JP2008086085A - Electric car controller - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve accurate anti-slip/skid control without using an expensive resolver for the speed detection of a permanent magnet synchronous motor. <P>SOLUTION: This electric car controller is provided with a pulse generator 5, which detects the revolutions of the permanent magnet synchronous motor 4, a sensorless vector control section 2, which estimates a rotor position of the synchronous motor 4 from a voltage command generated from a torque command value and a detection signal of a motor current supplied to the synchronous motor 4 and performs vector control from the estimated rotor position information, and an anti slip/skid control section 7, which estimates a slip condition between a wheel and a rail based on a speed signal calculated with an output pulse signal from the pulse generator 5 and adjusts the torque command value by adding acceleration torque or deceleration torque. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electric vehicle control apparatus using a pulse generator for detecting the number of revolutions of a permanent magnet type synchronous motor.

  FIG. 5 shows an example of an electric vehicle control apparatus using a conventional permanent magnet type synchronous motor.

  As shown in the figure, a conventional electric vehicle control apparatus 101 is generated based on a vector control unit 102 that receives a torque command value and executes vector control, and a voltage signal generated by the vector control unit 102. An inverter unit 103 driven by a PWM signal, a permanent magnet synchronous motor (PMSM) 104 whose rotation is controlled by the inverter unit, a resolver 105 for detecting a rotor position of the permanent magnet synchronous motor 104, A differential operation unit 106 that differentiates the rotor position detected by the resolver 105 and converts it into a speed signal, and an idling sliding control unit that inputs the speed signal calculated by the differential operation unit 106 and executes idling control. 107.

As is well known, when the permanent magnet synchronous motor 104 is vector-controlled, it is necessary not only to detect the speed of the rotor but also to detect its position. Conventionally, as shown in FIG. 5, a resolver 105 is used for position detection. The vector control unit 102 receives the position detection signal from the resolver 105 and executes vector control. In addition, the differential operation unit 106 differentiates the position detection signal to calculate a speed signal and supplies it to the idling / sliding control unit 107. The idling / sliding control unit 107 determines that idling has occurred in the wheel of the electric vehicle when the rate of change (acceleration) of the input speed signal exceeds a certain value, and generates a torque adjustment signal. The torque command value supplied to the vector control unit 102 is adjusted by the adjustment signal.
JP 2006-158046 A JP 2004-350389 A JP 2006-33911 A

  As described above, in the conventional electric vehicle control apparatus 101, the expensive resolver 105 is used for detecting the position of the rotor. However, this resolver 105 can detect the absolute position of the rotor of the permanent magnet type synchronous motor 104, but the position detection signal has a ripple. This ripple becomes noise, and the accuracy of the idling sliding control is improved. There is a problem of getting worse.

  In addition, in order to remove the ripples superimposed on the position detection signal of the resolver 105, a separate noise removal filter or the like is required, which not only complicates the apparatus configuration but also delays control. As a result, there was a problem that quick idling control became impossible.

  Thus, although it is conceivable to use a pulse generator instead of the resolver 105, the vector control of the permanent magnet synchronous motor cannot be performed with the speed pulse signal detected by the pulse generator.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an electric vehicle control device that enables accurate idling control without using an expensive resolver for speed detection of a permanent magnet synchronous motor. It is said.

  In order to achieve the above object, according to the first aspect of the present invention, there is provided an electric vehicle control apparatus that uses a permanent magnet type synchronous motor as a main motor and performs inverter control of the permanent magnet type synchronous motor. Estimating the rotor position of the permanent magnet type synchronous motor from a pulse generator for detecting the number of rotations, a voltage command generated from a torque command value and a detection signal of the motor current supplied to the permanent magnet type synchronous motor, Estimate the idling situation between wheels and rails based on the sensorless vector control unit that executes vector control based on the estimated rotor position information and the speed signal calculated using the output pulse signal from the pulse generator And an idle sliding control unit that adjusts acceleration torque or deceleration torque with respect to the torque command value.

  According to a second aspect of the present invention, there is provided an electric vehicle control apparatus that uses a permanent magnet type synchronous motor as a main motor and performs inverter control of the permanent magnet type synchronous motor, and a pulse generator that detects the rotational speed of the permanent magnet type synchronous motor; The rotor position of the permanent magnet synchronous motor is estimated from the voltage command generated from the torque command value and the motor current detection signal supplied to the permanent magnet synchronous motor, and the estimated rotor position information is Based on a sensorless vector control unit that executes vector control based on a speed signal calculated using an output pulse signal from the pulse generator, an idle state between a wheel and a rail is estimated, and acceleration with respect to the torque command value is performed. An idle running control unit that adjusts torque or deceleration torque, and an output pulse signal from the pulse generator, It is characterized in that it comprises a brake control device for generating a braking force signal for subtraction of braking force by estimating the sliding conditions between the rate of change wheel and rail.

  According to a third aspect of the present invention, there is provided an electric vehicle control apparatus that uses a permanent magnet type synchronous motor as a main motor and performs inverter control of the permanent magnet type synchronous motor, and a voltage command generated from a torque command value and the permanent magnet type synchronous motor. A sensorless vector control unit that estimates a rotor position of the permanent magnet synchronous motor from a detection signal of a motor current supplied to the motor, and executes vector control based on the estimated rotor position information; and A differential operation unit for differentiating the rotor position information to generate a speed signal, and based on the speed signal generated by the differential operation unit, the idling situation between the wheel and the rail is estimated, and an acceleration torque corresponding to the torque command value Alternatively, an idle running control unit that adjusts deceleration torque and a speed pulse signal obtained from the speed signal generated by the differential calculation unit are input, and the rate of change is input. It is characterized in that it comprises a brake control device for generating a braking force signal for subtraction of braking force by estimating the sliding conditions between Luo wheel and rail.

   According to a fourth aspect of the present invention, there is provided an electric vehicle control device that uses a permanent magnet type synchronous motor as a main motor and performs inverter control of the permanent magnet type synchronous motor, and a pulse generator that detects the rotational speed of the permanent magnet type synchronous motor; The rotor position of the permanent magnet synchronous motor is estimated from the voltage command generated from the torque command value and the motor current detection signal supplied to the permanent magnet synchronous motor, and the estimated rotor position information is Based on a sensorless vector control unit that executes vector control based on the speed signal calculated by using the output pulse signal from the pulse generator, the idling situation between the wheel and the rail is estimated, and the acceleration torque with respect to the torque command value Alternatively, an idling sliding control unit that adjusts deceleration torque and an output pulse from the pulse generator in a vehicle coasting state Wheel diameter correction unit for generating a speed signal for correcting the wheel diameter value of the wheel driven by the permanent magnet type synchronous motor using the speed signal calculated based on the number and the speed signal of the axle driven by another motor It is characterized by comprising.

  According to a fifth aspect of the present invention, in the electric vehicle control device according to any one of the first, second, and fourth aspects, the estimated motor rotational speed obtained by the sensorless vector control unit and the output pulse signal from the pulse generator are obtained. When the deviation from the rotational speed calculated by using is greater than or equal to an allowable value, a determination unit that determines that the system is abnormal is provided.

  According to the above configuration, since the pulse generator is used for speed detection of the permanent magnet type synchronous motor and the control is performed by sensorless vector control, not only an expensive resolver is required as in the prior art. Therefore, it is possible to control the idling with high accuracy. In addition, a filter for removing noise is not necessary, and the apparatus configuration can be simplified.

<First Embodiment>
FIG. 1 is a block diagram showing a first embodiment of an electric vehicle control apparatus according to the present invention.

  The electric vehicle control device 1a shown in FIG. 1 includes a sensorless vector control unit 2, an inverter unit 3 that drives and controls a permanent magnet synchronous motor (PMSM) 4 according to a three-phase voltage command from the sensorless vector control unit 2, and a permanent A pulse generator (PG) 5 that detects the rotation speed of the magnet synchronous motor 4 and generates an output pulse signal; a pulse-to-speed converter 6 that converts the pulse signal output from the pulse generator 5 into a speed signal; An idling sliding control unit 7 that inputs a speed signal from a pulse-to-speed converting unit 6 and executes idling sliding control, and a torque adjustment signal (acceleration torque or deceleration torque) output from the idling sliding control unit 7 is a torque command. An adder 8 that adjusts the torque command value by adding to the value, and a sensorless by detecting the three-phase output current supplied from the inverter 3 to the synchronous motor 4 And a current sensor 9 that outputs the vector control unit 2.

  The sensorless vector control unit 2 generates a d-axis and q-axis current command from the input torque command value, a d-axis current command generated by the current command generation unit 21, and a d-feedback. An ACR control unit 22 that generates a d-axis voltage command Vd by executing PI control (proportional / integral control) from the shaft current detection signal and a q-axis current command generated by the current command generation unit 21 are fed back. The ACR control unit 23 that executes PI control from the q-axis current detection signal to generate the q-axis voltage command Vq, and inputs the d-axis voltage command Vd and the q-axis voltage command Vq to input a three-phase voltage AC voltage command A coordinate conversion unit 24 that generates Vu, Vv, and Vw and supplies them to the inverter unit 3; a coordinate conversion unit 25 that inputs current signals Iu, Iv, and Iw obtained by detection by the current sensor 9 and performs coordinate conversion; , D The voltage command Vd, the q-axis voltage command Vq, the d-axis current detection signal Id, and the q-axis current detection signal Iq are input to estimate the phase of the rotor of the synchronous motor 4, and the phase estimation signal ^ θ is converted into the coordinate conversion unit 24. , 25 are respectively supplied to the phase estimation unit 26.

  The idling / sliding control unit 7 inputs the speed signal output from the pulse-to-speed converting unit 6 to estimate the idling state between the wheel and the rail, and adjusts the acceleration torque or the deceleration torque with respect to the torque command value.

  In the first embodiment having the above-described configuration, the pulse generator 5 is used for speed detection of the permanent magnet type synchronous motor 4, and the control is performed by sensorless vector control. Is not necessary, and it is possible to perform idling control with high accuracy. In addition, a filter for removing noise becomes unnecessary.

<Second Embodiment>
FIG. 2 is a block diagram showing the configuration of the second embodiment of the electric vehicle control apparatus according to the present invention. Note that the same components as those in FIG.

  A feature of the electric vehicle control device 1b in the second embodiment is that the pulse generator 5 provided in the permanent magnet type synchronous motor 4 is shared by the idle running control unit 7 and the brake control device 11.

  In other words, the output pulse signal detected by the pulse generator 5 is converted into a speed signal via the pulse-to-speed converter 6 and supplied to the idling / sliding controller 7, while being directly supplied to the brake controller 11. The brake control device 11 receives an output pulse signal from the pulse generator, generates a brake force signal based on the rate of change in rotation, and supplies the brake force signal to an air pressure control unit (not shown). As a result, it is possible to prevent the wheels from slipping when the brake is locked.

  In the conventional permanent magnet type synchronous motor, the vector control is executed by the signal from the resolver, and the brake control device 11 is executed by the output pulse signal from the pulse generator. In the second embodiment, one pulse generator is used. 5 can be shared, and the apparatus configuration can be simplified.

<Third Embodiment>
FIG. 3 is a block diagram showing the configuration of the third embodiment of the electric vehicle control apparatus according to the present invention.

  The electric vehicle control device 1c in the third embodiment is characterized in that a pulse generator for detecting the speed of the permanent magnet type synchronous motor 4 is not provided, and a speed signal is obtained from a rotor estimated position signal from a sensorless vector control unit. Thus, the brake control device 11 is supplied.

  That is, based on the differential operation unit 12 that generates a speed signal by differentiating the estimated rotor position information generated by the phase estimation unit 26 shown in FIG. 1, and the speed signal generated by the differential operation unit 12. Then, the idling condition between the wheel and the rail is estimated, and the idling / sliding control unit 7 for adjusting the acceleration torque or the decelerating torque with respect to the torque command value, and the speed pulse signal is generated from the speed signal generated by the differential calculation unit 12. A speed-to-pulse conversion unit 13; a brake control device 11 that inputs the generated speed pulse signal, generates a braking force signal that adjusts the braking force by estimating the sliding situation between the wheel and the rail from the rate of change; It is the composition provided with.

  In the third embodiment, since the pulse generator 5 is not provided as in the second embodiment, the configuration around the permanent magnet type synchronous motor 4 is further simplified.

<Fourth Embodiment>
FIG. 4 is a block diagram showing the configuration of the fourth embodiment of the electric vehicle control apparatus according to the present invention.

  A feature of the electric vehicle control apparatus 1d in the fourth embodiment is that a rotation speed signal for correcting a torque command is obtained based on a difference in wheel diameter.

  That is, a pulse → speed converter 6 that converts an output pulse signal from the pulse generator 5 into a speed signal, and a speed generated by the pulse → speed converter 6 based on the output pulse signal from the pulse generator 5 in a vehicle coasting state. A wheel diameter correction unit 14 for generating a rotation speed signal for correcting a wheel diameter value of a wheel driven by the permanent magnet type synchronous motor 4 using the signal and a speed signal of an axle driven by another motor, and a wheel diameter correction unit The torque command correction unit 15 that generates the torque command correction value by inputting the corrected rotation number signal generated in step 14 and the corrected rotation number signal from each wheel diameter correction unit, and the generated torque command correction are added. And an adding unit 16 for correcting the torque command.

  The wheel diameter correction unit 6 inputs the speed signal of the synchronous motor 4 output from the pulse-to-speed conversion unit 6 and also inputs the speed signals of the other three synchronous motors (not shown) to generate a corrected rotation speed signal. And supplied to the torque command correction unit 15. For example, when coasting when each motor is not outputting torque (when all wheels are not idling), the diameter of each wheel relative to the reference wheel diameter is calculated based on the difference in the speed signal of each wheel. The corrected rotation speed signal is calculated using the wheel diameter ratio.

  The torque command correction unit 15 inputs a correction signal from each wheel diameter correction unit, calculates a torque command correction value, and outputs it to the addition unit 16. The adder 16 corrects the torque command value with the torque command correction value and outputs it.

  According to the fourth embodiment, the idle running control and the wheel diameter correction can be performed by one pulse generator 5, and the device configuration can be further simplified.

<Other embodiments>
In each of the first, second, and fourth embodiments, the speed signal (motor rotational speed estimated value) calculated from the phase estimation signal obtained by the phase estimation unit 26 of the sensorless vector control unit 2 and the pulse generator 5 A rotational speed calculated using the output pulse signal may be input, and if the deviation is greater than or equal to an allowable value, a determination unit that determines that the system is abnormal may be provided.

  This makes it possible to detect an abnormality in the pulse generator 5 or an abnormality in the sensorless vector control unit 2 at an early stage.

It is a block diagram which shows the structure of 1st Embodiment of the electric vehicle control apparatus which concerns on this invention. It is a block diagram which shows the structure of 2nd Embodiment of the electric vehicle control apparatus which concerns on this invention. It is a block diagram which shows the structure of 3rd Embodiment of the electric vehicle control apparatus which concerns on this invention. It is a block diagram which shows the structure of 4th Embodiment of the electric vehicle control apparatus which concerns on this invention. It is a block diagram which shows an example of the conventional electric vehicle control apparatus.

Explanation of symbols

1a, 1b, 1c, 1d: Electric vehicle control device 2: Sensorless vector control unit 3: Inverter unit 4: Permanent magnet synchronous motor (PMSM)
5: Pulse generator (PG)
6: Pulse to speed conversion unit 7: Idling and sliding control unit 8: Addition unit 9: Current sensor 11: Brake control device 12: Differential operation unit 13: Speed → Pulse conversion unit 14: Wheel diameter correction unit 15: Torque command correction unit

Claims (5)

In an electric vehicle control device that uses a permanent magnet type synchronous motor as a main motor and performs inverter control of the permanent magnet type synchronous motor,
A pulse generator for detecting the rotational speed of the permanent magnet type synchronous motor;
A rotor position of the permanent magnet type synchronous motor is estimated from a voltage command generated from a torque command value and a motor current detection signal supplied to the permanent magnet type synchronous motor, and based on the estimated rotor position information. A sensorless vector control unit that executes vector control
An idle running control unit that estimates an idle state between a wheel and a rail based on a speed signal calculated using an output pulse signal from the pulse generator and adjusts an acceleration torque or a deceleration torque with respect to the torque command value; ,
An electric vehicle control device comprising: In an electric vehicle control device that uses a permanent magnet type synchronous motor as a main motor and performs inverter control of the permanent magnet type synchronous motor,
A pulse generator for detecting the rotational speed of the permanent magnet type synchronous motor;
A rotor position of the permanent magnet type synchronous motor is estimated from a voltage command generated from a torque command value and a motor current detection signal supplied to the permanent magnet type synchronous motor, and based on the estimated rotor position information. A sensorless vector control unit that executes vector control
An idle running control unit that estimates an idle state between a wheel and a rail based on a speed signal calculated using an output pulse signal from the pulse generator and adjusts an acceleration torque or a deceleration torque with respect to the torque command value; ,
A brake control device that inputs an output pulse signal from the pulse generator, generates a braking force signal that adjusts the braking force by estimating a sliding state between the wheel and the rail from the rate of change, and
An electric vehicle control device comprising: In an electric vehicle control device that uses a permanent magnet type synchronous motor as a main motor and performs inverter control of the permanent magnet type synchronous motor,
A rotor position of the permanent magnet type synchronous motor is estimated from a voltage command generated from a torque command value and a motor current detection signal supplied to the permanent magnet type synchronous motor, and based on the estimated rotor position information. A sensorless vector control unit that executes vector control
A differential operation unit for differentiating the estimated rotor position information to generate a speed signal;
Based on the speed signal generated by this differential operation unit, the idling state between the wheel and the rail is estimated, and an idling sliding control unit that adjusts acceleration torque or deceleration torque with respect to the torque command value,
A brake control device for inputting a speed pulse signal obtained from the speed signal generated by the differential operation unit and generating a braking force signal for adjusting the braking force by estimating a sliding situation between the wheel and the rail from the rate of change When,
An electric vehicle control device comprising: In an electric vehicle control device that uses a permanent magnet type synchronous motor as a main motor and performs inverter control of the permanent magnet type synchronous motor,
A pulse generator for detecting the rotational speed of the permanent magnet type synchronous motor;
A rotor position of the permanent magnet type synchronous motor is estimated from a voltage command generated from a torque command value and a motor current detection signal supplied to the permanent magnet type synchronous motor, and based on the estimated rotor position information. A sensorless vector control unit that executes vector control
Based on a speed signal calculated using an output pulse signal from the pulse generator, an idle running control unit that estimates an idle state between a wheel and a rail and adjusts acceleration torque or deceleration torque with respect to the torque command value;
Wheel diameter value of a wheel driven by the permanent magnet type synchronous motor using a speed signal calculated based on an output pulse signal from the pulse generator and a speed signal of an axle driven by another electric motor in a vehicle coasting state A wheel diameter correction unit that generates a speed signal for correcting
An electric vehicle control device comprising: In the electric vehicle control device according to any one of claims 1, 2, and 4,
When the deviation between the estimated motor rotational speed obtained by the sensorless vector control unit and the rotational speed calculated using the output pulse signal from the pulse generator is greater than or equal to an allowable value, a determination unit is provided that determines that the system is abnormal. ,
An electric vehicle control device characterized by that.

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