CN113756808A - Combined pressure relief method for blasting and large-diameter drilling of steeply inclined super-thick hard coal seam - Google Patents
Combined pressure relief method for blasting and large-diameter drilling of steeply inclined super-thick hard coal seam Download PDFInfo
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- CN113756808A CN113756808A CN202110902286.2A CN202110902286A CN113756808A CN 113756808 A CN113756808 A CN 113756808A CN 202110902286 A CN202110902286 A CN 202110902286A CN 113756808 A CN113756808 A CN 113756808A
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- 239000003245 coal Substances 0.000 title claims abstract description 60
- 238000005553 drilling Methods 0.000 title claims abstract description 36
- 238000005422 blasting Methods 0.000 title claims abstract description 30
- 238000000034 method Methods 0.000 title claims abstract description 29
- 230000000694 effects Effects 0.000 claims abstract description 22
- 238000012544 monitoring process Methods 0.000 claims abstract description 12
- 238000005065 mining Methods 0.000 claims abstract description 10
- 239000011435 rock Substances 0.000 claims abstract description 9
- 238000010276 construction Methods 0.000 claims abstract description 7
- 238000011156 evaluation Methods 0.000 claims 2
- 238000009933 burial Methods 0.000 claims 1
- 238000011084 recovery Methods 0.000 abstract description 5
- 238000009434 installation Methods 0.000 abstract description 2
- 238000004519 manufacturing process Methods 0.000 description 3
- 238000010586 diagram Methods 0.000 description 1
- 238000000605 extraction Methods 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 230000002265 prevention Effects 0.000 description 1
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21C—MINING OR QUARRYING
- E21C41/00—Methods of underground or surface mining; Layouts therefor
- E21C41/16—Methods of underground mining; Layouts therefor
- E21C41/18—Methods of underground mining; Layouts therefor for brown or hard coal
Abstract
The invention discloses a combined pressure relief method for blasting and large-diameter drilling of a steep and extremely-thick hard coal seam, which specifically comprises the following steps: firstly, in the mining process of a steeply inclined extra-thick hard coal seam, a top plate side roadway and a bottom plate side roadway are arranged in a staggered manner, and a plurality of borehole stressometers are arranged on the two roadways and cover the whole roadway and are used for monitoring the stress change of surrounding rocks of the roadway; determining installation parameters of the blast holes and the large-diameter drill holes according to the mechanical properties of the coal body and the top and bottom plates of the coal bed, arranging the large-diameter drill holes and the blast holes in the top plate side roadway, and arranging the blast holes in the bottom plate side roadway; finally, after the blasting large-diameter combined pressure relief drilling construction is finished, evaluating the pressure relief effect according to the stress value monitored by the drilling stress meter; the combined pressure relief method for blasting and large-diameter drilling of the steeply inclined super-thick hard coal seam can reduce stress concentration and impact danger degree of the steeply inclined coal seam, is better in pressure relief effect, effectively improves recovery rate, and is more suitable for particularity of the steeply inclined super-thick hard coal seam.
Description
Technical Field
The invention relates to the field of prevention and control of impact mine pressure, in particular to a combined pressure relief method for blasting and large-diameter drilling of a steeply inclined super-thick hard coal seam.
Background
Rock burst is a typical mine dynamic phenomenon, has great harmfulness to safety production of coal mines, and along with the increase of mining depth, the possibility and the harm of rock burst increase. When mining the steeply inclined and extremely thick hard coal, the problems of unobvious pressure relief effect, poor safety, fewer related pressure relief measures and the like exist during stoping of a working face due to mining conditions and the particularity of mechanical properties of a coal bed of the steeply inclined and extremely thick hard coal.
The existing research shows that the ultra-thick hard coal is easy to accumulate energy during working face extraction due to the harder mechanical effect of the coal quality. In order to ensure safe and efficient production of coal mines, measures suitable for complete pressure relief of steeply inclined super-thick coal seams are required. However, the existing pressure relief measures have the following three problems: firstly, the existing measures for steeply inclined super-thick hard coal are few, and the currently adopted measures cannot realize full pressure relief of the coal seam; secondly, the recovery rate is lower when the steeply inclined extra-thick hard coal working face is recovered; and thirdly, the pressure relief measure parameters are not matched with the field conditions of the working face.
Disclosure of Invention
The invention provides a combined pressure relief method for blasting and large-diameter drilling of a steeply inclined super-thick hard coal seam, which can reduce stress concentration and impact danger degree of the steeply inclined coal seam, relieve pressure in a targeted manner, achieve better pressure relief effect, effectively improve the recovery rate of the existing working face, ensure that pressure relief measure parameters are matched with the field conditions of the working face, and is more suitable for the particularity of the steeply inclined super-thick hard coal seam.
In order to achieve the purpose, the combined pressure relief method for blasting and large-diameter drilling of the steeply inclined extra-thick hard coal seam specifically comprises the following steps:
s1, arranging a top plate side roadway and a bottom plate side roadway in a staggered manner in the mining process of the steeply inclined ultra-thick hard coal seam, and installing a plurality of borehole stress meters on the two roadways and covering the whole roadway for monitoring the stress change of surrounding rocks of the roadway;
s2, determining parameters of the hole diameter, the hole depth, the distance and the position from the bottom plate of the blast hole and the large-diameter drill hole according to the mechanical properties of the coal body and the coal seam roof and bottom plate, and arranging the large-diameter drill hole and the blast hole in a top plate side roadway and arranging the blast hole in a bottom plate side roadway;
s3, after the blast hole and the large-diameter drill hole are constructed, evaluating the pressure relief effect according to the stress value monitored by the drill hole stress meter;
when the drilling stress count value is larger than the monitoring early warning value, the drilling stress count value is judged to be poor, and when the drilling stress count value is smaller than the monitoring early warning value, the drilling stress count value is judged to be good.
Further, the roof-side course staggering is arranged at the next level of the floor-side course in step S1.
Further, the burying depth of each drilling stress meter in the step S1 is 8-10m, and the distance between adjacent drilling stress meters is 5-30 m.
Further, the method is characterized in that in the step S2, the large-diameter drill holes on the top plate side roadway are respectively positioned on the right side and the bottom plate of the top plate side roadway;
a plurality of large-diameter drill holes on the right side of the top plate side roadway are positioned on the same plane, the aperture of each large-diameter drill hole is larger than 100mm, the hole depth is the distance between the top plate side roadway and the top of the bottom plate side roadway, the adjacent distance is 1-2m, and the distance between an opening and the bottom plate of the top plate side roadway is 0.8-1.5 m; and a plurality of large-diameter drill holes on the bottom plate of the top plate side roadway are arranged in the middle of the bottom plate of the top plate side roadway, the corresponding hole diameter is larger than 100mm, and the hole depth is three times of the roadway width of the top plate side roadway.
Furthermore, a plurality of blast holes on the roadway on the side of the top plate are positioned at the left and right upper corners, the aperture of each blast hole is 42mm, the hole depth is 8-10m, and the adjacent distance is 5m-10 m;
furthermore, the large-diameter drill holes at the right side of the top plate side roadway are arranged at an elevation angle of 10-30 degrees, and the blast holes at the bottom plate of the top plate side roadway are arranged at a depression angle of 45 degrees.
Furthermore, the large-diameter drill holes arranged in the top plate side roadway and the blast holes arranged on the large-diameter drill holes are arranged at intervals along the roadway direction, and four large-diameter drill holes are arranged between every two blast holes.
Further, a plurality of blast holes on the bottom plate side roadway are positioned on the left side of the bottom plate side roadway in the step S2, each hole is 42mm in diameter, 8-10m in depth, 5m-10m in adjacent distance, 0.5-1.2m in hole opening to the bottom plate of the bottom plate side roadway and is arranged at a depression angle of 30-45 degrees.
Further, in step S3, if the pressure relief effect is poor, increasing the arrangement density of the large-diameter drill holes and the blast holes in the top plate side roadway and the arrangement density of the blast holes in the bottom plate side roadway;
and evaluating the pressure relief effect again after the construction is finished until the pressure relief effect is good.
Further, when the corresponding blasting holes on the top plate side roadway and the bottom plate side roadway are blasted, the number of the blasting holes in each time is not more than 6.
Compared with the prior art, the combined pressure relief method for blasting and large-diameter drilling of the steeply inclined super-thick hard coal seam is characterized in that
In the mining process of the steeply inclined extra-thick hard coal seam, the top plate side roadway and the bottom plate side roadway are arranged in a staggered manner, so that the staggered arrangement mode effectively improves the recovery rate on the existing working face and increases the economic benefit of the coal mine;
the method for forming combined pressure relief of blasting large diameter can reduce stress concentration and impact danger degree of steeply inclined coal seams, achieves better pressure relief effect on surrounding rocks and deep coal bodies of roadways and is more suitable for specificity of steeply inclined extremely thick hard coal seams;
the large-diameter drill holes and the blast holes are arranged at different positions, different installation parameters are arranged on a working surface, and a plurality of borehole stress meters are utilized to cover the whole roadway, so that the stress change of surrounding rock of the roadway is monitored, the monitored stress value is evaluated for pressure relief effect, and the pressure relief measure parameters are matched with the field conditions of the working surface;
drawings
FIG. 1 is an overall flow chart of the present invention;
FIG. 2 is a diagram of a blasting large aperture combined pressure relief arrangement of the present invention;
FIG. 3 is a layout of a stress monitoring system in the present invention;
in the figure: 1. the method comprises the following steps of coal seam roof, 2 working faces, 3 coal seam floor, 4 roof side roadway, 5 major diameter drilled hole, 6 blast hole, 7 floor side roadway, 8 drilling stress meter, 9 goaf.
Detailed Description
The invention will be further explained with reference to the drawings.
As shown in fig. 1, the combined pressure relief method for blasting and large-diameter drilling of the steeply inclined ultra-thick hard coal seam specifically comprises the following steps:
s1, in the mining process of the steeply inclined super-thick hard coal seam, the top plate side roadway 4 and the bottom plate side roadway 7 are arranged in a staggered mode, and a plurality of borehole stress meters 8 are installed on the two roadways and cover the whole roadway and are used for monitoring stress changes of surrounding rocks of the roadway;
s2, determining parameters of the hole diameter, the hole depth, the distance and the distance between the blast hole 6 and the large-diameter drill hole 5 from the bottom plate according to the mechanical properties of the coal body and the top and bottom plates of the coal seam, arranging the large-diameter drill hole 5 and the blast hole 6 in the top plate side roadway 4, and arranging the blast hole 6 in the bottom plate side roadway 7;
s3, after the construction of the large-diameter drill hole 5 and the large-diameter combined pressure relief drill hole of the blast hole 6 is finished, evaluating the pressure relief effect according to the stress value monitored by the drill hole stress meter 8, and if the pressure relief effect is poor, increasing the arrangement density of the large-diameter drill hole 5 and the blast hole 6 of the top plate side roadway 4 and the arrangement density of the blast hole 6 of the bottom plate side roadway 7;
and evaluating the pressure relief effect again after the construction is finished until the pressure relief effect is good.
The present invention will be further described with reference to the following examples.
In the mining process of the steeply inclined extra-thick hard coal seam, the top plate side roadway 4 and the bottom plate side roadway 7 are arranged in a staggered manner, preferably, the top plate side roadway 4 is arranged at the next layer of the bottom plate side roadway 7 in a staggered manner, so that the staggered arrangement mode effectively improves the recovery rate on the existing working face 2, and increases the economic benefit of a coal mine;
as shown in fig. 3, a plurality of borehole stress meters 8 are arranged on the roof side roadway 4 and the floor side roadway 7, the buried depth of each borehole stress meter 8 is 8-10m, and the distance between adjacent borehole stress meters is 5-30 m; monitoring the stress change of surrounding rocks of the roadway by covering the whole roadway;
considering the particularity of the mechanical properties of the steeply inclined super-thick hard coal seam, namely, the pressure relief of the blast holes 6 only affects the peripheral area of a roadway and cannot relieve deep stress of the super-thick coal seam, and the plastic area formed by the large-diameter drill holes 5 adopted by the hard coal seam cannot effectively relieve high stress and is easy to accumulate energy when a working face 2 is used for mining, so that the large-diameter drill holes 5 and the blast holes 6 are arranged in a top plate side roadway 4, and the blast holes 6 are arranged in a bottom plate side roadway 7, and the parameters of all the drill holes are determined;
as shown in fig. 2, preferably, the large-diameter drilled holes 5 on the roof side drifts 4 are respectively located on the right upper and the bottom plate thereof;
a plurality of large-diameter drill holes 5 on the right side of the roof side roadway 4 are positioned on the same plane, the aperture of each large-diameter drill hole 5 is larger than 100mm, the hole depth is the distance between the roof side roadway 4 and the top of the floor side roadway 7, the adjacent distance is 1-2m, and the distance between the hole opening and the bottom plate of the roof side roadway 4 is 0.8-1.5 m; a plurality of large-diameter drill holes 5 on the bottom plate of the roof side roadway 4 are arranged in the middle of the roof side roadway 4, the corresponding hole diameter is larger than 100mm, and the hole depth is three times of the roadway width of the roof side roadway 4;
a plurality of blast holes 6 on the top plate side roadway 4 are positioned at the left and right upper corners, the aperture of each blast hole 6 is 42mm, the hole depth is 8-10m, and the adjacent distance is 5m-10 m;
further, the large-diameter drill holes 5 at the right upper side of the top plate side roadway 4 are arranged at an elevation angle of 10-30 degrees, and the blast holes 6 at the bottom plate of the top plate side roadway 4 are arranged at a depression angle of 45 degrees.
Further, the large-diameter drill holes 5 arranged in the roof-side tunnel 4 and the blast holes 6 arranged thereon are arranged at intervals in the tunnel direction, that is, four large-diameter drill holes 5 are arranged between every two blast holes 6.
And a plurality of blast holes 6 on the bottom plate side roadway 7 are positioned on the left side of the bottom plate side roadway 7, each hole has the diameter of 42mm, the hole depth is 8-10m, the adjacent distance is 5m-10m, the hole opening is 0.5-1.2m on the bottom plate of the bottom plate side roadway 7 and is arranged at a depression angle of 30-45 degrees.
When the top plate side roadway 4 is provided with the large-diameter drill hole 5 and the blast hole 6, and the bottom plate side roadway 7 is provided with the blast hole 6, namely after the blasting large-diameter combined pressure relief drill hole construction is finished, evaluating the pressure relief effect according to the stress value monitored by the drill hole stress meter 8, and providing a judgment basis for judging whether pressure relief needs to be enhanced;
when the numerical value of the borehole stress meter 8 is greater than the monitoring early warning value, the numerical value is evaluated to be poor, the pressure relief measures are taken to increase the arrangement density of the large-diameter boreholes 5 and the blast holes 6 of the top plate side roadway 4 and the arrangement density of the blast holes 6 of the bottom plate side roadway 7, and the pressure relief effect is evaluated again after the construction is finished until the pressure relief effect is good;
and when the numerical value of the borehole stress meter 8 is smaller than the monitoring early warning value, the result is evaluated to be good.
When the corresponding blasting holes 6 on the roof side roadway 4 and the floor side roadway 7 are blasted, the number of the blasting holes in each time is not more than 6.
The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined super-thick hard coal seam has important engineering significance and great economic benefit in the aspects of efficient pressure relief of the working face 2, safe production of a coal mine, reasonable benefit improvement and the like, and has wide application prospect.
Claims (10)
1. A combined pressure relief method for blasting and large-diameter drilling of a steep and extremely-thick hard coal seam is characterized by comprising the following steps:
s1, in the mining process of the steeply inclined super-thick hard coal seam, a roof side roadway (4) and a floor side roadway (7) are arranged in a staggered manner, and a plurality of borehole stressometers (8) are arranged on the two roadways and cover the whole roadway and are used for monitoring the stress change of surrounding rocks of the roadways;
s2, determining parameters of the hole diameter, the hole depth, the distance and the position from the bottom plate of the blast hole (6) and the large-diameter drill hole (5) according to the mechanical properties of the coal body and the coal seam roof and bottom plate, arranging the large-diameter drill hole (5) and the blast hole (6) in the roof side roadway (4), and arranging the blast hole (6) in the bottom plate side roadway (7);
s3, after the blast hole (6) and the large-diameter drill hole (5) are constructed, evaluating the pressure relief effect according to the stress value monitored by the drill hole stress meter (8);
when the numerical value of the drilling stress meter (8) is larger than the monitoring early warning value, the evaluation is poor, and when the numerical value of the drilling stress meter (8) is smaller than the monitoring early warning value, the evaluation is good.
2. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined super-thick hard coal seam according to claim 1, wherein the roof-side roadway (4) is staggered and arranged at the next level of the floor-side roadway (7) in step S1.
3. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined super-thick hard coal seam according to claim 2, wherein the burial depth of each borehole stress gauge (8) in step S1 is 8-10m, and the distance between adjacent boreholes is 5-30 m.
4. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined ultra-thick hard coal seam according to any one of claims 1 to 3, wherein the large-diameter drilling (5) in the roof side roadway (4) in the step S2 is respectively positioned on the right upper side and the bottom plate thereof;
a plurality of large-diameter drill holes (5) on the right upper of the roof side roadway (4) are positioned on the same plane, the aperture of each large-diameter drill hole (5) is larger than 100mm, the hole depth is the distance between the roof side roadway (4) and the top of the floor side roadway (7), the adjacent distance is 1-2m, and the distance between the hole opening and the floor of the roof side roadway (4) is 0.8-1.5 m; a plurality of large-diameter boreholes (5) are arranged in the middle of the floor of the roof-side drift (4), the corresponding bore diameter is greater than 100mm, and the bore depth is three times the drift width of the roof-side drift (4).
5. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined and extremely thick hard coal seam according to claim 4, characterized in that a plurality of blast holes (6) in the top plate side roadway (4) are positioned at the left and right highwall corners, the diameter of each blast hole (6) is 42mm, the depth of each blast hole is 8-10m, and the adjacent distance is 5m-10 m.
6. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined ultra-thick hard coal seam according to claim 5, characterized in that the large-diameter drilling (5) at the right upper side of the roof side roadway (4) is arranged at an elevation angle of 10-30 degrees, and the blast hole (6) at the bottom plate of the roof side roadway (4) is arranged at a depression angle of 45 degrees.
7. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined ultra-thick hard coal seam according to claim 6, characterized in that the large-diameter drilling holes (5) arranged in the roof side roadway (4) and the blasting holes (6) arranged thereon are arranged at intervals along the roadway direction, and four large-diameter drilling holes (5) are arranged between every two blasting holes (6).
8. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined super-thick hard coal seam according to claim 7, wherein the plurality of blast holes (6) in the bottom plate side roadway (7) in the step S2 are located at the left upper side of the bottom plate side roadway, each blast hole has a hole diameter of 42mm, a hole depth of 8-10m, adjacent intervals of 5m-10m, and a hole opening is 0.5-1.2m on the bottom plate of the bottom plate side roadway (7) and is arranged at a depression angle of 30-45 degrees.
9. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined super-thick hard coal seam according to any one of claims 1 to 3, wherein in step S3, if the pressure relief effect is poor, the arrangement density of the large-diameter drilling holes (5) and the blast holes (6) of the roof side roadway (4) and the arrangement density of the blast holes (6) of the floor side roadway (7) are increased;
and evaluating the pressure relief effect again after the construction is finished until the pressure relief effect is good.
10. The combined pressure relief method for blasting and large-diameter drilling of the steeply inclined and extremely thick hard coal seam according to claim 9, characterized in that when the corresponding blast holes (6) in the roof side drift (4) and the floor side drift (7) are blasted, the number of the blast holes per time does not exceed 6.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN114320268A (en) * | 2021-12-20 | 2022-04-12 | 山东唐口煤业有限公司 | Large-diameter drilling pressure relief effect evaluation method based on drilling stress monitoring |
CN117662150A (en) * | 2024-02-01 | 2024-03-08 | 矿冶科技集团有限公司 | Full life cycle unloading mining method for deep ore body |
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CN110529116A (en) * | 2019-09-27 | 2019-12-03 | 中国矿业大学(北京) | A kind of method that large diameter borehole realizes nearly horizontal high seam top hard coal reduction |
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2021
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CN104989405A (en) * | 2015-06-12 | 2015-10-21 | 北京科技大学 | Large-dip-angle coal mining rock burst orientation prevention method |
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CN117662150A (en) * | 2024-02-01 | 2024-03-08 | 矿冶科技集团有限公司 | Full life cycle unloading mining method for deep ore body |
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Application publication date: 20211207 |