JPH0654460A - Charging equipment - Google Patents

Abstract

PURPOSE:To perform the charging work to a battery properly and efficiently and shorten the charge time by omitting the troublesome work of performing the changeover of a tap line in advance, according to the voltage of an AC power source, and also, adjusting the output voltage of a transformer, according to the load condition of the transformer. CONSTITUTION:The primary winding of a transformer TR is provided with tap lines 13a and 13b. Moreover, a temperature sensor 26 is accommodated in the transformer TR. Furthermore, based on the detected data from a the temperature sensor 26, in the case where the temperature inside the transformer Tr rises, a controller 21 performs the changeover between the tap lines 13a and 13b of the primary winding 4 of the transformer TR from high voltage to low voltage. Conversely, in the case where the temperature inside the transformer Tr falls, it can perform the changeover between the tap lines 13a and 13b from low voltage to high voltage.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charging device such as a battery forklift truck.

[0002]

2. Description of the Related Art Conventionally, as shown in FIG. 4, there is known a charging device for charging a battery mounted as a driving power source for a battery type vehicle or the like.

That is, a charging device of this type is mounted on a vehicle, and when it is connected to a three-layer AC power source 2 via a plug 3,
Each layer of the AC power supply 2 has a magnet switch 7
Is connected to the primary side of the transformer TR. The secondary side of the transformer TR is connected to the rectifier circuit 9,
The AC voltage stepped down at is rectified by the rectifier circuit 9 into a DC voltage. Then, the battery 10 is charged by the DC power source rectified by the rectifier circuit 9.

Further, from the primary winding of the transformer TR of the charging device, 200, 210, 220, 23 in each phase.
A 0-volt switching tap wire 31 is led out. Then, according to the power supply voltage of the three-phase alternating current, each three-phase tap wire 3
Select a suitable tap line from 1 and connect it. That is,
At the time of factory shipment, the tap wire 31 is switched and connected according to the power supply voltage on the user side, for example, 220 volts.

[0005]

However, in the above-mentioned conventional charging device, it is necessary to connect each phase by means of a connector type terminal block or bolts or nuts with round ends depending on the power supply voltage of the three-phase AC. Therefore, there is a problem that the switching work is very troublesome.

If the tap line 31 is not connected to the tap line 31 having a voltage suitable for the three-phase power supply voltage, the transformer TR is overheated or defectively charged (overcharge or insufficient charge), and the battery 10 is discharged. There was a problem that it adversely affected the life of the.

An object of the present invention is to solve the above problems existing in the prior art, to eliminate the need for tap line switching work corresponding to changes in three-phase power supply voltage, and to overheat the transformer or insufficient or overcharge the battery. It is an object of the present invention to provide a charging device capable of suppressing charging and improving the life of a battery.

[0008]

In order to achieve the above object, the present invention provides a transformer for stepping down an AC power supply voltage, and a rectifying circuit for rectifying the AC voltage stepped down by the transformer into a DC voltage for battery charging. In the charging device, the output voltage adjusting means for adjusting the output voltage of the transformer, the transformer load state detecting means such as the operating temperature and operating time of the transformer, or the charging voltage for the battery, and the transformer load state detecting means Voltage control means for switching and controlling the output voltage adjusting means of the transformer based on the detection signal of.

[0009]

According to the present invention, the output voltage adjusting means of the transformer is controlled by the voltage control means on the basis of the detection signal output from the transformer load state detecting means such as the operating temperature and operating time of the transformer or the charging voltage for the battery. Therefore, the output voltage of the transformer is adjusted to an appropriate voltage according to the fluctuation of the power supply voltage, and the work of charging the battery is properly performed. Therefore, it is possible to prevent the transformer from overheating, the battery from being overcharged, or the battery from being insufficiently charged, and the life of the battery is improved.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments embodying the present invention will now be described with reference to FIGS.
It will be described with reference to FIG. FIG. 1 is a circuit diagram showing an electrical configuration of a charging device for charging a battery of this embodiment,
The charging device is mounted on a battery-powered forklift.

The charging device 1 is connected via a plug 3 to a charging plug 2a of a 220-volt three-phase AC power supply 2. Further, the charging device 1 has a transformer TR having a primary winding 4 and a secondary winding 5, and the primary winding 4 is connected to the plug 3 via a three-phase lead wire 6. Further, a magnet switch 7 for opening and closing a primary current is interposed in the lead wire 6, and a normally closed contact of a thermal relay 8 for overcurrent protection is connected to an operating circuit of the switch 7.

A rectifier circuit 9 composed of a diode bridge circuit for converting an AC voltage into a DC voltage is connected to the secondary winding 5 side of the transformer TR. A battery 10 that is charged by the DC voltage converted by the rectifier circuit 9 is connected to the rectifier circuit 9. In addition, 11 is a fuse and 12 is a contactor for connecting the charging device 1 and the battery 10.

As shown in FIG. 2, the primary winding 4 of the transformer TR is provided with tap lines 13a and 13b constituting output voltage adjusting means for switching the output voltage for each phase.
These tap wires 13a and 13b can be connected to the lead wires 6 of the respective phases via the switching contacts 14 which also constitute output voltage adjusting means. Further, each contact 14 is switched by an electromagnetic solenoid 15 which constitutes an output voltage adjusting means, so that the voltage induced in the secondary winding 5 of the transformer TR can be adjusted in two steps in this embodiment. I have to.

As shown in FIG. 1, two of the phases of the charging plug 3 are connected to the timer unit 16.
A timer (not shown) is built in the timer unit 16, and a charging start switch 17 for starting charging is connected. Further, the timer unit 16 is connected to the magnet switch 7 via the normally closed contact of the thermal relay 8.

The battery-powered forklift is equipped with a control device 21 as a voltage control means composed of a microcomputer. The control device 21 includes a central processing unit CPU 22, a read only memory ROM 23, a random access memory RAM 24.
And so on. Further, the control device 21 has various modes such as a charging mode in this embodiment and a traveling mode for traveling a forklift. further,
The control device 21 is connected to the electromagnetic solenoid 15, the timer unit 16, and the DC voltage sensor 25 for detecting the DC voltage supplied to the battery 10, respectively.

Further, a temperature sensor 26 as a transformer load state detecting means for detecting the internal temperature of the transformer TR is arranged in a space inside the case (not shown) in the transformer TR, and the temperature data detected by the sensor 26 is stored in the case. It is transmitted to the control device 21.

When the temperature data detected by the temperature sensor 26 exceeds a set value, the control device 21 outputs an operation signal to the electromagnetic solenoid 15 and operates the switching contact 14 to operate the tap wire 13a, The switching operation is performed between 13b.

Next, the operation of the charging device configured as described above will be described focusing on the flowchart showing the processing operation of the control device 21 during charging. now,
In FIG. 1, the charging plug 3 of the charging device 1 is connected to the charging plug 2a of the AC power supply 2 in a state where the electromagnetic solenoid 15 is demagnetized and the switching contact 14 is switched to the small voltage tap wire 13a side. . Then, the power from the AC power supply 2 is passed through the charging plug 3 to the timer unit 1
6, a signal indicating that the charging plug 3 has been inserted into the charging plug 2a (plug-in) is output to the control device 21. In response to this signal, the control device 21 enters the charging mode, cancels all the modes other than the charging mode, and waits for the charging start switch 17 to be turned on.

Next, when the charging start switch 17 connected to the timer unit 16 is turned on, a signal to that effect is output from the timer unit 16 to the control device 21, and in step S1 of FIG. Indicates that the charging start switch 17 has been turned on, and the process proceeds to the next step S2.

In step S2, the magnet switch 7 is turned on via the timer unit 16. Then, the electric power from the AC power supply 2 is applied to the magnet switch 7
And to the primary winding 4 via the switching contact 14 switched to the tap line 13a on the small voltage side. Then, the AC voltage stepped down by this transformer TR is
The AC voltage output from the secondary winding 5 of R is converted into a DC voltage by the rectifier circuit 9 and charged in the battery 10. Then, in step S3, the voltage sensor 2
5, the charging voltage V _B of the battery 10 is detected.

On the other hand, in step S4, the control device 21 determines whether or not the charging start is normal, and if NO, the abnormality processing is performed in step S5. If YES in step S4, step S6
, The electromagnetic solenoid 15 is excited and the switching contact 14 is switched to the high voltage tap wire 13b side, the high voltage is output from the secondary winding 5 of the transformer TR to the rectifier circuit 9, and the battery 10 has a high DC voltage. Charged by voltage.
(Step S7) On the other hand, the temperature inside the transformer TR is detected by the temperature sensor 26 that operates in synchronization with the start of the charging operation, and it is determined whether the detected data T _n exceeds the set value T _S.
Then, the magnitude relationship between the detection data T _n and the set value T _S is
When T _n > T _S , the electromagnetic solenoid 15 is turned off and the switching contact 14 is switched to the low voltage tap wire 13a side. On the contrary, when T _n <T _S , the electromagnetic solenoid 15 is turned on, the switching contact 14 is switched to the high voltage tap wire 13b side, and these on / off operations are repeated. (Step S8) For this reason, the temperature of the transformer TR does not rise or fall too much, and the charging operation is properly performed.

Next, in step S9, it is determined whether or not the charging voltage V _B of the battery exceeds the set voltage V _S , and YES
In this case, the electromagnetic solenoid 15 is turned off in step S10. If NO in step S9, the process returns to step S8.

Further, when the final charging time H _n after the turning off of the electromagnetic solenoid 15 in step S10 exceeds the set time H _S in step S11, the charging start switch 17 is turned off in step S12 to charge the battery. The work is finished.

In the above embodiment, the charging time H _n was measured, but if the charging capacity of the battery 10 can be measured, then 1
About 10% charge is desirable. As described above, in the embodiment of the present invention, when the temperature T _n in the transformer TR is detected by the temperature sensor 26 and becomes equal to or higher than the set value T _S , the output voltage of the transformer TR is reduced to the set value. When it becomes T _S or less, the control for increasing the output voltage is performed. Therefore, according to the voltage of the AC power supply 2, the tap wires 13a, 13
It is not necessary to select and fix the selection of b in advance according to the AC power supply 2 used.

Further, in the embodiment of the present invention, since the transformer TR steps down the AC voltage with an appropriate voltage, the battery 10 can be charged efficiently, and overcharging or insufficient charging can be eliminated.

The present invention is not limited to the above embodiment, but can be embodied as follows. (1) In the above-described embodiment, the temperature inside the transformer TR is detected by the temperature sensor 26, but instead of this, the operating time of the transformer TR is detected, and for example, the primary of the transformer TR is divided into the initial period, the middle period, and the latter period. Side voltage tap line 13
Adjust with a and 13b.

(2) Based on the detection signal from the DC voltage sensor 25, the tap lines 13a, 13 of the transformer TR are provided.
b should be controlled. (3) The tap line can be switched between three or more steps or steplessly.

[0028]

As described above in detail, according to the present invention, it is possible to omit the troublesome work of switching the tap line in advance according to the voltage of the AC power supply, and to change the transformer according to the load condition of the transformer. By adjusting the output voltage of the battery, there is an effect that the charging work to the battery can be properly and efficiently performed and the charging time can be shortened.

[Brief description of drawings]

FIG. 1 is an electric circuit diagram showing an embodiment embodying the present invention.

FIG. 2 is a circuit diagram in the vicinity of a primary winding of a transformer.

FIG. 3 is a flowchart showing a charging operation of the charging device.

FIG. 4 is an electric circuit diagram showing a conventional charging device.

[Explanation of symbols]

1 charger, 4 primary winding, 6 lead wire, 7 magnet switch, 9 rectifier circuit, 10 battery, 13
a, 13b Tap line constituting output voltage adjusting means, 1
4 switching contactor constituting output voltage adjusting means, 15
Electromagnetic solenoids constituting output voltage adjusting means, 17 charging start switch, 21 control device as voltage controlling means, 25 voltage sensor, 26 temperature sensor as transformer load state detecting means, TR transformer.

Claims (1)

[Claims] 1. A charging device comprising a transformer for stepping down an AC power supply voltage and a rectifier circuit for rectifying the AC voltage stepped down by the transformer into a DC voltage for charging a battery, wherein an output voltage of the transformer is adjusted. Output voltage adjusting means, transformer load state detecting means such as operating temperature, operating time of the transformer, or charging voltage for the battery, and output voltage adjusting means for the transformer based on a detection signal from the transformer load state detecting means. And a voltage control means for controlling the charging means.