JPH06237534A - Automatic charging apparatus - Google Patents

Abstract

PURPOSE:To prevent both electrode terminals from being degraded by an arc discharge caused across the electrode terminals on the ground side and the vehicle side by a method wherein a drop in the pressure of a fluid supplied to a cylinder or a drop in the pressure force of the cylinder is detected by a pressure detection means and the charging operation of a battery is suspended by the drop in the pressure of the fluid or in the pressure force of the cylinder. CONSTITUTION:When the pressure of the air is dropped during a charging operation, the pressure force of ground-side electrode terminals 18a, 18b pressed by vehicle-side electrode terminal 13a, 13b of an unmanned vehicle 1 is dropped. Then, when the pressure of the air is dropped down to a pressure set by a pressure switch 21, the pressure switch 21 sends out a pressure-drop signal to a control device 25. Then, the control device 25 excites and operates a charging coil 27a for a charger 26, and it turns off a charging switch 27. Then, the control device 25 operates a solenoid valve 20 for air, it sends the air to an air pipe, and it brings a piston rod back to a charging arm as an air cylinder.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic charging device.

[0002]

2. Description of the Related Art An unmanned vehicle driven by a battery is widely used as an unmanned guided vehicle used in a distribution system such as a factory. It is necessary to periodically charge the battery mounted on the unmanned vehicle, and the charging is mainly performed at night or on holidays after the end of work in a factory or the like. Therefore, the automatic charging device is used to charge the unmanned vehicle, and the applicant of the present invention is
No. 118743 proposes an automatic charging device for unmanned vehicles. This automatic charging device is installed in the charging station.

When the unmanned vehicle enters the charging station, the control device pushes the air cylinder of the charging electrode device toward the unmanned vehicle. Then, the ground electrode terminal of the charging electrode device provided at the tip of the air cylinder is pressed against the vehicle electrode terminal of the unmanned vehicle. The air that pushes out the air cylinder is made high pressure by an electric compressor and is widely used in the factory. When both electrode terminals are connected, the control device instructs the charger to start charging, and the charger charges the battery mounted on the unmanned vehicle through both electrode terminals. When the charging is completed after a lapse of a predetermined time, the control device pulls back the air cylinder of the charging electrode device to separate the electrode terminals. The unmanned vehicle exits the charging station after both electrode terminals are separated and returns to normal running.

[0004]

However, the charging of the battery mounted on the unmanned vehicle as described above is usually performed after the work is completed, for example, at night or on a factory holiday.
Further, since the unnecessary power source is stopped at night or on factory holidays, the electric compressor is also stopped and air is not supplied to the air supply source. Therefore, the air pressure of the air supply source decreases due to the charging operation to the unmanned vehicle and the air leakage. As a result, the pressing force with which the ground-side electrode terminal is pressed against the vehicle-side electrode terminal decreases, and the ground-side electrode terminal is separated from the vehicle-side electrode terminal during charging. Therefore, the battery is insufficiently charged. Further, since the charging voltage applied to both electrode terminals is high, arc discharge occurs between the ground electrode terminal and the vehicle side electrode terminal, and both electrode terminals deteriorate.

An object of the present invention is to prevent the air cylinder, which is pressed by the ground-side electrode terminal during charging, from being separated from the vehicle-side electrode terminal due to a decrease in air pressure, thereby preventing the electrode terminal from being deteriorated. An object is to provide an automatic charging device that can do this.

[0006]

SUMMARY OF THE INVENTION In order to solve the above problems, the present invention relates to a vehicle side electrode terminal connected to a battery mounted on a vehicle, wherein a ground side electrode terminal is pressed by a cylinder, In an automatic charging device that charges a battery via a vehicle-side electrode terminal and a ground-side electrode terminal, the battery is charged by a pressure detection unit that detects the pressure of the fluid supplied to the cylinder or the pressing force of the cylinder. while,
And a charging interruption means for interrupting the charging of the battery when the pressure detecting means has dropped to a predetermined pressure.

[0007]

According to the present invention thus constructed, the pressure detecting means detects the pressure of the fluid supplied to the cylinder or the decrease of the pressing force of the cylinder, and the ground electrode is detected by the decrease of the fluid pressure or the pressing force of the cylinder. Charging of the battery is interrupted before the terminals are separated from the vehicle-side electrode terminals. As a result, it is possible to prevent both electrode terminals from deteriorating due to arc discharge occurring between the ground side electrode terminal and the vehicle side electrode terminal.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment embodying the present invention will now be described with reference to FIGS.
It will be described with reference to FIG. FIG. 3 shows a schematic configuration of an unmanned transportation system using the unmanned vehicle 1. A travel route in which the electromagnetic induction wire 2a is laid is formed on the road surface.
An operation mark 3a for instructing operation information to the unmanned vehicle 1 is provided at a predetermined position on the electromagnetic induction wire 2a.
In addition, a service guide wire 2b for guiding the unmanned vehicle 1 to the charging station J is branched in the middle of the electromagnetic guide wire 2a, and operation information is also sent to the unmanned vehicle 1 at a predetermined position on the service guide wire 2b. An operation mark 3b for instructing is provided.

The operation marks 3a and 3b are arranged so that iron plates or the like are arranged in various patterns so that the operation information can be indicated. The unmanned vehicle 1 publicly discloses the operation information of the operation marks 3a and 3b. It is designed to be read by.

In this embodiment, the operation information indicated by the operation mark 3a is operation information for causing the unmanned vehicle 1 to spin backward in the counterclockwise direction in FIG. 3 and enter the charging station J. The operation information indicated by the operation mark 3b is operation information that causes the unmanned vehicle 1 to spin forward in the clockwise direction and return from the lead-in guide wire 2b to the travel route on which the electromagnetic guide wire 2a is laid.

Next, the unmanned vehicle 1 will be described. As shown in FIG. 1, the unmanned vehicle 1 moves forward and backward in accordance with forward and reverse rotations of a driving wheel 6 that constitutes a steering mechanism and a traveling mechanism driven by a steering motor 4 and a traveling motor 5, and driven wheels 7 that follow the traveling. Proceed. A mark sensor 8 for detecting the operation marks 3a and 3b is mounted on the lower surface of the unmanned vehicle 1. The mark sensor 8 outputs the detection signal to the controller C when detecting the operation marks 3a and 3b. Then, the controller C determines the operation information of the operation marks 3a and 3b based on the detection signal from the mark sensor 8 and controls the drive of the steering motor 4 and the traveling motor 5.

Further, a pickup coil 9 is mounted on the lower surface of the unmanned vehicle 1. The pickup coil 9 detects the electromagnetic induction wire 2a and the lead-in induction wire 2b, and outputs the detection signal to the controller C. Has become. Then, the controller C controls the drive of the steering motor 4 based on the detection signal from the pickup coil 9.

A vehicle-side optical communication device 10 is attached to one side surface of the unmanned vehicle 1. The vehicle side optical communication device 10 is connected to the controller C, and is connected to the charging station J.
When the vehicle side optical communication device 10 communicates with the controller C,
A stop signal is output to. The controller C stops the steering motor 4 and the traveling motor 5 in response to a stop signal from the vehicle side optical communication device 10.

The unmanned vehicle 1 is loaded with a battery 11 composed of a lead storage battery, and the electric power of the battery 11 drives the motors 4, 5 and various devices. A power receiving unit 12 is provided at the rear of the unmanned vehicle 1. The power receiving unit 12 includes vehicle-side electrode terminals 13a and 13b.
Is provided. The vehicle-side electrode terminals 13a and 13b are connected to the terminals of the battery 11 mounted on the unmanned vehicle 1.

As shown in FIG. 3, at the charging station J, the ground side optical communication device 1 communicating with the vehicle side optical communication device 10 is connected.
4 are installed. The ground-side optical communication device 14 is used when the unmanned vehicle 1 enters the charging station J.
It is provided at a position facing 0. Then, the unmanned vehicle 1 travels backward along the traveling route formed by the lead-in guide line 2b, and the vehicle side optical communication device 10 mounted on the side surface of the unmanned vehicle 1
When the ground optical communication device 14 and the ground side optical communication device 14 face each other, the motors 4 and 5 are stopped by the controller C, and the unmanned vehicle 1 is stopped at that position.

At the position where the unmanned vehicle 1 is stopped by the ground side optical communication device 14 and the vehicle side optical communication device 10 communicating with each other, a circle is formed at a position facing the power receiving portion 12 provided at the rear portion of the unmanned vehicle 1. A pillar 15 is erected on the floor. Prop 15
A charging arm 16 extending toward the stationary unmanned vehicle 1 is connected to the. The charging arm 16 is set to a height facing the power receiving unit 12 of the unmanned vehicle 1.

As shown in FIG. 1, the charging arm 16 is an air cylinder, and the piston rod 16a is inserted therein. An electrode bracket 17 is supported on the tip of the piston rod 16a. On the end surface of the electrode bracket 17, ground-side electrode terminals 18a and 18b connected to the vehicle-side electrode terminals 13a and 13b are provided so as to vertically project.

Further, air pipes 19a, 1a are attached to the column 15.
9b is provided. The air pipe 19a is provided at the joint between the support column 15 and the charging arm 16, and the charging arm 1
6 is supplied with air. Air piping 19b
Below the charging arm 16 along the charging arm 16
It is provided from 5 toward the tip of the charging arm 16. The air pipe 19b supplies air from the tip of the charging arm 16. When air is supplied to the charging arm 16 via the air pipe 19a, the piston rod 16a inserted in the charging arm 16 is pushed forward by the pressure of the air. When air is supplied to the charging arm 16 via the air pipe 19b, the piston rod 16a inserted in the charging arm 16 is pulled back to the charging arm 16 by the pressure of the air.

Air pipes 19a, 19b of the charging arm 16
Passes through the inside of the support column 15 and is connected to the solenoid valve 20 for air arranged below the support column 15. A pressure switch 21 as a pressure detecting means is arranged on the outer surface of the column 15. Air is supplied to the air solenoid valve 20 via a pressure switch 21. The pressure switch 21 is connected to an air supply source 23 via an air tube 22. The pressure switch 21 is an air supply source 23.
The pressure of the supplied air is detected, and the pressure of the ground side electrode terminals 18a, 18b against the vehicle side electrode terminals 13a, 13b is reduced and the piston rod 16a of the charging arm 16 is A pressure drop signal is sent when the pressure has dropped to a level where it can be pulled back.

The charging cables 24 for the ground-side electrode terminals 18a and 18b pass through the inside of the pillar 15 and are connected to the ground station T from the lower part of the pillar 15. As shown in FIG. 3, the ground station T is composed of a control device 25 and a charger 26.
A charger 26 is connected to the control device 25. Further, the ground side optical communication device 14, the air solenoid valve 20, and the pressure switch 21 are connected to the control device 25. When the ground-side optical communication device 14 communicates with the vehicle-side optical communication device 10, the unmanned vehicle 1 is connected to the charging station J.
A signal indicating that the vehicle has stopped at the predetermined position is output to the control device 25.

Next, the electrical configuration of the unmanned vehicle 1 and the ground station T will be described. As shown in FIG. 4, vehicle-side electrode terminals 13a, 13 connected to a battery 11 mounted on the unmanned vehicle 1
b is provided. The controller C of the unmanned vehicle 1 is connected to a vehicle side optical communication device 10, a steering motor 4, a traveling motor 5, a mark sensor 8 and a pickup coil 9.

The ground station T has vehicle-side electrode terminals 13a, 13
Ground-side electrode terminals 18a and 18b for pressing against b are provided. The ground electrode terminals 18a and 18b are connected to a charging circuit 28 via a charging switch 27. The charging coil 27a of the charging switch 27 is connected to the control device 25, and the charging coil 27a is excitation-controlled by a command from the control device 25, and is turned on (closed) / off (opened).
It is supposed to be done.

The charging circuit 28 includes a rectifying circuit 29 and a transformer 3.
It has 0. The charge switch 27 is a rectifier circuit 29.
Is connected to the transformer 30 via. The transformer 30 is connected to three-phase AC power supplies U, V, W via an electromagnetic switch 31. The electromagnetic coil 31a of the electromagnetic switch 31 is connected to the control device 25, and the electromagnetic coil 31a is excitation-controlled by a command from the control device 25 to be turned on (closed) or turned off (open).

Further, the pressure switch 21 and the solenoid valve 20 for air are connected to the control device 25. A pressure drop signal sent from the pressure switch 21 is input to the control device 25. Also, the control device 25
The air supplied from the air supply source 23 is appropriately switched to the air pipes 19a and 19b by controlling the air solenoid valve 20. Further, the control device 25 is connected to an abnormality display lamp 32 for notifying a charging abnormality when the unmanned vehicle 1 is not completely charged.
Further, the control device 25 causes the controller C to notify the ground side optical communication device 14 and the vehicle side optical communication device 10 when the charging is not completed.
The charging interruption signal is transmitted via the.

Next, the operation of the automatic charging device thus constructed will be described. First, the operation of the automatic charging device during normal charging will be described. In FIG. 3, the unmanned vehicle 1 normally travels on the travel route on which the electromagnetic induction wire 2a is laid, and when the mark sensor 8 detects the operation mark 3a, the controller C determines the arrangement pattern of the operation mark 3a based on the detection signal. recognize. Then, the operation information corresponding to the arrangement pattern (in this case, backward spin-turn traveling) is determined, and the controller C drives and controls the steering motor 4 and the traveling motor 5 to cause the unmanned vehicle 1 to perform the backward spin-turn to drive the unmanned vehicle. 1 is made to enter the traveling route of the lead-in guide wire 2b branched from the electromagnetic guide wire 2a, that is, the charging station J.

When the unmanned vehicle 1 enters the charging station J, the vehicle side optical communication device 10 attached to the side surface of the unmanned vehicle 1 and the ground side optical communication device 14 connected to the control device 25 face each other. Communicate. At this time, the controller C inputs a stop signal from the vehicle side optical communication device 10 to stop the driving of the steering motor 4 and the traveling motor 5 and stop the unmanned vehicle 1 at that position.

On the other hand, the ground side optical communication device 14 is provided with a control device 25.
And outputs a signal indicating that the unmanned vehicle 1 has stopped at a predetermined position of the charging station J, and the control device 25 controls the air solenoid valve 20.
Is controlled to feed air into the air pipe 19a. As a result, as shown in FIG. 2, the piston rod 16a inserted in the charging arm 16 is pushed toward the unmanned vehicle 1. The ground-side electrode terminals 18 a and 18 b protruding from the electrode bracket 17 are connected to the vehicle-side electrode terminals 13 of the unmanned vehicle 1.
It is pressed by a and 13b.

Subsequently, the controller 25 excites the charging coil 27a of the charger 26 to turn on the charging switch 27. At this time, the electromagnetic switch 31 of the charger 26 is turned on by the control of the electromagnetic coil 31 a by the control device 25. Therefore, from the charging circuit 28 to the charging cable 24, the ground side electrode terminals 18a and 18b and the vehicle side electrode terminal 13a,
Electric power is supplied to the battery 11 via 13b, and charging of the battery 11 is started. When the predetermined charging time elapses, the control device 25 causes the charging coil 27 of the charger 26 to
A is excited and the charging switch 27 is turned off to complete the charging. The control device 25 controls the solenoid valve 20 for air to send air into the air pipe 19b, and the piston rod 16a
Pull back. By pulling back the piston rod 16a, the ground-side electrode terminals 18a and 18b are separated from the vehicle-side electrode terminals 13a and 13b.

After that, the controller 25 controls the optical communication device 1 on the ground side.
4 and a charge end signal are output to the controller C via the vehicle side optical communication device 10. When the controller C inputs the charging end signal, the steering motor 4 and the traveling motor 5
To drive the unmanned vehicle 1 to move forward. Controller C
Detects the operation mark 3b by the mark sensor 8, and determines the operation information of the operation mark 3b (in this case, forward spin turn travel) based on the detection signal. Then, the controller C spins the unmanned vehicle 1 forward and turns it back to the traveling path of the electromagnetic induction wire 2a again.

The above operation is repeated to charge the battery 11 of the unmanned vehicle 1. When the pressure of air decreases during the charging, the pressing force of the ground electrode terminals 18a, 18b pressed by the vehicle electrode terminals 13a, 13b of the unmanned vehicle 1 decreases. When the air pressure drops to the pressure set in the pressure switch 21, the pressure switch 21 sends a pressure drop signal to the control device 25. When the control device 25 inputs the pressure drop signal, the charging coil 27 of the charger 26
The charging switch 27 is turned off by exciting a. Then, the control device 25 operates the electromagnetic valve 20 for air to send air into the air pipe 19b, and pulls the piston rod 16a back to the charging arm 16.

Further, the control device 25 sends a charge stop signal to the controller C via the ground side optical communication device 14 and the vehicle side optical communication device 10. The controller C inputs the charge stop signal and since the charging is not completed, the unmanned vehicle 1 is stopped at a predetermined position for charging and is not returned to the electromagnetic induction wire 2a. Further, the control device 25 lights up the abnormality display lamp 32 to notify the interruption of charging to the outside.

As described above, in the automatic charging apparatus of this embodiment, the pressure switch 21 detects the pressure drop of the air of the piston rod 16a which the ground side electrode terminals 18a, 18b press against the vehicle side electrode terminals 13a, 13b. A pressure drop signal is sent to the controller 25. The controller 25 inputs the pressure drop signal to turn off the charging switch 27 of the charger 26 to interrupt charging. Therefore,
Ground-side electrode terminals 18a and 18b and vehicle-side electrode terminal 13
Since the charging switch 27 is off even if the a and 13b are separated from each other, it is possible to prevent the electrode terminals from being deteriorated without causing arc discharge or the like between the two electrode terminals 13a, 13b, 18a and 18b. .

The present invention is not limited to the above-mentioned embodiments, but may be modified as follows without departing from the spirit of the present invention. (1) In the above embodiment, when the air pressure drops, charging is interrupted and the piston rod 16a is pulled back.
Stop charging and do not pull back the piston rod 16a,
You may make it maintain that state.

(2) In the above embodiment, only charging is interrupted, but when the factory starts operating, the pressure of the air is sufficient so that the ground side electrode terminals 18a, 18b are pressed against the vehicle side electrode terminals 13a, 13b. The charging may be restarted by detecting that the pressure has risen to a certain level.

(3) In the above embodiment, the unmanned vehicle 1 remains stopped at the charging station J when charging is interrupted.
You may make it return to the electromagnetic induction wire 2a after interruption of charging.

(4) Instead of the air cylinder of the charging arm 16 of the above embodiment, a lock type air cylinder having a lock mechanism may be used. In the lock type air cylinder, the piston rod 16a is pushed out and the ground side electrode terminal 18
Since a and 18b are locked where they are pressed by the vehicle-side electrode terminals 13a and 13b, air pressure is not required during charging. When the air pressure decreases, the control device 25 turns off the charging switch 27 to interrupt the charging and pulls back the piston rod 16a. Therefore, the charging is continued until the pressure of the air reaches the pressure to be pulled back, and the charging time can be lengthened accordingly.

(5) In the above embodiment, the vehicle is an automatic charging device for an unmanned vehicle 1 such as an automatic guided vehicle, but it may be applied to an automatic charging device for a vehicle equipped with a battery 11 such as an electric vehicle.

(6) Although air is used as the fluid in the cylinder in the above embodiment, a fluid cylinder such as a hydraulic cylinder may be used. (7) In the above-described embodiment, the air pressure of the air cylinder is detected as the pressure detecting means. However, for example, a plate-shaped pressure sensor may be used to detect the pressure at the power receiving portion 12 of the unmanned vehicle 1. Good.

[0039]

As described above in detail, according to the automatic charging device of the present invention, the pressure of the fluid supplied to the cylinder or the decrease of the pressing force of the cylinder is detected by the pressure detecting means, and the pressure of the fluid or the cylinder is reduced. Charging of the battery is interrupted before the ground-side electrode terminal and the vehicle-side electrode terminal are separated from each other due to the decrease in the pressing force. As a result, there is an excellent effect that it is possible to prevent both electrode terminals from deteriorating due to arc discharge occurring between the ground side electrode terminal and the vehicle side electrode terminal.

[Brief description of drawings]

FIG. 1 is a partial side cross section of an automatic charging device of the present invention.

FIG. 2 is a partial side sectional view showing a state in which an unmanned vehicle is being charged by an automatic charging device.

FIG. 3 is a diagram showing a schematic configuration of a traveling route and a charging station.

FIG. 4 is a diagram showing an electrical configuration of an unmanned vehicle and a charging station.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Unmanned vehicle, 11 ... Battery, 13a, 13b ... Vehicle-side electrode terminal, 16 ... Charging arm, 16a ... Piston rod, 18a, 18b ... Ground-side electrode terminal, 21 ... Pressure switch as pressure detecting means, 25 ... Charging Control device as stopping means, 26 ... charger, 27 ... charging switch, J ... charging station

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kenji Sakakibara 2-chome, Toyota-cho, Kariya city, Aichi Prefecture Toyota Industries Corporation

Claims (1)

[Claims] 1. A ground side electrode terminal is pressed by a cylinder against a vehicle side electrode terminal connected to a battery mounted on a vehicle, and the battery is charged through the vehicle side electrode terminal and the ground side electrode terminal. In the automatic charging device to perform, the pressure detection means for detecting the pressure of the fluid supplied to the cylinder or the pressing force of the cylinder, and the battery when the pressure detection means drops to a predetermined pressure while charging the battery. An automatic charging device comprising a charging interruption means for interrupting charging.