KR20160036806A - Initial Charging Circuit of Filter Capacitor - Google Patents

Abstract

An objective of the present invention is to provide an initial charging circuit of a filter capacitor which limits an inrush current by a voltage applied to the capacitor during initial charging, and decrease a risk of device destruction. The initial charging circuit of a filter capacitor comprises: a current limiting unit connected to one power line among three-phase input power lines connected to three-phase input power sources to decrease a voltage of the one power line; a rectifying unit connected to the three-phase input power lines; the capacitor charged by receiving a DC voltage from the rectifying unit; and a switch unit connecting the three-phase input power lines to the capacitor. The switch unit initially cuts off a connection between the three-phase input power lines and the capacitor, and connects the three-phase input power lines and the capacitor when the capacitor is charged with a prescribed voltage or higher.

Description

[0001] The present invention relates to an initial charging circuit of a filter capacitor,

The present invention relates to a filter capacitor initial charging circuit, and more particularly to a circuit for controlling a charging current applied to a capacitor.

In general, a stable DC power source with reduced ripple can be utilized as an input power source of a power source device through a circuit for charging a capacitor using a three-phase or single-phase power source and a rectifier diode, and a DC voltage of a desired level Can be applied. In constructing such a charging circuit, an inrush current flows while a rectified voltage source is applied to a capacitor that is not charged at the time of initial charging, and a configuration is required to prevent burnout of a device such as a rectifying diode by such inrush current.

Conventionally, with such a configuration, a voltage sensing circuit for sensing the voltage charged in the capacitor, a voltage comparison circuit for comparing the sensed charging voltage, and a circuit for operating the electromagnetic contactor and the stator contactor are further constructed and used Respectively.

The initial charging circuit prevents the application of a large voltage to the circuit components such as the capacitor during the initial charge, thereby reducing the risk of device destruction. However, the circuit configuration becomes complicated due to various additional circuits, There is a problem in that the cost is also increased.

The filter capacitor initial charging circuit according to an embodiment of the present invention is intended to limit an inrush current due to a voltage applied to a capacitor at the time of initial charging, thereby reducing the risk of device breakdown.

In addition, the filter capacitor initial charging circuit according to an embodiment of the present invention simplifies the circuit design by simplifying the configuration, and reduces the circuit construction cost.

The filter capacitor initial charging circuit according to an embodiment of the present invention

A current limiting unit connected to one of three-phase input power supply lines connected to each of the three-phase input power supplies to limit the capacitor charge current supplied from the power supply line; A rectifier connected to each of the three-phase input power supply lines; A capacitor charged with the direct current voltage from the rectifying part; And a switch unit for connecting each of the three-phase input power supply lines to the capacitor, wherein the switch unit initially disconnects the connection between each of the three-phase input power supply lines and the capacitor, and when the capacitor is charged with a predetermined voltage or more So that the cut-off three-phase input power line and the capacitor can be made conductive.

The filter capacitor initial charging circuit according to another embodiment of the present invention

A current limiting unit connected to a single-phase input power supply line connected to the single-phase input power supply and limiting a capacitor charging current supplied from the single-phase input power supply line; A rectifier connected to each of the single-phase input power supply lines; A capacitor charged with the direct current voltage from the rectifying part; And a switch unit connected to the single-phase input power line and the capacitor, wherein the switch unit initially disconnects the connection between the single-phase input power line and the capacitor, and when the capacitor is charged with a predetermined voltage or more, The input power line and the capacitor can be made conductive.

The current limiting portion may include a resistor.

The switch unit may include a plurality of switches connected in parallel with the capacitors and conducting each input power supply line when the predetermined voltage or more is applied to the capacitor.

The switch unit may turn on each of the input power supply lines when the capacitor is applied with 220 V or more.

The switch unit may include an electromagnetic contactor including a coil connected in parallel with the capacitor, and the electromagnetic contactor may include an electromagnetic contactor to which the constant voltage is applied to the coil when the predetermined voltage or more is applied to the capacitor.

The switch unit may include a normally closed type switch connected to the capacitor and disconnected when the input voltage is higher than the predetermined voltage and the capacitor is connected to the coil.

And a pair of switches operatively connected to the current limiting unit and the switch unit, respectively.

The filter capacitor initial charging circuit according to an embodiment of the present invention limits an inrush current due to a voltage applied to a capacitor at the time of initial charging, thereby reducing the risk of device breakdown.

In addition, the filter capacitor initial charging circuit according to the embodiment of the present invention simplifies the circuit design by simplifying the configuration, and can reduce the circuit construction cost.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram showing a filter capacitor initial charging circuit in a three-phase input power supply according to the prior art; FIG.
2 is a diagram showing an initial charging circuit of a filter capacitor in a three-phase input power supply according to an embodiment of the present invention.
3 is a diagram showing an initial charging circuit of a filter capacitor in a single-phase input power supply according to an embodiment of the present invention.
4 is a diagram showing a filter capacitor initial charging circuit in a single-phase input power supply according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

The present invention relates to a filter capacitor initial charging circuit, and more particularly, to a filter capacitor initial charging circuit used for a three-phase input power supply circuit and a single-phase input power supply circuit.

FIG. 1 illustrates a prior art three-phase filter capacitor initial charging circuit, in which a magnetic contactor 210 is connected to each of input power lines to basically keep the power lines disconnected . The resistors 110 connected in parallel with the electromagnetic contactor 210 are additionally provided between each of the input power supply lines and the rectifier diode 310 instead of the circuit line connected to the electromagnetic contactor 210. Thus, So that the capacitor 400 is charged through the resistor 110 and the rectifier diode 310.

The reason for configuring such a circuit diagram in the filter capacitor initial charging circuit is that when the resistor 110 and the electromagnetic contactor 210 are not provided, the input power is directly applied to the capacitor 400, The value of the voltage or the current applied to the rectifying diode 310 becomes large, thereby causing a failure in the circuit component such as the rectifying diode 310. [

Therefore, by configuring the circuit as shown in FIG. 1 in order to prevent the occurrence of such a failure, it is possible to reduce the value of the voltage or current applied to the capacitor 400 at the initial stage by each resistor 110, It is possible to prevent the occurrence of a failure in the circuit component such as the transistor 310.

However, such a prior art filter capacitor initial charging circuit includes a voltage measuring circuit 10 for measuring the voltage charged in the capacitor 400 as shown, a voltage comparator circuit 20 for comparing the measured voltage with a reference voltage And the switch operating circuit 30 for operating the electromagnetic contactor 210 or the like must be additionally provided. This leads to a problem that the circuit configuration is complicated and the cost is also increased.

Therefore, the present invention proposes a filter capacitor initial charging circuit which can simplify the circuit configuration and reduce the circuit construction cost by simplifying the configuration of the initial charging circuit of the filter capacitor. This will be described in more detail with reference to FIG.

2 is a diagram illustrating an initial charging circuit of a filter capacitor in a three-phase input power supply according to an embodiment of the present invention. As shown in FIG. 2, the filter capacitor initial charging circuit according to the present invention may include a current limiting unit 100 and a switch unit 200. The current limiting unit 100 includes a device or a circuit that can lower the charging current, and may include a resistor 110 in general. Further, the switch unit 200 may be a switch that conducts the circuit when a voltage exceeding a certain voltage is applied, and the electromagnetic contactor 210 may be generally used.

More specifically, the filter capacitor initial charging circuit in the three-phase input power supply according to the embodiment of the present invention includes a circuit connected from the three-phase input power supply line to the rectifying unit 300 through the switch unit 200 connected to each of the three- The current limiting unit 100 is connected in parallel with the switch unit 200 and connected to the rectifying unit 300 so that the voltage applied from the power supply line is reduced to a current The capacitor 400 can be charged through the restricting portion 100 and the rectifying portion 300.

The capacitor 400 charged in this way is connected in parallel with the coil 220 included in the conventional electromagnetic contactor 210 constituting the switch unit 200 or with another element which conducts the switch unit 200 when a constant voltage is applied .

A voltage applied to the capacitor 400 through the parallel connection of the capacitor 400 and the coil 220 included in the electromagnetic contactor 210 is applied to the coil 220 in the same manner. When the voltage applied to the capacitor 400 is higher than a predetermined voltage, that is, when the voltage applied to the coil 220 is higher than a predetermined voltage, the fixed iron core coupled with the coil 220 becomes an electromagnet to attract the movable iron core The switch unit 200 is activated to conduct each of the three-phase input power supply lines, thereby allowing the capacitor 400 to be fully charged based on the input power from each three-phase input power supply line. The predetermined voltage can be set based on 220V, which can be changed to a different value by the user and reflected in the circuit.

The switch unit 200 may include a normally closed type switch 230 connected to the capacitor 400 and interrupted when the voltage of the coil 220 is higher than the predetermined voltage. The normal close type switch 230 is cut off when the switch unit 200 is operated to make the three-phase input power line conductive.

In addition, the present filter capacitor initial charging circuit may include a pair of switches 500 connected to and operating on the current limiting unit 100 and the switch unit 200, respectively.

Specifically, the pair of switches 500 can be short-circuited to start initial charging, and the pair of switches 500 can be kept in a short-circuited state even after the operation of the switch unit. Further, in the event that a problem occurs in the filter capacitor initial charging circuit, the input from the three-phase input power supply line can be cut off by blocking the pair of switches 500.

3 is a diagram showing an initial charging circuit of a filter capacitor in a single-phase input power supply according to an embodiment of the present invention. As shown in FIG. 3, the filter capacitor initial charging circuit in the single-phase input power supply may also be composed of the current limiting unit 100 and the switch unit 200. The current limiting unit 100 includes an element or a circuit capable of lowering the charging current, and may include a resistor in general. Further, the switch unit 200 may be a switch that conducts the circuit when a voltage exceeding a certain voltage is applied, and the electromagnetic contactor 210 may be generally used.

More specifically, the filter capacitor initial charging circuit in the single-phase input power supply according to the embodiment of the present invention includes a circuit connected from the single-phase input power supply line to the rectifying unit 300 through the switch unit 200 connected to each of the single- The current limiting unit 100 is connected in parallel with the switch unit 200 to one of the single-phase input power supply lines and connected to the rectifying unit 300 so that the voltage applied from the power supply line The capacitor 400 can be charged through the current limiting unit 100 and the rectifying unit 300.

The capacitor 400 charged in this way is connected in parallel with the coil 220 included in the conventional electromagnetic contactor 210 constituting the switch unit 200 or with another element which conducts the switch unit 200 when a constant voltage is applied .

For example, the voltage applied to the capacitor 400 through the parallel connection of the capacitor 400 and the coil 220 included in the electromagnetic contactor 210 is applied to the coil 220 in the same manner, When the voltage applied to the coil 220 is higher than a predetermined voltage, that is, when the voltage applied to the coil 220 is higher than a predetermined voltage, the fixed iron core coupled with the coil 220 becomes an electromagnet to attract the movable iron core, Phase power supply line is activated to conduct the single-phase input power supply line, thereby allowing the capacitor 400 to be fully charged based on the input power from the single-phase input power supply line. The predetermined voltage may be set to 220V, which may be changed to a different value by the user and reflected in the circuit.

The switch unit 200 may include a normally closed type switch 230 connected to the capacitor 400 and interrupted when the voltage of the coil 220 is higher than the predetermined voltage. Phase input power supply line through the normal close type switch 230 when the switch unit 200 is operated.

In addition, the present filter capacitor initial charging circuit may include a pair of switches 500 connected to and operating on the current limiting unit 100 and the switch unit 200, respectively.

Specifically, the pair of switches 500 can be short-circuited to start initial charging, and the pair of switches 500 can be kept in a short-circuited state even after the operation of the switch unit. In addition, when a trouble occurs in the filter capacitor initial charging circuit, the input from the single-phase input power supply line can be cut off by shutting off the pair of switches 500.

4 is a diagram showing a filter capacitor initial charging circuit in a single-phase input power supply according to another embodiment of the present invention. As shown in FIG. 4, the filter capacitor initial charging circuit in the single-phase input power source is configured to charge one capacitor 400. As a result, as shown in FIGS. 2 and 4, the switch unit 200 is connected to the neutral line of the single-phase input without being connected to the capacitor 400, so that the switch 400 is connected in parallel with the capacitor 400 to charge the capacitor 400 So that the switch unit 200 can be operated.

Specifically, the filter capacitor initial charging circuit in the single-phase input power supply also includes the current limiting unit 100 and the switch unit 200. The current limiting unit 100 may include an element or a circuit capable of lowering the charging current, and generally a resistor may be connected. Further, the switch unit 200 may be a switch that conducts the circuit when a voltage exceeding a certain voltage is applied, and the electromagnetic contactor 210 may be generally used.

More specifically, the filter capacitor initial charging circuit in the single-phase input power supply according to another embodiment of the present invention includes a switch unit 200 connected to a single-phase input power supply line, and a circuit connected to the rectifying unit 300 from a single- And the current limiting unit 100 is connected in parallel with the switch unit 200 to one of the single-phase input power supply lines and connected to the rectifying unit 300 so that current The capacitor 400 can be charged through the restricting portion 100 and the rectifying portion 300.

The capacitor 400 is one capacitor 400 and the charging voltage thereof is the same as that of the current limiting unit 100. The switch unit 200 is connected to the capacitor 400 through the above- The same voltage can be applied. The switch unit 200 may receive the same voltage as the voltage applied to the capacitor 400 through the coil 220. The coil 220 may be connected to the switch unit 200, The coil 220 may be a coil included in a general magnetic contactor 210 constituting a coil.

For example, a voltage equal to the voltage applied to the capacitor 400 through the coil 220 coupled with the fixed iron core included in the electromagnetic contactor 210 is applied to the coil 220, When the applied voltage is equal to or higher than a certain voltage, the fixed iron core coupled to the coil 220 becomes an electromagnet and pulls the movable iron core, so that the switch unit 200 is operated to conduct the single-phase input power line. As a result, the input power is fully applied to the capacitor 400 from the single-phase input power supply line and charges the capacitor 400. The predetermined voltage may be set to 220V, which may be changed to a different value by the user and reflected in the circuit.

The switch unit 200 may include a normally closed type switch 230 connected to one of the single-phase input lines and intercepted when the predetermined voltage or more is applied to the coil 220. The normally closed type switch 230 is cut off when the switch unit 200 is activated to conduct the single-phase input power line.

In addition, the present filter capacitor initial charging circuit may include a pair of switches 500 connected to and operating on the current limiting unit 100 and the switch unit 200, respectively.

Specifically, the pair of switches 500 can be short-circuited to start initial charging, and the pair of switches 500 can be kept in a short-circuited state even after the operation of the switch unit. In addition, when a trouble occurs in the filter capacitor initial charging circuit, the input from the single-phase input power supply line can be cut off by shutting off the pair of switches 500.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10: voltage measurement circuit 20: voltage comparison circuit
30: Switch operation circuit
100: current limiting unit 200: switch unit
300: rectification part 400: capacitor
500: a pair of switches 110: a resistor
210: Magnetic contactor 220: Coil
230: Normal Open Type Switch
310: rectifier diode

Claims (8)

A current limiting unit connected to one of three-phase input power supply lines connected to each of the three-phase input power supplies to limit the capacitor charge current supplied from the power supply line;
A rectifier connected to each of the three-phase input power supply lines;
A capacitor charged with the direct current voltage from the rectifying part; And
And a switch unit connecting each of the three-phase input power supply lines to the capacitor,
Phase input power supply line and the capacitor when the capacitor is charged with a voltage equal to or greater than a predetermined voltage, and the switch unit turns off the connection between each of the three-phase input power supply line and the capacitor, Initial charging circuit. A current limiting unit connected to a single-phase input power supply line connected to the single-phase input power supply and limiting a capacitor charging current supplied from the single-phase input power supply line;
A rectifier connected to each of the single-phase input power supply lines;
A capacitor charged with the direct current voltage from the rectifying part; And
And a switch unit connected to the single-phase input power line and the capacitor,
Phase input power supply line and the capacitor, and when the capacitor is charged to a voltage equal to or higher than a predetermined voltage, the cutoff single-phase input power supply line and the capacitor are electrically connected to each other. Circuit. 3. The method according to claim 1 or 2,
The current limiter
Wherein the filter capacitor comprises a resistor. 3. The method according to claim 1 or 2,
The switch unit
And a plurality of switches connected in parallel with the capacitor to turn on each of the input power supply lines when the predetermined voltage or more is applied to the capacitor. 5. The method of claim 4,
The switch unit
Wherein the input power supply line is turned on when the voltage of 220 V or more is applied to the capacitor. The method of claim 4, wherein
The switch unit
And an electromagnetic contactor including a coil connected in parallel with the capacitor,
Wherein the electromagnetic contactor is an electromagnetic contactor to which the constant voltage is applied to the coil when the predetermined voltage or more is applied to the capacitor. The method according to claim 6,
The switch unit
Connected to the capacitor,
And a normally closed type switch which is cut off when the input power line and the capacitor are connected to each other by applying a predetermined voltage or more to the coil. 3. The method according to claim 1 or 2,
And a pair of switches connected to the current limiting unit and the switch unit, respectively, for operating the filter capacitor.

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