RU2537799C2 - Method of maintenance of complex technical systems and automated control system for its implementation - Google Patents

Abstract

FIELD: measurement technology.

SUBSTANCE: in addition to the formation of initiating actions and control of the object response in the additional sessions the power supply system of the object is controlled. For implementing the method the control system comprises a block of measuring currents, the additional communications in the object of control and in the control system, providing control of integrity of power supply system circuits of the object of control and the parameters of its power sources.

EFFECT: expansion of completeness of control of the control object.

2 cl, 1 dwg

Description

The invention relates to the field of maintenance of complex technical systems, including weapons systems and military equipment.

A known system for the automatic control of electronic circuit parameters according to copyright certificate No. 985764, G05В 23/02, SU.

The specified system implements a method of servicing technical systems, in which the control computer generates test combinations about the value of the stimulating signal, and the pin number to which the measuring unit is connected is entered into the pin switch through the register of test combinations. The measuring unit at a time interval necessary for measurement, gives the code of the measured parameter to the analysis unit. The analysis unit assesses the conformity of the measured controlled parameter to the permissible value and provides information to the control computer. In this way, control objects are controlled.

The disadvantage of this method is the limited control capabilities of a complex technical system.

Closest to the claimed method is a method implemented in an automated control system set forth in the description of patent RU 2248028 (G05B 23/02), taken as a prototype.

In the indicated automated control system, the controlled signals from the control object are fed through the matching unit and the signal distribution unit to the measuring unit, where they are converted into a code. The received code is transmitted through the interface unit and the control unit to the evaluation unit, where it is determined to be within the tolerance, as well as the magnitude and sign of the deviation of the parameter code from the tolerance limits and the parameter is evaluated as “Good”, “Not Good”. The parameter estimate is stored in the memory unit.

To implement this method of servicing complex technical systems in an automated control system, the control inputs required for test actions under the control program, inputs for supply voltages required under the control program for external supply of supply voltages to the control object, as well as the controlled outputs of the control object are connected through blocks coordination, signal distribution unit, input and output signal switch with test actions unit, power supply unit and measuring unit com, respectively. The block of test actions and the block of power sources according to the control data coming through the interface unit from the control block, in accordance with the control program, form the necessary test actions and supply voltages at the inputs of the control object, respectively. The supply of external supply voltages to the corresponding inputs of the control object is used to save the resource of power sources of the components of the control object.

However, this known known method of servicing complex technical systems in an automated control system also has disadvantages.

Firstly, to check the control object, the control object is supplied with power from external power sources. The supply of external supply voltages to the corresponding inputs of the control object is used to save the resource of power sources - components of the control object. However, in some cases, the power supply busbars of the components of the control object from external power supplies are not completely identical to the busbars from the built-in power supply system and possible malfunctions that are not detected when power is supplied from external power sources.

Secondly, the use of external power sources for the control object does not allow checking the proper functioning of their own power sources (built-in power supply system of the control object).

Thirdly, parametric failures in the power supply system of the control object are possible, for example, incorrect connections in the power supply buses, electrical insulation failures, and others that cannot be detected by simply connecting external sources and then checking the functioning of the components of the control object. Such failures can be manifested by increased energy consumption (increased current consumption from power sources). For a number of objects of control, this can lead to a premature loss of life of the built-in power supply system (for example, batteries of rocket technology) and unforeseen consequences that appear only after some time of operation of the object of control.

The aim of the proposed method of maintenance is to increase the completeness of control of complex technical systems.

The goal is achieved by dividing the control program into control sessions, using the additional outputs that connect to the power buses of the integrated power supply systems, conducting an additional monitoring session with the supply of normalized currents from external power sources, during which the created in the voltage supply busbars and the corresponding insulation resistance of the power supply busbars and in one of the monitoring sessions, the supply voltage from the external x sources, additionally provide initiating actions for switching on the monitoring object’s power system for a session, switch the signals from the power system outputs, convert them into a code, evaluate the code value at the time specified by the control program and store the evaluation results for subsequent analysis over the entire set of power system outputs object of control.

The drawing shows a structural diagram of an automated control system for implementing the proposed method of servicing complex technical systems, where:

1 - object of control;

2 - components of the object of control;

3 - built-in power supply system of the control object; the first outputs of the control object (from components 2);

5 - inputs of the control object (for supplying initiating influences and supply voltages from external sources);

6 - second outputs of the control object (from the power supply bus of the integrated power supply system 3);

7 - block interface with the inputs and outputs of the control object;

8 - block matching signals;

9 - switch input and output signals;

10 - power supply unit;

11 - block test effects;

12 - block measuring currents;

13 - measuring unit;

14 - interface unit;

15 - program blocks of control sessions;

16 - control unit;

17 - block call programs control sessions;

18 - the first block of memory;

19 - block storage programs control session;

20 - evaluation unit;

21 is the second block of memory.

An automated control system for implementing the proposed method of servicing complex technical systems works as follows.

The control object 1 contains components 2, including an integrated power supply system 3. For monitoring the state during maintenance, the first outputs 4 of the control object 1 are connected to the outputs of the individual components 2, the second outputs 6 are connected to the output buses of the power supply 3, for supply during maintenance of the initiating testing actions and supply voltages from external power sources, the inputs 5 of the control object are connected to the control inputs of the individual components 2, with control inputs hydrochloric power supply 3 and a power supply circuit 1 controls the object (its components 2) from the external power source. The inputs and outputs of the control object 1 are connected using the interface unit with the inputs and outputs of the control object 7 with the corresponding inputs and outputs of the signal matching unit 8. Using the call program block of the control session 17, control programs corresponding to the session are set and from the program control program storage unit 19 are entered through the control unit 16 to the first memory unit 18. After starting the program, the control unit 16 through the interface unit 14 in accordance with the program of the monitoring session transmits the necessary control data to the unit power supplies 10, a block of test actions 11, a block of measuring currents 12, a measuring block 13, a switch of input and output signals 9. A block of power supplies 10, a block of measuring currents 12 form the necessary supply voltages according to the control data supplied to them (or, in in accordance with the monitoring session, they do not generate supply voltage, or in accordance with the monitoring session, normalized currents are provided to provide an assessment of the insulation resistance of the object’s power supply busbars), which, as well as test initiating effects, f rmiruemye unit test inputs 11, through the switch input and output signals are supplied to unit 9 matching signals 8.

Block matching signals 8 provides parametric matching signals with actuators of the control object. It may contain normalizing amplifiers of signals coming from the control object and keys and signal amplifiers for actuators of the control object. Received from the switch input and output signals 9 (from the block of test actions 11) and the signals of the block of power supplies 10 and the block of measuring currents 12 are fed to the outputs for supply through the connected block to the inputs and outputs of the control object 7 to the control object 1.

The interface unit 7 provides a mechanical and electrical connection with the control circuits and control of the control object.

Controlled signals from the object of control 1, namely, signals from components 2 (from outputs 4) and potentials from the power supply bus of the integrated power supply system 3 (from outputs 6), through the interface unit with the inputs and outputs of the control object 7, are fed to the inputs of the block of signal matching 8 , which transmits through the switch input and output signals 9 to the measuring unit 13, which provides the conversion of the parameters of the input signals into code. The results of the conversion of the parameters from the measuring unit 13 are fed through the interface unit 14 and the control unit 16 to the evaluation unit 20 of the program block control sessions 15.

In block evaluation 20 produced:

assessment of the results of the parameter transformations to be within the tolerance at various points in time of the monitoring session (in the conditions of supplying voltage from external power sources, from block 10);

- assessment of compliance (discrepancy) with the required values of insulation busbars of the power supply from the integrated power supply system 3 of facility 1 (in one of the additional control sessions under conditions when the power supply voltage from unit 10 is not supplied, but normalized values of load currents from the unit of measuring currents are supplied 12);

- assessment of compliance (inconsistency) with the required values of the supply voltages generated by the power supply system 3 of facility 1 (in one of the final control sessions under the conditions of the corresponding initiating effect on the inclusion of the built-in power supply system during the specified session).

Data from the evaluation units 20 is stored in the second memory unit 21, transmitted to the control unit 16 and also stored in the first memory unit 18, in which a generalized assessment of the state of the control object 1 is formed, according to the estimates of the data of all control sessions implemented by the automated control system.

As in the well-known methods of maintenance of complex technical systems, the proposed method and an automated control system for its implementation allows you to control the correct response of the components of a complex technical system to the totality of the initiating effects of the respective control programs (through the use and evaluation of 20 data converted into codes with components 2).

The expansion of the completeness of control of the control object is achieved as follows.

Using and evaluating in the evaluation unit 20 additional data on the insulation resistance of the power supply busbars and data on the magnitude of the supply voltage from the built-in power supply system 3 (when the built-in power supply system is turned on for a short time in one of the final control sessions) allows:

- identify and diagnose errors in the connection of the power supply busbars of the control object;

- identify and diagnose violations in the components of the control object, leading to unforeseen increased resource consumption of the built-in power supply system;

- identify and diagnose violations of insulation of power supply busbars of the control object;

- identify and diagnose failures of the components of the built-in power supply system (for example, failures or inconsistencies with the requirements of batteries, converters and other components of the built-in power supply system).

The supply of the corresponding initiating effect on the inclusion of a separate monitoring session of the power supply system of the control object, the use and evaluation of 20 converted data from the power circuits of the control object in the evaluation unit 20 allows to identify and diagnose failures in the control of the power supply system of the control object.

An additional effect of using the proposed method of maintenance of complex technical systems and an automated control system for its implementation is that increasing the completeness of control during maintenance significantly reduces the risk of premature shutdown of complex technical systems due to malfunctions in the built-in power supply system and in other components of the facility control (for example, leading to an unforeseen consumption of power system resources), the risk of emergencies due to untimely identified malfunctions in the control object, reduces the average amount of losses during their subsequent operation.

Information sources

1. "System for the automatic control of electronic circuit parameters", copyright certificate No. 985764 ((G05B 23/02 RU) G05B 23/02 SU)

2. "Automated control system", patent No. 2248028.

Claims (2)

1. A method of servicing complex technical systems, in which test actions are generated and sent to the corresponding inputs of the control object according to the control program, they are formed and sent to the corresponding inputs of the control object of the supply voltage from external power sources, signals from the corresponding outputs of the control object are controlled, for which they commute signals from individual outputs, convert them into code, evaluate the value of the code at a time specified by the control program, and store the results of the evaluation as a whole in the outputs of the control object, characterized in that the control program is divided into control sessions, the outputs of the control object use additional outputs that are connected to the power buses of the integrated power supply system, conduct an additional control session with the supply of normalized currents from external power sources, during which evaluate the voltages created in the supply buses and the corresponding insulation resistances of the supply buses and do not apply voltage in one of the control sessions power supply from external sources, additionally initiating actions are applied to turn on the monitoring object’s power system during a session, switch the signals from the power system outputs, convert them into a code, evaluate the code value at a time set by the control program and store the evaluation results for subsequent analysis in the whole set outputs of the power supply system of the control object. 2. An automated control system for implementing the method according to claim 1, containing an object of control, which includes components and an integrated power supply system, a control unit, the first input and output of which are connected to the output and input of the first memory unit, and the second input and output - respectively, to the first outputs and input of the interface unit, the second input and output of which are connected respectively to the control outputs and inputs of the power supply unit, the unit of test actions, the measuring unit and the input and output switch with Ignalov, the first signal output of the input and output switch is connected to the signal input of the measuring unit, the matching unit, N blocks of programs of the control sessions, each of which contains an evaluation unit, a second memory block, and a call block of control programs, the input and output connected respectively to the third the output and the input of the control unit, which (3 + i) -mi (where i is the number of the program block of the control session) inputs and outputs are connected respectively to the first outputs and inputs of the storage blocks of the program of the control sessions, a (3 + m + i) -mi ( de m is the number of program session control blocks) inputs and outputs, respectively, to the first outputs and inputs of evaluation units, the second inputs and outputs of which are connected respectively to the outputs and inputs of the second memory blocks, characterized in that the signal matching unit is the first, second inputs and the first output connected respectively to the second, third signal outputs and the first signal input of the switch input and output signals, and the second outputs and third inputs, respectively, to the first inputs and first outputs of the block connections with the inputs and outputs of the control object, the second inputs and second outputs of which are connected respectively to the first outputs and inputs of the control object, the signal outputs of the power supply unit and the test action unit are connected to the fourth and fifth inputs of the matching unit, and the power supply bus of the control object is connected with the second outputs of the control object, which are connected to the third inputs of the interface unit with the inputs and outputs of the control object, the third outputs of which are connected to the sixth inputs of the block signals, and with the second signal inputs of the input and output signals switch are connected the outputs of the measuring currents block, the control inputs and outputs of which are connected to the second outputs and inputs of the interface unit.