JP2013192407A - Power conversion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power conversion device that allows protecting against an overvoltage and an overcurrent at the time of abnormality of an inverter by a simplified circuit configuration and a simplified logic.SOLUTION: An inverter 20 generates an AC voltage for driving a permanent magnet type synchronous motor 21 by using a DC voltage outputted from a battery 24. A protective discharge circuit 10 is configured by parallely connecting a protective discharge resistor 11 and a protective discharge switching element 12, and is interposed between the battery 24 and the inverter 20. A protective operation determination section 13 turns OFF the protective discharge switching element 12 and connects the battery 24 and the inverter 20 via the protective discharge resistor 11, as a protective operation that turns OFF all the switching elements of the inverter 20 is performed.

Description

  The present invention relates to a power conversion device that generates AC power for driving a load such as a synchronous motor based on DC power obtained from a DC power source such as a battery, and more particularly to a permanent magnet type synchronization used as a power source for an electric vehicle or the like. The present invention relates to a power conversion device suitable for driving an electric motor.

  Permanent magnet type synchronous motors have the advantage of higher efficiency in a low speed and low torque range than induction motors. For this reason, the permanent magnet type synchronous motor is expected as a power source of an electric vehicle, and its development is being advanced.

  On the other hand, in a permanent magnet type synchronous motor, a field magnetic flux is generated by a permanent magnet. Therefore, the field magnetic flux is always constant, and the induced electromotive force generated by the electric motor is proportional to the rotational speed. Therefore, in the high-speed rotation region, the induced electromotive force generated by the electric motor becomes high, and when the induced electromotive force reaches the upper limit value determined by the power supply voltage, the current for obtaining the required output from the electric motor cannot be supplied to the electric motor. Therefore, in the high-speed rotation region, so-called weak magnetic flux control is often performed in which a negative d-axis current is caused to flow through the motor to generate a demagnetizing effect due to the d-axis armature reaction and to reduce the magnetic flux in the d-axis direction.

  By the way, while an electric vehicle (for example, an electric vehicle) is traveling at a high speed, a protective operation of an inverter that drives a permanent magnet type synchronous motor that is a power source of the electric vehicle may be performed for some reason. In such a case, since a normal negative d-axis current is not supplied from the inverter to the motor, the motor does not perform the flux-weakening control, the motor generates a high induced electromotive force, and this high induced electromotive force is generated from the terminal of the motor. Output to the inverter side. As a result, an overvoltage is applied to the DC capacitor for smoothing the input voltage applied from the battery to the inverter, or the battery is charged with an excessive current.

  FIG. 7 is a block diagram showing a configuration of a conventional power conversion apparatus that solves such a problem. This power converter includes a battery 24 that is a DC power source, an initial charging circuit 25, an inverter 20 that drives a permanent magnet type synchronous motor 21, a control device 22 that controls the inverter 20, a discharge transistor 32, and a discharge resistor. And a determination circuit 33 for switching the discharge transistor 32 on and off.

  In this power converter, during normal operation, the initial charging circuit 25 is ON and the discharge transistor 32 is OFF, and the capacitor 26 is charged with the output voltage of the battery 24 as a DC intermediate voltage. The inverter 20 is a means for converting the DC intermediate voltage charged in the capacitor 26 into a three-phase AC voltage for driving the permanent magnet type synchronous motor 21. The inverter 20 is a bridge circuit configured using six sets of IGBTs (Insulated Gate Bipolar Transistors) and flywheel diodes, as in the case of known inverters. The control device 22 is a device that generates a gate drive signal for performing ON / OFF switching of each IGBT of the inverter 20.

  The determination circuit 33 constantly monitors the DC intermediate voltage of the capacitor 26. Here, for example, when excessive power is regenerated from the permanent magnet type synchronous motor 21 to the battery 24 side via the inverter 20 and the DC voltage of the capacitor 26 exceeds a predetermined threshold value, the determination circuit 33 turns on the discharge transistor 32. The charge of the capacitor 26 is discharged through the discharge resistor 31 and the discharge transistor 32, and the DC intermediate voltage is lowered.

  FIG. 8 is a block diagram showing the configuration of another power conversion apparatus that has solved the above problem. This power converter is disclosed in Patent Document 1. Compared with the power converter shown in FIG. 7, the power converter shown in FIG. 8 does not include the dynamic brake circuit including the discharge transistor 32 and the discharge resistor 31 and the determination circuit 33. Instead, in the power conversion device shown in FIG. 8, a determination circuit 42 and a relay control circuit 43 are added, and a current sensor 41 is connected to a DC bus between the initial charging circuit 25, the capacitor 26, and the inverter 20. Is attached. The other points are the same as those of the power converter shown in FIG.

  In the power conversion device shown in FIG. 8, the determination circuit 42 detects the current flowing through the DC bus by the current sensor 41. The control device 22 monitors the current flowing through the DC bus via the determination circuit 42 and the current sensor 41, and based on the monitoring result, excessive power is transferred from the permanent magnet type synchronous motor 21 to the battery 24 via the inverter 20. When the regeneration is detected, the relay control circuit 43 turns off the high-power relay of the initial charging circuit 25 to prevent an excessive regenerative current from flowing through the battery 24. At the same time, the control device 22 turns on some of the IGBTs of the inverter 20, absorbs the induced electromotive force output from the electric motor 21, and protects the capacitor 26 from overvoltage.

JP 2002-17098 A

  By the way, in the above-described power conversion device of FIG. 7, when the protection operation of the inverter 20 is performed for some reason and all the IGBTs of the inverter 20 are turned off, the discharge occurs if the DC intermediate voltage of the capacitor 26 exceeds the threshold value. It is possible to prevent the overvoltage from being applied to the capacitor 26 due to the regenerative power from the electric motor 21 when the transistor 32 is turned on.

However, in the power conversion device shown in FIG. 7, unless the high power relay of the initial charging circuit 25 is turned off, the direct current intermediate voltage of the capacitor 26 is clamped by the battery 24 to prevent the direct current intermediate voltage from rising. Overvoltage protection is not performed.

  On the other hand, when the high-voltage relay of the initial charging circuit 25 remains ON, when the protective operation of the inverter 20 is performed, the induced electromotive force generated by the permanent magnet type synchronous motor 21 is transferred to the battery 24 via the flywheel diode of the inverter 20. And the battery 24 is charged. For this reason, the following problems occur.

  FIG. 9 is a waveform diagram for explaining a problem that occurs with the protection operation of the inverter 20. When the protection operation of the inverter 20 is performed and all the IGBTs of the inverter 20 are turned off, a large regeneration is performed from the permanent magnet type synchronous motor 21 to the battery 24 side via the flywheel diode of the inverter 20 when the voltage of the battery 24 is low. Current flows. As a result, a large torque in the direction opposite to the rotation direction, that is, a large braking force is generated at the shaft end of the electric motor 21.

  On the other hand, in the case of the power conversion device of FIG. 8 described above, if the high power relay of the initial charging circuit 25 can be turned off when the control device 22 detects a large regenerative current, it prevents the large regenerative current from flowing, A large braking force can be prevented from being generated in the electric motor 21. However, many high voltage relays are difficult to turn off after a large current starts flowing. In addition, there is a high-power relay that can be turned off even after a large current starts to flow, but such a high-performance high-power relay is expensive.

  Further, in the power conversion device of FIG. 8, the following problem occurs when the protection operation of the inverter 20 is performed. FIG. 10 is a waveform diagram for explaining a problem that occurs with the protection operation of the inverter 20. When the high power relay of the initial charging circuit 25 is turned off in the power conversion device shown in FIG. 8, the inductive energy accumulated in the inductive load such as the winding of the electric motor 21 is released and the capacitor 26 is charged. However, generally, the main circuit capacitor (corresponding to the capacitor 26 in FIG. 8) of the inverter for an electric vehicle has a low capacitance value. Therefore, when the induced energy released from the electric motor 21 is charged, this charging exceeds the withstand voltage of the capacitor 26. There is a risk that an overvoltage is applied to the capacitor 26.

  In order to avoid such a risk, Patent Document 1 proposes to turn on a part of the IGBTs of the inverter 20 to absorb inductive energy when the high-power relay is turned off. However, in order to realize this scheme, a complicated logic circuit is required for switching the inverter 20 from the protection operation state to the absorption operation state in which some IGBTs are turned on.

  The present invention has been made in view of the circumstances described above, and an object thereof is to provide a power conversion device capable of protecting against overvoltage and overcurrent when an inverter abnormality occurs with a simple circuit configuration. It is said.

  In this invention, a DC power source that outputs a DC voltage, an inverter that generates an AC voltage for driving an electric motor using the DC voltage output from the DC power source, a protective discharge resistor and a protective discharge switching element are connected in parallel. And a protective discharge circuit in which each of the protective discharge resistor and the protective discharge switching element is inserted in parallel between the DC power source and the inverter. .

  According to the present invention, for example, when the protective operation of the inverter is performed for some reason, the direct current power source and the inverter can be connected via the protective discharge resistor by turning off the protective discharge switching element. In this case, even if the regenerative current from the electric motor is supplied to the DC power supply side, the DC input voltage applied to the inverter is restricted by the output voltage of the DC power supply, and excessive increase is prevented. In addition, since there is a protective discharge resistance in the path of the regenerative current from the motor to the DC power supply, it is possible to prevent an excessive regenerative current from flowing and a large braking force from being generated in the motor. Further, since the regenerative power from the electric motor is consumed by the protective discharge resistance, the regenerative current can be suppressed.

It is a block diagram which shows the structure of the power converter device which is one Embodiment of this invention. It is a figure which shows the state at the time of normal operation | movement of the power converter device. It is a figure which shows the state at the time of the protection operation | movement of the power converter device. It is a wave form diagram which shows the 1st example of the waveform of each part at the time of protection operation | movement being performed in the same power converter device. It is a wave form diagram which shows the 2nd example of the waveform of each part at the time of protection operation | movement being performed in the same power converter device. It is a block diagram which shows the structural example of the protection operation judgment part of the same power converter device. It is a block diagram which shows the 1st structural example of the conventional power converter device. It is a block diagram which shows the 2nd structural example of the conventional power converter device. It is a wave form diagram which shows the waveform of each part at the time of protection operation | movement being performed in the 1st structural example of the conventional power converter device. It is a wave form diagram which shows the waveform of each part at the time of protection operation | movement being performed in the 2nd structural example of the conventional power converter device.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing a configuration of a power conversion apparatus according to an embodiment of the present invention. In this power converter, the main circuit includes a battery 24 that is a DC power source, an initial charging circuit 25, an inverter 20 that drives the permanent magnet type synchronous motor 21, a capacitor 26 that is connected in parallel to the inverter 20, The protective charging circuit 10 is inserted in the middle of the DC bus between the initial charging circuit 25 and the inverter 20. The protective discharge circuit 10 is formed by connecting a protective discharge resistor 11 and a protective discharge switching element 12 in parallel. In the example shown in FIG. 1, the protective discharge switching element 12 includes an IGBT 12A and a diode 12B connected in parallel to each other. The IGBT 12A has a collector connected to the inverter 20 and an emitter connected to the initial charging circuit 25. The diode 12B has an anode connected to the initial charging circuit 25 and a cathode connected to the inverter 20.

  The inverter 20 is a means for converting the DC intermediate voltage charged in the capacitor 26 into a three-phase AC voltage for driving the permanent magnet type synchronous motor 21, and, like a known inverter, a switching element such as an IGBT and a flywheel. This is a bridge circuit configured using six sets of diodes. The control device 22 is a device that generates a gate drive signal for performing ON / OFF switching of each switching element of the inverter 20 according to a predetermined control procedure. The control device 22 monitors the operation of the inverter 20 by the function of software, and when an abnormality in the operation of the inverter 20 is detected, the control device 22 performs a protective operation to turn off all the switching elements of the inverter 20. The permanent magnet type synchronous motor 21 is protected and a protection signal is output to the protection operation determination unit 13.

  The protection circuit 23 monitors the output voltage and output current of the inverter 20 via hardware (not shown), and when the abnormality of the output voltage or output current of the inverter 20 is detected, the control device 22 controls all switching of the inverter 20. The element is turned off to protect the inverter 20 and the permanent magnet type synchronous motor 21 and output a protection signal to the protection operation determination unit 13. In addition, the protection circuit 23 can safely stop the inverter 20 and the permanent magnet type synchronous motor 21 when the normal operation of the control device 22 becomes impossible.

  The protection operation determination unit 13 is means for performing ON / OFF control of the protection discharge switching element 12 in accordance with a protection signal output from the control device 22 or a protection signal output from the protection circuit 23.

  Next, the operation of this embodiment will be described. During normal operation, the protection operation determination unit 13 turns on the protection discharge switching element 12. In this case, as shown in FIG. 2, in a driving state where the permanent magnet type synchronous motor 21 operates as a motor, current flows from the battery 24 side to the inverter 20 side via the diode 12B, and the permanent magnet type synchronous motor 21 generates power. In the regenerative state that operates as a machine, current flows from the inverter 20 side to the battery 24 side via the IGBT 12A.

  When some abnormality occurs, for example, when the control device 22 detects this abnormality by the function of software, the control device 22 supplies the inverter 20 with a gate drive signal for turning off all the switching elements of the inverter 20. At the same time, the control device 22 outputs a protection signal to the protection operation determination unit 13.

  Accordingly, the protection operation determination unit 13 outputs a protection operation command signal for turning off the IGBT 12A of the protection discharge circuit 10. As a result, the state of the power conversion device is as shown in FIG. 3, and the regenerative current supplied from the permanent magnet type synchronous motor 21 via the inverter 20 flows to the battery 24 via the protective discharge resistor 11. In this state, since the capacitor 26 is connected to the battery 24 via the protective discharge resistor 11, the DC intermediate voltage of the capacitor 26 is restricted by the output voltage of the battery 24, and excessive increase is prevented.

  FIG. 4 is a waveform diagram illustrating the waveform of the phase current of the inverter 20 and the DC intermediate voltage of the capacitor 26 during the operation described above. As shown in this figure, in this embodiment, when the protective operation of the inverter 20 is performed, the direct current intermediate voltage of the capacitor 26 is almost clamped to the output voltage of the battery 24, and an excessive increase can be prevented.

  On the other hand, for example, when the permanent magnet type synchronous motor 21 is rotating at high speed, it is assumed that a protective operation for turning off all the switching elements of the inverter 20 is performed. Also in this case, the IGBT 12A of the protective discharge circuit 10 is turned off as the protective operation of the inverter 20 is performed. In this case, a high induced electromotive force proportional to the rotation speed is output from the permanent magnet type synchronous motor 21 and charged to the battery 24 via the full bridge rectifier circuit constituted by the diode of the inverter 20 and the protective discharge resistor 11. At this time, the protective discharge resistor 11 is provided in the path of the regenerative current from the permanent magnet type synchronous motor 21. Since this protective discharge resistor 11 consumes the power regenerated from the permanent magnet type synchronous motor 21, the regenerative current is greatly increased. It is possible to suppress the occurrence of a large brake.

  FIG. 5 is a waveform diagram illustrating the waveform of the phase current of the inverter 20 and the direct current intermediate voltage of the capacitor 26 during the protection operation described above. As shown in this figure, in this embodiment, when the protective operation of the inverter 20 is performed, an excessive increase in the DC intermediate voltage of the capacitor 26 can be prevented, and the regenerative current is suppressed and a large brake is applied. Torque can be prevented from being generated.

  The characteristic operation of this embodiment has been described above by taking as an example the case where the control device 22 outputs a protection signal by the function of software. However, in this embodiment, the protection circuit 23 monitors the output voltage and output current of the inverter 20 by the function of hardware, and when an abnormality in the output voltage or output current is detected, all the switching elements of the inverter 20 are detected. And a protection signal is output to the protection operation determination unit 13. Also in this case, the protection operation determination unit 13 turns off the IGBT 12 </ b> A of the protection discharge switching element 12 and connects the battery 24 and the inverter 20 via the protection discharge resistor 11.

  FIG. 6 is a block diagram illustrating a configuration example of the protection operation determination unit 13 in the present embodiment. As illustrated in FIG. 6, the protection operation determination unit 13 includes a pulse operation detection unit 131, a timer 132, and a logical operation circuit 133.

  The pulse operation detector 131 is supplied with the same six-phase gate drive signal as that supplied to the inverter 20 by the controller 22. This six-phase gate drive signal is a pulse width modulation signal generated in the control device 22 based on a drive voltage command value or the like. When the inverter 20 is operating normally, the level inversion of one of the gate drive signals always occurs within a certain time interval shorter than the carrier period of pulse width modulation. If all the six-phase gate drive signals are not inverted in level within a certain time interval, it is considered that either the inverter 20 is stopped or the inverter 20 is protected. Therefore, the pulse operation detection unit 131 monitors the six-phase gate drive signals output from the control device 22, and outputs a protection signal when all the six-phase gate drive signals are not level-inverted within a certain time interval. . In a preferred embodiment, the fixed time interval used for determining whether or not to output the protection signal is set from the control device 22 to the pulse operation detector 131.

  The timer 132 outputs a protection signal to the logic operation circuit 133 when a preset time has elapsed after the protection signal is output from the pulse operation detector 131. The logical operation circuit 133 performs an OR operation on the protection signal output from the control device 22 according to the software, the protection signal output from the protection circuit 23 by the operation of the hardware, and the protection signal output from the timer 132. When the signal is given, a protection operation command signal for turning off the IGBT 12A of the protection discharge switching element 12 is output.

  The time measured by the timer 132 can be freely set. After the pulse operation detection unit 131 outputs the protection signal, an appropriate clocking is performed so that the protection operation command signal is output from the logic operation circuit 133 at an appropriate timing when the regenerative current from the permanent magnet type synchronous motor 21 starts to increase. The time may be set in the timer 132. If it is preferable to output the protection operation command signal immediately after the pulse operation detection unit 131 outputs the protection signal, the timer 132 may be omitted.

  According to the present embodiment, since such a protection operation determination unit 13 is provided, for example, even if the control device 22 stops for some reason, the level inversion of the gate drive signal is stopped, the output voltage or output current of the inverter When the abnormality is detected, the protective discharge switching element 12 can be turned off to protect the entire power converter.

<Other embodiments>
Although one embodiment of the present invention has been described above, other embodiments can be considered in addition to this. For example:

(1) In the above embodiment, the protective discharge switching element 12 is configured by the IGBT 12A and the diode 12B, but other power semiconductor elements, semiconductor relays, or mechanical relays may be used instead of the IGBT 12A.

(2) In the above embodiment, when the protection operation of the inverter 20 is performed, it is not necessary to limit the current supplied from the battery 24 side to the inverter 20 side, and therefore only the current flowing from the inverter 20 side to the battery 24 side. A diode 12B is used to prevent this. However, instead of the diode 12B, a transistor capable of ON / OFF switching may be used, and the protection operation determination unit 13 may turn off both the IGBT 12A and this transistor in response to the generation of the protection signal.

(3) In the above embodiment, the protective discharge circuit 10 is provided between the positive electrode of the battery 24 and the high-potential side power supply node of the inverter 20, but between the low-potential side power supply node of the inverter 20 and the negative electrode of the battery 24. May be provided.

(4) In the above embodiment, the present invention is applied to a power converter that drives a permanent magnet type synchronous motor as an example in which a particularly remarkable effect is obtained. However, the present invention is a power converter that drives other types of motors. It is also applicable to.

24 ...... Battery, 20 ... Inverter, 26 ... Capacitor, 21 ... Permanent magnet synchronous motor, 22 ... Control device, 23 ... Protection circuit, 13 ... Protection operation determination unit, 25 ... Initial charging circuit DESCRIPTION OF SYMBOLS 10 ... Protection discharge circuit, 11 ... Protection discharge resistance, 12 ... Protection discharge switching element, 12A ... IGBT, 12B ... Diode, 131 ... Pulse operation detection part, 132 ... Timer, 133 ... Logic Arithmetic circuit.

Claims (8)

DC power supply that outputs DC voltage;
An inverter that generates an AC voltage for driving an electric motor using a DC voltage output from the DC power supply;
A protective discharge circuit in which a protective discharge resistor and a protective discharge switching element are connected in parallel, and each of the protective discharge resistor and the protective discharge switching element is interposed in parallel between the DC power supply and the inverter; A power converter characterized by comprising.   As the protective operation for protecting the inverter from overvoltage or overcurrent due to regenerative power generated by the electric motor is performed, the protective discharge switching element is turned OFF, and the DC power supply and the inverter are connected to the protective discharge resistor. The power conversion device according to claim 1, further comprising a protection operation determination unit connected through the power conversion device. The protective discharge switching element includes a diode for passing a current supplied from the DC power source to the inverter when the electric motor is in a driving state, and the inverter to the DC power source when the electric motor is in a regenerative state. It is formed by connecting in parallel with a power semiconductor switching element that flows current supplied to the
The protection operation determination unit turns off the power semiconductor switching element in the protection discharge switching element as a protection operation for protecting the inverter from overvoltage or overcurrent due to regenerative power generated by the electric motor is performed. The power converter according to claim 2, wherein the DC power source and the inverter are connected via the protective discharge resistor.   In the protection operation of the inverter, an operation of turning off all the switching elements of the inverter is performed, and the protection operation determining unit performs the operation of turning off all of the switching elements of the inverter. 4. The power conversion device according to claim 2, wherein a discharge switching element is turned off, and the DC power supply and the inverter are connected via the protective discharge resistor. 5.   The protection operation determination unit turns off the protection discharge switching element at the same time when all the switching elements of the inverter are turned off, and connects the DC power source and the inverter via the protection discharge resistor. The power converter according to claim 4, wherein   The protection operation determination unit turns off the protection discharge switching element after a predetermined time has elapsed since all the switching elements of the inverter are turned off, and connects the DC power source and the inverter via the protection discharge resistor. The power conversion device according to claim 4, wherein: A control device having means for outputting a gate drive signal for performing ON / OFF control of each switching element of the inverter and means for turning off all the switching elements of the inverter and outputting a first protection signal;
A protection circuit that outputs a second protection signal when an abnormality in the output current or output voltage of the inverter is detected;
The protection operation determination unit monitors the gate drive signal output from the control device with respect to the inverter, and generates a third protection signal when the level inversion of the gate drive signal does not occur for a predetermined time or more. 5. The power converter according to claim 4, wherein the protective discharge switching element is turned off when any of the first to third protection signals is generated.   The protection operation determination unit includes a timer that outputs the third protection signal after a predetermined time has elapsed after detecting that the level inversion of the gate drive signal does not occur for a predetermined time or more. The power conversion device according to claim 7.

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