KR20210144219A - Blasting machine for non-electric detonator and ignition system using same - Google Patents

Abstract

Blasting with a non-electric detonator is mainly performed at blasting sites for tunnel and underground excavation. Until now, a triggering method using a starter detonator and a starter, and a triggering method using a spark triggering device and an electric blasting machine have been used in triggering a non-electric detonator. However, the triggering method using the starter detonator and the starter requires high triggering costs and leaves plastic waste, and the triggering method using the spark detonator and the electric blasting machine requires low costs but often has failed in blasting since voltage is dropped as blasting leading wire gets long. Therefore, in order to solve the above problems, the present invention provides a blasting machine for a non-electric detonator and a triggering system, in which a means capable of directly or indirectly triggering the non-electric detonator is formed at the electric blasting machine and a starter capable of driving the electric blasting machine at a remote place is formed, thereby triggering the non-electric detonator at a remote place cheaply, safely and definitely. The blasting machine for the non-electric detonator and the triggering system using the same have an effect of being capable of triggering the non-electric detonator at a remote place cheaply, safely and definitely.

Description

Blasting machine for non-electric detonator and ignition system using same

The present invention relates to a detonator and a detonation system for remotely detonating a non-electric detonator.

At blasting sites for tunnels and underground excavation, blasting is mainly performed using non-electric detonators. Until now, detonation methods using starter detonators and percussion devices and detonation methods using spark detonators and electric detonators were used to detonate non-electric detonators. .

However, the detonation method using the starter detonator and percussion machine is expensive and leaves plastic waste, and the detonation method using the spark detonator and the electric blaster is inexpensive, but the voltage drops as the blasting bus length becomes longer and the blasting often fails. .

The present invention constitutes a means for directly or indirectly detonating a non-electric detonator to an electric blaster in order to solve the above problems, and a non-electric detonator blaster and detonator configured with a percussion unit capable of operating the electric blaster from a distance provide the system.

The non-electric detonator blaster and the detonation system using the same have the effect of safely and reliably detonating the non-electric detonator at a low detonation cost from a long distance.

1 is a configuration diagram of a conventional non-electric detonator detonation system.
Figure 2 is a configuration diagram of a detonation system using a blaster for non-electric detonators.
Figure 3 is a blasting circuit diagram of the blaster and detonation system for non-electric detonators.

The present invention relates to a blaster for a non-electric detonator that can safely and reliably detonate a non-electric detonator from a long distance, and a detonation system using the same.

Through the accompanying drawings, the problems of the conventional non-electric detonator detonation system will be examined and the blaster and detonation system of the present invention for improving this will be described.

1 is a block diagram of a conventional non-electric detonator detonation system.

1 [A] is a picture of the most conservative non-electric detonator detonation system. The blasting curtain 100 loaded with explosives as a non-electric detonator, and a bunch detonator in which the non-electric detonator of the blasting film field is finally connected as one non-electric detonator. (10), the detonation detonator 20 for detonating the bundle detonator, the signal tube 25 for evacuating to a safe distance from the scattered blasting rocks, and a percussion unit 40 for initial detonation of the signal tube.

In this configuration, the detonation detonator 20 for detonating the bunch detonator and the signal tube 25 of 3000 m or more to evacuate to a safe distance are usually composed of one product group, which is called the starter detonator 30 and is called the starter detonator from the blasting field. All detonators up to this point are composed of non-electric detonators through which the signal tube transmits virulence.

The above configuration is very safe from electrical hazards, but the cost of a starter detonator to secure a safe distance is high, and a waste plastic signal tube is generated every blasting, so this conservative detonation method is avoided in the actual field.

1 [B] is a configuration diagram of a non-electric detonator detonation system using a spark detonator presented as an alternative to solve the above problems.

If you look at this configuration in detail, the blasting curtain 100 loaded with a non-electric detonator, the bundle detonator 10 that connects the non-electric detonator of the blast film field with one final, and the spark detonator 200 that connects to the bundle detonator or starter detonator , It is composed of a blasting bus 300 for evacuating to a safe distance of 300 m or more by connecting to the spark detonator, and an electric blasting machine 400 for sending a high-voltage current by connecting to the end of the blasting bus.

However, the detonation method using the spark detonator has a low detonation cost, but as the distance increases, the resistance of the blasting bus bar increases and there are many joints, which causes leakage current, which sometimes fails to blast.

The present invention is to solve the above problems, and to provide a blaster for a non-electric detonator and a blasting system using the same for lowering the detonation cost at a long distance, reducing the blast failure, and safely and reliably detonating the non-electric detonator.

2 is a configuration diagram of a detonation system using a blaster for non-electric detonators.

The present invention configures a non-electric detonator detonation system that operates a blaster using a percussion device from a distance by placing a blaster for a non-electric detonator at a minimum safe distance from the blasting curtain.

Figure 2 [A] shows a wired detonation system for directly detonating the starter detonator, the bundle detonator 10 that is finally connected to the blasting field 100, and the starter detonator 30 to secure a safe distance by connecting with the bundle detonator ), the blaster 400 that directly detonates the starter detonator by charging and outputting a high-pressure current, the second blasting busbar 450 that secures an additional safety distance from the blaster to the blasting location, and the second blasting bus connected to the blasting bus Consists of a percussion device 500 that sends a percussion signal to the unit.

The blaster for the non-electric detonator is configured such that a spark terminal 401 for directly detonating the signal tube of the starter detonator is replaceable, and the spark terminal is a positive terminal (a), a gap insulator (b), and a negative electrode as shown in the enlarged figure. It is assembled with a terminal (c) and a plastic or metal housing (d) and fastened to the connection terminal of the blaster.

The most characteristic and noteworthy configuration of the detonation system should be a structure in which the blaster does not trigger even if the two lines of the second blasting bus bar 450 connecting the blaster and the percussion machine are short-circuited with each other.

Therefore, the second blasting bus line is not a structure in which the blasting switch of the blaster is simply connected for a long time, but is a type of communication line that transmits the current and command of the percussion device with a separate power source to the blaster and transmits the state of the blaster to the percussion unit. Without this, the electrical circuitry is constructed so that the blaster cannot be triggered.

The electric circuit of the blaster and detonation system for non-electric detonator having these characteristics will be described in detail again and will be omitted from the description of this drawing.

2 [B] shows a wired detonation system for non-electric detonators using the spark detonator 200, and the spark detonator 200, the first blasting bus 300, and the blaster are installed in the final signal tube of the blasting film field. 400, the second blasting busbar 450, and the percussion machine 500 are sequentially configured, and the detonation method is the same as described above, but the starter detonator is not connected to the blaster, but the blasting busbar and the spark detonation to the connection terminal 402 It is different that the device 200 is connected.

2 [C] relates to a wireless detonation system for a non-electric detonator that has replaced the second blasting bus by wireless, and a spark terminal 401 for directly detonating the starter detonator 30 or a connection terminal 402 for indirect detonating ) is composed of a wireless blaster (400-A), a wireless blaster (500-A) and a safety key 550 for preventing blasting accidents.

In the above configuration, the safety key 550 can access the loaded bar while carrying the wireless percussion device urgently when the blasting fails. It is a safety device to prevent operation when out of position.

3 is a blasting circuit diagram of a blaster and detonation system for non-electric detonators.

3 [A] shows the overall configuration of the detonation system composed of a blaster for non-electric detonators. For convenience of explanation, the blaster has a spark terminal 401 for directly detonating the starter detonator as a means for detonating the non-electric detonator. ) and a connection terminal 402 for indirect initiation by the spark initiator were formed at the same time.

Looking at the configuration of this system, the starter detonator 30, which is the final non-electric detonator of the blasting field, or the first blasting bus 300 to which the spark detonator is connected, the blaster 400 that generates a high-pressure current and blasts, the blaster A second blasting busbar 450 that connects a long distance from the to the blasting position by wire, and a dedicated percussion device 500 that can charge and trigger the blaster are sequentially connected and configured to prevent a blasting accident in the case of a wireless detonation system. The safety key 550 is additionally configured, and in the case of a wired detonation system, the percussion and the safety key are configured as one device.

The dedicated blaster of the above configuration is a spark terminal 401 for initiating by connecting a starter detonator or a connection terminal 402 of a first blasting bus bar connected to a spark detonator, a connection terminal 403 of a second blasting bus bar, a charging switch ( 400-a), the blasting switch 400-b, etc. are configured, and in the case of a wireless detonation system, the connection terminal 403 of the second blasting bus is replaced with a wireless antenna.

The dedicated percussion unit 500 has a built-in circuit that can generate a pulse signal using a battery (550-a), which is a separate power source, transmits it to the blaster and receives the state of the blaster, and can charge, trigger, and discharge the blaster. A switch is configured.

The safety key 550 has a built-in battery (550-a) that operates the dedicated percussion unit or has a structure of a switch that simply connects the circuit of the percussion unit. In this case, it must be configured separately so that blasting is never carried out even when approaching the blasting curtain while carrying the wireless percussion device.

3 [B] is a diagram expressing the configuration of the system as an electric circuit, and the most important feature of this configuration is a circuit in which the charging blaster cannot be triggered even if the second blasting bus line between the blaster and the percussion machine is short-circuited. should be

Therefore, the second blasting bus line is not a switch wire that switches the blasting switch 400-b of the blaster from a distance by simply shorting the two wires, but a communication line that transmits a separate current and electric signal for operating the blasting switch. do.

When the circuit of the above structure is described with reference to the accompanying drawings, a relay switch (R-1) is formed in parallel to the circuit of the blasting switch (400-b) inside the dedicated blaster 400, and this relay switch is the second It is connected to the connection terminal 403 for connecting the blasting bus, and the second blasting bus connected to the connection terminal 403 is connected to the percussion device 500 equipped with a battery.

Therefore, even if the second blast bus is short-circuited in the absence of the percussion unit, the percussion cannot be made because the relay switch (R-1) does not operate.

By applying this basic circuit, an MCU is additionally configured in the blaster and percussion unit, and a relay switch that can charge and discharge (R-2) in parallel with the charging switch (400-a) is additionally configured in the blaster to generate a percussion unit. Pressing the charging switch (500-a) and the triggering switch (500-b) in the blaster to charge and trigger, sometimes it is also possible to add a function of disconnecting the power when the blasting fails.

In addition, by configuring a wireless communication module in the connection terminal connecting the blaster having the above circuit and the second blasting bus of the percussion machine, it is possible to implement a wireless detonation system that controls the MCU and the relay switch built into the blaster according to mutually set radio signals. The circuit must be configured so that the radio trigger works only when the safety key is connected.

The blaster for a non-electric detonator of the present invention and a detonation system using the same can reduce blast failure and detonate a non-electric detonator safely and reliably from a greater distance.

10: bunch primer 30: starter primer
200: spark width device 300: first blast busbar
400: blaster 400-A: wireless blaster
450: second blast mother ship 500: percussion
500-A: wireless percussion 550: safety key

Claims (7)

In the blaster and detonation system for remotely detonating a non-electric detonator mainly used at a blasting site for tunnel excavation or underground excavation,
A spark detonator ( 200) and the first blasting bus 300 to ensure a minimum safety distance;
a blaster 40 for outputting a high-voltage current to the starter detonator or blast bus;
a second blasting busbar 450 that connects to the blaster to secure an additional safety distance to the blasting position and transmits a triggering signal;
Percussion device 500 for sending a percussion signal to the blaster connected to the second blasting bus;
A blaster for non-electric detonators characterized by detonating the non-electric detonator by pressing the percussion switch (500-b) of the percussion unit and detonation system using the same.
The method of claim 1,
The blaster is configured with a spark terminal 401 for initiating a starter primer or a connection terminal 402 for connecting the first blasting bus, and a connection terminal 403 for connecting the second blasting bus. A blaster for an electric detonator and a detonation system using the same.
3. The method of claim 1 and 2,
The blaster has a built-in relay switch in parallel to the electric circuit of the blasting switch (400-b).
The method of claim 1,
The second blasting bus is a blaster for non-electric detonators and a detonation system using the same, characterized in that it is a communication line that secures a safe distance and transmits the percussion signal of the percussion device to the blaster at the blasting position.
The method of claim 1,
A blaster for non-electric detonators and a detonation system using the same, which has a built-in battery and sends a trigger signal to the blaster and controls the relay switch or the MCU that operates the relay switch inside the blaster.
The method of claim 1,
Non-electric detonator blaster and detonation system using the same, characterized in that the percussion and detonator are a wireless percussion unit (500-A) and a radio detonator (400-A) with a built-in wireless communication module.
7. The method of claim 6,
The wireless percussion device (500-A) is a non-electric detonator blaster and a detonation system using the same, characterized in that it sends a firing signal only when the safety key 550 installed at the blasting position is connected.

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