KR101224589B1 - Multilevel inverter - Google Patents

Abstract

A multilevel inverter is disclosed. The multilevel inverter is based on a reference wave and a triangular wave in the form of a sine function and a switch unit for outputting a multilevel output voltage using a first and a second capacitor unit, a plurality of switches, and a plurality of diodes connected in series with each other. And a PWM controller configured to set an operation mode of the multilevel inverter, perform a control on the plurality of switches to generate different output voltages in each operation mode, and output the output voltage of the multilevel.

Description

Multilevel Inverter

The present invention relates to a multi-level inverter, and more particularly to a multi-level inverter for generating an output voltage having five levels with one H-bridge inverter.

Recently, the demand for high-voltage high-capacity inverter system is increasing according to the trend of high-capacity and high-pressure industrial facilities, and research on multi-level inverters that can overcome the limited rating of power semiconductor devices has been continuously conducted.

Multilevel inverters do not have the problem of unbalanced switching voltages of switch elements when using series-connected elements, compared to conventional two-level inverters. Harmonics by making the output voltage wave form closer to the square wave at the same switching frequency. The components can be significantly reduced, and the voltage change rate can be reduced to reduce electromagnetic interference.

The multilevel inverter is a flying capacitor type that uses a separate capacitor in a floating state to form an output level, and a diode clamped type that uses an diode clamp method to form an output level. It can be divided into three types of H-bridge type by combining the bridge shape by modularization.

On the other hand, the diode clamp type multi-level inverter is capable of back-to-back connection by sequentially switching to multiple stage taps obtained from a plurality of capacitors connected in series with a single high voltage DC link. Some have been put to practical use. However, a control method is needed to solve the DC link voltage imbalance problem. As the number of levels increases, it is difficult to realize a system, an imbalance voltage is applied to the clamping diode, and the current of the main switch elements becomes unbalanced. there is a problem.

Flying-capacitor multilevel inverters do not cause diode voltage imbalance problems, but as the level increases, an additional voltage is required to secure the initial voltage of the internal capacitor in a system requiring a large number of capacitor banks and a single input rectifier. In addition to the need for a conventional circuit, the switching control for maintaining the voltage of the capacitor is complicated, and the switching loss is also increased due to the increased switching frequency, which makes it difficult to put to practical use.

The H-bridge multilevel inverter is a method of obtaining a multilevel output voltage by connecting a plurality of inverter outputs of a conventional H-bridge configuration in series with each other. It has the advantage of being possible and simple to control. However, the number of switching elements is larger than that of the two-level inverter, and as the number of parts of the system increases, the reliability and efficiency of the system decreases, and the cost increases.

Accordingly, an object of the present invention is to provide a multi-level inverter capable of minimizing the number of switch elements.

Multi-level inverter according to the present invention for achieving the above object is a switch unit and a sine for outputting the multi-level output voltage using the first and second capacitor unit, a plurality of switches and a plurality of diodes connected in series with each other (sine) an operation mode of the multilevel inverter is set based on a reference wave and a triangular wave in the form of a function, and the control of the plurality of switches is performed to generate different output voltages in each operation mode, thereby outputting the multilevel And a PWM control unit for outputting a voltage.

The switch unit includes first and second diodes and first to sixth switches, wherein one end of the first diode and one end of the second diode are one end of the first capacitor and one end of the second capacitor. Commonly connected to the connected connection node, wherein the first switch is disposed between the other end of the first capacitor and the other end of the first diode to perform switching, and the second switch is connected to the other end of the second capacitor and the Disposed between the other end of the second diode to perform switching, one end of the third switch and one end of the fourth switch are connected to each other, and the other end of the third switch and the other end of the fourth switch are connected to the first diode. Respectively connected to the other end of the second diode and the other end of the second diode, one end of the fifth switch and one end of the sixth switch are connected to each other, and the other end and the phase of the fifth switch. The other end of the switch 6 may be connected respectively to the other end and the other end of the fourth switch of the third switch.

여기서,

는 기준파 전압의 순시값이며,

는 삼각파의 최대 전압값이다.On the other hand, the PWM control unit may generate a reference value for setting the operation mode by using the instantaneous value of the reference wave voltage in the form of a sine function and the maximum voltage value of the triangular wave as shown in the following equation.

here,

Is the instantaneous value of the reference wave voltage,

Is the maximum voltage value of triangle wave.

In this case, when the reference wave has a phase of 0 to 180 °, the PWM controller sets the operation mode to the first operation mode when the reference wave is greater than the maximum voltage value of the triangular wave, and the reference wave is If the value is between 0 and the maximum voltage value of the triangular wave, the operation mode is set to the second operation mode. When the reference wave has a phase of 180 ° to 360 °, the inverted reference wave is larger than the maximum voltage value of the triangular wave. When the size is small, the operation mode is set as the third operation mode. When the inverted reference wave is larger than the maximum voltage value of the triangular wave, the operation mode may be set as the fourth operation mode.

In this case, the PWM controller, in the first operation mode, when the value obtained by subtracting the maximum voltage value of the triangular wave from the reference wave is larger than the triangular wave, the PWM controller simultaneously turns on the first and second switches and the maximum voltage value of the triangular wave. If the value is less than the triangular wave, the first and second switches are turned off alternately. In the second operation mode, if the reference wave is larger than the triangular wave, the first and second switches are alternately Turn on the first and second switches alternately when the reference wave is smaller than the triangular wave, and in the third operation mode, when the inverted reference wave is larger than the triangular wave, the first and second switches Is alternately turned on and if the inverted reference wave is smaller than the triangular wave, the first and second switches are alternately turned off, and in the fourth operation mode, the inversion When the value obtained by subtracting the maximum voltage value of the triangular wave from the reference wave is larger than the triangle wave, the first and second switches are turned on simultaneously. When the value obtained by subtracting the maximum voltage value of the triangular wave is smaller than the triangle wave, the first and second switches are turned on. Can be turned off alternately.

The PWM controller turns on third and sixth switches included in the H-bridge inverter when the reference wave has a phase of 0 to 180 °, and the reference wave has a phase of 180 ° to 360 °. When having a, it is possible to turn on the fourth and fifth switches included in the H-bridge inverter.

According to the embodiment of the present invention described above, by reducing the number of switch elements compared to the existing multi-level inverter it is possible to improve the reliability and reduce the manufacturing cost. In addition, the PWM control signal for controlling the switch can be generated using one triangle wave, so that the configuration of the control circuit can be facilitated.

1 is a block diagram showing a configuration of a multilevel inverter according to an embodiment of the present invention;
2 is a circuit block diagram illustrating in detail the configuration of the power supply unit 110 and the switch unit 120 of FIG. 1 according to an embodiment of the present disclosure;
3 is a view for explaining the operation of the PWM control unit 130 for driving a multi-lever inverter according to an embodiment of the present invention,
4 to 7 are views for explaining an example of generating an output voltage of the multi-level inverter according to an embodiment of the present invention;
8A to 10 are diagrams showing simulation results of a multilevel inverter according to an embodiment of the present invention;
11 to 15 are diagrams illustrating a state in which a multilevel inverter is connected in different ways according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a configuration of a multilevel inverter according to an embodiment of the present invention. Referring to FIG. 1, the multi-level interconnector includes a power supply unit 110, a switch unit 120, a PWM control unit 130, and an output unit 140.

The power supply unit 110 supplies DC power to the switch unit 120. In the implementation, the power supply unit 110 may be implemented in a form of supplying DC power to the switch unit 120 by transforming, rectifying, and smoothing the input AC power by receiving a three-phase AC power. It may also be implemented in the form of supplying DC power to the switch unit 120 using a power source.

The switch unit 120 includes a plurality of switch elements, and generates an output voltage having five levels in accordance with the switching operation of the plurality of switch elements. To this end, it may include a plurality of Souch elements, diodes and H-Bridge (H-Bridge) inverter.

The PWM controller 130 may control the switching operation of the plurality of switch elements constituting the switch unit 120 to generate an output voltage having five levels. In detail, an operation mode of a multilevel inverter may be set by comparing a reference wave having a sinusoidal shape with a triangular wave, and PWM control of a plurality of switches may be performed to generate two different output voltages according to the operation mode.

The output unit 140 transmits a voltage having five levels generated by the switching operation of the switch unit to an external load.

Hereinafter, the configuration and implementation of the present multilevel inverter will be described in detail with reference to FIGS. 2 to 7.

FIG. 2 is a circuit block diagram illustrating in detail the configurations of the power supply unit 110 and the switch unit 120 of FIG. 1.

Referring to FIG. 2, the power supply unit 110 includes one DC power supply 205 (V _DC ) and first and second capacitors 210 and 215 connected in parallel thereto. Here, the first and second capacitors 210 and 215 are connected in series to each other as a DC link terminal to divide the DC power supply voltage V _DC . Therefore, when the DC power supply voltage of the DC power supply is V _DC , the first capacitor 210 and the second capacitor 215 respectively distribute the DC power to the voltage V _DC / 2.

The switch unit 120 receives DC power from the power supply unit 110 and includes first and second diodes 225 and 235 and first to sixth switches 220, 230, 240, 245, 250, and 255. do. Here, the third to sixth switches 240, 245, 250, and 255 are switches implementing the H-bridge inverter.

Looking at the circuit connection configuration of the specific switch unit 120 as follows.

One end of the first diode 225 and one end of the second diode 235 are commonly connected to a connection node to which one end of the first capacitor 210 and one end of the second capacitor 215 are connected. In addition, the first switch 220 is disposed between the other end of the first capacitor 210 and the other end of the first diode 225 to perform a switching operation, the second switch 230 of the second capacitor 215 It is disposed between the other end and the other end of the second diode 235 to perform a switching operation.

In addition, one end of the third switch 240 and one end of the fourth switch 250 are connected to each other, the other end of the third switch 240 and the other end of the fourth switch 250 is the other end of the first diode 225. And the other ends of the second diodes 235, respectively. One end of the fifth switch 245 and one end of the sixth switch 255 are connected to each other, and the other end of the fifth switch 245 and the other end of the sixth switch 255 are the other ends of the third switch 240. And the other end of the fourth switch 250, respectively.

Here, the first and second switches 220 and 230 receive V _DC / 2 at the maximum voltage from the first and second capacitors 210 and 215, and the H-bridge inverter receives V _DC at the maximum voltage. .

Meanwhile, the neutral points of the first and second capacitors 210 and 215 are connected to the midpoints of the reflux diodes 225 and 235 connected in series.

Hereinafter, the operation of the PWM control unit 130 for controlling the above-described switch unit 120 will be described in detail with the accompanying drawings.

3 is a view for explaining the operation of the PWM control unit 130 for driving a multi-lever inverter according to an embodiment of the present invention.

First, in order to determine the range of the operation mode according to each voltage level in the multi-level inverter, the instantaneous voltage modulation index ma is defined using the instantaneous magnitude of the reference wave vref and the triangular wave amplitude as shown in Equation 1 below. .

는 기준파 전압의 순시값이며,

는 삼각파의 최대 전압값이다.here,

Is the instantaneous value of the reference wave voltage,

Is the maximum voltage value of triangle wave.

를 이용하여 본 멀티레벨 인버터의 동작은 4가지의 전압레벨 동작 모드로 나눌 수 있으며, 각 모드는 서로 다른 2가지의 전압레벨을 출력한다. 아래의 표는 각 동작 모드의 범위와 출력 전압(V_OUT)을 나타낸다.

The multi-level inverter can be divided into four voltage level operation modes, and each mode outputs two different voltage levels. The table below shows the range of each operation mode and the output voltage (V _OUT ).

Operation mode Output voltage (V _OUT ) Operating Mode 1 (0.5≤m _a <1) V _DC or V _DC / 2 Operation Mode 2 (0≤m _a <0.5) V _DC / 2 or 0 Operation Mode 3 (-0.5≤m _a <0) 0 or -V _DC / 2 Operation Mode 4 (-1≤m _a <-0.5) -V _DC / 2 or -V _DC

The PWM controller 130 generates a control signal for controlling a switching operation of the plurality of switches constituting the switch unit 120 according to the operation mode defined above. To this end, the PWM controller 130 may use a reference wave (V _ref ) and a triangular wave (V _carrier ) having a phosphorus function.

Specifically, in operation mode 2 (0 ≦ m _a <0.5), that is, when the reference wave exists between 0 and Vc which is the maximum value of the triangle wave, the reference wave and the triangle wave are compared, and V _ref ＞ V _carrier , The first switch 220 (T ₁ ) and the second switch 230 (T2) are alternately turned on, and V _ref ＜ V _carrier In this case, the first switch 220 (T ₁ ) and the second switch 230 (T2) are alternately turned off.

Operating Mode 1 (0.5≤m_aIn the case of <1, that is, the reference wave is the maximum value of the triangular wave (V_cIf larger than), subtract the maximum value of the triangular wave from the reference wave, compare it with the triangular wave, and generate a switch control signal. That is, V_ref -V_C ＞ V_carrier The first switch 220 (T)_One) And the second switch 230 (T2) are turned on at the same time, V_ref -V_C <V_carrier The first switch 220 (T)_One) And the second switch 230 (T2) are alternately turned off.

On the other hand, in the operation mode 3 (-0.5≤m _a <0) and the operation mode 4 (-1≤m _a <-0.5), since the reference wave has a negative value, the PWM controller 130 sets the reference wave to 180. Reverse it (-V _ref ) and compare it with a triangle wave.

Specifically, in operation mode 3 (-0.5≤m _a <0), that is, when the inverted reference wave (-V _ref ) exists between 0 and Vc, the maximum value of the triangle wave, the inverted reference wave and the triangle wave are compared. , -V _ref ＞ V _carrier , The first switch 220 (T ₁ ) and the second switch 230 (T2) are alternately turned on, and -V _ref ＜ V _carrier In this case, the first switch 220 (T ₁ ) and the second switch 230 (T2) are alternately turned off.

In addition, in operation mode 4 (-1 ≦ m _a <−0.5), that is, when the inverted reference wave is larger than the maximum value of the triangular wave (V _c ), the maximum value of the triangular wave is subtracted from the reference wave and compared with the triangular wave. To generate a switch control signal. That is, -V _ref -V _C ＞ V _carrier In this case, the first switch 220 (T ₁ ) and the second switch 230 (T2) are turned on at the same time, and -V _ref -V _C ＜ V _carrier In this case, the first switch 220 (T ₁ ) and the second switch 230 (T2) are alternately turned off.

Meanwhile, the PWM controller 130 also generates control signals for the third to sixth switches 240, 245, 250, and 255 included in the H-bridge inverter. In detail, the PWM controller 130 turns on the third and sixth switches 240 and 255 when the reference wave has a positive value, that is, when the reference wave has a phase of 0 to 180 °. And turn off the fifth switches 245 and 250. The PWM controller 130 turns on the fourth and fifth switches 245 and 250 when the reference wave has a negative value, that is, when the reference wave has a phase of 180 to 360 °. The sixth switches 240 and 255 are turned off.

Here, the switching frequency of the first and second switches 220 and 230 is the same as the frequency of the triangular wave signal, and the third to sixth switches 240, 245, 250 and 255 are switched once during one cycle of the reference wave signal. Perform the action.

The PWM control signal generated by the PWM control unit 130 controls the switching operations of the plurality of switches 220, 230, 240, 245, 250, and 260, and accordingly, the multi-level inverters Five other output levels can be created.

Output voltage
(V _OUT ) Switch status First switch Second switch Third switch Fourth switch Fifth switch Sixth switch V _DC ON ON ON OFF OFF ON V _DC / 2
OFF ON ON OFF OFF ON ON OFF ON OFF OFF ON 0
OFF OFF ON OFF OFF ON OFF OFF OFF ON ON OFF -V _DC / 2
OFF ON OFF ON ON OFF ON OFF OFF ON ON OFF -V _DC ON ON OFF ON ON OFF

4 to 7 are diagrams for describing an example in which the multilevel inverter generates an output voltage according to an embodiment of the present invention.

Specifically, FIG. 4 illustrates an example of generating an output voltage of V _DC / 2 according to a PWM control signal for turning on the second switch 230, the third switch 240, and the sixth switch 260. 5 illustrates an example of generating an output voltage of V _DC / 2 according to a PWM control signal for turning on the first switch 220, the third switch 240, and the sixth switch 260. 6 illustrates an example of generating an output voltage of V _DC according to a PWM control signal for turning on the first switch 220, the second switch 230, the third switch 240, and the sixth switch 260. 7 illustrates an example in which an output voltage of 0 is generated according to a PWM control signal for turning on the third switch 240 and the sixth switch 260.

4 to 7, it can be seen that the multilevel inverter according to an embodiment of the present invention controls the turn-on operation of the switch to maintain the voltage balance of the DC link terminal capacitor. That is, the operation mode 1 may have three switching states as shown in FIGS. 4 to 6, and the operation mode 2 may have three switching states as shown in FIGS. 4 to 5 and 7. 4 and 5, when only the DC link stage switches (first and second switches) are turned on, the output voltages are all V _DC / 2, but the capacitors used are different. Therefore, in the present invention, the PWM controller 130 may generate a PWM control signal to alternately use the states of FIGS. 4 and 5 to balance the voltage of the DC link capacitor. That is, in operation mode 2, the DC link switches (first and second switches) are alternately turned on, and in operation mode 1, they are turned off alternately.

Table 3 below shows the number of switching elements, the number of conduction elements, and the number of switching elements in each switching cycle required for the multilevel inverter and the conventional single-phase diode clamping multilevel inverter according to an embodiment of the present invention. It is a comparison.

Active element Passive elements Conducting element for each mode Switching element in mode conversion Diode clamping method 8 4 4 2 This multilevel inverter 6 2 4 One

According to this, although the conduction loss is the same, it can be confirmed that the switching loss is small because the multi-level inverter uses less switching elements than the 5-level inverter of the single-phase diode clamping method.

8A to 10 are diagrams showing simulation results of a multilevel inverter according to an embodiment of the present invention. 8A is a diagram showing one periodic waveform of the reference wave used by the PWM control unit 130, and FIG. 8B is a diagram showing one periodic waveform of the output voltage of the present multilevel inverter. 9 shows the output voltage of the multilevel inverter seen in operation mode 1 and operation mode 2. FIG. 10 is an enlarged graph of triangular waves, reference waves, and inverter output voltages in operation mode 1 and operation mode 2. Referring to these, it can be seen that only one triangle wave is used to generate different output voltages.

11 to 15 are diagrams illustrating a state in which a multilevel inverter is connected in different ways according to an embodiment of the present invention.

FIG. 11 is a circuit diagram of cascading the multilevel inverters to each other, and it can be seen that the number of levels of the multilevel can be extended through this.

12 and 13 are circuit diagrams connecting the present multilevel inverter in three phases. Referring to these, the multi-level inverter can be installed in a Y connection or a DELTA connection to implement a three-phase five-level multi-level inverter.

14 and 15 are circuit diagrams connecting cascade-connected multilevel interconnectors in three phases. Through this, the number of levels can be extended than that of the three-phase five-level multilevel inverter shown in FIGS. 12 and 13, and an output voltage can be applied to three phases of a Y connection or a Δ connection.

Although preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the present invention belongs to the present invention without departing from the gist of the present invention as claimed in the claims. Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

110: power supply unit 120: switch unit
130: PWM control unit 140: output unit

Claims (6)

In a multilevel inverter,
First and second capacitor units connected in series with each other;
A switch unit for outputting a multilevel output voltage using a plurality of switches and a plurality of diodes; And
A reference value for setting an operation mode is calculated based on a reference wave and a triangle wave in the form of a sine function, and the operation mode of the multilevel inverter is defined differently according to the level to which the calculated reference value belongs, and each operation mode And a PWM control unit configured to control the plurality of switches so that different output voltages are generated at the same time, and output the output voltages of the multilevels. The method of claim 1,
Wherein,
First and second diodes;
Including first to sixth switches;
One end of the first diode and one end of the second diode are commonly connected to a connection node to which one end of the first capacitor and one end of the second capacitor are connected.
The first switch is disposed between the other end of the first capacitor and the other end of the first diode to perform switching,
The second switch is disposed between the other end of the second capacitor and the other end of the second diode to perform switching;
One end of the third switch and one end of the fourth switch are connected to each other, the other end of the third switch and the other end of the fourth switch are respectively connected to the other end of the first diode and the other end of the second diode,
One end of the fifth switch and one end of the sixth switch are connected to each other, and the other end of the fifth switch and the other end of the sixth switch are connected to the other end of the third switch and the other end of the fourth switch, respectively. Multi-level inverter characterized by. The method of claim 1,
The PWM control unit,
A multilevel inverter, characterized in that for generating a reference value for setting the operation mode by using the instantaneous value of the reference wave voltage and the maximum voltage value of the triangular wave in the form of a sine function:

here,

Is the instantaneous value of the reference wave voltage,

Is the maximum voltage value of triangle wave. The method of claim 3,
The PWM control unit,
When the reference wave has a positive value, if the reference wave is greater than the maximum voltage value of the triangular wave, the operation mode is set to a first operating mode, and the reference wave exists between 0 and the maximum voltage value of the triangular wave. Set the operation mode to the second operation mode,
When the reference wave has a negative value, if the inverted reference wave is less than the maximum voltage value of the triangle wave, the operation mode is set to a third operation mode, and if the inverted reference wave is greater than the maximum voltage value of the triangle wave And setting the operation mode to a fourth operation mode, respectively. 5. The method of claim 4,
The PWM control unit,
In the first operation mode, when the value obtained by subtracting the maximum voltage value of the triangular wave from the reference wave is greater than the triangular wave, the first and second switches are simultaneously turned on and the value obtained by subtracting the maximum voltage value of the triangular wave is smaller than the triangular wave. To alternately turn off the first and second switches,
In the second operation mode, the first and second switches are alternately turned on when the reference wave is larger than the triangle wave, and the first and second switches are alternately turned off when the reference wave is smaller than the triangle wave. And
In the third operation mode, when the inverted reference wave is larger than the triangular wave, the first and second switches are alternately turned on, and when the inverted reference wave is smaller than the triangular wave, the first and second switches are alternated. Turn off the enemy,
In the fourth operation mode, when the value obtained by subtracting the maximum voltage value of the triangular wave from the inverted reference wave is greater than the triangular wave, the first and second switches are simultaneously turned on and the value obtained by subtracting the maximum voltage value of the triangular wave is the triangular wave. If smaller, the first and second switches are alternately turned off. 5. The method of claim 4,
The PWM control unit,
When the reference wave has a positive value, the third and sixth switches are turned on,
And turning on the fourth and fifth switches when the reference wave has a negative value.

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