RU49386U1 - MICROPROCESSOR RELAY PROTECTION AGAINST ARC CLOSES - Google Patents

Abstract

The utility model relates to automation and computer technology, in particular, to control devices.

The purpose of the invention is the expansion of functionality by introducing an arc protection function by introducing signal recorders from fiber optic and photothyristor sensors and additional input nodes. The microprocessor-based device for relay protection against arc faults contains five registers, a decoder, a block of AND elements, two NOT elements, a command generation block, three groups of input nodes, a switch, two bus shapers, a blocking block and m - a relay with m-resistors, signal recorders from photo-thyristor sensors and recorders of signals from fiber-optic sensors, The proposed device can be used to protect complete switchgears of electrical substations in the event of a short circuit accompanied by an open electric arc, as well as to protect service personnel from injuries and damage during electrical accidents associated with an open electric arc.

Description

The utility model relates to automation and computer technology, in particular, to control devices, and can be used to protect complete switchgears of electrical substations in the event of short circuits accompanied by an open electric arc, as well as to protect maintenance personnel from injuries and damage during electrical accidents connected with an open electric arc.

A known device is a processor system for tripping a circuit breaker with a reliable display of the status of the circuit breaker system [A.S. PCT (WO) H 02 N 3/093, 3/24 No. 91/03828 B.I. No. 7 1990], which contains a liquid crystal display with a segment, a power battery, a manual switch, a latch, transistors, a processor that allows you to control the switch, has greater reliability due to the use of a low-power trip indication circuit, but does not protect against arc short circuits.

Device for monitoring and control [A.S. (SU) G 06 F 15/46 No. 1624481 B.I. No. 4 1991], containing a clock pulse generator, an OR element, two counters, two decoders, (k + 2) - blocks of OR elements, (k + 1) -blocks of And elements, k- settings registers, a comparison circuit, an And element, element NOT, to - output groups of AND elements, the unit for generating parameters adjustment commands and the delay unit controls the circuit breakers, but also does not protect against arc faults.

The closest technical solution is the device emergency control [A.S. (RU) 7 H 02 H 3/00 No. 2221318. Publication date - 2004.01.10] containing five registers, two counters, a decoder, a block of AND elements, two elements NOT, a command generation block, n - input nodes, a counting node, a switch, two bus formers, a blocking node and m - relay cm - resistors, provides local and remote control of circuit breakers, but it also lacks the function of protection against arc faults.

The purpose of the invention is the expansion of the functionality of the device by introducing the function of protection against arc faults.

This goal is achieved by the fact that in the known device containing five registers, a decoder, a block of AND elements, two elements NOT, a command generation block, n - input nodes, a switch, two bus shapers, a block node and m - relay cm - resistors, and the inputs n - input nodes are the first group of inputs of the device, the first and second group of inputs and outputs of the command generation unit is the first and second group of inputs and outputs of the device, relay contacts are the third group of inputs and outputs of the device, the group of inputs the encoder is connected to the group of outputs of the first bus

the shaper, the group of inputs of which is connected to the first group of inputs and outputs of the switch and the third group of inputs and outputs of the command generation unit, the reset output of which is connected to the first input of the blocking node, the second input of which is connected to the output of the second element NOT, the input of which is connected to the first control inputs the fourth and fifth registers and the first output of the first bus driver, the second output of which is connected to the input of the first element NOT and to the first input of the switch, the second input of which is connected to the third the output of the first bus driver, the output of the first element is NOT connected to the first input of the first register, the group of inputs of which is connected to the outputs of the n-nodes of the input, the second input of the first register is connected to the third output of the decoder, the second output of which is connected to the first input of the second register, the group of outputs of which connected to the groups of outputs of the second bus driver and the first register, with the first group of inputs of the block of elements And, with the groups of inputs of the third and fourth registers and with the second group of inputs and outputs ora, the second input of the fourth register is connected to the fourth output of the decoder, the first output of which is connected to the input of the third register, the group of outputs of which is connected to the second group of inputs of the block of elements AND, the group of outputs of which is connected to the group of inputs of the fifth register, the second input of which is connected to the fifth output a decoder, the seventh and eighth outputs of which are connected, respectively, with the first and second inputs of the second bus driver, each input from the group of inputs of which is connected through a corresponding resistor with the input of the corresponding m-th relay coil and the corresponding output of the fourth or fifth register, the outputs of the interlock unit are connected to the outputs of the relay windings, characterized in that two groups of x and y are input nodes, z-recorders of signals from photo-thyristor sensors and q -registers of signals from fiber-optic sensors, the inputs of which are the second group of inputs of the device, the third group of inputs of which are inputs of z-registrars of signals from photothyristor sensors, the outputs of all recorders of signal signals are connected to the corresponding inputs of the input nodes x and y, the outputs of which are connected to the group of inputs of the second register, the signal recorder from fiber-optic sensors contains k-signal amplifiers, three groups of k-resistors, a microprocessor, k-LEDs, and k-transistor optocouplers and k-varistors, wherein the signal recorder from the photo-thyristor sensors contains p-diodes, p-nodes of galvanic isolation, a microprocessor, p-resistors and p-LEDs, the input node containing four resistors, two diodes, a capacitor, and a comparator and optocoupler transistor, wherein the inputs from the signal recorder of fiber optic sensors are the input signals of amplifiers whose outputs are coupled to inputs of the corresponding resistors of the first and second groups, outputs of the first group of resistors connected to the supply circuit, resistors are connected the outputs of the second group

with inputs of a microprocessor, the first group of outputs of which is connected to the cathodes of k - LEDs, the anodes of which are connected to a power circuit, which connects the first inputs of k - optocouplers, the second inputs of which are connected to the inputs of resistors of the third group, the outputs of which are connected to the second group of outputs of the microprocessor, the first and second outputs of the k - optocouplers are the outputs of the signal recorder and are connected to the inputs and outputs of the corresponding k - varistors, and the inputs of the registrar of signals from the photo-thyristor sensors are inputs of r-g isolation junctions and anodes of p-diodes, the cathodes of which are outputs of the signal recorder, the outputs of the galvanic isolation are connected to the inputs of the microprocessor, the outputs of which are connected to the inputs of the p-resistors, the outputs of which are connected to the cathodes of the corresponding p-LEDs, the anodes of which are connected to the power circuit, and the inputs of the input node are the inputs of the first and second resistors, the output of the second resistor is connected to the anode of the first diode, with the input of the capacitor, with the first inputs of the comparator and optocouplers, the second input to which is connected to the input of the fourth resistor, the output of which is connected to the output of the comparator and to the output of the third resistor, the input of which is connected to the second input of the comparator, with the output of the capacitor and the cathode of the second diode, the anode of which is connected to the cathode of the first diode and the output of the first resistor, the first the output of the optocoupler is connected to the power circuit, the second output of the optocoupler is the output of the input node.

Figure 1 shows the structural diagram of the device;

figure 2 - block the formation of control commands;

figure 3 - node lock;

figure 4 - input node;

figure 5 - recorder signals from fiber optic sensors;

figure 6 - the recorder of signals from photothyristor sensors;

Fig.7 is an example of the connection of the device with sensors and switches

Figure 1 marked:

1 ₁ ... 1 _q - recorders of signals from fiber optic sensors;

2 ₁ -2 _z - recorders of signals from photothyristor sensors;

3 - control device;

4 ₁ - 4 _N 4 ₁ - 4 _x , 4 ₁ - 4 _y - the first, second and third group of input nodes;

5 - block forming teams;

6 - the first register of the type KR1554IR23 or similar;

7 - the second register type KR1554AP5 or similar;

8 - the first element is NOT of the type КР1554ЛН1 or similar;

9 - switch type КР1554АП9 or similar;

10 - the first bus former type KR1554AP5 or similar;

11 - the third register type KR1554IR23 or similar;

12 - decoder type KR1554ID7 or similar;

13 - the second element is NOT of the type КР1554ЛН1 or similar;

14 - the fourth register of type KR1554IR41 with Darlington amplifiers of type MCT1413BP at the output (not shown in the diagram for simplicity) or similar;

15 - block of elements And type KR1554LI1 or similar;

16 - the fifth register of type KR1554IR41 with Darlington amplifiers of type MCT1413BP at the output (not shown in the diagram for simplicity) or similar;

17 - blocking unit;

18 ₁ ... 18 _m - relay type RM83-1021-3 5-1024 of the company "RELOOL" or similar;

K ₁ ... K _m - relay contact chains making up the third group of inputs and outputs;

R ₁ ... R _M - resistors of type C2-23 or similar;

19 - the second bus former type KR1554APZ or similar;

20 - lines of discrete input signals;

21 - line input signals from fiber optic sensors;

22 - lines of input signals from photothyristor sensors;

23 - communication bus with PC;

24 - communication bus with ACS;

25 - signal line "RESET";

26 - bus address / data / control;

Figure 2 marked:

27 - a central processor of the type AT89C52-24PI or similar (to simplify the circuit, a resonator and control circuits are not shown);

27-1 - supervisor type ADM693AN firm "ANALOG DEVICES" or similar;

28 - real-time clock type RTC72423B of the company "EPSON" or similar;

29 - ROM type AT28S256 or similar;

30 - RAM type SRM2A256LLCT or similar;

31 - a set of buffer registers of the type KR1554IR23 or similar;

32 - indicators;

33 - keyboard ("Reset" button);

34 - a set of buffer registers type KR1554IR23 or similar;

35 - RAM type SRM2A256LLCT or similar;

36 - microprocessor type AT89C52-24PI or similar (to simplify the circuit, a resonator and control circuits are not shown);

37 - a set of bus formers of the type KP1554AP5 or 74NS244 or similar;

38, 39 - drivers for communication with automatic control systems and personal computers of the ADM232AAN type by ANALOG DEVICES or similar;

Figure 3 marked:

R1 ... R5 - resistors of type C2-33H or similar;

V - diode type 2D510A or similar;

T1 - transistor type KTZ 102A or similar;

T2 - transistor type KT837E or similar.

In figure 4 are indicated:

R1 ... R4 - resistor type RC 1206 company "Yageo" or similar;

V1, V2 - diodes of the type BAV99 manufactured by PHI or similar;

C - capacitor type TAJ firm "AVX" or similar;

40 - comparator - a chip type MC33164D-5 of the company "Motorola" or similar;

DV - transistor optocoupler type TLP281GB firm "Toshiba" or similar;

Figure 5 marked:

41 ₁ ... 41 _K - signal amplifier - microcircuit type HFBR-2412M manufactured by Hewlett-Packard or the like;

R1 ₁ ... R1 _K , R1 ₁ ... R2 _K , R3 ₁ ... R3 _K , - Yageo type RC 1206 resistors or similar;

42 - microprocessor type PIC16F628-I / SO company "Microchip" or similar;

F ₁ -F _K - LEDs (single indicator) type LS3369-EH company "Infineon" or similar;

DV ₁ - DV _K - transistor optocoupler type PVT422 of the company "International Rectifer" or similar;

RU ₁ ... RU _K - varistor type 592-275 / 2322 592 52716 of the company "PHI" or similar;

Figure 6 marked:

V1 ... V _p - diode type BYD17M company "PHI" or similar;

43 ₁ - 43 _r - galvanic isolation unit;

44 - microprocessor type PIC16F628-I / SO company "Microchip" or similar;

R ₁ ... R _P - resistors RC 1206 company "Yageo" or similar;

F ₁ - F _P - LEDs (single indicator) type LS3369-EH company "Infineon" or similar;

R1 ... R5 - resistors RC 1206 of the company "Yageo" or similar;

R _T - thermistor type B59339-A1122-P20 company "Epcos" or similar;

DV - transistor optocoupler type TLP281GB firm "Toshiba" or similar;

C - capacitor type CC 1206 company "Yageo" or similar.

7 are indicated;

45 - transformer switch;

46 ₁ , 46 ₂ , 46 ₃ - circuit of maximum current protection;

47 - input switch;

48 - sectional switch;

49 - industrial relay;

50 - adjacent section;

FTD ₁ ... FTD _R p, FTD ₁ ... FTD _S - photothyristor sensors;

T - transformer;

L ₁ ... L _d - high voltage switches;

VOD1 ... VODL, VOD1 ... VODi, ... VOD1 ... VODA - fiber optic sensors.

The command generation unit 5 is implemented in accordance with figure 2 of the prototype and can also be implemented on the basis of a microprocessor system in accordance with [N.N. Chernobrov, V.A.Semenov, "Relay protection of energy systems" 1998, p. 78 -783]. Detailed information on the microprocessor system is given there on Pages 778-783.

The locking unit in FIG. 3 is implemented in accordance with FIG. 5 of the prototype.

Schemes of these nodes are given to describe the operation of the device.

In the circuits of the signal recorders, the power nodes, microprocessor programming circuits, and the "Reset" signal generation circuit from the button are not shown.

The microprocessor-based device for relay protection against arc faults contains five registers 6, 7, 11, 14, 16, a decoder 12, a block of elements 15, two elements NOT 8 and 13, a block for generating commands 5, three groups of 4n, 4x and 4u input nodes , switch 9, two bus shapers 10 and 19, blocking node 17 and m - relays 18 cm - resistors R, 2z - signal recorders from photo-thyristor sensors and 1q - signal recorders from fiber-optic sensors, inputs 20 4n - input nodes are the first group of inputs of the device, the first 23 and second 24 group of inputs and outputs of the unit form of instructions 5 is the first and second group of inputs and outputs of the device, the contact circuits of the relays 18 are the third group of inputs and outputs of the device, the group of inputs of the decoder 12 is connected to the group of outputs of the first bus driver 10, the group of inputs of which is connected to the first group of inputs and outputs 26 the switch 9 and the third group of inputs and outputs of the command generation unit 5, the reset output 25 of which is connected to the first input of the locking unit 17, the second input of which is connected to the output of the second element HE 13, the input of which is connected to the first the control inputs of the fourth 14 and fifth 16 registers and the first output of the first bus driver 10, the second output of which is connected to the input of the first element HE 8 and to the first input of the switch 9, the second input of which is connected to the third output of the first bus driver 10, the output of the first element NOT 8 is connected to the first input of the first register 6, the group of inputs of which is connected to the outputs of the 4n input nodes, the second input of the first register 6 is connected to the third output of the decoder 12, the second output of which is connected to

the first input of the second register 7, the group of outputs of which is connected to the output groups of the second bus driver 19 and the first register 6, with the first group of inputs of the block of elements And 15, with the groups of inputs of the third 11 and fourth 14 registers and with the second group of inputs and outputs of the switch 9, the second input of the fourth register 14 is connected to the fourth output of the decoder 14, the first output of which is connected to the input of the third register 11, the group of outputs of which is connected to the second group of inputs of the block of elements And 15, the group of outputs of which is connected to the group of inputs of the fifth register 16, the second input of which is connected to the fifth output of the decoder 12, the seventh and eighth outputs of which are connected, respectively, with the first and second inputs of the second bus driver 19, each input from the group of inputs of which is connected through the corresponding resistor R to the input of the corresponding m -th winding of the relay 18 and the corresponding output of the fourth 14 or fifth 16 registers, the outputs of the locking unit 17 are connected to the outputs of the windings of the relay 18, the inputs 21 1q of the signal recorders from fiber optic sensors are W a second group of inputs of the device, the third group of inputs of which is 22 inputs of 2z-recorders of signals from photothyristor sensors, the outputs of all signal recorders are connected to the corresponding inputs of input nodes 4x and 4y, the outputs of which are connected to a group of inputs of the second register 7, a signal recorder from fiber-optic sensors 1 contains 41 k - signal amplifiers, three groups of k-resistors R, microprocessor 42, k - LEDs F, k-optocoupler of transistor DV and k-varistors R _u , a registrar of signals from photo-thyristor sensors 2 contains p-diodes V, p-nodes of galvanic isolation 43, microprocessor 44, p-resistors R and p-LEDs F, input node 4 contains four resistors R, two diodes V, capacitor C, comparator 40 and transistor optocoupler DV, recorder inputs signals from fiber optic sensors 21 are inputs of signal amplifiers 41, the outputs of which are connected to the inputs of the corresponding resistors of the first R1 and second R2 groups, the outputs of the resistors of the first group are connected to the power circuit, the outputs of the resistors of the second group are connected to the RA inputs of the microprocessor 42, p the first group of outputs RB is connected to the cathodes of K - LEDs F, the anodes of which are connected to a power circuit, to which the first inputs of the k - optocoupler DV are connected, the second inputs of which are connected to the inputs of the resistors of the third group R3, the outputs of which are connected to the second group of outputs of the RC microprocessor 42, first and second outputs k - DV optocouplers are outputs signals 1 and recorder connected to the inputs and outputs corresponding to - varistors R _u, 22 inputs signals from the recorder fototiristory sensors 2 are inputs p- electroplating times the tongue 43 and the anodes of the p-diodes V, the cathodes of which are the outputs of the signal recorder 2, the outputs of the galvanic isolation 43 are connected to the inputs RA of the microprocessor 44, the outputs RB of which are connected to the inputs of the p-resistors R, the outputs of which are connected to the cathodes of the corresponding p-LEDs F, anodes

which are connected to the power circuit, the inputs 20 of the input node 4 are the inputs of the first R1 and second R2 resistors, the output of the second resistor R2 is connected to the anode of the first diode VI, with the input of the capacitor C, with the first inputs 4 of the comparator 40 and 2 optocouplers DV, the second input 1 which is connected to the input of the fourth resistor R4, the output of which is connected to the output 1 of the comparator 40 and to the output of the third resistor R3, the input of which is connected to the second input 2 of the comparator 40, with the output of the capacitor C and the cathode of the second diode V2, the anode of which is connected to the cathode first diode VI and the output of the first resistor R1, a first outlet 3 optocoupler DV connected to the supply circuit, the second output of the optocoupler 4 is output DV input node.

The device provides:

- control of switches;

- monitoring the position of the circuit breaker, issuing an emergency shutdown signal, monitoring circuit breaker control circuits with the output of information to the console, output relays and serial channels;

- receiving discrete control signals, issuing control commands, emergency and warning alarms;

- receiving and transmitting control information via a standard communication channel;

- obtaining information from fiber-optic and photothyristor sensors when an arc fault occurs;

- storage and issuance of information on the quantity, time and causes of emergency trips of the circuit breaker;

- continuous operational performance monitoring (self-diagnosis) throughout the entire operation time;

The control of the switches is ensured by the formation of commands for turning on and off the sectional switch according to the signals:

- from relay protection blocks arriving at inputs 20;

- arriving through serial channels 23 and 24 (from a PC or ACS).

Indication of the position of the switch is provided by indicators 32.

The device operates as follows:

when the power is turned on, the supervisor 27-1 of the microprocessor 27 generates a "RESET" signal, through which the initial installation takes place. When the input voltage increases from 0 to the operating voltage at the digital inputs 20, which is equal to the reference voltage of the comparator 40, a signal appears at the output 1 of the comparator 40 and is transmitted through the optocoupler DV to the output of the input node 4. Then this signal is sent to register 6. Register 6 stores and transfers information through the switch 9 to the command generation unit 5.

When a short circuit occurs in the switchgear cell, accompanied by an electric arc, radiation appears from the arc column of the arc to which the fiber-optic, photo-thyristor sensors installed in these cells react (photo-resistor, phototransistor and photodiode sensors can also respond to the arc).

Fiber-optic WATER and photo-thyristor FTD sensors (Fig. 7) installed in the compartments of the cells of the input switch 47, the section switch 48 and the high-voltage switches A, generate signals that are sent to the inputs of the signal recorders 1 and 2 through lines 21 and 22 from the outputs 21 of the fiber-optic sensor, the water goes to the amplifier 41 of the recorder 1 (figure 5). The amplified signal is fed through the resistors R1, R2 to the input of the RA port of the microprocessor 42. The microprocessor 42 constantly polls the state of the logic level at the input of the port and estimates the duration of the voltage levels. When certain conditions are met, an output is generated at the output of the RB port by which the LED F is lit (which determines the operation of the corresponding sensor), and a signal is generated at the output of the RC port at which the optocoupler DV is triggered and at its output (at the limiting varistor R _u ) an input signal is generated input node 4 (figure 4). Further, this signal through the resistor R1 and the diode V2 is fed to the input of the comparator 40, where it is compared with the reference voltage of the comparator, when certain conditions are met, the signal arriving at the input of the register 7 is generated at the output of the comparator. Register 7 stores and transmits to the command generation unit 5 through switch 9 reading information on the incoming signal from the decoder 12. The microprocessor 27 commands forming unit 5 analyzes of the corresponding program information from the recorder and the input signal node and generates _N 4 od (address / data) that is supplied through the switch 9 to the register 14, and to expand the address space via the register 11 and the AND unit 15 to the register 16. Next, the signals from the outputs of registers 14 and 16 of the relay 18 ₁ ... 18 _m translates to the position corresponding to a specific switch command. Thus, the device monitors the health of the circuit breaker and its control circuits, and when a short circuit signal accompanying the presence of an arc appears, a signal is generated that comes from the microprocessor through the decoder 12, the element 13 to the interlock 17 and blocks all the windings of the relay 18 ( relieves voltage from the windings), i.e. turns off the corresponding switch.

The input signal from the outputs 22 of the photo-thyristor sensor FTD (Fig.7) is supplied to the diode V and the galvanic isolation node 43 of the recorder 2 (Fig.6). A galvanically isolated signal through the node resistor R5 is fed to the input of the RA port of the microprocessor 44. The microprocessor 44 constantly polls the state of the logic level at the port input and estimates the duration of the voltage levels. While doing

Under certain conditions, at the output of port RB, a signal is generated by which the LED F is lit (which determines the operation of the corresponding sensor), and a signal is fed to the diode V cathode at the input of input node 4. Further, the device operates similarly to the above.

To increase reliability, the device has a self-diagnosis system, which consists of two subsystems - background self-diagnosis, which provides control over the operability of the main components of the device during the entire period of operation, and a set of tests run on call.

Background self-diagnosis is performed continuously throughout the entire operation of the device, providing control over the operability of all major nodes. Self-diagnosis results are analyzed by the central processor. Diagnostics includes:

- verification of discrete inputs and outputs;

- check of serviceability of keys and coils of output relays;

- channel testing, etc.

For example, when diagnosing the outputs, the signal is removed from the resistors R ₁ ... R _M at the outputs of the Darlington keys of registers 14 and 16 and enters through the bus drivers 19, switch 9 to the microprocessor 27 (if the circuit is broken or the key fails, the signal level on the resistor will differ from level available in the working node.)

Checking the RS-232 and RS-485 channels of drivers 38 and 39 is done by checking the equality of transmitted and received information (by installing a stub and without it).

Thus, the introduction of registrars and additional input nodes, expands the functionality of the device, and while maintaining all the prototype qualities (reliability, noise immunity and operational control of circuit breakers), it can be used to protect complete switchgears of electrical substations in the event of short circuits accompanied by an open electric arc , as well as to protect maintenance personnel from injuries and damage during electrical accidents associated with open electrical arc.

Claims (1)

The microprocessor-based device for relay protection against arc faults containing five registers, a decoder, a block of AND elements, two NOT elements, a command generation unit, n-input nodes, a switch, two bus shapers, a blocking node and an m-relay with m-resistors, with inputs n -input nodes are the first group of device inputs, the first and second group of inputs and outputs of the command generation unit is the first and second group of device inputs and outputs, relay contact chains are the third group of device inputs and outputs, the group of inputs the decoder is connected to the group of outputs of the first bus driver, the group of inputs of which is connected to the first group of inputs and outputs of the switch and the third group of inputs and outputs of the command generation unit, the reset output of which is connected to the first input of the locking unit, the second input of which is connected to the output of the second element NOT, the input of which is connected to the first control inputs of the fourth and fifth registers and the first output of the first bus driver, the second output of which is connected to the input of the first element NOT and with the first input the ode of the switch, the second input of which is connected to the third output of the first bus driver, the output of the first element is NOT connected to the first input of the first register, the group of inputs of which is connected to the outputs of the n-nodes of the input, the second input of the first register is connected to the third output of the decoder, the second output of which is connected with the first input of the second register, the group of outputs of which is connected with the groups of outputs of the second bus driver and the first register, with the first group of inputs of the block of elements AND, with the groups of inputs of the third and fourth of the registers and with the second group of inputs and outputs of the switch, the second input of the fourth register is connected to the fourth output of the decoder, the first output of which is connected to the input of the third register, the group of outputs of which is connected to the second group of inputs of the block of elements AND, the group of outputs of which is connected to the group of inputs of the fifth register, the second input of which is connected to the fifth output of the decoder, the seventh and eighth outputs of which are connected respectively to the first and second inputs of the second bus driver, each input from the group the ode of which is connected through an appropriate resistor to the input of the corresponding m-th relay coil and the corresponding output of the fourth or fifth register, the outputs of the interlock unit are connected to the outputs of the relay windings, characterized in that two groups of x and y input nodes, z-recorders are introduced into it signals from photothyristor sensors and q-recorders of signals from fiber-optic sensors, the inputs of which are the second group of inputs of the device, the third group of inputs of which are inputs of z-recorders of signals from photothyristor sensors, the outputs of all signal recorders are connected to the corresponding inputs of the input nodes x and y, the outputs of which are connected to a group of inputs of the second register, and the signal recorder from fiber-optic sensors contains k-signal amplifiers, three groups of k-resistors, a microprocessor, LEDs, k-optocouplers of transistor and k-varistors, and the registrar of signals from photothyristor sensors contains p-diodes, p-nodes of galvanic isolation, a microprocessor, p-resistors and p-LEDs, and the input node contains three resistors, two diodes, a capacitor, a comparator and a transistor optocoupler, the inputs of the signal recorder from fiber optic sensors being inputs of signal amplifiers, the outputs of which are connected to the inputs of the corresponding resistors of the first and second groups, the outputs of the resistors of the first group are connected to the power supply, the outputs of the resistors the second group is connected to the inputs of the microprocessor, the first group of outputs of which is connected to the cathodes of the k-LEDs, the anodes of which are connected to the power circuit, to which the first inputs are connected k-optocouplers, the second inputs of which are connected to the inputs of the resistors of the third group, the outputs of which are connected to the second group of outputs of the microprocessor, the first and second outputs of the k-optocouplers are the outputs of the signal recorder and connected to the inputs and outputs of the corresponding k-varistors, the inputs of the signal recorder from photo thyristor sensors are the inputs of the r-galvanic isolation and the anodes of the r-diodes, the cathodes of which are the outputs of the signal recorder, the outputs of the galvanic isolation are connected to the inputs of the microprocessor, the passages of which are connected to the inputs of the p-resistors, the outputs of which are connected to the cathodes of the corresponding p-LEDs, the anodes of which are connected to the power circuit, the inputs of the input node being the inputs of the first and second resistors, the output of the second resistor connected to the anode of the first diode, with the input of the capacitor, with the first inputs of the comparator and the optocoupler, the second input of which is connected to the input of the fourth resistor, the output of which is connected to the output of the comparator and the output of the third resistor, the input of which is connected to the second input of the comparator ora, a yield of the capacitor and the cathode of the second diode, the anode of which is connected to the cathode of the first diode output and a first resistor, the first output of the optocoupler is connected to the supply circuit, the second output of the optocoupler input is the output node.