KR102165598B1 - Battery - Google Patents

Abstract

Embodiments of the present invention are to provide a battery capable of supplying an electrolyte so that an appropriate amount of the electrolyte is automatically filled according to the amount of the electrolyte inside the battery. The present invention may provide a battery comprising: a battery case provided with a plurality of cell spaces in which battery cells are disposed; a cover which shields an upper open surface of the battery case, and has an accommodation space in which the electrolyte can be accommodated, wherein an electrolyte supply part is formed at each position corresponding to the plurality of cell spaces; and an electrolyte supply cap installed in the electrolyte supply part to supply the electrolyte to the cell space according to an amount of the electrolyte accommodated in the cell space to maintain a state in which the electrolyte is accommodated in the plurality of cell spaces.

Description

Battery {BATTERY}

The present invention relates to a battery comprising a supply cap capable of automatically replenishing an electrolyte.

In general, batteries are installed in automobiles and used as power sources such as ignition and lighting when starting an engine or when power generation is insufficient.

Lead acid batteries (batteries), which are currently the most used for automobiles, are composed of positive and negative electrodes made of different metals, and an electrolyte, and by connecting both electrodes with a conductor, the active substance of each electrode and the chemical energy of the electrolyte are stored. It is supposed to be able to be drawn out with electrical energy. In addition, when electric energy is applied in reverse, it is returned to the original working material with chemical energy.

The electrolyte used in such a battery is a colorless, odorless, dilute sulfuric acid diluted with distilled water in sulfuric acid, which is in contact with the electrode plate and serves to conduct current inside the cell and generate or store the current.

If the change in the specific gravity of the electrolyte and the drop in the liquid level are not noticed by the inspector and elapsed for a long time, due to the depletion of the electrolyte, the electrical resistance increases and, in particular, has a fatal effect on the power supply of the device during high current discharge. In addition, the short circuit of the electrode plate leads to a dangerous situation in which the battery may explode, as well as causing fatal damage to the control equipment.

In this way, in order to prolong the life of the battery or prevent failure, the electrolyte must be maintained to have an appropriate specific gravity. Conventionally, the maximum rated level (MAX) and the minimum rated level (MIN) of the electrolyte that should be held outside the battery are marked with a scale, and the scale and the electrolyte are visually checked to determine how much electrolyte is filled. .

However, such a conventional method is indifferent to a decrease in the battery fluid while driving a vehicle, which causes a failure, and when attempting to check the charging state of the battery fluid, there is an inconvenience in that the bonnet must be opened and visually checked each time.

Republic of Korea Public Utility Model Publication No. 20-1998-041499 (1998.09.25)

Embodiments of the present invention are to provide a battery capable of supplying an electrolyte so that an appropriate amount of electrolyte is automatically filled according to the amount of the electrolyte inside the battery.

In addition, it is to provide a battery provided with a supply cap capable of automatically supplying or blocking the electrolyte according to the amount of the electrolyte inside the battery.

According to an embodiment of the present invention, there is provided a battery case provided with a plurality of cell spaces in which battery cells are disposed; A cover which shields an upper open surface of the battery case, and has an accommodation space in which an electrolyte can be accommodated, and an electrolyte supply part is formed at each position corresponding to the plurality of cell spaces; A battery including an electrolyte supply cap that is installed in the electrolyte supply unit and supplies an electrolyte solution to the cell space according to the amount of the electrolyte solution accommodated in the cell space so that a state in which the electrolyte solution is accommodated in the plurality of cell spaces is maintained. to provide.

In addition, the electrolyte supply cap is installed so as to be fixed to the electrolyte supply unit, the electrolyte in the receiving space is introduced into the interior, and the supplied electrolyte is supplied to the cell space; And a control unit connected to the electrolyte supply unit so as to be movable up and down according to the amount of the electrolyte stored in the cell space, and shielding or opening the supply of the electrolyte solution from the supply unit to the cell space. Can provide.

In addition, the supply unit, the body portion; An injection hole formed inside the body part, formed so as to extend from the accommodation space to the cell space, into which an electrolyte solution in the accommodation space can be injected; An electrolyte receiving portion formed under the body portion and communicating with a lower end of the injection hole to accommodate an electrolyte therein; And a discharge part communicating with the electrolyte receiving part and the cell space at the center of the body part located in the cell space. Including, it is possible to provide a battery, characterized in that the electrolyte in the receiving space is moved to the electrolyte receiving part through the injection hole, and the electrolyte in the electrolyte receiving part can be supplied to the cell space through the discharge part. .

In addition, the control unit may include a shielding film positioned in the electrolyte receiving unit to shield the discharge unit; A battery comprising: a moving part connected to the shielding film, positioned below the outer side of the electrolyte receiving part, and rising or falling according to the amount of the electrolyte in the cell space.

In addition, in a state in which an amount of electrolyte is accommodated in the cell space, the lower surface of the moving part is in contact with the surface of the electrolyte, and the moving part is raised by the surface height of the electrolyte, and the shielding film is positioned to shield the discharge part. In a state in which the amount of the electrolyte in the cell space is less than the set amount, the moving part descends as the surface height of the electrolyte decreases, and the shielding film descends according to the descending of the moving part, and the discharge part is opened. The battery can be provided.

According to an embodiment of the present invention, the electrolyte may be supplied so that an appropriate amount of the electrolyte is automatically filled according to the amount of the electrolyte inside the battery.

In addition, it is possible to automatically supply or cut off the electrolyte depending on the amount of the electrolyte inside the battery.

1 is a view showing a battery according to an embodiment of the present invention.
2 is a front cross-sectional view of a battery according to an embodiment of the present invention.
3 is a side cross-sectional view of a battery according to an embodiment of the present invention.
4 is a view showing a supply cap according to an embodiment of the present invention.
5 is a cross-sectional view of the supply cap according to FIG. 4.
6 is a view showing that the supply cap according to FIG. 5 is operated.

Hereinafter, a specific embodiment of the present invention will be described with reference to the drawings. However, this is only an example and the present invention is not limited thereto.

In describing the present invention, when it is determined that a detailed description of known technologies related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention and may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

The technical idea of the present invention is determined by the claims, and the following embodiments are only one means for efficiently describing the technical idea of the present invention to those of ordinary skill in the art.

1 is a view showing a battery 1 according to an embodiment of the present invention, FIG. 2 is a front cross-sectional view of a battery 1 according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention It is a side sectional view of the battery 1 according to.

1 to 3, a battery 1 according to an embodiment of the present invention may include a battery case 10, a cover 20, and a supply cap 30.

The battery case 10 may be provided with a plurality of cell spaces 100 in which battery cells are disposed. A battery cell (not shown) is disposed in each cell space 100, and an electrolyte L is accommodated in each cell space 100 by a set amount. At this time, it is preferable that the amount of the electrolyte solution L accommodated in each cell space 100 is maintained in a set amount. For example, as shown in FIG. 2, the set amount may be that the electrolyte is filled up to a height corresponding to the height h in the cell space.

In the present invention, so that the amount of electrolyte (L) accommodated in each cell space 100 through the supply cap 30 is maintained by a set amount, the amount of electrolyte solution (L) accommodated in each cell space 100 is Accordingly, the electrolyte solution L may be supplemented or cut off.

The cover 20 may be fastened to the battery case 10 so as to shield the upper open surface of the battery case 10. The cover 20 may be formed in a shape including an accommodation space 21 in which the electrolyte solution L can be accommodated. For example, the cover 20 may be formed to include at least a bottom surface, an upper surface, and four side surfaces. Accordingly, the receiving space 21 may be formed inside the plurality of surfaces.

An injection port 22 for injecting the electrolyte solution L into the receiving space 21 may be formed on the upper surface of the cover 20. The electrolyte solution L may be injected into the receiving space 21 of the cover 20 through the injection port 22. In this case, the level detection unit 23 may be installed in the liquid injection port 22. The level detection unit 23 may detect the remaining amount of the electrolyte solution L in the receiving space 21. As an example, the level detector 23 may be formed as a level indicator.

In addition, an electrolyte supply unit 24 may be formed on the lower surface of the cover 20 at each position corresponding to the plurality of cell spaces 100. The electrolyte supply unit 24 may be in the form of a hole formed at a position corresponding to the plurality of cell spaces 100 on the lower surface of the cover 20. The supply cap 30 may be positioned on the electrolyte supply unit 24.

The supply cap 30 is installed for each electrolyte supply unit 24 to supply the electrolyte solution L to the cell space 100 to maintain a state in which the electrolyte solution L is accommodated in a set amount in the plurality of cell spaces 100 Or cut off the supply of electrolyte (L). That is, the supply cap 30 may supply or block the electrolyte solution L to the cell space 100 according to the amount of the electrolyte solution L accommodated in the cell space 100.

4 is a view showing a supply cap 30 according to an embodiment of the present invention, Figure 5 is a cross-sectional view of the supply cap 30 according to FIG. 6 is a view showing that the supply cap 30 according to FIG. 5 is operated.

4 to 6, the supply cap 30 may include a supply unit 31 and an adjustment unit 32.

The supply unit 31 is installed to be fixed to the electrolyte supply unit 24, so that the electrolyte solution (L) of the receiving space 21 is introduced into the supply unit 31, and the injected electrolyte solution (L) is supplied to the cell space 100. I can.

The control unit 32 is connected to the supply unit 31 so as to be movable up and down according to the amount of the electrolyte solution L accommodated in the cell space 100, so that the electrolyte solution L is transferred from the supply unit 31 to the cell space 100. What is supplied can be shielded or opened.

Specifically, the supply part 31 may include a body part 311, an input hole 312, an electrolyte receiving part 313, an outlet part 314, an inlet part 315, and a guide part 316.

The body part 311 is a component constituting the body of the supply part 31 and may be divided into an upper part 3111, a center part 3112, and a lower part 3113. In this case, the upper portion 3111, the central portion 3112, and the lower portion 3113 of the body part 311 may be formed integrally, or may be formed by connecting each of them.

The body part 311 may be installed to be fixed to the electrolyte supply part 24. For example, the upper part 3111 of the body part 311 may be fixed to the electrolyte supply part 24. In addition, the central portion 3112 and the lower portion 3113 are located in the cell space 100.

The input hole 312 is formed inside the body part 311, and is formed from the upper part 3111 of the body part 311 to the center part 3112 so as to extend from the receiving space 21 to the cell space 100, The electrolyte solution L in the accommodation space 21 may be introduced into the body part 311.

The electrolyte receiving part 313 is formed to communicate with the lower end of the injection hole 312 in the lower part 3113 of the body part 311, and may be formed to accommodate the electrolyte solution L therein. That is, the electrolyte receiving portion 313 may be formed in the lower portion 3113 of the body portion 311 and may be a space in which the electrolyte solution L can be accommodated.

The discharge part 314 may be formed in the central part 3112 of the body part 311 located in the cell space 100 and may be formed to communicate with the electrolyte receiving part 313 and the cell space 100. Specifically, the discharge part 314 is formed in the shape of a hole penetrating the central part 3112 of the body part 311 to communicate with the cell space 100, and the electrolyte receiving part 313 and the inlet part 315 Can be communicated.

The inlet part 315 is in communication with the discharge part 314 and the electrolyte receiving part 313 at the lower side of the discharge part 314 and at the upper side of the electrolyte receiving part 313 at the center 3112 of the body part 311. Can be formed.

Therefore, the electrolyte solution L accommodated in the receiving space 21 of the cover 20 is introduced into the body part 311 through the injection hole 312 and flows into the electrolyte receiving part 313, and the electrolyte receiving part 313 ) Accommodated in the electrolyte (L) is discharged to the discharge unit 314 through the inlet 315. The electrolyte solution L discharged to the discharge unit 314 may be supplied to the cell space 100 in communication with the discharge unit 314.

The guide portion 316 is formed in the electrolyte receiving portion 313, extends downward from the lower surface of the central portion 3112 of the body portion 311, and may be disposed along the outer circumference of the outer peripheral surface of the inlet portion 315.

The guide part 316 may guide a position in which the shielding film 321 which will be described later that shields the inflow part 315 rises or falls.

The adjusting part 32 may include a shielding film 321, a moving part 322, a connection bar 323, a plate 324, and a support bar 325.

The shielding film 321 may be positioned in the electrolyte receiving part 313 to shield the discharge part 314. Specifically, the shielding film 321 may be formed in a form capable of shielding the inlet part 315 in order to block the supply of the electrolyte solution L to the discharge part 314. For example, the shielding film 321 may be formed in a plate shape having a diameter greater than or equal to the inlet portion 315 to shield the inlet portion 315.

The moving part 322 may be connected to the shielding film 321 and may be positioned below the outside of the electrolyte receiving part 313. Specifically, the moving part 322 may rise or fall according to the amount of the electrolyte solution L in the cell space 100. As the moving part 322 rises or falls, the shielding film 321 connected to the moving part 322 may rise or fall.

The moving part 322 may be in the form of an air bag filled with air. When the electrolyte solution L is filled in the cell space 100 by a set amount, the lower surface of the moving part 322 may be in contact with the surface of the electrolyte solution L.

A connection bar 323, a plate 324, and a support bar 325 may be formed between the shielding film 321 and the moving part 322.

The connection bar 323 is formed extending downward from the lower surface of the shielding film 321, and may penetrate the lower surface of the body part 311. When the connection bar 323 passes through the body part 311, the diameters of the through hole and the connection bar 323 correspond to each other, but may be formed to be vertically movable from the through hole to the connection bar 323. Accordingly, the connection bar 323 may move up and down in the through hole, but the electrolyte solution L in the electrolyte receiving portion 313 may not be discharged through the through hole.

In addition, the diameter of the through hole may be formed smaller than the diameter of the shielding film 321. Accordingly, when the moving part 322 descends and the shielding film 321 also descends, the shielding film 321 may be seated on the lower surface of the body part 311. Accordingly, the control unit 32 and the supply unit 31 are not separated and can be maintained in a connected state.

The plate 324 may be connected to the lower end of the connection bar 323 to shield the through hole. Therefore, the diameter of the plate 324 may be formed larger than the diameter of the through hole.

When the shielding film 321 shields the inflow part 315, the plate 324 may be positioned so that the through hole is shielded. That is, the height of the connection bar 323 may correspond to the distance between the shielding film 321 and the plate 324 in a state in which the shielding film 321 shields the inlet part 315 and the plate 324 shields the through hole. I can.

The support bar 325 may support the moving part 322 by connecting the plate 324 and the moving part 322.

Hereinafter, with reference to FIGS. 2, 5 and 6, the operation of the supply cap 30 will be described.

The state of the supply cap 30 of FIG. 5 is a state disposed in the cell space 100 filled with the electrolyte L so as to correspond to a set amount among the plurality of cell spaces 100 in FIG. 2.

Specifically, in a state in which the electrolyte solution L is accommodated in the amount set in the cell space 100, the lower surface of the moving part 322 is in contact with the surface of the electrolyte solution L, and the moving part is (322) is in an elevated state. When the moving part 322 is in an elevated state, the shielding film 321 is in a state of shielding the inflow part 315. Accordingly, the shielding film 321 shields the inlet portion 315 to block the electrolyte solution L supplied to the cell space 100 through the outlet portion 314.

The state of the supply cap 30 of FIG. 6 is a state in which the cell space 100 is filled with an amount of electrolyte L less than the set amount among the plurality of cell spaces 100 in FIG. 2.

Specifically, in a state in which the amount of the electrolyte solution L in the cell space 100 is less than the set amount, the moving part 322 descends as the surface height of the electrolyte solution L decreases. As the moving part 322 descends, the shielding film 321 may descend to open the inlet part 315.

When the inlet 315 is opened in this way, the electrolyte L injected into the electrolyte receiving part 313 through the inlet hole 312 is supplied to the discharge part 314 through the inlet 315, and the discharge part ( It may be supplied to the cell space 100 through 314.

In this way, the battery 1 including the supply cap 30 according to the present invention automatically covers 20 when the amount of electrolyte L in the cell space 100 is less than the set amount without separate operation. The electrolyte solution (L) accommodated in the receiving space 21 of) is supplied to the cell space 100, so that an insufficient amount of the electrolyte solution (L) can be supplemented. In addition, when the electrolyte solution L is filled in the amount set in the cell space 100, the supply of the electrolyte solution L may be blocked so that the electrolyte solution L is no longer supplied.

Although the exemplary embodiments of the present invention have been described in detail above, those of ordinary skill in the art to which the present invention pertains will understand that various modifications may be made to the above-described embodiments without departing from the scope of the present invention. . Therefore, the scope of the present invention is limited to the described embodiments and should not be determined, and should be determined by the claims and equivalents as well as the claims to be described later.

1: battery 10: battery case
100: cell space 20: cover
21: accommodation space 22: inlet
23: level detection unit 24: electrolyte supply unit
30: supply cap 31: supply unit
311: body part 3111: upper
3112: central 3113: lower
312: input hole 313: electrolyte receiving part
314: discharge unit 315: inlet
316: guide unit 32: adjustment unit
321: shielding film 322: moving part
323: connecting bar 324: plate
325: support bar L: electrolyte

Claims (5)

A battery case in which a plurality of cell spaces in which the battery cells are disposed is provided;
A cover which shields an upper open surface of the battery case, and has an accommodation space in which an electrolyte can be accommodated, and an electrolyte supply part is formed at each position corresponding to the plurality of cell spaces;
And an electrolyte supply cap installed in the electrolyte supply unit to supply an electrolyte solution to the cell space according to an amount of the electrolyte solution accommodated in the cell space so that a state in which the electrolyte solution is accommodated in the plurality of cell spaces is maintained.
The method according to claim 1,
The electrolyte supply cap,
A supply unit installed to be fixed to the electrolytic solution supply unit and capable of supplying the injected electrolytic solution to the cell space by introducing the electrolytic solution of the receiving space into the interior; And
A control unit connected to the supply unit so as to move up and down according to the amount of the electrolytic solution accommodated in the cell space, and shielding or opening the supply of the electrolytic solution from the supply unit to the cell space;
Battery comprising a.
The method according to claim 2,
The supply unit,
Body part;
An injection hole formed inside the body part, formed so as to extend from the accommodation space to the cell space, into which an electrolyte solution in the accommodation space can be injected;
An electrolyte receiving portion formed under the body portion and communicating with a lower end of the injection hole to accommodate an electrolyte therein; And
A discharge part formed in the center of the body part located in the cell space and communicating with the electrolyte solution receiving part and the cell space;
Including,
The battery, characterized in that the electrolyte in the accommodation space is moved to the electrolyte solution receiving part through the inlet hole, and the electrolyte solution of the electrolyte solution receiving part is supplied to the cell space through the discharge part.
The method of claim 3,
The adjustment unit,
A shielding film positioned in the electrolyte receiving part to shield the discharge part;
And a moving part connected to the shielding film, which is located below the outside of the electrolyte receiving part, and configured to rise or fall according to the amount of the electrolyte in the cell space.
The method of claim 4,
In a state in which an amount of electrolyte is accommodated in the cell space,
The lower surface of the moving part is in contact with the surface of the electrolyte, the moving part is raised by the height of the surface of the electrolyte, and the shielding film is positioned to shield the discharge part,
In a state in which the amount of electrolyte in the cell space is less than the set amount,
As the surface height of the electrolyte solution decreases, the moving part descends,
The battery, characterized in that the shielding film is lowered according to the lowering of the moving portion, and the discharge portion is opened.

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