KR20120058965A - Battery having Cell Tab Connecting Structure with Identical Parts - Google Patents

Abstract

PURPOSE: A battery with cell tap connect structure is provided to install conjugating sides of a cell tap and a connection member, thereby facilitating welding work, and improving uniformity and quality of welded state. CONSTITUTION: A battery(100) comprises a plurality of battery cells(110) respectively comprising a pair of tap(111) consisting of a negative electrode tap(111a) and a positive electrode tap(111b). The tap is plate-shaped, is projected toward one side of the cell in order for the plate-shaped surfaces of the positive electrode tap and the negative electrode tap to face each other. The cells are arranged in one or more rows in order for the plate-shaped surface of the other cell nearest-neighboring from the cell to face with the plate-shaped surface of a negative electrode tap of the cell. Between the negative electrode tap of the cell and the positive electrode tap of the nearest-neighboring cell, a connect member(130) is inserted.

Description

Battery having cell tab connecting structure made of the same member {Battery having Cell Tab Connecting Structure with Identical Parts}

The present invention relates to a battery having a cell tab connection structure made of the same member.

Batteries can be largely divided into primary and secondary batteries. Primary batteries generate electricity by using an irreversible reaction, so they cannot be reused after being used once. In this regard, a voltaic battery, and the like, and the secondary battery uses a reversible reaction, and thus, a rechargeable battery, a lithium ion battery, a Ni-Cd battery, and the like may be used as a rechargeable battery after use. 1 conceptually illustrates a structure of a general lithium ion battery which is one of secondary batteries. Lithium ion batteries and lithium ion polymer batteries have the same structure except that they differ only in the properties of the electrolyte (liquid / solid). In addition, depending on the battery, the material of the electrolyte or the electrode may be slightly different from the material of FIG. 1. As shown in FIG. 1, a lithium ion battery includes a cathode 1 generally made of carbon and a cathode 2 generally made of a lithium compound, an electrolyte 3 positioned between two poles 1, 2, and And a wire 4 connecting the cathode 1 and the anode 2. Lithium ions in the electrolyte 3 move toward the cathode 1 when charged and toward the anode 2 when discharged, and cause a chemical reaction by emitting or absorbing excess electrons at each pole. do. In this process, electrons flow through the wire 4, and thus electric energy is generated. Although described using a lithium ion battery herein, other secondary batteries also have the same basic principle and structure as those used as electrodes or electrolytes. That is, the secondary battery generally includes the negative electrode 1, the positive electrode 2, the electrolyte 3, and the electric wire 4 as described above.

At this time, the secondary battery may be formed with a single negative electrode 1, a positive electrode 2, an electrolyte 3 and an electric wire 4, but more generally, a single negative electrode 1 and a positive electrode ( 2), a plurality of unit cells 10 composed of an electrolyte 3 and an electric wire 4 are connected. That is, a plurality of unit cells 10 as described above are contained in the secondary battery pack. Of course, each unit cell 10 is electrically connected to each other.

In general, a secondary battery includes a plurality of unit cells therein, and generally, a pair of external terminal tabs connected to the electrodes of each cell (that is, one negative electrode to which negative electrodes of each unit cell are connected, A positive electrode is connected to each other, and a pair is provided per cell to serve as an electrode. Such secondary cells are generally connected to a plurality of secondary batteries rather than a single one to form a battery as a pack. In this pack type battery, each of the cells is called a cell (distinguishable from the unit cells constituting the battery), and the tabs of each cell are electrically connected.

As described above, a plurality of cells are connected to form a battery formed as one system. At this time, a connecting part made of a conductor such as a metal is assembled and used to connect the plurality of cells to each other. In order to assemble such connecting parts, conventionally, a connection method using laser welding, or a connection method through bolting has been used. However, in the case of the connection method using laser welding, welding must be performed after securing the contact of the tab, but there are many problems in that the defect rate is high. In the case of the connection method by bolting, the difficulty of the assembly of the connection parts There were problems of rise and increase in parts count. In order to solve this problem, many studies have been made in the past, but it was difficult to completely overcome the problems described above.

In Japanese Patent Laid-Open No. 2004-327310 (hereinafter, referred to as Prior Art 1), as shown in Fig. 2A, a connection structure and a connection method of a secondary battery to enable easy and reliable connection of terminals between adjacent cells The present invention relates to a terminal and a terminal connecting member, and discloses a technique in which the terminal and the terminal connecting member are joined by solder plating. In addition, in Korean Patent Laid-Open Publication No. 2009-0095949 (hereinafter, referred to as Prior Art 2), as shown in FIG. 2 (B), the conductivity for the electrical connection of the plate-shaped secondary battery cells ('battery cells') constituting the battery module The electrode terminal connecting member of the present invention, which includes a left wing connection part / right wing connection part formed with a slit so that the electrode terminals of a left / right battery cell can be inserted and connected, and bent and welded after the electrode terminal is inserted into the slit. The technique for connecting an electrode terminal and a connection member by this is disclosed. By the way, in the case of the prior art 1 and the prior art 2 there is an advantage that the contact stability is higher than the laser welding connection, the connection parts are reduced rather than the bolt fastening, as shown in Figure 2 (A) and (B), respectively Since the shape of the member is complicated, there is a problem that not only the manufacturing difficulty of the connecting member unit is high, but also the assembly difficulty is increased accordingly.

In addition, in the case of the conventional cell tab connection members as described above, in order to apply power from the outside, a separate member must be welded. In this case, three parts such as cell tab / connection member / separate member for power application are welded. It should be, there was a problem that the welding quality is degraded.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to simplify the cell tab connection structure in the connection structure of the cell tab constituting the battery, It is to provide a battery having a cell tab connection structure made of the same member to obtain a homogeneity.

A battery having a cell tab connection structure made of the same member of the present invention for achieving the above object has a plurality of tabs having a pair of tabs 111 each comprising a negative electrode tab 111a and a positive electrode tab 111b. In the battery 100 in which the battery cells 110 are arranged, the tab 111 is formed in a plate shape, and the plate surface of the negative electrode tab 111a and the positive electrode tab 111b are formed on one side of the cell 110. ) Is formed to protrude in parallel to face each other, the cell 110, the plate surface of the negative electrode tab 111a of one cell 110 and the cell 110 of the closest position of the one cell 110 The plate surfaces of the positive electrode tabs 111b are arranged in at least one row so as to face each other in parallel to each other, and the negative electrode tabs 111a of one cell 110 and the cell 110 at the nearest-most position of the one cell 110. Connection member 130 is provided between the positive electrode tab 111b of the), the connection The ash 130 is bent so that the plate has a U-shaped cross section, the first side surface 131a which is in contact with the negative electrode tab 111a, the second side surface 131b which is in contact with the positive electrode tab 111b, The connection surface 132 connects the first side surface 131a and the second side surface 131b, and the side surfaces 131a and 131b of the connection member 130 and the tab of the cell 110. Each of the 111 parts is connected by welding.

In this case, the battery 100 further includes a support member 120 interposed between the cells 110 to fix and support the position of the cell 110. The connection surface 132 is characterized in that it is arranged to be in contact with the upper surface of the support member 120.

In addition, the battery 100 may further include a voltage sensing member 140 that connects the connection members 130 adjacent to each other, and the voltage sensing terminal 145 is provided at one side thereof. At this time, the voltage sensing member 140 is a U-shaped plate, a pair of legs 141 which are in contact with each other and the welding surface 132 of the connection member 130 disposed adjacent to each other and It consists of a connecting portion 142 for connecting a pair of the leg portion 141, characterized in that the voltage sensing terminal 145 is provided on the connecting portion 142.

In addition, the battery 100 is connected to the connection member 130, characterized in that further comprises a power applying member 150 having a power applying terminal 155 on one side. At this time, the power applying member 150 is formed of a straight plate, one side is in contact with the connecting surface 132 of the connection member 130 is welded and the other side is provided with the power supply terminal 155 It features.

In addition, the connection member 130, the voltage sensing member 140 and the power applying member 150 is characterized in that made of a metal having a melting point of 600 ° C or more containing a copper alloy.

In addition, the connection member 130, the voltage sensing member 140 and the power applying member 150 is characterized in that the plated with a metal having a melting point of 600 ° C or less.

According to the present invention, in the cell tab connection structure of the battery, the tabs are connected by connecting members formed in the same shape, thereby making the cell tab connection process much easier than in the related art, while maintaining the uniformity and goodness of the connection state. There is a big advantage that can be increased. More specifically, according to the present invention, since the joint surface of the cell tab and the connecting member is first installed in parallel, the welding operation is much easier than before. Also, when the cell tap is connected, the cell tab and the connecting member are connected to each other, and the voltage sensing member or the power applying member is welded to the connecting member, so that the welding is performed by the cell tap-connecting member / connecting member-voltage sensing member / connecting member- Since the welding is made between the power supply members and two welding is performed in any case, the uniformity and goodness of the welding state can be further increased than before.

In addition, since the shape of the connection member itself is much simpler than the conventional bolting method or the conventional method of using a connection member, not only the effect of reducing the process and the number of parts but also the difficulty of the process can be further reduced.

In addition, according to the present invention, there is an effect that the voltage sensing can be easily made through the connection member, and thus the prevention of overcurrent or overcharging can be made more quickly and accurately, thereby increasing the stability and safety of battery operation. There is also an effect.

1 is a structural diagram of a typical lithium ion battery.
2 is a conventional cell tab connection structure.
3 is a perspective view of a battery basic structure.
4 and 5 are cell tab connection structure of the present invention.

Hereinafter, a battery having a cell tab connection structure made of the same member according to the present invention having the above configuration will be described in detail with reference to the accompanying drawings.

3 is a perspective view of a battery basic structure. As shown, the battery 100 is composed of a plurality of battery cells 110 having a pair of tabs 111, the tab 111 is a negative electrode tab 111a per one cell (110) And one positive electrode tab 111b, that is, a pair of the tabs 111 are provided per one cell 110. At this time, the tabs 111 are formed in a plate shape, and protruded so that the plate surface of the negative electrode tab 111a and the plate surface of the positive electrode tab 111b face each other in parallel to one side of the cell 110. (In the drawings of the present specification, as an example, the tab 111 protrudes upward. However, the tab 111 may be positioned at both sides with respect to the battery 100, for example.) In addition, the cell 110 is the anode of the cell 110 at the plate surface of the negative electrode tab 111a of one cell 110 and the innermost proximal position of the one cell 110. The plate surfaces of the tabs 111b are arranged in at least one row so as to face each other in parallel. To illustrate, the cell 110 generally has a flat rectangular parallelepiped shape, wherein the pair of tabs 111 are perpendicular to one of the narrow sides of the cell 110 and parallel to the wider surface. It is made in the form of extending side by side. In addition, the cells 110 are arranged so that the surfaces are overlapped with each other, so that the tabs 111 formed parallel to the surfaces of the cells 110 are naturally all aligned with each other as the cells 110 are arranged. It will be arranged side by side.

In this case, a support member 120 may be interposed between the cells 110 to fix and support the position of the cell 110. In the cell tab connection structure of the present invention, the presence or absence of the support member 120 is not particularly important. The support member 120 may be made of a metal material such as aluminum, or may be made of an electrical insulator material.

In the basic structure of the battery formed as described above, the present invention proposes the following structure for connection between the tabs 111 of the cell 110. 4 illustrates a cell tap connection structure according to the present invention, and FIG. 5 illustrates a voltage sensing terminal and a power supply terminal connection structure in addition to the cell tap connection. A cell tab connection structure of the present invention will be described with reference to FIGS. 4 and 5.

In the present invention, the connection member 130 is interposed between the negative electrode tab 111a of the one cell 110 and the positive electrode tab 111b of the cell 110 at the closest position of the one cell 110. As shown in FIG. 4, the plate is formed in a bent form to have a U-shaped cross section. In more detail, the connection member 130 may include a first side surface 131a contacting the negative electrode tab 111a, a second side surface 131b contacting the positive electrode tab 111b, and the first side surface 131a. ) And a connection surface 132 connecting the second side surface 131b. That is, the connecting member 130 can be simply formed by bending both ends of the plate to stand vertically, at which time the bent portion becomes both side surfaces 131a and 131b.

The side tabs 131a and 131b of the connection member 130 and the tabs 111 of the cell 110 made as described above are connected to each other by welding, thereby forming a cell tab connection structure of the present invention. That is, in any one connecting member 130, the first side surface 131a of the connecting member 130 is welded in contact with the negative electrode tab 111a of one cell 110, and the connecting member 130 is welded. ), The second side surface 131b is contacted and welded to the positive electrode tab 111b of the cell 110 at the closest position of the one cell 110, whereby one cell 110 is formed by the connection member 130. The negative electrode tab 111a of the cell 110 and the positive electrode tab 111b of the cell 110 at the closest position of the one cell 110 are electrically connected to each other.

Such a cell tab connection structure by the connection member 130 of the present invention has the advantage that it is possible to obtain the uniformity and goodness of the connection state while being very simple compared to the conventional. First, compared with the conventional connection structures as shown in Figure 2, the connection member 130 of the present invention is made of a plate formed in a U-shaped cross-section bar is very simple, the connection member ( 130 It is very easy to manufacture and the production cost can also be dramatically lower. In addition, the side surfaces 131a and 131b of the connection member 130 and the tabs 111 of the cell 110 may be disposed by interposing the connection member 130 between the tabs 111. According to the shape of the natural contact is made, therefore, there is no difficulty in performing welding, so the welding process for connection is also much simpler than in the prior art.

5 illustrates an embodiment of a voltage sensing terminal and a power applying terminal in a battery having a cell tap connection structure according to the present invention. As described above, the cell tab connection structure according to the present invention has a very simple structure in which the tabs 111 are connected by the connecting member 130 formed at both ends of the plate to have a U-shaped cross section. Have In this case, using the connection structure of the present invention, voltage sensing is performed using the connection surface 132 except for the side surfaces 131a and 131b which are in contact with the tabs 111 in the connection member 130. The connection structure of the terminal and the power supply terminal can also be much simpler than in the related art.

In the present invention, the battery 100 further connects the connection members 130 adjacent to each other to connect the voltage sensing terminals, and further includes a voltage sensing member 140 having a voltage sensing terminal 145 on one side. To be done. At this time, the voltage sensing member 140 is a U-shaped plate, as shown in Figure 5, a pair of each contacted and welded to the connection surface 132 of the connection member 130 disposed adjacent to each other The connection part 142 connecting the leg part 141 and a pair of the leg part 141 may be provided on the connection part 142 to be provided with the voltage sensing terminal 145. The voltage sensing member 140 also has an extremely simple form like the connection member 130, and thus, the manufacturing of the voltage sensing member 140 is also very easy and the production cost is also low.

In addition, in the present invention, the battery 100 is connected to the connection member 130 to apply power, and further comprises a power applying member 150 having a power applying terminal 155 on one side. At this time, the power applying member 150 is also formed of a straight plate, as shown in Figure 5, one side is welded in contact with the connecting surface 132 of the connecting member 130 and the power to the other side The application terminal 155 may be provided. The power applying member 150 is formed in a more simplified form than the voltage sensing member 140, so that the manufacturing difficulty and the production cost can be minimized so that it can no longer be lowered.

At this time, as described above, both the voltage sensing member 140 and the power applying member 150 are connected to each other by welding a part of the voltage sensing member 140 and the connection surface 132 of the connection member 130. That is, in the present invention, the external terminal and the tab are not directly connected, but are indirectly connected by the connecting member.

In more detail, in the present invention, the connection between the cell tabs is made by contacting and welding between the tab 111-side surface 131 of the connection member 130, and the voltage sensing terminal is provided with the connection member 130. Connection surface 132 of the connection member 132 of the voltage sensing member 140 by the contact and welding of the leg 141 of the voltage sensing member 140. It is made by contact and welding between one side of the power applying member 150. In summary, in the present invention, for the connection between the cell tabs and the provision of an external terminal (voltage sensing terminal or power supply terminal), welding between each member can be achieved by two sheets of welding.

As such, the present invention excludes direct connection between the external terminal and the tab, and allows the tab and the external terminal member to be welded to the connecting member, respectively, so that only two welding parts are made at all times, so that the welding portion for connection is uniform. And goodness can be achieved much more easily than in the prior art. In addition, as described above, according to the present invention, voltage sensing may be easily performed through the connection member, and thus prevention of overcurrent or overcharging may be performed more quickly and accurately, thereby increasing stability and safety in battery operation.

The connection member 130, the voltage sensing member 140, and the power applying member 150 are preferably made of a metal having a melting point of 600 ° C. or higher so as not to be damaged by heat generated by a high voltage. One such metal having this property and suitable for use as a terminal is typically copper alloy. Copper alloys have high electrical conductivity and high abrasion resistance and corrosion resistance, making them suitable for use as the members.

In addition, the members are coupled to the tab 111 by welding. In the case of a metal such as copper alloy, the melting point may be very high, such as about 970 ° C., to increase the welding current consumption. To compensate for this, the members are preferably plated with a metal having a melting point of 600 ° C. or less. An example of such a metal may be tin, but since tin has a melting point of about 230 ° C., which is very easy to weld, and copper alloy has good plating property, the electrical conductivity, wear resistance, High corrosion resistance can be facilitated welding.

The present invention is not limited to the above-described embodiments, and the scope of application of the present invention is not limited to those of ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications can be made.

100: battery (of the present invention)
110: cell 111: tab
111a: negative electrode tab 111b: positive electrode tab
120: support member
130: connecting member
131a: first side 132a: second side
133: connecting surface
140: voltage sensing member
141: leg portion 142: connecting portion
145: voltage sensing terminal
150: power supply member 155: power supply terminal

Claims (8)

In the battery 100 in which a plurality of battery cells 110 having a pair of tabs 111 each consisting of a negative electrode tab 111a and a positive electrode tab 111b are arranged,
The tab 111 is formed in a plate shape, and protrudes from one side of the cell 110 such that the plate surface of the negative electrode tab 111a and the plate surface of the positive electrode tab 111b face in parallel to each other.
In the cell 110, the plate surface of the negative electrode tab 111a of one cell 110 and the plate surface of the positive electrode tab 111b of the cell 110 at the closest position of the one cell 110 face each other in parallel. Arranged in at least one column for viewing,
The connecting member 130 is interposed between the negative electrode tab 111a of one cell 110 and the positive electrode tab 111b of the cell 110 at the closest position of the one cell 110. 130 is a shape in which the plate is bent to have a U-shaped cross-section, the first side 131a in contact with the negative electrode tab 111a, the second side 131b in contact with the positive electrode tab 111b, and the first It consists of a connection surface 132 connecting the first side (131a) and the second side (131b),
The side tabs (131a) (131b) of the connection member 130 and the tab (111) of the cell (110) is a battery having a cell tab connection structure made of the same member, characterized in that each connected by welding.
The method of claim 1, wherein the battery 100
Interposed between the cells 110 is formed further comprising a support member 120 for holding and supporting the position of the cell 110, the connection member 130 is the connection surface 132 the support member A battery having a cell tab connection structure made of the same member, which is arranged to be in contact with an upper surface of the 120.
The method of claim 1, wherein the battery 100
A battery having a cell tab connection structure formed of the same member, wherein the connection members 130 adjacent to each other are connected to each other, and further comprising a voltage sensing member 140 having a voltage sensing terminal 145 on one side. .
The method of claim 3, wherein the voltage sensing member 140
As a U-shaped plate, a pair of leg portions 141 and a pair of leg portions 141 which are in contact with each other and welded to the connection surfaces 132 of the connection member 130 disposed adjacent to each other are connected. The battery having a cell tab connection structure made of the same member, characterized in that the connection portion 142, the voltage sensing terminal 145 is provided on the connection portion 142.
The method of claim 1, wherein the battery 100
The battery having a cell tab connection structure made of the same member is connected to the connection member 130, further comprising a power applying member 150 having a power applying terminal 155 on one side.
The method of claim 5, wherein the power applying member 150 is
Cell tab connection structure formed of the same member is formed of a straight plate, one side is in contact with the connection surface 132 of the connection member 130 is welded and the other side is provided with the power supply terminal 155 Battery having.
The method of claim 1, 3, 5, wherein the connection member 130, the voltage sensing member 140 and the power applying member 150 is
A battery having a cell tab connection structure made of the same member, which is made of a metal having a melting point of 600 ° C. or higher including copper alloy.
The method of claim 1, 3, 5, wherein the connection member 130, the voltage sensing member 140 and the power applying member 150 is
A battery having a cell tab connection structure comprising the same member, which is plated with a metal having a melting point of 600 ° C. or less.

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