JP2007209108A - Power conversion unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power conversion unit with two different types of converters, a rectifier and an inverter, which is reduced size and cost as a whole unit, by commonizing some of insulted power supplies of a drive unit so as to decrease the number of necessary insulated power supplies for the whole unit. <P>SOLUTION: This power conversion unit includes: a rectifier for converting AC power into DC power by switching operations of an AC switch; and an inverter for converting DC power output from the rectifier into AC power. A common insulated power supply unit 97 drives: all of semiconductor switching elements 14, 14, 14, composing a PWM rectifier 1, of which electrodes on a current flowing-out side, or emitters, connect to negative electrode sides in the DC section of a PWM inverter 2; and all of semiconductor switching elements 20UN, 20VN, 20WN, composing the PWM inverter 2, of which electrodes on the current flowing-out side connect to the side of negative electrodes in the DC. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a power conversion device including a rectifier that converts AC power into DC power by a switching operation of an AC switch, and an inverter that converts the DC power into AC power, and in particular, connection of a power source for driving a semiconductor switching element. The present invention relates to a power converter having a characteristic in configuration.

FIG. 4 shows a power conversion device including a diode rectifier 150 and an inverter 170. Reference numeral 160 denotes an electrolytic capacitor connected to the DC portion of the inverter 170.
This power conversion device converts the AC power of the three-phase AC power source 200 into DC power by the diode rectifier 150, and can convert this DC power into AC power having an arbitrary amplitude and frequency by the inverter 170. Therefore, it is widely used as a power source for a load 300 such as an electric motor. However, since the diode rectifier 150 is used, there is a problem that power cannot be regenerated and a large electrolytic capacitor 60 is required in the direct current portion, and the volume cannot be ignored.

FIG. 5 shows a power conversion device including a PWM rectifier 180 and a PWM inverter 190 using an AC switch.
This type of technology is disclosed in Non-Patent Document 1 and not only can power be regenerated, but also does not require an energy buffer such as a capacitor in the DC section, so that the apparatus can be miniaturized.

The AC switch 100 used in the PWM rectifier 180 is composed of two unidirectional semiconductor switching elements 101 and 102 having reverse blocking capability, and can not only control the input current waveform but also regenerate power.
Since the switching elements 101 and 102 need to be controlled independently according to the polarity of the power supply voltage and the direct current i _dc in order to prevent the opening of the load end, it is necessary to provide a drive unit 110 for each switching element. . As shown in FIG. 5, the plurality of semiconductor switching elements 103 constituting the inverter 190 are also individually driven by the drive unit 110 having the same configuration.

The drive unit 110 includes a drive circuit 111 that drives a semiconductor switching element based on a PWM command from a control device (not shown), and an insulated power source 112 for the drive circuit. Since the PWM rectifier 180 using the six AC switches 100 has a total of twelve unidirectional semiconductor switching elements, the same number of drive units 110 are required.
Similarly, since the PWM inverter 190 is composed of six semiconductor switching elements 103, the same number of drive units 110 are required, and 18 drive units 110 are required for the entire apparatus.

On the other hand, Patent Document 1 discloses an AC direct conversion device in which the number of insulated power supplies is reduced to simplify the circuit configuration and reduce the cost.
This prior art includes, for example, first and second semiconductor switching elements in which a plurality of AC switch circuits respectively connected between an AC input phase and an AC output phase are connected in reverse parallel to each other, A plurality of first semiconductor switching elements are driven by using a first common power source having a potential of the alternating current input phase as a reference potential. In addition, the current outflow side electrodes of the plurality of second semiconductor switching elements are connected to the same AC output phase, and a plurality of second power supplies are used using a second common power source having the potential of the AC output phase as a reference potential. The semiconductor switching element is driven.

Osamu Tarumi, Kenichi Iimori, Katsuji Shinohara, “Characteristics of converter control of voltage-type inverter without smoothing circuit”, 1996 Annual Conference of the Institute of Electrical Engineers of Japan, T-23 Japanese Patent Laying-Open No. 2004-72886 ([0013] to [0023], FIG. 1 etc.)

According to the prior art described in Patent Document 1, when the input / output of the direct conversion device has three phases, the number of power supplies having independent potentials as reference potentials can be reduced from nine to six. Is possible.
However, Patent Document 1 is only intended for one AC direct conversion device such as a matrix converter, and is intended to reduce the number of power sources for driving semiconductor switching elements constituting the conversion device. As described in Document 1, it cannot be directly applied to a power conversion device in which two converters, ie, a rectifier having an AC switch and an inverter are combined.

  Therefore, a problem to be solved by the present invention is that in a power converter having two different converters, a rectifier and an inverter, a part of the insulated power source of the drive unit is made common to both converters, so that the insulation required for the entire apparatus is obtained. An object of the present invention is to provide a power conversion device that is reduced in size and cost by reducing the number of power supplies.

In order to solve the above-mentioned problem, the invention described in claim 1 includes a rectifier that converts AC power into DC power by a switching operation of an AC switch, an inverter that converts DC power output from the rectifier into AC power, In a power conversion device comprising:
All the semiconductor switching elements that constitute the rectifier and whose current outflow side electrode is connected to the negative electrode side of the inverter, and the inverter, and the current outflow electrode thereof is the direct current part All semiconductor switching elements connected to the negative electrode side are driven using a common insulated power supply.

The invention described in claim 2 is the power conversion device described in claim 1,
The rectifier includes a plurality of first AC switches connected between the AC input phase and the DC unit positive electrode, and a plurality of second AC switches connected between the AC input phase and the DC unit negative electrode, respectively. And comprising
The first AC switch includes first and second semiconductor switching elements connected in antiparallel to each other, and the second AC switch includes third and fourth semiconductor switching elements connected in antiparallel to each other. ,
The plurality of first switching elements are connected by a first insulated power supply having a current potential side electrode of a plurality of first semiconductor switching elements connected to the DC section positive electrode side and a potential on the DC section positive electrode side as a reference potential. The plurality of fourth semiconductor switching elements are driven and connected to the direct current portion negative electrode side, and the plurality of fourth semiconductor switching elements are connected to the direct current portion negative electrode side by a second insulation power source having a potential on the direct current portion negative electrode side as a reference potential. A third insulating power source that drives the switching element 4 and connects the current outflow side electrodes of the second and third semiconductor switching elements to the same AC input phase and uses the potential of the AC input phase as a reference potential. Thus, the second and third semiconductor switching elements are driven.

According to a third aspect of the present invention, in the power conversion device according to the first aspect,
The rectifier includes a plurality of first AC switches connected between the AC input phase and the DC unit positive electrode, and a plurality of second AC switches connected between the AC input phase and the DC unit negative electrode, respectively. And comprising
The first AC switch includes an anti-parallel connection of a forward series connection circuit of the first semiconductor switching element and the first diode and a forward series circuit of the second semiconductor switching element and the second diode. And configure
The second AC switch connects the forward series connection circuit of the third semiconductor switching element and the third diode and the forward series circuit of the fourth semiconductor switching element and the fourth diode in antiparallel connection. And configure
The plurality of first switching elements are connected by a first insulated power supply having a current potential side electrode of a plurality of first semiconductor switching elements connected to the DC section positive electrode side and a potential on the DC section positive electrode side as a reference potential. The plurality of fourth semiconductor switching elements are driven and connected to the direct current portion negative electrode side, and the plurality of fourth semiconductor switching elements are connected to the direct current portion negative electrode side by a second insulation power source having a potential on the direct current portion negative electrode side as a reference potential. A third insulating power source that drives the switching element 4 and connects the current outflow side electrodes of the second and third semiconductor switching elements to the same AC input phase and uses the potential of the AC input phase as a reference potential. Thus, the second and third semiconductor switching elements are driven.

The invention described in claim 4 is the power conversion device described in claim 1,
The rectifier includes a plurality of first AC switches connected between the AC input phase and the DC unit positive electrode, and a plurality of second AC switches connected between the AC input phase and the DC unit negative electrode, respectively. And comprising
The first AC switch includes an anti-parallel circuit of a first semiconductor switching element and a first diode, and an anti-parallel circuit of a second semiconductor switching element and a second diode, and the first , Configured by connecting the cathodes of the second diode,
The second AC switch includes an antiparallel circuit of a third semiconductor switching element and a third diode, and an antiparallel circuit of a fourth semiconductor switching element and a fourth diode, and a third The cathodes of the fourth diodes are connected in series,
The plurality of first switching elements are connected by a first insulated power supply having a current potential side electrode of a plurality of first semiconductor switching elements connected to the DC section positive electrode side and a potential on the DC section positive electrode side as a reference potential. The plurality of fourth semiconductor switching elements are driven and connected to the direct current portion negative electrode side, and the plurality of fourth semiconductor switching elements are connected to the direct current portion negative electrode side by a second insulation power source having a potential on the direct current portion negative electrode side as a reference potential. A third insulating power source that drives the switching element 4 and connects the current outflow side electrodes of the second and third semiconductor switching elements to the same AC input phase and uses the potential of the AC input phase as a reference potential. Thus, the second and third semiconductor switching elements are driven.

According to the present invention, in a power conversion device including a rectifier having an AC switch and an inverter, when the AC switch is configured by a unidirectional semiconductor switching element, the current outflow side electrode of each switching element is connected to the AC input phase, DC By connecting to the partial positive electrode side or the direct current unit negative electrode side, it is possible to share an insulated power source for driving a plurality of switching elements within the rectifier and over both the rectifier and the inverter. Thereby, the number of insulated power supplies can be reduced, and the whole apparatus can be reduced in size and cost.
In particular, the present invention is more effective when applied to a power conversion device in which a rectifier and an inverter are housed in the same case.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
First, FIG. 1 shows a first embodiment of the present invention and corresponds to the invention according to claim 2. The invention according to claim 1 is an invention encompassing the invention of claim 2 and below, and is embodied by the following embodiments. As will be described later, some semiconductor switching elements constituting a rectifier and This is based on the idea of sharing an insulating power source for driving across both of the semiconductor switching elements constituting the inverter.

In FIG. 1, the power conversion device of this embodiment is composed of a PWM rectifier 1A using an AC switch and a PWM inverter 2 as in FIG. 5, and the R, S, T phases on the three-phase AC power supply 200 side. It is connected between the terminal and the U, V, W phase terminal on the load 300 side.
The configuration of the PWM inverter 2 is substantially the same as that in FIG. 5 except for the reference numerals of the constituent elements. 20UP, 20UN, 20VP, 20VN, 20WP, 20WN are semiconductor switching elements, 80 is a drive unit, 81 Is a drive circuit and 82 is an insulated power supply.

On the other hand, in the PWM rectifier 1A of FIG. 1, 10RP, 10RN, 10SP, 10SN, 10TP, and 10TN are all AC switches having the same configuration, and unidirectional semiconductor switching elements 11, 12 (upper arm) such as IGBT, 13, 14 (lower arm) are connected in antiparallel.
Here, the AC switches 10RP, 10SP, and 10TP are referred to as first AC switches, and the AC switches 10RN, 10SN, and 10TN are referred to as second AC switches. The semiconductor switching elements 11 to 14 are referred to as first to fourth semiconductor switching elements, respectively.

  The reference potential of the drive unit of the switching elements 11, 12, 13, and 14 needs to be equal to the emitter potential of the element to be driven. Therefore, for elements whose emitters are connected in common with the emitters of other elements, the reference potentials of the respective drive units are equal, so a common insulated power supply having this reference potential should be used as the power supply for each drive circuit. Can do.

  For example, in FIG. 1, since the semiconductor switching elements 11, 11, and 11 in the AC switches 10RP, 10SP, and 10TP are all connected to each other and have the same potential, these three switching elements 11, 11, and 11 are connected. Can be driven by one drive unit 60. The drive unit 60 includes drive circuits 61, 62, 63 and a first insulated power supply 64, and a PWM signal is input to the terminal P from an external control circuit.

That is, the drive circuits 61, 62, and 63 in the drive unit 60 drive the switching element 11 in the AC switch 10RP, the switching element 11 in the AC switch 10SP, and the switching element 11 in the AC switch 10TP, respectively. An emitter common to three elements is connected to the circuits 61, 62, and 63 to obtain a reference potential. These emitters are also connected to an insulated power source 64, and power is supplied from the insulated power source 64 to the drive circuits 61, 62, 63. Note that the gates of the switching elements 11, 11, and 11 are also connected to the drive circuits 61, 62, and 63, respectively.
As a result, the prior art shown in FIG. 5 requires separate insulated power supplies for each drive circuit. In the present embodiment, the number of the insulated power supplies 64 can be reduced by reducing the number of drive units. And the cost of the apparatus can be reduced.

Similarly, since the switching elements 14, 14, 14 in the AC switches 10 RN, 10 SN, 10 TN have the same emitter potential, the second insulated power source 97 in the drive unit 90 is made common to each drive circuit 91, 92, The power can be supplied to 93 to drive each switching element 14, 14, 14.
Further, the switching element 12 in the AC switch 10RP, the switching element 13 in the AC switch 10RN, the switching element 12 in the AC switch 10SP, the switching element 13 in the AC switch 10SN, the switching element 12 in the AC switch 10TP, and the AC switch 10TN. Since the emitter potentials of the switching elements 13 are also equal to each other, the third insulated power supply 73 in the drive unit 70 can be shared to supply power to the drive circuits 72 and 71 to drive the switching elements. it can.

On the other hand, on the PWM inverter 2 side, since the emitter potentials of the switching elements 20UN, 20VN, and 20WN of the lower arm are equal, the second insulated power source 97 in the drive unit 90 is shared to supply power to the drive circuits 94, 95, and 96. Can be supplied.
Therefore, the same insulated power source 97 is used for the switching elements 14, 14, 14 in the AC switches 10RN, 10SN, 10T in the lower arm of the PWM rectifier 1A and the switching elements 20UN, 20VN, 20WN in the lower arm of the PWM inverter 2. Can be driven.

  As described above, in the prior art shown in FIG. 5, a separate insulated power supply is required for each drive circuit, so a total of 18 insulated power supplies are required for the entire apparatus. On the other hand, according to this embodiment, the entire apparatus is insulated. The number of power supplies can be reduced to eight (one each of the first and second insulated power supplies 64 and 97, three third insulated power supplies 73, and three insulated power supplies 82 on the inverter 2 side). Can be reduced, and the size of the apparatus can be reduced.

Next, FIG. 2 is a block diagram showing a second embodiment of the present invention. In the PWM rectifier 1B shown in FIG. 2 corresponding to the invention according to claim 3, the upper arms 30RP, 30SP, and 30TP are all the same. The AC switches 30RP, 30SP, 30TP are composed of unidirectional semiconductor switching elements 11, 12 such as IGBTs and diodes 15, 16. That is, the collector of the switching element 11 is connected to the cathode of the diode 15, the anode of the diode 15 is connected to the emitter of the switching element 12, the collector of the switching element 12 is connected to the cathode of the diode 16, and The anode is connected to the emitter of the switching element 11.
Also, the AC switches 30RN, 30SN, and 30TN of the lower arm are configured exactly the same as the AC switches 30RP, 30SP, and 30TP by the unidirectional semiconductor switching elements 13 and 14 and the diodes 17 and 18.
Here, the diodes 15 to 18 are referred to as first to fourth diodes, respectively.

Also in this embodiment, switching elements 11, 11, and 11 in AC switches 30RP, 30SP, and 30TP, switching elements 14, 14, and 14 in AC switches 30RN, 30SN, and 30TN, switching element 12 in AC switch 30RP, and AC A total of five sets, such as a switching element 13 in the switch 30RN, a switching element 12 in the AC switch 30SP and a switching element 13 in the AC switch 30SN, a switching element 12 in the AC switch 30TP and a switching element 13 in the AC switch 30TN. Since the emitter potentials of the switching elements are equal to each other, the insulated power supplies 64, 73, 97 are used in common for the drive circuits 61, 62, 63, 71, 72, 91, 92, 93 as shown in FIG. Can do.
The PWM inverter 2 side is the same as that of the first embodiment, and is common to the drive circuits 91, 92, 93 with respect to the drive circuits 94, 95, 96 of the switching elements 20UN, 20VN, 20WN of the lower arm. An insulated power source 97 can be used.

  As a result, as in the first embodiment, it is possible to reduce the number of insulated power supplies, which is 18 in the prior art, to 8 as the entire apparatus.

Next, FIG. 3 is a block diagram showing a third embodiment of the present invention.
In the PWM rectifier 1C according to the present embodiment, the upper arm AC switches 40RP, 40SP, and 40TP all connect the unidirectional semiconductor switching elements 11, 12 such as IGBTs in series in the reverse direction, and the switching elements 11, 12 are connected in series. The diodes 16 and 15 are connected in antiparallel to each other.
The lower arm AC switches 40RN, 40SN, and 40TN are configured in exactly the same way as the AC switches 40RP, 40SP, and 40TP by the unidirectional semiconductor switching elements 13 and 14 and the diodes 17 and 18.
In this embodiment, for convenience, the diode 16 is a first diode, 15 is a second diode, 17 is a third diode, and 18 is a fourth diode.

Also in the present embodiment, the switching elements 11, 11, and 11 in the AC switches 40RP, 40SP, and 40TP, and the switching elements 14, 14, and 14 in the AC switches 40RN, 40SN, and 40TN, as in the first and second embodiments. , Switching element 12 in AC switch 40RP and switching element 13 in AC switch 40RN, switching element 12 in AC switch 40SP and switching element 13 in AC switch 40SN, switching element 12 in AC switch 40TP and AC switch 40TN Since the emitter potentials of a total of five sets of switching elements are equal to each other, such as the switching elements 13, the insulated power supplies 64, 73, 97 are provided to the drive circuits 61, 62, 63, 71, 72, 91, 92, 93. Use in common It can be.
Further, the PWM inverter 2 side is the same as that of the first and second embodiments, and the drive circuits 91, 92, 93 are connected to the drive circuits 94, 95, 96 of the switching elements 20UN, 20VN, 20WN of the lower arm. A common insulated power source 97 can be used.

  Therefore, as in the first and second embodiments, the number of insulated power supplies, which is 18 in the prior art, can be reduced to 8 as the entire apparatus.

  As described above, in each embodiment, in the power conversion device including two converters, that is, the PWM rectifier and the PWM inverter, a plurality of emitter potentials that are the same in the PWM rectifier and over both the PWM rectifier and the PWM inverter. Since the insulated power supply for the switching element drive circuit is shared, the number of the insulated power supplies can be reduced, thereby simplifying the configuration of some of the drive units, reducing the overall size of the apparatus, and reducing the cost.

It is a block diagram which shows 1st Embodiment of this invention. It is a block diagram which shows 2nd Embodiment of this invention. It is a block diagram which shows 3rd Embodiment of this invention. It is a block diagram which shows a prior art. It is a block diagram which shows another prior art.

Explanation of symbols

1A, 1B, 1C: PWM rectifier 2: PWM inverter 10RP, 10RN, 10SP, 10SN, 10TP, 10TN, 30RP, 30RN, 30SP, 30SN, 30TP, 30TN, 40RP, 40RN, 40SP, 40SN, 40TP, 40TN: AC switch 11, 12, 13, 14: Unidirectional semiconductor switching elements 15, 16, 17, 18: Diodes 20UP, 20UN, 20VP, 20VN, 20WP, 20WN: Semiconductor switching elements 60, 70, 80, 90: Drive units 61, 62 63, 71, 72, 81, 91, 92, 93, 94, 95, 96: drive circuit 64, 73, 82, 97: insulated power supply 200: three-phase AC power supply 300: load

Claims (4)

In a power converter comprising: a rectifier that converts AC power into DC power by a switching operation of an AC switch; and an inverter that converts DC power output from the rectifier into AC power.
All the semiconductor switching elements that constitute the rectifier and whose current outflow side electrode is connected to the negative electrode side of the inverter, and the inverter, and the current outflow electrode thereof is the direct current part A power conversion device, wherein all semiconductor switching elements connected to the negative electrode side are driven using a common insulated power supply. In the power converter device according to claim 1,
The rectifier includes a plurality of first AC switches connected between the AC input phase and the DC unit positive electrode, and a plurality of second AC switches connected between the AC input phase and the DC unit negative electrode, respectively. And comprising
The first AC switch includes first and second semiconductor switching elements connected in antiparallel to each other, and the second AC switch includes third and fourth semiconductor switching elements connected in antiparallel to each other. ,
The plurality of first switching elements are connected by a first insulated power supply having a current potential side electrode of a plurality of first semiconductor switching elements connected to the DC section positive electrode side and a potential on the DC section positive electrode side as a reference potential. The plurality of fourth semiconductor switching elements are driven and connected to the direct current portion negative electrode side, and the plurality of fourth semiconductor switching elements are connected to the direct current portion negative electrode side by a second insulation power source having a potential on the direct current portion negative electrode side as a reference potential. A third insulating power source that drives the switching element 4 and connects the current outflow side electrodes of the second and third semiconductor switching elements to the same AC input phase and uses the potential of the AC input phase as a reference potential. To drive the second and third semiconductor switching elements. In the power converter device according to claim 1,
The rectifier includes a plurality of first AC switches connected between the AC input phase and the DC unit positive electrode, and a plurality of second AC switches connected between the AC input phase and the DC unit negative electrode, respectively. And comprising
The first AC switch includes an anti-parallel connection of a forward series connection circuit of the first semiconductor switching element and the first diode and a forward series circuit of the second semiconductor switching element and the second diode. And configure
The second AC switch connects the forward series connection circuit of the third semiconductor switching element and the third diode and the forward series circuit of the fourth semiconductor switching element and the fourth diode in antiparallel connection. And configure
The plurality of first switching elements are connected by a first insulated power supply having a current potential side electrode of a plurality of first semiconductor switching elements connected to the DC section positive electrode side and a potential on the DC section positive electrode side as a reference potential. The plurality of fourth semiconductor switching elements are driven and connected to the direct current portion negative electrode side, and the plurality of fourth semiconductor switching elements are connected to the direct current portion negative electrode side by a second insulation power source having a potential on the direct current portion negative electrode side as a reference potential. A third insulating power source that drives the switching element 4 and connects the current outflow side electrodes of the second and third semiconductor switching elements to the same AC input phase and uses the potential of the AC input phase as a reference potential. To drive the second and third semiconductor switching elements. In the power converter device according to claim 1,
The rectifier includes a plurality of first AC switches connected between the AC input phase and the DC unit positive electrode, and a plurality of second AC switches connected between the AC input phase and the DC unit negative electrode, respectively. And comprising
The first AC switch includes an anti-parallel circuit of a first semiconductor switching element and a first diode, and an anti-parallel circuit of a second semiconductor switching element and a second diode, and the first , Configured by connecting the cathodes of the second diode,
The second AC switch includes an antiparallel circuit of a third semiconductor switching element and a third diode, and an antiparallel circuit of a fourth semiconductor switching element and a fourth diode, and a third The cathodes of the fourth diodes are connected in series,
The plurality of first switching elements are connected by a first insulated power supply having a current potential side electrode of a plurality of first semiconductor switching elements connected to the DC section positive electrode side and a potential on the DC section positive electrode side as a reference potential. The plurality of fourth semiconductor switching elements are driven and connected to the direct current portion negative electrode side, and the plurality of fourth semiconductor switching elements are connected to the direct current portion negative electrode side by a second insulation power source having a potential on the direct current portion negative electrode side as a reference potential. A third insulating power source that drives the switching element 4 and connects the current outflow side electrodes of the second and third semiconductor switching elements to the same AC input phase and uses the potential of the AC input phase as a reference potential. To drive the second and third semiconductor switching elements.

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