KR100993365B1 - Motor drive system of green car - Google Patents

Abstract

In controlling the motor drive of the environmental vehicle, it is to minimize the motor loss in the field weakening area, to secure a wide constant output area to provide a stable output and high efficiency at high speed operation.

The present invention includes an inverter for converting a DC voltage supplied from the battery into a three-phase (U, V, W) voltage by switching by a battery, a motor and a PWM signal as a main power source, and wound around the rotor core of the motor. Potato coil; It controls the phase change operation of the inverter by outputting a PWM signal for controlling the behavior of the motor according to the motor behavior control signal applied from the HCU, the battery status information applied from the BMS, and the torque control signal of the motor applied from the TCU. A MCU for controlling a voltage supply to the potato coil in a constant output region in which a driving of the motor is weakly controlled; In accordance with a control signal applied from the MCU in the constant output region in which the driving of the motor is weakly controlled provides a motor drive device for an environmental vehicle including a current controller for supplying the battery power to the potato coil.

Environmental vehicle, motor, potato coil, rotor core, magnetic flux offset

Description

Motor Drive Device for Environmental Vehicles {MOTOR DRIVE SYSTEM OF GREEN CAR}

1 is a configuration diagram of an embodiment of a driving device for a motor for an environmental vehicle according to the present invention.

2 is a view schematically showing the structure of a motor for an environmental vehicle according to the present invention;

3 is a schematic flowchart for executing drive control of a motor for an environmental vehicle according to the present invention;

4 is a diagram showing a motor characteristic curve obtained through drive control of a motor for an environmental vehicle according to the present invention.

5 is a view showing driving characteristics of a conventional environmental vehicle motor.

<Description of the symbols for the main parts of the drawings>

10; Battery 20; inverter

30; Motor 40; MCU

50; Current controller 60; Slip contactor

70; Potato Coil

The present invention relates to an environmental vehicle, and more particularly, to a motor driving apparatus for an environmental vehicle that minimizes motor loss in the field weakening area and secures a wide constant output area to provide stable output and high efficiency at high speed. It is about.

Environmental vehicle motors require a high starting torque and a wide operating range, which are not usually met by conventional motors.

That is, in the case of a general motor, if the starting torque is high, high speed operation is impossible, and in order to operate the high speed, the starting torque needs to be reduced.

In addition, when the designer sets the base speed (ω _b ) during the design of the motor, the constant power section is less than or equal to 2 times the base speed at the base speed, considering that the general motor constant speed ratio (CPSR) is 2 or less. Becomes

Unlike general motors, motors applied to environmental vehicles can achieve the desired output even in the high speed range of the motor if the driver can secure a wide constant power range in terms of vehicle speed maintenance. A lot.

Therefore, the positive to the field-weakening control in the output area, but the control by increasing the D-axis current (I _d), and acts as a loss in the motor by increasing the D-axis current (I _d) When thereof, so that the motor A disadvantage arises that reduces the efficiency.

The characteristics of the motor will be described with reference to FIG. 5 as follows.                         

The characteristics of each motor operating region are classified into a constant torque region (I), a constant output region (II) and a characteristic region (III). In the constant torque region (I), a constant magnetic flux flows so that the constant torque is maintained. When the base speed (ω _b ) is reached, the magnetic flux (Φ) must be weakened because the voltage (V) is constant to increase the speed of the motor according to the relationship of V = KΦω.

In other words, it is necessary to control the weak field.

The constant output area II is a section in which the field weakening is controlled by weakening the magnetic flux Φ, and by controlling the current by increasing the D-axis current I _d in order to reduce the magnetic flux Φ, high speed operation is possible.

The characteristic region III is a constant voltage operation region in which the use efficiency of the motor is lowered.

As described above, in controlling the motor applied to the environmental vehicle, weak field control is performed by increasing the D-axis current I _d in order to control the high speed operation in the constant output region. It acts as a loss of, and thus acts as a disadvantage that the efficiency of the motor is lowered.

The present invention has been invented to solve the above problems, the object of which is to control the driving of the motor applied to the environmental vehicle to minimize the motor loss in the field weakening area, secure a wide constant output area during high-speed operation In order to achieve a stable output and high efficiency.                         

In addition, by modifying the rotor structure of the motor applied to the environmental vehicle, by further winding the potato coil to generate a magnetic flux in the opposite direction to the magnetic flux generated in the permanent magnet of the rotor, the field weakening control to minimize the magnitude of the total magnetic flux It extends the output area and provides high speed operation and high efficiency.

The present invention for realizing the above object includes an inverter for converting the DC voltage supplied from the battery into a three-phase (U, V, W) voltage by switching by a battery and a motor and a PWM signal as the main power source,

delete

delete

Potato coil wound around the rotor core of the motor; It controls the phase change operation of the inverter by outputting a PWM signal for controlling the behavior of the motor according to the motor behavior control signal applied from the HCU, the battery status information applied from the BMS, and the torque control signal of the motor applied from the TCU. A MCU for controlling a voltage supply to the potato coil in a constant output region in which a driving of the motor is weakly controlled; It provides a motor drive device for an environmental vehicle, characterized in that it comprises a current controller for supplying the power of the battery to the potato coil is operated in accordance with a control signal applied from the MCU in the constant output region in which the driving of the motor is weak field controlled. .

delete

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, a driving control apparatus for a motor for an environmental vehicle according to the present invention includes a battery 10, an inverter 20, a motor 30, an MCU 40, a current controller 50, and a sleep contactor 60. ) And potato coil 70.

The battery 10 supplies driving power to the motor 30 applied to the environmental vehicle as the main power source.

The inverter 20 is composed of a plurality of Insulated Gate Bipolar Transistor (IGBT) switch elements, and the DC voltage supplied from the battery 10 is converted into three phases (U, V, W) by switching by a pulse width modulation (PWM) signal. The voltage is converted into a voltage and supplied as a phase voltage for driving the motor 30.

MCU 40 is a motor control unit (Motor Control Unit) signal of the motor behavior control applied from the HCU (Hybrid Control Unit) and the status information of the battery 10 applied from the BMS (Battery Management System), TCU (Torque Control) The phase change operation of the inverter 20 is controlled by outputting a PWM signal for controlling the behavior of the motor 30 according to the behavior torque control signal of the motor 30 applied from the unit.

The current controller 50 is operated according to a control signal applied from the MCU 40 at the time when expansion of the constant output region is required in the constant output region in which the driving of the motor 30 is weakly controlled. The voltage is supplied to the potato coil 70 of the motor 30.

The sleep contactor 60 stably transmits the power supplied through the current controller 50 to the potato coil 70 wound around the rotor of the motor 30.

The sleep contactor 60 is in sliding contact with the potato coil 70 and the power supply terminal.

Potato coil 70 is wound on the rotor of the motor 30, so that the magnetic flux in the opposite direction to the magnetic flux generated in the permanent magnet in the rotor is generated, the total magnetic flux is maximized by the offset of the magnetic flux in the constant power region Try to have a small value.

The potato coil 70 will be described in more detail with reference to FIG. 2 as follows.

Potato coil 70 is wound in each core groove 110 of the rotor core 100, the winding direction is wound in the opposite direction with respect to the core groove 110 neighboring each other.

The potato coil 70 wound on the rotor core 100 is wound so that magnetic fluxes opposite to each other are formed with the permanent magnets formed in the center direction corresponding to each core.

When the permanent magnet in the rotor has a polarity of 'N' winding direction of the potato coil 70 is rotated counterclockwise, when the permanent magnet in the rotor has a polarity of 'S' potato coil 70 Winding direction of the winding in the clockwise direction so that the magnetic flux generated in the permanent magnet (N pole, S pole) and the magnetic flux generated in the potato coil 70 are opposite to each other and the two magnetic flux is wound to offset.

Referring to the operation of controlling the motor drive in the present invention including the function as described above are as follows.

The MCU 40 outputs a PWM signal according to the behavior control signal of the environmental vehicle applied from the HCU, the state information of the battery 10 applied from the BMS, and the torque control signal applied from the TCU, thereby switching the phase change of the inverter 20. By controlling this, the drive of the motor 30 is controlled.

If the state of the drive of the motor 30 that controls the constant output area (S101) the torque and detects the speed (S102) setting the area of the motor 30, that of the 'T _a' as shown in Figure 4 It is determined whether the point ① is reached, at which the relationship between the torque and 'ω _a ' is formed (S103).

In the judgment of step S103, if the point ① is not reached, the control is maintained at the current constant output area. If the relationship between the torque and the speed is reached at the point ①, it is determined that the expansion of the constant power area is required. The MCU 40 outputs a control signal for controlling the current supply to the potato coil 70 to the current controller 50.

Accordingly, the current controller 50 supplies the current to the potato coil 70 wound around the rotor of the motor 30 with the voltage of the battery 10 according to the control signal applied (S104).

Accordingly, as shown in FIG. 2, the potato coil 70 wound around the rotor core of the motor 30 in the clockwise or counterclockwise direction is opposite to the magnetic flux generated in the permanent magnets formed in the rotor. By generating the magnetic fluxes of each other and canceling each other, the total magnetic flux generated in the rotor of the motor 30 is reduced (S105).

Therefore, field weakening control is performed in which the magnetic flux generated between the rotor and the stator of the motor 30 is substantially weakened to secure a wider constant output area, thereby ensuring high speed operation without generating a motor loss. S106).

That is, in the case of the weak field control through the current (Id) control as shown in FIG. 4, the constant output region is shifted to the characteristic region at the base velocity and the maximum velocity (ω1) as shown by 'A'. In the case of control of the weak field using 70, the constant output region is extended to the region of 'ω _c ' as in 'B', so that a stable output is secured at high speed.

As described above, the present invention secures a wider constant output area in controlling a motor applied to an environmental vehicle, thereby ensuring a stable output for high-speed driving of the vehicle, and does not require current control for weak field control. There is an effect that no loss occurs.

Claims (9)

delete delete delete delete In an environmental vehicle, It includes an inverter that converts the DC voltage supplied from the battery into three-phase (U, V, W) voltage by switching by the main power source battery, motor and PWM signal, Potato coil wound around the rotor core of the motor; It controls the phase change operation of the inverter by outputting a PWM signal for controlling the behavior of the motor according to the motor behavior control signal applied from the HCU, the battery status information applied from the BMS, and the torque control signal of the motor applied from the TCU. A MCU for controlling a voltage supply to the potato coil in a constant output region in which a driving of the motor is weakly controlled; And a current controller which is operated according to a control signal applied from the MCU in the constant output region in which the driving of the motor is controlled by the field weakening and supplies the battery power to the potato coil. The method of claim 5, Potato coil wound on the motor rotor is a motor drive device for an environmental vehicle, characterized in that the power is supplied by a slip contactor having a sliding contact method. delete delete delete

Images