KR20240012272A - Battery pack and vehicle including same - Google Patents

Abstract

A battery pack according to one aspect of the present invention includes a plurality of pouch-type battery cells stacked in at least one direction; a pack case storing the pouch-type battery cell in an internal space; and a cell cover that at least partially surrounds at least some of the pouch-type battery cells among the plurality of pouch-type battery cells in an internal space of the pack case, wherein the cell cover has a separation space between the wrapped pouch-type battery cells. It has a partition member extending from the inside of the cell cover and configured to partition the space.

Description

Battery pack and vehicle including same}

The present invention relates to a battery pack and a vehicle including the same, and more specifically, to a battery pack with excellent safety against thermal events and a vehicle including the same.

As technology development and demand for various mobile devices, electric vehicles, energy storage systems (ESS), etc. increase significantly, interest in and demand for secondary batteries as an energy source are rapidly increasing. Conventionally, nickel-cadmium batteries or nickel-hydrogen batteries were widely used as secondary batteries, but recently, lithium secondary batteries have almost no memory effect compared to nickel-based secondary batteries, allowing for free charging and discharging, a very low self-discharge rate, and high energy density. Batteries are widely used.

These lithium secondary batteries mainly use lithium-based oxide and carbon material as positive and negative electrode active materials, respectively. A lithium secondary battery includes an electrode assembly in which positive and negative electrode plates coated with the positive and negative electrode active materials are disposed with a separator in between, and an exterior material, that is, a battery case, that seals and stores the electrode assembly together with an electrolyte.

Generally, secondary batteries can be classified into can-type batteries in which the electrode assembly is built into a metal can and pouch-type batteries in which the electrode assembly is built in a pouch of an aluminum laminate sheet, depending on the shape of the exterior material.

Recently, battery packs have been widely used for driving or energy storage in medium to large-sized devices such as electric vehicles and ESS. A conventional battery pack includes one or more battery modules inside the pack case and a control unit that controls charging and discharging of the battery pack, such as a BMS (Battery Management System). Here, the battery module is configured to include a plurality of battery cells inside a module case. That is, in the case of a conventional battery pack, a plurality of battery cells (secondary batteries) are stored inside a module case to form each battery module, and one or more of these battery modules are stored inside the pack case to form a battery pack.

In particular, pouch-type batteries have advantages in many aspects, such as being light in weight and requiring less dead space when stacked, but they are vulnerable to external shocks and have somewhat poor assembly properties. Therefore, it is common to manufacture a battery pack by first modularizing a plurality of battery cells and then storing them inside a pack case.

However, in the case of conventional battery packs, they may be disadvantageous in terms of energy density, assembly, cooling, etc. due to modularization. Specifically, in the process of modularizing multiple battery cells by storing them inside a module case, the volume of the battery pack is unnecessarily increased or the space occupied by the battery cells is reduced due to various components such as the module case or stacking frame. You can. Since a battery module is first constructed by modularizing a plurality of battery cells and then the battery module is stored in a pack case, the manufacturing process of the battery pack becomes complicated. Since the module case is stored inside the pack case and the battery cells are stored inside the module case, when the heat from the battery cells stored inside the module case is discharged to the outside of the pack case through the module case, cooling efficiency is reduced and the cooling structure It can also get complicated.

Additionally, in the case of battery packs, one of the most important issues is safety. In particular, when a thermal event occurs in one of the plurality of battery cells included in the battery pack, propagation of this event to other battery cells needs to be suppressed.

If thermal propagation between battery cells is not properly suppressed, this may lead to thermal events in other battery cells included in the battery pack, causing larger problems such as ignition or explosion of the battery pack. Moreover, ignition or explosion occurring in the battery pack can cause significant damage to people or property in the surrounding area. Accordingly, in the case of such battery packs, a configuration capable of appropriately controlling the above-mentioned thermal events is required.

Accordingly, the present invention was created to solve the above problems, and the technical problem to be solved by the present invention is to provide a battery pack with excellent energy density, assemblyability, and/or cooling properties, and a vehicle including the same.

Another technical problem to be solved by the present invention is to provide a battery pack that can ensure excellent safety when a thermal event occurs and a vehicle including the same.

However, the technical problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned will be clearly understood by those skilled in the art from the description of the invention described below.

A battery pack according to one aspect of the present invention includes a plurality of pouch-type battery cells stacked in at least one direction; a pack case storing the pouch-type battery cell in an internal space; and a cell cover that at least partially surrounds at least some of the pouch-type battery cells among the plurality of pouch-type battery cells in an internal space of the pack case, wherein the cell cover has a separation space between the wrapped pouch-type battery cells. It has a partition member extending from the inside of the cell cover and configured to partition the space.

Here, the cell cover may be configured to support the pouch-type battery cell in an upright state.

Additionally, the cell cover may cover the upper side of the pouch-type battery cell, and the partition member may protrude from an inner top of the cell cover and extend downward.

Additionally, the cell cover may be configured to partially surround the pouch-type battery cell so that at least one side of the wrapped pouch-type battery cell is exposed toward the pack case.

Additionally, the pouch-type battery cell may include a storage portion in which the electrode assembly is stored and an edge portion around the storage portion, and the cell cover may be configured to cover a portion of the storage portion and an edge portion of the pouch-type battery cell.

Additionally, the cell cover may be provided to cover both sides of the storage portion and the upper edge of the wrapped pouch-type battery cell.

Here, the cell cover is an upper cover portion configured to surround the upper portion of the upper edge portion of the pouch-type battery cell, extends downward from one end of the upper cover portion, and covers the outside of one side storage portion of the wrapped pouch-type battery cell. It may include a first side cover portion that surrounds the first side cover portion, and a second side cover portion that extends downward from the other end of the upper cover portion and surrounds the outside of the other side storage portion of the wrapped pouch-type battery cell.

The thickness of the partition member may be thinner than the thickness of the upper cover, the first side cover, and the second side cover.

According to one embodiment, the separation space is formed between the upper cover part and the pouch-type battery cell.

At this time, the partition member may extend downward from the upper cover portion to the top of the pouch-type battery cell.

The pouch-type battery cell may be configured to be in close contact with the inner surfaces of the first and second side covers.

The cell cover may surround a plurality of pouch-type battery cells, and the partition member may be configured to partition each of the plurality of pouch-type battery cells.

In addition, the cell cover may surround a plurality of pouch-type battery cells, and the partition member may be configured to form a venting path corresponding to each of the plurality of pouch-type battery cells along a stacking direction of the plurality of pouch-type battery cells. there is.

The pouch-type battery cell has an accommodating portion in which the electrode assembly is stored and an edge portion around the accommodating portion, and the cell cover is configured to surround the accommodating portion and an upper edge portion of the wrapped pouch-type battery cell, and the upper The side edge portion is a sealing portion, the cell cover surrounds a plurality of pouch-type battery cells, and the partition member prevents the upper edge portion of one pouch-type battery cell from directly facing the upper edge portion of the other pouch-type battery cell. It may be covering it.

According to one embodiment, the cell cover surrounds a plurality of pouch-type battery cells, the cell cover exposes electrode leads protruding in the longitudinal direction of the pouch-type battery cell, and the plurality of pouch-type battery cells are They are stacked in the width direction perpendicular to the longitudinal direction, and the partition members have partition walls continuously constructed along the longitudinal direction and arranged to be spaced apart along the width direction.

Venting gas moves through the separation space, and the partition member may be configured to prevent the movement of the venting gas.

For example, the cell cover exposes electrode leads protruding in the longitudinal direction of the pouch-type battery cell, the venting gas moves along the longitudinal direction, and the partition member moves in the width direction perpendicular to the longitudinal direction. The partition walls continuously configured along the may be arranged to be spaced apart along the longitudinal direction.

At this time, the cell cover includes an upper cover portion configured to surround the upper portion of the upper edge portion of the pouch-type battery cell, a first side cover portion extending downward from one end of the upper cover portion, and a lower portion from the other end of the upper cover portion. It may include a second side cover portion extending in a direction, and the partition wall may be a plate in contact with the inner surface of the upper cover portion, the upper inner surface of the first side cover portion, and the upper inner surface of the second side cover portion.

Additionally, the partition wall may be provided in a plane direction perpendicular to the inner surface of the upper cover portion, or may be provided in a form inclined at an acute or obtuse angle.

The partition member may be a portion provided in an uneven shape on the inner surface of the cell cover.

At this time, the cell cover exposes electrode leads protruding in the longitudinal direction of the pouch-type battery cell, the venting gas moves along the longitudinal direction, and the uneven concave and convex portions extend along the longitudinal direction. They can be positioned alternately.

The cell cover may be composed of a single plate bent.

The cell cover may include an insulating coating layer on the inner side.

The battery pack includes a heat sink, and the pouch-type battery cell may be thermally coupled to the heat sink.

Additionally, thermal resin may be interposed between the pouch-type battery cell and the heat sink.

In addition, the battery pack according to the present invention may further include a control module stored in the internal space of the pack case and configured to control charging and discharging of the pouch-type battery cells.

Additionally, a vehicle according to another aspect of the present invention may include a battery pack according to the present invention.

The battery pack of the present invention is a Cell To Pack (CTP) concept, and by eliminating the module case, cooling performance and energy density can be improved.

According to one aspect of the present invention, a plurality of pouch-type battery cells can be stably stored inside a pack case without the need for a stacking frame such as a plastic cartridge or a separate module case.

In particular, according to one embodiment of the present invention, a configuration in which a plurality of pouch-type battery cells are stacked side by side in the horizontal direction while standing vertically can be easily implemented.

According to one aspect of the present invention, the energy density of a battery pack can be improved. Moreover, according to one embodiment of the present invention, since the battery cells are directly stored in the pack case without being modularized, it is possible to manufacture a battery pack that does not require a module case for the battery module. Accordingly, by reducing the space occupied by the module case, more battery cells can be placed inside the pack case. Therefore, the energy density of the battery pack is further improved. By assembling pouch-type battery cells directly into the pack case of the battery pack, space utilization of the battery pack can be maximized and energy capacity can be significantly improved.

Moreover, according to one aspect of the present invention, a pouch-type battery cell having a case made of a flexible material can be easily made into a sturdy form, so that a configuration in which the battery cells are directly stacked inside the pack case can be more easily implemented. Accordingly, the assemblyability and mechanical stability of the battery pack can be improved.

Additionally, according to one aspect of the present invention, the cooling efficiency of the battery pack can be further improved. In particular, in the case of one embodiment of the present invention, a portion of each pouch-type battery cell is directly exposed to the pack case, so heat from each pouch-type battery cell can be effectively discharged to the outside through the pack case.

Furthermore, according to one aspect of the present invention, when thermal runaway occurs in a specific battery cell, it is possible to effectively respond to the thermal event. In particular, in the case of the present invention, among the three elements (fuel, oxygen, and ignition source) that generate a flame, the accumulation or discharge of heat corresponding to the ignition source can be blocked or appropriately controlled. Furthermore, in the case of the present invention, in order to block heat accumulation and prevent flame emission, venting gas emission control, directional venting, and spark blocking can be implemented.

Additionally, according to one aspect of the present invention, even when a thermal event occurs, internal short circuit or structural collapse can be prevented.

According to the present invention, a battery pack with increased safety against thermal runaway, fire, explosion, etc., that is, thermal safety, is provided. In a battery pack containing a plurality of battery cells, when some battery cells generate heat, radio waves to surrounding battery cells can be reliably blocked.

According to one aspect of the present invention, when a battery cell thermally runs away, the flow of venting gas or flame is guided through the inner upper part of the cell cover and can be discharged to the outside through the opening of the cell cover. Accordingly, not only can the flow of venting gas or flame be guided in a more constant direction, but also the transition of venting gas or flame between adjacent battery cells can be minimized.

Additionally, according to one aspect of the present invention, the safety of the battery pack can be improved. In particular, according to one embodiment of the present invention, gas discharged from each battery cell can be smoothly discharged to the outside. Furthermore, according to an embodiment of the present invention, the discharge direction of gas or flame discharged from a battery cell can be controlled. Accordingly, thermal runaway propagation between adjacent battery cells can be effectively prevented.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the invention described later, so the present invention includes the matters described in such drawings. It should not be interpreted as limited to only .
1 is a schematic perspective view showing some components of a battery pack separated according to an embodiment of the present invention.
Figure 2 is an exploded perspective view schematically showing the configuration of a pouch-type battery cell and a cell cover stored inside a battery pack according to an embodiment of the present invention.
Figure 3 is an exploded perspective view schematically showing the configuration of a pouch-type battery cell and a cell cover stored inside a battery pack according to another embodiment of the present invention.
Figure 4 is a combined perspective view of the configuration of Figure 2.
Figure 5 is a cross-sectional view of Figure 4.
FIG. 6 is a perspective view of the cell cover shown in FIG. 2.
Figure 7 is a bottom perspective view of the cell cover shown in Figure 2.
Figure 8 is a diagram schematically showing a partial cross-sectional configuration of a battery pack according to an embodiment of the present invention.
Figure 9 is a perspective view schematically showing another cell cover that may be included in a battery pack according to an embodiment of the present invention.
FIG. 10 is a diagram schematically showing a cross-sectional configuration along the Y-axis direction when the cell cover shown in FIG. 9 surrounds the pouch-type battery cell.
FIG. 11 is a diagram schematically showing the cross-sectional configuration of the cell cover shown in FIG. 9 along the X-axis direction.
FIG. 12 is a view corresponding to FIG. 11 and is a view showing another embodiment of the cell cover of FIG. 9.
FIG. 13 is a view corresponding to FIG. 11 and is a view showing another embodiment of the cell cover of FIG. 9.
Figure 14 is a diagram schematically showing the configuration of a vehicle according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. Terms or words used in this specification and claims should not be construed as limited to their common or dictionary meanings, and the inventor may appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted with meaning and concept consistent with the technical idea of the present invention based on the principle that it is. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so at the time of filing the present application, various alternatives may be used to replace them. It should be understood that equivalents and variations may exist.

In the drawings, the size of each component or a specific part constituting the component is exaggerated, omitted, or schematically shown for convenience and clarity of explanation. Therefore, the size of each component does not entirely reflect the actual size. If it is determined that specific descriptions of related known functions or configurations may unnecessarily obscure the gist of the present invention, such descriptions will be omitted.

1 is a schematic perspective view showing some components of a battery pack separated according to an embodiment of the present invention. Figure 2 is an exploded perspective view schematically showing the configuration of a pouch-type battery cell and a cell cover stored inside a battery pack according to an embodiment of the present invention.

Referring to FIGS. 1 and 2 , the battery pack 10 according to an embodiment of the present invention includes a pouch-type battery cell 100, a pack case 300, and a cell cover 200.

The pouch-type battery cell 100 may include an electrode assembly, an electrolyte, and a pouch exterior material. A plurality of such pouch-type battery cells 100 may be included in the battery pack 10 .

And, these plurality of pouch-type battery cells 100 may be stacked in at least one direction. For example, referring to FIGS. 1 and 2 , a plurality of pouch-type battery cells 100 may be stacked and arranged in a horizontal direction, for example, in a left-right direction (Y-axis direction in the drawing). For example, if the direction along the long axis of the pouch-type battery cells 100 is called the longitudinal direction (X-axis direction), the pouch-type battery cells 100 are stacked in the width direction (Y-axis direction) perpendicular to this longitudinal direction. It can be. Additionally, the plurality of pouch-type battery cells 100 may be arranged in the front-back direction (X-axis direction), as shown in FIG. 1 . Furthermore, the plurality of pouch-type battery cells 100 may be arranged in the horizontal direction (Y-axis direction), forming multiple rows in the left-right and horizontal directions. For example, referring to FIG. 1 , a plurality of pouch-type battery cells 100 may be stacked with two cell rows arranged in the left and right directions in the front-back direction.

The battery pack according to the present invention can employ various types of pouch-type battery cells 100 known at the time of filing of the present invention, and therefore detailed description of the configuration of such pouch-type battery cells 100 will be omitted.

The pack case 300 has an empty space inside and can accommodate a plurality of pouch-type battery cells 100. For example, the pack case 300 may include an upper case 310 and a lower case 320, as shown in FIG. 1 . As a more specific example, the lower case 320 is configured in the form of a box with an open top and can accommodate a plurality of battery cells in the internal space. Additionally, the upper case 310 may be configured in the form of a cover that covers the upper opening of the lower case 320. At this time, the upper case 310 may be configured in the form of a box with an open bottom. In addition, the cell cover 200 along with a plurality of pouch-type battery cells 100 can be accommodated in the internal space of the pack case 300. The pack case 300 may be made of plastic or metal. In addition, the pack case 300 may adopt exterior materials of various battery packs known at the time of filing the present invention.

The cell cover 200 may be configured to surround the pouch-type battery cell 100 in the internal space of the pack case 300. That is, the cell cover 200 may be configured to cover at least some of the pouch-type battery cells 100 among the plurality of pouch-type battery cells 100 included in the battery pack 10. Furthermore, the cell cover 200 may be provided to at least partially cover the pouch-type battery cell 100.

In addition, the cell cover 200 may be configured to support the stacked state of the plurality of pouch-type battery cells 100 inside the pack case 300 through a structure that surrounds the battery cells. For example, a plurality of pouch-type battery cells 100 may be stacked in a horizontal direction, as shown in FIGS. 1 and 2 . At this time, the cell cover 200 may be configured to stably maintain the stacked state of the plurality of pouch-type battery cells 100 stacked in the horizontal direction.

According to this aspect of the present invention, a plurality of pouch-type battery cells 100 can be directly seated and stored inside the pack case 300 without a module case. In particular, in the case of the pouch-type battery cell 100, the exterior material is made of a soft material such as an aluminum laminate sheet pouch, so it is vulnerable to external shock and has low hardness. Therefore, it is not easy to store the pouch-type battery cell 100 itself inside the pack case 300 without storing it in the module case. However, in the case of the present invention, the plurality of pouch-type battery cells 100 are combined with the cell cover 200 in a state in which at least a portion is surrounded by the cell cover 200, and are directly stored inside the pack case 300. , the stacked state can be maintained stably.

Moreover, in the case of the present invention, a CTP type battery pack using the pouch-type battery cell 100 can be implemented more efficiently. That is, in the case of the present invention, rather than storing the pouch-type battery cell 100 inside a separate module case and storing this module case inside the pack case 300, the pouch-type battery cell 100 is directly placed in the pack case. (300) The battery pack 10 may be provided to be stored inside. At this time, at least one side of the pouch-type battery cell 100 may be exposed to the outside of the cell cover 200 and may be arranged to directly face the pack case 300.

Therefore, according to this aspect of the present invention, there is no need to additionally provide the battery pack 10 with a module case, a stacking frame, or fastening members such as bolts for maintaining the stacked state of the cells. Accordingly, the space occupied by other components, such as a module case or a stacking frame, or the resulting space for securing tolerances can be eliminated. Therefore, since the battery cells can occupy more space as the space removed, the energy density of the battery pack can be further improved.

Additionally, according to this aspect of the present invention, since a module case, stacking frame, bolts, etc. are not provided, the volume and weight of the battery pack can be reduced and the manufacturing process can be simplified.

Additionally, according to this aspect of the present invention, handling of the pouch-type battery cell 100 may become easier. For example, when storing a plurality of pouch-type battery cells 100 inside the pack case 300, the pouch-type battery cells 100 can be held by a jig or the like. At this time, the jig may hold the cell cover 200 surrounding the pouch-type battery cell 100 without directly holding the pouch-type battery cell 100. Accordingly, damage or breakage of the pouch-type battery cell 100 caused by the jig can be prevented.

Additionally, according to this aspect of the present invention, the cell cover 200 is coupled to the pouch-type battery cell 100, so that the pouch-type battery cell 100 can be effectively protected without a module case.

Figure 3 is an exploded perspective view schematically showing the configuration of a pouch-type battery cell and a cell cover stored inside a battery pack according to another embodiment of the present invention. With reference to FIGS. 2 and 3 , the cell cover 200 will be looked at in more detail.

The cell cover 200 may be configured to surround one or more pouch-type battery cells 100. For example, in the exemplary configuration of FIG. 2, one cell cover 200 is shown surrounding three pouch-type battery cells 100. In this way, the cell cover 200 may be configured to surround two or more pouch-type battery cells 100 together.

In the exemplary configuration of FIG. 3, one cell cover 200 is shown to surround one pouch-type battery cell 100. As shown here, one cell cover 200 may be configured to cover only one pouch-type battery cell 100. In this case, it can be said that the cell cover 200 is individually coupled to each pouch-type battery cell 100 among the plurality of pouch-type battery cells 100.

The cell cover 200 may be at least partially adhered to the outer surface of the pouch-type battery cell 100. For example, the cell cover 200 may have its inner surface adhered to the receiving portion of the pouch-type battery cell 100. The member for adhesion may be thermally conductive. Through this adhesion, the cell cover 200 is firmly coupled to the pouch-type battery cell 100 and helps discharge heat generated in the pouch-type battery cell 100 to the outside of the pouch-type battery cell 100. You can.

One or more cell covers 200 may be included in the battery pack 10 . The cell cover 200 may be configured to group and unitize a plurality of pouch-type battery cells 100 included in the battery pack. In this case, one cell cover 200 can be said to constitute one cell unit. Additionally, one cell unit may include one or multiple pouch-type battery cells 100.

For example, in Figure 2, one cell unit is shown, as indicated by U1. The battery pack 10 may include a plurality of cell units U1, and its scale can be easily expanded by increasing the number of cell units U1. This cell unit (U1) facilitates handling and installation of the battery cells 100 and prevents damage to the battery cells 100 during the manufacturing process of the battery pack 10 including a plurality of pouch-type battery cells 100. While preventing this, it has the effect of simplifying and reducing the weight of the structures required for mounting the battery cell 100.

In this case, it can be said that a plurality of cell covers 200 are included in the battery pack 10. For example, when the cell cover 200 is configured to surround one pouch-type battery cell 100, the battery pack 10 has the same number of cell covers 200 as the number of pouch-type battery cells 100. may be included. As another example, when the cell cover 200 is configured to surround two or more pouch-type battery cells 100, the battery pack 10 has a smaller number of cell covers 200 than the number of pouch-type battery cells 100. may be included.

The cell cover 200 may be configured to support a plurality of pouch-type battery cells 100 in an upright state. As shown in FIG. 2, each pouch-type battery cell 100 has two wide surfaces, and a sealing portion or folded portion of the pouch exterior material may be present at a narrow corner connecting the two wide surfaces. Therefore, it is generally difficult to stack the pouch-type battery cells 100 in an upright direction. However, in the battery pack according to the present invention, the cell cover 200 surrounds one or more pouch-type battery cells 100 and supports the erect state, that is, the standing state, of the wrapped pouch-type battery cells 100. It can be configured.

In particular, the cell cover 200 may be configured so that a plurality of pouch-type battery cells 100 can be stacked horizontally while standing upright (Z-axis direction in the drawing). For example, a plurality of cell covers 200 may be stacked on each other in a horizontal direction, and each cell cover 200 may be configured to surround one or more pouch-type battery cells 100. In this case, the cell cover 200 can stably maintain a configuration in which a plurality of pouch-type battery cells 100 are stacked side by side in the horizontal direction while each is standing upright.

In particular, the cell cover 200 can be configured to stand on its own in the internal space of the pack case 300. In other words, the cell cover 200 can be configured to maintain an upright position on its own without the help of other components provided in the battery pack 10, such as the pack case 300 or the pouch-type battery cell 100.

For example, the cell cover 200 may be directly seated on the bottom surface of the lower case 320 in the embodiment of FIG. 1 . At this time, a portion of the cell cover 200, such as the lower end of the cell cover 200 indicated as C1 in FIG. 2, may be seated in direct contact with the bottom surface of the lower case 320. In addition, when the lower end of the cell cover 200 is seated in this way, the cell cover 200 may be configured to maintain a stable seated state. At this time, if the cell cover 200 is made of a metal material with excellent rigidity such as steel, especially SUS material, the self-standing state can be maintained more stably. Therefore, in this case, the standing state of the pouch-type battery cell 100 can be more reliably supported.

The cell cover 200 may be configured to partially surround the pouch-type battery cell 100 so that at least one side of the wrapped pouch-type battery cell 100 is exposed to the outside. That is, the cell cover 200 may not completely surround the pouch-type battery cell 100 as a whole, but may only partially cover the pouch-type battery cell 100. In particular, the cell cover 200 may be configured so that at least one side of the pouch-type battery cell 100 is exposed toward the pack case 300. In this respect, the cell cover 200 may be referred to by terms such as a cell sleeve.

For example, referring to the exemplary configuration of FIG. 3, the cell cover 200 is configured to surround one pouch-type battery cell 100, and the wrapped pouch-type battery cell 100, that is, accommodated in the internal space The lower portion of the pouch-type battery cell 100 may not be surrounded by the cell cover 200. Accordingly, the lower portion of the pouch-type battery cell 100 is exposed toward the pack case 300 and can directly face the pack case 300. In particular, referring to the exemplary configuration of FIG. 1, the lower portion of the pouch-type battery cell 100 may be exposed toward the bottom of the lower case 320.

According to this implementation configuration of the present invention, the cooling performance of the battery pack 10 can be secured more effectively. In particular, according to the above-mentioned configuration, the pouch-type battery cell 100 and the pack case 300 can be in direct contact with each other through the open end of the cell cover 200. That is, one side of the pouch-type battery cell 100 disposed adjacent to the open end of the cell cover 200 may directly face or contact the pack case 300. Accordingly, the heat emitted from each pouch-type battery cell 100 is directly transferred to the pack case 300, and cooling performance can be improved. Additionally, in this case, since a separate cooling structure does not need to be provided between the pouch-type battery cell 100 and the pack case 300, efficient cooling performance can be implemented. In this case, there may not be space between the pouch-type battery cells 100 for a refrigerant such as air to flow in.

Additionally, in this case, at least one side of the cell cover 200 is opened, which may be advantageous in reducing the weight of the battery pack. For example, when the cell cover 200 is made of a material such as steel, if the lower end of the cell cover 200 is formed in an open form, the weight of the cell cover 200 can be reduced by the amount of the lower plate. Moreover, as shown in FIG. 1, the battery pack 10 may include many cell covers 200, and if all cell covers 200 do not have a lower plate and are formed in an open form, the battery pack 10 (10) The weight can be significantly reduced.

As shown in FIGS. 2 and 3, each pouch-type battery cell 100 may be provided with a storage portion indicated by 'R' and an edge portion indicated by 'E1 to E4. Here, the storage portion R may be a portion that accommodates an electrode assembly composed of a positive electrode plate and a negative electrode plate stacked with a separator interposed therebetween. Additionally, electrolyte solution may be stored in this storage portion (R). Additionally, the edge portions E1 to E4 may be arranged to surround the receiving portion R.

In particular, the edge portions E1 to E4 may be sealing portions in which the pouch exterior material, which is the case of the pouch-type battery cell 100, is sealed. For example, in the implementation configuration of FIGS. 2 and 3, four edge portions E1 to E4 are provided, and with respect to the storage portion R, the upper edge, the lower edge, the front edge, and the rear, respectively. It can be said to be located at the side edge. At this time, all four edge parts (E1 to E4) may be sealing parts. Alternatively, some of the four edge parts (E1 to E4) may be configured in a folded form rather than a sealing part. For example, in the implementation configuration of FIGS. 2 and 3, the upper edge portion E1, the front edge portion E3, and the rear edge portion E4 are all sealing portions, but the lower edge portion E2 may be a portion where the pouch exterior material is folded. For example, the upper edge portion E1 may be a so-called Double Side Folding (DSF) portion as a sealing portion of the pouch-type battery cell 100, and the lower edge portion E2 may be a pouch-type battery cell 100. It may be an unsealed portion of the battery cell 100.

Here, a battery cell in which all four edge portions (E1 to E4) are sealed can be referred to as a four-side sealing cell, and a battery cell in which three edge portions (E1, E3, and E4) are sealed can be referred to as a three-side sealing cell. there is.

In this configuration, the cell cover 200 is configured to cover a portion of the receiving portion (R) and the edge portions (E1 to E4) of the pouch-type battery cell 100, which may be a 4-side sealing cell or a 3-side sealing cell. You can. Furthermore, the cell cover 200 may be provided to cover both sides and the upper edge portion E1 of the storage portion R with respect to one or more pouch-type battery cells 100 accommodated and wrapped therein. .

For example, as shown in FIG. 3, when one cell cover 200 is configured to surround one pouch-type battery cell 100, the cell cover 200 covers the same pouch-type battery cell 100. Surfaces on both sides of the receiving portion (R) (e.g., the left and right surfaces of the same receiving portion (R)), and a portion of the edge portion of the pouch-type battery cell 100, especially the upper edge portion located at the upper side edge. It may be configured to surround (E1) from the outside.

As another example, when one cell cover 200 is configured to surround a plurality of pouch-type battery cells 100, for example, a plurality of battery cells arranged in the left and right directions, the outer surface of the storage portion of the outermost battery cell, It may be configured to surround one edge portion of the entire battery cell. As a more specific example, as shown in FIG. 2, when one cell cover 200 is configured to surround three pouch-type battery cells 100 stacked in the left and right directions, the cell cover 200 is attached to the left battery. It may be configured to surround the left surface of the storage portion of the cell, one edge portion of the left battery cell, one edge portion of the right battery cell, and the right surface of the storage portion of the right battery cell.

In the illustrated example, the cell cover 200 partially covers the pouch-type battery cell 100 to form an opening where at least one side, particularly the lower side, of the wrapped pouch-type battery cell 100 is exposed toward the pack case 300. It's wrapped around. According to one aspect of the present invention, the cooling efficiency of the battery pack 10 can be further improved. In particular, in the case of one embodiment of the present invention, a portion of each pouch-type battery cell 100 may be directly exposed to the pack case 300, so that the heat of each pouch-type battery cell 100 is transmitted to the pack case 300. It can be effectively discharged to the outside.

In addition, according to this implementation configuration, a configuration that supports and protects one or more pouch-type battery cells 100 can be easily implemented as a single cell cover 200. In addition, according to the above-mentioned configuration, a process of handling one or more pouch-type battery cells 100 through the cell cover 200 can be easily and safely performed. Moreover, according to the above-mentioned configuration, one cell cover 200 can face the surfaces of the two storage portions R with respect to the pouch-type battery cell 100 accommodated therein. Accordingly, cooling performance between the storage portion R and the cell cover 200 can be further improved. In particular, in this case, surface cooling is implemented through the large surface of the storage portion (R), so cooling efficiency can be improved.

In particular, the cell cover 200 may be configured to surround an edge portion not provided with an electrode lead among several edge portions of the pouch-type battery cell 100 accommodated therein. For example, referring to the exemplary configuration shown in FIGS. 2 and 3, the pouch-type battery cell 100 may be provided with two electrode leads 110, that is, a positive lead and a negative electrode lead. At this time, the two electrode leads may protrude in the longitudinal direction of the pouch-type battery cell 100. For example, two electrode leads may be located on the front edge E3 and the rear edge E4, respectively. At this time, the cell cover 200 may be configured to surround one of the two edge parts E1 and E2 excluding the front edge part E3 and the rear edge part E4.

The pouch-type battery cell 100 may be said to be formed approximately hexahedron. Additionally, electrode leads 110, that is, a negative electrode lead and a positive electrode lead, may be formed on two of the six surfaces. Additionally, the cell cover 200 is provided to cover at least a portion of three of the four sides of the six-sided pouch-type battery cell 100 except for the two sides on which the electrode leads 110 are formed. In this way, the cell cover 200 may be configured so that openings are formed on both sides corresponding to the electrode lead 110.

According to this implementation configuration of the present invention, the discharge direction of flame, etc. can be guided to the opening of the cell cover 200. For example, according to the above-described configuration, the front and rear sides of the cell cover 200 where the electrode lead 110 is located are open, so flames, etc. can be discharged in these open directions. In particular, when the cell cover 200 is configured with the front and back open as described above, side directional venting can be easily implemented. Alternatively, when the bottom or top of the cell cover 200 is configured to be open, directional venting may be performed toward the open side (open end) of the bottom or top of the cell cover 200.

According to this embodiment of the present invention, a structure that supports and protects one or more battery cells can be easily implemented as a single cell cover 200. In particular, according to the above embodiment, the lower edge portion E2 is located adjacent to the open end of the cell cover 200, is not surrounded by the cell cover 200, and faces the pack case 300, There may be direct face-to-face contact with the case 300. Accordingly, heat from the pouch-type battery cell 100 wrapped by the cell cover 200 can be quickly and smoothly discharged toward the pack case 300 below. Accordingly, the cooling performance of the battery pack 10 can be secured more effectively.

In particular, this configuration can be implemented more effectively when cooling is mainly performed at the bottom of the pack case 300. For example, in the case of a battery pack mounted on an electric vehicle, cooling may occur mainly at the bottom of the pack case 300 because it is mounted at the bottom of the vehicle body. At this time, as in the above embodiment, when the lower edge portion E2 of each pouch-type battery cell 100 is in face-to-face contact with the pack case 300, the pack case 300 is separated from each pouch-type battery cell 100. Heat is quickly transferred to the side, and cooling performance can be further improved.

In addition, according to the above-mentioned configuration, when high-temperature gas or flame is discharged from the pouch-type battery cell 100 in a situation such as thermal runaway, it is possible to effectively prevent the discharged gas or flame from heading toward the upper side. In particular, when a passenger is located on the upper side of the battery pack 10, such as in an electric vehicle, according to the above-mentioned configuration, it is possible to suppress or delay gas or flame from heading toward the passenger.

Figure 4 is a combined perspective view of the configuration of Figure 2.

As shown in FIGS. 2 and 4 , the cell unit U1 may further include a busbar frame 170 and an insulating cover 180.

The bus bar frame 170 supports the electrode lead 110 of at least one pouch-type battery cell 100 covered by the cell cover 200, and connects this electrode lead 110 to another pouch-type battery cell 100. ) may be configured to be electrically connected to the electrode lead 110. In this case, the bus bar frame 170 may be provided with a terminal electrically connected to the electrode lead 110.

The insulating cover 180 may be configured to prevent short circuit of the electrode lead 110 or bus bar. For this purpose, the insulating cover 180 may be made of polymer synthetic resin with insulating properties.

Moreover, when the electrode leads 110 are provided on both sides of the pouch-type battery cell 100, the bus bar frame 170 and the insulating cover 180 may also be included on both sides where the electrode leads 110 are provided. . For example, as shown in FIGS. 2 and 4, when the electrode lead 110 protrudes both on the front side (X-axis direction in the drawing) and on the rear side (-X-axis direction in the drawing), the bus bar frame 170 and the insulating cover 180 may also be located on both the front and rear sides.

Meanwhile, in the battery pack according to the present invention, TIM (Thermal Interface Material) may be interposed to increase heat transfer performance between different components. For example, between the pouch-type battery cell 100 and the cell cover 200, between the cell cover 200 and the pack case 300, and/or between the pouch-type battery cell 100 and the pack case 300. TIM can be filled. In this case, the cooling performance of the battery pack can be further improved. TIM is intended to reduce contact thermal resistance between members. In battery packs where cooling is important, it is necessary to improve the thermal performance of the entire system by using materials that can minimize contact thermal resistance. TIMs can be diverse, including thermally conductive grease, thermal sheets, thermal pads, thermally conductive adhesives, and PCMs (phase change materials). For a specific example, the TIM may be any one of a thermally conductive silicone-based bond, a thermally conductive silicone pad, and a thermally conductive acrylic bond. Heat-dissipating silicone-based adhesives and heat-dissipating acrylic adhesives are commercially available in one-component or two-component types and can be applied between different components by coating or injection. The heat dissipating silicone pad includes a base film such as double-sided tape and release paper on the top and bottom of the pad, and can be applied between different components using an adhesive method after removing the release paper. Heat-dissipating silicone-based adhesives, heat-dissipating silicone pads, and heat-dissipating acrylic adhesives have higher thermal conductivity than general adhesives, so they can further increase the amount and speed of heat transfer between different components. Therefore, according to this embodiment of the present invention, the heat dissipation performance of the pouch-type battery cell 100 can be further improved, and the cooling performance of the battery pack 10 can be further improved.

As seen in FIGS. 2 to 4, the cell cover 200 can be said to be formed in a shape roughly similar to the letter n. And, through this shape, the cell cover 200 covers the pouch-type battery cell 100 housed inside, excluding the front and rear sides where the electrode lead 110 protrudes, and other parts except the lower side. It can be said that it is composed of: That is, the cell cover 200 may be provided to cover the outer and upper sides of the housing portion (R) of the pouch-type battery cell 100 accommodated therein.

Figure 5 is a cross-sectional view of Figure 4. FIG. 6 is a perspective view of the cell cover shown in FIG. 2. Let's look at a preferred embodiment of the cell cover 200 with reference to FIGS. 2 to 6.

More specifically, the cell cover 200 may include an upper cover part 220, a first side cover part 230, and a second side cover part 240, as shown in FIGS. 2 to 6. there is. In addition, the cell cover 200 has a separation space (S) between it and the pouch-type battery cell 100, and a partition member 210 extends from the inside of the cell cover 200 and is configured to partition the separation space (S). ) may include. Venting gas may be discharged into the separation space (S). There may be more than one partition member 210.

The pouch-type battery cell 100 is light, has a low possibility of electrolyte leakage, and has flexibility in shape, so it has the advantage of being able to implement a secondary battery of the same capacity with a smaller volume and mass. Because there is a risk of explosion, ensuring safety is one of the important tasks. Overheating of the pouch-type battery cell 100 occurs for various reasons, one of which is when an overcharge exceeding the limit flows through the pouch-type battery cell 100. When overcurrent flows, the pouch-type battery cell 100 generates heat by Joule heat, so the internal temperature of the pouch-type battery cell 100 rapidly increases. A rapid rise in temperature may cause a decomposition reaction of the electrolyte and generate gas. This may cause a swelling phenomenon, a type of swelling phenomenon, due to increased pressure inside the pouch exterior material, which may cause serious problems such as secondary battery explosion. When gas is generated inside the pouch-type battery cell 100 due to such overcurrent as well as exposure to high temperature, external impact, etc., it is necessary to ensure the safety of the secondary battery by effectively discharging the gas. Venting is the process of discharging gas generated inside a secondary battery to the outside. The cell cover 200 included in the battery pack 10 according to an embodiment of the present invention is configured to allow venting gas to be discharged into the separation space (S) between the pouch-type battery cells 100 and the secondary battery. ensures safety.

Here, the upper cover portion 220 may be configured to surround the upper portion of the upper edge portion E1 of the pouch-type battery cell 100 accommodated therein. In particular, the portion (cover portion) located between the two side cover portions of the cell cover 200 and the side of the pouch-type battery cell 100 facing the portion may be spaced apart from each other by a predetermined distance. And, a separation space (S) is formed between the upper cover part 220 and the pouch-type battery cell 100. This separation space (S) may be configured in an empty form.

For example, the upper cover portion 220 may be configured to be spaced apart from the upper edge portion E1 of the pouch-type battery cell 100. More specifically, referring to the implementation drawing of FIG. 5, the lower surface (inner surface) of the upper cover part 220 and the side part of the pouch-type battery cell 100 disposed adjacent to the upper cover part 220 are each other. They may be spaced apart by a predetermined distance (D). And, at least a portion of this separation space (S) may be configured as an empty space.

According to this implementation configuration of the present invention, a path through which venting gas, etc. moves can be provided due to the empty space formed between the side of the pouch-type battery cell 100 and the cell cover 200. For example, when venting gas is generated from the pouch-type battery cell 100 accommodated inside the cell cover 200 due to thermal runaway, etc., the generated venting gas is generated at the upper edge portion adjacent to the upper cover portion 220. It can move in the front-back direction (in other words, longitudinal direction) through the empty space between (E1) and the upper cover part 220. Accordingly, the internal pressure of the cell cover 200 can be prevented from increasing, and efficient venting control, such as guiding the discharge direction of the venting gas, can be achieved.

For this configuration, in particular, as shown in FIG. 6, the cell cover 200 may be configured so that the height of both sides is higher by m1 than the height of the pouch-type battery cell 100. Here, m1 may be set to D or higher.

For example, at least one pouch-type battery cell 100 is disposed between the first side cover part 230 and the second side cover part 240 of the cell cover 200, and is connected to the upper cover part 220. It may be arranged to be spaced apart from the upper cover part 220 by m1 so that a predetermined space is formed therebetween. Then, the distance (D) between the upper cover part 220 and the side of the pouch-type battery cell 100 is spaced apart from the upper cover part 220 by an amount equal to m1 to form a separation space (S), and the pouch-type battery cell 100 can be spaced apart from the upper cover part 220 by an amount equal to m1. The lower side of the battery cell 100 and the lower side of the cell cover 200 may be placed on the same plane. As another example, at least one pouch-type battery cell 100 is disposed between the first side cover part 230 and the second side cover part 240 of the cell cover 200, and is connected to the upper cover part 220. It may be arranged to be spaced apart from the upper cover part 220 by D so that a predetermined space is formed therebetween. Then, the lower side of the cell cover 200 may protrude further by m1-D than the lower side of the pouch-type battery cell 100.

The pouch-type battery cell 100 may be configured to be in close contact with the inner surfaces of the first side cover portion 230 and the second side cover portion 240. In this case, at least one pouch-type battery cell 100 may be adhered and fixed to the inner surfaces of the first side cover part 230 and the second side cover part 240. The member for adhesion may be thermally conductive. Through this adhesion, the cell cover 200 is firmly coupled to the pouch-type battery cell 100 and makes thermal contact with the pouch-type battery cell 100, so that the heat generated from the pouch-type battery cell 100 is transferred to the pouch-type battery cell 100. (100) It can be helpful in discharging it to the outside. In addition, the gap between the pouch-type battery cell 100 and the upper cover part 220 can be maintained, making it possible to maintain the separation space (S).

The upper cover part 220 may be configured in a flat shape. In this case, the upper cover portion 220 is formed in a straight horizontal cross-section and can surround the upper edge portion E1 of the pouch-type battery cell 100 in a straight line from the outside.

The first side cover part 230 may be configured to extend downward from one end of the upper cover part 220. For example, the first side cover part 230 may be configured to extend long from the left end of the upper cover part 220 in a downward direction (-Z axis direction in the drawing). Furthermore, the first side cover portion 230 may be formed in a flat shape. At this time, the first side cover part 230 may be configured in a bent form from the upper cover part 220.

And, the first side cover portion 230 may be configured to surround the outside of one side storage portion (R) of the pouch-type battery cell 100 accommodated therein. For example, when one pouch-type battery cell 100 is accommodated in the cell cover 200, the first side cover portion 230 covers the left surface of the receiving portion (R) of the accommodated pouch-type battery cell 100. It can be configured to wrap from the left side. Here, the first side cover part 230 may be in direct contact with the outer surface of the receiving part (R).

The second side cover part 240 may be positioned to be spaced apart from the first side cover part 230 in the horizontal direction. And, the second side cover part 240 may be configured to extend downward from the other end of the upper cover part 220. For example, the second side cover part 240 may be configured to extend downward from the right end of the upper cover part 220. Moreover, the second side cover part 240 may also be configured in a flat shape like the first side cover part 230. At this time, the second side cover part 240 and the first side cover part 240 can be said to be arranged parallel to each other while being spaced apart in the horizontal direction.

And the second side cover portion 240 may be configured to surround the outside of the other side storage portion (R) of the pouch-type battery cell 100 accommodated therein. For example, when one pouch-type battery cell 100 is accommodated in the cell cover 200, the second side cover portion 240 covers the right surface of the receiving portion (R) of the accommodated pouch-type battery cell 100. It can be configured to wrap from the right side. Here, the second side cover portion 240 may be in direct contact with the outer surface of the receiving portion (R).

In the above-mentioned configuration, the internal space may be limited by the upper cover part 220, the first side cover part 230, and the second side cover part 240. Additionally, the cell cover 200 can accommodate one or more battery cells 100 in this limited internal space.

In addition, in the above embodiment, the cell cover 200 has one side with respect to the internal space between the first side cover part 230 and the second side cover part 240, which are vertically parallel to each other. It may be closed and the remaining side may be open. For example, the space between the first side cover part 230 and the second side cover part 240 is closed on the upper side by the upper cover part 220, and the front, rear, and lower sides have open ends. can be formed. At this time, the front edge portion E3 and the rear edge portion E4, where the electrode lead 110 is located, are disposed adjacent to the front open end and the rear open end, respectively, and the lower edge portion E2 is located at the lower end. It may be placed adjacent to the side open end.

In addition, in the above embodiment, as indicated by C1 in FIGS. 2 and 6, an end C1 that is not connected to the upper cover portion 220 among the ends of the first side cover portion 230 and a second side cover portion ( Among the ends of 240, the end C1 that is not connected to the upper cover part 220 forms an opening through which the lower side of the pouch-type battery cell 100 is exposed toward the pack case 300.

The lower ends (C1) of the first side cover part 230 and the second side cover part 240 may contact the bottom surface of the pack case 300. In particular, the contact configuration between the lower end C1 of the first side cover part 230 and the second side cover part 240 and the pack case 300 may be formed in a shape extending long in the front-back direction. . According to this implementation configuration, the self-standing configuration of the cell cover 200, which can maintain the pouch-type battery cell 100 accommodated therein in an upright state, can be implemented more stably.

Moreover, the first side cover part 230 and the second side cover part 240 may have the same height. That is, the first side cover part 230 and the second side cover part 240 may have the same length extending downward from the upper cover part 220. In this case, the self-standing configuration of the cell cover 200 can be more easily achieved.

Meanwhile, to describe again the cell cover 200 and the pouch-type battery cell 100 according to an embodiment of the present invention, the upper cover portion 220 is the upper edge portion (E1) of the pouch-type battery cell 100. Can face and can surround the upper edge portion (E1) together with the first side cover portion 230 and the second side cover portion 240.

In addition, the cross-sectional area of the first side cover part 230 and the second side cover part 240 is that of the pouch-type battery cell 100 where the first side cover part 230 and the second side cover part 240 face each other. It is provided larger than the cross-sectional area to prevent the storage part (R) from being exposed to the outside, thereby ensuring maximum safety.

In particular, the pouch-type battery cell 100 may include a sealed portion and an unsealed portion as edge portions E1 to E4. The cell cover 200 surrounds the pouch-type battery cell 100, and may be configured to surround at least a portion of the sealed portion among the edge portions E1 to E4, while at least a portion of the unsealed portion is exposed to the outside without being wrapped. . For example, referring to the implementation of FIG. 2, the cell cover 200 may be configured to cover the upper edge portion E1, which is part of the sealing portion of the pouch-type battery cell 100. In this case, the pouch-type battery cell 100 accommodated inside the cell cover 200 can be said to be configured so that the upper edge portion E1, which is a sealing portion, faces the upper cover portion 220. Additionally, the cell cover 200 may cover the pouch-type battery cell 100 so that the lower edge portion E2, which is an unsealed portion of the pouch-type battery cell 100, is exposed to the outside. In this case, the lower edge portion E2, which is an unsealed portion of the pouch-type battery cell 100, can be said to be disposed on the open surface of the cell cover 200.

In the pouch-type battery cell 100, the upper edge portion E1, which serves as a sealed portion, may be relatively more vulnerable to the discharge of high-temperature gas or flame than the lower edge portion E2, which is an unsealed portion. However, according to the above embodiment, the upper edge portion E1, which is a sealing portion, is disposed to face the upper cover portion 220, which may be more advantageous for directional venting.

In addition, in the pouch-type battery cell 100, the lower edge portion E2, which is an unsealed portion, has a relatively larger cross-sectional area than the upper edge portion E1, which is a sealed portion, and is provided in a flat shape to form an open surface of the cell cover 200. It can be placed in, and cooling efficiency can be increased by direct contact with the thermal resin, which will be described later.

Furthermore, when the lower case 320 is seated on one side of the car body, the first side cover part 230 and the second side cover part 240 may extend from the upper cover part 220 toward one side of the car body, The upper edge portion E1 may be disposed farther from one side of the vehicle body than the lower edge portion E2. That is, when the lower case 320 is seated on one side of the vehicle body, the cell cover 200 may be configured so that the side disposed relatively close to the one side of the vehicle body is open.

The cell cover 200 may be formed as one piece. In this case, the cell cover 200 may be constructed by bending a metal plate with a plate structure. That is, the cell cover 200 may be composed of a single plate bent.

The cell cover 200 may be configured to cover one or more pouch-type battery cells 100 by bending both ends of a plate in the same direction. In particular, when one cell cover 200 is provided with an upper cover part 220, a first side cover part 230, and a second side cover part 240, the upper cover part 220 and the first side cover part 240 The portion 230 and the second side cover portion 240 may be made of one plate. In this case, the cell cover 200 can be said to be made of several components integrated into one piece.

Here, each component can be distinguished through a bend. In particular, two bent portions may be formed in one plate. And, based on these two bent parts, the upper cover part 220, the first side cover part 230, and the second side cover part 240 can be distinguished. In particular, the central portion of one plate forms the upper cover portion 220, and both sides are bent or folded in the downward direction around the upper cover portion 220, thereby forming the first side cover portion 230 and the second side cover portion 230. A side cover portion 240 may be formed. In this way, forming a bent portion in one plate to form the cell cover 200 can be implemented in various ways, such as pressing or roll forming.

According to this implementation configuration of the present invention, manufacturing of the cell cover 200 can be made simpler. In addition, the cell cover 200 of a simplified structure is made of a metal material with higher rigidity than the case of the pouch-type battery cell 100, such as the pouch exterior material, and is made of at least one pouch-type battery cell 100 covered by the cell cover 200. The battery cell 100 can be protected from external shock or vibration. In addition, in this case, heat conduction performance through the cell cover 200 is further improved, and cooling performance can be further improved.

Meanwhile, the cell cover 200 may be made of various materials to ensure rigidity. In particular, the cell cover 200 may be made of a metal material. In the case of such a metal material, the stacked state of the pouch-type battery cells 100 can be maintained more stably and the pouch-type battery cells 100 can be more safely protected from external shock. In particular, the cell cover 200 may be made of steel, or even stainless steel (SUS). For example, the cell cover 200 may be entirely made of SUS material. The cell cover 200 made of SUS may have a thickness of approximately 2 mm. For example, as shown in Figure 5, when the cell cover 200 includes an upper cover part 220, a first side cover part 230, and a second side cover part 240, the upper cover part 220 ), the thickness d2 of the first side cover 230, and the thickness d4 of the second side cover 240 may be the same and be approximately 2 mm.

As such, when the cell cover 200 is made of a steel material, it has excellent mechanical strength and rigidity, and thus can more stably support the stacked state of the pouch-type battery cells 100. Additionally, in this case, it is possible to more effectively prevent damage or breakage of the pouch-type battery cell 100 from external impacts, such as needles. Additionally, in this case, handling of the pouch-type battery cell 100 may become easier.

Additionally, as in the above embodiment, when the cell cover 200 is made of a steel material, due to its high melting point, when a flame occurs from the pouch-type battery cell 100, the overall structure can be stably maintained. In particular, in the case of steel material, the melting point is higher than that of aluminum material, so it does not melt even with flame ejected from the pouch-type battery cell 100 and its shape can be stably maintained. Therefore, excellent flame propagation prevention or delay effects and venting control effects between the pouch-type battery cells 100 can be secured, and even when a thermal event occurs, internal short circuits or structural collapse can be prevented, thereby increasing structural safety. .

The cell cover 200 may include an insulating coating layer on its inner surface. The insulating coating layer may be coated, applied, or attached to any one of silicone resin, polyamide, and rubber. According to the configuration of the insulating coating layer of the cell cover 200 according to this embodiment, the insulating coating effect can be maximized with a minimum coating amount. Additionally, since an insulating coating layer is applied to the inner surface of the cell cover 200, insulation between the pouch-type battery cell 100 and the cell cover 200 can be strengthened.

Additionally, the cell cover 200 may further include an insulating member. The insulating member may be made of an electrically insulating material and may be provided on the inner surface of the cell cover 200 in which the pouch-type battery cell 100 is accommodated. In particular, the insulating member may have an adhesive layer on at least one side and be adhered to the inner surface of the cell cover 200. In addition, the insulating member has adhesive layers on both sides, so that it can be adhered not only to the inner surface of the cell cover 200 but also to the pouch-type battery cell 100. Additionally, the insulating member may be made of a heat-resistant material. For example, the insulating member may be formed in the form of a heat-resistant tape in which an adhesive is applied to the surface of a heat-resistant ceramic sheet. The insulating member may be a film made of PI (polyimide). The thickness of the insulating member may be approximately 0.5 mm. Additionally, the insulating member may be located on both the inner and outer surfaces of the cell cover 200.

In addition, the battery pack 10 according to the present invention may further include a control module 400 stored in the internal space of the pack case 300, as shown in FIG. 1. This control module 400 may include a BMS. The control module 400 is mounted in the internal space of the pack case 300 and may be configured to generally control charging and discharging operations and data transmission and reception operations of the pouch-type battery cell 100. The control module 400 may be provided in pack units rather than module units. More specifically, the control module 400 may be provided to control the charge/discharge state, power state, and performance state of the pouch-type battery cell 100 through pack voltage and pack current. The control module 400 estimates the state of the pouch-type battery cell 100 in the battery pack 10 and manages the battery pack 10 using the estimated state information. For example, state information of the battery pack 10, such as state of charge (SOC), state of health (SOH), maximum input/output power allowance, and output voltage, is estimated and managed. And, using this state information, the charging or discharging of the battery pack 10 can be controlled, and it is also possible to estimate the replacement time of the battery pack 10.

The battery pack 10 according to the present invention may further include a battery cut-off unit, as shown in FIG. 1. The battery disconnect unit (BDU) 500 may be configured to control the electrical connection of battery cells to manage the power capacity and function of the battery pack 10. To this end, the battery blocking unit 500 may include a power relay, a current sensor, a fuse, etc. The battery cut-off unit 500 is also provided in pack units rather than module units, and various cut-off units known at the time of filing of the present invention may be employed.

In addition, the battery pack 10 according to the present invention may further include components of various battery packs known at the time of filing of the present invention. For example, the battery pack 10 according to an embodiment of the present invention may further include a manual service disconnector (MSD) that allows an operator to cut off power by manually disconnecting the service plug. Additionally, it may further include flexible busbars or cables for interconnecting at least one cell unit block.

Referring again to FIG. 5 to look at the partition member 210 in more detail, the cell cover 200 covers the upper side of the pouch-type battery cell 100, and the partition member 210 covers the inside of the cell cover 200. It protrudes from the top and extends downward.

The thickness (d1) of the partition member 210 is the thickness (d2) of the upper cover part 220, the thickness (d3) of the first side cover part 230, and the thickness (d4) of the second side cover part 240. It can be thinner (d1<d2, d3, d4). By thinning the thickness d1 of the partition member 210, the directional venting effect can be enjoyed while minimizing the total weight of the cell cover 200 including the partition member 210. Therefore, according to the present invention, the overall weight and volume of the battery pack 10 can be reduced, and manufacturing costs can be reduced.

In this embodiment, where the cell cover 200 surrounds a plurality of pouch-type battery cells 100, the partition member 210 may be configured to partition each of the plurality of pouch-type battery cells 100. For example, as shown, when the cell cover 200 surrounds three pouch-type battery cells 100, two partition members 210 are included to partition each of these pouch-type battery cells 100. You can. That is, the number of partition members 210 can be adjusted corresponding to the number of pouch-type battery cells 100 surrounded by the cell cover 200. Preferably, one or more partition members 210 may be arranged along the stacking direction (Y-axis direction in the drawing) of the pouch-type battery cells 100.

Preferably, the partition member 210 blocks the upper edge portion E1 of one pouch-type battery cell 100 from directly facing the upper edge portion E1 of the other pouch-type battery cell 100. there is. To this end, the partition member 210 extends downward from the upper cover portion 220 to the top of the pouch-type battery cell 100.

As a result, the separation space S is clearly partitioned, and there is an effect of individually storing the pouch-type battery cells 100 in each partitioned space S. Through this configuration, heat transfer or venting gas movement to other adjacent pouch-type battery cells 100 can be suppressed. In addition, when the partition member 210 is securely inserted between the two pouch-type battery cells 100, in addition to the isolation between the partitioned space S, the airtightness of the space S in the width direction is improved. , the effect of venting gas being discharged in the longitudinal direction can be increased. In other words, there is an effect of securing a directional venting path for each pouch-type battery cell 100 even inside the cell cover 200, which performs directional venting on a cell unit basis.

As described above, the upper edge portion E1 of the pouch-type battery cell 100 may be a DSF portion, and according to the present embodiment, the partition member 210 is adjacent to the pouch-type battery cell 100. It has the effect of isolating the DSF part. Venting gas or flame may be discharged from the DSF portion of the pouch-type battery cell 100, and according to this configuration of the partition member 210, simultaneous ignition between adjacent pouch-type battery cells can be more reliably suppressed. .

Figure 7 is a bottom perspective view of the cell cover shown in Figure 2.

Referring to FIG. 7 , the partition member 210 is configured to form a venting path corresponding to each of the plurality of pouch-type battery cells 100 along the stacking direction of the plurality of pouch-type battery cells 100. This venting path may provide a space through which venting gas or flame discharged from the pouch-type battery cell 100 can flow inside the cell cover 200.

Preferably, the partition member 210 is a partition wall. In this embodiment, these partition walls may be configured to be continuous along the length direction of the pouch-type battery cell 100, and may be arranged to be spaced apart along the width direction of the pouch-type battery cell 100. The partition wall may be formed parallel to the direction in which the venting gas is discharged (forward-backward direction), and in this case, gas movement or heat transfer in the direction crossing the partition wall (left-right direction) can be suppressed. Accordingly, when a thermal event occurs, diffusion to the adjacent pouch-type battery cell 100 can be reduced, and the battery pack 10 including it can ensure excellent safety against thermal events.

The cell cover 200 may be configured to have openings formed on both sides corresponding to the electrode lead 110, so that venting gas in the space S can escape through both sides of the cell cover 200. Accordingly, the flow of venting gas within the space S is forward and backward parallel to the longitudinal direction of the pouch-type battery cell 100. By forming a partition parallel to this longitudinal direction, when the pouch-type battery cell 100 thermally runs away, the flow of venting gas or flame is guided through the inner upper part of the cell cover 200 and passes through the opening of the cell cover 200. It may be discharged to the outside. Accordingly, the flow of venting gas or flame can be guided in a more constant direction.

Figure 8 is a diagram schematically showing a partial cross-sectional configuration of a battery pack according to an embodiment of the present invention.

As shown in FIG. 8, the battery pack 10 may be configured to include a heat sink 330. Here, the heat sink 330 refers to an object that absorbs and radiates heat from another object through direct or indirect thermal contact. This heat sink 330 may be placed on the bottom of the pack case 300. In particular, in order to lighten the battery pack 10 and simplify its components, the bottom plate of the lower case 320 may be provided in the form of a heat sink with a flow path through which coolant can flow.

The pouch-type battery cell 100 is thermally coupled to the heat sink 330. The pouch-type battery cell 100 and the heat sink 330 may be in direct thermal contact. The pouch-type battery cell 100 may be thermally coupled in such a way that the cell cover 200 thermally coupled to the pouch-type battery cell 100 is in direct thermal contact with the heat sink 330 without direct thermal contact. . In this case, the cell cover 200 serves as a cooling fin that transfers the heat of the pouch-type battery cell 100 to the heat sink 330, thereby simplifying and efficient the battery pack manufacturing process and making the pouch-type battery cell ( 100) Cooling performance can be improved.

According to the configuration of the cell cover 200 of this embodiment, the lower edge portion of the pouch-type battery cell 100 is exposed below the cell cover 200 through the lower opening of the cell cover 200 and is exposed to the bottom of the lower case 320. It can be placed facing the bottom plate. Thermal resin 340 may be provided between the lower edge of the pouch-type battery cell 100 and the bottom plate of the lower case 320. Therefore, in the battery pack 10 according to another embodiment of the present invention, the heat of each pouch-type battery cell 100 is connected to the lower edge portion and/or the cell cover 200 of each pouch-type battery cell 100 → thermal. Resin 340 → Heat can be dissipated to the lower case 320, which functions as a heat sink 330.

In this implementation configuration, thermal resin 340 is interposed between the heat sink 330 and the plurality of pouch-type battery cells 100. Thermal resin 340 may be applied to the upper surface of the heat sink 330. Then, a plurality of cell units U1, that is, a plurality of pouch-type battery cells 100 and a plurality of cell covers 200, are seated on the upper surface of the heat sink 330 on which the thermal resin 340 is applied. It can be.

Here, the thermal resin 340 may be made of a material that conducts heat and has adhesive properties. The thermal resin 340 can transfer heat to the heat sink 330 so that the heat generated in the pouch-type battery cell 100 is dissipated through the heat sink 330. In addition, since the thermal resin 340 has adhesive properties, the cell cover 200 can be structurally coupled to the heat sink 330.

In this implementation configuration, the plurality of pouch-type battery cells 100 combined with the cell cover 200 may be directly seated on the upper surface of the heat sink 330 to which the thermal resin 340 is applied. In this case, the plurality of cell units U1 can be stably coupled and fixed to the upper surface of the heat sink 330 by the thermal resin 340. In particular, the pouch-type battery cell 100 and the cell cover 200 included in each cell unit (U1) may have a length in the vertical direction longer than the width in the left and right directions. Accordingly, the pouch-type battery cell 100 and the cell cover 200 can be said to be seated on the upper surface of the heat sink 330 in an erect state, that is, in an upright state. At this time, the thermal resin 340 can maintain the upright state of the cell cover 200 more stably.

As another example, a means such as a fixing groove that allows the lower end of the cell cover 200 to be inserted and fixed is provided on the top of the heat sink 330, and the cell cover 200 can be inserted and fixed there. According to this example, the coupling between the cell cover 200 and the heat sink 330 can be further improved. Therefore, even in situations such as vibration or impact applied to the battery pack 10 or swelling of the pouch-type battery cell 100, the cell cover 200 and the pouch-type battery cell 100 accommodated therein are The stacked state can be maintained stably. Moreover, according to this example, it is possible to effectively prevent the cell cover 200 from moving in the left and right directions. Additionally, the assembly position of the cell cover 200 can be guided through a fitting configuration between the cell cover 200 and the heat sink 330. Therefore, in this case, the assembling of the battery pack 10 can be further improved.

A plurality of cell covers 200 may be included in the battery pack 10 . When a plurality of cell covers 200 are included, the plurality of cell covers 200 may be spaced apart from each other as shown in FIG. 8 . For example, the plurality of cell covers 200 may be spaced apart in the Y-axis direction. Direct heat transfer between the cell covers 200 can be blocked through the spaced apart space. Additionally, separate members required to construct the battery pack 10 can be inserted through the spaced apart space. Alternatively, an insulating pad or flame suppression pad may be interposed at least partially between the plurality of cell covers 200. These insulating pads or flame suppression pads can prevent heat or flame that may occur within one cell cover 200 from being transferred to the other cell cover 200 and affecting other pouch-type battery cells 100. . The flame suppression pad may be formed of a heat-resistant resin such as vinyl chloride resin, a material such as silicon or ceramic, a composite of a heat-resistant resin and a ceramic or glass filler, or a metal plate coated with insulation, but this is an example and a flame retardant material. This is enough. It is desirable if the pouch-type battery cell 100 is made of a material that does not decompose, melt, or ignite at least up to the temperature at which thermal runaway occurs (e.g., 150°C to 200°C).

Additionally, when the battery pack 10 includes a plurality of cell covers 200 stacked, an adhesive member may be interposed between the cell covers 200. For example, an adhesive member may be interposed in a portion where the two cell covers 200 face each other to adhesively fix them. Through this adhesive configuration, the connection configuration between multiple cell covers 200 can be made more robust.

Figure 9 is a perspective view schematically showing another cell cover that may be included in a battery pack according to an embodiment of the present invention. FIG. 10 is a diagram schematically showing a cross-sectional configuration along the Y-axis direction when the cell cover shown in FIG. 9 surrounds the pouch-type battery cell. FIG. 11 is a diagram schematically showing the cross-sectional configuration of the cell cover shown in FIG. 9 along the X-axis direction.

Referring to FIGS. 9 to 11, venting gas moves through the space S within the cell cover 200. Here, the partition member 210 is configured to prevent the movement of the venting gas. In particular, the partition member 210 may be configured to prevent horizontal movement of the venting gas. Additionally, in this case, one or more partition members 210 may be disposed along the flow direction of the venting gas.

The venting gas moves along the longitudinal direction or front-back direction of the pouch-type battery cell, as indicated by the thick dotted arrow in FIG. 9. At this time, the partition member 210 may be located in the movement path of the venting gas. Accordingly, when the venting gas moves, the movement may be suppressed by the partition member 210. A preferred partition member 210 is a partition wall. The partition walls may be configured continuously along the width direction of the pouch-type battery cell 100, and may be arranged to be spaced apart along the length direction. In this way, the cell cover 200 including the partition-type partition member 210 may be called a cell cover including a partition on the upper inner surface. In particular, in this embodiment, the partition wall is installed across the direction of movement of the venting gas, thereby reducing the ability of the venting gas to travel in a straight line.

Preferably, the partition wall may be provided at a portion of the cell cover 200 surrounding the upper edge portion E1 of the pouch-type battery cell 100. In an embodiment in which the cell cover 200 includes an upper cover part 220, a first side cover part 230, and a second side cover part 240, these partition walls include the inner surface of the upper cover part 220, It may be a plate in contact with the upper inner surface of the first side cover part 230 and the upper inner surface of the second side cover part 240. A plate is roughly a rectangular parallelepiped and refers to a structure whose height is small compared to the width and length of its wide surface. This plate may be placed in an upright position on the inner surface of the upper cover portion 220 of the cell cover 200. In particular, the wide side of the partition wall may be arranged to face the venting gas.

When venting gas is generated from the pouch-type battery cell 100 accommodated in the cell cover 200, the venting gas moves toward the upper cover portion 220 due to its high temperature characteristics and is likely to move in the front-back direction. At this time, when the partition wall is located on the inner surface of the upper cover part 220, the effect of blocking flames or sparks can be reliably achieved.

As shown in FIG. 11, the partition wall may be provided so that the plane direction is perpendicular to the inner surface of the upper cover part 220. In this case, while the venting gas moves forward and backward, the effect of stopping sparks, etc., can be further improved by the partition wall.

FIG. 12 is a view corresponding to FIG. 11 and is a view showing another embodiment of the cell cover of FIG. 9.

Referring to FIG. 12, the partition wall may be provided in an inclined form with respect to the inner surface of the upper cover part 220. What is shown is that the partition wall is tilted at an acute angle α with respect to the inner surface of the upper cover part 220, with the plane direction inclined toward the direction in which the venting gas travels. Conversely, the partition wall may be configured in a shape in which the plane direction is inclined at an obtuse angle with respect to the inner surface of the upper cover portion 220.

This partition type partition member 210 is effective in blocking flames, sparks, particles, etc. when venting gas is discharged along the length direction from the upper part of the pouch-type battery cell 100. If a fire or explosion occurs in a portion of the pouch-type battery cell 100, fragments and flames of the high-temperature electrode assembly may be discharged together with the high-temperature venting gas. In this case, if the venting gas has a strong straight flow, there is a risk that high-temperature debris and flames are discharged with strong force, for example, directly hitting the pack case 300. The partition-type partition member 210 acts as an obstacle in the direction of movement of the venting gas and reduces the straight flow of the venting gas, thereby suppressing strong emissions such as flames and sparks. Accordingly, the safety of the battery pack 10 can be greatly improved. According to this implementation configuration, it not only suppresses or delays the emission of flames or sparks with strong straight propagation, but also contributes to lowering the temperature of the venting gas while it is discharged along a longer movement path.

FIG. 13 is a view corresponding to FIG. 11 and is a view showing another embodiment of the cell cover of FIG. 9.

The partition member 210 may be a portion provided in an uneven shape on the inner surface of the cell cover 200.

Referring to FIG. 13 , concave and convex portions 210a and convex portions 210b may be alternately positioned along the length of the pouch-type battery cell 100.

In the illustrated example, the cross-sections of the concave portion 210a and the convex portion 210b are angular, but the cross-sections of the concave portion and the convex portion may have a curved shape, for example, like a wave pattern. The angled cross-section can provide excellent blocking effects by forming a reliable physical barrier against flames, sparks, and blocking. A curved cross section can be advantageous in terms of venting gas discharge because the generation of vortices that may occur when hitting the partition member 210 is less than when the cross section has an angled cross section.

In addition, the irregularities formed on the inner surface of the cell cover 200 may be provided by the shape of the cell cover 200 itself, but may be formed by gluing or combining a mesh-structured plate to the inner surface of the cell cover 200. It may be prepared by

The mesh structure may be one in which a number of holes are installed on a metal mesh or metal plate. Holes can be formed by removing part of the metal plate by punching or etching. A metal mesh is formed by weaving multiple metal wires together to form a so-called wire mesh. In a preferred example, the mesh structure consists of one or more layers, preferably several layers, of two or more mesh metal nets. Mesh is a method of grading based on the size of the mesh, expressed as the number of meshes per inch of length. In other words, mesh refers to a unit that represents the size of the holes or particles of a sieve, and can be said to be the number of meshes in a 1-inch square. For example, 200 mesh means that wires measuring 2/1000 inches in diameter are spaced 3/1000 inches apart, meaning there are 200 meshes in 1 inch in length. Therefore, N mesh is N/25.4mm, and for example, if a metal mesh of 2 mesh or more is used, the size of one hole is 12.7x12.7mm ² or less. Considering only anti-flammability, the smaller the mesh gap, the better, but if the gap is too narrow, it is often clogged by foreign substances such as dust, so be sure to use it appropriately.

The mesh structure may be non-combustible. These materials can be any material that is difficult to burn. Specifically, any one of copper, aluminum, cast iron, Monel (Ni+Cu), SUS, and steel can be used, but it is not limited thereto. In addition, the mesh structure is preferably selected from a material that not only has anti-flammability ability to suppress flames, but also has mechanical properties that can withstand explosion pressure.

The mesh structure can be used purely by itself or laminated with a polymer resin layer, but is not limited to this. The polymer resin layer includes polyvinylidene fluoride-hexafluoropropylene, polyvinylidene fluoride-trichloroethylene, polymethyl methacrylate, polyacrylonitrile, polyvinylpyrrolidone, and polyvinylacetate. , polyethylene-vinyl acetate copolymer, polyethylene oxide, cellulose acetate, cellulose acetate butylate, cellulose acetate propionate, cyanoethyl pullulan, cyanoethyl polyvinyl alcohol, cyanoethyl cellulose, cyanoethyl sucrose, pullulan. , carboxyl methyl cellulose, acrylonitrile-styrene-butadiene copolymer, polyimide, and mixtures thereof can be used, but is not limited thereto.

This mesh structure not only splits the flame into small pieces as it passes through, but also causes an endothermic reaction that absorbs the energy of the flame, resulting in a temperature drop and an anti-inflammatory effect. More specifically, the mesh structure has small holes, so gases such as gas or steam can pass through, but it is difficult for flames to pass through. Additionally, when the mixture of combustible gas and air inside the secondary battery is ignited, the mesh structure absorbs and dissipates the heat generated from the combustible gas mixture, lowering the combustion temperature so that the gas on the other side does not rise to the spontaneous ignition temperature. This is because the heated gas with high heat loses heat to the material that makes up the mesh structure as it passes through the mesh structure. The mesh structure is made of a metal material with numerous holes, creating a heat absorbing plate with a very large cross-sectional area.

Therefore, as the flame passes through the mesh structure, it loses enough heat that the flame can no longer maintain, and the explosion may subside.

Since the mesh structure can be provided as a thin plate, it can be appropriately placed in the space S within the cell cover 200 and can suppress an increase in the size of the cell unit. Additionally, because the mesh structure has multiple holes, it can also suppress weight gain. In this way, according to the present invention, an increase in the size and weight of the battery pack 10 is suppressed, and even in the event of a flame erupting from the secondary battery, ejection of flame to the outside is prevented and safety is improved. According to this implementation configuration of the present invention, external discharge of sparks, flames, and high-temperature active material particles contained in the venting gas can be suppressed. Therefore, fire suppression performance can be further improved. In this way, according to the present invention, spark blocking, etc. can be implemented. When the pack case 300 is made of aluminum to reduce weight, if sparks fly directly into the pack case 300, the pack case 300 may melt and structural collapse may occur. According to an embodiment of the present invention, sparks can be prevented from flying directly toward the pack case 300, and thus such structural collapse can be prevented.

Figure 14 is a diagram schematically showing the configuration of a vehicle according to an embodiment of the present invention.

Referring to FIG. 14, a vehicle V according to an embodiment of the present invention may include the battery pack 10 according to an embodiment of the present invention described above. Here, the vehicle V may include, for example, a vehicle that uses electricity as a driving source, such as an electric vehicle or a hybrid vehicle. In addition, the vehicle V may further include various other components included in the vehicle, such as a vehicle body or a motor, in addition to the battery pack 10 according to the present invention.

The battery pack 10 may be disposed at a predetermined location within the vehicle V. The battery pack 10 can be used as an electrical energy source to drive the vehicle V by providing driving force to the motor of the electric vehicle. In this case, the battery pack 10 has a high nominal voltage of 100V or more.

The battery pack 10 may be charged or discharged by an inverter depending on the driving of the motor and/or internal combustion engine. The battery pack 10 can be charged by a regenerative charging device combined with a brake. The battery pack 10 may be electrically connected to the motor of the vehicle V through an inverter.

Meanwhile, in this specification, terms indicating directions such as up, down, left, right, front, and back are used, but these terms are only for convenience of explanation and may vary depending on the location of the target object or the location of the observer. It is obvious to those skilled in the art that this can be done.

Although the present invention has been described above with limited examples and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the description below will be understood by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalence of the claims.

10: Battery pack 100: Pouch type battery cell
110: electrode lead 170: busbar frame
180: Insulating cover 200: Cell cover
210: Partition member 220: Upper cover part
230: first side cover part 240: second side cover part
300: pack case 330: heat sink
340: Thermal Resin S: Separation space
U1: Cell Unit V: Car

Claims (26)

A plurality of pouch-type battery cells stacked in at least one direction;
a pack case storing the pouch-type battery cell in an internal space; and
In the inner space of the pack case, a cell cover that at least partially surrounds at least some of the pouch-type battery cells among the plurality of pouch-type battery cells,
The cell cover has a separation space between the wrapped pouch-type battery cells and includes a partition member extending from the inside of the cell cover to partition the separation space. The battery pack according to claim 1, wherein the cell cover is configured to support the pouch-type battery cell in an upright state. The battery pack of claim 2, wherein the cell cover covers an upper side of the pouch-type battery cell, and the partition member protrudes from an inner top of the cell cover and extends downward. The battery pack of claim 1, wherein the cell cover partially surrounds the pouch-type battery cell so that at least one side of the wrapped pouch-type battery cell is exposed toward the pack case. The method of claim 1, wherein the pouch-type battery cell has an accommodating portion in which the electrode assembly is stored and an edge portion around the accommodating portion,
The battery pack is characterized in that the cell cover is configured to cover a portion of the storage portion and the edge portion of the pouch-type battery cell. The battery pack according to claim 5, wherein the cell cover is provided to cover both sides of the storage portion and an upper edge portion of the wrapped pouch-type battery cell. The method of claim 5, wherein the cell cover includes an upper cover portion configured to surround an upper portion of an upper edge portion of the pouch-type battery cell, extending downward from one end of the upper cover portion, and numbering one side of the wrapped pouch-type battery cell. A battery comprising a first side cover portion surrounding the outside of the charger, and a second side cover portion extending downward from the other end of the upper cover portion and surrounding the outside of the other side storage portion of the wrapped pouch-type battery cell. pack. The battery pack of claim 7, wherein the partition member is thinner than the upper cover, the first side cover, and the second side cover. The battery pack according to claim 7, wherein the separation space is formed between the upper cover portion and the pouch-type battery cell. The battery pack according to claim 9, wherein the partition member extends downward from the upper cover portion to the top of the pouch-type battery cell. The battery pack according to claim 7, wherein the pouch-type battery cell is configured to be in close contact with the inner surfaces of the first and second side covers. The battery pack of claim 7, wherein the cell cover surrounds a plurality of pouch-type battery cells, and the partition member is configured to partition each of the plurality of pouch-type battery cells. The method of claim 7, wherein the cell cover surrounds a plurality of pouch-type battery cells, and the partition member forms a venting path corresponding to each of the plurality of pouch-type battery cells along a stacking direction of the plurality of pouch-type battery cells. A battery pack characterized in that it is configured to do so. The method of claim 1, wherein the pouch-type battery cell has an accommodating portion in which the electrode assembly is stored and an edge portion around the accommodating portion,
The cell cover is configured to surround the storage portion and upper edge portion of the wrapped pouch-type battery cell,
The upper edge portion is a sealing portion,
The cell cover surrounds a plurality of pouch-type battery cells, and the partition member blocks the upper edge of one pouch-type battery cell from directly facing the upper edge of another pouch-type battery cell. . The method of claim 7, wherein the cell cover surrounds a plurality of pouch-type battery cells, the cell cover exposes electrode leads protruding in a longitudinal direction of the pouch-type battery cell, and the plurality of pouch-type battery cells are A battery pack that is stacked in a width direction perpendicular to the length direction, and wherein the partition member has partition walls continuously formed along the length direction and arranged to be spaced apart along the width direction. The battery pack according to claim 1, wherein venting gas moves through the space, and the partition member is configured to prevent the movement of the venting gas. The method of claim 16, wherein the cell cover exposes electrode leads protruding in the longitudinal direction of the pouch-type battery cell, the venting gas moves along the longitudinal direction, and the partition member is perpendicular to the longitudinal direction. A battery pack, characterized in that partition walls formed continuously along the width direction are arranged to be spaced apart along the longitudinal direction. The method of claim 17, wherein the cell cover includes an upper cover portion configured to surround an upper portion of an upper edge portion of the pouch-type battery cell, a first side cover portion extending downward from one end of the upper cover portion, and the upper cover. It includes a second side cover portion extending downward from the other end of the portion,
The battery pack, wherein the partition wall is a plate in contact with the inner surface of the upper cover portion, the upper inner surface of the first side cover portion, and the upper inner surface of the second side cover portion. The battery pack according to claim 18, wherein the partition wall is provided so that its plane direction is perpendicular to the inner surface of the upper cover part or is inclined at an acute or obtuse angle. The battery pack according to claim 16, wherein the partition member is a portion provided in a concavo-convex shape on an inner surface of the cell cover. 21. The method of claim 20, wherein the cell cover exposes electrode leads protruding in the longitudinal direction of the pouch-type battery cell, the venting gas moves along the longitudinal direction, and the uneven concave portion and convex portion are A battery pack characterized in that it is located alternately along the longitudinal direction. The battery pack according to claim 1, wherein the cell cover is formed by bending one plate. The battery pack according to claim 1, wherein the cell cover includes an insulating coating layer on an inner surface. The battery pack of claim 1, wherein the battery pack includes a heat sink, and the pouch-type battery cell is thermally coupled to the heat sink. The battery pack according to claim 24, wherein thermal resin is interposed between the pouch-type battery cell and the heat sink. A vehicle comprising a battery pack according to any one of claims 1 to 25.

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