SU1177797A1 - Device for checking control channels and signalling system channels of ship power plants - Google Patents

Description

keys to the output bus of the control unit; the third input is combined with the third input of the first register and connected to the output bus of the codogram generation unit; the outputs of the second register are connected to the corresponding first inputs of the OR element block and the second inputs of the second block of AND elements, the second inputs of the OR element block are connected to the corresponding outputs of the first register, the outputs of the block of elements OR are connected through the block of inverters with the corresponding third inputs of the display unit, the third, fourth inputs and the second input bus Lok analysis are connected to corresponding output buses remote control, codified forming unit and the decoder, the control unit output is connected to a fourth input of the indication node.

2. The device according to claim 1, that is, that the control panel contains a block of buttons, a digital display and the first, second, third display of the display, the outputs of the block of buttons are connected to the output bus of the control, the inputs of the digital display, of the first, second and the third display panel are respectively the first, second, third and fourth inputs of the control panel.

3. The device according to claim 1, characterized in that the display unit contains an amplifier unit, the first, second amplifiers and the block of elements And, the inputs of the amplifier unit are connected

to the input bus of the display unit, the inputs of the first, second amplifiers, the first and second inputs of the AND block are respectively the first, second, third and fourth inputs of the display node, the outputs of the amplifier block, the first, second amplifiers and the AND cell of the elements, respectively, are the first, the second, the third. h the fourth outputs of the display unit,

4. The device according to claim 1, that the control unit contains the OR elements, the AND element, the delay element, the inverter, the one-shot and the triggers, the outputs of the first, second and third OR elements are connected to the first inputs of the first, second, respectively and the third trigger, the direct output of the first trigger is connected to the first input of the AND element and

through the delay element - with the second input of the first trigger; the inverse output of the first trigger is connected to the input of the first one-oscillator; the output of the AND element is connected to the first inputs of the fourth and fifth OR elements; the output of the fourth trigger is connected to the second inputs of the fourth and fifth elements; OR, the second output the trigger is connected to the third input of the fourth element OR, the output of which is connected through an inverter to the input of the second one-shot, the inputs of the first, second, third elements OR, the first input of the fourth trigger, combined the second inputs of the second, third, fourth flip-flops are connected to the input bus of the control unit; the second input of the AND element is the input of the control unit; the outputs of the fourth OR element, the second one-oscillator, the fifth OR element, the first one-oscillator, the AND element, the first output of the first trigger are connected to the output bus of the control unit, the output of the third flip-flop is the output of the control unit.

5. The device according to claim 1, characterized in that the analysis unit comprises a code converter, a register, an inverter, AND elements, triggers and a comparison element, the outputs of the code converter are connected to the corresponding first inputs of the register, the outputs of which are connected to the corresponding first inputs of the comparison element, the output of which is connected to the first input of the first element I and, through an inverter, to the first input of the second element I, the outputs of the first and second elements; Both are connected to the first BXi.-dami of the corresponding first and second triggers, the second inputs of the comparison element, the combined second inputs

The first and second triggers and the third register input are respectively the first, second and third inputs of the analysis unit, the second register input and the combined second inputs of the first and second elements I are connected to the first input bus of the analysis unit, the inputs of the code converter are connected to the second input bus of the analysis unit The outputs of the first and second triggers are respectively

the first and second outputs of the analysis block.

6. The device according to claim 1, wherein the codogram forming unit contains the elements OR, the BANNER elements, the delay elements, the trigger and the registers, the output of the first element OR is connected to the inverse input of the first BANNER element, the first direct input of the second the BANNER element and the direct input of the third BANNER element, the output J. of the third BANNER element is connected to the first input of the first register, the outputs of which are connected to the corresponding inputs of the second OR element, the output of which is connected to the right input of the first BANNER and the first delay element - with the inverse input of the third BANNER element, the output of the first BAN element is connected to the first input of the trigger, the output of the trigger is connected to the second direct input of the second

7797

BAN element whose outputs are connected to the corresponding inputs of the third OR element, the output of which is connected through the second delay element with the inverse of the second BAN element, the output of the third delay element is connected to the inverse input of the fourth BAN element and the first input of the fourth OR element, the output of the fourth OR element is connected with the second inputs of the trigger, the first and second registers, the combined inputs of the first OR element and the third inputs of the first and second registers, respectively, the second input of the fourth th element and the combined OR input of the third delay element and a straight fourth input element connected to the inverted input bus codified forming unit, outputs of first, second, fourth registers and an output member connected to the inverted output bus unit codified form.

The invention relates to the field of test control of shipborne automation equipment and can be used to monitor control channels and signaling power plants. The aim of the invention is to expand the functionality of the device by simulating the absence of input signal deviations (installation parameters) and reducing the time for carrying out autonomous mooring tests on the installation units as their installation is completed. Fig 1 shows a structural diagram of the device; Fig. 2 is a functional diagram of a codogram generation unit; FIG. 3 shows functional diagrams of a memory unit and a control unit; Fig, 4 - the same, the block of elements OR, the block of inverters and blocks of elements And; fig, 5 - the same, switches and block of keys; figure 6 is a functional diagram of the analysis unit. A device for monitoring control and signaling channels of ship power plants (FIG. 1) contains a monitoring control unit, a codogram generation unit 2, a decoder 3, a memory unit 4, a register 5, a unit 6 of elements And, a sensor 7 of single signals, a sensor 8 of zero signals , switches 9-14, inverter block 15, analysis block 16, display unit 17, control block 18, AND block 19, control signal generator 20, key block 21, control block 22, sensor block 23, register 24 and block 25 elements OR, Remote 1 control contains a block of 26 kn Opok, digital scoreboard 27 and display 28-28 display. The display unit 17 comprises an amplifier unit 31, a unit element 32 And amplifiers 33 and 34. The memory unit 4 (FIG. 3) contains outputs 35-40. Block 25 of the elements OR (Fig, 4) contains elements or 41-43, Block 26 of the buttons (Fig, 2) contains buttons (keys) 44-47. The codogram generation unit 2 (Fig. 2) contains registers 48 and 49, elements OR 50-53, BANES 54-57 elements, elements aperture 58-60, and trigger 61. Amplifier block 31 (Figs. 2) contains amplifiers 62 -65, Digital display 27 (FIG. 2) contains digital indicators 66 U and 67 g. Memory block 4 (FIG. 3) contains code converters 68-71, inverters 72-74, and elements OR 75-80. The control unit 18 (FIG. 3) contains the triggers 81-84, the elements OR 15 85-89, the element AND 90, the inverter 91, the one-shot 92 and 93, and the element 94 delay. Blocks 6, 19 and 32 elements And (Fig about 4) contain elements And 95-103 and amplifiers 104-112. The inverter unit 15 20 (fig „4) contains inverters 113-115о. The switches 9-14 () contain the windings 116-121 of the relay and the contacts 112-127 of the relay. The key block 21 (contains the relay coil 128 and the relay contacts 129-132. The block 22 of the actuators 1, FIG. 5) contains the actuators 133-135 The analysis block 16 (FIG. 6) contains a code converter 136 30, register 137, element 138 comparisons, inverter 139, elements And 140 and 141 and triggers 142 and 143s.

The device works as follows, 35

In the initial state, the ship power plant is in one of the possible states; in the pre-start preparation mode or in the mode of maintaining the specified energy 40 of the heterogeneous power level, and there are no signals from the outputs of blocks 6 and 19. As a result, the signals of the sensor unit 23 (figo) of the set parameters:: and through the switches 45 9-14 are fed to the input of the control signal generator 20, which, in order to maintain the set operating mode of the installation, send through the key block 21 a set of control actions 50 to block 22 executive elements. The control device has three modes of operation: on-line test control of the control and signaling channels when the ship’s power installation is in operation at an energy level of power, autonomous mooring tests of individual units

installations as soon as their installation is completed, and complex mooring tests of a fully assembled ship power plant in all operational modes of operation. The modes and operation program of the device are set by the operator from the console 1 of the control by means of codograms - decimal numbers defining the list of operations and addresses of the channels being checked.

The various operations of the operational test control are given by codograms with numbers from 1 to K, the modes of complex mooring tests of the installation are selected by codograms with numbers from K + 1 to I., and the modes of autonomous mooring tests of individual units of the installation - by codograms with numbers from L + 1 to M. The codograms with the numbers M + 1 and K + 2 are intended to form service commands: with the M + 1 command, the Enter test command is formed during autonomous mooring trials of individual units, and the M + 2 test record, respectively, the Reset test command if LLR autonomous installation of complex tests ,.

The proposed control device, in which the number of codograms necessary for specifying the operations and modes of the device, does not exceed 100 and which are represented by two-fold decimal numbers, works as follows:

A set of codograms is produced by successively pressing buttons 44 and 45 (Fig 2), each of which corresponds to one of ten digits.

llrv tt 1 m sp

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In the initial STATUS, the value of the output signals of the registers 48 and 49 and the trigger 61 is equal. The first time one of the digital buttons 44 and 45 is pressed, the corresponding register register bit 48 is recorded 1, the Write enable signal (input C) in register 48 is formed by the elements OR 50 and 51, by the elements BAN 54 and delays 58 provided that button 44 or 45 is pressed and there is no information in register 48 “After. recording information in re; The record 48 write enable signal is removed by the elements OR 51, BAN 54 and the delay element 58. After releasing the previously pressed trigger 61, it goes to state 1, preparing the recording of information when the button 44 or 45 is subsequently pressed into register 49c. Setting the trigger 61 to the state is done by OR 50 and 51 and BAN 56. When the button 44 or 45 is pressed again ( the second bit set of the codogram is the recording resolution signal present at input C of the register 49. The recording resolution signal is formed by the elements OR 50 and 53, BAN 55 and the delay element 59 under the condition of pressing the button 44 or 45, the presence of information in the register 48 and the absence of information In register 49, after the information is recorded in register 49, the write enable signal is removed by the elements OR 53, BAN 55 and the element 59 delay elements. The delay elements 58 and 59 serve to eliminate the register output signals and to remove the write enable signals From the outputs of the registers 48 and 49 signals are fed to amplifiers 62-65 of block 31, which serve to illuminate the digital indicators 66 and 67 of the digital display 27 of the control panel 1 of the control. On a digital board 27, the operator visually checks the correctness of the dial-up of the code frame. In the case of an incorrect dialing, the operator presses the Reset button 47, the signal from which through the OR element 52 sets registers 48 and 49 and the trigger 61 to the state O. In the case of correct dialing, the operator presses the button 46 Input, the signal from which through the pulse shaper, formed by the BANGE 57 element and the delay element 60, goes to the control input: the matrix decoder 3, resulting in one of the outputs of the interpreter 3 in accordance with the number on An early set of signals appears on the control list. Operational test monitoring of the control and signaling channels is performed when the ship’s power plant is working on power by momentarily blocking the control channels of the power plant, setting the input test signal and comparing the actual response of the control channels. signaling to the test with the reference value of the output signals. When dialing a codogram with one of the numbers from 1 to K at the corresponding output of the decoder 3, a signal appears at the input of the code converter 68 (FIG. 3) of the memory block 4. At outputs 1, .c, P of converter 68, where P is the number of sensors of parameters of the ship power installation, a binary code is created to simulate the deviations of the parameters of the installation through the OR 75-77 elements to the inputs of register 5 of the parameters of the deviation simulation. Simultaneously, from outputs 1, ... P of converter 68, the code for simulating the deviation of parameters is supplied through inverters 72-74 and elements 1-SHI 78-80 to the inputs of register 24 of the code for simulating operational values of parameters. The write enable signal is fed to the inputs C of registers 5 and 24 from the codogram generation unit 2 (FIG. 2). At the same time, the signal corresponding to a given test is received from one of the outputs 1, .. To the decoder 3 of the OR element 85 of the control unit 18 (FIG. 3) and sets the trigger 81 to state 1, the output signal of which acts on the winding 128 of the relay of the key unit 21 (FIG. 5). The opening contacts 130-132 of the relay 128 disconnect the windings 133-135 of the executive elements of the unit 22 from the control signal generator 20 (the control channels are blocked / The closing contact 129 of the relay 128 generates a signal confirming the simplification channels are blocked and coming to the second (lower) input element AND 90, at the first input of which signal 1 is already present from the output of the trigger 81 (FIGES), Element AND 90 generates a control start signal arriving at the control input of the analysis unit 16 (FIG. 6) and through the elements OR 88 and 89 (FIG. ) on the control inputs of blocks 6 and 19, respectively (figs, 4b) From the outputs of amplifiers 104-109, blocks 6 and 19, binary codes recorded in registers 5 and 24 (Fig. 3) are fed to the windings of the relay 116-121 and switches 9-14 ( 5), as a result, irrespective of the values of the output signals of the sensor parameters block 23, which are installed on the inputs of the control driver 20 according to the state of the switching contacts 122-127 of the switches 9-14 from the outputs of the sensor 7 single signals and the sensor 8 zero signals a set of single and zero signals arrives, and the unit value of the binary code of the test recorded in the register 5 of the simulation parameter deviation code (FIG. 3) corresponds to the unit test signal, and the unit test bit of the binary code of the test recorded in the register 24 of the simulation parameter operational values is zero test signal. The set of output commands of the control signal generator 20 (fig.b formed in accordance with the test goes to the first inputs of the comparison element 138 of the reaction analysis block 16 (fig.b), which compares them with exemplary reaction signals. The exemplary response signals to this test are generated by the converter 136 of the code, to the inputs of which from outputs 1 ,,, To decoder 3 (FIG 2), a signal is received that corresponds to the specified test C of outputs 1 G. O. N (where N is the number of output commands of the control generator 20. control signals) of converter 136 (fig ) samples e, the reaction signals arrive at the inputs of the register 137, from whose outputs they are fed to the inputs of the comparison element 138. The write enable signal at input C, the register 137, comes from the output of the BAN 57 element of the code 2 generation unit of FIG. When the set of output commands of the control signal generator 20 coincides (.fig, 5 with response signals), the signal at the output of the comparison element 1.38 (FIG. 6 takes the value 1 and goes through the input 141 to the trigger 143, setting it to state 1 The output signal of trigger 143 is amplified by the amplifier 33 of the test result signals and illuminates the board 29. The equipment is in good condition. If the set of output shunts of the driver 20 does not match with the exemplary reaction signals, the signal at the output of the comparison element 138 takes the value O, the invert Inverter 139 and through the element 140 is fed to the input of the trigger 142, set it to state 1, the output signal of the trigger 142 is amplified by the amplifier 34 of the signals of the test results and illuminates the scoreboard 30. The hardware fails. determined by the delay time of the delay element 94 (Fig 3), the trigger 81 is set to the state O by the delay element 94. At the same time, the control start signal is removed from the outputs of the AND 90 and RSHI 88 elements, which leads to the appearance of a pulse at the output of the one-vibrator 93, which sets the registers 5 and 24 to the initial state. At the same time, the single-vibrator 92 generates a setting pulse to the initial state of register 137 (FIG. 6) and the control signal generator 20 (FIG. 5). The blanking of the scoreboard 29 and 30 (FIGSB) is performed by setting the O state of the flip-flops 142 and 143 by pressing the button 47 Reset Sfig, 3). Comprehensive mooring testing of the ship power plant is carried out after the completion of installation of all its units. The installation is tested at the energy level of the power, the triggering of the emergency protection of the installation and the restriction of the permissible power level are checked by simulating the control system of the maximum deviations of the installation parameters (for example, emergency increase of turbine speed). Measures are taken to prevent the installation of emergency protection devices that may occur, for example in the case of the arrival at the inputs of the generator 20 of the control signals (FIG. 5), the signals of the sensor 8 are zero signals instead of the output signals of the block 23 of sensors Parameters settings. The necessary modes for simulating deviations of installation parameters are given by a set of codograms with numbers from K + 1 to L, Upon receipt of codograms from the outputs of block 2, Aorming codograms (Fig. 2) to the inputs of the decoder 3 at one of the outputs K + 1., L decoder 3 A signal appears at the corresponding input of the code converter 69 (FIG. 3) of the memory block 4. On outputs 1 .., P converter 69, where P is the number of sensors of parameters of the ship power plant, generates with a binary code imitation of deviations of the parameters of the installation, coming through the elements OR 75-77 to the inputs of register 5 of the code of simulation of deviation of parameters. The write enable signal is fed to input C of register 5 from the output of the BANCH 57 element of the codogram generation unit 2 (FIG. 2). At the same time, the signal corresponding to the specified test is received from one of the outputs K +. ,, L, decoder 3 to the input the element OR 86 of the control unit 18 (FIG. 3) and sets the trigger 82 to state 1, the output of which through the element OR 88 goes to the control input of the unit 6 (figure 4). From the outputs of amplifiers 104-106 of block 6, the binary code recorded in the register is fed to the windings of the relay 116-118 of switches 9-11 (FIG. 5). As a result, a single signal is received at some input of the driver 20 if the value of the corresponding code bit The simulation of the deviation of the parameters is 1, or the actual value of the sensor signal of the installation parameter with equal O of the corresponding bit of the code of simulation of the deviation of the parameters. At the end of the control by the operator of the correct operation of the ship power plant, the Test test is reset according to the standard indicators of the control panel of the plant (not shown). For this purpose, a codogram is dialed corresponding to the output M + 2 of the decoder 3 (FIG. 2). The signal from this output sets the trigger 82 (FIG. 3) to the state O, as a result, the signal is removed from the control input of block 6 (FIG. 4) and the initial state of register 5 is set to the deflection simulation code In the case of autonomous mooring tests of any unit, the installation of the installation units may be jHe completed, or the units generally may not be on board the ship at the time of the test, resulting in incorrect inputs to the shaper 20 (figure 5). sensor signal values of adjacent units of the installation, which prevent the testing of the algorithms of control channels and signaling the tested unit in all operational modes of operation. For testing the unit in all operational modes of operation using a monitoring device, simulate both the maximum deviations of the parameters of this unit and the normal operating parameters adjacent units, the installation of which is not completed at the time of autonomous mooring tests of this unit, the operator It provides information on the emergency test channels operating in this mode of the unit. Modes of autonomous mooring tests of the unit are given by codograms with numbers from L + 1 to M. When inputting from console 1 (FIG. 2), the control of the corresponding codogram at one of the L + loM outputs of the decoder 3 appears at the same time as the inputs of the converters 70 and 71 of the code of memory block 4 (FIG. 3). In this case, the code for simulating the deviation of parameters goes from the outputs 1., “P converter 71 through the I-ITIH 75-77 elements to the register 5 of the imitation code. parameter deviations, and the code of operational values of the parameters - from outputs 1,. P of converter 70 through OR elements 78-80 to register 24. The recording resolution signal is fed to input C of registers 5 and 24 from the output of BAN 57 block of codogram generation (FIG. 2). Simultaneously, from the outputs L + ltt M of the decoder 3, the signal corresponding to the specified test is fed to the inputs of the element OR 87 (FIGURE) and sets the trigger 83 to the state 1. The signal from the output of the trigger 83 goes to the control input of the block 32 (FIG. 4) In the outputs of registers 5 and 24 (Fig. 3), the codes for simulating the deviation of parameters and operating values of parameters are fed to the inputs of block 25 of the elements OR 41-43 (figure 4, from the output of which through the inverters 113-115 of the block are fed to the information .. block 32; At; the output signals of block 32 light up on the board 28 There are 1 control indicators corresponding to the activated channels of the emergency protection of the ship's power plant.After checking that the control device is working correctly, the panel 28 shows the activated channels of the emergency protection of the units from the control panel 1 of the control unit and sends a start test of the unit corresponding to the M + 1 output of the decoder 3 (Fig. 2). The signal from the M + 1 output of the decoder 3 sets the trigger 84 (Fig. 3 to state 1. The output signal of the trigger 84 through the elements OR 88 and 89 goes to the control inputs block Kev 6 and 19 (.phi 4), as a result, the output signals of the registers 5 and 24 through the blocks 6 and 19 arrive at the relay 116-121 of the switches 9-14 (, FIG. 5) in accordance with the codes recorded in registers 5 and 24 (.fig. 3), to the inputs of the control signal generator 20. (Fig. 5J receives a single signal if the value of the corresponding bit of the parameter of the parameter deviation simulation is 1, or a zero signal if the value of the corresponding bit of the code of the simulation of the operational knowledge of the parameters is 1 , or the actual value of the sensor signal of the installation parameter with equality The current bit of the parameter for deviating the parameters and operating values of the parameters (Table) 712 The control signal generator 20 sends a set of control actions to the input of the actuator block 22 via the key block 21, resulting in the initial operation mode of the unit. The change in the operating mode of the unit is controlled by the operator according to the standard indicators of the installation control panel (not shown. After completing the testing of the specified test, the operator resets the test by dialing the codogram corresponding to the output M + 2 of the decoder 3 (FIG. 2). At the same time, the triggers 83 and 84 ( FGSZ / are set to the state O, which leads to the removal of signals from the control inputs of blocks 6,19 and 32 (FIG. 4) and to the resetting of registers 5 and 24 (FIG. 3). The known device allows perform both control and sig check the implementation of the unchanged operation mode of the installation, as well as complex mooring tests of the installation while maintaining the standard schemes of the main equipment and the operation of the necessary emergency protection of the installation. In the process of building the vessel to reduce the overall delivery period of the vessel, the need arises for autonomous mooring their readiness “However, incomplete mobility of adjacent units prevents the testing of control channels and signaling the unit to be handed over to the customer in all operations GOVERNMENTAL rezhig swing operation of the unit because of the lack of possibility for simulating signals normal operating values of adjacent units parameters.

The value of the corresponding bit of the register test code | 24O

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The value of the signal at the corresponding input of the imager 20 control signals

Implement Parameter Sensor Signal

Zero test signal corresponding to the normal operating value of the unit meter

Single test signal corresponding to the deviation of the aggregate parameter

The combination of signals is not used.

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Claims (6)

(54 1. DEVICE FOR MONITORING THE CONTROL CHANNELS AND SIGNALING OF SHIPPING POWER INSTALLATIONS, comprising a control panel, the output bus of which is connected to the input bus of the encoding unit, the output bus of which is connected to the input buses of the decoder and display unit, the output bus of the decoder is connected memory and control unit, the first outputs of the memory unit are connected to the corresponding first inputs of the first register, the outputs of which are connected to the corresponding first inputs of the first block of electronic elements And, the outputs of which are connected to the control inputs of the corresponding first switches, the first information inputs of which are combined and connected to the output of the sensor of single signals, the second information inputs are connected to the corresponding outputs of the sensor block, the outputs of the first switches are connected to the first information inputs of the corresponding second switches, the second information the inputs of which are combined and connected to the output of the zero signal sensor, controlling · * · '· the inputs are connected to the corresponding it outputs ΒτρυοΓΟ block element and outputs the second switches are connected to respective first inputs of the driver control signals, which outputs are ^g are connected to respective first inputs of the block analysis and data inputs of a key block, the first outputs a key block connected to the respective unit final control inputs, the second output $ connected to the input of the control unit, the output bus of the control unit is connected to the second input of the first block of AND elements, the second input of the first register, the first input the house of the second block of AND elements, the second input of the driver of the control signals, the first input bus of the analysis unit and; with a control input of the key block, the first and second outputs of the analysis block are connected to the corresponding first and second inputs of the display unit, the first, second and third outputs of which are connected to the corresponding first, second and third inputs of the control panel, and the inverter block, characterized in that, in order to expand the functionality of the device by providing a simulation of the absence of deviations of the input signals, a second register and a block of OR elements are introduced into it, the first inputs of the second register are connected to the corresponding to the outputs of the memory block, the second key input to the output bus of the control unit, the third input is combined with the third input of the first register and connected to the output bus of the coding unit, the outputs of the second register are connected to the corresponding first inputs of the block of OR elements and second inputs of the second block of AND elements , the second inputs of the block of elements OR are connected to the corresponding outputs of the first register, the outputs of the block of elements OR are connected through the block of inverters with the corresponding third inputs of the display unit, the third, the fourth inputs and the second input bus of the analysis unit are connected to the corresponding output buses of the control panel, coding unit and decoder, the output of the control unit is connected to the fourth input of the display unit. 2. The device according to claim 1, characterized in that the control panel contains a block of buttons, a digital display and a first, second, third display panel, the outputs of the button block are connected to the output bus of the control panel, inputs of a digital panel, the first, second and third display panel are respectively the first, second, third and fourth inputs of the control panel. 3. The device according to claim 1, characterized in that the display unit contains an amplifier block, first, second amplifiers and a block of elements AND, the inputs of the amplifier block are connected to the input bus of the display node, the inputs of the first, second amplifiers, the first and second inputs of the block of elements And are respectively the first, second, third and fourth inputs of the display unit, the outputs of the amplifier block, the first, second amplifiers and the block of elements And are respectively the first, second, third. and the fourth outputs of the display unit. 4. The device according to claim 1, characterized in that the control unit contains OR elements, an AND element, a delay element, an inverter ·, a single vibrator and triggers, the outputs of the first, second and third OR elements are connected to the first inputs of the first, second and third triggers, respectively , the direct output of the first trigger is connected to the first input of the And element and through the delay element to the second input of the first trigger, the inverse output of the first trigger is connected to the input of the first one-shot, the output of the And element is connected to the first inputs of the fourth and fifth electric OR, the output of the fourth trigger is connected to the second inputs of the fourth and fifth elements OR, the output of the second trigger is connected to the third input of the fourth element OR, the output of which is connected through an inverter to the input of the second one-shot, the inputs of the first, second, third elements OR, the first input of the fourth trigger , the combined second inputs of the second, third, fourth triggers are connected to the input bus of the control unit, the second input of the AND element is the input of the control unit, the outputs of the fourth OR element, the second one-shot Ator, fifth OR gate, a first monostable multivibrator, the AND, the direct output of the first flip-flop connected to the output bus of a control unit of the third flip-flop output is the output of the control unit. 5. The device according to claim 1, characterized in that the analysis unit comprises a code converter, a register, an inverter, AND elements, triggers and a comparison element, the outputs of the code converter are connected to the corresponding first inputs of the register, the outputs of which are connected to the corresponding first inputs of the comparison element, the output of which is connected to the first input of the first And element and through an inverter to the first input of the second And element, the outputs of the first and second elements; And connected to the first inputs of the corresponding first and second triggers, the second inputs of the comparison element, the combined second inputs of the first and second triggers and the third input of the register are respectively the first, second and third inputs of the analysis unit, the second input of the register and the combined second inputs of the first and second elements And are connected to the first input bus of the analysis unit, the inputs of the code converter are connected to the second input bus of the analysis unit, the outputs of the first and second triggers are respectively the first and second outputs of the analysis unit. 6. The device according to claim 1, characterized in that the codogram generating unit comprises OR elements, BAN elements, delay elements, trigger and registers, the output of the first OR element is connected to the inverse input of the first BAN element, the first direct input of the second BAN element and direct input of the third element is FORBID, the output of the third element is FORBID connected to the first input of the first register, the outputs of which are connected to the corresponding inputs of the second element OR, the output of which is connected to direct ·· '· :. by the input of the first element BAN and through the inverse input of the third element BAN, the output of the first element BAN is connected to the first input of the trigger, the output of the trigger is connected to the second direct input of the second element BAN, the outputs of which are connected to the corresponding inputs of the third element OR, the output which is connected through the second delay element to the inverse input of the second element BAN, the output of the third delay element is connected to the inverse input of the fourth element and the first input of the fourth OR element, the output of the fourth OR element is connected to the second inputs of the trigger, the first and second registers, the combined inputs of the first! OR element and the third inputs of the first and second registers, the second input of the fourth OR element, and the combined input of the third delay element and the direct input of the fourth element connected to the input bus of the codogramming unit, the outputs of the first, second registers and the output of the fourth element BAN are connected to the output bus of the coding unit.