KR100271665B1 - Coil driving apparatus of electronic contactor - Google Patents

Abstract

PURPOSE: A coil driving device of an electronic contact is provided to extend the life span of the electronic contact by minifying the arc generated in a main contact and rapidly absorbing the count electromotive force generated from the coil. CONSTITUTION: A rectifying section(11) receives the voltage through an input terminal(10) and rectifies the voltage so as to output a direct current voltage. A potential divider(12) receives the direct voltage from the rectifying section(11) and divide the voltage into low voltages. An electrostatic voltage section(13) generates the electrostatic voltage by receiving the direct current voltage. An input voltage detecting section(14) receives the electrostatic voltage so as to output a sucking signal or releasing signal. A pulse section(15) outputs a PWM signal. A square wave generating section(16) is provided to generate the square wave having a constant frequency. A power switching section(18) receives a signal from an output section(17) so as to control the current flowing through the coil. A flywheel section(20) is provided to rapidly absorb the count electromotive force.

Description

Coil Driving Device for Magnetic Contactor {COIL DRIVING APPARATUS OF ELECTRONIC CONTACTOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a coil driving device of a magnetic contactor, and more particularly, to a coil driving device of a magnetic contactor capable of quickly absorbing energy remaining in a coil upon release of the magnetic contactor so as to shorten the release time of the magnetic contactor.

1 is a circuit diagram of a coil driving apparatus of a conventional magnetic contactor, and as shown therein, a rectifying unit 11 for receiving a power supply voltage through an input terminal 10 and rectifying it to output a DC voltage; A voltage dividing unit 12 which receives the DC voltage of the rectifying unit 11 and divides the DC voltage into low voltages; A constant voltage unit 13 for receiving a DC voltage of the rectifier 11 to generate a constant voltage; The input voltage detector 14 receives the divided voltage of the voltage dividing unit 12 and the constant voltage of the constant voltage unit 13 and outputs a suction signal when the voltage rises above the suction voltage setting value or outputs a release signal when the voltage falls below the suction voltage setting value. Wow; A pulse unit 15 for outputting a pulse width modulated signal corresponding to the energization time of the suction current of the coil by the signal detected by the input voltage detector 14; A square wave generator (16) which receives a detection signal of the input voltage detector (14) and a pulse width modulated signal of the pulse unit (15) and generates a square wave having a constant frequency accordingly; An output unit 17 for receiving the pulse width modulation signal of the pulse unit 15 and the square wave signal of the square wave generator 16 and outputting the sum signal; A power switching unit 18 for receiving a signal from the output unit 17 and controlling a current flowing through the coil accordingly; The output of the rectifier 11 and the anode of the first diode (D11) is connected, and the capacitor (C11) in parallel with the cathode of the first diode (D11) and the cathode of the second diode (D12), and The anode terminal of the first diode D11 is connected to the base of the N-type transistor Q11 through a first resistor R11, and the n-type transistor Q11 is connected to the cathode terminal of the second diode D12. The emitter terminal of the third diode (D13) and the anode of the third diode (D13) connected to the connection point of the coil and the power switching unit (11) of the ENP transistor (Q11) The collector is connected, and the varistor ZNR1 is connected in parallel to the emitter and the collector terminal of the ENP transistor Q11, so that the counter electromotive force remaining in the coil when the power switching unit 18 is turned off. It consists of a flywheel unit 19 for absorbing for a certain time, The operation of the conventional apparatus configured as described above will be described with reference to the timing diagram of FIG.

First, when a power supply voltage such as (a) of FIG. 2 is applied to the input terminal 10, the power supply voltage is rectified through the rectifier 11, and the voltage divider 12 is separated from the rectifier 11. The rectified DC voltage is output and divided into low voltages to be output, and the constant voltage unit 13 receives the rectified DC voltage output from the rectifier 11 to generate a constant voltage.

At this time, the input voltage detector 14 receives the divided voltage of the voltage dividing unit 12 and the constant voltage of the constant voltage unit 13 and outputs a suction signal corresponding thereto as shown in FIG. The pulse unit 15 receives the constant voltage of the constant voltage unit 13 and the suction signal as shown in (b) of FIG. 2 of the pressure voltage detection unit, and thus corresponds to the energization time of the coil COil according to FIG. c) outputs a pulse width modulated signal as shown in FIG. 2, wherein the square wave generator 16 is a suction signal such as (b) of FIG. 2 of the input voltage detector 14 and (b) of FIG. A pulse width modulated signal as shown in c) is input to generate a square wave having a constant frequency as shown in FIG.

Thereafter, the output unit 17 receives the square wave signal as shown in FIG. 2 (d) of the square wave generator 16 and the pulse width modulated signal as shown in FIG. In addition, a signal as shown in FIG. 2E is output, and accordingly, the power switching unit 18 receives an output signal as shown in FIG. 2E as shown in FIG. The current i1 flowing is controlled.

That is, while the power switching unit 18 is turned on by the square wave signal as shown in FIG. 2 (d) of the square wave generating unit 16, the capacitor C11 of the flywheel unit 19 is connected to the diodes D11 and D12. When the charge is charged as much as the voltage drop of the power, when the power switching unit 18 is off, the charge charged in the capacitor (C11) is discharged through the resistor (R11) is applied to the base of the ENP transistor Q11, Accordingly, when the NPT transistor Q11 is turned on and the power switching unit 18 is turned on, current and back electromotive force (force generated when the coil is turned on / off) are transferred through the NPT transistor Q11. By again flowing to the coil COIL, the current i1 flows through the coil COIL as shown in FIG.

At this time, since the full discharge time of the capacitor C11 is longer than the off time of the power switching unit 18, and the power switching unit 18 repeatedly turns on / off, the coil CO1 of FIG. A constant current i2 such as) flows to provide a constant holding force to the magnetic contactor.

Thereafter, when the power supply voltage as shown in FIG. 2 (a) input to the input terminal 10 falls below the release voltage or the supply of the power supply voltage is cut off, the input voltage detection unit 14 outputs the low potential release voltage. The switching unit 18 is turned off.

Accordingly, when charge accumulated in the capacitor C11 of the flywheel unit 19 is applied to the base of the ENP transistor Q11 through the resistor R11, the ENP transistor Q11 is connected to the coil (C11) while being conducted. The charge accumulated in the COIL is consumed so that the current i2 flows through the N-type transistor Q11, and then, the charge accumulated in the capacitor C11 is consumed and the base of the N-type transistor Q11 is used. If no current is applied to the nP transistor Q11, the n-type transistor Q11 is turned off, so that the residual current i3 such as (h) of FIG. 2 remaining in the coil COIL is consumed in the varistor ZNR1, and the residual current When (i3) falls below the suction holding force of the magnetic contactor, the magnetic contactor is released.

However, in the conventional apparatus operating as described above, the counter electromotive force is applied to the power switching unit and the ENP transistor during the delay time when the ENP transistor is turned on after the power switching unit is turned off, and the varistor absorbs more than the set value of the varistor. The remaining current is naturally dissipated by the core of the magnetic contactor and is released as a ratio when it falls below the suction holding force of the magnetic contactor. Therefore, the release time may be delayed.

Accordingly, the present invention devised in view of the above problems provides a coil driving device of a magnetic contactor to shorten the release time of the magnetic contactor by quickly absorbing the energy remaining in the coil when the magnetic contactor is released. There is this.

1 is a circuit diagram showing the configuration of a conventional magnetic contactor coil drive device.

2 is a timing diagram of each part in FIG. 1;

Figure 3 is a circuit diagram showing the configuration of the magnetic contactor coil drive device of the present invention.

4 is a timing diagram of each part in FIG. 3;

***** Description of the symbols for the main parts of the drawings *****

10: input terminal 11: rectifier

12: voltage divider portion 13: constant voltage portion

14 input voltage detector 15 pulse unit

16: square wave generator 17: output unit

18: power switching part 20: flywheel part

SCR1: Thyristor

The present invention for achieving the above object is an input voltage detection unit for receiving a divided voltage and a constant voltage and outputs a suction signal for the rise above the suction voltage set value or a release signal when falling below the set release voltage, and the input voltage A pulse unit for outputting a pulse width modulated signal corresponding to the energization time of the coil suction current by the signal detected by the detector, and receiving the detection signal and the pulse width modulated signal of the input voltage detector and generating a square wave accordingly; In the coil drive device of a magnetic contactor comprising a square wave generator, an output unit for adding the pulse width modulation signal and the square wave and outputting the power wave, and a power switching unit for controlling a current flowing through the coil by the output signal of the output unit. One terminal of the coil is connected to the anode of the diode and the other terminal of the diode Connect the cathode of the diode and the anode of the thyristor, ground the cathode of the diode, apply the detection signal of the input voltage detection unit to the base of the ENP transistor, and collect the ENP transistor. The constant voltage is applied to the gate and the gate of the thyristor is connected. The emitter of the ENP transistor is grounded and a capacitor is connected between the ground and the gate of the thyristor. It characterized in that it comprises a flywheel portion for quickly absorbing back electromotive force remaining in the coil when the power switching unit is turned off by the constant voltage.

Hereinafter, with reference to the accompanying drawings, the operation and effects of the coil drive device of the magnetic contactor according to the present invention will be described in detail.

Figure 3 is a circuit diagram showing an embodiment of the coil drive device of the magnetic contactor of the present invention, as shown in the rectifier 11 for receiving a power supply voltage through the input terminal 10 and rectifying it to output a DC voltage Wow; A voltage dividing unit 12 which receives the DC voltage of the rectifying unit 11 and divides the DC voltage into low voltages; A constant voltage unit 13 for receiving a DC voltage of the rectifier 11 to generate a constant voltage; The input voltage detector 14 receives the divided voltage of the voltage dividing unit 12 and the constant voltage of the constant voltage unit 13 and outputs a suction signal when the voltage rises above the suction voltage setting value or outputs a release signal when the voltage falls below the suction voltage setting value. Wow; A pulse unit 15 for outputting a pulse width modulated signal corresponding to the energization time of the suction current of the coil by the signal detected by the input voltage detector 14; A square wave generator (16) which receives a detection signal of the input voltage detector (14) and a pulse width modulated signal of the pulse unit (15) and generates a square wave having a constant frequency accordingly; An output unit 17 for receiving the pulse width modulation signal of the pulse unit 15 and the square wave signal of the square wave generator 16 and outputting the sum signal; A power switching unit 18 which receives a signal from the output unit 17 and controls a current flowing through the coil accordingly; The flywheel unit 20 receives the detection signal and the constant voltage of the input voltage detector 14 and quickly absorbs the counter electromotive force remaining in the coil when the power switching unit 18 is turned off.

In particular, the flywheel 20 is connected to the anode of the diode D21 to one terminal of the coil (COIL) and the cathode of the diode D21 to the other terminal, the cathode and the thyristor (D2) of the diode (D2) The anode of SCR1 is connected, the cathode of the thyristor SCR1 is grounded, the detection signal of the input voltage detector 14 is applied to the base of the ENP transistor Q2, and this ENP transistor Q2 is applied. The output terminal of the constant voltage section 13 and the gate of the thyristors SCR1 are connected to a collector of the ND transistor, and the emitter of the ENP transistor Q2 is connected to the ground, and between the ground and the gate of the thyristors SCR1. The condenser C21 is connected and configured, and the operation of one embodiment of the present invention will be described with reference to FIG.

First, the general operation is the same as in the prior art. That is, when the power supply voltage as shown in FIG. 4 (a) is applied to the input terminal 10, the power supply voltage is rectified through the rectifier 11, and the voltage divider 12 is rectified by the rectifier 11. The rectified DC voltage is output from the rectified DC voltage outputted from the rectifier 11 and receives the rectified DC voltage outputted from the rectifier 11 to generate a constant voltage.

At this time, the input voltage detector 14 receives the divided voltage of the voltage dividing unit 12 and the constant voltage of the constant voltage unit 13 and outputs a suction signal for the same as shown in FIG. The pulse unit 15 receives a constant voltage of the constant voltage unit 13 and a suction signal as shown in FIG. 4B of the input voltage detector 14 to correspond to the energization time of the coil. A pulse width modulated signal as shown in FIG. 4C is output, wherein the square wave generator 16 is a suction signal as shown in FIG. 4B of the input voltage detector 14 and the pulse unit 15 as shown in FIG. A pulse width modulated signal as shown in FIG. 4 (c) is input and a square wave signal having a constant frequency is generated as shown in FIG.

Thereafter, the output unit 17 receives the square wave signal as shown in (d) of FIG. 4 of the square wave generator 16 and the pulse width modulated signal as shown in (c) of FIG. In addition, the signal output as shown in (e) of FIG. 4 is added, and accordingly, the power switching unit 18 receives the output signal as shown in (e) of FIG. 4 of the output unit 17 and accordingly to the coil COIL. Control the current flowing through it.

At this time, while the power switching unit 18 is turned on by the square wave signal as shown in FIG. 4D of the square wave generating unit 16, a current i1 is applied to the coil COIL, and the power switching unit When 18 is off, the current i1 applied to the coil COil flows through the diode D21 while the power switching unit 18 is on, so that a constant current flows in the coil COIL. When the power switching unit 18 is turned off, a counter electromotive force such as (g) of FIG. 4 generated in the coil COIL is not applied to the power switching unit 18 without the diode D21. It flows through.

Here, when the power supply voltage is applied to the input terminal 10 below the release voltage or the supply of the power supply voltage is cut off, the input voltage detection unit 14 outputs a low potential release signal and the power switching unit 18 by the low potential release signal. ) Is off, and accordingly, the low potential release signal of the input voltage detection unit 14 is applied to the base of the ENP transistor Q2, so that the ENP transistor Q2 is turned off, and the gate of the die Lister SCR1 is turned off. A constant voltage is applied to the die thruster SCR1, so that the residual current as shown in FIG. 4 (h) remaining in the coil COIL flows to the ground through the die thruster SCR1, thereby releasing the magnetic contactor.

At this time, the condenser C21 is connected between the gate and the ground of the die thruster SCR1 in order to prevent the die thruster SCR1 from being turned on due to noise being applied to the gate of the thyristor SCR1.

As described in detail above, the present invention minimizes the arc generated at the main contact point by quickly absorbing the back EMF generated from the coil during coil driving and quickly dissipating the energy remaining in the coil when the magnetic contactor is released. There is an effect that can extend the electrical life of the magnetic contactor.

Claims (1)

An input voltage detector for outputting a suction signal when the divided voltage and the constant voltage rise above the suction voltage set value or a release signal when the voltage falls below the suction voltage set value; and a suction current of the coil by the signal detected by the input voltage detector. A pulse unit for outputting a pulse width modulated signal corresponding to an energizing time of a square wave, a square wave generator for receiving a detected signal of the input voltage detector and the pulse width modulated signal and generating a square wave according to the pulse width modulated signal; In the coil drive device of a magnetic contactor having an output unit for adding the square wave and outputting the power, and a power switching unit for controlling the current flowing through the coil by the output signal of the output unit, the coil driving device of the magnetic contactor connected to the anode of the diode The cathode of the diode is connected to the other terminal and is different from the cathode of the diode. The anode of the lister is connected, the cathode of the diester is grounded, the detection signal of the input voltage detector is applied to the base of the ENP transistor, and the constant voltage is applied to the collector of the ENP transistor, And the emitter of the ENP transistor is grounded, and a capacitor is connected between the ground and the thyristor gate, and the power switching unit is turned off by a constant voltage and a detection signal of the input voltage detector. Coil drive device for a magnetic contactor comprising a flywheel portion for quickly absorbing back electromotive force remaining in the coil.

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