KR20200063413A - Battery module and battery package with the same - Google Patents

Abstract

Disclosed are battery modules, and a battery package in which the plurality of battery modules are combined. The disclosed battery modules comprise: a plurality of battery cells arranged in a matrix; a lower end support member formed of electrically insulating plastic, and having lower ends of the plurality of battery cells seated on an upper surface thereof; an upper end support member formed of the electrically insulating plastic, and having upper ends of the plurality of battery cells seated on a lower surface thereof; and a plurality of pillars spaced apart around the plurality of battery cells, having upper ends fixed to and supported by the upper end support member, and having lower ends fixed to and supported by the lower end support member. First brackets protruding outward to be in contact with the pillars are provided on one side surface of the lower end support member, the other side surface of the lower end support member, one side surface of the upper end support member, and the other side surface of the upper end support member. Second brackets protruding outward so as not to be in contact with the pillars are provided on at least one surface among one side surface of the lower end support member, the other side surface of the lower end support member, one side surface of the upper end support member, and the other side surface of the upper end support member. The second brackets are disposed at a position symmetrical to the first brackets formed on the opposite side surface based on a center line spaced apart, by the same distance, from the side surface on which the second brackets are formed and an opposite side surface thereof.

Description

Battery module and a battery package having the same {Battery module and battery package with the same}

The present invention relates to a battery module having a plurality of electrically connected battery cells, and a battery package having the battery module.

Batteries are used to supply electrical energy, from small electronic devices such as mobile phones to automobiles, devices such as satellites, and energy storage systems (ESSs). Specifically, a secondary battery capable of charging and discharging is used. Except for small-sized battery devices, a plurality of battery cells are collected and electrically connected to devices such as automobiles, satellites, and energy storage systems, and electrically connected to constitute a battery package, resulting in high voltage, large power, and It is trying to meet long usage time.

In Korean Patent Publication No. 10-2018-0083991, a battery package according to a conventional example is disclosed. However, the battery package has a problem that the electric capacity is fixed and difficult to change. In other words, the battery package includes a plurality of battery cells, an upper support member, a lower support member, an upper fixed layer, a lower fixed layer, a cover, and a base. Among the above-described components, all components except the plurality of battery cells are All of them are manufactured in a predetermined shape and size to fix and support a predetermined number of battery cells. Therefore, if it is desired to increase the number of battery cells to manufacture a battery package having a larger electric capacity, the upper support member, the lower support member, the upper fixed layer, the lower fixed layer, the cover, and the base must be redesigned and manufactured. Its scalability is poor. On the other hand, when the members are produced to cope with various electric capacities, the production cost is increased due to small production.

On the other hand, a method of increasing the electric capacity by electrically connecting a plurality of battery packages having a single electric capacity may be applied, but there is a problem in that the installation space is increased, and a component that electrically connects the plurality of battery packages is additionally required. Costs may increase, and energy efficiency may decrease. In addition, when a plurality of battery packages electrically connected to a moving device or a harsh environment such as a car or a satellite is installed, it may be difficult to supply stable electrical energy due to the above-described electrical connection being disconnected.

Republic of Korea Patent Publication No. 10-2018-0083991

The present invention provides a battery package in which a plurality of battery modules are combined with a battery module that is easy to couple and detach from each other.

The present invention is formed of a plurality of battery cells (battery cells) arranged in a matrix, an electrically insulating plastic, the lower end of the plurality of battery cells is formed of a lower end support member, an electrically insulating plastic seated on the upper side, the A battery module having an upper end support member for seating an upper end of a plurality of battery cells on a lower side, and a plurality of pillars for engaging and fixing between the upper end support member and the lower end support member, wherein the lower end support member is itself It has a plurality of first brackets protrudingly arranged to fit the pillar on one side and the other side of the, and a plurality of second brackets protruding at different positions and heights from the plurality of first brackets, and the lower end supporting member The positions of the first bracket on one side and the second bracket on the other side are opposite, and the positions of the second bracket on the one side of the lower support member and the first bracket on the other side are opposite, and different batteries are provided on both sides of the battery module. It provides a battery module formed so that the module can be coupled.

The upper support member includes a plurality of first brackets protrudingly arranged to fit the pillars on one side and the other side thereof, and a plurality of the upper support members are provided on at least one side of one side and the other side of the column. It has a plurality of second brackets protruding from different positions and heights of the first bracket, the position of the second bracket of the upper support member, the position of the first bracket protruding from the opposite side of the side from which it protrudes Can be faced with.

In addition, the present invention is formed of a plurality of battery cells (battery cell) arranged in a matrix, an electrically insulating plastic, the lower end of the plurality of battery cells is formed of a lower end support member, an electrically insulating plastic seated on the upper side, The upper end supporting member that is seated on the lower surface of the upper end of the plurality of battery cells, and is disposed spaced apart around the plurality of battery cells, the upper end is fixedly supported by the upper supporting member and the lower end is fixedly supported by the lower supporting member. It has a plurality of pillars (pillar), one side of the lower support member, the other side of the lower support member, one side of the upper support member, and the other side of the upper support member to the outside so as to contact the pillar The protruding first bracket is provided, and protrudes outwardly on at least one side of one side of the lower end support member, the other side of the lower end support member, one side of the upper end support member, and the other side of the upper end support member. However, a second bracket that is not in contact with the pillar is provided, and the second bracket includes a first bracket formed on the opposite side about a center line spaced apart by the same distance from the side where the second bracket is formed and the opposite side thereof. It provides a battery module disposed in a symmetrical position.

The second bracket is formed on the upper support member, and the second bracket formed on the upper support member may be positioned higher than the first bracket formed on the upper support member.

The second bracket is formed on the lower support member, and the second bracket formed on the lower support member may be positioned lower than the first bracket formed on the lower support member.

The battery module of the present invention, the first end of the plurality of battery cells and the electrode (electric pole) of one end, respectively, is electrically connected (通電) is electrically connected to each other, the first electrode electric wire (electric wire) coated and A second electrode wire and a module printed circuit board (PCB) that is electrically connected to the other end of the first electrode wire and the second electrode wire may be further provided.

The module PCB is fixedly supported by the upper end support member, the first electrode wire is not pressed against the upper end of the battery cell, and the first electrode wire and the second electrode wire pass through the upper end support member. A wire through-hole is formed so that a wire arrangement groove may be formed in the lower end support member so that the second electrode wire is not pressed against the lower end of the battery cell.

The other end portions of the first electrode wire and the second electrode wire and the lower surface of the module PCB may be detachably connected by a connector.

In addition, the present invention is provided with a plurality of the above-described battery module, the plurality of battery modules are arranged in a row adjacent to the battery package, a second battery module provided in one of the pair of adjacent adjacent battery modules The bracket provides a battery package that is disposed to overlap and overlap with the first bracket provided in the other battery module and is coupled to each other.

The first bracket and the second bracket, which are arranged to overlap the top and bottom, are coupled by a bolt, and the bolt can be fixedly coupled to the pillar by penetrating through the second bracket and the first bracket.

The battery package of the present invention is configured by arranging and combining a plurality of battery modules of one type. Therefore, it is possible to easily change the electric capacity of the battery package by adding or subtracting the number of battery modules. In other words, the battery cell constituting the battery module, the lower end support member, the upper end support member, and each of the pillars can be designed and manufactured, and the number of battery modules can be adjusted to manufacture battery packs of various electric capacities. The production cost of the package can be lowered, and the battery package can be supplied in response to an order quickly.

1 is a perspective view of a battery package according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of FIG. 1 taken along line II-II.
3 and 4 are exploded perspective views of the battery module of Figure 1, Figure 3 is a view seen from above, Figure 4 is a view seen from below.
FIG. 5 is a perspective view showing the battery cell of FIG. 3, a wire connected to the battery cell, and a connector connected to the wire.

Hereinafter, a battery module and a battery package having the same according to embodiments of the present invention will be described in detail with reference to the accompanying drawings. Terminology used in the present specification are terms used to properly express a preferred embodiment of the present invention, which may vary according to a user or operator's intention or customs in the field to which the present invention pertains. Therefore, definitions of these terms should be made based on the contents throughout the specification.

1 is a perspective view of a battery package according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of FIG. 1 taken along line II-II. Referring to FIG. 1, a battery package 1 according to an embodiment of the present invention includes a plurality of battery modules 10A, 10B, 10C, 10D, and 10E arranged adjacent to each other in a line parallel to the X axis. , For example, can be used to supply electrical energy to devices such as satellites, automobiles. Alternatively, the battery package 1 may be used in an energy storage system (ESS). Although not shown in FIG. 1, the battery package 1 may further include a battery box in which the plurality of battery modules 10A, 10B, 10C, 10D, and 10E are accommodated. The battery box may include a base (not shown) and a cover (not shown) that are detachably coupled.

3 and 4 are exploded perspective views of the battery module of FIG. 1, FIG. 3 is a view seen from above, FIG. 4 is a view seen from below, and FIG. 5 is a battery cell of FIG. 3, a wire connected to the battery cell, It is a perspective view showing a connector connected to an electric wire. Each of the plurality of battery modules 10A, 10B, 10C, 10D, and 10E shown in FIG. 1 has the same configuration. 3 and 4, the battery module 10 to which reference number '10' is assigned is the same as each battery module 10A, 10B, 10C, 10D, 10E shown in FIG. Referring to Figure 3 and 4 together, the battery module 10 according to an embodiment of the present invention, a plurality of battery cells (battery cell) 11, the lower support member 20, the upper support member 50, It has a plurality of pillars (73), and a module printed circuit board (PCB) 80.

Referring to FIG. 5, each battery cell 11 may be a secondary battery capable of discharging and charging. The battery cell 11 is cylindrical, and an electrode (electric pole) is formed on the upper part 12 and the lower part 13 (see FIG. 4 ). In the embodiment illustrated in FIG. 5, an anode is formed on the upper portion 12 and a cathode is formed on the lower portion 13, but an electrode may be formed on the contrary. One end of the first electrode wire 14 is connected to the electrode of the upper end 12, and one end of the second electrode wire 15 is connected to the electrode of the lower end 13. The first electrode wire 14 and the second electrode wire 15 are formed of, for example, a metal core (not shown) formed of a copper (Cu) material and extending in one direction, and an outer circumferential surface of the metal core. It is provided with an insulating insulating covering.

A metal core of one end of the first electrode wire 14 and one end of the second electrode wire 15 is soldered to the top 12 electrode and the bottom 13 electrode of the battery cell 11 (14w) ). The metal core of the other end of the first electrode wire 14 and the other end of the second electrode wire 15 may be detachably connected to a module PCB 80 (see FIG. 4) to be described later (connector) ( 16) are combined. The connector 16 is one of a male connector and a female connector. In FIG. 5, the first electrode wire 14 and the second electrode wire 15 are illustrated as extending in contact with the surface of the battery cell 11, but this is only exemplary. In addition, in FIG. 5, portions of the first electrode wire 14 and the second electrode wire 15 are shown to extend in the same direction in contact with each other, but this is only exemplary.

Referring to FIGS. 3 and 4 together, a plurality of battery cells 11 provided in the battery module 10 are arranged in a matrix in an erected state, respectively. In the embodiment shown in Figs. 3 and 4, 39 battery cells 11 are arranged in an 11x3 matrix. Here, 11 battery cells 11 arranged parallel to the X axis form a row, and 3 battery cells 11 arranged parallel to the Y axis form a column. However, the battery cells 11 arranged in the 11×3 matrix described above are exemplary and the present invention is not limited to the 11×3 matrix described above.

The lower end support member 20 is a member supporting the lower end of the plurality of battery cells 11 by seating the lower end of the plurality of battery cells 11 on the upper side, and the upper end support member 50 is the plurality of battery cells The upper end of (11) is seated on the lower side and is a member supporting the upper ends of the plurality of battery cells (11). The lower end support member 20 is a substantially rectangular board-shaped member, and the lower end seating groove 21 in which the lower end portions of the plurality of battery cells 11 are spaced apart from each other, and the lower end of the battery cell 13 ), the second electrode wire 15 (refer to FIG. 5) connected to the electrode is pressed against the lower end 13 of the battery cell 11 seated in the lower end seating groove 21 than the lower seating groove 21. A deeply dug wire arrangement groove 22 is formed.

The lower seating groove 21 is formed such that 39 lower seating grooves 21 are arranged in an 11×3 matrix to correspond to the matrix of the plurality of battery cells 11. The wire placement groove 22 extends parallel to the X axis to connect the 11 lower seating grooves 21 arranged along the same row.

Like the lower end support member 20, the upper end support member 50 is also a generally rectangular board-shaped member, and the upper end seating groove 51 in which the upper ends of the plurality of battery cells 11 are spaced apart from each other on the lower side ) Is formed. The upper seating groove 51 is formed so that 39 upper seating grooves 51 are arranged in an 11×3 matrix to correspond to the matrix of the plurality of battery cells 11.

The upper end supporting member 50 has a first electrode wire 14 (refer to FIG. 5) connected to an electrode of the battery cell upper end 12 (see FIG. 5 ), the upper end 12 of the battery cell 11 seated in the upper seating groove 25. Without being pressed by, a wire through hole 52 is formed so that the first electrode wire 14 and the second electrode wire 15 penetrate the upper end support member 50. The wire through hole 52 extends parallel to the X axis to connect the 11 upper seating grooves 51 arranged along the same row.

The lower end support member 20 and the upper end support member 50 are formed of an electrically insulating plastic to prevent electric leakage or short circuit between the upper end 12 and the lower end 13 of the battery cell 11. Preferably, the lower support member 20 and the upper support member 50 to protect the battery cell 11 from external shocks and vibrations have excellent rigidity and excellent electrical insulation properties. ).

The module PCB 80 is electrically connected to the other end of the first electrode wire 14 and the second electrode wire 15 described with reference to FIG. 5. Specifically, a connector 82 to which the connector 16 coupled to the other end of the first and second electrode wires 14 and 15 is detachably connected is mounted on the lower surface of the module PCB 80. If the connector 16 coupled to the other end of the first and second electrode wires 14 and 15 is a male connector, the connector 82 mounted on the module PCB 80 is a female connector, and the first and second If the connector 16 coupled to the other end of the electrode wires 14 and 15 is a female connector, the connector 82 mounted on the module PCB 80 is a male connector. The connector 82 mounted on the module PCB 80 may be arranged in an array of 11 × 3 matrices corresponding to the battery cells 11 arranged in a matrix.

The module PCB 80 is fixedly supported by a plurality of bolts (not shown) on the upper support member 50 as shown in FIG. 2. A plurality of bolt through holes 81 through which the plurality of bolts penetrate are formed at an outer circumferential edge portion of the module PCB 80, and the plurality of bolts are fitted on the upper side of the upper support member 50 to fit the plurality of bolts A plurality of bolt fastening holes 71 aligned with the through holes 81 are formed.

Since the connector 16 of each battery cell 11 and the connector 82 of the module PCB 80 are detachably connected one-to-one, some of the battery cells 11 are discharged and charged among the battery cells 11 Even if the disablement occurs, discharging and charging of the entire battery module 10 are not impossible. In addition, the connector 16 of each battery cell 11 and the connector 82 of the module PCB 80 are one-to-one even if all the battery cells 11 are not erected with the anode up and the cathode down. Once connected, the battery module 10 works correctly. Therefore, the assembly of the battery module 10 and the battery package 1 having the same (see FIG. 1) is easy, thereby improving assembly productivity and reducing assembly failure by unskilled workers.

The plurality of pillars 73 are members extending in the vertical direction, and are spaced apart from the plurality of battery cells 11. Each pillar 73 is formed of a metal material such as, for example, an aluminum alloy, and the lower and upper ends of each pillar 73 are fixedly supported by the lower end support member 20 and the upper end support member 50.

The lower support members 20 are generally rectangular board-shaped in which the first and second side surfaces 24 and 31 extend parallel to the Y axis, and the third and fourth side surfaces 38 and 39 extend parallel to the X axis. It is provided. The lengths of the first and second side surfaces 24 and 31 extending in a direction parallel to the Y axis are longer than the lengths of the third and fourth side surfaces 38 and 39 extending in a direction parallel to the X axis. The first and second side surfaces 24 and 31 are spaced by the same distance around the imaginary center line ML1 of the lower end support member 20 parallel to the Y-axis direction.

Like the lower end support member 20, the upper end support member 50 is also generally rectangular board-shaped, the first and second side surfaces 54 and 61 extending parallel to the Y axis, and the third and third extending parallel to the X axis. It has a fourth side (65, 66). The lengths of the first and second side surfaces 54 and 61 extending in the direction parallel to the Y axis are longer than the lengths of the third and fourth side surfaces 65 and 66 extending in the direction parallel to the X axis. The first and second side surfaces 54 and 61 are spaced by the same distance around the imaginary center line ML2 of the upper end support member 50 parallel to the Y-axis direction.

The lower support member 20 has first brackets 25, 32, 40 projecting outwardly from the first, second, third, and fourth sides 24, 31, 38, 39 . The lower end of the pillar 73 is fitted into the first brackets 25, 32, and 40 of the lower end supporting member 20 to be contacted and supported. The first bracket (25, 32, 40) of the lower end support member 20, the grooves (groove) (26, 33, 41) of the lower side of the pillar grooves (26, 33, 41) that are dug down from the upper side so as to fit And bolt holes 27, 34, and 42 aligned vertically with the pillar fitting grooves 26, 33, and 41. A bolt fastening hole 74 through which a bolt (not shown) penetrating the bolt through holes 27, 34 and 42 of the first brackets 25, 32 and 40 is fitted is formed at a lower end of the pillar 73.

The lower support member 20 further includes a flange 43 that protrudes outwardly from the third and fourth side surfaces 38 and 39, and the flange 43 penetrates the flange 43 in the vertical direction. A plurality of bolt through holes 44 are formed. A plurality of bolts (not shown) are fastened to the base (not shown) of the battery package 1 (see FIG. 1) through the bolt hole 44 of the flange 43, so that the battery module 10 is attached to the base. It is fixedly supported.

Like the lower end support member 20, the upper end support member 50 also has first brackets 55, 62, which protrude outward from the first, second, third, and fourth sides 54, 61, 65, 66. 67). The upper ends of the pillars 73 are fitted to the first brackets 55, 62, and 67 of the upper support member 50 to be supported in contact. The first bracket (55, 62, 67) of the upper support member (50), the pillar fitting grooves (56, 63, 68) that are dug up from the lower side so that the upper end of the pillar (73) is fitted, and the pillar fitting groove Bolt holes 57, 64, and 69 aligned with (56, 63, 68) up and down are formed. A bolt fastening hole 75 through which a bolt (not shown) penetrating the bolt through holes 57, 64 and 69 of the first brackets 55, 62 and 67 is fitted is formed at the upper end of the pillar 73.

The lower support member 20 further includes second brackets 28 and 35 protruding outward from the first side 24 and the second side 31. Bolt through holes 29 and 36 penetrating the second brackets 28 and 35 in the vertical direction are formed in the second brackets 28 and 35 of the lower support member 20. The pillar 73 does not contact the second brackets 28 and 35 of the lower support member 20.

The plurality of first brackets 25, 32, and 40 provided on the lower end support member 20 are formed at the same height as each other. That is, the plurality of first brackets 25, 32, and 40 provided on the lower end support member 20 have the same Z-axis coordinate values. The plurality of second brackets 28 and 35 provided on the lower end support member 20 are formed at the same height. That is, the plurality of second brackets 28 and 35 provided on the lower end support member 20 have the same Z-axis coordinate values. Meanwhile, the plurality of second brackets 28 and 35 provided on the lower end support member 20 are positioned lower than the plurality of first brackets 25, 32 and 40 provided on the lower support member 20. That is, the Z-axis coordinate values of the plurality of second brackets 28 and 35 provided on the lower support member 20 are Z of the plurality of first brackets 25, 32 and 40 provided on the lower support member 20. It is smaller than the axis coordinate value.

The second brackets 28 and 35 of the lower support member 20 are formed on opposite sides 24 and 31 of the side surfaces 24 and 31 where they protrude around the center line ML1 of the lower support member 20. It is disposed at a position symmetric to the first bracket (25, 32). In other words, the second bracket 28 protruding outward from the first side 24 of the lower support member 20 is a first bracket protruding outward from the second side 31 of the lower support member 20. (32) and the center line (ML1) is disposed in a symmetrical position around the center. The second bracket 35 protruding outward from the second side 31 of the lower end supporting member 20 is the first bracket 25 protruding outward from the first side 24 of the lower supporting member 20. And the center line ML1 at a symmetrical position.

In other words, the Y-axis coordinate values of the plurality of second brackets 28 protruding outward from the first side 24 of the lower end support member 20 are from the second side 31 of the lower end support member 20. The one-to-one correspondence with the Y-axis coordinate values of the plurality of first brackets 32 protruding outward is the same. In addition, the Y-axis coordinate values of the plurality of second brackets 35 protruding outward from the second side surface 31 of the lower end supporting member 20 are outside from the first side 24 of the lower supporting member 20. The one-to-one correspondence with the Y-axis coordinate values of the plurality of first brackets 25 protruding with the same.

The upper support member 50 further includes a second bracket 58 protruding outward from the first side 54. The second bracket 58 of the upper support member 50 is formed with a bolt through-hole 59 penetrating the second bracket 58 in the vertical direction. The pillar 73 is not in contact with the second bracket 58 of the upper support member 50.

The plurality of first brackets 55, 62, and 67 provided on the upper support member 50 are formed at the same height as each other. That is, the plurality of first brackets 55, 62, and 67 provided on the upper end support member 50 have the same Z-axis coordinate values. The plurality of second brackets 58 provided on the upper support member 50 are formed at the same height as each other. That is, the plurality of second brackets 58 provided on the upper support member 50 have the same Z-axis coordinate values. Meanwhile, the plurality of second brackets 58 provided on the upper support member 50 are positioned higher than the plurality of first brackets 55, 62 and 67 provided on the upper support member 50. That is, the Z-axis coordinate values of the plurality of second brackets 58 provided on the upper support member 50 are the Z-axis coordinates of the plurality of first brackets 55, 62 and 67 provided on the upper support member 50. Greater than the value

The second bracket 58 of the upper support member 50 is the first bracket 62 formed on the opposite side 61 of the side 54 protruding itself around the center line ML2 of the upper support member 50 And symmetrical positions. In other words, the second bracket 58 protruding outward from the first side 54 of the upper support member 50 is a first bracket protruding outward from the second side 61 of the upper support member 50. It is disposed at a position symmetrical about the 62 and the center line ML2. In other words, the Y-axis coordinate values of the plurality of second brackets 58 protruding outward from the first side 54 of the upper support member 50 are from the second side 61 of the upper support member 50. The one-to-one correspondence with the Y-axis coordinate values of the plurality of first brackets 62 projecting outward is the same.

The battery module 10 shown in FIGS. 3 and 4 includes a second bracket on the first and second sides 24 and 31 of the lower support member 20 and the first side 54 of the upper support member 50. (28, 35, 58), the second side 61 of the upper support member 50 is not provided with a second bracket. However, the battery module of the present invention is not limited to the embodiments shown in FIGS. 3 and 4, and the first and second side surfaces 24 and 31 of the lower support member 20 and the upper support member 50 If a second bracket protruding outward is provided on at least one of the first and second side surfaces 54 and 61, the present invention is included.

1 and 2 together, the battery package 1 includes a plurality of battery modules 10A, 10B, 10C, 10D, and 10E having the same configuration as the battery module 10 described with reference to FIGS. 3 and 4. It is provided. The plurality of battery modules 10A, 10B, 10C, 10D, and 10E are arranged adjacent to each other in a line along a direction parallel to the X axis. Specifically, the lower end supporting member 20 and the first side surfaces 24 and 54 of the upper supporting member 50 of the first battery module 10A are the lower supporting member 20 and the upper end of the second battery module 10B. The second side surfaces 31 and 61 of the support member 50 are disposed to face each other, and the lower side support members 20 and the first side surfaces 24 and 54 of the upper support member 50 of the second battery module 10B are disposed. Is disposed facing the lower support member 20 of the third battery module 10C and the second side surfaces 31 and 61 of the upper support member 50, and the lower support member 20 of the third battery module 10C ) And the first side surfaces 24 and 54 of the upper support member 50 face the lower side support members 20 and the second side surfaces 31 and 61 of the upper end support member 50 of the fourth battery module 10D. The first supporting surfaces 20 and 54 of the fourth battery module 10D and the lower side support members 20 of the fifth battery module 10E are provided with the first side surfaces 24 and 54 of the fifth battery module 10E. It is disposed to face the second side surfaces 31 and 61 of the upper support member 50.

In the battery package 1, a second bracket 28, 35, 58 provided in one battery module among a pair of battery modules 10A, 10B, 10C, 10D, and 10E arranged adjacent to each other is The first brackets (25, 32, 55, 62) provided in the battery module are disposed to overlap each other and are coupled to each other. Referring to FIG. 2, for example, the second bracket 28_A provided on the first side 24 of the lower end support member 20 of the first battery module 10A supports the lower end of the second battery module 10B. The first bracket 32_B provided on the second side 31 of the member 20 is disposed to overlap vertically. In addition, the second bracket 35_B provided on the second side 31 of the lower support member 20 of the second battery module 10B is the first of the lower support member 20 of the first battery module 10A. The first bracket 25_A provided on the side surface 24 is disposed to overlap vertically. In addition, the second bracket 58_A provided on the first side 54 of the upper support member 50 of the first battery module 10A is the second of the upper support member 50 of the second battery module 10B. The first bracket 62_B provided on the side 61 is disposed to be overlapped vertically.

Columns are provided in the column fitting grooves 26, 33, 41, 56, 63, and 68 of the first brackets 25, 32, 40, 55, 62, and 67 of the lower support member 20 and the upper support member 50. 73) the lower end and the upper end are fitted. The first bracket and the second bracket, which are arranged to overlap vertically in the adjacent battery modules 10A, 10B, 10C, 10D, and 10E of the battery package 1, are coupled by a bolt (not shown), and the bolt is the first 2 It is fixedly coupled to the pillar through the bracket and the first bracket.

For example, the second bracket 28_A of the lower end support member 20 of the first battery module 10A overlapped up and down, and the first bracket 32_B of the lower end support member 20 of the second battery module 10B. , And the lower end of the pillar 73 is coupled by a bolt (not shown). Specifically, the bolt penetrates the bolt through hole 29 of the second bracket 28_A, and the bolt through hole 34 of the first bracket 32_B, and the bolt fastening hole 74 of the lower end of the pillar 73 It is fitted to the screw (screw) is fastened to the lower end of the pillar (73).

The second bracket 35_B of the lower end supporting member 20 of the second battery module 10B overlapping up and down, the first bracket 25_A of the lower supporting member 20 of the first battery module 10A, and the pillar ( 73) is also coupled by a bolt (not shown). Specifically, the bolt penetrates the bolt through hole 36 of the second bracket 35_B, and the bolt through hole 27 of the first bracket 25_A, and the bolt fastening hole 74 of the lower end of the pillar 73 By being screwed into the screw, it is fixedly coupled to the lower end of the pillar 73.

The second bracket 58_A of the upper support member 50 of the first battery module 10A overlapped up and down, the first bracket 62_B of the upper support member 50 of the second battery module 10B, and the pillar ( 73) is also coupled by a bolt (not shown). Specifically, the bolt penetrates the bolt through hole 59 of the second bracket 58_A and the bolt through hole 64 of the first bracket 62_B, and the bolt fastening hole 75 of the upper end of the pillar 73 By being screwed into the screw, it is fixedly coupled to the upper end of the pillar 73.

In addition, the first brackets 55_A and 67_A of the upper support member 50 that do not overlap with the second bracket and the upper ends of the pillars 73 fitted to the first brackets 55_A and 67_A are bolts (not shown) ). Specifically, the bolt penetrates through the bolt hole 57 of the first brackets 55_A and 67_A and is screwed into the bolt fastening hole 75 at the upper end of the pillar 73 to be fixed by screwing on the upper end of the pillar 73 Combined. In addition, the first bracket 40_A of the lower end supporting member 20 that is not overlapped with the second bracket, and the lower end of the pillar 73 fitted to the first bracket 40_A are coupled by bolts. Specifically, the bolt penetrates the bolt through hole 41 of the first bracket 40_A and is screwed into the bolt fastening hole 74 at the lower end of the pillar 73 to be fixedly coupled to the lower end of the pillar 73. .

Meanwhile, referring to FIGS. 3 and 4 again, in the case of a battery package having a single battery module 10, the second bracket and the first bracket of the adjacent pair of battery modules 10 do not overlap. Accordingly, in this case, the first brackets 25, 32, 40 of the lower end supporting member 20 and the lower ends of the pillars 73 fitted to the first brackets 25, 32, 40, the first bracket It can be coupled by a bolt (not shown) through the bolt through holes (27, 34, 42) of (25, 32, 40) and screwed into the bolt fastening hole 74 at the lower end of the pillar 73. And, the first bracket (55, 62, 67) of the upper support member 50 and the upper end of the pillar 73 fitted to the first bracket (55, 62, 67), the first bracket (55, 62) , 67) through the bolt through holes (57, 64, 69) and fitted into the bolt fastening hole (75) at the upper end of the pillar (73) can be coupled by a screw fastening bolt (not shown).

The battery package 1 described above is configured by arranging and combining a plurality of battery modules 10 of one type. Therefore, it is possible to easily change the electric capacity of the battery package 1 by adding or subtracting the number of the battery modules 10. In other words, the battery cell 11 constituting the battery module 10, the lower end support member 20, the upper end support member 50, and the pillar 73 are designed and manufactured one by one, respectively, and the battery module 10 Since it is possible to manufacture the battery package 1 of various electric capacities by adding or subtracting the number, the production cost of the battery package 1 can be lowered, and the battery package 1 can be supplied in quick response to an order.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. Therefore, the true protection scope of the present invention should be defined only by the appended claims.

1: Battery package 10: Battery module
11: Battery cell 20: Lower support member
25,28,32,35,55,58,62: Bracket 50: Upper support member
73: column 80: module PCB

Claims (10)

A plurality of battery cells arranged in a matrix; A lower support member formed of electrically insulating plastic and having lower ends of the plurality of battery cells seated on an upper side; It is formed of an electrically insulating plastic, the upper end support member is seated on the lower side of the upper end of the plurality of battery cells; And, a plurality of pillars (pillar) for engaging and fixing between the upper support member and the lower support member;
The lower support member includes a plurality of first brackets protrudingly arranged to fit the pillars on one side and the other side thereof, and a plurality of second brackets protruding at different positions and heights from the plurality of first brackets. and,
The positions of the first bracket on one side of the lower support member and the second bracket on the other side are opposite, and the positions of the second bracket on one side of the lower support member and the first bracket on the other side are opposite,
A battery module characterized in that the other battery module is formed to be coupled to both sides of the battery module. According to claim 1,
The upper support member has a plurality of first brackets protrudingly arranged to fit the pillars on one side and the other side thereof, and a plurality of the upper support members are provided on at least one side of one side and the other side of the column. It has a plurality of second brackets protruding from different positions and heights of the first bracket of,
The position of the second bracket of the upper support member is opposite to the position of the first bracket protruding from the side opposite to the protruding side of the battery module. A plurality of battery cells arranged in a matrix; A lower support member formed of electrically insulating plastic and having lower ends of the plurality of battery cells seated on an upper side; It is formed of an electrically insulating plastic, the upper end support member is seated on the lower side of the upper end of the plurality of battery cells; And a plurality of pillars arranged to be spaced apart around the plurality of battery cells, the upper end being fixedly supported by the upper end supporting member, and the lower end being fixedly supported by the lower end supporting member.
One side of the lower end support member, the other side of the lower end support member, one side of the upper end support member, and the other side of the upper end support member is provided with a first bracket protruding outward to contact the pillar,
A second side that protrudes outwardly but does not contact the pillar on at least one side of one side of the lower end support member, the other side of the lower end support member, one side of the upper end support member, and the other side of the upper end support member Bracket is provided,
The second bracket, the battery module, characterized in that arranged in a position symmetrical to the first bracket formed on the opposite side about the center line spaced apart by the same distance from the side and the opposite side where the second bracket is formed. According to claim 3,
The second bracket is formed on the upper support member,
The second bracket formed on the upper support member, the battery module, characterized in that located higher than the first bracket formed on the upper support member. According to claim 3,
The second bracket is formed on the lower support member,
A battery module, characterized in that the second bracket formed on the lower support member is located lower than the first bracket formed on the lower support member. The method of claim 1 or 3,
A first electrode wire and a second electrode wire coated with insulation, one end of which is electrically connected to electric poles of upper and lower ends of the plurality of battery cells, respectively; And a module printed circuit board (PCB) that is electrically connected to the other end of the first electrode wire and the second electrode wire. The method of claim 6,
The module PCB is fixedly supported by the upper support member,
A wire through hole is formed in the upper support member so that the first electrode wire does not press against the upper end of the battery cell, and the first electrode wire and the second electrode wire penetrate the upper support member,
A battery module characterized in that the lower electrode support member is provided with a wire arrangement groove so that the second electrode wire is not pressed against the lower portion of the battery cell. The method of claim 7,
The battery module, characterized in that the other end of the first electrode wire and the second electrode wire, and the lower surface of the module PCB are detachably connected by a connector. A battery package having a plurality of battery modules according to any one of claims 1 to 8, wherein the plurality of battery modules are arranged adjacently in a line,
A battery package, characterized in that the second bracket provided on one battery module among the pair of battery modules disposed adjacent to each other is disposed to overlap and overlap with the first bracket provided on the other battery module. The method of claim 9,
The first bracket and the second bracket disposed to overlap the upper and lower are coupled by bolts,
The bolt is a battery package, characterized in that through the second bracket and the first bracket is fixedly coupled to the pillar.

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