KR20000001770A - Drive controlling device of boost converter for power factor control - Google Patents

Abstract

PURPOSE: A drive controlling device of a boost converter for the power factor control is provided to prevent the bad influence by the harmonics by raising the power factor of power circuit, to raise the power efficiency and to improve the system reliability by meeting the international standard. CONSTITUTION: The drive controlling device of a boost converter comprises:a boost converter unit(20) for performing the action to improve the power factor of the voltage outputted from a stopping unit; a power-factor control signal driving unit(30) for outputting the switching signal for controlling the power factor to the boost converter unit(20) by detecting the output voltage and using the power and voltage values thereof; and an auto power breaking unit(40) for breaking the supplied power of the power-factor control signal driving unit(30) by the signal inputted from the excessive current sensing units(17, 21).

Description

Drive control device of step-up converter for power factor control

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drive control apparatus for a step-up converter for power factor control, and more particularly, in driving a boost converter by applying a power factor control device for improving power factor in an air conditioner. Drive control of a step-up converter for power factor control to protect the switching element of a step-up converter by automatically shutting off the power supply of the power factor control device in the event of abnormal operation by interlocking with a current detecting resistor and an overcurrent protection circuit configured to protect the switching element. Relates to a device.

In the outdoor unit of the air conditioner, in order to realize a wide range of rotational speed control of the motor in the compressor, an AC power source is first converted into a DC power source, and the configuration of the motor driving apparatus for controlling the rotational speed of the motor by an inverter using the same is illustrated in FIG. 1. A noise filter 11 for removing noise contained in the commercial power supply 10 as described above; A power factor correction filter (12) located at the rear end of the noise filter (11) to improve the power factor of the power source; A rectifier 13 for rectifying and outputting commercial power inputted through the power factor improving filter 12; A smoothing capacitor C for smoothing the voltage output from the rectifying unit 13 and converting the voltage into a direct current; An inverter (14) for converting the DC voltage of the smoothing capacitor (C) into an alternating current having an arbitrary variable frequency through pulse width modulation (hereinafter referred to as " PWM "); A compressor motor 15 driven by an AC voltage supplied from the inverter 14; A current detector 16 which detects an output current of the inverter 14; An overcurrent detection unit (17) which receives the detection signal from the current detection unit (16) and determines whether there is an overcurrent; And a control unit 18 for outputting a PWM control signal according to the output signal of the overcurrent detecting unit 17 and controlling the inverter 14 through the inverter driving means 19. The explanation is as follows.

In FIG. 1, the noise filter 11 is connected to one side of the AC power source 10 to remove noise carried by the AC voltage, and the power factor improvement filter 12 located at the rear end of the noise filter 11 has a power factor of the power source. When the rectifier 13 rectifies and outputs the commercial power input through the power factor improving filter 12, the rectifier 13 receives the smooth power from the smoothing capacitor C and converts it to a direct current, as shown in FIG. It flows only when the input current is greater than the DC smoothing voltage (V ₀ ), not when it is small.

The DC voltage output from the smoothing capacitor C is inputted from the inverter 14 to the compressor motor 15 which becomes a load by changing to an alternating current having an arbitrary variable frequency through pulse width modulation (hereinafter referred to as "PWM"). The inverter 14 includes a three-phase switching bridge circuit composed of six switching elements 6a to 6f connected in three-phase bridges, and six diodes connected in anti-parallel to the switching elements 6a to 6f. D1 to D6).

The current detector 16 detecting the output current of the inverter 14 outputs a detection signal to the overcurrent detector 17 so as to protect the switching elements 6a to 6f from overcurrent, and receives the overcurrent detector 17. ) Determines whether there is an overcurrent and outputs a signal corresponding thereto to the controller 18, and the controller 18 inputs a PWM control signal according to the input signal to the inverter 14 through the inverter driving means 19. The rotation speed of the compressor motor 15 is controlled by supplying a three-phase AC voltage according to the PWM control signal.

As described above, in the prior art, when there is no separate power factor control function, the power factor usually has a value between 0.4 and 0.7, and the harmonics component is large, so that the international standard IEC 1000-3 cannot be satisfied. In addition, when the power factor of the power circuit is low, the harmonic current increases, which leads to an increase in power loss as well as an adverse effect of harmonics on the power bus. Also, when the power factor is low, the effective power also becomes small. There is this decreasing problem.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and includes a current detection resistor and an overcurrent protection circuit configured to protect a switching element of an inverter by applying a power factor controller for improving power factor. It is an object of the present invention to provide an apparatus for protecting a switching element of a boost converter by automatically interlocking a power supply of the power factor control device in an abnormal operation.

1 is a block diagram showing a configuration of a conventional electric motor drive device.

FIG. 2 is a waveform diagram illustrating a relationship between an input current and a DC smoothing voltage in FIG. 1. FIG.

Figure 3 is a block diagram showing the configuration of one embodiment of a drive control device of the boost converter for power factor control of the present invention.

*** Description of the symbols for the main parts of the drawings ***

13: rectifier 14: inverter

16: current detector 17, 21: overcurrent detector

18 control unit 20 step-up converter

30: power factor control signal driver 31: input current detector

32: input voltage detector 33: output voltage detector

34: error amplifier 35: multiplier

36: amplifier 37: oscillator

38: comparison unit 39: switching control unit

40: automatic power cutoff part C: smoothing capacitor

D1 to D6, D: diode S1, 6a to 6f: switching element

In order to achieve the above object, the drive control apparatus of the step-up converter for power factor control according to the present invention includes a rectifier, a smoothing capacitor, an inverter, a current detector, an overcurrent detector, a cooler motor, and a controller. A boost converter configured to perform an operation for improving a power factor with respect to the voltage output from the rectifier; A power factor control signal driver for detecting an input voltage and an output voltage generated during a load operation, and outputting a switching signal for power factor control to the boost converter using current and voltage values thereof; And an automatic power cut-off unit which cuts off a power supply of the power factor control signal driver by a signal input from the overcurrent detector.

The automatic power cut-off unit may receive the detection signal of the current detector through the overcurrent detector and operate in conjunction with the controller.

The power factor control signal driver comprises: an input current detector for detecting an input current; An input voltage detector for detecting an input voltage; An output voltage detector for detecting an output voltage generated during a load operation; An error amplifier for outputting a difference voltage generated by comparing the detected voltage of the output voltage detector with a reference voltage (the rated value of the direct current voltage); A multiplier for multiplying a detection voltage of the input voltage detector by an error voltage input from the error amplifier; An amplifier for amplifying and outputting a difference between the current value detected by the current detector and the output of the multiplier; An oscillator for generating and outputting a triangular wave of a predetermined period; A comparator for comparing the output of the amplifier with the triangular wave generated by the oscillator and outputting a pulse width modulated signal accordingly; And a switching control unit for outputting a control signal according to the pulse width modulation signal received from the comparing unit to the switching element of the boost converter unit.

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

Figure 3 is a block diagram showing an embodiment of a drive control device of the step-up converter for power factor control of the present invention, as shown in the rectifier 13, smoothing capacitor (C), inverter 14, cooler In a motor drive device including a motor 15, a current detector 16, a controller 18, and an overcurrent detector 21, a choke coil L for cutting off a high frequency current of a specific frequency or more. and; A switching element S1 that is turned on / off by a control signal of the power factor control signal driver 30 to control the amount of input current; A diode (D) for conducting when the switching element (S1) is off and applying a current flowing through the choke coil (L) to a smoothing capacitor; An input current detector 31 detecting an input current; An input voltage detector 32 detecting an input voltage; An output voltage detector 33 for detecting an output voltage generated during a load operation; An error amplifier 34 for outputting a difference voltage generated by comparing the detected voltage of the output voltage detector 33 with a reference voltage (rated value of the direct current voltage); A multiplier (35) multiplying the detected voltage of the input voltage detector (33) by the error voltage input from the error amplifier (34); An amplifier (36) for amplifying and outputting a difference between the current value detected by the input current detector (31) and the output of the multiplier (35); An oscillator 37 generating and outputting a triangular wave of a predetermined period; A comparator 38 for comparing the output from the amplifier 36 with the triangular wave generated by the oscillator 37 and outputting a pulse width modulated signal when the output of the amplifier 36 is higher than the triangular wave; A switching control unit 39 outputting a control signal according to the pulse width modulation signal received from the comparison unit 38 to the switching element S1 of the boost converter unit 20; The automatic power cut-off unit 40 cuts off the supply power of the power factor control signal driver 30 in response to the signal input from the overcurrent detector 21.

Referring to the operation process and effect of the embodiment according to the present invention configured as described above are as follows.

There are two methods used to improve the power factor, one of which can be improved by using a filter using a passive element, but cannot satisfy the international standard, and the other method is FIG. 3. The power factor and harmonics are reduced by using the power factor control shown in FIG.

3 shows the rectifying unit 13, the smoothing capacitor C, the inverter 14, the current detecting unit 16, the overcurrent detecting unit 17, the cooler motor 15, and the control unit 18 shown in FIG. The inverter further includes a booster converter 20, a power factor control signal driver 30, and an automatic power cut-off unit 40. When the commercial power supply 10 is rectified by the rectifier 13, the output (V _IN) ) Has a frequency twice as high as the input power frequency (60 kHz). When this voltage is used as an input, the switching element S1 of the boost converter unit 20 is switched, and the choke coil L is in phase with V _IN. Phosphorus current flows, but when viewed from the commercial power supply 10, a sine wave current in phase with an input voltage of 60 kV flows to bring the power factor closer to 1.0.

If the switching element S1, the diode D, and the choke coil L are all ideal, first, when the switching element S1 is turned on, the choke coil L receives an input voltage V _IN , and the current Rises linearly. At this time, power is supplied to the load by the smoothing capacitor (C). On the contrary, when the switching element S1 is turned off, the diode D is turned on so that (V ₀ -V _IN ) is applied to the choke coil L in the opposite direction to the above case. The choke coil current I _L decreases linearly. In this case, the smoothing capacitor C is charged by supplying power from an input to an output. This operation is repeated to improve the power factor by allowing the current I _L of the choke coil L to follow the shape of the input voltage.

The switching of the switching element S1 is controlled by the switching control unit 39 of the power factor control signal driver 30 as follows. First, the DC voltage generated in the smoothing capacitor C is detected in the divided state by the output voltage detector 33, and the error voltage generated due to the comparison between the detected voltage and the reference voltage (rated value of the DC voltage) is an error amplifier ( Outputted from 34). The input voltage detector 32 detects the output voltage of the rectifier 13, receives the input voltage from the multiplier 35, and multiplies the error voltage input from the error amplifier 34. Accordingly, in the multiplier 35, the input voltage waveform is corrected by the output of the error amplifier 34. Therefore, the output of the multiplier 35 corresponds to the increase of the voltage according to the DC voltage component and the input voltage.

In addition, the input current value is detected by the input current detector 31, which is compared with the output of the multiplier 35 in the amplifier 36 and amplifies the difference, thereby detecting the current waveform synchronized with the voltage waveform. . The output of the amplifier 36 is compared with a triangular wave of a certain period generated from the oscillator 37 by the comparator 38, and when the output of the amplifier 36 is higher than the triangular wave, a pulse width modulated signal is output. Numeral 39 outputs the control signal corresponding to the pulse width modulated signal to the switching element S1 of the booster converter 20.

Thereafter, the inverter 14 receives the pulse width modulation control signal output from the control unit 18 through the inverter driving means 19 and supplies three-phase AC power to control the rotational speed of the compressor motor 15, and load When an overcurrent flows or an abnormal operation occurs, it is detected by the current detector 16 detecting the output current, and then input to the overcurrent detector 21 to transmit an abnormal operation detection signal to the controller 18. The controller 18 outputs an operation stop signal to the inverter 14 through the inverter driving means 19 to stop the operation, while the automatic power cut-off unit 50 receives the signal received from the overcurrent detector 21. By automatically shutting off the power supplied to the power factor control signal driver 30 to stop the operation of the switching element S1 in the boost converter 20, thereby preventing damage to the switching element S1 due to an abnormal operation. Prevent .

As described above, the drive control apparatus of the step-up converter for power factor control according to the present invention increases the power factor of the power supply circuit, thereby preventing adverse effects due to harmonics on the power bus, and increasing the efficiency of power used at home. Satisfying the international standard IEC 1000-3 has the effect of improving the reliability of the system.

Claims (3)

In a motor driving apparatus including a rectifier, a smoothing capacitor, an inverter, a current detector, an overcurrent detector, and a cooler motor, a boost converter unit for performing an operation for improving the power factor with respect to the voltage output from the rectifier; ; A power factor control signal driver for detecting an input voltage and an output voltage generated during a load operation, and outputting a switching signal for power factor control to the boost converter using current and voltage values thereof; And an automatic power cut-off unit which cuts off a power supply of the power factor control signal driver by a signal input from the overcurrent detector. The driving control apparatus of claim 1, wherein the automatic power cut-off unit receives the detection signal of the current detection unit through the overcurrent detection unit and operates in conjunction with the control unit. The power control device of claim 1, wherein the power factor control signal driver comprises: an input current detector configured to detect an input current; An input voltage detector for detecting an input voltage; An output voltage detector for detecting an output voltage generated during a load operation; An error amplifier for outputting a difference voltage generated by comparing the detected voltage of the output voltage detector with a reference voltage (the rated value of the direct current voltage); A multiplier for multiplying a detection voltage of the input voltage detector by an error voltage input from the error amplifier; An amplifier for amplifying and outputting a difference between the current value detected by the input current detector and the output of the multiplier; An oscillator for generating and outputting a triangular wave of a predetermined period; A comparator for comparing the output of the amplifier with the triangular wave generated by the oscillator and outputting a pulse width modulated signal when the output of the amplifier is higher than the triangular wave; And a switching control unit for outputting a control signal according to the pulse width modulation signal received from the comparing unit to a switching element of the boosting converter unit.