KR20060089430A - Method for selecting a reactor of power factor compensation circuit - Google Patents

Abstract

The present invention relates to a method for optimizing and selecting a reactor used in a power factor correction circuit, comprising: a rectifying unit converting an AC power source into a DC power source, a reactor coupled between the rectifying unit and an AC power source, and detecting an input current; An input current detector, a zero crossing detector for detecting zero crossing of an input AC power supply, a DC link voltage detector for detecting a rectified DC voltage, and an ON / OFF operation according to a power factor correction control signal to vary the reactor output voltage. In the reactor optimization selection method of the power factor correction circuit including a power factor correction unit including a power factor correction switch to

Selecting a range of reactor values capable of maximum load operation while changing the reactor value; Extracting only reactor values satisfying a harmonic regulation range from the selected reactor values; And selecting a reactor value having the lowest power consumption among the extracted values as an optimal reactor value.

Reactor, power factor correction, harmonics.

Description

Reactor optimization of power factor correction circuit {METHOD FOR SELECTING A REACTOR OF POWER FACTOR COMPENSATION CIRCUIT}

1 is a diagram illustrating a configuration of a power factor correction circuit used in an inverter air conditioner according to an embodiment of the present invention.

FIG. 2 is a flow chart of reactor 102 optimization selection as one component of the power factor correction circuit shown in FIG.

3 is a diagram illustrating a current waveform according to an embodiment of the present invention.

The present invention relates to a power factor correction circuit, and more particularly, to a method for optimizing and selecting a reactor used in the power factor correction circuit.

The power factor correction circuit used in the inverter air conditioner will be described.

First, as shown in FIG. 1, the power factor correction circuit used in an inverter air conditioner includes a reactor 102 representing a reactance of an AC power supply 101, a bridge diode 104, and smoothing capacitors C1-C3. A rectifier 103 for converting the power into a DC power source, an inverter unit 105 for converting the DC power into an AC power source to drive the motor 106, an input current detector 107 for sensing the input current, and an input. A zero crossing detection unit 108 for detecting zero crossings of the AC power source, a DC link voltage detection unit 109 for detecting the rectified DC voltage, a power factor correction unit 110 for controlling the power factor compensation by a backflow compensation control signal, and The microcomputer 120 controls the inverter unit 105 using the data detected from the input current detector 107, the zero crossing detector 108, and the DC link detector 109, and controls the on / off of the backflow compensation switch. It is composed of

The power factor correction unit 110 is connected to the bridge diode 111 and the bridge diode 111 is switched on and off by the power factor correction control signal to actively change the high frequency noise and the output voltage. Power factor correction switch (IGBT) 112;

The operation of the power factor correction circuit having the above-described configuration will be described in detail.

The microcomputer 120 detects the zero crossing position of the input voltage through the zero crossing detection unit 108 and turns on the power factor correction switch IGBT when the zero crossing point of the detected input voltage is reached. Thereafter, after comparing the DC link voltage detected by the DC link voltage detector 109 with the target DC voltage, if the DC link voltage matches the target voltage, the power factor correction switch is turned off. Here, the target DC voltage sets the DC link voltage having the highest power factor as the target DC link voltage.

As described above, when the switch of the power factor correction unit is turned on at the zero crossing point of the power supply voltage, there is a limit to the power factor improvement. The reason is that the conventional power factor improving method detects the zero crossing position of the input voltage irrespective of the load, and then turns the power factor correction switch on and off at regular intervals at that position, thereby maintaining a constant power factor for a wide operating range of the load. Because it can't be controlled.

In order to solve this problem, there is a "power factor compensation control method of the inverter control circuit" filed by the applicant of the present application to the Korean Patent Office. The power factor correction control method,

Detecting a zero crossing position of the input voltage phase, setting an on time of the power factor correction switch at a time delayed from the zero crossing position, and checking whether the set time delay has elapsed. Turning on the power factor correction switch when the current DC link voltage reaches the target DC voltage after comparing the current DC link voltage with the target DC link voltage; And measuring the magnitude and adaptively decrementing the time delay value for the on time of the power factor correction switch according to the motor load size according to the measurement result.

However, in the inverter air conditioner employing the "power factor correction control method" having the characteristics described above, the power factor correction is improved by varying the time delay value for the on time of the power factor correction switch according to the motor load size. The use of the reactor has the disadvantage that the power consumption of the entire circuit increases.

Therefore, an object of the present invention is to select a reactor that satisfies the maximum load operating conditions, to provide a reactor optimization selection method that can increase the power use efficiency by selecting a reactor that the power consumption is reduced according to the use of the reactor.

Reactor optimization selection method according to an embodiment of the present invention for achieving the above object, the rectifier for converting AC (AC) power source to the DC power source, the reactor coupled between the rectifier and AC power source, and detecting the input current An input current detector, a zero crossing detector for detecting zero crossing of an input AC power source, a DC link voltage detector for detecting a rectified DC voltage, and an ON / OFF operation according to a power factor correction control signal to vary the reactor output voltage. As a method for applying to a power factor correction circuit including a power factor correction unit having a power factor correction switch,

Selecting a range of reactor values capable of maximum load operation while changing the reactor value;

Extracting only reactor values satisfying a harmonic regulation range from the selected reactor values;

And selecting a reactor value having the lowest power consumption among the extracted values as an optimal reactor value.

Furthermore, for each of the selected reactor values,

A reactor value satisfying a harmonic regulation range is extracted while changing the time delay value for turning on the power factor correction switch on the basis of the point where the phase of the input voltage is zero-crossed.

According to the characteristics of the present invention, it is possible to minimize the power consumption according to the use of the reactor while satisfying the maximum load operating conditions, that is, the maximum operating frequency and the harmonic regulation range, resulting in improved power usage efficiency. will be.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

First, FIG. 1 illustrates a configuration diagram of a power factor correction circuit used in an inverter air conditioner according to an embodiment of the present invention, and FIG. 2 illustrates optimization of a reactor 102 which is one component of the power factor correction circuit illustrated in FIG. 3 shows a selection flow chart, and FIG. 3 shows an example of a current waveform according to an embodiment of the present invention.

In order to optimize the reactor value used in the power factor correction circuit according to the embodiment of the present invention, a test power factor correction circuit as shown in FIG. 1 should be basically constructed.

The power factor correction circuit shown in FIG. 1 is basically composed of a reactor 102 representing the reactance of the AC power source 101, a bridge diode 104, and a smoothing capacitor C1-C3 to convert the AC power source to the DC power source. A rectifier 103, an inverter unit 105 that converts a DC power source into an AC power source to drive the motor 106, an input current detector 107 that senses an input current, and detects zero crossing of the input AC power source. A zero crossing detection unit 108, a DC link voltage detection unit 109 for detecting the rectified DC voltage, a power factor correction unit 110 for controlling the power factor correction by a backflow compensation control signal, and the input current detection unit 107 And the microcomputer 120 that controls the inverter unit 105 and controls the on / off of the backflow compensation switch (IGBT) 112 by using the data detected by the zero crossing detection unit 108 and the DC link detection unit 109. can do.

For reference, the microcomputer 120 may be programmed to sequentially change a time delay value for turning on the power factor correction switch based on a point where the phase of the input voltage is zero-crossed according to a user command.

Meanwhile, the power factor correction unit 110 is switched on / off by a bridge diode 111 connected to an input AC link and a power factor correction control signal connected to the bridge diode 111 and output from the microcomputer 120. And a power factor correction switch (IGBT) 112 that actively varies the output voltage.

Hereinafter, a method for optimizing the reactor 102 value of the power factor correction circuit having the above-described configuration will be described in detail with reference to FIG. 2.

First, as the first step S1, a range of reactor values capable of maximum load operation is selected while changing the reactor 102 value of the power factor correction circuit shown in FIG. In the case of the inverter control circuit, the maximum load operation is possible from 8mH to 30mH.

When a range of reactor values capable of maximum load operation is selected as the first step S1, only reactor values satisfying the harmonic regulation range are extracted from the selected reactor values as the second step. The method for extracting only reactor values satisfying a harmonic regulation range among the selected reactor values may include the power factor based on the point where the phase of voltage AC input to the power factor correction circuit is zero-crossed for each of the selected reactor values. It can be implemented by checking whether the microcomputer 120 satisfies the harmonic regulation range while changing the value of the time delay (defined as “on time delay”) for turning on the compensation switch 112 according to an operator's command.

For reference, referring to FIG. 3, it can be seen that the current waveform represented by the solid line has moved to the dotted line according to the on time delay adjustment. The current waveform moved by the on time delay shows that the harmonic components are removed.

On the other hand, if only the reactor value satisfying the harmonic regulation range is extracted from the reactor values selected in the first step, the reactor value having the lowest power consumption is selected as the optimal reactor value (S3). Finally, the optimal reactor value is finally applied to the actual power factor correction circuit. In addition, the step of selecting an optimal reactor value may be expressed as selecting a reactor design. This is because the power consumption of the reactor 102 depends on the size of the reactor, the number of winding coils, and the like.

As described above, the present invention can select the reactor with the minimum power consumption while satisfying the maximum load operating conditions, and as a result, the power usage efficiency of the power factor correction circuit can be improved.

Meanwhile, as a modified embodiment of the present invention, an optimal reactor may be selected by the following method.

First, after temporarily selecting the reactor value, it is checked whether the selected reactor value satisfies the maximum load operating condition.If not, the new reactor value is temporarily selected, and if it is satisfied, the reactor value is selected. Model is selected. Then, if the harmonic regulation range is satisfied while changing the "on time delay" value with respect to the tentatively selected reactor value, the reactor value is selected as the optimal reactor value. The above-described process is repeated.

Such a modified embodiment of the present invention is also able to select the reactor with the minimum power consumption while satisfying the maximum load operating conditions, as a result it is possible to improve the power usage efficiency of the power factor correction circuit.

As described above, in the present invention, in selecting a reactor value of a power factor correction circuit used in an inverter control circuit such as an inverter air conditioner, the reactor can be selected to satisfy a maximum load operating condition while minimizing power consumption. Therefore, there is an advantage to increase the power use efficiency of the entire circuit.

On the other hand, the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be defined only by the appended claims.

Claims (2)

A rectifier for converting AC power to DC power, a reactor coupled between the rectifier and an AC power source, an input current detector for sensing input current, a zero crossing detector for detecting zero crossing of the input AC power, A reactor optimization selection method of a power factor correction circuit including a DC link voltage detector for detecting a rectified DC voltage and a power factor compensation unit including a power factor compensation switch for turning the reactor output voltage on and off according to a power factor correction control signal. To Selecting a range of reactor values capable of maximum load operation while changing the reactor value; Extracting only reactor values satisfying a harmonic regulation range from the selected reactor values; And selecting a reactor value having the lowest power consumption among the extracted values as an optimal reactor value. The method of claim 1, wherein for each of the selected reactor value, Reactor optimization selection method characterized in that for extracting only the reactor value satisfying the harmonic regulation range while changing the time delay value for turning on the power factor correction switch on the basis of the point where the phase of the input voltage is zero crossing.

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