KR102054154B1 - Cannon fuse - Google Patents

Abstract

Disclosed is a projectile detonator comprising: a passive element (200) which receives power to explode; and a digital circuit (100) which is supplied with power on/off in response to a detonation signal and applies the power to the passive element (200). Accordingly, the present invention has an advantage that the power can be applied to the passive element in accordance with the detonation signal, and the projectile detonator is redundantly configured, and performs stable detonation without causing an explosion accident due to an unspecified cause by using a reverse capacitor.

Description

Shell detonator {CANNON FUSE}

The present invention relates to a detonator and, more particularly, to a detonator for detonating a shell.

One application of the detonator is the shell detonator. The detonator may detonate the shell in response to the detonation signal. The detonator must ensure the stability of the passive elements detonated by the control circuit and the construction of the control circuit that processes the detonator signal in order to stably fire the shell when the detonator signal is given. In the conventional detonator, the stability of the passive element is low, and the operation of detonating the shell may be unstable as the configuration of the control circuit is complicated. There is a need for a detonator that improves the problem of such a detonator.

Registration No. 10-1336424, Detonator Circuit of Electronic Primer Registration No. 10-0659219, Detonator

An object of the present invention for solving the above problems is to provide a detonator for applying power to a passive element in accordance with the detonator signal.

Another object of the present invention is to provide a detonator configured to be redundant.

It is also an object of the present invention to provide an initiator using a reverse capacitor.

The present invention for achieving the above object, the passive element 200 that receives the power to explode; And a digital circuit 100 that is supplied with power on / off in response to the detonation signal and applies power to the passive element 200.

In addition, the digital circuit 100 is composed of two, each of the two passive circuits 200 is configured in the digital circuit (100).

The passive element 200 is also a reverse capacitor 210.

The passive element 200 is also a forward capacitor 220.

In addition, the passive element 200 is a resistor 230 with the coating peeled off.

In addition, the digital circuit 100 may include a first input terminal for receiving an initiator signal; A second input terminal receiving power; An output terminal to which the passive element 200 is connected; And a control circuit for supplying power to the output terminal according to the detonation signal and applying power to the output terminal.

In the case of using the detonator according to the present invention as described above, power can be applied to the passive element according to the detonator signal.

In addition, there is an advantage in that the redundant configuration and the use of the reverse capacitor to perform a stable detonation without causing an explosion accident due to an unspecified cause.

1 is an exemplary view showing a conventional detonator.
2 is a block diagram showing an initiator.
3 is an illustration of the initiator.
4 is a first embodiment of the initiator.
5 is a second embodiment of the initiator.
6 is a third embodiment of the initiator.
7 is a block diagram illustrating a digital circuit 100.
8 is a fourth embodiment of the initiator.
FIG. 9 shows that the debris scatters due to an explosion when an overvoltage or reverse voltage is applied to the capacitor.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present disclosure does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The detonator is suitable for shells, but can be sufficiently adapted to other applications where detonation is required. For example, the detonator may be applied to a shell detonator.

The detonator may apply power to the passive element in accordance with the detonator signal. The detonator has the advantage of performing a stable detonation without duplication due to an unspecified cause by using a redundant configuration and a reverse capacitor.

1 is an exemplary view showing a conventional detonator.

Conventional detonator power supply unit 10 for conducting only a certain voltage or more; A charge / discharge circuit 20 for charging or discharging the power of the power supply unit 10; And a digital circuit 30 that supplies the power of the charge / discharge circuit 20 to the detonation wire on / off in response to the detonation signal.

The power supply unit 10 conducts only a certain voltage or more. The detonator should use a stable voltage when detonating the shell. The power supply unit 10 conducts only a predetermined voltage or more to provide a stable voltage to the detonator.

The charge / discharge circuit 20 charges or discharges the power of the power supply unit 10 according to a charging signal. The charge / discharge circuit 20 charges or discharges the power of the power supply unit 10 according to the control of the charging signal to supply power to the digital circuit 30. Since the detonation wire is sensitive to power supply and the shell may be detonated when the power is inadvertently applied, the charge / discharge circuit 20 performs an operation of applying power to the digital circuit 30 only when the charging signal is on.

The digital circuit 30 supplies the power of the charge / discharge circuit 20 to the detonation wire on / off in accordance with the detonation signal. The digital circuit 30 supplies the power of the charge / discharge circuit 20 to the detonation wire in accordance with the detonation signal so that the detonation wire explodes to detonate the shell.

The conventional detonator comprises a power supply unit 10, a charge and discharge circuit 20 and a digital circuit 30 to stably use the detonation wire sensitive to power application. As a control signal, a charge signal and an initiator signal are used, and the charge signal is input to the charge / discharge circuit 20 and the initiator signal is input to the digital circuit 30. Conventional detonator uses a detonation wire sensitive to the power supply, the explosion of the detonation wire may occur due to unspecified causes. Without using such a detonator wire, the structure of a detonator is also simplified, and the demand for a detonator is made high.

2 is a block diagram showing an initiator of the present invention.

The detonator includes a passive element 200 that receives power and explodes; And a digital circuit 100 that is supplied with power on / off in response to the detonation signal and applies power to the passive element 200.

The passive element 200 receives the power and explodes. The passive element 200 is not sensitive to power and explodes by being supplied with a constant voltage.

The digital circuit 100 receives power on / off according to the detonation signal and applies power to the passive element 200. If the detonation signal is on, power is supplied to the passive element 200, and if the detonation signal is off, power is not supplied to the passive element 200. The digital circuit 100 turns the power on / off in accordance with the on / off of the detonation signal.

3 is an illustration of the initiator.

The digital circuit 100 is composed of two, and the passive elements 200 are configured in each of the two digital circuits 100. The digital circuit 100 is composed of two to duplicate the operation of the detonator. The detonator is redundant so that only one of the two digital circuits 100 can operate normally.

4 is a first embodiment of the initiator.

The passive element 200 is a reverse capacitor 210. The digital circuit 100 applies power to the reverse capacitor 210 to explode. If the passive element 200 is the reverse capacitor 210, when the digital circuit 100 applies the power to the reverse capacitor 210, the forward power is applied to the reverse capacitor 210 to explode the reverse capacitor 210. The detonator uses the explosion of the reverse capacitor 210 to detonate the shell.

5 is a second embodiment of the initiator.

The passive element 200 is a forward capacitor 220. The digital circuit 100 applies power to the forward capacitor 220 to explode. If the passive element 200 is the forward capacitor 220, when the digital circuit 100 applies the power to the forward capacitor 220, the forward power is applied to the forward capacitor 220, and if the predetermined power exceeds the forward capacitor 220. Will explode. The detonator detonates the shell using the explosion of the forward capacitor 220. When the passive element uses the capacitors 210 and 220 as shown in the first and second embodiments, the passive element is more expensive than the resistance. However, in the case of the capacitor, if the capacitor provides an appropriate voltage condition, the capacitor is critical. As a result of reaching the temperature, the capacitor explodes, and the debris of the exploded capacitor due to the explosion has an advantage of spreading (spreading) heat well to the surroundings. This heat spreading can accurately trigger the explosives formed around the capacitor. On the other hand, the conventional method using a passive device such as a wire method or a resistance is different from the operation method of the capacitor because the debris due to the explosion does not diffuse heat to the surroundings, but transfers the heat to the surroundings. As a result, when a capacitor among passive elements is used as an element of the detonator, it explodes accurately when desired, so that operation is stable.

6 is a third embodiment of the initiator.

The passive element 200 is a resistor 230 with the coating peeled off. The digital circuit 100 explodes by applying power to the exposed resistor. If the passive element 200 is a resistor 230 having the coating peeled off, when the digital circuit 100 applies the power to the exposed resistor, the forward power is applied to the exposed resistor 230, and if the predetermined time is exceeded, the exposure is performed. It explodes due to the heat generated by the peeling resistor 230. The detonator detonates the shell using an explosion of the exposed resistance 230.

7 is a block diagram illustrating a digital circuit 100.

The digital circuit 100 may include a first input terminal ON / OFF for receiving an initiator signal; A second input terminal VIN receiving power; An output terminal VOUT to which the passive element 200 is connected; And control circuits Q1 and Q2 for supplying power to the output terminal according to the detonation signal and for supplying power to the output terminal.

The first input terminal ON / OFF receives an initiator signal. The second input terminal VIN receives power. The output terminal VOUT is connected to the passive element 200. The control circuits Q1 and Q2 are powered on / off according to the detonation signal and apply power to the output terminal VOUT. FETs are used for the control circuits Q1 and Q2 to drive on / off in accordance with the detonation signal. The FET Q1 of the control circuit is turned on / off by the detonation signal, and the FET Q2 of the control circuit is powered on / off by the FET Q1. The control circuits Q1 and Q2 operate to supply power to the passive element 200 on / off by the detonation signal.

8 is a fourth embodiment of the initiator.

The detonator may further include a timer controller 300 for operating the timer when the detonator command is issued to execute a time delay and then output the detonator signal. The detonation signal output from the timer controller 300 is input to the digital circuit 100 so that the digital circuit 100 bursts the passive element 200 so that the bomb is detonated. The timer controller 300 outputs a detonation signal after executing a time delay by operating a timer when the detonation command is issued.

FIG. 9 shows that the debris scatters due to an explosion when an overvoltage or reverse voltage is applied to the capacitor. As shown in FIG. 9, unlike the passive element such as the resistor, the capacitor has an advantage of igniting the explosive material formed at the periphery because debris including high heat is scattered and diffused.

In summary, the present invention constitutes a detonator circuit with a digital circuit, and when the detonator signal is input, the detonator detonates the passive element 200 to detonate the bomb stably. Conventional detonators are analog circuits that can cause unexpected operation, but the detonators of the present invention improve reliability by providing a detonator circuit that reacts when a detonator signal is given to a digital circuit. In addition, since the detonator of the present invention does not need the same configuration as the charge / discharge circuit 20 used to stably supply the input of the digital circuit 30 in the shell detonator, the charge / discharge circuit 20 is configured. This can reduce the cause of the explosion malfunction that can occur due to the malfunction of the resistor and the capacitor or the asymmetrical operation of the capacitor, and also reduce the size of the entire detonator and lower the cost.

The detonator may apply power to the passive element in accordance with the detonator signal.

The detonator has the advantage of performing a stable detonation without duplication due to an unspecified cause by using a redundant configuration and a reverse capacitor.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

10: power supply unit 20: charge and discharge circuit
30: digital circuit 100: digital circuit
200: passive element 210: reverse capacitor
220: forward capacitor 230: stripped resistance
300: timer control unit

Claims (6)

Passive element 200 that receives the power to explode; And
And a digital circuit 100 that is supplied with power on / off according to the detonation signal and applies power to the passive element 200.
The digital circuit 100 is composed of two, and each of the passive elements 200 are configured in two digital circuits 100 so that one of the two digital circuits 100 can operate normally,
The passive element 200 is a reverse capacitor 210 or a forward capacitor 220,
The digital circuit 100 is
When the passive element 200 is the reverse capacitor 210, when the digital circuit 100 applies the power to the reverse capacitor 210, the forward power is applied to the reverse capacitor 210 to explode the reverse capacitor 210. ,
When the passive element 200 is the forward capacitor 220, when the digital circuit 100 applies the power to the forward capacitor 220, the forward power is applied to the forward capacitor 220, and if the predetermined power exceeds the forward capacitor 220. Detonator). delete delete delete delete The method of claim 1,
The digital circuit 100 includes a first input terminal for receiving an initiator signal;
A second input terminal receiving power;
An output terminal to which the passive element 200 is connected; And
And a control circuit for receiving the power on / off according to the detonation signal and applying the power to the output terminal.

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