Elimination of Coal and Gas Outburst Dynamic Disasters in Dengfeng Coalfield through Gas Extraction Based on Extremely Thin Protective Coal Seam Mining

No. 21 coal seam is a full-thickness structured soft coal in Dengfeng coalfield. )e coal seam gas-bearing capacity is high, and the permeability is poor, thus resulting in serious coal and gas outburst dynamic disasters. According to the gas geological conditions of BaoyushanMine, No. 17 coal seamwithout outburst danger, which is 0.5m thick and 23.4m under No. 21 coal seam, was mined in advance as the lower protective seam. At the same time, a gas extraction roadway was constructed in No. 21 coal seam floor. Cross-layer boreholes were constructed to extract the pressure relief gas of No. 21 coal seam for comprehensive treatment of mine gas. )e mobile deformation of the overburden coal and rock mass after mining No. 17 coal seam, the fracture development characteristics of No. 21 coal seam, the pressure relief gas migration of the coal seam, the gas extraction, and the outburst danger elimination were studied. )e research findings showed the following: (1) after mining No. 17 coal seam, the overburden hard and extremely thick limestone roof sagged slowly, albeit leading to no craving zone. (2) )e permeability of No. 21 coal seam was increased by about 394 times, from 0.0012 mD to 0.4732 mD. (3) After the extraction of pressure relief gas through the gas extraction roadway on the floor through the cross-layer borehole, the gas pressure of No. 21 coal seam decreased from 1.17MPa to 0.12MPa, while the gas content decreased from 9.74m/t to 3.1m/t, which suggested that the coal and gas outburst dynamic danger of No. 21 coal seam was totally eliminated and the goal of safe and efficient mining in the mine was realized.


Introduction
Coal is the major energy of China, which accounts for more than 60% of the primary energy [1,2]. With the rapid development of Chinese economy, the coal demand also increased dramatically. From 2001 to 2020, China's coal output soared from 1.106 billion tons to 3.7 billion tons. Limited by the conditions of coal resources, 90% of coal resources are obtained through underground mining. e mining depth of coal increases at an annual rate of 10∼30 m. Currently, the average mining depth of the coal resources in China has exceeded 600 m, with the deepest one exceeding 1,500 m. With the intensification of coal mining, the mining depth keeps on increasing, resulting in growing ground stress on the working seam, increasing coal seam gas pressure and gas emission amount, and increasing complexity and danger of gas disasters [3]. Many low gas mines have been turned into high gas ones, and the high gas ones have been turned into coal and gas outburst ones. In China, the coal mines had a tendency to increase gas grade and increase the number of outburst mines. In particular, the mines in central China are characterized by in-depth mining, high coal seam gas content, high gas pressure, complex geographical conditions, and soft and crushed coal seam structure, so the coal mines are faced with serious gas disasters [4][5][6][7].
Located in about 60 km southwest of Zhengzhou, Henan Province, Dengfeng coalfield is about 70 km long and 8∼15 km wide and covers an area of about 1,000 km 2 . e coalfield stratum can be divided into Permian System Shanxi Group and Taiyuan Group. No. 2 1 coal seam under the bottom of Shanxi Group is stable. It is the major minable coal seam of the coalfield. No. 2 1 coal seam features a thickness of about 0∼26.73 m and an average thickness of 4.57 m. us, it is a medium-thickness coal seam. e coal rank is the meager coal. Affected by the extrusion, rubbing, and other tectonic movements, No. 2 1 coal seam is characterized by full-thickness constructed soft coal. Most coals are of types III∼V. e coal strength and permeability are extremely low, the coal seam gas content is high, and the coal seam gas extraction effect is poor. us, the gas disasters are extremely serious. For a long time, the gas disasters of No. 2 1 coal seam in Dengfeng coalfield, especially the coal and gas outburst disasters, have greatly limited the development of the local coal mine enterprises and seriously threatened the safety of miners. In order to ensure the mining safety of No. 2 1 coal seam in the deep area of the mine, the regional outburst prevention measures should be adopted to eliminate the coal and gas outburst dynamic disasters of No. 2 1 coal seam.
Many mines in China have achieved remarkable results by adopting the measure of protective coal seam mining to prevent and control coal and gas outburst dynamic disasters [8][9][10][11]. Concerning the gas geological conditions of No. 2 1 coal seam of Dengfeng coalfield, the adoption of protective seam mining combined with stress-relief gas extraction technique is the most effective, simplest, and most economic measure to prevent the coal and gas outburst disasters [12][13][14][15][16].
e technique can eliminate the coal and gas outburst dynamic disasters and finally realize the goal of safe and efficient mining. However, mines adopting the measure must be equipped with the condition of coal seam group occurrence. In other words, within the effective protection vertical interval, there should be a coal seam free of outburst danger whose thickness is no smaller than 0.5 m acting as the protective seam. According to the geological data of Dengfeng coalfield, the gas content of No. 1 7 coal seam, which is 23.4 m below No. 2 1 coal seam and whose thickness averages 0.5 m, is extremely low, so it is the coal seam free of outburst danger and can be first mined as the lower protective seam. At the same time, the adoption of the gas extraction roadway during the construction in the chassis of No. 2 1 coal seam and the extraction of the pressure relief gas of No. 2 1 coal seam in the cross-layer boreholes can eliminate the coal and gas outburst dynamic disasters. However, there is a layer of 7.3 m thick hard limestone between No. 1 7 coal seam and No. 2 1 coal seam, which is unfavorable to the pressure relief and permeability increase effect of No. 2 1 coal seam.
erefore, under the condition, it is necessary to conduct an experiment and field study to see whether the technique of mining extremely thin No. 1 7 coal seam combined with the pressure relief gas extraction technique can eliminate the coal and gas outburst dynamic dangers of No. 2 1 coal seam. e Baoyushan Mine in Dengfeng coalfield was adopted as the research object. rough the experiment and field test, the gas parameters of No. 2 1 coal seam were obtained, and the outburst danger was analyzed. rough studying the overburden coal-rock mass displacement and distortion, the mining fracture development characteristics of No. 2 1 coal seam, and the coal seam pressure relief gas migration and convergence rules, the authors hope that the research findings can guide Baoyushan Mine to conduct site protective seam mining. e research of the extremely thin protective seam mining combined with the pressure relief gas extraction under the hard and extremely thick limestone condition is the first of its kind. e research findings are of vital significance to the prevention and control of coal and gas outburst dynamic disasters during the in-depth mining of No. 2 1 coal seam in Dengfeng coalfield.
e mine is about 5∼11 km long and 1.1∼3.0 km wide and covers an area of 21.2186 km 2 . It is a coal and gas outburst mine with a design production capacity of 600,000 ton per annum. No. 2 1 coal seam is the major mining area of the mine. e mine adopts the inclined shaft and the vertical shaft mixed exploitation method, the full-seam mining method, and the fully caving roof management. ere are two major minable coal seams, namely, No. 2 1 coal seam and No. 1 7 coal seam.
e composite histogram of the mine is shown in Figure 2. No. 2 1 coal seam is about 0∼18.98 m thick, which is averaged at 3.1 m. e coal bed pitch is 30°. e gas content of No. 2 1 coal seam is high. e gas content is above 8 m 3 /t. e mine mainly treats the gas outbursts through the drainage borehole, bleeder off hole, and increase of the wind amount for the mining working face. However, due to high gas content of No. 2 1 coal seam, the coal seam is soft and has poor permeability. As a result, the gas extraction effect is poor. During the mining process, the gas density in the ventilation roadway often exceeds the limit, which seriously threatens the safe production of the mine. Even if the wind amount for the working face is increased to above 1,000 m 3 / min, the problem still remains unresolved. During the blasting process, the gas exceeds the limit more seriously. At the same time, due to the large wind amount for the working face, the working face is filled with the coal dust, thus worsening the working environment of miners. It is apt to say that gas disasters directly restrain the safe and efficient production of the mine.
In order to solve the difficulties facing the prevention and control of gas disaster, based on Detailed Rules of Coal and Gas Outburst Prevention and Control and the conditions of the coal seam, the authors decided to adopt the protective seam mining combined with pressure relief gas extraction technique. No. 1 7 coal seam of the mine was adopted as the lower protective seam for prior mining. At the same time, the gas extraction roadway was placed in the proper position of the chassis of No. 2 1 coal seam. e pressure relief gas was extracted from No. 2 1 coal seam through the boreholes. e thickness of No. 1 7 coal seam in Baoyushan Mine is about 0.12∼1.1 m, which averages 0.5 m. It belongs to the extremely thin coal seam and the coal seam gas content is low, which is about 0.5～1.5 m 3 /t, so No. 1 7 coal seam has no outburst danger. No. 1 7 coal seam is mined using spiral drilling machine and adopts the gradual sagging method to manage the roof [17]. e average mining height of No. 1 7 coal seam is 0.5 m. e coal absorption performance experiment was based on the coal's gas absorption theory. Generally speaking, the absorption constants, a and b, are the two indexes evaluating the coal's gas absorption performance. e measurement of coal's gas absorption constants was conducted in the lab according to the national standard, Measurement Method of Coal's Gas Absorption Amount. First, the sample of No. 2 1 coal seam was obtained from Baoyushan Mine. Using the HCA high-pressure volume method, the gas absorption experiment devices, and 5E-MAG6600 full-automatic industrial analyzer, the gas absorption constants, moisture, ash content, and volatile components of No. 2 1 coal seam were measured, respectively. e experiment devices are shown in Figure 3. e actually measured value of a, an absorption constant of No. 2 1 coal seam, was 28.834 m 3 /t; the actually measured value of b, the other absorption constant, was 0.835 MPa −1 ; the moisture of No. 2 1 coal seam was 1.12%; the ash content was 8.98%; and the volatile components were 13.03%. e coal's porosity refers to the ratio of the bulk volume of the hole to the bulk volume of the coal. is index decides the absorbability, permeability, and strength of coal and the gas migration characteristics within the coal. e porosity of No. 2 1 coal was calculated through the actually measured true and false proportion of No. 2 1 coal sample. e result showed that the porosity of No. 2 1 coal was 2.82%.

Coal Structure, Gas Diffusion Initial Velocity, and
Firmness Coefficient. Detailed Rules of Coal and Gas Outburst Prevention and Control clearly divides the coal destruction types into five. I and II are the nontectonic coal without outburst dangers. III, IV, and V coal are the tectonic coal; they are basically corresponding to the tectonically crashed coal, the fractionalized coal, and the mylonitic coal. e site observation of No. 2 1 coal seam in Baoyushan Mine shows that No. 2 1 coal seam has the following characteristics: the coal mass is mainly powdery and seldom granulous or flaky. It lacks luster and has no bedding. Its strength is low and can be twiddled into powder by hand. e protogenesis structure of the coal has been seriously damaged. e lump coal formed through press of the pulverized coal is mixed in the coal mass now and then. e strength is low, and it can be fragmented by the press of a finger. It belongs to the fullthickness tectonic coal, and the destruction type of its coal mass belongs to IV-V coal. e WT-1 gas diffusion rate tester and the coal firmness coefficient tester were employed to test the gas diffusion initial velocity and the coal firmness coefficient of No. 2 1 coal seam. e experiment devices are shown in Figure 3. e actually measured gas initial velocity of No. 2 1 coal seam in Baoyushan Mine was 12∼27 mmHg, and the firmness coefficient of the coal mass was 0.1∼0.18.

Gas Pressure and Gas Content of No. 2 1 Coal Seam.
Seam gas pressure refers to the acting force generated by the free thermal motion of the gas molecules within the hole of the coal seam, namely, the gas pressure exerted on the hole wall. e gas pressure of the coal seam is an important index to evaluate the outburst danger and the gas content of the coal seam [18]. At the same time, the gas pressure is also the basic parameter which decides the gas migration power and the potential of gas power. It plays a guiding role in the research and evaluation of gas emission, gas migration, gas extraction, and gas outburst [13,[19][20][21][22].

Advances in Civil Engineering
According to the requirements of direct measurement methods of the gas pressure of the coal seam under the coal mine, slip casting and hole sealing pressure measurement method was adopted to test the gas pressure of No. 2 1 coal seam in Baoyushan Mine. e piezometer tube with the holder was installed to the predetermined pressure depth under the mine. e porthole was sealed with the chuck and the quick-drying cement. e slip casting tube was installed. e use amount of the puff and nonshrink cement was determined by the depth of hole sealing. e hole sealing cement paste was prepared according to certain proportion (water-cement ratio was 2 : 1; the mixing amount of the swelling agent was 12% of the cement). e hole sealing cement paste was continuously injected into the borehole at once with the injection pump. After the slip casting lasted for 24 h, the triple-channel devices and the piezometer were installed in the porthole. Based on the natural permeation principle of gas in No. 2 1 coal seam, the gas pressure to achieve the balance in the borehole disclosed area was tested (see Figure 4). e site's actually tested gas pressure of No. 2 1 coal seam in Baoyushan Mine was 1.17 MPa. e coal seam gas content refers to the gas content in the unit mass or volume of the original coal mass. According to the requirements of direct measurement methods of the gas pressure of the coal seam under the coal mine, a hole was drilled in Baoyushan Mine. rough hole drilling, No. 2 1 sample coal was fetched from the in-depth coal seam and was sealed in the bottle immediately. e field test of the gas desorption amount lasted for two hours. According to the gas desorption rule of the coal sample, the gas loss amount before the gas was sealed in the coal sample bottle was deducted. en, the coal sample bottle was taken to the lab to conduct the remaining gas content test. e test devices are shown in Figure 5. e coal seam gas content is the sum of the gas loss amount, gas desorption amount, and remaining gas amount. e actually measured gas content of No. 2 1 coal seam of Baoyushan Mine was 9.74 m 3 /t.

Coal and Gas Outburst Disasters of No. 2 1 Coal Seam of the Adjacent Coal Mines.
e coal mines which focus on mining the shallow part of No.   According to the investigation, the gas dynamic phenomenon of the adjacent mines is shown as follows: Pochi Mine, Poxin Mine, Lugou No. 8 Mine, and Lugou Mine are the coal mines which mined the shallow part of No. 2 1 coal seam. During the mining period, the coal seam gas emission is low. In recent years, the gas grade has been identified as the low level. No coal and gas outburst dynamic phenomena have ever happened.
Shangzhuang Mine is located in the shallow part of Changhong Mine. In February 1977, there was a gas explosion accident. Two persons died and 17 were burned. In August 1981, gas combustion occurred, leading to the death of one person. It has ceased production.
Baoyushan No. 2 Mine is located in the shallow part of Changhong Mine and in the west of Shangzhuang Mine. On September 5, 2000, in +250 m horizontal transportation avenue, an extremely serious coal and gas outburst happened, leading to the death of 14 persons and the injury of 8 persons. On November 21, 2001, a gas stifling accident caused the death of two. Now, it has ceased production.
Hezhuang Mine and Baoyushan Mine are not connected with each other but are close to each other. e gas dynamic phenomena happened here several times. In 2007, it was identified as coal and gas outburst mine. On April 8, 2009, in the 11030 Transportation Avenue, a medium-size coal and gas outburst happened. e outburst coal and rock amount was 215 t and that of the gas amount was 10,089 m 3 .
Changhong Mine is connected with the west part of Baoyushan Mine. On October 16, 2004, during the tunneling process of the roadway on No. 2 1 coal seam, a coal and gas outburst happened. e sound of coal blasting lasted for a long time, and the gas emission was abnormal. e gas concentration rose to 1.69% within a short time. e outburst coal amount reached about 13 t, and the outburst gas was about 500 m 3 . e actually measured gas content near the outburst point when the outburst happened was 5.34 m 3 / t. In 2008, it was identified as the coal and gas outburst coal mine. On March 21, 2014, during the tunneling face of the roadway in Changhong Mine, a serious coal and gas outburst happened, leading to the death of 13 persons.

Gas Outburst Parameters and Outburst Danger Evaluation of No. 2 1 Coal Seam.
e actually measured gas outburst parameters of No. 2 1 coal seam in Baoyushan Mine are shown in Table 1.
From Table 1, the following can be seen: (1) the gas pressure and gas content of No. 2 1 coal seam in Baoyushan Mine were high. Gas pressure was 1.17 MPa, which was higher than the critical value, 0.74 MPa, specified in Detailed Rules of Coal and Gas Outburst Prevention and Control. Gas content was 9.74 m 3 /t, which was higher than the critical value of 8 m 3 /t specified in Detailed Rules of Coal and Gas Outburst Prevention and Control and was far higher than that of No. 2 1 coal seam in the outburst point of Changhong Mine, which was 5.34 m 3 /t. (2) e initial velocity of gas emission of No. 2 1 coal seam was 12∼27 mmHg, which was higher than the critical value of 10 mmHg. (3) e coal mass structure of No. 2 1 coal seam features the pulverized coal, which was a full-thickness tectonic soft coal. e protogenesis structure of the coal seam suffered serious damage, and the strength is extremely low. e firmness coefficient of No. 2 1 coal seam was 0.1∼0.18, and the destruction type is V. e original permeability of No. 2 1 coal seam was 0.0012 mD, so the seam permeability is extremely poor. e gas outburst parameters of No. 2 1 coal seam in Baoyushan Mine are far higher than the outburst critical indexes specified in Detailed Rules of Coal and Gas Outburst Prevention and Control, so the outburst danger is high. No. 2 1 coal seam of the adjacent coal mines underwent several coal and gas outbursts. To sum up, No. 2 1 coal seam of Baoyushan Mine is a low permeability high gas outburst coal seam.

Feasibility Analysis and Outburst Elimination Principle of the Extremely Thin Protective Seam Mining Combined with the Pressure Relief Gas Extraction Technique
Since No. 2 1 coal seam is characterized by strong outburst danger, we decided to adopt the protective seam mining combined with the pressure relief gas extraction technique to eliminate the coal seam outburst danger. According to the protective coal seam mining theory, the feasibility analysis of No. 1 7 coal seam acting as the lower protective seam was first conducted. According to the requirements of Detailed Rules of Coal and Gas Outburst Prevention and Control, during the lower protective seam mining, the minimum interlayer spacing not ruining the upper protective seam could be defined through the following formula: α <60°in the formula H � KM cos α, where H stands for the minimum interlayer spacing of the minable protective seam, M stands for the mining thickness of the protective seam and is set to be 0.5 m, α stands for the coal bed pitch and is set to be 30°, and K stands for the roof management  e maximum protection vertical distance for the lower protective layer mining, S, was calculated according to the requirement of Detailed Rules of Coal and Gas Outburst Prevention and Control: S � S lower β 1 β 2 . In the formula, S lower stands for the maximum protection vertical distance of the protective seam, m. It is related to the working face length, L, and the mining depth, H. According to Detailed Rules of Coal and Gas Outburst Prevention and Control about S lower , the following can be found: (1)

Protective Seam Mining Principle of Prevention of Coal and Gas
Outburst. After mining the protective seam, a free space will be formed in the rock mass, destroying the balance of the primary rock stress, redistributing the ground stress, moving the rock mass to the goaf, and resulting in phenomena including roof caving and sagging, chassis heaving, and so on [23][24][25]. e coal seam and the rock mass will undergo pressure relief and dilatation and lead to fractures of different sizes. e increase of the permeability coefficient will result in the increase of the gas flow. e gas emission will cause the decrease of the coal seam gas content, pressure, and potential. e gas emission enhances the coal mass strength. In other words, the antioutburst performance of the coal is intensified. us, it can be seen that the cause and basis of the serious of changes are the deformation and movement of the rock (coal) seam. e larger the deformation and movement are, the more adequate the pressure relief is and the better the protection effect is. e closer to the mining seam, the better the protective effect is; otherwise, the poorer it is. e protection effect is mainly decided by the mining geological and technical conditions.
To sum up, after mining the protective seam, the change order of the stress, deformation, gas, and the other parameters of the seam to be protected is shown as follows: first, the rock seam undergoes movement and deformation.
e seam to be protected shows the pressure relief phenomenon. e ground stress of the coal seam decreases. e coal seam is inflated and deformed. e permeability of the coal seam is increased. With the gas desorption in the coal seam, the gas changes from the absorption state to the unbound state. With the increase of the borehole gas flow, the gas extraction amount increases, the coal seam gas pressure decreases, the coal seam gas content is reduced, and the mechanical strength of the coal seam is increased. All the above parametric changes suggest that the protection effect of the protective seam is the comprehensive function of pressure relief, permeability increase, and gas emission [26,27]. e pressure relief and permeability increase after the start of the protective seam mining plays the most important and decisive role in parametric changes. As long as the seam to be protected plays the role of pressure relief and permeability increase, the major parameters, including coal mass structure, gas pressure, gas content, and coal seam permeability, follow the above order. All these parametric changes will decrease or eliminate the coal seam outburst danger.

e Function of the Pressure Relief Gas Extraction. Detailed Rules of Coal and Gas Outburst Prevention and
Control specifies that, "during the protective seam mining, the pressure relief gas of the seam to be protected shall be extracted as well." e thickness of the protective seam in Baoyushan Mine is 0.5 m, and there is a hard 7.3 m thick limestone between seams, which would definitely cause unfavorable influence to the pressure relief and permeability increase effect of the overburden No. 2 1 coal seam. In order to accelerate and expand the pressure relief and permeability increase function of the protective seam mining, the protective seam mining must extract the pressure relief gas of No. 2 1 coal seam. Such extraction might further decrease the ground stress, increase the coal strength, and reach the goal of comprehensive prevention and control of outbursts.

Movement and Deformation of the Overburden Coal Mass, Mining Fracture Development Characteristics of No. 2 1 Coal Seam, Pressure Relief Gas Migration Rule, and Gas Extraction Methods
Since the mining thickness of No. 1 7 coal seam is 0.5 m, the average interlayer spacing between No. 1 7 coal seam and No. 2 1 coal seam is 23.4 m, and there is a hard 7.3 m thick limestone in between, it is necessary to analyze and study the pressure relief and permeability increase effect of the overburden No. 2 1 coal seam after mining No. 1 7 coal seam, the movement and deformation of the overburden coal mass, the mining fracture development characteristics of No. 2 1 coal seam, and the pressure relief gas migration rules. Based on the research findings, the corresponding gas extraction methods can be adopted.

Movement and Deformation of the Overburden Coal Mass, Fracture Development of No. 2 1 Coal Seam, and Pressure Relief Gas Migration.
rough the theoretical analysis and the field experiment, it was found that, during the mining process of No. 1 7 coal seam, the whole overburden coal mass    1 coal seam, and the deformation, movement, and fractures of the coal seam. As a result, the balance of the gas absorption and desorption will be destroyed, a lot of gas is turned from the absorption state to the free state, and the desorption gas of the coal mass expands to the fracture, leading to the dramatic increase of the gas concentration in the fractures.
us, under the mining effect of No. 1 7 coal seam, the migration conditions of the pressure relief gas, namely, "desorption⟶diffusion⟶transfusion," are formed.
Due to the dominant fracture distribution of bedding fracture in No. 2 1 coal seam, the pressure relief gas has good bedding migration conditions. erefore, the pressure relief gas in the protected seam only flows in the bedding fracture.
In order to effectively and evenly extract the gas in the protected seam during the migration active period of the pressure relief gas, it is necessary to create the conditions to enable the bedding migration and convergence of the pressure relief gas. rough the special extraction roadway of No. 2 1 coal seam, the borehole was made for the extraction of the pressure relief gas. It can be seen that the gas is turned from the absorption state to the free state.
rough the bedding separation fracture flow and the convergence in the borehole, and affected by the extraction negative pressure, a lot of pressure relief gas of No. 2 1 coal seam is extracted.
It should be noticed that when No. 1 7 coal seam is mined for a period of time, the overburden coal mass movement and deformation are gradually stabilized. e pressure relief effect exerted on No. 2 1 coal seam gradually disappears, the permeability of the coal seam is reduced correspondingly, and the desorbed gas will be reabsorbed by the coal mass.
us, it is necessary to extract the gas within the valid pressure relief period of No. 2 1 coal seam and realize the goal of reducing the coal seam gas content and eliminating the coal seam outburst danger.
What is interesting in this study is that the overburden hard and extremely thick limestone roof sagged slowly but led to no craving zone. Now, let us focus on explaining this phenomenon. As the working face of No. 1 7 coal seam is mined forward, the working face is directly overhanging. Because the immediate roof of No. 1 7 coal seam is L 7 hard and extra-thick limestone roof, which is stable and not easy to collapse, there is no obvious movement and deformation of the overlying coal-rock mass in the early mining stage. As a large amount of coal is mined in the working face of No. 1 7 coal seam, the hard and extra-thick limestone roof of L 7 begins to bend and sink slowly under the action of gravity of the overlying coal and rock mass. It can be seen that the overlying coal and rock mass produce the overall slow bending subsidence deformation, without falling zone and obvious fault zone, and No. 2 1 coal seam is in the bending subsidence zone.
ere are separation cracks at the boundary of soft and hard strata of the overlying coal-rock mass, but there are few vertical fracture cracks. It can be seen from the field measurement that the gas pressure of No. 2 1 coal seam drops gradually and slowly without sudden drop, which can also indicate that the roof is slowly sinking without caving phenomenon. e reason for these phenomena is that the mining height of No. 1 7 coal seam is only 0.5 m, and the roof of No. 1 7 coal seam is very hard and extra-thick limestone roof. It is found that there are many bedding tensile fractures on the surface of No. 2 1 coal seam, some of which have gone deep into the interior of the coal seam, while the number of vertical fracture fractures is few and not obvious. As the overlying strata are gradually compacted, the width and number of separation cracks between strata are reduced. A careful observation of No. 2 1 coal seam shows that the coal seam is also gradually compacted and the width and number of bedding tensile cracks in the coal seam are obviously reduced.

Extraction Methods of the Pressure Relief Gas in No. 2 1 Coal Seam.
Concerning the actual mining geological conditions of Baoyushan Mine and in order to accelerate and expand the pressure relief and permeability increase function of No. 1 7 coal seam, mining No. 1 7 coal seam should extract the pressure relief gas of No. 2 1 coal seam as well. During the mining process of No. 1 7 coal seam, the pressure relief gas of the overburden No. 2 1 coal seam has sound bedding migration conditions. e chassis grid drilling method can be adopted to extract the gas in the drill hole. To put it specifically, the method is to tunnel a special roadway for the gas extraction in the chassis rock seam; in the roadway, a drill site is dug at the interval of certain distance. Within the drill site, an upward drill hole is made in No. 2 1 coal seam. e drill holes are evenly distributed in the coal seam in the form of grid. Relying on the pressure relief and permeability increase effect, the gas in No. 2 1 coal seam is evenly and effectively extracted.

e Selection of the Special Gas Extraction Roadway.
Concerning the practical geological conditions of Baoyushan Mine, No. 1 7 coal seam roof is a layer of 7.3 m thick L 7 limestone. e upper part is a 2.6 m thick sandy mudstone, 11 m thick silty-fine sand, 2.5 m thick sandy mudstone, and 3.1 m thick No. 2 1 coal seam. erefore, the gas extraction roadway in the chassis should be conducted along the L 7 limestone roof. e distance from the extraction roadway to No. 2 1 coal seam is maintained above 10 m, and the roadway construction fracture surface is above 6 m 2 .

e Layout of the Cross-Layer Borehole for the Gas Extraction Roadway.
A 5 m long extraction drill site perpendicular to the extraction roadway is set up every 20 m. In the drill site, the borehole is made and the gas is extracted. Every drill site sets up a group of fan-shaped gas extraction boreholes. e borehole features a diameter of 91 mm. Every drill site sets up seven cross-layer boreholes. e borehole space within the fully pressure relief area is 20 m and in the inadequate pressure relief area is 10 m. e borehole spacing adopts the coal seam medium thickness as the standard. e two zones of the extraction roadways tunnel the connection roadway on the interior section and the end section. e fully negative pressure ventilation is formed. e gas extraction of the upward borehole on the grid is shown in Figure 8. All the extraction boreholes must finish their construction before mining No. 1 7 coal seam. After the hole sealing, the gas extraction pipeline is switched on. After mining No. 1 7 coal seam, the coal mass of No. 2 1 coal seam undergoes dilatation, deformation, and pressure relief. e gas is thus activated. Under the join effect of the mine negative pressure and the coal seam gas pressure, the pressure relief gas is extracted. With the decrease of the coal seam gas content, the outburst danger of No. 2 1 coal seam is eliminated.

Gas Extraction Devices.
Two sets of 2BEC-40 gas extraction pumps are set up on the ground, whose exhaust capacity is 90 m 3 /min. One is in use and the other stands by. e drilling devices feature the ZYG-150, 220, and 330 drill with the drill pipe having a diameter of 50 mm∼63 mm and a drill bit of 110 mm to make the boreholes for the gas extraction.

The Pressure Relief, Permeability Increase, and Gas Extraction Effect after Mining the Extremely Thin Protective Seam
e pressure relief and permeability increase effect of the protective seam is related to the interlayer spacing, the protective seam mining height, the interlayer lithology, and so on. Since No. 1 7 coal seam thickness of Baoyushan Mine is just 0.5 m, the interlayer space between No. 1 7 and No. 2 1 coal seam averages 23.4 m, and there is a hard 7.3 m thick limestone in between, field inspection and experiment are needed to study the pressure relief and permeability increase of the overburden No. 2 1 coal seam after mining No. 1 7 coal seam. Two indexes, namely, coal seam pressure relief, and deformation and permeability changes, are adopted to directly reflect the pressure relief and permeability increase effect of the protective seam.

e Pressure Relief and Permeability Increase Effect of the Protective Seam.
e permeability of the coal seam is an important parameter to reflect the difficulty degree of the gas migration and one of the feasible indexes to evaluate the gas extraction. It is also one of the indexes to judge the coal and gas outburst danger. e original coal mass permeability of No. 2 1 coal seam is 0.0012 mD. After mining No. 1 7 coal seam, No. 2 1 coal seam undergoes pressure relief, dilatational deformation. e permeability of No. 2 1 coal seam also undergoes corresponding changes. e permeability increases greatly. By comparing the permeability before and after the pressure relief of No. 2 1 coal seam, an in-depth understanding of the changes of No. 2 1 coal seam before and after the protective seam mining can be gained. rough the hole drill under the shaft, the actually measured permeability coefficient of No. 2 1 coal seam after mining the protective seam is increased by about 400 times, about 0.4732 mD. e permeability of coal seam increases by nearly 400 times, and the analysis reasons are as follows: in the process of mining No. 1 7 coal seam, the overlying coal and rock mass gradually bends and sinks without caving zone and obvious fault zone. Due to the slow subsidence deformation of the overlying coal-rock mass, there are stratification fissures along the layers between different soft and hard rock strata, resulting in the expansion deformation of No. 2 1 coal seam. A large number of bedding tensile fractures are produced in No. 2 1 coal seam, so the permeability of the coal seam increases, and the pressure relief gas in No. 2 1 coal seam flows along the bedding tensile fractures formed between layers. At this time, the pressure relief gas of No. 2 1 coal seam must be strengthened to be extracted. e site experiment suggests that, after mining No. 1 7 coal seam, the roof and chassis of No. 2 1 coal seam slowly sag along with the limestone. However, the sagging speed of No. 2 1 coal seam chassis is more quick than that of the roof. In this way, No. 2 1 coal seam is stretched. In other words, the roof and chassis of No. 2 1 coal seam undergo dilatational deformation.
e relative deformation of the roof and chassis of No. 2 1 coal seam obtained through the deep point method can be employed to reflect the pressure relief and permeability increase effect of No. 2 1 coal seam. During the construction of deformation borehole, the borehole is required to enter the coal seam roof by 1.0 m. A pair of steel wedges is installed on the roof and chassis of the coal seam to fix the deep points. e steel wedges are made up of steel pipes and steel plates, which look like inverted wedge-shaped rock bolt, but they are not solid inside. A reinforcing steel bar of about 10 mm thickness is welded to the steel wedge of the coal seam roof, which goes through the steel wedge of the coal seam chassis to the porthole. e steel wedge is welded with a seamless steel tube with a diameter of about 15 mm, which is covered on the reinforcing steel bar connected with the steel wedge. e dial indicator and the micrometer calipers are used to measure the relative displacement of the steel pipe and the reinforcing steel bar. en, the relative deformation of the coal seam roof and chassis is calculated. On 1# borehole, the deep point method is used to test the dilatational deformation of the chassis and roof of No. 2 1 coal seam. e coal thickness in 1# deformed hole is about 3.5 m. e actually measured dilatation deformation is 72 mm, and the maximum dilatational deformation ratio is 72/3,500 � 20.6%. e maximum dilatational deformation is found in the 20 m of the working face. is suggests that the protective seam mining results in great reduction of the ground stress of No. 2 1 coal seam. Due to the pressure relief, dilatational deformation of the coal seam within the coal layer to form the bedding fractures, it is beneficial for the migration of the pressure relief gas within the coal seam. e advance distance between the deformation of No. 2 1 coal seam chassis and roof in 1# borehole of No. 2 drill site and the working face of the protective seam is shown in Figure 9.

Advances in Civil Engineering
Based on the analysis of Figure 9, the following conclusions can be drawn: (1) the protective seam mining has a great influence on the deformation of No. 2 1 coal seam chassis and roof. With the progress of the protective seam mining, the deformation follows the change of compression, rapid dilatation, dilatational deformation reduction, and stabilization. In other words, the corresponding lower protective seam of No. seam is in a pressure increase state, which might squeeze the free gas within the coal seam. e drill hole might be filled with the high concentration gas, but the gas amount is low. When the compressive deformation turns into the dilatational deformation, the coal seam will rapidly undergo pressure relief and permeability increase. e permeability will increase by a hundred times. e borehole will be filled with the high concentration gas, which will be emitted along with the pressure relief gas. It is the best time for the extraction of the pressure relief gas. With the increasing mining distance of the working face of the coal seam, since the overburden coal mass is formed and slowly sags, No. 2 1 coal seam is gradually compacted and the dilatational deformation of No. 2 1 coal seam gradually decreases. After reaching certain level, it will tend to be stable. At the moment, due to the gradual close of the fracture, the gas channels will be closed, the gas concentration within the borehole will rapidly decrease, and the gas amount will be reduced as well. is is the intermission for the gas extraction in the borehole. With the reduction of the remaining gas amount of No. 2 1 coal seam and the significant reduction of the gas concentration and gas amount in the borehole, the extraction of the pressure relief gas is generally completed.  Currently, the gas extraction amount in the mine is about 30∼35 m 3 /min, the gas concentration is 33%, the pure gas amount is 10∼12 m 3 /min, and the annual pure gas extraction amount reaches above 4 million m 3 . e gas extraction rate of the mine reaches 35∼45%. With the intensification of the gas extraction, the gas extraction rate increases correspondingly.
In this experiment, apart from the measurement of the original gas pressure and the gas content of No. 2 1 coal seam, the remaining gas pressure and the gas content of No. 2 1 coal seam after mining the protective seam are measured. Before mining the extremely thin protective seam, the maximum value of the gas pressure of No. 2 1 coal seam reaches 1.17 MPa. e maximum gas content is about 9.73 m 3 /t. After the combination of the extremely thin protective seam and the pressure relief gas extraction, the maximum remaining gas pressure of No. 2 1 coal seam is 0.12 MPa, and the remaining gas content is 3.1 m 3 /t. e pressure relief protective effect of No. 2 1 coal seam after mining the extremely thin protective seam is listed in Table 2.
In the process of the protective seam mining, the gas pressure of the drill hole decreases gradually, and no sharp drop occurs. erefore, it can be deduced that there is no direct fracture between the goaf of the protective seam working face and No. 2 1 coal seam. is also proves that, after mining the extremely thin protective seam working face, the overburden limestone roof sags gradually and shows no caving.

e Site Verification of the Outburst Elimination Effect.
After the protective seam mining is combined with the pressure relief gas extraction, the blast capacity of No. 2 1 coal seam mining working face is decreased from 950 m 3 /min to 500 m 3 /min. e return air gas concentration of subroadway under the working face is decreased from the critical state to 0.3∼0.5%. e absolute gas emission quantity decreases from 8.5∼10 m 3 /min to the current level of below 3 m 3 /min. e absolute gas emission rate of the return air of the mining working face decreases by 70%. During the production process, the gas never exceeds the limit, which well solves the problem of excessive gas and coal dust flying during the production process. e working face output is also increased by a large margin.
In the past, the tunneling of the roadway in No. 2 1 coal seam without the mining protective seam was fulfilled by the 2 * 15 kW pivot axial flow fan. Under the condition of 300 m 3 / min wind supply, the gas concentration of the return air reached above 0.6%. During the gas emission period, the gas often exceeded the limit. e monthly footage should not exceed 50 m. When the gas amount was high, the tunneling had to be stopped. Now, after the adoption of the mining protective seam, the gas concentration ranges within 0.15∼0.3%, when the tunneling is conducted in the protected roadway with the adoption of the 2 * 15 kW pivot axial flow fan and the wind supply of 200 m 3 /min. e tunneling speed is increased from less than 50 m to about 120 m now, which not only eliminates the phenomenon of the excessive gas concentration and ensures the safe tunneling in the roadway of the mine but also alleviates the tension of production alternation and achieves good social and economic benefits.

Conclusions
(1) e actually measured gas pressure of No. 2 1 coal seam of Baoyushan Mine in Dengfeng coalfield is 1.17 MPa, the gas content is 9.74 m 3 /t, and the gas emission initial velocity is 12∼27 mmHg. e original structure of the coal has been seriously damaged. e coal mass is filled with the block coal formed by the pressed pulverized coal. e strength is low and is fragile. It belongs to the full-thickness tectonic coal. e coal destruction type belongs to IV ∼ V coal. e firmness coefficient of No. 2 1 coal ranges within 0.1∼0.18. e permeability rate of the original coal seam is 0.0012 mD. e permeability of the coal seam is extremely poor. e parameters of No. 2 1 coal seam gas outburst in Baoyushan Mine are far higher than the outburst critical indexes specified in Detailed Rules of Coal and Gas Outburst Prevention and Control, so the outburst danger is high and the coal and gas outburst dynamic disasters are very serious. According to the gas geological conditions of the Baoyushan Mine in Dengfeng coalfield, No. 1 7 coal seam, being about 23.4 m under No. 2 1 coal seam and having a thickness of 0.5 m, is regarded as the lower protective seam for prior mining. At the same time, the special gas extraction roadway is set up in the chassis of No. 2 1 coal seam. e borehole is made to extract the pressure relief gas of No. 2 1 coal seam to achieve comprehensive treatment of the gas.
(2) During mining the extremely thin protective seam, the overburden coal and rock mass shows no caving zone. e whole overburden coal and rock mass bends, sags, and deforms along with the generation of the hard limestone roof. No. 2 1 coal seam is located above the extremely thin protective seam roof and the bent sagging zone. Macroscopically speaking, there are no obvious cross-layer fractures, and a vertically smooth fracture cannot be formed between the extremely thin protective seams. Due to the function of the extremely thin protective seam, No. 2 1 coal seam undergoes pressure relief and dilatational deformation. erefore, a lot of bedding fractures are formed in No. 2 1 coal seam. e permeability of the coal seam along the bedding direction is increased by a large margin, while the permeability vertical to the bedding direction is relatively small. After No. 2 1 coal seam obtains the pressure relief protection effect, the coal seam gas is desorbed. However, since a lot of bedding fractures are formed in the coal seam, the pressure relief gas in the coal seam flows along the bedding fractures. Concerning the distribution characteristics of the mining fractures of No. 2 1 coal seam and the sound bedding migration conditions of the pressure relief gas, the gas extraction method is adopted in the borehole in the chassis.
(3) e field experiment results showed that, after mining No. 1 7 coal seam, the permeability rate of No. 2 1 coal seam was increased by about 394 times, from 0.0012 mD to 0.473 mD. After adopting the chassis grid borehole to extract the gas, the gas pressure of No. 2 1 coal seam decreased from 1.17 MPa to 0.12 MPa. e gas content decreased from 9.74 m 3 /t to 3.1 m 3 /t, which fully eliminates the coal and gas outburst dynamic disasters of No. 2 1 coal seam and realizes the safe and effective mining of the mine. (4) e adoption of No. 1 7 as the protective seam in combination with the pressure relief gas extraction technique for the comprehensive treatment of No. 2 1 coal seam can eliminate the problem threatening the safe production of the mine. e gas concentration of the return air of No. 2 1 coal seam working face is maintained within 0.3%∼0.4%, which wipes out the phenomenon of excessive gas and achieves significant results for the gas treatment. In this way, the high gas outburst coal seam can be mined safely under the low gas state, and the mine achieves significant economic and safety benefits [28,29].

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that they have no conflicts of interest.