CN112229369A

CN112229369A - Orifice positioning device for rapidly giving drilling azimuth angle device and using method

Info

Publication number: CN112229369A
Application number: CN202011026863.8A
Authority: CN
Inventors: 罗文兵; 赵建明; 王吉斌
Original assignee: Guizhou Panjiang Refined Coal Co Ltd
Current assignee: Guizhou Panjiang Refined Coal Co Ltd
Priority date: 2020-09-25
Filing date: 2020-09-25
Publication date: 2021-01-15
Anticipated expiration: 2040-09-25
Also published as: CN112229369B

Abstract

The invention discloses an orifice positioning device for quickly setting a drilling azimuth angle device, which comprises: the framework air bag is a cylindrical air bag with an inflation inlet, is in a circular arch shape after being filled with air, and is matched with the edge of the working surface; the orifice positioning surface is provided with 6 rows and 7 columns of circular hole rectangular arrays, the orifice positioning surface is fixedly connected with the lower surface of the skeleton air bag, and the orifice positioning surface is completely unfolded after the skeleton air bag is filled with air; the central hole is formed in the arc center of the orifice positioning surface; and the inflating device is communicated with an inflating opening of the skeleton air bag. The problem that the prior art is large in size and weight and difficult to move in a roadway is solved.

Description

Orifice positioning device for rapidly giving drilling azimuth angle device and using method

Technical Field

The invention relates to the technical field of hole opening positioning, in particular to a hole opening positioning device for quickly setting a drilling azimuth angle device and a using method.

Background

When a gas extraction borehole is constructed on a goaf (roadway) coal uncovering and tunneling working face or in a drill site, the azimuth angle of the borehole is set to be crucial, and the correct set azimuth angle of a rotary hole is an important factor for measuring the control range of the borehole. In the prior art, a compass is usually adopted to directly set a horizontal included angle between a drill hole and a central line, then a slope gauge is used to set a vertical included angle between the drill hole and the central line, and an azimuth angle of the drill hole is obtained after the horizontal included angle and the vertical included angle are set.

However, in the prior art, the fact that the tunneling working face is often provided with a plurality of ironware which are magnetic can seriously affect the accuracy of the compass, the horizontal included angle between a drill hole and a central line is inaccurate, and the final azimuth angle of the drill hole is inaccurate.

In order to solve the above problems, the inventor has developed a device for rapidly azimuth-setting a borehole, the device comprising: the orifice positioning device is detachably mounted on a working surface, and a 6-row and 7-column circular hole rectangular array is arranged on the orifice positioning device; the center line positioning device comprises a fixing plate and a first laser, the first laser is arranged on the fixing plate, and the central axis of the first laser is perpendicular to the front surface of the fixing plate; the intersection point positioning device comprises a distance meter, a first frame body and an intersection point positioning hole, wherein the intersection point positioning hole is formed in the first frame body, and the distance meter is arranged on the first frame body; the drill rod guide device comprises a second laser and a universal mechanism, the second laser is movably connected to the first frame body through the universal mechanism, and the central axis of the second laser passes through the center of the intersection point positioning hole.

In practice, the applicant has found that the orifice positioning device, if used with a conventional solid rack, can be relatively bulky and heavy and difficult to move within the roadway.

Disclosure of Invention

To address the above shortcomings and deficiencies of the prior art, it is an object of the present invention to provide an aperture locating device and method of use for a fast given borehole azimuth device.

The technical scheme of the invention is as follows: an aperture locating device for a fast given borehole azimuth device, comprising:

the framework air bag is a cylindrical air bag with an inflation inlet, is in a circular arch shape after being filled with air, and is matched with the edge of the working surface;

the orifice positioning surface is provided with 6 rows and 7 columns of circular hole rectangular arrays, the orifice positioning surface is fixedly connected with the lower surface of the skeleton air bag, and the orifice positioning surface is completely unfolded after the skeleton air bag is filled with air;

the central hole is formed in the arc center of the orifice positioning surface;

and the inflating device is communicated with an inflating opening of the skeleton air bag.

Further, the inflator includes:

the first reaction bottle is used for placing citric acid solution;

a second reaction bottle, wherein a baking soda solution is placed in the second reaction bottle;

the two ends of the first communicating pipe are respectively communicated with the bottoms of the first reaction bottle and the second reaction bottle;

the first valve is arranged in the middle of the first communication pipe;

and the gas outlet is arranged at the upper part of the second reaction bottle and is communicated with the inflation inlet of the skeleton air bag.

Further, still include:

and the defoaming sponge is arranged at the upper part of the liquid level of the baking soda in the second reaction bottle.

Further, still include:

and the second one-way check valve is arranged on the air outlet, and the conduction direction of the second one-way check valve is from the inside of the second reaction bottle to the outside of the second reaction bottle.

Further, still include:

a second valve disposed on the air outlet.

A method of using an aperture locating device for a fast given borehole azimuth device, the method comprising: and opening the first valve to inflate the framework air bag, fixing the orifice positioning device in the roadway, enabling the orifice positioning surface to be tightly attached to the working surface and be parallel to the working surface, and marking 6 rows and 7 columns of circular orifice rectangular arrays on the working surface according to the circular orifice rectangular arrays on the orifice positioning surface to obtain the orifices of the drilled holes.

The invention has the beneficial effects that: compared with the prior art, the method has the advantages that,

1) the invention uses the inflator to inflate the skeleton airbag to fix the orifice positioning surface on the working surface, so that the orifice positioning surface directly positions the orifice position, marks the corresponding working surface according to the rectangular array of the round holes on the orifice positioning surface to quickly obtain the orifice position, and marks the position of the arc central point at the upper part of the working surface through the central hole, so that the central line positioning device is more quickly and conveniently installed, the skeleton is raised in waves, the orifice positioning surface can be folded and retracted when not inflated, the size and the weight are smaller, and the carrying is convenient;

2) according to the invention, the mixing of citric acid and baking soda is realized through the first valve switch, so that carbon dioxide is generated and supplied to the skeleton air bag for inflation;

3) in the invention, bubbles generated when citric acid and sodium bicarbonate are mixed are eliminated through the defoaming sponge, and splashed water drops are prevented from entering a pipeline communicated with the skeleton air bag in the second reaction bottle to corrode the skeleton air bag;

4) the second one-way check valve prevents gas from coming out of the skeleton air bag, so that the air pressure of the skeleton air bag is reduced, and the orifice is not accurately positioned or the skeleton air bag is not stably fixed;

5) the air pressure of the framework air bag is controlled through the second valve, and the second valve is closed after the air pressure is enough;

6) according to the invention, the framework air bag is inflated by opening the first valve, the orifice positioning device is fixed in the roadway, the orifice positioning surface is tightly attached to the working surface and is parallel to the working surface, 6 rows and 7 columns of circular orifice rectangular arrays are marked on the working surface according to the circular orifice rectangular arrays on the orifice positioning surface, and the drilled orifices are obtained, so that the orifice position positioning is rapid and convenient, and the measuring operation is not required.

Drawings

FIG. 1 is a front view of a roadway according to the present invention;

FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1;

fig. 3 is a front view of the orifice positioning device of the present invention;

FIG. 4 is a partial view at B of FIG. 3;

FIG. 5 is a cross-sectional view taken along line C-C of FIG. 4;

FIG. 6 is a perspective view of the orifice positioning device of the present invention;

FIG. 7 is a partial view taken at H in FIG. 6;

FIG. 8 is a perspective view of the centerline positioning device of the present invention;

FIG. 9 is a perspective view of an aligner of the present invention;

FIG. 10 is a partial view taken at D of FIG. 9;

FIG. 11 is a perspective view of the intersection locating device of the present invention;

FIG. 12 is a partial view at G of FIG. 11;

FIG. 13 is a perspective view of the drilling rig of the present invention;

FIG. 14 is a partial view taken at F of FIG. 13;

FIG. 15 is a block diagram of the electrical connections at the first controller of the present invention;

fig. 16 is a block diagram of the circuit connection at the second controller of the present invention.

Detailed Description

The invention will be further described with reference to the following drawings and specific embodiments:

example 1 was carried out: the embodiment provides an orifice positioning device for quickly setting a drilling azimuth angle device, which comprises: the framework air bag 301 is a cylindrical air bag with an inflation inlet, the framework air bag 301 is in a circular arch shape after being filled with air, and the framework air bag 301 is matched with the edge of the working surface; the orifice positioning surface 302 is provided with 6 rows and 7 columns of circular hole rectangular arrays 303, the orifice positioning surface 302 is connected with the lower surface of the framework air bag 301 in an adhesive manner, and the orifice positioning surface 302 is completely unfolded after the framework air bag 301 is filled with air; a central hole 304, wherein the central hole 304 is opened at the center of the circular arc on the orifice positioning surface 302; and the inflating device is communicated with an inflating opening of the skeleton air bag 301.

Further, the inflator includes: a first reaction bottle 305, wherein a citric acid solution is placed in the first reaction bottle 305; a second reaction bottle 306, wherein the second reaction bottle 306 is filled with a sodium bicarbonate solution; a first communicating pipe 307, wherein two ends of the first communicating pipe 307 are respectively communicated with the bottoms of the first reaction bottle 305 and the second reaction bottle 306; a first valve 309, the first valve 309 being disposed in the middle of the first communication pipe 307; and the air outlet 310 is arranged at the upper part of the second reaction bottle 306, and the air outlet 310 is communicated with the inflation inlet of the skeleton air bag 301.

Further, still include: and a defoaming sponge 313, wherein the defoaming sponge 313 is arranged at the upper part of the liquid level of the baking soda in the second reaction bottle 306.

Further, still include: and the second one-way check valve 311 is arranged on the air outlet 310, and the conduction direction of the second one-way check valve 311 is from the inside of the second reaction bottle 306 to the outside of the second reaction bottle 306.

Further, still include: and a second valve 312, the second valve 312 being disposed on the air outlet 310.

A method of using an aperture locating device for a fast given borehole azimuth device, the method comprising: and opening the first valve 309 to inflate the skeleton airbag 301, fixing the orifice positioning device 3 in the roadway 1, enabling the orifice positioning surface 302 to be tightly attached to the working surface and be parallel to the working surface, and marking 6 rows and 7 columns of circular orifice rectangular arrays 303 on the working surface according to the circular orifice rectangular arrays 303 on the orifice positioning surface 302 to obtain drilled orifices.

Example 2 was carried out: the embodiment provides a device for rapidly giving a drilling azimuth angle, which comprises: the orifice positioning device 3 is detachably mounted on a working surface, and 6 rows and 7 columns of circular hole rectangular arrays 303 are arranged on the orifice positioning device 3; the center line positioning device 304 comprises a fixing plate 201 and a first laser 202, wherein the first laser 202 is arranged on the fixing plate 201, and the central axis of the first laser 202 is perpendicular to the front surface of the fixing plate 201; the intersection point positioning device 5 comprises a distance meter 507, a first frame body and an intersection point positioning hole 506, wherein the intersection point positioning hole 506 is arranged on the first frame body, and the distance meter 507 is arranged on the first frame body; the drill rod guiding device comprises a second laser 510 and a universal mechanism, the second laser 510 is movably connected to the first frame body through the universal mechanism, and the central axis of the second laser 510 passes through the center of the intersection point positioning hole 506.

Further, the orifice positioning device 3 includes: the framework air bag 301 is a cylindrical air bag with an inflation inlet, the framework air bag 301 is in a circular arch shape after being filled with air, and the framework air bag 301 is matched with the edge of the working surface; the orifice positioning surface 302 is provided with 6 rows and 7 columns of circular hole rectangular arrays 303, the orifice positioning surface 302 is connected with the lower surface of the framework air bag 301 in an adhesive manner, and the orifice positioning surface 302 is completely unfolded after the framework air bag 301 is filled with air; a central hole 304, wherein the central hole 304 is opened at the center of the circular arc on the orifice positioning surface 302;

and the inflating device is communicated with an inflating opening of the skeleton air bag 301.

Further, the centerline positioning device 304 further comprises: the calibration table 204 is welded on the upper part of the fixed plate 201, and the upper surface of the calibration table 204 is vertical to the front surface of the fixed plate 201; a first level 205, the first level 205 being disposed on an upper surface of the calibration stand 204.

Further, the centerline positioning device 304 further comprises: the supporting legs 203, the supporting legs 203 include 3, and the supporting legs 203 is connected on the fixed plate 201, and the supporting legs 203 are evenly distributed around the axis of the first laser 202.

Further, the supporting foot 203 includes: a fixing nail 2032, wherein one end of the fixing nail 2032 is pointed; the adjusting rod 2031 is provided, one end of the adjusting rod 2031 is rotatably connected with the fixing nail 2032, the end of the fixing nail 2032 connected with the adjusting rod 2031 is opposite to the pointed end of the fixing nail 2032, the outer surface of the adjusting rod 2031 is provided with an external thread, and the adjusting rod 2031 is in threaded connection with the fixing plate 201.

Further, the centerline positioning device 304 further comprises: calibrator 4, calibrator 4 includes second support body 401 and center pointer 402, second support body 401 and 1 section phase-match in tunnel, center pointer 402 sets up the central point department at second support body 401 upper portion circular arc.

Further, the calibrator 4 further includes: a first controller 406; a photosensor 403, the photosensor 403 being disposed at the central indicator point 402, the photosensor 403 being wired to the first controller 406; a first signal lamp 405, the first signal lamp 405 being wired to the first controller 406. The first controller 406 may be a PLC, Arduino, raspberry pi, or other controller with peripheral circuitry.

Further, the calibrator 4 further includes: perpendicularity checking mechanisms 404, the perpendicularity checking mechanisms 404 include more than 3, and the perpendicularity checking mechanisms 404 are arranged on the left side, the right side and the upper side of the second frame body 401.

Further, the perpendicularity checking mechanism 404 includes: the guide groove 4041 is connected to the left side, the right side and the upper side of the second frame body 401 in a welding manner, the length direction of the guide groove 4041 passes through the center point of the arc at the upper part of the second frame body 401, and the guide groove 4041 is parallel to the plane where the second frame body 401 is located; the L-shaped inspection rod 4042 comprises a guide rod 40422 and a measuring rod 40421, one end of the guide rod 40422 is connected with one end of the measuring rod 40421 in a welding mode, the guide rod 40422 and the measuring rod 40421 are perpendicular to each other, the guide rod 40422 is matched with the guide groove 4041, the guide rod 40422 is slidably mounted on the guide groove 4041, and the end of the guide rod 40422 connected with the measuring rod 40421 is located at one end far away from the center point of the arc at the upper part of the second frame body 401.

Further, the verticality checking mechanism 404 further includes: and one end of the pressure spring 4043 is connected with one end of the guide groove 4041 close to the central point of the upper arc of the second frame body 401, and the other end of the pressure spring 4043 is connected with the guide rod 40422.

Further, the first frame body includes: the triangular support comprises supporting legs 501 and an operating platform 502, three supporting legs 501 of the triangular support are telescopic rods, the three supporting legs 501 are connected to the lower surface of the operating platform 502 through hinges, and the three supporting legs 501 are uniformly distributed around the central axis of the operating platform 502; the lower end of the lifting rod 503 is welded to the upper surface of the operating platform 502, and the central axis of the lifting rod 503 is perpendicular to the upper surface of the operating platform 502; friction formula rotation axis 504, friction formula rotation axis 504 is installed in lifter 503 upper end, and nodical locating hole 506 welded connection is in friction formula rotation axis 504 upper end, and nodical locating hole 506 axis is perpendicular with friction formula rotation axis 504 axis.

Further, the intersection point positioning device 5 further includes: and one end of the U-shaped frame 506 is connected to the friction type rotating shaft 504, the other end of the U-shaped frame 506 is connected with a distance meter 507, and the distance meter 507 is positioned right above the intersection point positioning hole 506.

Further, the gimbal mechanism includes: an intersection point positioning ball 508, wherein the intersection point positioning hole 506 is opened on the intersection point positioning ball 508, the intersection point positioning hole 506 passes through the spherical center of the ferromagnetic spherical ball, and the intersection point positioning ball 508 is made of ferromagnetic material; magnetic base 509, magnetic base 509 one end be with nodical location ball 508 surface assorted concave sphere, magnetic base 509 passes through concave sphere magnetism and inhales at nodical location ball 508 surface, magnetism and inhales base other end welded connection second laser instrument 510 bottom, and magnetic base 509 axis passes nodical location ball 508's centre of sphere, and second laser instrument 510 axis and magnetic base 509 axis coincide.

Further, the drill rod guide device further comprises: the azimuth correction hole 511 is arranged on the drilling machine 6, and the central axis of the azimuth correction hole 511 is superposed with the central axis of a drill rod 601 of the drilling machine 6; a second controller 513; an optoelectronic switch 514, wherein the optoelectronic switch 514 is arranged at the bottom of the azimuth correction hole 511 close to one end of the drill pipe 601, and the optoelectronic switch 514 is connected with a lead of the second controller 513; and a second signal lamp 512, wherein the second signal lamp 512 is in wire connection with a second controller 513. The second controller 513 may be a PLC, Arduino, raspberry pi, or other controller with peripheral circuitry.

A method of rapidly giving a borehole azimuth, the method comprising the steps of:

s01, installing the calibrator 4 in the roadway 1, wherein the distance between the calibrator 4 and the working surface is greater than the intersection point distance, and the plane where the second frame body 401 is located is parallel to the working surface;

s02, driving the fixing nail 2032 into the center point of the circular arc on the working surface, rotating the adjusting rod 2031 to make the first level 205 on the calibration stand 204 in a horizontal state, and irradiating the laser emitted by the first laser 202 onto the photoelectric sensor 403 to make the first signal lamp 405 light, and finally making the center line pass through the center point of the circular arc on the upper portion of the arch tunnel 1;

s03, opening the first valve 309, inflating the skeleton airbag 301, fixing the orifice positioning device 3 in the roadway 1, enabling the orifice positioning surface 302 to be tightly attached to the working surface and to be parallel to the working surface, and marking 6 rows and 7 columns of circular orifice rectangular arrays 303 on the working surface according to the circular orifice rectangular arrays 303 on the orifice positioning surface 302 to obtain drilled orifices;

s04, calculating the hole bottom position of each drill hole;

s05, connecting the hole bottom position of the drilled hole with the hole opening position of the drilled hole on the working surface, calculating the distance d from the intersection point to the working surface by the intersection point of the extension line of the connection line and the projection of the central line on the horizontal plane;

s06, arranging an intersection point positioning device 5 at a position d away from the working surface, and enabling laser emitted by the first laser 202 to pass through the intersection point positioning hole 506;

s07, adjusting the orientation of the second laser 510 to enable the laser emitted by the second laser 510 to be directed to the hole;

and S08, adjusting the drilling machine 6 to enable the laser emitted by the second laser 510 to pass through the azimuth correction hole 511 and irradiate the photoelectric switch 514, and when the second signal is on, fixing the angle of the drilling machine 6 to enable the drilling machine 6 to drill in the pointing direction of the drill rod guide device by aligning the drill rod 601 of the drilling machine 6 with the hole.

The invention has the advantages that the method has the advantages that,

1) according to the invention, the framework airbag 301 is inflated by using the inflating device to fix the orifice positioning surface 302 on the working surface, so that the orifice positioning surface 302 directly positions the orifice position, the corresponding working surface is marked according to the circular hole rectangular array 303 on the orifice positioning surface 302, the orifice position is quickly obtained, and the position of the arc central point at the upper part of the working surface is marked through the central hole 304, so that the central line positioning device 304 is more quickly and conveniently installed, the framework wave and the orifice positioning surface 302 can be folded and retracted when not inflated, the size and the weight are smaller, and the carrying is convenient;

2) according to the invention, the mixing of citric acid and baking soda is realized through the opening and closing of the first valve 309, so that carbon dioxide is generated and supplied to the skeleton air bag 301 for inflation;

3) in the invention, bubbles generated when citric acid and sodium bicarbonate are mixed are eliminated through the defoaming sponge 313, and splashed water drops are prevented from entering a pipeline communicated with the skeleton air bag 301 of the second reaction bottle 306 to corrode the skeleton air bag 301;

4) according to the invention, the second one-way check valve 311 is used for preventing gas from coming out of the skeleton air bag 301, so that the air pressure of the skeleton air bag 301 is reduced, and the orifice is not positioned accurately or the skeleton air bag 301 is not fixed stably;

5) the air pressure of the skeleton air bag 301 is controlled through the second valve 312, and the second valve 312 is closed after the air pressure is enough;

6) according to the invention, the framework air bag 301 is inflated by opening the first valve 309, so that the orifice positioning device 3 is fixed in the roadway 1, the orifice positioning surface 302 is tightly attached to the working surface and is parallel to the working surface, 6 rows and 7 columns of circular hole rectangular arrays 303 are marked on the working surface according to the circular hole rectangular arrays 303 on the orifice positioning surface 302, and the orifices of the drill holes are obtained, so that the orifice position positioning is rapid and convenient, and the measurement operation is not required.

The foregoing is a more detailed description of the invention in connection with specific preferred embodiments and it is not intended that the invention be limited to these specific details. For those skilled in the art to which the invention pertains, several simple deductions or substitutions can be made without departing from the spirit of the invention, and all shall be considered as belonging to the protection scope of the invention.

Claims

1. An aperture locating device for a fast given borehole azimuth device, comprising:

the framework air bag (301), the framework air bag (301) is a cylindrical air bag with an inflation inlet, the framework air bag (301) is in a circular arch shape after being filled with air, and the framework air bag (301) is matched with the edge of the working surface;

the air bag structure comprises an orifice positioning surface (302), wherein the orifice positioning surface (302) is provided with 6 rows and 7 columns of circular hole rectangular arrays (303), the orifice positioning surface (302) is fixedly connected with the lower surface of a framework air bag (301), and the orifice positioning surface (302) is completely unfolded after the framework air bag (301) is filled with air;

a central aperture (304), the central aperture (304) opening at a circular arc center on the orifice locating face (302);

and the inflating device is communicated with an inflating opening of the skeleton air bag (301).

2. The apparatus of claim 1, wherein said inflation means comprises:

a first reaction bottle (305), wherein a citric acid solution is placed in the first reaction bottle (305);

a second reaction bottle (306), wherein the second reaction bottle (306) is internally provided with a baking soda solution;

the two ends of the first communication pipe (307) are respectively communicated with the bottoms of the first reaction bottle (305) and the second reaction bottle (306);

a first valve (309), the first valve (309) being disposed in the middle of the first communication pipe (307);

and the air outlet (310) is arranged at the upper part of the second reaction bottle (306), and the air outlet (310) is communicated with an inflation inlet of the framework air bag (301).

3. The apparatus of claim 2, further comprising:

and the defoaming sponge (313), the defoaming sponge (313) is arranged at the upper part of the liquid level of the baking soda in the second reaction bottle (306).

4. The apparatus of claim 2, further comprising:

and the second one-way check valve (311) is arranged on the air outlet (310), and the conduction direction of the second one-way check valve (311) is from the inside of the second reaction bottle (306) to the outside of the second reaction bottle (306).

5. An aperture locating device for a fast given borehole azimuth device according to any of claims 2 to 4, further comprising:

a second valve (312), the second valve (312) being disposed on the air outlet (310).

6. Use of an aperture positioning device for a fast given borehole azimuth device according to claim 5, characterized in that the method is: and opening the first valve (309), inflating the framework air bag (301), fixing the orifice positioning device (3) in the roadway (1), enabling an orifice positioning surface (302) to be tightly attached to the working surface and be parallel to the working surface, and marking 6 rows and 7 columns of circular orifice rectangular arrays (303) on the working surface according to the circular orifice rectangular arrays (303) on the orifice positioning surface (302) to obtain drilled orifices.