KR940008529Y1 - Inspecting circuit for measuing reliability of impact switch in proximity fuses - Google Patents

Abstract

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Description

Shock switch operating function test circuit of shell near fuse

1 is a circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: Shock switch 2: Comparator

3: oscillation circuit 4,5: counter circuit

6 optical sensor 7 reset switch

8 inverter 9 flip-flop circuit

10: Display lamp AND ₁ -AND ₂ : AND gate

R ₁ -R ₄ : Resistance

The present invention relates to a functional test circuit of the impact switch that can screen only the high-quality products according to the measurement result by examining the function of the impact switch built in the shell proximity fuse.

The function of the impact switch in the shell proximity fuse has the function to paralyze the melee function that can cause the shell to explode when reaching a specific target after firing or to explode when colliding with the bottom when an abnormality occurs in the fuse. In other words, when the shell collides with the ground, the contact point of the switch is connected by an impact to apply an ignition signal to the primer to cause the shell to explode. Therefore, a shock switch having this function should be connected over a certain impact range. If the impact position is not connected during collision with the ground, the ignition signal cannot be applied to the primer and the shell cannot be exploded and thus cannot function as an impact switch.

Therefore, the present invention is to select only good quality products by checking whether the shock switch used for the shell proximity fuse is connected within the regulated impact range. It is an object of the present invention to provide an operation function test circuit of the impact switch that can detect only the high-quality product by detecting it when the switch is connected by the impact.

Hereinafter, described in detail by the accompanying drawings as follows.

As shown in FIG. 1, 20 V power is applied to one end of the shock switch 1 through the resistor R ₁ , and the other terminal is connected to the non-inverting terminal of the comparator 2 via the resistor R ₂ . A 2V reference low voltage is applied to the inverting terminal, while the input of the AND gate AND ₁ applies a frequency of 10 MHZ from which the output signal of the comparator 2 is generated in the oscillation circuit 3, but the output terminal thereof is applied to the counter circuit 4 ( 5) the signal of the optical sensor 6 mounted on the counter circuit (4) (5) and the device for imparting a shock condition and the clock of the counter circuit (4) (5) and the gate (NAD ₂ ). To the flip-flop circuit 9 and to turn on the lamp 10 as an output signal thereof, and to the reset switch 7 to which a 5V power is applied, through the resistor R ₃ , through each counter circuit 4. Shock switch operation function of shell near fuse connected to flip-flop circuit (9) through (5) and inverter (8) It is an inspection circuit.

Referring to the effect of the present invention made of the configuration as described above are as follows.

First, in order for the impact switch 1 to have a normal function, two conditions must be satisfied. First, when the shock switch 1 is connected, the resistance value of the shock switch 1 should be less than 10Ω. The reason is that when the resistance value of the shock switch 1 itself is high, the power of the battery built in the fuse is shocked. Because the switch 1 consumes a lot of energy, proper ignition energy cannot be applied to the primer. Therefore, the resistance value of the impact switch 1 should be 10 kΩ or less.

Second, the time that the impact switch 1 is connected should satisfy the condition of 5usec or more. This is because power should be applied to the primer that can explode the propellant for a certain time. If the connection is made only for a short time of less than 5usec, the result is that the primer cannot be ignited. Therefore, when the above conditions are satisfied, the lamp 10 is turned on to indicate that the product is of good quality.

Referring to FIG. 1, if a shock is applied to the damper with a shock switch 1 built in a device (not shown) that has the same effect when a collision with the ground occurs after the shell is fired, The sensor 6 operates to apply a signal to the AND gate AND ₂ , while the connection piece embedded in the shock switch 1 is connected to a contact, and as a result, the shock switch 1 is turned on. .

Therefore, when the shock switch 1 is connected, a 20V power supply is applied to the non-inverting terminal of the comparator 2 by limiting the current by the resistors R ₁ and R ₂ . At this time, the output signal of the comparator 2 is " high " when the two input conditions of the input current and the resistance value are 10 kΩ or less compared to the reference voltage 2V (concept of 10 mA) input to the inverting terminal of the comparator 2. It is applied to one terminal of the AND gate (AND ₁ ) and counted by the counter circuit (4) (5) by simultaneously combining the frequencies of 10 MEZ output from the inverting circuit (3). AND ₂ ) combines the counting signal of the two counter circuits 4 and 5 and the signal of the optical sensor 6 to the set terminal of the flip-flop circuit 9 when this value is switched from "high" to "low". As it is applied, the lamp 10 is turned on to indicate that it is connected for more than 5usec. If the time that the impact switch 1 is connected is less than the prescribed time, the output signal of the counter circuit 5 is kept low, so that the set signal cannot be applied to the flip-flop circuit 9, so that the lamp 10 Does not light up. Therefore, when the connection resistance of the shock switch 1 is 100 kW or less and the connection time is 5usec or more, the lamp 10 is turned on to confirm that the shock switch 1 is of good quality. On the other hand, when initializing the circuit after the measurement is completed, when the reset switch 7 is connected to the on state, the 5V power supply is supplied through the resistor R ₃ to reset the counter circuits 4 and 5 and the flip-flop circuit 9. When the signal is transmitted to the set end, all circuits are cleared and returned to the ready state in which the other impact switch 1 can be measured. In the present invention, a plurality of circuits as shown in FIG. 1 are connected to several shock switches 1 at a time. Since it is to measure the operation state of many impact switch (1) in a short time.

The present invention, which operates as described above, examines the operation function of the impact switch 1 used for the shell proximity fuse, that is, the resistance value and the time that is connected when the impact switch 1 is connected, and the two conditions are determined. When present in the standard range by the lamp 10 is to be turned on to measure the impact switch 1 quickly and precisely to select only good quality products.

Claims (1)

At one end of the shock switch 1, a 20V power supply is applied through a resistor R ₁ , and the other terminal is connected to a non-inverting terminal of the comparator 2 via a resistor R ₂ , and a reference of 2V to the inverting terminal. While the voltage is applied, the input of the AND gate AND ₁ applies the output signal of the comparator 2 and the frequency of 10 MHZ generated from the oscillation circuit 3, but transmits its output terminal to the counter circuit 4, 5. The signal of the optical sensor 6 and the clock of the counter circuit 4 and 5 mounted on the counter circuit 4 and 5 and the device imparting the impact condition are flip-flop circuits through the AND gate AND ₂ . 9) and to turn on the lamp 10 as its output signal, and to the reset switch 7 to which 5V power is applied, through the resistor R ₃ , each counter circuit 4 and 5 and the inverter Impact switch actuator of the shell proximity fuse, characterized in that connected to the flip-flop circuit (9) through (8) Test circuit.