DE202022106464U1 - Terminal cover structure for an electric cell and electric cell - Google Patents

Abstract

A terminal covering structure for an electric cell, characterized in that it comprises a rivet component, a first insulating member, a covering, a second insulating member and a terminal; wherein the rivet component comprises a connecting plate and a plurality of rivets, and wherein the connecting plate has a first surface and a second surface opposite to each other, and wherein the plurality of rivets are fixedly connected to the second surface, and wherein each of the rivets in turn the first insulating member , The cover and the second insulating penetrates and is firmly connected to the pole.

Description

TECHNICAL AREA

The present utility model relates to the technical field of battery manufacturing, particularly to a terminal cover structure for an electric cell and an electric cell.

STATE OF THE ART

In modern society, the drive power source of more and more new energy electric tools and vehicles is developing toward high storage capacity and good safety. The lithium-ion batteries have become a widely used power battery due to their low self-discharge and high energy density. The lithium-ion batteries usually include multiple electrical cells.

The inventor has found that in the manufacture of electrical cells, several scattered rivets (e.g. 2-5) must be passed through the adapter piece and cover one at a time and then mated with the pole. The more rivets that mate with the pole, the more difficult it is to ensure a consistent assembly. If one or even more of the rivets does not fit well with the terminal, leakage of the terminal can easily occur in the subsequent liquid injection, resulting in the scrapping of the entire electric cell.

CONTENT OF PRESENT UTILITY MODEL

The purpose of the present utility model is to provide an electric cell and a pole cover structure therefor to ensure the unitary assembly of multiple rivets and the pole, at the same time the energy conversion efficiency of the electric cell can be improved and the safety risk can be reduced.

In a first aspect, the present utility model provides a terminal cover structure for an electric cell, comprising a rivet component, a first insulating member, a cover, a second insulating member, and a terminal;
wherein the rivet component comprises a connecting plate and a plurality of rivets, and wherein the connecting plate has a first surface and a second surface opposite to each other, and wherein the plurality of rivets are fixedly connected to the second surface, and wherein each of the rivets in turn the first insulating member , The cover and the second insulating penetrates and is firmly connected to the pole.

In an optional embodiment, the first surface is used to weld an eyelet.

In an optional embodiment, a first locating notch is provided on the first face and is used to weld the eyelet.

In an optional embodiment, a second positioning groove is provided on a surface of the first insulating member facing away from the cover, the shape of the connection plate being matched to the shape of the second positioning groove, and the connection plate fitting into the second positioning groove;
and or
a sheet connected at an angle is arranged on a surface of the first insulating member opposite to the cover, the lengthwise direction of the sheet being the same as the lengthwise direction of the first insulating member, and the sheet corresponding to a widthwise side of the connecting plate.

In an optional embodiment, the terminal cover structure for an electric cell further comprises a sealing member disposed between the connection plate and the cover, with a plurality of the rivets penetrating the sealing member.

In an optional embodiment, the first insulating member is provided with a penetrating through hole, the shape of the through hole being matched to the sealing member, and the sealing member fits into the through hole and is compressed by the cover and the connecting plate.

In an optional embodiment, the terminal covering structure for an electric cell further comprises an explosion-proof valve; wherein the cover is provided with a penetrating positioning hole, and wherein the first insulating member is provided with an air-permeable mesh portion corresponding to the positioning hole to collectively form an installation groove, and the explosion-proof valve is accommodated in the installation groove.

In an optional embodiment, the terminal cover structure for an electric cell further includes a protective patch disposed on a surface of the cover opposite the first insulating member to seal the explosion-proof valve.

In an optional embodiment, the cover is further provided with an injection hole, wherein the electric cell terminal cover structure further comprises a sealing nail used for sealing the injection hole.

In a second aspect, the present utility model provides an electric cell comprising a terminal covering structure for an electric cell as set forth in any of the preceding embodiments.

• durch die einteilige Verbindung zwischen der Verbindungsplatte und den mehreren Nieten ist die Struktur nicht anfällig für eine Verformung, so dass eine einheitliche Montage von den mehreren Nieten und dem Pol sichergestellt werden kann, nachdem die mehreren Nieten mit dem Pol fest verbunden waren. Darüber hinaus werden die Montageteile insgesamt verringert, so dass der Montageprozess verkürzt und die Produktionseffizienz verbessert wird.

The embodiment of the present utility model has the following advantages:

• the integral connection between the connecting plate and the multiple rivets makes the structure not prone to deformation, so that unitary assembly of the multiple rivets and the pole can be ensured after the multiple rivets are fixed to the pole. In addition, the assembly parts are reduced as a whole, so that the assembly process is shortened and production efficiency is improved.

character list

• 1 zeigt eine Explosionsansicht einer Polabdeckungsstruktur für eine elektrische Zelle in einem Ausführungsbeispiel des vorliegenden Gebrauchsmusters.
• 2 zeigt eine Schnittansicht einer Polabdeckungsstruktur für eine elektrische Zelle in einem Ausführungsbeispiel des vorliegenden Gebrauchsmusters.

In order to explain the specific embodiments of the present utility model or the prior art technical solution more clearly, the figures to be used in the explanation of the specific embodiments or the prior art are briefly introduced below. Obviously, the figures below only show some embodiments of the present utility model. Those of ordinary skill in the art can obtain other figures based on the figures without having any creative work.

• 1 Fig. 12 shows an exploded view of a terminal cover structure for an electric cell in an embodiment of the present utility model.
• 2 Fig. 12 is a sectional view of a terminal cover structure for an electric cell in an embodiment of the present utility model.

Reference List

1

rivet component

10

connection plate

11

First face

12

First positioning groove

13

rivet

2

First insulating element

21

Second positioning groove

22

Sheet

23

through hole

24

Air permeable mesh section

3

sealing element

31

First convex ring

4

cover

41

through hole

42

injection hole

5

Second insulating element

51

Second convex ring

6

pole

7

Explosion proof valve

8th

protective plaster

9

sealing nail

DETAILED DESCRIPTION

In connection with figures in the embodiments of the present utility model, the technical solution in the embodiments of the present utility model will be explained clearly and completely in the following, so that the object, the technical solutions and the advantages of the present utility model will become clearer. Obviously, the exemplary embodiments described do not represent all exemplary embodiments, but only a part of the exemplary embodiments of the present utility model. The components of the exemplary embodiments of the present utility model explained and illustrated in the figures can normally be arranged and designed in various configurations.

Due to this, the detailed explanation in the exemplary embodiments of the present utility model according to the figures does not serve to limit the scope of protection of the present utility model, but only represents the selected exemplary embodiments of the present utility model based on the embodiments in the present utility model without any creative work should be considered to be within the scope of the present utility model.

It should be noted: similar reference numbers and alphabets do not represent represent similar elements, if an element is defined in one figure, there is no need to further define and explain the article in additional figures.

It should be noted that in the explanation of the present utility model, the directional or positional relationships are denoted by terms such as "middle", "top", "bottom", "left", "right", "vertical", "horizontal", "inside", "outside" etc. are based on the directional or positional relationships shown in figures or represent the directional or positional relationships with which the product of the utility model are normally placed. They only serve to explain the present utility model and to facilitate the explanation. They do not indicate or imply that the devices or elements depicted have any particular orientation or should be constructed and operated in any particular direction. For this reason, they cannot be understood as a limitation for the present utility model. Furthermore, the terms "the first", "the second", "the third" are used only to explain the objective and cannot be taken to indicate or imply the relative meaning.

Furthermore, the presence of the technical terms "horizontal", "vertical", "hanging vertical" does not imply that the component must be absolutely horizontal or hanging vertical, but rather can be slightly tilted. For example, "horizontal" only means that its direction is more horizontal than "vertical", it does not mean that the structure has to be completely horizontal, but can be slightly tilted.

It should be noted that the terms "arranged", "installed", "coupled" and "connected" in the explanation of the present utility model should be understood in a broad sense in the absence of clear rules and regulations. For example, it can be both fixed connection and demountable connection, or integrated connection; it can be mechanical connection or electrical connection; it can be direct connection or indirect connection through a medium, it can also be a connection between the interiors of two elements. Those of ordinary skill in the art can understand the specific meanings of the above terms in the present utility model based on the specific situations.

Some embodiments of the present utility model are explained in more detail below in connection with figures. The following embodiments and the features in the embodiments can be combined with each other in the case of no conflicts.

An embodiment of the present utility model provides an electric cell terminal cover structure which is mainly used for the electric cell, therefore the embodiment of the present utility model also provides an electric cell having the terminal cover structure for an electric cell.

Please refer 1 , the terminal covering structure for an electric cell in the present embodiment comprises a rivet component 1, a first insulating member 2, a covering 4, a second insulating member 5 and a terminal 6 arranged in sequence;
wherein the rivet component 1 comprises a connecting plate 10 and a plurality of rivets 13, and wherein the connecting plate 10 has a first face 11 and a second face opposite to each other, and wherein the first face 11 is used for welding an eyelet, and wherein the plurality rivets 13 are fixed to the first face 11, and each of the rivets 13, after successively penetrating the first insulating element 2, the cover 4 and the second insulating element 5, is fixed to the pole 6.

Therefore, the structure is not susceptible to deformation caused by the integral connection between the connection plate 10 and the plurality of rivets 13, so that uniform assembly of the plurality of rivets 13 and the pole 6 can be ensured after the plurality of rivets 13 with the pole 6 were firmly connected.

Because the rivet and the adapter piece are separate entities, the current transmission occurs only via the contact connection through the annular surface between them, which has a high resistivity, resulting in the current transmission between the inside and outside of the electric cell a a large amount of heat is generated, reducing the energy conversion efficiency, moreover, it causes a safety hazard.

The first surface 11 of the connection plate 10 can be used for welding the eyelet without needing the adapter piece, therefore the problem of high resistivity in the prior art can be solved to increase the energy conversion efficiency and reduce the safety risk. In addition, the assembly parts are reduced as a whole, so that the assembly process is shortened and production efficiency is improved.

It should be noted that since the prior art adapter is L-shaped, the eyelet must be ultrasonically welded to the adapter. The clamping device of the existing ultrasonic welding machine is difficult to develop and can hardly position and fix the adapter piece, the welding is difficult, and the thickness of the adapter piece is usually about 0.5mm-1mm, so it can easily be damaged by forces in ultrasonic welding be deformed, which affects the subsequent assembly. In the present embodiment, since the eyelet can be welded directly to the first surface 11 of the connecting plate 10, the difficulty of welding is reduced.

In general, the first insulating member 2, the cover 4, the second insulating member 5 and the pole 6 are rectangular, and they respectively have the same length direction, the same width direction and the same thickness direction, accordingly, the connecting plate 10 is also rectangular, and the length direction of the connecting plate 10 is the same as the length direction of the cover 4, the width direction is the same as the width direction of the cover 4, and the thickness direction is also the same as the thickness direction of the cover 4.

The cover 4 is processed with the stamping process, has high overall strength and will not be deformed by external forces, which can ensure the stability and durability of the assembly and sealing of the pole 6, so its main function is to support the rest of the components and to be assembled with the housing. The pole 6 and the rivets 13 can be laser welded to create a solid connection, thus completing the current exchange between the inside and outside of the electric cell.

In the present embodiment, a first positioning groove 12 is provided on the first surface 11 of the connection plate 10, which is used for welding the eyelet, therefore, by the first positioning groove 12, the eyelet can be positioned and limited to ensure the accuracy of the position when welding the eyelet to ensure that the eyelet will not shift accidentally, a laser welding process can be used between the eyelet and the connecting plate 10.

The main function of the first insulating member 2 is to ensure insulation between the rivets 13 and the cover, a second positioning groove 21 is provided on a surface of the first insulating member 2 opposite to the cover 4, and the shape of the connecting plate 10 is adapted to the shape of the second positioning groove 21 is matched, and the connecting plate 10 fits into the second positioning groove 21, therefore, by means of the second positioning groove 21, the connecting plate 10 can be limited to achieve the limiting function for the rivets 13, which is conducive to assembling the entire terminal cover structure for is an electric cell.

After the terminal cover structure for an electric cell and the electric cell are assembled in the case, the originally stretched eyelet is folded due to the space limitation, and the folded eyelet is extremely easy to come into contact with the sidewall of the case, resulting in the short circuit, therefore is on A sheet 22 connected at an angle is arranged on a surface of the first insulating member 2 facing away from the cover 4 in the present embodiment, the length direction of the sheet 22 being the same as the length direction of the first insulating member 2, and the sheet 22 being on a width-direction side of the connector plate 10, and the sheet 22 is rectangular in shape to insulate the eyelet from the housing, ensuring the safety of the electric cell.

On a side of the sealing member close to the cover 4 are arranged first convex rings 31 provided in a same number as the rivets 13, the first convex rings 31 in one-to-one correspondence into plural on the cover 4 located through holes 41 fit through which the plurality of rivets 13 can pass, thus penetrating the rivets 13 in one-to-one correspondence the first convex rings 31. With the arrangement of the first convex rings 31 on the sealing member 3, the Pole 6 and the sealing element 3 itself are positioned indirectly. In addition, since the first convex rings 31 fit into the through holes 41, the rivets 13 can be separated from the cover 4 to achieve an insulating function.

The main function of the second insulating element 5 is to insulate the pole 6 and the cover 4 . On a surface of the second insulating member 5 facing the cover 4, circular second convex rings 51 provided in a same number as the rivets 13 are arranged, the second convex rings 51 in one-to-one correspondence into plural on the cover 4 through holes 41 through which the plurality of rivets 13 can pass, thus the rivets 13 penetrate the second convex rings in one-to-one correspondence 51. With the arrangement of the second convex rings 51 on the second insulating element 5, the pole 6 and the second insulating element 5 can themselves be positioned indirectly. Moreover, since the second convex rings 51 fit into the through holes 41, the rivets 13 can be separated from the cover 4 to achieve an insulating function.

Here, the first insulating member 2 and the second insulating member 5 are each made of plastic, which is relatively soft, so that the rivets 13 and the pole 6 gradually fit together, resulting in the cover 4, the pole 6 and the rivet component 1 being insulated from each other when the cover 4 and the terminal 6 and the connecting plate 10 approach each other, respectively, thereby improving the overall compactness of the structure and saving space.

In the present embodiment, the structure of the cover 4 of a pole 6 for an electric cell further includes a sealing member 3 formed into a substantially rectangular shape, the sealing member having the same length direction, width direction and thickness direction as the cover 4 . The sealing element 3 is arranged between the connecting plate 10 and the cover 4 , with several of the rivets penetrating the sealing element 3 . This is how the sealing effect is achieved.

Since the plurality of rivets 13 and the connection plate 10 adopt an integral structure, the force is applied uniformly to the entire sealing member 3 to increase the sealing qualification rate of the structure of the cover 4 of an electric cell terminal 6 .

Optionally, the first insulating member 2 is provided with a penetrating through hole 23, specifically, the through hole 23 penetrates the bottom wall of the second positioning groove 21 and is located at the center of the second positioning groove 21, therefore the shape of the through hole 23 is matched to the sealing member 3, the sealing member 3 fits into the through hole 23, and the cover 4 is compressed by the connecting plate 10, so that sealing is realized after the sealing member 3 is compressed and deformed.

In the present embodiment, the structure of the cover 4 of a pole 6 for an electric cell further includes an explosion-proof valve 7, the main function of the explosion-proof valve 7 is to protect the electric cell to prevent that due to a problem inside the electric Excessive pressure in the housing will lead to greater damage to the cell. The cover 4 is provided with a penetrating positioning hole, the first insulating member 2 is provided with an air-permeable mesh portion 24 corresponding to the positioning hole to collectively form an installation groove, and the explosion-proof valve 7 is received in the installation groove to facilitate the positioning and to realize installation of the explosion-proof valve 7 and ensure uniform assembly.

In the present embodiment, the terminal cover structure for an electric cell further includes a protective patch 8 disposed on a surface of the cover 4 opposite to the first insulating member 2 to seal the explosion-proof valve 7 . At the same time, with the arrangement of the protective plaster 8, consequential damage caused by debris flying around after the explosion-proof valve 7 bursts can be prevented.

In the present embodiment, the cover 4 is further provided with an injection hole 42 and a sealing nail 9, the injection hole 42 is mainly used to inject the electrolytes through the injection hole 42 into the inside after connecting the cover 4 and the electric cell case to inject the electric cell. The sealing nail 9 is used to plug the injection hole 42, so that after the electric cell injection process to seal the electric cell in the last step, after this step, the electric cell is in a fully sealed state.

In summary, in the electric cell and the terminal cover structure for an electric cell in the embodiment of the present utility model, the structure is not prone to deformation due to the integral connection between the connection plate 10 and the plurality of rivets 13, so that a unitary assembly of the plurality Rivets 13 and the pole 6 can be ensured after the plurality of rivets 13 were firmly connected to the pole 6. Since the first surface 11 of the connection plate 10 can be used to weld the eyelet without needing the adapter piece, the problem with the high resistivity in the prior art can be solved to increase the energy conversion efficiency and reduce the safety risk, moreover the difficulty of welding is reduced. In addition, the assembly parts are reduced as a whole, so that the assembly process is shortened and production efficiency is improved.

In the end, it should be noted that the above embodiments only serve to explain the technical solution of the present utility model instead of limiting it. Although the present utility model is explained in more detail in connection with the above exemplary embodiments, those skilled in the art should understand that they can change the technical solutions given in the above respective exemplary embodiments or replace the technical features partially or completely equivalently. With these changes or replacements, the corresponding technical solutions should still be considered to be within the scope of the technical solutions of the respective embodiments of the present utility model.

Claims (10)

A terminal cover structure for an electric cell, characterized in that it comprises a rivet component, a first insulating member, a cover, a second insulating member and a terminal; wherein the rivet component comprises a connecting plate and a plurality of rivets, and wherein the connecting plate has a first surface and a second surface opposite to each other, and wherein the plurality of rivets are fixedly connected to the second surface, and wherein each of the rivets in turn the first insulating member , The cover and the second insulating penetrates and is firmly connected to the pole. Pole cover structure for an electric cell claim 1 , characterized in that the first surface is used for welding an eyelet. Pole cover structure for an electric cell claim 2 , characterized in that a first positioning groove is provided on the first surface, which is used for welding the eyelet. Pole cover structure for an electric cell claim 1 , characterized in that a second positioning groove is provided on a surface of the first insulating member opposite to the cover, the shape of the connection plate being matched to the shape of the second positioning groove, and the connection plate fitting into the second positioning groove; and/or a sheet connected at an angle is arranged on a surface of the first insulating member opposite to the cover, the lengthwise direction of the sheet being the same as the lengthwise direction of the first insulating member, and the sheet corresponding to a widthwise side of the connecting plate. Pole cover structure for an electric cell claim 1 , characterized in that the terminal cover structure for an electric cell further comprises a sealing member disposed between the connecting plate and the cover, a plurality of the rivets penetrating the sealing member. Pole cover structure for an electric cell claim 5 , characterized in that the first insulating member is provided with a penetrating through hole, the shape of the through hole being matched with the sealing member, and the sealing member fits into the through hole and is pressed by the cover and the connecting plate. Pole cover structure for an electric cell claim 1 characterized in that the terminal cover structure for an electric cell further comprises an explosion-proof valve; wherein the cover is provided with a penetrating positioning hole, and wherein the first insulating member is provided with an air-permeable mesh portion corresponding to the positioning hole to collectively form an installation groove, and the explosion-proof valve is accommodated in the installation groove. Pole cover structure for an electric cell claim 7 , characterized in that the terminal cover structure for an electric cell further comprises a protective patch disposed on a surface of the cover opposite to the first insulating member to seal the explosion-proof valve. Pole cover structure for an electric cell claim 1 characterized in that the cover is further provided with an injection hole, wherein the terminal cover structure for an electric cell further comprises a sealing nail used for sealing the injection hole. An electric cell, characterized in that it comprises a terminal covering structure for an electric cell according to any one of Claims 1 until 9 includes.

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