METHOD FOR REMINING RESIDUAL COAL PILLAR IN RESIDUAL MINING AREA BY COLLABORATION OF PILLAR-SIDE BACKFILLING AND IN-SITU GASIFICATION

Abstract

Disclosed is a method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification. The method includes the following steps of: ascertaining geological and hydrological conditions, a geometric shape and a reserve of a residual coal pillar; determining the feasibility of underground gasification mining for the residual coal pillar; carrying out side supporting on the residual coal pillar in a goaf by using a pillar-side backfilling method; and carrying out the underground gasification mining on the residual coal pillar by means of an underground coal gasification process.

Claims

1. A method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification, comprising following steps of: ascertaining geological and hydrological conditions, a geometric shape and a reserve of the residual coal pillar; determining feasibility of underground gasification mining of the residual coal pillar; carrying out side supporting on the residual coal pillar in a goaf by using the pillar-side backfilling; and carrying out underground gasification mining on the residual coal pillar by means of an underground coal gasification process.

2. The method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification according to claim 1, comprising following steps of: step 1: determining feasibility of the underground gasification mining of the residual coal pillar in the residual mining area; step 2: drawing a distribution pattern map of the residual coal pillar in the residual mining area; step 3: arranging a gas inlet pipeline and an exhaust pipeline in a pillar mining area beside the residual coal pillar, wherein one end of the gas inlet pipeline is arranged in the residual coal pillar, an other end of the gas inlet pipeline is connected to a gas pump on ground, one end of the exhaust pipeline is arranged in the residual coal pillar, and an other end of the exhaust pipeline is connected to a diffusing tower and a gas collection device on the ground; step 4: arranging a backfilling pipeline in the pillar mining area beside the residual coal pillar, wherein one end of the backfilling pipeline is arranged in the pillar mining area or connected to the gas inlet pipeline, and an other end of the backfilling pipeline is connected to backfilling equipment on the ground; step 5: injecting a backfilling material uniformly into the pillar mining area at both sides of the residual coal pillar under an action of the backfilling equipment so as to form a pillar-side backfill body; step 6: heating the residual coal pillar by an ignition device at the one end of the gas inlet pipeline, continuously introducing a gasifying agent into the residual coal pillar by using the gas pump on the ground, enabling coal of the residual coal pillar to start burning and continuing a gasification reaction; and exhausting a combustible gas generated by the gasification reaction to the diffusing tower and the gas collection device on the ground through the exhaust pipeline until the residual coal pillar is completely gasified; step 7: after the gasification reaction of the residual coal pillar is completed, repeating step 3 to step 6, continuing to carry out the pillar-side backfilling and the in-situ gasification on a next residual coal pillar which is adjacent to the completely gasified residual coal pillar in the residual mining area, and carrying out the underground gasification mining on remaining residual coal pillars in the mining area step by step.

3. The method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification according to claim 2, wherein the residual coal pillar in the residual mining area has a thickness of greater than 2 m and a buried depth of greater than 300 m.

4. The method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification according to claim 2, wherein the pillar mining area has a width from 20 m to 160 m.

5. The method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification according to claim 2, wherein the backfill body comprises following raw materials in weight percentage: 15%-30% of cement, 10%-20% of coal ash, 10%-20% of water, 55%-65% of sand/building debris, and 1%-3% of water reducer.

6. The method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification according to claim 2, wherein the gasifying agent comprises air, oxygen, water vapor, and carbon dioxide.

7. The method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification according to claim 2, wherein a temperature generated by the ignition device is from 600? C. to 1,500? C.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0029] FIG. 1 is a schematic diagram of a system for remining by collaboration of pillar-side backfilling and in-situ gasification according to an embodiment of the present disclosure;

[0030] FIG. 2 is a schematic diagram of a pillar-side backfilling process for a residual coal pillar in a residual mining area according to an embodiment of the present disclosure;

[0031] FIG. 3 is a schematic diagram of an underground gasification process for a residual coal pillar in a residual mining area according to an embodiment of the present disclosure;

[0032] FIG. 4 is a schematic diagram of a backfill body after gasification of a residual coal pillar in a residual mining area;

[0033] FIG. 5 is a schematic diagram of a method of combining a backfilling pipeline and a gas inlet pipeline; and

[0034] FIG. 6 is schematic flowchart of a method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification according to an embodiment of the present disclosure.

[0035] In the drawings: 1 gas pump on the ground; 2 backfilling equipment; 3 backfilling pipeline; 4 gas inlet pipeline; 5 exhaust pipe; 6 ignition device; 7 residual coal pillar; 8 pillar mining area; 9 diffusing tower; 10 gas collection device; 11 pillar-side backfill body; 12 underground gasification combustion space area; 13 combined pipeline; and 14 grouting nozzle.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0036] For ease of understanding of the present disclosure, the present disclosure is described more fully below with reference to the accompanying drawings. The present disclosure may, however, be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided for the purpose of providing a more complete and thorough understanding of the present disclosure.

Embodiment 1

[0037] As shown in FIG. 1 through FIG. 4, a method for remining a residual coal pillar in a residual mining area by collaboration of pillar-side backfilling and in-situ gasification includes the following specific steps.

[0038] In step 1, in view of original geological and hydrological data and mining history data of a mine, and the feasibility of gasification mining of a residual coal pillar 7 in a residual mining area is determined by using an underground gasification comprehensive evaluation model described in the paper Study on Comprehensive Evaluation and Stable Production Technology for Underground Gasification of Residual Coal.

[0039] In step 2, the original geological and hydrological data and technical production data of the mine are considered to find out a distribution area, height, width and length of the residual coal pillar 7 of the mine; a three-dimensional laser scanner and a mine roadway geological detector are used to ascertain the distribution of the residual coal pillar 7 and a geological structure of the residual mining area, so as to draw a distribution pattern map of the residual coal pillar 7 of the residual mining area. The residual coal pillar 7 in the residual mining area has a thickness of greater than 2 m and a buried depth of greater than 300 m, and a pillar mining area 8 has a width from 20 m to 160 m.

[0040] In step 3, a gas inlet pipeline 4 and an exhaust pipeline 5 are arranged in the pillar mining area 8 beside the residual coal pillar 7 by using a directional drilling technology. One end of the gas inlet pipeline 4 is arranged in the residual coal pillar 7, and the other end of the gas inlet pipeline 4 is connected to a gas pump 1 on the ground. One end of the exhaust pipeline 5 is arranged in the residual coal pillar 7, and the other end of the exhaust pipeline 5 is connected to a diffusing tower 9 and a gas collection device 10 on the ground. The gas pump 1 on the ground includes an air pump, an oxygen pump, a water vapor pump, and a carbon dioxide pump. The gas collection device 10 is a large gas collection tank.

[0041] In step 4, a casing drilling technology is used to carry out drilling construction from the ground position above the pillar mining area 8, so as to form the borehole with a diameter of 300 mm, an inclination angle of 10-15?, and an inclination direction consistent with a stratum thereof, and a backfilling pipeline 3 for conveying backfilling paste is arranged in the pillar mining area 8 on each of both sides of the residual coal pillar 7. One end of the backfilling pipeline 3 is arranged in the pillar mining area 8, with an end head connected to a spray pump truck, and the other end of the backfilling pipeline 3 is connected to the backfilling equipment 2 on the ground. The backfilling equipment 2 includes a backfilling pump, a blender, a mixer, a storage device, a charger, a feeding rack, a slurry producing machine, a slurry filter, or a loader.

[0042] In step 5, under the action of the backfilling equipment 2, the backfilling paste is uniformly injected into the pillar mining area 8 on both sides of the residual coal pillar 7 to form a pillar-side backfill body 11. The backfilling paste includes the following raw materials by weight percentage: 15%-30% of cement, 10%-20% of coal ash, 10%-20% of water, 55%-65% of sand/building debris, and 1%-3% of water reducer. The backfilling paste with such composition is free of instable failure after the gasification process is finished, which can stably support the roof overlying rock after high-temperature combustion, and cannot generate large fractures and crushing during gasification, so as to ensure the airtightness of the gasification channel. The backfilling paste is backfilled by a backfilling method for pillar-side bilateral parts disclosed in Chinese Patent Publication No. CN104832174A. The configuration volume and backfilling time of the backfilling paste and a flow rate of a flowmeter need to be determined according to the ascertained underground space of the residual mining area and the size and distribution of the residual coal pillar.

[0043] In step 6, the residual coal pillar 7 is heated by an ignition device 6 at the one end of the gas inlet pipeline 4, a gasifying agent is continuously introduced into the residual coal pillar 7 by using the gas pump 1 on the ground to make the coal start burning and continue a gasification reaction, and the produced combustible gas of the gasification reaction is exhausted to a diffusing tower 9 and a gas collection device 10 on the ground through the exhaust pipeline 5 until the residual coal pillar 7 is completely gasified. The outer side of the residual coal pillar 7 is also provided with an electron temperature sensor to detect the temperature change in the residual coal pillar, so as to obtain the progress condition of gasification reaction in the coal pillar. The start and stop of the gasification reaction can be controlled by opening/closing the ignition device and turning on/off the gas pump. The gasifying agent includes air, oxygen, water vapor, and carbon dioxide, and the composition of the gasification agent can be adjusted according to a high-temperature coal gas required for production. The temperature produced by the ignition device 6 is from 600? C. to 1,500? C.

[0044] In step 7, after the gasification of the residual coal pillar 7 is completed, step 3 to step 6 are repeated to continue pillar-side backfilling and in-situ gasification on a next residual coal pillar 7 which is adjacent to the completely gasified residual coal pillar in the residual mining area, and the remaining residual coal pillars in the mining area are subjected to gasification mining step by step.

Embodiment 2

[0045] The difference of the Embodiment 2 from the Embodiment 1 is that, as shown in FIG. 5, in the step 4, one end of the backfilling pipe 3 is connected to the gas inlet pipeline 4 to form a combined pipeline 13, and a portion, in the pillar mining area 8, of the combined pipeline 13 is provided with multiple grouting nozzles 14. In the step 5, the backfilling paste is replaced with backfilling slurry to prevent blocking the combined pipeline 13. An operation process of backfilling and gasification in the Embodiment 2 is as follows. Firstly, a switch of the backfilling pipeline 3 is turned on, the grouting nozzles of the combined pipeline 13 are opened, and an inlet of the gas inlet pipeline 4 and an outlet, which is arranged in the residual coal pillar, of the combined pipeline 13 are closed for the operation process of backfilling. After the operation process of backfilling is finished, the grouting nozzles 14 of the combined pipeline 13 are closed. After the backfilling slurry is solidified and hardened, the gas pump 1 on the ground is turned on, and the outlet, which is arranged in the residual coal pillar, of the combined pipeline 13 is opened to perform the operation process of gasification for the underground coal.

[0046] The method is simple in operation, by combining the backfilling pipeline and the gas inlet pipeline. So, the required equipment is less, and the cost is lower.

[0047] The foregoing embodiments are preferred embodiments of the present disclosure. It should be noted that any variations and modifications made to the process above without departing from the technical essence and principle of the present disclosure fall within the scope of protection of the present disclosure.