JP3584686B2 - Voltage source power conversion circuit - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention provides a voltage-type power converter that controls a DC voltage of a voltage-type inverter, electrically insulates an input side and an output side of a circuit, and can obtain an AC voltage or a DC voltage of a desired magnitude as an output. It concerns the circuit.
[0002]
[Prior art]
FIG. 11 shows a DC-DC conversion circuit (DC-DC converter) as a conventional technique. 101 is a DC power supply, 201 is a reactor, 301 is a semiconductor switching element Tr5 and a diode connected in antiparallel to a diode. D1; a boost chopper 401; a smoothing capacitor 401; a single-phase voltage source inverter 501 including semiconductor switching elements Tr1 to Tr4 in which diodes are connected in anti-parallel; 601 an insulating transformer; 801 is a smoothing capacitor on the secondary side of the transformer 601, and 901 is a load such as a DC motor.
[0003]
In this prior art, the boost chopper 301 is used to obtain a DC voltage to be supplied to the inverter 501.
That is, the switching element Tr5 is turned on, the energy of the DC power supply 101 is stored in the reactor 201, and the switching element Tr5 is turned off, so that the energy stored in the reactor 201 is transferred through the diode D1 together with the energy supplied from the DC power supply 101. Supplied to the smoothing capacitor 401. As a result, the voltage of the smoothing capacitor 401 becomes a DC voltage higher than the power supply voltage.
[0004]
On the other hand, the inverter 501 is a single-phase voltage-type PWM inverter having the DC voltage of the smoothing capacitor 401 as an input voltage, and including self-extinguishing type semiconductor switching elements Tr1 to Tr4 such as IGBTs in two sets of upper and lower arms.
The operation of the single-phase voltage-type PWM inverter is publicly known and will not be described. However, two switching patterns for determining the polarity of the output voltage by controlling the conduction state of the four arms, and the upper arm or the lower arm are used. Two types of switching patterns called a so-called zero voltage vector in which all are made conductive and both output voltages become zero can be selected.
By setting the capacity of the smoothing capacitor 401 to be sufficiently large, the switching of the boost chopper 301 and the switching of the inverter 501 can be independently and freely performed.
[0005]
FIG. 12 shows another conventional technique, in which 102 is a single-phase AC power supply, 103 is a single-phase full-wave rectifier circuit, and 302 is a sine-wave converter. This prior art includes a sine wave converter 302 for converting an input current waveform into a sine wave having a high power factor and the single-phase voltage source inverter 501. The sine-wave converter 302 includes a semiconductor switching element Tr6 in which diodes are connected in anti-parallel and a diode D2, and has substantially the same configuration as the boost chopper 301.
The operation of the sine-wave converter 302 is well-known and will not be described in detail. However, the full-wave rectification of the AC power supply voltage by the rectifier circuit 103 and then short-circuiting by the semiconductor switching element Tr6 through the reactor 301 to change the waveform of the input current Form. As a result, it is possible to obtain a direct current from an alternating current and simultaneously control the input current in a sine wave shape.
[0006]
[Problems to be solved by the invention]
11 and 12, the power conversion circuit as a whole requires five self-extinguishing type semiconductor switching elements. If these drive circuits, drive power supplies, control circuits, and the like are included, the circuit configuration is complicated and expensive. It will be.
Further, the reactor 201 is inserted on the input side of the step-up chopper 301 and the sine wave converter 302, which hinders miniaturization.
[0007]
Therefore, the present invention reduces the number of semiconductor switching elements used, simplifies the circuit configuration, downsizes the device, and reduces the cost. An object of the present invention is to provide a voltage-type power conversion circuit capable of controlling an input current in a sine wave shape.
[0008]
[Means for Solving the Problems]
In order to solve the above problem, the invention according to claim 1 is a DC power supply, a voltage type inverter for converting the power of the DC power supply into AC power by the operation of a semiconductor switching element, and connected to a DC input terminal of the inverter. In a voltage source power conversion circuit including a smoothing capacitor and an insulation transformer having a primary side connected to an AC output terminal of the inverter, one end of a DC power supply is connected to an intermediate tap or a neutral point on the primary side of the insulation transformer. At the same time, the other end of the DC power supply is connected to one end of the smoothing capacitor, and when the zero voltage vector is output by the inverter, zero-phase power is transferred between the DC power supply and the smoothing capacitor via the leakage inductance of the inverter and the insulating transformer. By doing so, the DC voltage of the inverter is controlled.
[0009]
FIG. 1 is a conceptual diagram of the first aspect of the present invention. In the figure, reference numeral 400 denotes a smoothing capacitor, which is connected to the DC input side of a single-phase or three-phase voltage source inverter 500 or the like. Reference numeral 600 denotes a single-phase or three-phase insulating transformer whose primary side is connected to the AC output terminal of the voltage-source inverter 500, and is provided between an intermediate tap or neutral point on its primary side and one end of the smoothing capacitor 400. DC power supply 100 is connected. The DC power supply 100 may be configured by combining an AC power supply and a rectifier circuit.
A rectifier circuit 700 such as full-wave rectification or half-wave rectification is connected to the secondary side of the insulating transformer 600, and a load 900 is connected to the output side. Note that the rectifier circuit 700 may be omitted and AC power may be supplied directly from the insulating transformer 600 to the load 900.
[0010]
In the above configuration, by causing the inverter 500 to output a zero voltage vector, the DC power supply voltage becomes a zero-phase voltage when viewed from the AC output terminal of the inverter 500, and this zero-phase voltage does not appear in the output voltage of the insulating transformer 600. It does not affect the rectifier circuit 700 and the load 900 side. That is, considering the positive phase component, the voltage applied to the insulating transformer 600 operates as a conventional voltage source inverter.
On the other hand, considering the zero-phase component, when outputting a zero voltage vector, the plurality of upper and lower arms of the voltage source inverter 500 can be regarded as one upper and lower arm that switches at a ratio of the zero voltage vector. The same operation as a chopper or a sine wave converter can be performed. Further, the insulating transformer 600 can be regarded as a reactor having a value of leakage inductance.
Thus, between the DC power supply (including the combination of the AC power supply and the rectifier circuit) 100 and the smoothing capacitor 400, power is transferred from the primary side of the insulating transformer 600 via the voltage source inverter 500, and the voltage source DC voltage of inverter 500 is controlled to a predetermined value. When an AC power supply is used as the power supply, the current waveform can be controlled in a sine wave shape.
[0011]
The invention of claim 1 is embodied by the following inventions.
First, a second aspect of the present invention provides a DC power supply, a voltage-type inverter for converting the power of the DC power supply into single-phase AC power by operating a semiconductor switching element, and a smoothing capacitor connected to a DC input terminal of the inverter. And a voltage-type power conversion circuit comprising an insulating transformer having a primary side connected to an AC output terminal of the inverter.
The feature is that one end of the DC power supply is connected to the intermediate tap on the primary side of the insulating transformer, and the other end of the DC power supply is connected to one end of the smoothing capacitor. The DC voltage of the inverter is controlled by transmitting and receiving zero-phase power between the DC power supply and the smoothing capacitor via the leakage inductance of the transformer.
As a result, the conventional boost chopper can be substituted by using the zero voltage vector of the inverter.
[0012]
According to a third aspect of the present invention, an upper and lower arm formed by connecting two semiconductor switching elements in series is connected in parallel to the smoothing capacitor, and a middle point of the upper and lower arms is connected to an insulating transformer via a DC power supply. It is connected to the intermediate tap on the primary side.
[0013]
According to a fourth aspect of the present invention, the DC power supply according to the second or third aspect includes an AC power supply and a rectifier circuit connected to the AC power supply. Then, the control circuit generates a zero-phase voltage command value for causing the inverter to output a zero-voltage vector based on a deviation between the sine-wave-shaped zero-phase current command value and the zero-phase current detection value. When the vector is output, the input current of the rectifier circuit is controlled in a sine wave shape.
Thus, the conventional sine wave converter can be substituted by using the zero voltage vector of the inverter.
[0014]
According to a fifth aspect of the present invention, in the second to fourth aspects of the present invention, a reactor is inserted between the intermediate tap of the insulating transformer and a power supply side, and the core of the insulating transformer is used as the core of the reactor. .
In other words, by sharing the core of the insulating transformer with the reactor, it is possible to minimize the size of the entire circuit, and even if the leakage inductance of the insulating transformer alone cannot sufficiently suppress the ripple due to switching and requires a separate reactor. In addition, current ripple can be suppressed without impairing the miniaturization of the circuit.
[0015]
According to a sixth aspect of the present invention, in the invention of the second to fifth aspects, a rectifier circuit such as a full-wave rectifier circuit or a half-wave rectifier circuit is connected to a secondary side of the insulating transformer, and a load connected to the rectifier circuit. To supply DC power to the power supply.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
First, FIG. 2 is a circuit diagram showing an embodiment of the invention described in claim 2. In the figure, a DC power source 101 is connected to an intermediate tap 601a of an insulating transformer 601 as described above. That is, this configuration corresponds to a configuration in which the boost chopper 301 and the reactor 201 in FIG. 11 are removed, and the positive electrode of the DC power supply 101 is connected to the intermediate tap 601 a of the primary winding of the insulating transformer 601. The other circuit configuration is the same as that of FIG.
[0017]
This embodiment focuses on the zero voltage vector of the single-phase voltage source inverter 501. That is, in order to output the zero voltage vector in the single-phase voltage source inverter 501, there are two types of switching patterns, that is, a case where all two sets of upper arms are made conductive and a case where all two sets of lower arms are made conductive. The form uses this degree of freedom.
Since the zero-phase voltage output from the inverter 501 does not appear in the output voltage, it does not affect the output voltage on the secondary side of the insulating transformer 601, and there is no problem in supplying power to the load 901. Accordingly, the equivalent circuit for the positive phase is as shown in FIG. 3, and the inverter 501 operates in the same manner as in the prior art to apply an AC voltage to the primary side of the insulating transformer 601.
When a three-phase voltage source inverter is used as the voltage source inverter, a zero voltage vector is output by turning on all three sets of upper arms or turning on all three sets of lower arms, as is well known. You.
[0018]
On the other hand, when considering the zero-phase component, it is as shown in FIG. 4, and the two sets of upper and lower arms of the inverter 501 in FIG. 2 can be regarded as one arm 501 'that performs switching operation at the ratio of the zero voltage vector. That is, by turning on the switching elements Tr1 and Tr3 of the upper arm of the inverter 501 or the switching elements Tr2 and Tr4 of the lower arm and outputting a zero voltage vector, a reactor described later is connected between the DC power supply 101 and the smoothing capacitor 401. Energy can be transferred via 601 'and the DC voltage of the inverter 501 can be controlled by using the boost chopper 301 shown in FIG.
The reactor 601 ′ in FIG. 4 has the value of the leakage inductance of the insulating transformer 601 and replaces the reactor 201 in FIG. 11 and FIG.
[0019]
That is, when the inverter 501 outputs a zero-voltage vector, the same operation as the conventional boost chopper 301 can be performed by transferring zero-phase power between the DC power supply 101 and the smoothing capacitor 401 via the inverter 501. Therefore, the number of semiconductor switching elements and their driving circuits can be reduced when viewed from the entire power conversion circuit. Therefore, the circuit configuration can be simplified, downsized, and reduced in cost.
Here, in the embodiment of FIG. 2, the positive electrode of the DC power supply 101 is connected to the intermediate tap 601a, and the negative electrode is connected to the connection point between the smoothing capacitor 401 and the switching element Tr2. 601a, and the positive electrode may be connected to a connection point between the smoothing capacitor 401 and the switching element Tr1.
[0020]
The inverter 501 in FIG. 2 is PWM-controlled, and the PWM pulse is generated by, for example, a control circuit shown in FIG.
That is, in FIG. 5, the deviation between the DC voltage command value v _dc ^* and the DC voltage detection value v _dc (the voltage of the smoothing capacitor 401 in FIG. 2) is input to the voltage controller 551, and the zero-phase (input) current is obtained from the output thereof. The command value i ₀ ^* is obtained.
Then, a deviation between the zero-phase current command value i ₀ ^* and the zero-phase current detection value i ₀ is input to the current controller 552 to obtain a zero-phase voltage command value v ₀ ^* . The zero-phase voltage command value _v ^{0 *,} adds the _{-v inv} ^* and through the output voltage command value _{v inv} ^* and sign inverter 553 of the inverter, respectively input the addition result to the comparator 554, 555. The comparators 554 and 555 compare each input with a triangular wave, and invert the output by the upper and lower arms to obtain a PWM pattern for the switching elements Tr1 to Tr4 of the inverter 501.
[0021]
In other words, the inverter 501 performs an operation in which the single-phase voltage-source inverter and the boost chopper are overlapped with each other by changing the switching pattern. The former is controlled by the positive-phase current and the latter is controlled by the zero-phase current.
[0022]
Next, FIG. 6 is a circuit diagram showing an embodiment of the invention described in claim 3. In this embodiment, a converter upper / lower arm 502 composed of a series circuit of semiconductor switching elements Tr7 and Tr8 in which diodes are connected in anti-parallel is connected to both ends of a smoothing capacitor 401. The positive electrode is connected to an intermediate tap 601 a of the primary winding of the insulating transformer 601.
[0023]
The upper and lower arms 502 control so that the potential at the middle point thereof is half of the DC voltage of the inverter 501 on average. In this case, the control circuit of the inverter 501 may be the control circuit shown in FIG. There is also a method in which the converter upper and lower arms 502 perform a boosting action or a rectifying action of an input current, and do not superimpose a zero-phase voltage on the inverter 501.
[0024]
FIG. 7 is a circuit diagram showing an embodiment of the invention described in claim 4. In this embodiment, a combination of a single-phase AC power supply 102 and a single-phase full-wave rectifier circuit 103 is used instead of the DC power supply 101 of FIG.
In this case, a control circuit as shown in FIG. 8 is used to make the input current waveform of the rectifier circuit 103 a sine wave.
[0025]
8, differs from the FIG. 5 receives the output of the voltage controller 551 to the multiplier 556, the power supply voltage and in phase with a size of the absolute value of the first sine-wave | sinω _{s t} | a multiplied by zero-phase The point is that the (input) current command value i ₀ ^* is obtained.
As a result, the DC voltage of the inverter 501 can be controlled while maintaining the input current waveform as a sine wave. The operation in this case is such that the single-phase voltage-source inverter and the single-phase input single-stone sine-wave converter are superimposed.
Although the embodiment of FIG. 7 uses a single-phase AC power supply 102 and a single-phase full-wave rectifier circuit 103, a three-phase AC power supply can be used in combination with a three-phase full-wave rectifier circuit.
The idea of using a combination of an AC power supply and a rectifier circuit instead of a DC power supply is also applicable to the embodiment of FIG.
[0026]
FIG. 9 shows an embodiment of the invention described in claim 5. In this embodiment, a reactor 602 is connected to an intermediate tap of an insulating transformer 601 in the embodiment of FIG. The reactor 602 can be mounted inside the insulating transformer 601 by using the core of the insulating transformer 601 as the iron core.
As a result, even when current ripple due to switching cannot be sufficiently suppressed only by the leakage inductance of the insulating transformer 601, current ripple can be suppressed without impairing miniaturization.
The idea of mounting the reactor 602 sharing the iron core inside the insulating transformer 601 as in this embodiment is also applicable to the embodiments of FIGS.
5 or 8 may be applied to the control circuit of the inverter 501.
[0027]
Next, FIG. 10 shows an embodiment of the invention described in claim 6, in which a single-phase half-wave rectifier circuit is used instead of the single-phase full-wave rectifier circuit 701 on the secondary side of the insulating transformer 601 in the embodiment of FIG. 702 is connected, and the intermediate tap 601 b on the secondary side of the insulating transformer 601 is connected to the load 901 and one end of the smoothing capacitor 801. The idea of connecting the half-wave rectifier circuit to the secondary side of the insulating transformer 601 as in the present embodiment is also applicable to the embodiments of FIGS. 6, 7, and 9.
Note that as the control circuit of the inverter 501, the control circuit in FIG. 5 or FIG.
[0028]
In the present invention, for example, when a three-phase voltage-source inverter is used as a voltage-source inverter and a three-phase insulation transformer is connected to the AC output side, a tap is provided at a neutral point on the primary side of the insulation transformer to provide a direct-current output. What is necessary is just to connect the positive electrode of a power supply or the positive output terminal of a rectifier circuit.
[0029]
【The invention's effect】
As described above, according to the first to sixth aspects of the present invention, the leakage inductance of the insulating transformer can be used to replace the conventional input-side reactor, so that the circuit can be reduced in size and cost can be reduced. .
In particular, according to the first, second and fourth to sixth aspects of the present invention, an operation equivalent to a conventional boost chopper or a sine wave converter can be performed by using a zero voltage vector by an inverter. It is possible to reduce the number of switching elements and the accompanying reduction in the number of drive circuits and control power supplies.
Furthermore, according to the fourth aspect of the present invention, the input current waveform of the rectifier circuit can be controlled to a high power factor sinusoidal waveform.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram of the invention described in claim 1;
FIG. 2 is a circuit diagram showing an embodiment of the invention described in claim 2;
FIG. 3 is a positive phase equivalent circuit of the embodiment of FIG. 2;
4 is a zero-phase equivalent circuit of the embodiment of FIG. 2;
FIG. 5 is a control circuit diagram of the embodiment of FIG. 2;
FIG. 6 is a circuit diagram showing an embodiment of the invention described in claim 3;
FIG. 7 is a circuit diagram showing an embodiment of the invention described in claim 4;
FIG. 8 is a control circuit diagram of the embodiment of FIG. 7;
FIG. 9 is a circuit diagram showing an embodiment of the invention described in claim 5;
FIG. 10 is a circuit diagram showing an embodiment of the invention described in claim 6;
FIG. 11 is a circuit diagram showing a conventional DC-DC conversion circuit.
FIG. 12 is a circuit diagram showing a conventional DC-DC conversion circuit.
[Explanation of symbols]
Reference Signs List 100 DC power supply 400 Smoothing capacitor 500 Voltage-source inverter 600 Insulation transformer 700 Rectifier circuit 900 Load 101 DC power supply 401, 801 Smoothing capacitor 501 Single-phase voltage-type inverter 501 'Arm 502 Converter upper / lower arm 551 Voltage controller 552 Current controller 553 Sign inversion 554, 555 Comparator 556 Multiplier 601 Insulation transformer 601 'Reactor 601a, 601b Intermediate tap 701 Single-phase full-wave rectifier 702 Single-phase half-wave rectifier 901 Load Tr1 to Tr4, Tr7, Tr8 Self-extinguishing type semiconductor switching element

Claims (6)

A DC power supply, a voltage source inverter that converts the power of the DC power supply into AC power by the operation of the semiconductor switching element, a smoothing capacitor connected to a DC input terminal of the inverter, and a primary side connected to an AC output terminal of the inverter. A voltage-source power conversion circuit comprising:
Connect one end of the DC power supply to the intermediate tap or neutral point on the primary side of the insulating transformer, and connect the other end of the DC power supply to one end of the smoothing capacitor,
When the zero voltage vector is output by the inverter, the DC voltage of the inverter is controlled by transferring zero-phase power between the DC power supply and the smoothing capacitor via the leakage inductance of the inverter and the insulating transformer. Voltage source power conversion circuit. A DC power supply, a voltage-source inverter that converts the power of the DC power supply into single-phase AC power by the operation of the semiconductor switching element, a smoothing capacitor connected to the DC input terminal of the inverter, and a primary side connected to the AC output terminal of the inverter. A voltage-type power conversion circuit comprising:
Connect one end of the DC power supply to the intermediate tap on the primary side of the insulating transformer, and connect the other end of the DC power supply to one end of the smoothing capacitor,
When the zero voltage vector is output by the inverter, the DC voltage of the inverter is controlled by transferring zero-phase power between the DC power supply and the smoothing capacitor through the leakage inductance of the inverter and the insulating transformer. Voltage source power conversion circuit. A DC power supply, a voltage-source inverter that converts the power of the DC power supply into single-phase AC power by the operation of the semiconductor switching element, a smoothing capacitor connected to the DC input terminal of the inverter, and a primary side connected to the AC output terminal of the inverter. A voltage-type power conversion circuit comprising:
The upper and lower arms formed by connecting two semiconductor switching elements in series are connected in parallel to the smoothing capacitor, and the middle point of the upper and lower arms is connected to the intermediate tap on the primary side of the insulating transformer via a DC power supply. Voltage-type power conversion circuit. The voltage-type power conversion circuit according to claim 2 or 3,
As the DC power supply, an AC power supply and a rectifier circuit connected to the AC power supply are provided, and a zero-phase voltage command value for causing the inverter to output a zero-voltage vector, a sine-wave zero-phase current command value and a zero-phase current detection. Generated based on the deviation from the value,
A voltage-type power conversion circuit, wherein an input current of the rectifier circuit is controlled in a sine wave shape when a zero voltage vector is output by an inverter. The voltage-type power conversion circuit according to claim 2, 3 or 4,
A voltage-type power conversion circuit, wherein a reactor is inserted between an intermediate tap of the insulating transformer and a power supply side, and an iron core of the insulating transformer is used as an iron core of the reactor. The voltage-type power conversion circuit according to claim 2, 3, 4, or 5,
A voltage-type power conversion circuit, wherein a rectifier circuit is connected to a secondary side of the insulating transformer, and DC power is supplied to a load connected to the rectifier circuit.

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