JP2019103185A - Electric motor control device - Google Patents

Abstract

To provide an electric motor control device capable of widening a low-voltage region where control of an electric motor is possible.SOLUTION: An inverter actuation circuit 18 receives a power from any larger one of a power supply voltage Vb of a power supply 3 and an output voltage Vc of a step up/down circuit 34. A power supply line 20 electrically connects between the inverter actuation circuit 18 and the power supply 3. The power supply line 20 is provided with semiconductor relays 14 and 15. The semiconductor relays 14 and 15 actuate by being supplied with a power via the inverter actuation circuit 18, and turn ON/OFF the supply of power from the power supply 3 to an electric motor 11. A capacitor 16 is provided between the power supply 3 and an inverter 12. A precharge circuit 17 supplies a power to the capacitor 16 not via the semiconductor relays 14 and 15. The precharge circuit 17 supplies a power to the capacitor 16 and the inverter actuation circuit 18 via the power supply line 20.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a motor control device suitable for use in, for example, an electric brake device or the like.

  As a brake device mounted in vehicles, such as a four-wheeled motor vehicle, the electric brake device (electric booster) which comprised the structure which electrically controls the brake hydraulic pressure generated with a master cylinder is known. Such an electric brake device drives a motor by power supplied from a battery serving as a power source, and controls the brake fluid pressure. On the other hand, the battery also supplies power to the starter motor that performs the start operation of the engine. For this reason, when the battery voltage is reduced by the driving of the starter motor accompanying the start of the engine, the motor of the electric brake device may not operate sufficiently, and the braking force may be reduced. Patent Document 1 discloses a configuration in which, when the brake fluid pressure is supplied when the power supply voltage is lowered, the coil connection of the motor is shorted to maintain the brake fluid pressure.

JP 2014-108656 A

  By the way, the brake device of patent document 1 is provided with the inverter which consists of a some switching element (for example, MOSFET) between a motor and a battery, and is controlling the motor using this inverter. At this time, in the low voltage region where the power supply voltage is lowered, the gate voltage of the MOSFET may be insufficient before the driving power of the motor is insufficient, and the operation of the inverter may become impossible. As a result, in the brake device described in Patent Document 1, the coil connection of the motor can not be short-circuited, and the hydraulic pressure may be insufficient.

  The present invention has been made in view of the above-described problems of the prior art, and an object of the present invention is to provide a motor control device capable of expanding a low voltage region in which control of the motor can be performed.

  In order to solve the problems described above, the present invention provides a motor, an inverter for driving the motor, an inverter operation circuit for operating the inverter, a storage device for supplying power to the inverter operation circuit, and the inverter operation circuit. An arithmetic unit to control, a voltage step-up / down circuit supplying power to the arithmetic device by raising or lowering the voltage of the power storage device, a first path for supplying power to the inverter operation circuit from the power storage device, the elevation A second path joining the first path from the pressure circuit to the inverter operation circuit to supply power, the first path between the first path, a junction of the second path, and the power storage device Between a first diode provided on the upper side, a second diode provided on the second path between the junction and the step-up / down circuit, and between the power storage device and the first diode Are provided between the power storage device and a third path for supplying the power of the storage device to the inverter, the branch point of the third path in the first path, and the storage device, and the power storage device to the motor A semiconductor relay that switches whether to supply power or shut off, and provided in the inverter operation circuit, raises a voltage input to the inverter operation circuit to supply power to the semiconductor relay and a switching element of the inverter A motor control device, comprising: a booster circuit; and a precharge circuit for supplying power of the power storage device to a capacitor provided in the third path without passing through the semiconductor relay, wherein the inverter operation circuit is When the voltage of the storage device is greater than the voltage of the step-up / step-down circuit, the precharge is performed when the semiconductor relay is off. Power from the power storage device via the first path and the first path, and when the semiconductor relay is on, power from the power storage device is received via the semiconductor relay and the first path; When the voltage is smaller than the voltage of the step-up / step-down circuit, power is supplied from the step-up / step-down circuit via the second path.

  According to the present invention, it is possible to widen the low voltage region where control of the motor is possible.

FIG. 1 is a circuit diagram showing an electric brake device according to an embodiment of the present invention. It is explanatory drawing which shows the application state of the voltage when a semiconductor relay turns off in FIG. FIG. 2 is an explanatory view showing an applied state of a voltage when a precharge circuit operates in FIG. 1; It is explanatory drawing which shows the application state of the voltage when a semiconductor relay turns on in FIG. FIG. 6 is a characteristic line diagram showing temporal changes of an output voltage of a booster circuit, an input voltage of an inverter operation circuit, a voltage of a capacitor and the like. It is a flowchart which shows the control process of the precharge switch and semiconductor relay which the calculating | arithmetic apparatus in FIG. 1 performs. It is a circuit diagram showing the electric brake equipment by a comparative example.

  Hereinafter, a case where the motor control device according to the embodiment is applied to an electric brake device of a four-wheeled vehicle will be described as an example with reference to the accompanying drawings.

  In FIG. 1, the electric brake device 1 applies a braking force to stop the vehicle. The electric brake device 1 is an electric booster (not shown) for electrically controlling the brake fluid pressure generated by the master cylinder (M / C) 2 in order to supply the brake fluid to a wheel cylinder (not shown) of the vehicle. Make up an electric booster). Therefore, the electric brake device 1 includes an electric motor 11 for controlling the brake fluid pressure, and an arithmetic unit 31 for controlling the electric motor 11.

  At this time, the motor-driven brake device 1 includes a motor drive power supply system 10 for supplying drive power of the motor 11 and a logic drive power supply system 30 for supplying drive power of the arithmetic device 31. The motor drive power supply system 10 includes an electric motor 11, an inverter 12, an inverter operation circuit 18, and the like. The logic drive power supply system 30 includes an arithmetic unit 31, a step-up / step-down circuit 34, and the like.

  The power source 3 is, for example, a battery mounted on a vehicle, and constitutes a power storage device. The power supply 3 stores electric power of a generator (not shown) that is rotationally driven by an engine (not shown) formed of an internal combustion engine to generate electric power. The power supply 3 is connected to a starter motor 5 which is a starting device of the engine via a power supply line 4. Therefore, the power supply 3 supplies power when the starter motor 5 is driven. Further, the power supply 3 supplies power to the motor 11 via the inverter 12. In addition to this, the power supply 3 supplies power to the inverter operating circuit 18. Furthermore, the power supply 3 also supplies power to the arithmetic device 31 and the like.

  Further, a stroke sensor 6 is connected to the computing device 31. The stroke sensor 6 detects the amount of operation (depression) of the brake pedal by the driver, and outputs a detection signal corresponding to the amount of operation to the arithmetic device 31 as a braking request signal of the present invention.

  Next, the motor drive power supply system 10 will be described. The motor drive power supply system 10 includes an electric motor 11, an inverter 12, an inverter operation circuit 18, and the like.

  The motor 11 outputs a braking force in response to the braking request signal. The electric motor 11 is configured as an electric motor of an electric booster configured of, for example, a DC brushless motor, and is driven and controlled by an arithmetic unit 31 described later. The electric motor 11 operates a piston (not shown) in the master cylinder 2 based on the amount of operation (depression) of a brake pedal (not shown) to generate brake fluid pressure in the master cylinder 2.

  The motor 11 is connected to the power supply 3 via the inverter 12. The inverter 12 is configured using a plurality of switching elements S made of, for example, n-type MOSFETs. The inverter 12 converts DC power from the power supply 3 into AC power and supplies the AC power to the motor 11. Thus, the inverter 12 drives the motor 11. Here, in the inverter 12, ON / OFF of each switching element S is controlled by the inverter operation circuit 18.

  Further, in the inverter 12, a circuit for one phase is formed by the high-side switching element S (upper arm) and the low-side switching element S (lower arm). Therefore, in order to control the three-phase motor 11, the inverter 12 constitutes a circuit of three phases by a total of six switching elements S, for example.

  Since the source of the n-type MOSFET is at the ground level in the low-side switching element S, ON and OFF can be switched by applying the power supply voltage Vb from the power supply 3 to the gate. On the other hand, in the high-side switching element S, since the source of the n-type MOSFET may rise to the power supply voltage level, it is necessary to apply a voltage higher than the power supply voltage Vb to the gate.

  The inverter 12 is connected to the power supply 3 via a power supply line 13 separate from the power supply line 4. The power supply line 13 branches from an intermediate position of the power supply line 20 connecting the power supply 3 and the inverter operation circuit 18. The power supply line 13 branches from the power supply line 20 between the power supply 3 and the first diode 21 and constitutes a third path for supplying the power of the power supply 3 to the inverter 12. Semiconductor relays 14 and 15 are provided in the power supply line 20. At this time, the power supply line 13 branches from the power supply line 20 at a position downstream of the semiconductor relays 14 and 15. Therefore, the power supply 3 supplies power to the inverter 12 when the semiconductor relays 14 and 15 are turned on (connected state).

  The semiconductor relays 14 and 15 are fail-safe relays that stop the power supply to the motor 11 and the inverter 12 when the operation of the motor 11 is not desired, for example, when the motor 11 is not activated or when an abnormality occurs. The semiconductor relays 14 and 15 are configured in substantially the same manner as the switching element S of the inverter 12. At this time, the semiconductor relays 14 and 15 are connected in series with each other. In the semiconductor relays 14 and 15, the polarities of the diodes connected in parallel to the MOSFETs are opposite to each other.

  The semiconductor relays 14 and 15 are supplied with power via the inverter operating circuit 18 to operate and turn on / off the power supply from the power source 3 to the motor 11. Specifically, the gates of the semiconductor relays 14 and 15 are connected to the output of the booster circuit 18A of the inverter operation circuit 18 through the switches 14A and 15A. The semiconductor relays 14 and 15 are provided between the power supply 3 and a branch point Pb of the power supply line 13 in the power supply line 20, and switch whether to supply or shut off the power from the power supply 3 to the motor 11. The semiconductor relays 14 and 15 are turned ON by applying a voltage (high side gate voltage VgH) higher than the power supply voltage Vb from the booster circuit 18A to the gates of the semiconductor relays 14 and 15. The ON / OFF of the switches 14A and 15A is controlled by the arithmetic unit 31.

  The capacitor 16 (inverter capacitor) is provided between the semiconductor relays 14 and 15 and the inverter 12. Specifically, capacitor 16 is located between semiconductor relays 14 and 15 and inverter 12 and connected to power supply line 13. The capacitor 16 constitutes a smoothing circuit, and is used for the purpose of smoothing the fluctuation included in direct current. The capacitor 16 is connected to the power supply 3 via the precharge circuit 17.

  The precharge circuit 17 supplies the power of the power supply 3 to the capacitor 16 provided on the power supply line 13 without passing through the semiconductor relays 14 and 15. The precharge circuit 17 is electrically connected to the power supply 3 on the upstream side of the semiconductor relays 14 and 15 and electrically connected to the power supply line 13. For example, if the semiconductor relays 14 and 15 are conducted in a state in which the charge is not stored in the capacitor 16, an inrush current is generated. The precharge circuit 17 is a circuit that charges the capacitor 16 in advance in order to prevent the occurrence of such inrush current. The precharge circuit 17 includes a precharge resistor 17A and a precharge switch 17B connected in series with each other. The precharge circuit 17 supplies the power of the power supply 3 (power supply for logic) to the capacitor 16 through the precharge resistor 17A and the precharge switch 17B. At this time, since the current is limited by the precharge resistor 17A, a large current does not flow even if the precharge switch 17B is turned on. The ON / OFF of the precharge switch 17B is controlled by the arithmetic unit 31. The precharge circuit 17 is electrically connected to the power supply line 20 via the power supply line 13. Therefore, the precharge circuit 17 supplies power to the capacitor 16 and the inverter operation circuit 18 via the power supply line 20.

  The inverter operating circuit 18 operates the inverter 12. Specifically, the inverter operation circuit 18 is configured by a pre-driver IC, and controls ON / OFF of each switching element S of the inverter 12 based on a command from the arithmetic device 31. Thus, the inverter operation circuit 18 controls the drive of the motor 11. The input side of the inverter operation circuit 18 is connected to the power supply 3. The output side of the inverter operation circuit 18 is connected to the switching element S of the inverter 12. The inverter operation circuit 18 further includes a booster circuit 18A, a drive circuit 18B, and a current sensor 18C.

  The booster circuit 18A is configured of, for example, a charge pump circuit. The booster circuit 18A is provided in the inverter operation circuit 18, raises the voltage (the power supply voltage Vb or the output voltage Vc) input to the inverter operation circuit 18, and supplies power to the switching elements S of the semiconductor relays 14 and 15 and the inverter 12. Supply. The input side of the booster circuit 18A is connected to the power supply 3. The output side of the booster circuit 18A is connected to the gate of the high side switching element S via the drive circuit 18B. The booster circuit 18A boosts the power supply voltage Vb and outputs the high side gate voltage VgH higher than the power supply voltage Vb. At this time, the potential difference between the power supply voltage Vb and the high side gate voltage VgH is set to a value larger than a predetermined value determined in advance as a value that enables the high side switch element to be turned on and off.

  The drive circuit 18B is formed of, for example, a plurality of switching elements (not shown), and connects or disconnects the booster circuit 18A and the gate of the high side switching element S (MOSFET). It connects or cuts off with the gate of the element S (MOSFET). At this time, the switching element of the drive circuit 18B is switched between ON (connected state) and OFF (disconnected state) in accordance with a command from the arithmetic device 31. Thus, the drive circuit 18B switches the application state of the high side gate voltage VgH to the gate of the high side switching element S. In addition to this, the drive circuit 18B switches the application state of the power supply voltage Vb to be the low side gate voltage VgL to the gate of the low side switching element S. Thus, the inverter operation circuit 18 controls ON / OFF of the switching element S of the inverter 12 to operate the inverter 12.

  The current sensor 18C detects the current flowing through the motor 11, and outputs a detection signal to the arithmetic device 31. The input side of the current sensor 18C is connected to both ends of a current detection resistor 19 connected between the source of the low side switching element S and the ground. At this time, the potential difference between both ends of the current detection resistor 19 has a value corresponding to the current flowing through the motor 11. Therefore, the current sensor 18C amplifies the potential difference between both ends of the current detection resistor 19 using the power supply voltage Vb, and outputs a detection signal according to the potential difference to the arithmetic device 31.

  The inverter operation circuit 18 is connected to the power supply 3 via the power supply line 20 (first path). At this time, the power supply line 20 constitutes a first path for supplying power from the power supply 3 to the inverter operation circuit 18. The power supply line 20 electrically connects the power supply 3 and the inverter operation circuit 18.

  In the middle of the power supply line 20, a first diode 21 is provided between the semiconductor relays 14 and 15 and the inverter operation circuit 18. Specifically, the first diode 21 is provided between the semiconductor relay 15 on the downstream side of the semiconductor relays 14 and 15 and the inverter operation circuit 18. The first diode 21 allows current in the direction from the power supply 3 to the inverter operation circuit 18, and cuts off current in the reverse direction.

  Further, to the power supply line 13, a first monitor circuit 22 which is located between the semiconductor relays 14 and 15 and the inverter 12 and which is a voltage sensor is connected. At this time, the first monitor circuit 22 measures the voltage V1 of the capacitor 16. The first monitor circuit 22 detects the voltage V1 of the capacitor 16 and outputs a detection signal corresponding to the voltage V1 to the arithmetic unit 31.

  Connected to the power supply line 20 is a second monitor circuit 23 which is located between the first diode 21 and the inverter operation circuit 18 and which is a voltage sensor. The second monitor circuit 23 measures the voltage V2 input to the inverter operation circuit 18 (boost circuit 18A). The second monitor circuit 23 detects an input voltage V2 of the inverter operation circuit 18, and outputs a detection signal corresponding to the voltage V2 to the arithmetic device 31.

  Connected to the power supply 3 is a third monitor circuit 24 composed of a voltage sensor. The third monitor circuit 24 detects the power supply voltage Vb, and outputs a detection signal corresponding to the power supply voltage Vb to the arithmetic unit 31.

  Next, the logic drive power supply system 30 will be described. The logic drive power supply system 30 includes an arithmetic unit 31, a step-up / step-down circuit 34, and the like.

  Arithmetic unit 31 controls inverter operation circuit 18. Specifically, the arithmetic unit 31 controls the motor 11 using the inverter operation circuit 18 and the inverter 12 and constitutes a part of the electric brake device 1. The arithmetic unit 31 includes, for example, a microcomputer (MCU) or the like, and is driven by the drive voltage Vd generated by the step-up / step-down circuit 34 and the regulator 35. The arithmetic unit 31 is a master pressure control unit that drives and controls the motor 11 of the electric booster to generate a brake fluid pressure in the master cylinder 2. The stroke sensor 6, the current sensor 18C, and the monitor circuits 22, 23, 24 are connected to the input side of the arithmetic unit 31. In addition to this, a sensor 32 composed of a resolver or the like for detecting the rotation angle of the motor 11 is connected to the input side of the arithmetic unit 31. On the other hand, an inverter operation circuit 18 (drive circuit 18B), semiconductor relays 14 and 15, and a precharge switch 17B are connected to the output side of the arithmetic unit 31. Further, the arithmetic unit 31 is connected to a communication circuit 33 for communicating with various controllers (not shown) provided in the vehicle through a controller area network (CAN). The sensor 32 and the communication circuit 33 are also driven by the drive voltage Vd, similarly to the arithmetic device 31.

  Arithmetic unit 31 receives the detection value of stroke sensor 6 based on the driver's operation of the brake pedal. Then, the arithmetic unit 31 operates the motor 11 based on the detection signal (braking request signal) of the stroke sensor 6 to generate the brake fluid pressure in the master cylinder 2. The arithmetic unit 31 further includes a storage unit (not shown) including ROM, RAM, etc., and the storage unit includes the semiconductor relays 14 and 15 (switches 14A and 15A) and the precharge switch 17B shown in FIG. A program for controlling ON / OFF is stored. Arithmetic unit 31 controls ON / OFF of semiconductor relays 14 and 15 and precharge switch 17B by executing this program.

  The step-up / step-down circuit 34 raises or lowers the power supply voltage Vb of the power supply 3 to supply power to the arithmetic device 31. Specifically, the step-up / step-down circuit 34 is constituted by, for example, a step-up / step-down chopper circuit (step-up / step-down DCDC circuit), and outputs a constant output voltage Vc (DC voltage) at all times. At this time, the step-up / step-down circuit 34 raises or lowers the power supply voltage Vb supplied from the power supply 3 to convert the power supply voltage Vb into a predetermined constant output voltage Vc. Therefore, when the power supply voltage Vb is higher than the output voltage Vc, the step-up / step-down circuit 34 functions as a step-down circuit. Conversely, when the power supply voltage Vb is lower than the output voltage Vc, the step-up / step-down circuit 34 functions as a step-up circuit. At this time, the input side of the step-up / step-down circuit 34 is connected to the power supply 3. The output side of the step-up / step-down circuit 34 is connected to the arithmetic unit 31, the sensor 32, the communication circuit 33 and the like via the regulator 35. The regulator 35 is, for example, a series regulator, removes ripples and the like from the output voltage Vc, and supplies a constant drive voltage Vd to the arithmetic device 31 and the like.

  The output side of the step-up / step-down circuit 34 is connected to the inverter operation circuit 18 via the auxiliary power supply line 36. At this time, the auxiliary power supply line 36 constitutes a second path that electrically connects the power supply 3 and the inverter operation circuit 18 via the step-up / step-down circuit 34. Therefore, the step-up / step-down circuit 34 supplies power to the inverter operation circuit 18 and the arithmetic unit 31.

  Auxiliary power supply line 36 is electrically connected to power supply line 20. Specifically, one end side of the auxiliary power supply line 36 is connected to the output side of the step-up / down circuit 34, and the other end side of the auxiliary power supply line 36 is connected to an intermediate position of the power supply line 20. Therefore, the auxiliary power supply line 36 joins the power supply line 20 and is electrically connected to the inverter operation circuit 18. The auxiliary power supply line 36 joins the power supply line 20 from the buck-boost circuit 34 to the inverter operation circuit 18 to supply power. At this time, the junction point Pj between the auxiliary power supply line 36 and the power supply line 20 is located between the first diode 21 and the inverter operation circuit 18. Therefore, the first diode 21 is provided on the power supply line 20 between the junction point Pj of the power supply line 20 and the auxiliary power supply line 36 and the power supply 3. Therefore, the second monitor circuit 23 connected to the cathode side of the first diode 21 detects the voltage V2 at the junction point Pj.

  In the middle of the auxiliary power supply line 36, a second diode 37 is provided which allows current in the direction from the step-up / step-down circuit 34 to the inverter operation circuit 18 and cuts off current in the reverse direction. At this time, the second diode 37 is provided on the auxiliary power supply line 36 between the junction Pj and the step-up / step-down circuit 34. Thus, the inverter operation circuit 18 can also supply power from the step-up / step-down circuit 34, and receives power supply from the power supply 3 or the step-up / step-down circuit 34 whichever has the larger voltage value. That is, when the power supply voltage Vb of the power supply 3 is lower than the output voltage Vc of the step-up / step-down circuit 34, the inverter operation circuit 18 receives the supply of power from the power supply 3 via the auxiliary power supply line 36.

  Next, processing of controlling ON / OFF of the semiconductor relays 14 and 15 and the precharge switch 17B by the arithmetic unit 31 will be described with reference to FIGS. 1 and 6. Each step in the flowchart shown in FIG. 6 uses the notation “S”, and for example, step 1 is indicated as “S1”.

  Arithmetic unit 31 executes the process shown in FIG. 6 to control ON / OFF of semiconductor relays 14 and 15 and precharge switch 17B. When the process shown in FIG. 6 is started, the arithmetic unit 31 determines in S1 whether the operation of the motor 11 is necessary. If the operation of the motor 11 is unnecessary, the arithmetic unit 31 turns off the precharge switch 17B in S2 to cut off the power supply to the inverter 12, and switches the switches 14A and 15A of the semiconductor relays 14 and 15 in S3. Turn it off.

  On the other hand, when the operation of the motor 11 is necessary, the process proceeds to S4, and it is determined whether the semiconductor relays 14 and 15 are already in the ON state. If the semiconductor relays 14 and 15 are in the ON state, the inverter operating circuit 18 (pre-driver IC) can be operated with the voltage (power supply voltage Vb) of the power supply 3 supplied via the semiconductor relays 14 and 15. There is no need to supply power via the charge circuit 17. For this reason, it determines with "YES" by S4, and transfers to S5. At S5, the arithmetic unit 31 turns off the precharge switch 17B, and continues to turn on the semiconductor relays 14 and 15 (switches 14A and 15A) at S6.

  If the semiconductor relays 14 and 15 are in the OFF state, it is determined as "NO" in S4, and the process proceeds to S7 in order to turn on the semiconductor relays 14 and 15. In S7, the arithmetic unit 31 turns on the precharge switch 17B to charge the capacitor 16 with charge, and supplies the voltage (power supply voltage Vb) of the power supply 3 to the inverter operation circuit 18.

  At S8, the voltage V1 of the capacitor 16 detected by the first monitor circuit 22 and the power supply voltage Vb detected by the third monitor circuit 24 are compared, and the voltage V1 of the capacitor 16 is about the same as the power supply voltage Vb It is determined whether or not the voltage Vb has risen to 90% or more).

  Until the electric charge of the capacitor 16 is sufficiently stored, it is determined as "NO" in S8, and the arithmetic unit 31 holds the semiconductor relays 14, 15 (switches 14A, 15A) in the OFF state in S10. On the other hand, when the voltage V1 of the capacitor 16 has risen to the same level as the power supply voltage Vb, it is determined as "YES" in S8, and the process proceeds to S9.

  In S9, the input voltage V2 of the inverter operation circuit 18 detected by the second monitor circuit 23 is compared with the power supply voltage Vb detected by the third monitor circuit 24 and the input voltage V2 is approximately the same as the power supply voltage Vb. It is determined whether or not the voltage Vb has risen to 90% or more).

  Until a sufficient voltage is supplied to the inverter operation circuit 18, it is determined as "NO" in S9, and the arithmetic unit 31 holds the semiconductor relays 14 and 15 (switches 14A and 15A) in the OFF state in S10. . On the other hand, when the electric charge of the capacitor 16 is sufficiently stored and the input voltage V2 of the inverter operation circuit 18 rises to the same level as the power supply voltage Vb, "YES" is determined in S9, and the process shifts to S11. At this time, since a sufficient voltage is also supplied to the inverter operation circuit 18, the arithmetic unit 31 turns on the switches 14A and 15A of the semiconductor relays 14 and 15 in S11.

  The electric brake device 1 according to the present embodiment has the above-described configuration. Next, the operation of the electric brake device 1 will be described with reference to FIG.

  When the driver of the vehicle depresses the brake pedal, the arithmetic unit 31 controls the operation of the motor 11 based on the detection value of the stroke sensor 6 that detects the depression amount of the brake pedal. The brake fluid pressure generated in the master cylinder 2 by the operation of the electric motor 11 is distributed to the front and rear wheel brakes and supplied, and the braking forces are respectively transmitted to the left and right front wheels and the left and right rear wheels. Granted.

  When the vehicle is started, the driver drives the starter motor 5 to start the engine in a state where the driver steps on the brake pedal. At this time, the starter motor 5 is driven by supplying power from the power supply 3. In addition to this, the power supply 3 also supplies power to the inverter operating circuit 18. Therefore, if the voltage of the power supply 3 (power supply voltage Vb) is temporarily reduced when the starter motor 5 is driven, the inverter operation circuit 18 becomes inoperable, and there is a possibility that the control of the motor 11 and the brake fluid pressure can not be performed.

  Therefore, in the present embodiment, power is supplied to the inverter operation circuit 18 from both the power supply 3 and the step-up / step-down circuit 34. When the voltage of the power supply 3 decreases and the output voltage Vc of the step-up / step-down circuit 34 becomes higher than the power supply voltage Vb, the output voltage Vc of the step-up / step-down circuit 34 is supplied to the inverter operation circuit 18. Thereby, even when the power supply voltage Vb is lowered, the control of the motor 11 can be continued, and the necessary brake fluid pressure can be generated.

  The relationship between the power supply voltage Vb and the inverter operation circuit 18 will be described in detail below.

  When the power supply voltage Vb is normal (normal state), the power supply voltage Vb is higher than the output voltage Vc of the step-up / step-down circuit 34 (Vb> Vc). In this case, the power supply voltage Vb is supplied to the inverter operation circuit 18 via the first diode 21. At this time, the booster circuit 18A of the inverter operation circuit 18 operates with the power supply voltage Vb, and boosts the power supply voltage Vb to generate the high side gate voltage VgH. Therefore, the inverter operation circuit 18 controls the switching element S of the inverter 12 using the high side gate voltage VgH higher than the power supply voltage Vb and the low side gate voltage VgL of the same degree as the power supply voltage Vb. Thus, the inverter operation circuit 18 can control the operation of the motor 11 by switching ON / OFF of the switching element S formed of a MOSFET.

  On the other hand, for example, when the starter motor 5 is driven, the power supply voltage Vb is lower than in the normal state. As described above, when the power supply voltage Vb is low (in a low voltage state), the power supply voltage Vb may be lower than the output voltage Vc of the step-up / step-down circuit 34 (Vb <Vc). In this case, the output voltage Vc of the step-up / step-down circuit 34 is supplied to the inverter operation circuit 18 via the second diode 37. At this time, the booster circuit 18A of the inverter operation circuit 18 operates with the output voltage Vc of the step-up / step-down circuit 34, and generates the high side gate voltage VgH by boosting the output voltage Vc. Therefore, the inverter operation circuit 18 controls the switching element S of the inverter 12 using the high side gate voltage VgH higher than the power supply voltage Vb and the low side gate voltage VgL at the same level as the output voltage Vc. Thus, the inverter operation circuit 18 can control the operation of the motor 11 by switching ON / OFF of the switching element S formed of a MOSFET.

  Here, the voltage at which the step-up / step-down circuit 34 becomes inoperable has a lower value than the voltage at which the inverter operation circuit 18 becomes inoperable. As a result, the low voltage region of the power supply voltage Vb which can be controlled by the motor 11 can be expanded to a voltage at which the step-up / step-down circuit 34 can not operate. Thus, even when the power supply voltage Vb is lowered, the inverter 12, the current sensor 18C, etc. operate and the control of the motor 11 can be continued until the voltage drops to the inoperable voltage of the step-up / step-down circuit 34.

  Further, in the present embodiment, the switch (failsafe relay) disposed between the power supply 3 and the inverter 12 is configured by the semiconductor relays 14 and 15. At this time, in order to drive the semiconductor relays 14 and 15, it is necessary to apply a voltage at least 4 to 5 V higher than the power supply voltage Vb to the gates of the MOSFETs of the semiconductor relays 14 and 15, as in the inverter 12. . The voltage for driving the semiconductor relays 14 and 15 is supplied from the booster circuit 18A in the inverter operation circuit 18.

  On the other hand, in the present embodiment, in order to widen the low voltage region of power supply voltage Vb that can be controlled by motor 11, inverter operating circuit 18 can supply power from buck / boost circuit 34 in addition to power supply 3. Power is supplied from the larger one of the voltage value (power supply voltage Vb) supplied with power from the power supply 3 and the voltage value (output voltage Vc) supplied with power from the buck-boost circuit 34.

  Therefore, as shown in FIG. 2, only the output voltage Vc from the voltage step-up / step-down circuit 34 is supplied to the inverter operation circuit 18 when the semiconductor relays 14 and 15 between the power supply 3 and the inverter 12 are nonconductive. . Under normal conditions, the output voltage Vc from the step-up / step-down circuit 34 becomes lower than the power supply voltage Vb (Vc <Vb). Therefore, there is a problem that the semiconductor relays 14 and 15 can not be driven to switch from OFF (non-conduction state) to ON (conduction state) as it is.

  Therefore, in the present embodiment, when the semiconductor relays 14 and 15 are OFF, the power supply voltage Vb is supplied to the inverter operation circuit 18 via the precharge circuit 17. Next, specific operations of the semiconductor relays 14 and 15 and the precharge circuit 17 will be described with reference to FIGS. 3 to 5.

  As shown in FIG. 3, when the semiconductor relays 14 and 15 are in the OFF state, the precharge switch 17B is turned on to charge the capacitor 16 in order to drive the semiconductor relays 14 and 15. As shown in FIG. 5, when the capacitor 16 is charged, the voltage V1 of the motor drive power supply line 13 rises and becomes higher than the output voltage Vc from the step-up / step-down circuit 34 (V1> Vc). At this time, the power from the precharge circuit 17 is also supplied to the inverter operation circuit 18 (pre-driver IC). When the charge of the capacitor 16 is completed and the voltage supplied to the inverter operation circuit 18 becomes sufficiently high, the semiconductor relays 14 and 15 can be driven, and the arithmetic unit 31 issues an ON command. As a result, the switches 14A and 15A are switched from OFF to ON, and the semiconductor relays 14 and 15 are turned ON. After conduction of the semiconductor relays 14 and 15, the inverter operation circuit 18 can be operated with the power supplied via the semiconductor relays 14 and 15. Further, since the precharge circuit 17 can not flow a large current, it is necessary to turn off the precharge switch 17B when operating the motor 11. From this, after conduction of the semiconductor relays 14 and 15, before the control of the inverter 12 is started, the precharge switch 17B is turned off (see FIG. 4).

  Thus, in the present embodiment, power supply line 20 electrically connecting inverter operating circuit 18 to power supply 3 and inverter operating circuit 18 electrically connected to power supply 3 via step-up / step-down circuit 34 And an auxiliary power supply line 36 electrically connected to the power supply line 20. Thus, the inverter operation circuit 18 can supply power also from the buck-boost circuit 34 in addition to the power supply 3. In addition to this, one of the voltage value (power supply voltage Vb) supplied with power from the power supply 3 and the voltage value (output voltage Vc) supplied with power from the step-up / step-down circuit 34 is larger in the inverter operating circuit 18 Power supply from Specifically, when the power supply voltage Vb of the power supply 3 is larger than the output voltage Vc of the step-up / step-down circuit 34 (Vb> Vc), the inverter activation circuit 18 performs the precharge circuit when the semiconductor relays 14 and 15 are off. The power supply 3 receives power supply via the power supply line 17 and the power supply line 20, and receives power supply from the power supply 3 via the semiconductor relays 14 and 15 and the power supply line 20 when the semiconductor relays 14 and 15 are ON. Further, inverter operation circuit 18 supplies power from step-up / step-down circuit 34 via auxiliary power supply line 36 when power supply voltage Vb of power supply 3 is smaller than output voltage Vc of step-up / step-down circuit 34 (Vb <Vc). Receive

  Therefore, even when the power supply voltage Vb drops to a voltage at which the inverter operation circuit 18 can not operate, the output voltage Vc is supplied to the inverter operation circuit 18 from the step-up / step-down circuit 34. As a result, inverter operating circuit 18 can expand the low voltage region of operable power supply voltage Vb, and can stabilize the operation of inverter operating circuit 18 in the low voltage state of power supply 3.

  Further, inverter operation circuit 18 includes a power supply line 20 (first path) electrically connected to power supply 3, and an auxiliary power supply line 36 (second power supply line) electrically connected to power supply 3 via step-up / step-down circuit 34. And the inverter operating circuit 18 receives power from the power supply 3 through the power supply line 20 when the power supply voltage Vb of the power supply 3 is higher than the output voltage Vc of the step-up / step-down circuit 34. When the output voltage Vc of 34 is higher than the power supply voltage Vb of the power supply 3, the auxiliary power supply line 36 receives power supply from the buck-boost circuit 34, and the buck-boost circuit 34 supplies power to the inverter operating circuit 18 and the arithmetic unit 31. Supply.

  Therefore, in the normal state where power supply voltage Vb is higher than output voltage Vc of voltage step-up / step-down circuit 34, step-up / step-down circuit 34 supplies power to arithmetic device 31, and power supply voltage Vb is higher than output voltage Vc of voltage step-up / step-down circuit 34. Power is supplied to both the inverter operating circuit 18 and the arithmetic unit 31 in a low voltage state. Thereby, the operation of both the inverter operating circuit 18 and the arithmetic unit 31 in the low voltage state of the power supply 3 can be stabilized. In addition to this, since the step-up / step-down circuit 34 for supplying power to the arithmetic unit 31 can be used as a backup power source in the low voltage state, there is no need to provide a new power supply for the low voltage state. The cost rise can be suppressed.

  Further, the auxiliary power supply line 36 joins the power supply line 20 and is electrically connected to the inverter operation circuit 18, and is provided between the power supply 3 and the junction point Pj of the power supply line 20 and the auxiliary power supply line 36. A first diode 21 and a second diode 37 provided between the junction Pj and the step-up / step-down circuit 34 are provided.

  Thus, only by adding the auxiliary power supply line 36 and the two diodes 21 and 37, power is supplied to the inverter operation circuit 18 from whichever of the power supply 3 and the step-up / step-down circuit 34 has a larger voltage value. can do. As a result, the operation of the inverter operating circuit 18 in the low voltage state of the power supply 3 can be stabilized with a simple circuit configuration.

  Further, in the present embodiment, the precharge circuit 17 supplies power to the capacitor 16 and the inverter operation circuit 18 via the power supply line 20 (first path). Thereby, the semiconductor relays 14 and 15 can be driven using the existing precharge circuit 17. When the semiconductor relays 14 and 15 do not conduct, the precharge switch 17 B is turned ON, and the power supply voltage Vb is supplied to the inverter operation circuit 18 via the precharge circuit 17. As a result, a voltage (high side gate voltage VgH) higher than the power supply voltage Vb can be supplied to the semiconductor relays 14 and 15 from the booster circuit 18A of the inverter operation circuit 18 to drive the semiconductor relays 14 and 15. After the semiconductor relays 14 and 15 are turned on, the precharge switch 17B is turned off to supply the power supply voltage Vb to the inverter operation circuit 18 via the semiconductor relays 14 and 15. Thus, even after the conduction of the semiconductor relays 14 and 15, the driving of the semiconductor relays 14 and 15 can be continued by the voltage supplied from the booster circuit 18A of the inverter operation circuit 18.

  According to the present embodiment, it is possible to supply the power of the power supply 3 to the inverter operation circuit 18 when the semiconductor relays 14 and 15 are OFF, without adding new components to the existing circuit configuration. It becomes.

  For example, as a configuration for supplying power of the power supply 3 to the inverter operation circuit 18 when the semiconductor relays 14 and 15 are OFF, the configuration of the comparative example shown in FIG. 7 can be considered. The electric brake device 41 according to the comparative example shown in FIG. 7 supplies power from the power supply 3 to the inverter operating circuit 18 through the power supply line 42 connected to the front stage (the power supply 3 side) of the semiconductor relays 14 and 15 as another path. , Drive the fail safe relays (semiconductor relays 14 and 15). However, when the inverter operating circuit 18 and the power supply 3 are constantly connected, current flows in the inverter operating circuit 18 when the motor 11 is not started, and unnecessary power consumption occurs. Therefore, in order to prevent unnecessary power consumption, the arithmetic device 43 needs to cut off the power supply line 42 when the semiconductor relays 14 and 15 are turned off. That is, it is necessary to add a circuit element such as the switch 44 to the power supply line 42 at a stage before the diode 21. On the other hand, in the present embodiment, since the semiconductor relays 14 and 15 play the role of switches necessary in the front stage of the diode 21, it is not necessary to add a circuit.

  In the embodiment, two semiconductor relays 14 and 15 connected in series with each other are provided between the power supply 3 and the inverter 12. The present invention is not limited to this. For example, one of the two semiconductor relays 14 and 15 may be omitted. In this case, it is preferable to replace the semiconductor relay 15 with a diode for backflow prevention.

  In the above embodiment, one first diode 21 is connected in the middle of the power supply line 20, but a plurality of first diodes may be connected in series. Similarly, although one second diode 37 is connected in the middle of the auxiliary power supply line 36, a plurality of second diodes may be connected in series.

  In the said embodiment, the case where required damping | braking force was calculated from the stroke amount of the brake pedal which the stroke sensor 6 detected was mentioned as the example, and was demonstrated. However, the present invention is not limited to this. For example, the necessary braking force may be calculated from the braking force required from the braking request from the other external unit mounted on the vehicle. Alternatively, the required braking force may be calculated by detecting the state of the road on which the vehicle is located.

  In the above embodiment, two diodes 21 and 37 are used, so that the inverter operation circuit 18 receives power supply from whichever of the power supply 3 and the step-up / step-down circuit 34 has a larger voltage value. The present invention is not limited to this. For example, two switches may be provided instead of the two diodes 21 and 37, and the arithmetic device 31 may compare the power supply voltage Vb with the output voltage Vc of the step-up / step-down circuit 34. The two switches may be switched on and off.

  In the above embodiment, the case where a MOSFET is used as the switching element S has been described as an example, but another switching element such as an IGBT may be used.

  As a motor control device based on the embodiment described above, for example, the one described in the following can be considered.

  In a first aspect, an electric motor, an inverter for driving the electric motor, an inverter operation circuit for operating the inverter, a storage device for supplying power to the inverter operation circuit, and an arithmetic device for controlling the inverter operation circuit A step-up / step-down circuit for supplying power to the arithmetic device by raising or lowering a voltage of the storage device, a first path for supplying power to the inverter operation circuit from the storage device, and the inverter from the step-up / step-down circuit A second path for joining the first path to the operating circuit and supplying power; a first path provided on the first path between the first path, a junction of the second path, and the storage device A diode, a second diode provided on the second path between the junction and the step-up / step-down circuit, a branch from between the power storage device and the first diode, and Provided between a third path for supplying the power of the device to the inverter, the branch point of the third path in the first path, and the storage device, and supplying power from the storage device to the motor, or A semiconductor relay which switches whether to shut off, a booster circuit which is provided in the inverter operation circuit and raises a voltage inputted to the inverter operation circuit to supply power to the semiconductor relay and a switching element of the inverter; A motor control device, comprising: a precharging circuit for supplying power of the storage device to the capacitors provided in three paths without passing through the semiconductor relay, wherein the inverter operating circuit is configured such that the voltage of the storage device is the voltage of the storage device. When the semiconductor relay is off when the voltage is higher than the voltage of the step-up / down circuit, the precharge circuit and the first path Via the semiconductor relay and the first path, when the semiconductor relay is on, the voltage of the storage device is the voltage of the step-up / step-down circuit. When the voltage is smaller than the voltage, power is supplied from the step-up / step-down circuit via the second path.

  Moreover, as a brake device based on the embodiment described above, for example, the one described in the following can be considered.

  A second aspect of the present invention is a brake apparatus comprising an electric motor that outputs a braking force in accordance with a braking request signal, and an electric motor control device that controls the electric motor, wherein the electric motor control device drives the electric motor An inverter, an inverter operation circuit for operating the inverter, a storage device for supplying power to the inverter operation circuit, an arithmetic device for controlling the inverter operation circuit, and the voltage of the storage device being increased or decreased A step-up / step-down circuit for supplying power, a first path for supplying power from the storage device to the inverter operation circuit, and a step for joining the first path from the step-up / step-down circuit to the inverter operation circuit to supply power. A first diode provided on the first path between the second path, the first path, a junction of the second path, and the power storage device; A second diode provided on the second path between the power supply and the step-up / down circuit, and a third path which branches from between the power storage device and the first diode and supplies the power of the power storage device to the inverter And a semiconductor relay provided between the branch point of the third path in the first path and the power storage device, which switches whether power is supplied from the power storage device to the motor or cut off, and the inverter operation The semiconductor relay is provided in a booster circuit which is provided in a circuit and raises the voltage input to the inverter operation circuit to supply power to the semiconductor relay and the switching element of the inverter, and a capacitor provided in the third path. And a precharging circuit for supplying the power of the storage device without passing through, and the inverter operating circuit is configured to increase the voltage of the storage device. If the voltage is higher than the voltage of the pressure circuit, the power supply of the power storage device is supplied via the precharge circuit and the first path when the semiconductor relay is OFF, and the semiconductor relay is received when the semiconductor relay is ON. And the electric power supplied from the storage device via the first path, and when the voltage of the storage device is smaller than the voltage of the step-up / step-down circuit, the power from the step-up / step-down circuit via the second path It is characterized by receiving supply.

  According to a third aspect, in the second aspect, the power storage device supplies power to a starting device of an internal combustion engine.

1 Electric brake device (brake device)
3 Power supply (power storage device)
5 Starter motor (starter)
11 motor 12 inverter 13 power supply line (route 3)
14, 15 Semiconductor relay 16 Capacitor 17 Precharge circuit 18 Inverter operation circuit 20 Power supply line (first path)
21 first diode 31 arithmetic unit 34 step-up / down circuit 35 regulator 36 auxiliary power supply line (second path)
37 2nd diode

Claims (1)

Electric motor,
An inverter for driving the motor;
An inverter operating circuit for operating the inverter;
A storage device for supplying power to the inverter operation circuit;
An arithmetic unit for controlling the inverter operation circuit;
A step-up / step-down circuit which supplies the power to the arithmetic unit by raising or lowering the voltage of the storage device;
A first path for supplying power from the storage device to the inverter operation circuit;
A second path for joining the first path from the step-up / step-down circuit to the inverter operation circuit to supply power;
A first diode provided on the first path between the first path, a junction of the second path, and the power storage device;
A second diode provided on the second path between the junction and the buck-boost circuit;
A third path branched from between the power storage device and the first diode and supplying power of the power storage device to the inverter;
A semiconductor relay provided between a branch point of the third path in the first path and the power storage device, which switches whether power is supplied from the power storage device to the motor or is shut off;
A booster circuit provided in the inverter operation circuit, which raises the voltage input to the inverter operation circuit to supply power to the semiconductor relay and the switching element of the inverter;
A motor control device, comprising: a precharging circuit that supplies power of the power storage device to the capacitor provided in the third path without passing through the semiconductor relay.
The inverter operating circuit is
If the voltage of the storage device is greater than the voltage of the buck-boost circuit,
When the semiconductor relay is off, power is supplied from the power storage device via the precharge circuit and the first path,
When the semiconductor relay is ON, power is supplied from the power storage device via the semiconductor relay and the first path,
When the voltage of the storage device is smaller than the voltage of the step-up / step-down circuit,
A motor control device characterized in that power is supplied from the step-up / step-down circuit through the second path.

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