KR20100104006A - Device of voltage compensation for a momentary power failure - Google Patents

Abstract

PURPOSE: By controlling the rush current created in the initial charge process the dynamic voltage-dip controller prevents the malfunction of the dynamic voltage-dip controller. CONSTITUTION: It is connected to the input and the first rectifier(200) changes the alternating current into the direct current. The inverter(300) changes the direct current outputted in the first rectifier into the alternating current. In the high-cap(400) is the steady status, the charging current is emitted to inverter. The SH 1(210) is serially connected between high-cap and inverter. SH1 detects the charging current of high-cap. The voltage detector(220) is connected between the first rectifier and high-cap in parallel with the first rectifier.

Description

Power Failure Compensation Device {DEVICE OF VOLTAGE COMPENSATION FOR A MOMENTARY POWER FAILURE}

The present invention relates to an instantaneous power failure compensation device, and more particularly, to an instantaneous power failure compensation device in which a large capacity capacitor provided in the instantaneous power failure compensation device is rapidly charged and safety control means for inrush current are added.

In recent years, in the industrial field, the reliability is very high, but in spite of this, instantaneous voltage drop and instantaneous power failure often occur, which causes defective products or stops the operation of the production line, resulting in huge loss. Occurs. These momentary instabilities are caused by short circuits in the power system, lightning strikes, and switching of large loads.The duration of these abnormal power quality states is typically less than 1 second in power systems, and more If so, it shall be regarded as permanent blackout and the equipment shall be stopped.

Most industrial equipment can withstand momentary power outages due to its mechanical properties and electrical inertia, but relays, starters, microcontrollers, etc. Loss by voltage-sag / Dip. Therefore, an uninterruptible power supply (UPS) has been introduced to switch to an alternative power source to continuously receive power even in the event of a power failure in preparation for such a power failure.

The instantaneous power failure compensator uses energy stored in the battery to protect the electrical and electronic equipments from power failure such as short time power failure and voltage drop in a short time, and continuously supplies rated control power to the load even during the power failure time. It is invented to allow the equipment to operate normally.

The configuration of the conventional momentary power compensation device is shown in FIG. 1.

Referring to FIG. 1, the conventional instantaneous power failure compensator is connected to a commercial power supply 100 and converts an alternating current into a direct current, and is connected to an output terminal of the rectifier 200 and in the rectifier 200. The inverter 300 receives the output DC current and converts it into an AC current and supplies it to the load 700, and an output terminal thereof is connected between the rectifier 200 and the inverter 300 to provide a charging current in case of power failure. The battery 400 discharged to the inverter 300 and the battery 400 and the inverter 300 are connected in the forward direction so that the current output from the rectifier 200 at the time of non-interruption to the battery 400. Blocking diode 500 and the input terminal is connected to the commercial power source 100, the output terminal is connected to the power supply of the storage battery 400 to the inverter 300 in the case of power failure 400 and the blocking diode Is connected between the (500) and converts the alternating current into a direct current and gradually increases the amount of current is composed of a rectifying charge circuit 600 for supplying a charging current to the storage battery (400). In addition, a first switch 910 connected between the load 700 and the inverter 300, and a second switch 920 connected between the commercial power source 100 and the inverter 300 The synchronous transfer switch 900 is further provided, when the output current of the inverter 300 is output, the second switch 920 is not energized and the first switch 910 is energized. When the output current is cut off, the second switch 920 is energized so that the current is supplied to the load 700.

However, the instantaneous power failure compensating device connects the blocking diode 500 between the inverter 300 and the storage battery 400 to block the current output from the rectifier 200 from flowing into the storage battery 400 at the time of non-interruption. In the meantime, since the current flows from the storage battery 400 to the inverter 300 during the power failure, only one power output from one rectifier (that is, the rectifier of the rectifier charging circuit 600) is stored in the storage battery 400. Is charging. Therefore, the rate of charging is slowed down when the power is turned on during instantaneous power failure, and thus there is a problem that it is not possible to prepare for repeated instantaneous power failure.

In addition, the conventional instantaneous power outage compensator has no means for controlling the inrush current generated during initial charging, and thus adversely affects the failure of the power failure compensator due to the inrush current and the lifespan of the industrial electric equipment employing the compensating device. There was a problem that.

In addition, the conventional instantaneous power outage compensator has a problem that the capacity of the charging device becomes large because the capacity of the separate charging device employing the blocking diode is set only for charging (that is, the capacity of the charging device is commercial power). (Nearly the same as the main dose).

Accordingly, an object of the present invention is to solve the above problems, the power supply is turned on during instantaneous power failure, the charging speed is shortened, the charging time is shortened, and thus the instantaneous power failure compensation device that can be prepared for repeated instantaneous power failure In providing.

Another object of the present invention is to prevent the breakdown of the instantaneous power failure compensation device by controlling the inrush current generated during the initial charging and to prevent the loss of the industrial electrical equipment employing this compensation device to improve the instantaneous power failure compensation device In providing.

It is still another object of the present invention to simplify the circuit and miniaturize the charging device as compared to the instantaneous power failure compensator having a separate charging device employing a blocking diode, and the size of the industrial electrical equipment employing the same becomes compact. An electrostatic compensation device is provided.

In order to achieve the above technical problem, an instantaneous power failure compensating device according to the present invention includes: a first rectifier connected to an input (INPUT) and converting an AC current into a DC current; An inverter connected to an output terminal of the first rectifier and receiving a DC current output from the first rectifier, converting the AC current into an AC current, and supplying the same to an output; A high cap (HY-CAP) whose output terminal is connected between the first rectifier and the inverter to discharge charging current to the inverter during a power failure; A SH1 (shunt) connected in series between the high cap and the inverter to detect a charging current of the high cap; A voltage detector connected between the first rectifier and the high cap in parallel with the first rectifier to detect a charging voltage across the high cap; A second rectifier connected between the input and a resistor R1 to charge the high cap; It is characterized by consisting of a synchronous transfer switch connected between the inverter and the output.

The synchronous transfer switch may further include a first switch connected between the output and the inverter; And a second switch connected between the input and the inverter, wherein when the output current of the inverter is output, the second switch is not energized and the first switch is energized so that current is supplied to the output. .

In addition, the voltage detector is characterized in that for detecting the charging voltage across the high cap.

In addition, the voltage detector detects the charging voltage of the high cap, and when about one third of the full charge voltage is charged, by operating the first rectifier connected in parallel with the self-capacitor characterized in that the high-cap fast charging.

In addition, the second rectifier is characterized in that the charging capacity to prevent the inrush current generated during the initial charge of the high cap to 1/5 of the first rectifier.

As described above, the instantaneous power failure compensating device of the present invention has the advantage that the charging time is shortened by charging the high cap by the redundant charging method, thereby preparing for the repeated power failure.

In addition, the instantaneous power failure compensation device of the present invention can control the inrush current generated during the initial charging to prevent the failure of the momentary power failure compensation device and to prevent the loss of industrial electrical equipment employing this compensation device to improve the safety There is this.

In addition, the instantaneous power failure compensating device of the present invention has the advantage that the circuit is simplified and the charging device is downsized, so that the size of the industrial electric equipment employing the same is compact.

Hereinafter, the instantaneous power failure compensating device according to the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to a client's or operator's intention or custom. Therefore, the definition should be based on the contents throughout this specification.

Like numbers refer to like elements throughout the drawings.

2 is a circuit diagram illustrating the concept of a momentary power compensation device according to the present invention.

As shown in FIG. 2, the instantaneous power failure compensating device according to the present invention is connected to an input terminal, and is connected to a first rectifier 200 for converting an AC current into a DC current and an output terminal of the first rectifier 200. The inverter 300 receives the DC current output from the first rectifier 200, converts the AC current into an AC current, and supplies the same to the output OUTPUT, and an output terminal thereof is the first rectifier 200 and the inverter 300. ) Is connected to the high-capacity capacitor (400, hereinafter referred to as "hy-cap (HY-CAP)) to discharge the charging current to the inverter 300 in the event of power failure, the high cap 400 and the inverter 300 ) Is connected in series to detect the charging current of the high cap 400 (shunt 210), and between the first rectifier 200 and the high cap 400 and the first rectifier 200 and A voltage detector 220 connected in parallel to detect a charging voltage across the high cap 400, and the input and the resistor R1 240; And a second rectifier 230 connected between the AC rectifier and the DC current to charge the high cap 400, and a synchronous transfer switch 900 connected between the inverter 300 and the output.

Referring to Figure 1, look at the circuit operation of the momentary power compensation device according to the present invention. In normal operation, the high cap 400 begins to be charged in no time when the power is input through the input by the second rectifier 230 connected between the input and the resistor R1 240. At the same time, an input through the input is applied to the first rectifier 200. The first rectifier 200 starts to detect the charging current of the high cap 400 through the SH1 210 connected in series with the inverter and at the same time the inverter. Supply a DC current to (300). Thereafter, when the charge voltage of the high cap 400 is detected by the voltage detector 220 connected in parallel with the first rectifier 200, when about 1/3 of the full charge voltage is charged, the voltage detector 220 is charged. By operating the first rectifier 200 connected in parallel with the self to continue to charge the high cap 400, and detects the charging current of the high cap 400 through the SH1 (210) the high cap 400 At the same time as a charging current appropriate to the charging capacity of the ()) and a DC current is continuously supplied to the inverter (300). At this time, the second rectifier 230 is automatically stopped due to the difference in the set voltage.

However, the second rectifier 230 has a charging capacity of 1/5 of the capacity of the first rectifier 200 to prevent inrush current during initial charging so that the first rectifier 200 rapidly charges the high cap 400. By improving the safety of the device by serving as an auxiliary role, the circuit can be simplified and the charging device can be miniaturized, and the size of the industrial electric device employing the device can be made compact compared with the conventional charging device equipped with a non-locking diode. . Here, the fast charging means that it can help to supply power to the load in an uninterrupted manner for the time promised by the short time repetitive backup (BACK-UP).

In addition, between the inverter 300 and the output includes a first switch 910 connected between the output and the inverter 300, and a second switch 920 connected between the input and the inverter 300. When the synchronous transfer switch 900 is connected and the output current of the inverter 300 is output, the second switch 920 is not energized and the first switch 910 is energized. When the output current is cut off, the second switch 920 is energized so that the current is supplied to the output.

In addition, the synchronous transfer switch 900 is a switch made in case the power supply output from the inverter 300 is interrupted due to a breakdown of the momentary power failure compensation device, the two thyristors are coupled in parallel to each other in two pairs That is, it is a contactless switch that forms the first switch 910 and the second switch 920. The first switch 910 is connected between an input and an output, and the other pair is connected between the inverter 300 and the output so that when the device is normally operated, the current of the inverter 300 is supplied to the output as it is. In case of failure of the device itself, the power supply is synchronized with the input) so as to prevent power failure.

Therefore, the instantaneous power failure compensation device according to the present invention configured as described above charges the high cap 400 with the second rectifier 220 having a capacity 1/5 of the first rectifier 200 during the initial charging, and then the capacity. The high cap 400 is configured to rapidly charge the high cap 400 with the large first rectifier 200, thereby controlling generation of inrush current during initial charging, and then enabling rapid charging, thereby making the output voltage more stable. Is supplied. Therefore, there is an advantage that can prevent a malfunction or system down by providing a stable power supply to the controller, such as semiconductor equipment, computer systems sensitive to instantaneous voltage changes. In addition, the power is turned on during the instantaneous power outage, the charging speed is fastened to shorten the charging time, thereby having the advantage that it is possible to prepare for a repetitive momentary power failure. In addition, there is an advantage that the circuit is simpler than the conventional momentary power compensation device, and the charging device is downsized, so that the size of an industrial electric device employing the same can be made compact. In addition, since the life of the high cap 400 is extended, there is an advantage that the maintenance is easy and the cost of repairing the high cap 400 is reduced. In addition, when the power supply of the inverter 300 is cut off, the synchronous transfer switch 900 is configured to be connected to the input, thereby preventing power supply to the output in case of an unexpected device failure, thereby preventing electrical and electronic equipment. There is an advantage to double protection. In addition, when the contact point of each switch is changed, the phase of the power output from the synchronous transfer switch 900 is synchronized with the input so that the output has the advantage that power is supplied without any phase change.

In the above-described embodiment, the synchronous transfer switch 900 is composed of two pairs of switches in which two thyristors are arranged in parallel, but other methods may be possible. For example, it may be possible to configure a separately designed switching circuit, or it may be configured as a relay with a magnetic switch or a contact. In addition, it may be possible to configure a triple or quadruple power backup system by arranging the switches further in accordance with the needs of those skilled in the art.

As described above, the present invention has been described based on the preferred embodiments, but these embodiments are intended to illustrate the present invention, not to limit the present invention, so that those skilled in the art to which the present invention pertains can perform the above without departing from the technical spirit of the present invention. Various changes, modifications or adjustments to the example will be possible. Therefore, the protection scope of the present invention shall be limited only by the appended claims and should be construed as including all changes, modifications or adjustments.

1 is a circuit diagram showing a conventional momentary power compensation device.

Figure 2 is a circuit diagram showing a momentary power compensation device of the present invention.

Explanation of symbols on the main parts of the drawings

200: first rectifier 210: SH1

220: voltage detector 230: second rectifier

240: resistance `300: inverter

400: high cap 800: automatic voltage regulator

900: synchronous transfer switch

Claims (5)

A momentary power outage compensator for temporarily supplying a pre-charged charging power to an output during a power outage at an input. A first rectifier connected to an input to convert an AC current into a DC current; An inverter connected to an output terminal of the first rectifier and receiving a DC current output from the first rectifier, converting the AC current into an AC current, and supplying the same to an output; A high cap (HY-CAP) whose output terminal is connected between the first rectifier and the inverter to discharge charging current to the inverter during a power failure; A SH1 (shunt) connected in series between the high cap and the inverter to detect a charging current of the high cap; A voltage detector connected between the first rectifier and the high cap in parallel with the first rectifier to detect a charging voltage across the high cap; A second rectifier connected between the input and a resistor R1 to charge the high cap; And a synchronous transfer switch connected between the inverter and the output. The switch of claim 1, wherein the synchronous transfer switch comprises: a first switch connected between the output and the inverter; And a second switch connected between the input and the inverter, wherein when the output current of the inverter is output, the second switch is not energized and the first switch is energized so that current is supplied to the output. Momentary power outage compensation device. The momentary power compensation device of claim 1, wherein the voltage detector detects a charging voltage across the high cap. According to claim 1 or claim 3, wherein the voltage detector detects the charge voltage of the high cap and when about 1/3 of the full charge voltage is charged, by operating the first rectifier connected in parallel with the high cap to operate the high cap Instantaneous power failure compensation device, characterized in that for fast charging. The momentary power compensation device of claim 1, wherein the second rectifier prevents inrush current generated during initial charging of the high cap at a charge capacity of 1/5 of the first rectifier.

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