RU2290761C1 - Method for checking automated controlling and monitoring equipment - Google Patents

Abstract

FIELD: technology for checking controlling equipment.

SUBSTANCE: method includes checking completeness, external integrity of blocks, presence of dents on cases and sockets, checking external condition of harnesses, in particular, integrity of isolation and sockets. After that output and input sockets of each one of control blocks of energy and information circuits of automated controlling equipment are connected. Commands are generated and sent to dispense certain control signal. Time interval is set during which control signal is dispensed. Voltage is measured at output of aforementioned control block as well as time interval, during which voltage is generated. Voltage fed onto input socket of aforementioned control block is measured as well as time interval during which voltage is received. Measured values of voltages and times are compared to given values. Same order of actions is repeated for other controlling signals.

EFFECT: increased quality of serviceability control of controlling and monitoring equipment.

Description

The invention relates to the field of testing and control of electrical systems and control circuits, and can be used to test the performance of automated cocktail test equipment, consisting of a control and monitoring unit (PC) and several control units for energy and information circuits.

Known, chosen as the closest analogue, is a method for diagnosing and repairing a gas turbine propulsion system operating on liquid fuel, which consists in the fact that it checks the completeness, external condition of electrical equipment, checks the external condition of the harnesses for the integrity of the insulation and connectors (RF Patent No. 2173451 , class G 01 M 15/00, published on September 10, 2001, Bull. No. 25).

The disadvantage of this method is that it does not check the correctness and accuracy of automated test equipment designed to control the energy and information circuits of multi-channel communication systems.

The technical task of the proposed method is to improve the quality control of the operability of test equipment.

This object is achieved by the fact that in the method of checking automated test equipment, which consists in the fact that it checks for completeness, checks the external state of the blocks for integrity and dents of the housings and connectors, checks the external state of the harnesses for the integrity of the insulation and connectors, connect the output connector to the input, form and give a command to issue a test voltage, set the time interval during which it is issued, measure the output voltage control and testing equipment, receive and measure the voltage on the automated control and testing equipment and compare it with the voltage measured at the output, also compare the time intervals for issuing the test voltage specified and actual, set the load resistance between the input and output connectors, form and send a command to the issuance of a control signal with a given current strength, for a given time interval, measure the voltage at the output of the test equipment for the load sensing resistance, calculate the resistance value, receive a control signal on automated test equipment, measure the voltage and calculate the resistance value, compare the obtained resistance values with the value of the load resistance, also compare the time intervals for the output of the control signal, the set and actual form and issue a command for issuing voltage variable in value from 0 V to 6 V for 12 s and from 6 V to 0 V for 12 s, measure the output voltage to on-test equipment and the time of its change, take and measure the voltage and time of its change on the automated test equipment, compare the set voltage and its change in time with the measured at the output of the test equipment and the voltage measured by the test equipment itself and their change in time, form and send a command to issue a voltage that varies from 0 V to 1 V for 1 s, output a voltage of 1 V for 1 s and the subsequent change in Other voltages from 1 V to 0 V for 1 s, measure the voltage at the output of the test equipment and the time of its change, take and measure the voltage and time of its change on the automated test equipment, compare the set voltage and its change in time with the voltages measured at the output of the test equipment and measured by the test equipment itself and their time variation, a command is generated and sent to issue an AC control signal with times personal frequencies, measure the voltage and frequency at the output of the test equipment, receive and measure the voltage and frequency at the automated test equipment and compare them with the specified voltages and frequencies and measured at the output.

The proposed method is implemented as follows.

At the initial stage of the check, the completeness of the automated test equipment is checked, the external state of the blocks is examined for their integrity, and dents are present on the cases and connectors. Damaged blocks and connectors are sent for repair. Next, check the external condition of the harnesses for the integrity of the insulation and connectors. Places of damage to the insulation are repaired, removable damage to the connectors is repaired. If damage to the connectors is not repairable, they are sent for recycling.

At the second stage, the output and input of one of the control units of the energy and information circuits of automated test equipment (for example, ACPA according to the RF patent for invention No. 2250565) are connected to each other, connecting the output connector to the input using any known device (for example, jumpers or plugs), in which bends are provided, ending with sockets for connecting measuring instruments (for example, a voltmeter, oscilloscope, etc.).

Then the measuring device is connected, as a rule, this device is an oscilloscope, but it can also be a voltmeter connected to an electronic stopwatch to a device connecting the output connector to the input. Using the control and monitoring unit, which can be used as a personal computer, a command is generated and supplied with a voltage of 0.01 V (the command is sent to the output shaper of the control unit for energy and information circuits. In this case, the output shapers have an output resistance of 100 MΩ - 500 megohms) and set the time interval (any, for example 5 s) during which a voltage of 0.01 V is output. Using a measuring device connected to a jumper connecting the output and input connectors of the e energetic and information circuits of automated test equipment, measure the voltage at the output (jumper) and the time interval during which a voltage of 0.01 V is output. Using a voltmeter included in the power and information circuit control unit of the automated test equipment, An electronic stopwatch measures the voltage supplied to the input connector and the time interval during which this voltage has been supplied. The numerical value of this voltage and the time interval during which it was received are displayed on the display of the control and monitoring unit. Then, the set voltage value and the time during which it was issued are compared, the readings of the measuring device connected to the jumper connecting the output and input connectors of the power and information circuit control unit of the automated test equipment, and the numerical voltage value and time displayed which it came in. The three voltage values should not have a difference of more than 30 mV, and the time intervals should not deviate from the set by more than 10%.

Further, with the help of the control and control unit, commands are issued and issued to issue a voltage of 0.3 V, 6.3 V, 27 V, 115 V for any given time intervals. In this case, the verification of automated test equipment is carried out in the same way as when forming and issuing a command for the output of a voltage of 0.01 V, and the difference in voltage values should not exceed the following values:

- for 0.3 V - 30 mV,

- for 6.3 V - 0.6 V,

- for 27 V - 2.5 V,

- for 115 V -11.5 V.

Moreover, the time intervals should not deviate from the set by more than 10%.

If during the verification it is revealed that the discrepancies between the numerical values of the voltages exceed the permissible ones or the time intervals deviate from the set by more than 10%, then the verified unit for monitoring the energy and information circuits of the automated control and testing equipment is deemed unsuitable for further operation.

If during the verification it is revealed that the discrepancies between the numerical values of the voltages do not exceed the permissible ones or the time intervals deviate from the set by no more than 10%, then the checked unit for monitoring the energy and information circuits of the automated control and testing equipment is subjected to further verification.

In the third stage, between the jumper and the output connector set the load resistance (in the form of a resistor or rheostat). The initial value of the load resistance should correspond to 5 kOhm.

Using the control and monitoring unit, a command is generated and sent to issue a control signal with any possible specified current (the command is sent to the output driver of the control unit for energy and information circuits), a time interval is set (any, for example, 5 s), during which give this control signal. Using a measuring device connected to a jumper connecting the output and input connectors of the control unit for energy and information circuits of automated test equipment, measure the voltage across the jumper, for load resistance, and the time interval during which a control signal with a given current . Using the voltmeter and electronic stopwatch included in the energy and information circuit control unit of the automated test equipment, the voltage applied to the input connector and the time interval during which this voltage is supplied are measured. Then, the obtained voltage value is divided by a predetermined current value, obtaining the resistance value. The numerical value of this resistance and the time interval during which the control signal was received are displayed on the display of the control and control unit. The numerical value of the load resistance installed between the jumper and the output connector is compared with the value of the resistance obtained as a result of the calculation, as well as the time intervals specified and the one during which the control signal is issued. Resistance values should not have a discrepancy of more than 0.5 kOhm, and time intervals should not deviate from the set by 10%.

Next, between the jumper and the output connector, load resistances of 10 kΩ and 14 kΩ are set. In this case, the verification of automated test equipment is carried out in the same way as when the load resistance was set to 5 kOhm, and the discrepancy between the resistance values should not exceed the following values:

- for 10 kOhm - 1 kOhm,

- for 14 kOhm - 1.4 kOhm.

Moreover, the time intervals should not deviate from the set by more than 10%.

If during the verification it is revealed that the discrepancies between the numerical values of the resistances exceed the permissible ones or the time intervals deviate from the set by more than 10%, then the tested unit for monitoring the energy and information circuits of the automated control and testing equipment is considered unsuitable for further operation.

If during the verification it is revealed that the discrepancies between the numerical values of the resistance do not exceed the permissible ones or the time intervals deviate from the set by no more than 10%, then the tested unit for monitoring the energy and information circuits of the automated control and testing equipment is subjected to further verification.

At the fourth stage of the test, the load resistance between the jumper and the output connector is disconnected from the jumper (connect the jumper to the output connector). Using the control and monitoring unit, a command is generated and sent to issue a voltage that varies in value from 0 V to 6 V for 12 s and from 6 V to 0 V for 12 s ("symmetrical saw"). Using a measuring device that measures the magnitude of the voltage, measure the voltage on the jumper and the time of its change. The voltage received through the input connector of the energy and information circuit control unit of the automated test equipment is measured using the voltmeter included in it and the voltage change time using the time meter included in its composition (for example, an electronic stopwatch) and displayed on the control and monitoring unit numerical value of voltage and time of its change. Then, the set voltage and its time variation are compared, the readings of the voltage measuring device connected to the jumper connecting the output and input connectors of the energy and information control unit of the automated test equipment and the displayed numerical value of the voltage received through the input connector of the control unit energy and information circuits of automated test equipment and its change in time. The voltage values should not have a difference of more than 30 mV, and the times of voltage changes should not have a difference of more than 0.2 s.

Then, using the control unit, a command is generated and sent to issue a voltage that varies from 0 V to 1 V for 1 s, output a voltage of 1 V for 1 s, and then change the voltage from 1 V to 0 V for 1 s . At the same time, the verification of the control unit of the energy and information circuits of the automated test equipment is carried out in the same way as in the option of forming and issuing a command to issue a voltage of variable value from 0 V to 6 V for 12 s and from 6 V to 0 V for 12 s (meander). In this case, the voltage values should not have a difference of more than 0.1 V, and the times of voltage changes should not have a difference of more than 0.01 s.

If during the verification it is revealed that the discrepancies between the three readings of the voltage or time at any voltage exceed the permissible, then this control unit of the energy and information circuits of the automated test equipment is considered unsuitable for further operation.

Then form and submit a command to issue alternating current signals with an amplitude of 50 V and a frequency of 10 kHz. Using a measuring device that measures the magnitude of the voltage (in this case, it is most appropriate to use an oscilloscope), measure the magnitude of the voltage and frequency on the jumper. The voltage and frequency obtained through the input connector of the energy and information circuit control unit of the automated test equipment are measured. The numerical value of this voltage and frequency is displayed on the display of the control and monitoring unit. Then, the set value of the voltage and frequency, the readings of the measuring device connected to the jumper connecting the output and input connectors of the control unit of the energy and information circuits of the automated test equipment are compared, and the numerical value of the voltage and frequency displayed. Three values of voltages and frequencies should not have a discrepancy of more than 0.25%. Then, without changing the amplitude, the frequency of the AC signals is changed to the following values:

- 12.5 kHz

- 100 kHz

- 250 kHz.

In this case, the frequency differences should not exceed 0.25%.

Then, using the control and monitoring unit, they form and send commands for issuing AC signals with amplitudes of 5 V, 2.5 V, 1 V, 500 mV, 250 mV, 100 mV, 50 mV, 25 mV. In this case, the verification of automated test equipment is carried out in the same way as when generating alternating current signals with an amplitude of 50 V.

In this case, the discrepancy between the voltage values should not exceed the following values:

- for 5 V - 0.1%

- for 2.5 V - 0.1%,

- for 1 V - 0.1%,

- for 500 mV - 0.1%,

- for 250 mV - 0.1%,

- for 100 mV - 0.1%,

- for 50 mV - 0.1%,

- for 25 mV - 0.1%.

Moreover, the time intervals should not deviate from the set by more than 10%.

If during the verification it is revealed that the discrepancies between the numerical values of the voltages exceed the permissible ones or the frequencies deviate from more than 0.25%, then the checked unit for monitoring the energy and information circuits of the automated control and testing equipment is deemed unsuitable for further operation.

If during the verification it is revealed that the discrepancies between the three voltage readings or frequencies at any voltage do not exceed the permissible ones, then this control unit for the energy and information circuits of the automated test equipment is considered suitable for further operation.

Voltage values of 0.01 V, 0.3 V, 6.3 V, 27 V, 115 V and resistance values of 5 kOhm, 10 kOhm and 14 kOhm, as well as impulse signals of the "symmetrical saw" and "meander" types are the most common operating parameters in the operation of electrical systems and control circuits of aircraft. Thus, due to the fact that when checking automated test equipment, tight control of the issuance and reception of control signals with the main operating parameters is increased, the quality of the performance monitoring of automated test equipment is improved.

Claims (1)

A method for checking automated test equipment, namely, that it checks for completeness, checks the external state of the blocks for integrity and dents of housings and connectors, checks the external state of the harnesses for the integrity of insulation and connectors, characterized in that they are connected output and input connectors of one of the control units of energy and information circuits of automated test equipment, form and send a command for issuing a test full-time voltage, set the time interval during which it is issued, measure the voltage at the output of the specified control unit and the time interval during which the voltage is supplied, using the voltmeter and electronic stopwatch included in the specified control unit, measure the voltage supplied to the input terminal of the specified of the control unit, and the time interval during which this voltage was supplied, compare the set value of the voltage and the time during which it was issued, the readings of the measuring device and, connected to the jumper connecting the output and input connectors of the specified control unit, and the numerical value of the voltage displayed on the display of the specified control unit and the time during which it arrived, set the load resistance between the jumper and the output connector, form and issue a command for issuing the control signal with a given current strength for a given time interval, measure the voltage at the output of the specified block of resistance control and the time interval during which o give a control signal with a given current strength, calculate the resistance value, take a control signal at the input connector of the specified control unit, measure the voltage and the time interval during which this voltage has been received, calculate the resistance value, compare the obtained resistance values with the value of the load resistance, also compare the time intervals for the issuance of the control signal, the set and the actual, form and send a command to issue a voltage, variable in value from 0 V to 6 V for 12 s and from 6 V to 0 V for 12 s, measure the voltage at the output of the specified control unit and the time of its change, measure the voltage received and received through the input connector of the specified control unit and the time of its change, compare the set voltage and its change by time with the voltage measured at the output of the specified control unit, and the voltage received through the input connector of the specified control unit, and their change in time, form and send a command to issue a voltage that varies in value from 0 V to 1 V for 1 s, the output voltage of 1 V for 1 s and the subsequent change in voltage from 1 V to 0 V for 1 s, measure the voltage at the output of the specified control unit and the time of its change, measure the voltage received through the input connector of the specified control unit and the time of its change, compare the set voltage and its change in time with the voltage measured at the output of the specified control unit, and the voltage received through the input connector of the specified control unit, and their change in time, form and submit command to issue an AC control signal with different frequencies, measure the voltage and frequency at the output of the specified control unit, measure the voltage and frequency received through the input connector of the specified control unit and compare them with the specified voltage and frequency, and measured at the output of the specified control unit.