KR20110044129A - Battery unit and battery pack therewith - Google Patents

Abstract

PURPOSE: A battery unit is provided to improve insulation and cooling properties between battery cells by employing an insulation wall equipped with a plurality of protrusions which is close to the battery cell. CONSTITUTION: A battery unit includes a battery cell(510), an insulation wall, and a support material. The insulation wall includes a plurality of protrusions which is close to the battery cell. The protrusions extend to at least a part of the gap of edges opposite to the insulation wall. The protrusions define the space between battery cells and the region between the protrusions.

Description

Battery unit and battery pack having same {Battery unit and battery pack therewith}

The present invention relates to a battery unit and a battery pack having the same, and more particularly, to a battery unit formed by stacking a plurality of unit battery cells, a battery unit covering and protecting a unit battery cell with a cell cover, and a battery pack having the same. It is about.

A rechargeable battery refers to a battery that can be charged and discharged unlike a primary battery that is not rechargeable. Secondary batteries are widely used in the field of advanced electronic devices such as cellular phones, notebook computers, camcorders, and are also used as automotive batteries.

The secondary battery includes an electrode assembly and an electrolyte solution. The electrode assembly includes a positive electrode plate, a negative electrode plate, and a separator. The electrolyte solution often contains lithium ions. The positive electrode plate and the negative electrode plate of the electrode assembly may be provided with electrode tabs respectively drawn out.

The electrode assembly may be accommodated in the case, and the electrode terminals may be exposed to the outside of the case. The electrode tab may be drawn out of the electrode assembly and electrically connected to the electrode terminal. The case may be cylindrical or angular.

The unit battery cells of the plurality of secondary batteries may be stacked horizontally or vertically to form a battery pack. Each unit battery cell needs to be protected from the outside in the battery pack, and insulation between secondary batteries stacked next to each other is required.

It is an object of the present invention to provide a battery unit including at least one unit battery cell and capable of improving insulation and cooling characteristics between respective unit battery cells and a battery pack having the same.

The present invention, a battery cell; And an insulating wall having a plurality of protrusions in contact with the battery cell, wherein the protrusions extend at least in part between opposite edges of the insulating wall, the space between the battery cells and the area between the protrusions. It provides a battery unit that defines.

The insulating wall may further include at least one support member protruding from an edge thereof to support the battery cell in the protrusion.

And at least one second insulating wall protruding from the at least one edge of the insulating wall in the same direction as the protrusion, wherein one or more of the second insulating walls support the battery cell in the protrusion. At least one support member protruding from the edge may be further provided.

The insulating wall may have openings aligned with the area between the protrusions along the opposite edges.

The openings disposed along the opposite edges may be aligned with each other.

The plurality of protrusions may be parallel to each other.

The insulating wall may have a plurality of second openings disposed in an area between the protrusions.

The plurality of second openings may have a plurality of slit openings extending along at least a portion between the openings along the opposite edges.

The plurality of second openings may include a plurality of holes spaced apart from each other between the openings along the opposite edges.

And at least one second insulating wall protruding from at least one of the opposite edges of the insulating wall in the same direction as the protrusions, wherein the at least one second insulating wall is aligned with the vent member of the battery cell. It may have seal openings.

The heat dissipation sheet may be further provided on one side of the insulating wall opposite to the side where the protrusions are located.

Another aspect of the invention, the frame; And a plurality of battery units disposed on the frame and stacked on each other, wherein each of the battery units includes an insulating wall including a battery cell and a plurality of protrusions contacting the battery cells. A battery pack extends at least in part between opposite edges of an insulating wall and defines a space between the battery cells and an area between the protrusions.

The insulating wall may further include at least one support member protruding from an edge thereof to support the battery cell in the protrusion.

Each of the battery units further includes at least one second insulating wall protruding from the at least one edge of the insulating wall in the same direction as the protrusion, wherein one or more of the second insulating walls is the protrusion. At least one support member protruding from the corner to support the battery cell may be further provided.

The insulating wall may have openings aligned with the area between the protrusions along the opposite edges.

The openings disposed along the opposite edges may be aligned with each other.

The plurality of protrusions may be parallel to each other.

The insulating wall may have a plurality of second openings disposed in an area between the protrusions.

The plurality of second openings may have a plurality of slit openings extending along at least a portion between the openings along the opposite edges.

The plurality of second openings may include a plurality of holes spaced apart from each other between the openings along the opposite edges.

Each of the battery units further comprises at least one second insulating wall protruding in the same direction as the protrusions from at least one of the opposite edges of the insulating wall, the at least one second insulating wall being the It may have openings aligned with the vent member of the battery cell.

Each of the battery units may further include at least one second insulating wall that protrudes from the insulating wall and extends between the opposite edges along the insulating wall.

At least one second insulating wall may include at least one second protrusion protruding outward from an outer surface of the battery cell, and the at least one second protrusion may be fastened to an insertion portion of the frame.

Each of the battery units may further include a heat dissipation sheet disposed on one side of the insulating wall opposite to the side where the protrusions are located.

The frame may include a plurality of openings aligned with a space between the battery cells.

According to the battery unit and the battery pack having the same according to the present invention, in the battery pack including at least one or more unit battery cells, it is possible to improve the insulation and cooling characteristics between each unit battery cell.

1 is a perspective view of a battery pack in which a plurality of battery cells are horizontally stacked in accordance with one embodiment of the present invention.
FIG. 2 is a perspective view schematically illustrating a battery unit in which a unit battery cell is accommodated in a cell cover in the battery pack of FIG. 1.
3 is a perspective view schematically showing an opposite side of the battery unit of FIG. 2.
4 is a cross-sectional view taken along the line IV-IV of the battery unit of FIG. 2.
5 is an exploded perspective view illustrating a battery cell and a cell cover separated from the battery unit of FIG. 2.
6 is a perspective view schematically illustrating two battery units stacked adjacent to each other in the battery pack of FIG. 1.
FIG. 7 is a perspective view schematically illustrating another embodiment of a battery unit in which a unit battery cell is accommodated in a cell cover in the battery pack of FIG. 1.
8 is a perspective view schematically illustrating a frame that supports a battery module formed by stacking a plurality of battery units in a battery pack of FIG. 1 from below.
9 is a perspective view schematically illustrating a cover plate in the battery pack of FIG. 1.
FIG. 10 is a view schematically illustrating that a battery unit is supported by a battery unit support of a side frame in the battery pack of FIG. 1.
FIG. 11 is a cross-sectional view taken along the line XI-XI of the battery pack of FIG. 10. FIG.
FIG. 12 is a schematic view of a part of the battery pack of FIG. 1 viewed from the bottom of the frame.

Hereinafter, with reference to the embodiments of the present invention shown in the accompanying drawings will be described in detail the configuration and operation of the present invention.

1 illustrates a battery pack 10 in which a plurality of battery cells 510 are stacked horizontally in accordance with one embodiment of the present invention. 2 illustrates a battery unit 500 in which a unit battery cell 510 is accommodated in a cell cover 520 in the battery pack 10. 3 shows an opposite side of the side shown in FIG. 2 of the battery unit 500. 4 is a view of the battery unit 500 of FIG. 2 viewed from a cross section taken along line IV-IV. In FIG. 5, the battery cell 510 and the cell cover 520 are separated from the battery unit 500.

Referring to the drawings, a battery unit 500 according to an embodiment of the present invention may include a battery cell 510, and a plurality of battery units 500 may be stacked to form one battery module 100. . In addition, the battery pack 10 may be formed by stacking the plurality of battery modules 100 vertically and / or left and right.

The battery pack 10 includes a battery module 100; Frame 200; Cover plate 300; And an assembly bar 400.

The battery module 100 may be a collection of battery units 500 formed by stacking a plurality of battery units 500 horizontally and / or vertically. The frame 200 may mount the battery module 100 thereon to support the battery module 100 from the bottom.

The cover plate 300 may be disposed at both ends of the battery module 100 to support the battery module 100 in which the unit battery units 500 are stacked in a horizontal direction. The assembly bar 400 may connect and support the plurality of battery units 500 stacked horizontally.

1 illustrates an embodiment in which the battery module 100 is formed by stacking a plurality of unit battery units 500 horizontally, but the present invention is not limited thereto. That is, unlike the embodiment illustrated in FIG. 1, each unit battery unit 500 may be stacked vertically to form a battery module 100, which is a collection of battery units 500.

In this case, the frame 200 mounts the battery module 100 thereon to support the battery module 100 from the side, the cover plate 300 supports the battery module 100 in the vertical direction, the assembly bar ( 400 may connect and support a plurality of battery units 500 stacked vertically. However, even when the plurality of unit battery units 500 are stacked vertically, features according to an embodiment of the present invention described below may be applied.

Meanwhile, each unit battery unit 500 stacked horizontally to form the battery module 100 may include a battery cell 510 and a cell cover 520. In this case, the cell cover 520 may be an insulating wall that insulates the battery cells 510 disposed adjacent to each other.

A plurality of battery cells 510 may be stacked in a horizontal direction to form a battery pack, and a conventional rectangular battery cell may be applied as shown in the drawing. However, the present invention is not limited thereto, and battery cells having various shapes including circular battery cells may be applied.

The battery cell 510 may be a conventional secondary battery. The secondary battery may include an electrode assembly and an electrolyte solution. The electrode assembly may include a positive electrode plate, a negative electrode plate, and a separator. The electrolyte may include lithium ions. The positive electrode plate and the negative electrode plate of the electrode assembly may be provided with electrode tabs respectively drawn out.

The electrode assembly may be accommodated in the case 511, and the electrode terminal 512 may be exposed to the outside of the case 511. The electrode tab may be drawn out of the electrode assembly and electrically connected to the electrode terminal 512. The case 511 may be cylindrical or rectangular.

A plurality of secondary batteries may be stacked horizontally or vertically to form the battery module 100. Secondary batteries stacked adjacent to each other in the battery module 100 may have electrode terminals 512 electrically connected to each other. In this case, the electrode terminals 512 of the neighboring secondary batteries may be electrically connected by the bus bar 600.

The cap plate 513 may be coupled to the opening of the case 511. The cap plate 513 is formed of a thin plate, and the cap plate 513 is formed with an electrolyte injection hole into which an electrolyte is injected, and the electrolyte injection hole may be sealed with a sealing plug 514 in a state where the electrolyte is injected.

In addition, a vent member 515 having a groove may be installed in the cap plate 513 so as to be broken according to a set internal pressure. The vent member 515 may be positioned such that the gas outlet 525 of the cell cover 520 corresponds to the vent member 515 when the battery cell 510 is mounted inside the cell cover 520.

The cell cover 520 may surround at least a portion of the unit battery cell 510 to protect the battery cell 510 from the outside. The cell cover 520 according to an embodiment of the present invention may improve insulation and cooling characteristics between each unit battery cell 510 in the battery unit 500 including at least one unit battery cell 510. Can be.

The cell cover 520 may include a cover body 521; Vertical ribs 522; A terminal insertion hole 523; Cell support 524; A gas outlet 525; And an assembly unit 526.

The cover body 521 surrounds at least a portion of the unit battery cell 510 to protect the battery cell from the outside. In this case, the cover body 521 may be an insulating wall that insulates adjacent battery cells 510 from each other. The insulating wall may have a plurality of protrusions in contact with the battery cell 510.

At least one vertical rib 522 is formed on one surface of the cover body 521 in the vertical direction so that the cover body 521 is spaced apart from the battery cell 510. In this case, the vertical ribs 522 may be a plurality of protrusions disposed to contact the battery cells 510 on at least one surface of the insulating wall.

In this case, the protrusions may extend at least a portion between opposite edges of the insulating wall, and may define a space between the protrusions and a space between adjacent battery cells 510.

The terminal insertion hole 523 penetrates the upper surface of the cover body 521 and is formed as a through hole so that the electrode terminals 512 of the battery cell 510 are inserted. The cell support part 524 supports the battery cell 510 stored in the cell cover 520 toward the inside of the cell cover 520.

In this case, the cell support 524 may include at least one support member protruding from an edge thereof so that the insulating wall supports the battery cell 510 with respect to the protrusion.

The gas discharge part 525 penetrates the upper surface of the cover body 521 at a position corresponding to the vent member 515 of the battery cell 510 accommodated in the cell cover 520 and is formed as a through hole. The assembly unit 526 is assembled with other battery units 500 stacked so that the mutual positions are fixed.

The cover body 521 protects the battery cell 510 from the outside by surrounding the at least one surface of the unit battery cell 510. In this case, at least one surface of the cover body 521 may be opened, and the battery cell 510 may be inserted or discharged into the cell cover 520 through the open surface.

The cover body 521 may be made of an insulating material. By forming the cover body 521 with an insulating material, the battery cells 510 accommodated in the cell cover 520 may be electrically insulated from other battery cells 510 stacked adjacent thereto.

To this end, the cover body 521 may be formed of a plastic material. Therefore, the battery cell 510 stored inside the cell cover 520 is insulated from other battery cells 510 stacked adjacent to each other by using a light and inexpensive material such as plastic, and the battery cell 510 stored therein is externally Protect from

In addition, the cooling passages for the unit battery cells 510 may be easily secured. In particular, it is possible to easily secure the cooling passages by the air flow between the adjacent unit battery cells 510. However, the present invention is not limited thereto, and the cover body 521 may be formed of various kinds of insulating materials in addition to plastic.

If an auxiliary wall made of aluminum or metal is inserted and anodized to make an air passage for insulation and cooling between unit battery cells, insulation cannot be guaranteed. However, when the cover body 521 is formed of an insulating material, insulation and cooling between adjacent battery cells 510 may be easily performed.

The cover body 521 may include a first surface 521a, a second surface 521b, an upper surface 521c, a lower surface 521d, and both side surfaces 521e. In this case, the first surface 521a may be the first insulating wall, and the upper surface 521c and / or the lower surface 521d may be the second insulating wall. The second insulating wall may protrude from at least one edge of the first insulating wall 521a in the same direction as the protrusion, for example the vertical rib 522. in this case,

One or more of the second insulating walls may further include at least one support member protruding from an edge thereof to support the battery cell 510 in the protrusion.

The first surface 521a is a support surface for supporting the battery cell 510 inserted into the cell cover 520. The second surface 521b is an open surface into which the battery cell 510 is inserted or discharged into the cell cover 520.

The upper surface 521c is a surface that protects the battery cell 510 from the upper side. The lower surface 521d is a surface for supporting the battery cell 510 from the lower side. Both sides 521e are surfaces that support and protect the battery cells 510 from the sides.

The first surface 521a may support the battery cells 510 inserted into the cell cover 520 and may be interposed between the battery cells 510 of the battery units 500 stacked adjacent to each other. Therefore, the battery cells 510 stacked adjacent to each other by the first surface 521a made of an insulating material may be spaced apart and insulated from each other by a predetermined interval. The first surface 521a may be a thin plate on which at least one vertical rib 522 is formed.

At least one vertical rib 522 is formed on one surface of the cover body 521, for example, the first surface 521a, so that the cover body 521 is spaced apart from the battery cell 510. In the embodiment shown in the figure, the vertical rib 522 may be formed on the inner surface of the first surface 521a. However, the present invention is not limited thereto, and the vertical rib 522 may be formed on the inner surface and / or the outer surface of the first surface 521a.

An air passage 532 may be formed in the spaced apart space between the first surface 521a and the battery cell 510 by the vertical rib 522 in the lower surface direction or from the lower surface to the upper surface direction. By allowing air to flow through the air passage 532, heat generated from the battery cell 510 or other components may be effectively discharged to the outside. At this time, the vertical ribs 522 may be disposed in parallel to each other, so as to efficiently secure the air passage.

Accordingly, the heat dissipation performance of the battery pack 10 may be improved. Accordingly, the electrical performance of the battery pack 10 can be improved. 5 and 6 show that air is circulated from the upper surface to the lower surface direction (arrow direction). However, the present invention is not limited thereto, and the positions of the air inlet 527 and the air outlet 528 may be interchanged with each other so that air may flow in the upper surface direction.

To this end, the insulating wall may be formed with aligned openings and regions between the protrusions along opposite edges. At this time, the openings may be aligned with each other so that air circulation may be smoothly performed.

For example, the cell cover 520 may have air inlets 527 and air outlets 528 as openings. The air inlet 527 may be formed at an edge where the top surface 521c or the top surface 521c and the first surface 521a of the cover body 521 meet. The air outlet 528 may be formed at an edge where the bottom surface 521d or the bottom surface 521d of the cover body 521 meets the first surface 521a.

Accordingly, the air passage 532 is formed from the air inlet 527 through the space between the battery cell 510 and the first surface 521a of the cover body 521 formed by the vertical ribs 522. It may be formed as an outlet 528. In addition, the slit 531 which is a slit-shaped opening in the space between the adjacent vertical ribs 522 of the first surface 521a of the cover body 521 so as to effectively discharge the heat generated by the battery cell 510. ) May be formed.

In addition, the cell cover 520 may further include a heat dissipation sheet 540. The heat dissipation sheet 540 may be attached to a surface of the cover body 521 facing the outside of the first surface 521a. Therefore, the heat dissipation sheet 540 may be in contact with the battery cells 510 of the battery units 500 stacked adjacent to each other.

In this case, heat generated from the battery cells 510 of the battery units 500 adjacent to each other may be discharged through the air passage 532 formed inside the cell cover 520 through the heat dissipation sheet 540. have. In this case, the battery unit stacked adjacently transferred through the heat dissipation sheet 540 by the slits 531 formed in the space between the adjacent vertical ribs 522 of the first surface 521 a of the cover body 521 ( Heat generated in the battery cell 510 of 500 may be effectively transferred to the air passage 532.

1 to 6, the slits 531 are formed in the space between adjacent vertical ribs 522 of the first surface 521a of the cover body 521, but the present invention is not limited thereto. . That is, as in the embodiment illustrated in FIG. 7, the battery cells 510 of the battery unit 500 that are stacked adjacent to each other through the plurality of through holes 531a formed on the first surface 521a in addition to the slit 531. Heat generated in) may be effectively transferred to the air passage 532.

The battery cell 510 may be inserted into or discharged into the cell cover 520 through the open second surface 521b. The first surface 521a or the heat dissipation sheet of the cell cover 520 of the battery unit 500 stacked adjacent to each other through the second surface 521b of the battery cell 510 stored inside the cell cover 520. And 540.

Meanwhile, the cell support part 524 may be provided on the second surface 521b. The cell support part 524 may be formed to protrude from the upper surface 521c and / or the lower surface 521c toward the battery cell 510 inserted into the cell cover 520. In this case, the cell support part 524 may be integrally formed with the upper surface 521c and / or the lower surface 521c.

The cell support part 524 may be formed to have elasticity so that the battery cell 510 may be inserted into the cell cover 520 even when the cell support part 524 protrudes from the upper surface 521c and / or the lower surface 521c. In this case, the cell support part 524 may elastically support the battery cell 510 accommodated in the cell cover 520 toward the inside of the cell cover 520.

The upper surface 521c may protect the battery cell 510 from the outside on the upper side. The terminal insertion hole 523 may be formed on the upper surface 521c to expose the electrode terminal 512 to the outside. The terminal insertion hole 523 is formed as a through hole through the upper surface 521c of the cover body 521 so that the electrode terminals 512 of the battery cell 510 are inserted to expose the electrode terminals 512 to the outside. Can be.

In addition, a gas discharge part 525 may be formed on the upper surface 521c to discharge gas generated in the battery cell 510. The gas discharge part 525 is formed in the form of a duct as shown in the drawing, and is connected to an external duct so that the gas generated in the battery cell 510 can be discharged to the outside.

To this end, the gas discharge part 525 may be formed as a through hole through the upper surface of the cover body 521 at a position corresponding to the vent member 515 of the battery cell 510 accommodated in the cell cover 520. have.

In addition, an air inlet 527 may be formed on the upper surface 521c to be connected to the air passage 532. The air inlet 527 may be formed of at least one through hole at an edge where the top surface 521c or the top surface 521c and the first surface 521a of the cover body 521 meet.

The lower surface 521d may protect and support the battery cell 510 from the lower side. When the battery module 100 is stacked on the frame 200, the lower surface 521d may contact the frame 200.

In addition, an air outlet 528 connected to the air passage 532 may be formed on the bottom surface 521d. The air outlet 528 may be formed of at least one through hole at a corner where the bottom surface 521d or the bottom surface 521d and the first surface 521a of the cover body 521 meet.

Both sides 521e may support and protect the battery cell 510 from the side. In addition, the battery units 500 stacked through the side surfaces 521e may be interconnected and supported.

Horizontal ribs 529 may be formed on inner surfaces of the side surfaces 521e that contact the battery cells 510. An inner surface contacting the battery cells 510 on both sides 521e by the horizontal ribs 529 is spaced apart from the battery cells 510 by a predetermined interval, and an air passage through which air can be distributed in the spaced space is formed. Can be. By the air passage, heat generated in the battery cell 510 may be more efficiently discharged.

To this end, the through hole 530 may be formed through the edge where the side surface 521e or side surface 521e and the first surface 521a of the cover body 521 meet. The through hole 530 may be connected to an air passage formed between the inner surface of the through hole 530 and the battery cell 510 of both side surfaces 521e.

The assembly unit 526 may be assembled with other battery units 500 that are stacked to fix positions of the battery units 500. The assembly unit 526 may be formed at both side surfaces 521e of the cell cover 520 to interconnect the battery cells 510 while supporting and fixing the battery cells 510 at the sides.

The assembling unit 526 may include an assembling plate 526a and an assembling hole 526b. The assembly plate 526a may be formed to protrude from the side surface 521e of the cell cover 520. In this case, the assembly plate 526a may be formed in a plate shape integral with the cell cover 520. The cell cover 520 in which the battery cells 510 are mounted may be stacked together with the other battery cells 510 by the assembly plate 526a.

The assembly hole 526b may be formed through the assembly plate 526a. The assembly bars 400 may be inserted through the assembly holes 526b formed in the assembly plates 526a of each of the battery units 500 stacked horizontally to be connected and supported by the plurality of battery units 500. That is, the assembly bar 400 may be stacked horizontally by supporting and fixing the plurality of battery units 500 from the side.

Accordingly, the battery module 100 may be formed by simply and easily stacking the battery units 500 through the assembly bar 400 and the assembly unit 526. In addition, the assembly bar 400 may firmly support and fix the plurality of battery units 500 to be stacked.

On the other hand, the cell cover 520 may be further provided with a side fixing part 550. The side fixing part 550 may be supported by the frame 200 to limit movement of the battery unit 500 in at least one direction. To this end, the side fixing part 550 may be formed on the side surface 521e of the cell cover 520.

The side fixing part 550 may be a hook-shaped fixing hook inserted into a hook insertion groove of the battery unit supporter 240 formed in the frame 200. In this case, the fixing hook of the side fixing part 550 is hooked to the hook insertion groove of the battery unit supporter 240, so that the cell cover 520 may be supported by the frame 200.

8 illustrates a frame 200 supporting a battery module 100 formed by stacking a plurality of battery units 500 in the battery pack 10 of FIG. 1. 9 shows a cover plate 300 in the battery pack 10.

FIG. 10 shows that the battery unit 500 is supported by the battery unit supporter 240 of the side frame 220 in the battery pack 10. FIG. 11 is a cross-sectional view taken along the line XI-XI in the battery pack 10 of FIG. 10. 12 illustrates a view of a part of the frame 200 from the bottom of the battery pack 10.

The frame 200 may mount the battery module 100 thereon to effectively support and fix the battery module 100 from the bottom. In addition, the frame 200 may effectively stack and support and fix the unit battery units 500. In addition, the air circulated from the unit battery unit 500 may be effectively discharged through the lower portion of the frame 200.

The frame 200 includes a lower frame 210 and a side frame 220; And cover plate assembly 230 may be provided.

The lower frame 210 may mount the battery module 100 thereon to support the battery module 100 from the bottom. The side frame 220 may extend from the lower frame 210 along the side of the battery unit 500 to support the battery module 100 at the lower side. The cover plate assembly 230 may be disposed at both ends of the lower frame 210 to support the cover plate 300.

The lower frame 210 may mount the battery module 100 thereon to support and fix the battery module 100 from the bottom. An air passage slit 212 may be further formed in the lower frame 210. The air passage slit 212 may be formed to penetrate the lower frame 210 in a slit shape at a position where each battery unit 500 of the lower frame 210 is disposed.

As illustrated in FIG. 12, the air passage slit 212 may be formed at a position corresponding to the air outlet 528 formed on the bottom surface of the battery unit 500. Therefore, the air discharged through the air passage 532 of each unit battery unit 500 can be effectively discharged through the air passage slit 212 formed in the lower frame 220. Accordingly, the heat dissipation performance of the battery cells 510 stacked and mounted horizontally on the frame 200 may be improved.

Meanwhile, as illustrated in FIG. 8, at least one through hole 213 may be formed in the lower frame 210. The through-holes 213 formed in the lower frame 210 may reduce the weight of the frame 200, and may effectively dissipate heat transferred from the battery unit 500.

The side frame 220 may extend along the side of the battery unit 500 from the lower frame 210 to support and fix the battery module 100 at the lower side. In order to effectively support each battery unit 500, a battery unit supporter 240 may be provided at a corresponding position of each battery unit 500 of the side frame 220.

The battery unit supporter 240 may be engaged with the side fixing part 550 of the cell cover 520 to support the battery unit 500. In this case, the battery unit supporter 240 may be a hook insertion groove into which the fixing hook of the side fixing part 550 may be inserted. In this case, the hook insertion groove of the battery unit supporter 240 may be hooked to the fixing hook of the side fixing part 550 so that the cell cover 520 may be supported by the lower frame 200.

Accordingly, the side fixing part 550 may be supported by the battery unit supporter 240 of the frame 200, thereby limiting the movement of the battery unit 500 in at least one direction. In the exemplary embodiment shown in the drawing, the hook insertion groove of the battery unit supporter 240 is inserted into the fixing hook of the side fixing part 550, so that the movement in the vertical direction of the battery unit 500 may be limited. Accordingly, each unit battery unit 500 may be effectively supported by the frame 200.

The cover plate assembly 230 may be disposed at both ends of the lower frame 210 to support and fix the cover plate 300. The cover plate assembly 230 fixes the cover plate 300 so that the battery modules 500 are stacked and efficiently supported by the frame 200 by the battery module 100 supported by both sides by the cover plate 300. You can do that.

A plurality of fastening holes 231 may be formed in the cover plate assembly 230 located at both ends of the lower frame 210 as shown in FIG. 8. The fastening hole 231 of the cover plate assembly 230 may be disposed at a position penetrating with the fastening hole 321 of the cover plate 300.

As illustrated in FIG. 1, the cover plate assembly 230 and the cover plate 300 may be penetrated through fastening holes 231 and 321 provided in the cover plate assembly 230 and the cover plate 300, respectively. ) Can be fastened and fixed. In this case, the fastening elements may be bolts and nuts which are fastened through the fastening holes 231 and 321. Accordingly, the cover plate 300 may be effectively supported and fixed to the cover plate assembly 230.

The cover plate 300 may be disposed at both ends of the battery module 100 to support and fix the battery module 100 in which the unit battery units 500 are horizontally stacked in the horizontal direction. The cover plate 300 is disposed at both ends of the battery module 100 in which the battery units 500 are stacked, and supports the battery modules 100 at both ends so that the battery units 500 maintain contact with each other. do.

Referring to FIG. 9, the cover plate 300 may include a side plate 310, a lower support part 320, an upper connection part 330, and a side connection part 340.

The side plate 310 is in contact with one surface of the battery unit 500 to support the battery unit 500 from the side. The lower support part 320 is supported by being seated on the cover plate assembly 230 of the lower frame 210 positioned below the cover plate 300. The upper connection part 330 supports another battery pack 10 on the top when the plurality of battery packs 10 are stacked vertically. The side connection part 340 supports another battery pack 10 on the side when the plurality of battery packs 10 are stacked side by side.

The side plates 310 are disposed at both ends of the battery module 100 in which the battery units 500 are stacked to support the battery modules 100 so that the battery units 500 maintain contact with each other at both ends. .

To this end, an assembly hole 311 may be formed in the side plate 310. The assembly hole 311 may be located where the assembly bar 400 is inserted into the side plate 310. The assembly bar 400 is inserted into the assembly hole 311 to be assembled and supported together with the battery module 100. In some embodiments, the assembly bar 400 is inserted into the assembly hole 311 so that the battery module 100 can be supported by the cover plate 300. Can be fixed.

The lower support part 320 may be seated on the cover plate assembly 230 corresponding to the seating part of the lower frame 210 positioned below the cover plate 300 to be supported and fixed. For this purpose, a fastening hole 321 may be formed in the lower support part 320.

The fastening hole 321 may be disposed to penetrate the fastening hole 231 formed in the cover plate assembly 230. The fastening hole 321 may be fastened by a fastening hole 231 of the cover plate assembly 230 and a fastening element 350 such as a bolt nut to fix the cover plate to the frame 200.

The upper connection part 330 may support and fix the other battery pack 10 on the top when the plurality of battery packs 10 are stacked vertically. The upper connection part 330 may be coupled to the lower surface of the cover plate assembly 230 of the lower frame 210 of the battery pack 10 stacked on the upper part.

To this end, a fastening hole 331 may be formed in the upper connection part 330. The fastening hole 331 may be disposed to penetrate the fastening hole 231 of the cover plate assembly 230 of the lower frame 210 of the battery pack 10 stacked thereon. The fastening hole 331 is fastened by a fastening element such as a bolt nut and the fastening hole 231 of the cover plate assembly 230, and the lower frame 200 of the battery pack 10 having the upper connection part 330 stacked thereon. ) May be fixed to the cover plate assembly 230.

The side connection part 340 may support and fix the other battery pack 10 on the side when the plurality of battery packs 10 are stacked side by side. The side connection part 340 may be coupled to the side connection part 340 of the battery pack 10 stacked on the side when the plurality of battery packs 10 are stacked side by side.

To this end, a fastening hole 341 may be formed in the side connection part 340. The fastening hole 341 may be disposed to penetrate the fastening hole 341 of the side connection part 340 of the battery pack 10 stacked on the side surface. The fastening hole 341 is fastened by a fastening hole 341 of the side connection part 340 of the battery pack 10 stacked on the side and a fastening element such as a bolt nut, such that the side connection part 340 is laminated on the side. The side connection portion 340 of the (10) can be fixed.

By the cover plate 300 according to an embodiment of the present invention, two or more battery packs 10 may be stacked while easily supporting each other up and down and / or from side to side to form an aggregate battery pack.

According to the present invention, in a battery pack including at least one unit battery cell, it is possible to improve insulation and cooling characteristics between each unit battery cell.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10: battery pack, 100: battery module,
200: frame, 300: cover plate,
400: assembly bar, 500: battery unit,
600: bus bar.

Claims (25)

Battery cells; And
And an insulating wall having a plurality of protrusions in contact with the battery cell,
And the protrusions extend at least in part between opposite edges of the insulating wall and define a space between the battery cells and an area between the protrusions. The method of claim 1,
And the insulating wall further comprises at least one support member protruding from an edge thereof to support the battery cell in the protrusion. The method of claim 1,
And at least one second insulating wall protruding from the at least one edge of the insulating wall in the same direction as the protrusion,
And at least one support member protruding from an edge thereof so that one or more of the second insulating walls support the battery cell in the protrusion. The method of claim 1,
And the insulating wall has openings aligned with the area between the protrusions along the opposite edges. The method of claim 4, wherein
And the openings arranged along the opposite corners are aligned with each other. The method of claim 1,
And a plurality of protrusions parallel to each other. The method of claim 4, wherein
The battery unit has a plurality of second openings in which the insulating wall is disposed in the region between the protrusions. The method of claim 7, wherein
And a plurality of slit openings extending in at least a portion between the openings along the opposite edges. The method of claim 7, wherein
And the plurality of second openings includes a plurality of holes spaced apart from each other between the openings along the opposite edges. The method of claim 1,
And at least one second insulating wall protruding in the same direction as the protrusions from at least one of the opposite edges of the insulating wall,
And the at least one second insulating wall has openings aligned with the vent member of the battery cell. The method of claim 1,
And a heat dissipation sheet disposed on one side of the insulating wall opposite to the side where the protrusions are located. frame; And a plurality of battery units disposed on the frame and stacked on each other,
Each said battery unit having an insulating wall having a battery cell and a plurality of protrusions in contact with said battery cell,
And the protrusions extend at least in part between opposite edges of the insulating wall and define a space between the battery cells and an area between the protrusions. The method of claim 12,
And the insulating wall further comprises at least one support member protruding from an edge thereof to support the battery cell in the protrusion. The method of claim 12,
Each of the battery units further comprises at least one second insulating wall protruding from the at least one edge of the insulating wall in the same direction as the protrusion,
And at least one support member protruding from an edge thereof so that one or more of the second insulating walls support the battery cell in the protrusion. The method of claim 12,
And the insulating wall has openings aligned with the area between the protrusions along the opposite edges. 16. The method of claim 15,
And the openings arranged along the opposite edges of the battery pack. The method of claim 12,
The battery pack of the plurality of protrusions are parallel to each other. The method of claim 14,
And a plurality of second openings in which the insulating wall is disposed in an area between the protrusions. The method of claim 18,
And a plurality of slit openings extending in at least a portion between the openings along the opposite edges. The method of claim 18,
And the plurality of second openings includes a plurality of holes spaced apart from each other between the openings along the opposite edges. The method of claim 12,
Each of the battery units further comprises at least one second insulating wall projecting in the same direction as the protrusions from at least one of the opposite edges of the insulating wall,
And the at least one second insulating wall has openings aligned with the vent member of the battery cell. The method of claim 12,
Each battery unit further comprising at least one second insulating wall protruding from the insulating wall and extending between the opposite edges along the insulating wall. The method of claim 22,
At least one second insulating wall has at least one second protrusion protruding outward from an outer surface of the battery cell,
And the at least one second protrusion is fastened to an insertion portion of the frame. The method of claim 12,
Each battery unit further comprises a heat dissipation sheet disposed on one side of the insulating wall opposite to the side where the protrusions are located. The method of claim 12,
And a frame having a plurality of openings aligned with a space between the battery cells.

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