KR102391263B1 - Buck-Boost converter controlled with variablel hysteresis, control method thereof, and electric vehicle charger with DC input - Google Patents

Abstract

A buck-boost converter according to the present invention for converting an input voltage of DC power to power provides an output voltage with a predetermined input/output voltage ratio to the input voltage to an output terminal. The buck-boost converter is controlled to: operate in an operation mode that is a buck mode when the input/output voltage ratio is less than a first mode change threshold, operate in an operation mode that is a buck-boost mode when the input/output voltage ratio is between the first mode change threshold and a second mode change threshold greater than the first mode change threshold, and operate the input/output voltage ratio in an operation mode that is a boost mode within a range greater than a second mode change threshold, wherein the first and second mode change thresholds have hysteresis when the operation mode is changed, and the hysteresis gap decreases with time after the operation mode is changed. Thus, according to the present invention, the probability of operating in buck or boost converter operation mode is maximized while stabilizing the system by minimizing the change of operation mode, so that system efficiency is maximized.

Description

Buck-Boost converter controlled with variablel hysteresis, control method thereof, and electric vehicle charger with DC input}

The present invention relates to a buck-boost converter by variable hysteresis control, a control method thereof, and a DC input electric vehicle charger, and more particularly, to operate in a buck or boost converter operation mode while stabilizing the system by minimizing a change in operation mode. A buck-boost converter capable of maximizing system efficiency by maximizing probability, a control method therefor, and a DC input electric vehicle charger.

In general, electric vehicle chargers use AC power as input power.

However, in recent years, interest in DC power transmission and distribution is increasing, and power generated from renewable energy such as solar power is supplied or power is supplied from an energy storage system (ESS, Energy Storage System) in some cases. An electric vehicle charger that uses an input is being developed.

The input voltage of an electric vehicle charger using DC power as an input is about 900 to 1100V, and the range of the output voltage is about 200 to 1000V. Here, comparing the input voltage and the output voltage, the output voltage is sometimes lower or higher than the input voltage, so a buck-boost converter is usually used as a converter for converting power.

1 shows a general configuration of a buck-boost converter. The input side operates as a buck converter and the output side operates as a boost converter. When the output voltage Vout is lower than the input voltage Vin, it is a buck operation mode in which only the buck converter operates, and when the output voltage Vout is higher than the input voltage Vin, it is a boost operation mode in which only the boost converter operates, and the output voltage When (Vout) is similar to the input voltage (Vin), it is a buck-boost operation mode in which the buck converter and the boost converter operate simultaneously.

If the duty ratio of the buck converter is D _bk and the duty ratio of the boost converter is D _bst , then the input/output voltage ratio G, which is the ratio of the output voltage Vout to the input voltage Vin, is given as follows.

G = Vout/Vin = D _bk /(1-D _bst )

When the buck converter and the boost converter operate at the same time, the switching loss becomes larger than when the buck converter or the boost converter operates alone, resulting in lower efficiency. Therefore, it is better to minimize the area where the buck converter and the boost converter operate simultaneously.

On the other hand, in the critical region where the buck converter or the boost converter starts or stops the operation, it is necessary to maintain the minimum ON pulse width of the switch element. The reason is that if the pulse width is too narrow, the ON switching operation and the OFF switching operation overlap and the device may be burned out by an instantaneous shoot-through current.

The buck-boost converter generally changes its operating mode to buck, buck-boost, and boost mode as the input/output voltage ratio increases, and vice versa when the input/output voltage ratio decreases. In real systems, problems arise.

For example, if the threshold point at which the operation mode is changed when the input/output voltage ratio increases and when the input/output voltage ratio decreases is the same, the buck mode and the buck-boost mode, or the buck-boost mode at the point where the duty ratio changes rapidly, that is, at the point where the operation mode changes Switching back and forth between and boost mode can cause the system to run unstable.

Conventionally, the hysteresis is set at the critical point at which the operation mode is changed so that the duty ratio change standard when the input/output voltage ratio increases and when the input/output voltage ratio decreases is different.

However, the buck-boost converter according to the prior art has a problem in that the buck-boost operation period increases due to hysteresis, and thus the efficiency is lowered than when the buck mode or the boost mode alone operates.

Therefore, the present invention has been devised to solve the problems of the prior art, and it is possible to maximize the efficiency of the system by maximizing the probability of operating in the buck or boost converter operating mode while stabilizing the system by minimizing the change in the operating mode. An object of the present invention is to provide a buck-boost converter by hysteresis control, a control method thereof, and a DC input electric vehicle charger.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. will be able

In order to achieve the above object, a buck-boost converter according to the present invention is a buck-boost converter that converts an input voltage of a DC power supply to power and provides an output voltage having a predetermined input/output voltage ratio with respect to the input voltage to an output stage. wherein the buck-boost converter operates in a buck mode operation mode in a range where the input/output voltage ratio is smaller than a first mode change threshold value, and the input/output voltage ratio is greater than the first mode change threshold value and the first mode change threshold value It operates in the buck-boost mode in the range between the large second mode change threshold and operates in the boost mode in the range where the input/output voltage ratio is greater than the second mode change threshold, the first and the second mode change threshold has hysteresis when the operation mode is changed, and the hysteresis gap decreases with the lapse of time after the operation mode is changed.

In the buck-boost converter according to the present invention, when the input/output voltage ratio has the first to fifth threshold voltage ratios in the order of magnitude, the first mode change threshold is a second threshold voltage ratio when the operation mode is the buck mode. is set, and is set to a first threshold voltage ratio when the operation mode is other modes, has a first hysteresis gap equal to the difference between the first and second threshold voltage ratios, and the second mode change threshold is the operation mode is set to the fourth threshold voltage ratio in the boost mode, and is set to the fifth threshold voltage ratio when the operation mode is in the other modes, so that a second hysteresis gap equal to the difference between the fourth and fifth threshold voltage ratios may be provided.

In the buck-boost converter according to the present invention, the first hysteresis gap has a first starting hysteresis gap when the operation mode is changed from the buck mode to the other modes, and the first starting hysteresis gap over time decreases to a first final hysteresis gap smaller than the gap, wherein the second hysteresis gap has a second starting hysteresis gap when the operation mode is changed from a boost mode to another mode, wherein over time the second hysteresis gap It is preferred to decrease to a second final hysteresis gap smaller than the starting hysteresis gap.

In the buck-boost converter according to the present invention, the first hysteresis gap is a first starting hysteresis gap when the operation mode is changed from the buck mode to the other mode and when the other mode is changed to the buck mode. is set differently, and the second hysteresis gap may be set to be different from the second starting hysteresis gap when the operation mode is changed from the boost mode to the other mode and when the other mode is changed to the boost mode there is.

In the buck-boost converter according to the present invention, the second and fourth threshold voltage ratios are set to a fixed value, and the first hysteresis gap increases with the passage of time so that the first threshold voltage ratio shifts toward the second threshold voltage ratio. It is preferable that the second hysteresis gap decreases as the fifth threshold voltage ratio is changed toward the fourth threshold voltage ratio with the lapse of time.

In the buck-boost converter according to the present invention, the first hysteresis gap decreases as a linear function or exponentially over time, and the second hysteresis gap is a linear function over time, Or it may decrease exponentially.

Buck-boost converter according to the present invention, an inductor; and first and second buck switches provided between the DC power supply and one end of the inductor and connected in series between both ends of the input voltage to be complementary switched, and a buck converter duty ratio according to the input/output voltage ratio. a buck switch unit controlling the switching operation of the first buck switch; and first and second boost switches provided between the other end of the inductor and the output end and connected in series between both ends of the output voltage to be complementary to each other, wherein the boost converter duty ratio is determined according to the input/output voltage ratio. and a boost switch unit for controlling the switching operation of the first boost switch, wherein the buck switch unit performs a switching operation at a buck converter duty ratio defined by Equation 1 below, and the boost switch unit is defined by Equation 2 below. A switching operation may be performed with the boost converter duty ratio.

[Equation 1]

D _bk = G (1-D _bst )

[Equation 2]

D _bst = 1-D _bk /G

(Where D _bk is the buck converter duty ratio, D _bst is the boost converter duty ratio, and G is the input/output voltage ratio.)

In the buck-boost converter according to the present invention, the buck converter duty ratio may be set to 1 in the boost mode operation mode, and the boost converter duty ratio may be set to 0 in the buck mode operation mode.

In the buck-boost converter according to the present invention, the boost converter duty ratio is a buck-boost mode in which the input/output voltage ratio is between the first mode change threshold value and the third threshold voltage ratio, the first boost switch is a first minimum is set to switch to an ON duty ratio, and the buck converter duty ratio is, in a buck-boost mode, wherein the input/output voltage ratio is between the third threshold voltage ratio and the second mode change threshold, the second buck switch 2 It may be set to switch with a minimum ON duty ratio, and the third threshold voltage ratio may be set to 1.

In order to achieve the above object, the control method of the buck-boost converter according to the present invention provides an output voltage having a predetermined input/output voltage ratio with respect to the input voltage by converting an input voltage of a DC power supply to an output terminal. A control method of a boost converter, comprising: calculating the input/output voltage ratio according to the input voltage and the output voltage; The operation mode of the buck-boost converter is determined and operated by comparing the input/output voltage ratio and the first mode change threshold value, and the input/output voltage ratio and a second mode change threshold value greater than the first mode change threshold value step; an operation mode change determination step of determining whether the operation mode has been changed; a hysteresis applying step of changing by applying hysteresis to at least one of the first and second mode change thresholds when the operation mode is changed; and reducing a hysteresis gap of the applied hysteresis over time.

In the control method of the buck-boost converter according to the present invention, in the operation mode determining step, if the input/output voltage ratio is in a range smaller than the first mode change threshold value, the operation mode is determined as the buck mode, and the input/output voltage ratio is the first and the second mode change threshold value, the operation mode may be determined as the buck-boost mode, and if the input/output voltage ratio is greater than the second mode change threshold value, the operation mode may be determined as the boost mode.

In the control method of the buck-boost converter according to the present invention, the first and second mode change thresholds have hysteresis when the operation mode is changed, and the hysteresis gap is increased with the lapse of time after the operation mode is changed. It is desirable to decrease

In order to achieve the above object, the DC input electric vehicle charger according to the present invention comprises a charging device for charging an electric vehicle with an output voltage having a predetermined input/output voltage ratio with respect to the input voltage by converting an input voltage input from a DC power source to power. However, the charging device according to the present invention is characterized in that it is configured to include a boost converter.

In the DC input electric vehicle charger according to the present invention, the DC power may include at least one of a DC transmission power source, a DC distribution power source, a solar power generation device, and an Energy Storage System (ESS).

According to the present invention, a buck-boost converter by variable hysteresis control, a control method thereof, and a DC input electric vehicle charger maximize the probability of operating in the buck or boost converter operation mode while stabilizing the system by minimizing the change in the operation mode. This has the effect of maximizing the efficiency of the system.

1 is a circuit diagram showing a general configuration of a buck-boost converter.
2 is a view for explaining the principle of changing the operation mode of the buck-boost converter according to the present invention according to the input/output voltage ratio.
3 is a diagram illustrating a hysteresis gap that decreases in a linear function with the lapse of time after the operation mode of the buck-boost converter is changed.
4 is a diagram illustrating a hysteresis gap that exponentially decreases with the lapse of time after the operation mode of the buck-boost converter is changed.
5 is a flowchart illustrating a control method of a buck-boost converter according to the present invention.

A preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. The following detailed description is merely exemplary, and only shows preferred embodiments of the present invention.

1 is a circuit diagram showing the configuration of a buck-boost converter applicable to the buck-boost converter of the present invention.

1, the buck-boost converter according to the present invention is provided between an inductor, a DC power supply providing an input voltage Vin, and one end of the inductor, and the buck converter duty ratio (G) according to the input/output voltage ratio (G). D _bk ) is provided between the buck switch unit 100, the switching operation of which is controlled, and the other end of the inductor and the output end to which the output voltage Vout is output, and the boost converter duty ratio (D _bst ) according to the input/output voltage ratio (G) A boost switch unit 200 that controls the low switching operation, and a switching control unit 300 that controls the switching operation of the buck switch unit 100 and the boost switch unit 200 according to the input/output voltage ratio (G). can

The switching control unit 300 of the present invention only controls the switching operations of the buck switch unit 100 and the boost switch unit 200 in an operation mode determined according to the result of comparison between the input/output voltage ratio (G) and a predetermined threshold value. Rather, it is characterized in that the threshold value is changed to have hysteresis whenever the operation mode is changed, but the gap of the hysteresis is controlled to decrease with the lapse of time. Details on this will be described later with reference to FIG. 2 .

The buck switch unit 100 is configured to include first and second buck switches S _bk1 and S _bk2 that are connected in series between both ends of the DC power supply providing the input voltage Vin and are complementary switched. can 1 , one end of the first buck switch S _bk1 is connected to the positive potential of the input voltage Vin, and the second buck switch S _bk2 is connected to the other end and input of the first buck switch S _bk1 . It may be connected in series between the negative potential of the voltage Vin.

The buck switch unit 100 configures a buck converter by connecting one end of an inductor to a portion where the first and second buck switches S _bk1 and S _bk2 are connected to each other.

The boost switch unit 200 may include first and second boost switches S _bst1 and S _bst2 that are connected in series between both ends of an output terminal providing the output voltage Vout and are complementary switched. there is. Referring to FIG. 1 , one end of the first boost switch S _bst1 is connected to a negative potential of the output voltage Vout, and the second boost switch S _bst2 is connected to the other end and output of the first boost switch S _bst1 . It may be connected in series between the positive potential of the voltage Vout.

The boost switch unit 200 configures a boost converter by connecting the other end of the inductor to a portion where the first and second boost switches S _bst1 and S _bst2 are connected to each other.

The buck switch unit 100 performs a switching operation at the buck converter duty ratio (D _bk ) expressed in Equation 1 below according to the input/output voltage ratio (G), and the boost switch unit 200 is the input/output voltage ratio (G) A switching operation is performed according to the boost converter duty ratio (D _bst ) expressed in Equation 2 below.

[Equation 1]

D _bk = G (1-D _bst )

[Equation 2]

D _bst = 1-D _bk /G

Here, D _bk is the buck converter duty ratio, D _bst is the boost converter duty ratio, and G is the input/output voltage ratio.

The duty ratio of the buck switch unit 100 is based on the ON time of the first buck switch S _bk1 , and the duty ratio of the boost switch unit 200 is the ON time of the first boost switch S _bst1 . ON) based on time.

Accordingly, the switching operation of the first buck switch S _bk1 is controlled by the buck converter duty ratio D _bk according to the input/output voltage ratio G, and the first boost switch S _bst1 is controlled by the boost converter duty ratio D _bst . of the switching operation is controlled. In addition, the first buck switch (S _bk1 ) and the first boost switch (S _bst1 ) are complementary to the second buck switch (S _bk2 ) and the second boost switch (S _bst2 ) are 1-buck converter duty ratios, respectively. The switching operation is controlled with a duty ratio corresponding to (D _bk ) and the 1-boost converter duty ratio (D _bst ).

On the other hand, in the critical region where the buck converter or boost converter starts or stops the operation, if the pulse width becomes too narrow, the ON switching operation and the OFF switching operation overlap and the device may be burned out by the instantaneous shoot-through current. Therefore, the switch elements of the buck switch unit 100 and the boost switch unit 200 need to be controlled to maintain a minimum ON pulse width.

Hereinafter, a duty ratio at which the first boost switch S _bst1 of the boost switch unit 200 switches with a minimum on-pulse width is defined as a first minimum ON duty ratio, and the second A duty ratio at which the buck switch S _bk2 switches with a minimum on-pulse width is defined as a second minimum on-duty ratio ΔD2. Here, the first and second minimum ON duty ratios may be set equal to each other, but may be set differently.

2 is a view for explaining the principle of changing the operation mode of the buck-boost converter according to the present invention according to the input/output voltage ratio (G).

Referring to FIG. 2 , in the buck-boost converter according to the present invention, the operation mode is determined according to which range the input/output voltage ratio G is located based on the first and second mode change threshold values TH1 and TH2. do. In other words, when the second mode change threshold TH2 is greater than the first mode change threshold TH1, in the buck-boost converter of the present invention, the input/output voltage ratio G is the first mode change threshold. It operates in the buck mode in a range smaller than the value TH1, and operates in the buck-boost mode in the range where the input/output voltage ratio G is between the first mode change threshold value TH1 and the second mode change threshold value TH2, and , in a range in which the input/output voltage ratio G is greater than the second mode change threshold value TH2, it is controlled to operate in the boost mode.

Here, the first and second mode change thresholds TH1 and TH2 are changed with hysteresis when the operation mode of the buck-boost converter is changed, and the hysteresis gap is reduced over time. .

When the input/output voltage ratio G is divided into the first to fifth threshold voltage ratios G1 to G5 as shown in FIG. 2 , the first mode change threshold TH1 is the first mode change threshold value TH1 when the operation mode is the buck mode. 2 is set to the threshold voltage ratio G2, and is set to the first threshold voltage ratio G1 when the operation mode is the buck-boost or boost mode, so that the first It has a hysteresis gap (Hg1).

In other words, when the operation mode is changed from the buck mode to the buck-boost mode, the input/output voltage ratio G is compared with the first mode change threshold TH1 having the second threshold voltage ratio G2, and the operation mode is changed to the buck-boost mode. When changing from the boost mode to the buck mode, the input/output voltage ratio G is compared with the first mode change threshold TH1 having the first threshold voltage ratio G1.

In this case, since the first hysteresis gap Hg1 of the first mode change threshold value TH1 corresponds to the difference between the first and second threshold voltage ratios G1 and G2, the first In order to decrease the hysteresis gap Hg1, the values of the first and second threshold voltage ratios G1 and G2 may be changed in a direction toward each other.

In particular, the boost converter duty ratio at the second threshold voltage ratio G2 at which the boost converter starts the switching operation so that the first boost switch S _bst1 of the boost switch unit 200 switches with a pulse width greater than or equal to the minimum on-pulse width. (D _bst ) must be equal to or greater than the first minimum on-duty ratio (ΔD1). Accordingly, the first hysteresis gap Hg1 may be controlled such that the second threshold voltage ratio G2 is fixed and is reduced by varying the first threshold voltage ratio G1 to approach the second threshold voltage ratio G2.

Similarly, when the input/output voltage ratio G is divided by the first to fifth threshold voltage ratios G1 to G5 as shown in FIG. 2 , the second mode change threshold TH2 is the operating mode boost When the mode is set to the fourth threshold voltage ratio G4, and when the operation mode is the buck-boost or buck mode, it is set to the fifth threshold voltage ratio G5, so that the difference between the fourth and fifth threshold voltage ratios G4 and G5 a second hysteresis gap Hg2 of

In other words, when the operation mode is changed from the boost mode to the buck-boost mode, the input/output voltage ratio G is compared with the second mode change threshold TH2 having the fourth threshold voltage ratio G4, and the operation mode is changed to the buck-boost mode. When changing from the boost mode to the boost mode, the input/output voltage ratio G is compared with the second mode change threshold TH2 having the fifth threshold voltage ratio G5.

In this case, since the second hysteresis gap Hg2 of the second mode change threshold TH2 corresponds to the difference between the fourth and fifth threshold voltage ratios G4 and G5, the second hysteresis gap Hg2 is In order to decrease the hysteresis gap Hg2, the values of the fourth and fifth threshold voltage ratios G4 and G5 may be changed in a direction toward each other.

In particular, the buck converter duty ratio at the fourth threshold voltage ratio G4 at which the buck converter starts the switching operation so that the second buck switch S _bk2 of the buck switch unit 100 switches with a pulse width greater than or equal to the minimum on-pulse width. (D _bk ) must be equal to or greater than the second minimum on-duty ratio (ΔD2). Accordingly, the second hysteresis gap Hg2 may be controlled such that the fourth threshold voltage ratio G4 is fixed and is reduced by varying the fifth threshold voltage ratio G5 to approach the fourth threshold voltage ratio G4.

Table 1 below shows the operation mode of the buck-boost converter according to the present invention and its duty ratio based on the above-described operating conditions and Equations 1 and 2.

input/output voltage ratio
(G=Vout/Vin) 0 to TH1 TH1-G3 G3-TH2 TH2- operation mode buck buck-boost buck-boost boost Buck Converter Duty Ratio
₍ D _bk ) G G*(1-ΔD1) 1-ΔD2 1.0 Boost Converter Duty Ratio
₍ D _bst ) 0 ΔD1 1-D _bk /G 1-1/G

Referring to Tables 1 and 2, in the buck-boost converter of the present invention, when the input/output voltage ratio G is lower than the first mode change threshold TH1, only the buck converter operates and the boost converter duty ratio D _bst is is kept at 0. As the input/output voltage ratio (G) increases, the buck converter duty ratio (D _bk ) increases in proportion to the input/output voltage ratio (G).

When the input/output voltage ratio G approaches the first mode change threshold TH1, the buck converter duty ratio D _bk approaches 1. At this time, the boost converter starts to operate so that the second buck switch S _bk2 of the buck switch unit 100 switches while maintaining the minimum on time, and the first boost switch S of the boost switch unit 200 _bst1 ) is also controlled to perform a switching operation with a minimum on-time.

When the input/output voltage is higher than the first mode change threshold TH1 and the boost converter enters the buck-boost mode in which the switching operation is performed, the output voltage Vout rises above the desired value, so the buck converter duty ratio D _bk is It is controlled so low.

In the buck-boost mode, as the input/output voltage ratio (G) continues to increase, the buck converter duty ratio (D _bk ) continues to increase, while the boost converter duty ratio ( D _bst ) continues to the first minimum on-duty ratio (ΔD1). maintain

When the buck converter duty ratio (D _bk ) continues to increase to reach the first-second minimum on-duty ratio (ΔD2), the buck converter duty ratio (D _bk ) does not increase any more and the boost converter duty ratio (D _bst ) is will increase

As the input/output voltage ratio (G) continues to increase, the boost converter duty ratio (D _bst ) increases sufficiently so that even if the buck converter duty ratio (D _bk ) is 1, if the minimum on-time of the boost converter is satisfied, the buck converter duty ratio (D _bk ) is set to 1, and instead, the boost converter duty ratio (D _bst ) is controlled as low as that, and a switching operation is performed in the boost mode.

If the input/output voltage ratio G continues to increase while the operation mode is the boost mode, the buck converter duty ratio D _bk is maintained at 1 and the boost converter duty ratio D _bst increases.

For convenience of design, the third threshold voltage ratio G3 described above may be set to 1, and the first and second minimum on-duty ratios ΔD1 and ΔD2 may be set to the same value.

FIG. 3 is a view showing a hysteresis gap that decreases linearly with time after the operation mode of the buck-boost converter is changed, and FIG. 4 is a diagram showing the hysteresis gap exponentially with the lapse of time after the operation mode is changed A diagram showing a decreasing hysteresis gap.

Referring to FIG. 3( a ), the first hysteresis gap Hg1 has a first start hysteresis gap Hg.st1 at a time t1 when the operation mode is changed from the buck mode to the other mode, but with the lapse of time Accordingly, it may be configured to decrease to a first final hysteresis gap (Hg.fn1) that is smaller than the first start hysteresis gap (Hg.st1).

In addition, referring to FIG. 3B , the second hysteresis gap Hg2 has a second start hysteresis gap Hg.st2 at a time t2 when the operation mode is changed from the boost mode to other modes, It may be configured to decrease to a second final hysteresis gap (Hg.fn2) that is smaller than the second start hysteresis gap (Hg.st2) over time.

Here, the first and second final hysteresis gaps Hg.fn1 and Hg.fn2 may be positive numbers other than 0, but a case of 0 is not excluded.

In addition, the first hysteresis gap Hg1 is different from the first starting hysteresis gap Hg.st1 when the operation mode is changed from the buck mode to the other mode and when the other mode is changed to the buck mode can be set. In particular, in order to ensure the minimum on-time of the buck converter and the boost converter, the increase of the second threshold voltage ratio G2 above a certain value is limited or has to be a fixed value, so the first start when changing from the buck mode to the other modes The first start hysteresis gap Hg.st1 when the mode is changed from the other mode to the buck mode may be set smaller than the hysteresis gap Hg.st1.

In addition, the second hysteresis gap Hg2 is different from the second start hysteresis gap Hg.st2 when the operation mode is changed from the boost mode to the other mode and when the other mode is changed to the boost mode can be set. In particular, in order to ensure the minimum on-time of the buck converter and the boost converter, the decrease of the fourth threshold voltage ratio G4 below a certain value is limited or has to be a fixed value. The second start hysteresis gap Hg.st2 when the mode is changed from the other mode to the boost mode may be set smaller than the start hysteresis gap Hg.st2.

The other modes described above may be a buck-boost mode.

The first hysteresis gap Hg1 may be in a form that decreases in a linear function over time as shown in FIG. 3(a), but decreases exponentially as shown in FIG. 4(a). may be in the form of

In addition, the second hysteresis gap Hg2 may have a form that decreases as a linear function over time as shown in FIG. 3(b), but is exponential as shown in FIG. 4(b). It may be in the form of decreasing to .

Although not shown in the drawings, the buck-boost converter of the present invention may be provided in a charging device to constitute a charger for charging an electric vehicle.

At this time, the DC input electric vehicle charger according to the present invention converts an input voltage (Vin) input from a DC power source to power and converts the electric vehicle to an output voltage (Vout) having a predetermined input/output voltage ratio (G) to the input voltage (Vin). Including a charging device for charging, the charging device according to the present invention described above is characterized in that it is configured to include a boost converter.

At this time, the DC power supply for supplying the DC voltage as the input voltage (Vin) to the electric vehicle charger of the present invention is at least one of a DC transmission power source, a DC distribution power source, a solar power generation device, and an Energy Storage System (ESS). It may be configured including the above, but the present invention is not limited thereto, and any power capable of supplying power sufficient to charge an electric vehicle as a DC power can be applied as a DC power source.

5 is a flowchart illustrating a control method of a buck-boost converter according to the present invention.

Referring to FIG. 5 , the control method of the buck-boost converter according to the present invention converts an input voltage (Vin) of a DC power supply to an output voltage (G) having a predetermined input/output voltage ratio (G) with respect to the input voltage (Vin). In the control method of a buck-boost converter that provides Vout as an output terminal, calculating an input/output voltage ratio G according to an input voltage Vin and an output voltage Vout (S100), and the arithmetic input/output voltage ratio G ) and the first mode change threshold value TH1, or the input/output voltage ratio G and the second mode change threshold value TH2, to determine the operation mode of the buck-boost converter and operate the operation mode determination step (S200) And, an operation mode change determination step (S300) of determining whether the operation mode has been changed, and when the operation mode is changed, applying hysteresis to at least one of the first and second mode change threshold values TH1 and TH2 and a hysteresis application step (S400) of changing the hysteresis and a step (S500) of reducing the hysteresis gap of the applied hysteresis over time (S500).

In addition, in the operation mode determination step S200, if the input/output voltage ratio G is in a range smaller than the first mode change threshold TH1, the operation mode is determined as the buck mode, and the input/output voltage ratio G is the first and second If the range is between the mode change thresholds TH1 and TH2, the operation mode is determined as the buck-boost mode, and if the input/output voltage ratio G is in the range greater than the second mode change threshold value TH2, the operation mode is determined as the boost mode to operate the buck-boost converter.

In addition, in the step of reducing the hysteresis gap ( S500 ), the first and second mode change thresholds TH1 and TH2 have hysteresis when the operation mode is changed, and the hysteresis gap decreases with time after the operation mode change. characterized by a decrease.

Through the above-described configuration, the buck-boost converter by variable hysteresis control, the control method thereof, and the DC input electric vehicle charger according to the present invention according to the present invention, through the above-described configuration, stabilize the system by minimizing the change in the operation mode to the buck or boost converter operation mode. It has the effect of maximizing the efficiency of the system by maximizing the probability of operation.

In the foregoing, the present invention has been described and illustrated on the basis of preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the configuration and operation as shown and described as such. It should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention.

100: buck switch unit 200: boost switch unit
300: switching control unit
Vin: input voltage Vout: output voltage
S _bk1 , S _bk2 : first and second buck switches
S _bst1 , S _bst2 : first and second boost switches
D _bk : buck converter duty ratio D _bst : boost converter duty ratio
G: input/output voltage ratio G1 to G5: first to fifth threshold voltage ratio
TH1, TH2: first and second mode change thresholds
ΔD1, ΔD2: first and second minimum on-duty ratios
Hgl, Hg2: first and second hysteresis gap
Hg.st1, Hg.st2: first and second starting hysteresis gap
Hg.fn1, Hg.fn2: first and second final hysteresis gap

Claims (14)

A buck-boost converter for converting an input voltage of a DC power supply to power and providing an output voltage having a predetermined input/output voltage ratio with respect to the input voltage to an output terminal, the buck-boost converter comprising:
The buck-boost converter operates in an operation mode that is a buck mode in a range where the input/output voltage ratio is smaller than a first mode change threshold value, and a second input/output voltage ratio greater than a first mode change threshold value and a first mode change threshold value Controlled to operate in an operation mode that is a buck-boost mode in a range between two mode change thresholds, and operate in an operation mode that is a boost mode in a range where the input/output voltage ratio is greater than a second mode change threshold,
The first and second mode change thresholds have hysteresis when the operation mode is changed, and the hysteresis gap decreases with the lapse of time after the operation mode is changed.
According to claim 1,
When the input/output voltage ratio has the first to fifth threshold voltage ratios in the order of magnitude,
The first mode change threshold is set to a second threshold voltage ratio when the operation mode is the buck mode, and is set to a first threshold voltage ratio when the operation mode is other modes, so that the first and second threshold voltage ratios are having a first hysteresis gap equal to the difference,
The second mode change threshold is set to a fourth threshold voltage ratio when the operation mode is the boost mode, and is set to a fifth threshold voltage ratio when the operation mode is the other mode, so that the fourth and fifth threshold voltage ratios are A buck-boost converter, characterized in that it has a second hysteresis gap equal to the difference.
3. The method of claim 2,
The first hysteresis gap has a first starting hysteresis gap when the operation mode is changed from the buck mode to the other mode, and decreases to a first final hysteresis gap smaller than the first starting hysteresis gap over time do,
The second hysteresis gap has a second start hysteresis gap when the operation mode is changed from the boost mode to the other mode, and decreases to a second final hysteresis gap smaller than the second start hysteresis gap over time Buck-boost converter, characterized in that.
3. The method of claim 2,
The first hysteresis gap is set to be different from the first starting hysteresis gap when the operation mode is changed from the buck mode to the other mode and when the other mode is changed to the buck mode,
The second hysteresis gap is characterized in that the second starting hysteresis gap when the operation mode is changed from the boost mode to the other mode and when the operation mode is changed from the other mode to the boost mode is set to be different from each other. boost converter.
3. The method of claim 2,
The second and fourth threshold voltage ratios are set to a fixed value,
The first hysteresis gap decreases as the first threshold voltage ratio is changed toward the second threshold voltage ratio with the lapse of time,
and the second hysteresis gap decreases as the fifth threshold voltage ratio is changed toward the fourth threshold voltage ratio with the lapse of time.
4. The method of claim 3,
The first hysteresis gap decreases linearly or exponentially over time,
The second hysteresis gap is a buck-boost converter, characterized in that it decreases as a linear function or exponentially with time.
3. The method of claim 2,
inductor;
and first and second buck switches provided between the DC power supply and one end of the inductor and connected in series between both ends of the input voltage to be complementary switched, and a buck converter duty ratio according to the input/output voltage ratio. a buck switch unit controlling the switching operation of the first buck switch; and
and first and second boost switches provided between the other end of the inductor and the output terminal and connected in series between both ends of the output voltage to be complementary to each other, and a boost converter duty ratio according to the input/output voltage ratio. 1 including a boost switch unit in which the switching operation of the boost switch is controlled,
The buck switch unit performs a switching operation with a buck converter duty ratio defined by Equation 1 below,
The boost switch unit, a buck-boost converter, characterized in that the switching operation is performed at the boost converter duty ratio defined by Equation (2) below.
[Equation 1]
D _bk = G (1-D _bst )
[Equation 2]
D _bst = 1-D _bk /G
(Where D _bk is the buck converter duty ratio, D _bst is the boost converter duty ratio, and G is the input/output voltage ratio.)
8. The method of claim 7,
The buck converter duty ratio is set to 1 in the operation mode of the boost mode,
The boost converter duty ratio is a buck-boost converter, characterized in that it is set to 0 in the operation mode of the buck mode.
8. The method of claim 7,
The boost converter duty ratio is set such that the first boost switch switches to a first minimum ON duty ratio in a buck-boost mode in which the input/output voltage ratio is between the first mode change threshold value and a third threshold voltage ratio; ,
The buck converter duty ratio is set such that the second buck switch switches to a second minimum ON duty ratio in a buck-boost mode in which the input/output voltage ratio is between the third threshold voltage ratio and the second mode change threshold. become,
The third threshold voltage ratio is set to 1 buck-boost converter
A control method of a buck-boost converter for converting an input voltage of a DC power supply to power and providing an output voltage having a predetermined input/output voltage ratio with respect to the input voltage to an output terminal,
calculating the input/output voltage ratio according to the input voltage and the output voltage;
The operation mode of the buck-boost converter is determined and operated by comparing the input/output voltage ratio and the first mode change threshold value, and the input/output voltage ratio and a second mode change threshold value greater than the first mode change threshold value step;
an operation mode change determination step of determining whether the operation mode has been changed;
a hysteresis applying step of changing by applying hysteresis to at least one of the first and second mode change thresholds when the operation mode is changed; and
and reducing a hysteresis gap of the applied hysteresis over time.
11. The method of claim 10,
In the operation mode determining step, if the input/output voltage ratio is less than the first mode change threshold, the operation mode is determined as the buck mode, and if the input/output voltage ratio is in the range between the first and second mode change thresholds, the operation mode is determined as the buck-boost mode, and when the input/output voltage ratio is greater than the second mode change threshold, the operation mode is determined as the boost mode.
12. The method of claim 11,
The first and second mode change thresholds have hysteresis when the operation mode is changed, and the hysteresis gap decreases with the lapse of time after the operation mode is changed. Control method of a buck-boost converter .
A charging device for charging an electric vehicle with an output voltage having a predetermined input/output voltage ratio with respect to the input voltage by converting an input voltage input from a DC power source to power;
The charging device is a DC input electric vehicle charger comprising the buck-boost converter according to any one of claims 1 to 9.
14. The method of claim 13,
The DC power source includes at least one of a DC transmission power source, a DC distribution power source, a solar power generation device, and an Energy Storage System (ESS).

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