RU2495367C1 - Method to determine characteristics of actuation of pyrotechnical items with electric initiation and device for its realisation - Google Patents

Abstract

FIELD: testing equipment.

SUBSTANCE: electric current from a DC source is supplied to an incandescence element of a pyrotechnical item, the current supply moment t₁ and the current value I are fixed. The moment is fixed for ignition of the pyrotechnical item charge t₂ by the moment of current surge on the element of incandescence of the pyrotechnical item, and the time is detected for initiation of the pyrotechnical item T, as the difference between the moment of ignition of the pyrotechnical item charge t₂ and the moment of DC supply t₁. The device for determination of pyrotechnical item actuation characteristics consists of a breaking circuit with a source of power supply connected to an element of incandescence of a pyrotechnical item. The device includes a unit of initiation time determination. The break circuit comprises the serially connected components: a power supply source, a key for circuit closing, an element of incandescence of a pyrotechnical item, a device for measurement of current force in the breaking circuit. The output of the current force measurement device is electrically connected to the input of the initiation time determination unit. The power supply source is made in the form of a DC voltage source.

EFFECT: improved reliability of tests.

3 cl, 1 dwg

Description

The invention relates to test equipment and is intended to determine the characteristics of pyrotechnic systems, components and products (undocking and separation systems, pyro valves, pyro locks, pies, pyrotechnic rollers, pyro bolts, etc.) with electrical initiation.

The invention can be used in rocket and space and aviation technology, as well as in other branches of technology where pyrotechnic products are used to determine such response characteristics of pyrotechnic units and products as the dependence of the initiation time on the magnitude of the direct current flowing through the glow element.

In this case, the initiation time is understood to mean the time from the moment of supplying direct current to the incandescent element of the pyrotechnic product to the moment of ignition of the explosive charge contained in the pyrotechnic product. The knowledge of these characteristics facilitates the design and development of control systems for the operation of pyrotechnic devices to ensure their operation at a given point in time.

The dependence of the initiation time on the magnitude of the direct current pyrotechnic product flowing through the incandescent element is a characteristic of the pyrotechnic product itself, since it is completely determined by the design of the product. The type of this functional dependence is now to be determined empirically.

A device is known for determining the response time of a non-initiating detonator capsule but patent RU 2328748, 07/10/2008, IPC: G01P 3/64 (2006/01), C06C 7/00 (2006/01), F42B 35/00 (2006/01) . The device comprises a chronograph, a chronograph start photo sensor and a chronograph stop sensor in the form of a piezoelectric vibration transducer. The photosensor responds to radiation from the front of the detonation wave passing inside the shock wave tube after its initiation. The piezoelectric sensor responds to shock when the detonator capsule is triggered and is located on a metal plate on the opposite side of the detonator capsule mounted opposite it. The thickness of the plate at the installation site of the piezoelectric transducer is 10-30 mm.

However, this device and the method by which it works cannot be used to determine the time of initiation of pyrotechnic products with electrical initiation, since with electrical initiation there is no radiation that could be detected by the photosensor to determine the initial moment of current supply. The photosensor cannot be used in this case also for fixing the moment of ignition of the explosive charge, since in the pyrotechnic products of rocketry and aviation the explosive charge is inside an opaque case.

In the known device, the piezoelectric transducer-vibration transducer serves to fix the moment of completion of operation of the detonator capsule and the description does not disclose that in this way it is possible to determine the start time of the ignition of the explosive in a pyrotechnic device with electrical initialization.

A device for testing explosive bolts (RF patent 2351879, 04/10/2009, IPC: F42B 3/00 (2006/01)), consisting of two brackets mounted on a power plate, one of which is rigidly fixed to one fixed disk, and coaxially with it, on the rails rigidly fixed in the brackets, there is a second movable disk with the possibility of moving along the rails towards the opposite bracket. The disks are in contact with each other with their end planes, but their axes are interconnected by an explosive bolt.

There is also known a device for testing explosive bolts and a method for determining the response characteristics of explosive bolts in the design of pyrotechnic assemblies (RF patent 2289088, 04/26/2004, IPC: F42B 3/00 (2006/01)), adopted as a prototype.

The device for testing explosive bolts consists of two brackets mounted on a power plate, on one of which one fixed disk is rigidly fixed, and a second movable disk is located coaxially with the guides rigidly fixed in the brackets, with the possibility of moving along the guides towards the opposite bracket moreover, in the disks along their axis there are sockets for a bursting bolt connecting them to each other, while the disks contact each other with their end planes.

A known method for determining the response characteristics of explosive bolts (speed and momentum of the separated parts, the magnitude of the axial force) when designing pyrotechnic units, is to fix the moment t _{1 of} separation of the disks and the moment t _{2 of the} collision of the second movable disk with the opposite bracket. The moment of collision and the moment of separation, corresponding to the beginning of motion of the second movable disk, is recorded, for example, using sensors or filming.

Although these method and device serve to determine the response characteristics of pyrotechnic products with electrical initiation, the initiation time in dependence of or supplied direct current in this method and using this device are not determined.

The objective of the claimed invention is the ability to determine the characteristics of pyrotechnic products installed on various objects, in particular, the time of initiation of a pyrotechnic product and related characteristics when installing pyrotechnic products in places inaccessible to visual observation of the moment of ignition of the latter.

The technical result of the invention is:

- fixing the moment of ignition of the explosive charge of pyrotechnic products installed in places inaccessible for visual observation of the moment of ignition and determining the time of its initiation, depending on various values of the supplied direct current;

- possibility to determine on the obtained current values depending safe value I _b, I long _for ignition current, the ignition current I stomillisekundnogo _100, ignition pulse _K in dependence or the current strength and the nominal ignition pulse K _n,

- determination of the duration of the high-temperature state of the products of chemical-physical transformation of the explosive charge inside the body of the pyrotechnic product, which corresponds to the state of high pressure inside the body of the product.

Moreover, by the value of the safe current I _{b we} mean the maximum value (upper limit) of the direct current, which does not cause ignition of the charge of the pyrotechnic product, no matter what time it flows through it; continuous flammable current I _dl - the minimum value (lower limit) of the direct current that flows through the pyrotechnic product for more than 1 minute will cause its operation; one hundred millisecond flammable current I ₁₀₀ - the minimum value of the direct current that flows through the pyrotechnic product for 100 ms, will cause its operation; ignition pulse K _in - the smallest value of the current pulse (constant) at which the pyrotechnic products are triggered (dimension of the ignition pulse A ² c); nominal ignition pulse K _n - the steady-state value of the ignition pulse, which occurs at a current equal to approximately twice the value of the hundred-milli-second igniting current (B. P. Kutuzov “Blasting operations.” M.: Nedra, 1974, p. 151, 152).

The technical result of the invention is achieved in that the method for determining the response characteristics of pyrotechnic products with electrical initiation consists in the fact that an electric current is supplied to the incandescent element of the pyrotechnic product, and the electric current is supplied from a constant voltage source. The time t _{1 of} the current supply and the value of the supplied current I are fixed, then the moment of ignition of the charge of the pyrotechnic product t _{2 is} fixed at the moment of the appearance of a current surge on the incandescent element of the pyrotechnic product. Next, the initiation time of the pyrotechnic product T is determined as the difference between the moment of ignition of the charge of the pyrotechnic product t ₂ and the moment of supply of direct electric current t ₁ and to obtain the dependence of the initiation time T on various values of the supplied current I repeat the above operations for various values of the currents the required number of times .

The technical result is also achieved by the fact that a unit for calculating the initiation time is introduced into the device for determining the response characteristics of pyrotechnic products with electrical initiation, consisting of an electric blast circuit with a power source connected to the incandescent element of the pyrotechnic product. In this case, the detonation circuit consists of a power supply connected in series, a key for closing the circuit, an incandescent pyrotechnic item, a current measuring device in the detonation circuit and adjustable resistance, the output of the current measuring device being electrically connected to the input of the initiation time determination unit, and the power source made in the form of a constant voltage source.

In addition, the adjustable resistance is made in the form of at least one variable resistance.

The invention is illustrated in the drawing (figure 1).

Figure 1 presents an example of a device for determining the initiation time of a pyrotechnic product (explosive pyro bolt), where:

1 - pyrotechnic product (pyro-bolt);

2 - unit for determining the initiation time;

3 - source of constant voltage;

4 - a device for measuring current in a blast circuit;

5 - key;

6 - adjustable resistance;

7 - an element of incandescent.

The implementation of the claimed device can be shown on the example of the device depicted in figure 1.

The device is made in the form of a blasting circuit, consisting of a DC voltage source (3) connected in series, a key to close the value (5), an incandescent element (7) of a pyrotechnic product (1), a current measuring device in the blasting circuit (4) and an adjustable resistance (6). The output of the current measuring device (4) is electrically connected to the input of the initiation time determination unit (2).

Adjustable resistance serves to set the magnitude of the amplitude of the current pulse when the pyro-bolt is detonated and can be made in the form of at least one variable resistance. This ensures the convenience of tuning to a given value of the initiation current, since there is no need to change one resistance to another.

Any pyrotechnic product containing explosive materials can be tested - these are pyro locks, squibs, detonators, etc., which are triggered by electric current.

The key (5) serves to close the undermining circuit.

A current measuring device in a blasting circuit (4) may, for example, be an electrical resistance mounted in series in a blasting circuit. The voltage drop, which is proportional to the current flowing through it, is recorded at the input of the initiation time determination unit (2). You can use any other device for measuring current strength, which is operable for short periods of time and signals from which are suitable for registration, for example contactless electromagnetic clamps.

The initiation time determination unit (2) can be a signal analyzer in which analog signals are converted into digital codes and can be processed according to specified algorithms. Such analyzers are widely used at present. For example, the A17U8 signal analyzer developed by Electronic Technologies of Measurement Systems CJSC (Zelenograd) can digitally record up to 8 signals. On its basis, it is possible to form the so-called virtual devices, such as event detectors for determining the start and end moments of registered processes and arithmetic processors for various calculations. Results can be displayed on an electronic display.

The claimed method can be illustrated by the example of the operation of the device depicted in figure 1.

The pyrotechnic product (1) is connected to a constant voltage source (3). The pyrotechnic product (1) is triggered, for which a key (5) is closed and, thereby, an electric current is supplied to the incandescent element (7) of the pyrotechnic product (1) from a constant voltage source (3), making it operate.

Thus, the current supply time t ₁ and the value of the supplied current value I are fixed using a current measuring device in the blast circuit (4).

Upon ignition of the charge of a pyrotechnic product, a high-temperature high-pressure plasma is formed around the filament. Due to the high electrical conductivity of the plasma, the voltage drop across the filament becomes almost zero and an electric current jump occurs in the blast circuit due to a drop in the total resistance of the closed blast circuit with a constant applied voltage. The constancy of voltage is important for detecting the current surge occurring in the undermining circuit.

Using the unit for determining the initiation time (2), the moment of ignition of the charge of the pyrotechnic product tz is fixed at the moment of the appearance of a current jump on the incandescent element of the pyrotechnic product, the initiation time of the pyrotechnic product T is determined as the difference between the moment of ignition of the pyrotechnic product t ₂ and the instant of supply of direct electric current t ₁ .

By applying currents of different values with the help of adjustment resistance (6), the dependence of the initiation time T on the different values of the supplied current I.

From the obtained dependence of the initiation time on the current strength, one can determine the characteristics associated with the initiation time. This is the value of the safe current (current, the initiation time for which is infinitely long), the value of the long igniting current and the hundred-millisecond current, for which the initiation time is 1 minute and 100 ms, respectively. The dependence of the initiation time on the current strength is used to construct the dependence of the current pulse on the current strength and determine the values of the ignition pulse and the nominal ignition pulse.

The duration of the current jump allows us to judge the duration of the high-temperature state of the products of chemical-physical conversion of the explosive charge of the pyrotechnic product (gas plasma), and hence the duration of the high-pressure state.

It is significant that the current source operates in constant voltage mode, that is, its internal resistance is much less than the load resistance. Otherwise, if the internal resistance of the current source is much greater than the load resistance (the power source acts as a current source), the change in the total resistance of the detonation circuit during ignition of the charge will be insignificant and the current surge will be difficult to detect due to its smallness. Given the above, the claimed method is implemented for relatively high initiation currents, when the resistance of the detonation circuit is comparable to or less than the electrical resistance of an incandescent element.

At low initiation currents, the resistance of the detonation circuit is usually large compared to the resistance of an incandescent element. As a result of this, the current jump due to a drop in the resistance of the incandescent element becomes invisible.

Claims (3)

1. The method of determining the response characteristics of pyrotechnic products with electrical initiation, consisting in the fact that an electric current is supplied to the incandescent element of the pyrotechnic product, characterized in that the electric current is supplied from a constant voltage source, the current supply time t ₁ and the value of the supplied current are recorded I, then fixed point ignition charge of pyrotechnic articles t ₂ to the time the current surge to an incandescent element pyrotechnic articles determine bp mja initiating pyrotechnic articles T as the difference between the instant of ignition charge of pyrotechnic articles t ₂ and the instant supply of a constant electric current t _1, and to obtain depending initiation time T from different magnitudes of the supplied current I repeat the above operations for different values of the current values required number of times . 2. A device for determining the response characteristics of pyrotechnic products with electrical initiation, consisting of a blast circuit with a power source connected to an incandescent element of the pyrotechnic product, characterized in that an initiation time determination unit is inserted into it, while the blast circuit consists of a power supply connected in series , a key for closing the circuit, an incandescent element of the pyrotechnic product, a device for measuring the current strength in the circuit of detonation and adjustable resistance, and in The output of the current measuring device is electrically connected to the input of the initiation time determination unit, and the power supply is made in the form of a constant voltage source. 3. The device according to claim 2, characterized in that the adjustable resistance is made in the form of at least one variable resistance.