RU2760666C1 - Electric explosive circuit tester - Google Patents

Abstract

FIELD: blasting operations.

SUBSTANCE: invention relates to devices for blasting operations, in particular to devices for testing the safety and performance of an electric explosive circuit, which includes an explosive device, conductors and an electric detonator. The safety of the explosive circuit is checked by the absence of stray currents in it, and the operability is checked by the formation in the explosive circuit of a current pulse from an explosive device, the amplitude and duration of which ensures the guaranteed operation of an electric detonator or other electrical means of initiation. The device contains a load resistor connected to the output of the explosive circuit, a full-wave rectifier, a test mode switch, sources of reference voltages for operation, non-operation and duration, comparators of operation, non-operation and duration, a duration-voltage converter and a light and sound indicator. The terminals of the load resistance are connected to a full-wave rectifier, the output of which is connected through the test mode switch either to the non-inverting input of the operation comparator, or to the non-inverting input of the non-operation comparator. The inverting inputs of the operate and non-operate comparators, respectively, are connected to the operate reference voltage source and to the non-operate reference voltage source. The output of the operation comparator is connected to the "duration-voltage" converter, to the output of which the non-inverting input of the duration comparator is connected, and its inverting input is connected to the source of the duration reference voltage. The outputs of the non-operation comparators and the duration comparator are connected to the light and sound indicator.

EFFECT: increasing the safety and reliability of explosive circuits.

1 cl, 1 dwg

Description

The invention relates to devices for blasting operations, namely, devices for testing the safety and performance of an electric explosive circuit (EEC), which includes an explosive device (EP), conductors and an electric detonator (ED). The safety of the explosive circuit is checked by the absence of stray currents in it, and the operability is checked by the formation in the explosive circuit of a current pulse from the EP, the amplitude and duration of which ensures the guaranteed operation of the electric detonator (EM) or other electrical means of initiation.

Known explosive machine KPM-3 ("Blaster Handbook" / BN Kutuzov, VM Skorobogatov, IE Erofeev and others. Publishing house "Nedra", Moscow, 1988, pp. 83-84) for control serviceability of which the probe panel is used, which is a resistance of 100 ohms, mounted in a plastic case. The probe panel has two leads with which it is connected to the clamps of the explosive machine, and two clamps for connecting to it two parallel-connected electric detonators, the explosion of which is used to test the machine. When checking, the resistance of the probe panel is connected in series with the exploding electric detonators.

The advantage of an explosive machine with a probe panel is the ability to test its operability using a 100 Ohm load resistance as an equivalent to the explosive circuit.

The disadvantage of this device is that the test of its operability is carried out without taking into account the actual resistance of the conductors of the explosive circuit and the transition resistances at the points of their connection to the explosive machine and the EM, which, in the event of a significant excess of the total resistance of 100 Ohm, can lead to the EM failure.

There is a known method for checking the conductivity of an electric explosive network (Patent RU No. 2110041, publ. 04/27/1998, IPC F42D 1/05, G01R 19/00), based on the induction of an electromotive force in each section of the electric explosive network from a source of an electromagnetic field of sound frequency and registration of the presence of an electric current at the input ends of the electric explosive network, which is used to judge the conductivity of the network.

The advantage of this test method is the ability to remotely check the integrity of the electric explosive network after its final assembly.

The disadvantage of the known verification method is the impossibility of predicting the actual parameters of the current pulse coming from the IP to the EM connection points, which does not guarantee the required reliability of EM operation, for example, when conducting an expensive physical experiment.

There is a known device for testing capacitor explosive machines (USSR Inventor's Certificate No. 142923, published in "Bulletin of Inventions No. 22" for 1961), in the control and measuring circuit of which a comparative device in the form of a thyratron is used, the anode of which is energized with a delay, corresponding to the required pulse duration, and to the control electrode - the pulse voltage of the explosive machine under test. Such an implementation of the device allows you to control the duration of the impulse developed by it without disassembling the machine.

To control the magnitude of the current pulse, a circuit of a thyratronic pulse indicator is used, which is triggered when a certain charge of the capacitor is reached, charged by the voltage developed by the machine in the load resistance and removed from a part of this resistance, as well as a circuit of a thyratronic current indicator that is triggered when the pulse indicator is lit and a given current in the circuit load resistance.

The advantage of this device is the presence of built-in control, which provides verification of the parameters of the current pulse output to its output terminals.

However, the specified device does not allow monitoring the explosive circuit for the presence of stray currents in it, as well as monitoring the amplitude and duration of the current pulse in the assembled explosive circuit before connecting the EM.

The objective of the present invention is to improve the safety and reliability of the explosive circuit.

The technical result of the proposed invention is provided by checking the explosive circuit for the absence of stray currents in it and monitoring the parameters of the current pulse at the point of connection of the EM.

The task is solved due to the fact that the device for testing the electrical explosive circuit contains a load resistance connected to the output of the explosive circuit, a full-wave rectifier, a test mode switch, sources of reference voltages of operation, non-operation and duration, comparators of operation, non-operation and duration, a converter "duration -voltage "and a light and sound indicator, while the terminals of the load resistance are connected to a full-wave rectifier, the output of which is connected through the test mode switch either to the non-inverting input of the operation comparator, or to the non-inverting input of the non-operation comparator, and the inverting inputs of the operation and non-operation comparators, respectively, are connected to to the reference voltage source of operation and to the source of reference voltage of non-operation, the output of the operating current comparator is connected to the "duration-voltage" converter, to the output of which The non-inverting input of the duration comparator is connected, and its inverting input is connected to the source of the duration reference voltage, while the outputs of the non-operation comparator and the duration comparator are connected to the light and sound indicator.

The essence of the claimed invention lies in the fact that the device contains a load resistance connected to the output of the explosive circuit, equal in magnitude to the resistance of the EM, from the terminals of which a voltage proportional to the current in the explosive circuit is removed.

A full-wave rectifier connected to the terminals of the load resistance provides a positive voltage regardless of the direction of the current in the explosive circuit.

The triggering reference voltage source delivers a voltage proportional to the current of guaranteed EM operation.

Accordingly, the reference voltage source of non-operation produces a voltage proportional to the current of the guaranteed non-operation of the EM.

The test mode switch in the "Triggered" position connects the output of the full-wave rectifier to the non-inverting input of the trip comparator, and in the "Non-trigger" position - to the non-inverting input of the non-trigger comparator.

The duration-to-voltage converter is a voltage integrator that generates a ramp voltage proportional to the duration of the signal produced by the trip comparator.

The duration comparator is used to generate a signal when the voltage produced by the "duration-voltage" converter is exceeded, the reference voltage corresponding to the duration of the current pulse, which ensures the guaranteed operation of the EM.

The light and sound indicator, when the switch is set to the "Triggering" test mode, gives a signal if the amplitude and duration of the current in the explosive circuit ensure the guaranteed triggering of the EM.

When the switch is set to the "Failure" test mode, the light and sound indicator emits a signal if the amplitude of stray currents in the explosive circuit exceeds a safe value for EM.

The technical result of the implementation of the proposed invention is achieved by using a combination of the listed components in the device.

The essence of the invention is illustrated by the functional diagram of the device shown in the figure.

The device for testing the electrical explosive circuit with its input terminals 1 and 2 is connected to the output of the conductors 3, 4 of the explosive circuit coming from the explosive device 5. A load resistance 6 is connected to the input terminals 1 and 2, the value of which is equal to the EM resistance.

When the mode switch 7 is set to the "Operation" position, the device operates as follows. When a current pulse is applied from an explosive device 5, a voltage drop is created across the load resistance 6, which is supplied to the full-wave rectifier 8. The rectified voltage through the test mode switch 7 is fed to the non-inverting input of the operation comparator 9. At the same time, a voltage drop is supplied to its inverting input from the reference voltage source 10 voltage corresponding to the current of guaranteed EM operation. If the voltage at the non-inverting input exceeds the voltage at the inverting input, then the operation comparator 9 switches to the "logical unit" state. The duration of the “logical unit” signal corresponds to the duration of the guaranteed EM operation in the explosive circuit.

The "logical unit" pulse is fed to the "duration-voltage" converter 11, which forms a linearly increasing voltage supplied to the non-inverting input of the duration comparator 12. A voltage corresponding to the duration of the current pulse is supplied to its inverting input from the reference voltage source of duration 13 guaranteed EM operation. If the voltage at the non-inverting input exceeds the voltage at the inverting input, then the duration comparator 12 switches to the "logical unit" state. The voltage of the "logical unit" is fed to the trigger input of the light and sound indicator 14, which signals that the amplitude and duration of the current in the explosive circuit have values that guarantee the operation of the EM.

When the operating mode switch 7 is set to the "Failure" position, the explosive circuit is checked for the presence of stray currents, the amplitude of which exceeds the safe value for the EM.

In the presence of stray currents across the load resistance 6, a voltage drop occurs, which is fed to the full-wave rectifier 8. The rectified voltage through the test mode switch 7 is fed to the non-inverting input of the non-operation comparator 15. At the same time, a voltage corresponding to current of guaranteed non-operation of EM. If the voltage at the non-inverting input exceeds the voltage at the inverting input, then the non-operation comparator 15 switches to the state of "logic one". The voltage of the "logical unit" is fed to the trigger input of the light and sound indicator 14, which signals that the amplitude of the stray currents in the explosive circuit exceeds the safe value for the EM.

The proposed technical solution allows checking the explosive circuit for the absence of stray currents in it and monitoring the parameters of the current pulse at the point of EM connection, ensuring its guaranteed operation.

The positive effect achieved with the implementation of the invention is to increase the safety and reliability of the explosive circuits.

Claims (1)

A device for testing an electrical explosive circuit, characterized by the fact that it contains a load resistance connected to the output of the explosive circuit, a full-wave rectifier, a test mode switch, sources of reference voltages of operation, non-operation and duration, comparators of operation, non-operation and duration, a duration-voltage converter and a light and sound indicator, while the terminals of the load resistance are connected to a full-wave rectifier, the output of which is connected through the test mode switch either to the non-inverting input of the operation comparator, or to the non-inverting input of the non-operation comparator, and the inverting inputs of the operation and non-operation comparators, respectively, are connected to the reference voltage source operation and to the reference voltage source of non-operation, the output of the operation comparator is connected to the "duration-voltage" converter, to the output of which the non-inverter is connected the input of the duration comparator, and its inverting input - to the source of the reference voltage of duration, while the outputs of the non-operation comparators and the duration comparator are connected to the light and sound indicator.

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