JPWO2019049449A1 - Power converter, motor module and electric power steering device - Google Patents

Abstract

The power converter is connected to the other end of the winding of an n-phase (n is an integer of 3 or more) motor, one end of which is Y-connected, and each has n legs including a low-side switch element and a high-side switch element. A first-phase separation relay circuit that switches the connection / disconnection of the inverter, the power supply, and the n-phase winding via the inverter for each phase, and at least one connected in parallel with the n legs of the inverter. A sub-inverter having a leg and connected to the other end of the n-phase winding, a second-phase separation relay circuit for switching between connection and non-connection of the power supply and the n-phase winding via the sub-inverter, and To be equipped with.

Description

The present disclosure relates to power converters, motor modules and electric power steering devices.

In recent years, an electric motor (hereinafter, simply referred to as "motor"), a power conversion device, and an electromechanical integrated motor in which an ECU is integrated have been developed. Especially in the in-vehicle field, high quality assurance is required from the viewpoint of safety. Therefore, a redundant design is adopted that can continue safe operation even if a part of the parts breaks down. As an example of the redundant design, it is considered to provide two power conversion devices for one motor. As another example, it is considered to provide a backup microcontroller as the main microcontroller.

Patent Document 1 discloses a motor drive device having a first system and a second system. The first system is connected to the first winding set of the motor and has a first inverter unit, a power supply relay, a reverse connection protection relay, and the like. The second system is connected to the second winding set of the motor and has a second inverter unit, a power supply relay, a reverse connection protection relay, and the like. When the motor driving device has not failed, it is possible to drive the motor using both the first system and the second system. On the other hand, when a failure occurs in one of the first system and the second system, or one of the first winding group and the second winding group, the power relay is released from the power supply to the failed system or the failed winding. Cut off the power supply to the grid connected to the wire set. It is possible to continue the motor drive using the other system that has not failed.

Patent Documents 2 and 3 also disclose a motor drive device having a first system and a second system. Even if one system or one winding set fails, the motor drive can be continued by the system that has not failed.

Patent Document 4 discloses a motor drive device having four electrical separation means and two inverters and converting electric power supplied to a three-phase motor. For one inverter, one electrical separation means is provided between the power supply and the inverter, and one electrical separation means is provided between the inverter and the GND. It is possible to drive the motor by a non-failed inverter using the neutral point of the winding in the failed inverter. At that time, the failed inverter is separated from the power supply and the GND by shutting off the two electrical separation means connected to the failed inverter.

Japanese Unexamined Patent Publication No. 2016-34204 Japanese Unexamined Patent Publication No. 2016-32977 Japanese Unexamined Patent Publication No. 2008-132919 Japanese Patent No. 5797751

In the above-mentioned conventional technique, further improvement of the motor output in the control at the time of abnormality has been required.

The embodiments of the present disclosure provide a power conversion device capable of improving the motor output in control at the time of abnormality.

The exemplary power conversion device of the present disclosure is a power conversion device that converts power from a power source into power supplied to a motor having n-phase (n is an integer of 3 or more) windings in which one ends are Y-connected. The inverter having n legs connected to the other end of the n-phase winding and each containing a low-side switch element and a high-side switch element, and the power supply and the n-phase winding. A sub-inverter having a first-phase separation relay circuit that switches connection / non-connection via an inverter for each phase and at least one leg connected in parallel with the n-legs of the inverter. A sub-inverter connected to the other end of the winding of the above, and a second-phase separation relay circuit for switching between connection and non-connection of the power supply and the n-phase winding via the sub-inverter.

According to an exemplary embodiment of the present disclosure, n-phase energization control (typically, by appropriately determining the on / off state of the first phase separation relay circuit and the second phase separation relay circuit according to the control mode. Three-phase energization control) can be continuously performed. As a result, a power conversion device capable of improving the motor output in control at the time of abnormality, a motor module including the power conversion device, and an electric power steering device including the motor module are provided.

FIG. 1 is a block diagram showing a typical block configuration of the motor module 1000 according to the exemplary embodiment 1. FIG. 2 is a circuit diagram showing a circuit configuration of the power conversion device 100 according to the exemplary embodiment 1. FIG. 3 is a schematic view showing the configuration of the bidirectional switch SW_2W. FIG. 4 is a block diagram showing a typical block configuration of the control circuit 300. FIG. 5 is a graph illustrating a current waveform (sine wave) obtained by plotting the current values flowing through the windings M1, M2, and M3 according to the three-phase energization control. FIG. 6 is a graph showing the relationship between the rotation speed (rps) per unit time of the motor and the torque T (Nm). FIG. 7 is a circuit diagram showing a circuit configuration of the power conversion device 100A according to the second embodiment. FIG. 8 is a schematic view showing a typical configuration of the electric power steering device 2000 according to the exemplary embodiment 3.

Hereinafter, embodiments of the power conversion device, the motor module, and the electric power steering device of the present disclosure will be described in detail with reference to the accompanying drawings. However, in order to avoid unnecessarily redundant explanations below and facilitate understanding by those skilled in the art, unnecessarily detailed explanations may be omitted. For example, detailed explanations of already well-known matters and duplicate explanations for substantially the same configuration may be omitted.

In the present specification, the present disclosure is carried out by exemplifying a power conversion device that converts power from a power source into power supplied to a three-phase motor having three-phase (U-phase, V-phase, W-phase) windings. The form will be described. However, a power conversion device that converts power from a power source into power supplied to an n-phase motor having n-phase (n is an integer of 4 or more) windings such as four-phase or five-phase is also within the scope of the present disclosure. ..

(Embodiment 1)

[Structure of motor module 1000 and power converter 100]

FIG. 1 schematically shows a typical block configuration of the motor module 1000 according to the present embodiment.

The motor module 1000 typically includes a power converter 100, a motor 200, a control circuit 300 and an angle sensor 500. Depending on the motor control method (for example, sensorless control), the angle sensor 500 may not be necessary.

The motor module 1000 can be modularized and manufactured and sold, for example, as an electromechanical integrated motor having a motor, sensors, drivers and controllers. Further, a system for driving a motor, which can include components other than the motor among the components of the motor module, can be called a "motor drive system". The motor drive system can also be modularized, manufactured and sold.

The power conversion device 100 includes an inverter 110, a sub-inverter 120, a first phase separation relay circuit 130, a second phase separation relay circuit 140, and a current sensor 400. The power conversion device 100 can convert the power from the power supply 101 (see FIG. 2) into the power supplied to the motor 200. The inverter 110 is connected to the motor 200. For example, the inverter 110 can convert DC power into three-phase AC power, which is a pseudo sine wave of U-phase, V-phase, and W-phase. In the present specification, the "connection" between parts (components) mainly means an electrical connection.

The motor 200 is, for example, a three-phase AC motor. The motor 200 has a U-phase winding M1, a V-phase winding M2, and a W-phase winding M3. One ends of the windings M1, M2 and M3 are Y-connected.

The control circuit 300 is composed of a microcontroller and the like. The control circuit 300 controls the power conversion device 100 based on the input signals from the current sensor 400 and the angle sensor 500. The control method includes, for example, vector control, pulse width modulation (PWM) or direct torque control (DTC).

The angle sensor 500 is, for example, a resolver or a Hall IC. The angle sensor 500 is also realized by a combination of an MR sensor having a magnetoresistive (MR) element and a sensor magnet. The angle sensor 500 detects the rotation angle of the rotor of the motor 200 (hereinafter, referred to as “rotation signal”) and outputs the rotation signal to the control circuit 300.

A specific circuit configuration of the power conversion device 100 will be described with reference to FIG.

FIG. 2 schematically shows the circuit configuration of the power conversion device 100 according to the present embodiment.

The power supply 101 generates a predetermined power supply voltage (for example, 12V). As the power source 101, for example, a DC power source is used. However, the power supply 101 may be an AC-DC converter or a DC-DC converter, or may be a battery (storage battery).

The fuse 102 is connected between the power supply 101 and the inverter 110. The fuse 102 can cut off a large current that can flow from the power supply 101 to the inverter 110 or the sub-inverter 120. A relay or the like may be used instead of the fuse.

Although not shown, a coil is provided between the power supply 101 and the inverter 110. The coil functions as a noise filter and smoothes high-frequency noise included in the voltage waveform supplied to the inverter or high-frequency noise generated by the inverter so as not to flow out to the power supply 101 side. A capacitor is connected to the power supply terminal of the inverter. The capacitor is a so-called bypass capacitor and suppresses voltage ripple. The capacitor is, for example, an electrolytic capacitor, and the capacitance and the number of capacitors to be used are appropriately determined by design specifications and the like.

The inverter 110 includes a bridge circuit having three legs. Each leg has a high side switch element and a low side switch element. The U-phase leg has a high-side switch element SW_AH and a low-side switch element SW_AL. The V-phase leg has a high-side switch element SW_BH and a low-side switch element SW_BL. The W-phase leg has a high-side switch element SW_CH and a low-side switch element SW_CL. As the switch element, for example, a field effect transistor (typically MOSFET) in which a parasitic diode is formed, or a combination of an insulated gate bipolar transistor (IGBT) and a freewheeling diode connected in parallel with the isolated gate bipolar transistor (IGBT) can be used.

The inverter 110 serves as, for example, a current sensor 400 (see FIG. 1) for detecting a current (sometimes referred to as “phase current”) flowing in the windings of each of the U-phase, V-phase, and W-phase. Each leg has a shunt resistance (not shown). The current sensor 400 has a current detection circuit (not shown) that detects the current flowing through each shunt resistor. For example, a shunt resistor can be connected between the low side switch element and ground on each leg.

The number of shunt resistors is not limited to three. For example, it is possible to use two shunt resistors for U-phase and V-phase, two shunt resistors for V-phase and W-phase, or two shunt resistors for U-phase and W-phase. The number of shunt resistors to be used and the arrangement of shunt resistors are appropriately determined in consideration of product cost, design specifications, and the like.

The U-phase leg of the inverter 110 (specifically, the node na between the high-side switch element SW_AH and the low-side switch element SW_AL) is connected to the other end of the U-phase winding M1 of the motor 200. Like the node na, the V-phase leg node nb is connected to the other end of the V-phase winding M2, and the W-phase leg node nc is connected to the other end of the W-phase winding M3.

The sub-inverter 120 can be connected to the other ends of the windings M1, M2 and M3. The sub-inverter of the present disclosure may have at least one leg connected in parallel with the three legs of the inverter. In the circuit configuration shown in FIG. 2, the sub-inverter 120 has one leg D connected in parallel with the three legs of the inverter 110. The leg D has a high-side switch element SW_DH and a low-side switch element SW_DL. The leg D can have a shunt resistor, similar to the leg of the inverter 110.

The node nd between the high-side switch element SW_DH and the low-side switch element SW_DL of the leg D can be connected to the windings M1, M2 and M3 via the second phase separation relay circuit 140 described later.

For example, the inverter 110 can be regarded as an inverter having four-phase legs of A phase, B phase, C phase and D phase. The inverter 110 and the sub-inverter 120 can be manufactured as a single bridge circuit having four legs including a leg D.

The first phase separation relay circuit 130 switches the connection / disconnection between the power supply 101 and the inverter 110 for each phase. In other words, the first phase separation relay circuit 130 can switch between the connection and non-connection of the power supply 101 and the windings M1, M2 and M3 via the inverter 110 for each phase.

The first phase separation relay circuit 130 is the three first phases connected between the high side node which is the power supply line and the three high side switch elements SW_AH, SW_BH and SW_CH in the inverter 110. It has three phase separation relays ISW_AH, ISW_BH and ISW_CH which are separation relays. The phase separation relay ISW_AH is on the U-phase leg. The phase separation relay ISW_BH is on the V-phase leg. The phase separation relay ISW_CH is on the W phase leg.

The first phase separation relay circuit 130 is further connected in the inverter 110 between the low side node which is the GND line and the three low side switch elements SW_AL, SW_BL and SW_CL, and the three second phases. It has three phase separation relays ISW_AL, ISW_BL and ISW_CL which are separation relays. The phase separation relay ISW_AL is on the U-phase leg. The phase separation relay ISW_BL is on the V-phase leg. The phase separation relay ISW_CL is on the W phase leg.

As the phase separation relay, for example, a semiconductor switch such as a MOSFET can be used. Other semiconductor switches such as thyristors and analog switch ICs or mechanical relays may be used. Moreover, the combination of the IGBT and the diode can be used.

FIG. 2 illustrates a MOSFET having a parasitic diode inside as a switch element of the inverter 110 and each phase separation relay. In each phase leg, the high-side phase separation relay and high-side switch element are connected in series so that the forward current flows in the same direction to the internal parasitic diode. The low-side phase separation relay and low-side switch element are connected in series so that the forward current flows in the same direction to the internal parasitic diode.

The second phase separation relay circuit 140 switches connection / disconnection between the power supply 101 and the windings M1, M2, and M3 via the sub-inverter 120. The second phase separation relay circuit 140 according to the present embodiment can switch the connection / non-connection between the sub-inverter 120 and the windings M1, M2 and M3 for each phase.

The second phase separation relay circuit 140 switches the connection / disconnection between the leg D of the sub-inverter 120 and the windings M1, M2 and M3, and is three phase separation relays ISW_AD which are three third phase separation relays. , IsW_BD and ISW_CD. One end of the phase separation relay ISW_AD is connected to the node nd of the leg D, and the other end is connected to the other end of the winding M1. One end of the phase separation relay ISW_BD is connected to the node nd of the leg D, and the other end is connected to the other end of the winding M2. One end of the phase separation relay ISW_CD is connected to the node nd of the leg D, and the other end is connected to the other end of the winding M3. As described above, one ends of the three phase separation relays ISW_AD, ISW_BD and ISW_CD are commonly connected to the node nd of the leg D.

FIG. 3 schematically shows the configuration of the bidirectional switch SW_2W.

As the three phase separation relays ISW_AD, ISW_BD and ISW_CD, a bidirectional switch SW_2W as shown can be used. A bidirectional switch SW_1W can be configured by combining two unidirectional switches SW_1W so that the internal diodes face opposite directions.

FIG. 4 schematically shows a typical block configuration of the control circuit 300.

The control circuit 300 includes, for example, a power supply circuit 310, an input circuit 320, a controller 330, a drive circuit 340, and a ROM 350. The control circuit 300 is connected to the power converter 100. The control circuit 300 controls the power conversion device 100, specifically, the inverter 110, the sub-inverter 120, the first phase separation relay circuit 130, and the second phase separation relay circuit 140 (see FIG. 1). The motor 200 can be driven. The control circuit 300 can realize closed loop control by controlling the position, rotation speed, current, and the like of the target rotor. A torque sensor may be used instead of the angle sensor 500 (see FIG. 1). In this case, the control circuit 300 can control the target motor torque.

The power supply circuit 310 generates a DC voltage (for example, 3V, 5V) required for each block in the circuit.

The input circuit 320 receives the motor current value (hereinafter, referred to as “actual current value”) detected by the current sensor 400. The input circuit 320 converts the level of the actual current value into the input level of the controller 330 as needed, and outputs the actual current value to the controller 330. The input circuit 320 is typically an analog-to-digital conversion circuit.

The controller 330 is an integrated circuit that controls the entire motor module 1000, and is, for example, a microcontroller or an FPGA (Field Programmable Gate Array).

The controller 330 receives the rotation signal of the rotor detected by the angle sensor 500. The controller 330 sets a target current value according to the actual current value, the rotation signal of the rotor, and the like, generates a PWM signal, and outputs the PWM signal to the drive circuit 340.

The controller 330 generates a PWM signal for controlling the switching operation (turn-on or turn-off) of each switch element in the inverter 110 and the sub-inverter 120 of the power conversion device 100. The controller 330 can further generate a signal that determines the on / off state of each phase separation relay in each phase separation relay circuit of the power converter 100.

The drive circuit 340 is typically a gate driver (or pre-driver). The drive circuit 340 generates a control signal (typically a gate control signal) for controlling the switching operation of each switch element in the inverter 110 and the sub-inverter 120 according to the PWM signal, and gives the control signal to each switch element. In the present embodiment, the drive circuit 340 generates an on / off control signal (analog signal) according to a signal from the controller 330 that determines the on / off state of each phase separation relay, and uses the control signals as the control signals. It is possible to give to.

A gate driver may not always be required when the drive target is a motor that can be driven at low voltage. In that case, the function of the gate driver may be implemented in the controller 330.

The ROM 350 is, for example, a writable memory (eg, PROM), a rewritable memory (eg, a flash memory), or a read-only memory. The ROM 350 stores a control program including a group of instructions for causing the controller 330 to control the power conversion device 100. For example, the control program is temporarily expanded to RAM (not shown) at boot time.

The control mode of the power converter 100 includes a control mode at the time of normal and a control mode at the time of abnormality. The control circuit 300 (mainly the controller 330) can switch the control of the power converter 100 from the normal control mode to the abnormal control mode. The on / off state of each phase separation relay of the first phase separation relay circuit 130 and the second phase separation relay circuit 140 is determined according to the control mode.

Hereinafter, the electric power supply 101, the inverter 110, the sub-inverter 120, and the windings M1, M2, and M3 in the on / off state and the on / off state of the first phase separation relay circuit 130 and the second phase separation relay circuit 140 are electrically connected. The connection relationship will be explained in detail.

In the present specification, "the first phase separation relay circuit 130 is turned on" means that all the phase separation relays ISW_AH, ISW_BH, ISW_CH, ISW_AL, ISW_BL and ISW_CL of the first phase separation relay circuit 130 are turned on. To do. "The first phase separation relay circuit 130 is turned off" means that all the phase separation relays ISW_AH, ISW_BH, ISW_CH, ISW_AL, ISW_BL and ISW_CL are turned off.

When the first phase separation relay circuit 130 is turned on, the inverter 110 is electrically connected to the power supply 101. When the first phase separation relay circuit 130 is turned off, the inverter 110 is electrically separated from the power supply 101.

As described above, it is possible to switch the connection / non-connection between the power supply 101 and the three legs of the inverter 110 for each phase. For example, by turning off the phase separation relays ISW_AH and ISW_AL, the U-phase leg is electrically separated from the power supply 101. The V-phase and W-phase legs remain connected to the power supply 101.

In the present specification, "the second phase separation relay circuit 140 is turned on" means that all the phase separation relays of the second phase separation relay circuit 140 are turned on. "The second phase separation relay circuit 140 is turned off" means that all the phase separation relays of the second phase separation relay circuit 140 are turned off.

In the circuit configuration shown in FIG. 2, when the second phase separation relay circuit 140 is turned on, the sub-inverter 120, more specifically, the leg D of the sub-inverter 120 is connected to the windings M1, M2 and M3. When the second phase separation relay circuit 140 is turned off, the leg D is electrically separated from the windings M1, M2 and M3.

As described above, it is possible to switch the connection / non-connection between the leg D of the sub-inverter 120 and the windings M1, M2 and M3 for each phase. For example, by turning on the phase separation relay ISW_AD and turning off the phase separation relays ISW_BD and ISW_CD, the leg D can be connected only to the winding M1.

[Operation of power converter 100]

Hereinafter, specific examples of the operation of the motor module 1000 will be described, and specific examples of the operation of the power conversion device 100 will be mainly described.

(1. Normal control)

First, a specific example of the normal control method of the power converter 100 will be described.

In the present specification, "normal" means that the inverter 110, the sub-inverter 120, and the windings M1, M2, and M3 of the motor 200 have not failed. The “abnormality” mainly means that a failure occurs in the switch element in the bridge circuit of the inverter 110. Switch element failures mainly refer to open failures and short-circuit failures of semiconductor switch elements (FETs). "Open failure" refers to a failure in which the source and drain of the FET are open (in other words, the resistance rds between the source and drain becomes high impedance), and "short failure" is a failure in which the source and drain of the FET are open. Refers to a short-circuit failure.

In the normal control mode, the control circuit 300 (mainly the controller 330) turns on the first phase separation relay circuit 130 and turns off the second phase separation relay circuit 140. By this control, the inverter 110 is connected to the power supply 101. In other words, the windings M1, M2 and M3 are electrically connected to the power supply 101 via the inverter 110. Further, the leg D of the sub-inverter 120 is electrically separated from the windings M1, M2 and M3. No power is supplied from the power supply 101 to the motor 200 via the sub-inverter 120.

The control circuit 300 can energize the three-phase windings M1, M2, and M3 by controlling the switching operation of the switch element of the inverter 110. In the present specification, such energization control is referred to as "three-phase energization control".

FIG. 5 illustrates a current waveform (sine wave) obtained by plotting the current values flowing through the windings M1, M2, and M3 according to the three-phase energization control. The horizontal axis represents the motor electric angle (deg), and the vertical axis represents the current value (A). I _pk represents the maximum value (peak current value) of the phase current flowing through each phase. In a general Y-connection type motor, the total current flowing through the three-phase winding in consideration of the direction of the current is "0" for each electric angle.

The control circuit 300 controls the switching operation of each switch element of the inverter 110 so that the pseudo sine wave shown in FIG. 5 can be obtained, for example. As a result, the power conversion device 100 can energize the windings M1, M2, and M3 under the control of the control circuit 300.

(2. Control at the time of abnormality)

If the power converter 100 is used for a long period of time, the switch element of the inverter 110 may fail. These failures are different from the manufacturing failures that can occur during manufacturing. When such a failure occurs, the above-mentioned normal control becomes impossible.

As an example of failure detection, the drive circuit 340 monitors the voltage Vds between the drain and the source of the switch element, and detects the failure of the switch element by comparing the predetermined threshold voltage with Vds. The threshold voltage is set in the drive circuit 340 by, for example, data communication with an external IC (not shown) and an external component. The drive circuit 340 is connected to the port of the controller 330 and notifies the controller 330 of the failure detection signal. For example, when the drive circuit 340 detects a failure of the switch element, it asserts a failure detection signal. When the controller 330 receives the asserted failure detection signal, it can read the internal data of the drive circuit 340 and determine which of the plurality of switch elements in the inverter 110 is failing. is there.

As another example of failure detection, the controller 330 can also detect a failure of the switch element based on the difference between the actual current value of the motor and the target current value. However, the failure detection is not limited to these methods, and a known method for failure detection can be widely used.

When the failure detection signal is asserted, the controller 330 switches the control of the power conversion device 100 from the normal control to the abnormal control. For example, the timing for switching the control from the normal time to the abnormal time is about 10 msec to 30 msec after the failure detection signal is asserted.

When one of the three legs of the inverter 110 fails, the control circuit 300 uses the phase separation relays ISW_AH, ISW_BH, and ISW_CH in the first phase separation relay circuit 130 for control in case of abnormality. The phase separation relay connected to the failed leg of the inverter 110 and the phase separation relay of the phase separation relays ISW_AL, ISW_BL and ISW_CL connected to the failed leg are turned off, and the remaining 4 Turn on the phase separation relays. Further, the control circuit 300 turns on the phase separation relay connected to the other end of the winding connected to the failed leg among the phase separation relays ISW_AD, ISW_BD and ISW_CD in the second phase separation relay circuit 140. Then, turn off the other two phase separation relays. In the present specification, failure of the switch element of the leg may be referred to as "failure of the leg".

Under the control of the control circuit 300, the power conversion device 100 uses two of the three legs of the inverter 110 other than the failed leg and the leg D of the sub-inverter 120 to wind three phases. The wire can be energized.

Hereinafter, the control method of the phase separation relay in each phase separation relay circuit will be described in detail with reference to an exemplary failure pattern.

See FIG. 2 again.

For example, consider the case where the high side switch element SW_AH in the U-phase leg of the inverter 110 fails open. In that case, the control circuit 300 turns off the phase separation relays ISW_AH and ISW_AL of the U-phase leg including the failed switch element in the first-phase separation relay circuit 130, and turns off the four V-phase and W-phase legs. Turn on the phase separation relays ISW_BH, ISW_BL, ISW_CH and ISW_CL. Further, the control circuit 300 turns on the phase separation relay ISW_AD connected to the winding M1 and turns off the phase separation relays ISW_BD and ISW_CD connected to the windings M2 and M3 in the second phase separation relay circuit 140. To do.

With these controls, the failed U-phase leg is electrically separated from the power supply 101. The windings M2 and M3 are connected to the power supply 101 via the V-phase and W-phase legs of the inverter 110. On the other hand, the U-phase winding M1 is connected to the leg D of the sub-inverter 120 instead of the U-phase leg of the inverter 110. In this connected state, the control circuit 300 can continue the three-phase energization control by using the V-phase leg and the W-phase leg of the inverter 110 and the leg D of the sub-inverter 120. That is, the leg D of the sub-inverter 120 can function as the U-phase leg of the inverter 110.

For example, consider the case where the high-side switch element SW_BH in the V-phase leg of the inverter 110 fails open. In that case, the control circuit 300 turns off the phase separation relays ISW_BH and ISW_BL of the V-phase leg including the failed switch element in the first-phase separation relay circuit 130, and turns off the four U-phase and W-phase legs. Turn on the phase separation relays ISW_AH, ISW_AL, ISW_CH and ISW_CL. Further, the control circuit 300 turns on the phase separation relay ISW_BD connected to the winding M2 and turns off the phase separation relays ISW_AD and ISW_CD connected to the windings M1 and M3 in the second phase separation relay circuit 140. To do. With these controls, the three-phase energization control can be continued using the U-phase leg and W-phase leg of the inverter 110 and the leg D of the sub-inverter 120. That is, the leg D of the sub-inverter 120 can function as the V-phase leg of the inverter 110.

For example, in an inverter having a four-phase leg that drives a four-phase AC motor, if one-phase leg fails, the leg D of the sub-inverter 120 can be used as the leg of the failed phase. As described above, the present disclosure can also be suitably used for driving a multi-phase motor having four or more phase windings.

According to this embodiment, in the control at the time of abnormality, the three-phase energization control using the three legs can be continuously performed by substituting the leg D of the sub-inverter 120.

FIG. 6 shows the relationship between the number of revolutions (rps) per unit time of the motor and the torque T (Nm). The horizontal axis of the graph shows the number of revolutions, and the vertical axis shows the value of the normalized torque. The rotation speed Wmn represents the maximum rotation speed. Wcn represents the number of revolutions at a change point where the torque changes abruptly in the motor output characteristics.

The so-called TN curve shown in FIG. 6 shows the characteristics of the motor output obtained by the control in the normal state and the motor output obtained by the control in the abnormal state. The torque value obtained by the control in the abnormal state indicates a value normalized by the torque value obtained by the control in the normal state. Further, as a comparative example, FIG. 6 shows the motor output characteristics in the control at the time of abnormality obtained by the control method disclosed in Patent Documents 1 (Japanese Patent Laid-Open No. 2016-34204) and 4 (Japanese Patent No. 5797751). ..

In the motor drive device of Patent Document 1, the motor is driven by using one of the first system and the second system that has not failed in the control at the time of abnormality. Since the maximum value of the phase current in the abnormal control is reduced to about 50% as compared with that in the normal control, the torque obtained in the abnormal control is also reduced to about 50% as compared with that in the normal control. .. On the other hand, since the maximum value of the phase voltage applied to the winding of each phase does not change by the control at the normal time and the abnormal time, the maximum rotation speed Wmn is maintained.

In the motor drive device of Patent Document 4, it is possible to independently control the current flowing through the three-phase windings in the normal control. On the other hand, in the control at the time of abnormality, the motor is driven by substantially only one inverter by utilizing the neutral point of the failed inverter. Since the maximum value of the phase voltage applied to the winding of each phase is reduced to about 58% compared to that in the normal state, the maximum rotation speed obtained by the control in the normal state is the maximum rotation speed Wmn in the normal state. Compared to about 58%. As a result, the high-speed rotation region is reduced to the low-speed side, and the motor cannot be driven at a higher speed. On the other hand, the maximum value of the phase current of the motor does not change under the control during normal and abnormal conditions, so that the torque is maintained.

According to this embodiment, the same three-phase energization control as in the normal state can be performed even in the abnormal state. Therefore, it is possible to obtain the same torque as the control at the normal time in the control at the time of abnormality. Further, since the maximum value of the phase voltage applied to the winding of each phase does not change by the control at the normal time and the abnormal time, the maximum rotation speed Wmn can be maintained and the rotation speed Wcn is maintained. Can be done. That is, the motor output characteristics do not change between the normal control and the abnormal control.

Summarizing the above, as shown in FIG. 6, the torque, the maximum rotation speed Wmn and the rotation speed Wcn of the motor can be maintained at the same values as in the normal state in the control at the time of abnormality as compared with the conventional case. As a result, it is possible to improve the motor output, that is, the drive range of the motor. In particular, higher torque can be obtained in the high speed rotation region. It is possible to further improve the motor output characteristics in the control at the time of abnormality.

(Embodiment 2)

[Structure of power converter 100A]

The structures of the sub-inverter 120 and the second phase separation relay circuit 140 of the power conversion device 100A according to the present embodiment are different from those of the power conversion device 100 according to the first embodiment. Hereinafter, the common description with the first embodiment will be omitted, and the differences will be mainly described.

FIG. 7 schematically shows the circuit configuration of the power conversion device 100A according to the present embodiment.

Like the inverter 110, the sub-inverter 120 has three legs, a U-phase leg, a V-phase leg, and a W-phase leg. The U-phase leg has a high-side switch element SW_DAH and a low-side switch element SW_DAL. The V-phase leg has a high-side switch element SW_DBH and a low-side switch element SW_DBL. The W-phase leg has a high-side switch element SW_DCH and a low-side switch element SW_DCL.

The three legs of the sub-inverter 120 are connected to the other ends of the windings M1, M2 and M3. Specifically, the node nda between the high side switch element SW_DAH and the low side switch element SW_DAL of the U-phase leg is connected to the other end of the winding M1 together with the node na of the inverter 110. The node ndb of the V-phase leg is connected to the other end of the winding M2 together with the node nb of the inverter 110. The W-phase leg node ndc is connected to the other end of the winding M3 together with the inverter 110 node nc.

The second phase separation relay circuit 140 switches between connection and non-connection between the power supply 101 and the sub-inverter 120. The second phase separation relay circuit 140 has a phase separation relay ISW_DH which is a third phase separation relay and a phase separation relay ISW_DL which is a fourth phase separation relay. The phase separation relay ISW_DH is connected between the high-side node ndh connecting the three high-side switch elements SW_DAH, SW_DBH and SW_DCH of the sub-inverter 120 and the power supply 101. The phase separation relay ISW_DL is connected between the low-side node ndl and GND that connect the three low-side switch elements SW_DAL, SW_DBL, and SW_DCL of the sub-inverter 120.

[Operation of power converter 100A]

In normal control, the control circuit 300 turns on the first phase separation relay circuit 130 and turns off the second phase separation relay circuit 140, as described in the first embodiment. As a result, the inverter 110 is connected to the power supply 101, and the sub-inverter 120 is separated from the power supply 101. The control circuit 300 performs three-phase energization control using the inverter 110.

When one of the three legs of the inverter 110 fails, the control circuit 300 uses the phase separation relays ISW_AH, ISW_BH, and ISW_CH in the first phase separation relay circuit 130 for control in case of abnormality. The phase separation relay connected to the failed leg of the inverter 110 and the phase separation relays of the phase separation relays ISW_AL, ISW_BL and ISW_CL connected to the failed leg are turned off, and the other four relays are turned off. Turn on the phase separation relay. The control circuit 300 further turns on the phase separation relays ISW_DH and ISW_DL of the second phase separation relay circuit 140.

The control circuit 300 includes two legs of the three legs of the inverter 110 other than the failed leg and the other end of the windings connected to the failed leg of the three legs of the sub-inverter 120. Three-phase energization control can be performed using a leg connected to the inverter.

Hereinafter, a control method of the power conversion device 100A will be described in detail with reference to an exemplary failure pattern.

For example, consider the case where the high side switch element SW_AH in the U-phase leg of the inverter 110 fails open. In that case, the control circuit 300 turns off the phase separation relays ISW_AH and ISW_AL of the U-phase leg including the failed switch element in the first-phase separation relay circuit 130, and turns off the four V-phase and W-phase legs. Turn on the phase separation relays ISW_BH, ISW_BL, ISW_CH and ISW_CL. The control circuit 300 further turns on the phase separation relays ISW_DH and ISW_DL of the second phase separation relay circuit 140.

With these controls, the failed U-phase leg is electrically separated from the power supply 101. The windings M2 and M3 are connected to the power supply 101 via V-phase and W-phase legs. Further, the winding M1 is connected to the power supply 101 via the U-phase leg of the sub-inverter 120 instead of the U-phase leg of the inverter 110. In this connected state, the control circuit 300 can continue the three-phase energization control by using the V-phase leg and the W-phase leg of the inverter 110 and the U-phase leg of the sub-inverter 120. That is, the U-phase leg of the sub-inverter 120 can function as the U-phase leg of the inverter 110.

For example, consider a case where two switch elements, the high-side switch element SW_AH of the U-phase leg of the inverter 110 and the high-side switch element SW_BH of the V-phase leg, fail to open. In that case, the control circuit 300 turns off the four phase separation relays ISW_AH, ISW_AL, ISW_BH and ISW_BL of the U-phase leg and the V-phase leg including the failed switch element in the first phase separation relay circuit 130. , W phase leg phase separation relays ISW_CH, ISW_CL are turned on. The control circuit 300 further turns on the phase separation relays ISW_DH and ISW_DL of the second phase separation relay circuit 140.

By these controls, the failed U-phase leg and V-phase leg are electrically separated from the power supply 101. The winding M3 is connected to the power supply 101 via a W-phase leg. Further, the windings M1 and M2 are connected to the power supply 101 via the U-phase leg and the V-phase leg of the sub-inverter 120 instead of the U-phase leg and the V-phase leg of the inverter 110. In this connected state, the control circuit 300 can continue the three-phase energization control by using the W-phase leg of the inverter 110 and the U-phase leg and the V-phase leg of the sub-inverter 120. That is, the U-phase leg and V-phase leg of the sub-inverter 120 can function as the U-phase leg and V-phase leg of the inverter 110.

If all three legs of the inverter 110 fail, the control circuit 300 can continue the three-phase energization control by using the three legs of the sub-inverter 120 instead of the inverter 110.

According to the present embodiment, as in the first embodiment, the three-phase energization control can be continuously performed by using the leg of the sub-inverter 120 in the control at the time of abnormality, and further, the motor in the control at the time of abnormality The output characteristics can be further improved.

(Embodiment 3)

FIG. 8 schematically shows a typical configuration of the electric power steering device 2000 according to the present embodiment.

Vehicles such as automobiles generally have an electric power steering (EPS) device. The electric power steering device 2000 according to the present embodiment includes a steering system 520 and an auxiliary torque mechanism 540 that generates an auxiliary torque. The electric power steering device 2000 generates an auxiliary torque that assists the steering torque of the steering system generated by the driver operating the steering handle. The auxiliary torque reduces the burden on the driver's operation.

The steering system 520 includes, for example, a steering handle 521, a steering shaft 522, a universal shaft joint 523A, 523B, a rotating shaft 524, a rack and pinion mechanism 525, a rack shaft 526, left and right ball joints 552A, 552B, tie rods 527A, 527B, and a knuckle. It may consist of 528A, 528B, and left and right steering wheels 529A, 729B.

The auxiliary torque mechanism 540 is composed of, for example, a steering torque sensor 541, an automobile electronic control unit (ECU) 542, a motor 543, a speed reduction mechanism 544, and the like. The steering torque sensor 541 detects the steering torque in the steering system 520. The ECU 542 generates a drive signal based on the detection signal of the steering torque sensor 541. The motor 543 generates an auxiliary torque according to the steering torque based on the drive signal. The motor 543 transmits the generated auxiliary torque to the steering system 520 via the reduction mechanism 544.

The ECU 542 includes, for example, the controller 330 and the drive circuit 340 according to the first embodiment. In automobiles, an electronic control system centered on an ECU is constructed. In the electric power steering device 2000, for example, the motor drive unit is constructed by the ECU 542, the motor 543, and the inverter 545. The motor module 1000 according to the first or second embodiment can be preferably used for the unit.

The embodiments of the present disclosure are also suitably used for X-by-wire such as shift-by-wire, steering-by-wire, brake-by-wire, and motor control systems such as traction motors. For example, the motor control system according to the embodiment of the present disclosure may be mounted on an autonomous vehicle that complies with Levels 0 to 4 (automation criteria) set by the Government of Japan and the National Highway Traffic Safety Administration (NHTSA).

The embodiments of the present disclosure can be widely used in various devices including various motors, such as vacuum cleaners, dryers, ceiling fans, washing machines, refrigerators and electric power steering devices.

100, 100A: Power converter, 101: Power supply, 102: Fuse, 110: Inverter, 120: Sub-inverter, 130: First phase separation relay circuit, 140: Second phase separation relay circuit, 200: Motor, 300: Control Circuit, 310: Power supply circuit, 320: Input circuit, 330: Microcontroller, 340: Drive circuit, 350: ROM, 400: Current sensor, 500: Angle sensor, 1000: Motor module, 2000: Electric power steering device

Claims (16)

There is a power converter that converts power from a power source into power supplied to a motor having n-phase (n is an integer of 3 or more) windings with one end Y-connected.

An inverter connected to the other end of the n-phase winding and having n legs, each containing a low-side switch element and a high-side switch element.

A first phase separation relay circuit that switches between connection and non-connection of the power supply and the n-phase winding via the inverter for each phase.

A sub-inverter having at least one leg connected in parallel with the n-legs of the inverter, and a sub-inverter connected to the other end of the n-phase winding.

A second phase separation relay circuit that switches between connection and non-connection of the power supply and the n-phase winding via the sub-inverter.

A power converter equipped with.

The power conversion device according to claim 1, wherein the second phase separation relay circuit switches connection / non-connection between the sub-inverter and the n-phase winding.

The second phase separation relay circuit according to claim 2, wherein the second phase separation relay circuit has n third phase separation relays for switching connection / disconnection between the at least one leg of the sub-inverter and the n-phase winding. Power converter.

The at least one leg of the sub-inverter is one leg including a low-side switch element and a high-side switch element.

One end of the n third phase separation relays is commonly connected to the node connecting the low side switch element and the high side switch element of the one leg.

The power conversion device according to claim 3, wherein the other end of the n third phase separation relays is connected to the other end of the n phase winding.

The power conversion device according to claim 3 or 4, wherein each of the n phase separation relays is a bidirectional switch.

The power conversion device according to claim 1, wherein the second phase separation relay circuit switches connection / disconnection between the power supply and the sub-inverter.

The at least one leg of the sub-inverter is n legs, each containing a low-side switch element and a high-side switch element.

The power conversion device according to claim 6, wherein the n legs of the sub-inverter are connected to the other end of the n-phase winding.

The second phase separation relay circuit

A third phase separation relay connected between the first node connecting the n high-side switch elements of the n legs and the power supply, and

The power conversion device according to claim 7, further comprising a second node connecting the n low-side switch elements of the n legs and a fourth phase separation relay connected between the grounds.

The first phase separation relay circuit

In the inverter, n first phase separation relays connected between the high side node connecting the n legs of the inverter and the n high side switch elements, and

In the inverter, n second phase separation relays connected between the low side node connecting the n legs of the inverter and n low side switch elements, and

The power conversion device according to any one of claims 1 to 8.

It has a normal control mode and an abnormal control mode as the power conversion control mode.

The power conversion device according to any one of claims 1 to 9, wherein in the normal control mode, the first phase separation relay circuit is turned on and the second phase separation relay circuit is turned off.

It has a normal control mode and an abnormal control mode as the power conversion control mode.

The first phase separation relay circuit

In the inverter, n first phase separation relays connected between the high side node connecting the n legs of the inverter and the n high side switch elements, and

In the inverter, n second phase separation relays connected between the low side node connecting the n legs of the inverter and n low side switch elements, and

Have,

When one of the n legs of the inverter fails, in the control at the time of the abnormality,

Of the n first phase separation relays, the first phase separation relay connected to the failed leg of the inverter and the n second phase separation relays connected to the failed leg. The second phase separation relay and the other n-1 first phase separation relay and the second phase separation relay are turned on.

Of the n third phase separation relays, the third phase separation relay connected to the other end of the winding connected to the failed leg is turned on, and the other n-1 third phase separation relays are turned on. The power conversion device according to claim 4, wherein the relay is turned off.

11. The n-phase winding is energized by using n-1 legs other than the failed leg among the n legs of the inverter and one leg of the sub-inverter. The power converter described in.

It has a normal control mode and an abnormal control mode as the power conversion control mode.

The first phase separation relay circuit

In the inverter, n first phase separation relays connected between the high side node connecting the n legs of the inverter and n high side switch elements, and

In the inverter, n second phase separation relays connected between the low side node connecting the n legs of the inverter and n low side switch elements, and

Have,

When one of the n legs of the inverter fails, in the control at the time of the abnormality,

Of the n first phase separation relays, the first phase separation relay connected to the failed leg of the inverter and the n second phase separation relays connected to the failed leg. The second phase separation relay and the other n-1 first phase separation relay and the second phase separation relay are turned on.

The power conversion device according to claim 8, wherein the second phase separation relay circuit is turned on.

Of the n-1 legs of the inverter other than the failed leg, and the windings of the n-legs of the sub-inverter connected to the failed leg of the inverter. The power conversion device according to claim 13, wherein the n-phase winding is energized by using a leg connected to the other end.

With the motor

The power conversion device according to any one of claims 1 to 14.

A control circuit that controls the power converter and

Motor module with.
An electric power steering device having the motor module according to claim 15.

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