JPH09149508A - Electric vehicle power supply - Google Patents

Abstract

(57) Abstract: From a main battery 1 of an electric vehicle to a load such as a drive motor control device 6 for controlling a drive motor 7,
Power is supplied through the main relay 2 controlled by the key switch 8. The load has a built-in large-capacity capacitor 5 that absorbs voltage fluctuations. When the key switch is turned off to turn off the main relay, the load is discharged through the discharge resistor. However, if the main relay contact 2-2 is welded when the key switch is turned off, current continues to flow from the main battery to the discharge resistance, resulting in burnout. SOLUTION: A discharge resistor 4 and a discharge control relay 3 of a normally open type.
A series connection with A is connected in parallel to the capacitor 5, and a discharge control circuit 10 is provided which turns on the discharge control relay 3A for a predetermined time after the key switch 8 is turned off. Then, even if the main relay 2 is welded during energization, the electric current flows through the discharge resistor 4 only for the predetermined time, and therefore, the burnout does not occur.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply device for an electric vehicle for supplying electric power to a drive motor and other electric loads in the electric vehicle.

[0002]

2. Description of the Related Art In an electric vehicle, as a main power source,
A battery having a high voltage and a large capacity sufficient to drive a drive motor is installed, and this battery is turned on or off by turning a key switch on or off. Then, according to the voltage required by each electric load,
Power is supplied directly from the battery, or is supplied after being converted to a suitable voltage by a voltage converter.

FIG. 2 is a diagram showing a conventional power supply device for an electric vehicle. In FIG. 2, 1 is a main battery, 2 is a main relay, 2-1 is a main relay coil, 2-2 is a main relay contact, 3 is a discharge control relay, 3-1 is a discharge control relay coil, 3-2 is a discharge. Control relay contact, 4 discharge resistance, 5 capacitor, 6 drive motor control device, 7
Is a drive motor, 8 is a key switch, and 9 is a sub battery.

The main battery 1 is a battery having a high voltage (eg, 300 V) and a large capacity enough to drive the drive motor 7. After passing through the main relay 2, the main battery 1 is connected to the drive motor control device 6 or another voltage converter (not shown). The main relay coil 2-1 is connected to the key switch 8. The output of the drive motor control device 6 is supplied to the drive motor 7,
Control such as rotation and stop of the drive motor 7 is performed by a control circuit (not shown) built in the drive motor control device 6.

A large-capacity capacitor 5 is connected between power supply input lines in the drive motor control device 6. This is for absorbing noise generated by a drive motor that is a load or some other cause, or for absorbing a temporary change in the power supply voltage. A discharge control relay 3 and a discharge resistor 4 are connected between power supply input lines to the drive motor control device 6. The discharge control relay coil 3-1 is connected to the key switch 8. The discharge resistor 4 and the discharge control relay 3 are for discharging the electric charge stored in the capacitor 5 when the key switch 8 is turned off and the operation of the electric vehicle is completed. This is because when the key switch 8 is turned off, the capacitor 5 is in a state of being charged to the same high voltage as the main battery 1, and it is dangerous to leave it as it is.

Since the discharge is completed in a short time, the discharge resistor 4
A short-time rated one is used as. The discharge control relay 3 is required to be turned off when the key switch 8 is turned on and turned on when the key switch 8 is turned off, and therefore, for example, a normally closed relay is used.

The sub-battery 9 is a low-voltage (for example, 12V) battery for operating a control circuit and a normal vehicle-mounted electric load. In FIG. 1, the main relay 2 and the discharge control relay 3 are energized via the key switch 8.

Next, the operation will be described. (1) When the key switch 8 is turned on When the key switch 8 is turned on, the main relay coil 2-1 is energized by the auxiliary battery 9 and the main relay contact 2-
2 turns on. On the other hand, when the key switch 8 is turned on,
Since the discharge control relay coil 3-1 is also energized by the sub battery 9, the discharge control relay contact 3-2 which is a normally closed contact.
Is turned off. Therefore, the main battery 1 supplies power to the drive motor control device 6 and the voltage converter (not shown). The power supply to the drive motor control device 6 charges the capacitor 5. The control of the output from the drive motor control device 6 to the drive motor 7 is performed according to the driving operation (accelerator operation or the like) of the driver.

(2) When the key switch 8 is turned off When the key switch 8 is turned off to end the operation of the electric vehicle, the main relay coil 2-1 is deenergized and the main relay contact 2-2 is turned off. Become. for that reason,
Power supply to the drive motor control device 6 and the voltage converter (not shown) is stopped. Therefore, the drive motor 7 and other vehicle-mounted electric loads stop operating. On the other hand, when the key switch 8 is turned off, energization of the discharge control relay coil 3-1 is also terminated, so that the discharge control relay contact 3-2 is turned on. As a result, the electric charge of the capacitor 5 is discharged through the path of the capacitor 5 (positive side terminal) → discharge resistor 4 → discharge control relay contact 3-2 → capacitor 5 (negative side terminal).

Prior art documents relating to a power supply device for an electric vehicle include, for example, JP-A-4-117102 and JP-A-6-276610.

[0011]

[Problems to be solved by the invention]

(Problem) Since the main relay contact 2-2 is a contact through which a large current flows, the main relay contact 2-2 may be welded by heat generated during energization or opening / closing operation of the contact. When the main relay contact 2-2 is welded, the main relay contact 2-2 does not return to off even if the key switch 8 is turned off, but the discharge control relay contact 3-2 returns to on. Therefore, main battery 1 → main relay contact 2-2 →
Discharge resistance 4 → Discharge control relay contact 3-2 → Main battery 1
There is a problem that a closed circuit is formed and current continues to flow until the discharge resistor 4 burns out. An object of the present invention is to solve the above problems.

[0012]

In order to solve the above-mentioned problems, in a power supply device for an electric vehicle of the present invention, it is turned on when a key switch is turned on and turned off when it is turned off.
Switch means, a load including a drive motor, a power source connected through the first switch means, a capacitor connected between power lines from the power source, and a resistor connected in parallel with the capacitor. And a control means for controlling the second switch means so as to be turned off when the key switch is turned on and to turn on only for a predetermined time after the key switch is turned off. I decided to prepare it.

A normally open relay is used as the second switch means, and the control means is a control circuit for controlling the normally open relay to be energized only when the key switch is turned off for a predetermined time after the key switch is turned off. Good.

(Summary of Operation to Be Solved) The series connection body which is connected in parallel to the capacitor and which includes the resistor and the second switch means provides a path for discharging the electric charge of the capacitor when the key switch is turned off. . When the key switch is turned off, the second switch means is controlled by the control means so that the second switch means is turned on only for a predetermined time after the key switch is turned off. Therefore, even if the first switch means is welded, The current flows through the resistor only for the predetermined time. Therefore, the resistance does not burn out.

[0015]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a diagram showing a power supply device for an electric vehicle of the present invention, and reference numerals correspond to those in FIG. 3A is a discharge control relay, 3A-1 is a discharge control relay coil, 3A-2 is a discharge control relay contact,
Is a discharge control circuit, 11 is a relay, 12 is a monostable multivibrator, 13 is a power supply circuit, 14 and 15 are diodes, 16 is a resistor, 17 is a transistor, 18 is a relay,
18-1 is a relay coil and 18-2 is a relay contact. 1 have the same configurations as those in FIG. 1 and operate in the same manner, so description thereof will be omitted.

In terms of configuration, the first difference from the conventional example of FIG. 1 is that a normally open relay is used as the discharge control relay instead of the normally closed relay. The discharge control relay 3 of the conventional example is a normally closed relay that turns off when the discharge control relay coil 3-1 is energized, but in the present invention, discharge control is performed when the discharge control relay coil 3A-1 is energized. A normally open relay in which the relay contact 3A-2 is turned on was used. The second difference from the conventional example is that the discharge control circuit 10 is provided. The discharge control circuit 10 is a circuit for controlling ON / OFF of the discharge control relay 3A.

The structure of the discharge control circuit 10 is as follows. First, a relay 18 connected in series with the sub battery 9 is provided. The relay 18 is a normally open relay connected so as to be turned on when the key switch 8 is turned on and the transistor 17 is turned on, and has a role of guiding power to the power supply circuit 13 and the relay 11 in the discharge control circuit 10. It's done. One end of the relay coil 18-1 is connected to the sub battery 9 and the other end is connected in series to the transistor 17. Therefore, by controlling the on / off of the transistor 17, the relay 18 is controlled.

A monostable multivibrator 12 is provided on the base of the transistor 17 in addition to the first path in which the signal from the key switch 8 is directly input via the diode 15.
And a second path for input through the diode 14 is provided. The monostable multivibrator 12 is triggered when a falling signal (that is, a signal when the key switch 8 is turned from ON to OFF) is input, and then outputs only for a set time T.

Therefore, the first path supplies a signal which turns on the transistor 17 while the key switch 8 is turned on. The second path is that when the key switch 8 is turned off, the transistor 1
Provide a signal to keep 7 on. The power supply circuit 13 is a circuit that supplies power for operating the monostable multivibrator 12. The resistor 16 is a resistor for adjusting current.

Relay 18 and discharge control relay coil 3A-
A relay 11 is connected between the relays 1 and 1. That is,
When both the relay 18 and the relay 11 are turned on, the discharge control relay 3A is turned on. A normally closed relay is used as the relay 11, and its relay coil 1
1-1 is connected in series with the key switch 8. Therefore,
When the key switch 8 is turned on, the relay contact 11-2 is turned off, and when the key switch 8 is turned off, it is turned on.

Next, the operation will be described. (1) When the key switch 8 is turned on When the key switch 8 is turned on, the following operation is performed. The main relay coil 2-1 is energized, the main relay contact 2-2 is turned on, and the voltage of the main battery 1 is applied to the drive motor control device 6 and a voltage converter (not shown). Transistor 17 via diode 15 and resistor 16
The base is turned on, the transistor 17 is turned on, and the relay 18 is turned on. Monostable multivibrator 12
Is applied with a voltage via the power supply circuit 13, and is in a state of waiting for an operable trigger. The relay coil 11-1 is energized and the relay contact 11
-2 is off. Therefore, even if the relay 18 is turned on, the discharge control relay coil 3A-1 is not energized, and the discharge control relay contact 3A-2 remains off.

As a result of such operation, the capacitor 5 in the drive motor control device 6 is charged and the drive motor 7 can be controlled. Further, no current flows through the discharge resistor 4.

(2) When the key switch 8 is turned off When the key switch 8 is turned off, the following operation is performed. The main relay 2 is turned off. Therefore, power supply to the drive motor control device 6 and the voltage converter is stopped. Key switch 8 on the monostable multivibrator 12
Since the falling signal due to turning off is input, the output is output from that time for the time T set in the monostable multivibrator 12. The output is input to the base of the transistor 17 via the diode 14 and the resistor 16 to keep the transistor 17 on. Since the power supply to the relay coil 11-1 is stopped,
The relay contact 11-2 returns to ON.

As a result of such an operation, a current flows through the route of sub battery 9 → relay contact 18-2 → relay contact 11-2 → discharge control relay coil 3A-1 → ground, and discharge control relay contact 3A-. 2 turns on. Therefore, the electric charge of the capacitor 5 is discharged through the discharge resistor 4. Since the relay contact 18-2 is kept on only for the set time T, the discharge control relay 3A is set after the set time T.
Is also turned off and the discharge is stopped. Therefore, it is preferable to set the length of the set time T set by the monostable multivibrator 12 to a length long enough to almost discharge the capacitor 5.

Even if the main relay contact 2-2 is welded, after the key switch 8 is turned off, the set time T
Since the discharge control relay 3 is only turned on, the current from the main battery 1 does not continue to flow through the discharge resistor 4 forever. Therefore, the discharge resistance 4 does not burn out. Further, the welding of the main relay contact 2-2 needs to warn the driver by an alarm device (not shown) provided separately, and there are various publicly known alarm devices. Since it is not the purpose of the invention, it is omitted.

[0026]

As described above, according to the power supply device for an electric vehicle of the present invention, the discharge control relay 3A connected in series with the discharge resistor 4 is controlled so that it is turned on only for a predetermined time after the key switch 8 is turned off. Therefore, even if the main relay 2 is welded, the current does not continue to flow from the main battery to the discharge resistor 4 and is not burned.

[Brief description of the drawings]

FIG. 1 is a diagram showing a power supply device for an electric vehicle according to the present invention.

FIG. 2 is a diagram showing a conventional electric vehicle power supply device.

[Explanation of symbols]

1 ... Main battery, 2 ... Main relay, 2-1 ... Main relay coil, 2-2 ... Main relay contact, 3, 3A ... Discharge control relay, 3-1, 3A-1 ... Discharge control relay coil, 3-2 , 3A-2 ... Discharge control relay contact, 4 ... Discharge resistance, 5 ... Capacitor, 6 ... Driving motor control device, 7
... drive motor, 8 ... key switch, 9 ... sub battery,
10 ... Discharge control circuit, 11 ... Relay, 12 ... Monostable multivibrator, 13 ... Power supply circuit, 14, 15 ... Diode, 16 ... Resistor, 17 ... Transistor, 18 ... Relay, 18-1 ... Relay coil, 18-2 … Relay contacts

Claims (2)

[Claims] 1. A key switch is turned on when it is turned on,
First switch means that is turned off when turned off, a load including a drive motor, a power supply connected through the first switch means, a capacitor connected between power supply lines from the power supply, The capacitor is connected in parallel and the resistor and the second
And a second series connecting means consisting of the switch means of the above and the second switch means are turned off when the key switch is turned on,
A power supply device for an electric vehicle, comprising: a control unit that controls to turn on only for a predetermined time after being turned off when turned off. 2. A control that uses a normally open relay as the second switch means, and controls the control means so that when the key switch is turned off, the normally open relay is energized only for a predetermined time from when the key switch is turned off. The power supply device for an electric vehicle according to claim 1, wherein the power supply device is a circuit.