KR20170050187A - Supplying device of electrolyte for battery - Google Patents

Abstract

The present invention relates to a device for supplying an electrolyte to a battery. Specifically, the device for supplying an electrolyte to a battery comprises: a battery having a plurality of cells each having an inlet formed on an upper surface thereof; and an electrolyte supply unit positioned on an upper portion of the battery to be moved in a vertical direction to inject an electrolyte into the inlets of the cells. An electrolyte can be additionally supplied to improve battery life. Since an equal amount of the electrolyte can be quickly injected into each cell by the electrolyte supply unit consisting of a single inlet unit and a plurality of supply pipes, work time and convenience are improved. Since a position where an electrolyte enters from the outside can be freely set, design performance and marketability are improved.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a battery electrolyte supply device, and more particularly, to a battery electrolyte supply device for injecting the same amount of an electrolyte into all the cells inside the battery.

Generally, a battery used in a car requires a long time of use unlike a battery used in a mobile phone or a notebook computer.

At this time, the cell, which is the smallest unit constituting the battery, is composed of an anode, a cathode, a separator, and an electrolyte.

The electrolyte, one of the components of the battery, is depleted by decomposition reaction as the battery is used, and the depletion of the electrolyte greatly affects the life of the battery.

On the other hand, although the content of the electrolyte is an important factor in the life span, since it is related to the volume and weight of the battery, it is impossible to inject a large amount unconditionally at the time of production. In case of injecting a large amount, And the like may be deteriorated.

However, in the prior art, it is impossible to inject an appropriate amount when fabricating a battery cell, and it is difficult to inject the same amount of the electrolyte solution into all the cells in the battery pack, thereby decreasing the life of the battery and deteriorating the merchantability. There is a problem that the working time and convenience are reduced.

Patent 1: Korean Patent No. 10-0614394

An object of the present invention is to provide a battery electrolyte supplying device for solving the above problems, and in particular, to allow the same amount of electrolyte to be injected into all the cells inside the battery.

The present invention provides a battery pack comprising: a battery having a plurality of cells each having an injection port formed on a top surface thereof; And an electrolyte supply part located above the battery and movable up and down to inject electrolyte into each injection port formed in the cell.

The electrolyte solution supply unit includes an inflow unit for supplying an electrolyte solution from the outside; A plurality of supply lines connected to the inlet and inserted into the inlet formed in each of the cells to supply an electrolyte; And a connection pipe connecting the inlet portion and the plurality of supply pipes and supplying the same amount of the electrolytic solution to each of the supply pipes.

Preferably, each of the injection ports has a guide line for inserting the supply pipe, and a supply hole is formed in the lower side of the supply pipe, the supply hole being opened or closed from the guide line of the injection port in accordance with the vertical movement of the electrolyte supply part.

And an elastic body is formed between the connection tube and the upper surface of the cell so that the electrolyte solution supply portion can be vertically moved up and down.

And a pack cover for covering the plurality of cells and the electrolyte solution supply unit is provided outside the battery so as to prevent the supply pipe from being separated from the electrolyte solution supply unit when the electrolyte solution supply unit is moved up and down by the elastic member.

And protrusions are formed at both ends of the lower portion of the supply pipe so as to prevent the supply pipe from departing when the electrolyte supply portion is lifted by the elastic body.

The electrolyte supply part may be screwed with a cell provided at both ends of the battery to control the vertical movement of the electrolyte supply part.

According to another aspect of the present invention, there is provided a battery pack comprising: a battery having a plurality of cells each having an injection port formed on an upper surface thereof; And an electrolyte supply part positioned above the battery and forming a permeation net to inject electrolyte into each injection port formed in the cell.

The electrolyte solution supply unit includes an inflow unit for supplying an electrolyte solution from the outside; A plurality of supply pipes connected to the inlet, inserted into the injection port formed in each of the cells, and configured to form the permeation net to allow the electrolyte to permeate into the cell as time elapses during the injection of the electrolyte, thereby supplying the electrolyte; And a connection pipe connecting the inlet portion and the plurality of supply pipes and supplying the same amount of the electrolytic solution to each of the supply pipes.

According to another aspect of the present invention, there is provided a battery pack comprising: a battery having a plurality of cells each having an injection port formed on an upper surface thereof; And an electrolyte supply part located above the battery and having a funnel to inject electrolyte into each injection port formed in the cell.

The electrolyte solution supply unit includes an inflow unit for supplying an electrolyte solution from the outside; A plurality of supply lines connected to the inlet, inserted into the inlet formed in each of the cells, the funnel being formed to allow the electrolyte to drop into the cell over time during the injection of the electrolyte, thereby supplying the electrolyte; And a connection pipe connecting the inlet portion and the plurality of supply pipes and supplying the same amount of the electrolytic solution to each of the supply pipes.

As described above, the present invention can further supply the electrolyte solution to improve the battery life, and it is possible to quickly inject the same amount of electrolyte solution into each cell through the electrolyte solution supply part including one inlet part and a plurality of supply pipes It is possible to increase the working time and convenience, and to freely set the position where the electrolyte flows from the outside, thereby improving the design performance and the merchantability.

1 is a view showing a first embodiment of an apparatus for supplying an electrolyte for a battery of the present invention,
2 is a view showing a structure in which an elastic body is applied in the first embodiment of the electrolyte supply device for a battery of the present invention,
3 is a view showing a structure in which projections are applied in the first embodiment of the electrolyte supply device for a battery of the present invention,
4 is a view showing a structure in which a screw is applied in the first embodiment of the electrolyte supply device for a battery of the present invention,
5 is a view showing a second embodiment of an apparatus for supplying an electrolyte solution for a battery of the present invention,
6 is a view showing a third embodiment of the electrolyte supply device for a battery of the present invention,
7 is a view showing a vehicle to which an electrolytic solution supply device for a battery of the present invention is applied.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(Embodiment 1)

1 to 4, a battery 100 according to an embodiment of the present invention includes a battery 100 having a plurality of cells 110 having injection ports 111 formed thereon, And an electrolyte solution supply unit 200 for injecting an electrolyte solution into the injection port 111 of the electrolyte solution supply unit 110.

As shown in FIG. 1, the battery 100 includes a plurality of cells 110, and an inlet 111 is formed in each cell 110 so that an electrolyte can be injected into the upper surface.

The electrolyte supply part 200 is located above the battery 100 and is movable up and down to inject electrolyte into each injection port 111 formed in the cell 110.

The electrolyte solution supply unit 200 includes an inlet 210 formed at an upper portion thereof, a supply pipe 220 formed at a lower portion thereof, and a connection pipe 230 connecting the inlet 210 and the supply pipe 220.

The inflow part 210 receives an electrolytic solution from the outside.

The supply pipe 220 is connected to the inflow unit 210 and is provided with a plurality of the supply pipes 220 inserted into the injection ports 111 formed in the respective cells 110 to supply the electrolytic solution.

The connection pipe 230 connects the inlet 210 and the plurality of supply pipes 220 and supplies the same amount of the electrolytic solution to each of the supply pipes 220.

At this time, a guide line (not shown) is formed in each injection port 111 formed in the cell 110 so that the supply pipe 220 can be inserted. In the lower part of the side of the supply pipe 220 inserted into the injection port 111, The supply hole 221 is formed so as to be opened or closed from the guide line of the injection port 111 in accordance with the vertical movement of the electrolyte solution supply part 200.

That is, in the present invention, the electrolytic solution supplied through the inflow part 210 is supplied to the supply pipe 220 through the connection pipe 230. At this time, when the electrolytic solution supply part 200 is not moved downward, The supply hole 221 is blocked by the guide line of the injection port 111 so that the electrolyte of the supply pipe 220 is stored in the supply pipe 220 without being injected into the cell 110 and the electrolyte solution supply unit 200 is moved downward The supply pipe 220 is also moved downward and the supply hole 221 is opened so that the electrolyte stored in the supply pipe 220 drops and is injected into the cell 110.

2, the elastic member 120 is provided between the connection pipe 230 and the upper surface of the cell 110 of the battery 100 so that the electrolyte solution supply unit 200 can vertically move up and down do.

A plurality of cells 110 and a pack cover 130 covering the electrolyte supply part 200 are provided outside the battery 100 so that when the electrolyte supply part 200 is moved upward by the elastic body 120 It is desirable to prevent the phenomenon that the supply pipe 220 is detached from the injection port 111 of the cell 110. [

3, protrusions 222 are formed at both ends of the lower portion of the supply pipe 220 so that the supply pipe 220 is moved upward when the electrolyte solution supply unit 200 is moved upward by the elastic body 120, It is preferable to prevent the phenomenon that the cell 110 is separated from the injection port 111 of the cell 110.

4, the electrolyte supply part 200 may be connected to the cells 110 provided at both ends of the battery 100 and the screws 140 to form the electrolyte solution supply part 200, It is preferable to be able to control the vertical movement of the main body 200.

As described above, the present invention provides a battery 100 including a plurality of cells 110 having an injection port 111 formed on an upper surface thereof; And an electrolyte supply part 200 located above the battery 100 and movable up and down to inject electrolyte into each injection port 111 formed in the cell 110 so that the electrolyte can be supplied additionally It is possible to rapidly inject the same amount of the electrolyte solution into each cell 110 through the electrolyte supply part 200 composed of one inlet part 210 and a plurality of supply pipes 220 while improving the life of the battery 100 As a result, it is possible to freely set the position where the electrolyte flows from the outside as shown in FIG. 7, thereby improving design performance and merchantability.

(Second Embodiment)

5, a battery 100 according to an embodiment of the present invention includes a plurality of cells 110 having injection ports 111 formed therein, a transmission net 201, And an electrolyte solution supply unit 200 for injecting an electrolyte solution into the injection port 111 of the electrolyte solution supply unit 200.

The battery 100 includes a plurality of cells 110, and an inlet 111 is formed in each cell 110 so that an electrolyte can be injected into the cell.

The electrolyte supply part 200 is located above the battery 100 and a permeation net 201 is formed to inject an electrolyte into each injection port 111 formed in the cell 110.

The electrolyte solution supply unit 200 is connected to the inlet 210 through which the electrolyte solution is supplied from the outside and a plurality of the electrolyte solution supply unit 200 are inserted into the injection holes 111 formed in the cells 110, A supply pipe 220 for forming a permeable net 201 and allowing the electrolyte to permeate into the cell 110 with the lapse of time when the electrolyte is injected to supply the electrolyte solution and a connection pipe 220 connecting the inlet 210 and the plurality of supply pipes 220 And a connection pipe 230 for supplying the same amount of electrolytic solution to the respective supply pipes 220.

That is, according to the present invention, the electrolytic solution supplied through the inlet 210 is supplied to the supply pipe 220 through the connection pipe 230. At this time, the electrolytic solution supply unit 200 supplies the electrolytic solution to the supply pipe 220 201 and stored in the supply pipe 220. The electrolyte solution is injected into the cell 110 as it passes through the permeable net 201 as time elapses.

As described above, the present invention provides a battery 100 including a plurality of cells 110 having an injection port 111 formed on an upper surface thereof; And an electrolyte supply part 200 located above the battery 100 and formed with a permeation net 201 to inject an electrolyte into each injection port 111 formed in the cell 110 so that the electrolyte can be supplied additionally It is possible to rapidly inject the same amount of the electrolyte solution into each cell 110 through the electrolyte supply part 200 composed of one inlet part 210 and a plurality of supply pipes 220 while improving the life of the battery 100 As a result, it is possible to freely set the position where the electrolyte flows from the outside as shown in FIG. 7, thereby improving design performance and merchantability.

(Third Embodiment)

6, a battery 100 according to the present invention includes a battery 100 having a plurality of cells 110 having an injection port 111 formed therein, a funnel 202, And an electrolyte solution supply unit 200 for injecting an electrolyte solution into the injection port 111 of the electrolyte solution supply unit 200.

The battery 100 includes a plurality of cells 110, and an inlet 111 is formed in each cell 110 so that an electrolyte can be injected into the cell.

The electrolyte supply part 200 is located above the battery 100 and a funnel 202 is formed to inject electrolyte into each injection port 111 formed in the cell 110.

The electrolytic solution supply unit 200 includes an inlet pipe supplied with an electrolyte from the outside and a plurality of openings connected to the inlet 210 and inserted into an inlet 111 formed in each cell 110, A supply pipe 220 for supplying the electrolytic solution to the inside of the cell 110 with a lapse of time during the injection of the electrolytic solution to supply the electrolytic solution to the cell 110, a connection pipe 220 connecting the inlet 210 and the plurality of supply pipes 220, And a connection pipe 230 for supplying the same amount of the electrolytic solution.

That is, according to the present invention, the electrolytic solution supplied through the inlet 210 is supplied to the supply pipe 220 through the connection pipe 230. In this case, the electrolytic solution supply unit 200 includes a funnel 202 And is injected into the cell 110 as the electrolyte falls by the funnel 202 over time.

As described above, the present invention provides a battery 100 including a plurality of cells 110 having an injection port 111 formed on an upper surface thereof; And an electrolyte supply part 200 which is located above the battery 100 and in which a funnel 202 is formed to inject an electrolyte into each of the injection openings 111 formed in the cell 110, It is possible to rapidly inject the same amount of the electrolyte solution into each cell 110 through the electrolyte supply part 200 including one inlet part 210 and a plurality of supply pipes 220, It is possible to increase the working time and convenience, and as shown in FIG. 7, the position where the electrolyte flows from the outside can be set freely, thereby improving the design performance and the merchantability.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

100: Battery 110: Cell
111: Inlet port 120: Elastic body
130: Pack cover 200: Electrolyte supply part
201: permeable mesh 202: funnel
210: inlet portion 220: feed pipe
221: Supply hole 230: Connector

Claims (11)

A battery having a plurality of cells each having an injection port formed on an upper surface thereof;
And an electrolyte supply unit disposed above the battery and movable up and down to inject an electrolyte into the respective injection ports formed in the cell.
The method according to claim 1,
Wherein the electrolyte solution supply unit includes:
An inflow part for supplying the electrolytic solution from the outside;
A plurality of supply lines connected to the inlet and inserted into the inlet formed in each of the cells to supply an electrolyte;
And a connection pipe connecting the inlet portion and the plurality of supply pipes, and supplying the same amount of the electrolyte solution to the supply pipes.
The method of claim 2,
Wherein a guide line is formed in each of the injection ports so as to insert the supply pipe, and a supply hole is formed in the lower side of the supply pipe so as to be opened and closed from the guide line of the injection port in accordance with the vertical movement of the electrolyte supply part. Device.
The method of claim 3,
Wherein an elastic body is formed between the connection pipe and the upper surface of the cell so that the electrolyte solution supply unit can be vertically moved up and down.
The method of claim 4,
And a pack cover for covering the plurality of cells and the electrolyte solution supply unit is provided outside the battery so as to prevent the supply pipe from departing when the electrolyte solution supply unit is moved up and down by the elastic member.
The method of claim 4,
And a protrusion is formed on both ends of the lower portion of the supply pipe to prevent the supply pipe from being separated when the electrolyte supply portion is lifted by the elastic body.
The method of claim 3,
Wherein the electrolyte solution supply unit is screwed to cells provided at both ends of the battery to control the vertical movement of the electrolyte solution supply unit.
A battery having a plurality of cells each having an injection port formed on an upper surface thereof;
And an electrolyte supply unit disposed above the battery and having a permeation net to inject an electrolyte into the respective injection ports formed in the cell.
The method of claim 8,
Wherein the electrolyte solution supply unit includes:
An inflow part for supplying the electrolytic solution from the outside;
A plurality of supply pipes connected to the inlet, inserted into the injection port formed in each of the cells, and configured to form the permeation net to allow the electrolyte to permeate into the cell as time elapses during the injection of the electrolyte, thereby supplying the electrolyte;
And a connection pipe connecting the inlet portion and the plurality of supply pipes, and supplying the same amount of the electrolyte solution to the supply pipes.
A battery having a plurality of cells each having an injection port formed on an upper surface thereof;
And an electrolyte supply unit disposed above the battery and having a funnel for injecting an electrolyte into the respective injection ports formed in the cell.
The method of claim 10,
Wherein the electrolyte solution supply unit includes:
An inflow part for supplying the electrolytic solution from the outside;
A plurality of supply lines connected to the inlet, inserted into the inlet formed in each of the cells, the funnel being formed to allow the electrolyte to drop into the cell over time during the injection of the electrolyte, thereby supplying the electrolyte;
And a connection pipe connecting the inlet portion and the plurality of supply pipes, and supplying the same amount of the electrolyte solution to the supply pipes.

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