SU65916A1 - Device for measuring the ignition pulse of electric igniters and electric detonators - Google Patents

Description

The present invention is based on the method for determining the ignition pulse of electrical ellalguns and electric detonators by measuring the 1st ignition ignition during the flow of a constant current of constant force. A device for measuring; ;;;; In the ignition of electrons according to the type of electronic measuring instrument, an instrument whose indicator switches on at the moment when the electric detonator is switched on and off automatically at the moment of ignition of the latter. A distinctive feature of the device, according to the invention, is that to turn off the ballistic galvanometer, which is used as a specified indicator, a circuit is used consisting of electronic lanita, at the input of which is applied a voltage from an electric detonator, two cascaded transformers that convert the output voltage of the specified lamp is in two sharp cm-pulses, and two cascade-connected thyratrons, to the input of which these pulses are applied, and which serve to create a pulse, including ba listic talvanometer. ,, - j

The invention is illustrated in the drawing, fng. 1 which is given the scheme of the device, and on the fng. Figure 2 shows the curves of currents and voltage changes in various parts of the device.

If a constant current of a constant force is passed through the electric igniter and the oscillogram of the voltage across its clamps is removed, then this oscillogram will look like an inclined broken line. (FMG. 2a): until a certain moment th, the voltage increases at one rate, and beginning from the moment tb onwards - by another, and, moreover, is significantly higher.

With a constant current strength, the increase in voltage drop can only be explained by an increase in the resistance of the electric bridge of the igniter, which can be caused by a significant increase in its temperature.

A sharp change in the rate of 1) voltage drop and, therefore, the temperature of the bridge, at time th. Can be explained only by the fact 1WhL from the moment of switching on the current to tb, the temperature rise of the bridge occurs only due to emitted by the current, and starting from the lightning chamber / 6 to the bridge burnout - due to the heat released by the heat source, as well as by ignition of the electric igniter head. As follows from this, that momeite tb, which occurs in a sharp bend of the osilogram, is the moment when ignition of the electric igniter head, i.e. 13 ps, started, which elapsed from switching on to current / and is the ignition time.

The product of this time by the square of the current gives an impulse of ignition of the electric igniter under investigation.

In the proposed device (fit. I), a ballistic galvanometer is used to measure the replenishment time (tb).

The operation of the circuit is as follows. When the key / Ci is closed, the known constant current (/) is simultaneously supplied to the electric igniter EV and the known constant current (/) to the ballistic galvanometer BG. The current supplied to the galvanometer passes an EL-t three-electrode electron tube, in which the grid voltage is zero by the time the key is closed.

On the sea of the electric-current heating of the EV bridge, the fall of U for some time will increase, as shown in FIG. 2a

This rise in voltage drop will cause a change in the anodic current ta in the circuit of the electrolysis lamp of EL-2 operating on the rectilinear part of the characteristic {fig. 26).

The increasing anodic current will cause some electromotive force C in the secondary winding of the unsaturated transformer Tp-1, the magnitude of which will depend on the rate of growth of the anode current. As a result, at the moment of key closure K. and at the moment when the growth rate of the voltage drop changes, there will be a sharp increase in e. At the rest of the time, due to the invariance of the anode current temperature, it will remain constant (Fig. 2c) .

The electromotive force e in its circuit will cause some current / I, the nature of the change of which is shown in FIG. 2 years

In his. a change in current / will be in the ptorichi winding of the transformer) Tr-2 some electromotive force e. At the same time, this e. d. only R will be generated at the moment when the switch L is closed and at the moment of the change in the rate of rise of the voltage drop, when the voltage is reached (Fig. 2e).

The first impulse from .. this e. d. will cause the ignition of the thyratron Tyr- /, however, due to its insufficiency, it will not be able to cause the second thyratron Tyr-2 to fall, to which more than one anode voltage has been applied for this purpose.

Immediately after the thyratron is ignited, Tyr- / will start charging capacitor C; In this case, the voltage from on this capacitor will increase in time, and so on. as shown in FIG. e.

The scheme is assembled in such a way that the voltage and the speed of one is from 2 and the sum of the second thyratron of Tir-2 is fed to the grid. However, such an addition will give a noticeable result only with the appearance of the second pulse e / electromotive force.

The circuit elements are calculated so that the sum of Uc - {- ez is greater than va and that it is sufficient for igniting Tyr-2.

Thus, when a second pulse of EU is supplied, which occurs at the time of the change in the rate of increase of voltage drop ia of the EV clamps, the second thyratron Tyr-2 will be ignited. As a result, the grid potential of the EL-1 electron tube located in the galvanometer circuit will try to impose an effective potential, which will immediately erase this lamla, which will cause the discontinuity of the galvanometer ceetics.

At the same time, the turning off of the galvanometer will take place just at the moment when the change in the rate of increase of the voltage drops on the chemical oxides of the EV, i.e. at the moment when the ignition head of the EV starts to burn.

Thus, the proposed scheme turns on a ballistic galvanometer at the moment of turning on the EV circuit and turns it off at the moment the ignition head EV starts burning, i.e., it sets the duration of current passing through the galvanometer equal to the time 1KK-11.-1amen1111 th.

The required ignition time is:

/ 6 .- a,

at

where C is the ballistic constant of the galvanometer, and a is the first offal of the galvanometer. Since condition 4 is const, then,

WITH

, f, we get. at

That is, the desired ignition time is equal to the first throw-off of a ballistic galvanometer multiplied by a constant coefficient. To determine the ignition impulse — the ultimate goal of the test — it would take only the measured ignition time to be multiplied by the square of the current that was passed in the test through the EV.

Subject invention

Claims (3)

1. A device for measuring the ignition pulse of electric igniters and electric detonators, made according to the type of measuring instrument, the indicator of which turns on at switching on the circuit, the electric detonator a and automatically switches off at the time of extinguishing the latter, characterized in that. that for switching off, used as a specified indicator, an irimeyen circuit consisting of an Al-2 electron tube, to the input of which a voltage was applied from the terminals of the test electric detonator, two cascade-connected transformers that convert the output voltage of the E.G-2 lamp into two a sharp pulse, and two cascaded switched on thyratrons, to the input of which these pulses are fed and which serve to create a pulse that turns off the ballistic galvanometer. 2. the form of the device according to claim 1, about 10 and 10 times with the application of an electronic lamp 3l- / as an instrument, turning off its galvano-meter, for the input of it is fed to you. voltage of the second thyratron. 3. The form of the device according to claim 1 of claim 10; and with the ifa output of the first thyratron to the key, the capacitor connected to the input of the second thyratron in series with the resistance to which the voltage from the input of the first thyratron is applied, to ensure that the galvanometer is turned off only with an impulse resuming at the moment of ignition of the electric detonator. FIG. one