal dust. The coal dust particles with better wettability had stronger ability to combine with droplets, which enhanced the dust-suppression efficiency via spraying. According to the above results, anthracite sample ranked only second to lignite sample in terms of wettability. However, according to the measured results, the dust-suppression efficiency of anthracite sample was slightly lower than that of gas coal sample. Anthracite sample ranked third in dust-suppression efficiency. This may be attributed to the nonidentical particle sizes of above 6 coal dust samples. As shown in Table 1, the characteristic size of anthracite sample (D₅₀ = 81.86 μm) was significantly smaller than that of gas coal sample (D₅₀ = 121.98 μm). In general, smaller coal dust particles are more difficult to be captured and thus exhibited lower dust-suppression efficiency. The above experimental results demonstrated that the dust-suppression efficiency via spraying was highly correlated with the wettability of coal dust. Due to the difference in wetting performance, the dust-suppression efficiency via spraying varied among coal dust particles with different metamorphic degrees. It can also be observed from Figure 13 that the dust-suppression efficiency via spraying was enhanced gradually with the increase of water-supply pressure. Under higher water-supply pressure, smaller droplets moved at a high velocity, and a greater amount of water was atomized in a unit space. As a result, the collision between droplets and dust particle was promoted and the dust-suppression efficiency was enhanced. This conclusion is consistent with the results from theoretical calculation [58, 59, 61, 62].

Table 3 lists the growth rates of dust-suppression efficiency within different pressure ranges. By combining Table 3 and Figure 14, it can be seen that, within the same pressure range, the growth rate of dust-suppression efficiency is different for the 6 coal dust samples. Overall, the coal dust with poor wettability had a larger growth rate, and the difference in the dust-suppression efficiency among 6 coal dust samples gradually decreased with the increase of water-supply pressure. Figure 14 shows the relationship between dust-reduction efficiency via spraying and the contact angle of coal dust. From the figure, when the wettability of coal dust is better, the dust-reduction efficiency is slightly increased with the change of the water-supply pressure. On the other hand, when the wettability of coal dust is poorer, the dust-reduction efficiency is dramatically increased with the change of the water-supply pressure. As water-supply pressure increased from 0.5 MPa to 2.0 MPa, the dust-suppression efficiency was enhanced by only 6.32% for lignite with highest wettability. On the other hand, with the same increase of the water-supply pressure, the dust-suppression efficiency was enhanced by 39.61% and 27.09% for coking coal sample and meager-lean coal with poor wettability, respectively.

When the water-supply pressure was low, the droplet concentration in the roadway space was small, the droplet size was large, and the movement velocity of the droplets was low. As a result, the probability of the collision between the droplet and the dust was low and the bonding ability between them was weak [63, 64]. The dust-suppression efficiency via spraying was related to not only the probability of collision between droplets and dust but also the wettability of coal dust, especially when the water-supply pressure was low. Under low water-supply pressure, the difference in wettability of coal dust can lead to significant difference in dust-suppression efficiency [65, 66]. The dust-suppression efficiency was higher for the coal dust with better wettability and lower for the dust with poor wettability. With the increase of water-supply pressure, the droplet size continuously decreased, while the concentration and the movement velocity of the droplet were improved. As a result, the probability of collision and bonding ability between the droplet and coal dust were greatly improved. The coal dust with poor wettability had low bonding ability with the droplets. Thus, under low water-supply pressure, the dust-suppression efficiency was low due to the small droplet concentration and low movement velocity. With the increase of water-supply pressure, the droplet concentration and the movement velocity increased significantly, which can reduce the impact of the different wettability of the coal dust [67]. Therefore, the dust-suppression efficiency for the coal dust with poor wettability can be significantly improved with the increase of water supply pressure. The coal dust with good wettability had stronger bonding ability with the droplets and better dust-suppression efficiency under low water-supply pressure. As the water-supply pressure increased, the improvement of the dust-suppression efficiency for the coal dust with high wettability was not as significant as that for the coal dust with poor wettability. Thus, the influence of the wettability of coal dust on dust-suppression efficiency via spraying was reduced with the increase of water-supply pressure. Therefore, with the increase of water-supply pressure, the dust-suppression efficiencies corresponding to the six types of coal dust gradually approached closer, while the gaps among different types of dust were smaller and smaller.

4. Conclusions

In this study, the microproperties and wetting performances of coal dust with different metamorphic degrees were measured. In addition, the relationship between the wettability of coal dust and the metamorphic degree was investigated, and the influence mechanism of the wettability was analyzed at microlevel. Using the custom-designed experimental platform, the dust-suppression experiment via spraying was performed and the effects of coal dust wettability on the dust-suppression efficiency were obtained. The main conclusions from this study are described as follows:(1)As the metamorphic degree of coal was improved, the characteristics of the coal dust including the hydrophilic oxygen-containing functional groups on the surface, the surface roughness, the specific surface area, and the internal pore diameter of coal dust all decreased.(2)As the metamorphic degree of coal was enhanced from lignite to meager-lean coal, the contact angle increased gradually. As the quality of coal was enhanced to anthracite, the contact angle decreased instead of increasing. For all the 5 coal dust samples except anthracite, there was a linear relationship between the content of oxygen-containing functional groups on the surface and the contact angle, and the correlation coefficients of the fitting curve were 0.9394 and 0.8369, respectively. For the coal dust samples with close ash contents, the wettability can be qualitatively and quantitatively evaluated by the areas of the absorption peaks corresponding to oxygen-containing function groups on the surface.(3)The dust-suppression efficiency via spraying was highly correlated with the wettability of coal dust. The dust-suppression efficiency was higher for the coal dust with better wettability. With the increase of water-supply pressure, the effects of coal dust wettability on the dust-suppression efficiency via spraying decreased, and the difference of the dust-suppression efficiency among different coal dust samples also decreased gradually.

Data Availability

The data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare no conflicts of interest.

Acknowledgments

This research was supported by the National Natural Science Foundation of China (No. 51574123) and the Scientific Research Project of Hunan Province Office of Education (No. 18A185).

References

J. Wang, G. Zhou, X. Wei, and S. Wang, “Experimental characterization of multi-nozzle atomization interference for dust reduction between hydraulic supports at a fully mechanized coal mining face,” Environmental Science and Pollution Research, vol. 26, no. 10, pp. 10023–10036, 2019.
View at: Publisher Site | Google Scholar
P. Wang, C. Tian, R. Liu, and J. Wang, “Mathematical model for multivariate nonlinear prediction of SMD of X-type swirl pressure nozzles,” Process Safety and Environmental Protection, vol. 125, pp. 228–237, 2019.
View at: Publisher Site | Google Scholar
Y. Ma, G. Zhou, J. Ding, S. Li, and G. Wang, “Preparation and characterization of an agglomeration-cementing agent for dust suppression in open pit coal mining,” Cellulose, vol. 25, no. 7, pp. 4011–4029, 2018.
View at: Publisher Site | Google Scholar
L. Qiu, D. Song, Z. Li, B. Liu, and J. Liu, “Research on AE and EMR response law of the driving face passing through the fault,” Safety Science, vol. 117, pp. 184–193, 2019.
View at: Publisher Site | Google Scholar
Y. Li, P. Wang, R. Liu, and R. Gao, “Optimization of structural parameters and installation position of the wall-mounted air cylinder in the fully mechanized excavation face based on CFD and orthogonal design,” Process Safety and Environmental Protection, vol. 130, pp. 344–358, 2019.
View at: Publisher Site | Google Scholar
S. Yin, W. Nie, Q. Liu, and Y. Hua, “Transient CFD modelling of space-time evolution of dust pollutants and air-curtain generator position during tunneling,” Journal of Cleaner Production, vol. 239, Article ID 117924, 2019.
View at: Publisher Site | Google Scholar
Y. Li, P. Wang, R. Liu, Y. Jiang, and H. Han, “Determination of the optimal axial-to-radial flow ratio of the wall-mounted swirling ventilation in fully mechanized excavation face,” Powder Technology, vol. 360, pp. 890–910, 2020.
View at: Publisher Site | Google Scholar
J. C. Kumia, A. P. Sasmito, and A. S. Mujumdar, “Dust dispersion and management in underground mining faces,” International Journal of Mining Science and Technology, vol. 24, pp. 39–44, 2014.
View at: Google Scholar
Q. Zhou, B. Qin, F. Wang, H. Wang, J. Hou, and Z. Wang, “Effects of droplet formation patterns on the atomization characteristics of a dust removal spray in a coal cutter,” Powder Technology, vol. 344, pp. 570–580, 2019.
View at: Publisher Site | Google Scholar
P. Wang, Y. Li, R. Liu, and Y. Shi, “Effects of forced-to-exhaust ratio of air volume on dust control of wall-attached swirling ventilation for mechanized excavation face,” Tunnelling and Underground Space Technology, vol. 90, pp. 194–207, 2019.
View at: Publisher Site | Google Scholar
H. Wang, W. Nie, W. Cheng, Q. Liu, and H. Jin, “Effects of air volume ratio parameters on air curtain dust suppression in a rock tunnel’s fully-mechanized working face,” Advanced Powder Technology, vol. 29, no. 2, pp. 230–244, 2018.
View at: Publisher Site | Google Scholar
Q. Liu, W. Nie, Y. Hua, H. Peng, C. Liu, and C. Wei, “Research on tunnel ventilation systems: dust diffusion and pollution behaviour by air curtains based on CFD technology and field measurement,” Building and Environment, vol. 147, pp. 444–460, 2019.
View at: Publisher Site | Google Scholar
National Health Commission of the People’s Republic of China, Health and Wellness Development Statistics Reports for China, National Health Commission of the People’s Republic of China, Beijing, China, 2019, http://www.nhc.gov.cn/guihuaxxs/s10748/201905/9b8d52727cf346049de8acce25ffcbd0.shtml.
W. Zhou, W. Nie, C. Liu et al., “Modelling of ventilation and dust control effects during tunnel construction,” International Journal of Mechanical Sciences, vol. 160, pp. 358–371, 2019.
View at: Publisher Site | Google Scholar
Z. Liu, W. Nie, H. Peng, S. Yang, D. Chen, and Q. Liu, “The effects of the spraying pressure and nozzle orifice diameter on the atomizing rules and dust suppression performances of an external spraying system in a fully-mechanized excavation face,” Powder Technology, vol. 350, pp. 62–80, 2019.
View at: Publisher Site | Google Scholar
P. Wang, Y. Shi, L. Zhang, and Y. Li, “Effect of structural parameters on atomization characteristics and dust reduction performance of internal-mixing air-assisted atomizer nozzle,” Process Safety and Environmental Protection, vol. 128, pp. 316–328, 2019.
View at: Publisher Site | Google Scholar
P. Wang, K. Zhang, and R. Liu, “Influence of air supply pressure on atomization characteristics and dust-suppression efficiency of internal-mixing air-assisted atomizing nozzle,” Powder Technology, vol. 355, pp. 393–407, 2019.
View at: Publisher Site | Google Scholar
C. Xu, W. Nie, Z. Liu, H. Peng, S. Yang, and Q. Liu, “Multi-factor numerical simulation study on spray dust suppression device in coal mining process,” Energy, vol. 182, pp. 544–558, 2019.
View at: Publisher Site | Google Scholar
H. Wang, Y. Du, X. Wei, and X. He, “An experimental comparison of the spray performance of typical water-based dust reduction media,” Powder Technology, vol. 345, pp. 580–588, 2019.
View at: Publisher Site | Google Scholar
H. Wang, X. Wei, Y. Du, and D. Wang, “Experimental investigation on the dilatational interfacial rheology of dust-suppressing foam and its effect on foam performance,” Process Safety and Environmental Protection, vol. 123, pp. 351–357, 2019.
View at: Publisher Site | Google Scholar
S. Yang, W. Nie, S. Lv et al., “Effects of spraying pressure and installation angle of nozzles on atomization characteristics of external spraying system at a fully-mechanized mining face,” Powder Technology, vol. 343, pp. 754–764, 2019.
View at: Publisher Site | Google Scholar
H. Peng, W. Nie, P. Cai, Q. Liu, Z. Liu, and S. Yang, “Development of a novel wind-assisted centralized spraying dedusting device for dust suppression in a fully mechanized mining face,” Environmental Science and Pollution Research, vol. 26, no. 4, pp. 3292–3307, 2019.
View at: Publisher Site | Google Scholar
H. Han, P. Wang, Y. Li, R. Liu, and C. Tian, “Effect of water supply pressure on atomization characteristics and dust-reduction efficiency of internal mixing air atomizing nozzle,” Advanced Powder Technology, vol. 31, no. 1, pp. 252–268, 2020.
View at: Publisher Site | Google Scholar
Z. Xiu, W. Nie, J. Yan et al., “Numerical simulation study on dust pollution characteristics and optimal dust control air flow rates during coal mine production,” Journal of Cleaner Production, vol. 248, Article ID 119197, 2020.
View at: Publisher Site | Google Scholar
W. Nie, W. Wei, P. Cai et al., “Simulation experiments on the controllability of dust diffusion by means of multi-radial vortex airflow,” Advanced Powder Technology, vol. 29, no. 3, pp. 835–847, 2018.
View at: Publisher Site | Google Scholar
Y. Shi, P. Wang, R. Liu, X. Tan, and W. Zhang, “Numerical simulation and engineering application of coalbed water injection,” Mathematical Problems in Engineering, vol. 2019, Article ID 6309160, 12 pages, 2019.
View at: Publisher Site | Google Scholar
P. Cai, W. Nie, D. Chen, S. Yang, and Z. Liu, “Effect of air flowrate on pollutant dispersion pattern of coal dust particles at fully mechanized mining face based on numerical simulation,” Fuel, vol. 239, pp. 623–635, 2019.
View at: Publisher Site | Google Scholar
Z. Xiu, W. Nie, D. Chen et al., “Numerical simulation study on the coupling mechanism of composite-source airflow-dust field in a fully mechanized caving face,” Powder Technology, vol. 356, pp. 443–457, 2019.
View at: Publisher Site | Google Scholar
Q. Liu, W. Nie, Y. Hua et al., “Long-duct forced and short-duct exhaust ventilation system in tunnels: formation and dust control analysis of pressure ventilation air curtain,” Process Safety and Environmental Protection, vol. 132, pp. 367–377, 2019.
View at: Publisher Site | Google Scholar
W. Zhou, H. Wang, D. Wang, K. Zhang, Y. Du, and H. Yang, “The effect of geometries and cutting parameters of conical pick on the characteristics of dust generation: experimental investigation and theoretical exploration,” Fuel Processing Technology, vol. 198, Article ID 106243, 2020.
View at: Publisher Site | Google Scholar
D. Prostański, “Using of air-water spraying systems for improving dust control in mines,” Journal of Sustainable Mining, vol. 12, no. 2, pp. 29–34, 2013.
View at: Publisher Site | Google Scholar
H. Zhang, W. Nie, Y. Liu, H. Wang, H. Jin, and Q. Bao, “Synthesis and performance measurement of environment-friendly solidified dust suppressant for open pit coalmine,” Journal of Applied Polymer Science, vol. 135, no. 29, p. 46505, 2018.
View at: Publisher Site | Google Scholar
Q. Zhou, B. Qin, F. Wang, and H. Wang, “Experimental investigation on the performance of a novel magnetized apparatus used to improve the dust wetting features of surfactant-magnetized water,” Powder Technology, vol. 354, pp. 149–157, 2019.
View at: Publisher Site | Google Scholar
Q. Bao, W. Nie, C. Liu et al., “The preparation of a novel hydrogel based on crosslinked polymers for suppressing coal dusts,” Journal of Cleaner Production, vol. 249, Article ID 119343, 2020.
View at: Publisher Site | Google Scholar
H. Wang, W. Xuan, Z. Zhang, and B. Qin, “Experimental investigation of the properties of dust suppressants after magnetic-field treatment and mechanism exploration,” Powder Technology, vol. 342, pp. 149–155, 2019.
View at: Publisher Site | Google Scholar
Y. Chen, G. Xu, J. Huang, J. Eksteen, X. Liu, and Z. Zhao, “Characterization of coal particles wettability in surfactant solution by using four laboratory static tests,” Colloids and Surfaces A: Physicochemical and Engineering Aspects, vol. 567, pp. 304–312, 2019.
View at: Publisher Site | Google Scholar
G. Xu, Y. Chen, J. Eksteen, and J. Xu, “Surfactant-aided coal dust suppression: a review of evaluation methods and influencing factors,” Science of the Total Environment, vol. 639, pp. 1060–1076, 2018.
View at: Publisher Site | Google Scholar
P. Wang, X. Tan, L. Zhang, Y. Li, and R. Liu, “Influence of particle diameter on the wettability of coal dust and the dust suppression efficiency via spraying,” Process Safety and Environmental Protection, vol. 132, pp. 189–199, 2019.
View at: Publisher Site | Google Scholar
H. Peng, W. Nie, H. Yu et al., “Research on mine dust suppression by spraying: development of an air-assisted PM10 control device based on CFD technology,” Advanced Powder Technology, vol. 30, no. 11, pp. 2588–2599, 2019.
View at: Publisher Site | Google Scholar
P. Dong, Z. J. Shan, and Z. Li, “Study on the surface wet characteristic of ultrafine coal powder,” Journal of China Coal Society, vol. 29, pp. 346–349, 2004.
View at: Google Scholar
J. H. Wen, J. Xue, and L. Zhang, “Analysis on relationship between wettability and ash of long flame coal based on X-ray diffraction experiment,” Coal Science and Technology, vol. 43, pp. 83–86, 2015.
View at: Google Scholar
W. M. Cheng, J. Xue, G. Zhou, W. Nie, and L. S. Liu, “Study of coal dust wettability based on FTIR,” Journal of China Coal Society, vol. 39, pp. 2256–2262, 2014.
View at: Google Scholar
Z. B. Zhao, Y. Chen, C. Y. Sun, and X. Q. Shu, “Experimental study of coal dust wettability,” Journal of China Coal Society, vol. 36, pp. 442–446, 2011.
View at: Google Scholar
G. Zhou, J. Xue, W. M. Cheng, W. Nie, and H. Wang, “Effect of stacking structure on the wettability of coal dust based on X-ray diffraction experiment,” Chinese Journal of Engineering, vol. 37, pp. 1535–1541, 2015.
View at: Google Scholar
G. Zhou, W. M. Cheng, C. C. Xu, and W. Nie, “Characteristic analysis of 13C-NMR for the wettability difference of coal dust with diverse degrees of metamorphism,” Journal of China Coal Society, vol. 40, pp. 2849–2855, 2015.
View at: Google Scholar
G. H. Luo, B. Li, and Y. Y. Ding, “Study on influence of coal dust wettability by chemical composition and structure parameters,” Journal of Dalian Jiaotong University, vol. 37, pp. 64–67, 2016.
View at: Google Scholar
W. M. Huang, E. X. Tang, and Z. X. Qian, “Study on relationship between coal dust composition and water wettability,” Coal Technology, vol. 36, pp. 159–161, 2017.
View at: Google Scholar
H. Wang, L. Zhang, D. Wang, and X. He, “Experimental investigation on the wettability of respirable coal dust based on infrared spectroscopy and contact angle analysis,” Advanced Powder Technology, vol. 28, no. 12, pp. 3130–3139, 2017.
View at: Publisher Site | Google Scholar
J. Yang, X. K. Wu, G. P. Li, and Y. Z. Tan, “Study on the fractal characteristics for particle sizes of coal dusts,” Journal of Shandong University of Science and Technology (Natural Science), vol. 29, pp. 31–36, 2010.
View at: Google Scholar
J. Yang, H. Xu, and J. G. Gao, “Influence of particle size on surface characteristic and wetting mechanism of coal dust,” Journal of Coal Mine Safety, vol. 45, pp. 140–143, 2014.
View at: Google Scholar
Q. Zhou, B. T. Qin, J. Wang, H. T. Wang, and F. Wang, “Experimental investigation on the changes of the wettability and surface characteristics of coal dust with different fractal dimensions,” Colloids and Surfaces A: Physicochemical and Engineering Aspects, vol. 551, pp. 148–157, 2018.
View at: Publisher Site | Google Scholar
L. C. Wen and Q. Z. Liu, “Experimental research on effect of particle size on wettability of mine dust surface,” China Powder Science and Technology, vol. 21, pp. 99–103, 2015.
View at: Google Scholar
U. Ulusoy and M. Yekeler, “Variation of critical surface tension for wetting of minerals with roughness determined by surtronic 3⁺ instrument,” International Journal of Mineral Processing, vol. 74, no. 1–4, pp. 61–69, 2004.
View at: Publisher Site | Google Scholar
U. Ulusoy, M. Yekeler, and C. Hiçyılmaz, “Determination of the shape, morphological and wettability properties of quartz and their correlations,” Minerals Engineering, vol. 16, no. 10, pp. 951–964, 2003.
View at: Publisher Site | Google Scholar
P. T. L. Koh, F. P. Hao, L. K. Smith, T. T. Chau, and W. J. Bruckard, “The effect of particle shape and hydrophobicity in flotation,” International Journal of Mineral Processing, vol. 93, no. 2, pp. 128–134, 2009.
View at: Publisher Site | Google Scholar
W. Xia, C. Ni, and G. Xie, “The influence of surface roughness on wettability of natural/gold-coated ultra-low ash coal particles,” Powder Technology, vol. 288, pp. 286–290, 2016.
View at: Publisher Site | Google Scholar
R. N. Wenzel, “Surface roughness and contact angle,” The Journal of Physical and Colloid Chemistry, vol. 53, no. 9, pp. 1466-1467, 1949.
View at: Publisher Site | Google Scholar
A. B. D. Cassie, “Contact angles,” Discussions of the Faraday Society, vol. 3, pp. 11–14, 1948.
View at: Publisher Site | Google Scholar
J. Yang, Y. Z. Tan, Z. H. Zhang, Y. D. Shang, and W. B. Zhao, “Study on the coal dust surface characteristics and wetting mechanism,” Journal of China Coal Society, vol. 32, pp. 737–740, 2007.
View at: Google Scholar
X. D. Zhu, Z. B. Zhu, and C. J. Han, “Quantitative determination of oxygen-containing functional groups in coal by FTIR spectroscopy,” Journal of Fuel Chemistry and Technology, vol. 27, pp. 335–339, 1999.
View at: Google Scholar
P. F. Wang, R. H. Liu, M. Tang, W. Zhang, and Z. Gui, “Experimental study on atomization characteristics and dust suppression efficiency of high-pressure spray in underground coal mine,” Journal of China Coal Society, vol. 40, pp. 2124–2130, 2015.
View at: Google Scholar
P. Wang, X. Tan, W. Cheng, G. Guo, and R. Liu, “Theoretical calculation and analysis of dust suppression efficiency of high-pressure spray in underground coal mine dust removal efficiency of high pressure atomization in underground coal mine,” International Journal of Mining Science and Technology, vol. 28, no. 4, pp. 685–690, 2018.
View at: Publisher Site | Google Scholar
W. M. Cheng, G. Zhou, Q. M. Zuo, W. Nie, and G. Wang, “Experimental research on the relationship between nozzle spray pressure and atomization particle size,” Journal of China Coal Society, vol. 35, pp. 1308–1313, 2010.
View at: Google Scholar
S. P. Ma and Z. M. Kou, “Study of efficiency of dust suppression by mist spray and its matched parameters,” China Safety Science Journal, vol. 16, pp. 84–89, 2006.
View at: Google Scholar
F. Han, J. Zhang, Y. Zhao, and J. Han, “Experimental investigation on the interaction process between coal particles and foam,” AIP Advances, vol. 9, no. 1, Article ID 015023, 2019.
View at: Publisher Site | Google Scholar
B. M. Raj, R. K. Jain, and B. C. Meikap, “Comprehensive analysis for prediction of dust removal efficiency using twin-fluid atomization in a spray scrubber,” Separation and Purification Technology, vol. 63, pp. 269–277, 2008.
View at: Google Scholar
H. Yu, W. Cheng, H. Peng, and Y. Xie, “An investigation of the nozzle’s atomization dust suppression rules in a fully-mechanized excavation face based on the airflow-droplet-dust three-phase coupling model,” Advanced Powder Technology, vol. 29, no. 4, pp. 941–956, 2018.
View at: Publisher Site | Google Scholar

Copyright

Copyright © 2020 Pengfei Wang et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

PDF Download Citation

Download other formats

Order printed copies

Views

846

Downloads

985

Citations