4.1 Effect of different material rations on film thickness and thickness attenuation ration
The results of orthogonal test of the corner wall rapid film-forming plugging material are shown in Table 3. In this orthogonal test, a total of 4 factors that have a direct impact on the film formation of the material were selected. Each factor selected 3 levels for orthogonal test, considering 3 indicators that have a direct impact on the plugging effect. The experimental results are shown in Fig. 8.
Table 3
Orthogonal test results of film quality evaluation index
Test scheme
|
A. Alginate concentration/%
|
B. Amount of alginate/(L/m2)
|
C. Calcium chloride concentration/%
|
D. Amount of calcium chloride/(L/m2)
|
Film thickness
(mm)
|
12h Thickness attenuation ratio (%)
|
24h Thickness attenuation ratio (%)
|
|
1
|
1
|
2
|
5
|
2
|
2.1
|
28.57
|
47.62
|
|
2
|
1
|
3
|
7.5
|
3
|
2.9
|
27.59
|
44.8
|
|
3
|
1
|
4
|
10
|
4
|
4.1
|
24.39
|
48.78
|
|
4
|
1.25
|
2
|
7.5
|
4
|
2.1
|
28.57
|
47.62
|
|
5
|
1.25
|
3
|
10
|
2
|
3.1
|
28.51
|
45.16
|
|
6
|
1.25
|
4
|
5
|
3
|
3.8
|
23.68
|
42.11
|
|
7
|
1.5
|
2
|
10
|
3
|
2.5
|
24
|
44
|
|
8
|
1.5
|
3
|
5
|
4
|
3.7
|
19.01
|
37.8
|
|
9
|
1.5
|
4
|
7.5
|
2
|
4.2
|
21.43
|
40.48
|
|
K1 − 1
|
9.1
|
6.7
|
9.6
|
9.4
|
|
|
|
|
K1 − 2
|
9
|
9.7
|
9.2
|
9.2
|
|
|
|
|
K1 − 3
|
10.4
|
12.1
|
9.7
|
9.9
|
|
|
|
|
k1 − 1
|
3.033
|
2.233
|
3.2
|
3.133
|
|
|
|
|
k1 − 2
|
3
|
3.233
|
3.067
|
3.067
|
|
|
|
|
k1 − 3
|
3.467
|
4.033
|
3.233
|
3.3
|
|
|
|
|
R1
|
0.467
|
1.8
|
0.167
|
0.233
|
|
|
|
|
K2 − 1
|
80.55
|
81.14
|
71.26
|
78.51
|
|
|
|
|
K2 − 2
|
80.76
|
75.11
|
77.59
|
75.27
|
|
|
|
|
K2 − 3
|
64.44
|
69.5
|
76.9
|
71.97
|
|
|
|
|
k2 − 1
|
26.85
|
27.047
|
23.753
|
26.17
|
|
|
|
|
k2 − 2
|
26.92
|
25.037
|
25.863
|
25.09
|
|
|
|
|
k2 − 3
|
21.48
|
23.167
|
25.633
|
23.99
|
|
|
|
|
R2
|
5.37
|
3.88
|
2.11
|
2.18
|
|
|
|
|
K3 − 1
|
141.2
|
139.24
|
127.53
|
133.26
|
|
|
|
|
K3 − 2
|
134.89
|
127.76
|
132.9
|
130.91
|
|
|
|
|
K3 − 3
|
122.28
|
131.37
|
137.94
|
134.2
|
|
|
|
|
k3 − 1
|
47.067
|
46.413
|
42.51
|
44.42
|
|
|
|
|
k3 − 2
|
44.963
|
42.587
|
44.3
|
43.637
|
|
|
|
|
k3 − 3
|
40.76
|
43.79
|
45.98
|
44.733
|
|
|
|
|
R3
|
6.307
|
3.827
|
3.47
|
1.097
|
|
|
|
|
Table 3 is the summary of orthogonal test results, extreme value and variance analysis. Km−n (m = 1 ~ 3, n = 1 ~ 3) is the extreme value of three evaluation indexes, and Rm (m = 1 ~ 3) is the corresponding variance. The larger the film thickness, the better the plugging effect under the same conditions. Therefore, it can be seen from the data in Table 3 that A3B3C3D3 is the best ratio under this influencing factor. Since R1 (b) is much larger than the other three indicators, the amount of alginate (L / m2) has a major effect on the film thickness. For the 12 h and 24 h thickness attenuation ratio (%), the smaller the value, the better the plugging effect under the same conditions. Therefore, from the data of Table 3, it can be seen that A3B3C1D3 is the best ratio under the influence of 12 h thickness attenuation ratio, and A2B2C1D3 is the best ratio under the influence of 24 h thickness attenuation ratio (%). The R2 and 3 (a) are much larger than the other 6 (two groups). Therefore, the alginate concentration (%) has a major impact on the above two indicators.
Figures 8 (a) and (b) are the thickness attenuation statistics of 9 schemes after 12 h and 24 h constant temperature standing. Observing Table 2 and combining Fig. 8 (a) and (b), it can be seen that the film thickness of the 9 groups of test ratio schemes has a certain degree of attenuation over time. The reason for the above phenomenon is that the plugging membrane is a fluid with water as the solvent. After the crosslinking reaction of the two materials, a part of the unreacted complete solution will evaporate, resulting in a decrease in the thickness of the film. It can be seen from Fig. 8 (a) that after 12 hours of constant temperature standing, the attenuation ratio of the thickness of the plugging film in each group is more than 19%. Among them, the attenuation ratio of scheme 1 is the largest, which is 28.57%, and the attenuation ratio of scheme 8 is the smallest, which is 19.01%. In Fig. 8 (b), the thickness attenuation ratio after 24 hours of constant temperature standing is similar to that after 12 hours, and the attenuation ratio of scheme 1 is the largest, which is 47.62%. Scheme 8 has the smallest attenuation ratio, which is 37.8%.
From the above experimental data, it can be seen that the scheme 8, that is, 1.5% sodium alginate solution and 7.5% calcium chloride solution were sprayed at a ratio of 4:3 to form a plugging film in the film thickness, 12h and 24h thickness attenuation ratio can achieve the best effect. Sodium alginate has good film-forming properties and high liquid viscosity after being dissolved in water. The 1.5% concentration of sodium alginate solution can reduce the loss caused by solution flow as much as possible under the premise of ensuring good spraying effect and meeting the engineering field application. And the higher concentration of viscous solution volatilizes less water, so the effect of forming film is the best at this ratio.
4.2 Effect of different material ratios and PH on colloid coagulation time
Take 6 200ml beakers and add 100ml water in turn. Six portions of 2.5g PVA1788 were weighed, and 0.2g, 0.4g, 0.6g, 0.8g, 1.0g and 1.2g of borax were weighed respectively. The PVA powder and borax powder were mixed evenly and slowly added to 6 groups of 100 ml water, respectively, and stirred at a constant speed to form a colloid and record the time. Under the optimal colloid coagulation ratio selected by the above experiments, the pH of the slurry was adjusted to 4 ~ 9 by using the acid-base titration solution, and the above experiments were repeated again and the gel time of the slurry was recorded and summarized in Table 5. The experimental results are shown in Fig. 9.
Table 4
Colloid setting time under different material ratios
Number
|
PVA(%)
|
Borax(%)
|
Colloid formation time(min)
|
1
|
2.5
|
0.2
|
28
|
2
|
2.5
|
0.4
|
31
|
3
|
2.5
|
0.6
|
34
|
4
|
2.5
|
0.8
|
38
|
5
|
2.5
|
1.0
|
44
|
6
|
2.5
|
1.2
|
50
|
Table 5
Colloid condensation time at different PH values
Number
|
Material proportion
|
PH
|
Colloid formation time(min)
|
|
1
|
2.5% PVA + 0.6% Borax
|
4
|
62
|
|
2
|
2.5% PVA + 0.6% Borax
|
5
|
48
|
|
3
|
2.5% PVA + 0.6% Borax
|
6
|
37
|
|
4
|
2.5% PVA + 0.6% Borax
|
7
|
34
|
|
5
|
2.5% PVA + 0.6% Borax
|
8
|
24
|
|
6
|
2.5% PVA + 0.6% Borax
|
9
|
18
|
|
From Fig. 9 and Table 3, it can be seen that with the increase of borax content, the gelation time gradually prolonged. This is because in the process of stirring, the hydrolysis of borax to produce B (OH) 4−accelerates the hydrolysis of polyvinyl alcohol and the complexation reaction to form a polymer gel, which effectively alleviates the problem that polyvinyl alcohol is difficult to dissolve at room temperature. However, as the amount of borax increases, the hydrolysis time of borax will increase, resulting in a lag in the crosslinking reaction and an increase in the gelation time.
From the analysis of Fig. 9 and Table 4, with the increase of PH value, the coagulation time of colloid decreases significantly. This is because the main molecular structure of polyvinyl alcohol is 1,3-propanediol, which contains a large amount of -OH. -OH is an important functional group for the crosslinking reaction between polyvinyl alcohol and (OH) 4−. Under acidic conditions, the content of H + in the solution is high, and the priority of hydration reaction between -OH and H + is much higher than that of crosslinking reaction, resulting in a large amount of -OH consumed. Therefore, the crosslinking reaction was forced to delay. Based on the consideration of grouting time and grouting cost in the engineering site, 2.5% polyvinyl alcohol + 0.6% borax is the best ratio of crosslinking reaction. On this basis, the PH is adjusted to 6 ~ 7, and the reaction time is controlled at about 35 min, which can better meet the requirements of grouting in the engineering site.
4.3 Effect of different thickener concentrations on viscosity and adhesion properties
Viscosity and adhesion are important indicators to measure the plugging effect of grouting plugging materials. Higher viscosity and adhesion mean that the colloid has a better plugging effect. After the slurry is injected into the coal seam, with the passage of time, the liquid flows while the crosslinking reaction gradually occurs and generates a complex gel. The gel generated by stays in the fracture with its strong cohesiveness and effectively bonds and adheres to the upper and lower walls of the fracture, and finally plays a plugging effect. Therefore, the viscosity of the grouting material after gelation in the pores plays a decisive role in the plugging effect. The effects of different concentrations of thickeners on viscosity and adhesion are shown in Table 6. The data of viscosity and adhesion ability after gelling under different concentrations of thickeners are shown in Fig. 10.
Table 6
Viscosity and adhesion under different concentrations of thickeners
Number
|
Sodium carboxymethyl cellulose concentration (%)
|
Viscosity
/(mPa.s)
|
5min sliding distance (mm)
|
10min sliding distance(mm)
|
15min sliding distance (mm)
|
20min sliding distance (mm)
|
1
|
0.2
|
176600
|
1.1
|
1.7
|
2.2
|
2.6
|
2
|
0.3
|
192300
|
0.9
|
1.5
|
2.1
|
2.4
|
3
|
0.4
|
207100
|
0.8
|
1.4
|
1.7
|
2.1
|
4
|
0.5
|
221150
|
0.6
|
1.1
|
1.5
|
2.0
|
5
|
0.6
|
222550
|
0.5
|
1.2
|
1.4
|
1.8
|
6
|
0.7
|
223981
|
0.5
|
1.0
|
1.3
|
1.7
|
From Fig. 10 and Table 6, it can be seen that with the increase of thickener concentration, the gel viscosity increased linearly in the early stage and gradually balanced in the later stage. When the concentration of sodium carboxymethyl cellulose was greater than or equal to 0.5%, the gel viscosity gradually stabilized. The adhesion of the gel is characterized by the sliding distance at the same time when it is placed vertically on the glass plane. It is not difficult to see that with the increase of viscosity, the sliding distance of the colloid at the 4 times gradients of 5 ~ 20min is significantly reduced, and the adhesion ability is significantly increased. Therefore, 0.5% sodium carboxymethyl cellulose is the best thickener concentration.
Combined with the above measured data, the influence of material ratio on film thickness, 12 h and 24 h thickness attenuation ratio was comprehensively considered. The effect of borax concentration and PH value on the gelation time, the effect of different sodium carboxymethyl cellulose concentration on the viscosity of the gel, and the effect of the gel on the sliding amount of the smooth glass surface at the same time gradient. The optimal ratio of the rapid film-forming plugging material on the corner wall is: 1.5% sodium alginate: 7.5% calcium chloride = 4:3; the best ratio of grouting sealing material in the fracture fissure expansion area of the corner roof is: 2.5% polyvinyl alcohol + 0.8% borax + 0.5% sodium carboxymethyl cellulose, supplemented by 1% inorganic salt to enhance water retention, and PH is 6 ~ 7.
5. Capping Program
The air leakage in the goaf is the important case of gas overrun in the upper and lower corners. Because the air flow turns sharply at the corner, the air flow velocity here is low and it is easy to form an eddy current zone. At the same time, the gas accumulated in the goaf is easy to accumulate here under the influence of air leakage and its own floating in the air.
At present, for the problem of gas accumulation in the upper and lower corners, Weijiadi Coal Mine adopts a simple sandbag-stacked wall to seal the wall surface. The sandbag-stacked wall is placed at the upper and lower corners, and a layer of yellow mud is applied on the surface to strengthen the sealing of the sealing wall. However, its sealing is poor, and the gas in the goaf can still diffuse to the corner through the sealing wall. Therefore, in order to solve the above problems, a fast film-forming plugging material for the corner wall and a drilling grouting plugging material for the crack expansion area of the corner roof were developed. The " plugging-grouting " combined with the upper and lower corner gas overrun comprehensive control scheme formed by the dynamic combination of the advantages of the two materials was applied to the West 2109 working face of Weijiadi Coal Mine. The air leakage, gas concentration and temperature were selected as the evaluation parameters of the plugging scheme and the field measurement was carried out.
5.1 Corner wall rapid film-forming plugging
Sodium alginate is a kind of carbohydrate, which is a polymer formed by linear (1 → 4) bonded β-D-mannuronic acid and α-L-guluronic acid [23–24]. The molecular structure contains hydroxyl ether bond. When it encounters alkaline ions, especially Ca2+, complexation reaction occurs and film-forming behavior occurs. When the sodium alginate solution meets with Ca2+, the chemical bond connecting Na+ in the molecule is broken and cross-linked with Ca2+ to form a new chemical bond. In each sodium alginate molecule, substitution reaction occurs with the hydroxyl group adjacent to the ether bond to form an ether bond connecting the two molecules [25–28]. The above two chemical reactions synthesize calcium alginate molecules with high degree of polymerization by bonding dispersed sodium alginate molecules. The above reactions occur repeatedly, and the generated calcium alginate molecules are bonded horizontally and vertically to form a polymer. The polymer is macroscopically a dense polymer plugging film. The mechanism of plugging film formation is shown in Fig. 11
Based on the above laboratory material optimization and film forming mechanism analysis, combined with the current situation of the upper corner plugging of the west 2109 working face of Weijiadi Coal Mine, the rapid film forming plugging material is sprayed on the surface of the original plugging wall to form a dense film to make up for the effect of plugging the wall ventilation. Figure 12 (a) is the effect before the plugging membrane is not used, and Fig. 12 (b) is the plugging effect after the new plugging membrane is used. The comparison between the two shows that the plugging effect of the project site after the plugging membrane is used is significantly improved and more regular.
5.2 Drilling grouting plugging in fracture expansion development area of corner roof
Polyvinyl alcohol is a water-soluble polymer with good gelation property [29–30]. The large amount of -OH contained in the molecular chain of polyvinyl alcohol can carry out a series of chemical reactions between functional groups, and combine two or more polyvinyl alcohol molecules together by bridging to form a gel with high polymerization and high molecular weight [31–32]. Polyvinyl alcohol gel has become a popular plugging material because of its strong viscosity and expansibility. Borax is a commonly used crosslinking agent. Borax is a white solid powder at room temperature, and it will quickly dissolve into boric acid solution after encountering water. Boric acid solution in water will accept negatively charged OH−, and then generate borate ions (B(OH)4− ), B (OH)4− and the alcohol group on the polyvinyl alcohol condensation reaction to remove the water molecules at the same time, polyvinyl alcohol molecules cross-linked together, and ultimately to form a hydrogen bond in the form of bonding to form a high polymer, the macro performance of the elastic, viscosity and expansion of the gel [33–35]. The gelation mechanism of polyvinyl alcohol gel is shown in Fig. 13.
Based on the optimization of grouting materials and the analysis of gelling mechanism, combined with the fracture morphology and fracture characteristics of the fracture expansion development zone of the roof fissure in the corner of the west 2109 working face of Weijiadi Coal Mine, the length of the borehole in the plastic zone of the surrounding rock is designed to be 5m, and the length of the borehole in the fracture caving zone is designed to be 8m, so that the end of the borehole can penetrate into the fine-grained sandstone. The plugging slurry injected into the rock mass has a complex reaction at the edge of the flow, which makes the slurry become thick and eventually the gelling hysteresis flow, and the formed colloid stays and adheres to the fracture to complete the plugging.
5.3 Measurement and analysis of plugging solutions
In this field monitoring, 4 monitoring and 2 eddy current zones were set up in the upper and lower corners and goaf, a total of 6 monitoring points. Monitoring surface 1: It is mainly used to monitor the air volume of the air inlet, the gas content in the air flow and the temperature change. Vortex zone 1: It is mainly used to monitor the D air volume distribution, gas in the air flow and air leakage in the lower corner. Monitoring surface 3: It is mainly used to monitor the change of airflow distribution and gas in the airflow near the working face of intake roadway and return roadway. Vortex zone 2: It is mainly used to monitor the air flow distribution, gas in the air flow and air leakage in the upper corner. Monitoring surface 4: It is mainly used to monitor the air volume distribution of the return air roadway, the change of gas and air leakage in the air flow.
In order to obtain the changes of gas concentration and air leakage before and after the plugging scheme, six groups of field monitoring were carried out at the six measuring points (as shown in Fig. 14), and the average value and data change ratio were calculated. The change of gas concentration before and after plugging is shown in Fig. 15, and the change of air volume is shown in Figures.16 and 17.