KR200443044Y1 - Power factor correction circuit having noise removing means - Google Patents

Abstract

The present invention relates to a power factor correction circuit (PFC) circuit, and more specifically, to improve the power factor noise generated by the power factor correction circuit (PFC) provided in the switching mode power supply (SMPS) to flow back to the AC input stage. The present invention relates to a power factor correction circuit (PFC) having noise removing means capable of completely removing power to stabilize power factor, reducing heat generation by noise, and stabilizing a waveform of an input current.

Switching mode power supply, power factor correction circuit, noise

Description

Power factor correction circuit with noise reduction means {POWER FACTOR CORRECTION CIRCUIT HAVING NOISE REMOVING MEANS}

The present invention relates to a power factor correction circuit (PFC), and more particularly, to a power factor correction circuit (PFC) provided in a switching mode power supply (SMPS) to improve power factor. The power factor correction circuit (PFC) is equipped with a noise removing means for completely eliminating the noise flowing back to the AC input stage to stabilize the power factor, reduce heat generation by noise, and stabilize the waveform of the input current. It is about.

In general, a switching mode power supply (SMPS) uses a semiconductor device such as a power transistor (MOSFET) as a switch, converts an input voltage into a square wave voltage, and supplies a constant controlled DC output voltage to a load stage. As a device for controlling the flow of power using a switching processor of a semiconductor device, it is a stabilized power supply device that is highly efficient, strong in durability, and advantageous in miniaturization and light weight.

In such a switching mode power supply (SMPS), a pulse width modulation (PWM) method and a pulse frequency modulation (PFM) method are used as feedback control circuits capable of stabilizing an output voltage.

In recent years, a switching mode power supply using a switching converter has a power factor of a semiconductor device for correcting a power factor to improve power efficiency in a switching mode power supply (SMPS) or to obtain a high power saving effect by reducing current consumption. The trend is to develop products using compensation circuits (PFCs).

This power factor correction circuit (PFC) maximizes efficiency by raising the AC input voltage to DC 400V. The power efficiency reaches 95% or more, resulting in high power-saving effect, and the AC power supply in the 80 to 265V range without AC power selection switch. It has a merit that it does not generate audio noise in the audio band and is widely used.

As such, when the power factor correction circuit PFC is used at the input portion of the switching mode power supply SMPS that supplies power to the load stage, even if the output capacity of the switching mode power supply is high, the free voltage is easily obtained. Free Voltage) can be used, but there are cases where multiple load stages have to be operated simultaneously even at low input voltages with low input voltages.In this case, even if the current consumed by the power factor correction circuit (PFC) is low, Current flows on the AC line.

Accordingly, in case of using several sets of high frequency circuits such as street lamp, fluorescent ballast, etc. which uses the output of power factor correction circuit (PFC) as input power in parallel, the AC input terminal at low input voltage is used. There was a problem that the input waveform of is distorted.

In particular, when several sets of high frequency equipment are connected in parallel and aging test at a low input voltage of approximately 80 V, noise generated from a power factor correction circuit (PFC) flows back into the AC input stage. As described above, there is a problem that the current waveform measured at the AC input terminal is distorted as shown in FIG. 4 because the noise flowing back to the AC input terminal is not completely removed from the DC rectifying unit.

In addition, there is a problem in that the power factor is lowered due to the presence of the power factor correction circuit (PFC) that is not completely removed and thus generates a lot of heat in the power factor correction circuit, and the current waveform at the AC input stage is distorted. Accordingly, there was a problem that electromagnetic interference (EMI) occurs in the output terminal of the parallel driven load.

The technical problem to be solved by the present invention is the noise generated by the power factor correction circuit (PFC) generated by the power factor correction circuit (PFC) at the output terminal of the DC rectifying unit for rectifying the AC input power to the DC power source, the noise flowing back to the AC input terminal It is to provide a power factor correction circuit having a noise removing means for stabilizing the input waveform even when the switching mode power supply at a low input voltage in parallel drive.

The power factor correction circuit including the noise removing means for achieving the above problem is a power factor correction circuit (PFC) that receives AC power from an AC input terminal and improves the power factor output from the switching mode power supply device. A DC rectifier having a bridge diode rectified by a DC power supply and a first capacitor connected to two output terminals of the bridge diode; A switching unit having a booster and a switching transistor connected to an output terminal of the DC rectifying unit to raise the DC power to a voltage corresponding to the output of the switching mode power supply device; And a PFC controller for generating a control signal for controlling switching of the switching transistor, wherein the DC rectifying unit further comprises a noise removing means comprising an LC filter connected to an output terminal of the bridge diode.

The present invention is provided with a DC rectifier having noise canceling means for completely removing noise generated from the power factor correction circuit (PFC) and flowing back to the AC input stage, even when the switching mode power supply is driven in parallel with a low input voltage. It is advantageous to stabilize the input waveform at and reduce the heat generation in the power factor correction circuit (PFC).

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

1 is a block diagram of a power factor correction circuit with a noise removing means according to the present invention, Figure 2 is a detailed circuit diagram of a power factor correction circuit with a noise removing means according to the present invention.

1 and 2, the power factor correction circuit 10 including the noise removing unit according to an embodiment of the present invention receives an AC power supply (AC input voltage) from an AC input terminal and supplies the DC power supply. The rectifier includes a rectifying DC rectifying unit 200, a switching unit 300 for raising and outputting the rectified DC power to a predetermined voltage, and a PFC controller 400 for generating a control signal for controlling the switching unit. In this case, the power factor correction circuit (PFC), the DC rectifier, the switching unit and the PFC control unit except for the noise removing means for removing the noise that is added to the DC rectifier 200 in the form of an LC filter to flow back to the AC input stage It may be configured similarly to the compensation circuit PFC.

In addition, the power factor correction circuit 10 having the noise removing means removes noise of an AC voltage input through the AC input terminals ACL and ACN, absorbs a surge current, and removes noise, thereby eliminating noise. Zener diodes (ZN1, ZN2, ZN3) for supplying the AC and the AC input filter unit 100 with the capacitors (C2, C3, C4, C22) is preferably further included.

The DC rectifier 200 has a bridge diode (BD1) 210 for smoothing and rectifying an AC voltage filtered by a stable input power from the AC input filter unit with a DC voltage, and both terminals are connected to two output terminals of the bridge diode. It is configured to include a first capacitor (C7) connected.

That is, the AC input filter unit is connected to the input terminals (ACL, ACN) of the bridge diode 210, and the two terminals of the first capacitor (C7) are connected to the output terminals (+,-) of the bridge diode, respectively. do. Accordingly, the high frequency output noise of the power factor correction circuit PFC flowing back from the switching unit toward the bridge diode can be removed by the first capacitor C7.

In addition, the DC rectifier 200 further includes a noise removing unit 220 formed of an LC filter connected to the first capacitor C7 at the output terminal of the bridge diode. In this case, the noise removing means is configured to remove noise generated by the power factor correction circuit PFC and flowing back toward the AC input terminals ACL and ACN.

The noise removing unit 220 has one terminal connected to the output terminal (+) of the bridge diode BD1 and one terminal of the first capacitor C7 in common, and the other terminal is provided in the switching unit. An inductor L2 connected to one terminal of the booster L1, one terminal is commonly connected to the other terminal of the inductor and one terminal of the booster, and the other terminal is connected to the other terminal of the first capacitor C7. It is composed of an LC filter consisting of a second capacitor (C5) connected in common.

At this time, the first capacitor (C7) and the second capacitor (C5) is preferably configured by using a capacitor having a large capacity, to be configured to more completely eliminate the noise flowing back to the AC input terminal.

The switching unit 300 is connected to the output terminal of the DC rectifying unit booster (L1) and the switching transistor (Q1) for raising the DC power to the voltage corresponding to the output of the switching mode supply power supply (SMPS), approximately DC 400V It is configured to include. In addition, a first diode D1 connected to one terminal of the booster and a second diode D2 connected to the other terminal of the booster are further included.

The PFC controller 400 controls the switching unit so that the DC 400V is connected to the load terminal connected to the switching mode power supply even when the input voltage is low regardless of the magnitude of the AC voltage input to the AC input terminals ACL and ACN. It is configured to be connected to the gate of the switching transistor (Q1) to generate a control signal for controlling the time the current is applied to supply and maintain the DC voltage of the supply to the switching unit.

Accordingly, when the input AC voltage is a low voltage, the pulse width is largely controlled to increase the applied time, thereby improving the power factor, and when the input AC voltage is a high voltage, the pulse width is controlled small to reduce the applied time. Improve power factor.

At this time, the switching transistor Q1 supplies current to the anode terminal of the second diode D2 while switching by the control signal, thereby controlling the conduction of the second diode D2.

Thus, by forming a noise removing means made of an LC filter between the bridge diode of the DC rectifier and the booster of the switching part, the noise generated by the power factor correction circuit (PFC) and flowing back to the AC input stage is more completely removed. The input power of can be maintained more stably.

In addition, the power factor correction circuit (PFC) equipped with a noise removing means according to the present invention, the load of the switching mode power supply (SMPS) has a plurality of load sets, such as street lamps, fluorescent ballasts, etc. When connected in parallel and a low input voltage of 80V is applied to the AC input terminal, the power factor correction circuit (PFC) may be configured to output a DC 400V to each load by raising the low input voltage to a constant magnitude. In this case, the effect of eliminating the noise flowing back to the AC input terminal, the improvement according to the reduction of heat generation, and the elimination effect of the electromagnetic interference (EMI) can be more markedly realized.

3 is a waveform diagram of an input current measured at an AC input stage provided with a power factor correction circuit having a noise removing unit according to the present invention, and FIG. 4 is a waveform diagram of an input current measured at an AC input stage in the absence of a noise removing unit. to be.

3 and 4, when the noise removing means for removing the backflow noise is provided in the DC rectifying unit, it can be seen that the waveform of the input current measured at the AC input terminals ACL and ACN is stably maintained. In the absence of a removal means, the degree of improvement can be more clearly seen compared to the distorted waveform of the input current measured at the AC input. In addition, since the noise is more completely removed by the noise removing means, it is possible to prevent the power factor from falling or generating a lot of heat due to noise in the power factor correction circuit PFC.

In the above description, the technical idea of the present invention has been described together with the accompanying drawings, which describes exemplary embodiments of the present invention by way of example, and does not limit the present invention. In addition, it is obvious that any person having ordinary knowledge in the technical field to which the present invention belongs may make various modifications and imitations without departing from the scope of the technical idea of the present invention.

1 is a block diagram of a power factor correction circuit having a noise removing means according to the present invention;

2 is a detailed circuit diagram of a power factor correction circuit having noise removing means according to the present invention;

3 is a waveform diagram of an input current measured at an AC input terminal provided with a power factor correction circuit having a noise removing means according to the present invention;

4 is a waveform diagram of an input current measured at an AC input stage when there is no conventional noise removing means.

<Explanation of symbols for main parts of the drawings>

100-AC input filter part 200-DC rectifier part

210-Bridge Diode 220-Noise Reduction

300-switching part 400-PFC control part

Claims (2)

In the power factor correction circuit (PFC) for receiving the AC power from the AC input terminal to improve the power factor output from the switching mode power supply, A DC rectifier having a bridge diode receiving AC power and rectifying the DC power, and a first capacitor connected to two output terminals of the bridge diode; A switching unit having a booster and a switching transistor connected to an output terminal of the DC rectifying unit to raise the DC power to a voltage corresponding to the output of the switching mode power supply device; And A PFC controller configured to generate a control signal for controlling switching of the switching transistor, The DC rectifier is a power factor correction circuit with noise removing means, characterized in that it further comprises a noise removing means consisting of an LC filter connected to the output terminal of the bridge diode. The method of claim 1, The noise removing means, An inductor having one terminal connected in common to the output terminal of the bridge diode and one terminal of the first capacitor and the other terminal connected to the booster; And One terminal is connected to the other terminal and the booster of the inductor in common, and the other terminal is provided with a noise filter comprising an LC filter consisting of a second capacitor connected to the other terminal of the first capacitor. Power factor correction circuit.

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