SUMMERY OF THE UTILITY MODEL
In order to improve, even solve the aforesaid problem that produces metal debris in the top cap subassembly welding process, this application has proposed a connection piece, top cap subassembly and battery.
The application is realized as follows:
in a first aspect, examples of the present application provide a tab for connecting a battery core to a terminal post.
The connection piece includes: a sheet-like body. The sheet-like body has a first surface and a second surface that are arranged to face each other in a thickness direction. The first region of the first surface therein is configured to be welded with the post. The second surface has a second region corresponding to the first region in the thickness direction, and the second region has a groove.
The connection piece in this application example has the recess, consequently, carries out welded connection back with its utmost point post, can carry out operations such as point in above-mentioned recess to protect the welding point position, avoid during the metal debris that the welding produced falls into electric core, avoid electric core short circuit.
With reference to the first aspect, in a first embodiment of the present application, the bottom wall of the groove has a through-hole.
The through holes are arranged in the grooves, so that the glue is favorably contacted with the pole posts, and the glue space can be increased.
In combination with the first possibility of the first aspect, in a second embodiment of the present application, the through-hole is a circular hole.
Compared with polygonal holes, the circular holes are not easy to cause excessive negative influence on the body of the connecting piece. For example, the body of the tab is less likely to collapse.
In a third embodiment of the present application, in combination with the first aspect and the first to second possibilities, the first region has a depressed groove.
The first surface of body has the groove that sinks, therefore, when connection piece and utmost point post welding, utmost point post can sink to the inside of the certain thickness of connection piece.
In combination with the third aspect of the first aspect, in a fourth embodiment of the present application, the undercut is a cylindrical structure.
With reference to the first aspect, in a fifth embodiment of the present application, a bottom wall of the groove has a through hole, and the first region has a depressed groove, the depressed groove communicating with the groove.
When the through hole exists, the following effects are obtained: because the sunken grooves and the grooves on the two surfaces of the body of the connecting piece in the thickness direction are communicated, the dispensed glue can be directly contacted with the pole column. In other words, through such structural design, glue can contact with connection piece and utmost point post respectively, makes the area of contact of glue bigger, reduces its risk that drops.
With reference to the first aspect, in a sixth possible embodiment of the present application, a profile of the first region coincides with a profile of the second region in a thickness direction.
The body of connection piece, first region and second region structure according to above-mentioned mode, consequently, welding position between them also can correspond to be favorable to improving welding complex structural strength, also be difficult for damaging the body.
In a seventh possible embodiment of the present application in combination with the first aspect, the recess has a filler therein.
The filler body may serve to reduce or avoid adverse effects of the welding operation on the connecting tabs and/or the posts.
With reference to the eighth possibility of the first aspect, in a ninth implementation manner of the present application, the first surface of the body is connected with a pole in the first area by a welding manner, the pole has a concave hole, and the filling body extends from the concave groove into the concave hole.
Based on the connecting sheet, different products can be manufactured.
In a second aspect of the present application, a header assembly is provided that includes the above-described connecting tab.
In a second aspect of the present application, a battery is presented that includes a housing, a cell, and a cap assembly.
In the implementation process above, the connection piece that this application embodiment provided sets up the recess to through carrying out the point in this recess, thereby play and prevent that the metal debris that produces among the welding process from falling into electric core, and consequently also play and avoid electric core short circuit.
Detailed Description
The connecting piece (also called battery connecting piece) is arranged in the battery box and is used for contacting and conducting electricity with the battery (mainly referring to a battery core).
The terminal post is an indispensable component for electrically connecting the inside and the outside of the battery case.
The connecting sheet and the pole are generally connected by welding. For example, one end face of the pole is welded to one end face of the connecting piece, so that the pole and the connecting piece are fixedly connected and form an important component in the top cover assembly.
However, the process of battery involving the above process produces batteries with more or less risk of short circuits. For this reason, the prior art does not provide a particularly good solution or the cause of the above-mentioned problems is not known. It is generally considered that the defects of the battery cell or the assembly causes such as the overlapping of the internal electrical structure.
The inventors have unexpectedly found that the main causes of the above problems are: the welding operation of the tab and post can produce metal debris. After the components of the top cover assembly such as the connecting sheet and the pole are installed through the top cover, metal debris can have a great risk of falling into the interior of the battery cell. This can lead to a risk of short circuits when metal debris falls into the interior of the cell.
Therefore, with respect to the above-described problems, the inventors thought that it is possible to avoid the generation of metal debris by changing the manner of connection of the connecting piece and the pole; alternatively, the welding process is optimized to produce as little, if any, metal debris as possible. However, the above solutions have obvious disadvantages, such as difficult operation or difficult implementation, or too high implementation cost.
Through further research, the inventor proposes a method which is different from the scheme, has obvious effect and is easy to implement and can deal with the problem. In this application, the inventor selects to carry out "protection" to connection piece and utmost point post welding position to can be disregarded the production of metal clastic, even the welding has produced the piece, the scheme of this application example can avoid metal clastic to fall into electric core, thereby prevents electric core short circuit.
In an example, the structure of the connecting sheet is modified (and the pole column can be subjected to appropriate structural adjustment substantially at the same time), so that after the welding operation, the risk that metal scraps fall into the battery cell through the dispensing operation is reduced.
As an alternative adjustment, the choice of the specific composition of the glue etc. may be chosen so that a glue with a higher degree of matching is used. For example, the glue used in the dispensing operation has a certain adhesive strength so that it can have a higher adhesive strength with the connecting sheet and the terminal to prevent the glue from falling off, and the glue needs to be resistant to electrolyte/insulation and the like.
Based on the above description, the connection piece 400 of the example after structural modification is explained below. The tab 400 is used in a battery roll core to electrically connect to a terminal post 12 that is fitted to the top cap 1000, and wherein the terminal post 12 is inserted through the top cap 1000, see fig. 1-a and 1-B. That is, the top cover 1000 has a hole penetrating in its thickness direction, and both ends of the pole post 12 are passed through the hole. Which can serve as an exit for the electrode, from which the pole extends a certain distance when it is mated with the tab 400 and is connected in place to the tab 400 (mentioned again later in the first region).
As the name implies, the connecting sheet 400 is a sheet having a sheet-like structure. The specific structure is indefinite, and the adaptability is adjusted according to the specific design structure of different batteries. For example, the connecting piece 400 may be a narrow strip/long strip structure, or may be made square or circular, etc. Illustratively, in the present application, the connecting piece 400 is a substantially square piece, the structure of which can be seen in fig. 2, 3 and 4. The connecting piece 400 is in a delta configuration having a front end 910 and two rear ends 410. The two rear end portions 410 have a gap therebetween, and thus the two rear end portions 410 are spaced apart. And the structural alteration of the web 400 is at its forward end 910. This void may be used to make room for other components in the cell, but this is not intended to limit the tabs from having to have this void. In other words, the two rear end portions 410 may be integrally connected.
The connecting piece 400 has a sheet-like body and has two surfaces defining its thickness direction, i.e., it has a first surface 930 and a second surface 920 which are distributed oppositely. Wherein fig. 3 shows the second surface 920 of the connecting piece 400 and fig. 4 shows the first surface 930 of the connecting piece 400.
Fig. 5, 6 and 7 are schematic structural diagrams illustrating an assembly manner of the pole 12 and the connecting piece 400. As shown in fig. 5 and 6 and 7, the pole 12 is mated with the connecting tab 400 at the front end 910 thereof. In the fabricated and assembled battery structure, the terminal post 12 and the connecting plate 400 are substantially structurally and connected at the front end portion 910, and the connection (the conductive connection) is achieved by means of welding. And the sectional structure in the connected state of the connecting piece 400 and the pole is shown in fig. 8.
A first region of the first surface 930 of the connecting plate 400, the front end of the connecting plate 400, is provided for welding with the pole, see fig. 6 and 7. The second region of the second surface 920 of the connecting piece 400 is a region corresponding to the first region in the thickness direction, and has a groove 420, see fig. 2 and 3. Alternatively, the profile of the first region coincides with the profile of the second region in the thickness direction, thereby facilitating the welding, alignment operation. For example, during welding, the connecting plate 400 and the post 12 shown in the following figures can be aligned to prevent the connecting plate and the post from being excessively offset during welding, for example, the CCD recognizes the positioning of the through hole of the connecting plate and the blind hole of the post. Furthermore, the connection sheet and the pole are subjected to alignment structure design, so that the alignment of the connection sheet and the pole is more accurate. For example, the through hole 430 (shown in fig. 3 and 4) of the connecting piece 400 and the concave hole 121 (shown in fig. 9) of the pole 12, which are mentioned later, are cylindrical holes, and therefore, the connecting piece 400 and the pole 12 can be coaxially aligned through the two holes.
The structure design for falling metal debris generated during the welding of the connecting sheet and the terminal into the battery cell is a way, and in itself, the groove 420 on the second surface 920 of the connecting sheet 400 may be concave from the second surface 920 to the first surface 930, and does not penetrate through the connecting sheet 400. In the illustrated construction of the present example, the recess 420 is a cylindrical bore (i.e., blind bore), see fig. 2 and 3. Alternatively, in other examples, the recess 420 may be a ramp-like structure with appropriate transitions, or may be a stepped bore. Alternatively, the recess 420 may be a prismatic hole, such as a quadrangular prismatic hole.
The depth of the blind hole (the depth extending from the second surface 920 to the first surface 930) can be selected appropriately according to different structural designs, but it is not too thick to reduce the strength of the weld site too much.
Further, as an alternative, the bottom wall of the blind hole has a through hole 430, also cylindrical, as shown in fig. 3. In other words, the through-hole 430 penetrates the connection piece 400 in the thickness direction thereof. And, the blind hole covers the through hole 430 therein. As a more specific example, the blind hole and the through-hole 430 are coaxial. The depth of the blind and through holes 430 as described above can be adjusted and designed by the selected setting of the depth of the blind holes; similarly, the ratio of the diameters of the blind and through holes 430 may also be chosen differently.
In other alternative examples, the first surface 930 of the connecting sheet 400 may be configured to correspond to the through hole 430, for example, a first region of the first surface 930 may have a depression (not shown). When welding is performed, the end surface of the post may be inserted into the depression and contact the first region of the first surface 930 of the tab 400. The sunken groove can be used for mounting the pole, so that the relative position stability of the pole and the connecting piece 400 is improved, and the welding quality is also improved. In fig. 4 the first area of the first surface 930 is not provided with a undercut, in other words the first surface 930 is substantially flat.
Further, as described above, the connection piece 400 has a through hole 430, and thus the recess groove of the first surface 930 and the recess groove 420 of the second surface 920 may communicate through the through hole 430.
As mentioned above, the groove 420 of the connecting piece 400 may be filled with a glue to prevent damage from metal debris generated by welding. In essence, the recess 420 may be filled with the glue. Accordingly, a filler may be disposed within the recess 420 of the second surface 920 of the connecting tab 400. The filling body may be other than glue, or may be other kinds of substances without being limited to glue. The filler may be provided after the welding operation of the connection tab 400 and the post, or alternatively, may be provided (filled) before the welding operation and stably remain in the recess 420 by its adhesion or cohesiveness. When the through-hole 430 is formed in the groove 420, the filling member may be selected to be pre-filled in a portion of the groove 420.
In the structure of being fitted (welded) with the connection piece 400, the first surface 930 of the body is connected with the pole 12 in the first region by welding. In other words, the connection sheet 400 in the present example may be a structure equipped with the electrode post 12, and therefore, it may not be necessary to separately weld the electrode post 12 and the connection sheet 400 at the time of manufacturing the battery. In addition, based on the connection piece 400 having the groove 420 with the through hole 430, the post 12 may also be provided with a concave hole 121 (see fig. 8), and the filling body (not shown) extends from the groove 420 to the concave hole 121.
The recess 121 may be a variously shaped hole including, but not limited to, a sphere, a hemisphere, a cylinder, a prism, etc. In the illustrated example, the recess 121 is tapered. With reference to the tab and post being welded to each other, the tapered recess 121 has a tapered base located adjacent to the first surface 930 of the tab 400 and a tapered tip located away from the first surface 930 of the tab 400.
When glue (e.g., epoxy) is used for the filler, it has certain adhesion and structural strength, so that one part of the filler is located in the connecting piece 400 and the other part is located in the pole 12. By bonding the filling body to the connection sheet 400 and the post 12, respectively, the stability thereof is greatly improved.
According to the structural characteristics of the tab 400 in the example of the present application described above, the failure rate of the battery can be improved by making appropriate adjustments during the assembly of the battery. I.e., to avoid the occurrence of a short circuit caused by welding the connection piece 400 and the post 12. And, thus, the manufacturing process of the top cap assembly of the existing battery can be optimized.
For example, when manufacturing the top cover assembly, the connection piece 400 and the terminal 12 fitted to the top cover 1000 in the present example are welded together, and then the adhesive is dispensed into the groove 420 of the connection piece 400 so as to contact the connection piece 400 and the terminal 12, respectively. This makes it possible to obtain a cover assembly which is structurally robust and can avoid short circuits, and which also makes it possible to produce a battery having a relatively high level of safety, comprising a housing, a cell and a cover assembly. The housing and the battery core may adopt any structure in the mature battery technology, and therefore, details are not described in the present application.
In the above description, the connecting sheet is in the form of a groove, so as to be glued when the connecting sheet is connected with the pole, thereby preventing metal debris generated when the connecting sheet and the pole are welded and connected from entering the battery cell. In such an example, the connecting piece is made with glue-filled receiving spaces (grooves) in the form of removed material (grooving). However, in other examples, the aforementioned glue-filled receiving space, the recess, may also be realized in other ways, not necessarily by removing material from the connecting piece.
For example, by appropriately shaping the connecting piece, it is bent and thus a recess is formed, see for example fig. 10, 11 and 12.
Unlike the manner in which the grooves 420 are formed in the connecting tabs in fig. 2, 3 and 4, another manner in which the grooves 420 are formed in the connecting tabs is disclosed in fig. 10, 11 and 12. As shown in fig. 10, the connecting piece is bent/curved to form a groove 420. In an example, referring to fig. 12, at the front end 910, the connecting piece is bent from the first surface 930 to the second surface 920 to form a bent portion 940 (first bending), and then bent from the second surface 920 to the first surface 930 (second bending) to form the groove 420 on the second surface 920. Wherein after the second bending, a protruding structure 970 is formed on the first surface 930 at the same time that the groove 420 is formed on the second surface 920. The protruding structure 970 serves as a solid portion of the connecting tab for substantially contacting and connecting with the pole, and may be selectively connected by welding.
In this example, since it is not necessary to make the groove 420 by removing material from the relatively thin connecting piece, but to form the groove 420 by bending, it is possible to ensure a relatively higher strength to some extent (since the connecting piece has a smaller thickness, removing material to form the groove 420 further reduces its thickness at the groove 420, and thus the strength is also relatively smaller).
In the above example, the tab has been formed into the groove 420 by two bends and has both an annular channel 960 at the first surface 930 and an annular protrusion 950 at the second surface 920. Wherein, when the battery is applied, the annular protrusion 950 faces the inside of the battery (such as a cell) and the annular groove 960 faces the outside of the battery (such as a pole).
In addition, in the example where the groove 420 is formed in the connecting piece by bending, the degree and manner of the two-fold bending may also be selected. For example, in the present application, both bends are accomplished by an arcuate transition. In other examples, the bending transition may be performed by a straight bending manner. Further, the degree of protrusion of the annular protrusion 950 on the second surface 920, i.e., the distance between the top surface of the annular protrusion 950 and the second surface 920, may also be appropriately selected. Similarly, the protrusion degree of the top surface of the protruding structure 970, i.e. the distance between the top surface of the protruding structure 970 and the first surface 930 may also be appropriately selected, e.g. may be flush, in the example of fig. 9, the top surface of the protruding structure 970 is above the first surface 930.
The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.