JPH02155405A - Controller for motor-driven vehicle - Google Patents

Abstract

PURPOSE:To enable a predetermined acceleration or deceleration of speed with respect to variations in air gap between a linear induction motor and a reaction plate and the gradient railway line by detecting the real acceleration or deceleration of a train, and controlling the train driving motor so that the real acceleration or deceleration coincides with a target acceleration or deceleration. CONSTITUTION:When a train is moved, an acceleration/deceleration detection circuit 6 detects a real acceleration alpha by an input power drive command 10 and a train speed signal 9. A reference acceleration/deceleration generation circuit 7 generates a target acceleration alphaP, an operation part 4 compares the real acceleration alpha with the alphaF, and sends its deviation to an arithmetic circuit 5. The circuit 5 calculates a control signal with the deviation being zero, and controls an inverter 2. Thus, it can control the train at a predetermined acceleration/deceleration against variations in the air gap between the train linear induction motor and the ground reaction plate and the gradient of railway line.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a control device for an electric vehicle, and is particularly effective for use in a linear induction motor applied 'Rlh vehicle.
The present invention relates to a control device for an electric vehicle suitable for use in obtaining predetermined acceleration/deceleration.

[Conventional technology] A control device for an electric vehicle according to the conventional technology controls a vehicle disturbance motor based on a speed signal of one train, a load signal of a vehicle, and a power running command or a brake command from a master controller. It is something. DESCRIPTION OF THE PREFERRED EMBODIMENTS An example of a control device for an electric vehicle according to this type of conventional technology will be described below with reference to the drawings.

FIG. 3 is a block diagram showing the configuration of an example of the prior art. In FIG. 3, 1 is a control device, 2 is an inverter device, 3 is a gate quick-acting device, 4 is an arithmetic unit, 5 is an arithmetic circuit, and 8
is a linear induction motor, 12 is a voltage detection device,
14 is a current detection device.

16 is a load detector, 17 is a load detection device, 19 is a train speed detector, 20 is a reaction plate, 21 is a rail,
22 is a gap, 23 is a car body, 24 is a trolley, 25 is a wheel, 2
6 is a main controller.

In the prior art shown in FIG.
and inverter devices 2 and 5 that convert direct current from the overhead contact line into three-phase alternating current and apply it to the motor 8.
It is comprised of a gate displacement device 3 that controls the switching elements constituting the motor, a voltage detection device 12 that detects the 1M1 lane voltage, and a current detection device that detects the input current of the motor 8.

The control device 2 configured in this manner is configured to control the bogie 2 of the vehicle body 23.
4 and the contact line voltage signal 1 from the voltage detection device 12.
3, the passenger load signal 18 from the load detection device 17, and the train speed signal 9 from the train speed detector 19,
When the power running command 10 is given from the master controller 26, the brake command 11 is
is given, the inverter device 2 is controlled based on the calculation result of the calculation unit 4 based on a preset control method so as to obtain the target deceleration, and its output, 3-phase AC, is controlled. The motor voltage, motor current, and slip frequency of the linear induction motor 8 are controlled.

The electric vehicle obtains thrust between the linear induction motor 8 on the vehicle and the reaction plate 20 installed on the ground with an air gap 22, using the above-mentioned motor voltage, motor current, and suberi frequency. acceleration or deceleration control. The gap 22 is formed between the reaction plate 20 installed in the rail 21 and the linear induction motor 8 installed on the train, and is caused by the sinking of the rail when the train is running, the car @ 25 It fluctuates due to wear, etc., and due to long-term use, etc. Therefore, the one-herc characteristic of the linear induction motor 8 changes, and the acceleration/deceleration characteristic of the vehicle also changes.

Generally, the motor torque for acceleration/deceleration of a vehicle is controlled by setting the motor voltage, motor current, etc. based on the torque characteristics of the linear induction motor 8. Therefore, in order to compensate for acceleration/deceleration, A load detection device 17 is provided, and a load signal as a detection signal is used as part of the signal for setting the motor voltage and motor current.

Control of an electric vehicle according to the conventional technology configured as described above involves adjusting the motor voltage of the linear induction motor 8 and the motor voltage so that a predetermined motor torque is achieved regardless of whether the track condition is up or down. It sets the current, etc., and the acceleration/deceleration changes depending on the line distribution. The above-mentioned conventional technology does not take this point into consideration, and also does not take into account the change in acceleration/deceleration of the vehicle due to the change in the gap 22 between the linear induction motor 8 and the reaction plate 20 mentioned above. This is something that has not been done.

As for the conventional technology related to the above-mentioned control device for electric vehicles, for example, "Development of linear motor electric trains [III] J The techniques described under the title, etc. are known.

[Problems to be Solved by the Invention] The above-mentioned conventional technology quickly compensates for fluctuations in acceleration and deceleration of the vehicle due to fluctuations in the gap between the on-board linear induction motor and the ground reaction plate, and changes in the shape of the reaction plate. Furthermore, there was a problem in that no consideration was given to compensation for fluctuations in acceleration/deceleration due to uphill and downhill slopes of the track.

An object of the present invention is to solve the problems of the prior art, and to solve the problems of the prior art, even when there are factors that change the acceleration/deceleration of the vehicle due to changes in the gap between the linear induction motor and the reaction plate, changes in the gradient of the track, etc. An object of the present invention is to provide a control device for an electric vehicle that can obtain a predetermined acceleration/deceleration.

[Means for Solving the Problems] According to the present invention, the object is to detect the actual acceleration/deceleration of a train, and to adjust the train so that the actual acceleration/deceleration coincides with a preset target acceleration/deceleration. This is achieved by controlling the motor for driving the driver, for example, if the motor is an induction motor, by controlling the motor voltage, motor current, and slip frequency of the motor.

[Operation] A train acceleration/deceleration detection circuit is provided in the train disturbance motor control device, and this acceleration/deceleration detection circuit always detects the actual acceleration/deceleration of the train.

Then, the control device compares the detected actual acceleration/deceleration of the train with a preset target acceleration/deceleration, and adjusts the motor voltage, motor current, and , control frequency, etc.

Thereby, the train will be controlled at a predetermined target acceleration/deceleration even if there is a variable factor in the acceleration/deceleration.

[Embodiment] Hereinafter, an embodiment of a control device for an electric vehicle according to the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of essential parts of an embodiment of the present invention, and the second is a diagram illustrating various signals to explain its operation. In FIG. 1, 6 is an acceleration/deceleration detection circuit, 7 is a reference acceleration/deceleration generation circuit, and other symbols are the same as in FIG. 3.

One embodiment of the present invention shown in FIG. 1 is different from the conventional one explained in FIG. However, in other respects, the structure is similar to the conventional technology.

The calculation unit 4 of the control device 1, via the gate drive device 3,
Controls the gates of switching elements constituting the inverter device 2, converts direct current from the overhead contact line into three-phase alternating current,
It is supplied to the linear induction motor 8. The calculation unit 4 receives a power running command, a brake command, and a train speed signal 9 from the master controller, and calculates and generates a control signal to be given to the gate drive device 3 described above based on these signals.

In one embodiment of the present invention shown in FIG. 1, a power running command 10 is now inputted from the main controller to the calculation section 4, and the three-phase alternating current of the inverter device 3 controlled by the output is sent to the linear induction motor 8. When the applied train starts running, the acceleration/deceleration detection circuit 6 detects the actual acceleration α of the train based on the input power running command 10 and the train speed signal 9.

The reference acceleration/deceleration generation circuit 7 generates a target acceleration α2 with a certain time constant t to reduce shock when starting the train, based on the input command value of the power running command 1o. Thereafter, while the power running command 10 is being input, the calculation unit 4
internally compares the actual acceleration α of the train mentioned above and the target acceleration α9, and calculates the deviation Δα (Δα=α, −
α) is calculated and provided to the calculation circuit 5. The arithmetic circuit 5 calculates a control signal to be output to the gate drive circuit 3 so that this deviation Δα is always the minimum, that is, zero, and thereby controls the inverter device 2. That is, as a result, the motor voltage, motor current, and slip frequency of the linear induction motor 8 are controlled so that the aforementioned deviation Δα becomes zero. Note that the arithmetic circuit 5 includes an arithmetic circuit that limits a control signal for providing a control signal commensurate with the control capability of the inverter device 2 to the gate drive device.

FIG. 2 shows the movements of the target acceleration α, the actual acceleration α of the train, and the deviation Δα between them at the start of power running of the train and when the acceleration fluctuates during running. According to the embodiment of the present invention, the fluctuations in the actual acceleration of the train that occur at the start of acceleration and during acceleration running are as shown in FIG.
Since the deviation from the target value is detected and the deviation is immediately controlled to become zero, the train can be controlled so that the acceleration always matches the target acceleration.

Furthermore, when a brake command 11 is given from the master controller, the control device 1 naturally compares the deceleration that matches the brake command value with the actual deceleration of the train, and minimizes the deviation between them. So that the linear induction motor 8
control.

According to the above-described embodiment of the present invention, the acceleration/deceleration can be maintained at a predetermined value even in response to fluctuation factors in the acceleration/deceleration, such as changes in the air gap between the on-board linear induction motor and the reaction plate on the ground, and the slope of the track. It is possible to control trains.

The above embodiment of the present invention was described as applying the present invention to the control of an electric vehicle using a linear induction motor, but the present invention is also applicable to the control of an electric vehicle using a normal induction motor or a DC motor. It can also be applied to That is, a normal induction motor,
In the control of electric vehicles that use DC motors, etc., the problem with using the linear induction motor described above, which is the variation in acceleration/deceleration caused by the variation in the gap between the linear induction motor and the reaction plate, is However, it is not possible to eliminate fluctuations in acceleration/deceleration due to track slope conditions. Also in this case.

By applying the present invention, even in the control of electric vehicles using ordinary induction motors, DC motors, etc.
It becomes possible to eliminate fluctuations in the acceleration/deceleration of the train due to track slope conditions and run the train at a predetermined acceleration/deceleration.

[Effects of the Invention] As explained above, according to the present invention, the acceleration/deceleration of one train can be controlled to the target acceleration/deceleration.
When the present invention is applied to an electric vehicle using a linear induction motor, stable vehicle performance can be maintained over a long period of time despite changes in the gap between the linear induction motor on the vehicle and the reaction plate on the ground, and changes in the shape of the reaction plate. This has the effect of reducing gap maintenance.

Furthermore, according to the present invention, control that takes into account slope conditions can be performed naturally when issuing a brake command when traveling on an uphill slope, and when issuing a power running command when traveling on a downhill slope, so that unnecessary power consumption is avoided. This has the effect of reducing power consumption.

Furthermore, according to the present invention, it is possible to obtain a predetermined acceleration/deceleration even in response to changes in the passenger load of the train, so the passenger load detection device conventionally installed in trains can be dispensed with, and inexpensive electric vehicles can be used. The present invention has the effect that maintenance of the control device can be reduced.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of essential parts of an embodiment of the present invention, FIG. 2 is a diagram explaining various signals to explain its operation, and FIG. 3 is a block diagram showing the configuration of an example of the prior art. It is. 1...Control device, 2...Inverter device, 3...Gate IH operation device, 4...Fort control unit, 5...Calculation Circuit, 6...Acceleration/deceleration detection circuit, 7...Reference acceleration/deceleration generation circuit, 8
・・・・・・Linear induction motor, 12...
...Voltage detection device, 14...Current detection device 5
16...Load detector, 17...Load detection device, 19...Train speed detector, 20...
...Reaction plate, 21...Rail,
22...Gap, 23...Vehicle body, 24.
...Truck, 25...Wheels, 26...
...Main controller. Figure 1 Figure 2

Claims (1)

[Claims] 1. In a control device for an electric vehicle, means for detecting the actual acceleration/deceleration of a train based on a signal from a train speed detector installed in the train and signals of a power running command and a brake command for the train. and controlling a train drive motor so that the actual acceleration/deceleration of the train detected by the means becomes a target acceleration based on a preset power running command value or a target deceleration based on a preset brake command value. An electric vehicle control device featuring: 2. The electric vehicle control device according to claim 1, wherein the train drive motor is an induction motor or a linear induction motor. 3. The second aspect of the present invention is characterized in that the train drive motor is controlled by controlling the motor voltage, motor current, and slip frequency of the motor.
A control device for an electric vehicle as described in Section 1.