KR102627840B1 - Apparatus for blasting and method having the same - Google Patents

Abstract

The present invention relates to a blasting device, comprising: a gunpowder unit that destroys an object to be blasted through explosion by gunpowder reaction; an air pipe portion formed outside the gunpowder portion and having a predetermined space for receiving air; and a non-explosive part that improves the explosive power of the explosive part, wherein the non-explosive part is provided outside the explosive part.

Description

Blasting device and blasting method including the same {Apparatus for blasting and method having the same}

The present invention relates to a blasting device and a blasting method including the same, and more specifically, to a blasting device using an air tube and a blasting method including the same.

As industrialization progresses and urban concentration accelerates, civil engineering work is required to secure large-scale housing, roads, and factory sites. In such civil engineering construction, a process for removing the bedrock layer is essential. In other words, in order to crush rock to an appropriate size in civil engineering work, a rock crusher or gunpowder is usually used. In particular, when using gunpowder, a hole is formed in the target rock to a predetermined depth and the inside of the hole is filled with gunpowder. , a detonator connected to a connection line that can give impact to the gunpowder is installed, and the gunpowder is exploded by the detonator, blasting the rock layer.

Specifically, the method of blasting a rock layer using gunpowder is a drilling process of forming a plurality of drilling holes at regular intervals in a blasting object, such as a rock, and the inside of the drilling holes formed in a blasting object, such as a rock, through the drilling process. An explosive charging process in which explosives combined with a detonator are sequentially charged, a coloring process in which the upper part of the hole where the explosive is charged is sealed with gravel through the explosive charging process, and the lower part of the hole whose upper part is sealed through the coloring process. It is accomplished through a detonation process in which the explosives located in are detonated using a blaster.

The above blasting method is a general blasting method, and this blasting method generates significant vibration and explosion noise, has a risk of scattering, is uneconomical, and has problems with stability. In order to make up for the shortcomings of this general blasting method, a blasting method using a dispersed charge was developed in which explosives and spreaders are alternately arranged and blasted within a perforated hole. In addition, a line crack blasting method for the purpose of organizing the beveled surface and a charge blasting method were developed. There are various blasting methods, such as rock blasting using an air deck filled with rocks that forms an air deck space between the explosive and the explosive or between the explosive and the spreader inside the ball.

In such rock blasting, air decking is a technology that reduces the amount of explosives used and reduces the vibration and noise generated during blasting by blasting explosives in a space that functions as an element surface within a drilled hole in the rock. .

As a representative conventional air decking technology, a plug is installed between the flash material and the explosive to prevent explosive power from leaking through the blast hole during an explosion. This plug is made of a flexible, string-shaped material called a cap. The shape is installed in the blast hole to form an air layer, reduce stone and explosion noise during blasting, and increase the degree of crushing.

Meanwhile, in various rock blasting methods using these gunpowders, there are regulations on explosives in the country for various purposes such as stability. In particular, there are quantitative restrictions on explosives, and there is always a goal to enhance the performance of explosives, improve economic efficiency, and reduce vibration and noise within the scope of these regulations.

Therefore, in the industry, when using the above gunpowder, various, continuous and active efforts are being made to strengthen the performance of the gunpowder, improve economic efficiency, and reduce vibration and noise within the range of the quantity of gunpowder regulated by the country. Research and development are currently underway.

The present invention was created to solve the problems of the prior art as described above, and the purpose of the present invention is to provide a blasting device that can amplify gunpowder performance while avoiding the scope of gunpowder quantity regulation and a blasting method including the same. .

A blasting device according to an embodiment of the present invention includes a gunpowder unit that destroys an object to be blasted through an explosion by a gunpowder reaction; an air pipe portion formed outside the gunpowder portion and having a preset space for receiving air; and a non-explosive part that improves the explosive power of the explosive part, wherein the non-explosive part is provided outside the explosive part.

Specifically, the air pipe portion may be formed to be disposed closer to the outer side of the hole than the explosive portion when inserted into the hole formed in the object to be blasted.

Specifically, the non-explosive part may be formed of aluminum.

Specifically, the non-explosive part may be formed integrally with the air pipe part.

Specifically, the non-explosive portion may be formed to surround the explosive portion.

Specifically, the non-explosive part may extend downward along the outer periphery of the air pipe part, and may be formed to have a hollow shape on the inside to surround the explosive part.

Specifically, the non-explosive portion may be formed to be surrounded by the explosive portion.

Specifically, the non-explosive part may extend in the shape of a rod to the lower side of the air pipe part and be formed to be inserted into the explosive part.

Specifically, the explosive part may have a concave concave portion so that the non-explosive part is inserted.

Specifically, the non-explosive part may be formed in the preset space of the air pipe part.

A blasting method according to an embodiment of the present invention includes forming at least one perforation in an object to be blasted; Placing the blasting device in a hole formed in the object to be blasted; blackening the entrance of the perforation; and operating the blasting device to destroy the object to be blasted.

The blasting device according to an embodiment of the present invention and the blasting method including the same have the effect of amplifying gunpowder performance while avoiding the quantity regulation range of gunpowder by disposing aluminum outside the gunpowder.

In addition, the blasting device according to an embodiment of the present invention and the blasting method including the same have the effect of reducing blast pressure, scattering, vibration, and noise generated during blasting by disposing aluminum in the air pipe.

In addition, the blasting device according to an embodiment of the present invention and the blasting method including the same are formed so that aluminum surrounds the gunpowder part or is formed to surround the gunpowder part, thereby enhancing the gunpowder performance while efficiently using the space inside the perforation. It has the effect of effectively reducing vibration and noise.

Figure 1 is a conceptual diagram schematically showing a plurality of holes drilled in a blast material.
Figure 2 is a conceptual diagram of a blasting device according to an embodiment of the present invention mounted on a hole.
Figure 3 is a conceptual diagram schematically showing a blasting device according to an embodiment of the present invention.
Figure 4 is a conceptual diagram schematically showing a blasting device according to another embodiment of the present invention.
Figure 5 is a conceptual diagram schematically showing a blasting device according to another embodiment of the present invention.
Figure 6 is a flowchart of a blasting method using a blasting device according to an embodiment of the present invention.

The objectives, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments taken in conjunction with the accompanying drawings. In this specification, when adding reference numbers to components in each drawing, it should be noted that identical components are given the same number as much as possible even if they are shown in different drawings. Additionally, in describing the present invention, if it is determined that a detailed description of related known technologies may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The detailed description below will be described in detail together with the drawings shown below.

Figure 1 is a conceptual diagram schematically showing a plurality of holes drilled in a material to be blasted, Figure 2 is a conceptual diagram showing a blasting device according to an embodiment of the present invention mounted on the hole, and Figure 3 is a blasting device according to an embodiment of the present invention. 4 is a conceptual diagram schematically showing a blasting device according to another embodiment of the present invention, and FIG. 5 is a conceptual diagram schematically showing a blasting device according to another embodiment of the present invention.

As shown in Figures 1 to 5, the blasting device 1 according to the present invention includes an explosive part 10, an air tube part 20, a non-explosive part 30, a detonator 40, and a color sealing part 50. Includes.

Hereinafter, the blasting device 1 according to the present invention having the above configurations will be described in detail.

First, the blasting device 1 according to the present invention may be formed, for example, with a housing 1a extending between the upper part 1b and the lower part 1c. Alternatively, the blasting device 1 may be configured to be positioned within the perforation H without the housing 1a between the upper part 1b and the lower part 1c. In this case, only the air pipe portion 20, which will be described later, may have a separate housing.

The housing 1a is sized to be inserted into the hole H formed in the ground G (to-be-blasted material) and, for example, may have a long cylindrical shape. In other words, the housing (1a) can be manufactured by cutting to fit the diameter and depth of the perforation (H), or can be standardized into various sizes and used selectively.

In addition, the housing 1a may form a chamber in which the gunpowder part 10, the air tube part 20, and the non-explosive part 30, which will be described later, can be included. At this time, the explosive part 10 is arranged at the bottom, followed by the air tube part 20, and the arrangement position of the non-explosive part 30 may vary depending on the embodiment.

The housing 1a may include an internal fixing part (not shown) and an external fixing part (not shown) to facilitate fixation after insertion into the hole H.

The internal fixing part may be formed on the lowermost side of the housing 1a and have a protruding shape that can be inserted and fixed into the blast target (G). At this time, the internal fixing part may have the shape of a sharp needle or a rod, for example.

The external fixing part may be formed on the uppermost side of the housing 10 and may have a flange-type shape that can be fixed to the surface of the object to be blasted (G).

The gunpowder unit 10 destroys the object to be blasted (G) through an explosion caused by a gunpowder reaction. Specifically, the explosive unit 10 may receive a detonation signal from the outside (for example, the blaster 41) by wire or wirelessly (each line; L) and be detonated through the detonator 40 to explode, and the explosive ( 11).

The gunpowder unit 10 destroys the object to be blasted (G) by developing dynamic energy through an explosion caused by a gunpowder reaction. At this time, the explosive portion 10 may combine with the energy of the non-explosive portion 30 to increase the destructive power of the blasting device 1.

The explosive part 10 may be located in a separate space from the non-explosive part 30. That is, the explosive portion 10 may form a separate chamber from the non-explosive portion 30 within the housing 1a so as to be distinguished from the non-explosive portion 30.

The air pipe portion 20 is formed outside the gunpowder portion 10 and has a predetermined space 21 for receiving air.

The air tube part 20 plays the role of an air layer on the upper side of the gunpowder part 10 when blasting by the gunpowder part 10, and can greatly reduce the blasting vibration by acting as an element surface, and the gunpowder part 11 Vibration is attenuated by slowing down the explosion speed, and when an explosion occurs, the destruction boundary rises upward by the length of the air pipe part (20), so that the projection area on the blasted object (G) on the free surface is as large as possible, so that it is within the hole (H). As the voltage force increases, the amount of crushing of the object to be blasted (G) can be increased, and the color spreading length of the color spreading part 50 is also shortened, so that the size of the stone during blasting can be greatly reduced.

When inserted into the perforation H formed in the object to be blasted (G), the air pipe portion 20 may be disposed closer to the outer side of the perforation H than the explosive portion 10. Specifically, the air pipe part 20 may be located in a space separate from the gunpowder part 10, and may be located on the upper side of the gunpowder part 10 within the housing 1a. At this time, in another embodiment of the present invention, the air pipe part 20 can accommodate the non-explosive part 30 within a preset space 21 therein.

The non-explosive portion 30 improves the explosive power of the explosive portion 10 and is provided outside the explosive portion 10. Here, the non-explosive part 30 may be made of aluminum. Additionally, the non-explosive portion may be formed so that the explosive portion and the air pipe portion do not contact each other.

In this way, the blasting device 1 according to an embodiment of the present invention is provided with a non-explosive portion 30 formed outside the explosive portion 10 in addition to the legally regulated amount of gunpowder 11 accommodated in the explosive portion 10, There is an effect of effectively increasing the performance of the gunpowder 11 without adding additional gunpowder 11, that is, within the framework of legal regulations on the quantity of gunpowder 11.

The non-explosive part 30 may be formed integrally with the air tube part 20.

The non-explosive portion 30 may be formed to surround the explosive portion 10. That is, in one embodiment of the present invention, it may be formed to surround the explosive portion 10 as shown in FIG. 3.

Regarding this, referring to FIG. 3, the non-explosive part 30 extends downward along the outer circumference of the air tube part 20, but is formed to have a hollow shape on the inside to surround the explosive part 10. It can be. That is, the non-explosive portion 30 is not mixed with the explosive portion 10 and forms a separate chamber outside the explosive portion 10, and may be formed to surround the outside of the explosive portion 10.

The non-explosive portion 30 may be formed to be surrounded by the explosive portion 10. That is, in another embodiment of the present invention, it may be formed to be surrounded by the explosive portion 10 as shown in FIG. 4.

Regarding this, referring to FIG. 4, the non-explosive portion 30 extends in the shape of a rod to the lower side of the air tube portion 20, and may be formed to be inserted into the explosive portion 10. At this time, the explosive portion 10 may include a concave portion 12 that is concave so that the non-explosive portion 30 is inserted.

That is, the non-explosive portion 30 is not mixed with the explosive portion 10 and forms a separate chamber outside the explosive portion 10, and is surrounded by the explosive portion 10, that is, inside the explosive portion 10. It may be formed to be accommodated in the concave portion 12.

The non-explosive part 30 may be formed in a preset space 21 of the air tube part 20. That is, in another embodiment of the present invention, as shown in FIG. 5, it may be formed inside the air pipe portion 20, that is, in the preset space 21.

Therefore, the non-explosive part 30 is not mixed with the explosive part 10 and forms a separate chamber outside the explosive part 10, and can be formed to be accommodated inside the air tube part 20.

The detonator 40 is formed inside the gunpowder unit 10 and can detonate the gunpowder 11 of the gunpowder unit 10. That is, the detonator 40 can detonate the gunpowder 11 by receiving a detonation signal from the blaster 41 wirelessly or through a square line (L).

The electroplating unit 50 can focus the shock wave and pressure wave caused by the explosion of the explosive unit 10 at the blasting location of the object to be blasted (G), and may be made of mud and sand.

At this time, the color spreading unit 50 may be disposed above the blasting device 1, that is, at the uppermost side within the hole H.

The color blocking unit 50 can also serve to block explosive noise by sealing the entrance of the hole H where the blasting device 1 is mounted.

As such, the blasting device 1 and the blasting method including the same according to an embodiment of the present invention dispose the non-explosive portion 30, that is, aluminum, outside the explosive portion 10, It has the effect of amplifying gunpowder performance while avoiding the scope of regulations on the quantity of gunpowder included.

In addition, the blasting device 1 and the blasting method including the same according to an embodiment of the present invention dispose aluminum 30 in the air pipe portion 20 to reduce storm pressure, scattering, vibration, and noise generated during blasting. It has a reducing effect.

In addition, the blasting device 1 and the blasting method including the same according to an embodiment of the present invention are formed so that aluminum 30 surrounds the explosive portion 10 or is formed to be surrounded by the explosive portion 10, (H) It has the effect of enhancing gunpowder performance and efficiently reducing vibration and noise while using internal space efficiently.

Figure 6 is a flowchart of a blasting method using a blasting device according to an embodiment of the present invention.

The blasting method using the blasting device according to the embodiment of the present invention can be implemented by the blasting device 1 according to the embodiment described above, and each step of the blasting method using the blasting device 1 will be described below. do.

As shown in Figure 6, the blasting method using a blasting device according to an embodiment of the present invention includes forming at least one hole in the object to be blasted (S10), and placing the blasting device in the hole formed in the object to be blasted. It includes a step (S20), a step of blackening the entrance to the hole (S30), and a step of destroying the object to be blasted by operating a blasting device (S40).

In step S10, at least one perforation is formed in the object to be blasted.

At construction sites such as large-scale pipe construction to bury sewer pipes, gas pipes, or communication pipes underground, and at construction sites such as ground preparation or excavation work, at the site of crushing of blasted materials, drilling equipment (not shown) ), etc., a plurality of perforations (H) can be formed in the object to be blasted (G). At this time, the construction site may be formed in a downtown area.

In step S20, a blasting device is placed in a hole formed in the object to be blasted.

When the step of forming a plurality of holes H in the object to be blasted (G) in step S10 is completed, the blasting device 1 can be placed in the object to be blasted (G). At this time, the blasting device 1, as described above, is constructed with the explosive part 10, the air tube part 20, and the non-explosive part 30, and when inserted into the hole H of the object to be blasted G, , the gunpowder unit 10 and the air tube unit 20 may be inserted in that order in the direction from the inside of the object to be blasted (G) toward the outside. At this time, the arrangement or formation position of the non-explosive part 30 is as shown in Figures 3 to 5.

The blasting device 1 inserted into the hole H is primarily fixed to the inside of the hole H by an internal fixing part, and can be secondarily fixed to the outside of the perforation H by an external fixing part.

In step S30, the entrance to the perforation is blackened.

After placing the blasting device (1) on the object to be blasted (G) in step S20, the entrance of the perforation (H) is finally filled through the smearing part (50), and the remaining space in the perforation (H) is filled with the smearing material. Fill it with sand, clay, or crushed stone.

In step S40, the blasting device is operated to destroy the object to be blasted.

When the hole H is completely filled with the blasting device 1 and the coloring unit 50 in step S30, the blasting device 1 can be operated to destroy the blasted object G.

As such, the blasting device 1 and the blasting method including the same according to an embodiment of the present invention dispose the non-explosive portion 30, that is, aluminum, outside the explosive portion 10, It has the effect of amplifying gunpowder performance while avoiding the scope of regulations on the quantity of gunpowder included.

In addition, the blasting device 1 and the blasting method including the same according to an embodiment of the present invention dispose aluminum 30 in the air pipe portion 20 to reduce storm pressure, scattering, vibration, and noise generated during blasting. It has a reducing effect.

In addition, the blasting device 1 and the blasting method including the same according to an embodiment of the present invention are formed so that aluminum 30 surrounds the explosive portion 10 or is formed to be surrounded by the explosive portion 10, (H) It has the effect of enhancing gunpowder performance and efficiently reducing vibration and noise while using internal space efficiently.

Although the present invention has been described in detail through specific examples, this is for the purpose of specifically explaining the present invention, and the present invention is not limited thereto, and can be understood by those skilled in the art within the technical spirit of the present invention. It would be clear that modifications and improvements are possible.

All simple modifications or changes of the present invention fall within the scope of the present invention, and the specific scope of protection of the present invention will be made clear by the appended claims.

1: blasting device 1a: housing
1b: top 1c: bottom
10: gunpowder part 11: gunpowder
12: recess
20: Air tube 21: Preset space
30: Non-explosive part 40: Detonator
41: blaster 50: coloring unit
H: Perforated G; blood blast material
L: angle line

Claims (11)

delete delete delete delete delete delete A gunpowder unit that destroys the object to be blasted through an explosion caused by a gunpowder reaction;
an air pipe portion formed outside the gunpowder portion and having a preset space for receiving air; and
It includes a non-explosive part that improves the explosive power of the explosive part,
The non-explosive part,
It is provided outside the explosive unit,
Forming a separate chamber outside the gunpowder section to prevent it from mixing with the gunpowder section,
The non-explosive part,
It is formed so that the gunpowder portion and the air pipe portion do not contact,
The non-explosive part,
A blasting device, characterized in that it is formed to surround the explosive unit, extends in the shape of a rod below the air pipe unit, and is formed to be inserted into the explosive unit. delete The method of claim 7, wherein the explosive unit,
A blasting device characterized by having a concave concave portion into which the non-explosive portion is inserted. delete In the blasting method using the blasting device of any one of claims 7 and 9,
forming at least one perforation in the blast material;
Placing the blasting device in a hole formed in the object to be blasted;
blackening the entrance of the perforation; and
A blasting method comprising the step of operating the blasting device to destroy the object to be blasted.