KR101775357B1 - A manufacturing method of lead-acid battery - Google Patents

Abstract

The present invention relates to a method of manufacturing a lead acid battery, which comprises an additive storage tank (1) filled with an additive for storing an additive, an electrolyte tank (2) filled with diluted sulfuric acid mixed with water and sulfuric acid, A conveyor 3 for conveying the additive from the container 1 to the electrolyte tank 2 and a scale 4 for measuring the amount of the additive which is provided on the exit side of the conveyor 3 and for controlling the weighing and dosing of the additive (S100) of adding an additive to the additive storage tank (1) by using a lead-acid battery manufacturing apparatus including a control device for controlling the additive; A step (s200) of setting the amount of additive to be supplied to the electrolyte tank 2; a transfer step (s300) of transferring the added additive to the balance 4 using the conveyor 3; A metering step (S400) of measuring the transferred additive to the scale (4); A metering end step (S500) of an additive corresponding to an input amount of the set additive; (S600) of injecting the metered additive into the electrolyte tank (2), wherein the method comprises the steps of: reducing the amount of labor load generated by the operator by manually inserting the additive into the additive, And to be able to obtain the effect of relieving the health worry caused by.

Description

[0001] The present invention relates to a manufacturing method of a lead-acid battery,

The present invention relates to a method of manufacturing a lead-acid battery which improves the method of adding an additive to a lead-acid battery electrolyte.

Lead-acid batteries use diluted sulfuric acid as an electrolyte that conducts ions through an electrochemical reaction inside. Although lead acid batteries can be produced using only dilute sulfuric acid as an electrolyte, the life and performance of lead acid batteries can be improved by adding additives to the electrolyte solution. Thus, Patent Publication No. 10-20090045483 provides a technique for adding sodium sulfate as an additive to an electrolyte consisting of sulfuric acid and water. In addition, Japanese Laid-Open Patent Publication No. 1020070120011 provides a technique of adding carbon particles to an electrolyte solution made of sulfuric acid and water, and further adding a substance selected from calcium, strontium, potassium and sodium.

However, in the conventional method, the additive is injected into the electrolytic solution tank in an amount corresponding to the electrolytic solution filled in the electrolytic solution tank, and the additive is injected by gravity. Therefore, And the like. In particular, the electrolyte tank is installed at a generally high position for facilitating the charging of the electrolyte into the battery, so that it is difficult to inject the additive into the electrolyte tank at a high position because the electrolyte is charged into the battery using the potential energy.

Published patent application No. 1020090045483 'Electrolyte composition of lead-acid battery' Published date: 2009.05.08 Published Patent No. 1020070120011 'Electrolyte additive for battery and its manufacturing method' Published date: December 21, 2007

Therefore, the present invention aims to solve the problem that the additive can be easily injected in a fixed amount by improving the conventional method of adding the additive to the electrolytic solution, thereby saving the time for injecting the additive and reducing the manpower.

According to an aspect of the present invention, there is provided a method of manufacturing a lead-acid battery comprising the steps of: (1) adding an additive to an additive storage tank for storing an additive; (2) adding a dilute sulfuric acid- 2), a conveyor 3 for conveying the additive from the additive storage tank 1 to the electrolyte tank 2, a scale 4 for measuring the additive which is installed on the exit side of the conveyor 3 and conveyed, (S100) of adding an additive to the additive storage tank (1) by using a lead-acid battery manufacturing apparatus including a control device for controlling metering and an input amount of the additive; A step (s200) of setting the amount of additive to be supplied to the electrolyte tank 2; a transfer step (s300) of transferring the added additive to the balance 4 using the conveyor 3; A metering step (S400) of measuring the transferred additive to the scale (4); A metering end step (S500) of an additive corresponding to an input amount of the set additive; And an adding step (s600) of adding the additive to the electrolyte tank (2).

In the present invention as described above, when the operator inserts the additive into the additive tank, the additive is transported and measured by the conveyor to the installation place of the electrolyte tank installed at a height, and the additive is automatically introduced into the electrolyte tank. Therefore, It is possible to obtain the effect of reducing the amount of labor load to be incurred and solving the concern of health problems caused by additives.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a brief explanatory diagram of an additive adding device for carrying out the ice making process of the present invention. FIG.
Figure 2 is an illustration of an additive storage tank for storing additives and supplying additives to the conveyor belt.
3 is a simplified explanatory diagram of a scale for measuring the amount of additive.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a method of manufacturing a lead acid battery, comprising the steps of: (1) adding an additive to an additive to store an additive; (2) an electrolyte tank filled with diluted sulfuric acid mixed with water and sulfuric acid; A conveyor 3 for conveying the additive to the electrolyte tank 2 from the conveyor 1 and a balance 4 for measuring the amount of the additive to be conveyed, By using a lead-acid battery manufacturing apparatus including a control device,

A step (s100) of injecting an additive into the additive storage tank (1) (s100); a step (s200) of setting the amount of additive to be injected into the electrolyte tank (2); A transfer step (s300) for transferring the added additive to the scale (4) using the conveyor (3); A metering step (S400) of measuring the transferred additive to the scale (4); A metering end step (S500) of an additive corresponding to an input amount of the set additive; And an additive adding step (s600) of adding the metered additives to the electrolyte tank (2).

After the sulfuric acid solution of specific gravity to be used is filled in the electrolyte tank 2, the amount of the additive to be charged is set in the central control unit. The balance (4) is for charging a desired amount of additive. The weight of the additive is measured, and the balance is put into the electrolyte solution. The error range of the input amount during the addition should be within ± 0.1%. The balance (4) preferably includes a charging port (41) for charging the metered additive into the electrolyte tank (2).

The additive storage tank 1 is preferably made of a corrosion-resistant material in order to prevent corrosion of the tank in the additive injecting step (s100) of injecting the additive into the additive storage tank 1. [

The additive stored in the additive storage tank 1 in the transfer step s300 for transferring the added additive to the conveyor 3 is conveyed to the weighing scale 4 by the conveyor 3. Since the additive usually has the shape of small grains, it is preferred that the conveyor 3 be a screw conveyor for transporting from the ground to the top.

A metering step (S400) of measuring the transferred additive to the scale (4), a metering end step (s500) of the additive corresponding to the input amount of the additive, and an additive injecting step (s600) of injecting the metered additive When the weight of the additive is measured by a balance, and if it meets the set value, an additive is added to the produced sulfuric acid solution to prepare an electrolytic solution. This electrolytic solution is an electrolytic solution used in the production of lead-acid batteries.

 It is preferable to configure a central control device capable of operating all of the above operations by the operator so that the additive is automatically supplied to the electrolyte tank. This makes it possible to anticipate the effect of reducing the amount of labor load caused by the operator manually inserting the additive and solving the health concern over the additive.

By adding the electrolyte additive in a fixed amount, the life and performance of the lead-acid battery can be improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it should be understood that various changes and modifications will be apparent to those skilled in the art. It is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the scope of protection of the present invention should be construed according to the following claims, and all technical ideas which fall within the scope of equivalence by alteration, substitution, substitution and the like within the scope of the present invention, Range. In addition, it should be clarified that some configurations of the drawings are intended to explain the configuration more clearly and are provided in an exaggerated or reduced size than the actual configuration. It is to be understood that the appended claims are intended to facilitate understanding only and do not limit the shape and construction of the present invention to the accompanying drawings.

1. Additive storage tank
2. Electrolyte tank
3. Conveyor
4. Scales
41. Inlet

Claims (3)

A method of manufacturing a lead-acid battery,
An additive storage tank 1 filled with an additive for storing an additive, an electrolyte tank 2 filled with diluted sulfuric acid mixed with water and sulfuric acid, and additives from the additive storage tank 1 to the electrolyte tank 2 (4) for measuring the amount of the additive to be conveyed and installed on the conveying side (3) of the conveyor (3), and a control device for controlling the amount of the additive and the amount of the additive So,
An additive injecting step (s100) of adding an additive to the additive storage tank (1);
The step (s200) of setting the amount of the additive to be supplied to the electrolyte tank 2,
A transfer step (s300) for transferring the added additive to the scale (4) using the conveyor (3);
A metering step (S400) of measuring the transferred additive to the scale (4);
A metering end step (S500) of an additive corresponding to an input amount of the set additive;
(S600) of injecting the metered additive into the electrolyte tank (2)
The additive storage tank 1 is made of a corrosion-resistant material to prevent corrosion of the tank, and the additive is a granular additive in an additive injecting step (s100) of injecting an additive into the additive storage tank 1,
Wherein the conveyor (3) is a screw conveyor in a conveying step (s300) for conveying the introduced additive to the conveyor (3).

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