KR20220021765A - AGM battery electrolyte injection device that measures electrolyte by top-off method - Google Patents

Abstract

The present invention relates to an AGM battery electrolyte injection device for metering an electrolyte in a top-off manner, more specifically, to an AGM battery electrolyte injection device for metering an electrolyte in a top-off manner, using a measuring cup to measure an electrolyte in a top-off manner, which enables the measuring at high speed and measuring an electrolyte in an accurate amount. According to the present invention, it is possible to measure an electrolyte in a top-off manner using a measuring cup, thereby providing the effect that the electrolyte can be measured in an exact amount while being able to measure at high speed. In addition, the present invention prevents the deviation of an electrolyte meter from occurring due to mechanical wear and aging due to repeated use, thereby preventing the deviation between cells and products and reducing facility maintenance costs.

Description

AGM battery electrolyte injection device that measures electrolyte by top-off method

The present invention relates to an AGM battery electrolyte injection device for metering an electrolyte in a top-off method, and more particularly, by measuring the electrolyte in a top-off method using a measuring cup, it is possible to measure the electrolyte in an accurate amount while enabling fast measurement. It relates to an AGM battery electrolyte injection device for metering an electrolyte in a top-off manner to make it possible.

A battery is a device that supplies electric power by converting chemical energy into electrical energy using the redox reaction of electrons. In such a battery, a negative electrode material, a positive electrode material, and a separator are loaded in a cylindrical case, and an electrolyte is filled.

In order to inject the electrolyte into the battery configured as described above, the inside of the case is first formed in a vacuum state to form conditions for easily injecting the electrolyte, and then the electrolyte is injected and sealed through the processes of injecting the electrolyte. Since performance is determined by how much the electrolyte is fully charged inside the battery case, various studies are being conducted on the electrolyte injection process in the battery process.

1 is an exemplary view showing an injection nozzle of a conventional electrolyte injection device.

The injection nozzle 100 of FIG. 1 is installed in an automatic electrolyte injection device (not shown) for injecting electrolyte into the battery, and the injection nozzle 100 has a vacuum connection hole 101 connected to a vacuum suction device, and a pressure device. It consists of a pressurized connection hole 103 to be connected, an electrolyte inlet hole 105 to which an electrolyte is supplied, and a cell contact hole 107 contacting the battery so that the electrolyte introduced into the electrolyte inlet 105 is injected into the battery.

That is, the injection nozzle 100 is composed of a 3-way valve 109 that determines the vacuum, electrolyte injection and pressurization.

In the injection nozzle 100 configured in this way, when the 3-way valve 109 is rotated and vacuum, electrolyte injection, and pressurization are repeatedly and long-term, the 3-way valve 109 is worn and the electrolyte is introduced into the other valve. There is a problem that the electrolyte cannot be injected.

In addition, there is a problem in that the quality of the battery is deteriorated because a fixed amount of the electrolyte is not injected.

In addition, in the conventional process of injecting the electrolyte into the battery, the operation time is delayed because the electrolyte is manually injected while the battery is raised and lowered and the injection nozzle 100 is lowered so that the injection nozzle 100 and the battery are integrally connected. And, the quality becomes non-uniform, the work efficiency is lowered, and this causes the production to be reduced, and there are problems that defects occur if skilled workers do not work.

On the other hand, not only the general battery electrolyte injection process, but also in the case of the AGM product related to the present invention, it is necessary to inject a fixed amount of the electrolyte.

To be more specific, since the separator of AGM products is made of fiberglass, the electrolyte cannot be put into the glass fiber separator by pouring the electrolyte into the semi-finished product.

Therefore, the electrolyte is injected by holding the vacuum inside the semi-finished product and forcing the electrolyte to the inside of the glass fiber.

If the electrolyte is injected into the product for chemical conversion, the electrolyte impregnated in the glass fiber cannot be removed again, so it is necessary to measure the electrolyte in an accurate amount from the beginning in order to reduce variations by cell and product.

As a method of measuring the electrolyte, there are a method of measuring by volume and a method of measuring by weight.

The method of weighing by volume can measure quickly, but when it is used repeatedly for a long time, the setting value of the meter is changed due to mechanical wear, etc., and there is a disadvantage that deviation occurs for each product cell.

On the other hand, the method of weighing by weight has the advantage of being able to measure with an accurate value, but it requires an expensive load cell and a flow meter, and has a disadvantage in that the speed is very slow because the electrolyte is slowly measured to match the weight of the electrolyte.

Therefore, the present invention provides an AGM product electrolyte injector that has been proposed to measure the electrolyte solution in a top-off method in a measuring cup and to measure the electrolyte in an accurate amount while being able to quickly measure the electrolyte, and through this, the structure is simple, It is possible to provide the effect of reducing equipment deterioration and occurrence of deviations due to repeated use.

Republic of Korea Patent Publication No. 10-2007-51040 (2017.05.11.)

The present invention was devised to supplement the above-described problems.

An object of the present invention is to provide an AGM battery electrolyte injector for metering an electrolyte in a top-off manner in order to measure the electrolyte in a top-off manner using a measuring cup, and to measure the electrolyte in an accurate amount while being able to quickly measure.

In order to solve the above-mentioned problems and achieve the object, the AGM battery electrolyte injection device for metering the electrolyte in the top-off method of the present invention,

The electrolyte preparation tank 100 for storing the electrolyte to be injected into the AGM battery; and

A weighing tank 200 having an internal space and constituting a plurality of measuring cup parts 210 at regular intervals in the internal space; and

An electrolyte solution passage pipe 300 installed between the electrolyte production tank 100 and the metering tank 200 and configured to provide the electrolyte stored from the electrolyte production tank to the metering tank; and

A plurality of metering electrolyte movement path pipes 400, each of which one side is connected to the plurality of measuring cup parts 210, and the other side is connected to respective vacuum tanks to provide the electrolyte measured in the measuring cup part to the vacuum tank; class

A plurality of metered electrolyte passage tube valves 500 for supplying the metered electrolyte to the vacuum tank when each formed and opened in the plurality of metered electrolyte passage pipe 400; and

It is connected to the other side of the metered electrolyte movement path tube 400, and after capturing the vacuum present in the AGM battery located at the lower side, the metered electrolyte provided through the metered electrolyte movement passage tube 400 is injected into the AGM battery. By including a plurality of vacuum tanks (600); to solve the problem of the present invention.

The AGM battery electrolyte injection device for metering the electrolyte in the top-off method of the present invention has the effect that, through the above-described configuration, the electrolyte is metered in the top-off method using a measuring cup, so that it is possible to measure the electrolyte in an accurate amount while being able to measure it at a fast speed will provide

In addition, it prevents the deviation of the electrolyte meter from occurring due to mechanical wear and aging due to repeated use, thereby preventing the deviation between cells and products, and providing the effect of reducing facility maintenance costs.

1 is an exemplary view showing an injection nozzle of a conventional electrolyte injection device.
2 is a basic structural diagram of an AGM battery electrolyte injection device for metering an electrolyte in a top-off manner according to an embodiment of the present invention.
3 is a controller block diagram of an AGM battery electrolyte injection device for metering an electrolyte in a top-off manner according to an embodiment of the present invention.

AGM battery electrolyte injection device for metering electrolyte in a top-off method according to an embodiment of the present invention,

The electrolyte preparation tank 100 for storing the electrolyte to be injected into the AGM battery; and

A weighing tank 200 having an inner space and constituting a plurality of measuring cup units 210 at regular intervals in the inner space; and

An electrolyte solution passage pipe 300 installed between the electrolyte production tank 100 and the metering tank 200 and configured to provide the electrolyte stored from the electrolyte production tank to the metering tank; and

A plurality of metering electrolyte movement path pipes 400, each of which one side is connected to the plurality of measuring cup parts 210, and the other side is connected to respective vacuum tanks to provide the electrolyte measured in the measuring cup part to the vacuum tank; class

A plurality of metered electrolyte passage tube valves 500 for supplying the metered electrolyte to the vacuum tank when each formed and opened in the plurality of metered electrolyte passage pipe 400; and

It is connected to the other side of the metered electrolyte movement path tube 400, and after capturing the vacuum present in the AGM battery located at the lower side, the metered electrolyte provided through the metered electrolyte movement passage tube 400 is injected into the AGM battery. A plurality of vacuum tanks (600); characterized in that it is configured to include.

At this time, the measuring cup part 210,

It is characterized by injecting electrolyte into 6 cells of 12V AGM battery at once.

At this time, the measuring cup part 210,

It is characterized in that it is possible to adjust the amount of electrolyte according to the size of the measuring cup part by being measured in a top-off method.

At this time, the weighing tank 200,

The electrolyte production tank 100 and the other side are connected to one side, and the electrolyte discharge pipe 700 comprising the electrolyte discharge pipe valve 710; Then, when the electrolyte solution is filled up to the upper end of the measuring cup part, the electrolyte discharge pipe valve 710 is opened and the electrolyte existing in the measuring tank 200 is discharged to the electrolyte manufacturing tank, so that the electrolyte measured only in the plurality of measuring cup parts 210 is discharged. It is characterized in that it is stored.

At this time, the weighing tank 200,

By forming a water level sensor 800 in the internal space, when the electrolyte is supplied from the electrolyte production tank to the weighing tank, the water level is sensed and a water level detection signal is provided to the controller 900 when the set level value is reached. It is characterized in that the electrolyte discharge pipe valve 710 is opened by the valve opening signal.

At this time, the controller 900,

a water level detection signal acquisition unit 910 for obtaining a water level detection signal from the water level sensor 800;

an electrolyte discharge processing unit 920 for providing a valve opening signal to the electrolyte discharge tube valve 710 to open the electrolyte discharge tube valve 710 when the water level detection signal is obtained;

After providing the valve opening signal, a water level detection signal is requested from the water level sensor 800 at regular time intervals, and when the water level detection signal is not obtained after a predetermined time has elapsed, the valve is opened with the metered electrolyte passage pipe valve 500 and a metering electrolyte discharge processing unit 930 that provides a signal to open the metered electrolyte passage pipe valve 500 to supply the metered electrolyte to the vacuum tank.

Hereinafter, an AGM battery electrolyte injection device for metering an electrolyte in a top-off manner according to the present invention will be described in detail with reference to the drawings.

1 is a basic structural diagram of an AGM battery electrolyte injection device for metering an electrolyte in a top-off manner according to an embodiment of the present invention.

1, the AGM battery electrolyte injection device for metering the electrolyte in a top-off manner is an electrolyte preparation tank 100, a metering tank 200, an electrolyte movement path pipe 300, and a metered electrolyte movement path tube ( 400), a plurality of metered electrolyte passage pipe valves 500, and a plurality of vacuum tanks 600 are included.

In the above configuration, after the electrolyte of the desired specific gravity is prepared in the electrolyte production tank, the electrolyte is sent to the weighing tank, the electrolyte measured in the top-off method from the weighing tank is sent to the vacuum tank, and the electrolyte is injected while holding the vacuum inside the AGM semi-finished product way to do it

Specifically, the electrolyte preparation tank 100 is to store the electrolyte to be injected into the AGM battery.

This means an electrolyte production tank that matches the specific gravity of electrolyte to be injected into AGM products.

In addition, as shown in FIG. 1 , the measuring tank 200 has an internal space, and a plurality of measuring cup parts 210 are configured at regular intervals in the internal space.

This constitutes a plurality of measuring cups 210 in the inner space in order to measure an accurate amount of the electrolyte.

At this time, the measuring cup part 210,

Six 12V AGM batteries are formed, and electrolyte is injected into six cells of 12V AGM batteries at once.

Since the electrolyte must be measured for each product cell, there are 6 measuring cups inside the measuring tank (based on 12V lead-acid battery), and the bottom of the measuring cup is connected to each cell of the vacuum tank.

And, the measuring cup part 210,

It is characterized in that it is possible to adjust the amount of electrolyte according to the size of the measuring cup by measuring in a top-off method.

Since the measuring cup part is measured top off, the amount of electrolyte can be adjusted by setting the size of the cup.

Then, the electrolyte movement path pipe 300 is installed and configured between the electrolyte preparation tank 100 and the metering tank 200 .

Accordingly, a movement path for providing the electrolyte stored from the electrolyte preparation tank to the metering tank is provided.

Then, by connecting one side of each of the plurality of metering electrolyte movement path tubes 400 to the plurality of measuring cup units 210 and connecting the other end to each vacuum tank, the electrolyte measured in the measuring cup unit is transferred to a vacuum tank. will be provided as

In the embodiment of the present invention, since six measuring cups are constituted, it is a self-evident fact that six measuring electrolyte passage tubes 400 are formed.

In addition, when a plurality of metered electrolyte passage pipe valves 500 are formed and opened in the plurality of metered electrolyte passage tube 400, respectively, the metered electrolyte is supplied to each vacuum tank.

In the embodiment of the present invention, since six measuring cups are constituted, it is a self-evident fact that six measuring electrolyte passage pipe valves 500 are formed.

In addition, a plurality of vacuum tanks 600 are connected to the other side of the metered electrolyte movement path pipe 400 to constitute.

Therefore, after capturing the vacuum present in the AGM battery located at the lower side, the metered electrolyte provided through the metered electrolyte passage pipe 400 is injected into the AGM battery.

In other words, a vacuum tank that holds a vacuum and injects electrolyte into AGM semi-finished products will be provided.

On the other hand, according to an additional aspect, the weighing tank 200,

The electrolyte production tank 100 and the other side are connected to one side, and the electrolyte discharge pipe 700 comprising the electrolyte discharge pipe valve 710; Then, when the electrolyte solution is filled up to the upper end of the measuring cup part, the electrolyte discharge pipe valve 710 is opened and the electrolyte existing in the measuring tank 200 is discharged to the electrolyte manufacturing tank, so that the electrolyte measured only in the plurality of measuring cup parts 210 is discharged. It is characterized in that it is stored.

That is, the metering tank 200 is connected to the electrolyte production tank 100 on one side and the other side, and includes an electrolyte discharge pipe 700 including an electrolyte discharge pipe valve 710 .

Therefore, after sending the electrolyte from the electrolyte production tank to the metering tank, when the electrolyte is full up to the upper end of the measuring cup, the electrolyte discharge pipe valve 710 is opened to discharge the electrolyte present in the metering tank 200 to the electrolyte production tank, It is to store the measured electrolyte only in the plurality of measuring cups 210 .

To explain the operation process, when the electrolyte is sent from the electrolyte preparation tank to the weighing tank to fill the weighing tank, and the electrolyte is discharged through the electrolyte discharge pipe 700 installed at the bottom of the weighing tank, the electrolyte remains only in the measuring cup and is discharged.

When the metering electrolyte passage tube valve 500 formed in the metering electrolyte passage pipe 400 at the bottom of the measuring cup part is opened and the electrolyte flows into the vacuum tank, the electrolyte is injected from the vacuum tank to the semi-finished AGM product, and 1 cycle ends. do.

In the measuring tank, since the measuring cup has to be filled with electrolyte, a sufficient amount of electrolyte must be introduced, and the electrolyte that overflows and is discharged outside the measuring cup is recovered to the manufacturing tank.

Through the above configuration, it is possible to prevent the deviation of the electrolyte meter from occurring due to mechanical wear and aging due to repeated use, thereby preventing the deviation between cells and products, and providing the effect of reducing the facility maintenance cost.

On the other hand, the weighing tank 200,

By forming a water level sensor 800 in the internal space, when the electrolyte is supplied from the electrolyte production tank to the weighing tank, the water level is sensed and a water level detection signal is provided to the controller 900 when the set level value is reached. It is characterized in that the electrolyte discharge pipe valve 710 is opened by the valve opening signal.

That is, the water level sensor is configured in the inner space of the weighing tank 200, and preferably, it may be positioned on the same horizontal line as the measuring cup portion or may be configured at a slightly higher position.

Meanwhile, as another embodiment, by setting a water level value, it may be configured to operate when the water level value is reached.

That is, when the electrolyte is supplied from the electrolyte production tank to the weighing tank, the water level is sensed and when the set level value is reached, the water level detection signal is provided to the controller 900, and the electrolyte discharge pipe valve 710 according to the valve opening signal of the controller. ) to open.

For example, when the set water level height is 30 cm, when the corresponding water level height of 30 cm is detected, a water level detection signal is provided to the controller 900, and the electrolyte discharge pipe valve 710 is opened by the valve opening signal of the controller. will be.

2 is a block diagram of a controller 900 of an AGM battery electrolyte injection device for metering an electrolyte in a top-off manner according to an embodiment of the present invention.

As shown in Figure 2, the controller 900,

a water level detection signal acquisition unit 910 for obtaining a water level detection signal from the water level sensor 800;

an electrolyte discharge processing unit 920 for providing a valve opening signal to the electrolyte discharge tube valve 710 to open the electrolyte discharge tube valve 710 when the water level detection signal is obtained;

After providing the valve open signal, a water level detection signal is requested from the water level sensor 800 at regular time intervals, and when the water level detection signal is not obtained after a predetermined time elapses, the valve is opened with the metered electrolyte passage pipe valve 500 and a metering electrolyte discharge processing unit 930 that provides a signal to open the metered electrolyte passage pipe valve 500 to supply the metered electrolyte to the vacuum tank.

Specifically, the water level detection signal acquisition unit 910 obtains a water level detection signal from the water level sensor 800 .

That is, event information including the level detection signal is provided to the electrolyte discharge processing unit.

At this time, when the electrolyte discharge processing unit 920 obtains the water level detection signal, for example, when event information including the level detection signal is obtained, the electrolyte discharge pipe valve 710 provides a valve opening signal to the electrolyte discharge pipe The valve 710 is opened.

Then, the electrolyte existing in the measuring tank is discharged to the electrolyte preparation tank, and a certain amount of the electrolyte is contained in the measuring cup part.

Thereafter, after providing the valve opening signal, the metering electrolyte discharge processing unit 930 requests a water level detection signal from the water level sensor 800 at regular time intervals.

For example, if a water level detection signal is requested every 5 seconds, and a level detection signal is not obtained after a certain period of time, that is, when the electrolyte is discharged to the electrolyte manufacturing tank, the water level is lowered and the water level detection signal is not obtained. can't

At this time, a valve opening signal is provided to the metered electrolyte passage tube valve 500 to open the metered electrolyte passage tube valve 500 to supply the metered electrolyte to the vacuum tank.

As a result, by supplying a predetermined amount of the electrolyte measured under the control of the controller to the vacuum tank, it is possible to measure the electrolyte at a high speed while providing the effect of measuring the electrolyte in an accurate amount.

Through the configuration and operation as described above, the electrolyte is measured in a top-off manner using a measuring cup, thereby providing the effect that the electrolyte can be measured in an accurate amount while being able to measure at a high speed.

In addition, it prevents the deviation of the electrolyte meter from occurring due to mechanical wear and aging due to repeated use, thereby preventing deviation between cells and products, and providing the effect of reducing facility maintenance costs.

Among the above-described contents, the contents not shown in the drawings are contents that can be fully understood by those skilled in the art based on the above-described contents, and should be included in the rights of the present invention even if they are not shown in the drawings below.

Those skilled in the art to which the present invention pertains as described above will understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, it should be understood that the embodiments described above are illustrative in all aspects and not restrictive.

The scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. .

100: electrolyte production tank
200: weighing tank
300: electrolyte movement path tube
400: metered electrolyte flow path tube
500: metered electrolyte flow path pipe valve
600: vacuum tank

Claims (4)

In the AGM battery electrolyte injection device for metering the electrolyte in a top-off method,
The electrolyte production tank 100 for storing the electrolyte to be injected into the AGM battery; and
A weighing tank 200 having an internal space and constituting a plurality of measuring cup parts 210 at regular intervals in the internal space; and
An electrolyte movement path pipe 300 installed between the electrolyte production tank 100 and the metering tank 200 and configured to provide the electrolyte stored from the electrolyte production tank to the metering tank; and
A plurality of metering electrolyte movement path tubes 400 having one end connected to each of the plurality of measuring cup portions 210 and the other end connected to respective vacuum tanks to provide the electrolyte metered from the measuring cup portion to the vacuum tank; class
A plurality of metered electrolyte passage tube valves 500 for supplying the metered electrolyte to the vacuum tank when each formed and opened in the plurality of metered electrolyte passage pipe 400; and
It is connected to the other side of the metered electrolyte movement path tube 400, and after capturing the vacuum present in the AGM battery located on the lower side, the metered electrolyte provided through the metered electrolyte movement passage tube 400 is injected into the AGM battery. AGM battery electrolyte injection device for metering the electrolyte in a top-off method, characterized in that it includes a plurality of vacuum tanks (600). The method of claim 1,
The measuring cup part 210,
AGM battery electrolyte injection device for metering electrolyte in a top-off method, characterized in that the electrolyte is injected into 6 cells of 12V AGM batteries at once.
The method of claim 1,
The measuring cup part 210,
AGM battery electrolyte injection device for metering electrolyte in a top-off method, characterized in that by metering in a top-off method, the amount of electrolyte can be adjusted according to the size of the measuring cup.
The method of claim 1,
AGM battery electrolyte injection device for metering the electrolyte in a top-off manner, characterized in that the plurality of metered electrolyte passage pipe valves 500 discharge the metered electrolyte to the vacuum tank under the control of the controller.

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