RU2542883C1 - Device for monitoring and undermining sequential chains of pyrocartridges - Google Patents

Abstract

FIELD: blasting operations.

SUBSTANCE: device comprises pyrocartridges with two threads, each of which is shunted by semiconductor device of restoring the integrity of an electric circuit with transition from closed to open state, the switching units of current of blasting, the control element, each switching unit is arranged on two key elements. The monitoring key are integrated, in parallel with each of the first and second thread of pyrocartridges the identification resistor is integrated, the control element is made in the form of first and second ohmmeter, the ohmmeter outputs are the control output of the device, the connection points of the first and second key elements with successive chains of threads of pyrocartridges are the technological circuits of pyrocartridge control of the device.

EFFECT: improvement of reliability, which increases the level of safety, ensuring the possibility of long-term memorisation of fact of triggering of pyrocartridges during normal operation and the possibility of undermining the pyrocartridge one by one.

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Description

The invention relates to electronic devices of automation and can be widely used both in products of rocket and space technology (RCT), and when carrying out various types of blasting operations in the national economy, as well as in fire extinguishing control devices.

A device for controlling and detonating pyrocartridges according to RF patent No. 2266569 (IPC: G08B 17/08), which consists of a pyrocartridge with two threads, the first thread through the first field effect transistor and the first winding of the signal transformer, the second thread through the second field transistor and the second winding of the signal transformer is connected to a power supply. In addition, this device contains two pulse shapers and two signal switches, as well as differentiating circuits. The disadvantage of this device is the high current consumption, since the threads are connected in parallel to the power source.

A device for monitoring and undermining serial circuits of pyrocartridges according to the patent of the Russian Federation No. 2157564 (IPC: G08B 17/06) containing pyrocartridges with two threads, each of which is shunted by a semiconductor device for restoring an electric circuit with a transition from a closed state to an open, switching control current nodes and blasting, as well as a control element, while a serial circuit of two or more squibs is connected to the switching unit, while a block with a threshold function is connected in parallel to each of the squibs voltage limits, which is essentially a semiconductor device. The disadvantages of the device include the fact that on each threshold element after its inclusion, a voltage drop is formed, the value of which depends on the parameters of the threshold block itself and can reach a significant value. With an increase in the number of pyro-cartridges connected in series, the magnitude of the voltage drop across them also increases, which accordingly limits the total number of pyro-cartridges connected in series or reduces the efficiency and the need to increase the voltage of the power source, which is unacceptable in rocket and space technology. In addition, it should be noted that the inclusion of a current relay in series with each threshold block reduces the reliability of the entire device and further reduces the utilization of the power source. As well as the lack of information about a specific failed or non-working squib.

A device for monitoring and undermining serial circuits of pyrocartridges (RF Patent 2334278, G08B 17/06), comprising pyrocartridges with two threads, each of which is shunted by a semiconductor device for restoring the integrity of an electric circuit with a transition from closed to open state, switching nodes of control and detonation current , as well as a control element, each switching node is made on two key elements, while each key element is made on a field-effect transistor and has two inputs, the first of which is connected it is connected to the ground test equipment, and the second input is connected to the onboard control system, the first strands of each squib are connected together in series, the second strands of each squib are also connected in series, the first key elements are connected between the plus of the power source and the inputs of the sequential chains of the squib threads, the second key elements are connected between the minus of the power source and the outputs of the sequential chains of the pyro cartridge threads, the control element is made in the form of transforms torus with the two input windings and one output winding, the input winding of the first transformer is connected in series with the first threads of the squibs and the second input of the transformer winding is connected in series with the second threads squib, the output of the transformer winding is a control output of the apparatus. This device is selected as a prototype.

The disadvantage of this device is the lack of information about the failed or non-working number of the squib (impossibility to determine which failed or did not work squib), as well as the presence of galvanic connection of control circuits with circuits for blasting the squib, which reduces the reliability of the device.

The objective of the invention is to increase the reliability of the device due to the galvanic isolation of control circuits with circuits for blasting the squibs and increasing the information content about the failed or not working number of the squib.

The problem is solved due to the fact that in the device for monitoring and undermining successive circuits of the squibs, containing pyrocartridges with two threads, each of which is shunted by a semiconductor device for restoring the integrity of the electrical circuit with a transition from a closed to an open state, switching nodes of the blasting current, a control element, each switching unit is made on two key elements, the first strands of each squib are connected in series, the second strands of each squib interconnected in series, the first key elements are connected between the plus of the power source and the inputs of the serial chains of the pyrocartridge threads, the second key elements are connected between the minus of the power source and the outputs of the serial chains of the pyrocartridge threads, the first and second controlled keys are inserted, parallel to each first and every second pyrocartridge threads an identification resistor is included, the value of which is determined by the formula: R _n = R _c · 2n, where R _c is the total resistance of the squibs and lead wires c, and n are integers, the control element is made in the form of the first and second ohmmeter, the first ohmmeter is connected between the points of connection of the first and second key elements with serial chains of the first strands of the igniter, and the second ohmmeter is connected between the points through the second controlled key the connection of the first and second key element with serial circuits of the second threads of the squibs, the ohmmeter outputs are the control outputs of the device, the connection points of the first and second key elements with the last The connecting chains of the pyrocartridge filaments are the technological circuits of control of the squibs of the device.

Figure 1 shows the structural diagram of a device for monitoring and undermining sequential circuits of squibs.

The proposed device consists of squibs 1.1 ... 1.n, the first threads of which PN1 are connected together in series, the second threads of PN2 are also connected together in series, each thread of the squib is shunted by a semiconductor device for restoring an electric circuit with a transition from closed to open, made in the form of a dynistor 2.1 ... 2.n, the first key elements 3 are connected between the plus of the power supply (+ E) and the inputs of the first strings Пн1 and the second strings Пн2 respectively of the squibs 1.1 ... 1.n, respectively the second key elements 4 are connected between the minus of the power source (-E) and the outputs of the first threads PN1 and the second threads PN2 of the squibs 1.1 ... 1.n, respectively, connected in series, each key element 4 has an input: “Undermining”, which is connected to the on-board control system ( SU). The first 7 and second 9 control elements are made in the form of a resistance meter (ohmmeter) and, respectively, are connected through the first 6 controlled key between the connection points of the first 3 and second 4 key elements with serial chains of the first threads Mon1 squib 1.1 ... 1.n and through the second 8 controlled the key between the connection points of the first 3 and second 4 key elements with sequential chains of the second threads PN2 of squibs 1.1 ... 1.n. The outputs of the first 7 and second 9 control elements are the control outputs of the device. In parallel with each thread PN1 and PN2 of the squib 1.1 ... 1.n, resistors 5.1 ... 5.n are included. The point 10 of the connection of the first 3 key elements with serial chains of the first PN1 pyro cartridge and the point 11 of the connection of the second 4 key elements with serial chains of the first PN Mon pyro cartridge are the first technological outputs of the device. The point 12 of the connection of the first 3 key elements with the serial chains of the second PN2 strands of the squib 1.1 ... 1.n and the point 13 of the connection of the second 4 key element with the serial chains of the second PN2 of the squib 1.1 ... 1.n are the second technological conclusions of the device.

It should be noted that before the tests, they compile a table of correspondence of the resistance value of the indication resistor (determined by the above formula) to the number of the squib (identical for the first and second threads).

In addition, it should be noted that the integrity of the pyrocartridge filaments can be controlled both by an external measuring device (in the field, for example, a tester) when the product is not powered, and by the pyrocartridge state monitoring device when the controlled keys are closed when the product is properly supplied, including during field tests (in flight).

The proposed device operates as follows.

First, the serviceability of the circuit elements without pyrocartridges is checked, for this an external measuring device (not shown conventionally) is connected to the process terminals 10 and 11 of the first strings Py1 of the squibs connected in series and make sure that there is a resistance corresponding to the total resistance of the series-connected resistors 5.1 ... 5.n, if the resistance less, the value by which the resistance decreases will indicate the number of the shorted dinistor. Similar actions are carried out with the technological conclusions 12 and 13 of the second strings of PN2 of the squibs connected in series. Turn on the first key elements 3 and make sure the presence of a circuit between + E and process chains 10, 12, then turn on the second key elements 4 and make sure that there is a circuit between -E and process terminals 11, 13. After that, supply voltage to the buses E, include the first 3 and second 4 key element of the first filaments PN1 of the squibs and measure the current in this circuit with a contactless current sensor (not shown conditionally). Then, the first 3 and second 4 key elements of the second threads PN2 of the squibs are turned on and the current in this circuit is measured by a contactless current sensor (also not shown conditionally). The current value will be determined as (U _pit- U _pad ) / R _ogre , where U _pad is the total voltage drop across the dinistors 2.1 ... 2.n, R _org is a limiting resistor installed in series with the switching elements (not shown conditionally).

The presence of a small current in this case will indicate a malfunction of one of the dinistors 2.1 ... 2.n.

Next, disconnect the supply voltage from the E buses, connect the squib 1.1 ... 1.n and use an external measuring device (tester) through the process terminals 10, 11 to measure first the resistance of the first connected strings Py1 of the squibs first, then through the process leads 12, 13 the resistance of the second strings connected in series Mon2 squibs. In the event of a break in the pyro cartridge, the resistance of the measured circuit will increase by the value of the corresponding identification resistor 5.1 ... 5.n, if there are two pyro cartridge in the break, then the resistance of the measured circuit will increase by the sum of the corresponding identification resistors 5.1 ... 5.n, etc.

It remains only to confirm, with the help of the first 7 and second 9 ohmmeters, respectively, the resistance of the first PN1 and second PN2 of the pyro cartridge cartridges connected in series. To do this, turn on the first 6 and second 8 controllable switches and measure the resistance of the first PN1 and second PN2 of the pyrocartridge strings connected in series, respectively, with the first 7 and second 9 ohmmeters. The device is ready for combat work.

When the device is operating in flight and the need to detonate the squibs is energized, the E buses are energized, and commands "Sap 1.1 and Sap 1.2" are issued from the on-board control system, the duration of which is longer than the response time of the squib (1-3 ms). The first key elements 3 and the second key elements 4 are closed, as a result, a detonation current flows through the first threads PN1 of the squibs 1.1 ... 1.n connected in series, undermining the squibs.

After the “Blast” command is completed, the first 6 controlled key is turned on and the reading of the first 7 ohmmeter is measured, in the case of blasting all the squibs 1.1 ... 1.n (burnout of the first strings Mon1), the reading corresponds to the total resistance of the series-connected resistors 5.1 ... 5.n, if the resistance is less , then the value by which the resistance has decreased will indicate the number of the failed squib.

In this case, the command "Undermining 2.1 and undermining 2.2" is given, the first key elements 3 and the second key elements 4 are closed, as a result, the detonation current flows through the second strings PN2 of the squibs 1.1 ... 1.n in series, undermining the squibs. After the “Demolition” command is completed, they turn on the second 8-controlled key and measure the reading of the second 9 ohmmeter, in the case of blowing up all the squibs 1.1 ... 1.n (burnout of the first strings Mon2), the reading corresponds to the total resistance of the series-connected resistors 5.1 ... 5.n, if the resistance is less , then the value by which the resistance has decreased will indicate the number of the failed squib.

In critical cases, the commands "Demolition 1.1 and demolition 1.2", "Demolition 2.1 and demolition 2.2" are given simultaneously and then sequentially monitor the readings of the first 7 and second 9 ohm meters.

The mode of the switching elements of the pyrocartridge filaments is chosen so that the value of the flowing current is greater than the response current of the pyrocartridges (2A). If it is necessary to limit the current of the switching elements, resistors are installed in series with the latter.

It should be clarified that when a dinistor is shorted by a pyro cartridge, its resistance is several hundred kOhm and it practically does not affect the parameters of the yarn, since its resistance is 1-3 ohms. Taking into account the difference in response times of the pyrocartridge filaments (1-3 ms), suppose, for example, that the Mon1 pyrocartridge 1.1 thread is the first to operate, while a voltage exceeding the switching voltage of this dinistor is applied to the dinistor 2.1 connected in parallel (for example, the 2H102A dinistor has a switching voltage of 7 -10 V, current per pulse is 3 A). The dinistor 2.1 is turned on, while the residual voltage on it is 0.5-1 V, so the circuit parameters are practically unchanged. That is, the dinistor operates in the key mode: "closed-open" and after the thread of the squib is blown, it restores the electric circuit.

As a semiconductor device, you can use not only the dynistor, but also field-effect transistors and thyristors (for the wiring diagram, see the prototype).

At a supply voltage of E = 27 V, the RECK81 relays can be used as controlled keys and key elements in a coordinated one-time operation mode, resistors are used C2-33, dynistors are used of type 2H102A. To measure the current undermining the threads of the squibs, a non-contact current sensor DTB1 or CSA-1V is suitable.

Currently, laboratory testing of the proposed device has been carried out, which has shown high efficiency and simplicity.

Claims (1)

A device for monitoring and detonating serial circuits of pyrocartridges, containing pyrocartridges with two threads, each of which is shunted by a semiconductor device for restoring the integrity of the electric circuit with a transition from a closed to an open state, switching nodes of the blasting current, a control element, each switching node is made on two key elements, the first threads of each squib are connected together in series, the second threads of each squib are also connected together in series, the first ones beam elements are connected between the plus of the power source and the inputs of the sequential chains of the pyrocartridge threads, the second key elements are connected between the minus of the power source and the outputs of the serial chains of the pyrocartridge threads, characterized in that the first and second controlled keys are inserted, an identification indicator is connected in parallel with each first and every second thread of the squib resistor, whose value is determined by the _{formula: R n = R c · 2n} , wherein R _c - the combined resistance of the squibs and the lead wires, and n - integers control the first element is made in the form of a first and second ohmmeter, the first ohmmeter is connected between the points of connection of the first and second key elements with the serial chains of the first strands of the igniter through the first controlled key, and the second ohmmeter is connected between the points of connection of the first and second key elements with the serial the chains of the second strands of the squibs, the outputs of the ohmmeters are the control outputs of the device, the connection points of the first and second key elements with serial chains of the thread squib circuits are process control device squibs.