KR100992587B1 - Rectifier circuit using super capacitor - Google Patents

Abstract

PURPOSE: A rectifier circuit is provided to perform compensation in an instantaneous outage or instantaneous voltage drop by using a super capacitor. CONSTITUTION: A bridge diode(10) changes an input AC voltage to a DC voltage. A super capacitor(20) is connected to an output terminal of the bridge diode. The super capacitor performs compensation in an instantaneous outage or instantaneous voltage drop. An initial charging limiting and peak current reducing unit is connected between the bridge diode and the super capacitor and limits a current size and reduces a peak current when the super capacitor is initially charged. A controller(40) controls the driving of the initial charging limiting and peak current reducing unit according to the charging amount of the super capacitor.

Description

Rectifier circuit using super capacitor

The present invention relates to a rectifying circuit using a supercapacitor.

In general, the rectifier circuit for alternating current to direct current is mainly used to rectify using a smoothing capacitor. The rectifier circuit is classified into single phase half wave, single phase full wave rectifier circuit, three phase full wave rectifier circuit, etc., and rectifies and outputs alternating current by direct current with a semiconductor device such as diode or SCR.

1 and 2 are views illustrating a general single-phase full-wave rectifying circuit and a three-phase full-wave rectifying circuit, respectively.

As shown, both the single-phase full-wave rectifying circuit and the three-phase full-wave rectifying circuit have a smoothing capacitor C1 (C2) having a capacitance of 100 to 10,000 μF (microfarad) at the output terminal of the bridge diode BD1 (BD2). It is connected in parallel.

In this case, since the smoothing capacitor C1 and C2 are simply configured to perform only a filtering function of the rectifier circuit, the smoothing capacitor C1 and C2 are not compensated for when an input power failure or a sag occurs.

Therefore, when an input power failure or an instantaneous voltage drop occurs in the conventional rectifier circuit configured as described above, an error or data loss of various controllers such as a server computer occurs.

In view of these problems, conventionally, the UPS (uninterrupted power supply) is used to prepare for an input power failure or an instantaneous voltage drop, but there is an inconvenience of using a separate independent UPS, and the UPS is usually composed of a battery. There was a problem with a slow response.

SUMMARY OF THE INVENTION An object of the present invention is to provide a rectifying circuit using a supercapacitor that enables uninterruptible compensation during instantaneous power failure or instantaneous voltage drop by using a high capacity supercapacitor to solve the above problems.

The rectifier circuit using the supercapacitor according to the present invention for achieving the above object is connected to the output of the bridge diode and converts the input AC voltage to a direct current voltage, and performs the role of distortion and ripple reduction, Connected between the supercapacitor and the bridge diode and the supercapacitor to output the charged charge for a few seconds in case of power failure or voltage drop of the input power, and the bridge diode and the supercapacitor, and the DC voltage converted from the bridge diode during the initial charge of the supercapacitor. The initial charge limit and peak current reduction unit that limits the current size charged in the supercapacitor and reduces the peak current, and after the power failure compensation of the supercapacitor by the instantaneous power failure or voltage drop, the power is restored to charge the supercapacitor. The charge that is charged to the supercapacitor when performed If the charge amount of the supercapacitor is less than the preset reference charge amount, the initial charge limit and the peak current reduction unit are controlled. If the charge amount of the supercapacitor exceeds the preset reference charge amount, only the supercapacitor is charged. It may include a control unit to block the operation of the initial charge limit and the peak current reducing unit until the.

At this time, the above-mentioned supercapacitor is preferably configured to have a capacitance of 50 to 100 Farad.

In addition, the reference charge amount preset in the above-described control unit is preferably set to 20 pro of the capacitor capacity of the supercapacitor.

In addition, the initial charge limit and the peak current reduction unit described above limits the initial current size of the switch that is switched when the amount of charge charged in the supercapacitor is less than the preset reference charge amount according to the control signal of the controller, and the DC power converted by the bridge diode. And a coil and a resistor for outputting by reducing the peak current, and the switches, the coils, and the resistors are preferably connected in parallel.

As described above, according to the rectifying circuit using the supercapacitor of the present invention, the uninterruptible compensation is performed by using a high capacity supercapacitor during instantaneous interruption or voltage drop, so that the power failure is not performed without using an independent equipment such as a conventional UPS. Compensation is possible, and when a power supply or inverter employing the rectifier circuit of the present invention is used, there is an effect of configuring a product that performs an uninterruptible function.

1 and 2 are views illustrating a general single-phase full-wave rectifying circuit and a three-phase full-wave rectifying circuit, respectively.
3 is a circuit diagram schematically illustrating a configuration of a rectifying circuit using a supercapacitor according to an embodiment of the present invention.

Hereinafter, a rectifier circuit using the supercapacitor of the present invention will be described in detail with reference to the accompanying drawings.

3 is a circuit diagram schematically showing the configuration of a rectifying circuit using a supercapacitor according to the present invention.

As shown in the drawing, the rectifier circuit of the present invention includes a bridge diode 10, a supercapacitor 20, an initial charge limit and a peak current reduction unit 30, a controller 40, and the like.

The bridge diode 10 converts the input AC voltage into a DC voltage and outputs it to the rear stage.

The supercapacitor 20 is connected to the output side of the bridge diode 10 to reduce distortion and ripple, and to charge the charged charge for a few seconds (for example, at 0.5 seconds) in the case of a momentary power failure or a voltage drop in the input power supply. 1 second compensation) to output the power failure compensation.

At this time, the above-mentioned supercapacitor 20 is also called an ultra capacitor and a high capacity capacitor, and is preferably configured to have a capacitance of 50 to 100F. The capacitance of 50 to 100F is about 15,000 times that of the capacitor used in the conventional rectifier circuit having a capacitance of about 6800μF.

The initial charge limit and peak current reduction unit 30 is connected between the bridge diode 10 and the supercapacitor 20, and is superimposed by the DC voltage converted by the bridge diode 10 during initial charging of the supercapacitor 20. Limiting the magnitude of the current charged in the capacitor 20 and reduces the peak current.

The controller 40 is restored after the power failure compensation of the supercapacitor 20 is performed by the momentary power failure or the voltage drop, and when the charge is performed on the supercapacitor 20, the controller 40 checks the amount of charge charged in the supercapacitor 20, and the super When the charge amount of the capacitor 20 is less than the preset reference charge amount, the initial charge limit and the driving of the peak current reduction unit 30 are controlled. When the charge amount of the supercapacitor 20 exceeds the preset reference charge amount, Until the charging of only 20) is performed, the initial charging limit and the driving of the peak current reduction unit 30 are blocked.

In this case, the reference charge amount preset in the controller 40 is most preferably set to 20 pro of the capacity of the supercapacitor 20, but may be arbitrarily changed according to the use environment.

On the other hand, the above-described initial charge limit and peak current reduction unit 30, the switch (SW) is switched when the amount of charge charged in the supercapacitor 20 in accordance with the control signal of the control unit 40 is less than the predetermined reference charge amount, It includes a coil (L) and a resistor (R) for limiting the initial current size of the DC power converted by the bridge diode (10) and reducing and outputting a peak current, the switch (SW), coil (L), resistor (R) ) Are each connected in parallel.

Next, an operation process of the rectifier circuit using the supercapacitor according to the exemplary embodiment of the present invention configured as described above will be described.

First, an AC voltage input from the outside is converted into a DC voltage through the bridge diode 10, and the supercapacitor 20 is charged by the DC voltage converted through the bridge diode 10.

At this time, since the capacitance of the supercapacitor 20 is approximately 15,000 times larger than the capacity of the capacitor of the conventional rectifier circuit, the first charge (for example, when driving the rectifier circuit for the first time, or according to the instantaneous power failure or instantaneous voltage drop) When the power is restored after the blackout compensation), when the initial current limit and the peak current reduction are not performed through the initial charge limit and the circuit configuration of the peak current reduction unit 30, damage to the device may occur.

To this end, the control unit 40 checks the charge amount charged in the supercapacitor 20, and as a result of the check, the charge amount of the supercapacitor 20 is less than 20 pro, which is a preset reference charge amount (where 20 is a numerical value of the embodiment of the present invention). If the value is applied in the example, and can be changed according to the use environment or the circuit design), the initial charge limit and the driving of the switch SW of the peak current reducing unit 30 are controlled to control the coil L and the resistance R. ) To limit the initial current size of the DC power converted by the bridge diode 10 and to reduce the peak current to output to the supercapacitor 20.

If the charge amount of the supercapacitor 20 exceeds 20%, which is the preset reference charge amount, the controller 40 controls the initial charge limit and the peak current reduction unit 30 until the full charge of the supercapacitor 20 is performed. The switch SW is turned off to allow the power to charge the supercapacitor 20 through an external input AC power source.

After the supercapacitor 20 is charged as described above, if a momentary power failure or an instantaneous voltage drop occurs, the charge charged in the supercapacitor 20 is output to the rear stage to compensate for the power failure. When the power is applied again after the removal, the charging of the supercapacitor 20 is performed again through the initial charge limit and the peak current reduction unit 30 as described above.

Accordingly, the present invention can compensate for the instantaneous power failure or voltage drop of less than 1 second only by the circuit configuration of the initial charge limit and the peak current reduction unit 30 and the supercapacitor 30 in the rectifier circuit. Products employing rectifier circuits can perform uninterrupted functions without the need for independent equipment such as a UPS.

Herein, while the present invention has been described with reference to the preferred embodiments, those skilled in the art will variously modify the present invention without departing from the spirit and scope of the invention as set forth in the claims below. And can be changed.

10: bridge diode
20: Supercapacitor
30: initial charge limit and peak current reduction unit
40: control unit
SW: switch
L: coil
R: resistance
D: Diode

Claims (4)

Bridge diode converting input AC voltage into DC voltage and outputting
A supercapacitor connected to an output side of the bridge diode to perform distortion and ripple reduction, and outputting a charged charge for a few seconds in case of an instantaneous power failure or an instantaneous voltage drop of an input power supply, to perform an electrostatic compensation;
An initial charge limit and peak connected between the bridge diode and the supercapacitor and limiting the current amount charged in the supercapacitor by the DC voltage converted in the bridge diode during initial charging of the supercapacitor and reducing the peak current. A current reducing unit, and
When the supercapacitor compensates for the supercapacitor due to a momentary power failure or a voltage drop, when the charge is performed on the supercapacitor, the charge amount of the supercapacitor is checked, and the charge amount of the supercapacitor is less than a predetermined reference charge The controller controls the initial charge limit and the peak current reducing unit. When the charge amount of the supercapacitor exceeds a predetermined reference charge, the initial charge limit and peak current reducer are driven until only the supercapacitor is charged. It includes a control unit for blocking,
The initial charge limit and peak current reduction unit,
A switch switched when the amount of charge charged in the supercapacitor is less than a predetermined reference amount according to a control signal of the controller, and
Consists of a coil and a resistor that limits the initial current size of the DC power converted by the bridge diode and reduces the peak current to output,
The switch, the coil, the resistor is a rectifier circuit using a supercapacitor connected in parallel, respectively. The method of claim 1,
The supercapacitor,
Rectification circuit using a supercapacitor having a capacitance of 50 to 100 Farad. The method of claim 1,
The reference charge amount preset in the controller is,
And a rectifier circuit using the supercapacitor set to 20 pro of the supercapacitor capacity. delete

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