Results and discussion
Initial temperature. According to the statistics of the initial temperature of three groups of single tube test areas, the analysis of Tab 1 shows that the temperature of HP122 test area is the lowest, and the highest temperature is at T204-8, which reaches 169.2 ℃. The temperature of 1~5m is below 90 ℃, and the temperature of 6 and 7m is 96.5 ℃ and 105.6 ℃ respectively, which starts to accelerate oxidation; the temperature of HP201 test area is above 90 ℃, and the temperature of 1m and 2m underground is rapid oxygen in the chemical zone, the temperature at 3m underground reaches above 350 ℃, and the temperature at 5m and 6m underground reaches the highest; in the HP168 test zone, the temperature at 1m is below 90 ℃, the temperature at 2m and 3m is the rapid oxidation zone, the temperature at T304-4 reaches 432.5 ℃, and the temperature at T304-7 reaches the highest, 572.5 ℃, followed by T304-8, 544.2 ℃.
To sum up, the gangue in HP122 test area is in the oxidation stage, and there is no spontaneous combustion phenomenon. HP201 and HP168 test areas start spontaneous combustion at the depth of 3m and 4m respectively, and reach the highest temperature at 6m and 7m respectively. This is because the buried depth of 1 and 2m is easy to conduct heat conduction with the external environment, and the heat is easy to dissipate. The greater the buried depth of gangue, the easier the heat is to accumulate and difficult to dissipate, resulting in higher temperature.
Comparison between HP and without HP data. Take HP122 group test as an example, compare the control group with 3m depth and without HP, draw the temperature change diagram from HP installation to 700h, as shown in Fig 5.
It can be seen from Fig. 5 (a) ~5 (d) that the existence of HP has a great influence on the internal temperature change of coal gangue dump. In the case of no HP, the temperature of the gangue dump at this location increases from 66 ℃ to 71.7 ℃ within 700h, and the temperature rises by 5.7 ℃ with a large temperature change slope; while the temperature at T201-3, which is 0m away from the HP, decreases from 69.5 ℃ to 42.5 ℃ within 700h, and the temperature is in a state of continuous decline. The temperature of T202-3 in figure (b) rises from 72.2 ℃ to 74.5 ℃ at a horizontal distance of 1m from the HP, and then continues to drop to 55 ℃. After 100h, the temperature of T205-3 continues to drop by 13.5 ℃. The temperature of T203-3 temperature measuring point in figure (c) fluctuates from 70.5 ℃ to 74.2 ℃ at a distance of 2m from the HP horizontally, and then decreases continuously after 100h, which indicates that the heat transfer of the HP has stabilized at this time, with a decrease of 17.7%; the temperature of T206-3 temperature measuring point in figure (c) decreases from 79.5 ℃ to 70.3 ℃ within 700h, with a decrease of 9.2 ℃. The temperature measurement point T204-3 in figure (d) fluctuates from 73 ℃ to 75 ℃ at 3m away from the HP, and then continues to drop to 60 ℃.
To sum up, it can be seen that: (1) in the low-temperature oxidation zone where the temperature of gangue dump is below 90 ℃32-34, after the HP has been running for 700h, the temperature is in a state of continuous decline, and the temperature change slope is large, while the temperature of the control group without HP is in a state of continuous rise. (2) It takes about 100 hours for the HP to reach a stable heat transfer state. (3) The HP heat transfer has a certain disturbing effect on the temperature of the coal gangue dump, and accelerates the heat dissipation of it. The average cooling range at 3m underground is 21.44%, which effectively reduces the internal temperature of the study area. (4) It can be considered that the effective radius of the HP is 3 m in the low temperature oxidation zone below the critical temperature point (80 ~ 90 ℃).
Horizontal temperature variation. In order to study the horizontal temperature distribution characteristics of Gangue Mountain under the action of HP, taking HP201 test as an example, using the temperature data series collected by each temperature measurement point in the test, draw the contour map of horizontal temperature distribution in different depth inside the gangue mountain before and after installing the HP, as shown in Fig 6.
It can be seen that: (1) the overall distribution of temperature in the study area is that the temperature in the southeast is higher than that in the northwest. (2) The internal temperature distribution of gangue increases from top to bottom, and the temperature distribution of each layer is uniform without temperature concentration point. (3) The temperature at 5 and 6m is the highest because the temperature at 1 and 2m away from the ground can be heat transferred with the external temperature, and a part of the heat is dissipated by itself, and the temperature in the deep is not easy to spread to the outside, which leads to the formation of heat storage area.
After 90 days of continuous operation of HP, the temperature inside the coal gangue dump at 1 ~ 6m underground decreased to varying degrees. Among them, the cooling effect of shallow depth is the most obvious, and the influence of the disturbance action of HP is also used in the depth of 5 and 6m. The heat flux has changed, which indicates that the temperature of 6m can be disturbed when the buried depth of the HP is 3.5m.
Overall, the HP makes the temperature distribution in the coal gangue dump more uneven, which accelerates the heat dissipation rate and has a high efficiency of heat conduction.
Vertical temperature variation. In order to study the vertical temperature distribution characteristics of coal gangue dump in Yinying Coal Mine under the action of HP, taking HP201 test as an example, the vertical temperature distribution of measuring points is shown in Fig 7.
It can be seen that: (1) with the increase of the depth, the overall temperature has an upward trend, the minimum temperature is 104.7 ℃, the maximum temperature is 493.7 ℃, and the temperature of 3m depth reaches 320 ℃, and spontaneous combustion begins35. (2) The maximum temperature difference is 191.2 ℃ at the depth of 1 and 2m, and the minimum temperature difference is 3.2 ℃ at the depth of 5 and 6m. This is because, after the gangue spontaneous combustion, part of the heat conduction upward, making the surface temperature rise, part of the heat conduction downward, making the deep gangue temperature rise, and the surface is easy to have heat convection with the outside air and heat dissipation, after a period of time, the surface temperature drops, and the temperature difference between 1 and 2 m layers becomes larger; at this time, the deep temperature is greater than the shallow temperature, and the internal temperature of the gangue starts from the deep to the surface The temperature difference between 5 and 6 m layers becomes smaller. (3) The trend of vertical temperature at different temperature measuring points is basically the same, which reflects the common characteristics of the relationship between internal temperature and depth of the coal gangue dumps to a certain extent.
After 90 days of continuous operation of the HP, the temperature of the temperature measuring points at 0, 1, 2 and 3 m away from the HP decreases, and the closer the distance is, the better the cooling effect is. After cooling, the lowest temperature is 84.5 ℃ and the highest temperature is 473 ℃. The cooling range of T102 and T105 is basically the same, and that of T103 and T106 is basically the same. It can be seen from Fig 7 (d) that there is a certain cooling effect at a horizontal distance of 3m, but the cooling effect is the worst compared with other temperature measuring points, which indicates that the maximum controllable radius of the HP in this area is 3m.
The maximum drop in different temperature regions. The maximum cooling range of each depth in 90 days in three experimental areas under the action of HP was compared. It can be seen from Fig 8 that the temperature of the three groups of test temperature measuring points decreased in varying degrees. The results show that: (1) the effective cooling radius of the HP in the three temperature zones is 3m, and the farther the horizontal distance of the HP is, the smaller the cooling range is. (2) The cooling range of the shallow temperature is larger than that of the deep temperature, which is due to: the buried depth of the HP is 3.5m, the working medium in the evaporation section is 1m, the buried depth of 1 and 2m is easier to dissipate heat; the shallow temperature is easier to form heat convection with the outside world. (3) The gangue layer with the depth of 1-4m and the temperature between 90 ℃ and 450 ℃ has the best cooling effect.
Compared with the three groups of single tube test, HP122 group has the smallest cooling range, which is due to the low initial temperature of the temperature measuring point of this group, which belongs to the low temperature oxidation zone. After 90 days of operation of the HP, the average cooling is 25.6 ℃, and the temperature in this zone drops to a more stable range, which greatly reduces the oxidation reaction rate and prevents the possibility of rapid oxidation.
The initial temperature of group H168 is the highest in three groups, reaching 573 ℃, and the cooling range is the largest. This is because: in a platform where group HP201 is located, the temperature in a large area is high, and the vegetation on the surface has withered, with the obvious pungent smell; in some areas of the three platforms where group HP168 is located, the temperature is low, the vegetation growth is good, and there are relatively few high temperature concentration points; in the test area of group HP168, the temperature is 1 ~ 4m deep This test is a single tube test, which is caused by the limited cooling range.