KR101815512B1 - Triggering Device for a non-electric type Detonator using the Tunnel Blasting - Google Patents

Abstract

The present invention relates to an initiator of a non-electrical detonator for a tunnel blast which can reduce the amount of a signal tube usage which is a detonating cord, when an initiator of a non-electrical detonator is used to be applied to a site of a tunnel and underground excavation to reduce construction costs. In addition, when the leakage voltage is input from a working site, and the same is less than or equal to breakdown voltage of the diac, the conduction is not performed so the triac is not turned on. Thereafter, current is blocked to an end not to be initiated, thereby being safe from leakage current and static electricity. A varistor is connected to an ignition circuit, and the breakdown voltage is set by 2,000 to 2,500 V so as to be blocked when an abnormal voltage is input, thereby preventing mistaken bombing due to the lightning. In addition, one resistor is connected to an input terminal of a non-electrical detonator blasting device to confirm whether the ignition circuit is connected to the ignition circuit by a resistance measuring device. Furthermore, when two resistors are added to the input terminal of the non-electrical detonator blasting device to absorb an impact received by each element when a blast is performed or the lightning is introduced. Also, a signal tube of a non-electrical detonator is allowed to be ignited even without using an electrical detonator. Moreover, a capacitor is connected between the varistor and an output terminal of the ignition circuit forming a blast circuit module of an electrical detonator blasting device. Accordingly, charges are charged in the capacitor, and charged charges are discharged at once at a time point when a corona discharge is to be generated, thereby preventing a percussion failure of the signal tube. The initiator of a non-electrical detonator for a tunnel blast of the present invention comprises an electric generator, a blasting busbar, and a spark tip.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-electric detonator for a tunnel,

The present invention can reduce the amount of the signal tube used as a detonating line used for applying the detonator of the non-electric primer to the site of the tunnel and underground excavation, thereby reducing the construction cost. If leakage voltage is input from the work site, (Diac) breakdown voltage, it is not energized and can not turn on the triac. Therefore, it is safe from leakage current and static electricity because the current is cut off at the subsequent stage, and the varistor is connected to the detonation circuit The breakdown voltage is set to 2000V to 2500V so that it is possible to prevent the false alarm from lightning when the abnormal voltage is inputted. By connecting one resistor to the input terminal of the non-electric primer breaker, And two resistors are added to the input terminal of the non-electrical primer breaker to generate a blast or lightning It is possible to absorb the shocks received by the devices and to ignite the signal tube of the non-electric primer without using the electric primer, and the varistor of the explosion circuit constituting the electric primer blasting circuit module A device for detonating a non-electric primer for tunnel blasting that can prevent a trigger failure of a signal tube while simultaneously discharging the charged charge at the time of charging a capacitor to the capacitor so that a capacitor is connected between the output terminal and the corona discharge. Technology.

When excavating rocks such as underground spaces such as tunnels or storage facilities, building structures, foundation rock excavation of civil engineering structures, quarries, mines, etc., blasting work is carried out using industrial explosives. In order to prevent safety accidents, industrial explosives are manufactured to be very insensitive and not self-exploiting, so primers that act as initiators should be used to detonate industrial explosives. In other words, to exploit industrial gunpowder, it is necessary to detonate the primer from the ignition device (the pounder), and then the industrial gunpowder to bloom and detonate to destroy the rock.

In this way, blasting techniques, blasting electrical detonators, and non-electrical blasting techniques are used as techniques to detonate explosives. As a conventional technique, a method of blasting a primer by applying a black powder to a primer is ignited by a flame using an ignition device, which is a base stone, and is not used as a safety problem at present. This is due to the goal of the industry to increase productivity by increasing the stability of explosive blast due to the explosion of the explosive blast, the blasting at precise time, blasting and blasting.

Meanwhile, the electric blasting method is a method in which the ignition device is ignited due to the heat generated by the platinum wire installed in the primer tube by the electric energy using the ignition device, which is an electric blasting device. The explosion of electrical explosion, such as tunnels, underground spaces, and large blasts, is gradually reduced, and is classified into MS electric primers and LP electric primers .

1 is a block diagram illustrating a conventional electric blasting method. The electric blasting method shown in FIG. 1 is a method in which a primer is bonded to a shock tube having 0.02 g / m < 2 > of HMX + Al in a polyethylene (PE) circular tube having an outer diameter of 3 mm and an inner diameter of 1.5 mm, It is a method of igniting with a high-pressure spark by using an ignition device. The non-electric blasting method is an increasing trend in the application of blasting with electrical hazards, and it is a tendency that the application is increasing in the blasting operation with the open vent, the open-circuit connection primer, the connection primer for tunnel, MS (ms primer primer), LP (LP primer primer) ; A primer for shock tube detonation).

However, the blasting work is to crush the rock by using gunpowder, which causes blasting pollution such as zeolite, vibration, and storm pressure, and the explosive control law is forced to place the ignition site at a minimum distance from the blasting site .

Therefore, if a non-electric blasting method is applied in a blasting operation, it is inconvenient to apply a starter having a predetermined length or more. Further, the shock tube of the extended starter is disposable, and tube residue remains after blasting. Therefore, there is an inconvenience that the tube residue should be collected one by one in a large amount of use, resulting in an economical increase in construction cost. In order to solve the above-mentioned problem, a blasting method using a non-electric primer and an electric primer can be used.

In the meantime, the conventional blasting method using a non-electric primer and an electric primer in the prior art uses a non-electric primer for each blast hole when the explosive is loaded or a Bench blasting, and a final primer is connected using an electric primer, And electrical primer are blended together.

However, in the above-mentioned prior art, there is no difference from the electric detonating method in the blasting operation in which there is an electrical risk factor, so that there still remains the problem that it can be misinterpreted by the leakage current and the static electricity.

Therefore, it is possible to reduce the construction cost by reducing the amount of the signal tube, which is the detonation line used for applying the detonator of the non-electric primer to the site of the tunnel and underground excavation, and when the leakage voltage comes in from the work site, ), It is not energized and can not turn on the triac. Therefore, it is protected from leakage current and static electricity because the current is cut off at the subsequent stage, so that the varistor is connected to the detonation circuit and the breakdown voltage Is set to 2000V to 2500V. Thus, when an abnormal voltage is inputted, it is possible to prevent the false alarm from lightning, and a capacitor is connected between the varistor and the output terminal of the detonation circuit constituting the explosion circuit module of the electric detonator Charge the capacitor and charge it at the point of causing corona discharge. The development of control detonator at a time of discharging the charge, while the signal tube to prevent failure triggered non-electric detonators for blasting in the tunnel that is the situation that is urgently required.

KR 10-2009-0127687 (December 21, 2009)

Accordingly, it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to reduce the use of a signal tube, which is a detonating line used in applying a detonator of a non-electric primer to a tunnel and an underground excavation site, The present invention provides a detonator for a non-electric primer for tunnel blasting.

Another object of the present invention is to provide an apparatus and a method for controlling the leakage current of a semiconductor device which can prevent leakage current due to leakage current, And a detonator for a non-electric primer for tunnel explosion safe from static electricity.

Another object of the present invention is to provide a nonvolatile primer for detonating a tunnel which can prevent a fault from a lightning by connecting a varistor to an explosion circuit and setting a breakdown voltage between 2000V and 2500V, Device.

It is another object of the present invention to provide a detonator for a non-electric primer for tunnel blasting, which can confirm the connection of the detonation circuit by connecting a resistor to the input terminal of the non-electric primer detonator.

It is another object of the present invention to provide a detonator for a non-electric primer for tunnel blasting, which can absorb two or more resistances to the input of a non-electric primer breaker to receive the impact of each element when a blast or lightning is introduced.

It is another object of the present invention to provide a detonator for a non-electric detonator for tunnel blasting which enables the signal tube of a non-electric primer to be detonated without using an electric primer.

Another object of the present invention is to connect a capacitor between an output terminal and a varistor of an explosion circuit constituting a blasting circuit module of an electric detonator, so that a charge is charged in a capacitor, Which can prevent the detonation failure of the signal tube while simultaneously discharging the signal tube.

According to another aspect of the present invention, there is provided an apparatus for detonating a non-electrical primer for blasting a tunnel, comprising: an electric generator for generating electricity at a high voltage of 1200 to 2500 V to supply electric power to a non- A blasting bus for receiving the electricity generated by the electricity generator and delivering it to a non-electrical primer blender; and a spark terminal in the spark tip, which receives electricity through the blasting bus, An ignition device comprising a spark tip composed of electrodes and having two electrodes inserted in a signal tube to receive a high voltage current generated in an electricity generator to cause a strong spark discharge in a signal tube, A spark discharge is caused to explode the gunpowder applied in the signal tube A non-electric primer blaster for generating a spark discharge on the spark terminal, and a non-electric primer blaster for generating a spark discharge on the spark terminal, wherein the spark tip is made of brass or a similar conductive metal, And a signal tube connecting the non-electric primer blaster and the non-electric primer installed at the site of the tunnel and underground excavation, wherein the non-electric primer blaster is mounted on a printed circuit board (PCB) A first and a fifth blasting circuit module which are selectively mounted to any one of the electronic parts, and an upper and a lower case for protecting a spark terminal including a spark tip from which spark discharge is generated; A vise cap for coupling a signal tube coupled to a vise rack formed at a front end of the upper and lower cases; Wherein the fifth blasting circuit module is connected to the blasting bus and is connected to both ends of the blasting machine input terminal to which electricity generated from the electricity generator is input and to the presence or absence of connection of the detonating circuit by a resistance measuring instrument An eleventh resistor (R503) is connected to the rear end of the eleventh resistor (R503). When a leakage voltage near 380V is inputted from a work site, the voltage is lower than the breakdown voltage of the diode (D501) And a diode D501 that actively senses and controls a voltage input from the outside so as to prevent the lightning from being overheard and the ninth safety unit and the eleventh resistance unit R503 are connected at both ends, And a varistor V501 configured to cut off an abnormal voltage when a breakdown voltage is set to 2000 V to 2500 V in order to prevent a current from flowing into a detonated line (signal tube) A fifth capacitor C501 connected to the tenth safety unit to prevent a failure of the signal tube from being charged while charging the capacitor and discharging the charges charged at the time of causing the corona discharge at a time, And a breaker output terminal connected to a rear end of the unit C501 and connected to a non-electric primer installed at the site of a tunnel and underground excavation through a detour line (signal tube).

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In the present invention, the first blasting circuit module includes a shaker input terminal connected to the blasting bus line and receiving electricity generated from the electricity generator; A first resistor R102 connected to both ends of the input terminal of the shaker to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; When a leakage voltage in the vicinity of 380 V comes from a work site, when the breakdown voltage of the diode (D101) is lower than the breakdown voltage of the diode (D101), the triac (Q101) (Q101) that controls the external input so that the current is blocked because the current can not be turned on because it is unable to turn on the triac (Q101), and the triac From the sudden voltage rise between Diac (D101) and both terminals of the triac, A first safety part including a capacitor C101 for preventing the occurrence of a phenomenon and a safety resistor R101 of a triac Q101; A second resistor R103 connected at both ends of the first safety unit and the first resistor unit R102 to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The second resistor R103 is connected to the varistor V101 to block the current from flowing into the signal line when the abnormal voltage is set by setting the breakdown voltage to 2000V to 2500V in order to protect against the lightning strike A second safety part configured; A first capacitor unit C101 connected to the second safety unit to prevent a failure of the signal tube from being charged while charging the capacitor and discharging the charged charges at the time of causing the corona discharge; A breaker output terminal connected to a rear end of the first capacitor unit (C101) and connected to a non-electric primer installed at a site of tunnel and underground excavation through a detour (signal tube); .

In the present invention, the second blasting circuit module includes a shaker input terminal connected to the blasting bus and receiving electricity generated from the electricity generator; A third resistor R202 connected to both ends of the input terminal of the shaker to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; And is connected to the rear end of the third resistor R202. When a leakage voltage in the vicinity of 380 V enters from a work site, the voltage input from the outside is actively controlled so as not to be energized when the leakage voltage is below the breakdown voltage of the diode D201 A third safety part consisting of a diac (D201) for sensing and controlling; A fourth resistor R203 connected at both ends of the third safety unit and the third resistor R202 and configured to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The varistor V201 is connected to the fourth resistor R203 and is connected to the varistor V201 for blocking the current from flowing into the signal line when the abnormal voltage is set by setting the breakdown voltage to 2000V to 2500V A fourth safety part configured; A second capacitor unit C201 connected to the fourth safety unit and charged to the capacitor to prevent a failure of the signal tube while simultaneously discharging charges charged at the time of causing a corona discharge; A breaker output terminal connected to a rear end of the second capacitor unit C201 and connected to a non-electric primer installed at the site of a tunnel and underground excavation through a signal line; .

In the present invention, the third blasting circuit module includes a shaker input terminal connected to the blasting bus and receiving electricity generated from the electricity generator; Fifth resistors R301 and R302 that add two resistors R301 and R302 at the input terminal of the shaker to absorb the impact of each element when a blast or a lightning stroke occurs; A sixth resistor R303 having both ends connected to the fifth resistors R301 and R302 to check the presence or absence of wiring of the detonating circuit by a resistance meter; And is connected to the rear end of the sixth resistor R303. When a leakage voltage in the vicinity of 380 V comes from a work site, the voltage input from the outside is actively controlled so as not to be energized when the leakage voltage is below the breakdown voltage of the diode D301 A fifth safety part consisting of a diac D301 for detecting and controlling the first safety part; A seventh resistance unit R304 connected at both ends of the fifth safety unit and the sixth resistance unit R303 to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The varistor V301 is connected to the seventh resistor R304 and blocks the current when the abnormal voltage is inputted by setting the breakdown voltage to 2000V to 2500V to protect the lamp from the lightning strike A sixth safety part configured; A third capacitor unit C301 connected to the sixth safety unit for charging the capacitor and discharging the charges charged at the time of causing the corona discharge to prevent the triggering of the signal tube. A breaker output terminal connected to a rear end of the third capacitor unit C301 and connected to a non-electric primer installed at the site of a tunnel and underground excavation through a signal line; .

In the present invention, the fourth blasting circuit module includes a shaker input terminal connected to the blasting bus and receiving electricity generated from the electricity generator; An eighth resistance unit R401 and R402 for adding the two resistors R401 and R402 at the input terminal of the shaker to absorb the impact of each element when the blast or lightning is introduced; A ninth resistance unit R403 having both ends connected to the eighth resistor units R401 and R402 to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; And a varistor (V402) connected to the rear end of the ninth resistor (R403) and actively detecting and blocking the leakage voltage when a leakage voltage in the vicinity of 380 V comes from a work site; A tenth resistor R404 connected at both ends to the seventh safety unit and the ninth resistor R403 and setting the amount of current to a minimum value in order to flow the current of the detonation circuit; The varistor V401 is connected to the tenth resistor R404 and is configured to cut off the abnormal voltage when the breakdown voltage is set to 2000V to 2500V in order to protect the lamp from lightning, An eighth safety unit configured; A fourth capacitor unit C401 connected to the eighth safety unit and charged to the capacitor and discharging the charged charge at the time of causing the corona discharge to prevent the triggering of the signal tube. A breaker output terminal connected to a rear end of the fourth capacitor unit C401 and connected to a non-electric primer installed at the site of a tunnel and underground excavation through a detour line (signal tube); .

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As described above, the detonator of the non-electric primer for tunnel blasting according to the present invention has the following effects.

First, the present invention can reduce the construction cost by reducing the amount of the signal tube used as a detonation line used for applying the detonator of the non-electric primer to the field of tunnel and underground excavation.

Second, in the present invention, when a leakage voltage is inputted from a work site, when the breakdown voltage of the diac is below the breakdown voltage, it is not energized and the triac is not turned on. It is safe from static electricity.

Thirdly, according to the present invention, a varistor is connected to an explosion circuit and a breakdown voltage is set to 2000V to 2500V, so that when an abnormal voltage is inputted, it is possible to prevent misjudgment from lightning.

Fourth, the present invention can confirm the connection of the detonating circuit by connecting a resistor to the input terminal of the non-electric primer breaker and measuring the resistance.

Fifth, the present invention can add two resistors to the input terminal of the non-electric primer breaker to absorb the impact of each element when the blast or lightning is introduced.

Sixth, the present invention makes it possible to detonate the signal tube of a non-electrical primer without using an electrical primer.

Seventh, the present invention connects the capacitor between the varistor and the output terminal of the detonating circuit constituting the blasting circuit module of the electric detonator, so charges are charged in the capacitor, and the charged charge at the time of causing the corona discharge The discharge of the signal tube can be prevented by discharging all at once.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of a conventional electric blasting method.
2 is a view for explaining a state where an explosive device of a non-electric primer for tunnel blasting according to an embodiment of the present invention is used.
FIG. 3 is a diagram illustrating an internal configuration of a non-electric primer breaker in a configuration of a non-electric primer detonator for tunnel blasting according to an embodiment of the present invention. FIG.
4 is a view for explaining an assembly state of a spark tip in the configuration of a non-electric primer breaker according to an embodiment of the present invention.
5 is a diagram illustrating a configuration of a non-electric primer breaker according to an embodiment of the present invention.
FIG. 6 is an exploded circuit diagram of a non-electric primer breaker of a non-electric detonator for detonating a tunnel according to an embodiment of the present invention. FIG.
FIG. 7 is an exploded circuit diagram of a non-electric primer breaker of a non-electric detonating device for tunnel explosion according to another embodiment of the present invention. FIG.
FIG. 8 is an exploded circuit diagram of a non-electric primer breaker of a non-electric detonator for detonating a tunnel according to another embodiment of the present invention. FIG.
FIG. 9 is an exploded circuit diagram of a non-electric primer breaker of a non-electric primer for detonating a tunnel according to another embodiment of the present invention. FIG.
FIG. 10 is an exploded circuit diagram of a non-electric primer breaker of a non-electric primer detonator for tunnel blasting according to another embodiment of the present invention; FIG.
FIG. 11 is a diagram illustrating an internal configuration of a non-electric primer breaker of a non-electric primer detonator for tunnel blasting according to another embodiment of the present invention. FIG.
FIG. 12 is an exploded circuit diagram of a non-electric primer breaker of a non-electric primer detonator for tunnel blasting according to another embodiment of the present invention; FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, when it is determined that a detailed description of related art or configuration may unnecessarily obscure the gist of the present invention, The detailed description will be omitted, and the terms described below are defined in consideration of the functions of the present invention. This may vary depending on the intention or custom of the user, the operator, and the like. And should be based on the contents of this specification throughout the specification.

FIG. 2 is a view for explaining a state in which a detonator of a non-electric primer for tunnel blasting according to an embodiment of the present invention is used, and FIG. 3 is a view for explaining a state of a non-electric primer for tunnel blasting according to an embodiment of the present invention. FIG. 4 is a view for explaining an assembly state of a spark tip in the configuration of a non-electric primer breaker according to an embodiment of the present invention, and FIG. FIG. 5 is a view showing a shape of a non-electric primer breaker according to an embodiment of the present invention. FIG. 6 is a schematic view of a non-electric primer detonator of a non-electric primer for blasting a tunnel according to an embodiment of the present invention. FIG. 7 is an exploded circuit diagram of a non-electric primer breaker of a non-electric detonator for detonating a tunnel, according to another embodiment of the present invention, and FIG. FIG. 9 is an exploded schematic view of a non-electric detonator of the non-electric detonator for tunnel explosion according to another embodiment of the present invention. FIG. 10 is an exploded circuit diagram of a non-electric primer breaker of the non-electric detonator for detonating a tunnel in accordance with another embodiment of the present invention, and FIG. 11 is an exploded circuit diagram of the non- FIG. 12 is a diagram illustrating an internal configuration of a non-electric primer breaker of a non-electric primer detonator for tunnel explosion according to another embodiment of the present invention. FIG. It is the detonation circuit diagram of the non-electric primer breaker among the composition of the detonator of the electric primer.

The explosion device of a non-electric primer for tunnel blasting according to the present invention includes an electric generator 10, a blasting bus 20, a non-electric primer blaster 30, first to sixth blasting circuit modules 31, 32, 33, 34, 34-1, 34-2, a spark tip 35, a spark terminal 36, a vise rack 37, a vise projection 37-1, a fastening male thread 37-2, a vise cap 38, The signal tube insertion groove 38-1, the slanting tube body 38-2, the fastening female thread 38-3, the printed circuit board 39, the upper and lower cases 30A and 30B, 40), a non-electric primer (50), and a non-electric primer (60).

2 to 12, the detonator 60 for a non-electric detonator for tunnel blasting according to an embodiment of the present invention generates a high voltage of 1200 to 2500 V, A blasting bus 20 for receiving electricity generated by the electric generator 10 and transferring the electric power to a non-electric primer blasting machine 30, A non-electric primer breaker (30) that receives electricity through a bus (20) to cause a spark discharge in a spark terminal (36) in a spark tip (35) so that a gunpowder in the signal tube (40) And a signal tube 40 connecting a detonator 30 and a non-electrical primer 50 installed at the site of the tunnel and underground excavation. The non-electrical primer breaker 30 is connected to a printed circuit board (39), and a non-electric primer breaker (30) It is composed of electronic components to be the first to be selectively mounted in any one of the sixth blasting circuit modules (31, 32, 33, 34, 34-1, 34-2) and; Upper and lower cases 30A and 30B for protecting the spark terminal 36 including the spark tip 35 from which spark discharge is generated; A vise cap 38 for coupling a signal tube 40 coupled to a vise rack 37 formed at a front end of the upper and lower cases 30A and 30B; Respectively.

The function of each technical means according to the construction and configuration of the detonator 60 of the non-electrical primer for tunnel blasting will be described below.

As shown in FIGS. 2 to 12, the detonator 60 for a non-electric detonator for tunnel blasting generates a high voltage of 1200 to 2500 V to supply electric power to the non-electric primer breaker 30 through the blasting bus 20 A blasting bus 20 for receiving electric power generated by the electric generator 10 and transferring the electric power to the non-electric primer blasting machine 30; A non-electric primer breaker 30 for supplying a spark discharge to a spark terminal 36 in a spark tip 35 so that a gunpowder in the signal tube 40 is supplied to the spark tip 35, And a signal tube 40 connecting the non-electrical primer 50 installed at the site of underground excavation.

The non-electrical primer splitter 30 is comprised of electronic components mounted on a printed circuit board (PCB) 39 and allowing the non-electrical primer splitter 30 to be safely driven, First to sixth blasting circuit modules (31, 32, 33, 34, 34-1, 34-2); Upper and lower cases 30A and 30B for protecting the spark terminal 36 including the spark tip 35 from which spark discharge is generated; A vise cap 38 for coupling a signal tube 40 coupled to a vise rack 37 formed at a front end of the upper and lower cases 30A and 30B; .

3 to 5, the spark terminal 36 includes a spark tip 35 composed of two electrodes having a tight gap, and two electrodes are inserted in the signal tube 40 to electrically The spark tip 35 is inserted into the signal tube 40 and generates a strong spark discharge to be injected into the signal tube 40. The spark tip 35 is inserted into the signal tube 40, The main material of the spark terminal 36 is brass or a similar conductive metal, and the wire of the insulation coating constituting the spark tip 35 is made of Teflon wire or enamel wire.

The vise rack 37 is divided into a plurality of vice racks 37 which serve to tighten the signal tube 40 so as to prevent the signal tube 40 from being dislodged. A signal tube check groove 38-1 for confirming whether or not the spark tip 35 is inserted into the signal tube 40 and a fastening male thread 38-1 for fastening the vise cap 38 37-2).

When the vise cap 38 is fastened to the upper and lower cases 30A and 30B, the vise rack 37 is pressed against the inclined surface tube 38-2 of the vise cap 38 to tightly tighten the signal tube 40 Thereby restricting the signal tube 40 from coming off.

As shown in FIGS. 2, 3 and 6, the first blasting circuit module 31 is connected to the blasting bus 20 and includes a generator input for receiving electricity generated by the generator 10; A first resistor R102 connected to both ends of the input terminal of the shaker to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; When a leakage voltage in the vicinity of 380 V comes from a work site, when the breakdown voltage of the diode (D101) is lower than the breakdown voltage of the diode (D101), the triac (Q101) (Q101) that controls the external input so that the current is blocked because the current can not be turned on because it is unable to turn on the triac (Q101), and the triac A capacitor C101 for preventing an avalanche phenomenon from a sudden voltage rise between both terminals of the triac and a safety resistor R101 for a triac Q101, 1 safety part; A second resistor R103 connected at both ends of the first safety unit and the first resistor unit R102 to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The breaker is connected to the second resistor R103 and has a breakdown voltage of 2000V to 2500V for protecting against a lightning strike. When the breakdown voltage is exceeded, the varistor blocks the current from flowing to the explosion line (signal tube) V101); A first capacitor unit C101 connected to the second safety unit to prevent a failure of the signal tube from being charged while charging the capacitor and discharging the charged charges at the time of causing the corona discharge; And a breaker output terminal connected to a rear end of the first capacitor unit C101 and connected to a non-electric primer 50 installed at the site of a tunnel and underground excavation through a detour (signal tube) 40. [

2 and 7, the second blasting circuit module 32 is connected to the blasting bus 20 and includes a generator input for receiving electricity generated by the generator 10; A third resistor R202 connected to both ends of the input terminal of the shaker to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; And is connected to the rear end of the third resistor R202. When a leakage voltage in the vicinity of 380 V enters from a work site, the voltage input from the outside is actively controlled so as not to be energized when the leakage voltage is below the breakdown voltage of the diode D201 A third safety part consisting of a diac (D201) for sensing and controlling; A fourth resistor R203 connected at both ends of the third safety unit and the third resistor R202 and configured to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The breakdown voltage is set to 2000V to 2500V in order to protect against the lightning strike, and is connected to the fourth resistor R203. When the abnormal voltage is inputted, the varistor blocks the current from flowing into the explosion line (signal tube) V201); A second capacitor unit C201 connected to the fourth safety unit and charged to the capacitor to prevent a failure of the signal tube while simultaneously discharging charges charged at the time of causing a corona discharge; And a breaker output terminal connected to a rear end of the second capacitor unit C201 and connected to a non-electric primer 50 installed at the site of a tunnel and underground excavation through a detour line (signal tube) 40. [

As shown in FIGS. 2 and 8, the third blasting circuit module 33 is connected to the blasting bus 20 and includes a generator input for inputting electricity generated by the generator 10; Fifth resistors R301 and R302 that add two resistors R301 and R302 at the input terminal of the shaker to absorb the impact of each element when a blast or a lightning stroke occurs; A sixth resistor R303 having both ends connected to the fifth resistors R301 and R302 to check the presence or absence of wiring of the detonating circuit by a resistance meter; And is connected to the rear end of the sixth resistor R303. When a leakage voltage in the vicinity of 380 V comes from a work site, the voltage input from the outside is actively controlled so as not to be energized when the leakage voltage is below the breakdown voltage of the diode D301 A fifth safety part consisting of a diac D301 for detecting and controlling the first safety part; A seventh resistance unit R304 connected at both ends of the fifth safety unit and the sixth resistance unit R303 to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The breakdown voltage is set to 2000V to 2500V in order to protect against a lightning strike, and is connected to the seventh resistor R304. When the abnormal voltage is inputted, the varistor blocks the current from flowing to the explosion line (signal tube) V301); A third capacitor unit C301 connected to the sixth safety unit for charging the capacitor and discharging the charges charged at the time of causing the corona discharge to prevent the triggering of the signal tube. And a breaker output terminal connected to a rear end of the third capacitor unit C301 and connected to a non-electric primer 50 installed at the site of a tunnel and underground excavation through a detour (signal tube) 40. [

As shown in FIGS. 2 and 9, the fourth blasting circuit module 34 is connected to the blasting bus 20 and has a generator input for inputting electricity generated by the generator 10; An eighth resistance unit R401 and R402 for adding the two resistors R401 and R402 at the input terminal of the shaker to absorb the impact of each element when the blast or lightning is introduced; A ninth resistance unit R403 having both ends connected to the eighth resistor units R401 and R402 to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; And a varistor (V402) connected to the rear end of the ninth resistor (R403) and actively detecting and blocking the leakage voltage when a leakage voltage in the vicinity of 380 V comes from a work site; A tenth resistor R404 connected at both ends to the seventh safety unit and the ninth resistor R403 and setting the amount of current to a minimum value in order to flow the current of the detonation circuit; The breakdown voltage is set to 2000V to 2500V in order to protect against the lightning strike and is connected to the tenth resistor R404. When the abnormal voltage is inputted, the varistor blocks the current from flowing to the explosion line (signal tube) 40 V401); A fourth capacitor unit C401 connected to the eighth safety unit and charged to the capacitor and discharging the charged charge at the time of causing the corona discharge to prevent the triggering of the signal tube. And a breaker output terminal connected to a rear end of the fourth capacitor unit C401 and connected to a non-electric primer 50 installed at the site of a tunnel and underground excavation through a detonation line (signal tube) 40. [

As shown in FIGS. 2, 10 and 11, the fifth blasting circuit module 34-1 is connected to the blasting bus 20 and includes a generator input for inputting electricity generated by the generator 10, ; An eleventh resistor R503 connected to both ends of the input terminal of the shaker to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; And is connected to the rear end of the eleventh resistor R503. When a leakage voltage in the vicinity of 380 V is input from a work site, the voltage input from the outside is actively controlled so as not to be energized when the leakage voltage is below the breakdown voltage of the diode D501 A ninth safety part constituted by a diac (D501) for sensing and controlling; The ninth safety unit and the eleventh resistance unit R503 are connected at both ends and a breakdown voltage is set to 2000V to 2500V in order to protect against a lightning strike so that an abnormal voltage is blocked to block the current from flowing into the explosion line (signal tube) A tenth safety part constituted by a varistor V501 which is made up of: A fifth capacitor unit C501 connected to the tenth safety unit for preventing charges of the signal tube from failing while discharging charges charged at the time of causing the corona discharge to be discharged at the same time; And a breaker output terminal connected to a rear end of the fifth capacitor unit C501 and connected to a non-electric primer 50 installed at the site of a tunnel and underground excavation through a detour (signal tube) 40. [

As shown in FIGS. 2 and 12, the sixth blasting circuit module 34-2 includes a shaker input terminal connected to the blasting bus 20 and receiving electricity generated from the electricity generator 10; A twelfth resistor R603 connected to both ends of the input terminal of the shaker to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; The breaker V601 is connected to the rear end of the twelfth resistor R603 and is connected to the varistor V601 for blocking the flow of current to the explosion line (signal tube) when the breakdown voltage is set to 2000V to 2500V An eleventh safety part constituted by the eleventh safety part; A sixth capacitor portion C601 connected to the eleventh safety portion and charged to the capacitor and discharging the charged charge at the time of causing the corona discharge to prevent the triggering of the signal tube from failing; And a breaker output terminal connected to a rear end of the sixth capacitor unit C601 and connected to a non-electric primer 50 installed at the site of a tunnel and underground excavation through a detour (signal tube) 40. [

Therefore, in order to trigger the signal tube, a corona discharge must be generated between the two electrodes of the device. When the breaker bus line is long, the discharge is weakened due to the integration effect as the L component of the bus line becomes longer. ~ C601), it is possible to prevent the failure of the signal tube by discharging the charged charge at the time of causing the corona discharge.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It is not.

As described above, the detonator of the non-electric primer for tunnel blasting according to the present invention can be applied to tunnel sites and underground excavation sites, as well as to various types of building structures, foundation rock excavation of civil structure, quarry site, And therefore its use and application are broad.

10: electric generator 20: blasting bus
30: non-electric primer breaker 31: first blasting circuit module
32: second blasting circuit module 33: third blasting circuit module
34: fourth blasting circuit module 34-1: fifth blasting circuit module
34-2: Sixth Blasting Circuit Module 35: Spark Tip
36: Spark terminal 37: Vice rack
37-1: Vise projection 37-2: Fastening male thread
38: Vice cap 38-1: Signal tube insertion groove
38-2: sloped tube body 38-3: fastening female thread
39: printed circuit board (PCB) 30A: upper case
30B: lower case 40: signal tube (detonating wire)
50: non-electric primer 60: non-electric primer detonator

Claims (9)

In detonating a non-electrical primer for tunnel blasting,
An electric generator for generating a high voltage of 1200 to 2500 V to supply electric power to the non-electric primer blaster through a blasting bus, a blasting bus for receiving electricity generated from the electric generator and delivering the electric power to the non-electric primer blaster, The spark terminal in the spark tip includes a spark tip composed of two electrodes having a tight gap and the two electrodes are inserted into the signal tube to generate a high voltage current Wherein the spark tip is inserted into the signal tube to cause a strong spark discharge to explode the gun powder applied in the signal tube and the main material of the spark terminal is a brass or similar conductive The metal is an insulating sheath constituting the spark tip The electric wire uses a Teflon wire or an enamel wire, and a non-electric primer blaster for causing a spark discharge to the spark terminal. A signal tube for connecting the non-electric primer blaster to a non-electric primer installed in the tunnel and underground excavation Respectively,
The non-electrical priming blaster includes first to fifth blasting circuit modules, which are mounted on a printed circuit board (PCB) and are composed of electronic components that allow a non-electrical priming blaster to be safely driven, An upper and a lower case for protecting a spark terminal including a spark tip from which a discharge is generated; A vise cap for coupling a signal tube coupled to a vise rack formed at a front end of the upper and lower cases; Wherein the fifth blasting circuit module is connected to the blasting bus and is connected to both ends of the blasting machine input terminal to which electricity generated from the electricity generator is input and to the presence or absence of connection of the detonating circuit by a resistance measuring instrument An eleventh resistor (R503) is connected to the rear end of the eleventh resistor (R503). When a leakage voltage near 380V is inputted from a work site, the voltage is lower than the breakdown voltage of the diode (D501) And a diode D501 that actively senses and controls a voltage input from the outside so as to prevent the lightning from being overheard and the ninth safety unit and the eleventh resistance unit R503 are connected at both ends, And a varistor V501 configured to cut off an abnormal voltage when a breakdown voltage is set to 2000 V to 2500 V in order to prevent a current from flowing into a detonated line (signal tube) A fifth capacitor C501 connected to the tenth safety unit to prevent a failure of the signal tube from being charged while charging the capacitor and discharging the charges charged at the time of causing the corona discharge at a time, (C501) and connected to a non-electrical primer installed at the site of the tunnel and underground excavation through a detonation line (signal tube). The non-electric detonator for tunnel blasting Device. delete The method according to claim 1,
The first blasting circuit module is connected to the blasting bus and includes a generator input for receiving electricity generated by the generator; A first resistor R102 connected to both ends of the input terminal of the shaker to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; When a leakage voltage in the vicinity of 380 V comes from a work site, when the breakdown voltage of the diode (D101) is lower than the breakdown voltage of the diode (D101), the triac (Q101) (Q101) that controls the external input so that the current is blocked because the current can not be turned on because it is unable to turn on the triac (Q101), and the triac From the sudden voltage rise between Diac (D101) and both terminals of the triac, A first safety part comprising a capacitor C102 for preventing development and a safety resistor R101 of a triac Q101; A second resistor R103 connected at both ends of the first safety unit and the first resistor unit R102 to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The second resistor R103 is connected to the varistor V101 to block the current from flowing into the signal line when the abnormal voltage is set by setting the breakdown voltage to 2000V to 2500V in order to protect against the lightning strike A second safety feature configured; A first capacitor unit C101 connected to the second safety unit to prevent a failure of the signal tube from being charged while charging the capacitor and discharging the charged charges at the time of causing the corona discharge; A breaker output terminal connected to a rear end of the first capacitor unit (C101) and connected to a non-electric primer installed at a site of tunnel and underground excavation through a detour (signal tube); Wherein the detonator of the non-electrical detonator for tunnel blasting is characterized in that the detonator of the non-electrical detonator for tunnel blasting is detachable. The method according to claim 1,
The second blasting circuit module is connected to the blasting bus and includes a generator input for receiving electricity generated by the generator; A third resistor R202 connected to both ends of the input terminal of the shaker to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; And is connected to the rear end of the third resistor R202. When a leakage voltage in the vicinity of 380 V enters from a work site, the voltage input from the outside is actively controlled so as not to be energized when the leakage voltage is below the breakdown voltage of the diode D201 A third safety part consisting of a diac (D201) for sensing and controlling; A fourth resistor R203 connected at both ends of the third safety unit and the third resistor R202 and configured to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The varistor V201 is connected to the fourth resistor R203 and is connected to the varistor V201 for blocking the current from flowing into the signal line when the abnormal voltage is set by setting the breakdown voltage to 2000V to 2500V A fourth safety charge configured; A second capacitor unit C201 connected to the fourth safety unit and charged to the capacitor to prevent a failure of the signal tube while simultaneously discharging charges charged at the time of causing a corona discharge; A breaker output terminal connected to a rear end of the second capacitor unit C201 and connected to a non-electric primer installed at the site of a tunnel and underground excavation through a signal line; Wherein the detonator of the non-electrical detonator for tunnel blasting is characterized in that the detonator of the non-electrical detonator for tunnel blasting is detachable. The method according to claim 1,
The third blasting circuit module is connected to the blasting bus and includes a generator input for receiving electricity generated by the generator; Fifth resistors R301 and R302 that add two resistors R301 and R302 at the input terminal of the shaker to absorb the impact of each element when a blast or a lightning stroke occurs; A sixth resistor R303 having both ends connected to the fifth resistors R301 and R302 to check the presence or absence of wiring of the detonating circuit by a resistance meter; And is connected to the rear end of the sixth resistor R303. When a leakage voltage in the vicinity of 380 V comes from a work site, the voltage input from the outside is actively controlled so as not to be energized when the leakage voltage is below the breakdown voltage of the diode D301 A fifth safety part consisting of a diac D301 for detecting and controlling the first safety part; A seventh resistance unit R304 connected at both ends of the fifth safety unit and the sixth resistance unit R303 to set the amount of current to a minimum value in order to flow the current of the detonation circuit; The varistor V301 is connected to the seventh resistor R304 and blocks the current when the abnormal voltage is inputted by setting the breakdown voltage to 2000V to 2500V to protect the lamp from the lightning strike A sixth safety charge configured; A third capacitor unit C301 connected to the sixth safety unit for charging the capacitor and discharging the charges charged at the time of causing the corona discharge to prevent the triggering of the signal tube. A breaker output terminal connected to a rear end of the third capacitor unit C301 and connected to a non-electric primer installed at the site of a tunnel and underground excavation through a signal line; Wherein the detonator of the non-electrical detonator for tunnel blasting is characterized in that the detonator of the non-electrical detonator for tunnel blasting is detachable. The method according to claim 1,
The fourth blasting circuit module is connected to the blasting bus and includes a generator input for receiving electricity generated by the generator; An eighth resistance unit R401 and R402 for adding the two resistors R401 and R402 at the input terminal of the shaker to absorb the impact of each element when the blast or lightning is introduced; A ninth resistance unit R403 having both ends connected to the eighth resistor units R401 and R402 to check the presence or absence of wiring of the detonating circuit by a resistance measuring instrument; And a varistor (V402) connected to the rear end of the ninth resistor (R403) and actively detecting and blocking the leakage voltage when a leakage voltage in the vicinity of 380 V comes from a work site; A tenth resistor R404 connected at both ends to the seventh safety unit and the ninth resistor R403 and setting the amount of current to a minimum value in order to flow the current of the detonation circuit; The varistor V401 is connected to the tenth resistor R404 and is configured to cut off the abnormal voltage when the breakdown voltage is set to 2000V to 2500V in order to protect the lamp from lightning, An eighth safety charge constituted; A fourth capacitor unit C401 connected to the eighth safety unit and charged to the capacitor and discharging the charged charge at the time of causing the corona discharge to prevent the triggering of the signal tube. A breaker output terminal connected to a rear end of the fourth capacitor unit C401 and connected to a non-electric primer installed at the site of a tunnel and underground excavation through a detour line (signal tube); Wherein the detonator of the non-electrical detonator for tunnel blasting is characterized in that the detonator of the non-electrical detonator for tunnel blasting is detachable. delete delete delete

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