KR20220158537A - Battery pack - Google Patents

Abstract

The present invention provides a battery pack. The battery pack of the present invention comprises: a plurality of battery cells; a cell holder surrounding an accommodation space for accommodating the plurality of the battery cells and including a hollow protrusion unit formed at a position of detecting temperature to measure the temperature of the battery cell; a cover disposed on the cell holder to have an exposing hole for exposing the hollow protrusion unit; and a thermistor accommodated through the exposing hole into the hollow protrusion unit. According to the present invention, the battery packs having the same structure are used as one unit, so that a plurality of the battery packs are connected to one another to provide a module having various outputs and capacities and the number of the battery packs included in the module is increased or decreased to provide expandability of the battery packs such that adaptive action can be taken against various outputs and capacities by using the battery packs having the same structures.

Description

Battery pack {Battery pack}

The present invention relates to a battery pack.

In general, a secondary battery is a battery that can be charged and discharged, unlike a primary battery that cannot be charged. Secondary batteries are used as energy sources for mobile devices, electric vehicles, hybrid vehicles, electric bicycles, uninterruptible power supplies, etc. It is also used in the form of a pack in which batteries are connected and bundled into one unit.

Small mobile devices such as mobile phones can operate for a certain amount of time with the output and capacity of a single battery, but require long-term operation and high-power operation, such as larger-sized mobile devices such as laptops or electric vehicles and hybrid vehicles that consume a lot of power. In this case, a pack type including a plurality of batteries is preferred due to problems of output and capacity, and output voltage or output current can be increased according to the number of built-in batteries.

An embodiment of the present invention is a method in which a plurality of battery packs are connected to each other by using a battery pack having the same structure as a unit to provide a module with various outputs and capacities, and a battery included in the module A battery pack capable of providing scalability of a battery pack so as to adaptively respond to various outputs and capacities by using a battery pack having the same structure by increasing or decreasing the number of packs.

In another embodiment of the present invention, through the temperature detection position set for each battery pack, in a module expanded to include a plurality of battery packs, various temperature detection positions including the central position of the entire module can be set naturally, , It includes a battery pack with an improved structure so that there is no need to separately set the temperature detection position in the extended module.

In order to achieve the above and other objects, the battery pack of the present invention,

a plurality of battery cells;

A cell holder surrounding an accommodation space accommodating a plurality of battery cells, the cell holder including a hollow protrusion formed at a temperature detection position for measuring the temperature of the battery cells;

a cover disposed on the cell holder and having an exposure hole for exposing the hollow protrusion; and

and a thermistor accommodated in the hollow protrusion through the exposure hole.

For example, the plurality of battery cells are battery cells in which one row of battery cells arranged along a column direction is arranged in a plurality of rows, and battery cells in rows adjacent to each other along a transverse direction intersecting the column direction are Depending on the front position or the rear position can be arranged to be biased alternately with each other.

For example, the temperature detection location is

a first temperature detection position disposed at a central position of the cell holder; and

A second temperature detection position adjacent to a corner position rather than a central position of the cell holder may be included.

For example, the cell holder,

a first extension edge and a first accommodation edge facing each other along a column direction with the accommodation space interposed therebetween; and

It may include a second extension edge and a second accommodation edge facing each other along the transverse direction with the accommodation space interposed therebetween.

For example, the first extending edge and the first receiving edge,

first convex portions and second concave portions formed in complementary shapes that can be fitted to each other at the same row position; and

Including; a first concave portion and a second convex portion formed in complementary shapes that can be fitted to each other at another mutually same column position;

The first extended edge is formed in a zigzag shape including first convex portions and first concave portions alternately disposed along the transverse direction,

The first accommodating edge may be formed in a zigzag shape including second convex portions and second concave portions alternately disposed along the transverse direction.

For example, the second extension edge and the second accommodation edge may be formed flat.

For example, the second temperature detection position,

The first expansion edge, the first accommodating edge, the second expansion edge, and the second accommodating edge may include four second temperature detection positions disposed adjacent to four corner positions formed while contacting each other.

For example, the second temperature detection position may be adjacent to the corner position, but may be spaced apart from the first extended edge, the first accommodating edge, the second extended edge, and the second accommodating edge forming the corner position.

For example, the second temperature detection position may be formed at a position biased towards the first accommodating edge between the first expansion edge and the first accommodating edge.

For example, the second temperature detection position,

a 2-1st temperature detection position formed adjacent to the second extended edge; and

A 2-2nd temperature detection position formed adjacent to the second accommodating edge may be included.

For example, the 2-1st temperature detection positions include two 2-1st temperature detection positions spaced apart from each other in a column direction along the second extended edge,

The 2-2nd temperature detection positions may include two 2-2nd temperature detection positions spaced apart from each other in a column direction along the second accommodating edge.

For example, a first distance between the second extended edge and the 2-1st temperature detection position may be greater than a second distance between the second accommodating edge and the 2-2nd temperature detection position.

For example, a first extension piece protruding from the first extension edge toward the outside of the accommodation space is formed on the first extension edge;

A second extension piece protruding from the second extension edge toward the outside of the accommodating space may be formed on the second extension edge.

For example, the battery pack further includes a bus bar disposed in the accommodation space to connect the plurality of battery cells to each other,

The first and second extension pieces may extend from the bus bar toward the outside of the accommodating space along a column direction and a transverse direction.

For example, the bus bar,

Connecting a group of battery cells including a plurality of battery cells adjacent to each other among the plurality of battery cells in parallel;

A group of battery cells adjacent to each other along the column direction may be connected in series.

For example, the bus bar,

a main body portion extending between a group of battery cells adjacent to each other along a column direction; and

First and second branch portions may include first and second branch portions respectively extending from the main body toward a group of battery cells adjacent to each other with the main body interposed therebetween.

For example, the body unit may include a plurality of body units disposed with a group of battery cells interposed along a column direction.

For example, the first extension piece may extend along a column direction from an outermost body portion of any one of a frontmost or rearmost body portion along a column direction.

For example, the outermost body portion includes convex portions and concave portions alternately disposed along the transverse direction and extends in a zigzag form,

The first extension piece may include a plurality of first extension pieces extending from the concave portion of the outermost body part.

For example, the first extension piece extends along the column direction from the frontmost body portion along the column direction,

The frontmost body portion and the first extended edge are each formed in a first zigzag shape including first convex portions and first concave portions alternately disposed at alternate positions along the transverse direction,

The rearmost main body part and the first accommodating edge facing the outermost main body part and the first extended edge, respectively, include second convex parts and second concave parts alternately disposed at alternating positions along the lateral direction, and the second jig It is formed in a zag shape,

The first and second zigzag shapes may be complementary to each other.

For example, the second extension piece may extend along the transverse direction from an outermost position of the bus bar along the transverse direction.

For example, the second extension pieces may include a plurality of second extension pieces extending from an outermost position of the main body of the bus bar arranged along the column direction.

According to the present invention, it is possible to provide a module with various outputs and capacities by connecting a plurality of battery packs to each other by taking the battery packs having the same structure as one unit, and the number of battery packs included in the module By increasing or decreasing , it is possible to provide scalability of the battery pack so that it can adaptively respond to various outputs and capacities using a battery pack having the same structure.

According to the present invention, through the temperature detection position set for each battery pack, various temperature detection positions including the central position of the entire module can be set naturally in a module expanded to include a plurality of battery packs, and the extended A battery pack having an improved structure may be provided so that a temperature detection position in the module does not need to be separately set.

1 is an exploded perspective view of a battery pack according to a preferred embodiment of the present invention.
2 and 3 are perspective views of the upper holder and the lower holder shown in FIG. 1, respectively.
FIG. 4 is a plan view showing the arrangement of bus bars and battery cells of the battery pack shown in FIG. 1 .
5 and 6 are different plan views showing a structure in which the battery pack shown in FIG. 4 is extended in a column direction and a transverse direction, respectively.
FIG. 7 is an exploded perspective view of a battery pack according to an embodiment of the present invention, and a diagram for explaining assembly of the thermistor is shown.
FIG. 8 is an enlarged perspective view of a part of the upper holder shown in FIG. 7 .
9 is a perspective view showing a state in which the cover of FIG. 7 is assembled on the upper holder of FIG. 8 .
10 is a plan view for explaining the arrangement of thermistors in a module in which the battery pack according to the present invention is extended along a column direction.
11 is a plan view for explaining the arrangement of the thermistors in a module in which the battery pack according to the present invention is extended along the column and lateral directions.
12 is a perspective view for explaining assembly between a battery cell and a lower holder.
FIG. 13 is a perspective view showing the lower holder shown in FIG. 12 .
FIG. 14 is a plan view showing the lower holder shown in FIG. 13 .
15 is a plan view showing a lower holder in which battery cells are assembled.
FIG. 16 is a view showing a side view of the lower holder in which the battery cells of FIG. 15 are assembled in a column direction or a transverse direction, and is a view for explaining the settling depth of the battery cells.
17 is an exploded perspective view of a battery pack according to an embodiment of the present invention, and an exploded perspective view for explaining the structure of a cover is shown.
FIG. 18 is a perspective view illustrating the battery pack in a state in which the cover of FIG. 17 is assembled.
19 is a perspective view showing a cell holder of a battery pack according to another embodiment of the present invention.
FIG. 20 is a perspective view showing a state in which the cover is assembled on the cell holder shown in FIG. 19 .

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

1 is an exploded perspective view of a battery pack according to a preferred embodiment of the present invention. 2 and 3 are perspective views of the upper holder and the lower holder shown in FIG. 1, respectively. FIG. 4 is a plan view showing arrangement of bus bars and battery cells of the battery pack shown in FIG. 1 . 5 and 6 are different plan views showing structures in which the battery pack shown in FIG. 4 is extended in the column and lateral directions, respectively.

1 to 4 together, the battery pack 1 of the present invention is a battery cell 10 in which one row of battery cells 10 arranged along a column direction Z1 are arranged in a plurality of rows, The battery cells 10 in rows adjacent to each other along the transverse direction Z2 intersecting the direction Z1 are alternately skewed toward each other in a front position or a rear position along the row direction Z1. , A cell holder (W) surrounding the accommodation space in which the battery cell 10 is accommodated, disposed to face each other along the column direction (Z1) with the accommodation space interposed therebetween, formed in a shape complementary to each other. A cell holder (W) including a front wall (FW) and a rear wall (RW), a bus bar (B) disposed in the accommodating space and connecting a plurality of battery cells (10) to each other, and the bus bar (B) ) may include extension pieces E1 and E2 extending to the outside of the receiving space.

The battery cell 10 may include a plurality of battery cells 10 arranged along the column direction Z1, and one row of battery cells 10 arranged along the column direction Z1 may be arranged in the transverse direction Z2. ), a plurality of rows of battery cells 10 may be formed. Throughout the present specification, the column direction (Z1) is a direction in which the battery cells 10 are arranged, and when adjacent columns are alternately biased toward the front or rear positions, the front and rear directions are biased in adjacent columns. can mean direction. In one embodiment of the present invention, the column direction (Z1) may mean a direction in which the plurality of battery cells 10 are arranged on a straight line, and a transverse direction (Z2) intersecting the column direction (Z1) Accordingly, it can be seen that a plurality of battery cells 10 are arranged, but at this time, the battery cells 10 arranged along the transverse direction Z2 are arranged on a zigzag line rather than on a straight line can see. That is, in one embodiment of the present invention, the battery cells 10 are disposed on a straight line along the column direction Z1, and adjacent columns are moved to a forward position or a rear position along the column direction Z1. By being alternately skewed, the battery cells 10 may be arranged in zigzag lines rather than in straight lines along the transverse direction Z2 intersecting the column direction Z1.

In one embodiment of the present invention, the fact that adjacent rows are alternately skewed toward each other in the front or rear positions along the column direction Z1 means that the battery cells 10 in one row are adjacent to the battery cells 10 in the adjacent row. ), it may mean that a dense arrangement of the battery cells 10 is implemented. For example, the battery cells 10 of the first and second columns Q1 and Q2 adjacent to each other (see FIG. 4 ) are alternately skewed to the rear position and the front position along the column direction Z1, respectively, so that the first The battery cells 10 of the first column Q1 may be inserted into valleys between the battery cells 10 of the second column Q2 adjacent to each other along the column direction Z1, and vice versa. The battery cells 10 of the column Q2 may be inserted into valleys between the battery cells 10 of the first column Q1 adjacent to each other along the column direction Z1 . In this way, as adjacent columns are alternately skewed toward the front or rear positions along the column direction Z1, a larger number of battery cells 10 can be densely arranged within a small area, and the battery The energy density of the pack 1 can be increased.

Referring to FIGS. 1 to 4 , in one embodiment of the present invention, according to the arrangement of battery cells 10 staggered with each other in adjacent rows, the shape of the cell holder W accommodating the battery cells 10 It may also be formed in a form corresponding to the arrangement of the battery cells 10 . In one embodiment of the present invention, the cell holder (W) accommodating the battery cell 10 may include a wall surrounding the accommodation space in which the battery cell 10 is accommodated. At this time, the cell holder (W The walls of ) are the front wall (FW) and the rear wall (RW) facing each other along the column direction (Z1), and the first side wall facing each other along the transverse direction (Z2) intersecting the column direction (Z1) (SW1) and the second side wall (SW2) may be included. In one embodiment of the present invention, the front wall (FW) may include a first convex portion (F1) formed to protrude forward in response to the rows that are biased to the front position, and correspond to the rows that are biased to the rear position. Thus, a first concave portion F2 drawn from the front may be included. The first convex portion F1 and the first concave portion F2 correspond to the arrangement of the battery cells 10 that are alternately disposed toward the front or rear positions along the transverse direction Z2, It may be alternately arranged along Z2, and the first convex portion F1 and the first concave portion F2 may be connected to each other along the transverse direction Z2 to form the front wall FW. .

Similar to the front wall FW, the rear wall RW may include a second convex portion R1 formed to protrude rearward in response to the rows biased toward the rear, Corresponding to the row, a second concave portion R2 drawn from the rear may be included. The second convex portion R1 and the second concave portion R2 correspond to the arrangement of the battery cells 10 that are alternately disposed toward the rear position or the front position along the transverse direction Z2, They may be alternately arranged along Z2, and the second convex portion R1 and the second concave portion R2 may be connected to each other along the transverse direction Z2 to form the rear wall RW. .

In one embodiment of the present invention, the fact that one row is biased toward the front position means that the front wall FW corresponding to the one row includes the first convex portion F1 and at the same time the rear wall corresponding to the one row (RW) may mean that the second concave portion (R2) is included. As such, in one embodiment of the present invention, the first convex portion F1 of the front wall FW and the second concave portion R2 of the rear wall RW may be formed in the same column position, , can be formed in complementary shapes that can be fitted against each other at the same row position. Similarly, if one row is biased toward the rear position, the front wall FW corresponding to the one row includes the first concave portion F2, and the rear wall RW corresponding to the one row includes the first concave portion F2. It may mean that it includes 2 convex portions (R1). As such, in one embodiment of the present invention, the first concave portion F2 of the front wall FW and the second convex portion R1 of the rear wall RW may be formed in the same column position, , can be formed in complementary shapes that can be fitted against each other at the same row position.

In one embodiment of the present invention, the first convex portion F1 of the front wall FW and the second concave portion R2 of the rear wall RW are connected to each other, and the first concave portion of the front wall FW ( F2) and the second convex portion R1 of the rear wall RW are formed in complementary shapes that can be fitted into each other at the same row position, making the battery pack 1 of the same structure as one unit. In such a way that a plurality of battery packs 1 are connected to each other, it is possible to provide modules (100, see FIGS. 5 and 6) with various outputs and capacities, and the battery included in the module 100 This means that by increasing or decreasing the number of packs 1, it is possible to adaptively respond to various outputs and capacities using the battery pack 1 having the same structure, and to provide scalability of the battery pack 1. can

In one embodiment of the present invention, unlike the front wall (FW) and the rear wall (RW), the first and second side walls (SW1, SW2) may be formed flat, and the transverse direction (Z2) In the module 100 expanded to include a plurality of battery packs 1 along the horizontal direction Z2, the first and second sidewalls SW1 and SW2 of the battery packs 1 disposed adjacent to each other A module 100 extending to include a plurality of battery packs 1 along the lateral direction Z2 while contacting each other through outer surfaces formed flat to each other may be provided.

Referring to FIGS. 5 and 6 , in a module 100 expanded to include a plurality of battery packs 1 , adjacent battery packs 1 may be matched to each other. Here, matching the battery packs 1 adjacent to each other may include matching the front wall FW of one battery pack 1 and the rear wall RW of another battery pack 1 adjacent to each other. A first convex portion F1 formed on the front wall FW of one battery pack 1 and a second concave portion F2 formed on the rear wall RW of another battery pack 1 adjacent thereto. The structure of the front wall FW of one battery pack 1 and the structure of the rear wall RW of another battery pack 1 adjacent to each other so as to fit into the concave portion R2 and the second convex portion R1. It may mean that the structures are formed complementary to each other. In addition, in the module 100 in which the battery pack 1 having the same structure is expanded to include a plurality of battery packs 1 as a unit, in order to form adjacent battery packs 1, the same battery pack ( The front wall FW and the rear wall RW of 1) may have complementary shapes, and in the same battery pack 1, the front wall FW and the rear wall RW at the same column position are complementary to each other. It may include a first convex portion F1 and a second concave portion R2 of a shape, or may include a first concave portion F2 and a second convex portion R1 of complementary shapes.

For example, in order to provide scalability of the battery pack 1 by using the battery pack 1 having the same structure, the battery packs 1 adjacent to each other may be arranged in the same orientation, and thus, each other The rear wall RW of the battery pack 1 in the front position and the front wall FW of the battery pack 1 in the rear position formed in complementary shapes that can be fitted to each other may be molded to each other.

Referring to FIG. 4 , the plurality of battery cells 10 may be electrically connected to each other through bus bars B. More specifically, the bus bar (B) is connected to each other by connecting different battery cells 10 in parallel by connecting the same polarities of different battery cells 10 or by connecting different polarities of different battery cells 10 to each other. Other battery cells 10 may be connected in series. The battery cell 10 may include first and second electrodes 11 and 12 having different polarities, and in one embodiment of the present invention, the first and second electrodes 11 and 12 are It may be formed on the upper end of the battery cell 10 along the height direction Z3 crossing the direction Z1 and the lateral direction Z2. At this time, the first electrode 11 may be formed at a central position among the upper ends of the battery cell 10, and the second electrode 12 may be formed at a central position among the upper ends of the battery cell 10. ) may be formed at an edge position surrounding. In addition, the second electrode 12 may extend from an edge position of the upper end of the battery cell 10 to a lower end along the height direction Z3, forming a side surface between the upper end and the lower end of the battery cell 10. , may be formed over the entire lower end of the battery cell 10.

In one embodiment of the present invention, the bus bar B may connect a group of battery cells 10g including a plurality of battery cells 10 adjacent to each other in parallel, and a group of different neighboring battery cells ( 10g), it is possible to connect a plurality of battery cells 10 in series and parallel. In various embodiments of the present invention, the number of battery cells 10 forming a group of battery cells 10g connected in parallel or the number of groups of battery cells 10g connected in series with each other may vary according to the required output and capacity. Correspondingly, it can be adaptively designed.

In one embodiment of the present invention, a group of battery cells 10g connected in parallel may be arranged along a column direction Z1, and a group of different battery cells 10g adjacent to each other along the column direction Z1 may be arranged in series. The body portion B1 of the bus bar B may be extended between the group of battery cells 10g adjacent to each other along the column direction Z1. More specifically, the bus bar B includes a body portion B1 extending between a group of battery cells 10g adjacent to each other along a column direction Z1, and a body portion extending from the body portion B1 to the body portion. It may include first and second branch portions Ba and Bb extending toward the group of battery cells 10g adjacent to each other with B1 as a boundary. The main body portion B1 of the bus bar B may be arranged in a zigzag form between a group of battery cells 10g adjacent to each other along the column direction Z1, and extends along the transverse direction Z2 It can be. A group of battery cells 10g connected in parallel to each other includes a side of the battery cells 10 arranged on a zigzag line, and a bus bar B extending along the boundary of the group of battery cells 10g connected in parallel to each other The body portion B1 of ) may extend along the zigzag line along the sides of the battery cells 10 arranged on the zigzag line.

The body portion B1 of the bus bar B may electrically connect the first and second branch portions Ba and Bb extending from the body portion B1 to each other. For example, the first and second branch portions Ba and Bb may include a group of different battery cells 10g disposed on both sides of the body portion B1 along the column direction Z1 from the body portion B1. may be extended towards In one embodiment of the present invention, the first and second branch portions Ba and Bb may extend along the column direction Z1, and the battery cells arranged in a straight line along the column direction Z1 ( 10) may extend on a straight line along the interstices. For example, the first and second branch portions Ba and Bb may extend along opposite column directions Z1 from the body portion B1 of the bus bar B, and in the transverse direction Z2 It may be alternately formed at positions alternating with each other along. For example, the first and second branch portions Ba and Bb are columns of battery cells 10 adjacent to each other along a main body portion B1 extending along a zigzag line along the transverse direction Z2. It may extend between the rows of the battery cells 10 at alternate positions along the lateral direction Z2 .

In one embodiment of the present invention, a group of battery cells 10g connected in parallel may be arranged along a column direction Z1, and a bus is connected between a group of battery cells 10g adjacent to each other along the column direction Z1. A body portion B1 of the bar B may be disposed. That is, the body parts B1 of the bus bars B may be arranged along the column direction Z1, and a group of battery cells 10g disposed between the body parts B1 of the bus bars B adjacent to each other. ), the first and second branch portions Ba and Bb extending from the main body portion B1 of the bus bar B adjacent to each other toward each other may be disposed to be fitted into each other in a comb shape. In one embodiment of the present invention, the first and second branch parts Ba and Bb extending from the body part B1 of the bus bar B adjacent to each other can be fitted into each other without physical interference. To this end, the first and second branch portions Ba and Bb extend along the zigzag line along the transverse direction Z2 from the body portion B1 of the bus bar B to the transverse direction Z2 It can be extended at positions alternating with each other along.

In one embodiment of the present invention, the electrical connection of the plurality of battery cells 10 may be implemented in a mixture of series and parallel, including parallel connection and series connection of the battery cells 10 . For example, in one embodiment of the present invention, a plurality of battery cells 10g through a series connection between a group of battery cells 10g parallel to each other and another group of battery cells 10g connected in parallel among the plurality of battery cells 10 It is possible to implement a series-parallel mixed electrical connection including parallel and series with respect to the battery cell 10 .

More specifically, the plurality of bus bars B disposed on top of the battery cells 10 are disposed adjacent to each other while connecting in parallel a group of battery cells 10g disposed adjacent to each other. One group of battery cells 10g and another group of battery cells 10g may be connected in series. In one embodiment of the present invention, the arrangement of the plurality of battery cells 10 arranged along the column direction Z1 and the transverse direction Z2 includes a plurality of rows of batteries arranged on a straight line along the column direction Z1 It may include the cell 10 and a plurality of horizontal battery cells 10 arranged in a zigzag line along the horizontal direction Z2 . At this time, the bus bar (B) may connect the battery cells 10 of the adjacent two sides arranged on a zigzag line in parallel, for example, the battery cells 10 of the two sides adjacent to each other may be connected in parallel. By connecting, a group of battery cells 10g including two adjacent battery cells 10 may be connected in parallel. In addition, the bus bar (B) forms a group of battery cells 10g connected in parallel with each other by connecting the battery cells 10 of the two sides adjacent to each other in parallel, and also the battery cells of the adjacent two sides connected in parallel. A plurality of battery cells arranged along the column direction Z1 and the transverse direction Z2 by serially connecting different groups of battery cells 10g adjacent to each other along the column direction Z1 with (10) as a unit (10) can be electrically connected in a mixed way of series and parallel. For example, in one embodiment of the present invention, when it is assumed that two adjacent battery cells 10 connected in parallel to each other form a group of battery cells 10g connected in parallel to each other, as a whole, the column direction Z1 Accordingly, a group of six different battery cells 10g may be formed. At this time, a group of battery cells 10g connected in parallel with each other and another group of battery cells 10g adjacent along the column direction Z1 are adjacent to each other with the body portion B1 of the bus bar B interposed therebetween. In total, six groups of battery cells 10g, that is, a group of battery cells 10g connected in parallel with each other, with the main body portion B1 of the five bus bars B interposed therebetween It can contain 6 units. More specifically, in one embodiment of the present invention, a group of battery cells 10g connected in parallel with each other includes two horizontal battery cells 10 adjacent to each other, and the horizontals of each battery cell 10 are zigzag Since nine battery cells 10 are arranged in a line, a group of battery cells 10g connected in parallel with each other may include a total of 18 battery cells 10 . In one embodiment of the present invention, 18 battery cells 10 connected in parallel with each other are set as a group of battery cells 10g, and a total of 6 groups of battery cells 10g are connected in series along the column direction Z1, By making 18 battery cells 10 each other as one unit, a structure in which 6 units are connected in series, that is, an electrical connection of 6S18P may be formed. And, in the electrical connection of the 6S18P according to an embodiment of the present invention, a group of battery cells 10g including 18 battery cells 10 forming a parallel connection with each other connects the battery cells 10 in two directions. It may include, the side of each battery cell 10 may include nine battery cells (10). In one embodiment of the present invention, according to the number and arrangement of a group of battery cells 10g connected in parallel with each other, the battery pack 1 has four protruding walls (first convex) protruding along the column direction Z1. Corresponding to part F1 or second convex part R1) may be included. In one embodiment of the present invention, the protruding wall (corresponding to the first convex portion F1 or the second convex portion R1) is at least one of the front wall FW and the rear wall RW along the column direction Z1. For example, in one embodiment of the present invention, the four protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) may be formed on the rear wall RW. Throughout the present specification, when it is assumed that the front wall FW or the rear wall RW includes four protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) along the column direction Z1, the The number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) is the total number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) formed on the front wall FW or the rear wall RW. Corresponding) means the number of protruding walls (corresponding to the first convex portion F1) protruding from the front wall FW toward the outside, that is, toward the front, or the rear wall RW toward the outside, That is, it may mean the number of protruding walls (corresponding to the second convex portion R1) protruding toward the rear. In one embodiment of the present invention, when the rear wall RW includes four protruding walls (corresponding to the second convex portion R1), the four protruding walls (corresponding to the second convex portion R1) are, It means the total number of protruding walls (corresponding to the second convex portion R1) formed on the rear wall RW, for example, the protruding walls protruding from the rear wall RW toward the outside, that is, toward the rear ( This means that the number of protruding walls (corresponding to the second convex portion R1) is four, and the rear wall RW includes fewer than four protruding walls (corresponding to the second convex portion R1) or the rear wall It can be excluded that (RW) includes more than four protruding walls (corresponding to the second convex portion R1).

In various embodiments of the present invention, the total number of battery cells 10 forming the battery pack 1, the number of parallel and series connections, etc. vary according to the output and capacity required for the battery pack 1. can be transformed More generally, when the battery pack 1 of the present invention includes a plurality of battery cells 10 forming an mSnP electrical connection, a group of battery cells 10g forming a parallel connection to each other is n The battery cell 10 may be included, and the entire battery pack 1 may form a structure in which m units are connected in series by using n battery cells 10 connected in parallel with each other as one unit. At this time, when the n number of battery cells 10 are referred to as a group of battery cells 10g forming parallel connections with each other, the group of battery cells 10g including n number of battery cells 10 are arranged horizontally by L number It may be, and the side of each battery cell 10 may include K battery cells 10. At this time, the number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) protruding outward from the front wall FW or the rear wall RW along the column direction Z1 is an even number. Or it may be determined according to whether it corresponds to an odd number, and the front wall (FW) or the rear wall (RW), or more generally, the protruding wall protruding outward from the wall of the cell holder (W) (first convex portion F1 or second convex portion F1) The number of 2 convex portions (corresponding to R1) can be determined from the following relationship.

i) When K is an even number, the number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) is K/2

ii) When K is an odd number, the number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) is (K-1)/2

In one embodiment of the present invention, the plurality of battery cells 10 may include a plurality of battery cells 10 arranged along the column direction Z1, and the battery cells 10 in adjacent columns are It may be arranged alternately with each other in a front position or a rear position along the direction Z1. At this time, the battery cells 10 protruding to the front position or rear position along the column direction Z1 are battery cells 10 It is possible to form a protruding wall (corresponding to the first convex portion F1 or the second convex portion R1) protruding from the cell holder W accommodating to the front or rear position. At this time, according to the number of battery cells 10 forming the side of the battery cell 10, when the number K of the battery cells 10 forming the side of the battery cell 10 is an even number, the column direction The number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) is determined by K/2 according to the arrangement of the battery cells 10 alternately arranged in a front position or a rear position along Z1. For example, the same K/2 number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) may be formed on the front wall FW and the rear wall RW. In contrast, when the number K of the battery cells 10 forming the side of the battery cell 10 is an odd number, the battery cells 10 alternately arranged in a front position or a rear position along the column direction Z1 ) Depending on the arrangement of the protruding walls (corresponding to the first convex portion F1 or the second convex portion R1), the number of protruding walls may be determined as (K-1)/2, for example, the front wall (FW) or the rear wall (K−1)/2 number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) may be formed in (RW). In other words, when the battery pack 1 according to an embodiment of the present invention forms an electrical connection of mSnP, a group of battery cells 10g including n battery cells 10 connected in parallel with each other is one As a unit of , m units arranged adjacent to each other along the column direction Z1 may be serially connected to each other while a total of m units are arranged along the column direction Z1. In addition, a group of battery cells 10g including n battery cells 10 connected in parallel with each other are arranged in L sides, and each side of the battery cells 10 includes K battery cells 10 At this time, a protruding wall protruding outward from the wall of the cell holder W (first convex portion F1 or second corresponding to the convex portion R1) may be determined. In one embodiment of the present invention, the front wall (FW) and the rear wall (RW) along the column direction (Z1) according to the number (K) of the battery cells 10 included in each side of the battery cell (10) All the same K/2 number of protruding walls (corresponding to the first convex portion F1 or the second convex portion R1) are formed, or (K-1)/2 number of protruding walls are formed on the front wall (FW) or rear wall (RW). A protruding wall (corresponding to the first convex portion F1 or the second convex portion R1) may be formed.

In one embodiment of the present invention, the body parts B1 of the bus bar B may be arranged along the column direction Z1, and each body part B1 is zigzag along the transverse direction Z2. may extend over the line. As will be described later, the frontmost body portion B1 and the rearmost body portion B1 along the column direction Z1 may be formed to match the front wall FW and the rear wall RW, respectively.

More specifically, the frontmost body portion B1 and the front wall FW include a first convex portion F1 formed to protrude forward in response to the battery cells 10 in a row that are biased toward the front position; It may include a first concave portion F2 drawn from the front corresponding to the battery cells 10 in adjacent rows that are biased toward the rear position. As such, the first convex portion F1 and the first concave portion ( F2) may extend in a zigzag shape (first zigzag shape) along the horizontal direction Z2 while being alternately disposed with each other along the horizontal direction Z2. Similarly, the rearmost main body portion B1 and the rear wall RW include second convex portions R1 formed to protrude rearward in correspondence with the row of battery cells 10 that are biased toward the rearward position, and the front It may include second concave portions R2 drawn from the rear in correspondence with the battery cells 10 in adjacent rows that are skewedly disposed. As such, the second convex portion R1 and the second concave portion R2 may be included. ) may extend in a zigzag shape (second zigzag shape) along the transverse direction Z2 while being alternately disposed with each other along the transverse direction Z2.

The zigzag shape (first zigzag shape) of the frontmost body portion B1 and the front wall FW and the zigzag shape (second zigzag shape) of the rearmost body portion B1 and the rear wall RW are formed complementary to each other, so that the frontmost body part B1 and the rearmost body part B1 can form a complementary shape to each other, and the front wall FW and the rear wall RW also have a complementary shape to each other. can achieve As will be described later, the complementary shape between the frontmost body part B1 and the rearmost body part B1 depends on any one body part B1 among the frontmost body part B1 and the rearmost body part B1. Electrical connection between battery packs 1 adjacent to each other in the module 100 extended along the column direction Z1 can be made possible by electrically connecting them to each other through the formed first extension piece E1. have. In addition, the complementary shape between the front wall (FW) and the rear wall (RW) is between the battery packs 1 adjacent to each other in the module 100 extending along the column direction Z1 through fitting to each other. A physical connection can be made possible.

In one embodiment of the present invention, the first branch portion Ba includes a group of battery cells 10g disposed on one side and a group disposed on the other side around the body portion B1 of the bus bar B. Among the battery cells 10g of , while extending toward the group of battery cells 10g disposed on one side, a group of battery cells 10g disposed on one side may be connected in parallel, and the second branch ( Bb) extends toward the group of battery cells 10g disposed on the other side centered on the body portion B1 of the bus bar B, and connects the group of battery cells 10g disposed on the other side in parallel. can At this time, the body part B1 of the bus bar B connects the first and second branch parts Ba and Bb to each other, and a group of batteries disposed on one side connected to the first branch part Ba. A group of battery cells 10g disposed on the other side connected to the cell 10g and the second branch Bb may be serially connected to each other.

In one embodiment of the present invention, the first branch portion (Ba) connects a group of battery cells (10g) disposed on one side of the body portion (B1) of the bus bar (B) in parallel, or Two branch parts (Bb) connect a group of battery cells (10g) arranged on the other side of the main body part (B1) of the bus bar (B) in parallel, or the first and second branch parts (Ba, Bb) The body part B1 connecting the group of battery cells 10g disposed on one side and the group of battery cells 10g disposed on the other side in series is connected to each other in parallel by the bus bar B itself. Rather than forming a connection or series connection, it may mean that the battery cells 10 are connected in parallel or in series through a connecting member 50 (see FIG. 16) connected to the bus bar B.

In one embodiment of the present invention, a connecting member 50 (see FIG. 16 ) may be interposed between the bus bar B and the battery cell 10 to mediate the connection between them. In one embodiment of the present invention, the connection member 50 (see FIG. 16) may include a conductive wire or a conductive ribbon, and these connection members 50 (see FIG. 16) are wire bonded or ribbon bonded to the bus bar. It may be connected between (B) and the battery cell 10 . More specifically, the connecting member 50 (see FIG. 16) may be connected between the bus bar B and the electrodes 11 and 12 of the battery cell 10 to form a connection between them. At this time, Regarding series connection or parallel connection, the connection member 50 (see FIG. 16 ) connects the same electrodes 11 and 12 of different battery cells 10 to each other to connect different battery cells 10 in parallel. The different battery cells 10 may be connected in series by connecting the different electrodes 11 and 12 of the different battery cells 10 to each other. Referring to FIG. 4, the connection member 50 (see FIG. 16) controls the same polarity of a group of battery cells 10g disposed on one side with the body portion B1 of the bus bar B as the center. By connecting to one branch part Ba, a group of battery cells 10g disposed on one side can be connected in parallel, and similarly, centered on the body part B1 of the bus bar B, it is disposed on the other side. A group of battery cells 10g disposed on the other side may be connected in parallel by connecting the same polarities of the group of battery cells 10g to the second branch Bb.

The bus bar (B) is disposed in an accommodation space in which a plurality of battery cells 10 are accommodated to connect the plurality of battery cells 10 to each other, and extends from the bus bar (B) outside the accommodation space. The extension pieces E1 and E2 may be disposed. The expansion pieces E1 and E2 may form electrical connections between adjacent battery packs 1 in the module 100 expanded to include a plurality of battery packs 1 . More specifically, the extension pieces E1 and E2 may extend from the bus bar B along the column direction Z1 and the transverse direction Z2, and receive from the receiving space where the bus bar B is disposed. It can be disposed outside the space, and in one embodiment of the present invention, it can protrude out of the cell holder (W) surrounding the accommodation space.

The extension pieces E1 and E2 include a first extension piece E1 extending from the bus bar B in the column direction Z1 and a second extension piece E1 extending from the bus bar B in the transverse direction Z2. An extended piece (E2) may be included. The first and second extension pieces E1 and E2 extend from the bus bar B in the column direction Z1 and the transverse direction Z2, extending in the column direction Z1 and the transverse direction Z2. Can provide, more specifically, the module 100 extended in the column direction (Z1) and the transverse direction (Z2) to include a plurality of battery packs (1) along the column direction (Z1) and the transverse direction (Z2) ) can be provided. That is, in the module 100 extending along the column direction Z1 and the transverse direction Z2, the first extension piece E1 connects adjacent battery packs 1 along the column direction Z1 and the second extension piece E2 can connect neighboring battery packs 1 along the transverse direction Z2.

The first and second extension pieces E1 and E2 may extend from the bus bar B disposed in the accommodating space in which the plurality of battery cells 10 are accommodated to the outside of the accommodating space, for example, It may protrude from the cell holder W surrounding the accommodation space. 5 and 6, in the module 100 expanded to include a plurality of battery packs 1, a first protruding from one of the battery packs 1 between neighboring battery packs 1, The first and second extension pieces E1 and E2 of another battery pack 1 adjacent to each other and the bus bar B while the second extension pieces E1 and E2 are accommodated by another battery pack 1 adjacent to each other. may be connected to each other, and the module 100 having expanded output and capacity may be provided through connection of neighboring battery packs 1 .

The first and second extension pieces E1 and E2 may extend from the bus bar B, and may extend from the bus bar B along different column directions Z1 and transverse directions Z2. . Regarding the first extension piece E1, in the module 100 extended along the column direction Z1, battery packs 1 adjacent to each other along the column direction Z1 are a group of battery cells connected in parallel ( 10g) as one unit, it is possible to provide a module 100 in which the number of units of a group of battery cells 10g connected in series to each other is extended along the column direction Z1, and the first extension piece E1 ) may connect battery packs 1 adjacent to each other along the column direction Z1 while extending along the column direction Z1, for example, battery packs adjacent to each other along the column direction Z1 ( The expanded module 100 can be provided by connecting the bus bars B connected to the group of battery cells 10g forming the boundary of 1) to each other. Regarding the second extension piece E2, in the module 100 extended along the transverse direction Z2, the battery packs 1 adjacent to each other along the transverse direction Z2 are Columns of battery cells 10 may be expanded, and the second expansion piece E2 is formed between columns of battery cells 10 forming a boundary between battery packs 1 adjacent to each other along the transverse direction Z2. Can be connected, for example, by connecting the bus bars (B) connected to the columns of the battery cells 10 forming the boundary of the battery packs 1 adjacent to each other along the transverse direction (Z2). Rows of battery cells 10 extending along the transverse direction Z2 may be connected in parallel.

The first extension piece E1 is a serial connection between a group of battery cells 10g adjacent to each other along the column direction Z1 in one battery pack 1, and a plurality of cells arranged along the column direction Z1. It can be extended to the module 100 including the battery pack 1, and the second extension piece E2 is the battery cell 10 adjacent to each other along the transverse direction Z2 in one battery pack 1 Parallel connection between rows may be extended to a module 100 including a plurality of battery packs 1 arranged along the transverse direction Z2.

The first and second extension pieces E1 and E2 extend along the column direction Z1 and the transverse direction Z2 from the bus bar B disposed in the accommodation space in which the plurality of battery cells 10 are accommodated. For example, they may extend from different locations of the bus bar (B). In one embodiment of the present invention, the first extension piece E1 may extend from the outermost bus bar B along the column direction Z1, and, for example, the frontmost main body portion B1 And it may extend from any one of the rearmost main body parts B1. In one embodiment of the present invention, the first extension piece E1 may extend along the column direction Z1 from the frontmost body portion B1. For example, the frontmost body portion B1 and the front wall FW may extend in a zigzag shape matching each other, and the first convex portion F1 protruding forward along the transverse direction Z2 and the front It may include a first concave portion F2 drawn in from, and along the transverse direction Z2, the first convex portion F1 and the first concave portion F2 may be alternately formed at alternate positions. At this time, the first extension piece E1 may be formed at the position of the first concave part F2 in the frontmost main body part B1, and a plurality formed at the position of the first concave part F2 along the transverse direction Z2. It may include a first extension piece (E1) of. Referring to FIG. 5 , in the module 100 extending along the column direction Z1, the front wall FW, the first concave portion F2 and the rear wall RW, the second convex portion R1 are fitted to each other while the front wall FW and the second convex portion R1 are fitted to each other. Body portion B1 of bus bar B, in which the first extension piece E1 formed at the location of the first concave portion F2 of the wall FW is formed at the location of the second convex portion R1 of the front wall FW In contact with the battery packs 1 adjacent to each other along the column direction Z1 may be connected to each other. For example, the first extension piece E1 is formed by the rear bus bar B of the front battery pack 1 and the rear battery pack 1 in the front and rear battery packs 1 adjacent to each other along the column direction Z1. ), it is possible to electrically connect the front and rear battery packs 1 by connecting the front bus bars B to each other.

In one embodiment of the present invention, among the front wall (FW) and the rear wall (RW), the front wall (FW) on which the first expansion piece (E1) is formed is a first expansion edge (FW, corresponding to the front wall). and the rear wall RW on which the first extension piece E1 is not formed may be defined as a first accommodating edge RW (corresponding to the rear wall). Through the present specification, the expansion edge is an agent capable of connecting adjacent battery packs 1 along the column direction (Z1) and the transverse direction (Z2) so as to be expandable along the column direction (Z1) or the transverse direction (Z2) A wall adjacent to a location where the first extension piece E1 or the second extension piece E2 is formed or a location where the first and second extension pieces E1 and E2 are formed may be defined. In one embodiment of the present invention, the first expansion edge (FW, corresponding to the front wall) and the first accommodating edge (RW, corresponding to the rear wall) are front walls formed at positions facing each other along the column direction Z1. (FW) and the rear wall (RW). As will be described later, in relation to the second extension piece E2, the first sidewall SW1 on which the second extension piece E2 is formed is defined as the second extension edge SW1 (corresponding to the first sidewall body). and the second sidewall SW2 on which the second expansion piece E2 is not formed may be defined as a second accommodating edge SW2 (corresponding to the second sidewall body), and the second expansion edge ( SW1, corresponding to the first side wall body) and the second accommodating edge (SW2, corresponding to the second side wall body) are the first and second side walls SW1 and SW2 formed at positions facing each other along the transverse direction Z2 can mean

In one embodiment of the present invention, the second extension piece E2 may extend from the outermost position of the bus bar B along the transverse direction Z2, and the first sidewall along the transverse direction Z2 It may extend from the outermost position of the bus bar B adjacent to any one of the sidewalls SW1 and SW2. In one embodiment of the present invention, the second extension piece E2 may extend from an outermost position of the bus bar B adjacent to the first side wall SW1. The second extension piece E2 may extend along the transverse direction Z2 from the plurality of bus bars B arranged along the column direction Z1. In one embodiment of the present invention, the second extension piece E2 may extend from the body portion B1 of the plurality of bus bars B arranged along the column direction Z1. The main body portion B1 of the bus bar B may extend in a zigzag shape along the transverse direction Z2, and the second extension piece E2 may form a first sidewall body along the transverse direction Z2 ( It may extend on a straight line at the outermost position of the body portion B1 adjacent to SW1). Referring to FIG. 5, in the module 100 extending along the transverse direction Z2, the first sidewall SW1 and the second sidewall SW2 are butted with each other and formed adjacent to the first sidewall SW1. The battery packs 1 adjacent to each other along the transverse direction Z2 while the second extension piece E2 comes into contact with the body portion B1 of the bus bar B formed adjacent to the second side wall SW2 can be connected to each other.

In one embodiment of the present invention, the first sidewall body (SW1) formed with the second expansion piece (E2) among the first sidewall body (SW1) and the second sidewall body (SW2) has a second expansion edge (SW1, corresponding to the first sidewall body), and the second sidewall body SW2 on which the second extension piece E2 is not formed may be defined as the second accommodating edge SW2 (corresponding to the second sidewall body). can In other words, the second expansion edge (SW1, corresponding to the first side wall) and the second accommodating edge (SW2, corresponding to the second side wall) are formed at positions facing each other along the transverse direction (Z2). It may refer to the second sidewalls SW1 and SW2.

FIG. 7 is an exploded perspective view of a battery pack according to an embodiment of the present invention, and a diagram for explaining assembly of a thermistor is shown. FIG. 8 is an enlarged perspective view of a part of the upper holder shown in FIG. 7 . 9 is a perspective view showing a state in which the cover of FIG. 7 is assembled on the upper holder of FIG. 8 . 10 is a plan view for explaining the arrangement of thermistors in a module in which the battery pack according to the present invention is extended along a column direction. 11 is a plan view for explaining the arrangement of the thermistors in a module in which the battery pack according to the present invention is extended along the column and lateral directions.

Hereinafter, a disposition structure of the thermistor TH for detecting the temperature of the battery cell 10 according to an embodiment of the present invention will be described with reference to FIGS. 7 to 111 . In one embodiment of the present invention, the cell holder (W) may include a hollow protrusion (H) protruding along the height direction (Z3) intersecting the column direction (Z1) and the transverse direction (Z2), the An exposure hole C′ for exposing the hollow protrusion H may be formed in the cover C disposed on the cell holder W. Also, the thermistor TH for detecting the temperature of the battery cell 10 may be accommodated in the hollow protrusion H through the exposure hole C′.

The hollow protrusion H has an empty interior to accommodate the thermistor TH, protrudes along the height direction Z3, and extends the hollow protrusion H from the cell holder W along the height direction Z3. A thermistor (TH) may be accommodated into the inside. For example, the hollow protrusion (H) may include a sidewall formed along an annular shape to surround a central hollow in which the thermistor (TH) is accommodated, and in various embodiments of the present invention, the hollow protrusion (H), In addition to the annular shape, it may be formed in any shape surrounding the central hollow portion in which the thermistor TH is accommodated.

The hollow protrusion H may accommodate a thermistor TH for detecting the temperature of the battery cell 10 through a central hollow portion, and the position of the hollow protrusion H is accommodated in the hollow protrusion H. It may correspond to the position of the thermistor (TH) or the temperature detection position (A) where the temperature of the battery cell 10 is detected using the thermistor (TH). Throughout the present specification, the position of the hollow protrusion (H), the position of the thermistor (TH), and the temperature detection position (A) may all correspond to substantially the same position, and the column direction (Z1) and the transverse direction (Z2) The position of the hollow protrusion (H) on the plane to be formed, the position of the thermistor (TH) disposed in the hollow protrusion (H), and the temperature of the battery cell 10 is detected using the thermistor (TH) of the battery cell 10 It may mean a temperature detection location (A). Hereinafter, the temperature detection position A on the plane of the cell holder W will be described in more detail. Throughout the present specification, the plane of the cell holder (W) may mean the plane of the cell holder (W) formed in the column direction (Z1) and the transverse direction (Z2), and the temperature detection position (A) is the cell holder ( can be defined on the plane of W).

In one embodiment of the present invention, the temperature detection position (A) is a first temperature detection position (A1) formed at a central position on the plane of the cell holder (W) and a second temperature detection position adjacent to a corner position rather than the central position. location A2. In one embodiment of the present invention, the second temperature detection position A2 is adjacent to a corner position, but the front wall FW, the rear wall RW, or the first and second side walls forming the corner position It may correspond to a position spaced apart from (SW1, SW2). In other words, the cell holder W includes one of a front wall FW and a rear wall RW extending along the column direction Z1 and first and second walls extending along the transverse direction Z2. Any one of the two sidewalls (SW1, SW2) may include four corner positions formed while abutting each other, and the second temperature detection position (A2) is a total number disposed adjacent to each corner position. Four second temperature detection locations A2 may be included.

In one embodiment of the present invention, the central position may be comprehensively defined including a position including a center and a position adjacent to the center along the column direction Z1 and the transverse direction Z2 on the plane of the cell holder W. . The cell holder W includes front walls FW and rear walls RW facing each other along the column direction Z1 and first and second side walls SW1 and SW2 facing each other along the transverse direction Z2. ), wherein the corner position is a corner formed while the front wall (FW), the rear wall (RW), and the first and second side walls (SW1, SW2) extending in different directions come into contact with each other. And it can be comprehensively defined, including a position adjacent to a corner.

In one embodiment of the present invention, the temperature of the battery cell 10 disposed in the central position of the cell holder W can be detected from the first temperature detection position A1, and the cell temperature can be detected from the second temperature detection position A2. The temperature of the battery cell 10 disposed adjacent to the corner position of the holder W may be detected. In one embodiment of the present invention, the temperature detection position A includes one first temperature detection position A1 formed at a central position and four second temperature detection positions A2 formed at four corner positions. and may include a total of 5 temperature detection locations (A). In one embodiment of the present invention, the temperature information of the center position and corner position of the cell holder W or four positions adjacent to the corner position of the cell holder W can be grasped from a total of five first and second temperature detection positions A1 and A2, From the first and second temperature detection positions A1 and A2, the overall temperature distribution on the plane of the cell holder W can be grasped. As will be described later, in the module 100 extended to include the battery pack 1 or a plurality of battery packs 1, the central position is farther from the battery pack 1 or the outside of the module 100 than the corner position. Since it corresponds to the location, it may be a relatively high temperature area, and accordingly, for monitoring the central location, which is a relatively high temperature area, the central location of the battery pack 1 or module 100 is included in the temperature detection location (A) may be preferred. In one embodiment of the present invention, the first temperature detection position A1 may correspond to a central position in the battery pack 1 or the module 100 extended to include a plurality of battery packs 1 . For example, the first temperature detection position A1 corresponds to a central position in the battery pack 1, and referring to FIG. 10, in the module 100 extending along the column direction Z1, the first temperature detection position A1 The temperature detection location A1 may correspond to a central location along the horizontal direction Z2. In this way, the first temperature detection position A1 may correspond to the central position in the module 100 extended to include the battery pack 1 and a plurality of battery packs 1 along the column direction Z1. , When the module 100 extending along the column direction Z1 is formed by arranging a plurality of battery packs 1 including the first temperature detection position A1 along the column direction Z1, the module 100 Monitoring of the central position of the module 100 through the first temperature detection position A1 of the battery pack 1 without the need to select an additional temperature detection position A for monitoring the central position of this is possible

The second temperature detection position A2 is formed at a position adjacent to four corner positions, and in one battery pack 1 may correspond to a position adjacent to the corner position rather than a central position. Referring to FIG. 11, In the module 100 extending along the column direction Z1 and the transverse direction Z2, the second temperature detection location A2 may correspond to a central location of the module 100. That is, in the module 100 extended along the column direction Z1 and the transverse direction Z2, for example, two battery packs 1 adjacent to each other along the column direction Z1 and the transverse direction Z2 In the module 100 including a total of four battery packs 1 including two battery packs 1 adjacent to each other along It can be gathered adjacent to the central position of the expanded module 100, and in this way, the four second temperature detection positions A2 formed on each battery pack 1 are gathered together adjacent to the central position of the module 100. As a result, there is no need to select a separate temperature detection location (A) for monitoring the central position of the module 100 in the module 100 extended along the column direction (Z1) and the transverse direction (Z2), Temperature information about the central position of the module 100 can be grasped through the second temperature detection position A2 of each battery pack 1 gathered together adjacent to the central position of the module 100 .

In the module 100 extended along the column direction Z1 and the transverse direction Z2, for the second temperature detection position A2 gathered together adjacent to the central position of the module 100, one battery pack 1 ), the second temperature detection position A2 formed adjacent to the corner position at any second temperature detection position A2 according to the position of each battery pack 1 in the module 100 extended to include a plurality of battery packs 1 The temperature detection location A2 may also be disposed adjacent to the central location of the expanded module 100. That is, when a plurality of battery packs 1 having the same structure as one unit are arranged to face each other along the column direction Z1 and the transverse direction Z2, each battery pack According to the arrangement position of (1), a specific second temperature detection position A2 among the second temperature detection positions A2 formed in each battery pack 1 is disposed adjacent to the central position in the expanded module 100. can

In one embodiment of the present invention, the first expansion edge (FW, corresponding to the front wall) and the first receiving edge (RW, corresponding to the rear wall) may be disposed facing each other along the column direction Z1. In a specific embodiment of the invention, the first extension edge (FW, corresponding to the front wall) may correspond to the front wall (FW), and the first accommodating edge (RW, corresponding to the rear wall) may correspond to the rear wall (RW). may apply to In addition, in one embodiment of the present invention, the second expansion edge (SW1, corresponding to the first side wall) and the second accommodating edge (SW2, corresponding to the second side wall) are disposed to face each other along the transverse direction (Z2) In a specific embodiment of the present invention, the second expansion edge (SW1, corresponding to the first sidewall) may correspond to the first sidewall (SW1), and the second accommodating edge (SW2, corresponding to the second side wall) Corresponding to the wall) may correspond to the second side wall SW2. As such, in one embodiment of the present invention, in the module 100 extended along the column direction Z1 and the transverse direction Z2, the first expansion edge FW along the column direction Z1 corresponds to the front wall ) and the first accommodating edge (RW, corresponding to the rear wall) face each other, and the second expansion edge (SW1, corresponding to the first side wall) and the second accommodating edge (SW2, corresponding to the second side wall) face each other along the transverse direction Z2 Corresponding to the side walls) are disposed facing each other, the module 100 extending in the column direction (Z1) and the transverse direction (Z2) may be provided.

Referring to FIG. 7 , in one embodiment of the present invention, the second temperature detection location A2 formed in each battery cell 10 includes a second expansion edge SW1 facing each other along the transverse direction Z2. Corresponding to the first side wall body) and the second accommodating edge (SW2, corresponding to the second side wall body) may be disposed in asymmetrical positions, and in one embodiment of the present invention, four second temperature detection positions A2 ) is relatively toward the second accommodating edge (SW2, corresponding to the second sidewall) among the second expansion edge (SW1, corresponding to the first sidewall) and the second accommodating edge (SW2, corresponding to the second sidewall) It can be formed in a biased position. In one embodiment of the present invention, the second temperature detection position (A2) is any day between the second expansion edge (SW1, corresponding to the first sidewall body) and the second receiving edge (SW2, corresponding to the second sidewall body). side, for example, by being asymmetrically disposed at a position biased toward the second accommodating edge (SW2, corresponding to the second side wall), it is possible to provide more diverse monitoring of the temperature distribution of the battery pack 1. In one embodiment of the present invention, the temperature distribution of the entire battery pack 1 is more precisely monitored even through a limited number of temperature detection locations A, since the second temperature detection locations A2 are asymmetrically arranged. For example, it is possible to calculate or estimate the temperature distribution for the eight positions by symmetrically deploying the four second temperature detection positions A2 formed at asymmetric positions on the plane of the cell holder W. can

More specifically, in one embodiment of the present invention, the second temperature detection position A2 corresponds to the second expansion edge (SW1, corresponding to the first sidewall body) and the second receiving edge (SW2, corresponding to the second sidewall body) ), it may be formed at a position biased toward the second accommodating edge (SW2, corresponding to the second side wall) between them. That is, the second temperature detection position A2 includes the 2-1st temperature detection position A2-1 formed adjacent to the second extended edge SW1 (corresponding to the first sidewall) and the second accommodating edge SW2. , corresponding to the second sidewall body) may include a 2-2nd temperature detection location A2-2 formed adjacent to the second sidewall body. At this time, the first distance d1 between the second expansion edge SW1 (corresponding to the first sidewall body) and the 2-1st temperature detection position A2-1 is the second accommodating edge SW2 (corresponding to the second sidewall body). ) and the second distance d2 between the 2-2 temperature detection location A2-2. In one embodiment of the present invention, the 2-1st temperature detection position (A2-1) is two spaced apart from each other in the column direction (Z1) along the second extended edge (SW1, corresponding to the first sidewall). The 2-1st temperature detection position A2-1 may be included, and the 2-2nd temperature detection position A2-2 is in the column direction along the second accommodating edge SW2 (corresponding to the second sidewall). (Z1) may include two 2-2 temperature detection positions A2-2 spaced apart from each other.

Referring to FIG. 11 , in one embodiment of the present invention, the second temperature detection locations A2 formed at asymmetrical positions in each battery pack 1 extend along the column direction Z1 and the transverse direction Z2. The second temperature detection location A2 in the expanded module 100 may also be formed in an asymmetrical position. and the second accommodating edge (SW2, corresponding to the second side wall), and may be formed at an asymmetrical position, for example, four battery packs (1) each having four second temperature detection positions (A2) formed thereon. A total of 16 second temperature detection positions A2 in the module 100 including ) correspond to the second expansion edge SW1 forming the outer circumference of the module 100 along the transverse direction Z2, and the first sidewall. ) and the second accommodating edge (SW2, corresponding to the second side wall) may be disposed at a position biased toward the second accommodating edge (SW2, corresponding to the second side wall). Here, in the module 100 including four battery packs 1, a total of 16 second temperature detection locations A2 form the outer edge of the module 100 along the transverse direction Z2. (SW1, corresponding to the first side wall) and the second accommodating edge (SW2, corresponding to the second side wall) being disposed in a position biased towards the second accommodating edge (SW2, corresponding to the second side wall), Based on the center position of each battery pack 1, a total of 16 second temperature detection positions A2 form the periphery of the module 100, and the second receiving edge SW2 (corresponding to the second side wall) and It may mean that it is disposed at a position relatively biased toward the second accommodating edge (SW2, corresponding to the second sidewall) among the second expansion edges (SW1, corresponding to the first sidewall).

In one embodiment of the present invention, a more detailed temperature distribution can be obtained with respect to the central position or the vicinity of the central position of the extended module 100 from the second temperature detection position A2 formed at an asymmetrical position in each battery pack 1. can For example, in one embodiment of the present invention, the second temperature detection positions A2 formed in each battery pack 1 are formed at asymmetrical positions, so that different battery packs 1 in the expanded module 100 A total of four second temperature detection positions A2 formed in ) are too close to the central position of the module 100, resulting in substantially redundant temperature measurement, or disposed too far from the central position to measure the temperature at the central position. This can solve the problem of not being done. For example, in one embodiment of the present invention, the second expansion edge SW1 (corresponding to the first sidewall) and the second accommodating edge SW2 of the battery pack 1 adjacent to each other along the transverse direction Z2 When it is assumed that the extended module 100 is provided with the second side wall body) facing each other, the second accommodation facing the second expansion edge SW1 (corresponding to the first side wall body) of the opposite battery pack 1 The second temperature detection position A2 of the battery pack 1 having the edge (SW2, corresponding to the second side wall) can detect the temperature at a position closer to the central position of the module 100, and the opposite battery pack ( A second temperature detection position (A2) of the battery pack 1 having a second expansion edge (SW1, corresponding to the first sidewall) facing the second accommodating edge (SW2, corresponding to the second sidewall) of 1) The temperature may be detected at a location relatively far from the central location of the module 100.

In one embodiment of the present invention, the second temperature detection position (A2) relatively has a second receiving edge (SW2, corresponding to the second sidewall body) rather than a second expansion edge (SW1, corresponding to the first sidewall body). However, in various embodiments of the present invention, the second temperature detection location A2 is located at the second expansion edge SW1, rather than the second accommodating edge SW2, corresponding to the second sidewall body. 1 corresponding to the side wall), or the second temperature detection location A2 is the second expansion edge SW1 facing each other along the transverse direction Z2, corresponding to the first side wall ) and the second accommodating edge (SW2, corresponding to the second side wall) that is not formed in an asymmetrical position and faces each other along the column direction Z1. 1 It may be formed in an asymmetrical position between the receiving edges (RW, corresponding to the rear wall). Meanwhile, in various embodiments of the present invention, the second temperature detection positions A2 may be formed at symmetric positions on the plane of the cell holder W, for example, facing each other along the transverse direction Z2. It may be formed in a symmetrical position between the second expansion edge (SW1, corresponding to the first side wall) and the second accommodating edge (SW2, corresponding to the second side wall), and also along the column direction (Z1). It may be formed in a symmetrical position between the first expansion edge (FW, corresponding to the front wall) and the first accommodating edge (RW, corresponding to the rear wall) facing each other.

Referring to FIGS. 7 to 9 , in one embodiment of the present invention, a thermistor TH for measuring the temperature of the battery cell 10 may be disposed at the temperature detection location A. More specifically, the thermistor TH may be accommodated in a hollow protrusion H formed in the cell holder W, and may be accommodated in a hollow portion surrounded by the hollow protrusion H. The hollow protrusion H may protrude from the main body of the cell holder W along the height direction Z3, and the hollow protruding portion H and the guide piece G are formed on the main body of the cell holder W. can be formed. The guide piece (G) may protrude from the body of the cell holder (W) along the height direction (Z3) to fix the position of the bus bar (B), and the bus bar ( The assembly position of B) can be regulated. The position of the bus bar (B) can be regulated while the contours of the guide piece (G) of the cell holder (W) and the bus bar (B) physically interfere with each other, and the position of the bus bar (B) is determined by the cell. It may not flow on the plane of the holder (W). In one embodiment of the present invention, the hollow protrusions H protruding along the height direction Z3 from the main body of the cell holder W are also disposed on the cell holder W, similar to the guide piece G. It is possible to regulate the assembly position of the bus bar (B). For example, the assembly hole formed in the bus bar (B) is inserted into the hollow protrusion (H) formed on the cell holder (W), so that the bus bar ( The position of B) can be maintained more firmly. The hollow protrusion (H) and the guide piece (G) may form physical interference with the body portion (B1) of the bus bar (B). To this end, the hollow protrusion (H) and the guide piece (G) may be formed at a location where the body portion B1 of the bus bar B is disposed. In one embodiment of the present invention, the body portion B1 of the bus bar B may be disposed between a group of battery cells 10g adjacent to each other along the column direction Z1, and thus, the hollow The protruding portion H and the guide piece G may be formed at a position between a group of battery cells 10g adjacent to each other on a plane of the cell holder W.

In one embodiment of the present invention, since the position of the hollow protrusion (H) corresponds to the temperature detection position (A) where the thermistor (TH) is disposed, the temperature detection position (A) is mutually related along the column direction (Z1). It may be formed between a group of adjacent battery cells 10g, and more specifically, between two battery cells 10 adjacent to each other, that is, between four battery cells 10 adjacent to each other as a whole. can Since the hollow protrusion H is formed at the temperature detection position A between the battery cells 10 adjacent to each other, the thermistor TH accommodated in the hollow protrusion H is the temperature of a certain battery cell 10 It can be said that the temperature between neighboring battery cells 10 is measured rather than measuring .

Manufacturing of the battery pack 1 according to an embodiment of the present invention may be performed as follows. That is, the bus bar B and the connection member 50 (see FIG. 16) are disposed on the cell holder W to which the battery cell 10 is assembled, and the bus bar B and the connection member 50 (see FIG. 16) are placed. A potting resin (not shown) may be applied onto the cell holder W where ) is disposed. At this time, the potting resin (not shown) protects the connection member (50, see FIG. 16) disposed on the cell holder (W), and the bus bars (B) connected to each other through the connection member (50, see FIG. 16). And it is possible to protect the bonding portion of the connection member (50, see FIG. 16) formed on the upper end of the battery cell 10. At this time, the potting resin (not shown) is applied on the cell holder W on which the bus bar B and the connecting member 50 (see FIG. 16) are disposed, and the potting resin is applied in the height direction from the main body of the cell holder W ( A potting resin (not shown) may not be filled in the inside of the hollow protruding portion H protruding along Z3), that is, the hollow portion surrounded by the hollow protruding portion H. That is, the hollow protrusion H surrounds the hollow portion where the thermistor TH is disposed from the potting resin (not shown) applied on the cell holder W, thereby protecting the hollow portion where the thermistor TH is assembled. In addition, by excluding the potting resin (not shown) from the inside of the hollow part, assembly of the thermistor TH inserted into the hollow part can be prevented from being hindered.

As such, the cover C may be disposed on the cell holder W to which the potting resin (not shown) is applied, and the hollow protrusion of the cell holder W through the exposure hole C` of the cover C. H) may be exposed to the outside of the cover C, and the thermistor TH may be accommodated in the hollow protrusion H exposed to the outside of the cover C through the exposed hole C` of the cover C. can In other words, in the manufacture of the battery pack 1 according to an embodiment of the present invention, the assembly of the thermistor TH may be performed in the final step, and in the intermediate step for manufacturing the battery pack 1, the thermistor ( Assembling the thermistor (TH) through a simple process of assembling the thermistor (TH) to the hollow protrusion (H) exposed on the cover (C) in the final step without requiring separate consideration for assembly of the thermistor (TH) Since this is done, manufacturing of the battery pack 1 can be simplified, and the convenience of the manufacturing process can be improved.

Referring to FIG. 9 , the height of the hollow protrusion H may be designed to be substantially equal to or lower than the height formed by the outer surface of the cover C or lower than the height formed by the outer surface of the cover C. If the hollow protruding portion H protrudes from the outer surface of the cover C, the hollow protruding portion H protruding from the outer surface of the battery pack 1 is not protected from external impact, and the cover C is substantially removed. may not be able to function.

1 to 3 , in one embodiment of the present invention, the upper part of the battery cell 10 along the height direction Z3 may be assembled to the upper holder W1, and the lower part of the battery cell 10 may be assembled to the lower holder W2. At this time, the position fixing between the upper part of the battery cell 10 and the upper holder W1 may be made by bonding an adhesive (not shown), and the Position fixation between the lower part and the lower holder W2 may be achieved by an interference fit. In one embodiment of the present invention, the electrical connection between the upper end of the battery cell 10 (electrodes 11 and 12 formed on the upper end) and the bus bar B may be made through a connecting member 50 (see FIG. 16). And, since the connection member 50 (see FIG. 16) may be provided with a flexible member such as a conductive wire or a conductive ribbon, through solid position fixation through adhesion between the upper portion of the battery cell 10 and the upper holder W1. By suppressing rotation of the top or top end of the battery cell 10, damage to the connection member 50 (see FIG. 16) connected between the top end of the battery cell 10 and the bus bar B can be prevented. For example, a connecting member (50 (see FIG. 16) connecting the upper end of the battery cell 10 (electrodes 11 and 12 formed on the upper end) and the bus bar B connects them, one end of which is the battery cell 10 ) is bonded to the upper end (electrodes 11 and 12 formed on the upper end), and the other end is bonded to the bus bar (B), so that one end bonded to the upper end of the battery cell 10 and the other end bonded to the bus bar (B) Through this, it is possible to form an electrical connection between the upper end of the battery cell 10 and the bus bar (B). In one embodiment of the present invention, the connection member (50, see FIG. 16) may be provided with a conductive wire or a conductive ribbon, and the bonding of the connection member (50, see FIG. 16) is wire bonding or ribbon bonding. It can be done.

In one embodiment of the present invention, the upper and lower ends of the battery cell 10 along the height direction Z3 may be assembled in a state exposed to the outside from the respective upper holders W1 and lower holders W2, More specifically, with the upper end of the battery cell 10 exposed from the upper holder W1, the electrical connection between the electrodes 11 and 12 formed on the upper end of the battery cell 10 and the bus bar B is The battery cell 10 may be cooled through the lower end of the battery cell 10 while the lower end of the battery cell 10 is exposed from the lower holder W2. In other words, the upper end of the battery cell 10 exposed from the upper holder W1 may form an electrical connection with the bus bar B, and the lower end of the battery cell 10 exposed from the lower holder W2. may form thermal contact with the cooling plate 70 (see FIG. 1). Through this specification, the upper portion of the battery cell 10 is inserted into the upper holder W1 and the lower portion of the battery cell 10 is inserted into the lower holder W2 along the height direction Z3, for example, a battery The upper part of the battery cell 10 adjacent to the upper end of the cell 10 and the lower part of the battery cell 10 adjacent to the lower end of the battery cell 10 physically interfere with the upper holder W1 and the lower holder W2, respectively. While forming, it may mean that the upper and lower portions of the battery cell 10 are fixed. For example, the upper part of the battery cell 10 may mean a position between the upper end and the middle of the battery cell 10 along the height direction Z3, and the lower part of the battery cell 10 may mean the height It may refer to a position between the lower end and the middle of the battery cell 10 along the direction Z3.

In one embodiment of the present invention, assembly between the battery cell 10 and the cell holder W may be performed as follows. First, after applying an adhesive (not shown) on the upper portion of the battery cell 10, the upper portion of the battery cell 10 may be assembled by inserting it into the upper holder W1 while the upper holder W1 is placed upside down. Here, in a state where the upper holder W1 is turned over, the assembly by inserting the upper portion of the battery cell 10 into the upper holder W1 means that the battery cell 10 is assembled from the lower surface of the upper holder W1 toward the upper surface. It may mean that, the lower and upper surfaces of the upper holder (W1) are opposite to each other among the upper holder (W1), which means a surface opposite to the cover (C) and a surface facing the cover (C), respectively. can At this time, in a state in which an adhesive (not shown) is applied to the upper portion of the battery cell 10, the upper portion of the battery cell 10 to which the adhesive (not shown) is applied is inserted into the upper holder W1 to assemble the battery cell. Position fixation by an adhesive (not shown) between the upper portion of 10 and the upper holder W1 may be performed.

Then, the lower holder W2 may be assembled toward the battery cell 10 inserted into the upper holder W1. For example, the lower holder W2 may fix the lower portion of the battery cell 10 while forming an interference fit with the lower portion of the battery cell 10 . In one embodiment of the present invention, the lower holder (W2) can be assembled in a direction from the lower end toward the upper end of the battery cell 10, the battery cell 10 toward the lower holder (W2) through this specification Assembling may include that the lower holder W2 is assembled toward the battery cell 10, and the assembly direction between the lower holder W2 and the battery cell 10 is the same as the direction toward each other. In one embodiment of the present invention, assembly between the cell holder W and the battery cell 10 may be performed in a state where the cell holder W and the battery cell 10 are turned over, for example, the cell holder ( In a state where the upper holder W1 is turned over in W), the battery cell 10 having an adhesive (not shown) applied thereon is inserted and assembled, and the upper holder W1 and the battery cell 10 inserted into the upper holder W1 ) is inverted, the lower holder W2 may be fitted and assembled to the lower part of the battery cell 10 . The assembly between the cell holder W and the battery cell 10 throughout the present specification means that the cell holder W and the battery cell 10 are assembled in an inverted state, for example, as shown in FIG. In the orientation of the battery pack 1, assembly between the cell holder W and the battery cell 10 proceeds in a state where the upper and lower positions are reversed to each other along the height direction Z3. For example, a battery A bus bar (B) disposed at an upper position of the pack (1), an upper holder (W1) on which the bus bar (B) is supported, or an upper end of the battery cell (10) forming an electrical connection with the bus bar (B). may mean that assembly between the cell holder W and the battery cell 10 proceeds in a state where the cell holder W and the battery cell 10 are turned over so that they are placed in a relatively lower position.

Referring to FIGS. 1 to 3 , in one embodiment of the present invention, a plurality of battery cells 10 may be assembled to the cell holder W, and different upper and lower positions along the height direction Z3. It may include an upper holder (W1) and a lower holder (W2) disposed in the position. Through this specification, the upper holder W1 and the lower holder W2 are disposed at the upper and lower positions of the battery cell 10, respectively, at different levels along the height direction Z3 of the battery cell 10. It may mean that the upper holder W1 and the lower holder W2 are disposed, and the upper and lower positions of the battery cell 10 mean different levels along the height direction Z3 of the battery cell 10. This may mean, for example, a position relatively close to the bus bar B and a position relatively far from the bus bar B along the height direction Z3 of the battery cell 10 . Here, the height direction Z3 or the height direction Z3 of the battery cell 10 means a direction crossing the column direction Z1 and the transverse direction Z2, and in one embodiment of the present invention, the height The direction Z3 may mean a direction perpendicular to the column direction Z1 and the cross direction Z2. For example, the height direction Z3 may correspond to a longitudinal direction of the battery cell 10 or a direction in which the upper holder W1 and the lower holder W2 face each other and are assembled.

Throughout the present specification, the body of the cell holder (W) may mean the body of the upper holder (W1) or the body of the lower holder (W2), and the body of the upper holder (W1) or the body of the lower holder (W2) The main surface W1m of the upper holder W1 or the main surface W2m of the lower holder W2 may be included. For example, when it is assumed that the guide piece G and the hollow protrusion H protrude from the main body of the cell holder W along the height direction Z3 throughout the present specification, the guide piece G and the hollow protrusion (H) may mean that it protrudes along the height direction (Z3) from the body of the upper holder (W1), more specifically, the guide piece (G) and the hollow protrusion (H), the upper holder (W1) It may mean that it protrudes along the height direction (Z3) from the main surface (W1m) on which the bus bar (B) is seated in the body of the upper holder (W1). Similarly, when it is assumed that the protrusions P protrude from the main body of the cell holder W along the height direction Z3 throughout the present specification, the protrusions P protrude from the main body of the lower holder W2 in the height direction Z3. ), and more specifically, the protrusion (P) is the body of the lower holder (W2), that is, the rim part (which surrounds the outer circumference of the battery cell 10 among the lower holder (W2)) It may mean that L) protrudes along the height direction Z3 from the formed main surface W2m. The lower holder W2 including the protrusion part P and the rim part L will be described later in more detail.

A guide piece (G) for aligning the position of the bus bar (B) and a hollow protrusion (H) for accommodating the thermistor (TH) may be formed in the upper holder (W1), and these guide pieces (G) and the hollow The protruding portion H may protrude along the height direction Z3 from the body of the cell holder W, that is, the body of the upper holder W1 along the height direction Z3. And, in the lower holder W2 facing the upper holder W1 along the height direction Z3, the rim part L surrounding the outer circumference of the battery cell 10, and the height direction from the rim part L ( A protrusion P protrudes along Z3) may be formed.

12 is a perspective view for explaining assembly between a battery cell and a lower holder. FIG. 13 is a perspective view showing the lower holder shown in FIG. 12 . FIG. 14 is a plan view showing the lower holder shown in FIG. 13 . 15 is a plan view showing a lower holder in which battery cells are assembled. FIG. 16 is a view showing a side view of the lower holder in which the battery cells of FIG. 15 are assembled in a column direction or a transverse direction, and is a view for explaining the settling depth of the battery cells.

Referring to the drawings, the lower holder (W2) has a rim portion (L) surrounding the outer periphery of the battery cell 10 and is formed at different locations along the rim portion (L), and is formed in a height direction from the rim portion (L) ( A plurality of protrusions P protruding in a direction opposite to the assembly direction of the battery cell 10 may be formed along Z3). In one embodiment of the present invention, the protruding portion (P) is a rim portion (L) surrounding the outer periphery of any one battery cell 10, that is, the first battery cell 13, among a plurality of battery cells 10 It may include first to third protrusions P1 , P2 , and P3 formed at three different locations. For example, six different satellite battery cells 15 may be arranged along the outer circumference of the first battery cell 13, and the first battery cell 13 includes six different satellite battery cells. (15) can be surrounded by In one embodiment of the present invention, one row of battery cells 10 arranged along the column direction Z1 may be arranged in multiple rows, and adjacent to each other along the transverse direction Z2 intersecting the column direction Z1. While the battery cells 10 in a row are disposed biasedly toward the front or rear positions along the column direction Z1, the battery cells 10 in one row are inserted into the valleys of the battery cells 10 in another row adjacent to the battery cells. (10) can be implemented. In such a dense array of battery cells 10, six different satellite battery cells 15 may be arranged along the outer circumference of one battery cell 10, that is, the first battery cell 13, The protrusion part P may be formed between the first battery cell 13 and two satellite battery cells 15 adjacent to each other along the outer circumference of the first battery cell 13. For example, the protrusion part (P) may be disposed in a valley between the first battery cell 13 and two satellite battery cells 15 adjacent to each other along the outer circumference of the first battery cell 13 . Through this specification, the valley portion may mean, for example, a space formed between the outer circumferential surfaces of the cylindrical battery cells 10 adjacent to each other when the battery cells 10 are provided as cylindrical battery cells 10. have.

In one embodiment of the present invention, six different satellite battery cells 15 may be arranged along the outer circumference of the first battery cell 13, and adjacent to each other along the outer circumference of the first battery cell 13. A total of six valleys may be formed between the two satellite battery cells 15 and between the first battery cells 13. In one embodiment of the present invention, the protrusions P are the first battery cells. Rather than being formed on all six valleys along the outer circumference of (13), among the six valleys formed along the outer circumference of the first battery cell 13, alternating alternating along the outer circumference of the first battery cell 13 A total of three protrusions P, that is, first to third protrusions P1 , P2 , and P3 may be formed along the outer circumference of the first battery cell 13 . In one embodiment of the present invention, the protruding portion (P) is a protruding end (Pa) opposite to the rim portion (L) along the height direction (Z3), the rim portion (L) and the protruding end (Pa) Connecting between The side (Pb) may be included. In this case, the side surface Pb of the protrusion part P may have a gradient along the assembly direction of the battery cell 10 .

Referring to FIG. 14 , in one embodiment of the present invention, first to third protrusions P1 , P2 , and P3 may be formed along the outer circumference of the first battery cell 13 . Side surfaces Pb of the third protrusions P1 , P2 , and P3 may form circular traces OC and IC surrounding the first battery cell 13 . For example, side surfaces Pb of the first to third protrusions P1 , P2 , and P3 are located at different positions along the outer circumference of the first battery cell 13 , respectively, on the outer circumference of the first battery cell 13 . , and may form a circular trajectory (OC, IC) surrounding the first battery cell 13 to induce assembly of the first battery cell 13 . At this time, the circular trajectories OC and IC formed by the side surfaces Pb of the first to third protrusions P1, P2, and P3 have different diameters DO and DI along the height direction Z3. It can be. More specifically, the side surfaces Pb of the first to third protrusions P1 , P2 , and P3 are each separated from the rim portion L forming the support base for the first to third protrusions P1 , P2 , and P3 . It can extend to the protruding end (Pa) of the first to third protrusions (P1, P2, P3) of the first to third protrusions (P1, P2, P3) contacting the protruding end (Pa) of the side ( From the first circular trajectory OC formed by Pb) to the second circular trajectory IC formed by the side surfaces Pb of the first to third protrusions P1, P2, and P3 in contact with the rim portion L, Side surfaces Pb of the first to third protrusions P1 , P2 , and P3 may form circular trajectories OC and IC with gradually decreasing diameters DO and DI. As such, side surfaces Pb of the first to third protrusions P1 , P2 , and P3 , which induce assembly of the first battery cell 13 , are gradually reduced along the assembly direction of the first battery cell 13 . By forming circular trajectories (OC, IC), the outer circumferential surface of the first battery cell 13 and the side surfaces Pb of the first to third protrusions P1, P2, and P3 accompany the assembly of the first battery cell 13. ), the first battery cell 13 may be assembled in the right position through the interference between them.

For example, the first to third protrusions P1 , P2 , and P3 may include an inclined side surface Pb inclined along the height direction Z3 , and an inclined side surface having a smooth gradient without a step ( Pb) may be included. At this time, the side surfaces Pb of the first to third protrusions P1, P2, and P3 form circular trajectories OC and IC of different diameters DO and DI at different levels along the height direction Z3. can form Through this specification, the side surfaces Pb of the first to third protrusions P1 , P2 , and P3 along the height direction Z3 form circular trajectories OC and IC of different diameters DO and DI. , Among the side surfaces Pb of the first to third protrusions P1, P2, and P3, circular trajectories (OC, IC) continuously connecting the inner side surface Pb facing the outer circumferential surface of the first battery cell 13 Assuming , it may mean that the circular trajectories OC and IC may have different diameters DO and DI along the height direction Z3.

In one embodiment of the present invention, of the first to third protrusions P1 , P2 , and P3 contacting the protruding ends Pa among the side surfaces Pb of the first to third protrusions P1 , P2 , and P3 . The diameter DO of the first circular locus OC formed by the side surface Pb is the circular diameter DO formed by the side surface Pb of the first to third protrusions P1, P2, and P3 along the height direction Z3. The maximum value can be formed among the diameters (DO, DI) of the trajectories (OC, IC). In addition, among the side surfaces Pb of the first to third protrusions P1, P2, and P3, the side surfaces Pb of the first to third protrusions P1, P2, and P3 in contact with the rim portion L form a second The diameter DI of the circular trajectory IC is the diameter of the circular trajectory OC, IC formed by the side surfaces Pb of the first to third protrusions P1, P2, and P3 along the height direction Z3 ( DO, DI) can form the minimum value.

In one embodiment of the present invention, the diameter DO of the first circular trajectory OC forming the maximum diameter DO and the diameter DI of the second circular trajectory IC forming the minimum diameter DI ) may be set larger than the diameter of the first battery cell 13 . The circular trajectories OC and IC formed by the side surfaces Pb of the first to third protrusions P1, P2, and P3, in order to guide the first battery cell 13 to the correct position, the first battery cell (13) may be gradually reduced along the assembly direction, and at this time, the second circular trajectory IC forming the minimum diameter DI is substantially the first to third protrusions P1, P2, and P3. ) May correspond to the rim portion (L) forming a common support base, and as will be described later, the first battery cell 13 and the inside of the rim portion (L) facing the outer circumferential surface of the first battery cell 13 A contact protrusion (La) for forming an interference fit of may be formed. That is, in one embodiment of the present invention, the first to third protrusions P1 , P2 , and P3 suffice to guide the first battery cell 13 to the correct position, and the first battery cell 13 and It is not necessary to form an interference fit, and accordingly, the minimum diameter DI formed by the side surface Pb of the first to third protrusions P1, P2, and P3, that is, of the second circular trajectory IC The diameter (DI) may be set larger than the diameter of the first battery cell 13, and the first battery cell is guided to the correct position through the side surface (Pb) of the first to third protrusions (P1, P2, P3). (13) may be fixed in position while forming an interference fit with a contact protrusion (La) formed on the inside of the rim portion (L) facing the outer circumferential surface of the first battery cell (13).

While the first battery cell 13 is assembled toward the rim portion L, gradually through the side surface Pb of the first to third protrusions P1, P2, and P3 surrounding the first battery cell 13 The first and second circular trajectories OC and IC formed by the side surfaces Pb of the first to third protrusions P1, P2, and P3 may be guided to the correct position, and thus, the first and second circular trajectories OC and IC formed by the first battery It may be set larger than the diameter of the cell 13. For example, when the diameters DO and DI of the first and second circular trajectories OC and IC are smaller than or equal to the diameter of the first battery cell 13, the first battery cell 13 is It may be difficult to fit between the side surfaces Pb of the third protrusions P1 , P2 , and P3 . Rather than forming an interference fit with the contact protrusions La protruding from the rim portion L forming the support base toward the outer circumferential surface of the first battery cell 13, the first battery cell 13 ) may be difficult to assemble.

In one embodiment of the present invention, a plurality of protrusions P may be formed along the rim portion L surrounding the first battery cell 13, facing the outer circumference of the first battery cell 13 The side surface Pb of the plurality of protrusions P may form a trajectory that gradually changes along the height direction Z3. In one embodiment of the present invention, side surfaces Pb of the first to third protrusions P1 , P2 , and P3 facing the outer circumference of the first battery cell 13 form circular trajectories OC and IC. However, in various embodiments of the present invention, the side surfaces Pb of the plurality of protrusions P facing the outer circumference of the first battery cell 13 have trajectories other than the illustrated circular trajectories OC and IC. may form. Through this specification, it is known that the side surfaces Pb of the plurality of protrusions P facing the outer circumference of the first battery cell 13 form a trajectory that gradually changes along the height direction Z3, for example, the height It may mean that a trajectory followed by the side surface Pb of the plurality of protrusions P on a plane perpendicular to the direction Z3 is gradually changed along the height direction Z3. For example, the height direction Z3 The first locus formed by the side surfaces Pb of the plurality of protrusions P at the first level along ) and the side surface of the plurality of protrusions P at a second level different from the first level along the height direction Z3 ( The second trajectories formed by Pb) may be different from each other, and in this way, the trajectories formed at different levels along the height direction Z3 form a trajectory that gradually changes along the height direction Z3. While the side surface Pb of P) forms a gradient along the height direction Z3, the assembly of the first battery cell 13 may be guided to the correct position.

Hereinafter, with reference to FIGS. 12 to 15 , the shape of the rim portion L forming a common support base for the first to third protrusions P1 , P2 , and P3 will be described. In one embodiment of the present invention, the rim parts L surrounding each of the plurality of battery cells 10 may form a main surface (W2m, see FIG. 16) of the lower holder W2 while being connected to each other in a network form. . In one embodiment of the present invention, the rim parts (L) surrounding each of the battery cells 10 adjacent to each other are connected to each other around the valley between the neighboring battery cells 10 and formed in a network form, , For example, the rim parts (L) surrounding each of the three battery cells 10 adjacent to each other may come into contact with each other at the valley between the three neighboring battery cells 10, and from the valley A rim part (L) surrounding each of the three battery cells 10 adjacent to each other while being branched in three different directions may be formed. In other words, in one embodiment of the present invention, in the valley between the battery cells 10 adjacent to each other, the rim parts L surrounding each of the battery cells 10 adjacent to each other abut together and move in different directions. Dividing points DIV may be formed. For example, in a valley between three battery cells 10 adjacent to each other, a rim portion L surrounding each of the three battery cells 10 adjacent to each other may be formed. Dividing points (DIV) may be formed that all come into contact with each other and diverge in three different directions. As such, in one embodiment of the present invention, the rim portions L surrounding each of the three battery cells 10 adjacent to each other come into contact with each other at the valley between the three battery cells 10 adjacent to each other. Dividing points DIV branching in three different directions may be formed, and the valleys or diverging points DIV may be formed at six different locations along the outer circumferential direction of one battery cell 10 . For example, six different valleys or divergence points (DIV) may be formed along the outer circumferential direction of one battery cell 10 among a plurality of battery cells 10, that is, the first battery cell 13. have. For example, six different satellite battery cells 15 may be arranged along the outer circumferential direction of the first battery cell 13, and two adjacent to each other along the outer circumferential direction of the first battery cell 13. The satellite battery cell 15 and the first battery cell 13 may form a valley or a divergence point (DIV) between their outer circumferential surfaces, in other words, along the outer circumferential direction of the first battery cell 13. Six valleys or branching points (DIVs) may be formed. Throughout the present specification, the valley portion may mean a space formed between the outer circumferential surfaces of the battery cells 10 adjacent to each other, and the branch point DIV is the rim portion L surrounding each of the battery cells 10 adjacent to each other. When connected in a network form, it may mean a point where the rim parts (L) surrounding each of the battery cells 10 adjacent to each other come into contact with each other and diverge in three different directions. In one embodiment of the present invention, the Since the valley and the divergence point DIV mean positions between three adjacent battery cells 10 , the valley and the divergence point DIV may substantially correspond to the same position. That is, the valley portion and the divergence point DIV may be formed at six different locations along the rim portion L surrounding each of the plurality of battery cells 10 . For example, among the plurality of battery cells 10, one of the battery cells 10, that is, the valleys or branch points (DIV) are located at six different locations along the rim portion L surrounding the first battery cell 13. ) may be formed, and the first to third protrusions P1, P2, and P3 are formed at three valleys or diverging points (DIV) corresponding to alternate positions among a total of six valleys or diverging points (DIV). Support portions Lb may be formed at the remaining three valleys or branch points DIV where the first to third protrusions P1, P2, and P3 are not formed. More specific technical details of the support part (Lb) will be described later in more detail.

In one embodiment of the present invention, the rim portion L surrounding each of the plurality of battery cells 10 may surround each battery cell 10 while forming an angular closed loop shape. For example, the rim portion L surrounding each battery cell 10 may surround each battery cell 10 while being bent at each valley or divergence point (DIV), and a plurality of battery cells 10 The rim (L) surrounding one of the battery cells 10, that is, the first battery cell 13, extends in an angular closed loop shape in a form bent at each valley or branch point (DIV), thereby extending the first battery cell (13) can be surrounded. In other words, the rim portion L surrounding the first battery cell 13 includes a total of six strips extending in different directions so as to surround the first battery cell 13 at each valley or branch point (DIV). It may be formed in an abutting form. As will be described later, adjacent strips extending in different directions may come into contact with each other at the valley or branch point DIV along the outer circumferential direction of the first battery cell 13, and in this way, in different directions. At the valley or branch point (DIV), which is formed substantially angularly while the adjacent strips that extend come into contact with each other, the first battery cell 13 extends toward the outer circumferential surface of the first battery cell 13 from the valley or branch point DIV. A support portion (Lb) having a rounded end matched with the outer circumferential surface of may be formed.

In one embodiment of the present invention, a protrusion part P may be formed on the rim part L surrounding each battery cell 10, and the protrusion part P is a rim part surrounding each battery cell 10 It may include first to third protrusions P1, P2, and P3 protruding from three different locations along (L). In this case, each of the first to third protrusions P1 , P2 , and P3 may be formed at a valley or a branch point DIV between adjacent battery cells 10 , and three adjacent battery cells 10 While forming interference with the outer circumferential surface of ), it is possible to induce assembly of three battery cells 10 adjacent to each other.

More specifically, among the plurality of battery cells 10, one of the battery cells 10, that is, the first to third protrusions at three different locations along the rim portion L surrounding the first battery cell 13, respectively (P1, P2, P3) can be formed. At this time, the first to third protrusions P1 , P2 , and P3 include two satellite battery cells 15 adjacent to each other along the outer circumferential direction of the first battery cell 13 , and the first battery cell 13 ) can be formed in the valley between In one embodiment of the present invention, the protrusion (P) is formed between two satellite battery cells 15 and the first battery cell 13 adjacent to each other along the outer circumferential direction of the first battery cell 13 Out of a total of six valleys, it may be formed in three valleys alternately positioned with each other, and the outer circumferential surfaces of the three battery cells 10 adjacent to each other in the valleys where the protrusions P are not formed or the branch points DIV. A support part (Lb) for supporting may be formed. For example, the support portion Lb surrounds the three battery cells 10 adjacent to each other from the branch point DIV where the rim portions L surrounding each of the three battery cells 10 adjacent to each other come into contact with each other. It may be formed to protrude toward the outer circumferential surface. In one embodiment of the present invention, the protrusion part (P) and the support part (Lb) may be alternately formed at alternate positions along the rim part (L) surrounding the first battery cell 13, in other words, the The protrusion part P and the support part Lb may be alternately formed at alternate positions along the outer circumferential direction of the first battery cell 13 . In one specific embodiment of the present invention, the protrusions (P) may be formed at three places alternate with each other along the rim (L) surrounding the first battery cell (13), the support portion (Lb) is the first Along the rim portion L surrounding the battery cell 13, the protrusion portion P may be formed at three alternate locations. For example, the protrusion part P and the support part Lb may be formed between three battery cells 10 adjacent to each other, or may be formed between three battery cells 10 that are different from each other.

The support part Lb may protrude toward the outer circumferential surface of the three neighboring battery cells 10 from the branch point DIV where the rim parts L surrounding each of the three neighboring battery cells 10 come into contact with each other. . In one embodiment of the present invention, the fact that the support part Lb protrudes from the branch point DIV toward the outer circumferential surface of the three battery cells 10 adjacent to each other means that the support part Lb has a rim portion centered on the branch point DIV. It may include broadly supporting the outer circumferential surfaces of the battery cells 10 adjacent to each other while extending along (L). For example, the support part (Lb) may extend along the rim part (L) around the branch point (DIV) to widely support the outer circumferential surface of each battery cell 10, and along the rim part (L) It may extend between the protrusions P on both sides disposed with the support part Lb interposed therebetween. For example, the support portion (Lb) may extend along the rim portion (L) to a length short of the protrusions (P) on both sides, and may be formed between the protrusions (P) on both sides. Through this specification, the fact that the support part Lb supports the outer circumferential surface of the three neighboring battery cells 10 means that the support part Lb supports at least one battery cell 10 among the three neighboring battery cells 10. ) may form physical interference with the outer circumferential surface, and for example, it may include contacting the support part Lb with one of the battery cells 10. However, in various embodiments of the present invention, the support portion (Lb) does not directly contact the outer circumferential surface of the battery cell 10, but may contact the outer circumferential surface of the battery cell 10 according to the flow of the battery cell 10 Since the flow of the battery cell 10 can be controlled even when it is disposed with a certain gap therebetween, the support part Lb does not directly contact the outer circumferential surface of the battery cell 10 and has a certain gap therebetween. can be placed and placed.

The protrusion part P and the support part Lb are formed along a rim part L extending at an angle so as to surround one battery cell 10 among the plurality of battery cells 10, that is, the first battery cell 13 It is formed at three places that alternate with each other, and a rounded curved surface facing the outer circumferential surface of the first battery cell 13 may be formed. For example, the side surface Pb and the support portion Lb of the protrusion P An end of the first battery cell 13 may provide a rounded curved surface having a concave shape facing the outer circumferential surface of the first battery cell 13 . In one embodiment of the present invention, the protrusion part P and the support part Lb along the rim part L that extends generally angularly to be advantageous in terms of rigidity are rounded curved surfaces facing the outer circumferential surface of the first battery cell 13 By forming the , it is possible to provide an assembly position capable of stably holding the first battery cell 13 while being matched with the outer circumferential surface of the first battery cell 13 . In one embodiment of the present invention, a narrow portion recessed with a relatively narrow width between the protrusion portion P and the support portion Lb along the rim portion L surrounding the outer circumferential surface of the first battery cell 13 (Lc) may be formed, and the narrow portion (Lc) of the rim portion (L) is round facing the outer circumferential surface of the first battery cell 13 between the side surface (Pb) of the protrusion portion (P) and the support portion (Lb). A true curved surface can be provided. In one embodiment of the present invention, along the outer circumferential surface of the first battery cell 13, together with the protruding portion P and the supporting portion Lb, the narrow portion Lc of the rim portion L cooperates together, It is possible to form a rounded curved surface that continuously connects the outer circumferential surface of the first battery cell 13, and at this time, the narrow portion Lc of the rim portion L is between the protrusion portion P and the support portion Lb and While continuously connected, a rounded curved surface surrounding the outer circumferential surface of the first battery cell 13 as a whole may be provided.

A contact protrusion La protruding toward an outer circumferential surface of the first battery cell 13 may be formed inside the rim portion L surrounding the first battery cell 13 . In one embodiment of the present invention, the contact protrusion (La) is formed on a narrow portion (Lc) recessed with a relatively narrow width along the rim portion (L) surrounding the first battery cell (13) can In one embodiment of the present invention, the contact protrusion (La) may form an interference fit with the outer circumferential surface of the first battery cell (13), for example, the contact protrusion (La) is the first battery cell (13) ), the position of the first battery cell 13 can be firmly fixed. In one embodiment of the present invention, the contact protrusion (La) can be in close contact with the outer circumferential surface of the first battery cell 13 as the contact protrusion (La) is deformed as the assembly of the first battery cell 13 is performed. , It is possible to form an interference fit with the outer circumferential surface of the first battery cell 13 .

The contact protrusion La may adhere to the outer circumferential surface of the first battery cell 13 while being deformed as the first battery cell 13 is assembled. For example, the contact protrusion La is pushed in a direction opposite to the first battery cell 13 according to physical friction or interference with the first battery cell 13 assembled along the height direction Z3. While being deformed, it may adhere to the outer circumferential surface of the first battery cell 13 . In one embodiment of the present invention, the contact protrusion (La) is formed to protrude toward the innermost side toward the center of the first battery cell (13) among the rounded surfaces continuously surrounding the outer circumferential surface of the first battery cell (13). As a result, contact with the outer circumferential surface of the first battery cell 13 may be forced. In one embodiment of the present invention, the rounded curved surface continuously surrounding the outer circumferential surface of the first battery cell 13 may directly face the outer circumferential surface of the first battery cell 13, for example, the protrusion (P ), and may include a narrow portion Lc of the rim portion L formed between the side surface Pb of the protrusion P and the support portion Lb. In addition, the contact protrusions La protruding from the narrow portion Lc of the rim portion L toward the outer circumferential surface of the first battery cell 13 are rounded, continuously surrounding the outer circumferential surface of the first battery cell 13. Among the curved surfaces, a structure protruding inward toward the center of the first battery cell 13 may be formed.

The contact protrusion (La) may protrude to a predetermined length from the narrow portion (Lc) which is recessed with a relatively narrow width along the rim portion (L) surrounding the first battery cell (13), and is concave By protruding a predetermined length from the retracted narrow portion Lc toward the outer circumferential surface of the first battery cell 13, sufficient contact with the outer circumferential surface of the first battery cell 13 is allowed while allowing assembly of the first battery cell 13. The position of the contact protrusion La may be appropriately designed to form an interference fit. For example, while maintaining an appropriate length in consideration of the formation process of the contact protrusion La, the contact protrusion La protrudes excessively and is recessed so as not to interfere with the assembly of the first battery cell 13. The contact protrusion La may be formed to protrude from the narrow portion Lc toward the first battery cell 13 .

The contact protrusion (La) may be formed at a symmetrical position along the rim portion (L) surrounding the first battery cell 13, while forming an interference fit with the first battery cell 13 at a mutually symmetrical position The positions of the first battery cells 13 may be balanced. For example, it may be formed between the protrusions P and the support part Lb formed at three alternate positions along the rim part L surrounding the first battery cell 13, and the rim part L It can be formed in a total of six symmetrical positions along. In one embodiment of the present invention, a total of six narrow portions (Lc) and a total of six narrow portions (Lc) are located between the protruding portion (P) and the support portion (Lb) along the rim portion (L) surrounding the first battery cell (13). A contact protrusion La may be formed.

Hereinafter, referring to FIG. 16 , in the battery pack 1 according to an embodiment of the present invention, the battery cell 10 and the contact protrusion La are formed to form an interference fit with the battery cell 10. The positional relationship between the lower holders W2, more specifically, the height relationship between the battery cells 10 and the lower holders W2 in the height direction Z3 along the assembly direction of the battery cells 10 will be described. . In one embodiment of the present invention, the lower holder (W2) has a rim portion (L) formed to surround each of the plurality of battery cells (10) is connected to each other in the form of a net, the main surface (W2m) of the lower holder (W2) ) can be formed. At this time, the main surface W2m of the lower holder W2 may correspond to a surface occupying the largest area among the lower holder W2, and the main surface W2m facing the upper holder W1; It may include a main surface (W2m) opposite to the upper holder (W1). In one embodiment of the present invention, the lower holder (W2) may include a main surface (W2m) in which the rim parts (L) surrounding each battery cell 10 are connected to each other in a network form, and the height direction (Z3 ) may include an upper main surface S1 and a lower main surface S2 forming opposite main surfaces W2m along ), and more specifically, an upper main surface S1 facing the upper holder W1. ) and a lower main surface S2 opposite to the upper holder W1.

In one embodiment of the present invention, the battery cell 10 assembled to the lower holder W2 may include an upper end and a lower end along the height direction Z3. In this case, the lower end of the battery cell 10 may be disposed at a level lower than the main surface W2m of the lower holder W2, that is, the lower main surface S2 of the lower holder W2, for example, the lower main surface of the lower holder W2. It may protrude from the surface S2 to a predetermined anchoring depth t. In this specification, when referring to the main surface W2m of the lower holder W2 in relation to the fixing depth t of the battery cell 10 or the lower end of the battery cell 10, the main surface W2m of the lower holder W2 The surface W2m may mean a lower main surface S2 among the main surfaces W2m of the lower holder W2. In contrast, in this specification, when referring to the main surface W2m of the lower holder W2 in relation to the protrusions of the first to third protrusions P1, P2, and P3, the main surface of the lower holder W2 is referred to. The surface W2m may refer to an upper main surface S1 of the main surfaces W2m of the lower holder W2.

In one embodiment of the present invention, the lower end of the battery cell 10 may protrude downward from the main surface W2m of the lower holder W2 by a predetermined fixing depth t, and the The lower end protrudes downward from the main surface W2m of the lower holder W2 by a predetermined anchoring depth t, and may be disposed at a level lower than the main surface W2m. In one embodiment of the present invention, the anchoring depth t of the lower end of the battery cell 10 when the battery cell 10 is fixed is 1/ It can be set to a scale of about 10 mm to 1 mm, where the scale of about 1/10 mm to 1 mm is used in a broad sense that covers all depths from the scale corresponding to one decimal place to the scale corresponding to one place above the decimal point. can In a specific embodiment of the present invention, the anchoring depth t of the battery cell 10 may be set to a depth of 0.5 mm or more from the main surface W2m of the lower holder W2.

In one embodiment of the present invention, the first to third protrusions (P1, P2, P3, more specifically, the first to third protrusions) inducing assembly of the battery cell 10 assembled toward the lower holder (W2). The side surfaces Pb of P1, P2, and P3 are gradual from the first circular trajectory OC toward the second circular trajectory IC along the direction opposite to the assembly direction of the battery cell 10 along the height direction Z3. The battery cell 10 assembled between the first to third protrusions P1 , P2 , and P3 may be guided to the correct position while forming circular trajectories OC and IC in which the diameters DO and DI are reduced. . In addition, a contact protrusion La forming an interference fit with the battery cell 10 is formed on the rim portion L forming a common support base of the first to third protrusions P1, P2, and P3. The contact protrusion La is disposed at a lower level than the first to third protrusions P1, P2, and P3 formed on the rim portion L, and, for example, the main surface W2m formed by the rim portion L and Since it is disposed at an adjacent low level, the fixing depth t at which the battery cell 10 is fixed in position while forming an interference fit with the contact protrusion La, that is, the battery cell when the battery cell 10 is fixed in position ( The depth of the lower end of 10) may be formed at a lower height than, for example, the main surface W2m formed by the rim portion L, and thus, the contact protrusion formed on the battery cell 10 and the rim portion L A sufficient interference fit can be made between (La). Throughout the present specification, the anchoring depth t or the height of the lower end of the battery cell 10 all mean the depth or height from the main surface W2m of the lower holder W2 along the height direction Z3, and related descriptions It may be referred to as depth or height, but both may mean depth or height from the main surface W2m of the lower holder W2 along the height direction Z3.

In one embodiment of the present invention, the anchoring depth t of the battery cell 10 is the height of the rim portion L formed with the contact protrusion La forming an interference fit with the battery cell 10 or the rim portion L ) is formed at a height lower than the height of the main surface W2m formed, the lower end of the battery cell 10 may protrude downward from the rim portion L or the main surface W2m formed by the rim portion L. And, it may protrude from the rim part L or the main surface W2m formed by the rim part L to a predetermined fixing depth t.

In one embodiment of the present invention, the anchoring depth of the battery cell 10 (t, the depth of the lower end of the battery cell 10 when the battery cell 10 is fixed in position) is a contact protrusion forming an interference fit with the battery cell 10 By being formed at a height lower than the rim portion L where (La) is formed, it is possible to secure the secure positioning of the battery cell 10 . For example, the lower end of the battery cell 10 is disposed at a level lower than the rim portion L where at least the contact protrusion La is formed at a predetermined fixing depth t, so that the battery cell 10 and the contact protrusion La ) Through physical interference or interference fit between the battery cells 10, a solid position fixing of the battery cells 10 can be secured, and sufficient interference between the battery cells 10 and the contact protrusions La along the assembly direction of the battery cells 10. Through this, the solid position fixing of the battery cell 10 can be secured, and at this time, the fixation depth t in which the lower end of the battery cell 10 protrudes downward from the rim portion L is in contact with the battery cell 10 It may correspond to a predetermined assembly tolerance or margin for securing physical interference or interference fit between the protrusions La.

Referring to FIG. 1 , in one embodiment of the present invention, an electrical connection is formed between the battery cells 10 through the upper ends of the battery cells 10, and the battery cells 10 through the lower ends of the battery cells 10. ) cooling can be implemented. For example, in one embodiment of the present invention, a plurality of battery cells are provided through the electrodes 11 and 12 formed on the upper end of the battery cell 10 and the bus bar B placed on the upper end of the battery cell 10. It is possible to form an electrical connection such as parallel or series of (10), and through the lower end of the battery cell 10, that is, the battery cell 10 exposed from the lower holder W2 to a predetermined fixing depth t. ) Cooling of the battery cell 10 may be implemented through the lower end of the. In one embodiment of the present invention, a plurality of bus bars (B) forming electrical connections between the plurality of battery cells (10) are disposed on the upper holder (W1) into which the upper ends of the battery cells (10) are inserted. A cooling plate 70 (refer to FIG. 1 ) forming thermal contact with the plurality of battery cells 10 may be disposed on the lower holder W2 into which the lower ends of the battery cells 10 are inserted. For example, the bus bar (B) is disposed above the upper holder (W1), electrically connected to the upper end of the battery cell 10 (more specifically, the electrodes 11 and 12 formed on the upper end of the battery cell 10). The cooling plate 70 may form a connection, and the cooling plate 70 is disposed under the lower holder W2 and exposed to the lower end of the battery cell 10 (more specifically, from the lower holder W2 to a predetermined fixing depth t). The lower end of the battery cell 10) and thermal contact may be formed. Here, forming thermal contact between the cooling plate 70 and the lower end of the battery cell 10 includes direct contact between the cooling plate 70 and the lower end of the battery cell 10. For example, even if the cooling plate 70 and the lower end of the battery cell 10 do not directly contact each other, the cooling plate 70 and the lower end of the battery cell 10 are disposed adjacent to each other to the extent that heat transfer is possible. It can be used in a comprehensive sense including configuration. In one embodiment of the present invention, the electrical connection of the battery cell 10 and the cooling of the battery cell 10. By implementing through the upper and lower ends of the battery cells 10 spaced apart from each other along the height direction Z3, for example, in a position where the electrical connection and cooling of the battery cells 10 do not interfere with each other, the battery cells The electrical connection of (10) and the cooling of the battery cell (10) can be implemented smoothly. For example, unlike the present invention, when the electrical connection of the battery cell 10 is made through both the upper and lower ends of the battery cell 10, the lower portion of the battery cell 10 is electrically connected and has a cooling structure. All are required, and the overall structure of the battery pack 1 may be complicated in that a separate insulation structure for electrical connection and cooling insulation is required at the lower end of the battery cell 10 in particular.

17 is an exploded perspective view of a battery pack according to an embodiment of the present invention, and an exploded perspective view for explaining the structure of a cover is shown. FIG. 18 is a perspective view illustrating the battery pack in a state in which the cover of FIG. 17 is assembled.

Referring to FIGS. 17 and 18 , in one embodiment of the present invention, a cover C may be disposed on the cell holder W. The cover (C) has a front edge (CF) and a rear edge (CR) disposed facing each other along the column direction (Z1), and a first side edge (CS1) disposed facing each other along the transverse direction (Z2) and a second sidewall portion CS2. At this time, in order to form the module 100 extending along the column direction Z1 at the front edge portion CF and the rear edge portion CR, the first portion extending from the main body portion B1 of the frontmost bus bar B is formed. Openings C1 and C2 may be formed to expose portions of the extension piece E1 and the body portion B1 of the rearmost bus bar B. More specifically, a front opening C1 for exposing a first extension piece E1 extending from the body portion B1 of the frontmost bus bar B may be formed in the front edge portion CF, and the rear opening C1 may be formed. A rear opening C2 may be formed at the edge portion CR to expose a part of the body portion B1 of the rearmost bus bar B. In the extended module 100 including a plurality of battery packs 1 arranged along the column direction Z1, a first extension piece E1 exposed through the front opening C1 of one battery pack 1 And, the main body portion B1 of the bus bar B exposed through the rear opening C2 of the battery pack 1 adjacent to each other along the column direction Z1 overlaps each other along the column direction Z1. The frontmost bus bar (B) and the rearmost bus bar (B) of one battery pack (1) may be electrically connected to each other, and at this time, exposed from the front edge (CF) and the rear edge (CR) of the cover (C) By coupling the first extension piece E1 and the body portion B1 of the bus bar B to each other by welding or the like, adjacent battery packs 1 can be easily electrically connected to each other. For example, in one embodiment of the present invention, the battery packs 1 disposed next to each other along the column direction Z1 may have substantially the same structure, and the battery packs 1 formed with the same structure By arranging them along the column direction Z1, an extended module 100 including a plurality of battery packs 1 along the column direction Z1 can be provided. To this end, in the battery pack 1 according to an embodiment of the present invention, the front opening C1 formed on the front edge CF of the cover C and the rear opening formed on the rear edge CR of the cover C (C2) may be formed at a column position corresponding to each other, and the front opening (C1) and the rear opening (C2) are formed at positions facing each other along the column direction (Z1), thereby passing through the front opening (C1). The first extension piece E extending from the exposed foremost bus bar B and the rearmost bus bar B exposed through the rear opening C2 are mutually related to each other at positions corresponding to each other along the column direction Z1. can be combined for

Similarly, in order to form the module 100 extending along the transverse direction Z2 at the first and second side edges CS1 and CS2 of the cover C, bus bars along the transverse direction Z2 ( A second expansion piece E2 extending from the outermost position of one side of the main body part B1 of B) and an opening C3 for exposing the outermost position of the other side of the main body part B1 of bus bar B). C4) can be formed. In one embodiment of the present invention, the second extension piece E2 extending from the outermost position of one side of the main body portion B1 of the bus bar B along the transverse direction Z2 in the first side portion CS1 ) may be formed, and the outermost part of the other side of the body part B1 of the bus bar B may be formed in the second side part CS2 along the transverse direction Z2. A second lateral opening C4 for exposing the position may be formed. In the extended module 100 including a plurality of battery packs 1 along the lateral direction Z2, a second extension piece E2 exposed through the first lateral opening C3 of one battery pack 1 and the body portion B1 of the bus bar B exposed through the second lateral opening C4 of the battery pack 1 adjacent along the transverse direction Z2 overlaps each other along the transverse direction Z2. Bus bars (B) of battery packs (1) adjacent to each other may be electrically connected to each other, and at this time, the second extension piece (E2) exposed from the first and second side edges (CS3, CS4) of the cover (C). ) and the bus bar (B, the outermost position of the bus bar B along the lateral direction Z2) are coupled to each other by welding or the like, so that the battery packs 1 adjacent to each other can be easily electrically connected to each other. For example, in one embodiment of the present invention, the battery packs 1 disposed next to each other along the transverse direction Z2 may have substantially the same structure as each other, and the battery packs 1 formed with the same structure as each other By arranging them along the transverse direction Z2, an extended module 100 including a plurality of battery packs 1 along the transverse direction Z2 can be provided. To this end, in the battery pack 1 according to an embodiment of the present invention, the first and second lateral openings C3 and C4 formed in the first and second lateral edges CS1 and CS2 of the cover C are , Can be formed at transverse positions corresponding to each other, and the first and second lateral openings C3 and C4 are formed at positions facing each other along the transverse direction Z2, thereby exposing through the first lateral opening C3 The bus bar (B, the outermost position of bus bar B along the transverse direction Z2) exposed through the second extension piece E2 and the second lateral opening C4 may be formed at positions corresponding to each other, Since the first and second lateral openings C3 and C4 are formed at positions facing each other along the transverse direction Z2, the second extension piece E2 exposed through the first lateral opening C3 and the second lateral opening Bus bars (B, the outermost position of bus bar B along the transverse direction Z2) exposed through the opening C4 can be coupled to each other at positions corresponding to each other along the transverse direction Z2.

In one embodiment of the present invention, the openings C1 , C2 , C3 , and C4 may be formed in a notch shape or a hole shape. For example, the front opening C1 and the first lateral opening C3 for exposing the first and second extension pieces E1 and E2 may be formed in a notch shape, and the first and second extension pieces ( The front edges CF and the first lateral edges CS1 around E1 and E2 surround the first and second extension pieces E1 and E2 in an open loop shape with one side open, while the first and second extension pieces E1 and E2 are closed. It is possible to protect the extension pieces E1 and E2 from the external environment. In one embodiment of the present invention, the rear opening C2 and the second side opening C4 for exposing a part of the bus bar B along the column direction Z1 and the transverse direction Z2 are formed in the form of holes. The rear edge (CR) and the second side edge (CS2) around the bus bar (B) exposed to the outside surround a part of the bus bar (B) in a closed closed loop form and are exposed toward the outside. It is possible to protect a part of the bus bar (B) from the external environment.

19 is a perspective view showing a cell holder of a battery pack according to another embodiment of the present invention. FIG. 20 is a perspective view showing a state in which the cover is assembled on the cell holder shown in FIG. 19 .

Referring to FIGS. 19 and 20 together, the cell holder (W) may include a welding bead part (WB) for welding with the cover (C). For example, in one embodiment of the present invention, a weld bead portion WB may be formed at a position of the cell holder W in contact with the cover C. A bus bar (B) may be disposed on the cell holder (W) together with the cover (C), and the cell holder (W) and the cover (C) face each other along the height direction (Z3) and form a bond to each other. ) may be formed at positions in direct contact with each other, and the cell holder (W) may directly contact the cover (C) through the weld bead portion (WB).

The weld bead portion WB forms a coupling portion while directly contacting the cover C, and more specifically, the weld bead portion WB forms a coupling portion between the cell holder W and the cover C. can In one embodiment of the present invention, the weld bead portion (WB) forms a coupling portion with the cover (C) while directly contacting the cover (C), the weld bead portion (WB) is in the cell holder (W) It may be formed at a level closest to the cover C, that is, a level closest to the side of the cover C along the height direction Z3. As will be described later, the weld bead portion WB is formed at a level higher than the bus bar B supported on the cell holder W or the extension piece E1 extending from the bus bar B, The bar B may extend across the extension piece E1 that extends to the outside of the accommodating space.

In one embodiment of the present invention, the weld bead portion (WB) may surround the accommodation space of the cell holder (W) in a closed loop form along the periphery of the cell holder (W), and accommodate the cell holder (W). While enclosing the space, the battery cell 10 and the bus bar B disposed in the receiving space of the cell holder W may be sealed from the external environment. In one embodiment of the present invention, the weld bead portion (WB) extends from the bus bar (B) along the column direction (Z1) and the transverse direction (Z2) while surrounding the bus bar (B) disposed in the accommodation space It may extend across the extension piece E1 to be. Throughout the present specification, the fact that the weld bead portion WB extends across the extension piece E1 extending from the body portion B1 of the bus bar B means that the extension piece ( E1), at a level higher than the extension piece E1 along the height direction Z3, by extending across the extension piece E1, at least a level higher than the extension piece E1. can extend across the extension piece E1, that is, at least at a level closer to the cover C side than the extension piece E1 along the height direction Z3. The weld bead portion WB may form a coupling portion with the cover C while directly abutting the cover C at a height closer to the cover C than the extension piece E1. In one embodiment of the present invention, the weld bead part (WB) may form a joint between the cell holder (W) and the cover (C) by welding, and more specifically, form a joint through laser welding. can do. In one embodiment of the present invention, the cell holder (W) and the cover (C) may be formed of, for example, a polymer resin material such as engineering plastic to form a coupling part to each other through laser welding, , The cell holder (W) and the cover (C) may be formed of a material having excellent material compatibility, so as to form a solid coupling portion to each other. In one embodiment of the present invention, the cell holder (W) and the cover (C) may be formed of the same polymeric resin material capable of laser welding.

Through this specification, the fact that the weld bead portion WB extends across the extension piece E1 means that the weld bead portion WB surrounds the receiving space in which the bus bar B is accommodated, and the bus bar B It may mean that it extends across the extension piece E1 extending to the outside of the accommodation space from , and in various embodiments of the present invention, the object surrounded by the weld bead portion WB is the bus bar B It is not limited to the extension piece E1 extending from, for example, a portion of the bus bar B from which the extension piece E1 extends or a connected portion between the extension piece E1 and the bus bar B. can mean inclusively. For example, according to positional alignment or assembly tolerance between the cell holder W and the bus bar B where the weld bead portion WB is formed, the weld bead portion WB extends across the extension piece E1. Rather than being, for example, it may extend across a portion of the bus bar B from which the extension piece E1 extends, or may extend across a connected portion between the extension piece E1 and the bus bar B. . Even in this case, the weld bead portion WB extends across a portion of the bus bar B to which the extension piece E1 is connected or a portion connected between the extension piece E1 and the bus bar B, while extending across the bus bar. (B) and the battery cell 10 may surround the accommodating space.

Although the present invention has been described with reference to the embodiments shown in the accompanying drawings, this is only exemplary, and those skilled in the art to which the present invention belongs can make various modifications and equivalent other embodiments. you will understand the point.

1: battery pack 100: module
B: bus bar B1: main body of bus bar
Ba: first branch Bb: second branch
E1: 1st Extended Edition E2: 2nd Extended Edition
W: cell holder W1: upper holder
W2: lower holder FW: front wall
RW: rear wall SW1: first side wall
SW2: second side wall H: hollow protrusion
G: Guide TH: Thermistor
A: temperature detection position A1: first temperature detection position
A2: 2nd temperature detection position A2-1: 2nd-1st temperature detection position
A2-2: 2-2nd temperature detection position C: cover
C`: exposure ball

Claims (22)

a plurality of battery cells;
A cell holder surrounding an accommodation space accommodating a plurality of battery cells, the cell holder including a hollow protrusion formed at a temperature detection position for measuring the temperature of the battery cells;
a cover disposed on the cell holder and having an exposure hole for exposing the hollow protrusion; and
and a thermistor accommodated in the hollow protrusion through the exposure hole. According to claim 1,
The plurality of battery cells are battery cells in which one row of battery cells arranged along a column direction is arranged in a plurality of rows, and battery cells in rows adjacent to each other along a transverse direction intersecting the column direction are positioned forward or Battery packs characterized in that they are arranged alternately offset from each other in a rearward position. According to claim 1,
The temperature detection position is
a first temperature detection position disposed at a central position of the cell holder; and
and a second temperature detection position adjacent to a corner position of the cell holder rather than a center position. According to claim 3,
The cell holder,
a first expansion edge and a first accommodation edge facing each other along a column direction with the accommodation space interposed therebetween; and
A battery pack comprising: a second extension edge and a second accommodation edge facing each other in a lateral direction with the accommodation space interposed therebetween. According to claim 4,
The first extending edge and the first receiving edge,
first convex portions and second concave portions formed in complementary shapes that can be fitted to each other at the same row position; and
Including; a first concave portion and a second convex portion formed in complementary shapes that can be fitted to each other at another mutually same column position;
The first extended edge is formed in a zigzag shape including first convex portions and first concave portions alternately disposed along the transverse direction,
The battery pack of claim 1 , wherein the first accommodating edge includes second convex portions and second concave portions alternately disposed along the lateral direction and is formed in a zigzag shape. According to claim 4,
The battery pack, characterized in that the second expansion edge and the second receiving edge are formed flat. According to claim 4,
The second temperature detection position,
Characterized in that it comprises four second temperature detection positions disposed adjacent to four corner positions formed while the first extending edge, the first receiving edge, the second expanding edge, and the second receiving edge contact each other. battery pack. According to claim 7,
The second temperature detection position is adjacent to the corner position, but spaced apart from the first extension edge, the first accommodation edge, the second expansion edge, and the second accommodation edge forming the corner position. According to claim 4,
The battery pack, characterized in that the second temperature detection position is formed at a position biased towards the first accommodating edge between the first expansion edge and the first accommodating edge. According to claim 4,
The second temperature detection position,
a 2-1st temperature detection position formed adjacent to the second extended edge; and
and a 2-2nd temperature detection position formed adjacent to the second accommodating edge. According to claim 10,
The 2-1st temperature detection positions include two 2-1st temperature detection positions spaced apart from each other in a column direction along the second extended edge,
The battery pack according to claim 1 , wherein the 2-2nd temperature detection positions include two 2-2nd temperature detection positions spaced apart from each other in a column direction along the second accommodating edge. According to claim 11,
A first distance between the second extension edge and the 2-1st temperature detection position is greater than a second distance between the second accommodating edge and the 2-2nd temperature detection position. According to claim 4,
A first extension piece protruding from the first extension edge toward the outside of the accommodation space is formed on the first extension edge,
The battery pack of claim 1 , wherein a second extension piece protruding from the second extension edge toward the outside of the accommodating space is formed on the second extension edge. According to claim 13,
In order to connect the plurality of battery cells to each other, further comprising a bus bar disposed in the accommodation space,
The battery pack, characterized in that the first and second extension pieces extend from the bus bar toward the outside of the accommodation space along the column direction and the transverse direction. According to claim 14,
The bus bar,
Connecting a group of battery cells including a plurality of battery cells adjacent to each other among the plurality of battery cells in parallel;
A battery pack characterized in that a group of battery cells adjacent to each other are connected in series along a column direction. According to claim 14,
The bus bar,
a main body portion extending between a group of battery cells adjacent to each other along a column direction; and
A battery pack comprising first and second branch portions respectively extending from the main body toward a group of battery cells adjacent to each other with the main body interposed therebetween. According to claim 16,
The battery pack according to claim 1 , wherein the body portion includes a plurality of body portions disposed through a group of battery cells along a column direction. According to claim 13,
The battery pack, characterized in that the first extension piece extends along the column direction from the outermost body portion of any one of the frontmost or rearmost body portion along the column direction. According to claim 18,
The outermost body portion extends in a zigzag form including convex portions and concave portions alternately disposed along the transverse direction,
The battery pack according to claim 1 , wherein the first extension pieces include a plurality of first extension pieces extending from the concave portion of the outermost body part. According to claim 19,
The first extension piece extends along the column direction from the frontmost body portion along the column direction,
The frontmost body portion and the first extended edge are each formed in a first zigzag shape including first convex portions and first concave portions alternately disposed at alternate positions along the transverse direction,
The rearmost main body part and the first accommodating edge facing the outermost main body part and the first extended edge, respectively, include second convex parts and second concave parts alternately disposed at alternating positions along the lateral direction, and the second jig It is formed in a zag shape,
The battery pack, characterized in that the first and second zigzag shapes are formed complementary to each other. According to claim 4,
The battery pack, characterized in that the second extension piece extends along the lateral direction from the outermost position of the bus bar along the lateral direction. According to claim 21,
The second extension piece includes a plurality of second extension pieces extending from an outermost position of the main body of the bus bar arranged along the column direction.

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