KR102590241B1 - Non electric detonator ignition system - Google Patents

Abstract

The present invention relates to a non-electric detonator ignition system for safely and reliably igniting the shock tube of a non-electric detonator used for blasting from a long distance.
The present invention presents a method of igniting a shock tube using an air compressor and a blank bullet, and a method of igniting a shock tube using an electric blaster and a blank bullet.

Description

Non electric detonator ignition system}

The present invention relates to a non-electric detonator ignition system for safely and reliably igniting the shock tube of a non-electric detonator used for blasting from a long distance.

Prior art on how to efficiently ignite a non-electric detonator is described in detail in Domestic Patent Application No. 2010-0129434, “Detonator for a non-electric detonator using a spark detonator and a blasting construction method using the same.”

However, this method also could not be said to be completely safe from electrical hazards as the non-electric detonator is detonated when high-voltage electricity flows.

The purpose of the present invention is to present an ignition system to more safely detonate a non-electric detonator used for blasting purposes in tunnel excavation, etc. from electrical hazards.

Therefore, the present invention proposes a method of igniting the shock tube of a non-electric detonator using an air compressor and a blank bullet, and a method of igniting the shock tube using an electric blaster and a blank bullet, rather than a method of igniting the shock tube of a non-electric detonator with an electric shock.

It has the advantage of being able to reliably ignite the shock tube of a non-electric detonator from a long distance at a low cost and without electrical risk.

Figure 1: Configuration diagram of a shock tube ignition system using an air compressor and blank bullets.
Figure 2: Structural diagram of a pneumatic percussion device.
Figure 3: Configuration diagram of a shock tube ignition system using an electric blaster and a blank bullet.
Figure 4: Structural diagram of a solenoid driven electric trigger device.
Figure 5: Structural diagram of a motor-driven electric percussion device.
Figure 6: Configuration diagram of a remote ignition system using an air compressor and electric blaster.
Figure 7: Block diagram of remote safety ignition system.

In order to easily understand the contents of the present invention, it is as follows through the attached drawings.

Figure 1 is a configuration diagram of a non-electric detonator ignition system using an air compressor and blank bullets.

This figure shows a high-pressure air compressor (10), a pneumatic switch (15), an air tube (20) to ensure a safe distance from the tombstone of the blast site, a pneumatic percussion device (30), and a shock tube (40) for the non-electric detonator. . This is a diagram showing the configuration of an ignition system consisting of a blasting charge charger (50).

Inside the pneumatic percussion device 30, a tableting detonator or blank bullet containing a small amount of gunpowder is loaded. Hereinafter, in the present invention, it is collectively referred to as a blank bullet.

To explain this system in detail, when high-pressure air is compressed in the air compressor 10 and the pneumatic switch 15 is opened, the high-pressure air passes through the air tube 20 and operates the pneumatic percussion device 30. triggers a blank bomb. At this time, the blank bomb transfers heat and shock to the shock tube (40) of the non-electric detonator to ignite it, and the shock tube detonates the loaded explosive (50) of the blasting cap.

Figure 2 is a structural diagram of a pneumatic percussion device.

As shown in Figure 2[a], the pneumatic percussion device 30 includes a pneumatic cylinder 30-1 inside the housing, a reciprocating plunger 30-2, a strike composed of a recovery spring 30-3, and a blank shell 35. It consists of a chamber (30-4) into which it is inserted, and a shock tube receiving portion (30-5).

Figure 2[b] shows a state in which the pneumatic percussion device is triggered. When high-pressure air flows into the pneumatic cylinder (30-1), the plunger (30-2) protrudes and strikes the strike (30-3). , The ball is shown in a state in which the shock tube (40) is ignited by hitting the detonator of the blank bullet (35).

At this time, in the case of a blank bomb of normal power, the usual method is to cut the shock tube and bring it into contact with the blank bullet, then transfer the explosive power of the blank bullet directly to the explosive inside the shock tube tube and ignite it. However, if the power of the blank bullet is strong, it is also possible to ignite it. As shown in 2[c], the shock tube can be ignited with the explosive power by inserting the shock tube horizontally without cutting it and exploding the blank shell outside the tube body.

Figure 3 is a configuration diagram of a shock tube ignition system using an electric blaster and a blank bullet.

This system includes an electric blaster (10-e), a blasting bar (20-e) to ensure a safe distance from the tombstone in the blasting field, an electric percussion device (30-e), and a shock tube (40) for the non-electric detonator. This is a diagram showing the configuration of an ignition system consisting of a blasting charge charger (50).

Unlike typical high-voltage electric blasters of around 1,500V, the above electric blaster requires only enough voltage and current to drive the electric blast device.

Additionally, the electric trigger device 30-e is divided into solenoid driven type and motor driven type.

Figure 4 is a structural diagram of a solenoid driven electric percussion device.

Figure 4[a] is a diagram showing the state before the solenoid-driven electric trigger device (30-e) is triggered, and a solenoid (30-s) is built into it.

Figure 4[b] shows the state in which the electric trigger device is triggered. When electricity flows into the solenoid, the plunger (30-p) of the solenoid protrudes due to electromagnetic force and strikes the strike (30-3), This is a picture of the ball striking the detonator of the blank bullet (35) and igniting the shock tube (40).

Figure 5 is a structural diagram of a motor-driven electric percussion device.

The motor-driven type uses a motor (30-m) instead of a solenoid. Since the motor does not have a reciprocating plunger, a plunger gear (30-pg) in the form of a rack gear engages with the motor gear (30-mg) instead. ) is configured so that the striking plate of the plunger gear strikes the hammer.

The above configuration or structure can be modified to any extent depending on the designer, and an example of the simplest structure is as follows through the floor plan.

Figure 5[a] shows the state before the motor-driven electric percussion device is triggered, where the motor gear (30-mg) is engaged with the plunger gear (30-pg) in the form of a rack gear and the striking compression spring (30). -s) is a picture in a loose state.

Figure 5[b] shows a state in which the percussion device is triggered. The motor gear rotates and pulls the plunger gear, and then the plunger gear is separated. At this time, the compressed striking compression spring rapidly expands and strongly pushes the plunger gear, causing the plunger gear to detach. This picture shows the state in which the striking plate (30-hb) of the gear strikes the hammer, and the striker strikes the detonator of the blank shell, triggering the blank shell.

Figure 6 is a configuration diagram of a remote ignition system using an air compressor and an electric blaster.

This illustration shows a remote ignition system for igniting a non-electric detonator from hundreds of meters or kilometers away.

When using the air compressor 10, it becomes difficult to operate the pneumatic percussion device 30 because the air pressure decreases as the length of the air tube increases.

The above figure is intended to overcome this problem by installing an air tank (10-A) between the air tubes (20-A, 20-B) and using an electrically operated solenoid valve (15-) to open and close the air tank. After installing A), connect it with the blasting bus bar (20-e) to the blasting location hundreds of meters or several kilometers away. Then, connect the blast bus bar line to the electric blaster (10-e) and press the blaster. When the blaster is pressed, the solenoid valve opens and the pneumatic blast is fired. This is an example of how the device 30 operates.

In the present invention, the description is limited to the solenoid valve, but all electrically driven valves are included in the scope of the present invention.

Figure 7 is a block diagram of a remote safety ignition system.

The purpose of the present invention is to ignite the shock tube safely from a distance, and the trigger device should never be triggered due to unexpected electricity in the excavation tunnel.

Therefore, when blasting using an electric blaster, an ignition system must be installed to make it more electrically safe.

In the present invention, a method of firing a blank bullet with an electric blaster includes using a solenoid-driven percussion device, a motor-driven percussion device, and a solenoid valve.

However, for safer ignition, it is desirable that even if power is supplied to the percussion device, it does not operate without a special electrical signal.

Therefore, this picture shows a control board composed of an MCU and relays (including semiconductor switches such as thyristors) in front of the three trigger devices mentioned above, and the blaster is composed of a device that sends current and signals, so that a special electric signal is sent from the blaster. When it reaches the MCU, the MCU connects the relay to create a trigger circuit. When the trigger circuit is completed, the MCU sends a signal to the blaster to send a trigger current, showing a block diagram of how the final trigger device is driven.

10: Air compressor 15: Pneumatic switch 20: Air tube
30: Pneumatic percussion device 30-1: Pneumatic cylinder 30-2: Plunger
40) Shock tube 50) Loading explosives
10-e: Electric blaster 15-A: Solenoid valve
30-e: Electric trigger device (solenoid driven type, motor driven type)

Claims (7)

In the ignition system for igniting the shock tube of a non-electric detonator used for blasting purposes in tunnel excavation, etc.,
The ignition system includes an air compressor (10), a pneumatic switch (15), an air tube (20) to ensure a safe distance from the tombstone, a pneumatic percussion device (30), and a shock tube (40) for the non-electric detonator. Includes loaded explosives (50) for blasting,
The pneumatic percussion device includes a pneumatic cylinder (30-1) inside the housing, a plunger (30-2), a strike (30-3) with a recovery spring, a chamber (30-4) into which a blank bullet (35) is inserted, and a shock tube. A non-electric detonator ignition system including a receiving portion (30-5).
delete In the ignition system for igniting the shock tube of a non-electric detonator used for blasting purposes in tunnel excavation, etc.,
The ignition system consists of an electric blaster (10-e), a blasting bus bar (20-e) to ensure a safe distance from the tombstone, and the plunger (30-p) protrudes or the plunger gear (30-pg) rotates by supplying electricity. and an electric percussion device (30-e) that pressurizes the blank bullet (35) by hitting the ball, and a shock tube (40) of the non-electric detonator. A non-electric detonator ignition system that is characterized by consisting of a blasting film loaded explosive charge (50).
According to clause 3,
The electric percussion device has a solenoid inside, and when electricity flows into the solenoid, the plunger (30-p) of the solenoid protrudes by electromagnetic force and strikes the strike (30-3), and the strike strikes the detonator of the blank bullet (35). A non-electric detonator ignition system characterized by a solenoid-driven type that ignites the shock tube (40) by hitting it.
According to clause 3,
The electric percussion device has a motor inside, and the motor consists of a motor gear (30-mg) and a plunger gear (30-pg) in the form of a rack gear that engages with the motor gear. As the motor gear rotates, the plunger gear strikes. A non-electric detonator ignition system characterized by a motor-driven type in which the plate (30-hb) strikes the bomb, and the hammer strikes the detonator of the blank bullet to ignite the shock tube (40). In an ignition system that ignites the shock tube of a non-electric detonator used for blasting purposes in tunnel excavation, etc., from hundreds of meters or several kilometers away,
The ignition system includes an air compressor (10), air tubes (20-A, 20-B), an air tank (10-A), and an electrically operated solenoid valve (15-A) to open and close the air tank (10-A). ), a pneumatic percussion device (30), a shock tube (40) of a non-electric detonator, and a charging explosive (50) of a blasting field, and the solenoid valve includes a blasting mother line (20-e) of hundreds of meters or several kilometers and an electric When the blaster (10-e) is connected and the electric blaster is pressed, the solenoid valve opens and the pneumatic percussion device (30) operates to ignite the shock tube.
The pneumatic percussion device 30 includes a pneumatic cylinder 30-1, a plunger 30-2, a strike 30-3 with a recovery spring, and a chamber 30-4 into which a blank bullet 35 is inserted inside the housing. , a non-electric detonator ignition system including a shock tube receiving portion (30-5).
According to any one of paragraphs 3 or 6,
The ignition system consists of a control board consisting of an MCU and a relay at the front of the percussion device connected to the blasting mother line (20-e),
When a special electrical signal transmitted from an electric blaster that sends current and signals reaches the MCU,
The MCU is a non-electric detonator ignition system that connects a relay to create a trigger circuit and then transmits a signal to send a trigger current to the electric blaster.