KR102591517B1 - Battery pack - Google Patents

Abstract

The battery pack of the present invention includes a battery cell, a circuit board electrically connected to the battery cell, and a connection tab that mediates the electrical connection between the battery cell and the circuit board, wherein the connection tab extends in the direction of the connection tab. Accordingly, an extension portion formed between the battery cell and the tab hole of the circuit board, a coupling portion bent from the extension portion and inserted into the tab hole of the circuit board, and a battery cell from the tab hole of the circuit board along the extension direction of the connection tab. and a solder stopper extending in the opposite direction.
According to the present invention, a battery pack is provided that can prevent leakage of solder forming a connection between a battery cell and a circuit board and prevent electrical short circuit due to leakage or scattering of solder.

Description

Battery pack

The present invention relates to a battery pack.

Typically, secondary batteries are batteries that can be charged and discharged, unlike primary batteries that cannot be recharged. Secondary batteries are used as an energy source for mobile devices, electric vehicles, hybrid vehicles, electric bicycles, and uninterruptible power supplies. Depending on the type of external device to which they are applied, they may be used in the form of a single battery or may be used in multiple forms. It is also used in the form of a module in which batteries are connected and bundled into one unit.

Small mobile devices such as mobile phones can operate for a certain period of time with the output and capacity of a single battery, but in cases where long-term operation or high power operation is required, such as electric vehicles or hybrid vehicles that consume a lot of power, many devices can be operated due to problems with output and capacity. A module format that includes batteries is preferred, and the output voltage or output current can be increased depending on the number of built-in batteries.

One embodiment of the present invention includes a battery pack that can prevent leakage of solder forming a connection between a battery cell and a circuit board and prevent electrical short-circuiting due to leakage or scattering of solder.

One embodiment of the present invention includes a battery pack in which a circuit board connected to a battery cell can be stably supported, and a connection between the battery pack and the circuit board can be maintained with high reliability.

In order to solve the above problems and other problems, the battery pack of the present invention,

battery cell;

a circuit board electrically connected to the battery cell; and

Includes a connection tab that mediates the electrical connection between the battery cell and the circuit board,

The connection tab is,

An extension portion formed between the battery cell and the tab hole of the circuit board along the extension direction of the connection tab;

a coupling portion bent from the extension portion and inserted into a tab hole of the circuit board; and

It includes a solder stopper extending from the tab hole of the circuit board in a direction opposite to the battery cell along the extension direction of the connection tab.

For example, along the width direction of the tab hole, the width of the tab hole is formed to be larger than the width of the coupling portion,

The solder stopper may extend across the gap between the width of the coupling portion and the width of the tab hole.

For example, the solder stopper may extend across the edge of the tab hole beyond the width of the joint.

For example, the extension portion and the solder stopper form a plate member extending onto a plate in one plane,

The coupling portion may be bent from the plate member and inserted into a tab hole of the circuit board.

For example, a cut portion corresponding to a space in the bent coupling portion may be formed in the plate member.

For example, along the width direction of the tab hole, the width of the cut portion may be formed to be larger than the width of the coupling portion.

For example, the solder stopper may be formed of a portion of the plate member excluding the cutout portion among portions of the plate member extending from the tab hole in a direction opposite to the battery cell along the extension direction of the connection tab.

For example, the solder stopper may include a side portion formed on one side of the cut portion.

For example, the incision may be formed to be open toward the outside.

For example, the solder stopper may include a pair of side parts formed on both sides of the incision.

For example, the incision may be formed to be open toward the outside.

For example, the solder stopper is:

a pair of side portions formed on either side of the incision; and

It may include a terminal portion connecting the pair of side portions from the terminal portion of the connection tab along the extension direction of the connection tab.

For example, the incision may be formed in the form of a hole isolated from the outside.

For example, the plate member is disposed on the lower surface of the circuit board,

The coupling portion may be bent from the plate member and inserted into a tab hole of the circuit board to be exposed to the upper surface of the circuit board.

For example, the extension portion and the solder stopper formed on opposite sides of the tab hole may contact the lower surface of the circuit board.

For example, the extension portion and the solder stopper formed on opposite sides of the tab hole may be formed to have substantially the same thickness.

According to the present invention, by providing a solder stopper on the connection tab drawn out from the battery cell, the solder forming the electrical connection between the connection tab and the circuit board is prevented from flowing out to places other than the connection location, and the solder leakage and solder are prevented. It is possible to prevent electrical short circuits from occurring due to scattering, etc.

According to the present invention, the bending structure of the connection tab bent to be coupled to the circuit board can be maintained with high reliability despite spring back, and the workability of the process performed on the circuit board is improved by providing stable support for the circuit board. It can be improved.

Figure 1 shows an exploded perspective view of a battery pack according to an embodiment of the present invention.
2 and 3 show a perspective view and an exploded perspective view, respectively, of a portion of the battery pack shown in FIG. 1.
4 and 5 are enlarged views of a portion of the battery pack shown in FIG. 2, showing a perspective view and an exploded perspective view, respectively.
FIG. 6 shows a view showing a portion of the battery pack shown in FIG. 4 in the VI direction.
FIG. 7 shows a view of a portion of the battery pack shown in FIG. 4 as viewed from direction VII.
FIG. 8 is a diagram illustrating the structure of a first connection tab applicable to a comparative example compared to the present invention.
FIG. 9 shows a diagram showing the first connection tab shown in FIG. 8 in the IX direction.
FIG. 10 shows an exploded perspective view for explaining a modified embodiment of the first connection tab shown in FIG. 5.
FIG. 11 shows an exploded perspective view of a portion of the battery pack shown in FIG. 3.
Figure 12 shows a connection tab applicable to another embodiment of the present invention.

Hereinafter, a battery pack according to a preferred embodiment of the present invention will be described with reference to the attached drawings.

Figure 1 shows an exploded perspective view of a battery pack according to an embodiment of the present invention. 2 and 3 show a perspective view and an exploded perspective view, respectively, of a portion of the battery pack shown in FIG. 1.

Referring to the drawings, the battery pack of the present invention includes a battery cell 100 and a protection circuit module 200 that is electrically connected to the battery cell 100 to control charging and discharging operations of the battery cell 100. may include. In addition, the battery pack includes first and second covers 310 and 320 that cover opposite ends of the battery cell 100 and the protection circuit module 200, respectively, and the first and second covers 310 and 320. It may include first and second insulating sheets 330 and 340 surrounding the outer periphery of the exposed battery cell 100.

In one embodiment of the present invention, the battery cells 100 may be provided in numbers of two or more, and the two or more battery cells 100 may be electrically connected to each other through the protection circuit module 200. For example, the protection circuit module 200 is electrically connected to each battery cell 100 and has a conductive pattern (not shown) to provide a charging and discharging path connected to each battery cell 100. It can be included. More specifically, the protection circuit module 200 may include a circuit board 250 and a conductive pattern (not shown) formed on the circuit board 250, and may include a plurality of circuit boards mounted on the circuit board 250. It may include circuit elements.

The protection circuit module 200 may extend in a direction crossing the plurality of battery cells 100 and form an electrical connection with each of the battery cells 100 . For example, the protection circuit module 200 may extend across the plurality of battery cells 100 and form an electrical connection with each of the connection tabs 120 and 120′ drawn out from the battery cells 100. , charging and discharging currents from each connection tab 120, 120' can be collected and transmitted to an external circuit (not shown). The connection tabs 120 and 120' may include first and second connection tabs 120 and 120' drawn from different polarities of battery cells. Although not shown in the drawing, the first and second connection tabs 120 and 120' include positive electrode plates (not shown) of different polarities among the electrode assemblies (not shown) accommodated inside each battery cell 100, and Each may be electrically connected to a cathode electrode plate (not shown).

In one embodiment of the present invention, the first and second connection tabs 120 and 120' may be formed in different structures. Hereinafter, the structure of the first connection tab 120 will be mainly described, and the second connection tab 120 will be described below. The structure of (120') will be mainly explained on its differences from the first connection tab 120, and redundant description of technical features shared with the first connection tab 120 will be omitted.

In another embodiment of the present invention, the first and second connection tabs 120 and 120' may be formed in the same structure. For example, the structure of the first connection tab 120 described below is, It may be selectively applied to one of the first and second connection tabs 120 and 120′ having different polarities, or may be applied to both the first and second connection tabs 120 and 120′ having different polarities, and similarly, The structure of the second connection tab 120' described below can be selectively applied to any one of the first and second connection tabs 120 and 120' having different polarities, or to the first and second connection tabs 120 and 120' having different polarities. 2 It may be applied to both connection tabs (120,120`). As explained below, the first and second connection tabs 120 and 120' mediate the electrical connection between the battery cell 100 and the protection circuit module 200, and the technical advantages of each structure are However, there is no need to differentiate the structures of the first and second connection tabs 120 and 120', especially depending on polarity.

4 and 5 are enlarged views of a portion of the battery pack shown in FIG. 2, showing a perspective view and an exploded perspective view, respectively. FIG. 6 shows a view showing a portion of the battery pack shown in FIG. 4 in the VI direction.

Referring to the drawings, the first connection tab 120 may mediate an electrical connection between the battery cell 100 and the protection circuit module 200. More specifically, the first connection tab 120 may mediate an electrical connection between the battery cell 100 and the circuit board 250 of the protection circuit module 200, and the first connection tab 120 ) may be inserted into the tab hole 250' of the circuit board 250 and electrically connected to the circuit board 250 or the protection circuit module 200.

The first connection tab 120 may extend integrally from the battery cell 100 and is electrically connected to an electrode assembly (not shown) inside the battery cell 100 to charge the battery cell 100, A discharge pass can be formed. Although not shown in the drawing, the first connection tab 120 does not extend integrally from the battery cell 100 to the extent of connecting the battery cell 100 and the circuit board 250, and does not extend from the battery cell 100. It may include an electrode tab (not shown) extending from 100, and a connection member (not shown) conductively connected to the electrode tab (not shown) separately from the electrode tab (not shown). The connection tab 120 may also form a charging and discharging path for the battery cell 100.

The first connection tab 120 extends from the battery cell 100 and is inserted into the tab hole 250' of the circuit board 250, and is subjected to a high-temperature heat process such as soldering while inserted into the tab hole 250'. The molten solder (not shown) may permeate between the first connection tab 120 and the circuit board 250 to electrically connect the first connection tab 120 and the circuit board 250 to each other. The solder (not shown) may protrude onto the circuit board 250 at the position of the tab hole 250' along the first connection tab 120 inserted into the tab hole 250' to form a predetermined height, The first connection tab 120 and the circuit board 250 may be coupled to each other. For example, the first connection tab 120 may be fitted so as to protrude from the lower surface of the circuit board 250 to the upper surface, and an electrode pad 251 may be formed around the tab hole 250' of the circuit board 250. ) is formed, so that the electrode pad 251 and the first connection tab 120 can be electrically connected to each other using solder melted and solidified by a high-temperature thermal process. For example, the electrode pad 251 formed along the tab hole 250' of the circuit board 250 may be formed as part of a conductive pattern (not shown) formed on the circuit board 250, and may be formed as part of the circuit board 250. The charging and discharging current of the battery cell 100 may be communicated through the conductive pattern (not shown) of 250.

The first connection tab 120 has an extension portion 121 between the battery cell 100 and the tab hole 250′ and a tab hole 250′ along the extension direction of the first connection tab 120. It may include a coupling portion 122 inserted in and a solder stopper 123 extending from the tab hole 250′ in the opposite direction to the battery cell 100.

The extension portion 121 may be formed between the battery cell 100 and the tab hole 250′ along the extension direction of the first connection tab 120. The coupling portion 122 is formed in a bent shape from the extension portion 121 to be inserted into the tab hole 250′, and is inserted into the tab hole 250′ to form an electrical connection with the circuit board 250. You can. The solder stopper 123 extends across the periphery of the tab hole 250', blocks the gap between the coupling portion 122 and the tab hole 250', and melts the solder stopper 123 onto the lower surface of the circuit board 250. Solder (not shown) can be prevented from leaking.

The coupling portion 122 is inserted into the tab hole 250', and a predetermined clearance may be formed between the coupling portion 122 and the tab hole 250'. For example, the width W1 of the coupling portion 122 may be narrower than the width W2 of the tab hole 250′ (W1 < W2), and accordingly, the width of the coupling portion 122 Molten solder (not shown) may leak out from a gap at the edge of the tab hole 250' outside (W1). The solder stopper 123 is formed at a position outside the width W1 of the coupling part 122, and melts through a gap in the tab hole 250' at a position outside the width W1 of the coupling part 122. It is possible to block the outflow of solder (not shown). More specific technical details regarding the solder stopper 123 will be described in more detail later.

The extension portion 121 and the solder stopper 123 may form one plate member 120a extending on a plate to form the same plane, and the coupling portion 122 may be connected to the extension portion 121 and the solder stopper 123. The solder stopper 123 may be formed in a bent form from the plate member 120a and may be inserted into the tab hole 250' so as to protrude from the lower surface to the upper surface of the circuit board 250. The plate member 120a may be disposed on the lower surface of the circuit board 250, and the coupling portion 122 bent from the plate member 120a is connected to the lower surface of the circuit board 250. It may be exposed to the upper surface of the circuit board 250 through the tab hole 250'.

The extension portion 121 and the solder stopper 123 may be disposed on the lower surface of the circuit board 250, and the coupling portion 122 is a plate formed by the extension portion 121 and the solder stopper 123. It may be bent from the member 120a and inserted into the tab hole 250', and may be exposed to the upper surface of the circuit board 250 through the tab hole 250'.

A cut portion C existing as an empty space may be formed in the plate member 120a of the first connection tab 120 as the coupling portion 122 is bent. The cut portion C may correspond to a space in the coupling portion 122 bent from the plate member 120a, and the cut portion C and the coupling portion 122 may have the same width. However, if the cut portion C and the coupling portion 122 are formed to have the same width, the gap between the solder stopper 123 formed by the portion of the plate member 120a excluding the cut portion C and the coupling portion 122 Physical interference may occur, and in particular, when bending the coupling portion 122, physical interference may occur between the coupling portion 122 and the solder stopper 123, so the width of the cut portion C ( Wc) is formed to be larger than the width W1 of the coupling portion 122 to prevent physical interference between the solder stopper 123 and the coupling portion 122 that deviates from the width Wc of the cut portion C.

An extension portion 121 and a solder stopper 123 may be formed before and after the tab hole 250' along the direction in which the plate member 120a or the first connection tab 120 extends, respectively. More specifically, an extension 121 may be formed between the battery cell 100 and the tab hole 250' along the extension direction of the plate member 120a or the first connection tab 120, and a tab hole ( The solder stopper 123 may be formed in the opposite direction of the battery cell 100 from 250'). At this time, the solder stopper 123 may correspond to a portion of the plate member 120a extending from the tab hole 250′ in the opposite direction to the battery cell 100, excluding the cutout portion C. That is, since the solder stopper 123 is configured to block the edge gap of the tab hole 250', empty spaces such as the cutout C are not applicable, and the plate member 120a excluding the cutout C is not applicable. ) can be formed as part of. The solder stopper 123 may be formed as a part of the plate member 120a excluding the cut portion C, and may be formed as a portion of the plate member 120a that deviates from the width Wc of the cut portion C.

The solder stopper 123 can block the gap between the width W1 of the coupling portion 122 and the width W2 of the tab hole 250′ at a position outside the width Wc of the cut portion C. there is. Here, the width W1 of the coupling portion 122 may be measured in the same direction as the width W2 of the tab hole 250′, and the tab hole 250′ extends long along the width direction. It can be formed into a shape. The width W2 of the tab hole 250' and the width W1 of the coupling portion 122 may have an extra tolerance to enable fitting coupling.

The solder stopper 123 may extend across the edge of the tab hole 250' so as to block the gap of the tab hole 250', and the solder stopper 123 may extend across the tab hole 250'. It is possible to block the gap between the width (W2) of and the width (W1) of the coupling portion 122. For example, if an empty space exists between the width W2 of the tab hole 250′ and the width W1 of the coupling portion 122 along the direction of the width W2 of the tab hole 250′, Molten solder (not shown) may flow out to the lower surface of the circuit board 250 through the empty space.

In one embodiment of the present invention, the cut portion C formed in the plate member 120a may be formed as a space in the bent coupling portion 122, so the width Wc of the cut portion C is It may be formed to be substantially equal to the width W1 of the portion 122. However, in one embodiment of the present invention, when bending the coupling portion 122 from the plate member 120a, physical interference between the coupling portion 122 and the plate member 120a, more specifically, the solder stopper 123 is reduced. For this reason, the width (Wc) of the incision (C) can be made larger than the width (W1) of the coupling portion (122), and a position that does not directly contact the width (W1) of the coupling portion (122), that is, , the solder stopper 123 can be formed at a location spaced apart from the width W1 of the coupling portion 122 with a predetermined clearance. Since the solder stopper 123 is formed at a position outside the width Wc of the cut portion C, the solder stopper 123 and the coupling portion 122 are formed by forming the width Wc of the cut portion C wide. ), you can leave a margin between them.

The solder stopper 123 may extend from the tab hole 250' in a direction opposite to the battery cell 100 along the extension direction of the first connection tab 120, and extends from the edge of the tab hole 250'. As it extends across, it is possible to block the gap in the tap hole (250`). For example, the solder stopper 123 allows molten solder (not shown) filled in the tab hole 250' during the soldering process to enter the circuit through the gap between the coupling portion 122 and the tab hole 250'. It may serve to block the flow of molten solder (not shown) to prevent it from seeping into the lower surface of the substrate 250. The solder stopper 123 blocks the flow of solder (not shown) to prevent the molten solder (not shown) from flowing out to the lower surface of the circuit board 250, thereby preventing the molten solder (not shown) from flowing out to the lower surface of the circuit board 250. (not shown) can form a sufficient height to form a firm connection between the coupling portion 122 and the circuit board 250.

If the molten solder (not shown) filled in the tab hole 250 is placed in the gap between the coupling portion 122 and the tab hole 250′, that is, the tab hole 250′ not occupied by the coupling portion 122. ), the flatness of the circuit board 250 becomes poor due to the influence of solder balls (not shown) solidified on the bottom surface of the circuit board 250 and the circuit board 250 is infiltrated through the edge gap. 250 is not stably supported, and the workability of the process performed on the circuit board 250 deteriorates. In particular, if the molten solder (not shown) filled in the tab hole 250' is not controlled and flows in an arbitrary direction, for example, it leaves the tab hole 250' and flows to another area of the circuit board 250. When it flows, an electrical short circuit occurs between conductive patterns (not shown) or circuit elements formed on the circuit board 250, and due to scattering of molten solder (not shown), a large number of particles fall on the circuit board 250. Solder balls (not shown) may scatter and cause an electrical short circuit.

In the present invention, the first connection tab 120 that mediates the electrical connection between the battery cell 100 and the circuit board 250 has a gap in the tab hole 250' across the edge of the tab hole 250'. By forming the solder stopper 123 to block, the molten solder (not shown) filled in the tab hole 250' flows out to the lower surface of the circuit board 250, thereby lowering the flatness of the circuit board 250 and causing damage to the circuit board. (250) It is possible to prevent an electrical short circuit caused by solder balls (not shown) flying onto the surface.

The solder stopper 123 has the function of blocking the outflow of molten solder (not shown) through the gap between the edges of the tab hole 250' and can also function to support the circuit board 250 in a balanced manner, By supporting the circuit board 250 in a balanced manner, the bent shape of the coupling portion 122 can be maintained stably. This will be explained in more detail below.

FIG. 7 shows a view of a portion of the battery pack shown in FIG. 4 as viewed from direction VII.

Referring to the drawing, along the extension direction of the first connection tab 120, the solder stopper 123 is formed on the opposite side of the extension portion 121 with respect to the tab hole 250', and the solder stopper (123) and the extension portion 121 can support the circuit board 250 in a balanced manner on opposite sides of the tab hole 250' and stabilize the circuit board 250 with respect to the bottom surface (not shown). You can support it with For example, the plate member 120a formed by the extension portion 121 and the solder stopper 123 is disposed on the lower surface of the circuit board 250, has a uniform thickness t and has a bottom surface (not shown). ) and the circuit board 250 can stably support the circuit board 250.

The extension portion 121 and the solder stopper 123 disposed on opposite sides of the tab hole 250′ into which the coupling portion 122 is inserted can stably support the bending of the coupling portion 122. there is. For example, the coupling portion 122 is bent from the plate member 120a formed by the extension portion 121 and the solder stopper 123 and inserted into the tab hole 250. The bending of the coupling portion 122 The formed shape has the extension portion 121 and the solder stopper formed on opposite sides of the plate member 120a, despite the spring back tendency to return to the cut portion C of the plate member 120a 123) can be maintained stably.

For example, the plate member 120a may maintain a flat position parallel to the circuit board 250 on the lower surface of the circuit board 250, and a coupling portion bent from the plate member 120a and inserted into the tab hole 250 (122) may be forced into a bent shape by the side wall of the tab hole (250). That is, the relative bending between the plate member 120a and the coupling portion 122 overlaps the circuit board 250 and is disposed in parallel with the tab hole 250' of the plate member 120a and the circuit board 250. It can be maintained by, and at this time, the plate member 120a is spread over a large area on the lower surface of the circuit board 250 by the extension portion 121 and the solder stopper 123 formed on opposite sides of the plate member 120a. It can maintain a flat position parallel to the circuit board 250 by contacting it, and the coupling portion 122 inserted into the tab hole 250′ can maintain a shape bent from the plate member 120a. Accordingly, the electrical connection between the battery cells 100 and the circuit board 250, which are connected to each other through the coupling portion 122, can be maintained with high reliability.

FIG. 8 is a diagram illustrating the structure of a first connection tab applicable to a comparative example compared to the present invention. FIG. 9 shows a diagram showing the first connection tab shown in FIG. 8 in the IX direction.

Referring to the drawings, the first connection tab 20 has an extension part 21 extending from the battery cell 10 and is bent from the extension part 21 to form a tab hole 25' of the circuit board 25. It may include a coupling portion 22 fitted into. As such, in the first connection tab 20 of the comparative example in which the solder stopper is not provided, the extension portion 21 is on one side relative to the tab hole 25 ′ along the extension direction of the first connection tab 20. However, since there is no configuration corresponding to the extension portion 21 on the other side of the extension portion 21, the circuit board 25 is supported in a tilted state on one side or the support state is unstable. The workability of the process performed on the circuit board 25 deteriorates, as it is not stable in any one position and causes continuous shaking.

The engaging part 22 of the first connection tab 20 is inserted into the tab hole 25' of the circuit board 25, and the engaging part 22 is bent from the extension part 21 to form a tab hole ( 25'), the bent shape of the coupling portion 22 is difficult to maintain stably due to the effect of spring back, which tends to return to a flat position. That is, based on the tab hole 25' of the circuit board 25, an extension part 21 is formed on one side, but the other side of the extension part 21 is balanced to correspond to the extension part 21. There is no structure that can hold the device, and the contact area with the circuit board 25 is not sufficient, so it is difficult to maintain it in a flat position parallel to the circuit board 25, and the spring back of the coupling portion 22 occurs. As a result, the bending between the coupling portion 22 and the extension portion 21 is transformed from a relatively sharp angular shape to a rounded shape, causing the support state of the circuit board 25 to become unstable and deforming the coupling portion 22. Accordingly, the length of the coupling portion 22 penetrating the tab hole 25' may be shortened, thereby reducing the coupling force with the circuit board 25.

In one embodiment of the present invention shown in Figure 7, the solder stopper 123 may be balanced with the extension portion 121 on the opposite side with respect to the tab hole 250', for example, the solder stopper 123 and the extension portion 121 are parts of the plate member 120a having the same thickness t, and can maintain the circuit board 250 in a balanced state on opposite sides. Accordingly, the circuit board 250 can be maintained in a stable state, and the workability of processes performed on the circuit board 25 can be improved.

In one embodiment of the present invention shown in FIG. 7, a plate member ( 120a) supports the plate member 120a in a balanced manner on the lower surface of the circuit board 250 and is in contact with the circuit board 250 with a sufficient area to maintain a flat posture parallel to the circuit board 250. The coupling portion 122 bent from the plate member 120a is inserted into the tab hole 250′ despite the spring back tending to return to the cut portion C of the plate member 120a. The bent shape of the member 120a can be maintained.

In one embodiment of the present invention shown in FIG. 5, the solder stopper 123 may be formed to surround the cutout portion C. That is, the solder stopper 123 is formed as a part of the plate member 120a excluding the cutout portion C among the plate members 120a extending from the tab hole 250′ in the opposite direction to the battery cell 100. It may be, and in one embodiment of the present invention, the solder stopper 123 includes a pair of side portions 123a formed on both sides along the width (Wc) direction of the cut portion C, and side portions on both sides of the pair. It may include an end portion 123b connecting (123a).

The terminal portion 123b of the solder stopper 123 may correspond to the terminal portion of the first connection tab 120 along the extension direction of the first connection tab 120, and may correspond to the terminal portion of the first connection tab 120. The circuit board 250 can be stably supported at the position furthest from the battery cell 100 along the extension direction. In addition, the terminal portion 123b of the solder stopper 123 connects the side portions 123a to each other, thereby reinforcing the rigidity of the solder stopper 123.

The solder stopper 123 is formed as a part of the plate member 120a excluding the cutout portion C among the portions of the plate member 120a extending from the tab hole 250′ in the opposite direction to the battery cell 100. It can be, and the cutout part (C) surrounded by the solder stopper 123 including a pair of side parts 123a and an end part 123b connecting the pair of side parts 123a is in the form of a closed hole or isolated from the outside. It can be formed in the form of a hole.

FIG. 10 shows an exploded perspective view for explaining a modified embodiment of the first connection tab shown in FIG. 5.

Referring to the drawing, the first connection tab 220 includes a plate member 220a including an extension portion 221 and a solder stopper 223 formed on opposite sides of the tab hole 250′, and the It may include a coupling portion 222 that is bent from the plate member 220a and inserted into the tab hole 250′.

The solder stopper 223 can block the gap between the width W1 of the coupling portion 222 and the width W2 of the tab hole 250′, and the width W1 of the coupling portion 222 and the tab It may extend across the gap between the widths W2 of the holes 250'. A cutout portion C corresponding to the space of the coupling portion 222 bent from the plate member 220a may be formed in the plate member 220a, and the cut portion C may be formed in the space of the coupling portion 222. Therefore, the width Wc of the cut portion C may be formed to be substantially equal to the width W1 of the coupling portion 222. At this time, the solder stopper 223 is positioned outside the width (Wc) of the cut portion (C) or the width (W1) of the coupling portion (122), which is equal to the width (Wc) of the cut portion (C). , may extend across the gap between the width W1 of the coupling portion 222 and the width W2 of the tab hole 250′. In this embodiment, the solder stopper 223 is positioned in contact with the width (Wc) of the cut portion (C) or the width (W1) of the coupling portion (222), which is equal to the width (Wc) of the cut portion (C). By blocking the gap between the width W1 of the coupling portion 222 and the width W2 of the tab hole 250 ′, the solder (not shown) melted in the high-temperature thermal process is allowed to form on the circuit board 250. It can effectively prevent leakage to the bottom.

Referring to FIG. 3, the first and second connection tabs 120 and 120' mediate the electrical connection between the battery cell 100 and the circuit board 250, and the second connection tab 120' is , may have technical characteristics shared with the first connection tab 120. Hereinafter, the structure of the second connection tab 120' will be described, focusing on differences from the first connection tab 120, and overlapping technical features shared with the first connection tab 120. The explanation will be omitted.

FIG. 11 shows an exploded perspective view of a portion of the battery pack shown in FIG. 3.

Referring to the drawing, the second connection tab 120' extends from the battery cell 100 and can be inserted into the tab hole 250' of the circuit board 250, and connects the battery cell 100 and the circuit board. A charge and discharge pass can be formed between (250). The second connection tab 120′ includes an extension portion 121′ formed between the battery cell 100 and the tab hole 250′ along the extension direction of the second connection tab 120′, and the extension portion 121′ formed between the battery cell 100 and the tab hole 250′. A coupling portion 122′ bent from the portion 121′ and inserted into the tab hole 250′ of the circuit board 250, and a solder extending from the tab hole 250′ in the opposite direction of the battery cell 100. It may include a stopper (123`). Here, the solder stopper 123 ′ blocks the gap in the tab hole 250 ′ at a position outside the width of the cutout C, so that the molten solder (not shown) is on the lower surface of the circuit board 250. You can prevent it from leaking.

The solder stopper 123` is a portion of the plate member 120`a extending from the tab hole 250′ in the opposite direction to the battery cell 100, excluding the cutout portion C. ), and the solder stopper 123' may include a pair of side portions 123'a formed on both sides of the cut portion C. For example, the pair of side portions 123`a of the solder stopper 123` blocks the gap between the protrusion 122` and the tab hole 250` to prevent the flow of molten solder (not shown). You can block it.

The second connection tab 120' may include paired side portions 123'a on both sides of the cutout C, and unlike the first connection tab 120 shown in FIG. 5, the first connection tab 120' The terminal portion 123b formed at the terminal portion of the connection tab 120 to connect the pair of side portions 123a may not be included. That is, in the second connection tab 120', the pair of side portions 123'a of the solder stopper 123' may be formed to be spaced apart from each other at the end of the second connection tab 120'. , the cutout portion C of the second connection tab 120′ may be formed to be open toward the outside. The cutout portion C of the second connection tab 120′ may correspond to a space in the bent coupling portion 122′, and the cutout portion (C) extends long to the end of the second connection tab 120′. C) may mean that the coupling portion 122′ is formed to be long up to the end of the second connection tab 120′. In this structure of the second connection tab 120 ′, the coupling portion 122 ′ inserted into the tab hole 250 ′ is formed to be sufficiently long, so that the coupling force with the circuit board 250 can be improved.

Figure 12 shows a connection tab applicable to another embodiment of the present invention.

Referring to the drawing, the connection tab 120`` electrically connects the battery cell 100 and the circuit board 250 to each other, and the connection tab 120`` is connected to the connection tab 120``. An extension portion 121 `` formed between the tab hole 250 ` of the battery cell 100 and the circuit board 250 along the direction of extension, and the tab hole ( 121 ``) bent from the extension part 121 `` It may include a coupling portion 122 `` fitted into the tab hole 250 `` and a solder stopper 123 `` extending from the tab hole 250 `` in the opposite direction to the battery cell 100 . The extension part 121`` and the solder stopper 123`` can form a plate member 120``a extending on one plane, and the plate member 120``a has a bent member. A cutout portion C corresponding to the space of the coupling portion 122`` may be formed. The solder stopper 123 ``is a plate member (120``a or connection tab 120``) extending in the direction opposite to the battery cell 100 from the tab hole 250 ``along the extension direction of the plate member 120``a or the connection tab 120``. Among the parts of 120``a), it may be formed as part of the plate member (120``a) excluding the cut part (C).

The solder stopper (123``) may include one side part (123``a) formed on one side of the cut part (C). The side portion (123``a) extends across the edge of the tab hole (250``) and allows molten solder (not shown) to flow to the lower surface of the circuit board (250) through the edge of the tab hole (250``). Leakage can be blocked. Unlike the first and second connection tabs 120 and 120′ shown in FIGS. 5 and 11, respectively, the solder stopper 123″ does not include a pair of side portions formed on both sides of the cut portion C, and is It may include only one side portion (123``a) formed on one side of the portion (C). Accordingly, the cutout portion C of the connection tab 120`` may be formed in an open form toward the outside.

The cut portion C of the connection tab 120 `` may correspond to a space in the bent coupling portion 122 ``, and the cut part C extending widely in the width direction of the connection tab 120 `` ) may mean that the coupling portion 122 ``is formed wide in the width direction of the connection tab 120 ``. In this type of connection tab 120 ``, the coupling portion 122 `` fitted into the tab hole 250 ` is formed sufficiently wide, so that coupling strength with the circuit board 250 can be improved.

The structure of the connection tab 120`` described above with reference to FIG. 12 can be applied to any one connection tab selected from the first and second connection tabs 120 and 120' of the present invention. 2 It may be applied to both connection tabs 120 and 120`.

The present invention has been described with reference to the embodiments shown in the accompanying drawings, but these are merely illustrative, and various modifications and equivalent embodiments can be made by those skilled in the art. You will understand the point.

100: battery cell 120: first connection tab
120a,120a`,120a``: Plate member 121,121`,121``: Extension part
122,122`,122``: Joint 123,123`,123``: Solder stopper
123a, 123`a, 123`a: side 200: protection circuit module
250: Circuit board 250`: Tab hole
251: Electrode pattern 310,320: First and second covers
330,340: 1st, 2nd insulating sheet C: cutout

Claims (16)

battery cell;
a circuit board electrically connected to the battery cell; and
Includes a connection tab that mediates the electrical connection between the battery cell and the circuit board,
The connection tab is,
An extension portion formed between the battery cell and the tab hole of the circuit board along the extension direction of the connection tab;
a coupling portion bent from the extension portion and inserted into a tab hole of the circuit board; and
A solder stopper extending from the tab hole of the circuit board in the direction opposite to the battery cell along the extension direction of the connection tab,
The extension portion and the solder stopper form a plate member extending onto a plate on one plane,
A battery pack, characterized in that the plate member has a cut portion corresponding to the space of the bent coupling portion. According to paragraph 1,
Along the width direction of the tab hole, the width of the tab hole is formed to be larger than the width of the coupling portion,
The solder stopper is a battery pack characterized in that it extends across the gap between the width of the coupling portion and the width of the tab hole. According to paragraph 1,
The solder stopper is a battery pack characterized in that it extends across the edge of the tab hole beyond the width of the coupling portion. According to paragraph 1,
The battery pack, wherein the coupling portion is bent from the plate member and inserted into a tab hole of the circuit board. delete According to paragraph 1,
A battery pack, wherein along the width direction of the tab hole, the width of the cut portion is formed to be larger than the width of the coupling portion. According to paragraph 1,
The solder stopper is a battery pack, wherein the solder stopper is formed of a portion of the plate member excluding the cutout portion among portions of the plate member extending from the tab hole in a direction opposite to the battery cell along the extension direction of the connection tab. According to paragraph 1,
The solder stopper is a battery pack characterized in that it includes a side portion formed on one side of the cut portion. According to clause 8,
A battery pack, wherein the cutout portion is formed in an open form toward the outside. According to paragraph 1,
The solder stopper is a battery pack characterized in that it includes a pair of side portions formed on both sides of the cut portion. According to clause 10,
A battery pack, wherein the cutout portion is formed in an open form toward the outside. According to paragraph 1,
The solder stopper is,
a pair of side portions formed on either side of the incision; and
A battery pack comprising a terminal portion connecting the pair of side portions at the terminal portion of the connection tab along the direction in which the connection tab extends. According to clause 12,
A battery pack, wherein the cutout is formed in the form of a hole isolated from the outside. According to paragraph 4,
The plate member is disposed on the lower surface of the circuit board,
The battery pack, wherein the coupling portion is bent from the plate member, inserted into a tab hole of the circuit board, and exposed to the upper surface of the circuit board. According to paragraph 1,
The battery pack, wherein the extension portion and the solder stopper formed on opposite sides of the tab hole are in contact with the lower surface of the circuit board. According to paragraph 1,
A battery pack, wherein the extension portion and the solder stopper formed on opposite sides of the tab hole are formed to have substantially the same thickness.

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