JP2000166003A - Controller for electric car - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a highly reliable, small and lightweight controller for electric vehicle. SOLUTION: A controller for electric vehicle comprises a power converter 11 for converting power supplied from a DC power supplies 1, 2 through filter circuit 6, 10 in order to drive a motor 12, the capacitor 10 of the through filter circuit 6, 10 connected in parallel with the power converter 11, and a circuit including a resistor 13 and a chopper 8 connected in parallel with the capacitor 10 in order to regulate the load of power being generated from a power generating brake at the time of brake operation herein a charging current of the capacitor 10 is fed through the resistor 13.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement in an electric vehicle control device which obtains braking power by using a motor as a generator at the time of traveling braking.

[0002]

2. Description of the Related Art FIG. 2 shows a main circuit configuration of an electric vehicle control device which is an example of a conventional motor control device.
"No. 509 of Cybernetics Use Symposium on Fourth Railway". The electric vehicle control device includes a disconnector 3 to which DC power is supplied from a DC overhead line 1 via a pantograph 2, a charge switch 5 having one terminal connected to the disconnector 3, and the other of the charge switches 5. , One terminal is connected to the other terminal of the reactor 6, one terminal is connected to the other terminal, and the other terminal is connected to the ground terminal, and the capacitor 10 is connected in parallel to the capacitor 10. And a power converter 11 for supplying power to the electric motor 12. The power converter 11 is a voltage-type power converter such as a VVVF inverter.

[0003] This electric vehicle control device also includes a resistor 4 connected in parallel to a charging switch 5, a resistor 7 having one terminal connected to the other terminal of the reactor 6, and another terminal of the resistor 7. A chopper device 8 having one terminal connected to the other terminal and the other terminal connected to the ground terminal;
And a flywheel diode 9 whose cathode is connected to one terminal of the resistor 7.

In the electric vehicle control device having such a configuration, DC power is supplied from the DC overhead line 1 via the pantograph 2. At the time of startup, the disconnector 3 is turned on. First, in order to suppress an excessive inrush current, the capacitor 10 of the filter circuit is charged through the charging resistor 4 and the reactor 6 of the filter circuit. Capacitor 10 smoothes the input voltage of power conversion device 11,
A harmonic filter of an input current of the power converter 11 is formed by forming a filter circuit. When the charging of the capacitor 10 is completed, the charging switch 5 is turned on, and the resistor 4 is short-circuited.
Thus, the electric vehicle control device can drive the electric motor 12 by the voltage / current controlled by the power conversion device 11 without using the resistor 4 as a load, and can obtain the driving power of the electric vehicle.

[0005] The electric motor 12 is used for accelerating the electric vehicle (during power running).
Operates as an electric motor, but when braking an electric car,
As in the case of acceleration, after the current interrupter 3 is turned on and the capacitor 10 is charged through the resistor 4 and the reactor 6, the charging switch 5 is turned on and the power converter 11 is controlled to operate as a generator. You. The electric power generated as the generator is supplied to another electric vehicle through the DC overhead line 1, and this braking operation is called a regenerative brake. However,
When another electric vehicle is not running or when the other electric vehicle does not consume power, it becomes impossible to continue a stable regenerative braking operation.

Therefore, for such a case, the resistor 7,
A power generation brake chopper device including a chopper device 8 and a flywheel diode 9 is provided. The power generation brake chopper device variably controls the resistance value of the resistor 7 by adjusting the chopping operation flow rate of the chopper device 8 so that the power generated by the generator 12 (motor) is consumed by the resistor 7. Has become. This braking operation is called a power generation brake.

[0007]

The conventional electric vehicle control device as described above requires a plurality of large-capacity resistors.
The problem is that the reliability is reduced and the size is increased. As an example of a technique to solve such a problem, after charging the filter capacitor, the converter is set to the power running side, the power running control operation is performed by the chopper, the circuit is opened from the power supply during braking, and the converter is set to the braking side. Japanese Patent Application Laid-Open No. 55-155504 discloses an electric vehicle control device in which a filter capacitor is discharged, and a control operation of dynamic braking is performed by a chopper, and a braking resistor and a charging resistor are used. Further, a control device for an electric vehicle that serves both as a braking resistor and a charging resistor is disclosed in Japanese Patent Application Laid-Open No. Hei 8-19101.

The present invention has been made in view of the above-mentioned circumstances, and has high reliability, small size and light weight by using both a resistor for charging a filter capacitor and a braking resistor. It is an object to provide an electric vehicle control device.

[0009]

According to a first aspect of the present invention, there is provided an electric vehicle control apparatus for converting electric power supplied from a DC power supply through a filter circuit to drive an electric motor; A capacitor that is connected in parallel to the filter circuit, and a circuit that is connected in parallel with the capacitor and that includes a resistor and a chopper device for adjusting the load of power generated by the power generation brake during braking, and A charging current is caused to flow through the resistor.

An electric vehicle control device according to a second aspect of the present invention is a power conversion device for converting power supplied from a DC power supply through a filter circuit to drive an electric motor, and the power conversion device connected in parallel to the power conversion device. A capacitor of the filter circuit, a series circuit of a resistor and a chopper device connected in parallel to the capacitor and adjusting a load of electric power generated by the power generation brake during braking, and a flywheel of the chopper device connected in parallel to the resistor And a switch circuit that connects a diode, a cathode of the flywheel diode, and one end of the resistor, and turns off a charge current through the resistor and the flywheel diode when the capacitor is charged.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below.
The description will be made based on the drawings showing the above. FIG. 1 is a block diagram showing a configuration of an embodiment of an electric vehicle control device according to the present invention. The electric vehicle control device includes a disconnector 3 to which DC power is supplied from a DC overhead line 1 via a pantograph 2.
And a reactor 6 having one terminal connected to the disconnector 3
, A charging switch 5 having one terminal connected to the other terminal of the reactor 6, and a capacitor 10 having one terminal connected to the other terminal of the charging switch 5 and the other terminal connected to the ground terminal. And a power converter 11 connected in parallel with the capacitor 10 and supplying power to the electric motor 12.
And

The electric vehicle control device also includes a resistor 13 having one terminal connected to the other terminal of the reactor 6.
And one terminal is connected to the other terminal of the resistor 13,
A chopper device 8 having the other terminal connected to the ground terminal;
An anode is connected to one terminal of the chopper device 8,
A flywheel diode 9 having a cathode connected to the other terminal of the charging switch 5;

The operation of the electric vehicle control device having such a configuration will be described below. In this electric vehicle control device, DC power is supplied from a DC overhead line 1 via a pantograph 2.
At the time of startup, the disconnector 3 is turned on. First, the capacitor 10 of the filter circuit is charged through the reactor 6 of the filter circuit, the resistor 13 and the flywheel diode 9 in order to suppress an excessive rush current. Capacitor 10
Smoothes the input voltage of the power converter 11 and forms an inverse L-shaped filter circuit with the reactor 6 to suppress harmonics of the input current of the power converter 11. Capacitor 10
Is completed, the charging switch 5 is turned on, and the series circuit of the resistor 13 and the flywheel diode 9 is short-circuited. Thus, the electric vehicle control device can control the voltage / voltage controlled by the power conversion device 11 without using the resistor 13 as a load.
The electric motor 12 can be driven by the electric current to obtain the driving power of the electric vehicle.

The electric motor 12 is used when the electric vehicle is accelerating (power running).
Operates as an electric motor, but when braking an electric car,
As in the case of acceleration, the disconnector 3 is turned on, and the capacitor 10 is charged through the reactor 6, the resistor 13, and the flywheel diode 9, and then the charging switch 5 is turned on, and the resistor 13 and the flywheel diode 9 are connected in series. The circuit is shorted. Thereby, the electric motor 12 is controlled by the power converter 11 to operate as a generator. The electric power generated as this generator is supplied to another electric vehicle through the DC overhead line 1 without flowing through the resistor 13, and this braking operation is called regenerative braking.

However, if no other electric vehicle is running,
Alternatively, in a case where another electric vehicle does not consume power, the power generation brake chopper device including the resistor 13, the chopper device 8, and the flywheel diode 9 adjusts the duty ratio of the chopping operation of the chopper device 8, The resistance of the resistor 13 is variably controlled, and the power generated by the generator 12 (motor) is consumed by the resistor 13. This braking operation is called a power generation brake.

[0016]

According to the electric vehicle controller of the first invention, the power converter converts the power supplied from the DC power supply through the filter circuit to drive the motor.
The capacitor of the filter circuit is connected in parallel to the power converter, and the circuit including the resistor and the chopper device is connected in parallel to the capacitor, and adjusts the load of power generated by the power generation brake during braking. When charging the capacitor, a charging current is passed through the resistor. As a result, a highly reliable, compact and lightweight electric vehicle control device can be realized.

According to the electric vehicle control device of the second invention,
A power converter converts the power supplied from the DC power supply through the filter circuit to drive the electric motor. The capacitor of the filter circuit is connected in parallel to the power converter,
The series circuit of the resistor and the chopper device is connected in parallel to the capacitor, and adjusts the load of the electric power generated by the power generation brake during braking. The switch circuit connects the cathode of the flywheel diode connected in parallel to the resistor and one end of the resistor, and turns off the charge current through the resistor and the flywheel diode when the capacitor is charged. As a result, a highly reliable, compact and lightweight electric vehicle control device can be realized.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of an electric vehicle control device according to the present invention.

FIG. 2 is a block diagram showing a configuration example of a conventional electric vehicle control device.

[Explanation of symbols]

1 DC overhead wire (DC power supply), 2 pantograph (DC power supply), 3 current breaker, 5 charge switch, 6 reactor (filter circuit), 8 chopper device, 9 flywheel diode, 10 capacitor (filter circuit),
11 power converter, 12 motor, 13 resistor.

Continued on the front page F term (reference) 5H115 PA00 PC02 PG01 PI03 PI11 PI29 PO02 PO06 PO17 PU08 PV03 PV09 PV22 PV29 QI03 QI04 SE04 5H530 AA02 AA05 BB24 CC08 CE15 CE16 CF06 DD03 DD05 EE01 EE05 5H576 AA01 BB03 BB06 DD01 DD02 DD01 DD02 HB02 JJ26 MM03

Claims (2)

[Claims] 1. A power converter for converting power supplied from a DC power supply through a filter circuit to drive a motor, a capacitor of the filter circuit connected in parallel to the power converter, and A circuit including a resistor and a chopper device for adjusting a load of electric power generated by the power generation brake at the time of braking, and a charging current flowing through the resistor when the capacitor is charged. Electric car control device. 2. A power converter for converting electric power supplied from a DC power supply through a filter circuit to drive an electric motor, a capacitor of the filter circuit connected in parallel to the power converter, A series circuit of a resistor and a chopper device that are connected in parallel and adjust the load of electric power generated by the power generation brake during braking, a flywheel diode of the chopper device connected in parallel to the resistor, and a cathode of the flywheel diode And an end of the resistor, and a switch circuit for turning off the charge current through the resistor and the flywheel diode when the capacitor is charged.