KR0159876B1 - Automatic electrolyte reserving apparatus and control method - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automated manufacturing system for battery elements. In the related art, since the process of injecting electrolyte into battery cans in the conventional system relies on manual labor, it is possible to maintain the productivity and reliability of the product. There was a problem.

The present invention is installed in the electrolyte reservoir 3 for injecting the electrolyte to improve the problems of the prior art, the electrolyte height detection unit 13 for detecting a constant level of the electrolyte reservoir 3 to generate a detection signal, The AD converter 12 which is connected to the output side of the electrolyte height detection unit 13 and performs analog / digital conversion processing on the signal detected therefrom, and the digital data which is connected to the output side of the AD converter 12 and inputted are referred to as reference value data. In comparison, the microcomputer 11 which provides a constant control signal to the solenoid valve 15 which supplies electrolyte solution to electrolyte storage tank, the valve drive part 14 which connects to the output side of this microcomputer 11, and drives a solenoid valve, SUMMARY OF THE INVENTION The present invention provides an apparatus for automatically holding a certain amount of battery electrolyte solution composed of a solenoid valve 15 connected to an output side of a valve drive unit 14 and a control processing method thereof.

Description

Battery electrolyte automatic holding device and control method

1 is an example showing an automated production process of a battery device.

2 is a circuit block diagram of the battery electrolyte constant amount automatic holding apparatus according to the present invention.

Figure 3 is an embodiment of the automatic holding amount of electrolyte constant associated with FIG.

4 is a flowchart showing a method for automatically controlling a predetermined amount of electrolyte according to the present invention.

* Explanation of symbols for main parts of the drawings

11: Micom 12: Adie Converter

13: electrolyte height detection part 13a: variable resistance

13b: movable lever 14: valve driving unit

15: solenoid valve 3: electrolyte storage tank

31: battery can 32: nozzle

33: support rod 33a: ball

34: supply pipe

The present invention relates to an automated manufacturing system for a battery element, and in particular, to improve the productivity of such a system by enabling the automatic supply of a certain amount of electrolyte to the battery cans in such a system.

An example of the automatic manufacturing system of the battery element is shown in FIG.

In this case, the battery element is molded into a cylindrical battery can 31, and then moved to a predetermined position of the conveyor line 4, followed by an electrolyte injection process through an electrolyte injection device 5 for injecting electrolyte into the battery can 31. After the electrolyte is injected through the electrolyte injection device 5, the battery cap 6 is assembled into a battery cap 6 assembly process that closes the opening of the battery can 31.

After the battery cap 6 is assembled, the battery element 7 is obtained through a pre-discharge process.

In such an automated manufacturing process of a battery element, there is a lack of precision, such as whether or not the electrolyte is injected into the battery can 31 from the electrolyte injection device 5 by hand, so that a certain amount is properly filled. It was difficult to avoid the inconvenience and hassle of the injection work.

In addition to this work by manual operation, the time required for the injection work is slow, there is a problem that affects the overall productivity.

An object of the present invention is to be able to automate the process of injecting the electrolyte solution of the battery can of the battery element in order to improve such a conventional problem, so that it is possible to obtain a good productivity improvement and reliability of the article.

Particularly, the present invention is provided in an electrolyte storage tank for injecting electrolyte solution so as to realize the above object, and is connected to the electrolyte height detection unit for detecting a constant level of the electrolyte storage tank and generating a detection signal, and the output of the electrolyte height detection unit. To the solenoid valve for electronic control of the AD converter for analog-to-digital conversion of the detected signal from the AD converter, and the air supply valve for supplying the electrolyte to the electrolyte reservoir by comparing the digital data received at the output side of the AD converter with the reference value data. And a battery electrolyte holding device including a microcomputer providing a constant signal, a valve driving unit connected to the output side of the microcomputer to drive the solenoid valve, and a solenoid valve connected to the output side of the valve driving unit.

A further feature of the present invention is that the micro valve is mounted on the microcomputer and supplies the electrolyte to the electrolyte reservoir, measures the height of the electrolyte, and compares this value with the electrolyte reference value associated with the electrolyte reference amount supplied to the can of the battery element. It is characterized by a predetermined amount of automatic control processing method of the electrolyte consisting of a series of processing to control the.

Hereinafter, more specific features of the present invention will be understood by describing the same in detail with the accompanying drawings.

That is, FIG. 2 shows a circuit block diagram constituting the electrolyte constant amount automatic holding apparatus according to the present invention.

Here, the electrolyte height detection unit 13 is installed in the electrolyte storage tank 3 for injecting the electrolyte solution and detects a constant level of the electrolyte storage tank 3 to generate a detection signal, and the output side of the electrolyte height detection unit 13 The AD converter 12 which performs analog / digital conversion processing of the detected signal and the digital data which is connected to the output side of the AD converter 12 and compares the input digital data with reference value data to supply or block the electrolyte solution to the electrolyte storage tank. The microcomputer 11 which provides a constant control signal to the valve 15, the valve drive part 14 which is connected to the output side of this microcomputer 11, and drives an electromagnetic valve, and the output side of this valve drive part 14 is connected. It consists of a solenoid valve 15.

The electrolyte height detector 13 may be implemented as shown in FIG. 3.

In this case, a buckle 33a capable of arcing movement around the point a provided at a predetermined portion of the electrolyte reservoir 3, a support rod 33 supporting the buckle 33a, and the support rod 33 One end may be extended to form the movable lever 13b of the potentiometer, and may be constituted by the variable resistor 13a whose resistance value changes in connection with the circular arc operation of the movable lever 13b.

In addition, an electrolyte supply pipe 34 is provided on one side of the main body of the electrolyte storage tank 3, and the electrolyte supply pipe 34 is provided with a solenoid valve 15 controlled by the valve drive unit 14.

In addition, 32 is an electrolyte solution nozzle which inject | pours electrolyte solution into the battery can 31 here.

On the other hand, the electrolyte constant amount control processing program 100 associated with the system circuit is shown in FIG.

Here, the solenoid valve is opened by comparing the electrolytic solution with the electrolytic solution, which is mounted on the microcomputer 11, to supply the electrolytic solution to the electrolytic solution storage tank 3, and specifies the height of the electrolytic solution and the electrolytic solution reference value supplied to the can of the battery element. It consists of a series of processes to control.

That is, when the step is started, the electrolyte is first supplied to the electrolyte storage tank 3 (step 101), and the electrolyte height is measured (step 102).

Next, the amount of electrolyte shortage is calculated by the system microcomputer 11 (step 103), and the electrolyte is supplied by the amount insufficient by the electrolyte supply pump (step 104).

The electrolyte height is measured again (step 105). As a result, if the electrolyte height <reference value, the electrolyte supply pump operation step (step 104) goes out (step 106). If it is not the same, the process proceeds to the step 101 (step 107).

In the present invention, when the battery can 31 is positioned on the side of the electrolyte injection device 5 in the process of moving the battery element on the conveyor line 4 as shown in FIG. 1, the electrolyte of the electrolyte storage tank 3 is shown in FIG. The electrolyte is injected into the battery can 31 through the supply nozzle 32.

At this time, the electrolyte storage tank 3 maintains a constant reference value by the electrolyte constant amount automatic holding apparatus according to the present invention, so that the hydraulic pressure of the electrolyte supplied from the electrolyte supply nozzle 32 is kept constant. If the opening and closing time of the supply nozzle 32 is correctly maintained, the amount of electrolyte can be added to the battery can 31.

On the other hand, in the electrolyte constant amount automatic holding circuit which constitutes the constant amount automatic holding device, the float 33a inside the electrolyte reservoir 3 is variable according to the height of the water surface, and the height of the float 33a is displaced. At this time, the amount of electricity controlled by the movable lever 13b for changing the value of the variable resistor 13a of the electrolyte height detector 13 is transmitted to the AD converter 12.

In the AD converter 12, the analog signal provided from the electrolyte height detection unit 13 is converted into a digital signal and provided to the microcomputer 11, and the microcomputer 11 already provides the reference surface data of the electrolyte storage tank 3. If the measured value is equal to the reference value compared to the currently input detection data, the solenoid valve 15 is closed through the valve driving unit 14, and when the value is lower than the reference value, the solenoid valve 15 is opened. .

Due to the opening of the spiral solenoid valve 15, when the water level of the electrolyte storage tank 3 is increased, the height of the float 33a is also increased. When the water surface reaches the reference value in this process, the solenoid valve 15 is shut off. Keep your sleep at a certain level.

Therefore, when the electrolyte is supplied to the battery can 31 through the electrolyte supply nozzle 32, the water level is lowered, so the system opens the solenoid valve 15 again so that the electrolyte is maintained at a constant height through the supply pipe 34. It will be controlled repeatedly.

On the other hand, in the control process as described above, the microcomputer 11 performs the control operation together with the electrolytic solution constant amount control processing program 100 of FIG.

Here, after the electrolyte is supplied to the electrolyte storage tank 3, the height of the electrolyte is measured, the amount of electrolyte shortage is calculated, and a constant water surface is maintained (step 101-104).

Thereafter, the height of the surface of the water is measured and the surface of the water is kept constant by comparing with the reference value (steps 105-107).

The present invention can automatically supply a fixed amount of the electrolyte injected into the battery can in the automated manufacturing system of the battery element can improve the production of such a battery element and can obtain a good reliability of the product.

Claims (3)

In an automated production system for a battery element, an electrolyte height detector (13) installed in an electrolyte reservoir (3) for injecting electrolyte and detecting a constant level of the electrolyte reservoir (3) to generate a detection signal, and the electrolyte height detector (1) The AD converter 12 for analog / digital converting the signal detected therefrom following the output side of 13, and the digital data received at the output side of the AD converter 12 are compared with the reference value data to store the electrolyte solution. The microcomputer 11 which provides a constant control signal to the solenoid valve 15 which electronically controls the supply pipe 34 which supplies electrolyte to it, and connects to the output side of this microcomputer 11, and drives the solenoid valve 15 is carried out. A battery electrolyte constant amount automatic holding device comprising a valve drive unit (14) and a solenoid valve (15) connected to an output side of the valve drive unit (14). According to claim 1, wherein the electrolyte height detection unit 13 is a buckle (33a) that can be circularly moved around the point (a) provided in a predetermined portion of the electrolyte reservoir 3, and to support the buckle (33a) The support bar 33 and one end of the support bar 33 are extended to form a movable lever 13b of the potentiometer, and the variable resistor 13a whose resistance value changes in relation to the arc operation of the movable lever 13b. Battery constant amount automatic holding device, characterized in that is configured. In the method for supplying an electrolyte solution to a battery can in an automated production process of a battery element, the electrolyte solution is supplied to the electrolyte storage tank 3 through a supply pipe 34 (step 101), and the electrolyte height is measured (step 102). The amount of electrolyte shortage is calculated by the microcomputer 11 (step 103) and supplied by the amount of the shortage through the electrolyte supply pump (step 104), and the electrolyte height is measured again (stem 105). (Step 106) checks whether the electrolyte height = reference value, if it is not (step 106), and if it is the same, the battery electrolyte solution automatic control process characterized in that it consists of a series of processing process going to the stem 101 (stem 107) Way.