KR20140127404A - Boost converter improved line regulation - Google Patents

Abstract

The present invention relates to a boost converter which is used to output a voltage higher than an input voltage. The boost converter according to an embodiment of the present invention includes: a voltage input unit; a rectifying unit; an output voltage unit; an output voltage determination unit; a reference voltage generating unit; a voltage comparison unit; and a pulse width modulation (PWM) unit. The reference voltage generation unit is used as a supply voltage by giving feedback to the output voltage (VOUT). The rectifying unit includes at least one diode.

Description

[0001] BOOST CONVERTER IMPROVED LINE REGULATION [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a boost converter for outputting a voltage higher than an input voltage and more particularly to a boost converter for generating a constant reference voltage V _REF by feeding an output voltage V _OUT to a reference voltage generator, The present invention relates to a boost converter capable of improving a line voltage variation rate capable of generating a constant output voltage (V _OUT ) irrespective of a change in an input voltage (V _IN ) by making the output voltage (V _OUT ) reachable.

In recent years, various power supply devices capable of boosting low DC voltage for fuel cell or battery-based electric drive system, semiconductor manufacturing equipment, large display device, ultrasonic wave and X-ray device have been researched and developed .

A typical example of such a power supply device is a boost converter. Boost converter refers to a circuit capable of boosting the voltage and can obtain a higher output voltage V _OUT compared to the input voltage V _IN whereas the output current I _OUT is equal to the input current I _IN , So that it does not violate the energy conservation law.

The operation principle of a basic boost converter will be described. When power is applied to an input terminal, energy is accumulated in the inductor while current flows through an inductor.

When the power supply is stopped by the use of a switch, the energy stored in the inductor is released, and the emitted energy has a polarity opposite to the input current for energy storage.

The phenomenon that a current flows in the direction opposite to the current flowing when the current is shed is referred to as a counter electromotive force. Such a back electromotive force is generated, but the voltage rises at a short moment, and this phenomenon is caused by the self induction phenomenon for a quite long time .

The generated output voltage (V _OUT ) is outputted and then rectified by a diode or the like in order to filter only the current of the required component.

Even if the above phenomenon is maintained for a long period of time, it is only maintained for several tens to several hundreds of seconds. Therefore, the above-described procedure must be continuously repeated to obtain a constant output. That is, it is preferable to use a pulse signal because the switching process requires a very fast process. The duty ratio of the on / off time of the pulse signal may be a gain of the boost converter, Lt; / RTI > This will be described later.

However, the conventional boost converter for generating the desired output voltage (V _OUT) the reference voltage (V _REF) and a comparison function, and pulse width modulation matching and at the same time, a voltage based on the function (V _REF) in order to maintain or control the size of the The input voltage V _IN is generally used. However, in the case of the reference voltage V _REF , when the input voltage V _IN changes, the size of the input voltage V _IN changes correspondingly.

This is because, when the reference voltage V _REF changes, the output voltage V _OUT is not maintained constant, and fluctuates according to the change of the reference voltage V _REF , thereby deteriorating the line regulating characteristic.

Therefore, it is inevitable to develop a boost converter in which the output voltage of the boost converter is constant, that is, the line voltage variation rate is improved.

The present invention is conceived to solve the problems of the prior art, by using the generation of the reference voltage (V _REF) the output voltage (V _OUT) of the boost converter, the effect on the variation of the input voltage (V _IN) The present invention is directed to a boost converter with improved line voltage fluctuation.

The technical objects to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical subjects which are not mentioned can be clearly understood by those skilled in the art from the description of the present invention .

According to an aspect of the present invention, there is provided a boost converter for generating an output voltage higher than an input voltage, the boost converter comprising: a voltage input unit for applying an input voltage V _IN to the boost converter; A rectification part connected between the voltage input part and the output voltage part to prevent reverse current of the current, an output voltage part for generating an output voltage V _OUT having a predetermined ratio of the input voltage, (V _OUT) the reference voltage to be compared with a Dividing output voltage (V _{REF _ OUT)} measured at the output voltage determining unit, said output voltage determining unit for determining with a Dividing output voltage (V _{REF_OUT)} measuring the amount of ( V _REF) Dividing the output voltage (V _REF measured in the reference voltage generating unit, said output voltage determining unit that generates _{_ OUT)} and the size of a reference voltage (V _REF) generated by the reference voltage generation unit And a pulse width modulation (PWM) unit for varying a duty ratio of the pulse signal according to a comparison result in the voltage ratio granting unit and the voltage ratio granting unit, On signal time divided by one cycle time of the pulse signal and the reference voltage generator uses the output voltage as a feedback voltage to use as a supply voltage. Boost converter.

In the present invention, the rectifying unit preferably includes at least one diode.

In the present invention, the output voltage unit may include at least one capacitor.

In the present invention, it is preferable that a predetermined ratio with _respect to the input voltage (V _IN ) corresponds to "1 / (1 - D)" (D is duty).

The output voltage determining section at least is composed, including at least two resistors, the second size and Dividing the output voltage of the output voltage (V _OUT) each of one or more resistance across the both ends of the resistance (V _{REF _ OUT)} In the present invention, And the gain of the boost converter is determined.

The pulse width modulation according to the present invention comprises: the Dividing output voltage (V _{REF _ OUT)} in this case is lower than the reference voltage (V _REF) and to increase the duty ratio (D) of the pulse signal, the Dividing output voltage (V If _{REF _ OUT)} is higher than the reference voltage (V _REF) it is preferably configured to reduce the duty ratio (D) of the pulse signal.

In the present invention, the pulse signal may be input to a gate of an N-type MOSFET (Metal Oxide Semiconductor Field Effect Transistor).

In the present invention, during the initial operation of the boost converter, the output voltage (V _OUT ) is generated at the input voltage (V _IN ), the reference voltage generator is operated, and the boosted output voltage (V _OUT ) It is preferable that the reference voltage generator is operated using only the reference voltage generator.

The present invention is an output voltage (V _OUT) for feedback to the reference voltage (V _REF) by using a supply voltage of generating a constant reference voltage (V _REF) to changes in the input voltage (V _IN) of the boost converter is generated, whereby A constant output voltage V _OUT is generated, and a boost converter in which the above-mentioned process is repeatedly improved in the line voltage variation rate can be provided.

FIG. 1 is an exemplary view showing the operation principle of a conventional boost converter; FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a boost converter.
3 is a configuration diagram of a boost converter with improved line voltage variation according to an embodiment of the present invention.
4 is a detailed block diagram of a boost converter with improved line voltage variation according to an embodiment of the present invention.
5 is a graph showing the line voltage variation rate of a conventional boost converter.
FIG. 6 is a graph showing a line voltage variation rate of a boost converter with improved line voltage variation according to an embodiment of the present invention. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present description and claims should not be construed as limited to ordinary or dictionary meanings, and the inventor should properly interpret the concepts of the terms in order to describe their invention in the best way. It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It is to be understood that equivalents and modifications are possible.

By using the output voltage V _OUT of the boost converter as the supply voltage for generating the reference voltage V _REF , a line regulation that is not affected by the change of the input voltage V _IN According to the present invention, there is provided an improved boost converter comprising: a voltage input unit for applying an input voltage (V _IN ) to a boost converter; and a control unit for controlling the voltage input unit and the output voltage An output voltage section for generating an output voltage V _OUT having a voltage magnitude at a predetermined ratio with respect to the input voltage V _IN and an output voltage section for generating an output voltage V and _OUT) output voltage is determined by taking the Dividing output voltage (V _{REF _ OUT)} measuring the determiners of, be compared with a Dividing output voltage (V _{REF_OUT)} measured by the output voltage determiner Applied voltage (V _REF) to a reference voltage generator for generating, a Dividing output voltage measured by the output voltage determining unit (V _{REF _ OUT)} and the size of a reference voltage (V _REF) generated by the reference voltage generation unit And a pulse width modulation (PWM) unit for generating a pulse ratio signal and a duty ratio D of the pulse signal according to the voltage comparison result of the voltage comparison unit The reference voltage generator uses the output voltage V _OUT as a feedback voltage. The duty (D) corresponds to a value obtained by dividing the ON signal time of one pulse of the pulse signal by one cycle time of the pulse signal.

As shown in Fig. 1 (a), the boost converter has a configuration capable of boosting and amplifying the input power. Before describing the present invention in detail, the operation principle of the conventional boost converter will be described as follows.

First, when the pulse signal is on, the N-type MOSFET is turned on and energy is stored in the inductor with the inductor current (I _L ) flowing through the inductor (Inductor).

Thereafter, when the pulse signal is off, the N-type MOSFET is turned off, and the energy stored in the inductor is transferred to the output terminal in the form of current through a diode for rectification.

Since the inductor current I _L stored in the inductor and the current delivered from the inductor must have the same energy due to the energy conservation law, the output voltage V _OUT having a predetermined ratio to the input voltage V _IN is extracted You can do it.

A circuit having such characteristics is called a boost converter, and the value of the output voltage V _OUT according to the input voltage V _IN can be determined by the duty D of the pulse signal, which will be described later.

1C shows the magnitude of the inductor current I _L corresponding to the pulse signal. As described above, when the pulse signal is ON, the inductor current I _L increases through the inductor. On the contrary, The inductor current I _L is decreased.

The slope of the inductor current I _L is determined by the characteristics of the inductor element, the input voltage V _IN and the output voltage V _OUT , and the value thereof is V _IN / L when the pulse signal is on, This corresponds to (V _IN - V _OUT ) / L when the signal is off.

FIG. 2 shows an example of a configuration of a conventional boost converter and characteristics of the line voltage variation rate.

In the present invention, the line voltage fluctuation rate refers to the maximum change amount of the output voltage (V _OUT ) in a steady state that occurs when the line voltage changes stepwise.

The maximum amount of change in the steady state of the output current I _{OUT that} occurs when the line current changes in a stepwise manner is referred to as a line current variation rate .

Referring to FIG. 2A, it can be seen that the configuration for generating the reference voltage V _REF uses the input voltage V _IN of the boost converter as the supply voltage.

That is, the reference voltage (V _REF) is desired before and after it reaches the output voltage and when the magnitude of the input voltage (V _IN) changes, regardless of the supply voltage of the arrangement for generating a reference voltage (V _REF) also change is generated This means that the value of

When the value of the reference voltage (V _REF) changes, on the basis of this, compared to the size and Dividing output voltage (V _{REF_OUT)} of the reference voltage (V _REF) whether or reaches the value of the target output voltage (V _OUT) The resulting output voltage (V _OUT ) also varies.

FIG. 2B is a graph in which the magnitude of the reference voltage V _REF according to the change of the input voltage V _IN is divided into an ideal case and an actual case. In the graph, There is seen that the magnitude of the input voltage (V _iN) regardless of the reference voltage (V _REF) and a size change of the constant, but, in practice, the larger the magnitude of the input voltage (V _iN) the reference voltage (V _REF) The magnitude of the magnetic field is also increased in proportion thereto.

As a result, the magnitude of the reference voltage V _REF changes according to the magnitude of the input voltage V _IN and the magnitude of the output voltage V _OUT changes with the magnitude of the reference voltage V _REF , The line regulating characteristic becomes poor.

In order to solve the above problems, the present invention provides a power supply system including a voltage input unit 100, a rectifier unit 200, an output voltage unit 300, an output voltage determination unit 400, a reference voltage generation unit 500, FIG. 3 is a block diagram of a boost converter according to an embodiment of the present invention. FIG. 4 is a block diagram of a boost converter according to an embodiment of the present invention. A detailed configuration diagram of the boost converter is shown.

In addition, the present invention requires an element capable of applying a pulse signal to replace a role of a switch, and the element may be an N-type MOSFET (Metal Oxide Semiconductor Field Effect Transistor).

Here, the MOSFET refers to a metal oxide semiconductor field effect transistor, and corresponds to a field effect transistor most commonly used in a digital circuit and an analog circuit. Of these, the N-type MOSFET is formed of a channel of an N-type semiconductor material, and can be classified into an N-type MOSFET, a P-type MOSFET or a C-type MOSFET depending on the material.

The voltage input unit 100 preferably corresponds to an input voltage V _IN applied to obtain an output voltage V _OUT to be achieved by using a boost converter and preferably uses a DC voltage. An element for storing energy may be included, and the element is preferably an inductor (L).

When the pulse signal is turned off while the inductor current I _L flows through the inductor due to the input voltage V _IN at the time of the pulse signal provided by the pulse width modulator 700, The inductor current I _L instantly becomes zero, so that a very high voltage is generated and a back electromotive force is generated.

The rectifying unit 200 includes at least one diode (D) so that the energy stored in the off-state inductor of the pulse signal serving as on / off of the switch is converted into a current I _L And flows toward the output voltage portion.

Similarly, when the pulse signal is turned on, it functions to prevent the inductor current (I _L ) from flowing in the direction of the output voltage portion.

Meanwhile, the output voltage unit 300 includes at least one capacitor (C _OUT ) to perform a function of obtaining an output voltage V _OUT obtained by amplifying the input voltage V _IN at a predetermined ratio And the output voltage section in the present invention can provide the output voltage V _{OUT as} the supply voltage of the reference voltage generator.

The output voltage determination unit 400 determines a value of a current output voltage V _OUT . Embodiment, the two resistors (R _1, R ₂₎ is composed of an output voltage (V _OUT) for each size and the measured Dividing output voltage (V _{REF _ OUT)} of the resistance across the both ends of the two resistors in the drawing To determine the magnitude of the output voltage (V _OUT ).

In other words, the output voltage (V _OUT) is V _O, and two of the output voltage determining unit Dividing output voltage to be measured in (V _{REF _ OUT)} when the resistance of each of R ₁ and R ₂ V ₁ is R ₂ / (R ₁ + R ₂ ) x V _O , the output voltage (V _OUT ) V _O becomes (R ₁ + R ₂ ) / R ₂ x V ₁ .

In addition, the output voltage determination unit can be configured by disposing a separate voltage meter or arranging less than two resistors or three or more resistors, but it is preferable to exclude means that can affect the output voltage V _OUT desirable.

Also, the reference voltage generator 500 receives the output voltage V _OUT of the output voltage unit as a supply voltage, and can use it as a reference voltage generator (V _REF ). This is because it is possible to generate a constant reference voltage V _REF by providing the supply voltage with an output voltage V _OUT that maintains a constant value instead of the input voltage V _IN which can be changed from time to time.

And it is compared to a Dividing output voltage (V _{REF _ OUT)} measured by the voltage ratios in the grant 600 the reference voltage (V _REF) and an output voltage created by the reference voltage generation unit determination unit. The reference voltage V _REF corresponds to a criterion that can be used to determine whether the output voltage V _OUT has reached a target voltage to which the output voltage V _OUT has reached. Thus, the reference voltage V _REF corresponds to the voltage magnitude of the boost converter So that boosting is repeatedly performed until the target is reached.

The voltage ratio reference voltage (V _REF) of Dividing output voltage (V _{REF _ OUT)} results Dividing output voltage (V _{REF _ OUT)} the reference voltage (V _REF) of comparing the size of the measurement and in the delivery (target voltage) If more low, than the pulse width modulation unit 700 increases the output voltage (V _OUT) to increase the duty ratio (D) of the pulse signal and, Dividing the output voltage (V _{REF _ OUT)} the reference voltage (V _REF) in The duty ratio D of the pulse signal is reduced in the pulse width modulator 700 to reduce the output voltage V _OUT .

The process of calculating the ratio of the output voltage V _OUT corresponding to the input voltage V _IN by adjusting the duty D of the pulse signal is as follows.

First, when the pulse signal is on, the N-type MOSFET is turned on and energy is stored in the inductor _L while the inductor current I _L flows through the inductor L. The value of the inductor current I _L flowing at this time is dI _ON = (V _IN x dT _ON ) / L.

Thereafter, when the pulse signal is off, the N-type MOSFET is turned off, and the energy stored in the inductor L is transferred to the output terminal through the diode D for rectification. The value of the inductor current I _L flowing at this time becomes dI _OFF = (V _IN - V _OUT ) x dT _OFF / L.

Since the two inductor currents (I _L ) must be equal to each other according to the energy conservation law, dI _ON = dI _OFF is obtained, and V _OUT / V _IN = 1 / (1 - D).

Here, D (Duty) is dT _ON / T, and V _OUT always has a larger value than V _IN because it always has a value smaller than 1.

As discussed above, the output voltage (V _OUT) is "1 / (1 - D) " to the input voltage (V _IN), so that it outputs a value multiplied by a ratio of as much as, to increase the output voltage (V _OUT) D (Duty) value, and to decrease the output voltage (V _OUT ), the value of D (duty) must be decreased.

5 is a graph showing the line voltage fluctuation rate of the conventional boost converter, and FIG. 6 is a graph showing the line voltage fluctuation rate of the boost converter according to an embodiment of the present invention, A line voltage variation rate of the line voltage is shown.

5, when the input voltage V _IN increases, the reference voltage V _REF also increases. When the reference voltage V _REF increases, the output voltage V _OUT also increases. .

Similarly, when the input voltage V _IN decreases, the reference voltage V _REF also decreases. When the reference voltage V _REF decreases, the output voltage V _OUT decreases accordingly. However, the swing level of the input voltage V _IN is very large, while the swing level of the reference voltage V _REF and the output voltage V _OUT are relatively small. However, The result that a constant output voltage (V _OUT ) can not be output even if it is small.

That is, there is a problem that the reference voltage V _REF changes according to the change of the input voltage V _IN , and consequently the output voltage V _OUT also changes, and the characteristic of the line voltage variation rate is poor.

6, by using the output voltage V _{OUT as} the supply voltage of the reference voltage generator, a constant reference voltage V _REF is generated regardless of whether the input voltage V _IN increases or decreases, It can be seen that a constant output voltage (V _OUT ) is also generated.

In addition, the pulse signal can be applied using an N-type MOSFET (Metal Oxide Semiconductor Field Effect Transistor) among the above-mentioned MOSFET types, and is input to the gate terminal of the N-type MOSFET. The N-type MOSFET is a MOSFET in which a source and a drain are an N + region and a body is a P region, and the pulse signal can be input to a gate terminal, not a source and a drain, of the MOSFET. .

After the present invention is by using a supply voltage for generating the reference voltage by feeding back a constant output voltage (V _OUT) of the boost converter, a constant reference voltage (V _REF) to changes in the input voltage (V _IN) is generated, whereby It is possible to provide a boost converter in which a constant output voltage V _OUT is generated even when the input voltage V _IN is changed and the above process is repeated to improve the line voltage variation rate.

While the present invention has been described with reference to the specific embodiments, it is to be understood that the invention is not limited thereto. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents. Various modifications and variations are possible.

100:
200: rectification part
300: Output voltage part
400: Output voltage judging unit
500: Reference voltage generating section
600: voltage ratio grant
700: Pulse width modulation section
V _IN : Input voltage
V _REF : Reference voltage
V _OUT : Output voltage
V _{REF _ OUT} : Dividing Output Voltage
L: Inductor
I _L : Inductor current
D: Diode
C _OUT : Capacitor

Claims (8)

A boost converter for generating an output voltage higher than an input voltage, the boost converter comprising:
A voltage input unit for applying an input voltage V _IN to the boost converter;
A rectifier connected between the voltage input part and the output voltage part to prevent a reverse flow of current flowing from the voltage input part to the output voltage part;
An output voltage section for generating an output voltage (V _OUT ) having a voltage magnitude of a predetermined ratio with respect to the input voltage (V _IN );
An output voltage determining unit for determining the magnitude of the output voltage V _OUT generated by the output voltage unit using the measured _dividing output voltage V _{REF_OUT} ;
A reference voltage generator for generating a reference voltage (V _REF) to be compared with a Dividing output voltage (V _{REF _ OUT)} measured by the output voltage determining section;
The output Dividing the output voltage measured by the voltage determination unit (V _{REF _ OUT)} and the voltage ratio issued to compare the magnitude of a reference voltage (V _REF) generated by the reference voltage generation section; And
A pulse width modulation (PWM) unit that generates a pulse signal and changes a duty (D) of the pulse signal according to a voltage comparison result of the voltage comparator; , ≪ / RTI &
Wherein the reference voltage generating unit feeds back the output voltage V _OUT and uses the feedback voltage as a supply voltage.
The method according to claim 1,
Wherein the rectification unit includes at least one diode. 5. The boost converter according to claim 1, wherein the rectification unit includes at least one diode.
The method according to claim 1,
Wherein the output voltage unit includes at least one capacitor. 4. The boost converter according to claim 1, wherein the output voltage unit comprises at least one capacitor.
The method according to claim 1,
Wherein a predetermined ratio of the input voltage to the input voltage V _IN is 1 / (1 - D), wherein D is duty.
The method according to claim 1,
Is configured by the output voltage determining unit comprises at least two or more resistance, calculated using the output voltage (V _OUT) to the size and Dividing output voltage (V _{REF _ OUT)} of each of the resistance applied to the two or more resistors across the The boost converter comprising: a boost converter for boosting the output voltage of the boost converter;
The pulse width modulation apparatus according to claim 1,
The Dividing output voltage (V _{REF _ OUT)} in this case is lower than the reference voltage (V _REF) and to increase the duty ratio (D) of the pulse signal, the Dividing the reference voltage the output voltage (V _{REF _ OUT)} ( V _REF ), the duty ratio (D) of the pulse signal is reduced.
The method according to claim 1,
Wherein the pulse signal is input to a gate (GATE) of an N-type MOSFET (Metal Oxide Semiconductor Field Effect Transistor).
The method according to claim 1,
The boost converter generates the output voltage V _OUT at the input voltage V _{IN and} operates the reference voltage generator at the initial drive of the boost converter and uses the boosted output voltage V _OUT only after the boosting is started. And the reference voltage generation unit is operated.

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