KR890000624Y1 - A tester - Google Patents

Abstract

No content.

Description

Power relay tester

1 is a block diagram for explaining the present invention,

2 is a connection diagram inside the tester C / P.

3 is an internal wiring diagram of the tester C / M.

4 is a regenerative control circuit diagram for explaining the present invention.

5 is a S.C.R signal input detection circuit diagram.

6 is a digital type counter circuit diagram.

7 is an exemplary diagram of an overcurrent relay test connection.

* Explanation of symbols for main parts of the drawings

A: power supply section B: signal detection S, C, R circuit

C: Fine current adjustment circuit D: Lamp display selection circuit

E: instantaneous element measuring circuit F: digital counter circuit

R: Relay FA: Regenerative Control Winding

CT, CT ₂ : Current transformer SCR: Silicon controlled rectifier

The present invention relates to a device for testing a power relay that protects various electronic devices such as transformers, circuit breakers, and electric motors. The present invention is designed to separate and protect other electric power systems or electric devices of the system against failure or abnormality of the power system. The present invention relates to a tester for electric equipment protection relays, which is capable of judging whether or not a relay is relayed by artificially testing a protective relay ("OCR", etc.) under the same conditions as in an accident.

Conventionally, in order to perform such a test, a simple relay tester using a combination circuit measurement in the field was used. However, since the relay is tested with a simple current different from the actual current, there is a defect that is different from the actual operating characteristics.

The present invention artificially generates various elements such as voltage, current, and phase in the same state as the input signal received by the protective relay in the event of an accident such as a power meter to solve such a conventional defect, and the operation conditions of various relays by type All sorts of relay tests can be easily read by using the IC direct readout digital counter to measure the operation cycle of the protective relay easily and completely, and to measure the operation cycles of the protective relay by automatic sorting and withdrawal. It makes it extremely easy and enables instantaneous element characteristic test of the relay with the instantaneous element part among various relays, so that various characteristics of the protective relay are tested and measured under the same condition as the actual power system accident. Described in detail by same.

FIG. 1 is a block diagram for explaining the present invention. An external relay R can be experimented with a power supply A composed of a current adjusting circuit and a voltage adjusting circuit, and the operation completion signal of the relay R is detected. An operating SCR circuit (B) is connected, and a fine current adjustment circuit (C) comprising a regenerative control winding FA and a current transformer CT ₁ (CT ₂ ) is connected to the power supply unit A, and a lamp is displayed. The sorting circuit D, the instantaneous element measuring circuit E, and the digital counter circuit F are connected.

In addition, a specific circuit for the above fine current adjustment circuit is shown in FIG. That is, the regenerative control winding (FA) and the current transformer (CT ₁ ) (CT ₂ ) consists of the regenerative control winding (FA) to the current transformer (CT ₁ ) (CT ₂ ), the current transformer (FA) is connected in parallel The current transformer (CT ₂ ) is connected in series so that the regenerative control winding (FA) can precisely adjust the load current to a minute current, and adjust the current as low as possible and adjust the current high when the load current is small. It consists of a winding.

Therefore, when the load current I _L flows to the load through the secondary winding of the regenerative control winding FA, the current of I _i is induced in the primary winding of the regenerative control winding FA, and this current I _i ) joins the current I ₂ supplied from the slide (SLID ₂ ) and is greater than the secondary side current (I ₂ ) when I ₁ > I ₂ the primary side (I ₁ ) is powered by the slide (SLID ₂ ) feedback decreases the load current (I _L) by the primary current (I ₁₎ than the secondary-side current If (I ₂₎ is large (I ₁ <I _2), the secondary current (I ₂₎ is the regenerative control winding (FA To further reduce the load current I _L of the secondary winding.

The circuit operating as described above has almost no power loss, the structure is simple, and can precisely adjust even minute portions of the current. Since the two current transformers CT ₁ and CT ₂ have two effects, heat dissipation is also very large.

On the other hand, the lamp display sorting circuit (D) for selecting signal input and output elements of test terminals for each relay is composed of a selector, a diode, and a relay as shown in FIG. When the selector is set in the position, the lamp is turned on at the terminal that draws out the elements necessary for the test, and the relay (R) receives the operation signal so that the test apparatus can be operated. ), So even beginners can make a complete wiring test without a wrong wiring when testing relay (R).

In addition, in the instantaneous element measuring circuit E of the present invention, as shown in FIG. 3, before pressing the test switch, the capacitor C ₁ contacts the resistor R ₁ and the test switch Test SW. When (B) is charged and the test switch (Test SW) is pressed, the trigger signal is discharged to the gate of S · C · R through the contact point (b). When the trigger of S · C · R is triggered, the auxiliary relay operates to operate the power supply unit (A). The power supply is cut off by contact (P ₁ ) of). Even though the test switch (Test SW) is kept pressed, the auxiliary relay does not operate again but operates when the test switch is pressed. You can test the instantaneous element characteristics of a relay with an instantaneous element by pressing the switch again and then pressing it again.

The operation state of the present invention, which operates as described above, will be described as an example when the overcurrent metering device "0" type is tested, and the power supply brake switch (ON) and the selector of the lamp display sorting circuit (D) are set to OCR-. selecting only after the lamp operation the terminal placed on the O to a connection as in claim 7 also press the following accident switch (Faun SW) relay (PP _1), this is opened is excited power contact point (P _1), in the SLID ₂ gradually When increasing, the ammeter instructs the flow of current. For example, if 5A flows through the plug A when the current TAP of the relay R is placed at 4A, the input voltage of the regenerative control certificate FA is adjusted to SLID ₂ . Can be adjusted to 4A, and if 3A flows, the regenerative control winding (FA) can be adjusted to 3A.

At this time, if the accident switch is released (OFF) and the test switch is pressed, the current flows through the relay, and this current becomes the secondary current of the current transformer (CT ₂ ) in case of a power system accident. At the same time, the fault current flows from the terminal (CC.T) to the A plug, and S · C · R ₁ of the S, C, and R circuits of the signal detection circuit (B) are operated to turn on the power switch contact point (P _1). ) Is cut off and the power is cut off.

At this time, the digital counter (F) for time measurement is activated when the auxiliary relay (Aux Reley) is excited when the test switch (Test SW) is pressed and the auxiliary relay contact is operated simultaneously with the contact point (P ₁ ). The counter starts.

In addition, the S · C · R ₁ element turns off the auxiliary relay so that the counter contact is interrupted to stop the counter operation. As a result, the digital counter F accurately records the time from the operation of the electric relay to the stop.

The operation description of the present invention is related to the overcurrent relay among various relays, but even when testing other relays, when the selector of the lamp display sorting circuit (D) is set according to the relay type and connected, the operation can be performed almost identically. will be.

The present invention not only has the advantage of preventing various defects of the relays or defects such as the circuit breaker and the control circuit in advance, but also corrects the relay more quickly than the circuit breaker by measuring the interlocking time with the circuit breaker. It is designed with the effect that various relays can be tested easily.

Claims (1)

In connecting and testing the relay R to the power supply unit A configured in the current and voltage adjustment circuit, an SCR circuit B for detecting the operation completion signal of the relay R is connected, and the regenerative power is supplied to the power supply unit A described above. Connect the micro-current adjusting circuit (C) consisting of the control winding (FA) and the current transformer (CT ₁ ) (CT ₂ ), the lamp display sorting circuit (D), the instantaneous element measuring circuit (E), and the digital counter circuit (F). Power relay test device characterized in that the configuration.