KR102293122B1 - Test method for relay performance using relay performance test device. - Google Patents

Abstract

The present invention relates to a method for testing relay performance using a relay performance tester. The method for testing relay performance using a relay performance tester in accordance with one embodiment of the present invention comprises: turning on a relay connected to a relay unit and applying a test signal generated from a measurement signal generating unit to the relay to measure, with a process unit, a minimum operating voltage and a coil resistance of the relay; opening the test signal being applied from the measurement signal generating unit by turning off the relay connected to the relay unit to measure a maximum recovery voltage of the relay; measuring, with the process unit, an operation time and a return time of the relay by repeatedly turning on and off, with the measurement signal generating unit, the operating voltage of the relay; measuring a contact resistance at each contact when the relay applies the operating voltage and contact resistance at each contact when the operating voltage is opened, respectively; measuring chattering when each contact of the relay is in contact; and transmitting result data measured in the relay performance tester to an operation unit.

Description

Relay performance test method using relay performance test device {Test method for relay performance using relay performance test device.}

The present invention relates to a relay performance test method using a relay performance test device. More specifically, it relates to a relay performance test method using a relay performance test device for testing the performance of a relay.

In general, relays are electrically controlled to convert electrical energy into mechanical energy by means of electromagnetic, electrostatic, thermal, electrical distortion, and other effects. It is a device, which operates the interlocking mechanism by mechanical energy to operate the contact that controls the electric circuit, and is also called a relay.

There are various types of these relays, and in order to distinguish them, prefixes indicating their operation, mechanism (structure), use, etc. are added, and AC relay, antenna relay, homing relay, differential relay, delay relay , electromagnetic relay, solenoid relay, telephone relay, low voltage relay, distance relay, etc.

In addition, the structure of the electronic relay consists of an excitation coil that generates magnetic force by receiving power, and a switch part whose contact is closed or opened when the excitation coil is magnetized. In some cases, the number of is two or more, and the state of the contacts is opposite to each other while operating at the same time, that is, one is a contact and the other is b contact.

By controlling the excitation coil with a small current using a relay having such a structure, a large current passing through the contact is interrupted.

Such relays are used in various electrical control devices including voltage regulators installed in power plants or transmission relay bases. The electrical characteristic value of such a relay, especially the resistance value, directly affects the voltage value of the output current controlled by the voltage regulator. It should be kept as set. However, the resistance of the contact changes over time due to oxidation or corrosion. Therefore, in order to provide high-quality service to consumers, it is necessary to periodically check the resistance of the contact point of the relay.

Conventionally, the check of the contact point of such a relay has been manually performed by a facility manager of a power plant or a transmission relay base. However, such manual inspection is not only very cumbersome and time-consuming, but also varies the position and strength of contacting the input/output terminals of the testing machine with the relay contact points at each measurement, even for each individual checking or the same person. A problem of obtaining different measurement values for each time occurred, and in order to solve this problem, (Patent Document 1) is supplemented.

(Patent Document 1) relates to a multi-relay inspection device. According to this, a relay socket unit provided with a plurality of relay sockets to which a relay to be measured can be connected, and a relay socket unit connected to the coil resistance, contact resistance, contact It includes a main test unit for testing time, operation, and return voltage, a database including a database for storing test-completed data in the main test, and a barcode reader for identifying types of relays.

However, in the aforementioned (Patent Document 1), the relay's coil resistance, contact resistance, contact time, operation, and return voltage were tested, but by performing the test in the case of the maximum voltage or the minimum voltage, the correct test value of the relay This could not be calculated, and there is a problem in that the error range is rather wide.

Republic of Korea Patent Publication No. 10-0783136

It is an object of the present invention to provide a relay performance test method using a relay performance test apparatus for testing the performance of a relay and minimizing a test error.

In order to solve the above problem,

In a relay performance test method using a relay performance test apparatus including a relay unit, a measurement signal generator, a process unit, and an operation unit according to an embodiment of the present invention,

(a) turning on the relay connected to the relay unit by applying the test signal generated from the measurement signal generating unit to the relay, and measuring the minimum operating voltage and coil resistance of the relay in the process unit;

(b) turning off the relay connected to the relay unit by opening the test signal applied from the measurement signal generating unit to the relay, and measuring the maximum return voltage of the relay;

(c) repeating On and Off the operation voltage of the relay in the measurement signal generating unit, and measuring the operation time and return time of the relay in the process unit;

(d) Measuring the contact resistance of each NO (Normal Open, contact a) contact when the relay applies the operating voltage and the contact resistance of each NC (Normal Close, B contact) contact when the operating voltage is opened, respectively ;

(e) measuring chattering when contacting each contact point of the relay;

(f) transmitting the result data measured in steps (a) to (e) to the operation unit; may include.

In addition, in the relay performance test method using the relay performance test apparatus according to an embodiment of the present invention, the measurement signal generator generates a current signal to test the performance of the relay and inputs a value to the relay. generator; and

a voltage signal generator generating a voltage signal to test the performance of the relay and inputting a value to the relay; may include.

In addition, in the relay performance test method using the relay performance test apparatus according to an embodiment of the present invention, the process unit receives the current signal generated from the load current generator and measures the minimum operating voltage and the maximum recovery voltage of the relay a voltage measuring unit;

a time measuring unit receiving the voltage signal generated from the voltage signal generating unit and measuring an operation time and a return time of the relay; and

a resistance measuring unit receiving the resistance signal generated from the resistance measuring unit and measuring the coil resistance of the relay and the contact resistance of each contact; may include.

In addition, in the relay performance test method using the relay performance test apparatus according to an embodiment of the present invention, the time measuring unit measures the time from Off to On when the operating voltage is Off and the operating voltage is from On to Off. Including the return time to measure the time to

The first contact resistance for measuring the contact resistance for each NO contact (Normal Open, a contact) when the operating voltage is On and the contact resistance for each NC contact (Normal Close, b contact) when the operating voltage is Off a second contact resistance; may include.

In addition, in the relay performance test method using the relay performance test apparatus according to an embodiment of the present invention, the first contact resistance is a NO contact (Normal Open, a contact) when the operating voltage is switched from Off to On. A first chattering measurement step of measuring the chattering of the motion; may include.

In addition, in the relay performance test method using the relay performance test apparatus according to an embodiment of the present invention, the second contact resistance is an NC contact (Normal Close, b contact) when the operating voltage is switched from On to Off. a second chattering measurement step of measuring the chattering of the motion; may include.

In addition, in the relay performance test method using the relay performance test apparatus according to an embodiment of the present invention, the operation unit transmits the test signal generated by the measurement signal generator to the process to control and manage the performance test of the relay. test operation department;

a database for storing performance test data of the relay in the test operation unit;

a history management unit for managing a history of the relay performance test data stored in the database; and

an output unit for outputting performance test data of the relay stored in the database; includes,

In step (f), the test operation unit may calculate the performance test data of the relay, the calculated data may be stored in the database, and the performance test data of the relay may be output to the output unit.

In addition, in the relay performance test method using the relay performance test apparatus according to an embodiment of the present invention, the step (f) reports the performance test history of the relay from the history management unit for the relay performance test data stored in the database. or a report generating unit that converts it into a report and outputs it to the output unit; may include.

These solutions will become more apparent from the following detailed description of the invention based on the accompanying drawings.

Prior to this, the terms or words used in the present specification and claims should not be construed in their ordinary and dictionary meanings, and the inventor may properly define the concept of the term in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it is possible.

According to an embodiment of the present invention, when a test signal is applied to the relay, the minimum operating voltage, the maximum recovery voltage, the coil resistance, the contact resistance for each contact, the operation time, the return time, and the chattering time during operation can be sequentially measured. have.

1 is a block diagram showing a relay performance test apparatus according to an embodiment of the present invention.
2 is a flowchart illustrating a relay performance test method using a relay performance test apparatus according to an embodiment of the present invention.
3 is a graph showing a test signal applied to the relay of the relay performance test method using the relay performance test apparatus according to an embodiment of the present invention.

The specific aspects and specific technical features of the present invention will become more apparent from the following detailed description and embodiments in conjunction with the accompanying drawings. In the present specification, in adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as possible even though they are indicated on different drawings. In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. When a component is described as being “connected”, “coupled” or “connected” to another component, the component may be directly connected to or connected to the other component, but another component may exist between each component. It should be understood that elements may be “connected,” “coupled,” or “connected.”

Hereinafter, an embodiment of the present invention will be described in detail based on the accompanying drawings.

As shown in FIG. 1, the relay performance test apparatus R according to an embodiment of the present invention includes a relay unit 10 including one or more connection units 11 capable of connecting a relay to be subjected to a performance test; The measurement signal generating unit 20 that generates a test signal to the relay connected to the relay unit 10, and receiving the test signal generated by the measurement signal generating unit 20, measure the voltage, resistance, operation and return time of the relay. It includes a process unit 30 for measuring and an operation unit 40 for storing and managing data histories measured by the process unit 30 .

The relay unit 10 has a structure in which one or more connection units 11 for connecting a relay to be subjected to a performance test are provided, and one relay is installed in the connection unit 11, and the relay connected to the connection unit 11 may be constructed in a structure in which performance tests are performed sequentially or simultaneously.

The measurement signal generating unit 20 generates current, voltage and resistance signals to test the performance of the relay connected to the relay unit 10 and performs a function of inputting a signal value to the relay, and a load generating a current signal It may include a current generator 21 and a voltage signal generator (load current generator) that generates a voltage signal.

The process unit 30 receives the test signal generated from the measurement signal generator 20 and applies the test signal to the relay to perform a performance test of the relay, and a voltage signal generator (load current generator) It may include a voltage measuring unit 31 for receiving the voltage signal generated from the applying a voltage signal to the relay connected to the connection unit 11 to measure the minimum operating voltage and the maximum recovery voltage of the relay.

In addition, the process unit 30 receives the load current signal generated from the load current generator 21 and applies the load current signal of the relay connected to the connection unit 11 to measure the coil resistance of the relay and the contact resistance for each contact. A time measuring unit that receives the current signal generated from the resistance measuring unit 32 and the load current generating unit 21 and applies the current signal of the relay connected to the connecting unit 11 to measure the operation time and return time of the relay (33) may be further included.

The time measuring unit 33 may measure an operating time for measuring the time from Off to On of the operating voltage and a return time for measuring the time from On to Off of the operating voltage, for example, when the operating voltage is The first contact resistance for measuring the contact resistance of each NO contact (Normal Open, a contact) when On and the second contact for measuring the contact resistance of each NC contact (Normal Close, b contact) when the operating voltage is Off Each resistance can be measured.

The process unit 30 performs a performance test of the relay through the voltage measuring unit 31 , the resistance measuring unit 32 and the time measuring unit 33 , and after the performance test is completed, the data is transmitted to the operation unit 40 . to send

The operation unit 40 controls the performance tests of the measurement signal generation unit 20 and the process unit 30 , and performs a function of managing data on which the performance measurement is completed, the test operation unit 41 , the database 42 , and the history It may include a management unit 43 and an output unit 44 .

The test operation unit 41 performs a function of controlling the performance test of the relay performed by the measurement signal generation unit 20 and the process unit 30, and specifically, the test signal generated by the measurement signal generation unit 20 and The relay performance test performed by the process unit 30 may be controlled.

The performance test result data calculated by completing the performance test of the relay through the test operation unit 41 can be stored in the database 42 to achieve big data, or the performance test data can be recorded through the history management unit 43. have. The performance test data recorded in the history management unit 43 may output the performance test data through the output unit 44 .

At this time, the output unit 44 includes a report management unit 45 that converts the relay performance test history in the history management unit 43 into a report or report, and may output data by converting the report or report.

1 to 3, in the relay performance test method using the relay performance test device R, the test signal generated by the measurement signal generator 20 by turning on the relay connected to the relay unit 10 is applied to the relay, measuring the minimum operating voltage and coil resistance of the relay in the process unit 30 (S11 to S15), and turning off the relay connected to the relay unit 10 to generate a measurement signal generating unit 20 ), open the test signal, measuring the maximum recovery voltage of the relay (S16 ~ S19), and repeat the ON and OFF of the relay operating voltage in the measurement signal generator 20 to operate the relay and measuring the return time (S21 to S25), and measuring the contact resistance of each contact when the relay receives the operating voltage and the contact term of each contact when the operating voltage is opened (S26) and of the relay and measuring chattering when each contact is made (S27 to S28).

By turning on the relay, the test signal generated by the measurement signal generator 20 (in the present invention, as shown in FIG. 3, will be described based on the voltage signal) is applied to the relay (S11), and the voltage signal is applied When it rises to the maximum value (S12), the voltage at the time when the relay is normally closed (indicated by S14 in FIG. 3), that is, the minimum operating voltage, is measured through the voltage measuring unit 31 (S13, S14).

Here, the coil resistance (a portion indicated by S15 in FIG. 3 ) when the voltage applied to the relay is maximum may be measured by the resistance measuring unit 32 ( S15 ).

When the voltage applied to the relay is at its maximum (NC), when the voltage is gradually opened to 0V by turning off the relay, the voltage at the time when the relay is NO (normally open) (indicated by S19 in FIG. 3), that is, the maximum The recovery voltage is measured through the voltage measuring unit 31 (S19).

That is, in steps S11 to S19, when the voltage is gradually applied to the relay, the minimum operating voltage and the coil resistance can be measured, and when the voltage is gradually opened to the relay, the maximum recovery voltage can be measured.

Thereafter, the voltage applied to the relay may be rapidly applied from 0V to 24V, or the test may be performed in the form of applying and opening a voltage in the form of a pulse wave that rapidly opens the voltage 24V applied to the relay to 0V.

For example, when the operating voltage is On (S21), the relay is changed from NO to NC, and the operation time for applying power to the relay can be measured by the time measuring unit 33 (S22), when the operating voltage is On When the operating voltage is turned off at (S23), the relay is changed from NC to NO and the time measuring unit 33 can measure the return time for opening the power applied to the relay (S24).

As described above, by repeatedly applying and opening a voltage to the relay in the form of a pulse wave, it is possible to measure the operation time and return time of the relay (S25).

Here, when the relay is changed from NO to NC (S21), the contact resistance at the NC contact (referred to as the first contact resistance in the present invention) can be measured, and when the relay is changed from NC to NO (S23) ), the contact resistance at the NO contact (referred to as the second contact resistance in the present invention) can be measured (S26).

In addition, after measuring the first contact resistance and the second contact resistance, when changing from NO to NC, the chattering of the contact operation (the first chattering measurement in the present invention) can be measured, and the change from NC to NO can be performed. When the chattering of the contact operation (in the present invention, the second chattering measurement) can be measured (S27 ~ S28).

The method of measuring chattering can measure the chattering of the contact operation by measuring the number of vibrations, specifically, the number of vibrations, amplitude, and vibration time when the contact point of the relay is closed or opened, and the time measuring unit 33 ), when measuring operation time and return time, chattering of contact operation can be measured together.

In the relay performance test method using the relay performance test device in the present invention, when a test signal (the present invention has been described based on voltage) is applied to the relay, the minimum operating voltage, the maximum recovery voltage, the coil resistance, and the contact resistance for each contact , operation time, return time, and chattering time during operation can be sequentially measured.

Although the present invention has been described in detail through one embodiment, this is for describing the present invention in detail, and the relay performance test method using the relay performance test apparatus according to the present invention is not limited thereto. And, terms such as "include", "comprise", or "have" described above mean that the component may be embedded unless otherwise stated, so excluding other components is It should be construed as being able to further include other components rather than other components, and all terms including technical or scientific terms are generally understood by those of ordinary skill in the art to which the present invention belongs, unless otherwise defined. has the same meaning as being

In addition, the above description is merely illustrative of the technical idea of the present invention, and various modifications and variations are possible by those skilled in the art to which the present invention pertains without departing from the essential characteristics of the present invention. Accordingly, one embodiment disclosed in the present invention is not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by this one embodiment. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10 - relay part 11 - connection part
20 - Measurement signal generator 21 - Load current generator
22 - voltage signal generator
30 - Process unit 31 - Voltage measurement unit
32 - resistance measuring part 33 - time measuring part
40 - Operation Department 41 - Test Operation Department
42 - Database 43 - History Management Department
44 - Output unit 45 - Reporter management unit
R - Relay performance tester

Claims (8)

In the relay performance test method using a relay performance test device including a relay unit, a measurement signal generator, a process unit and an operation unit,
(a) turning on the relay connected to the relay unit by applying the test signal generated from the measurement signal generating unit to the relay, and measuring the minimum operating voltage and coil resistance of the relay in the process unit;
(b) turning off the relay connected to the relay unit by opening the test signal applied from the measurement signal generating unit to the relay, and measuring the maximum return voltage of the relay;
(c) repeating On and Off the operation voltage of the relay in the measurement signal generator to measure the operation time and return time of the relay in the process unit;
(d) Measuring the contact resistance of each NO (Normal Open, contact a) contact when the relay applies the operating voltage and the contact resistance of each NC (Normal Close, B contact) contact when the operating voltage is opened, respectively ;
(e) measuring chattering when contacting each contact point of the relay;
(f) transmitting the result data measured in steps (a) to (e) to the operation unit; including,
The measurement signal generator includes: a load current generator for generating a current signal to test the performance of the relay and inputting a value to the relay; and
a voltage signal generator generating a voltage signal to test the performance of the relay and inputting a value to the relay; includes,
The process unit receives the current signal generated from the load current generation unit, the voltage measurement unit for measuring the minimum operating voltage and the maximum recovery voltage of the relay;
a time measuring unit receiving the voltage signal generated from the voltage signal generating unit and measuring an operation time and a return time of the relay; and
a resistance measuring unit receiving the load current signal generated from the load current generating unit and measuring the coil resistance of the relay and the contact resistance of each contact; including,
The time measuring unit includes an operating time for measuring the time from Off to On of the operating voltage and a recovery time for measuring the time from On to Off of the operating voltage,
The first contact resistance for measuring the contact resistance for each NO contact (Normal Open, a contact) when the operating voltage is On and the contact resistance for each NC contact (Normal Close, b contact) when the operating voltage is Off a second contact resistance; includes,
The first contact resistance is a first chattering measuring step of measuring the chattering of the NO contact (Normal Open, a contact) operation when the operating voltage is switched from Off to On; and
a second chattering measurement step of measuring the chattering of an NC contact (Normal Close, b contact) operation when the operating voltage is switched from On to Off; Including, relay performance test method.
delete delete delete delete delete The method according to claim 1,
The operation unit transmits the test signal generated by the measurement signal generator to the process to control and manage the performance test of the relay;
a database for storing performance test data of the relay in the test operation unit;
a history management unit for managing a history of the relay performance test data stored in the database; and
an output unit for outputting performance test data of the relay stored in the database; includes,
In the step (f), the test operation unit calculates the performance test data of the relay, the calculated data is stored in the database, and the relay performance test data is output to the output unit.
8. The method of claim 7,
The step (f) may include: a reporter generating unit that converts the relay performance test data stored in the database into a report or a report and outputs the relay performance test history in the history management unit to the output unit; Including, relay performance test method.

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