KR100988564B1 - Power converter using fixed duty converter and variable duty converter - Google Patents

Abstract

PURPOSE: A power converter is provided to reduce the weight and volume of a linear power supply device by using a fixed drop down voltage linear regulator. CONSTITUTION: A DC-DC converter(220) changes the output voltage of a power factor improving converter(210) to a different voltage level. A linear regulator(230) is connected to the rear terminal of the DC-DC converter and drops the DC power outputted from the DC-DC converter with a preset level. An input terminal of a controller(240) is connected to the output terminal of the linear regulator. The output terminal of the controller is connected to the power factor improving converter. The controller improves a power factor by comparing the output of the linear regulator with a reference voltage.

Description

Power converter using fixed duty converter and variable duty converter

The present invention relates to a power converter using a fixed duty converter and a variable duty converter.

More specifically, the fixed duty converter and the variable duty converter can reduce the weight and volume of the linear power supply system by implementing the DC-DC converter using the fixed duty three level converter and the power factor improving converter (PFC). It relates to a power converter using.

Most of the components constituting the interior of various electronic devices used today require a DC voltage, but since the required values are different from each other, it is very important to properly convert the level of the voltage supplied to these components. Accordingly, converters for outputting a desired voltage by boosting or stepping down a predetermined voltage are widely used.

In particular, a DC-DC converter that converts an input DC power source into a DC power source having a different level has been widely used to control the flow of power using a switching operation of a power semiconductor device. The implementation of the device was made possible.

These power supplies can be divided into linear power supplies and switching power supplies.

Although the general configuration of the linear power supply is not shown in the drawing, a commercial power source includes an AC-DC converter and a capacitor including an input power supply unit receiving 220V AC power, a transformer connected to the input power supply, and a bridge diode. It consists of a DC smoothing part made up of, and when the AC power is applied through the input power source, the AC power is transformed into a voltage in the transformer consisting of the primary coil and the secondary coil and the DC power supply through the DC smoothing part composed of bridge diodes. This smooth and smooth DC power is supplied to the electronics connected to the linear supply, allowing the electronics to operate.

In addition, the switch mode power supply (SMPS) is a switching power supply, and due to the development of the related technology, it is becoming smaller and lighter than the linear power supply.

FIG. 1 is a circuit diagram showing a configuration of a general switching mode power supply device. A switching mode power supply circuit for supplying predetermined DC power to each device by receiving input power includes a transformer 10 and a rectification smoothing unit 20. And a switching unit 30 and a feedback unit 40.

In addition, the transformer 10 induces an output voltage Vout proportional to the winding ratio to the secondary side according to the input power Vin of the primary winding, and the rectification smoothing unit 20 is the secondary side of the transformer. It is connected to the output terminal of, and rectifies and smoothes the output voltage induced on the secondary side of the transformer to output a predetermined level of the induced voltage.

In addition, the switching unit 30 is connected in series with the secondary output terminal of the transformer, and detects an error of the output voltage rectified and smoothed by the rectifying smoother 20 and feeds it back to the feedback unit 40. In addition, the output voltage is applied to a regulator (not shown).

Accordingly, the feedback unit 40 includes a PWM IC (not shown) to convert the duty ratio of the primary on-off of the transformer according to the voltage level of the detection signal. A control signal generated according to the pulse width oscillation of the PWM IC is output to an internal switching element connected to the primary side of a transformer (not shown), and the switching element repeatedly performs an on-off operation by the control signal. The secondary induced voltage of the transformer is kept constant through the regulator.

However, the conventional general linear power supply has the advantages of low noise and simple structure, but has the disadvantage of being heavy, bulky and low efficiency.

In addition, switching power supplies have the disadvantage of being small in volume, light in weight and high in efficiency, but having a lot of noise components in the output.

The present invention has been made to solve the above problems of the prior art, an object of the present invention is to implement a DC-DC converter using a fixed duty three (Three) level converter and power factor correction converter (PFC) to provide a linear power supply The present invention provides a power converter using a fixed duty converter and a variable duty converter capable of reducing the weight and volume of a supply system.

In addition, the present invention provides a power conversion device using a fixed duty converter and a variable duty converter that can reduce the weight and volume of the linear power supply using a fixed drop down voltage linear regulator.

One embodiment of the present invention proposed to solve the above technical problem, in the power conversion device using a fixed duty converter and a variable duty converter, the duty is controlled by receiving the output voltage input to the load feedback A power factor improving converter 210 having a variable duty control, a DC-DC converter 220 having a fixed duty control for receiving an output voltage of the power factor improving converter 210 and converting it to another voltage level, and the DC-DC converter 220. And a linear regulator 230 connected to a rear end of the linear regulator 230 to supply a DC voltage by lowering a DC power output through the DC-DC converter 220 by a predetermined output voltage level, and the linear regulator 230. The input terminal is connected to the output terminal of the linear regulator 230 so that the output can be fed back, and the output terminal is controlled by the power factor improving converter 210. It is connected to output a call, and the feedback of the output of the linear regulator 230 is compared with a preset reference voltage, and the input terminal power factor improvement by using the drop-down correction voltage and the duty ratio generated by the comparison result value Characterized in that it consists of a controller 240 of a variable duty control to perform.

The DC-DC converter 220 is characterized in that the fixed duty three (Three) level converter.

The DC-DC converter 220 is characterized in that a full-bridge converter.

The DC-DC converter 220 is characterized in that the forward (forward) converter.

      The DC-DC converter 220 is characterized in that the flyback (Flyback) converter.

The controller 240 receives an output voltage of the linear regulator 230, an adder 241 for adding a drop-down corrected voltage to the input output voltage, and a duty to the output of the adder 241. Multiplier 242 for multiplying the information, generating the multiplied result as a power factor compensation control signal, and outputting the multiplier 242 to the power factor improving converter 210.

The output voltage of the linear regulator 230 is the output voltage of the linear regulator 230 × (duty of the pre-regulator × turn-ratio ratio of the transformer)-the calculated value of the voltage drop of the linear regulator is loaded by the linear regulator 230 The final output voltage is characterized in that the output.

The present invention having the configuration and operation and the preferred embodiment as described above is less ripple and noise than the switching power supply, the weight and volume is reduced as well as the efficiency is increased compared to the linear power supply.

In addition, the present invention can take less feedback sensitivity, and there is an effect that the immediate response is improved.

In addition, the present invention is easy to configure because the configuration of the control unit is simplified by configuring the existing dual feedback loop as a single feedback loop, and the cost is reduced due to the simplification of the circuit, the efficiency by using the voltage stress in the regulator switch at the lowest There is an effect to improve the.

1 is a block diagram illustrating a configuration of a switching power supply according to the prior art.
2 is a view for explaining the configuration of a linear power supply system according to the present invention.
FIG. 3 is a diagram for describing the controller of FIG. 2.
4 is a diagram illustrating a specific embodiment of the linear regulator applied to FIG. 2.
FIG. 5 is a detailed exemplary view of the pre-regulator shown in FIG. 2.

Hereinafter, a power conversion apparatus using a fixed duty converter and a variable duty converter according to the present invention will be described.

The power converter using the fixed duty converter and the variable duty converter of the present invention includes a power factor improving converter 210 having a variable duty control in which a duty is controlled by receiving an output voltage input to a load, and the power factor improving converter ( A DC-DC converter 220 having a fixed duty control for receiving an output voltage of 210 and converting it to a different voltage level, and connected to a rear end of the DC-DC converter 220 and outputting the DC-DC converter 220. The input terminal is connected to an output terminal of the linear regulator 230 so that the DC regulator is supplied with the output of the linear regulator 230 and the linear regulator 230 to supply the DC voltage by down by a predetermined output voltage level. The output terminal is connected to output a control signal to the power factor improving converter 210 and the output of the linear regulator 230. The control unit 240 includes a variable duty control controller 240 configured to receive the feedback, compare the reference voltage with a preset reference voltage, and perform input stage power factor improvement using the drop-down correction voltage and the duty ratio generated by the comparison result.

The DC-DC converter 220 includes a fixed duty three-level converter.

The DC-DC converter 220 includes a full-bridge converter, a forward converter, and a flyback converter.

The controller 240 receives an output voltage of the linear regulator 230, an adder 241 for adding a drop-down corrected voltage to the input output voltage, and a duty to the output of the adder 241. The multiplier 242 multiplies the information, generates the multiplied result as a power factor correction control signal, and outputs the multiplied result to the power factor improving converter 210.

The output voltage of the linear regulator 230 is the output voltage of the linear regulator 230 × (duty of the pre-regulator × turn-ratio ratio of the transformer)-the calculated value of the voltage drop of the linear regulator is loaded by the linear regulator 230 It consists of the final output voltage outputted by.

As shown in FIG. 2, the power factor improving converter 210 receives an AC voltage, which is commercial power, and converts it into a predetermined voltage in response to the power factor improving control signal input from the controller 240. ) Then, the DC-DC converter 220 receives the output of the power factor improving converter 210 and converts the output to another voltage level. In other words, the DC-DC converter 220 converts the input voltage back into a voltage proportional to the fixed duty ratio and outputs the linear regulator 230 to supply the output voltage to the load terminal.

That is, the DC-DC converter 220 is composed of three (Three) level converter as shown in Figure 5, the switch (S1, S2 and switches S3, S4 provided in the three (Three) level converter are mutually One pair is turned on or off by the same signal. Therefore, the output voltage of the three (Three) level converter is changed in proportion to the input voltage by the duty ratio of the switch.

The DC-DC converter 220 may be implemented as a fixed duty converter. The fixed duty converter fixes the duty ratio to a pre-calculated value to fix the ratio of input to output. That is, the fixed duty converter always outputs a constant output value with respect to the input.

In addition, the linear regulator 230 is an interleaving power factor improvement boost converter as shown in FIG. 4, and the power factor improvement boost converter chops the input current when the switch S1 is turned on or off to alternating current 60 Hz. The power factor is maintained at 1 by making the voltage waveform and the trend of.

The output of the linear regulator 230 is usually 1 to 4 times the input voltage, and in the present invention, the final output voltage can be controlled by adjusting the output value of the power factor improving boost converter.

At this time, the linear regulator 230 removes the ripple and noise of the voltage input from the DC-DC converter 220.

In the present invention, the final output voltage output to the load is the power factor improving boost converter output voltage x (duty of the three level converter x turn ratio of the transformer) minus the voltage drop of the linear regulator.

The resulting value of the duty ratio of the three-level converter x the turn ratio of the transformer can be replaced with a predetermined fixed value, and the voltage drop value of the linear regulator is also a fixed value.

In the present invention, since the output voltage is generated in proportion to the input, if the power factor improvement boost converter is precisely adjusted, the output voltage is precisely adjusted to receive the desired output voltage.

The DC-DC converter 220 applied to the present invention may be implemented as a full-bridge converter, a forward converter, and a flyback converter in addition to the fixed duty three-level converter described above. .

As mentioned above, although preferred embodiments of the present invention have been described in detail, those of ordinary skill in the art to which the present invention pertains should realize the present invention without departing from the spirit and scope of the present invention as defined in the appended claims. Although various modifications or changes may be made, these are included in the spirit and scope of the invention as included in the appended claims.

210: power factor converter
220: DC-DC converter
230: linear regulator
240: controller
241: adder
242: multiplier
S₁ ~ S₄: switch

Claims (7)

In a power converter using a fixed duty converter and a variable duty converter,
A power factor improvement converter 210 of a variable duty control in which a duty is controlled by receiving an output voltage inputted from a load;
A fixed duty control DC-DC converter 220 which receives the output voltage of the power factor improving converter 210 and converts the output voltage to another voltage level;
A linear regulator 230 connected to a rear end of the DC-DC converter 220 to supply a DC voltage by lowering a DC power output through the DC-DC converter 220 by a predetermined output voltage level;
The input terminal is connected to the output terminal of the linear regulator 230 so that the output of the linear regulator 230 is feedback, and the output terminal is connected to output a control signal to the power factor improving converter 210. The controller of the variable duty control which receives the output of the linear regulator 230 and compares it with a preset reference voltage and performs input stage power factor improvement using the drop-down correction voltage and the duty ratio generated by the comparison result value ( 240);
Power converter using a fixed duty converter and a variable duty converter, characterized in that consisting of.
The method of claim 1,
The DC-DC converter (220) is a fixed duty converter (3) level converter, characterized in that the power converter using a fixed duty converter and a variable duty converter.
The method of claim 1,
The DC-DC converter 220 is a full-bridge converter, characterized in that the power converter using a fixed duty converter and a variable duty converter.
The method of claim 1,
The DC-DC converter 220 is a power converter using a fixed duty converter and a variable duty converter, characterized in that the forward (forward) converter.
The method of claim 1,
The DC-DC converter 220 is a flyback (Flyback) converter characterized in that the power converter using a fixed duty converter and a variable duty converter.
The method of claim 1,
The controller 240 receives an output voltage of the linear regulator 230, an adder 241 for adding a drop-down corrected voltage to the input output voltage, and a duty to the output of the adder 241. Multiplier (242) for multiplying information, generating a multiplied result value as a power factor correction control signal and outputs to the power factor improving converter 210, characterized in that the power conversion device using a fixed duty converter and a variable duty converter.
The method of claim 1,
The output voltage of the linear regulator 230 is the output voltage of the linear regulator 230 × (duty of the pre-regulator × turn-ratio ratio of the transformer)-the calculated value of the voltage drop of the linear regulator is loaded by the linear regulator 230 Power converter using a fixed duty converter and a variable duty converter, characterized in that the final output voltage is output to.

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