KR880001584Y1 - Inrushing current probihit apparatus of inductive load - Google Patents

Abstract

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Description

Inrush current prevention device for power supply of inductive load

1 is a schematic configuration diagram of an apparatus of the present invention.

2 is a circuit diagram of the present invention.

3 (a), 3 (b) and 3 (c) are diagrams of voltage waveforms of respective portions of the circuit.

The present invention connects the instantaneous power failure detection unit and the instantaneous power failure delay unit with the microprocessor to reduce the inrush current generated from the inductive load during the momentary power failure in the power device supplied to the inductive electrical equipment. When the power failure detection unit detects this, it cuts off the power momentarily and at the same time, cuts off the power control signal from the microprocessor and turns on the power control triac at zero crossing point of current when the power is turned on again. In addition, the present invention relates to a configuration of an inrush current prevention device for a power supply device of an inductive load which outputs a power control signal to control power and protects an element of the power control stage from damage caused by inrush current.

In the conventional power control device, the excessive inrush current generated from the inductive load during the momentary power failure of the power source is not reduced, so that an excessive force is applied to the power control stage, thereby preventing the smooth power control. There was a problem that was often damaged.

In order to solve the above problems, the present invention cuts off the power control signal according to the signal detected by the momentary power failure of the power supply to reduce the inrush current generated from the inductive load to protect the parts and to improve the life of the device. It is designed to extend and improve reliability.

The configuration of the device of the present invention will be described with reference to FIGS. 1 and 2 as follows.

That is, the emitter of the electrostatic detection unit 2 through the resistor R ₁ in the diode D ₅ cathode of the constant voltage circuit unit 1 so that the DC output of the constant voltage circuit unit 1 is sensed by the electrostatic detection unit 2. It is connected to the base of the grounded transistor (Q ₁ ), the collector is connected to one input (+) of the comparator (B), and the power (-V ₁ ) voltage is connected to the other input (-) of the comparator (B). R _5, R ₆ ) to be divided and applied, and the output of the comparator (B) outputs the diode D ₆ so that the output signal of the blackout detecting unit 2 can be delayed by the blackout time delay unit 3 for a predetermined time. Through R, C charging and discharging circuits (R _8, R ₄ ) through and connected to one input (-) of the comparator (C), the other input (+) the power supply (-V ₁ ) voltage (R ₉ , R ₁₀₎ applied to, and is divided ever, the power failure time delay unit (3) the output signal is a microprocessor (4), a power failure detecting terminal (the emitter and the control signal output terminal (P ₂₎ at the same time, input to P ₁₎ of the The hayeoseo will be entered to the base of the transistor (Q ₂₎ connected in the power control section 5.

Reference numeral P ₃ : Terminal of the microprocessor 4 to which the signal detecting the "0" intersection point of the alternating current is input, T ₁ : Triac, RY: Relay, A: Integrated circuit for constant voltage 6: AC 0 cross detector to be.

Effects of the present invention are as follows.

In normal operation, since the DC voltage rectified by the diodes D ₁ and D ₂ is applied to the base of the transistor Q ₁ through the resistors R ₁ and R _{2 as} shown in FIG. ₂ , the transistor Q _Since the base voltage of ₁ ) is always lower than the emitter voltage by a constant voltage V _RE1 , the transistor Q ₁ is in an on state, so the collector voltage of the transistor Q ₁ becomes OV.

Therefore, since the input (+) of the comparator (B) is OV, its output is also OV, and the voltage across the capacitor C ₄ of the blackout time delay unit 3 is also charged from -V ₁ to OV. Therefore, the output of the comparator (C) outputs the power (-V ₁ ) voltage, so the power failure detection terminal (P ₁ ) of the processor 4 detects the level of the voltage (-V ₁ ) to perform the normal operation. do.

That is, the processor 4 outputs a control signal at the control signal output terminal P ₂ at the portion where the input AC voltage is maximum (the portion where the phase angle is 90 ° in AC 6OHZ), and according to the control signal, a normal operation is performed. As a result, the triac T ₁ of the power control unit 5 acts to smoothly adjust the power source ACV. If there is a momentary power failure even during half cycle of AC 6OHZ, it should detect this and cut off the output.

In other words, when a power failure occurs for half a period, the voltage waveform appearing across the capacitor C ₁ becomes like the dotted line in FIG. 3 (a), and the voltage difference between the emitter and the base of the transistor Q ₁ is the transistor conduction voltage Transistor Q ₁ is turned off by falling below V _{RE 1} ).

Therefore, the collector voltage of the transistor Q ₁ becomes -V ₁ , and the output voltage of the comparator (B) also becomes -V ₁ , thereby sequentially discharging the voltage charged in the capacitor C ₄ , thereby reducing the output of the comparator C. Invert to OV. Therefore, since a signal indicating that a power failure is input is input to the power failure detection terminal P _{1 of the} processor 4, the processor 4 immediately turns off the output P ₂ , and the processor 4 detects the power failure for a predetermined time. During the blackout time delay unit 3, the delay is set as shown in FIG. 3 (c).

Until steady state, that is, the output of the processor 4, a power failure detecting terminal control signal output terminal (P ₂₎ until the voltage -V ₁ is detected (P ₁₎ of maintains an OFF state, when the normal state Detects the zero crossing point of the power supply (ACV) at the terminal (P ₃ ) and calculates the point at which the voltage is maximum, that is, the point where the phase of the voltage waveform is 90 °, to give the output (P ₂ ) This will significantly reduce the inrush current at.

As such, the present invention can protect the circuit components by reducing the inrush current generated from the inductive load during the momentary power failure of the power supply, which not only prolongs the life of the device but also eliminates the need to add circuits for component protection as in the prior art. Cost reduction and circuit configuration have been simplified.

Claims (1)

Rectifying the commercial AC input (AC) diodes via a (D _1, D _2), the constant-voltage integrated circuit (A) connected to a constant voltage circuit (1), a rectifier diode (D _1, D ₂₎ and the constant-voltage IC (A) of A diode D ₅ is provided between the diode D ₅ and the rectifier diodes D ₁ and D _2. The collector of the transistor Q ₁ has a comparator with a reference potential supplied to the input (B). Connect to the base of the transistor Q ₁ of the electrostatic detection unit 2 connected to the input (+) of the ground, and ground it with a diode D ₃ , D ₄ and a capacitor C ₁ , The output of the comparator (2) of 2) is a power failure time delay unit (3) having a capacitor (C ₄ ) and a diode (D ₆ ) connected to an input (-) of a comparator (C) to which a reference potential is supplied to an input (+). It is connected to the input (-) of the comparator (C) through the diode (D ₆ ) of the output, the output of the comparator (C) is connected to the contact of the relay Ry and the gate of the triac (T ₁ ) The transistor Emitter to the output of the (Q ₂₎ the power control section 5 and the transistor zero crossing detector 6 is connected to the connection to the base and at the same time the input power source (AC) of the (Q ₂₎ of the connected to the collector of the P terminal (P ₃₎ It is connected to the electrostatic detection terminal (P ₁ ) of the connected microprocessor (4), the control signal output (P ₂ ) of the microprocessor (4) is connected to the emitter of the transistor (Q ₂ ), the increasingly portion of the relay (Ry) Inrush current prevention device for power supply of inductive load connected to the gator terminal of triac (T ₁ ) and one side of AC power output