KR19990033937U - Coil Drive Circuit of Magnetic Contactor - Google Patents

Abstract

The present invention relates to a coil driving circuit of a magnetic contactor. In the related art, the resistance value of a coil changes according to the ambient temperature when power is applied to the magnetic contactor. Increasing the holding force of the magnetic contactor, which increases the holding force of the coil driving circuit of the magnetic contactor, shortening the lifespan, and reducing the holding current at high temperature, thus reducing the holding force than at room temperature. . Therefore, the present invention has an effect of maintaining a high reliability for the use temperature environment by preventing the malfunction caused by out of the use temperature range during outdoor installation by widening the use temperature range of the magnetic contactor.

Description

Coil Drive Circuit of Magnetic Contactor

The present invention relates to a coil driving circuit of a magnetic contactor, and in particular, by widening the operating temperature range of the magnetic contactor to prevent malfunction caused by out of the operating temperature range during outdoor installation, thereby maintaining high reliability for the operating temperature environment. It relates to a coil drive circuit.

1 is a coil drive circuit diagram of a conventional magnetic contactor, and as shown therein, a rectifier 1 for receiving and rectifying a power supply voltage; A voltage divider 2 for receiving the signal output from the rectifier 1 and dividing the signal to a low voltage; A constant voltage unit (3) for receiving a rectified DC power (DC) from the rectifier (1) to generate a constant voltage; A voltage detector (4) for receiving a low voltage of the voltage dividing unit (2) and a constant voltage of the constant voltage unit (3) and outputting a detection signal when the voltage becomes higher than a set value; ONE SHOT PULSE (hereinafter referred to as an OE SPIR business card; 5) for generating a pulse signal by receiving the detection signal of the voltage detector 4 and the constant voltage of the constant voltage unit 3; A constant current signal part 6 for receiving a pulse signal from the OS skin 5 and outputting a suction and holding level; A sawtooth wave generator 7 for receiving a detection signal of the voltage detector 4 and outputting a sawtooth wave at a predetermined period; A comparison unit (8) for comparing the signals output from the constant current signal unit (6) and the sawtooth wave generator (7); A power switching unit 9 for controlling the on / off current flowing through the coil of the magnetic contactor according to the comparison signal output from the comparing unit 8; It consists of a surge absorbing portion 10 for absorbing back electromotive force generated in the coil when the current flowing through the coil of the magnetic contactor by the power switching unit 9 is blocked and energized.

The voltage detector 4 connects a resistor R1 applied with a constant voltage and a resistor R2 grounded at one side thereof, and connects a connection point thereof to an inverting terminal (−) of the first op amp U1, and divides the voltage. The resistor R3 to which the divided voltage output from the unit 2 is applied is connected to the resistor R4 having one side grounded, and the connection point thereof is connected to the non-inverting terminal + of the first op amp U1. In the first op amp U1, a resistor R5 is connected between the non-inverting terminal (+) and the output terminal.

The OS skin 5 connects the voltage detection signal output from the voltage detector 4 in series with a resistor R6 having one side grounded through the capacitor C1 in sequence, and connects the capacitor C1 and the resistor R6. ) Is connected to the inverting terminal (-) of the second op amp U2, a resistor R7 applied with a constant voltage and a resistor R8 grounded at one side thereof are connected, and the connection point is connected to the second op amp (2). A non-inverting terminal (+) of U2) is connected, and a pulse signal is output from the output terminal of the second op amp U2.

The constant current signal unit 6 is configured to connect a resistor R10 applied with a constant voltage and a resistor R11 grounded at one side thereof, and to be connected to an output terminal of the OS skin 5 through the resistor R9 at the connection point. .

The comparison unit 8 receives the signal output from the sawtooth wave generator 7 to the inverting terminal (−) of the third op amp U3 and non-inverts the signal output from the constant current signal unit 6. When applied to the terminal (+), the output signal of the third op amp U3 is configured to output a comparison signal.

The power switching unit 9 has a source grounded and a coil connected to the drain of the FET which is electrically controlled by receiving a signal from the comparator 8 to the gate.

The surge absorbing unit 10 is configured by the diode D1 being connected in parallel to the coil connected to the drain of the FET in a reverse direction.

When a power supply voltage as shown in (a) of FIG. 2 is applied, the voltage is rectified through the rectifier 1, and the constant voltage unit 3 receives a signal output from the rectifier 1 to generate a constant voltage. In addition, the voltage divider 2 divides the voltage of the rectifier 1 into a low voltage and outputs the divided voltage.

Accordingly, the voltage detector 4 receives the divided voltage of the voltage dividing unit 2 and the voltage divided by the voltage division law of the resistors R3 and R4 receives the non-inverting terminal of the first op amp U1. + And a voltage divided by the voltage division law of the resistor R1 and the resistor R2 is applied to the inverting terminal (-) of the first op amp U1. When the voltage exceeds the set value, the detection signal as shown in FIG. 2B is output by the hysteresis characteristic of the first op amp U1.

At this time, the OS skin 5 receives the detection signal and outputs a single square wave having a constant magnitude as shown in FIG. 2 (c), wherein the output voltage of the constant current signal part 6 is The output voltage of the constant current signal section 6 after the square wave is output is Becomes That is, the output voltage in the constant current signal section 6 varies according to the output of the square wave, and outputs the suction and sustain levels, and the sawtooth wave generator 7 receives the output signal of the voltage detector 4 in Fig. 2 (e). Outputs a sawtooth wave signal having a constant period as shown in Fig. 2), and the comparing unit 8 compares the output signals of the constant current signal unit 6 and the sawtooth wave generating unit 7 as shown in FIG. Outputs a square wave, and the power switching unit 9 receives a signal from the comparator 8 to switch the coil of the magnetic contactor so that a suction current and a holding current are applied to the coil, and is sucked when the suction current is applied. After the suction operation is completed, the holding current is applied to perform the holding operation, and the counter electromotive force generated in the coil of the magnetic contactor when the power switching unit 9 is turned on or off is absorbed by the diode D1 of the surge absorbing unit 10. do.

However, in the conventional technology as described above, the resistance value of the coil changes according to the ambient temperature when the power is applied to the magnetic contactor and then maintained, so that the magnetic contactor increases the holding current at low temperature and increases the holding force. There was a problem in that the magnetic contactor malfunctioned because it impeded the power switching part of the coil drive circuit of the contactor to shorten the lifespan, and the holding current was decreased at high temperature and the holding force was reduced than at room temperature.

Therefore, the present invention has been devised to solve the conventional problems as described above, and by widening the use temperature range of the magnetic contactor to prevent malfunction caused by out of the use temperature range at the time of outdoor installation to prevent high operating temperature environment It is an object of the present invention to provide a coil driving circuit of a magnetic contactor to maintain reliability.

1 is a coil drive circuit diagram of a conventional magnetic contactor.

FIG. 2 is a waveform diagram of each part of FIG. 1.

3 is a coil drive circuit diagram of a magnetic contactor according to the present invention.

4 is a waveform diagram of each part according to the change in ambient temperature of FIG. 3.

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

1: rectification part 2: partial pressure part

3: constant voltage unit 4: voltage detection unit

5: OS skin 6: Temperature compensation constant current signal part

7: Sawtooth wave generating unit 8: comparing unit

9: power switching unit 10: surge absorption unit

U1 to U3: Op amp R1 to R14: Resistance

T1: Thermistor SUM: Adder

FET: FT D1: Diode

Coil drive circuit of the present invention magnetic contactor for achieving the above object is in the magnetic contactor consisting of a rectifier, a voltage divider, a constant voltage unit, a voltage detection unit, OS skin, a comparison unit, a power switching unit and a surge absorption unit, It is achieved by receiving a pulse signal from the temperature compensation constant current signal portion for outputting the suction, the maintenance level according to the ambient temperature, will be described in detail below with reference to the accompanying drawings an embodiment according to the present invention.

3 is a coil drive circuit diagram of a magnetic contactor to which the present invention is applied, and the rectifier 1 receives and rectifies a power supply voltage as shown therein; A voltage divider 2 for receiving the signal output from the rectifier 1 and dividing the signal to a low voltage; A constant voltage unit (3) for receiving a rectified DC power (DC) from the rectifier (1) to generate a constant voltage; A voltage detector (4) for receiving a low voltage of the voltage dividing unit (2) and a constant voltage of the constant voltage unit (3) and outputting a detection signal when the voltage becomes higher than a set value; An OS skin 5 for receiving a detection signal of the voltage detector 4 and a constant voltage of the constant voltage unit 3 to generate a pulse signal; A temperature compensation constant current signal part 6 which receives a pulse signal from the OS skin 5 and outputs a suction and holding level according to the ambient temperature; A sawtooth wave generator 7 for receiving a detection signal of the voltage detector 4 and outputting a sawtooth wave at a predetermined period; A comparison unit (8) for comparing the signal output from the temperature compensation constant current signal unit (6) and the sawtooth wave generator (7); A power switching unit 9 for controlling the on / off current flowing through the coil of the magnetic contactor according to the comparison signal output from the comparing unit 8; It consists of a surge absorbing portion 10 for absorbing back electromotive force generated in the coil when the current flowing through the coil of the magnetic contactor by the power switching unit 9 is blocked and energized.

The temperature compensating constant current signal part 6 connects a resistor R10 applied with a constant voltage and a resistor R11 grounded at one side thereof, and is connected to the output terminal of the OS skin 5 through the resistor R9 at the connection point. In addition, it is connected to the input terminal (a) of the adder (SUM), and connected a resistor (R12) applied with a constant voltage and a resistor (R13) grounded at one side, and the connection point is connected to the resistor (R14) and one side at the ground. The thermistor T1 is connected in series and the connection point is configured to be connected to the input terminal b of the adder SUM.

When a power supply voltage is applied, the voltage is rectified through the rectifier 1, and the constant voltage unit 3 receives a signal output from the rectifier 1 to generate a constant voltage, and the voltage divider 2 generates the rectifier ( The voltage of 1) is divided into low voltage and output.

Accordingly, the voltage detector 4 receives the divided voltage of the voltage dividing unit 2 and the voltage divided by the voltage division law of the resistors R3 and R4 receives the non-inverting terminal of the first op amp U1. + And a voltage divided by the voltage division law of the resistor R1 and the resistor R2 is applied to the inverting terminal (-) of the first op amp U1. When the voltage exceeds the set value, the detection signal is output by the hysteresis characteristic of the first op amp U1.

At this time, the OS skin 5 receives the detection signal and outputs one square wave having a constant magnitude, and at this time, the voltage inputted from the temperature compensation constant current signal part 6 to the input terminal a of the adder SUM ( Va) is The voltage Va of the input terminal a after the square wave is output is The voltage Vb of the other input terminal b becomes Vcc1 (T1 / (T1 + R14)). At this time, the output of the adder becomes (Va + Vb), where the input terminal voltage Va receives the output of the OS skin 5 and converts it to the level of suction and holding, and the other input terminal voltage Vb is the ambient temperature. As the resistance value of the thermistor T1 changes, it changes in proportion. Here, the thermistor T1 is a variable resistance element having negative temperature characteristics as shown in FIG. 5.

Since the output of the temperature compensating constant current signal part 6 is output in inverse proportion to the ambient temperature, the duty ratio of the comparator 8 also changes accordingly, and thus the on / off ratio of the power switching unit 9 also changes. At this time, the current flowing through the coil of the magnetic contactor As the ambient temperature changes to low temperature, room temperature, and high temperature, the resistance component of the coil becomes large, and on the contrary, the duty ratio of the comparator 8 becomes smaller and smaller. It remains constant regardless of change.

On the other hand, the sawtooth wave generator 7 receives the output signal of the voltage detector 4 and outputs a sawtooth wave signal having a predetermined period, and the comparison unit 8 is the temperature compensation constant current signal unit 6 and the sawtooth wave generator 7 The square wave is output by comparing the output signal of the power source, and the power switching unit 9 receives the signal of the comparator 8 to switch the coil of the magnetic contactor so that the suction current and the holding current are applied to the coil. Is sucked, and after completion of the suction operation, a holding current is applied to perform the holding operation.

Accordingly, the magnetic contactor has a constant holding force, and the counter electromotive force generated in the coil of the magnetic contactor when the power switching unit 9 is turned on or off is absorbed by the diode D1 of the surge absorbing unit 10.

As described above, the coil drive circuit of the inventive magnetic contactor widens the operating temperature range of the magnetic contactor, thereby preventing malfunctions caused by being out of the operating temperature range during outdoor installation, thereby maintaining high reliability in the operating temperature environment. It works.

Claims (2)

In the magnetic contactor consisting of rectifier, voltage divider, constant voltage unit, voltage detector, OS skin, comparator, power switching unit and surge absorbing unit, a pulse signal is input from the OS skin and outputs suction and holding levels according to the ambient temperature. A coil drive circuit of a magnetic contactor comprising a temperature compensation constant current signal portion. According to claim 1, wherein the temperature compensation constant current signal unit, a resistor connected to a constant voltage and grounded on one side in series, and connected to the input terminal of the adder and connected to the output terminal of the OS through the resistance to the connection point. And a resistor connected with a constant voltage and a grounded one side in series, and a connection point connected in series with a resistor and a grounded one side thermistor connected to the input terminal of the adder. Coil driving circuit.