RU2267804C1 - System for controlling parameters of multi-functional systems - Google Patents

Abstract

FIELD: engineering of control system, possible use for controlling multi-functional electronic systems of various uses.

SUBSTANCE: system has modes control block, control panel, block of controlled imitators of analog sensor, first and second commutators, and additionally has block for forming control code, block of controlled imitators of frequency sensors, block of controlled imitators of signaling sensors, block for receiving single signals, block for transformation of constant voltage and block for forming and receiving multi-polar code.

EFFECT: expanded functional capabilities and control system application area, possible workability check of multi-functional control subjects, possible self-control of all control system elements to provide for high trustworthiness of results.

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Description

The invention relates to control systems and can be used to control multifunctional electronic systems for various purposes.

The system should have sufficient functionality to solve the task, for example, tasks for the diagnostic control of multifunction blocks (systems) for various purposes. The system should provide high reliability control parameters of multifunctional electronic systems.

Known systems:

"Automated control system for the parameters of electronic circuits" (author certificate, USSR No. 1500996 A1, class G 05 V 23/02), which contains a mode control unit connected to a control computer, a switch connected to a stimulating signal unit, an input signal measuring unit .

The specified system has limited functionality and scope.

The closest in technical essence and achieved effect in relation to the proposed technical solution is the "Device for parameter control" (ed. Certificate of the USSR No. 1513418 A1, class G 05 V 23/02), which has a control and control panel (control computer , information output unit, terminal), a block of controlled simulators of analog sensors (stimulating signal block), connected through a switch to a block of meters.

The specified system has insufficient functionality and scope due to the fact that it does not provide monitoring and diagnostics of multifunctional monitoring objects, which, in addition to analog measuring channels, have frequency measuring channels, channels for receiving a multipolar code, channels for receiving single signals, channels for monitoring input circuits and produce single signals, constant voltage, bipolar code, etc.

Multifunctional objects of control can be implemented, for example, according to technical solutions in accordance with patents of Ukraine:

- No. 51353 A, cl. F 02C 9/28, "System for automatic control, monitoring and recording parameters of a gas turbine engine";

- No. 46494 A, cl. F 02C 9/28, "System for automatic control, monitoring and recording parameters of a gas turbine engine";

- No. 40478 A, cl. F 02C 9/28 "System for automatic control and monitoring of the parameters of a gas turbine engine."

The present invention is aimed at creating a system that should have enhanced functionality and scope, as well as provide control of multifunctional objects of control and reduce the time spent on their control, which, in turn, will reduce downtime of equipment that uses multifunctional systems for its control .

The aim of the invention is to expand the functionality and scope by providing control of multifunctional objects.

This goal is achieved by the fact that in the known system, which contains a mode control unit, a control and control panel, a unit of controlled simulators of analog sensors connected through a first switch to a meter unit, and a second switch, an additional control code generation unit, a unit of controlled frequency simulators are additionally introduced sensors, a unit for generating and receiving a bipolar code, a unit for controlled simulators of signaling devices, a unit for receiving single signals, a unit for converting direct voltage The control and control panel, through the control code generation unit, is connected to the mode control unit, the unit of controlled simulators of frequency sensors, the unit of controlled simulators of analog sensors and the unit of controlled simulators of signaling devices, the output of which is the output of the system, and through the second switch and the unit for receiving single signal is connected to the control and management panel, the first output of the mode control unit is connected to the unit for generating and receiving a bipolar code, the second switch and ohm of DC voltage conversion, and the second and third outputs of the mode control unit are connected to the control input of the first switch, the second information input of which is connected to the output of the unit of controlled simulators of frequency sensors, the output of the switch is the second output of the system, the second input of the second switch is the first input of the system, and the second input of the system through the DC voltage conversion unit is connected to the input of the control and control panel, the input-output of which through the formation and reception unit and the bipolar code is connected to the input / output of the system, the last output of the meter unit is connected to the DC voltage conversion unit.

Introduction to the system of additional features, namely:

a control code generation unit, a unit of controlled frequency sensor simulators, a unit of controlled simulators of signaling devices, a single signal reception unit, a DC voltage conversion unit, a unit for generating and receiving a bipolar code can expand the functionality, scope and control of multifunctional monitoring objects, which will allow in turn, reduce downtime of equipment that uses multifunctional systems for its control.

As can be seen from the above, the proposed technical solution has significant features that allow you to expand the functionality, scope and provide control of multifunctional objects of control, which will, in turn, reduce downtime of equipment that uses multifunctional systems for its control.

The principle of operation of the system is illustrated by drawings, where figure 1 shows the structural diagram of the system; figure 2 is an example implementation of a block of controlled simulators of frequency sensors.

The system comprises a control and control panel 1, a control code generation unit 2, a mode control unit 3, a unit 4 of controlled frequency sensor simulators, a unit of 5 controlled analog sensor simulators, a unit for generating and receiving a bipolar code 6, a first switch 1, a unit of 8 meters, a unit 9 controlled simulators of sensor-signaling devices, control object 10, single signal receiving unit 11, constant voltage conversion unit 12, second switch 13.

The object 10 of the control is not part of the system.

The remote control 1 includes a calculator 14, a block 15 of a set of commands, a block 16 for displaying messages, a block 17 for outputting information.

Block 4 of controlled simulators of frequency sensors includes a code receiving unit 18, a constant-voltage code converter 19 ... 19n, a constant voltage-frequency converter 20 ... 20n, and a galvanic isolation block 21 ... 21n.

The control and control panel 1 through the control code generation unit 2 is connected to the mode control unit 3, the unit 4 of controlled frequency sensor simulators, the block 5 of controlled analog sensor simulators and the block of 9 controlled sensor-signal simulators, the output (first output of the system) of which is directly connected to the control object 10, and through the second switch 13 and the single signal receiving unit 11 is connected to the control and control panel 1, the first output of the mode control unit 3 is connected to the forming unit 6 and the reception of a bipolar code, by the second switch 13 and the DC voltage conversion unit 12, the second and third outputs of the mode control unit 3 are connected to the control inputs of the switch 1, the information inputs of which are connected to the outputs of the block 4 of controlled frequency sensor simulators and block 5 of controlled analog sensor simulators, and the output (second system output) of the switch 7 is connected to the meter unit 8 and the monitoring object 10, the first output (first system input) of which is connected to the second switch 13, the second output the control object 10 (the second input of the system) through the DC voltage conversion unit 12 is connected to the control and control panel 1, the input-output of which is connected to the input-output (input-output of the system) of the control object 10 through the unit 6 for generating and receiving a bipolar code, the last the output of the meter unit 8 is connected to the DC voltage conversion unit 12.

The code receiving unit 18 of the block 4 of the controlled frequency sensor simulators simulated by the input is connected to the control code generating unit 2, and the output is connected to n channels of series-connected code-constant voltage converters 19, constant-voltage-frequency converters 20 and galvanic isolation blocks 21 of block 4.

The remote control 1 control and management can be performed on the basis of a standard portable laptop computer and a portable printing device.

The control code generation unit 2 and the mode control unit 3 can be performed based on standard processors.

Block 5 of controlled simulators of analog sensors can be performed on the basis of a standard processor and standard converters code-constant voltage, code-resistance, code-alternating voltage and galvanic isolation elements. Block 6 generation and reception of a bipolar code can be performed on the basis of a standard processor and standard shapers and receivers of bipolar voltage.

Switches 7 and 13 can be made on the basis of standard keys with galvanic isolation or electromechanical relays.

Block 8 meters can be performed on the basis of standard processors, standard high-precision elements of microelectronics, for example, on the basis of a technical solution according to the patent of Ukraine No. 40478, cl. F 02C 9/28 "System for automatic control and monitoring of the parameters of a gas turbine engine."

Block 9 of controlled simulators of sensor-signaling devices can be performed on the basis of a standard processor and keys, both electronic and electromechanical.

Block 11 of the reception of single signals can be performed on the basis of standard galvanic isolation elements and a standard processor.

Block 12 DC voltage conversion can be performed on the basis of a standard processor, switch, and analog-to-code converter.

The system operates as follows.

The system provides the following operating modes:

- system self-control mode;

- automatic one-time check mode with fixing the test results on the control panel 1 control and management without stopping if there are failures in the control object 10;

- automatic one-time check mode with fixing the test results on the control and control panel 1 with a stop if there are failures in the control object 10;

- step-by-step operation with a stop after each elementary measurement cycle, etc.

In accordance with the program, which is stored in the memory of the calculator 14 of the console 1, code 2 is issued to block 2, under the action of which block 2 generates address codes for controlling blocks 3, 4, 5 and 9 at its output. In the initial state, outputs 3-1 , 3-2 and 3-3 of the mode control unit 3, the control signals of the switches 7 and 13, the unit 6 for generating and receiving a bipolar code, and the unit 12 for converting the DC voltage are absent.

Before checking the operability of the control object 10, a system self-control is carried out in the following order.

An operator is typed on the block 15 of the set of commands of the console 1, under the action of which a program is launched in the calculator 14 of the console 1, which ensures the issuance by the calculator of 14 code messages to the block 2 of the formation of the control code. Then block 2 generates at its output address informational code parcels, under the influence of which the system goes into self-monitoring mode.

Unit 3 control modes under the action of code parcels from unit 2 generates an output 3-1 signal, which provides the transition:

- block 6 of the formation and reception of a bipolar code in the interactive mode of operation with the transmitter 14 remote 1;

- block 12 into the mode of converting direct voltage from the output of block 8 meters;

- switch 13 to the switching mode of the signals of block 9 of the controlled simulators of sensor-signaling devices to block 11 of the reception of single signals.

At the outputs 3-2, 3-3 of block 3, there are no signals. In this case, the signals of the sensor simulators from the outputs of unit 4 and 5 pass through the switch 7 to the inputs of the unit 8 meters, the signals of the sensor-signaling devices from the output of the unit 9 pass through the switch 13 to the unit 11 for receiving single signals, and the constant voltage from the output of the unit 8 of the meters enters block 12, where it is converted to binary code.

Consider the system during the self-monitoring of the measuring frequency channels of block 8 meters and block 12 DC voltage conversion.

Block 18 receiving code of block 4 selects the code parcels from the output of block 2. The code received by block 18 of block 4 is analyzed and then output to converter 19 (19n), where the code is converted to a predetermined constant voltage value, under which the output of converter 20 (20n) a variable frequency signal is generated. Moreover, the variable code corresponds to the value of the control code, which is stored in the memory of the calculator 14 of the console 1. Further, the frequency signal is fed through the block 21 (21n) of galvanic isolation to the output of block 4 and through the switch 7 is fed to block 8 meters. Block 21 (21n) of block 4 is necessary for galvanic isolation of the system power supply and the supply voltage of the meter 8 and the monitoring object 10, which require its operation conditions. Frequency signals of variable value from the output of block 4 through the switch 7 are fed to the inputs of the frequency meters of block 8. The converters of the frequency measuring channels of block 8 convert the frequency signals of the given value into a binary code proportional to the frequency, which in the corresponding form (serial unipolar or unipolar) comes from the output of the block 8 to the calculator 14 of the console 1.

In addition, the unit 8 meters gives a predetermined constant voltage proportional to the input given frequency signals.

To check the operability of the unit 8 meters and unit 12 converting DC voltage, as described above, at the output of unit 4, a setpoint frequency signal is set, which is fed to block 8 meters, where the setpoint constant voltage is converted to binary code, which is supplied to the unit 12 DC voltage conversion. The binary code proportional to the given input frequency from the output of the DC voltage conversion unit 12 and the meter unit 8 is compared with the specified control code, which is stored in the memory of the calculator 14 of the console 1. If the code from the output of the unit 12 and the output of the meter unit 8 corresponds to the control code of the calculator 14 with a given tolerance, the measuring frequency channel of block 8 and block 12 are operational. And if the value of the binary code from the output of block 12 and block 8 does not correspond to the control code with a given tolerance, then the measuring frequency channel of block 8 or block 12 is faulty and the system needs repair. The results of the self-monitoring of the measuring frequency channels of the unit 8 meters and unit 12 converting DC voltage are recorded in the memory of the calculator 14 and displayed for display on block 16 of the console 1.

After checking the operability of the measuring frequency channels of unit 8 in accordance with the self-monitoring program, the operability of the control channels of the sensor circuit of unit 8 is monitored. The sequence of monitoring the sensor circuits of unit 8 of the frequency meters is carried out in the following order.

According to the commands of the calculator 14 of the console 1, code 2 is sent to block 2, under the action of which block 2 generates address codes at its output, which the mode control block 3 receives. After analyzing the received code, block 3, at its output 3-2, generates signals that disconnect the frequency sensors simulators of block 4 from the frequency inputs of block 8. At the same time, a code message is generated at the output of block 8, for example, in the form of a binary code to calculator 14 of console 1, which indicates a violation of the frequency sensor circuits. The transmitter 14 of the console 1 compares the code message of the block 8 meters with the set code value, which is stored in the memory of the calculator 14 of the console 1, and if it meets the specified code value, then the control channels of the circuit of the frequency sensors of block 8 are working, and if it does not, the control channels circuits of frequency sensors of block 8 are faulty. In this case, the system requires repair.

After checking the operability of the control channel of the circuit of the frequency sensors of block 8, the signals from the output 3-2 of block 3 are removed and the frequency signals from the output of block 4 pass through the switch 7 to the inputs of block 8.

The results of the self-monitoring of the control channels of the circuit of the frequency sensors of block 8 are recorded in the memory of the calculator 14 and displayed for display on block 16 of the console 1.

Consider the system’s self-monitoring of the measuring analog channels of block 8. Block 5 of the controlled simulators of analog sensors selects the code messages from the output of block 2, which provide the output of analog signals of a given value to the output of block 5. The code received by block 5 is analyzed and then issued to its corresponding converters, where the code is converted to a predetermined value of constant voltage, alternating voltage or resistance, which are fed through switch 7 to block 8 meters. Converters of analog measuring channels of block 8 convert the analog signals of a given value into a proportional binary code, which in the appropriate form (serial unipolar or bipolar) comes from the output of block 8 to the transmitter 14 of the console 1.

The binary code proportional to the given analog signal from the output of block 8 is compared with the given code, which is stored in the memory of the calculator 14 of the console 1. If the code from the output of block 8 corresponds to the set value of the code with a given tolerance, then the measuring analog channels of block 8 are operational. And if the value of the binary code from the output of block 8 does not correspond to the set value of the code with a given tolerance, then the measuring analog channels of block 8 are faulty and the system needs repair. The results of the self-monitoring of the measuring analog channels of block 8 are recorded in the memory of the calculator 14 and displayed for display on block 16 of the console 1.

After checking the operability of the measuring analog channels of block 8 according to the self-monitoring program, the operability of the channels of control of the circuits of the analog sensors of block 8 is monitored. The sequence of monitoring the operability of the channels of block 8 of the control circuits of analog sensors is carried out in the following order.

According to the commands of the calculator 14 of the console 1, code 2 is sent to block 2, under the action of which block 2 generates address codes at its output, which the mode control block 3 receives. After analyzing the received code, block 3, at its output 3-3, generates signals that disconnect the simulators of the analog sensors of block 4 from the inputs of block 8. At the same time, a code message is generated at the output of block 8, for example, in the form of a binary code for transmitter 14 of console 1, which indicates a violation of the analog sensor circuits. The transmitter 14 of the console 1 compares the code message of the block 8 with the set value of the code stored in the memory of the calculator 14 of the console 1, and if it meets the specified code value, the control channels of the analog sensors of the block 8 are operational, and if it does not, the control channels of the chains block 8 analog sensors are faulty. In this case, the system requires repair. After checking the operability of the control channels of the circuit of the analog sensors of block 8, the signals from the output 3-3 of block 3 are removed and the analog signals from the output of block 5 pass through the switch 7 to the inputs of block 8.

The results of the self-monitoring of the control channels of the circuit of the analog sensors of block 8 are recorded in the memory of the calculator 14 and displayed for display on block 16 of the console 1.

As mentioned above, the mode control unit 3, under the action of code parcels from block 2, generates a signal 3-1 at the output, which ensures the transition of the unit 6 for generating and receiving a bipolar code to the interactive mode of operation with the calculator 14 of console 1. In this case, the output of the channel for generating a bipolar block 6 code is connected to the input of the receiving channel of the bipolar block 6 code.

According to the self-monitoring program, the transmitter 14 of the console 1 generates code messages to the channel for generating the bipolar code of block 6, the output of which appears a bipolar code of the set value, which is fed to the input of the reception channel of the bipolar code of block 6. From the output of the reception channel of the bipolar code of block 6 to the input of calculator 14 remote control 1 receives a code in a form suitable for reception by the calculator 14. If the received code by the calculator 14 of the remote 1 corresponds to the set value of the code issued by the calculator 14 to the channel for generating a different field Nogo code unit 6, the generating unit 6 and receiving bipolar code serviceable and if not, then the defective unit 6 and the system requires repair.

The results of the self-monitoring of the channels of the unit 6 for generating and receiving a bipolar code are recorded in the memory of the calculator 14 of the console 1 and displayed for display on the block 16 of the console 1.

Further, according to the self-monitoring program, the serviceability of the block 9 of the controlled simulators of the sensor-signaling devices, the switch 13 and the block 11 for receiving single signals is checked.

According to the self-monitoring program, block 9 receives the corresponding code messages from the output of the control code generation block 2 and generates single signals at its output, for example, in the form of a constant voltage, which through the switch 13 enter the block 11 for receiving single signals. Upon receipt of single signals, the block 11 generates at its output code messages that arrive to the transmitter 14 of the console 1, which compares them with a given code value.

If these code values are equal, then the system is working, and if not, then the system is faulty and needs repair.

The results of the self-monitoring of block 9 of controlled simulators of sensor-signaling devices, switch 13 and block 11 for receiving single signals are recorded in the memory of calculator 14 of console 1 and displayed for display on block 16 of console 1.

The results of self-monitoring of the entire system are formed in the form, for example, of a text protocol and are printed by unit 17 of the console 1.

This ends the self-control of the system, which covers all its parts.

After the self-control of the system and if it is in good condition, the health check of the control object 10 is carried out.

Modern objects of control 10 are multifunctional, i.e. they produce various kinds of signals, for example, direct voltage, single signals (one-time commands), a bipolar code, depending on the functioning algorithm and the value of the input signals from the sensor simulators. The signals from the simulators of the sensors simultaneously arrive at the inputs of the object 10 of the control and block 8 meters.

The output code of the frequency and analogue measuring channels of block 8 can correspond, for example, to the specified physical values (revolutions -%, temperature - ° C, pressure - kgf / cm ² , differential pressure - kgf / cm ² , etc.) parameter, and the corresponding values of the input signal, represented by the voltage (V) of direct and alternating current, the frequency (Hz) of the alternating signal, etc. depending on the functioning algorithm of the block of 8 meters.

The output constant voltage of the control object 10 changes in proportion to the change in the input signal from simulators of analog and frequency sensors.

Single output signals (one-time commands) of the control object 10 are issued when the corresponding parameters, both frequency and analog, reach their limit, emergency value. Each issued single signal corresponds, for example, to a given physical value (revolutions -%, temperature - ° С, pressure - kgf / cm ² , pressure drop - kgf / cm ² , etc.) of the parameter, which, in turn, corresponds to the set value of the binary code, which is stored in the memory of the calculator 14 of the remote control 1 control and management.

Therefore, the reference value of the code stored in the memory of the calculator 14 of the console 1 according to the physical representation, is identical to the measured code obtained from the output of the block 8 meters.

So, for example, object 10 produces a single signal at an input frequency of 3000 Hz, which corresponds to the physical value of the engine speed of "103%", which is represented by the set value of the binary code, which, in turn, is entered into the memory of the calculator 14 of the control panel 1 of the control and management.

When a single signal “103%” of the engine speed is received from object 10 to the transmitter 14 of console 1, the transmitter 14 of console 1 from the output of the channel of the same name of the meter unit 8 captures the value of the measured binary code, which corresponds to the physical value of the speed in “%”. This value of the binary code is compared with the control code, which corresponds, for example, to the “103%” revolutions level and is located in the memory of the calculator 14 of the console 1. By the result of the comparison of the codes, the health of the measuring frequency or analog channels of the control object 10 is determined.

The health check of the control object 10 is carried out in the following order.

The operator on block 15 of the set of commands of the console 1 dials a command that will ensure the launch of the program of the calculator 14 to check the operability of the control object 10. In the calculator 14 of the console 1, a program is launched that provides the issuance by the calculator 14 of the code messages to block 2 of the formation of the control code. Then block 2 generates at its output address informational code parcels, under the influence of which the system goes into the mode of checking the operability of the control object 10.

In the initial state, at the outputs 3-1, 3-2 and 3-3 of the mode control unit 3, the control signals of the switches 7 and 13, the unit 6 for generating and receiving a bipolar code, and the unit 12 for converting DC voltage are absent.

In this case, the signals from the outputs of block 4 and 5 through the switch 7 are fed to the inputs of the block 8 meters and the control object 10, the signals from the first output of the control object 10 through the switch 13 are sent to the block 11 for receiving single signals, and the signals from the second output of the control object 10 are received to block 12 converting DC voltage.

Consider the operation of the system for monitoring the measuring frequency channels of object 10. Block 18 receiving code of block 4 selects code parcels from the output of block 2, which ensure the issuance and change of frequency at the output of block 4. The code received by block 18 of block 4 is analyzed and then output to converter 19 ( 19n), where the code is converted to the corresponding constant voltage value, under the action of which a signal of the corresponding frequency is generated at the output of the converter 20 (20n). Next, the frequency signal enters through the block 21 (21n) galvanic isolation to the output of block 4 and through the switch 7 is fed to the block 8 meters and the object 10 of the control. Block 21 (21n) of block 4 is necessary for galvanic isolation of the system power supply and the supply voltage of the meter 8 and the monitoring object 10, which require its operation conditions. Depending on the change in the code received by block 18 of block 4, the frequency signals of the channels, and accordingly of block 4, change. Frequency signals from the output of block 4 through the switch 7 are fed to the inputs of the frequency meters of block 8 and the control object 10. Converters of the frequency measuring channels of block 8 convert the frequency signals into a binary code proportional to the frequency or physical value of the “%” speed, which in the appropriate form (serial unipolar or bipolar) comes from the output of block 8 to the transmitter 14 of console 1.

At the same time, the frequency signals from the output of block 4 are fed to the inputs of the monitoring object 10 to the frequency measuring channels, where the frequency signals are converted into a binary code proportional to them, which is further analyzed, for example, by tolerance control algorithms to ensure the output of single signals from the output of the object 10. Moreover, the output a single signal corresponds to the physical value of the parameter, for example, “%” revolutions.

Single signals through the switch 13 are received by unit 11, which at the same time generates code messages to the transmitter 14 of console 1 at its output. Upon receipt of a message in the code messages of block 11 to the computer 14 of console 1 about the object 10 issuing single signals, the transmitter 14 of console 1 fixes the binary value code from the output of block 8. This value of the binary code is compared with the control code, which is in the memory of the calculator 14 and corresponds to the output of a single signal, and if it corresponds to the control code with the given d start, the issuance of a single frequency channel signal measuring object 10 is correct. This indicates the serviceability of the measuring frequency channel and its correct functioning in generating and outputting a single signal by object 10. And if the value of the binary code from the output of block 8 does not correspond to the control code with a given tolerance, then the measuring frequency channel is faulty and object 10 needs repair. The number of single signals that are issued by the measuring frequency channels of the object 10 depends on the algorithm of its functioning.

In addition, the object 10 produces a constant voltage proportional to the input frequency signals.

To test the operability of the channels of the object 10, which provide a constant voltage proportional to the input frequency signals to the DC voltage converting unit 12, the set value frequency signal is installed at the output of the unit 4, which is also transmitted to the meter unit 8, where it is converted to binary code. The binary code proportional to the given input frequency from the output of the DC voltage conversion unit 12 is compared with the code that comes from the output of the measuring frequency channel of block 8. If the code from the output of block 12 corresponds to the code from the output of the measuring frequency channel of block 8 with a given tolerance, then the measuring the frequency channel of the object 10 is operational. And if the value of the binary code from the output of block 12 does not match the code from the output of the measuring frequency channel of block 8 with a given tolerance, then the measuring frequency channel of object 10 is faulty and requires repair.

Verification of the correct issuance of single signals by the object 10 through the frequency channels can also be controlled by the calculator 14 of the console 1 according to the codes received from the output of block 12 (applies to the frequency channels by which single signals are output) and the codes from the output of the measuring frequency channels of block 8 at the time of receipt of a single signal from the exit of the object 10.

If the code from the output of block 12 at the time of issuing a single signal corresponds to the code from the output of the measuring frequency channel of block 8 with a given tolerance, then the measuring frequency channel of the object 10, through which a single signal was issued, is operational. And if the value of the binary code from the output of block 12 at the time of issuing a single signal does not correspond to the code from the output of the measuring frequency channel of block 8 with a given tolerance, then the measuring frequency channel of object 10 is faulty and requires repair.

After checking the operability of the measuring frequency channels of the object 10 according to the program, the operability of the channels of monitoring the circuits of the sensors of the object 10 is monitored. The sequence of monitoring the channels of the object 10 for monitoring the circuits of the sensors is carried out in the following order.

According to the commands of the calculator 14 of the console 1, code 2 is sent to block 2, under the action of which block 2 generates address codes at its output, which the mode control block 3 receives. After analyzing the received code, block 3 at its output 3-2 generates signals that disconnect the simulators of frequency sensors of block 4 from the inputs of block 8 and object 10. At the same time, a code message is generated at the output of block 8, for example, in the form of a binary code to the transmitter 14 of the console 1, which indicates a violation of the frequency sensor circuits. If the channels of the object 10 for monitoring the circuits of frequency sensors are operational, then from its output through the switch 13 will be issued single signals that are received by block 11, and which, in turn, forms a code message, for example, in the form of a binary code to the transmitter 14 of console 1 , which indicates a violation of the frequency sensor circuits. The transmitter 14 of the console 1 compares the code message of block 11 with the code message of block 8, and if it corresponds to the code value of block 8, then the channel of the object 10 for monitoring the frequency sensor circuits is faulty, and if it does not respond, then the channel of the object 10 for monitoring the frequency sensor chains . In this case, the object 10 requires repair. After checking the operability of the monitoring channel of the frequency sensors of the object 10, the signals from the output 3-2 of block 3 are removed and the frequency signals from the output of block 4 pass through the switch 7 to the inputs of block 8 and object 10.

Consider the operation of the system for monitoring the measuring analog channels of object 10. Block 5 of the controlled simulators of analog sensors selects the code messages from the output of block 2, which provide the generation and change of analog signals at the output of block 5. The code received by block 5 is analyzed and then issued to its corresponding converters, where the code is converted to the corresponding value of constant voltage, alternating voltage or resistance, which are supplied through switch 7 to block 8 meters and object 10. Depending on the change in the code received by block 5, the analog signals of the channels at its output are changed. Analog signals from the output of block 5 through the switch 7 are fed to the inputs of the analog meters of block 8 and the object 10 of the control. Converters of analog measuring channels of block 8 convert the analog signals into a binary code proportional to analog signals, which in the appropriate form (serial unipolar or bipolar) comes from the output of block 8 to the calculator 14 of console 1.

At the same time, the analog signals from the output of block 5 are fed to the inputs of the monitoring object 10 to the analog measuring channels, where the analog signals are converted into a proportional binary code, which is further analyzed, for example, by tolerance control algorithms to ensure the issuance of single, single signals from the output of the object 10. Single the signals from the output of the object 10 through the switch 13 are received by the unit 11, which, at the same time, generates code messages at its output to the transmitter 14 of the console 1. When a message is received in the code the output messages of block 11 to the transmitter 14 of the console 1 about the object issuing 10 single signals, the transmitter 14 of the console 1 captures the value of the binary code from the output of block 8. This value of the binary code is compared with the control code that is stored in the memory of the calculator 14 and corresponds to the generated single signal and if it corresponds to the control code with a given tolerance, then the output of a single signal by the measuring analog channel of the object 10 is correct. This indicates the serviceability of the measuring analog channel and its correct functioning in generating and issuing a single signal by object 10. And if the value of the binary code from the output of block 8 does not correspond to the control code with a given tolerance, then the measuring analog channel is faulty and object 10 needs repair. The number of single signals that are issued by the measuring analog channels of the object 10 depends on the algorithm of its functioning.

In addition, the object 10 produces a constant voltage proportional to the input analog signals.

To check the operability of the channels of the object 10, which provide a constant voltage proportional to the input analog signals, to the DC voltage conversion unit 12, a predetermined analog signal is installed at the output of block 4, which also goes to the meter unit 8, where it is converted to binary code. The binary code proportional to the given analog signal from the output of the DC voltage conversion unit 12 is compared with the code that comes from the output of the measuring analog channel of block 8. If the code from the output of block 12 corresponds to the code from the output of the measuring analog channel of block 8 with a given tolerance, then the measuring the analog channel of object 10 is operational. And if the value of the binary code from the output of block 12 does not correspond to the code from the output of the measuring analog channel of block 8 with a given tolerance, then the measuring analog channel of object 10 is faulty and requires repair.

Verification of the correct issuance of single signals by object 10 through analog channels can also be controlled by calculator 14 of console 1 using codes received from the output of block 12 (applies to analog channels by which single signals are output) and codes from the output of measuring analog channels of block 8 at the moment of arrival of a single signal from the output of the object 10.

If the code from the output of block 12 at the time of issuing a single signal corresponds to the code from the output of the measuring analog channel of block 8 with a given tolerance, then the measuring analog channel of object 10, through which a single signal was issued, is operational. And if the value of the binary code from the output of block 12 at the time of issuing a single signal does not correspond to the code from the output of the measuring analog channel of block 8 with a given tolerance, then the measuring analog channel of object 10 is faulty and requires repair.

After checking the operability of the measuring analog channels of the object 10 according to the program, the operability of the channels of the object 10 is monitored for monitoring the circuits of analog sensors.

The sequence of monitoring the operability of the channels of the object 10 for monitoring the circuits of analog sensors is carried out in the following order.

According to the commands of the calculator 14 of the console 1, code 2 is sent to block 2, under the action of which block 2 generates address codes at its output, which the mode control block 3 receives. After analyzing the received code, block 3 at its output 3-3 generates signals that disconnect the simulators of the analog sensors of block 4 from the inputs of block 8 and object 10. At the same time, a code message is generated at the output of block 8, for example, in the form of a binary code to the transmitter 14 of the remote control 1, which indicates a violation of the analog sensor circuits. If the control channels of the circuit of the analog sensors of the object 10 are operational, then single signals will be generated from its output, which are received through the switch 13 by the block 11, and which, in turn, forms a code message, for example, in the form of a binary code to the transmitter 14 of the console 1, which indicates a violation of the circuits of analog sensors. The transmitter 14 of the console 1 compares the code message of block 11 with the code message of block 8, and if it corresponds to the code value of block 8, then the channel of the object 10 for monitoring the circuits of analog sensors is working, and if it does not answer, the channel of the object 10 for monitoring the circuits of analog sensors is faulty . In this case, the object 10 requires repair.

After checking the operability of the channel for monitoring the circuits of analog sensors, object 10, the signals from the output 3-3 of block 3 are removed and the analog signals from the output of block 5 pass through the switch 7 to the inputs of block 8 and object 10.

In accordance with the control program of the object 10, block 9 receives the corresponding code messages from the output of block 2 of the formation of the control code and generates at its output single signals, for example, in the form of a constant voltage, which arrive before the control object 10. Upon receipt of single signals from block 9 to the control object 10, the latter uses them in tolerance control algorithms when generating single signals from frequency and analog input signals and issues single signals through switch 13 to block 11 for receiving single signals.

In this case, the block 11 generates at its output code parcels to the transmitter 14 of the console 1. When a message is received in the code parcels of the block 11 to the calculator 14 of the console 1 about the object giving 10 single signals, the calculator 14 of the console 1 compares it with the control code that is stored in its memory , which, in turn, ensured the formation of the command by block 2 to block 9, and if it corresponds to the control code, then the output of a single signal by the measuring analog or frequency channel of object 10 is correct. This indicates the serviceability of the channel for receiving single signals of object 10. And if the value of the binary code from the output of block 11 does not correspond to the control code, then the channel for receiving single signals is faulty and object 10 needs repair. The number of single signals that are issued by the measuring analog or frequency channel of the object 10 in the presence of single signals from the output of block 9 at its input depends on the algorithm of functioning of the object 10.

In accordance with the program for monitoring the object 10, the transmitter 14 of the console 1 generates code messages to the channel for generating the bipolar code of block 6, the output of which appears a bipolar code of the set value, which is fed to the input of the channel for receiving the bipolar code of object 10. algorithm, and the analysis result in the form of a given code value gives a bipolar code to the reception channel of the bipolar code of block 6. From the output of the reception channel of the bipolar code of block 6 to the input d of the calculator 14 of the console 1 receives a code in a form suitable for reception by the calculator 14. If the received code by the calculator 14 of the console 1 corresponds to the set value of the code that is stored in the memory of the calculator 14 of the console 1, then the channel for receiving and generating a bipolar code of object 10 is operational, and if no, then the object 10 needs repair.

The results of the health check of the object 10 are recorded in the memory of the calculator 14 of the console 1, displayed on the block 16 for display and printed, for example, in the form of text protocols block 17.

The present invention allows to expand the functionality and scope, as well as provide a test of the operability of multifunctional objects of control, which, in turn, will reduce downtime of equipment, for example, an aircraft that uses multifunctional systems for its control.

In addition, the system provides self-control of all its elements, which allows, in turn, to ensure high reliability of the results of the control of the object 10.

Claims (1)

A system for monitoring the parameters of multifunctional systems, which contains a mode control unit, a control and control panel, a unit of controlled simulators of analog sensors connected through a first switch to a meter unit and a first system output, and a second switch, which is characterized in that a code generation unit is additionally introduced into the system control unit, a unit of controlled simulators of frequency sensors, a unit for generating and receiving a bipolar code, a unit of controlled simulators of sensor-signaling devices, a unit for receiving of foreign signals, a DC-voltage conversion unit, a control and control panel through a control code generation unit is connected to a mode control unit, a unit of controlled frequency sensor simulators, a unit of controlled analog sensor simulators and a unit of controlled sensor-signal simulators, the output of which is the second output of the system, and through the second switch and the unit for receiving single signals connected to the control panel, the first output of the mode control unit is connected to the unit the second switch and the DC voltage conversion unit, and the second and third outputs of the mode control unit are connected to the control inputs of the first switch, the second information input of which is connected to the output of the unit of controlled frequency sensor simulators, the first input of the system is connected to the second switch, and the second input of the system through the DC voltage conversion unit is connected to the input of the control and control panel, the input-output of which through the formation unit and iema bipolar code, connected to the input-output system, the first output of block gauges connected to monitoring and control, and the other - with the unit conversion constant voltage.

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