KR20130005500A - Reactive power compensating apparatus for alternating current motor - Google Patents

Abstract

PURPOSE: A reactive power compensating apparatus for an alternating current motor is provided to reduce the volume and weight of the apparatus. CONSTITUTION: A reactive power compensating apparatus for an alternating current motor comprises three compensation capacitors(11) connected to three power load connection lines(203) through three compensation capacitor lines(11a). The reactive power compensating apparatus comprises a voltage conversion part(20) and a coil switching part(30), three series reactors(13), a detection part(40), and a compensation control part(15). [Reference numerals] (15) Compensation control part; (202) Load; (40) Detection part

Description

TECHNICAL FIELD [0001] The present invention relates to a reactive power compensating apparatus for an AC motor,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reactive power compensating apparatus for an alternating-current motor, and more particularly, to a reactive power compensating apparatus for an alternating-current motor which compensates reactive power exchanged between an alternating-current power supply and an alternating- Gt;

The AC motor drive circuit that supplies the operating voltage to the AC motor load includes an AC voltage power supply, a power load connection line that electrically connects the AC voltage power and the AC motor load, and a motor control board (MMC: Motor Control Center).

The alternating voltage power source may be three-phase or single-phase, and the power load connecting line may be a three-phase line or a single-phase line in accordance with the alternating voltage power source.

The motor control panel is equipped with the necessary components for supplying the operating voltage to the AC motor such as NFB, CT, M / C, ammeter, LAMP thermostat relay, operation button.

On the other hand, an AC motor is an inductive load. When an AC voltage is supplied to these AC motor loads, reactive power is generated in accordance with a phase difference between a voltage power source and a load current flowing in the line.

Reactive power causes disadvantages such as increasing the amount of current flowing in the line, causing heat loss, or increasing the capacity of the transformer, the switchboard, and the like.

There is no reactive power compensating device for AC motor for compensating reactive power exchanged between AC voltage power supply and line, having capacitors connected to AC voltage power source so as to be parallel to AC motor load in order to solve the disadvantage due to reactive power Has been used.

5 is a configuration diagram of a conventional reactive power compensating apparatus for an alternating-current motor.

5, a conventional reactive power compensating device for an alternating-current motor includes five compensation capacitors 111 connected to a power load connecting line 203 through a compensating capacitor connecting line 111a and one compensating capacitor 111 connected to a single series reactor And a compensation capacitor connection line 111a connected to the power supply connection line 203 and the compensation capacitor connection line 111. The capacitor switching unit 130 includes five capacitor switching units 130, And a compensation control unit 115 for controlling the on / off operation of the capacitor switching unit 130 based on the detection value of the detection unit 140.

Each compensation capacitor 111 is connected to the power load connecting line 203 so as to be in parallel with the AC motor load 202.

Each of the capacitor switching units 130 is implemented using a diode and a silicon controlled rectifier (SCR) so that the conduction directions are different from each other.

The compensation capacitor 111 is charged by the diode.

The SCR operates so that the electrical connection between the compensation capacitor 111 and the power load connecting line 203 is turned on and off according to control signals (gate trigger signal and turn-off signal) from the outside.

The series reactor 113 is provided for preventing distortion of a voltage waveform applied to the compensation capacitor 111 by harmonics. Since the series reactor 113 having such a function is widely used in the art, a detailed description thereof will be omitted.

The detecting unit 140 detects a current flowing through the power load connecting line 203 and a voltage applied to the compensating capacitor connecting line 111a through a CT (Current Transformer) type current sensor and a PT (Potential Transformer) type sensor Can be implemented.

The compensation control unit 115 has a detection unit 140 connected to an input terminal thereof and a capacitor switching unit 130 connected to an output terminal thereof.

The control operation of the compensation controller 115 having such a configuration will now be described.

First, the power factor is calculated on the basis of the detected current value detected by the detecting section 140, and the ground load reactive power amount is calculated.

Next, the compensated reactive power amount for each compensation capacitor 111 is calculated based on the detection voltage value detected by the detection unit 140. [

Next, each of the capacitor switching units (not shown) is connected to the power supply connecting line 203 so that the compensation capacitor 111 corresponding to the compensable reactive power amount having the maximum value within a range not exceeding the grounded reactive power amount calculated from the compensable reactive power amount 130 in response to the control signal.

However, according to the conventional reactive power compensating apparatus for an AC motor, since the number of compensation capacitors 111 equal to the value of the phase-ineffective energy level to be provided is required, there is a problem that the volume and weight of the apparatus are increased. If the volume and weight of the reactive power compensating device increases, it becomes difficult to install the reactive power compensating device in the motor control panel.

When the ground reactive power amount of the AC motor load changes during the operation of the AC motor, the operation of interrupting the voltage supplied to one of the compensating capacitors 111 and the operation of applying the voltage to the other compensating capacitor 111, There is a problem that the number of times of the voltage blocking operation and the voltage applying operation for the compensation capacitor 111 increases because the amount of power is changed. When the voltage blocking operation and the number of voltage applying operations for the compensation capacitor 111 are increased, the spark and heat generated due to the arc during the voltage supply operation and the voltage blocking operation, the surge voltage input, the generation of the impulse current, There is a risk that the lifetime of the compensation capacitor 111 is shortened, or a trouble occurs in the control circuit or a fire occurs.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a reactive power compensating device for an AC motor which can provide a plurality of phase-ineffective powers by using one compensation capacitor.

According to the present invention, there is provided an AC motor drive circuit having a three-phase AC voltage power supply electrically connected to a three-phase AC motor load through three power supply connecting lines, wherein the AC voltage power supply and the AC motor load And is connected to form a Y connection mode and a? Connection mode, and is connected to the AC motor load through three compensation capacitor connection lines. Three compensation capacitors connected to the three power supply connecting lines so as to be parallel to each other; And a secondary winding of a single winding, wherein the power supply connecting line is connected in parallel to the plurality of primary windings and the secondary winding is connected to the compensation capacitor Three voltage converters installed; Three winding switching units each of which is provided for each of the primary windings and is operated to turn on and off an electrical connection between the primary winding and the power load connecting line in accordance with a control signal from the outside; A detecting unit for detecting a current flowing in each of the power load connecting lines and a voltage applied to each of the compensating capacitor connecting lines; Calculating a ground load reactive power amount for each phase based on the detection current value detected by the detection unit, calculating an output voltage output through the secondary winding based on the detection voltage value detected by the detection unit, Calculating a compensated reactive power amount for each of the primary windings based on an output voltage of the secondary winding wound on the secondary winding, and calculating a compensatable reactive power having a maximum value within a range not exceeding the calculated grounded reactive power, Off operation of each of the winding switching units so that a primary winding corresponding to an amount of power is connected to the power supply connecting line. The reactive power compensating apparatus for an AC motor according to claim 1, And connected via three compensation capacitor connection lines to the AC motor load Achieve a column with three compensation capacitors are connected to said three power load connecting line; Each having a primary winding and a plurality of secondary windings different from the primary winding of the single winding, wherein the power supply connecting line is connected to the primary winding and the plurality of secondary windings are connected in parallel to the compensation capacitor Three voltage converters installed; Three winding switching units each of which is provided for each of the secondary windings and operated to turn on and off an electrical connection between the secondary winding and the compensation capacitor in accordance with a control signal from the outside; A detecting unit for detecting a current flowing in each of the power load connecting lines and a voltage applied to each of the compensating capacitor connecting lines; Calculating a ground load reactive power amount for each phase based on the detection current value detected by the detection unit, calculating an output voltage output through the secondary winding based on the detection voltage value detected by the detection unit, Calculating a compensated reactive power amount for each of the secondary windings based on an output voltage of the secondary winding wound on the secondary winding, and calculating a compensated reactive power having a maximum value within a range not exceeding the calculated grounded reactive power amount, And a compensation control unit for controlling on / off operation of each winding switching unit so that a secondary winding corresponding to a power amount is connected to the compensation capacitor.

Therefore, according to the present invention, one compensating capacitor is provided for each phase, and the voltage magnitude applied to the compensating capacitor is varied by using the voltage converting section, so that the reactive power is adjusted to the fluctuation of the ground load reactive power amount of the AC motor load So that a plurality of true phase reactive power can be compensated by using one compensation capacitor. As a result, the volume and weight of the device are reduced, and the reactive power compensation device can be installed in the motor control panel.

When the ground reactive power amount of the AC motor load changes during the operation of the AC motor, the amount of phase reactive power to be compensated can be changed without voltage cut-off operation (depending on the applied voltage magnitude) to the compensation capacitor. This can shorten the life of the compensation capacitor or prevent trouble or fire in the control circuit.

1 is a configuration diagram of a reactive power compensating apparatus for an AC motor according to an embodiment of the present invention;
FIGS. 2, 3 and 4 are diagrams showing a configuration of a reactive power compensating apparatus for an alternating-current motor according to another embodiment of the present invention,
5 is a configuration diagram of a conventional reactive power compensating apparatus for an alternating-current motor.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a reactive power compensating apparatus for an AC motor according to an embodiment of the present invention.

1, the reactive power compensating apparatus for an alternating-current motor according to the embodiment of the present invention includes three compensating capacitors connected to three power load connecting lines 203 via three compensating capacitor connecting lines 11a, The three voltage converters 20, the winding switching unit 30 and the three series reactors 13 provided in the three compensation capacitor connection lines 11a and the respective power load connecting lines 203, Off operation of the winding switching unit 30 based on the detection value of the detection unit 40. The detection unit 40 detects the current flowing through the compensation capacitor connection line 11a and the current flowing through the compensation capacitor connection line 11a, (15).

The compensation capacitor 11 is connected to the power load connecting line 203 so as to be in parallel with the AC motor load 202.

The compensation capacitors 11 may be interconnected to form a Y wiring or a △ wiring.

It is preferable that the maximum capacity of each compensation capacitor 11 is set so as to have a phase ineffective power of the same magnitude as the maximum grounded load reactive power of the AC motor load (50 KVA when the expected maximum grounded load reactive power of the AC motor load is 50 KVA) .

Each of the voltage converters 20 has a plurality of primary windings 21 and a secondary winding 22 of a single winding.

The plurality of primary windings 21 are constituted by the primary windings 21a of the windings N1 and the primary windings 21b of the windings N1 + N2.

 The voltage converter 20 shown in FIG. 1 is implemented in the form of a three-phase transformer in which the primary windings of the voltage converter are connected to each other. Each voltage converter 20 can be implemented using a single winding type winding other than the lottery type, and can be implemented in a form (conventionally known) in which the winding winding can be controlled by external operation or the winding winding can be electronically controlled have.

The voltage conversion section 20 having such a configuration is installed such that the power supply connecting line 203 is connected in parallel to the plurality of primary windings 21 and the secondary winding 22 is connected to the compensation capacitor 11 .

The winding ratio of the secondary winding 22 to the primary winding 21 is set to 1 under the condition that the compensating reactive power amount for each primary winding 21 described later does not exceed the maximum grounded load reactive power of the AC motor load Or more.

The winding switching unit 30 is installed one for each primary winding 21 by using a bidirectional switching element such as a pair of SCR (Silicon Controlled Rectifier) or the like.

One of the two primary windings 21 has an SCR1 / SCR2 group and the other has an SCR3 / SCR4 group.

In accordance with control signals (gate trigger signal and turn-off signal) from the outside, the SCR operates so that the electrical connection between the primary winding 21 and the power load connecting line 203 is turned on and off.

Each series reactor 13 is provided for preventing distortion of a voltage waveform applied to the compensation capacitor 11 by harmonics. Since the series reactor 13 having such a function is widely used in the art, a detailed description thereof will be omitted.

The detecting unit 40 detects a current flowing through each power load connecting line 203 through a CT (Current Transformer) type current sensor and is applied to each compensating capacitor connecting line 11a through a PT (Potential Transformer) type sensor Voltage (which is the same as the voltage applied to the power load connecting line) is detected.

Then, a CT (Current Transformer) type current sensor for detecting the current flowing through the compensating capacitor connecting line 11a is added to the detecting unit 40 and the detection value is transmitted to the compensation controlling unit 15 to compensate the current unbalance of the compensating capacitor 11 It is possible to take measures corresponding to the lifetime reduction, short-circuit, and phase-lag phenomenon of the compensation capacitor 11.

The compensation control unit 15 has a detection unit 40 connected to an input terminal thereof and a winding switching unit 30 connected to an output terminal thereof.

The control operation of the compensation controller 15 having such a configuration will now be described.

First, based on the detection current value detected by the detection unit 40, the power factor of the phase current of the three-phase alternating-current voltage power source and the detected current value is calculated to calculate the ground load reactive power amount for each phase.

Next, based on the detected voltage value detected by the detecting section 40, the output voltage outputted through the secondary winding 22 is calculated by reflecting the turns ratio between each primary winding 21 and the secondary winding.

The compensated reactive power amount for each primary winding 21 is calculated based on the output voltage of the secondary winding 22 calculated next. For example, assuming that the capacity of the compensation capacitor 11 is 50 KVA at a rated voltage of 400 Volt and that the output voltage of one of the primary windings is 280 Volt, the magnitude of the phase-inrun power of the capacitor is proportional to the square of the applied voltage The compensating buoyant power of the primary winding with an output voltage of 280 volts is approximately 25 kVA.

Next, in order to connect the primary winding 21 corresponding to the compensable reactive power amount having the maximum value within a range not larger than the ground load reactive power amount calculated in the compensable reactive power amount to the power load connecting line 203, Off operation of the microcomputer 30.

For example, if the calculated reactive power for each primary winding (21) is 25KVA and 15KVA, and the ground load reactive power of the calculated AC motor load is 26KVA, the primary winding corresponding to 25KVA is connected to the power load connecting line Off operation of each winding switching unit 30 so as to be connected to the switching unit 203. [

When the compensated reactive power amount for each of the calculated primary windings 21 is 25 KVA and 15 KVA and the ground load reactive power amount of the calculated AC motor load is 20 KVA, the primary winding corresponding to 15 KVA is connected to the power load connecting line 203, Off operation of each of the winding switching units 30 so as to be connected to each of the windings.

That is, the compensation control unit 15 controls the winding switching unit 30 corresponding to the other primary winding 21 to perform the ON / OFF operation of the SCR group belonging to the winding switching unit 30 corresponding to the selected primary winding 21 And controls the SCR group to remain in the OFF state. For example, when the primary winding 21a of N1 is selected, the SCR1 / SCR2 group corresponding to the primary winding 21a is turned on and off, that is, SCR1 is on SCR2 is off in the positive voltage interval and SCR1 is negative Off SCR2 are turned on while the SCR3 and SCR4 are kept in the off state.

3, a plurality of primary windings 21 are connected in parallel to each other so as to have one primary winding 21 'and a plurality of secondary windings 22' So that the present invention can be implemented.

2, components having the same structure and function as those of the reactive power compensating apparatus for an AC motor according to an embodiment of the present invention are denoted by the same reference numerals.

2, the compensation control unit 15 calculates the output voltage output through the secondary winding 22 'and outputs the compensated reactive power amount for each secondary winding 22' .

The plurality of secondary windings 22 'are composed of the secondary windings 22'a of the windings N1 and the secondary windings 22'b of the windings N1 + N2.

Then, the compensation controller 15 controls the compensation capacitor 11 so that the secondary winding 22 'corresponding to the compensable reactive power amount having the maximum value within a range not exceeding the ground load reactive power calculated from the compensable reactive power is connected to the compensation capacitor 11 Off operation of each winding switching unit 30 is controlled.

Although the three-phase AC voltage power supply 201 has been described in the above embodiments, the present invention can be applied to the single-phase voltage power supply 201 'as shown in FIG. 3 and FIG. 4 to be.

3 and 4, the components having the same structure and function as those of the reactive power compensating apparatus for an AC motor according to the embodiment of the present invention are denoted by the same reference numerals.

The three-phase AC voltage power source 201 and the inductive load 202, which can be applied to the present invention, may be any one of YY wiring, Y-? Wiring,? -Y wiring and? .

As described above, according to the embodiment of the present invention, one compensation capacitor 11 is provided for each phase and the voltage magnitude applied to the compensation capacitor 11 is varied by using the voltage conversion units 20 and 20 ' It is possible to compensate for the reactive power by adapting to the fluctuation of the ground load reactive power amount of the AC motor load 202 so that a plurality of phase reactive power can be compensated by using one compensation capacitor 11. [ As a result, the volume and weight of the device are reduced, and the reactive power compensation device can be installed in the motor control panel.

When the ground reactive power amount of the AC motor load changes during the operation of the AC motor, the amount of phase reactive power to be compensated for can be changed without voltage cut-off operation (depending on the voltage magnitude applied) to the compensation capacitor 11. Thus, the life of the compensation capacitor 11 can be shortened, or troubles in the control circuit can be prevented or a fire can be prevented.

11, 111: compensation capacitor 13, 113: series reactor
15, 115: compensation control unit 20, 20 ': voltage conversion unit
21, 21 ': primary windings 22, 22': secondary windings
30: winding switching unit 40, 140: detecting unit
130: Capacitor switching unit

Claims (4)

Phase AC power supply connected electrically to the three-phase AC motor load through three power load connecting lines, and the ground load reactive power exchanged between the AC voltage power supply and the AC motor load 1. A reactive power compensating apparatus for an AC motor, comprising:
Three compensation capacitors connected to the three power supply connecting lines so as to form one of the Y wiring type and the? Wiring type and connected in parallel to the AC motor load through three compensation capacitor connecting lines;
And a secondary winding of a single winding, wherein the power supply connecting line is connected in parallel to the plurality of primary windings and the secondary winding is connected to the compensation capacitor Three voltage converters installed;
Three winding switching units each of which is provided for each of the primary windings and is operated to turn on and off an electrical connection between the primary winding and the power load connecting line in accordance with a control signal from the outside;
A detecting unit for detecting a current flowing in each of the power load connecting lines and a voltage applied to each of the compensating capacitor connecting lines;
Calculating a ground load reactive power amount for each phase based on the detection current value detected by the detection unit, calculating an output voltage output through the secondary winding based on the detection voltage value detected by the detection unit, Calculating a compensated reactive power amount for each of the primary windings based on an output voltage of the secondary winding wound on the secondary winding, and calculating a compensatable reactive power having a maximum value within a range not exceeding the calculated grounded reactive power, Off operation of each of the winding switching units so that a primary winding corresponding to an amount of power is connected to the power supply connecting line. Phase AC power supply connected electrically to the three-phase AC motor load through three power load connecting lines, and the ground load reactive power exchanged between the AC voltage power supply and the AC motor load 1. A reactive power compensating apparatus for an AC motor, comprising:
Three compensation capacitors connected to the three power supply connecting lines so as to form one of the Y wiring type and the? Wiring type and connected in parallel to the AC motor load through three compensation capacitor connecting lines;
Each having a primary winding and a plurality of secondary windings different from the primary winding of the single winding, wherein the power supply connecting line is connected to the primary winding and the plurality of secondary windings are connected in parallel to the compensation capacitor Three voltage converters installed;
Three winding switching units each of which is provided for each of the secondary windings and operated to turn on and off an electrical connection between the secondary winding and the compensation capacitor in accordance with a control signal from the outside;
A detecting unit for detecting a current flowing in each of the power load connecting lines and a voltage applied to each of the compensating capacitor connecting lines;
Calculating a ground load reactive power amount for each phase based on the detection current value detected by the detection unit, calculating an output voltage output through the secondary winding based on the detection voltage value detected by the detection unit, Calculating a compensated reactive power amount for each of the secondary windings based on an output voltage of the secondary winding wound on the secondary winding, and calculating a compensated reactive power having a maximum value within a range not exceeding the calculated grounded reactive power amount, And a compensation controller for controlling the on / off operation of each of the winding switching units so that a secondary winding corresponding to a power amount is connected to the compensation capacitor. Phase alternating-current voltage power source electrically connected to the single-phase alternating-current motor load through a pair of power supply connecting lines, and compensates for the grounding load reactive power exchanged between the alternating-voltage power source and the alternating-current motor load Wherein the reactive power compensator comprises:
A compensation capacitor connected to the power load connecting line so as to be parallel to the AC motor load through a pair of compensation capacitor connecting lines;
A plurality of primary windings of different winding speeds and a secondary winding of a single winding, wherein the power supply connecting line is connected in parallel to the primary winding and the secondary winding is connected to the compensation capacitor, Wealth;
A winding switching unit operative to turn on and off an electrical connection between the primary winding and the power load connecting line according to a control signal from the outside;
A detecting unit for detecting a current flowing through the power load connecting line and a voltage applied to the compensating capacitor connecting line;
Calculating a ground load reactive power amount based on the detected current value detected by the detection unit, calculating an output voltage output through the secondary winding based on the detected voltage value detected by the detection unit, , And calculates a compensated reactive power amount for each of the primary windings based on the output voltage of the primary winding, and calculates a compensated reactive power amount corresponding to the compensable reactive power amount having a maximum value in a range not larger than the calculated ground- And a compensation control unit for controlling the on / off operation of the winding switching unit so that the primary winding is connected to the power load connecting line. Phase alternating-current voltage power source electrically connected to the single-phase alternating-current motor load through a pair of power supply connecting lines, and compensates for the grounding load reactive power exchanged between the alternating-voltage power source and the alternating-current motor load Wherein the reactive power compensator comprises:
A compensation capacitor connected to the power load connecting line so as to be parallel to the AC motor load through a pair of compensation capacitor connecting lines;
And a plurality of secondary windings which are different from the primary windings of the single winding winder, wherein the power supply connecting line is connected to the primary winding and the secondary windings are connected in parallel to the compensation capacitor Wealth;
A winding switching unit operable to turn on and off an electrical connection between the secondary winding and the compensation capacitor according to a control signal from the outside;
A detecting unit for detecting a current flowing through the power load connecting line and a voltage applied to the compensating capacitor connecting line;
Calculating a ground load reactive power amount based on the detected current value detected by the detection unit, calculating an output voltage output through the secondary winding based on the detected voltage value detected by the detection unit, , And calculates a compensated reactive power amount for each of the secondary windings based on the output voltage of the secondary windings, and calculates a compensated reactive power amount corresponding to the compensated reactive power amount having a maximum value in a range not larger than the calculated ground- And a compensation control unit for controlling on / off operation of the winding switching unit so that the secondary winding is connected to the compensation capacitor.

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