KR20230148119A - Battery module with reinforced safety - Google Patents

Abstract

The present invention discloses a battery module with improved safety and improved structure so as to appropriately control the emission of flames generated inside the battery module. A battery module according to one aspect of the present invention includes a cell assembly including a plurality of battery cells; a module case storing the cell assembly in an internal space; a module terminal electrically connected to the cell assembly and installed on the front side of the module case; and an expansion member disposed on the front side of the cell assembly in the internal space of the module case and configured to expand in volume by heat to fill at least a portion of the front side space of the cell assembly.

Description

Battery module with reinforced safety}

The present invention relates to batteries, and more specifically, to battery modules with enhanced safety, battery packs and automobiles including the same.

As the demand for portable electronic products such as smartphones, tablet PCs, and smart watches has increased significantly, and electric vehicles have become increasingly widespread, research on batteries used in them, especially secondary batteries capable of repeated charging and discharging, is being actively conducted. .

Currently commercialized secondary batteries include nickel cadmium batteries, nickel hydrogen batteries, nickel zinc batteries, and lithium secondary batteries. Among these, lithium secondary batteries have little memory effect compared to nickel-based secondary batteries, so they can be freely charged and discharged. It is receiving attention for its extremely low self-discharge rate and high energy density.

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 a positive electrode plate and a negative electrode plate coated with the positive electrode active material and the negative electrode active material 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 solution.

Generally, lithium secondary batteries can be classified into can-type secondary batteries in which the electrode assembly is built into a metal can and pouch-type secondary 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, secondary batteries have been widely used for driving or energy storage not only in small devices such as portable electronic devices, but also in medium to large devices such as electric vehicles and energy storage systems (ESS). A plurality of these secondary batteries can be electrically connected and stored together inside a module case to form one battery module. At this time, each secondary battery included in one battery module may be referred to as a battery cell. Additionally, multiple such battery modules can be connected to form one battery pack.

However, when a battery pack includes a plurality of battery modules and each battery module includes a plurality of battery cells, it may be vulnerable to a thermal chain reaction between battery modules or battery cells. For example, if an event such as thermal runaway occurs inside one battery module, propagation of such thermal runaway to other battery modules or other battery cells needs to be suppressed. If thermal runaway propagation between battery modules or battery cells is not properly suppressed, an event occurring in a specific battery module or battery cell may cause a chain thermal reaction in other battery modules or battery cells, causing an explosion or fire. There are concerns that the scale may become larger.

In particular, if an event such as thermal runaway occurs in one of the battery modules, gas or flames may be randomly discharged to the outside. At this time, if the emission of gas or flame is not properly controlled, there is a risk that the gas or flame will be discharged toward other battery modules, causing a thermal chain reaction in other battery modules. In particular, there may be a module terminal on the front side of the battery module to be electrically connected to another battery module or battery pack, such as a module bus bar. Therefore, if flame is discharged to the front of the battery module, it may damage the module terminals within the battery pack and cause an electrical short. Additionally, since other battery modules may exist in front of a battery module, when a flame is emitted toward the front of a specific battery module, the ejected flame is directed to other battery modules, making it easy for fire to spread between battery modules.

If thermal propagation between battery modules or between battery cells is not properly controlled, the voltage drop of the battery module or battery pack may occur rapidly. And this can cause sudden interruption of devices equipped with battery modules or battery packs, causing unexpected damage. For example, if a battery pack voltage drop suddenly occurs while an electric vehicle is in operation, it is not possible to secure enough time to move the electric vehicle to a safe location.

In addition, if a fire or explosion suddenly occurs due to failure to properly control thermal propagation between battery modules or battery cells, there is a high possibility of causing personal injury to users. For example, when thermal runaway occurs in an electric vehicle, if a certain level of time is not secured before a full-scale fire develops, occupants may not be able to escape safely.

Therefore, the present invention was created to solve the above problems, and provides a battery module with an improved structure to properly control the emission of flames generated inside the battery module, a battery pack containing the same, and a vehicle. The purpose is to provide

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 module according to one aspect of the present invention for achieving the above object includes a cell assembly including a plurality of battery cells; a module case storing the cell assembly in an internal space; a module terminal electrically connected to the cell assembly and installed on the front side of the module case; and an expansion member disposed on the front side of the cell assembly in the internal space of the module case and configured to expand in volume by heat to fill at least a portion of the front side space of the cell assembly.

Here, the expansion member may include a material that is foamed by heat.

Additionally, the expansion member may be arranged to be spaced a predetermined distance away from the electrode lead of the cell assembly.

Additionally, at least a portion of the expansion member facing the cell assembly may be coated with an electrically insulating material.

In addition, the battery module according to an embodiment of the present invention is provided with an electrically insulating material, is interposed between the front side of the cell assembly and the module case, and includes a front insulating cover with the expansion member attached to the inner surface. can do.

Additionally, the module case may have a front fastening hole formed, and the front insulating cover may have a front fastening protrusion inserted into the front fastening hole.

Additionally, the expansion member may be configured to close the front fastening hole when expanded.

Additionally, the expansion member may be configured to block the flame or gas discharged by expansion from being directed toward the module terminal when flame or gas is emitted from the cell assembly.

Additionally, the expansion member is configured in the form of a sheet and may be configured to be expanded both in a direction parallel to the surface and in a direction perpendicular to the surface.

Additionally, the expansion member may include composite sheets made of different materials.

In addition, the battery module according to an embodiment of the present invention is disposed on the front and rear sides of the cell assembly, respectively, and is composed of a bus bar terminal electrically connected to the cell assembly and an electrical insulating material, and the bus bar terminal It may further include a bus bar assembly having a bus bar housing configured to be mounted, and the expansion member may be located on the front side and spaced a predetermined distance away from the front side bus bar assembly.

Additionally, the bus bar housing provided in the front bus bar assembly may include a front housing protrusion protruding toward the expansion member.

Additionally, the expansion member may be configured such that its lower end is positioned higher than the lower end of the bus bar terminal.

Additionally, the module case may have a top hole communicating with the internal space formed on the upper side.

Additionally, a battery pack according to another aspect of the present invention for achieving the above object includes a battery module according to the present invention.

In addition, a vehicle according to another aspect of the present invention for achieving the above object includes a battery module according to the present invention.

According to the present invention, when gas or flame is generated inside a battery module, the discharge of such gas or flame can be appropriately controlled.

In particular, according to one aspect of the present invention, the flame of a cell ignited inside a battery module can be directed to a direction other than the direction in which the electrode leads or module terminals are located.

Therefore, according to this aspect of the present invention, thermal runaway propagation between battery modules can be prevented, and the spread of fire can be prevented or suppressed.

Additionally, according to this aspect of the present invention, it is possible to prevent electrical short circuits from occurring inside the battery pack.

And, according to one aspect of the present invention, when a battery cell ignites, exposure of flame to the outside of the battery pack can be suppressed as much as possible.

Additionally, according to one aspect of the present invention, the problem of thermal runaway propagating between battery cells or between battery modules can be more effectively prevented or suppressed.

In particular, according to one embodiment of the present invention, even if gas or flame is generated in a specific battery cell, it is possible to prevent or minimize the influence of the gas or flame on other adjacent battery cells.

Therefore, according to this aspect of the present invention, even if thermal runaway occurs in a specific battery cell or a specific battery module, it is possible to prevent or delay thermal propagation between cells or between modules. Therefore, it is possible to ensure that the user has time to take appropriate measures, such as escape or fire suppression.

According to one aspect of the present invention, a battery module with improved safety and an application device thereof can be provided. In particular, when the battery module according to the present invention is applied to a vehicle, the safety of occupants can be more effectively guaranteed.

In addition, the present invention may have various other effects, and these will be described in each implementation configuration, or the description of effects that can be easily inferred by those skilled in the art will be omitted.

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. Therefore, the present invention includes the matters described in such drawings. It should not be interpreted as limited to only .
1 is a perspective view schematically showing the configuration of a battery module according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of the configuration of Figure 1.
FIG. 3 is a diagram schematically showing a partial configuration of a cell assembly included in a battery module according to an embodiment of the present invention.
Figure 4 is a diagram schematically showing the internal front side configuration of a battery module according to an embodiment of the present invention.
Figure 5 is a diagram showing a cross-sectional configuration of the front side of a battery module according to an embodiment of the present invention.
FIG. 6 is a diagram showing one form in which the expandable member is expanded in the configuration of FIG. 5.
Figure 7 is a top view schematically showing the configuration of a battery pack including a plurality of battery modules according to an embodiment of the present invention.
FIG. 8 is an enlarged view of portion A3 of FIG. 7.
Figure 9 is an exploded and enlarged perspective view of some components of a battery module according to an embodiment of the present invention.
Figure 10 is an enlarged view showing a partial configuration of a battery module according to an embodiment of the present invention.
Figure 11 is a diagram schematically showing an example of an expansion configuration of an expansion member according to an embodiment of the present invention.
Figure 12 is an exploded perspective view schematically showing the configuration of an expansion member according to another embodiment of the present invention.
Figure 13 is a diagram schematically showing the configuration of an expansion member according to another embodiment of the present invention.
Figure 14 is a diagram schematically showing the configuration of an expansion member according to another embodiment of the present invention.
Figure 15 is a diagram schematically showing a partial configuration of a battery module according to an embodiment of the present invention.
Figure 16 is a top view schematically showing the configuration of a battery module according to an embodiment of the present invention.
Figure 17 is an enlarged view showing a portion of a battery module according to an embodiment of the present invention.
Figure 18 is a perspective view showing some components of a battery module according to another embodiment of the present invention in isolation.
Figure 19 is a diagram of the combined configuration of a battery module according to another embodiment of the present invention as seen from the top.
Figure 20 is a perspective view schematically showing the configuration of a battery module according to another embodiment of the present invention.
FIG. 21 is a perspective view showing some components of the battery module of FIG. 20 separated.
Figures 22 and 23 are enlarged views of a portion of a battery module according to an embodiment of the present invention.
Figure 24 is a diagram schematically showing the configuration of a blocking cover according to an embodiment of the present invention.
FIG. 25 is a diagram schematically showing the cross-sectional configuration of the battery module to which the blocking cover of FIG. 24 is applied.
FIG. 26 is an enlarged view of portion A9 of FIG. 25.
27 and 28 are perspective and cross-sectional views schematically showing some configurations of a battery module according to another embodiment of the present invention.
Figure 29 is a diagram schematically showing the configuration of a battery cell and a taping member included in a battery module according to another embodiment of the present invention.
Figure 30 is a diagram schematically showing the configuration of a battery cell and a taping member included in a battery module according to another embodiment of the present invention.
Figure 31 is a rear perspective view of a battery module according to an embodiment of the present invention.
FIG. 32 is a diagram showing some of the components of FIG. 31 separated.
Figure 33 is a diagram showing a state in which flame, etc. is ejected from a battery module according to an embodiment of the present invention.
Figure 34 is a diagram schematically showing a partial configuration of a battery module according to an embodiment of the present invention.
Figure 35 is a diagram showing a cross-sectional configuration of the rear side of a battery module according to an embodiment of the present invention.
Figure 36 is an enlarged view of portion C3 in Figure 35.
Figure 37 is a perspective view showing the front side configuration of a battery module according to an embodiment of the present invention.
FIG. 38 is an exploded perspective view of a portion of the configuration of FIG. 37.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor must appropriately use the concept of terms to explain his or her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of definability.

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 entirely represent the technical idea of the present invention, so at the time of filing the present application, various options that can replace them are available. It should be understood that equivalents and variations may exist.

Meanwhile, in this specification, terms indicating directions such as up, down, left, right, front, and back may be used, but these terms are only for convenience of explanation and do not refer to the location of the target object or the location of the observer. It is obvious to those skilled in the art that it may vary depending on the subject.

Additionally, in this specification, terms indicating directions such as inside or outside may be used. Unless otherwise specified, inside may refer to a direction toward the central portion of the battery module, and outside may refer to the opposite direction. there is.

In addition, this specification includes various embodiments, but detailed descriptions of parts that are the same or similar to other embodiments will be omitted, and the description will focus on parts where there are differences for each embodiment.

1 is a perspective view schematically showing the configuration of a battery module according to an embodiment of the present invention. Additionally, Figure 2 is an exploded perspective view of the configuration of Figure 1.

Referring to FIGS. 1 and 2 , the battery module according to the present invention may include a cell assembly 100, a module case 300, and/or a module terminal 200.

The cell assembly 100 may include a plurality of battery cells 110. Here, each battery cell 110 may refer to a secondary battery. A secondary battery may include an electrode assembly, an electrolyte, and a battery case. In particular, the battery cell 110 may be a pouch-type secondary battery. The configuration of this pouch-type battery will be described in more detail with reference to FIG. 3.

FIG. 3 is a diagram schematically showing a partial configuration of a cell assembly 100 included in a battery module according to an embodiment of the present invention.

Referring to FIG. 3, the battery cell 110 is a pouch-type battery, and the case may be made of a pouch exterior material. In particular, in the case of a pouch-type battery, it may include a receiving part and a sealing part.

Here, the receiving part may be a part in which the electrode assembly is accommodated inside the pouch exterior material and protrudes outward, such as the part indicated by S1 in FIG. 3 . Additionally, the sealing portion may be a portion formed by fusion of two pouch exterior materials around the storage portion S1, such as the portion indicated by S2 in FIG. 3 . In particular, when the pouch-type battery is formed in a substantially square shape, the sealing portion S2 may be located at three or four corners of the edge of the pouch-type battery. At this time, a pouch-type battery in which the sealing portion (S2) is located at four corners is referred to as a four-side sealing cell, and a pouch-type battery in a form in which the sealing portion (S2) is located at three corners is referred to as a three-side sealing cell. It could be. For example, the battery cell 110 shown in FIG. 3 may be a three-sided sealed cell in which the top edge, front edge, and rear edge are sealed.

A plurality of battery cells 110 may be stacked side by side in at least one direction. For example, as shown in FIG. 2, multiple battery cells 110 may be stacked side by side in the left and right direction (Y-axis direction). At this time, each battery cell 110 may be configured to stand upright (Z-axis direction). For example, in the plurality of battery cells 110 provided in the cell assembly 100, as shown in FIGS. 2 and 3, the storage portion S1 is oriented in the left and right directions, and the sealing portion S2 is oriented forward and backward. In an upright position facing upward, they can be arranged side by side in the left and right directions. Additionally, each battery cell 110 may be stacked with the storage portion S1 facing each other.

Here, in order to maintain the stacked state of the cell assembly 100 more stably, the battery cells 110 may be bonded to each other. For example, as shown in the portion indicated by DT in FIG. 2, a cell adhesive member may be interposed between the battery cells 110. At this time, the cell adhesive member DT may be configured in the form of a double-sided adhesive tape in which adhesive is applied to both sides of the substrate.

In a pouch-type cell, the electrode lead 111 may be arranged to protrude in the front-back direction. For example, as shown in the embodiment of FIG. 3, the electrode lead 111 may be provided at the front (+X-axis direction) side end and the rear (-X-axis direction) side end of the pouch-type cell, respectively. there is.

Meanwhile, in this specification, unless otherwise specified, the direction in which the battery cells 110 are stacked is referred to as the left and right direction, and the direction in which the electrode lead 111 is located in each battery cell 110 may be referred to as the front-to-back direction. . Accordingly, each drawing will be described based on the X-axis direction being shown as a front-to-back direction and the Y-axis direction being shown as a left-right direction.

The module case 300 may be formed in an empty space inside and configured to accommodate the cell assembly 100 in the internal space. For example, as shown in FIGS. 1 and 2, the module case 300 includes a main body frame 310 formed in the form of a tube with both ends open and an end frame covering the open portions at both ends of the main body frame 310. (320) can be provided. This type of body frame 310 is open at the front and rear, and may be provided with a left plate, a right plate, an upper plate, and a lower plate. Additionally, the left plate, right plate, upper plate, and lower plate may be formed in an integrated form, and this body frame 310 may also be referred to as a mono frame. Additionally, the end frames 320 located at the front and rear of the main body frame 310 may be referred to as a front frame (front plate) and a rear frame (rear plate), respectively.

In this implementation configuration, the module case 300 has an internal space limited by the main body frame 310 and the end frame 320, and various components including the cell assembly 100 can be accommodated in the limited internal space. there is.

In addition, the module case 300 may be formed in various other forms. For example, the left plate, right plate, and bottom plate may be configured in an integrated form. At this time, the integrated case part may be referred to as a U-frame. Alternatively, the module case 300 may be provided with a box-shaped lower case in which the left plate, right plate, front plate (front frame), and back plate (rear frame) are integrated, and an upper cover that closes the upper open end of the lower case. there is.

Each component of the module case 300, such as the main body frame 310 and the end frame 320, may be coupled to each other in various ways, such as welding, insertion, adhesion, and hooking. Additionally, the module case 300 may be made of various materials such as metal or plastic. In particular, both the main body frame 310 and the end frame 320 may be made of aluminum. In this case, mutual weldability is excellent, it is advantageous for weight reduction, and cooling performance can also be improved.

The module terminal 200 may be electrically connected to the cell assembly 100. In particular, the cell assembly 100 includes a plurality of battery cells 110 and may be electrically connected to each other in series and/or parallel. Additionally, the plurality of electrically connected battery cells 110 may be connected to other components outside the battery module, such as other battery modules or pack terminals. For example, the module terminal 200 may be connected to a busbar between modules and connected to another battery module.

The module terminal 200 allows charging and discharging currents to flow for the cell assembly 100, and can be said to be a gateway to an electrical path through which these charging and discharging currents can be connected to other components located outside the battery module. . The module terminal 200 may have two terminals, that is, a positive terminal and a negative terminal.

The module terminal 200 may be installed on the outside of the module case 300, especially on the front side. For example, referring to the exemplary configuration of FIG. 2, the electrode lead 111 of each battery cell 110 is provided to protrude toward the front and rear sides of the cell assembly 100, and the module terminal 200 has these electrodes. It may be electrically connected to the lead 111. Here, the module terminal 200 may include a positive terminal and a negative terminal, and both the positive terminal and the negative terminal may be installed on the front side of the module case 300. Additionally, the module terminal 200 may be located on the upper side of the module case 300. In this case, external components can be easily connected to the module terminal 200.

The expansion member 500 may be disposed on the front side of the cell assembly 100 in the internal space of the module case 300. For example, as shown in FIG. 2, the expansion member 500 is disposed in the internal space defined by the mono frame and the end frame 320, and is located along the +X axis in the front side direction of the cell assembly 100. It can be located in any direction.

In addition, the expansion member 500 may be configured to expand in volume by heat to fill at least a portion of the internal space of the module case 300. This will be described in more detail with additional reference to FIGS. 4 to 6.

Figure 4 is a diagram schematically showing the internal front side configuration of a battery module according to an embodiment of the present invention. Additionally, Figure 5 is a diagram showing a cross-sectional configuration of the front side of a battery module according to an embodiment of the present invention. And FIG. 6 is a diagram showing one form in which the expandable member 500 is expanded in the configuration of FIG. 5 .

Referring to FIGS. 4 to 6 , the expansion member 500 may be disposed on the front side of the cell assembly 100 and may be configured to cover at least a portion of the front of the cell assembly 100 . For example, as shown in FIGS. 4 and 5 , the front side of the cell assembly 100 in the internal space of the module case 300 may be covered by the expansion member 500. In addition, the expansion member 500 disposed on the front side of the cell assembly 100 may be configured to expand by heat. For example, when thermal runaway occurs inside the cell assembly 100, heat may be transferred from the cell assembly 100 to the expansion member 500. At this time, the expansion member 500 is expanded in volume by the heat transferred in this way, and can fill at least a portion of the empty space located on the front side of the cell assembly 100, as shown in FIG. 6. Moreover, the expansion member 500 may be configured to fill the empty space between the front frame 320F and the cell assembly 100. For example, the expandable member 500 may fill at least a portion of the portion indicated by B1 in FIG. 5 by expansion.

According to the above-mentioned configuration, it is possible to suppress or reduce exposure of flame, heat, electrode discharge, etc. to the front side of the battery module where the module terminal 200 is located due to expansion of the expansion member 500. Furthermore, a terminal hole HT may be formed in the module case 300 so that the module terminal 200 can be exposed to the outside. According to the above-mentioned configuration, flames, etc. are emitted through the terminal hole HT. It can be prevented or suppressed from happening. In this case, it may be more effective in suppressing heat propagation between battery modules or preventing voltage drop of the battery pack. This will be described in more detail with additional reference to FIGS. 7 and 8.

Figure 7 is a top view schematically showing the configuration of a battery pack including a plurality of battery modules according to an embodiment of the present invention. Furthermore, FIG. 7 may be said to be a diagram showing the configuration of a battery pack according to an embodiment of the present invention. FIG. 8 is an enlarged view of portion A3 of FIG. 7.

Referring to FIGS. 7 and 8 , a plurality of battery modules according to an embodiment of the present invention may be stored in the internal space of the pack housing (PH). For example, a battery pack may include eight battery modules, as indicated by M1 to M8 in FIG. 7 . At this time, each battery module may be placed on a side where the module terminal 200 faces another battery module. For example, in the implementation configuration of FIG. 8, the first module (M1) has a module terminal 200 located at an end in the -X axis direction, and the second module (M2) has a module terminal 200 located at an end in the +X axis direction. can be located.

Moreover, in the case of the battery module according to the present invention, the module terminal 200 can be arranged so that it is located on the front side. Looking at the implementation configuration of FIGS. 7 and 8, the two battery modules have their front sides facing each other. It can be placed inside the pack housing (PH) in a fixed form. In this way, when each battery module is arranged so that the module terminal 200 is located on a side close to another battery module, connection between battery modules using a module bus bar, etc. can be facilitated.

In such an arrangement configuration between multiple battery modules, if flame or high-temperature gas is discharged to the front where the module terminal 200 is located, the fire may spread to other battery modules or problems such as thermal runaway propagation are likely to occur. However, in the case of the battery module according to the present invention, the discharge of flames or gases in the direction toward other battery modules or the module terminal 200 can be suppressed, so problems such as fire spread or heat spread between these modules are more effectively prevented. It can be prevented.

In addition, in the case of the above implementation configuration, discharge of electrode discharge to the module terminal 200 is prevented, and electrode discharge is attached to the module terminal 200 or the bus bar between modules, etc., and is prevented from being discharged to the module terminal 200 or the inside of the battery pack. This can prevent short circuits from occurring. In addition, according to the above-mentioned configuration, when the expansion member 500 is expanded, flame or heat is prevented from being directed toward the front frame 320F, and the front frame 320F can be prevented from being melted by flame. . Therefore, even when flame erupts from inside the battery module, structural collapse of the module case 300 can be prevented as much as possible.

The expansion member 500 may include a material that is foamed by heat. For example, the expandable member 500 may include a material that begins to foam at 200°C or higher. Furthermore, the expansion member 500 may be configured to be foamed by a flame or a high-temperature gas that provides such temperature conditions. As a specific example, the expansion member 500 may be made of a carbon-based material and configured to be expanded by heat.

According to this implementation configuration, when a flame or high-temperature gas is generated due to thermal runaway, etc. on the cell assembly 100, the space on the front side of the cell assembly 100 can be quickly filled. Accordingly, it is possible to quickly block or suppress flames, etc. from being exposed to the front side of the cell assembly 100.

The expansion member 500 may be arranged to be spaced apart from the electrode lead 111 of the cell assembly 100 by a predetermined distance.

For example, the expandable member 500 may be spaced apart from the electrode lead 111 at a certain distance or more, as shown in the portion indicated by B1 in FIG. 5 . That is, the expansion member 500 may be mounted in the internal space of the module case 300 so as not to directly contact the electrode lead 111.

According to this implementation configuration, it is possible to use an electrically conductive material for the expansion member 500. That is, even if the expansion member 500 includes an electrically conductive material, there is no direct contact between the electrode lead 111 and the expansion member 500, so problems such as short circuits due to direct contact between them can be prevented. You can.

Additionally, the expandable member 500 may be at least partially insulated. In particular, at least a portion of the expansion member 500 facing the cell assembly 100 may be coated with an electrically insulating material.

For example, referring to the exemplary configuration of FIG. 5, the surface of the expansion member 500 facing the cell assembly 100, that is, the rear surface, may be coated with a PET (PolyEthylene Terephthalate) material. However, in addition to this, the insulating coating layer may be made of various other materials.

According to this implementation configuration, it may be advantageous to secure electrical insulation for the expandable member 500. For example, in this case, when the expansion member 500 directly contacts the electrode lead 111 or other electrical components, electrical problems such as short circuits can be prevented from occurring. In particular, the battery module according to the present invention can be installed in automobiles that may be exposed to vibration or shock during use. At this time, according to the above implementation configuration, even when the expandable member 500 temporarily contacts the electrode lead 111 during vibration or impact, problems such as short circuit can be prevented from occurring.

As shown in FIGS. 2 and 5, the battery module according to the present invention may further include an insulating cover 900, particularly a front insulating cover 900F.

The front insulating cover 900F may be made of an electrically insulating material. For example, the front insulating cover 900F may be made of a polymer material such as plastic. As a more specific example, the front insulating cover 900F may be made of Modified Polyphenylene Oxide (MPPO) material.

The front insulating cover 900F may be interposed between the front side of the cell assembly 100 and the module case 300. That is, the front insulating cover 900F may be interposed between the cell assembly 100 and the front frame 320F. Accordingly, electrical insulation can be secured between the cell assembly 100 and the front frame 320F. In particular, electrical components such as electrode leads 111 may be located on the front side of the cell assembly 100. And, the front frame 320F may be made of an electrically conductive material such as aluminum. At this time, the front insulating cover 900F made of an electrically insulating material is interposed between the electrode lead 111 and the front frame 320F of the cell assembly 100, thereby electrically insulating them.

The front insulating cover 900F may have an expansion member 500 attached to its inner surface. That is, the expansion member 500 may be attached to the rear of the front insulating cover 900F using double-sided tape or the like. In this case, the front insulating cover 900F may be configured to provide a space to which the expansion member 500 can be attached. For example, the rear of the front insulating cover 900F may have a flat portion to which the expansion member 500 can be attached. In this case, the expansion member 500 can be stably positioned inside the module case 300. In particular, it is desirable for the expandable member 500 to be spaced a certain distance away from the electrode lead 111 of the cell assembly 100. In the above-described configuration, the distance between the expandable member 500 and the electrode lead 111 is kept stable. It can be ensured.

Meanwhile, the front insulating cover 900F may be made of a polymer material, in which case it may melt or disappear in a high temperature flame. However, in the present invention, even if the front insulating cover 900F melts or disappears on the front side of the cell assembly 100, the expansion member 500 may foam or expand and block the front side of the cell assembly 100. In addition, when the expansion member 500 is expanded, flames, etc., can be suppressed from being directed toward the front insulating cover 900F, thereby minimizing melting or loss of the front insulating cover 900F.

The front insulating cover 900F may be fastened to the module case 300 through a protrusion structure. This will be described in more detail with reference to FIG. 9 .

Figure 9 is a perspective view showing an exploded and enlarged partial configuration of a battery module according to an embodiment of the present invention. In particular, Figure 9 shows the front frame 320F and the front insulating cover 900F being separated from each other.

Referring to FIG. 9, the module case 300, particularly the front frame 320F, may have a front fastening hole formed in the portion indicated by HLF. In addition, the front insulating cover 900F may have a front fastening protrusion formed in the portion indicated by PLF. Here, the front fastening protrusion (PLF) may be inserted into the front fastening hole (HLF) when assembling the battery module. A plurality of front fastening protrusions (PLF) may be formed on the front insulating cover 900F. Additionally, a plurality of front fastening holes (HLF) may also be formed in the front frame 320F to correspond to the plurality of front fastening protrusions (PLF).

Moreover, the front fastening protrusion (PLF) may be inserted in a form that penetrates the front frame 320F from the inside to the outside. Additionally, the outer end of the front fastening protrusion (PLF) exposed to the outside of the front frame 320F may be formed to be thicker than the penetrating portion. That is, the outer end of the front fastening protrusion (PLF) may be formed to be larger than the size of the front fastening hole (HLF). At this time, the thick portion of the outer end may be prepared by inserting the front fastening protrusion (PLF) into the front fastening hole (HLF) and then pressing it by applying heat and pressure.

According to this embodiment of the present invention, the coupling force between the front frame 320F and the front insulating cover 900F can be stably secured. Additionally, in this case, it is possible to prevent the front insulating cover 900F or the expansion member 500 attached therefrom from moving toward the electrode lead 111 and contacting the electrode lead 111, etc.

The expansion member 500 may be configured to close the front fastening hole (HLF) when expanded. First, the expansion member 500 may be positioned in a position to block the front fastening hole (HLF) when expanded. The expansion member 500 may be disposed in a position to cover the front fastening hole (HLF) on the Y-Z axis plane when expanded. Additionally, the expansion member 500 may have a shape or structure that can block the front fastening hole (HLF) when expanded. In particular, the expansion member 500 may have a position and shape capable of covering the front fastening hole (HLF) on the Y-Z axis plane even before expansion.

As a more specific example, when a plurality of front fastening holes (HLF) are formed in the front frame 320F, the expansion member 500 may be configured to block all of the plurality of front fastening holes (HLF) in an expanded state. .

According to this embodiment of the present invention, even if at least a portion of the front insulating cover 900F is melted or lost, flame, high temperature gas, electrode discharge, etc. are ejected to the front side of the battery module through the front fastening hole (HLF). You can prevent it from happening. In particular, in normal conditions, the front fastening hole (HLF) is blocked by the front fastening protrusion (PLF) of the front insulating cover (900F), but if the front insulating cover (900F) melts or disappears due to high heat caused by a flame, etc., the front fastening hole (HLF) is blocked by the front fastening projection (PLF) of the front insulating cover (900F). The hole (HLF) may be opened. However, by preventing the expansion member 500 from opening the front fastening hole (HLF), external exposure such as flame through the front fastening hole (HLF) can be reliably limited.

The expansion member 500 may be configured to block flame or gas from being directed toward the module terminal 200. This will be described in more detail with additional reference to FIG. 10.

Figure 10 is an enlarged view showing a partial configuration of a battery module according to an embodiment of the present invention. For example, FIG. 10 may be an enlarged view showing the configuration of the upper part of the drawing of FIG. 5.

With additional reference to FIG. 10 along with FIGS. 5 and 6 , the expandable member 500 may expand when flame or gas is emitted from the cell assembly 100 . In particular, the module terminal 200 may be located on the upper front side, and an empty space may exist at the bottom of the module terminal 200, as indicated by B2 in FIG. 10. However, when a thermal runaway situation occurs in the cell assembly 100 and the expansion member 500 expands, at least a portion of the lower empty space B2 of the module terminal 200 may be filled by the expansion member 500. there is.

In this case, as shown in the portion indicated by arrow B3 in FIG. 10, even if a flame, etc., heads from the cell assembly 100 toward the module terminal 200, the already expanded expansion member 500 can prevent the movement of the flame. In particular, there may be a terminal hole (HT) on the module terminal 200 side, and the expansion member 500 is such that, in an expanded state, flame, gas, electrode discharge, etc. are discharged to the outside toward the terminal hole HT. can be suppressed. Therefore, according to this implementation configuration, it is possible to more effectively prevent heat propagation or flame propagation between modules, or short circuit in the electrical connection configuration between modules.

The expansion member 500 may be configured to expand in all directions by heat. This will be described in more detail with additional reference to FIG. 11.

FIG. 11 is a diagram schematically showing an example of the expansion configuration of the expansion member 500 according to an embodiment of the present invention.

Referring to FIG. 11, the expansion member 500 may have a sheet shape with two large surfaces facing the front-back direction (X-axis direction). At this time, the expansion member 500 may be made of a material that expands not only in the front-back direction, which is the thickness direction, but also in all directions, including up, down, left, and right. For example, as indicated by six arrows in FIG. 11, the expandable member 500 can be expanded in all directions of the +X direction, -X direction, +Y direction, -Y direction, +Z direction, and -Z direction. there is. That is, the sheet-shaped expansion member 500 can be configured to be expandable in all directions in the direction parallel to the surface (direction parallel to the Y-Z plane) and the direction perpendicular to the surface (±X-axis direction) when expanded. . Furthermore, the expansion member 500 may be made of a material that foams in all directions when expanded by thermal foaming.

According to this implementation configuration, even if the shape or structure of the expansion member 500 in a normal state is not specially provided, the empty space inside the module case 300 can be well filled when the expansion member 500 is expanded. Accordingly, manufacturability of the expansion member 500 or the internal space of the module case 300 equipped with the expansion member 500 may be easy. In addition, the flame blocking effect by the expansion member 500 can be stably secured.

The expansion member 500 may be configured in the form of a sheet of a single material. However, the present invention is not necessarily limited to this form, and the expansion member 500 may be configured in various other forms. In particular, the expansion member 500 may be configured in the form of a composite sheet made of different materials. This will be described in more detail with reference to FIG. 12.

Figure 12 is an exploded perspective view schematically showing the configuration of an expansion member 500 according to another embodiment of the present invention.

Referring to FIG. 12, the expandable member 500 may include two sheets, that is, a first expandable sheet 510 and a second expandable sheet 520. Here, the first expandable sheet 510 and the second expandable sheet 520 may be made of different materials. Moreover, the first expandable sheet 510 may be configured to be specialized for expansion, and the second expandable sheet 520 may be configured to be specialized for flame blocking. In this case, the second expandable sheet 520 may be made of a material with a higher melting point than the first expandable sheet 510. Additionally, the first expandable sheet 510 and the second expandable sheet 520 may be made of materials with different electrical conductivity. Furthermore, the first expandable sheet 510 may be made of an electrically conductive material, and the second expandable sheet 520 may be made of an electrically insulating material.

As a representative example, the first expandable sheet 510 may be made of a material that foams by heat, such as a graphite-based foam material. Additionally, the second expansion sheet may be made of mica material.

Additionally, the first expandable sheet 510 and the second expandable sheet 520 may have different thicknesses. For example, the first expandable sheet 510 may be configured to have a thickness of 3 mm, and the second expandable sheet 520 may be configured to have a thickness of 1 mm.

The first expandable sheet 510 and the second expandable sheet 520 may be stacked on each other in the thickness direction. In particular, the second expandable sheet 520 may be located inside the first expandable sheet 510. In particular, when the expansion member 500 is located on the front side of the cell assembly 100, the second expansion sheet 520 may be stacked on the rear side of the first expansion sheet 510. In this case, the second expandable sheet 520 may directly face the electrode lead 111 of the cell assembly 100, and the first expandable sheet 510 may not directly face the electrode lead 111.

According to this implementation configuration, even if the first expandable sheet 510 is made of a graphite-based material and is electrically conductive, the first expandable sheet 510 is formed by the electrode lead 111 by the second expandable sheet 520, which has electrical insulation. ) can be prevented from coming into direct contact with etc. Therefore, electrical insulation between the first expansion sheet 510 and the electrode lead 111 can be stably secured.

In addition, according to the above-mentioned configuration, even if flame or high-temperature gas is ejected from the cell assembly 100 toward the front, the second expandable sheet 520 will primarily block the flame, etc. from heading toward the first expandable sheet 510. You can. Accordingly, the first expandable sheet 510 can be stably foamed or expanded without being immediately burned by a flame or the like.

Additionally, according to the above-described implementation configuration, the overall thickness of the expandable member 500 can be reduced. For example, according to the above embodiment, the expansion space of the first expandable sheet 510 is reduced by the space occupied by the second expandable sheet 520, so even if the thickness of the first expandable sheet 510 is not increased, the cell The space on the front side of the assembly 100 can be filled more quickly and reliably. Therefore, even if it is configured with a thin thickness, the performance of the expansion member 500, which seals the space on the front side of the cell assembly 100 and blocks flame emission on the front side, can be more effectively secured.

FIG. 13 is a diagram schematically showing the configuration of an expansion member 500 according to another embodiment of the present invention. In particular, Figure 13 (a) is a diagram showing the cross-sectional configuration of the expandable member 500 before it is expanded, and Figure 13 (b) is a diagram showing the cross-sectional configuration of the expandable member 500 after it is expanded. .

Referring to FIG. 13, the expansion member 500 may be made of different materials in the vertical direction. For example, in the previous embodiment of FIG. 12, two sheet members may be stacked on each other in the thickness direction, but in the embodiment of FIG. 13, two sheet members may be stacked on each other in the planar direction. In particular, two sheet members, that is, the first expandable sheet 510 and the second expandable sheet 520, may be stacked in the vertical direction with their edges facing each other. At this time, the first expandable sheet 510 may be stacked on top of the second expandable sheet 520. In this respect, the first expandable sheet 510 may be referred to as an upper expandable sheet, and the second expandable sheet 520 may be referred to as a lower expandable sheet.

The first expandable sheet 510 and the second expandable sheet 520 may be made of different materials. In particular, the first expandable sheet 510 and the second expandable sheet 520 may have different thermal expansion rates. Furthermore, the first expandable sheet 510 may have a higher thermal expansion rate than the second expandable sheet 520.

For example, as shown in (a) of FIG. 13, the first expandable sheet 510 and the second expandable sheet 520 may have the same or similar thickness to each other before being expanded. On the other hand, the first expandable sheet 510 and the second expandable sheet 520 may have different thicknesses after expansion, as shown in (b) of FIG. 13. In particular, the first expandable sheet 510 may be configured to have a higher thermal expansion rate than the second expandable sheet 520.

That is, when heat is applied from the cell assembly 100 side, as indicated by the dotted arrow in FIG. 13 (a), the first expandable sheet 510 expands as indicated by arrow B4 in FIG. 13 (b). It can expand in the thickness direction. Additionally, the second expandable sheet 520 may expand in the thickness direction as indicated by arrow B4' in (b) of FIG. 13. At this time, the thickness direction expansion rate of the first expandable sheet 510 may be greater than the thickness direction expansion rate of the second expandable sheet 520. That is, after expansion, the first expandable sheet 510 may become thicker than the second expandable sheet 520.

According to this implementation configuration, the expansion rate of the expansion member 500 is configured to be partially different, thereby suppressing or inducing the flame, etc. to move to a specific part. For example, as shown in FIG. 13, when the expansion rate of the first expandable sheet 510 laminated on the top is thick, as indicated by arrow B5 in (b), the direction from the inside to the outside (+X axis direction) ) When the flame or electrode discharge directed to hits the expansion member 500 and is reflected toward the upper side, the reflection angle may be less than 90 degrees (°). That is, in the case of the above-mentioned configuration, the flame or electrode discharge is reflected in a bent state toward the rear (-

Meanwhile, in the embodiment of FIG. 13, an embodiment is shown in which two expansion sheets arranged in a vertical direction have the same initial thickness but are made of materials with different expansion rates. However, the expansion thickness of the expansion member 500 is different. The configuration may be implemented in other ways. This will be described in more detail with reference to FIG. 14.

FIG. 14 is a diagram schematically showing the configuration of an expansion member 500 according to another embodiment of the present invention. In particular, Figure 14 (a) is a diagram showing the cross-sectional configuration of the expandable member 500 before it is expanded, and Figure 14 (b) is a diagram showing the cross-sectional configuration of the expandable member 500 after it is expanded. .

First, referring to (a) of FIG. 14, the first expandable sheet 510 and the second expandable sheet 520 may have different thicknesses before expansion. That is, the thickness of the first expandable sheet 510 located on the upper side is indicated as B6, and the thickness of the second expandable sheet 520 located on the lower side is indicated as B6'. At this time, B6 and B6' are different values and may have a relationship of B6>B6'.

And, as indicated by the dotted arrow, when heat is applied from the cell assembly 100, the first expandable sheet 510 and the second expandable sheet 520 may expand in the thickness direction. At this time, as shown in (b) of FIG. 14, the first expandable sheet 510 and the second expandable sheet 520 may have different thicknesses after expansion. That is, the first expandable sheet 510 may have a thickness indicated by B7, and the second expandable sheet 520 may have a different thickness indicated by B7'. In particular, B7 and B7' have a relationship of B7>B7', and the thickness of the first expandable sheet 510 after expansion may be thicker than the thickness of the second expandable sheet 520 after expansion.

Even in this configuration, as described in the previous embodiment of FIG. 13, movement of flames or particles in a specific direction can be suppressed or induced. Moreover, in this embodiment, the first expandable sheet 510 and the second expandable sheet 520 do not need to have different expansion rates, so they can be made of the same material. Additionally, the first expandable sheet 510 and the second expandable sheet 520 may be manufactured in an integrated form, and a process of separately manufacturing them and then joining them together may not be necessary. Therefore, in this case, manufacturing of the expansion member 500 becomes easier and structural stability can be ensured.

Meanwhile, in the embodiments of FIGS. 13 and 14, the explanation is centered on the configuration in which the expandable member 500 is expanded in the thickness direction. However, as described above, the expandable member 500 is expanded in the plane (Y-Z plane) direction. You may.

The battery module according to the present invention may include a busbar assembly 400, as shown in FIG. 2. The bus bar assembly 400 may be connected to the electrode lead 111 of the battery cell 110. Furthermore, the electrode leads 111 of the battery cell 110 may be located at both front and rear ends of the cell assembly 100, as shown in FIG. 3 . In this case, the bus bar assembly 400 may be disposed on the front and rear sides of the cell assembly 100, respectively.

More specifically, the busbar assembly 400 may include a busbar terminal 410 and a busbar housing 420. Here, the bus bar terminal 410 may be electrically connected to the cell assembly 100. In particular, the bus bar assembly 400 is made of a conductive metal material such as copper and can be in direct contact with the electrode lead 111. In addition, the bus bar housing 420 is made of an electrically insulating material such as plastic, and the position of the bus bar terminal 410 can be fixed by mounting the bus bar terminal 410 thereon. To this end, the bus bar housing 420 may be provided with a space or structure in which the bus bar terminal 410 can be mounted.

The bus bar assembly 400 may include one or more unit bus bars depending on the series or parallel connection state between the plurality of battery cells 110 included in the cell assembly 100. For example, as shown in FIG. 2, a plurality of bus bar terminals 410 (unit bus bars) may be mounted on one bus bar housing 420. At this time, the bus bar housing 420 can prevent contact between different unit bus bars.

The module terminal 200 may be connected to the bus bar terminal 410 of the bus bar assembly 400. For example, the module terminal 200 may be provided connected to the upper part of the bus bar terminal 410. In particular, the module terminal 200 may be configured to be integrated with at least a portion of the bus bar terminal 410. For example, in the implementation configuration of FIG. 2, the module terminal 200 may be provided in an integrated form with the bus bar terminal 410 located at the outermost side in the left and right direction. As a more specific example, among the plurality of bus bar terminals 410, the bus bar terminal 410 located on the leftmost side may be configured with the positive terminal of the battery module integrated at the top. Additionally, the bus bar terminal 410 located on the far right may be configured as an integrated negative terminal of the battery module.

The module terminal 200 is connected to the bus bar assembly 400 located inside the module case 300, and needs to be exposed to the outside of the module case 300 for connection to external components. Accordingly, a hole may be formed in the module case 300 to expose the module terminal 200 to the outside. Moreover, since the module terminal 200 is located on the front side of the module case 300, it can be formed on the front frame 320F located on the front side of the module case 300. As a more specific example, referring to the exemplary drawing of FIG. 2, a terminal hole may be formed at the top of the front frame 320F, as in the portion indicated by HT. Additionally, the module terminal 200 connected to the bus bar terminal 410 may be exposed to the outside of the module case 300 through the terminal hole HT.

In this configuration, the expansion member 500 may be positioned at a predetermined distance from the front bus bar assembly 400. For example, the expansion member 500 may be located at a position spaced a predetermined distance forward from the bus bar terminal 410 or the bus bar housing 420, as indicated by B1 in FIG. 5 . That is, in a normal state in which thermal runaway, etc. does not occur, an empty space may be located between the expansion member 500 and the busbar assembly 400. Also, when thermal runaway occurs and the expandable member 500 expands, this empty space may be filled by the expandable member 500. For example, the expansion member 500 may be configured to be expanded by heat to fill the space between the bus bar assembly 400 and the insulating cover 900.

According to this implementation configuration, even if the expansion member 500 includes an electrically conductive material, electrical insulation between the expansion member 500 and the bus bar terminal 410 can be secured. Additionally, in this case, problems such as damage to the bus bar assembly 400 due to the expansion member 500 coming into contact with the bus bar assembly 400 despite external shock or vibration can be prevented.

The bus bar housing 420 of the front side bus bar assembly 400 may include a front housing protrusion. This will be described in more detail with additional reference to FIG. 15.

Figure 15 is a diagram schematically showing a partial configuration of a battery module according to an embodiment of the present invention. In particular, in Figure 15, the front frame 320F and the front insulation cover 900F are removed from the front side of the battery module, and the expansion member 500 is moved further to the front side of the bus bar assembly 400. It is shown.

Referring to FIG. 15, the front bus bar assembly 400 may include a bus bar terminal 410 and a bus bar housing 420. At this time, the busbar housing 420 may have a front housing protrusion as indicated by PHF. The front housing protrusion (PHF) may be formed to protrude toward the expansion member 500 located at the front. In particular, a bus bar terminal 410 is mounted on the bus bar housing 420, and the electrode lead 111 may be contact-coupled to the bus bar terminal 410 in a bent form. At this time, the front housing protrusion (PHF) may protrude further forward than the bus bar terminal 410 or the electrode lead 111 in contact with it.

According to this embodiment of the present invention, in a normal state, direct contact between the bus bar terminal 410 or the electrode lead 111, which is a component for electrical connection, and the expansion member 500 can be more reliably prevented. . In particular, even if the expansion member 500 is made of an electrically conductive material, the separation distance between the bus bar terminal 410 or the electrode lead 111 and the expansion member 500 is stably secured by the front housing protrusion (PHF). can do.

Referring to the embodiment of FIG. 5, the front housing protrusion (PHF), as in the portion indicated by B1, is an expansion member ( It may be configured to protrude toward 500). At this time, the front end of the front housing protrusion (PHF) may be positioned at a predetermined distance apart from the inner surface of the expansion member 500 without directly contacting it. In this case, a tolerance can be stably secured between the expansion member 500 and the busbar assembly 400.

As another example, the front end of the front housing protrusion (PHF) may directly contact the inner surface of the expandable member 500. In this case, the expansion member 500 can maintain its position more stably inside the module case 300 despite external vibration or shock.

Additionally, the front housing protrusion (PHF) may be formed to extend long in the vertical direction. In particular, since the bus bar terminal 410 mounted on the bus bar housing 420 may be formed to extend long in the vertical direction, the front housing protrusion (PHF) may be formed to be long in the vertical direction like the bus bar terminal 410. You can.

Additionally, a plurality of bus bar terminals 410 may be arranged to be spaced apart from each other in the left and right directions in the bus bar housing 420. At this time, the front housing protrusion (PHF) may be interposed between adjacent bus bar terminals 410, as shown in FIG. 15. Moreover, a plurality of front housing protrusions (PHF) may be arranged horizontally in the busbar housing 420. In this case, a stable separation distance can be maintained between all bus bar terminals 410 and the expansion member 500. Additionally, in this case, a state of physical separation between adjacent bus bar terminals 410 can be stably secured.

The expansion member 500 may be configured so that its lower end is positioned higher than the lower end of the bus bar terminal 410.

For example, referring to the exemplary configuration of FIG. 5, in a normal, non-expanded state, the lower end of the expansion member 500 may be positioned higher than the lower end of the bus bar terminal 410 as indicated by B8. In other words, the lower end of the bus bar terminal 410 may be located at a lower position than the lower end of the expansion member 500.

According to this implementation configuration, electrical insulation between the expansion member 500 and the bus bar terminal 410 can be improved. In particular, if electrolyte leaks from the cell assembly 100 or moisture flows into the module case 300, the electrolyte or moisture may accumulate on the bottom of the module case 300. At this time, if the height of the lower end of the expansion member 500 is configured to be higher than the lower end of the bus bar terminal 410, electricity flow between the bus bar terminal 410 and the expansion member 500 can be prevented even if the electrolyte, etc. is filled to a predetermined height. You can. Therefore, the electrical safety of the battery module can be improved even in situations where electrolyte, etc. leaks or moisture flows in.

The module case 300 may have a top hole (HV) formed on at least one side, such as the portion indicated by HV in FIGS. 1 and 2. This top hole (HV) may be provided to penetrate the module case 300 inside and out and communicate with the internal space of the module case 300. In particular, the top hole (HV) may be formed on the upper side of the module case 300. For example, when the module case 300 is configured in the form of a mono frame including an upper plate, a lower plate, a left plate, and a right plate as shown in FIG. 2, a top hole (HV) may be formed in the upper plate.

Additionally, a plurality of top holes (HV) may be formed on the upper plate of the module case 300. For example, a number of top holes HV may be arranged in the horizontal direction, that is, in the front-back direction (X-axis direction) and/or in the left-right direction (Y-axis direction), on the upper side of the main body frame 310.

According to this embodiment of the present invention, when venting gas or flame is generated inside the battery module due to an event such as thermal runaway, such gas or flame is smoothly discharged to the outside of the module case 300. You can. Therefore, in an emergency, the internal pressure of the module case 300 can be quickly lowered to prevent an explosion of the battery module.

Additionally, according to the implementation configuration of the present invention, the discharge direction of gas, flame, etc. can be appropriately controlled. Therefore, it is possible to minimize heat propagation or flame propagation between battery modules due to the emission of gas or flame.

In addition, according to the above embodiment, when the expansion member 500 is provided on the front side of the cell assembly 100, the flame or gas does not first head to the expansion member 500, but passes through the top hole (HV) to the upper part. It can be discharged to the side. In this case, only heat is first transferred to the expandable member 500, allowing the expandable member 500 to sufficiently inflate. Moreover, before the expansion member 500 is expanded, gas or flame is first ejected into the expansion member 500, and the expansion member 500 is separated by the gas or flame, or flames, etc. are emitted into the empty space before expansion. Leakage can be prevented.

In the cell assembly 100, a taping member 120 may be attached to each of the plurality of battery cells 110, as shown in FIG. 3. That is, in the battery module according to the present invention, the cell assembly 100 may include the taping member 120 together with the battery cell 110.

The taping member 120 may be provided with an adhesive on at least one side and may be attached to the battery cell 110. Furthermore, the taping member 120 may be attached to the sealing portion of the battery cell 110. In particular, the taping member 120 may be attached to at least the upper sealing portion of the battery cell 110 when each battery cell 110 is placed in an upright position, as shown in FIGS. 2 and 3. .

More specifically, referring to the exemplary configuration of FIG. 3, in the battery cell 110, the sealing portion includes a front sealing portion indicated by S2F, a rear sealing portion indicated by S2R, and an upper sealing portion indicated by S2U. can do. At this time, the taping member 120 may be attached to the upper sealing part (S2U) located on the upper side among these various sealing parts.

The taping member 120 may be attached not only to the upper sealing part S2U but also to the receiving part S1. Furthermore, when the battery cell 110 is viewed from the front side, the storage portion S1 may be arranged to protrude in the left and/or right direction with the upper seal portion S2U as the center. At this time, the central portion of the taping member 120 may be bonded to the upper sealing portion S2U, and both left and right ends may be bonded to the receiving portion S1 disposed in the left and right directions, respectively.

Meanwhile, in order to reduce the space occupied by the battery cell 110 inside the battery module, at least one sealing portion may be folded. For example, referring to the configuration shown in FIG. 3, the upper sealing portion (S2U) where the electrode lead 111 is not located may be folded. This folding of the sealing part may be referred to as side folding or wing folding. In addition, the manufacturing process in which the sealing part is folded twice, or the part in which such a process is performed, is also referred to as double side folding (DSF). In the exemplary drawing of FIG. 3, the upper sealing unit S2U can be said to be shown in a double side folded form.

In this configuration in which the upper sealing portion S2U is folded, the taping member 120 may be configured to maintain the folded shape. For example, the taping member 120 may be attached to the battery cell 110 in a manner that secures the top sealing portion S2U and both storage portions while the top sealing portion S2U is folded twice.

In particular, the taping member 120 may be partially attached to the upper sealing portion (S2U) of the battery cell 110. That is, the taping member 120 may not be attached entirely to a specific sealing portion of the battery cell 110, but may be attached only to a certain portion. Accordingly, a section to which the taping member 120 (tape) is attached and a section to which the taping member 120 (tape) is not attached may exist in a specific sealing portion of the battery cell 110.

For example, in the exemplary configuration of FIG. 3, the taping member 120 is attached to the upper sealing portion (S2U) of the battery cell 110, but only partially, so the taping member 120 is attached to the upper sealing portion (S2U) of the battery cell 110, as shown in the portion indicated by A1. There may be a section where the tape is not attached.

The taping member 120 can reduce the space occupied by the cell assembly 100 by fixing the folding configuration of the sealing portion. Additionally, the taping member 120 can suppress swelling of the cell assembly 100 in the Z-axis direction. That is, during use of the battery cell 110, gas may accumulate inside the battery cell, causing swelling of the cell. However, the taping member 120 can prevent the cell from expanding toward the top.

Meanwhile, when the top hole (HV) is formed on the upper side of the module case 300, the top of the cell assembly 100 may be arranged to face the top hole (HV) of the module case 300. At this time, the module case 300 may be configured so that at least a portion of the unattached section of the taping member 120 at the top of the cell assembly 100 is located in a portion where the top hole (HV) is formed.

For example, referring to FIG. 3, the taping member 120 may be partially, but not entirely, attached to the upper sealing portion (S2U) of the plurality of battery cells 110 provided in the cell assembly 100. You can. Accordingly, in the upper sealing portion S2U of the battery cell 110, there may be an unattached section where the taping member 120 is not attached, such as a portion indicated by A1. The top hole (HV) of the module case 300 may be positioned at a location where at least a portion of the unattached section of the taping member 120 is located. More specifically, in the exemplary configuration of FIG. 3, the top hole (HV) may be formed in the module case 300 so that at least a portion of the top hole (HV) is located on the upper side in the Z-axis direction of the non-attached section indicated by A1. This configuration will be described in more detail with additional reference to the implementation configuration in FIG. 16.

Figure 16 is a top view schematically showing the configuration of a battery module according to an embodiment of the present invention.

Referring to FIG. 16, the upper side of the cell assembly 100 stored in the internal space of the module case 300 may be exposed through the top hole (HV) formed in the upper plate of the module case 300. At this time, at least a portion of the top hole (HV) may be formed so that at least a portion of an unattached section of the upper part of the cell assembly 100 to which the taping member 120 is not attached is exposed. For example, in the exemplary configuration of FIG. 16 , a section indicated by A2 in the At this time, the top hole (HV) may be formed in the main body frame 310 so that at least a portion of the non-attached section is exposed to the outside.

According to this embodiment of the present invention, when storing at high temperature or generating internal gas, the Z-axis direction of the battery cell 110 is moved by the taping member 120 attached to the upper sealing portion (S2U) (eg, DSF portion). While appropriately controlling or suppressing swelling, in the event of an emergency such as thermal runaway, venting gas or flames can be directed to erupt in the direction of the upper sealing unit (S2U). That is, in the above-mentioned embodiment of the present invention, the taping member 120 is only partially attached to the upper sealing portion (S2U) of the battery cell 110, and therefore the taping member 120 is attached to the entire upper sealing portion (S2U). The fixing force may be weakened compared to the case where it was used. Therefore, when gas or flame is ejected from the inside of the battery cell 110 to the outside, the ejection can be made toward the upper sealing part (S2U). In addition, since a top hole (HV) is provided at the upper side of the cell assembly 100 in the module case 300, gas or flame, etc. can be quickly and smoothly discharged to the outside of the module case 300.

In particular, among the upper sealing portions (S2U) of the battery cell 110, the fixing force of the section where the taping member 120 is not attached may be the weakest. Therefore, gas, flame, etc. are likely to be released first through this non-attached section. Therefore, as in the above embodiment, when the top hole (HV) is formed at a position directly corresponding to the unattached section of the taping member 120, external emissions such as gas or flame emitted from the cell assembly 100 are more likely to occur. It can be done easily.

The taping member 120 may be attached separately to each battery cell 110 or may be commonly attached to several battery cells 110 .

In particular, when the cell assembly 100 is provided with a plurality of battery cells 110, a separate taping member 120 may be attached to each battery cell 110. That is, the taping member 120 can be independently attached to each individual battery cell 110. For example, when 20 battery cells 110 are arranged in the left and right directions in the cell assembly 100, a separate taping member 120 is attached to the upper sealing portion (S2U) for each of the 20 battery cells 110. It can be.

In this case, even if the taping member 120 is separated from a specific battery cell 110 due to ejection of gas or flame, the taping member 120 of the other battery cell 110 may be maintained as is. Accordingly, the function of the taping member 120 in other battery cells 110 can be maintained as is.

Additionally, when a problem such as thermal runaway occurs in a specific battery cell 110, the temperature may rise first before gas or flame is ejected. And, this temperature increase may weaken the adhesive force of the taping member 120 attached to the battery cell 110. Accordingly, even if the taping member 120 is attached to the upper sealing portion S2U, the adhesive force is not strong, and thus the ejection can be easily performed toward the upper sealing portion S2U.

In addition, as in the previous embodiment, when the module terminal 200 is located on the front side of the module case 300, connection with the bus bar terminal 410 located on the front side of the cell assembly 100 can be easily made. You can. In particular, according to the above embodiment of the present invention, a top hole (HV) is formed on the upper side of the module case 300, and an unattached section of the taping member 120 exists opposite the upper side top hole (HV). It is configured to do so.

Therefore, when high-temperature gas or flame is ejected from the battery cell 110, it is likely to be discharged to the upper side where the electrode lead 111 is not located. That is, according to the implementation configuration of the present invention, it is possible to suppress or delay the discharge of flames, etc. in the direction where the module terminal 200 is located.

Additionally, the front and rear sides of the module case 300 where the electrode leads 111 are located may be relatively spacious compared to other parts. At this time, if the flame is not properly discharged to the outside of the module case 300, the flame may be concentrated toward the electrode lead 111 and the voltage of the battery module may rapidly decrease. However, as in the embodiment of the present invention, when flames are discharged to the upper side and not in the direction where the electrode lead 111 is located, short circuits between cells can be suppressed and the voltage drop time of the battery module can be delayed as much as possible. . Moreover, in this case, the drop time during which the voltage of the battery module falls to 0V can be maintained above a certain level, for example, 5 minutes or more. Additionally, preventing the flame from being directed toward the electrode lead 111 may be advantageous in suppressing thermal runaway or flame propagation between battery cells 110 included within one battery module.

Therefore, when such a battery module is mounted on an electric vehicle, etc., even if a flame or the like occurs in a specific battery cell 110 due to thermal runaway, the vehicle can be operated for a certain period of time, allowing the occupants to move the electric vehicle to a safe place or You can secure time to escape.

Multiple taping members 120 may be attached to one battery cell 110 . In particular, the plurality of taping members 120 may be attached to the upper sealing portion S2U of one battery cell 110 to be spaced apart in the front-back direction.

For example, referring to FIG. 3, a plurality of taping members 120 are attached to the upper DSF of one battery cell 110, and the plurality of taping members 120 are oriented in the front-back direction (X-axis direction). It can be placed at a predetermined distance apart.

In this implementation configuration, an unattached section as indicated by A1 may be formed in the space between the taping members 120 spaced apart in the front and rear directions. In addition, by forming a section where the taping member 120 is not attached in this way, the upper sealing portion (S2U) can burst when the internal pressure of the battery cell 110 increases.

According to this implementation configuration, swelling and venting of the battery cell 110 can be appropriately controlled depending on the situation. That is, the taping member 120 controls swelling in the Z-axis direction of the battery cell 110 when the internal pressure of the battery cell 110 is below a certain level, while when the internal pressure of the battery cell 110 is above a certain level. If it exceeds the limit, the upper part of the battery cell 110 may burst. Therefore, by directing gas or flame to the upper side of the battery module, it can be more effective in smoothly controlling venting and suppressing heat spread between modules.

As shown in FIGS. 2 and 3, three taping members 120 may be attached to one battery cell 110 in the front-back direction. At this time, the two taping members 120 may be arranged to be positioned as far as possible outside the upper sealing portion (S2U) (DSF) of the battery cell 110 in the front-back direction. Additionally, the remaining taping member 120 may be disposed at the center of the upper sealing portion (S2U) (DSF) of the battery cell 110 in the front-back direction.

According to this implementation configuration, swelling in the Z-axis direction is appropriately suppressed through the taping member 120, and the fixing force of the taping member 120 is not excessively set with respect to the upper seal portion (S2U), thereby ensuring an appropriate timing. The upper sealing part (S2U) may burst. In addition, according to the above-mentioned configuration, the distance between the taping members 120 in the front and rear direction is appropriately secured, and the top holes (HV) can be formed in a sufficient number or with a sufficient area in the non-attached section. Therefore, venting gas or flames can be smoothly discharged through the top hole (HV).

At least a portion of the top hole (HV) may be configured to expose to the outside a portion between the plurality of taping members 120 spaced apart in the front-back direction. That is, in the upper sealing portion S2U of the battery cell 110, the space between the taping members 120 spaced apart in the front and rear directions, as shown in the portion shown as A1 in FIG. 3, may exist as an untaped section. Additionally, the top hole (HV) may be arranged to correspond to at least a portion of the untaped section of the battery cell 110.

Looking more specifically, as shown in FIG. 16, a plurality of top holes (HV) may be formed on the upper side of the module case 300. Moreover, a plurality of top holes (HV) may be arranged in the front-back direction (X-axis direction) of the battery module. At this time, among the plurality of top holes (HV), at least some of the top holes (HV) may be formed in a position and/or shape such that the untaped section can be exposed to the outside.

For example, the plurality of top holes (HV) may be arranged to form five rows in the front-to-back direction, from the first venting row (HV1) to the fifth venting row (HV5). At this time, in the second venting row (HV2) and the fourth venting row (HV4), the untaped section of the upper sealing portion (S2U) is exposed to the outside with respect to the plurality of battery cells 110 provided in the cell assembly 100. It may be formed to penetrate the module case 300 so as to be exposed.

According to this implementation configuration of the present invention, venting gas or flame, etc. can be quickly discharged to the outside through the top hole (HV) disposed opposite to the non-attached section of the taping member 120. Therefore, it prevents venting gas or flames from remaining inside the module case 300, suppresses heat spread between battery cells 110, and quickly lowers the internal pressure of the module case 300, thereby causing the battery module to explode. etc. can be prevented.

Moreover, according to the above-mentioned configuration, it is possible to prevent flames, etc. from heading toward the module terminal 200 located on the front side of the module case 300. Therefore, heat propagation between battery modules can be prevented more effectively.

Additionally, the top hole HV may be configured so that the non-attached portion of the taping member 120 is exposed more than the attached portion of the taping member 120 at the top of the cell assembly 100. In particular, in the upper plate of one module case 300, a plurality of top holes (HV) may be provided to open the inside of the module case 300 to the outside. Here, only the section to which the taping member 120 is not attached can be exposed through the plurality of top holes (HV) of the upper sealing portion (S2U) of the module case 300. Alternatively, the attached section of the taping member 120 along with the non-attached section of the taping member 120 may be exposed to the outside through the plurality of top holes (HV). In this case, the top hole HV may be configured so that the non-attached section of the taping member 120 is relatively more exposed than the attached section of the taping member 120.

For example, referring to the implementation configuration of FIG. 16, among the plurality of top holes (HV), only the unattached section of the taping member 120 is exposed in the second venting row (HV2) and the fourth venting row (HV4). The attachment section of the taping member 120 may be configured not to be exposed. In addition, the first venting row (HV1), the third venting row (HV3), and the fifth venting row (HV5) may be configured so that the non-attached section and the attached section of the taping member 120 are both exposed to the outside. At this time, when the first venting row (HV1), the third venting row (HV3), and the fifth venting row (HV5) are viewed from the top, the external exposed area of the unattached section of the taping member 120 is the taping member ( It may be configured to be wider than the external exposure area of the attachment section of 120).

In this implementation configuration, the open area of the top hole (HV) for the non-attached section of the taping member 120 is 1.5 times or more, at most 2 times or more, compared to the open area for the attached section of the taping member 120. It can be configured to be at most 3 times or more.

According to this implementation configuration of the present invention, the portion to which the taping member 120 is not attached is exposed to a greater extent to the top hole (HV), so that flame or gas is discharged more quickly and smoothly through the top hole (HV). You can make it happen. Accordingly, it is possible to more reliably suppress flames, etc. from being discharged in the direction of the module terminal 200, for example, toward the front of the battery module.

The module case 300 may be configured such that the top hole (HV) is located at the top of all battery cells 110 provided in the cell assembly 100. For example, as shown in FIG. 2, a plurality of battery cells 110 may be arranged side by side in the left and right direction (Y-axis direction) in an upright position. At this time, the module case 300 may be provided so that the top sealing portion (S2U) of the plurality of battery cells 110 stacked in the left and right directions directly faces the top hole (HV). That is, the upper ends of all battery cells 110 may be exposed to the outside through the top hole (HV).

More specifically, referring to the implementation configuration of FIG. 16, a plurality of top holes (HV) are arranged in the Y-axis direction, and the upper ends of all battery cells 110 will be exposed to the outside through these plurality of top holes (HV). You can. In particular, the untaped section of all battery cells 110 may be configured to directly face the top hole (HV).

For example, among the plurality of battery cells 110 provided in the cell assembly 100, some of the battery cells 110 are connected to the upper sealing part through the second venting row (HV2) and/or the fourth venting row (HV4). The untaped section of (S2U) may be exposed to the outside. In addition, all remaining battery cells 110 in which the untaped section of the top sealing portion (S2U) is not exposed to the outside through the second venting row (HV2) or the fourth venting row (HV4) are in the first venting row ( The top sealing portion (S2U) may be exposed to the outside through the third venting column (HV1), the third venting column (HV3), and/or the fifth venting column (HV5). Moreover, in the case of the second venting row (HV2) and/or the fourth venting row (HV4), the battery cells stacked in the left and right directions are formed as close as possible to the left and right ends of the upper plate of the module case 300 ( 110), the top hole (HV) may be disposed correspondingly at the top of the outermost battery cell 110.

In this implementation configuration of the present invention, the top sealing portion (S2U) of the plurality of battery cells 110 provided in the cell assembly 100 may be exposed to the outside through the plurality of top holes (HV). In particular, in all battery cells 110, the unattached section of the taping member 120 may be directly exposed to the outside through the top hole (HV). That is, in the above-mentioned configuration, among the plurality of battery cells 110 provided in the cell assembly 100, there will be no battery cell 110 whose top sealing portion (S2U) is not exposed through the top hole (HV). You can.

According to the above implementation configuration, the area of the top hole (HV) can be secured as wide as possible. In addition, according to the above-mentioned configuration, even if gas or flame, etc. is ejected from any of the battery cells 110 provided in the cell assembly 100, each battery cell 110 directly responds to the top. A top hole (HV) may exist. Accordingly, venting response to all battery cells 110 can be performed quickly and smoothly. In addition, by directing the flame or gas ejected from a specific battery cell 110 directly toward the top and preventing it from flowing in the horizontal direction, the influence of the flame or gas on other battery cells 110 can be minimized. there is. Therefore, in this case, it can be more effective in quickly responding to thermal runaway of some battery cells 110 and preventing the spread of thermal runaway between cells.

In the module case 300, a plurality of top holes (HV) may be arranged to be staggered in the front-back direction. For example, the first venting row (HV1), the third venting row (HV3) and/or the fifth venting row (HV5) may have a second venting row (HV2) and/or a fourth venting row disposed adjacent to these venting rows. It can be arranged to be located in different positions in the column (HV4) and in the left and right directions (Y-axis direction).

According to this implementation configuration of the present invention, while forming a plurality of top holes (HV) in the module case 300, the rigidity of the module case 300 due to the top holes (HV) can be secured at a certain level or more. That is, a plurality of top holes (HV) are formed in the front and rear directions of the module case 300, but the left and right direction arrangements are varied between each top hole (HV), so that the rigidity of the module case 300 is increased in certain parts in the left and right directions. Excessive degradation can be prevented. Moreover, according to the above-mentioned configuration, through the zigzag arrangement of the top holes (HV), the gap between the top holes (HV) is secured at a certain level or more, thereby facilitating the production of a press for forming the top hole (HV). Meanwhile, a configuration that allows all cells to be exposed to the top hole (HV) can also be easily implemented.

Furthermore, when the top holes (HV) have multiple rows in the front-to-back direction, the number of top holes (HV) may be different between adjacent venting rows. For example, the first to fifth venting rows (HV1 to HV5) may be configured to have a different number of top holes (HV) than the adjacent venting row.

As a more specific example, the first venting row (HV1), the third venting row (HV3), and/or the fifth venting row (HV5) may be configured to have three top holes (HV) in the left and right directions. In addition, the second venting row (HV2) and/or the fourth venting row (HV4) disposed adjacent to this venting row may be configured to have four top holes (HV) in the left and right directions.

In particular, in the module case 300, in a plurality of venting rows, the number of top holes (HV) included in the venting row in which only the non-taped section is exposed is greater than the number of top holes (HV) included in the venting row in which both the non-taped section and the taped section are exposed. It may be configured to be more than the number of holes (HV). For example, in the case of the second venting row (HV3) in which only the non-taped section is exposed, four top holes (HV) are formed, so that the first venting row (HV1) in which both the non-taped section and the taped section are exposed. The number of top holes (HV) may be greater than the three top holes (HV) included in the third venting row (HV3).

According to this implementation configuration of the present invention, it is possible to expose as much of the untaped section of the cell assembly 100 as possible. Therefore, when flame or venting gas, etc. is ejected from the untaped section of the battery cell 110, it can be discharged to the outside of the module case 300 as quickly and smoothly as possible.

Additionally, the number of venting rows in which both the non-attached and attached sections of the taping member 120 are exposed can be formed in a larger number than the venting row in which only the non-attached section of the taping member 120 is exposed. For example, in the implementation configuration of FIG. 16, three venting rows in which the taped section and the taped section are exposed together can be formed in the front-back direction (HV1, HV3, HV5), whereas only the taped section is exposed. Two venting rows can be formed in the front-back direction (HV2, HV4).

According to this implementation configuration of the present invention, venting performance can be achieved uniformly for each of the plurality of battery cells 110 included in the cell assembly 100. That is, the cell assembly 100 may include a battery cell 110 with both the untaped section and the taped section exposed, and a battery cell 110 with only the untaped section exposed. At this time, according to the above-mentioned configuration, the battery cell 110, in which not only the taped section but also the taped section is exposed through the top hole (HV), is exposed to the outside through more top holes (HV). You can. Therefore, compared to the battery cell 110 in which only the untaped section is exposed, it is possible to prevent the venting performance of flames, etc. from being deteriorated.

Figure 17 is an enlarged view showing a portion of a battery module according to an embodiment of the present invention. For example, FIG. 17 may be an enlarged view of portion A4 of FIG. 2.

With additional reference to FIG. 17 along with FIGS. 2 and 16 , the battery module according to the present invention may further include a thermistor, as indicated by TH.

The thermistor (TH) may be a component configured to measure ambient temperature. The thermistor may be located on at least one side of the cell assembly 100 to measure the temperature inside the battery module, for example, the cell assembly 100. Moreover, the thermistor TH may be disposed on the upper side of the cell assembly 100.

Additionally, a plurality of thermistors (TH) may be included in one cell assembly 100. For example, two thermistors (TH) may be included. In this case, two thermistors TH may be disposed on the front and rear sides of the top of the cell assembly 100, respectively, as shown in FIGS. 2 and 16 .

In particular, the thermistor TH may be disposed on the upper side of the taping member 120, as shown in FIGS. 2 and 17. That is, since the taping member 120 may be partially attached to the upper part of the cell assembly 100, an unattached section and an attached section of the taping member 120 may exist together. In this configuration, the thermistor TH may be disposed on the upper side of the cell assembly 100, above the portion where the taping member 120 is attached. Moreover, when three taping members 120 are attached to the cell assembly 100 to be spaced apart from each other in the front-back direction, the upper side of the frontmost taping member 120 and the upper side of the rearmost taping member 120 In each, a thermistor (TH) may be located.

According to this implementation configuration of the present invention, it can help prevent damage to the thermistor (TH) or the battery cell 110. For example, when vibration or shock occurs to the battery module, or when a large or repetitive force is applied between the thermistor (TH) and the battery cell 110, the pouch exterior material of the thermistor (TH) or the battery cell 110 may cause damage. However, the taping member 120 can have the effect of suppressing such damage. In addition, the taping member 120 may include an adhesive layer and a base layer, and the adhesive layer or base layer may be made of an elastic material. In this case, the effect of preventing damage to the thermistor (TH) or the battery cell 110 from vibration or impact can be further improved.

Additionally, the taping member 120 may be made of an electrically insulating material. In this case, the measurement accuracy of the thermistor TH can be further improved by preventing the thermistor TH from contacting the aluminum layer included in the pouch exterior material of the battery cell 110. Moreover, even if cracks, etc. occur in the pouch exterior material and the aluminum layer, etc. is exposed to the outside, it is possible to prevent a situation where the current affects the thermistor (TH).

In addition, the battery module according to the present invention may further include a protection member, such as the portion indicated by PT in FIG. 17.

The protection member (PT) is configured to surround the thermistor (TH) and can prevent or reduce pressure or impact from being applied to the thermistor (TH). In particular, the protection member PT may be configured to surround the thermistor TH in the horizontal direction.

The protection member PT may be configured to be taller than the thermistor TH in order to prevent pressure or impact applied in the vertical direction from being applied to the thermistor TH. Additionally, the protective member PT may be made of an elastic material capable of absorbing pressure or impact, such as polyurethane, silicone, or other foam material.

According to the above implementation configuration, when swelling in the Z-axis direction of the battery cell 110 occurs or pressure or impact is applied from the upper part of the module case 300 to the module case 300, the thermistor (TH) from the pressure or impact, etc. ) can prevent damage or cracks from occurring.

Meanwhile, the thermistor (TH) may be located inside the module case 300 and exposed to the outside through a top hole (HV) formed in the module case 300. For example, as shown in FIG. 16, the front thermistor (TH) is exposed to the upper side through the top hole (HV) of one of the first venting rows (HV1), and the rear thermistor (TH) is exposed to the upper side through the top hole (HV) of one of the first venting rows (HV1). It can be installed to be exposed to the upper side through one of the top holes (HV) (HV5).

In this case, the mechanical stability of the thermistor (TH) can be improved. In particular, even when swelling in the Z-axis direction occurs in the cell assembly 100, the problem of cracks or damage occurring by pressing the thermistor TH by the module case 300 can be prevented. Additionally, in this case, when a situation such as a failure of the thermistor (TH) occurs, replacement or repair of the thermistor (TH) can be easily performed.

Figure 18 is a perspective view showing some components of a battery module according to another embodiment of the present invention in isolation. Figure 19 is a diagram of the combined configuration of a battery module according to another embodiment of the present invention as seen from the top.

Referring to FIGS. 18 and 19 , the battery module according to the present invention may further include a top cover 600.

The top cover 600 may be made of an electrically insulating material. For example, the top cover 600 may be made of plastic material. Additionally, the top cover 600 may be located inside the module case 300. Moreover, the top cover 600 may be disposed on the upper side of the cell assembly 100. In particular, the top cover 600 may be interposed between the top of the cell assembly 100 and the module case 300.

The top cover 600 may be configured in a plate shape. In addition, the top cover 600 covers the upper side of the cell assembly 100 inside the module case 300, so that the upper side of the cell assembly 100 does not directly contact the upper plate of the module case 300. It can be configured not to do so. In particular, the module case 300 may be made of a metal material such as aluminum or SUS. At this time, the top cover 600 made of an electrically insulating material can ensure electrical insulation between the cell assembly 100 and the module case 300.

In particular, the top cover 600 may have a cover hole formed in the portion indicated by HC in FIG. 18. This cover hole HC may be formed to penetrate the top cover 600 in the thickness direction. In particular, the cover hole HC may be provided to be located in a portion opposite to the portion where the top hole HV is formed. That is, the position where the cover hole (HC) is formed in the top cover 600 may be provided in a portion corresponding to the position where the top hole (HV) is formed in the module case 300. For example, referring to FIG. 19, when the top cover 600 is inserted into the module case 300, the cover hole HC extends outward, that is, to the upper side, through the top hole HV. It can be placed in a location where it can be exposed.

According to the above-described embodiment of the present invention, electrical insulation between the module case 300 and the cell assembly 100 can be stably secured through the top cover 600, and the top cover 600 can be installed in the top hole in an emergency. (HV) can be used to prevent venting gas from being discharged. For example, if a situation such as thermal runaway occurs in some of the battery cells 110 provided in the cell assembly 100, venting gas may be released first. At this time, the venting gas can be quickly and smoothly discharged to the outside of the module case 300 through the cover hole (HC) and top hole (HV). Therefore, both electrical insulation and stable venting performance can be achieved by the top cover 600.

Additionally, according to the above-mentioned configuration, the top cover 600 can be restrained in the downward direction with respect to the upper sealing portion S2U of the cell assembly 100. In particular, the top cover 600 can press each battery cell 110 in the downward direction when swelling of each battery cell 110 in the Z-axis direction occurs, thereby preventing swelling of the battery cells 110 in the Z-axis direction. The amount generated can be reduced.

As shown in FIG. 18, multiple cover holes HC may be formed in one top cover 600. Moreover, the plurality of cover holes HC may be grouped into several groups and distributedly arranged. In particular, each cover hole (HC) may be formed in a smaller size than the top hole (HV) formed in the module case 300. In addition, when the top cover 600 is inserted into the module case 300, a plurality of cover holes (HC) may be disposed in correspondence with one top hole (HV).

For example, referring to Figure 19, a plurality of top holes (HV) are formed in the module case 300, and each top hole (HV) has a much smaller size than each top hole (HV). The cover hole (HC) may be positioned in communication. As a more specific example, 6 to 12 cover holes (HC) may be arranged to correspond to one top hole (HV).

Each cover hole HC may be configured to have a size of 1 cm or less, further 0.8 cm or less, particularly 0.6 cm or less. However, these sizes are only examples, and each cover hole HC formed in the top cover 600 may be formed in various sizes and shapes.

According to the above implementation configuration, it may be more advantageous to improve the safety of the battery module. In particular, according to one aspect of the present invention, a top hole (HV) may be formed on at least one side of the module case 300, further on the upper side. At this time, a small cover hole (HC) is provided at the bottom of the top hole (HV), thereby preventing fingers, etc. of workers or users from entering the inside of the battery module. In this case, the cover hole HC may be provided in a size smaller than the size of a typical user's finger. In addition, according to the above-mentioned configuration, it is possible to prevent external foreign substances, etc. from entering through the top hole (HV), causing damage or breakage of the battery module.

The cover hole HC may be formed in a honeycomb structure. For example, a plurality of cover holes HC may be formed in the top cover 600, and at least some of the cover holes HC may be formed in a hexagonal shape. Additionally, the edge of each cover hole HC may be formed to be parallel to the edge of the adjacent cover hole HC.

As a more specific example, corresponding to one top hole (HV), a plurality of cover holes (HC) may form one or two rows and be arranged side by side in the front-to-back direction. Furthermore, in the embodiment shown in FIG. 19, six cover holes (HC) may be arranged in communication in a honeycomb structure in the front-back direction, corresponding to each top hole (HV).

According to this embodiment of the present invention, it is possible to prevent insertion of fingers or foreign substances through the top hole (HV), while securing the overall area of the cover hole (HC) in the top cover 600 as wide as possible. . Therefore, the venting gas can be discharged to the outside quickly and smoothly through the cover hole (HC).

The battery module according to the present invention may include a printed circuit board 700, as shown in FIG. 18.

The printed circuit board 700 may be interposed between the cell assembly 100 and the top cover 600. Additionally, the printed circuit board 700 may be configured to transmit electrical signals to the cell assembly 100. For example, the bus bar assembly 400 may be disposed on the front and rear sides of the cell assembly 100, and each battery cell 110 included in the cell assembly 100 can be connected from the bus bar assembly 400. Voltage, etc. can be measured. And, these voltage measurement values can be transmitted to the inside or outside of the battery module through the printed circuit board 700.

Additionally, the printed circuit board 700 may provide a path for transmitting the temperature measurement value by the thermistor (TH). Furthermore, the printed circuit board 700 may be configured to be equipped with a thermistor (TH). For example, as shown in portions A5 and A5' in FIG. 18, the printed circuit board 700 may be provided with a thermistor mounting portion. And, the thermistor (TH) can be mounted on one side of the printed circuit board 700 in this thermistor mounting part.

In particular, the thermistor mounting portion may be formed to be concave downward, such as portions indicated by A5 and A5'. Additionally, the thermistor TH may be attached to the upper surface of the printed circuit board 700 in this concave portion. In this case, the thermistor TH can be positioned as close to the cell assembly 100 as possible. Here, as shown in the embodiment of FIG. 17, when the protection member (PT) is surrounded around the thermistor (TH), both the thermistor (TH) and the protection member (PT) are attached to the thermistor mounting portion of the printed circuit board 700. It can be mounted on the top.

Additionally, the printed circuit board 700 may be configured such that the thermistor mounting portion is located on the upper part of the taping member 120. According to this implementation configuration, it is possible to prevent the thermistor mounting portion formed concavely in the downward direction from directly contacting the battery cell 110. Accordingly, electrical insulation can be ensured between the printed circuit board 700 or the thermistor (TH) and the pouch exterior material of the battery cell 110. Accordingly, it is possible to prevent or reduce noise or errors from occurring in electrical signals transmitted through the printed circuit board 700 or in measurement results of the thermistor (TH). In addition, according to the above implementation configuration, it is possible to prevent the printed circuit board 700 or the battery cell 110 from being damaged or broken due to vibration, impact, friction, etc.

The printed circuit board 700 may be configured in the form of an FPCB, that is, a flexible printed circuit board 700. Additionally, the printed circuit board 700 may be formed to extend long in the front-back direction where the electrode leads 111 of each battery cell 110 are located in the cell assembly 100. Moreover, the printed circuit board 700 is configured to connect the bus bar assembly 400 located in front of the cell assembly 100 and the bus bar assembly 400 located in the rear of the cell assembly 100. It can be.

The battery module according to the present invention may further include a module connector, as indicated by MC in FIGS. 18 and 19. This module connector (MC) may be a terminal that transmits and receives electrical signals for the battery module to and from the outside. In particular, the printed circuit board 700 can transmit battery module information to various control devices such as external components, such as a Battery Management System (BMS) or Energy Controller Unit (ECU), through the module connector (MC). there is.

As such, in an embodiment in which the battery module includes the printed circuit board 700, the top cover 600 may be configured so that the cover hole HC is not formed on the upper side of the printed circuit board 700.

For example, referring to FIG. 18, the top cover 600 is configured so that no cover hole HC is formed in the center portion in the left and right direction (Y-axis direction), such as the portion indicated by A6. It can be. This implementation configuration can be said to be because the printed circuit board 700 is located in a shape that extends long in the front-back direction from the central portion of the lower part of the top cover 600.

In this case, most of the cell assembly 100 disposed under the top cover 600 may be exposed to the upper side through the cover hole HC, but the printed circuit board 700 disposed under the top cover 600 ) may not be exposed to the upper side through the cover hole (HC).

According to this implementation configuration of the present invention, the printed circuit board 700 may not be exposed to the outside of the battery module through the cover hole HC. Therefore, it is possible to fundamentally block foreign substances from flowing into components mounted thereon, such as the printed circuit board 700 or the thermistor (TH), which are vulnerable to particles or moisture. Therefore, in this case, it is possible to more effectively prevent damage or malfunction of the printed circuit board 700 and the components mounted thereon.

In addition, according to the above-mentioned configuration, the configuration of attaching the printed circuit board 700 to the top cover 600 can be more easily implemented. For example, the printed circuit board 700 may be attached to the lower part of the top cover 600 using a double-sided adhesive tape, etc. In the above embodiment, the printed circuit board 700 is double-sided attached to the portion where the cover hole HC is not formed. Tape can be attached. Therefore, in this case, there may be sufficient space in the top cover 600 to attach the double-sided adhesive tape, so the printed circuit board 700 can be more stably fixed inside the module case 300.

The module case 300 may be configured to have a top hole (HV) formed on the printed circuit board 700 as well.

For example, looking at the configuration of FIG. 19, most of the top holes (HV) arranged in a zigzag shape have a plurality of cover holes (HC) arranged in direct communication with each other, but some of the top holes (HV) have cover holes (HC) is not placed at all. In particular, among the five venting rows formed in the front-back direction (X-axis direction), the top hole (HV) is located in the center in the left-right direction (Y-axis direction) in the 1st, 3rd, and 5th venting rows (HV1, HV3, HV5). , the cover hole HC is not disposed at all. In addition, the two top holes (HV) located on the center side in the 2nd and 4th venting rows (HV2, HV4) have only one line with the cover holes (HC) disposed on the outer side in the left and right directions. Here, in the case of the top hole (HV) in which the cover hole (HC) is not arranged at all or is only partially communicated, this can be said to be because the printed circuit board 700 is located below it.

That is, in the above-mentioned configuration, in the case of the top hole (HV) formed in the lower portion where the printed circuit board 700 is located, the cover hole (HC) is not formed at all or is formed only partially. On the other hand, in the case of the top hole (HV) formed in the lower portion where the printed circuit board 700 is not located, the cover hole (HC) may be configured to be sufficiently communicated.

According to this implementation configuration, flames generated in the cell assembly 100 can be smoothly and sufficiently discharged to the upper side. In particular, if the thermal runaway of the cell assembly 100 intensifies beyond a certain level, a flame may occur. Such a flame may melt the printed circuit board 700 or the top cover 600 due to high heat or pressure. Or it can be lost. Therefore, in normal conditions, even if it is a top hole (HV) that does not directly expose the cell assembly 100 due to the printed circuit board 700 and the top cover 600, the printed circuit board 700 and the top cover 600 may be damaged due to flame. If the cover 600, etc. is lost, it can play the role of discharging flames, etc. Therefore, by allowing the flame, etc. to be discharged sufficiently and quickly through the top hole (HV) of the module case 300, it is possible to prevent the flame, etc. from heading toward the front side where the module terminal 200 is located.

Figure 20 is a perspective view schematically showing the configuration of a battery module according to another embodiment of the present invention. Additionally, FIG. 21 is a perspective view showing some components of the battery module of FIG. 20 separated. 22 and 23 are enlarged views of a portion of a battery module according to an embodiment of the present invention. In particular, FIGS. 22 and 23 can be said to be enlarged views showing the configuration of portion A7 of FIG. 20 before and after the top hole (HV) is opened.

Referring to FIGS. 20 to 23, the battery module according to the present invention may further include a blocking cover 800.

The blocking cover 800 may be located outside the module case 300. In particular, the blocking cover 800 may be located on the upper side of the module case 300. Moreover, a top hole (HV) may be located on the upper side of the module case 300, and the blocking cover 800 may be attached to the outside of the module case 300, at least in the portion where the top hole (HV) is formed. there is. Additionally, as described in the previous embodiment, the battery module according to an embodiment of the present invention may include a top cover 600. At this time, the top cover 600 may be located inside the module case 300, and the blocking cover 800 may be located outside the module case 300.

Additionally, the blocking cover 800 may be located not only on the side where the top hole (HV) is formed, but also on the side where the top hole (HV) is not formed. For example, the blocking cover 800 is formed in an approximately n-shape, so that not only the upper plate of the module case 300 with the top hole (HV) is formed, but also the top plate of the module case 300 without the top hole (HV) is formed. ) can also be attached to the outside of the left and right plates.

The blocking cover 800 may be made of a heat-resistant material that can withstand high temperatures. For example, the blocking cover 800 may be made of a ceramic material such as mica. Moreover, the blocking cover 800 may be provided with a mica sheet. In this case, the blocking cover 800 can more reliably prevent flames from moving or spreading toward the inside or outside of the battery module.

The blocking cover 800 may be configured to open and close the top hole (HV) of the module case 300. Furthermore, the blocking cover 800 may be configured to open or close the top hole (HV) depending on the internal pressure of the module case 300. In particular, the blocking cover 800 may be provided with an opening and closing portion configured to open and close the top hole (HV) according to the internal pressure of the module case 300, as shown in the portion indicated by OC in FIGS. 20 to 23. Here, the opening/closing portion (OC) may be formed at a position corresponding to the top hole (HV) of the module case 300 with the blocking cover 800 attached to the outside of the module case 300. Additionally, the opening/closing portion (OC) of the blocking cover 800 may be formed in a shape corresponding to the top hole (HV) of the module case 300. For example, when the top hole (HV) of the module case 300 is formed in a substantially elliptical shape, the opening and closing portion (OC) of the blocking cover 800 may also be of a similar size and shape and may be formed in a substantially elliptical shape.

More specifically, the opening/closing portion (OC) of the blocking cover 800 may be configured to close all top holes (HV) in a normal state when the internal pressure of the module case 300 is below a certain level. For example, as shown in FIG. 21, a top hole (HV) may be formed in the module case 300. However, as shown in FIGS. 20 and 22, when the blocking cover 800 covers the top of the module case 300, the top hole (HV) of the module case 300 is the blocking cover 800. By being covered by the opening/closing unit (OC), it may not be exposed to the outside, especially to the upper side.

However, when the internal pressure of the module case 300 increases above a certain level, the blocking cover 800 may be configured to open at least part of the top hole (HV). For example, if thermal runaway occurs in the cell assembly 100 and gas or flame is generated, the internal pressure of the module case 300 may increase. And, when this internal pressure exceeds a certain level, the opening and closing part (OC) of the blocking cover 800 is opened, and the top hole (HV) located below it can be opened. Accordingly, gas or flame existing inside the module case 300 may be released to the outside of the module case 300, especially to the upper side, as indicated by an arrow in FIG. 23.

According to this embodiment of the present invention, when the battery module is in a normal state, the top hole (HV) is closed by the blocking cover 800, so external foreign matter enters the module case 300 through the top hole (HV). For example, it can block moisture or dust from entering.

And, according to this embodiment of the present invention, when venting gas or flame is generated inside the module case 300 due to thermal runaway, etc., the opening and closing portion (OC) of the blocking cover 800 is opened, so that venting gas or flame, etc. It can be discharged quickly to the outside, especially to the upper side where the top hole (HV) is formed. Accordingly, it is possible to prevent such flames from affecting other battery cells 110 inside the relevant battery module or affecting other battery modules located on the side of the relevant battery module.

In addition, according to the above implementation configuration, even if venting gas or flames are emitted from another battery module due to thermal runaway, etc., the top hole (HV) of another normal battery module can be maintained in a closed state. Accordingly, it is possible to prevent venting gas or flame from flowing into the top hole (HV) of another normal battery module. Therefore, it is possible to more effectively prevent thermal runaway or flames from spreading between battery modules.

The opening and closing portion (OC) of the blocking cover 800 may be configured to form a cut line (OCL) in the sheet constituting the blocking cover 800. For example, referring to the exemplary configuration of FIG. 22, an opening/closing portion (OC) may be provided on the mica sheet provided as the blocking cover 800 in the form of an incision line (OCL), as indicated by OCL. At this time, the cutting line OCL may be formed by completely cutting the blocking cover 800 in the thickness direction, or by partially cutting it to form a notch or groove. In addition, the opening/closing unit (OC) may be configured in various other ways. For example, the opening/closing unit (OC) may be configured in a form in which a hole is covered with a stopper, or in a form in which a door is provided in the hole.

Meanwhile, a plurality of top holes (HV) of the module case 300 may be formed, and a plurality of opening and closing portions (OC) of the blocking cover 800 may also be formed corresponding thereto. At this time, each of the plurality of opening and closing units (OC) provided in one battery module may perform an opening and closing operation independently. For example, even if some openings and closing parts OC are open, other openings and closing parts OC may remain closed.

For example, in the embodiment of FIGS. 20 and 21, an event occurs in some of the battery cells 110 among the plurality of battery cells 110 included in the cell assembly 100, and venting gas or flame is ejected first. You can. At this time, venting gas or flame may first be directed to the top hole (HV) corresponding to or adjacent to the battery cell 110 (event cell) where an event occurred. Then, the opening/closing part (OC) corresponding to the event cell or the adjacent top hole (HV) is opened first, so that venting gas or flame, etc. can be discharged. At this time, the other top hole (HV) may remain closed for at least a certain period of time.

According to this implementation configuration, even if venting gas or flames are discharged from an event cell in which thermal runaway, etc., has occurred within one battery module, such venting gases or flames can be prevented from flowing into other normal battery cells 110. there is. Accordingly, the propagation of heat runaway or flame between battery cells 110 within the battery module may be blocked or delayed. Moreover, according to this implementation configuration of the present invention, it may be advantageous to delay the rate of voltage drop of the battery module.

The blocking cover 800 may be configured in the form of a sheet having a composite layer. This will be described in more detail with additional reference to FIGS. 24 to 26.

Figure 24 is a diagram schematically showing the configuration of the blocking cover 800 according to an embodiment of the present invention. FIG. 25 is a diagram schematically showing a cross-sectional configuration of a battery module to which the blocking cover 800 of FIG. 24 is applied. For example, FIG. 25 may be a cross-sectional view taken along line A8-A8' of FIG. 20. Additionally, FIG. 26 is an enlarged view of portion A9 of FIG. 25.

24 to 26, the blocking cover 800 may include a first seat cover 810, a second seat cover 820, and/or a third seat cover 830. The first seat cover 810, the second seat cover 820, and the third seat cover 830 may be sequentially stacked from top to bottom.

The first seat cover 810 may be located on the outermost side of the blocking cover 800, particularly on the upper side. Additionally, the first seat cover 810 may be made of a flame-resistant material such as mica. Moreover, as shown in FIGS. 25 and 26, the first seat cover 810 is positioned and shaped to correspond to the top hole (HV) when the blocking cover 800 is attached to the module case 300. An blocking hole (OCH) may be formed. These blocking holes (OCH) may be formed in advance to penetrate the first seat cover 810 in the thickness direction. That is, the blocking hole OCH may be configured to have an open shape in which a portion of the first seat cover 810 is cut away.

Moreover, the blocking hole OCH may be formed to have a larger size than the top hole HV. For example, as shown in FIG. 26, the horizontal direction (Y-axis direction) length of the blocking hole OCH may be formed to be larger than the horizontal direction (Y-axis direction) length of the top hole HV. In this case, the venting gas discharged from the top hole (HV) can be smoothly discharged outside the battery module through the blocking hole (OCH).

The second seat cover 820 may be placed in contact with the lower portion of the first seat cover 810. For example, the second seat cover 820 may be adhered to the first seat cover 810. Furthermore, the second seat cover 820 may have the above-described incision line OCL formed at a position corresponding to the blocking hole OCH of the first seat cover 810. Therefore, in a normal state, the top hole (HV) of the module case 300 may be closed by the second seat cover 820 without communicating with the blocking hole (OCH) of the first seat cover 810. And, when the internal pressure increases and gas or flame is applied through the top hole (HV) of the module case 300, the incision line (OCL) is torn or opened, and the top hole (HV) is damaged by the first sheet cover ( It may be opened by communicating with the blocking hole (OCH) of 810).

The second seat cover 820, similar to the first seat cover 810, may be made of a flame-resistant material. For example, the second seat cover 820 may be made of mica material.

The third seat cover 830 may be placed in contact with the lower portion of the second seat cover 820. Additionally, the third seat cover 830 may be attached to the outside of the module case 300 by directly contacting it. The third seat cover 830 may be made of an electrically insulating material such as plastic. For example, the third seat cover 830 may be made of polyurethane material. The third seat cover 830 may be adhered to the module case 300 and/or the second seat cover 820. Moreover, adhesive is applied to both sides of the third seat cover 830, so that the module case 300 and the second seat cover 820 can be bonded. Additionally, the third seat cover 830 may perform a waterproof or dustproof function to prevent moisture or dust from entering the top hole (HV) from the outside of the module case 300.

The third seat cover 830 may be made of a material with a lower melting point than the first seat cover 810 or the second seat cover 820. Therefore, if a flame or the like occurs in the top hole (HV) of the module case 300, it may melt or disappear and be removed. Therefore, as shown in FIG. 24, even if no special hole is formed in the third seat cover 830, flames, etc. can be ejected from the top hole (HV) toward the blocking hole (OCH).

According to the above-described implementation configuration, in the portion where the top hole (HV) is not formed, the first seat cover 810 and the second seat cover 820 can block flame as a composite layer. Therefore, flame blocking performance can be improved in areas other than the top hole (HV). Therefore, it is possible to prevent or suppress the battery cells 110 inside the battery module from being affected by flames emitted from other battery modules or other parts of the battery module.

Additionally, in the case of the above-mentioned configuration, the cut line (OCL) is formed on the second seat cover 820 having a relatively thin thickness, so that the cut line (OCL) can be easily formed on a sheet member such as mica. In addition, according to the above-mentioned configuration, when the internal pressure of the module case 300 increases, the thin second sheet cover 820 ruptures quickly, so that flame or gas discharge through the top hole (HV) can be quickly and smoothly performed. there is.

Moreover, in the case of the above embodiment, the first seat cover 810 and the second seat cover 820 are included in the blocking cover 800 in the form of a composite layer, thereby reducing the thickness of the second seat cover 820, The overall thickness of the blocking cover 800 can be secured to a certain level or higher. Therefore, stable blocking of flames from the outside and rapid opening configuration when internal pressure increases can be easily implemented.

In addition, according to the above-mentioned configuration, the second seat cover 820 with the cut line (OCL) formed is disposed below the first seat cover 810. In this case, even if flame or gas discharged from another battery module flows along the outer surface of the first seat cover 810, the second seat cover 820 located inside cannot be easily ruptured. Therefore, it is possible to more effectively prevent flames or gases from a battery module in which a thermal event occurs from rupturing or damaging the second seat cover 820 of another battery module, thereby preventing flames from entering the interior of another battery module.

The first seat cover 810, the second seat cover 820, and/or the third seat cover 830 are bent to surround the upper surface and left and right sides of the module case 300, as shown in FIG. 24. It can have a shape.

The battery module according to the present invention may include a spacer, such as the portion indicated by FR in FIGS. 20 and 21, etc.

The spacer FR may be placed on top of the blocking cover 800. For example, the spacer FR may be attached to the upper surface of the first seat cover 810. Furthermore, the spacer FR may be configured to protrude upward from the blocking cover 800.

Additionally, a plurality of spacers FR may be provided and arranged to be spaced apart from each other in the horizontal direction on the top of the blocking cover 800. In addition, the spacer FR may be located in the space between the surface of the blocking cover 800 and the opening and closing portion OC.

The spacer FR may be made of an elastic material such as foam. For example, the spacer FR may be made of silicon.

According to the above-mentioned configuration, when flame or gas is generated and gas is released from the top hole (HV) side, the blocking cover 800 can be prevented from moving toward the pack housing (PH) side. For example, when the battery module as shown in FIG. 25 is stored in the pack housing (PH), the top cover of the pack housing (PH), etc. may be positioned on top of the battery module. At this time, when flames, etc. are discharged from the battery module through the top hole (HV) and the blocking hole (OCH), the blocking cover 800 may be lifted to the upper side by the discharge pressure. At this time, if the blocking cover 800 is lifted too much, flames, etc. flow into the space between the blocking cover 800 and the module case 300, and the flames are not properly discharged to the outside of the blocking cover 800. Flames, etc. can only stay in the space between the blocking cover 800 and the module case 300. However, in the case of the above implementation configuration, the spacer FR prevents the blocking cover 800 from being lifted above a certain level toward the pack housing (PH), thereby preventing such a problem. Therefore, according to this implementation configuration, the discharge performance of venting gas or flame through the top hole (HV) and the blocking hole (OCH) can be sufficiently and stably secured.

27 and 28 are perspective and cross-sectional views schematically showing some configurations of a battery module according to another embodiment of the present invention. For example, FIG. 27 is an enlarged view of a portion of the blocking cover 800 where one opening/closing portion (OC) is formed, and may be a modified example of portion A7 of FIG. 20 . In addition, FIG. 28 is a diagram showing the cross-sectional structure of the upper side of the battery module to which the embodiment of FIG. 27 is applied, and can be said to be a modified example of portion A9 of FIG. 25.

27 and 28, in the battery module according to the present invention, the blocking cover 800 may be provided with a blocking protrusion configured to protrude upward, such as a portion indicated by OCW. The blocking protrusion OCW may be formed around the opening and closing portion OC. For example, when the opening and closing portion OC is formed in a substantially oval shape, the blocking protrusion OCW may be formed in a ring shape along the edge of the oval.

According to the above implementation configuration, opening of the opening and closing portion OC of the blocking cover 800 due to external flame, venting gas, etc. can be more reliably prevented. For example, referring to the exemplary configuration of FIG. 18, flame or venting gas discharged from another battery module or another opening/closing unit (OC) may flow along the outer surface of the blocking cover 800, especially the first seat cover 810. It can flow. At this time, the flame flowing along the outer surface of the blocking cover 800 may hit the blocking protrusion OCW and be redirected upward, as indicated by the arrow. In particular, this change in direction can prevent flames, etc. from heading toward the opening/closing portion (OC) of the blocking cover 800, particularly toward the cutting line (OCL) of the second seat cover 820. Therefore, by preventing the opening and closing portion OC of the blocking cover 800 from being opened due to an external flame, etc., it is possible to effectively prevent the spread of flame, etc. between cells or between modules.

The blocking protrusion (OCW) may be formed on the upper surface of the first seat cover 810. At this time, the blocking protrusion OCW may be provided in the process of forming the blocking hole OCH in the first seat cover 810. For example, in order to form the blocking hole (OCH) in the first seat cover 810, the blocking hole (OCH) is formed by passing a penetrating press from the bottom to the upper direction, and at the same time, the border of the blocking hole (OCH) is formed. Burrs can be formed intentionally. Additionally, these burrs may function as blocking protrusions by being formed to protrude upward around the blocking hole OCH.

Meanwhile, in the previous embodiment of FIGS. 2 and 3, a plurality of taping members 120 are spaced apart in the front-back direction at the upper sealing portion (S2U) of each battery cell 110 provided in the cell assembly 100. It is attached in the form. At this time, the plurality of taping members 120 may be attached with the same adhesive force. On the other hand, multiple taping members 120 attached to one battery cell 110 may be attached with different adhesive forces. This will be explained in more detail with reference to FIG. 29.

FIG. 29 is a diagram schematically showing the configuration of the battery cell 110 and the taping member 120 included in a battery module according to another embodiment of the present invention.

Referring to FIG. 29, the plurality of taping members 120 attached to the upper sealing portion (S2U) of the battery cell 110 may be configured to have different adhesive strengths, at least partially. For example, as shown in FIG. 29, the first tape T1, the second tape T2, and the third tape T3 are attached to the upper sealing portion S2U of the battery cell 110 in the front-back direction. It can be. Here, the first tape T1 and the third tape T3 are the taping members 120 located at the frontmost and rearmost sides of the upper sealing part S2U of the battery cell 110, and are the front end sealing part. And it may be arranged close to the rear end sealing part. And, the second tape T2 may be positioned between the first tape T1 and the third tape T3.

At this time, the first tape T1 and the third tape T3 located on the outside may have different adhesive strengths from the other taping member 120, that is, the second tape T2. In particular, the first tape T1 and the third tape T3 located on the outside may have stronger adhesive force than the second tape T2, which is the other taping member 120. In other words, the second tape T2 located in the center may have weaker adhesive force than the first tape T1 and the third tape T3.

Here, configuring the adhesive force between the plurality of taping members 120 differently can be implemented by varying the sizes of the taping members 120. For example, as shown in FIG. 29, the first tape T1 and the third tape T3 may have larger attachment areas than the second tape T2. In this case, the plurality of taping members 120 may be configured to have the same materials and characteristics, and differences in adhesive strength may occur simply by adjusting the size. As another example, configuring the adhesive force differently between the plurality of taping members 120 may be implemented by varying the amount or type of adhesive used for the taping members 120. For example, the first tape T1 and the third tape T3 may be attached to the upper sealing portion S2U of the battery cell 110 using an adhesive that has stronger adhesion than the second tape T2. .

According to this implementation configuration of the present invention, when gas or flame, etc., is discharged from the inside of the battery cell 110, it can be directed to a specific part of the upper sealing portion (S2U). In particular, as in the embodiment of FIG. 29, when the adhesive force of the second tape T2 located in the center is made smaller than the adhesive force of the first tape T1 and the third tape T3 located on the outside, the battery cell 110 ), there is a high possibility that flames, etc. are discharged from the central portion of the upper sealing portion (S2U) of the battery cell 110, not from the portion close to the electrode lead 111. Moreover, when the internal pressure of the battery cell 110 increases, flames, etc. are likely to be discharged first from the untaped section between each taping member 120 in the upper sealing portion S2U of the battery cell 110. In addition, if the flame or gas emissions increase, even the taping attachment section may be opened and flames may be discharged. In this case, the centrally located second tape (T2) is used rather than the first tape (T1) or the third tape (T3). There is a high possibility that it will tear first or separate from the pouch exterior material. Therefore, flames, etc., are likely to be directed toward the top hole (HV) disposed at the top of the battery cell 110, toward the side of the battery module where the electrode lead 111 is located, and especially toward the front where the module terminal 200 is located. Heading to the side can be suppressed.

FIG. 30 is a diagram schematically showing the configuration of the battery cell 110 and the taping member 120 included in a battery module according to another embodiment of the present invention.

Referring to FIG. 30, the taping member 120 may be configured to have an inclined end. For example, in the embodiment of FIG. 30, the first tape T1 and the third tape T3 are located on the lower side of the portion attached to the pouch exterior material of the battery cell 110, such as the portion indicated by A10 and A10'. The end may be configured to be inclined in a way that it becomes higher in a specific direction.

In particular, the taping member 120 may be configured in such a way that the attachment length becomes shorter in the direction toward the central portion. For example, the first tape T1 disposed on the front side may be configured such that its length in the vertical direction becomes shorter as it moves toward the center toward the rear (-X-axis direction), as shown in the portion indicated by A10. Additionally, the third tape T3 disposed on the rear side may be configured to have a length in the vertical direction that becomes shorter as it moves forward (+X-axis direction) toward the central portion, as shown in the portion indicated by A10'.

According to this implementation configuration of the present invention, in one taping member 120, it may be possible to control which part is damaged or separated first. For example, in the embodiment of FIG. 30, the first tape T1 is likely to be separated from the outer surface of the battery cell 110 at the rear side first because the adhesive force at the rear side is weak. Therefore, when flame or gas is discharged from the inside of the battery cell 110, the central portion of the upper sealing portion (S2U) of the battery cell 110 is opened first rather than the front edge where the electrode lead 111 is located. It can be induced. Also, in the case of the third tape T3, the central portion of the upper sealing portion S2U of the battery cell 110 may be induced to be opened first rather than the rear edge where the electrode lead 111 is located. Therefore, in this case, the flame, etc., is induced to eject from the top sealing portion (S2U) of the battery cell 110 toward the upper side through the central portion, and the ejection is suppressed as much as possible toward the front or rear where the electrode lead 111 is located. can do.

Additionally, the battery module according to the present invention may include a compression pad, as shown in the portion indicated by CP in FIG. 2.

In the cell assembly 100, the compression pad CP may be disposed between at least some of the battery cells 110 and/or outside the stack. For example, the compression pad CP may be arranged between every four battery cells 110 in the plurality of battery cells 110 stacked in the left and right directions.

This compression pad CP may be made of an elastic material to absorb swelling of the battery cell 110. For example, the compression pad (CP) may be made of a foam material such as polyurethane. Alternatively, the compression pad CP may be made of a material capable of blocking heat or flame. For example, the compression pad (CP) may be made of an insulating or fire-retardant material such as silicon or mica.

Additionally, the module case 300 may be formed with a rear hole (HR). This will be described in more detail with additional reference to FIGS. 31 and 32.

Figure 31 is a rear perspective view of a battery module according to an embodiment of the present invention. Additionally, FIG. 32 is a diagram showing some of the components of FIG. 31 separated.

Referring to FIGS. 31 and 32 , in the module case 300, a rear hole (HR) may be formed, such as a portion indicated by HR, on the opposite side of the portion where the module terminal 200 is installed, that is, on the rear side. Like the top hole (HV), this rear hole (HR) may also be provided to communicate with the internal space of the module case 300.

According to this implementation configuration of the present invention, it is possible to control the direction of flames emitted from the inside of the battery module. This will be described in more detail with additional reference to FIG. 33.

Figure 33 is a diagram showing a state in which flame, etc. is ejected from a battery module according to an embodiment of the present invention.

Referring to FIG. 33, when a situation such as thermal runaway occurs within the cell assembly 100 stored inside the module case 300, flame, high temperature venting gas, electrode discharge, etc. may be generated. And, when such flames exceed a certain level, they may be discharged to the outside of the module case 300. At this time, in the case of the battery module according to an embodiment of the present invention, a top hole (HV) is formed on the upper side and a rear hole (HR) is formed on the rear side, so the flame can be guided upward and rearward. That is, flames, etc. may be discharged to the upper side through the top hole (HV), as indicated by a solid arrow in FIG. 33, or to the rear side through the rear hole (HR), as indicated by a dotted line arrow in FIG. 33. Accordingly, according to this embodiment of the present invention, flame emission can be suppressed or delayed toward the front side where the module terminal 200 is located.

Moreover, in the case of the present invention, the top hole (HV) and the rear hole (HR) can allow flames to be discharged in different directions other than the front side. More specifically, the top hole (HV) allows flames to be discharged in a vertical direction (upwards), and the rear hole (HR) allows flames to be discharged in a horizontal direction (rearward). Therefore, through the simultaneous upward and rearward discharge of the flame, etc., the flame can be dispersed and discharged into spaces other than the front side, while the front side discharge can be suppressed as much as possible.

In addition, according to this embodiment of the present invention, when venting gas or flame is generated inside the battery module due to an event such as thermal runaway, such gas or flame is smoothly discharged to the outside of the module case 300. can do. Therefore, in an emergency, the internal pressure of the module case 300 can be quickly lowered to prevent an explosion of the battery module. Therefore, the safety of the battery module can be improved.

Meanwhile, the end frame 320 may include a front frame 320F and a rear frame 320R.

Here, the front frame 320F may be configured to cover the front side opening of the main body frame 310. And, the front frame 320F may be equipped with a module terminal 200. For example, the front frame 320F may provide a space or structure where the module terminal 200 can be mounted or exposed, such as a terminal hole HT. The rear frame 320R may be configured to cover the rear side opening of the main body frame 310. Additionally, the rear frame 320R may be formed with a rear hole (HR).

In this implementation configuration, flames or electrode discharges inside the module case 300 are discharged upward and rearward through the top hole (HV) of the main body frame 310 and the rear hole (HR) of the rear frame 320R. It can be. In addition, a hole through which flames, etc. can be discharged may not be formed in the front frame 320F. In this case, the flame or electrode discharge may be directed upward or backward, but not toward the front.

A plurality of rear holes HR may be formed in the rear frame 320R. For example, as shown in FIG. 31, a plurality of rear holes HR may be formed in the rear frame 320R in the horizontal and/or vertical directions. Furthermore, the plurality of rear holes HR may be formed in a substantially circular shape and may be configured in a form in which there are no separate vertices. Additionally, a plurality of rear holes HR may be arranged to be spaced a predetermined distance apart from each other on the rear frame 320R.

According to the above implementation configuration, rear flame discharge through a plurality of rear holes (HR) can be achieved more smoothly and quickly. In addition, according to this implementation configuration, it is possible to prevent the rear hole HR or the rear frame 320R from being broken or damaged due to discharge pressure of flame or gas.

The battery module according to the present invention may further include a rear insulating cover 900R as an insulating cover 900, as shown in FIGS. 2 and 32.

The rear insulating cover 900R may be made of an electrically insulating material. For example, the rear insulating cover 900R may be made of a polymer material such as plastic. The rear insulating cover 900R may be interposed between the cell assembly 100 and the rear frame 320R. Accordingly, electrical insulation can be secured between the cell assembly 100 and the rear frame 320R. In particular, electrical components such as electrode leads 111 may be located on the rear side of the cell assembly 100. And, the rear frame 320R may be made of an electrically conductive material such as aluminum. At this time, the rear insulating cover 900R made of an electrically insulating material is interposed between the electrode lead 111 and the rear frame 320R of the cell assembly 100, thereby electrically insulating them.

The rear insulating cover 900R may be configured to close the rear hole HR of the module case 300. That is, one or more rear holes (HR) may be formed in the rear frame 320R, so that the internal space of the module case 300 may be exposed to the outside. However, the rear insulating cover 900R can prevent the internal space of the module case 300 from being exposed to the outside. The rear insulating cover 900R is provided on the inside (front side) of the rear frame 320R and can close the rear hole HR from the inside.

In particular, as shown in FIG. 31, the rear insulating cover 900R has a rear hole ( HR) can be closed. In this case, components stored inside the module case 300, such as the cell assembly 100, may not be exposed to the outside through the rear hole HR.

According to this implementation configuration, when the battery module is in a normal state, external foreign substances, such as dust or moisture, can be prevented from penetrating into the internal space of the module case 300 through the rear hole (HR).

In addition, according to the above-described configuration, safety can be ensured by preventing conductors, fingers, etc. from entering through the rear hole (HR).

The rear insulating cover 900R may be in close contact with the inner surface of the rear frame 320R. In this case, a wider storage space and venting space can be secured inside the module case 300. Additionally, in this case, the effect of preventing penetration of foreign substances can be further improved.

The rear insulating cover 900R may be configured to at least partially expose the rear hole HR when heat is discharged from the cell assembly 100. For example, when a flame occurs in some of the battery cells 110 provided in the cell assembly 100 due to thermal runaway, at least a portion of the rear hole HR may be opened.

When the rear insulating cover 900R opens the rear hole HR, the internal space of the module case 300 may be exposed to the outside through the rear hole HR. Accordingly, the cell assembly 100 stored inside the module case 300 may be exposed to the outside through the rear hole HR.

In this implementation configuration, the configuration in which the rear insulating cover 900R opens the rear hole HR by heat can be implemented by deforming or changing the shape or state of at least a portion of the rear insulating cover 900R due to heat. there is. In particular, the rear insulating cover 900R may melt and/or disappear due to the heat and pressure of the flame generated during thermal runaway. And, due to this melting or disappearance, the rear insulating cover 900R can no longer completely close the rear hole HR and may be separated from the rear hole HR, thereby opening the rear hole HR.

To this end, the rear insulating cover 900R may be made of a plastic material that melts at a certain temperature or higher. In particular, the rear insulating cover 900R may be made of a plastic material that is weak to heat so that it can be melted by flame. For example, the rear insulating cover 900R may be made of polycarbonate (PC) material.

According to the above implementation configuration, when the battery module is in a normal state, the rear hole (HR) is completely closed, and water and dust proof effects, electrical safety, etc. can be stably secured. Also, in an abnormal state in which a flame, etc. occurs inside the battery module, the rear hole (HR) is opened, so that the flame, etc. generated inside the battery module can be smoothly discharged to the rear side. Accordingly, the internal pressure of the battery module can be quickly lowered to prevent explosion of the battery module, while also effectively preventing flames, etc. from being ejected toward the front of the battery module where the module terminal 200, etc. are located.

The rear frame 320R may have a rear fastening hole formed in the portion indicated by HLR in FIG. 32. Additionally, the rear insulating cover 900R may be provided with a rear fastening protrusion as shown in the portion marked PLR. Here, the rear fastening protrusion (PLR) may be inserted into the rear fastening hole (HLR) when assembling the battery module. A plurality of rear fastening protrusions (PLR) may be formed on the rear insulating cover 900R. Additionally, a plurality of rear fastening holes (HLR) may also be formed in the rear frame 320R to correspond to the plurality of rear fastening protrusions (PLR).

Meanwhile, one or more rear holes (HR) may be formed in the rear frame 320R. In this case, the rear fastening hole (HLR) may be formed in a different position from the rear hole (HR) in the rear frame (320R). In particular, the rear fastening hole (HLR) may be formed at a location spaced apart from the rear hole (HR) on the rear frame (320R).

The rear fastening protrusion (PLR) may be inserted to penetrate the rear frame 320R from the inside to the outside. Additionally, the outer end of the rear fastening protrusion (PLR) exposed to the outside of the rear frame 320R may be formed to be thicker than the penetrating portion. That is, the outer end of the rear fastening protrusion (PLR) may be formed to be larger than the size of the rear fastening hole (HLR). At this time, the thick portion of the outer end may be prepared by inserting the rear fastening protrusion (PLR) into the rear fastening hole (HLR) and then pressing it by applying heat and pressure.

According to this embodiment of the present invention, the coupling force between the rear frame 320R and the rear insulating cover 900R can be stably secured. Additionally, in this case, it is possible to prevent the rear insulating cover 900R from moving toward the electrode lead 111 and contacting the electrode lead 111, etc. Accordingly, it is possible to prevent the rear insulating cover 900R or the electrode lead 111 from being damaged or having an electrical short circuit due to shape deformation.

Meanwhile, as shown in FIGS. 31 and 32, the outer surface of the rear frame 320R may be formed to be concave inward at the portion where the rear fastening hole (HLR) is formed. In this case, a space in which the thick end of the rear fastening protrusion (PLR) is seated may be provided in the rear frame 320R. Accordingly, it is possible to prevent or minimize the creation of a portion protruding toward the rear of the battery module due to the rear fastening protrusion (PLR).

As shown in FIG. 3, the bus bar assembly 400 may be disposed on the front side of the cell assembly 100 and connected to the front electrode lead 111. And, as shown in FIG. 32, the bus bar assembly 400 may be disposed on the rear side of the cell assembly 100 and connected to the rear electrode lead 111.

In an embodiment in which the bus bar assembly 400 is provided on the rear side of the cell assembly 100, the rear insulating cover 900R is made of a material with a lower melting point than the bus bar housing 420 of the rear bus bar assembly 400. can be provided. For example, both the busbar housing 420 and the rear insulating cover 900R of the rear busbar assembly 400 are made of plastic, but the plastic material constituting the rear insulating cover 900R is the rear busbar assembly 400. It may be made of a material with a lower melting point than the plastic material constituting the housing 420. As a more specific example, when the rear insulating cover 900R is made of a PC material, the busbar housing 420 may be made of a material with a higher melting point than the PC material, such as MPPO.

According to this embodiment of the present invention, when a thermal runaway situation occurs inside the battery module, the rear insulating cover 900R may melt or disappear before the rear bus bar housing 420. Therefore, before the rear bus bar housing 420 melts, the rear insulating cover 900R first melts and the rear hole HR opens, so that the flame inside the battery module can be quickly and smoothly discharged to the outside. . Therefore, flames, etc. remain in the inner space of the module case 300, especially on the inner rear side, thereby preventing or delaying the structural collapse of the rear bus bar housing 420.

The bus bar housing 420 of the rear side bus bar assembly 400 may include a rear housing protrusion. This will be described in more detail with additional reference to FIG. 34.

Figure 34 is a diagram schematically showing a partial configuration of a battery module according to an embodiment of the present invention. In particular, Figure 34 shows the rear frame 320R and the rear insulating cover 900R removed from the rear side of the battery module.

Referring to FIG. 34, the rear bus bar assembly 400 may include a bus bar terminal 410 and a bus bar housing 420. At this time, the busbar housing 420 may have a rear housing protrusion as indicated by PHR. The rear housing protrusion (PHR) may be formed to protrude toward the rear insulating cover (900R) located at the rear. In particular, a bus bar terminal 410 is mounted on the bus bar housing 420, and the electrode lead 111 may be contact-coupled to the bus bar terminal 410 in a bent form. At this time, the rear housing protrusion (PHR) may protrude further rearward than the bus bar terminal 410 or the electrode lead 111 in contact with it.

According to this embodiment of the present invention, in a normal state, direct contact between the bus bar assembly 400 or the electrode lead 111 and the rear insulating cover 900R can be more reliably prevented. Therefore, it is possible to prevent the bus bar assembly 400 or the electrode lead 111 from being damaged by the rear insulating cover 900R due to external vibration or impact.

In addition, according to the above implementation configuration, in a thermal runaway situation, a sufficient empty space is secured between the bus bar assembly 400 and the rear insulating cover 900R, so that venting gas or flames are smoothly discharged into the space between them. can do. In addition, according to the above-mentioned configuration, when the rear insulating cover 900R is melted, the space between the bus bar assembly 400 and the rear frame 320R can be secured at a certain level or more. Therefore, flames, etc. can be discharged more quickly and smoothly through the rear hole (HR).

In addition, according to the above-mentioned configuration, the physical distance between the rear frame 320R and the electrode lead 111 is maintained at a certain level or more, and a stable electrical insulation distance can be secured.

The rear housing protrusion (PHR) may be formed to extend long in the vertical direction. In particular, since the bus bar terminal 410 mounted on the bus bar housing 420 may be formed to extend long in the vertical direction, the rear housing protrusion (PHR) may be formed to be long in the vertical direction like the bus bar terminal 410. You can.

Additionally, a plurality of bus bar terminals 410 may be arranged to be spaced apart from each other in the left and right directions in the bus bar housing 420. At this time, the rear housing protrusion (PHR) may be interposed between adjacent bus bar terminals 410, as shown in FIG. 34. Moreover, a plurality of rear housing protrusions (PHR) may be arranged horizontally in the busbar housing 420. In this case, the separation distance between the bus bar assembly 400 and the rear insulating cover 900R can be stably secured in the entire horizontal direction at the rear side of the cell assembly 100. Additionally, in this case, the physical separation state between adjacent bus bar terminals 410 can be stably maintained.

Meanwhile, in an embodiment in which the battery module is provided with a rear insulating cover 900R and a front insulating cover 900F, the front insulating cover 900F may be made of a material having a higher melting point than the rear insulating cover 900R. there is. In particular, both the front insulating cover 900F and the rear insulating cover 900R may be made of a plastic material, and the front insulating cover 900F may be made of a plastic material with a higher melting point than the rear insulating cover 900R.

According to this embodiment of the present invention, when a situation such as thermal runaway occurs inside the battery module, the rear insulating cover 900R may melt before the front insulating cover 900F. Accordingly, before the front insulating cover 900F melts or disappears, the rear hole HR may be opened first. Therefore, flames or high-temperature venting gas generated inside the module case 300 are quickly discharged to the outside through the rear hole (HR), and flames, etc., can be suppressed from heading toward the front.

The module case 300 may be configured such that the rear hole HR can communicate with the inner space on the upper side of the cell assembly 100. This will be described in more detail with additional reference to FIGS. 35 and 36.

Figure 35 is a diagram showing a cross-sectional configuration of the rear side of a battery module according to an embodiment of the present invention. Figure 36 is an enlarged view of portion C3 in Figure 35.

First, referring to FIG. 35, an empty space may be formed between the cell assembly 100 and the rear insulating cover 900R or the rear frame 320R, as shown in the portion indicated by C1. In particular, the empty space C1 on the rear side may be formed to extend from the inner upper portion of the rear frame 320R to the portion where the rear hole HR is formed.

And, this rear empty space C1 may be connected to the upper space of the cell assembly 100, such as the part indicated by C2 inside the module case 300. Accordingly, when the rear insulating cover 900R is removed, it can be said that the rear hole HR formed in the rear frame 320R communicates with the upper space of the cell assembly 100. Furthermore, the rear frame 320R may be configured to be continuously spaced from the cell assembly 100 to the bus bar assembly 400 from the top to the rear hole HR.

According to this embodiment of the present invention, the flame ejected from the upper side can be smoothly guided and discharged toward the rear hole (HR). For example, as indicated by the dotted arrow in FIG. 35, flame, electrode discharge, venting gas, etc. discharged into the upper space C2 of the cell assembly 100 are discharged from the top hole (HV) of the module case 300. ) as well as to the rear hole (HR) side. Therefore, by allowing the flame or gas to be smoothly discharged upward and rearward, the internal pressure of the battery module can be quickly lowered, while flames from being directed toward the front can be more effectively suppressed.

The module case 300 may have an inclined portion. This inclined portion may be configured so that the distance from the cell assembly 100 gradually increases as it moves toward the rear hole HR. Moreover, these inclined portions may be provided on the inner surface of the module case 300.

For example, referring to FIG. 36, an inclined portion may be formed in the rear frame 320R, as indicated by C4. This inclined portion C4 may be provided in a direction that moves away from the cell assembly 100 from the top to the bottom, that is, toward the rear (-X-axis direction). This inclined portion may be implemented in a form where the corners are rounded (chamfered) on the inner surface of the rear frame 320R.

According to this implementation configuration of the present invention, flames, etc. can be discharged more smoothly to the rear hole (HR) side of the module case 300. In particular, as shown in the portion indicated by C5 in FIG. 36, the empty space between the cell assembly 100 and the rear frame 320R may be expanded due to the inclined portion C4. Accordingly, a wider venting path can be secured at the rear side of the cell assembly 100.

In addition, according to the above-mentioned configuration, when flames, etc. are discharged from the upper side of the cell assembly 100 to the rear hole (HR), the flames, etc., move more smoothly along the slope, as shown by the dotted arrow in FIG. 36. can move easily. In particular, in the rear space of the cell assembly 100, the flame discharge path may be formed at a gently obtuse angle rather than at a right angle due to the inclined portion C4.

Figure 37 is a perspective view showing the front side configuration of a battery module according to an embodiment of the present invention. Additionally, FIG. 38 is an exploded perspective view of a portion of the configuration of FIG. 37. In particular, in Figure 38, the front frame 320F, which is a component located on the outside of the battery module, is left behind, and some components located on the inside of the battery module are moved to the outside.

Referring to FIGS. 37 and 38 , as described above, a terminal hole HT may be formed in the module case 300, particularly the front frame 320F, through which the module terminal 200 can pass. Additionally, the module terminal 200 may be exposed to the outside through the terminal hole HT.

Additionally, the battery module according to the present invention may further include a terminal sealing member (ST). The terminal sealing member (ST) may be configured to seal the space between the terminal hole (HT) and the module terminal 200. For example, referring to FIG. 38, since the terminal hole HT of the front frame 320F is formed larger than the module terminal 200, an empty space is left between the module terminal 200 and the front frame 320F. It can exist. At this time, the terminal sealing member ST may seal at least a portion of the space between the front frame 320F and the module terminal 200 in the terminal hole HT.

Additionally, as described above, the battery module according to an embodiment of the present invention may further include a front insulating cover 900F. Furthermore, this front insulating cover 900F can electrically insulate between the front frame 320F and the module terminal 200 at the portion where the terminal hole HT of the front frame 320F is formed. At this time, the front insulating cover 900F may be interposed in the space between the front frame 320F and the module terminal 200, as shown in FIG. 37. However, the front insulating cover 900F may have an insulating hole formed in the front insulating cover 900F, such as a portion indicated by HI, in order to expose the module terminal 200 to the outside. In particular, the insulating hole HI for exposing the module terminal 200 may be indicated as HI1 to distinguish it from the insulating hole for exposing the module connector MC, which will be described later, and may be referred to as a first insulating hole. there is. Here, the insulating hole of the front insulating cover 900F may communicate with the terminal hole HT of the front frame 320F. However, the insulation hole HI has a smaller size than the terminal hole HT, so that it can be interposed in the space between the module terminal 200 and the end frame 320 to electrically insulate them.

In this implementation configuration, the terminal sealing member ST may be interposed between the module terminal 200 and the first insulating hole HI1 of the front insulating cover 900F. Accordingly, the space between the module terminal 200 and the terminal hole HT can be sealed by the front insulating cover 900F and the terminal sealing member ST.

The terminal sealing member (ST) may be made of an elastic material to secure sealing force. Additionally, the terminal sealing member (ST) may be made of a heat-resistant material so that it can withstand heat, flame, etc. In particular, the terminal sealing member (ST) may be made of a heat-resistant rubber material. For example, the terminal sealing member (ST) may be made of or include a fluorine rubber material.

According to this implementation configuration of the present invention, it is possible to prevent or suppress flames, etc. from being exposed to the exposed portion of the module terminal 200. In particular, according to the above-described configuration, leakage of flames, etc. around the module terminal 200 can be minimized. Therefore, other battery modules are located on the front side of the battery module where the module terminal 200 is located, or flames are ejected through separate inter-module bus bars connecting the modules, causing thermal runaway propagation between modules or pack voltage drop. This can be prevented more effectively.

Additionally, the battery module according to the present invention may further include a module connector (MC), as described above. This module connector (MC) is a connection structure for exchanging various information with the outside of the battery module, and allows electrical signals to be transmitted and received.

Additionally, a connector hole for inserting the module connector MC may be formed in the module case 300. In the case of such a connector hole, it may be formed to penetrate the module case 300 in the inner and outer directions, as shown in the portion indicated by HN in FIG. 38. In particular, the module connector (MC), like the module terminal 200, may be provided on the front side of the battery module. Accordingly, the connector hole HN may also be formed in the front frame 320F together with the terminal hole HT. In addition, when the front insulating cover 900F is interposed between the cell assembly 100 and the front frame 320F, the module connector MC can be exposed or penetrated into the front insulating cover 900F, as shown in FIG. 38. As shown, a second insulating hole HI2 may be formed.

In this embodiment provided with the module connector (MC), the battery module according to the present invention may further include a connector sealing member (SC), as shown in FIGS. 37 and 38. The connector sealing member (SC) may be configured to seal the space between the module case 300 and the module connector (MC) in the connector hole (HN) of the module case 300.

The connector sealing member (SC) may be made of an elastic material to secure sealing force. Additionally, the connector sealing member (SC) may be made of a heat-resistant material so that it can withstand heat, flame, etc. In particular, the connector sealing member (SC) may be made of a heat-resistant rubber material. For example, the connector sealing member (SC) may be made of or include a fluorine rubber material.

According to this embodiment of the present invention, it is possible to prevent or suppress flames, etc. from being exposed to the exposed portion of the module connector MC. In particular, according to the above-described implementation configuration, leakage of flames, etc. around the module connector (MC) can be minimized. Therefore, when another battery module is located on the front side of the battery module where the module connector (MC) is located, or flames erupt through separate inter-module bus bars connecting modules, etc., causing thermal runaway propagation between modules and pack voltage drop. This can be prevented more effectively.

Moreover, in the case of an embodiment configuration including the terminal sealing member (ST) and/or the connector sealing member (SC) as described above, when combined with the various other embodiments described above, it is more effective in suppressing forward emission of flames, etc. It can be. In particular, in combination with the previously described embodiment in which the top hole (HV) is provided on the upper side, the embodiment in which the expansion member 500 is disposed on the front side, and/or the embodiment in which the rear hole (HR) is provided on the rear side, etc. If so, the effect of inducing upward and/or rearward emission of flames, etc. and suppressing forward emission can be significantly improved.

The battery pack according to the present invention may include one or more battery modules according to the present invention described above. For example, the battery pack according to the present invention may be configured to include a pack housing (PH) and a plurality of battery modules according to the present invention therein, as shown in FIG. 7 . In particular, within the pack housing PH, two or more battery modules may be arranged with their front sides facing each other so that the module terminals 200 are arranged adjacent to each other. At this time, when the battery module according to the present invention is stored, even in an arrangement where the module terminals 200 face each other, the direction of flames, etc. toward other battery modules can be effectively suppressed or delayed. Also, in this case, short circuits between module terminals 200 can be prevented. Therefore, in emergency situations such as thermal runaway, the effect of preventing heat spread between modules is excellent, and sufficient response or escape time for users, etc. can be secured.

In addition, the battery pack according to the present invention further includes various other components in addition to the battery module, such as various battery pack components known at the time of filing of the present invention, such as BMS, busbar, relay, current sensor, etc. can do.

Meanwhile, components such as BMS, bus bars, relays, and current sensors may be included as components of the battery module according to the present invention. In this case, components such as BMS, bus bar, relay, and current sensor may be provided inside the module case 300. At this time, the battery module may be referred to as a battery pack, and the module case 300 may be referred to as a pack housing (PH). Moreover, in this case, the battery module according to the present invention may be a cell-to-pack type battery pack in which the battery cells 110 are directly mounted on the pack housing (PH).

The battery module according to the present invention can be applied to automobiles such as electric vehicles or hybrid vehicles. That is, the vehicle according to the present invention may include a battery module according to the present invention or a battery pack according to the present invention. Additionally, the vehicle according to the present invention may further include various other components included in the vehicle in addition to the battery module or battery pack. For example, the vehicle according to the present invention may further include a control device such as a vehicle body, a motor, or an electronic control unit (ECU), in addition to the battery module according to the present invention.

As described above, although the present invention has been described with limited examples and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following 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 patent claims to be described.

100: Cell assembly
110: battery cell
111: electrode lead
120: Taping member
200: module terminal
300: module case
310: main body frame, 320: end frame
320F: front frame, 320R: rear frame
400: Busbar assembly
410: Busbar terminal, 420: Busbar housing
500: expansion member
510: first expansion sheet, 520: second expansion sheet
600: Top cover
700: printed circuit board
800: Blocking cover
810: first seat cover, 820: second seat cover, 830: third seat cover
900: Insulating cover
900F: front insulating cover, 900R: rear insulating cover
S1: Storage part, S2: Sealing part
S2U: Top sealing part, S2F: Front sealing part, S2R: Rear sealing part
DT: Cell adhesion member
HT: terminal hole
HI: Insulating hole
HI1: 1st insulating hole, HI2: 2nd insulating hole
HV: Top hole
HC: Cover hole
HR: Rear Hole
HN: Connector hole
PH: Pack Housing
M1~M8: Battery module (1st module~8th module)
MC: module connector
OC: open/close
OCL: incision line, OCH: blocking hole, OCW: blocking projection
TH: thermistor
PT: protection member
FR: spacer
T1 to T3: Taping members (1st tape to 3rd tape)
CP: compression pad
HLF: front fastening hole, HLR: rear fastening hole
PLF: front fastening protrusion, PLR: rear fastening protrusion
PHF: Front housing protrusion, PHR: Rear housing protrusion
ST: Terminal sealing member
SC: Connector sealing member

Claims (16)

A cell assembly including a plurality of battery cells;
a module case storing the cell assembly in an internal space;
a module terminal electrically connected to the cell assembly and installed on the front side of the module case; and
An expansion member disposed on the front side of the cell assembly in the inner space of the module case and configured to expand in volume by heat to fill at least a portion of the front side space of the cell assembly.
A battery module comprising: According to paragraph 1,
A battery module, wherein the expansion member includes a material that is foamed by heat. According to paragraph 1,
The battery module is characterized in that the expansion member is arranged to be spaced a predetermined distance from the electrode lead of the cell assembly. According to paragraph 1,
The battery module, wherein at least a portion of the expansion member facing the cell assembly is coated with an electrically insulating material. According to paragraph 1,
A battery module comprising an electrically insulating material, interposed between the front side of the cell assembly and the module case, and further comprising a front insulating cover in which the expansion member is attached to an inner surface. According to clause 5,
The module case has a front fastening hole formed,
The front insulating cover is a battery module characterized in that it has a front fastening protrusion inserted into the front fastening hole. According to clause 6,
The battery module is characterized in that the expansion member is configured to close the front fastening hole when expanded. According to paragraph 1,
The expansion member is configured to block the flame or gas discharged by expansion from being directed toward the module terminal when flame or gas is discharged from the cell assembly. According to paragraph 1,
The expansion member is configured in the form of a sheet, and is configured to be expanded in both directions parallel to and perpendicular to the surface. According to paragraph 1,
A battery module, wherein the expansion member includes composite sheets of different materials. According to paragraph 1,
A bus bar assembly is disposed on the front and rear sides of the cell assembly, respectively, and includes a bus bar terminal electrically connected to the cell assembly and a bus bar housing made of an electrically insulating material and configured to mount the bus bar terminal. Contains more,
The expansion member is a battery module, characterized in that it is located on the front side and spaced a predetermined distance from the front bus bar assembly. According to clause 11,
The battery module, wherein the bus bar housing provided in the front bus bar assembly includes a front housing protrusion protruding toward the expansion member. According to clause 11,
The battery module is characterized in that the lower end of the expansion member is configured to be located higher than the lower end of the bus bar terminal. According to paragraph 1,
The module case is a battery module, characterized in that a top hole communicating with the internal space is formed on the upper side. A battery pack comprising the battery module according to any one of claims 1 to 14. A vehicle comprising the battery module according to any one of claims 1 to 14.

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