JP2011101456A - Power converter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the size of the overall apparatus and facilitate its maintenance work, by sharing a part of the functions of an inverter circuit and a charge/discharge chopper circuit and enabling both circuits to be switched for operation. <P>SOLUTION: A power converter includes an inverter circuit 24, which has a smoothing capacitor 3 and an inverter bridge 4, a charge/discharge chopper circuit 25 to which a capacitor 16 is connected via changeover switches 23u-23w and a reactor 15 to the AC output terminal of the inverter bridge 4 and which charges/discharges the capacitor 16 by the operation of a semiconductor switching element within the inverter bridge 4; an inverter control circuit 13; and a charge/discharge control circuit 14. The converter switches a function of driving a motor 5 by making the semiconductor switching element operate inside the inverter bridge 4 by the inverter control circuit 13 and a function of charging/discharging the capacitor 16, by making the semiconductor switching element operate inside the inverter bridge 4 by the charge/discharge chopper control circuit 14 by means of a control switching signal. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a power conversion device having both functions of an inverter circuit and a charge / discharge chopper circuit.

  FIG. 2 shows a conventional technology of a power conversion device including an inverter circuit for driving an electric motor and a charge / discharge chopper circuit that charges a power storage device by effectively using regenerative electric power from the electric motor. This prior art is substantially the same as the power conversion device described in Patent Document 1 described later.

  In FIG. 2, 1 is a three-phase AC power source, 2 is a rectifier that converts the AC voltage of the power source 1 into a DC voltage, 3 is a smoothing capacitor that smoothes the DC voltage output from the rectifier 2, and 4 is a smoothed DC voltage. An inverter bridge that converts a three-phase AC voltage having a predetermined magnitude and frequency and supplies the three-phase AC voltage to a three-phase AC motor (hereinafter also simply referred to as an electric motor) 5, and an inverter circuit 20 is configured by these. The inverter bridge 4 is formed by bridge-connecting semiconductor switching elements such as IGBTs having reflux diodes connected in reverse parallel for three phases (6 in total).

  Reference numeral 6 denotes a step-down chopper circuit, and reference numeral 7 denotes a step-up chopper circuit. A series circuit of these chopper circuits 6 and 7 is connected to the smoothing capacitor 3 in parallel. Reference numeral 8 denotes a reactor, and 9 denotes a power storage device including an electrolytic capacitor, an electric double layer capacitor, a battery, and the like. A series circuit of the reactor 8 and the power storage device 9 is connected in parallel to the step-up chopper circuit 7. Here, the chopper circuits 6 and 7 are configured by a semiconductor switching element such as an IGBT in which freewheeling diodes are connected in antiparallel.

Further, 10 is a current detector that detects the DC current of the inverter circuit 20, 11 is a voltage detector that detects a DC intermediate voltage (DC voltage across the smoothing capacitor 3), and 12 is a DC current detection by the current detector 10. This is a chopper control circuit that receives the value and the DC voltage detection value by the voltage detector 11 and controls the chopper circuits 6 and 7 to charge and discharge the power storage device 9.
The step-down chopper circuit 6, the step-up chopper circuit 7, the reactor 8, the chopper control circuit 12, and the like constitute a charge / discharge chopper circuit.

In this prior art, during power running, the inverter bridge 4 performs DC-AC conversion, outputs a three-phase AC voltage, and drives the motor 5.
Further, when the electric motor 5 is used in, for example, a crane facility, and regenerative power flows from the electric motor 5 to the inverter bridge 4 when the crane is lowered, the switching element of the step-down chopper circuit 6 is turned on to generate the regenerative power. The power is supplied to the power storage device 9 and the power storage device 9 is charged.
Further, when the switching element of the boosting chopper circuit 7 is turned on in this state, the discharge current of the power storage device 9 flows to the switching element via the reactor 8. Next, when this switching element is turned off, the energy accumulated in the reactor 8 is supplied to the smoothing capacitor 3 via the freewheeling diode of the step-down chopper circuit 6, so that the smoothing capacitor 3 is charged. The voltage of the smoothing capacitor 3 is supplied to the inverter bridge 4 when the electric motor 5 is driven by a power running operation.

  As described above, according to the prior art of FIG. 2, the electric power stored in the power storage device 9 at the time of regeneration can be supplied to the electric motor 5 via the inverter bridge 4 at the time of power running. Can be obtained.

Japanese Patent Laid-Open No. 10-164862 (paragraphs [0013] to [0025], FIG. 1, FIG. 2, etc.)

  In the prior art shown in FIG. 2, the inverter circuit and the charge / discharge chopper circuit (buck-boost chopper circuit) are provided individually as an inverter device and a charge / discharge chopper device, respectively. However, in applications such as crane facilities that require multiple inverter devices and charge / discharge chopper devices as power conversion devices, the overall size of the device can be reduced, and maintenance work including emergency measures in the event of a failure can be facilitated. It is desired. In addition, since it is necessary to prepare the inverter device and the charge / discharge chopper device separately in preparation for device replacement in the event of a failure, etc., it is possible to reduce the number of spare inverter devices and charge / discharge chopper devices. It is desired. The above prior art in which the inverter device and the charge / discharge chopper device are provided as separate and independent devices cannot meet such a demand.

  Therefore, a problem to be solved by the present invention is that power conversion that can be used as both an inverter device and a charge / discharge chopper device by switching and operating both circuits while partially sharing the components of the inverter circuit and the charge / discharge chopper circuit. It is an object of the present invention to provide a power conversion device that can reduce the size of the entire device, facilitate maintenance work, reduce the number of spare device stocks, and the like.

In order to solve the above-mentioned problem, the invention according to claim 1 converts a DC voltage of a DC intermediate circuit having a smoothing capacitor into an AC voltage by the operation of a semiconductor switching element connected in reverse parallel with a free-wheeling diode. An inverter circuit that supplies a load via an inverter circuit having an inverter bridge in which the semiconductor switching elements are bridge-connected,
An inverter control circuit for operating the inverter circuit;
When the reactor and the power storage device are connected to the AC output terminal of the inverter bridge via the changeover switch, the power storage device is charged and discharged by the operation of the semiconductor switching element in the inverter bridge, and the DC intermediate circuit and the A charge / discharge chopper control circuit for causing the voltage to be stepped up and down with the power storage device,
In response to a control switching signal, the inverter control circuit operates the semiconductor switching element in the inverter bridge to drive the load, and the charge / discharge chopper control circuit operates the semiconductor switching element in the inverter bridge. The function of charging / discharging the power storage device is switched.

The invention according to claim 2 is the power conversion device according to claim 1,
When charging and discharging the power storage device by the charge / discharge chopper control circuit,
Means are provided for commonly connecting the DC intermediate circuit to a DC intermediate circuit of another inverter circuit having another inverter bridge for driving another load.

  In addition, as described in claims 3 to 5, an electrolytic capacitor, an electric double layer capacitor, or a battery can be used for the power storage device.

  According to the present invention, an inverter bridge that constitutes an inverter circuit and a charge / discharge chopper circuit as in the prior art are not independently provided as separate devices, but a function of driving a load with a single device and a power storage device It can be applied to both inverter devices and charge / discharge chopper devices, and the entire device can be downsized, maintenance and inspection work can be facilitated, and maintenance items can be reduced. is there. In particular, the present invention is optimal for applications such as crane facilities that require a plurality of inverter devices and charge / discharge chopper devices.

It is a circuit diagram showing an embodiment of the present invention. It is a circuit diagram which shows a prior art.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a circuit diagram showing this embodiment. Components having the same functions as those in FIG. 2 are denoted by the same reference numerals, description thereof is omitted, and different portions will be mainly described below.

In the power conversion device 100 shown in FIG. 1, a changeover switch 21 that operates according to a control changeover signal is connected between the rectifier 2 and the smoothing capacitor 3. The function of the control switching signal will be described later.
The three-phase phases (U, V, and W phases) on the AC output side of the inverter bridge 4 are connected to the AC motor 5 through changeover switches 23u, 23v, and 23w that are similarly operated by control switching signals. A current detector 17 is provided between the inverter bridge 4 and the changeover switches 23u, 23v, and 23w.

One end of the reactor 15 can be connected to the switching terminals of the changeover switches 23u, 23v, and 23w for each phase, and the power storage device 16 is connected to the other end of these reactors 15. In addition, the electrical storage apparatus 16 consists of an electrolytic capacitor, an electrical double layer capacitor, a battery etc., as described in Claims 3-5.
The change-over switches 23u, 23v, and 23w are all operated simultaneously by the control change signal, and connect the AC output terminal of the inverter bridge 4 and the electric motor 5 during power running to drive the electric motor 5 by the output voltage of the inverter bridge 4, When the charge / discharge chopper operation is performed, the switching operation is performed so that the AC output terminal of the inverter bridge 4 is connected to each end of the reactor 15 and the electric motor 5 is disconnected.

The DC voltage detection value by the voltage detector 11 provided in the DC intermediate circuit of the inverter circuit is input to the inverter control circuit 13 and the charge / discharge chopper control circuit 14 together with the current detection value by the current detector 17. These control circuits 13, 14 generate a drive signal (gate signal) for switching the semiconductor switching element of the inverter bridge 4 using the DC voltage detection value and the current detection value, and use them as switching terminals of the changeover switch 22. Output each.
The changeover switch 22 is also changed over by a control changeover signal, and drive signals for the three-phase upper and lower arms (total of six) output from the common terminal are applied to the semiconductor switching element of the inverter bridge 4.

  In the power converter 100 described above, the inverter circuit 24 is configured by the three-phase AC power source 1, the rectifier 2, the smoothing capacitor 3, and the inverter bridge 4, and the reactor 15 and the power storage device are connected to the switching terminals of the changeover switches 23u, 23v, and 23w. By connecting 16, the inverter bridge 4, the changeover switches 23 u, 23 v, 23 w and the reactor 15 constitute a charge / discharge chopper circuit 25 for charging / discharging the power storage device 16.

On the other hand, 30 is another inverter circuit, which is composed of a three-phase AC power supply 31, a rectifier 32, a smoothing capacitor 33, and an inverter bridge 34, and is a system for driving another electric motor 35. For example, a crane facility or the like often includes a plurality of inverter circuits. Therefore, in this embodiment, it is assumed that there is another inverter circuit 30 in addition to the inverter circuit 24 in the power conversion device 100. Yes.
Here, a switch 41 is provided between the inverter circuit 24 and the inverter circuit 30. When the switch 41 is turned on, the DC intermediate circuits of the inverter circuits 24 and 30 are connected in common. Yes. The switch 41 is turned on when the charge / discharge chopper operation is performed at the same timing as the control switching signal.

Next, the operation of this embodiment will be described.
In the power conversion device 100, when the electric motor 5 is driven by the inverter circuit 24, the selector switches 21, 22, 23u, 23v, 23w and the switch 41 are in the state shown in FIG. 1 and are output from the inverter control circuit 13. By turning on and off the semiconductor switching element of the inverter bridge 4 by the drive signal, a desired AC voltage is applied to the electric motor 5 and functions as an inverter device.

  When the charge / discharge chopper circuit 25 is operated, the selector switches 21, 22, 23u, 23v, and 23w are switched and the switch 41 is turned on. Thus, the drive signal output from the charge / discharge chopper control circuit 14 is applied to the semiconductor switching element of the inverter bridge 4, and the AC output terminal of the inverter bridge 4 is disconnected from the electric motor 5 and connected to the reactor 15. At the same time, the rectifier 2 is disconnected from the DC intermediate circuit of the inverter circuit 24. Further, when the switch 41 is turned on, the DC intermediate circuits of the inverter circuits 24 and 30 are commonly connected.

  In this state, for example, when electric power is regenerated from the electric motor 35 on the inverter circuit 30 side via the inverter bridge 34, the regenerative electric power charges the smoothing capacitor 3 of the inverter circuit 24 in the power converter 100, and the voltage is To rise. At this time, if the semiconductor switching element in the inverter bridge 4 is operated by the drive signal from the charge / discharge chopper control circuit 14 in the same manner as the step-down chopper circuit 6 in FIG. 2, the changeover switches 21, 22, 23u, 23v, 23w The power storage device 16 can be charged via the reactor 15 and functions as a charging chopper device.

Thereafter, when the semiconductor switching element in the inverter bridge 4 is operated in the same manner as the step-up chopper circuit 7 in FIG. 2, the power storage device 16 is connected to the reactor 15, the changeover switches 21, 22, 23 u, 23 v, 23 w and the inverter bridge 4. The smoothing capacitor 3 of the inverter circuit 24 and the smoothing capacitor 33 of the inverter circuit 30 can be charged to a predetermined voltage, and function as a discharge chopper device.
Therefore, the electric power stored in the power storage device 16 during regeneration can be supplied from the smoothing capacitors 3 and 33 of the inverter circuits 24 and 30 to the electric motors 5 and 35 via the inverter bridges 4 and 34 during power running. Effective use is possible.

During the charge / discharge chopper operation described above, the inverter bridge 4 in the inverter circuit 24 in FIG. 1 functions as the chopper circuits 6 and 7 in FIG. 2, and the inverter circuit 30 in FIG. 1 functions as the inverter circuit 20 in FIG. Is equivalent to
Therefore, when paying attention to the power conversion device 100, the inverter bridge 4 has the switching operation at the time of power running in which the inverter circuit 24 drives the electric motor 5, and the charge / discharge chopper circuit 25 charges and discharges the power storage device 16 (DC intermediate circuit and The switching operation at the time of the chopper operation (increasing / decreasing the voltage with the power storage device 16) is performed, and the single inverter bridge 4 performs two functions.

Therefore, according to the present embodiment, the overall size of the device can be reduced as compared with the case where the inverter bridge 4, the step-down chopper circuit 6 and the step-up chopper circuit 7 are provided as separate devices as in the prior art of FIG. And maintenance work can be facilitated.
A voltage detector 11 that detects a DC intermediate voltage necessary for inverter control when driving a load and a current detector 17 that detects an output current are a DC voltage detection value and a current detection value required for charge / discharge chopper control. Therefore, it can be applied to both the inverter device and the charge / discharge chopper device without newly adding a voltage detector and a current detector.
Further, since it has a function of driving a load with a single device and a function of charging / discharging a power storage device, it can be applied to both an inverter device and a charge / discharge chopper device. Therefore, a spare inverter device and a charge / discharge chopper It becomes possible to reduce the stock number of the apparatus.

  In the above-described embodiment, the inverter circuits 24 and 30 and the AC motors 5 and 35 are all described as having a three-phase configuration, but these may have a single-phase configuration. Further, the DC input voltage of the inverter circuits 24 and 30 may be obtained directly from the DC power source as well as the combination of the AC power source and the rectifier.

DESCRIPTION OF SYMBOLS 1,31: Three-phase alternating current power supply 2,32: Rectifier 3,33: Smoothing capacitor 4,34: Inverter bridge 5,35: AC motor 11: Voltage detector 13: Inverter control circuit 14: Charging / discharging chopper control circuit 15: Reactor 16: Power storage device 17: Current detector 21, 22, 23u, 23v, 23w: Changeover switch 24, 30: Inverter circuit 25: Charge / discharge chopper circuit 41: Switch 100: Power converter

Claims (5)

An inverter circuit that converts a DC voltage of a DC intermediate circuit including a smoothing capacitor into an AC voltage by an operation of a semiconductor switching element connected in reverse parallel with a freewheeling diode, and supplies the AC voltage to a load via a changeover switch. An inverter circuit having an inverter bridge in which switching elements are bridge-connected;
An inverter control circuit for operating the inverter circuit;
When the reactor and the power storage device are connected to the AC output terminal of the inverter bridge via the changeover switch, the power storage device is charged and discharged by the operation of the semiconductor switching element in the inverter bridge, and the DC intermediate circuit and the A charge / discharge chopper control circuit for causing the voltage to be stepped up and down with the power storage device,
In response to a control switching signal, the inverter control circuit operates the semiconductor switching element in the inverter bridge to drive the load, and the charge / discharge chopper control circuit operates the semiconductor switching element in the inverter bridge. A power conversion device that switches between a function of charging and discharging a power storage device. In the power converter device according to claim 1,
When charging and discharging the power storage device by the charge / discharge chopper control circuit,
A power converter comprising: means for commonly connecting the DC intermediate circuit to a DC intermediate circuit of another inverter circuit having another inverter bridge for driving another load. In the power converter device according to claim 1 or 2,
The power storage device, wherein the power storage device is an electrolytic capacitor. In the power converter device according to claim 1 or 2,
The power storage device is an electric double layer capacitor. In the power converter device according to claim 1 or 2,
The power storage device, wherein the power storage device is a battery.

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