KR102651371B1 - Block for non-electric surface detonators - Google Patents

Abstract

The present invention is a non-electric surface detonator block that can simultaneously perform the functions of a TLD (Trunkline delay detonator) connector, a conventional surface detonator for open-air blasting, and a bunch connector, a surface detonator for tunnel blasting. Regarding this, the non-electric surface detonator block according to the present invention is formed with two inlets that allow the insertion of five shock tubes per inlet, and the inlet area is large, so that it can be conveniently inserted without the need to cut the tubes, Since moisture does not penetrate into the shock tube, it has the effect of being able to be used regardless of the environment or location, such as tunnels where groundwater leaks and a lot of water accumulates, or open air during rainy weather. In addition, the non-electric surface detonator block according to the present invention By discharging the shock tubes inserted into the two inlets to the outside through the side tube discharge port, unlike the conventional TLD connector, the 10 shock tubes inserted into the body of the block do not put pressure on the body of the block, causing damage over time. This also has the effect of preventing the body of the block from being damaged.

Description

Block for non-electric surface detonators}

The present invention relates to a block for a non-electric surface detonator, and specifically, it can simultaneously perform the functions of a TLD (Trunkline delay detonator) connector, a conventional surface detonator for open air blasting, and a bunch connector, a surface detonator for tunnel blasting. It relates to a non-electric surface detonator block characterized in that it can be used.

A non-electric blasting detonator is a structure in which a body made of synthetic resin into which a plurality of shock tubes are inserted, and a non-electric detonator that applies a detonation signal to the shock tube inserted into the body are inserted into the body. A detonation signal is transmitted to a plurality of explosive detonators through gunpowder.

As shown in FIG. 1, the non-electric detonator is a structure in which the charging agent (a), the detonating element (b), and the delay element (c) are sequentially charged in the tube and connected to the tube (d), depending on the use of detonation. When used for open-air blasting, it is mounted inside the body (1) of a TLD (Trunkline delay detonator) connector with a structure as shown in Figure 3, and when used for tunnel blasting, it is a bunch connector with a structure as shown in Figure 6. It is used by being mounted inside the body (1) of the (Bunch Connector), and the detonator and method of the non-electric detonator are known in Patent Documents 1 and 2.

Looking at the arrangement structure of the TLD connector and the charged hole for open-air blasting, as shown in FIG. 2, the number of charged holes (2) connected to the TLD connector is 8 or less, and the TLD connector is mounted on the charged hole (2). It is connected to the detonators for detonating explosives. For reference, symbol 3 in FIG. 2 is a non-electric blaster.

In this way, the TLD connector has eight or less charged holes (2) distributed in all directions, and the number of shock tubes connected to the explosive detonator detonators mounted on the charged holes (2) is eight or less, so Figure 3 In the conventional TLD connector 200 as shown in (a) to 3(c), the cross section of the body 1 is divided into four and the shock tube is formed on the upper surface where the inlet 3 into which the shock tube is inserted is formed. It is a structure that penetrates to the lower surface where the outlet (5) is formed, allowing the insertion of two shock tubes (2) into one tube inlet (3), so a maximum of eight shock tubes (2) can be inserted. It consists of

In tunnels or open-air blast sites, there may be water at the blast site due to groundwater leaks, rain, or spraying water in the open air to reduce dust. Therefore, it is important to prevent moisture from penetrating inside the shock tube filled with explosives. As shown in 3(c) and Figure 4, a sealing tube with a sealing portion 4 is used to seal the end of the shock tube.

The TLD connector 200 has a narrow area of the inlet 3 and outlet 5 through which the shock tube 2 is introduced, so as shown in FIG. 3(c), the first shock tube 2 is inserted into the inlet 3. ), and then inserting the second shock tube (2), there is a problem in that it cannot be inserted smoothly due to the sealing part (4). Therefore, in order to facilitate work in the field, the second shock tube (2) is irregularly inserted. When inserting 2), the sealing part (4) is cut and then inserted, moisture penetrates into the tube through the cut end of the shock tube (2), and the detonation signal is not transmitted to the detonator for the explosive, causing detonation to fail. Problems may arise.

In addition, in the conventional TLD connector 200, when two sealing tubes are to be inserted into the tube inlet 3 on the upper surface of the body 1, the sealing formed on the shock tube as shown in FIG. 5(a) Not only can the shock tube not be properly inserted into the tube inlet (3) due to the part (4), but as shown in Figure 5(b), the shock tube inserted through the upper inlet (3) is not inserted into the lower outlet. Even if it is discharged from the body of the block through (5), the eight shock tubes continue to apply pressure to the connector body (1) made of synthetic resin, so over time, as shown in Figure 5(c), the connector body (1) A problem occurs in which the lower fixing ring 10 is damaged.

Looking at the arrangement structure of the bunch connector for tunnel explosion and the charged hole, as shown in FIG. 6, the number of charged holes 50 connected to the bunch connector 300 is about 20, and the bunch connector is the charged hole 50. ) is connected to the detonators for explosives mounted on the device.

The bunch connector 300 has about 20 shock tubes connected to the explosive detonator detonators mounted on about 20 charging holes 50 distributed in all directions, so the bunch connector as shown in FIG. 7(a) Using (300), as shown in Figure 7 (b), the wire (6) is mounted in the wire mounting hole (7), then knotted to form a through hole (8), and then the fixing cap (9) is closed. Then, as shown in FIG. 7(c), a bundle of 20 or more shock tubes (2) penetrated into the through hole (8) is wrapped with a wire (6) and tied into one bundle to fix the bundle of shock tubes (2). use.

The bunch connector 300 as described above not only does not close well when the fixing cap 9 is closed to fix the wire 6 after mounting the wire 6 in the wire mounting hole 7, but also the wire 6 is damaged. Problems arise such as easy entanglement between the plurality of protrusions and grooves formed on the mounting port (7) and the fixing cap (9).

In addition, the conventional non-electric detonator had the inconvenience of having to separately provide a TLD connector for open air blasting and a bunch connector for tunnel blasting that connect the shock tube depending on the blasting purpose, manage them, and use them according to the blasting purpose.

Domestic Patent Publication No. 10-2006-0000164 (published on January 6, 2006) Non-electric detonator detonator and method Domestic Registered Patent Publication No. 10-1128046 (announced on March 29, 2012) Tunnel blasting method that divides the outer hole of the tunnel into multiple areas using a non-electric detonator and blasts them.

As a way to improve the above problems, the present invention is a device that can simultaneously perform the functions of the TLD (Trunkline delay detonator) connector, which is a conventional surface detonator for open air blasting, and the bunch connector, which is a surface detonator for tunnel blasting. The task is to provide a non-electric surface detonator block characterized by the following.

In addition, the non-electric surface detonator block according to the present invention is formed with two inlets that allow the insertion of five shock tubes per inlet, and the area of the inlets is large, so that the shock tubes can be conveniently inserted without the need to cut the tubes. Another task is to provide a non-electrical surface detonator block, which is characterized in that it can be used without any restrictions in the environment or location, such as tunnels where groundwater leaks and a lot of water accumulates due to groundwater leakage, or open air during rainy weather, as moisture does not penetrate into the interior. .

In addition, the non-electric surface detonator block according to the present invention discharges the shock tubes inserted into the two inlets to the outside through the side tube outlet, so that, unlike the conventional TLD connector, there are 10 shock tubes inserted into the body of the block. Another task is to provide a block for a non-electric surface detonator, which is characterized in that the body of the block is not damaged over time by not putting pressure on the body of the block.

The block for a non-electric surface detonator according to a preferred embodiment of the present invention for achieving the above problem is made in a cylindrical shape, an internal space 11 is formed so that the non-electric detonator 100 is located therein, and a plurality of blocks are formed. In the block into which the shock tube 200 is inserted and fixed, an inlet 21 is formed through the upper part of the block to allow the shock tube 200 to be inserted, and the block is formed horizontally from the outside to the inside at the bottom of the inlet 21. The upper part 20 is cut to form a fitting groove 22 into which the dopok line 300 is inserted; A middle portion 30 in which a plurality of discharge ports 31 are formed at the lower part of the upper portion 20 through which the shock tube 200 inserted through the inlet 21 is discharged to the outside; A means for solving the problem includes a lower part 40 formed at the lower part of the middle part 30 and through which the non-electric detonator 100 is inserted and fixed.

In the non-electric surface detonator block according to the present invention, the upper part 20 is divided by a support member 23 on the inside, and a ring part 24 is formed to form an inlet 21 into which the shock tube 200 is inserted. and; It is characterized in that it includes a groove portion 25 that is spaced downward from the ring portion 24 and is cut from the outside to the inside in a horizontal direction to form a fitting groove 22 into which the dopok line 300 is inserted.

And in the non-electric surface detonator block according to the present invention, the fitting groove 22 of the groove 25 is characterized by having a fixing protrusion 26 to prevent the detonation line 300 from being separated.

In addition, in the non-electric surface detonator block according to the present invention, the middle part 30 is vertical at a position corresponding to the support 23 of the ring part 24 at the bottom of the groove 25 of the upper part 20. It has a support part 32 formed in a direction, and has an auxiliary support part 33 formed between the support parts 32, and is inserted through the inlet 21 between the support part 32 and the auxiliary support part 33. It is characterized in that an outlet 31 through which the shock tube 100 is discharged is formed.

In the non-electric surface detonator block according to the present invention, the lower part 40 has a locking groove 41 formed on the outer peripheral surface and has an insertion hole 42 for inserting the non-electric detonator 100 through the lower part, It is shaped like a ring, the inner circumferential surface of which is partially combined with the outer circumferential surface of the insertion hole 42, and a fixing ring 44 on the top of which a locking hole 43 is formed to be caught in the locking groove 41.

And in the non-electric surface detonator block according to the present invention, the fixing ring 44 of the lower part 40 is connected to the insertion hole 42 and a portion thereof when the non-electric detonator 100 is inserted through the lower part of the insertion hole 42. The coupled portion is separated, and the locking hole 43 of the fixing ring 44 is caught in the locking groove 41 of the insertion hole 42, thereby fixing the non-electric detonator 100.

In addition, in the non-electric surface detonator block according to the present invention, the lower part of the locking groove 41 of the insertion hole 42 of the lower part 40 is inclined from the outside to the inside, so that the fixing ring 44 follows the slope. It is characterized in that it moves upward so that the locking hole 43 of the fixing ring 44 is caught in the locking groove 41 of the insertion hole 42.

Unlike conventional non-electric surface detonator blocks that select and use connectors with different structures depending on the blasting use, the non-electric surface detonator block according to the present invention combines the functions of a TLD connector for open air blasting and a bunch connector for tunnel blasting. It has the effect of having both functions, and the non-electric surface detonator block according to the present invention is formed with two inlets that allow the insertion of five shock tubes per inlet, and the area of the inlet is large, so it can be conveniently used without the need to cut the tubes. Since it has an insertable structure, moisture does not penetrate into the shock tube, so it can be used without restrictions in the environment and location, such as tunnels where groundwater leaks and a lot of water accumulates, or open air in rainy weather. In addition, the rain according to the present invention The electric surface detonator block discharges the shock tubes inserted into the two inlets to the outside through the side tube outlet, so that, unlike the conventional TLD connector, the 10 shock tubes inserted into the body of the block do not put pressure on the body of the block. This has the effect of preventing the body of the block from being damaged even as time passes.

Figure 1 is a cross-sectional view illustrating the structure of a typical non-electric detonator.
Figure 2 is an overall configuration diagram for explaining a method of blasting an open air using a TLD connector, a non-electric detonator for open air blasting according to the prior art.
Figures 3(a) to 3(c) are diagrams for explaining the TLD connector, which is a non-electric detonator for open-air blasting.
Figure 4 is a diagram for explaining a sealing tube in which a sealing portion is formed near the end of a shock tube used in a non-electric detonator.
Figure 5 is a diagram illustrating the problems of the TLD connector, a non-electric detonator for open-air blasting according to the prior art.
Figure 6 is an overall configuration diagram illustrating a method of dividing the outer hole of a tunnel into a plurality of areas and blasting it using a bunch connector, a non-electrical detonator for tunnel blasting according to the prior art.
Figures 7(a) to 7(c) are diagrams for explaining a bunch connector, a non-electrical detonator for tunnel blasting.
Figure 8 is a perspective view of a block for a non-electric surface detonator according to a preferred embodiment of the present invention.
Figure 9 is a front view of a block for a non-electric surface detonator according to a preferred embodiment of the present invention.
Figure 10 is a cross-sectional view of a block for a non-electric surface detonator according to a preferred embodiment of the present invention.
Figure 11 is a diagram showing a state in which a non-electric detonator is inserted into a block for a non-electric surface detonator according to a preferred embodiment of the present invention.
Figure 12 is a diagram for explaining the use state of a non-electric surface detonator block according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail based on the attached drawings. Meanwhile, in each drawing and detailed description, illustrations and references to the configuration and operation that can be easily understood by those in the field of general non-electric surface detonator block manufacturing are simplified or omitted.

Among the terms described in the specification of the present invention, the term 'non-electric surface detonator block' refers to a block containing a block into which a plurality of shock tubes are inserted and a non-electric detonator that applies a detonation signal to the shock tubes inserted into the block. The term ‘non-electric surface detonator block’ refers to a block made of synthetic resin into which a shock tube is inserted, excluding the non-electric detonator from the ‘non-electric surface detonator block’.

Referring to FIGS. 8 to 12, the block for a non-electric surface detonator according to the present invention has a cylindrical shape, an internal space 11 is formed so that the non-electric detonator 100 is located therein, and a plurality of shock tubes are provided. (200) is inserted and fixed, and an inlet 21 is formed so that the shock tube 200 is inserted through the upper part, and the lower part of the inlet 21 is cut horizontally from the outside to the inside to insert the dopok line 300. An upper part 20 in which a fitting groove 22 is formed, and a middle part in which a plurality of discharge holes 31 are formed through which the shock tube 200 inserted through the inlet 21 at the lower part of the upper part 20 is discharged to the outside. (30) and a lower part (40) formed at the lower part of the middle part (30), through which the non-electric detonator (100) is inserted and fixed.

The upper part 20 has a ring part 24 inside which is divided by a support member 23 to form an inlet 21 into which the shock tube 200 is inserted, and is spaced downward from the ring part 24 in a horizontal direction. It includes a groove portion 25 that is cut from the outside to the inside to form a fitting groove 22 into which the dopok line 300 is inserted.

The inlet 21 divided by the support member 23 of the ring portion 24 is formed into two to allow the insertion of five shock tubes. If the inlet 21 is formed as one, there is a risk that the shock tube 200 inserted into the inlet 21 moves freely and the shock tubes 200 become twisted due to interference with each other, and if the inlet 21 is formed as four. In this case, there is a problem that insertion of the shock tube 200 is difficult. To solve this problem, in a preferred embodiment of the present invention, the inlet 21 is formed into two to facilitate the insertion of the shock tube 200 and at the same time, the inserted shock tube 200 ) can be maintained stably.

Meanwhile, the groove portion 25 is formed to be spaced apart from the lower part of the ring portion 24 to form a fitting groove 22, and the lower part of the fitting groove 22 is connected to the middle portion 30 in a cylindrical shape. At this time, the guide line 300 is inserted and fixed into the fitting groove 22, and a fixing protrusion 26 is formed to prevent the guide line 300 from being separated.

The middle portion 30 has a support portion 32 formed in the vertical direction at a position corresponding to the support portion 23 of the ring portion 24 at the lower portion of the groove portion 25 of the upper portion 20, and between the support portions 32. It has an auxiliary support part 33 formed in, and an outlet 31 through which the shock tube 100 inserted through the inlet 21 is discharged is formed between the support part 32 and the auxiliary support part 33. At this time, the support portion 32 of the middle portion 30 extends upward as shown in (b) of FIG. 10 and is formed on the inner peripheral surface of the groove portion 25 of the upper portion 20, and the shock tube 200 is divided. When inserted through the inlet 21, it acts as a guide to ensure stable discharge through the outlet 31.

In the above, the support portion 32 is formed to extend to the inner peripheral surface of the groove portion 25 because the support portion 32 is formed at a position corresponding to the support port 23 of the ring portion 24, so that the shock tube 200 is connected to the inlet 21. This is to ensure that when inserted through, it is stably guided to the support part 32 and discharged through the outlet 31. In addition, the auxiliary support portion 33 may be formed to extend to the inner peripheral surface of the groove portion 25, but since the auxiliary support portion 33 is formed perpendicular to the support port 23 of the ring portion 24, it can be formed through the inlet 21. Since the shock tube 200 is caught by the auxiliary support 33 when inserted, making stable insertion difficult, it is preferable to extend the support 32 to the inner peripheral surface of the groove 25.

The lower part is formed in the lower part of the middle part, and the non-electric detonator is inserted and fixed through the lower part. The lower part 40 has a locking groove 41 formed on the outer peripheral surface to allow the non-electric detonator 100 to be inserted through the lower part. It has an insertion hole 42, is shaped like a ring, has an inner circumferential surface partially coupled to the outer circumference of the insertion hole 42, and has a fixing ring 44 on the top of which a locking hole 43 is formed so as to be caught in a locking groove 41.

On the other hand, the lower part of the locking groove 41 of the insertion hole 42 of the lower part 40 is inclined from the outside to the inside, so that the fixing ring 44 moves upward along the slope, and the locking hole 43 of the fixing ring 44 moves upward. ) is caught in the catching groove (41) of the insertion hole (42). That is, the fixing ring 44 of the lower part 40 is partially combined with the insertion port 42 when the non-electric detonator 100 is inserted through the lower part of the insertion port 42 and the fixing ring is struck upward. is separated and moves upward so that the locking hole 43 of the fixing ring 44 is caught in the locking groove 41 of the insertion hole 42 so that the non-electric detonator 100 is fixed. At this time, a cutout 45 is formed at the upper part of the fixing ring of the lower part 40 to penetrate both sides. This means that when the fixing ring 44 is separated from the insertion hole 42 and moves upward, the incision 45 narrows inward, allowing the fixing ring 44 to move stably upward.

And, as shown in FIG. 11, the lower part 40 has a plurality of locking protrusions ( 46) is formed. In other words, the non-electric detonator 100 is formed with a wrinkled portion on the outer circumferential surface, and is inserted through the insertion hole 42 of the lower part 40 to form a wrinkle of the non-electric detonator 100 on the locking protrusion 46 of the lower part 40. Part 110 is fixed.

As described above, the pleated portion 110 of the non-electric detonator 100 is primarily fixed by the locking protrusion 46 formed on the inner peripheral surface of the lower portion 40, and is secondarily fixed through the fixing ring 44. Because of its structure, the non-electric detonator 100 can be inserted through the insertion hole 42 of the lower part 40 and stably fixed.

Meanwhile, the upper end of the non-electric detonator 100 inserted through the insertion hole 42 of the lower part 40 is positioned below the fitting groove 22 of the upper part 20. This is to prevent interference with the non-electric detonator 100 when the detonator wire 300 is inserted into the fitting groove 22 of the upper part 20.

As described above, the non-electric surface detonator block according to the preferred embodiment of the present invention has the functions of the TLD connector for open-air blasting, unlike the conventional non-electric detonator block that selects and uses connectors with different structures depending on the blasting use. , It has the effect of simultaneously having the function of a bunch connector for tunnel explosion, and the non-electric surface detonator block according to the present invention is formed with two inlets through which five shock tubes can be inserted per inlet, and the area of the inlet is large, so that the tube Since it has a structure that can be conveniently inserted without the need to cut, moisture does not penetrate into the shock tube, so it can be used regardless of the environment and location, such as tunnels where groundwater leaks and a lot of water accumulates, or in the open air during rainy weather. In addition, the non-electric surface detonator block according to the present invention discharges the shock tubes inserted into the two inlets to the outside through the side tube outlet, so that, unlike the conventional TLD connector, there are 10 shock tubes inserted into the body of the block. Since there is no pressure on the body of the block, there is an effect that the body of the block is not damaged over time.

Figure 12 is a diagram for explaining the use state of a non-electric surface detonator block according to a preferred embodiment of the present invention.

Referring to FIG. 12, the non-electric surface detonator block 10 according to a preferred embodiment of the present invention having the above-described configuration is used for open air blasting and tunnel blasting. Figure 12 (a) shows the state when used for open-air blasting, where there are less than 10 shock tubes 200 and the blast wire 300 is not used. That is, the shock tube 200 is inserted through the inlet 21 of the upper part 20, and the shock tube 200 is guided by the support part 32 of the middle part 30 and discharged through the outlet 31. , the end of the shock tube 200 discharged through the outlet 31 can be tied so as not to come loose. In addition, Figure 12 (b) shows the state when used for tunnel explosion, in which 10 or more shock tubes 200 are used and the bombing wire 300 is used. In other words, the shock tube 200 is wrapped around one side of the conduction line 300 and clamped, and the conduction line 300 is inserted into the fitting groove 22 of the upper end 20 for use.

As described above, the non-electric surface detonator block according to the preferred embodiment of the present invention has been described, but this is merely an example, and various changes and modifications are possible without departing from the technical spirit of the present invention. Those skilled in the art will understand well.

10: Block for non-electric surface detonator
20: upper part 21: input port
22: Fitting groove 23: Support district
24: ring part 25: groove part
26: fixing protrusion 30: middle part
31: outlet 32: support
33: auxiliary support 40: lower part
41: Locking groove 42: Insertion hole
43: Locking hole 44: Fixing ring
100: non-electric detonator 200: shock tube
300: Dopokseon

Claims (7)

In the block, which has a cylindrical shape, an internal space 11 is formed so that the non-electric detonator 100 is located inside, and a plurality of shock tubes 200 are inserted and fixed,
The block has an inlet 21 formed through the upper part so that the shock tube 200 is inserted, and a fitting groove ( 22) is formed at the upper end (20);
A middle portion 30 in which a plurality of discharge ports 31 are formed at the lower part of the upper portion 20 through which the shock tube 200 inserted through the inlet 21 is discharged to the outside;
It is formed at the lower part of the middle part 30, and includes a lower part 40 through which the non-electric detonator 100 is inserted and fixed,
The upper part 20 is,
a ring portion 24 divided by a support member 23 to form an inlet 21 into which the shock tube 200 is inserted;
A non-electrical surface comprising a groove portion 25 that is spaced downward from the ring portion 24 and is cut from the outside to the inside in a horizontal direction to form a fitting groove 22 into which the conductor line 300 is inserted. Detonator block.
According to clause 1,
A block for a non-electric surface detonator, characterized in that the fitting groove 22 of the groove 25 has a fixing protrusion 26 to prevent the detonation line 300 from being separated.
According to paragraph 1,
The middle portion 30 has a support portion 32 formed in the vertical direction at a position corresponding to the support portion 23 of the ring portion 24 at a lower portion of the groove portion 25 of the upper portion 20, and the support portion 32 is formed in the vertical direction. (32) has an auxiliary support portion 33 formed between the support portion 32 and the auxiliary support portion 33, and an outlet 31 through which the shock tube 200 inserted through the inlet 21 is discharged. A non-electric surface detonator block, characterized in that a is formed.
According to paragraph 1,
The lower part 40 has a locking groove 41 formed on the outer peripheral surface and has an insertion hole 42 through which the non-electric detonator 100 is inserted, and is made in a ring shape so that the inner peripheral surface is the outer peripheral surface of the insertion hole 42. A block for a non-electric surface detonator, characterized in that it has a fixing ring (44) partially combined with and having a locking hole (43) formed at the top to be caught in the locking groove (41).
According to clause 4,
The fixing ring 44 of the lower part 40 is such that when the non-electric detonator 100 is inserted through the lower part of the insertion hole 42, the portion partially coupled to the insertion hole 42 is separated and the fixing ring 44 A block for a non-electric surface detonator, characterized in that the locking hole (43) is caught in the locking groove (41) of the insertion hole (42) and the non-electric detonator (100) is fixed.
According to clause 5,
The lower part of the locking groove 41 of the insertion hole 42 of the lower part 40 is inclined from the outside to the inside, so that the fixing ring 44 moves upward along the slope to form a locking hole for the fixing ring 44. A block for a non-electric surface detonator, characterized in that (43) is caught in the locking groove (41) of the insertion hole (42). delete

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