KR102596731B1 - A system for testing relay - Google Patents

Abstract

The present invention relates to a relay inspection system, and more specifically, to a relay inspection system that can automatically verify the health of the relay by injecting a signal into the coil and contacts of the relay and analyzing the measured signal.
The relay inspection system according to an embodiment of the present invention is a relay inspection system for inspecting multiple types of inspection items for a relay including a coil and a contact point, is connected to the coil and contact point of the relay, and receives a socket portion provided to transmit power to the relay; an input unit provided to generate voltage and current and input them into the socket unit; an inspection unit that controls the voltage and current generated in the input unit, is connected to the socket unit, measures a signal on the relay, and determines whether the measured signal is normal under preset criteria for each inspection item; and an output unit provided to output a signal measured through the inspection unit and a result of determining whether the measured signal is abnormal.

Description

Relay testing system{A system for testing relay}

The present invention relates to a relay inspection system, and more specifically, to a relay inspection system that can automatically verify the health of the relay by injecting a signal into the coil and contacts of the relay and analyzing the measured signal.

A relay is a type of electrical switch that uses the property of a coil to become a magnet when current flows through it. In other words, when the coil becomes an electromagnet, the relay attracts the iron piece by magnetic force and performs a switching operation where the contact points of the switch part attach or fall according to the movement of the iron piece. These relays are widely used in sequence control circuits in various systems, including vehicles.

Meanwhile, the relay's performance deteriorates as it is installed in the system and used for a long time, and even if operating power is supplied, the excitation force may become weak and may not operate properly. In addition, the contacts of the relay may be damaged or burned out due to currents other than the operating current flowing through the contacts. If the contacts of the relay are damaged, chattering may occur in which the contacts attach and fall repeatedly in a very short period of time due to mechanical vibration when the contacts attach or detach. As a result, it can become a factor that makes the system unstable.

As such, it is difficult to predict the lifespan of relays, and it is necessary to regularly inspect relays for defects so that the system can operate stably. Additionally, since relays may be defective from the time they are shipped, if a defective relay is installed in the system, the system may become unstable. Therefore, it is necessary to check whether the relay is defective even before applying it to a product.

According to the related art, it is common for workers to check whether a relay is operating properly by listening to the sound generated when contacts are attached or separated in the process of connecting or disconnecting the operating power to the relay. As another example, while the operator connects the operating power to the relay, he or she may check whether the relay is defective by measuring the conduction or resistance value between terminals connected to the contact points using typical test equipment.

In this case, without a separate test device, the operator manually tests each terminal of the relay for deformation, whether each terminal is energized, and the resistance value of the coil using the naked eye and other test equipment (resistance meter, etc.). There is a problem of inefficiency because the experiment takes a lot of time. In addition, when there are various types of relays subject to inspection, it is inconvenient because the operator must check each terminal one by one, connect the operating power, and measure whether or not the terminals are energized or the resistance value.

Recently, the technology described in Korean Patent No. 10-1499997 was proposed to solve this problem. The technology described in this technology determines whether the relay operation is normal through a current sensor and prevents disconnection between the relay and the current sensor. There is an advantage in preventing this, but it has the problem of not being able to measure the main characteristics of the relay, such as the relay's operation/return voltage, coil resistance, and contact resistance.

In particular, in the case of conventional relay inspection equipment, it is impossible to test and verify the soundness of the conduction voltage and conduction current of the relay contact point, the effect of vibration that may occur on the contact point, and the magnetic force and polarity of the arc-extinguishing magnet, making it impossible to verify the performance and soundness of the relay. The situation is that it is not being used as appropriate inspection and testing equipment for essential inspection items in verification.

Korean Patent No. 10-1499997 (2015.03.02)

The present invention was created to solve the above-mentioned problems. More specifically, in order to test various types of test items for relays, a signal suitable for each test item is injected into the coil and contact point and the measured signal is analyzed to make a decision. The purpose is to provide a relay inspection system that can verify the health of the relay by determining whether it is normal under the standards.

The relay inspection system according to an embodiment of the present invention is a relay inspection system for inspecting multiple types of inspection items for a relay including a coil and a contact point, is connected to the coil and contact point of the relay, and receives a socket portion provided to transmit power to the relay; an input unit provided to generate voltage and current and input them into the socket unit; an inspection unit that controls the voltage and current generated in the input unit, is connected to the socket unit, measures a signal on the relay, and determines whether the measured signal is normal under preset criteria for each inspection item; and an output unit provided to output a signal measured through the inspection unit and a result of determining whether the measured signal is abnormal.

More specifically, the socket unit is configured to separately connect the input unit and the inspection unit to terminals extending from the contact point, so that the inspection unit can measure the resistance of the contact point by applying a 4-wire resistance measurement technique. It is characterized by including a 4-wire contact socket provided.

More specifically, the inspection unit is provided to supply a voltage lower than the rated voltage of the relay to the socket unit through the input unit, measure the current and voltage on the coil of the relay, and calculate a resistance value for the coil of the relay. It is characterized in that it includes a coil resistance inspection unit.

More specifically, the coil resistance inspection unit determines that the coil resistance of the relay is abnormal when the calculated resistance value is outside a preset judgment standard.

More specifically, the inspection unit increases or decreases the voltage generated at the input unit and supplies it to the socket unit, measures the voltage change on the contact point of the relay, and detects the voltage at the point when the contact point is turned on or off. It is characterized by including an operation/return voltage inspection unit provided to measure the voltage applied to the coil.

More specifically, the operation/return voltage inspection unit determines that if the voltage applied to the coil measured at the time the contact point is turned on is a value outside the preset judgment standard, the operation voltage of the relay is in an abnormal state. , and if the voltage applied to the coil measured at the time the contact point is turned off is a value outside the preset judgment standard, it is characterized in that it is determined that the return voltage of the relay is in an abnormal state. .

More specifically, the inspection unit is a contact resistance inspection unit provided to supply current to the socket unit through the input unit, measure the voltage applied to the contact point of the relay, and calculate a resistance value for the contact point of the relay. It is characterized by including.

More specifically, the contact resistance inspection unit determines that the contact resistance of the relay is abnormal when the calculated resistance value is outside a preset judgment standard.

More specifically, the contact resistance test unit supplies a voltage corresponding to the rated voltage of the relay to the socket unit through the input unit, and when the contact point of the relay is in the ON state, the voltage applied to the contact point and the When the contact point of the relay is in an OFF state by blocking the voltage supplied to the socket part through the input part, the voltage applied to the contact point is measured.

More specifically, the contact resistance test unit measures the voltage applied to the contact point and calculates the range of variation of the resistance value for the contact point of the relay while repeating the supply and blocking of voltage to the socket part through the input part. It is characterized by

More specifically, the socket part includes a vibrator attached to the socket part to generate vibration, and the contact resistance test part drives the vibrator to apply vibration to the contact point of the relay. It is characterized by calculating the resistance value for the contact point and comparing it with the resistance value when vibration is not applied.

More specifically, the inspection unit supplies the signal to the socket unit while increasing one or more signals selected from the voltage or current generated in the input unit, and the signal supplied to the socket unit when the contact point of the relay is turned on. It is characterized by including a conduction voltage/current inspection unit provided to measure.

More specifically, the conduction voltage/current inspection unit determines that the contact conduction current of the relay is abnormal when the measured signal is a current and exceeds the preset judgment standard, and the measured signal is a voltage and If the value exceeds the set judgment standard, the contact conduction voltage of the relay is determined to be in an abnormal state.

More specifically, the relay includes an arc-extinguishing magnet installed adjacent to the contact point and provided to perform an arc-extinguishing function, and the inspection unit is provided to detect the polarity of the arc-extinguishing magnet and measure the intensity of magnetic force. It is characterized in that it includes a fire extinguishing inspection unit.

More specifically, the arc-extinguishing inspection unit determines that the polarity of the arc-extinguishing magnet is abnormal when the detected polarity does not match the direction of the current flowing through the contact point, and determines that the measured strength of magnetic force is preset. If the value is less than the standard, the intensity of the magnetic force of the arc-extinguishing magnet is determined to be in an abnormal state.

The relay inspection system according to an embodiment of the present invention includes an inspection unit, so that it can measure the signal on the relay and determine whether the measured signal is abnormal, so that the health of the relay can be automatically verified, and the existing manual operation can be performed automatically. It provides the effect of solving the measurement error problem of the verification method.

In particular, the relay inspection system according to an embodiment of the present invention includes an inspection unit, so that it can measure the coil resistance, operation/return voltage, contact resistance, conduction voltage/current, polarity of the magnet for extinguishing, and strength of magnetic force of the relay. In addition, it is possible to determine whether various test items for the relay are normal based on the judgment criteria in the form of clear numbers, providing the effect of conducting more accurate verification of the health of the relay.

In addition, the relay inspection system according to an embodiment of the present invention measures the resistance value of the contact when vibration is applied to the contact of the relay through the vibrator and contact resistance inspection unit, and detects the vibration that may occur when peripheral equipment is operated at the contact. It provides the effect of making it easier to inspect the impact on and stability of contact resistance.

In addition, the relay inspection system according to an embodiment of the present invention includes a 4-wire contact socket, so that only the contact resistance of the relay can be precisely measured without being affected by the connection resistance of the socket, so when measuring the contact resistance of the relay It provides the effect of minimizing errors that occur.

1 is a block diagram illustrating a relay inspection system according to an embodiment of the present invention.
Figure 2 is a block diagram illustrating an example of the detailed configuration of a relay inspection system according to an embodiment of the present invention.
Figure 3 is a diagram showing an example of a 4-wire contact socket constituting a relay inspection system according to an embodiment of the present invention.
Figure 4 is a diagram showing an example of a state in which the magnetic force sensor constituting the relay inspection system according to an embodiment of the present invention is installed on the socket portion.
Figure 5 is a usage state diagram showing an example of a state in which a signal measured through an inspection unit is output on an output unit constituting a relay inspection system according to an embodiment of the present invention.

The detailed description of the present invention described below refers to the accompanying drawings, which show by way of example specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein with respect to one embodiment may be implemented in other embodiments without departing from the spirit and scope of the invention.

Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description that follows is not intended to be taken in a limiting sense, and the scope of the invention is limited only by the appended claims, together with all equivalents to what those claims assert, if properly described. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

Hereinafter, in order to enable those skilled in the art to easily practice the present invention, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

First, a relay inspection system according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

Figure 1 is a block diagram illustrating a relay inspection system according to an embodiment of the present invention, and Figure 2 is a block diagram illustrating an example of the detailed configuration of a relay inspection system according to an embodiment of the present invention.

Here, the relay inspection system of the present invention is a system for inspecting multiple types of inspection items for the relay (R) including the coil 100 and the contact point 200.

As shown in Figures 1 and 2, the relay inspection system 1000 of the present invention includes a relay (R), a socket unit 300, an input unit 400, an inspection unit 500, and an output unit 600. .

First, the relay (R) includes a coil 100 and a contact point 200.

More specifically, the relay (R) is a type of electric switch that uses the property of becoming a magnet when current flows through the coil 100. When the coil 100 becomes an electromagnet, it attracts an iron piece by magnetic force and causes the iron piece to move. Accordingly, the contact point 200 of the switch performs a switching operation of being attached or dropped.

Next, the socket portion 300 is connected to the coil and contact point of the relay and is provided to transmit power supplied from the outside to the relay.

More specifically, the socket portion 300 is characterized in that it is connected to each terminal extending from the coil and contact point of the relay.

Additionally, as shown in FIG. 2, the socket unit 300 includes a shunt (SHUNT) provided to convert the current flowing on the coil of the relay into voltage.

And, as shown in FIGS. 1 and 2, the socket unit 300 includes a 4-wire contact socket 310, a vibrator 320, and a magnetic force sensor 330.

Here, the four-wire contact socket 310 is configured so that the input unit and the inspection unit are separately connected to terminals extending from the contact point.

More specifically, the four-wire contact socket 310 is characterized in that the inspection unit is equipped to measure the resistance of the contact point by applying a four-wire resistance measurement technique.

Hereinafter, the four-wire contact socket 310 will be described in more detail with reference to FIG. 3, which will be described later.

Additionally, the vibrator 320 is attached to the socket portion to generate vibration.

More specifically, the vibrator 320 may include a motor to generate vibration, but is not limited to this and may include various vibration generating means.

In addition, the vibrator 320 is controlled to drive through the inspection unit, and generates vibration so that the influence of vibration and the stability of the contact resistance can be tested when measuring contact resistance through the contact resistance inspection unit, which will be described later.

More specifically, the vibrator 320 generates vibration and is attached to the socket portion so that the vibration is transmitted to the contact point of the relay.

Next, the magnetic force sensor 330 is installed adjacent to the outside of the relay and is provided to detect the state of an arc-extinguishing magnet formed to perform an arc-extinguishing function on the relay.

Hereinafter, the magnetic force sensor 330 will be described in more detail with reference to FIG. 4, which will be described later.

Next, the input unit 400 is provided to generate voltage and current and input them into the socket unit.

More specifically, the input unit 400 includes a coil voltage generator and a contact voltage/current generator, as shown in FIG. 2.

Here, the coil voltage generator is controlled through the inspection unit and is provided to apply voltage to the coil of the relay connected to the socket unit.

More specifically, the coil voltage generator can vary the voltage applied to the coil from 0% to 100% of the rated voltage so that the inspection unit measures the operation/return voltage of the contact point.

In addition, the contact voltage/current generator is controlled through the inspection unit and is provided to apply voltage or current to the contact point of the relay connected to the contact socket of the socket part.

Next, the inspection unit 500 controls the voltage and current generated in the input unit, is connected to the socket unit, measures the signal on the relay, and determines whether the measured signal is normal under the judgment criteria for each preset inspection item. Equipped to judge.

More specifically, as shown in FIG. 2, the inspection unit 500 is configured to include a CPU, a D/A converter, a contact voltage meter, and an A/D converter.

Here, the CPU is equipped to receive input software and programs for performing each test item of the relay.

More specifically, the CPU is characterized in that it outputs control data to control the coil voltage generator and the contact voltage/current generator of the input unit according to the input software and program.

In addition, the CPU is characterized in that it receives measurement value data for various signals output from the socket unit.

Next, the D/A converter is configured to convert the digital signal into an analog signal.

More specifically, the D/A converter receives control data output from the CPU as a digital signal and transmits each analog signal to the coil voltage generator of the input unit, the contact voltage/current generator, and the oscillator of the socket unit. .

Next, the contact voltage meter is connected to the 4-wire contact socket of the socket portion and is equipped to measure the voltage applied to the contact point to calculate the contact resistance of the relay.

More specifically, the contact voltage meter is configured in the form of a voltmeter, and may be equipped with a voltage amplifier to amplify the voltage when the measured voltage is a small voltage.

Next, the A/D converter is configured to convert the analog signal into a digital signal.

More specifically, the A/D converter converts the analog signals output from the above-described shunt, contact voltage meter, and magnetic force sensor into digital signals and transmits them to the CPU in the form of measured value data.

Through this configuration, the relay inspection system of the present invention includes an inspection unit 500, so that it can measure the signal on the relay and determine whether the measured signal is abnormal, thereby automatically performing health verification for the relay. , It provides the effect of solving the measurement error problem of the existing manual operation verification method.

In addition, as shown in FIG. 1, the inspection unit 500 includes a coil resistance inspection unit 510, an operation/return voltage inspection unit 520, a contact resistance inspection unit 530, a conduction voltage/current inspection unit 540, and an arc extinguishing inspection unit. Includes (550).

First, the coil resistance test unit 510 supplies a voltage lower than the rated voltage of the relay to the socket unit through the input unit, measures the current and voltage on the coil of the relay, and calculates a resistance value for the coil of the relay. It is provided.

More specifically, the coil resistance inspection unit 510 determines that the coil resistance of the relay is abnormal when the calculated resistance value is outside the preset judgment standard.

For example, the coil resistance test unit 510 controls the coil voltage generator of the input unit to supply a voltage lower than the rated voltage to the coil of the relay connected to the socket unit.

And, when a coil current flows through a shunt (SHUNUT) connected in series to the coil, the coil resistance test unit 510 measures the voltage at both ends of the shunt (SHUNT) due to the coil current with an A/D converter.

Afterwards, the coil resistance inspection unit 510 calculates the coil current by dividing the measured voltage at both ends of the shunt (SHUNT) by the shunt resistance, and divides the coil voltage, which is the voltage supplied from the coil voltage generator, by the coil current to calculate the coil resistance. The value for can be calculated.

Accordingly, the relay inspection system of the present invention can measure the coil resistance of the relay by including the coil resistance inspection unit 510, providing the effect of easily checking whether the coil included in the relay is damaged.

Next, the operation/return voltage inspection unit 520 increases or decreases the voltage generated at the input unit and supplies it to the socket unit, and measures the voltage change on the contact point of the relay to determine whether the contact point is ON or OFF. It is equipped to measure the voltage applied to the coil at the point in time.

More specifically, the operation/return voltage inspection unit 520 determines that if the voltage applied to the coil measured at the time the contact point is turned on is a value outside the preset judgment standard, the operation voltage of the relay is It is determined to be in an abnormal state.

In addition, the operation/return voltage inspection unit 520 detects that the return voltage of the relay is in an abnormal state when the voltage applied to the coil measured at the time the contact point is turned off is a value outside the preset judgment standard. judged to be

For example, in order to measure the operating voltage of the relay, the operation/return voltage inspection unit 520 gradually increases the voltage generated by the coil voltage generator of the input unit from 0 V and supplies it to the coil of the relay connected to the socket unit. Control.

At the same time, the operation/return voltage inspection unit 520 measures the change in voltage on the contact point of the relay, and when the contact voltage rapidly decreases, it determines that the contact point is ON, and at this point, the voltage generated by the coil voltage generator is determined to be ON. Measure the voltage as the operating voltage of the relay.

In order to measure the return voltage of the relay, the operation/return voltage inspection unit 520 controls the voltage generated by the coil voltage generator of the input unit to be supplied to the coil of the relay connected to the socket unit while gradually reducing the voltage from the rated voltage. .

At the same time, the operation/return voltage inspection unit 520 measures the change in voltage on the contact point of the relay, and when the contact voltage rapidly increases, it determines that the contact point is OFF, and at this point, the voltage generated by the coil voltage generator is determined to be OFF. Measure the voltage as the return voltage of the relay.

Next, the contact resistance test unit 530 is provided to supply current to the socket unit through the input unit, measure the voltage applied to the contact point of the relay, and calculate the resistance value for the contact point of the relay.

More specifically, the contact resistance inspection unit 530 determines that the contact resistance of the relay is abnormal when the calculated resistance value is outside the preset judgment standard.

In addition, the contact resistance test unit 530 supplies a voltage corresponding to the rated voltage of the relay to the socket unit through the input unit, and when the contact point of the relay is in the ON state, the voltage applied to the contact point and the input When the contact point of the relay is in an OFF state by blocking the voltage supplied to the socket part through the unit, the voltage applied to the contact point is measured.

More specifically, when the contact point of the relay is in the ON state, the contact resistance inspection unit 530 measures the voltage applied to contact point A and determines the contact point resistance through calculation with the current supplied through the input unit. It can be derived.

Here, the A contact point is a NO (Normally Open) terminal, which maintains an open state when power is not supplied and is closed when power is supplied and the switch operates.

In addition, when the contact point of the relay is in the OFF state, the contact resistance test unit 530 measures the voltage applied to the B contact point and calculates the contact B resistance through calculation with the current supplied through the input unit. there is.

Here, the B contact is an NC (Normally Close) terminal, which maintains a closed state when power is not supplied and opens when power is supplied and the switch operates.

For example, the contact resistance test unit 530 supplies current to both ends of the contact points of the relay through a 4-wire contact socket of the socket part through the contact current generator of the input part to measure resistance in the contact ON state. , supply the rated voltage to the coil of the relay through the coil voltage generator.

Afterwards, when the contact point is turned on by the coil, the contact resistance test unit 530 measures the voltage across the contact point as a contact voltage, and measures the current supplied through the contact current generator as a contact current. The resistance value at that point is calculated as the resistance of the contact ON state, that is, the resistance of contact A.

In order to measure the resistance in the contact OFF state, the contact resistance test unit 530 supplies current to both ends of the contact points of the relay through the contact current generator of the input part and the four-wire contact socket of the socket part, and the relay Block the voltage supplied to the coil.

Afterwards, when the contact point is turned off by the coil, the contact resistance test unit 530 measures the voltage across the contact point as a contact voltage, and measures the current supplied through the contact current generator as a contact current. The resistance value at the starting point is calculated as the resistance in the contact OFF state, that is, the B contact resistance.

In addition, the contact resistance test unit 530 measures the voltage applied to the contact point while repeating supply and cutoff of voltage to the socket part through the input part and calculates the variation range of the resistance value for the contact point of the relay. Do it as

More specifically, the contact resistance inspection unit 530 repeatedly measures the resistance of the relay in the contact ON and OFF states, that is, the A contact resistance and the B contact resistance, to determine the respective contact resistance. Calculate the fluctuation range.

For example, the number of repetitions of each contact resistance measurement may be approximately 20.

Here, the fluctuation range of the contact resistance is calculated as the difference between the maximum and minimum values of the measured and calculated resistance values.

And, if the calculated fluctuation range of contact resistance exceeds the preset judgment standard, it is determined that the contact resistance fluctuation of the relay is abnormal, that is, the contact resistance is not maintained stably.

In addition, the contact resistance inspection unit 530 drives the above-described vibrator to calculate the resistance value of the contact point when vibration is applied to the contact point of the relay, and compares it with the resistance value when vibration is not applied. It is characterized by:

More specifically, the contact resistance inspection unit 530 detects that when the difference between the compared resistance values exceeds a preset judgment standard, the contact resistance of the relay is in an abnormal state, that is, a state in which the contact resistance is not stably maintained. judged to be

Accordingly, the formation of the contact resistance inspection unit 530 provides the effect of making it easier to inspect the influence of vibration and the stability of the contact resistance when measuring the contact resistance of the relay.

Next, the conduction voltage/current inspection unit 540 increases one or more signals selected from the voltage or current generated from the input unit and supplies them to the socket unit, and at the point when the contact point of the relay is turned on, the socket unit It is equipped to measure the signal supplied to the unit.

More specifically, the conduction voltage/current inspection unit 540 determines that the contact conduction current of the relay is abnormal when the measured signal is a current and exceeds a preset judgment standard.

In addition, the conduction voltage/current inspection unit 540 determines that the contact conduction voltage of the relay is abnormal when the measured signal is a voltage and a value that exceeds a preset judgment standard.

For example, in order to measure the conduction voltage of the contact point, the conduction voltage/current inspection unit 540 gradually increases the voltage from 0 to the contact point of the relay through the 4-wire contact socket of the socket part through the contact voltage generator of the input part. Supply increases.

At the same time, when the contact point is in the ON state, the conduction voltage/current inspection unit 540 passes the contact point and measures the voltage generated from the contact voltage generator at this point as the conduction voltage. do.

In order to measure the conduction current of the contact point, the conduction voltage/current inspection unit 540 gradually increases the current from 0 to the contact point of the relay through the 4-wire contact socket of the socket part through the contact current generator of the input part. supply.

At the same time, when the contact point is in the ON state, the conduction voltage/current inspection unit 540 passes the supplied current through the contact point, and at this point measures the current generated from the contact current generator as the conduction current. do.

Accordingly, the formation of the conduction voltage/current inspection unit 540 provides the effect of making it easier to inspect the conduction performance of the relay contact point and determine whether the gold plating of the contact point is damaged.

Next, the arc extinguishing inspection unit 550 is equipped to detect the polarity of the arc extinguishing magnet formed to perform the arc extinguishing function on the relay and measure the strength of the magnetic force.

More specifically, the arc extinguishing inspection unit 550 may detect the polarity of the arc extinguishing magnet and measure the magnetic force intensity through the magnetic force sensor 330 of the socket portion described above.

And, if the detected polarity does not match the direction of the current flowing through the contact point, the arc extinguishing inspection unit 550 determines that the polarity of the arc extinguishing magnet is abnormal.

In addition, the arc-extinguishing inspection unit 550 determines that the magnetic force intensity of the arc-extinguishing magnet is abnormal when the measured intensity of magnetic force is less than a preset determination standard.

As described above, the relay inspection system of the present invention includes an arc extinguishing inspection unit 550, thereby providing the effect of more easily verifying the suitability of the arc extinguishing magnet and arc extinguishing function of the relay.

Hereinafter, the arc-extinguishing magnet and magnetic force sensor will be described in more detail with reference to FIG. 4, which will be described later.

Next, the output unit 600 is provided to output a signal measured through the inspection unit and a result of determining whether the measured signal is abnormal.

Hereinafter, the output unit 600 will be described in more detail with reference to FIG. 5, which will be described later.

Next, with reference to FIG. 3, the four-wire contact socket 310 constituting the relay inspection system of the present invention will be described in more detail.

Figure 3 is a diagram showing an example of a 4-wire contact socket 310 constituting a relay inspection system according to an embodiment of the present invention.

First, as described above, the four-wire contact socket 310 is characterized in that the inspection unit is equipped to measure the resistance of the contact point by applying a four-wire resistance measurement technique.

As shown in FIG. 3, the four-wire contact socket 310 is configured so that the input unit 400 and the inspection unit 500 are separately connected to terminals extending from the contact point 200 of the relay.

More specifically, the four-wire contact socket 310 is provided with two connection parts for each terminal of the contact point 200 of the relay, and each connection part includes a current supply line connected to the constant current generator of the input unit 400 and the inspection unit ( The voltage measurement line connected to the voltmeter (500) is configured to be connected.

In addition, the constant current generator and the voltmeter connected to the connection part of the 4-wire contact socket 310 through a line are characterized in that both ends are not connected to each other.

In particular, the impedance of the voltmeter is designed to be high so that the current generated from the constant current generator does not flow.

By including the 4-wire contact socket 310 configured as described above, only the contact resistance of the relay can be precisely measured without being affected by the connection resistance of the socket, eliminating errors that occur when measuring the contact resistance of the relay. Provides effects that can be minimized.

Next, with reference to FIG. 4, the arc-extinguishing magnet (M) and magnetic force sensor 330 that constitute the relay inspection system of the present invention will be described in more detail.

Figure 4 is a diagram showing an example of a state in which the magnetic force sensor 330 constituting the relay inspection system according to an embodiment of the present invention is installed on the socket portion 300.

As shown in Figure 4, the relay (R) includes a magnet (M) for extinguishing the arc.

Here, the fire-extinguishing magnet (M) is installed adjacent to the contact point of the relay (R) to perform the fire-extinguishing function.

More specifically, the arc-extinguishing magnet (M) is configured to prevent the lifespan of the contact point from being shortened by sparks and arcs that occur when the relay contact point is switched from the ON state to the OFF state. do.

And, as shown in FIG. 4, the socket portion 300 includes a magnetic force sensor 330.

Here, as described above, the magnetic force sensor 330 is installed adjacent to the outside of the relay (R) and is provided to detect the state of the arc extinguishing magnet (M).

More specifically, the magnetic force sensor 330 may be provided in the form of a Hall sensor, but is not limited to this and may be provided in various forms to detect polarity and strength of magnetic force.

Accordingly, by including a magnetic force sensor 330 formed in the socket portion, it is possible to detect the polarity of the arc-extinguishing magnet and measure the magnetic force intensity through the arc-extinguishing inspection unit described above.

Next, the output unit 600 constituting the relay inspection system of the present invention will be described in more detail with reference to FIG. 5.

Figure 5 is a usage state diagram showing an example of a state in which a signal measured through the inspection unit is output on the output unit 600 constituting the relay inspection system according to an embodiment of the present invention.

First, as described above, the output unit 600 is provided to output a signal measured through the inspection unit and a result of determining whether the measured signal is abnormal.

For example, as shown in FIG. 5, the output unit 600 may output information about the current value, maximum value (MAX), minimum value (MIN), and fluctuation range of the measured signal in numerical form.

In addition, the output unit 600 can output the result of determining whether the signal measured through the inspection unit is abnormal in a visual form such as letters or flashing lights, and can be accompanied by an auditory identification such as a warning sound. .

Accordingly, the relay inspection system of the present invention includes an output unit 600, which outputs the signal measured from the coil and contact of the relay and the result of determining whether the signal is abnormal, allowing the inspector to check and identify the output information. It provides the effect of facilitating inspection.

In the above, the present invention has been described with specific details such as specific components and limited embodiments and drawings, but this is only provided to facilitate a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , a person skilled in the art to which the present invention pertains can make various modifications and variations from this description.

Therefore, the spirit of the present invention should not be limited to the above-described embodiments, and the scope of the patent claims described below as well as all modifications equivalent to or equivalent to the scope of the claims fall within the scope of the spirit of the present invention. They will say they do it.

1000: Relay inspection system
100: coil 200: contact
300: Socket portion 310: 4-wire contact socket
320: Vibrator 330: Magnetic force sensor
400: input unit
500: Inspection section 510: Coil resistance inspection section
520: Operation/return voltage inspection unit 530: Contact resistance inspection unit
540: Conduction voltage/current inspection unit 550: SOHO inspection unit
600: output unit
R: Relay M: Magnet for SOHO

Claims (15)

In the relay inspection system for inspecting multiple types of inspection items for the relay (R) including the coil 100 and the contact point 200,
A socket portion 300 connected to the coil and contacts of the relay and provided to transmit power supplied from the outside to the relay;
An input unit 400 provided to generate voltage and current and input them into the socket unit;
an inspection unit 500 that controls the voltage and current generated in the input unit, is connected to the socket unit, measures a signal on the relay, and determines whether the measured signal is normal under a preset judgment standard for each inspection item; and
An output unit 600 provided to output a signal measured through the inspection unit and a result of determining whether the measured signal is abnormal,
The inspection unit 500,
A contact resistance test unit 530 provided to supply current to the socket unit through the input unit, measure the voltage applied to the contact point of the relay, and calculate a resistance value for the contact point of the relay,
The contact resistance inspection unit 530,
A voltage corresponding to the rated voltage of the relay is supplied to the socket unit through the input unit, and when the contact point of the relay is in the ON state, the voltage applied to the contact point and the voltage supplied to the socket unit through the input unit are blocked. A relay inspection system characterized in that, when the contact point of the relay is in an OFF state, the voltage applied to the contact point is measured. According to clause 1,
The socket portion 300,
A 4-wire contact socket 310 configured to separately connect the input unit and the inspection unit to terminals extending from the contact point, so that the inspection unit can measure the resistance of the contact point by applying a 4-wire resistance measurement technique. A relay inspection system comprising: According to clause 1,
The inspection unit 500,
A coil resistance inspection unit 510 provided to supply a voltage lower than the rated voltage of the relay to the socket unit through the input unit and measure the current and voltage on the coil of the relay to calculate a resistance value for the coil of the relay. A relay inspection system comprising: According to clause 3,
The coil resistance inspection unit 510,
A relay inspection system characterized by determining that the coil resistance of the relay is abnormal when the calculated resistance value is outside the preset judgment standard. According to clause 1,
The inspection unit 500,
Increase and decrease the voltage generated at the input unit and supply it to the socket unit, measure the voltage change on the contact point of the relay, and measure the voltage applied to the coil when the contact point is turned on or off. A relay inspection system comprising an operation/return voltage inspection unit 520. According to clause 5,
The operation/return voltage inspection unit 520,
If the voltage applied to the coil measured at the time the contact point is turned on is outside the preset judgment standard, it is determined that the operating voltage of the relay is abnormal,
A relay inspection system characterized in that, if the voltage applied to the coil measured at the time the contact point is turned off is a value that exceeds a preset judgment standard, the return voltage of the relay is determined to be in an abnormal state. delete According to clause 1,
The contact resistance inspection unit 530,
A relay inspection system characterized by determining that the contact resistance of the relay is abnormal when the calculated resistance value is outside the preset judgment standard. delete According to clause 1,
The contact resistance inspection unit 530,
A relay inspection system characterized in that the voltage applied to the contact point is measured while repeating the supply and cutoff of voltage to the socket part through the input part and the variation range of the resistance value for the contact point of the relay is calculated. According to clause 1,
The socket portion 300,
It includes a vibrator 320 attached to the socket portion and provided to generate vibration,
The contact resistance inspection unit 530,
A relay inspection system characterized by driving the vibrator to calculate the resistance value of the contact point when vibration is applied to the contact point of the relay, and comparing it with the resistance value when vibration is not applied. According to clause 1,
The inspection unit 500,
A conduction voltage/current provided to increase one or more signals selected from the voltage or current generated from the input unit and supply them to the socket unit, and to measure the signal supplied to the socket unit when the contact point of the relay is turned on. A relay inspection system comprising an inspection unit 540. According to clause 12,
The conduction voltage/current inspection unit 540,
If the measured signal is a current and has a value that exceeds the preset judgment standard, it is determined that the contact conduction current of the relay is in an abnormal state,
A relay inspection system characterized in that, when the measured signal is a voltage and a value that exceeds a preset judgment standard, it is determined that the contact conduction voltage of the relay is in an abnormal state. According to clause 1,
The relay (R) is,
It includes an arc-extinguishing magnet installed adjacent to the contact point and provided to perform an arc-extinguishing function,
The inspection unit 500,
A relay inspection system comprising: an arc-extinguishing inspection unit 550 provided to detect the polarity of the arc-extinguishing magnet and measure the intensity of magnetic force. According to clause 14,
The fire extinguishing inspection unit 550,
If the detected polarity does not match the direction of the current flowing through the contact point, it is determined that the polarity of the arc-extinguishing magnet is abnormal,
A relay inspection system characterized in that, when the measured strength of magnetic force is less than a preset judgment standard, it is determined that the magnetic strength of the arc-extinguishing magnet is in an abnormal state.