CN212380471U - Hard shell button cell - Google Patents

Abstract

The utility model relates to a hard shell button battery, which comprises an upper shell, a lower shell, an insulating part and a pole core; the upper shell and the lower shell are in insulation sealing connection with each other through an insulation piece so as to form a sealing cavity on the inner sides of the upper shell and the lower shell; the pole core is accommodated in the sealing cavity; the pole core is formed by laminating and winding a positive plate, a diaphragm and a negative plate; the first end of the positive foil is abutted with the inner wall of the lower shell, the second end of the negative foil is abutted with the inner wall of the upper shell, and the first end of the positive foil and/or the second end of the negative foil is/are provided with a ceramic layer. Compared with the prior art, the ceramic has high strength, can strengthen the strength of the anode foil and the cathode foil, and avoids the easy stress deformation of the end face of the pole core; the supporting effect of the pole core is improved.

Description

Hard shell button cell

Technical Field

The utility model belongs to the technical field of button cell, especially, relate to a crust button cell.

Background

Button cells, also known as button cells, are generally larger in diameter and thinner in thickness (relative to cylindrical cells such as AA 5 in the market). The button cell comprises a hard-shell button cell and a soft-package button cell.

Among them, the hard-shell button cell is an all-metal shell sealed cell, and its characteristics are small cell volume and strong sealing property, so that it can be extensively used in computer, hearing aid, electronic watch, radio and various electronic small products.

The existing hard shell button cell respectively leads out tabs from two pole pieces with opposite electrical properties, and then the two tabs are respectively welded to an upper shell and a lower shell, thereby realizing the electrical connection of a pole core and the upper shell and the lower shell; meanwhile, extra insulation protection is needed between the pole lug and the end face of the pole core. The hard shell button battery has a complex structure and high processing difficulty, the pole piece and the shell are connected by welding, the internal resistance of the battery is high, and the energy density is low.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: aiming at the problems of complex structure and large internal resistance of the existing hard-shell button cell, the hard-shell button cell is provided.

In order to solve the above technical problem, an embodiment of the present invention provides a hard-shell button battery, which includes an upper shell, a lower shell, an insulating member, and a pole piece; the upper shell and the lower shell are in insulation sealing connection with each other through the insulation piece so as to form a sealing cavity on the inner sides of the upper shell and the lower shell; the pole core is accommodated in the sealing cavity;

the pole core is formed by laminating and winding a positive plate, a diaphragm and a negative plate; the positive plate comprises a positive foil and a positive coating formed by coating a positive active substance on the surface of one side or two sides of the positive foil, and the negative plate comprises a negative foil and a negative coating formed by coating a negative active substance on the surface of one side or two sides of the negative foil;

the first end of the wound positive electrode foil piece in the width direction is used as a positive electrode lug at the first end of the electrode core, and the positive electrode lug is abutted against the inner wall of the lower shell; the second end of the wound negative electrode foil piece in the width direction is used as a negative electrode tab at the second end of the pole core, and the negative electrode tab is abutted against the inner wall of the upper shell;

the first end of the positive electrode foil is provided with a first area which is not coated with positive electrode active substances, and a ceramic layer is arranged on the first area; and/or

The second end of the negative foil has a second region not coated with a negative active material, and the second region is provided with a ceramic layer.

Optionally, when the ceramic layer is disposed on the first region and the second region is not disposed on the second region, the separator covers an end surface of the second end of the positive electrode plate, and an end surface of the first end of the positive electrode plate is not covered by the separator.

Optionally, an end of the first region remote from the cathode coating has a first blank region not covered by the ceramic layer.

Optionally, the second area is a second blank area.

Optionally, when the ceramic layer is disposed on the second region and the ceramic layer is not disposed in the first region, the separator covers the end face of the first end of the negative electrode plate, and the end face of the second end of the negative electrode plate is not covered by the separator.

Optionally, an end of the second region remote from the negative electrode coating has a third blank region not covered by the ceramic layer.

Optionally, the first area is a fourth blank area.

Optionally, a first conductive adhesive layer is pasted on the inner wall of the end face, facing the first end of the positive foil, of the lower shell, a second conductive adhesive layer is pasted on the inner wall of the end face, facing the second end of the positive foil, of the upper shell, the positive tab abuts against the first conductive adhesive layer, and the negative tab abuts against the second conductive adhesive layer.

Optionally, the upper shell is a cylindrical structure with a downward opening, and an opening edge of the upper shell extends outwards to form a first annular folded edge; the lower shell is of a cap-shaped structure, and the edge of the lower shell is bent towards the upper shell to form a second annular folding edge wrapping the first annular folding edge.

Optionally, the first annular flange extends radially outwardly of the pole piece.

Compared with the prior art, the hard-shell button battery provided by the embodiment of the utility model has the advantages that the first end surface of the positive foil is directly abutted with the inner wall of the lower shell so as to realize the electric connection of the pole core and the lower shell, and the second end surface of the negative foil is directly abutted with the inner wall of the upper shell so as to realize the electric connection of the pole core and the upper shell, so that the contact area of the electric connection is increased, the internal resistance of the battery is reduced, the current density is more uniform, and the charge-discharge multiplying power is improved; the electrode core and the upper shell or the lower shell are electrically connected without adding a tab, so that the welding of the tab and the upper shell and the welding of the tab and the lower shell are avoided, an insulating structure is also avoided from being arranged between the tab and the end surface of the electrode core, the structure of the hard-shell button battery is simplified, the production process of the hard-shell button battery is simplified, the processing is convenient, and the manufacturing cost is reduced; meanwhile, the ceramic layer is arranged at the first end of the anode foil and/or the second end of the cathode foil, so that the strength of the ceramic is high, the strength of the anode foil and the cathode foil can be enhanced, and the end face of the pole core is prevented from being easily deformed under stress; the supporting effect of the pole core is improved; and the insulating property of the ceramic is good, even if the first end surface of the positive foil and the lower shell are extruded or the second end surface of the negative foil and the upper shell are extruded to cause ceramic falling, the falling ceramic is contacted with the negative plate or the positive plate, so that the internal short circuit of the battery can not be caused, and the quality of the hard shell button battery is improved.

Drawings

Fig. 1 is a schematic structural view of a hard-shell button battery according to an embodiment of the present invention;

fig. 2 is a schematic structural view of a hard-shell button battery according to another embodiment of the present invention;

FIG. 3 is a schematic structural diagram of the first pole piece of FIG. 1;

FIG. 4 is an enlarged left side view of FIG. 3;

FIG. 5 is a schematic view of the structure of the second pole piece of FIG. 1;

fig. 6 is an enlarged left side view of fig. 5.

The reference numerals in the specification are as follows:

1. an upper shell; 11. a first annular flange;

2. a lower case; 21. a second annular folded edge;

3. an insulating member; 4. sealing the cavity;

5. a pole piece; 51. a diaphragm;

52. a positive plate; 521. a positive electrode foil; 5211. a first blank area; 522. a positive electrode coating; 523. a ceramic layer;

53. a negative plate; 531. a negative electrode foil; 5311. a second blank area; 532. a negative electrode coating;

6. a first conductive adhesive layer; 7. and the second conductive adhesive layer.

Detailed Description

In order to make the technical problem, technical solution and advantageous effects solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to illustrate the present invention in further detail. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

As shown in fig. 1, the hard-shell button battery provided by the embodiment of the present invention includes an upper shell 1, a lower shell 2, an insulating member 3, and a pole piece 5; the upper shell 1 and the lower shell 2 are in insulation sealing connection with each other through an insulating piece 3 to form a sealing cavity 4 on the inner sides of the upper shell and the lower shell; the pole core 5 is accommodated in the sealed cavity 4;

the pole core 5 is formed by laminating and winding a positive pole piece 52, a diaphragm 51 and a negative pole piece 53; the positive electrode sheet 52 includes a positive electrode foil 521 and a positive electrode coating 522 formed by coating a positive electrode active material on one or both surfaces of the positive electrode foil 521, the negative electrode sheet 53 includes a negative electrode foil 531 and a negative electrode coating 532 formed by coating a negative electrode active material on one or both surfaces of the negative electrode foil 531,

the first end of the wound positive foil 521 in the width direction is used as a positive tab at the first end of the pole core 5, and the positive tab abuts against the inner wall of the lower case 2; the second end of the wound negative electrode foil 531 in the width direction thereof serves as a negative electrode tab at the second end of the pole piece 5, and the negative electrode tab abuts against the inner wall of the upper case 1.

The end face of the first end of the positive foil 521 is directly abutted with the inner wall of the lower shell 2 so as to realize the electric connection of the pole core 5 and the lower shell 2, the end face of the second end of the negative foil 531 is directly abutted with the inner wall of the upper shell 1 so as to realize the electric connection of the pole core 5 and the upper shell 1, the first end of the positive foil 521 is directly used as a positive lug, and the second end of the negative foil 531 is directly used as a negative lug, so that the contact area of the electric connection is improved, the internal resistance of the battery is reduced, the current density is more uniform, and the charge-discharge multiplying power is; the electrode core 5 and the upper shell 1 or the lower shell 2 are electrically connected without adding an electrode lug additionally, so that the welding of the electrode lug and the upper shell 1 and the welding of the electrode lug and the lower shell 2 are avoided, an insulating structure is also avoided being arranged between the electrode lug and the end face of the electrode core 5, the structure of the hard-shell button battery is simplified, the production process of the hard-shell button battery is simplified, the processing is convenient, and the manufacturing cost is reduced.

The positive plate 52, the diaphragm 51 and the negative plate 53 are laminated and wound to form the pole core 5, then the pole core 5 is placed into the upper shell 1, electrolyte is filled into the upper shell 1 to enable the pole core 5 to be completely immersed in the electrolyte, then the lower shell 2 is covered and pressed tightly to enable two end faces of the pole core 5 to be respectively abutted against the upper shell 1 and the lower shell 2, and then the upper shell 1 and the lower shell 2 are connected in an insulation sealing mode through the insulation piece 3, so that the hard shell button battery is obtained. After the winding is completed, the first end of the positive electrode sheet 52 in the width direction thereof exceeds the first end of the negative electrode sheet 53 in the width direction thereof in the axial direction of the pole core 5, the end face of the first end of the positive electrode foil 521 is wound to become the first end face of the pole core 5, the second end of the negative electrode sheet 53 in the width direction thereof exceeds the second end of the positive electrode sheet 52 in the width direction thereof in the axial direction of the pole core 5, and the end face of the second end of the negative electrode foil 531 is wound to become the second end face of the pole core 5; the first end face of the pole piece 5 is connected with the lower shell 2 in an abutting mode to achieve electric connection, and the second end face of the pole piece 5 is connected with the upper shell 1 in an abutting mode to achieve electric connection.

When the positive plate 52 is prepared, a positive active material is coated on a large-area positive foil 521 to form a positive coating, and then laser striping is adopted to obtain a plurality of positive plates 52; the production efficiency is greatly improved, and meanwhile, the coating at the cut part can be cleaned by laser striping, so that the end surface of the anode foil 521 is exposed.

When the negative electrode sheet 53 is prepared, a negative electrode active material is coated on a large-area negative electrode foil 531 to form a negative electrode coating, and then laser striping is adopted to obtain a plurality of negative electrode sheets 53; the production efficiency is greatly improved, and meanwhile, the coating at the cut part can be cleaned by laser striping, so that the end face of the negative foil 531 is exposed.

In one embodiment, as shown in fig. 1, the first end of the positive electrode foil 521 has a first region not coated with the positive electrode active material, and the first region is provided with a ceramic layer 523; the strength of the ceramic is high, the strength of the positive foil 521 can be enhanced, and the end face of the pole core 5 is prevented from being easily deformed by stress; the supporting effect of the pole core 5 is improved, and the stability of extrusion electric connection in the hard shell button battery is improved; and the insulation property of the ceramic is good, even if the first end of the positive foil 521 is extruded with the lower shell 2 to cause ceramic to fall off, the fallen ceramic is contacted with the negative plate 53, the internal short circuit of the battery can not be caused, and the quality of the hard shell button battery is improved.

Specifically, as shown in fig. 1, the separator 51 covers the end surface of the second end of the positive electrode sheet 52, and the end surface of the first end of the positive electrode sheet 52 is not covered by the separator 51; the end face of the second end of the positive plate 52 and the end face of the second end of the negative plate 53 can be ensured to be isolated, and when the end face of the second end of the negative foil 531 extrudes the upper shell 1 to cause the falling of the negative active material, the falling negative active material is not in contact with the end face of the second end of the positive plate 52, so that the internal short circuit of the battery is avoided.

The separator 51 is folded in half along the center broken line, the positive electrode sheet 52 is inserted into the separator 51 after the folding in half, and the first end of the separator 51 after the folding in half exceeds the first end of the negative electrode sheet 53; the positive plate 52 and the negative plate 53 are ensured to be separated, the structure is simple, and the processing is convenient.

Specifically, as shown in fig. 3 and 4, an end of the first region remote from the positive electrode coating 522 has a first blank region 5211 not covered by the ceramic layer 523; the positive electrode foil 521 at the first end of the positive electrode tab 52 is ensured to be exposed, and the electrical connection of the positive electrode foil 521 and the lower case 2 is ensured.

Specifically, as shown in fig. 5 and 6, the second end of the negative electrode foil 531 has a second region not coated with the negative electrode active material, the second region being a second blank region 5311; the negative foil 531 at the second end of the negative plate 53 is ensured to be exposed, the electrical connection between the negative foil 531 and the upper case 1 is ensured, and the falling of the negative active material of the negative coating 532 caused by the extrusion of the second end face of the negative foil 531 and the upper case 1 can also be avoided.

In another embodiment, not shown in the drawings, the second end of the negative foil 531 has a second region not coated with the negative active material, the second region being provided with a ceramic layer; the strength of the ceramic is high, the strength of the negative foil 531 can be enhanced, and the end face of the pole core 5 is prevented from being easily deformed by stress; the supporting effect of the pole core 5 is improved, and the stability of extrusion electric connection in the hard shell button battery is improved; and the insulating property of the ceramic is good, even if the second end of the negative electrode foil 531 is extruded with the upper shell 1 to cause ceramic to fall off, the fallen ceramic is contacted with the positive electrode plate 52, the internal short circuit of the battery can not be caused, and the quality of the hard shell button battery is improved.

Specifically, the separator 51 covers the end face of the first end of the negative electrode sheet 53, and the end face of the second end of the negative electrode sheet 53 is not covered by the separator 51; the end face of the first end of the negative plate 53 and the end face of the first end of the positive plate 52 can be isolated, and when the end face of the first end of the positive foil 521 is extruded with the upper shell 1 to cause the falling of the positive active material, the falling positive active material is not in contact with the end face of the first end of the negative plate 53, so that the internal short circuit of the battery is avoided.

Specifically, one end of the second area, which is far away from the negative electrode coating, is provided with a third blank area which is not covered by the ceramic layer; the negative electrode foil 531 of the second end of the negative electrode tab 53 is ensured to be exposed, and the electrical connection of the negative electrode foil 531 to the upper case 1 is ensured.

Specifically, the first end of the positive electrode foil 521 has a first region not coated with the positive electrode active material, the first region being a fourth blank region; the positive electrode foil 521 at the first end of the positive electrode sheet 52 is ensured to be exposed, the electrical connection between the positive electrode foil 521 and the lower casing 2 is ensured, and the falling of the positive electrode active material of the positive electrode coating 522 caused by the extrusion of the first end surface of the positive electrode foil 521 and the lower casing 2 can also be avoided.

In another embodiment, not shown in the drawings, the first end of the positive electrode foil 521 has a first region not coated with the positive electrode active material, and the ceramic layer 523 is provided on the first region; the second end of the negative foil 531 has a second region not coated with a negative active material, and the second region is provided with a ceramic layer; the stress of the two end faces of the pole core 5 is enhanced, the supporting effect of the pole core 5 is greatly improved, and the influence on the stability of the extrusion electric connection inside the hard shell button battery caused by the easy stress deformation of the two end faces of the pole core 5 is avoided.

Specifically, the end of the first region remote from the positive electrode coating 522 has a first blank region 5211 not covered by the ceramic layer 523; the end of the second area far away from the negative electrode coating is provided with a third blank area which is not covered by the ceramic layer; the positive electrode foil 521 at the first end of the positive electrode sheet 52 and the negative electrode foil 531 at the second end of the negative electrode sheet 53 are ensured to be exposed, and the electrical connection between the positive electrode foil 521 and the lower case 2 and the electrical connection between the negative electrode foil 531 and the upper case 1 are ensured.

In one embodiment, as shown in fig. 2, a first conductive adhesive layer 6 is adhered to the inner wall of the end surface of the lower case 2 facing the first end of the positive foil 521, and the positive tab abuts against the first conductive adhesive layer 6; the terminal surface and the 6 butts of first end of anodal foil 521 promptly, thereby the terminal surface of each layer positive plate 52 is difficult to align when avoiding convoluteing and influences the area of contact that utmost point core 5 and inferior valve 2 electricity are connected, first conductive adhesive layer 6 can guarantee that the first terminal surface of every layer anodal foil 521 can both realize the electricity with inferior valve 2 and be connected, ensure the area of contact that utmost point core 5 and inferior valve 2 electricity are connected, guarantee crust button cell's quality, reduced the processing degree of difficulty.

In one embodiment, as shown in fig. 2, a second conductive adhesive layer 7 is attached to an inner wall of an end surface of the upper case 1 facing the second end of the positive foil 521, and the negative tab abuts against the second conductive adhesive layer 7; the terminal surface and the second conducting glue layer 7 butt of the second end of negative pole foil 531 promptly, thereby the terminal surface of each layer negative pole piece 53 is difficult to align when avoiding convoluteing and influences the area of contact that utmost point core 5 and epitheca 1 electricity are connected, and second conducting glue layer 7 can guarantee that the second terminal surface of every layer negative pole foil 531 can both be connected with epitheca 1 electricity, ensures the area of contact that utmost point core 5 and epitheca 1 electricity are connected, guarantees crust button cell's quality, has reduced the processing degree of difficulty.

In one embodiment, as shown in fig. 1 and 2, the upper shell 1 is a cylindrical structure with a downward opening, and an opening edge of the upper shell 1 extends outwards to form a first annular folding edge 11; thereby for face and face extrusion during epitheca 1 and inferior valve 2 extrusion installation, avoid the extrusion excessively to lead to epitheca 1 to pierce through insulating part 3 and directly lead to the short circuit with inferior valve 2 contact.

The lower shell 2 is in a cap-shaped structure, and the edge of the lower shell 2 is bent towards the upper shell 1 to form a second annular folding edge 21 wrapping the first annular folding edge 11; the sealing performance of the connection of the upper case 1 and the lower case 2 is improved.

Preferably, the first annular flap 11 extends radially outwards of the pole piece 5; simple structure and convenient processing.

In one embodiment, as shown in fig. 1 and 2, the insulator 3 wraps the open end of the upper shell 1; the end of the second annular flange 21 overlaps the insulator 3; the mutual insulation of the upper shell 1 and the lower shell 2 is ensured, and the short circuit is avoided.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A hard-shell button battery is characterized by comprising an upper shell, a lower shell, an insulating part and a pole core; the upper shell and the lower shell are in insulation sealing connection with each other through the insulation piece so as to form a sealing cavity on the inner sides of the upper shell and the lower shell; the pole core is accommodated in the sealing cavity;

the pole core is formed by laminating and winding a positive plate, a diaphragm and a negative plate; the positive plate comprises a positive foil and a positive coating formed by coating a positive active substance on the surface of one side or two sides of the positive foil, and the negative plate comprises a negative foil and a negative coating formed by coating a negative active substance on the surface of one side or two sides of the negative foil;

the first end of the wound positive electrode foil piece in the width direction is used as a positive electrode lug at the first end of the electrode core, and the positive electrode lug is abutted against the inner wall of the lower shell; the second end of the wound negative electrode foil piece in the width direction is used as a negative electrode tab at the second end of the pole core, and the negative electrode tab is abutted against the inner wall of the upper shell;

the first end of the positive electrode foil is provided with a first area which is not coated with positive electrode active substances, and a ceramic layer is arranged on the first area; and/or

The second end of the negative foil has a second region not coated with a negative active material, and the second region is provided with a ceramic layer.

2. The hard-shell button cell of claim 1, wherein when said ceramic layer is disposed on said first region and said second region is not disposed on said second region, said separator covers an end surface of said second end of said positive plate, said end surface of said first end of said positive plate not being covered by said separator.

3. The hard-shell button cell of claim 2, wherein an end of the first region distal from the positive coating has a first void region not covered by the ceramic layer.

4. The hard-shell button cell of claim 2, wherein the second region is a second void region.

5. The hard-shell button cell of claim 1, wherein when the ceramic layer is disposed on the second region and the ceramic layer is not disposed on the first region, the separator covers an end surface of the first end of the negative plate, and an end surface of the second end of the negative plate is not covered by the separator.

6. The hard-shell button cell of claim 5, wherein an end of the second region distal from the negative coating has a third void region not covered by the ceramic layer.

7. The hard-shell button cell of claim 5, wherein the first region is a fourth clear region.

8. The hard-shell button cell as recited in claim 1, wherein a first layer of conductive adhesive is affixed to an inner wall of the end surface of the lower shell facing the first end of the positive foil, a second layer of conductive adhesive is affixed to an inner wall of the end surface of the upper shell facing the second end of the positive foil, the positive tab abuts the first layer of conductive adhesive, and the negative tab abuts the second layer of conductive adhesive.

9. The hard-shell button cell of claim 1, wherein said upper shell is a downwardly open cylindrical structure, said upper shell having an open edge extending outwardly to form a first annular flap; the lower shell is of a cap-shaped structure, and the edge of the lower shell is bent towards the upper shell to form a second annular folding edge wrapping the first annular folding edge.

10. The hard-shell button cell of claim 9, wherein the first annular bead extends radially outward of the pole piece.

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