KR890001044B1 - Excess electric current relay of electron type - Google Patents

Abstract

The relay has two functions of no-voltage relay and overcurrent relay using the CMOS integrated circuit. In checking a loading current which flows practically in an operation indicator lamp, the starting state of overload is easily shown by the relay. A desired operation is properly performed by this relay.

Description

Electronic overcurrent relay

1 is a connection diagram illustrating an external connection method of the present invention.

2 is a circuit diagram of the present invention.

3 is an inverse time overload operation characteristic curve of FIG.

4 is an instantaneous overload operation characteristic curve of FIG.

* Explanation of symbols for main parts of the drawings

A: Instantaneous element setting part B: Negative voltage rectifying circuit part

D: Automatic return overload relay section E: Delay circuit section

F: Circuit inspection part R, S, T: 3 phase AC input terminal

DR: Bridge Rectifier Circuit CT ₁ , CT ₂ , CT ₃ : Current Transformer

C _a : AC capacitor TH: Thermistor

Q ₁ -Q ₅ : transistor G ₁ -G ₇ : naked gate

SW ₁ -SW ₃ : Selective Switch S ₁ : Test Button Switch

S ₂ : Reset Button Switch S ₃ : On Switch

S _4: switch-off LED: light emitting diode

D ₁ -D ₁₄ : Diode C ₁ -C ₇ : Capacitor

ZD: Zener Diode R ₁ -R ₁₉ : Resistance

VR ₁ -VR ₅ : Variable resistor RY: Auxiliary relay

The present invention relates to an electronic overcurrent relay capable of acting as a voltageless relay and an overcurrent relay using a CMOS integrated circuit.

Conventionally, there was a thermal relay and an inductive overcurrent relay using bimetal as an AC load overload device, but the structure is complicated, the overload start state cannot be identified, and the fault and the amount of load that do not solve the accumulation of overload due to frequent start-up As there are many types of relays required, the relays are not universal and are limited to a certain standard. Their operation is not precise, the production cost is high, and the desired current and time correction is very difficult.

The present invention is to solve the above-mentioned drawbacks, the object of the present invention is to be able to perform the desired precise operation and to know the load current flowing through the operation indicator lamp easily confirm the overload operation start state visually It is to provide electronic overcurrent relay which can check current and play the role of voltageless relay, inductive disk type overcurrent relay and ammeter function.

Hereinafter, the configuration according to the accompanying drawings, Figure 2 as follows.

Three-phase current transformers on the AC input terminals (R) (S) (T ) (CT 1) (CT 2) 2 side of the connection to the load side through (CT ₃₎ and current transformer _{(CT 1) (CT 2)} (CT 3) Is connected directly to the terminal point (a) via diodes (D ₁ , D ₂ , D ₃ ) and at the terminal point (a) thereof, the thermistor (TH), the variable resistor (VR ₁ ), the resistors (R ₁ , R ₂ ) and The instantaneous element setting unit (A) connected to the transistor (Q ₅ ) is connected directly to the ground point, and is connected to the ground point through the resistor (R ₃ ) (R ₄ ) and the variable resistor (VR ₂ ) at the terminal point (a) to change it. The resistor 5 is connected to the collector side of the transistor Q ₁ by connecting to the base side of the transistor Q ₁ and the terminal point 2 of the selector switch SW ₁ to the variable side terminal of the resistor VR ₂ . Through the terminal point (b) and the emitter side is grounded, the collector side of the transistor (Q ₁ ) is connected directly to the input side of the naked gate (G ₂ ) through the naked gate (G ₁ ) and the variable resistor (VR ₃ ) and its output side. a diode (D ₁₀₎ and the bottle to a variable resistor (VR ₄₎ in To the terminal thereof connected to natdeu gate (G ₃₎ (G ₄₎ and a resistor (R _I1) through was connected to the base shaft of the transistor (Q ₄₎ natdeu gate (G,) the diode (D ₆₎ to the output side of the Ground connected via resistor (R ₆ ) and light-emitting diode (LED) and connected to resistor (R ₇ ), capacitor (C ₁ ) and diode (D ₈ , D ₉ ) at the output side of naked gate (G ₁ ). A negative voltage double-circuit rectifier circuit B is formed to connect the diode D ₈ to the anode side contact of the diode D ₉ and the base side of the transistor Q ₃ , and the resistor R ₈ to the base side thereof. Is connected to the terminal point (b) and the capacitor (C ₉ ) is connected to the ground point and through the resistor (R ₉ ) on the collector side of the transistor (Q ₃ ) to the terminal point (2) of the selector switch (SW ₃ ). The capacitor C ₂ is connected directly to the ground point and the emitter of the transistor Q ₃ is grounded and the terminal point _{1 of the} selector switch SW ₁ is connected. Connecting the transistor (Q ₂₎ the bias resistor (R ₁₄₎ in kolraek teocheuk terminal point (b) via a resistor (R ₁₅₎ to the connection thereof transistor (Q ₂₎ of, and also natdeu gate in kolraek teocheuk terminal (G ₅ ) and the diode (D ₁₅ ) is input to the gate (G ₆ ) through the variable resistor (VR ₅ ) and diode (D ₁₃ ) in parallel at the output side of the gate and the gate (G ₇ ) and diode (D ₁₁₎ Connected to the terminal point (3) of the selector switch (SW ₃ ) and grounded at its terminal via a capacitor (C ₃ ), and at the terminal point (a) the diode (D ₄ ) and the resistor (R ₁₃ ) and the test In the circuit check part (F) connected to the terminal point (b) via the button switch (S ₁ ), the capacitor (C ₄ ) (C ₅ ) is knocked gate (G ₆ ) (G ₇ ) at its terminal point (b). also connected to the input side and the terminal point (b) upon via a resistor ₍₁₈₎ connected to the bridge rectifier circuit (DR) and a ground side through a capacitor (C ₇₎ on its side terminal in the rectifying circuit And also the terminal point (b) a Zener diode (ZD) and a capacitor (C _6), each ground and terminal point (b) a capacitor (C ₈₎ and select change-over switch (SW ₂₎ and the resistance in the (R ₁₇₎ via at, A self-resetting overload relay unit (D) is formed by connecting a diode (D ₁₄ ) (D ₁₀ ), a variable resistor (VR ₄ ) and a naked gate (G ₂ ) (G ₃ ) to the selection switching switch SW ₂ . At the terminal point (2) via a diode (D ₅ ) to the cathode side of the diode (D ₆ ) and at the terminal point (e) via a diode (D ₁₂ ) to the input of the naked gate (G ₆ ) to its input side At ground via resistor (R ₁₆ ), connect the emitter side of transistor (Q ₂ ) directly to the ground point, and connect the naked gate (G ₂ ) input terminal to the terminal point (1) of the selector switch (SW ₃ ). Connected to the collector terminal of transistor Q ₅ through resistor R _{12 on} the input side of dee (G ₃ ) and the auxiliary relay on the positive terminal of the bridge rectifier circuit. (RY) and ground via a collector emitter of transistor (Q ₄ ), and connect a resistor (R ₁₉ ) and an AC capacitor (C _a ) to the AC input power terminals (L ₁ ) (L ₂ ). Connected to the DR).

Reference numeral F denotes a circuit checking portion and E denotes a delay circuit portion.

1 is a connection diagram illustrating an external connection method of an overcurrent relay for clearly explaining the operation principle of the overcurrent relay of the present invention.

Referring to the operation and effect of the present invention configured as such a circuit as follows.

The signal detected by the current transformers CT ₁ , CT ₂ , and CT ₃ is half-wave rectified by the sub-locking diodes D ₁ , D ₂ , and D ₃ to adjust the current scale lower limit set resistance R ₃ and the variable current resistor. Connect (VR ₂ ), upper limit value setting resistor (R ₄ ), instantaneous operation control variable resistance (VR ₁ ), instantaneous element upper limit value and lower limit value setting resistance (R ₁ , R ₂ ), and connect them in parallel to the temperature compensation thermistor (TH). When a minute DC voltage is applied to the terminal point (a), the bias signal of the amplifying transistors Q ₁ , Q ₂ , and Q ₅ is applied, and the minute signal is amplified by the transistor Q ₁ to give the gate N _1. When applied to the input of), the phase is reversed and amplified so that the high-state signal appearing at the output of the naked gate (G ₁ ) turns on the light emitting diode (LED) through the diode (D ₆ ) and the resistor (R ₆ ) to overload. Inform start state.

The output signal of the naked gate (G ₁ ) is the capacitor (C ₂ ) through the terminal (1) (2) of the selector switch (SW ₃ ) via the diode (D ₇ ) and the operating time adjustment variable resistor (VR ₃ ). The charging speed depends on the time constant of the variable resistor (VR ₃ ) and condenser (C ₂ ) and the magnitude of the overload forces. If the output of the capacitor (C ₂₎ natdeu gate (G ₂₎ when the charging voltage natdeu gate (G ₂₎ rises above one-half of the supply voltage of the output of the instantaneous low natdeu gate (G ₃₎ is It becomes high and the output of the naked gate G ₄ becomes low to turn off the transistor Q ₄ so that the auxiliary relay RY is turned off and becomes overloaded.

This overload condition is so natdeu gate (G ₃₎ the high state, the output resistance (R ₁₇₎ and the feedback diode (D ₁₄₎ feedback to the input side of natdeu gate (G ₂₎ by the back of the reset boteon switch (S ₂ Press to continue holding until the charge voltage of the capacitor C ₂ is forcedly discharged. In the normal operation state without an overload signal, the output of the naked gate (G ₁ ) goes low and biases the positive potential distributed by the resistor (R ₈ ) and the capacitor (C ₉ ) to the transistor (Q ₃ ). As a result, the charging voltage of the capacitor C ₂ constitutes an automatic reset circuit which discharges through the resistor R ₉ , thereby preventing malfunction of the pulsating load.

If the overload signal is input and the output of the naked gate G ₁ becomes high, the negative voltage is applied to the base side of the transistor Q ₃ by the secondary voltage rectifying circuit part B, thereby providing a transistor (Q _3). ), The discharge of the capacitor C ₂ is stopped and charging starts, and the overload signal accumulation starts.

However, if the overload is intermittent, the capacitor C ₂ charges and discharges its signal to prevent the accumulation of the signal, thereby preventing malfunction of the load. Then, the selector switch SW ₂ disconnects the feedback circuit of the diode D ₁₄ and the resistor R ₁₇ , and inputs the signal of the capacitor C ₈ to the hard gate G ₃ to give a high state. The auto-return overload relay unit (D) in which the resistor (VR ₄ ) and the diode (D ₁₀ ) connected in parallel between the output of the knock gate (G ₂ ) and the input of the knock gate (G ₃ ) is described. a capacitor (C ₂₎ when the charging voltage rises above one-half of the supply voltage of the natdeu gate (G ₂₎ natdeu output of the gate (G ₂₎ is changed to the low state and remains high by the capacitor (C ₈₎ The input of the naked gate (G ₃ ) was discharged momentarily through the frame of the diode (D ₁₀ ) to go to the low state.

At this time, if the input of the naked gate (G ₃ ) is low, the output of the naked gate (G ₃ ) is high and the output of the naked gate (G ₄ ) is turned low so that the bias of the transistor (Q ₄ ) is not applied and the auxiliary relay ( RY) off. When the bono relay RY is off, the magnetic contactor (MC: magnet contact) is also opened to cut off the load current and the overload signal disappears.

Therefore, if the input of the naked gate (G ₁ ) is high and its output is low and the input of the naked gate (G ₂ ) is low, its output is high, but the capacitor (C ₈ ) already charged with negative potential The input of the knock gate C ₃ is kept low, and the positive potential of the knock gate C ₂ is gradually charged through the variable resistor VR _{4 for} adjusting the return time. ₂ ) When the voltage becomes more than 1/2 of its power supply voltage, the output of the naked gate (G ₃ ) becomes low and the output of the naked gate (G ₄ ) becomes high to turn on the transistor (Q ₄ ) to turn on the auxiliary relay (RY). ) Is excited and reset to its original state.

That is, the automatic return time is determined by the time constants of the variable resistor VR ₄ and the capacitor C ₈ .

If the self-resetting overload circuit is used as a self-resetting current limiting relay, each customer's load limiter will contribute to a suitable, planned and accident-free power supply as a replacement for the maximum receiving power meter. In addition, by connecting the instantaneous element setting unit (A) connected with the variable resistor (VR ₁ ), the instantaneous element upper and lower limit setting resistors (R ₁ ) (R ₂ ), and the transistor (Q ₅ ) and the naked gate protection resistor (R ₁₂ ). It prevents the short circuit of the power line.The operation of the resistor (R ₁ ) is for setting the lower limit current, the resistor (R ₂ ) is for setting the upper limit current, the variable resistor (VR ₁ ) is for instantaneous operating current adjustment and the resistance (R ₁₂ ) is the integrated circuit protection resistor and thermistor (TH) is for temperature compensation. If a short circuit occurs in the line, a strong pulsed voltage formed at the secondary side of the current transformers CT ₁ (CT ₂ ) and CT ₃ is input to the base side of the transistor Q ₅ by the variable resistor VR ₁ . When the transistor Q ₅ is turned on, the input of the knock gate G ₃ becomes low, the output thereof becomes high, and the output of the knock gate G ₄ becomes low, and thus the transistor Q ₄ is turned off while the overload relay is turned off. Will be activated.

As described above, the principle of operation is explained according to the inverse temporal characteristic curve, and the circuit for obtaining the next definite temporal characteristic curve is explained as follows.

Switching the terminal point (1) of the selector switch (SW ₃ ) in the dashed direction of the terminal point (3), the hard gate (G) in the normal state connected to the output side of the naked gate (G ₇ ) via the diode (D ₁₁ ) _Since the input of ₅ ) is high by the capacitor C ₅ , the output of the naked gate G ₇ remains low.

In the no-load state, since there is no signal voltage on the secondary side of the current transformers CT ₁ , CT ₂ , CT ₃ , and there is no transistor Q ₂ base voltage, the transistor Q ₂ is turned off and the input of the hard gate G ₅ is high. Its output becomes low and therefore the output of the naked gate (G ₆ ) is high, the output of the naked gate (G ₇ ) is low. If the load is a motor load, the output of the knock gate (G ₁ ) becomes high while the large current flows 6 times at start-up, but the output of the knock gate (C ₇ ) is low, and it is naked through the diode (D ₁₁ ). The output signal of the gate G ₁ is discharged so that the input of the naked gate G ₂ remains low.

However, when voltage is applied to the base side of transistor Q ₂ due to overload, transistor Q ₂ is turned on so that output of naked gate G ₅ becomes high and output of naked gate G ₆ becomes low and the capacitor the output of the (C ₅₎ the charging voltage is a variable resistor (VR ₅₎ and a slow discharge through the voltage natdeu gate (G ₇₎ soon natdeu gate (G ₇₎ falls below one-half of the supply voltage of the high- the charging voltage diode of natdeu gate (G _2), so the discharge of the input signal to stop the natdeu the input of the gate (G _2), and the high natdeu gate (G ₂₎ output and the low of the capacitor (C ₈₎ ( Immediately discharged through D ₁₀ ), the input of the knock gate (G ₃ ) goes low and its output goes high, and the output of the knock gate (G ₄ ) goes low to turn off the transistor (Q ₄ ) to reduce the load current. Will be blocked.

At this time, the relay overload operation can be delayed according to the time constant of the capacitor (C ₅ ) and the variable resistor (VR ₅ ) when starting the motor. If the load fails to start within the specified time, the load current is immediately cut off. Here, the diode D ₁₂ is a feedback diode for maintaining an overload operation. When the terminal point _{1 of the} selector switch SW ₁ is connected to the terminal point 2, the terminal device 2 becomes an accurate time instantaneous overcurrent relay, and when the terminal point 1 is connected to the terminal point 3, it can be used as an accurate instantaneous overcurrent relay. Contacting the terminal point (1) and the terminal point (2) of the selective disease switch (SW ₂ ) results in a manual return overcurrent relay, and contacting the terminal point (3) and the terminal point (4) results in an automatic return overcurrent relay. .

As the diode (D ₄ ) and the test button switch (S ₁ ) between the DC power supply side and the terminal point (a), it is easy to test the operation of the overload relay without flowing an overload current. A direct current connection to the capacitor for alternating current to the AC input side of the object is widely available to the operating range of the operating power to the relay bridge rectifier circuit (DR) (C _a) and for preventing a rush current resistance (R ₁₉₎ and a bridge rectifier circuit (DR) A Zener diode (ZD) was connected to supply a constant voltage to the integrated circuit by forming a smoothing circuit formed by forming a capacitor (C ₇ ) (C ₆ ) and a resistor (R ₁₈ ) on the side.

FIG. 1 is a block diagram for easily explaining the operation principle of the current relay of the present invention. The operation principle thereof will be described in detail with reference to FIG. Power is supplied to the three-phase AC input terminals (R) (S) (T) and supplied to the AC input power terminals (L ₂ ) (L ₁ ) through the fuse (F ₁ ) (F ₂ ) and the off switch (S ₄ ). When a voltage is applied, the coil of the auxiliary relay RY is excited to change the connection of the auxiliary contact.

At this time, when the on switch (S ₃ ) is turned on the circuit is operated, the coin (ML) of the magnetic contactor (MC) is excited and the load current flows. At this time, when the overcurrent relay is operated by the overcurrent relay, the auxiliary relay RY is turned off to cut off the load current by turning off the magnetic contactor coil ML. As such, when the auxiliary relay RY is normally excited, the principle of turning off the auxiliary relay RY in the case of a power failure is the same as that of a no-voltage relay, and thus the overcurrent relay can function as a no-voltage relay.

The present invention which operates in this way makes it possible to set the overload setting very precisely by using the current regulating variable resistor and the light emitting diode so that the overload setting can be made very precisely. (The load fluctuates severely.) There is no malfunction in the load, and the circuit of the present invention can be used to simplify the use of the circuit by increasing or decreasing the number of conductor penetrations on the primary side of the current transformer from one of the smallest horsepower to several thousand horsepower as a relay. It is possible to reduce the production cost, and the power supply can be voltage drooped by using a condenser for the alternating current, to operate a small DC relay, which can reduce the power consumption as much as possible, and can be used for both 110V-220V. It can be used as a no-voltage relay and induction disk overvoltage It can function as two kinds of relays and ammeter, so it can be used for various purposes. It has temperature compensation so that it does not affect the change of ambient temperature (-20 ℃ ~ 70 ℃), and it is characterized by compact and compact. And by removing and bypassing the sub-locking diode installed in the secondary side of the current transformer in Figure 2, it can be used as a grounding relay (ground relay) is a very ideal that can be used as a multi-function relay.

Claims (7)

In a circuit in which secondary terminals of the current detection current transformers CT ₁ (CT ₂ ) and CT _{3 of the} three-phase AC input terminals R, S, and T are connected, respectively, the current transformer is a bridge rectifier circuit for power supply. (DR) is connected to the ground point and the other terminal of the current transformer is connected to the terminal point (a) through the diodes (D ₁ , D ₂ , D ₃ ) to the thermistor (TH) and the variable resistor ( VR ₁ ) and resistors (R ₁ , R ₂ ) are connected to the base side of transistors (Q ₂ , Q ₅ ) and input to the naked gates (G ₁ to G ₇ ) of the CMOS integrated circuit to emit light as an overload identification circuit. Overload signal accumulation prevention circuit consisting of negative (-) double voltage rectifier circuit (B), resistors (R ₈ , R ₉ ), capacitors (C ₉ ) and transistors (Q ₃ ) connecting a diode (LED), automatic return overload The signal of the last gate of the naked gate (G ₄ ) generated by the operation of the relay unit (D), delay circuit unit (E), and instantaneous element setting unit (A) and the like is directly connected to the bridge rectifier circuit (DR). An electronic overcurrent relay, characterized in that the auxiliary relay RY is connected in series at both ends of the transistor Q ₄ before the furnace passes to operate the auxiliary relay to cut off the overcurrent when the overcurrent occurs. The method of claim 1, wherein the variable terminal of the variable resistor (VR ₂ ) is connected to the base terminal of the transistor (Q ₁ ), the collector is connected to the input side of the naked gate (G ₁ ) and the resistor (R ₅ ) and the hard gate (G). ₁ ) Through the diode (D ₇ ) and the variable resistor (VR ₃ ), the naked gate (G ₂ ), the variable resistance (VR ₄ ) for adjusting the return time, the diode (D ₁₀ ) and the naked gate (G ₃ , G ₄ ) The bias resistor (R ₁₁ ) of the transistor (Q ₄ ) is connected in series, and the capacitor (C ₂ ) is connected between the input of the naked gate (G ₂ ) and the ground point, and the input and hard gate of the naked gate (G ₂ ) are connected. Between the output side of (G ₃ ), the overload operation holding composed of the resistor (R ₁₇ ), the diode (D ₁₄ ) and the diode (D ₅ ) is connected, and the feedback circuit of the operation indication holding circuit is connected and the resistor (R ₈ , R ₉ ), An overload signal accumulation prevention circuit consisting of a capacitor (C ₉ ) and a transistor (Q ₃ ) and a resistor (R ₇ ), a capacitor (C ₁ ), and a diode (D ₈ , D ₉ ) Configure and connect negative double voltage rectifier circuit part (B), and identify overload consisting of diode (D ₆ ), resistor (R ₆ ) and light emitting diode (LED) between the output of the gate (G ₁ ) and the ground point. An electronic overcurrent relay comprising a passive reset circuit comprising a circuit, a resistor (R ₁₀ ), and a reset button switch (S ₂ ) to have inverse time characteristics. The instantaneous element setting unit A connects the thermistor TH between the terminal point (a) and the ground point, and connects the resistors R ₁ and R ₂ and the variable resistor VR ₁ to the angular terminals thereof. An electronic overcurrent relay, characterized in that connected in series and connected from the variable terminal of the variable resistor (VR ₂ ) to the base side of the transistor (Q ₅ ) and its emitter terminal connected to the ground point. The circuit check unit F according to claim 1, wherein the circuit check unit F is connected between the terminal point a and the terminal point b by connecting the test button switch S ₁ , the resistor R ₁₃ , and the diode D ₄ in series. Electronic overcurrent relay, characterized in that the circuit test is possible by connecting to or between the input side of the naked gate (G ₁ ) and the ground point. The method according to claim 1, wherein the terminal point (2) of the selector switch (SW ₃ ) is brought into contact with the terminal point (3) to ground through the capacitor (C ₃ ) and the naked gate (G ₇ ) through the diode (D ₁₁ ). The overcurrent input signal is input to the base side of the transistor (Q ₂ ) via the selector switch (SW ₁ ), and the collector is connected through the input terminal of the naked gate (G ₅ ) and the resistor (R ₁₅ ). The delay circuit part E connected to the terminal point (b) and the variable resistor (VR ₅ ) and the diode (D ₁₃ ) are connected in parallel through the naked gate (G ₆ ), the diode (D ₁₅ ), and the naked gate (G ₆ ). Form and connect the naked gate (G ₇ ) to its terminal point, connect the capacitor (C ₄ ) between the input side of the naked gate (G ₆ ) and the terminal point (b), and also through the feedback diode (D ₁₂ ) natdeu stylized gate connected to the output side of the (C ₃₎ and ground through a resistance (R ₁₆₎ between condenser natdeu gate input side and the terminal point (b) of (G ₇₎ Electronic overcurrent relay, characterized in that the (C ₅₎ connected to the set to have a visibility attribute. The method of claim 1, wherein an AC input power terminal (L ₁ ) (L ₂ ) is connected to the bridge rectifier circuit (DR), and an inrush current preventing resistor (R ₁₉ ) and a voltage diminishing phase alternating current are connected to the terminal (L ₂ ) side thereof. a capacitor (C _a) a connection, and having a constant-voltage circuit hayeoseo connect its bridge rectifier circuit resistance in direct current side terminal of the (DR) (R ₁₈₎ and capacitor (C ₆₎ (C ₇₎ and a Zener diode (ZD) for Electronic overcurrent relay, characterized in that. 2. The automatic return overload relay section according to claim 1, wherein the selector switch SW ₂ is switched to be connected to the terminal points 3 and 4 so as to be connected between the terminal point b side and the input side of the naked gate G ₃ . Electronic overcurrent relay, characterized in that by connecting the capacitor (C ₈ ) constituting the D).

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