KR20220011096A - Pressure balancing device - Google Patents

Abstract

The present invention relates to a pressure balancer, comprising: a cover; a base; and a mounting member formed of metal and covering a fluid inlet from below the fluid inlet, wherein the mounting member is snap-fitted to the base and connected to the battery pack by a fastener to be assembled in a battery pack. The mounting member is snap-fitted to the base to facilitate the removal of the mounting member. The mounting member and the battery pack are firmly connected by the fastener, ensuring connection stability and preventing the mounting member from falling off the battery pack. In addition, the mounting member formed of metal is advantageous in preventing adverse thermal effects or consequences due to the hot gas/environment in the battery.

Description

PRESSURE BALANCING DEVICE

The present disclosure relates to a pressure balancing device, and more particularly, to a pressure balancing device for balancing internal and external pressures of a battery pack.

The battery pack generates heat during use, causing the temperature of the battery pack to rise. As the temperature of the gas inside the battery pack increases, the pressure inside the battery pack increases. If the gas inside the battery pack is not discharged to the outside in a timely manner, the normal use of the battery is disturbed. For this reason, it is often necessary to mount a pressure balancing device on the battery pack, and gas inside the battery pack is discharged to the outside environment through the pressure balancing device to ensure pressure balance between the inside and the outside of the battery pack.

In general, the pressure balancer is formed of a plastic material. If the temperature of the internal gas of the battery pack is excessively high, the pressure balancer may be thermally deformed and come off the battery pack, thereby exposing a hole in the battery pack for mounting the pressure balancer.

At least one object of the present disclosure is to provide a pressure balancing device capable of preventing spontaneous detachment from a battery pack.

The pressure balancer is configured to be assembled to a battery pack, comprising: a cover; a base, the base having a receiving cavity defined between the base and the cover, the base being provided with a fluid inlet, the fluid inlet positioned below the receiving cavity and in fluid communication with the receiving cavity; and a mounting member formed of metal and covering the fluid inlet from below, the mounting member being provided with a plurality of vents to allow gas inside the battery pack to flow into the fluid inlet through the plurality of vents; A mounting member is sanp-fitted to the base and connected to the battery pack by fasteners.

According to the above configuration, the mounting member includes at least one elastic arm including a hook, and the base includes at least one step portion; The mounting member and the base are configured to achieve a snap-fit connection by means of hooks and corresponding steps.

According to the above configuration, the hook is formed of an elastic piece connected to the elastic arm, the elastic arm includes a window, the upper end of the elastic piece is connected to the upper side of the window, the bottom end of the elastic piece forms a free end, and the elastic The piece is configured to be elastically deformed relative to another portion of the resilient arm to move in and out of the window.

According to the above configuration, the hook is formed by bending the upper side of the elastic arm outward.

According to the above configuration, the mounting member includes at least one screw fastening hole for being fixed to the battery pack by the fastener.

According to the above configuration, the mounting member includes at least one sleeve, and the at least one screw fastening hole is disposed in the at least one sleeve.

According to the above configuration, the mounting member is in the form of a flat plate, and the elastic arm and the at least one screw fastening hole are disposed close to the peripheral edge of the mounting member.

According to the above configuration, the pressure balancing device further comprises a heat insulating member formed of metal and positioned below the mounting member, the heat insulating member being configured to cover the fluid inlet, the heat insulating member having a plurality of additional vents provided so that gas inside the battery pack can be introduced into the fluid inlet through the plurality of additional vents and the plurality of vents.

According to the above configuration, the plurality of additional vents and the plurality of vents are alternately arranged.

According to the above configuration, the battery pack is configured to be sandwiched between the mounting member and the heat insulating member, and the heat insulating member is connected to the mounting member by a fastener.

The mounting member of the pressure balance device of the present disclosure is formed of a metal material such as a sheet metal. The mounting member may snap fit to the base to facilitate removal of the mounting member. The mounting member and the battery pack are firmly connected by the fastener to prevent the mounting member from falling off the battery pack. Therefore, when the temperature inside the battery pack is excessively high, the mounting member and the battery pack can also be reliably connected, so that the plastic-formed component comes off from the battery pack, so the hole in the battery pack for mounting the pressure balancer exposure can be prevented. In addition, the mounting member formed of metal may also have some thermal insulation and heat dissipation effect, so that heat accumulation is reduced and thus the hot gas can be better prevented from being transferred to the pressure balancer. Thus, it is useful to prevent negative thermal effects or consequences caused by the hot gases/environment within the battery.

1A and 1B are structural perspective views of a pressure balancing device mounted on a battery pack housing from two viewpoints according to an embodiment of the present disclosure;
FIG. 2 is a structural perspective view of the pressure balancing device shown in FIG. 1A .
3A and 3B are structural exploded perspective views of the pressure balancing device shown in FIG. 2 as viewed from two viewpoints.
4A and 4B are structural perspective views of a mounting member of the pressure balancing device shown in FIG. 3A as viewed from two viewpoints;
5A is a cross-sectional view of a pressure balancer mounted to the battery pack housing shown in FIG. 1B taken along line AA;
FIG. 5B is a cross-sectional view of the pressure balancer mounted to the battery pack housing shown in FIG. 1B along line BB;
6A and 6B are structural perspective views of a pressure balancing device mounted on a battery pack housing from two viewpoints according to another embodiment of the present disclosure.
Fig. 6c is a bottom view of the pressure balancing device shown in Fig. 6a;
7A and 7B are structural exploded perspective views of the pressure balance device shown in FIG. 6A as viewed from two viewpoints.
FIG. 8 shows a cross-sectional view of the pressure balancer mounted to the plate shown in FIG. 6A taken along line CC of FIG. 6C ;

Various specific embodiments of the present disclosure will be described below with reference to the accompanying drawings, which form a part hereof. The terms “front”, “rear”, “top”, “bottom”, “left”, “right”, “top”, “bottom”, “inside” and “outside” refer to structural parts and elements of various examples of this disclosure. Although used to describe , these terms are used in the present invention for ease of illustration only, and are determined based on the exemplary orientation shown in the accompanying drawings. As the embodiments disclosed in this disclosure may be disposed in different orientations, terminology indicating such orientations is illustrative only and should not be regarded as limiting.

1A and 1B are structural perspective views of the pressure balancing device 100 mounted on the battery pack housing from two viewpoints according to an embodiment of the present disclosure. In the example as shown in the figures, only a portion of the plate 101 of the battery pack housing used to mount the pressure balancer 100 is shown. Although the complete battery pack is not shown in the drawing, it may be understood that the space below the plate 101 is the internal space of the battery pack for accommodating the battery assembly, and the space above the plate 101 is in fluid communication with the external environment. have.

1A and 1B , the pressure balancer 100 is generally cylindrical and is configured to be mounted to a plate 101 of a battery pack housing. An internal space of the battery pack may be in fluid communication with an external environment through the pressure balancer 100 . When the gas pressure inside the battery pack is higher than the gas pressure in the external environment, the gas inside the battery pack is discharged to the external environment through the pressure balancer 100 to reduce the pressure of the battery pack. However, during storage or use of the battery pack, the gas pressure inside the battery pack may also be lower than the ambient air pressure. In this case, gases from the external environment may also flow through the pressure balancer to the battery pack.

In this embodiment, the pressure balancing device 100 is mounted to the plate 101 of the battery pack housing by fasteners (not shown). Specifically, the pressure balancing device 100 includes a body 104 and a mounting member 109 , the body 104 includes a base 111 and a cover 112 connected together, and a mounting member 109 . is disposed under the base 111 of the main body 104 and is connected to the base 111 . In this embodiment, the mounting member 109 has a bottom 107 which projects downward in the axial direction. A plurality of resilient arms 115 , for example four resilient arms 115 , extending axially upwardly with respect to the bottom 107 of the mounting member 109 around the periphery of the bottom 107 of the mounting member 109 . this is provided

The plate 101 has a mounting opening 102 and a plurality of circular holes 105 , the circular holes 105 being disposed around the mounting opening 102 . For example, there are four circular holes 105 symmetrically disposed around the mounting opening 102 . The shape of the mounting opening 102 of the plate 101 coincides with the shape of the bottom 107 of the mounting member 109 . In other words, the mounting opening 102 generally receives the bottom 107 of the mounting member 109 so that when the mounting member 109 is mounted to the mounting opening 102 , the bottom 107 of the mounting member 109 is It can move downward through this mounting opening 102 and extend under the plate 101 . Also, the mounting opening 102 has four end grooves around it to receive each of the four resilient arms 115 .

The mounting member 109 is provided with a screw fastening hole 216 (see FIG. 2 ) corresponding to the position of the circular hole 105 of the plate 101 , and the circular hole 105 of the plate 101 is provided with the mounting member When the bottom 107 of the 109 passes through the mounting opening 102 , four circular holes 105 are formed with the four screwing holes (see the screwing holes 216 in FIG. 2 ) of the mounting member 109 and Positioned to be aligned with each other, fasteners (not shown) can pass through holes 105 in plate 101 such that fasteners (not shown) are securely connected to threaded holes 216 of mounting member 109 and thus pressure balancer ( 100 ) can be firmly connected to the plate 101 . For example, the inner wall of the circular hole 105 may also be threaded. In this embodiment, the mounting member 109 is formed of a metal material such as a sheet metal material. Of course, the mounting member 109 may also be formed of other types of metal materials as long as it has a certain high temperature resistance. Similarly, the fastener is also formed of a metallic material to make the connection of the fastener to the screw hole 216 more reliable.

In this embodiment, a plurality of vents 108 are also provided at the bottom of the mounting member 109 of the pressure balancer 100, and the inside of the battery pack is connected to the inside of the pressure balancer 100 through the vents 108. be in fluid communication. A plurality of ventilation holes 113 are provided on the upper side of the cover 112 , and the inside of the pressure balancing device 100 may be in fluid communication with the external environment through the ventilation holes 113 . In this way, the interior of the battery pack may be in fluid communication with the external environment through the pressure balancer 100 .

FIG. 2 shows a structural perspective view of the pressure balancing device 100 of FIGS. 1A and 1B for showing the external structure of the pressure balancing device 100 . As shown in FIG. 2 , the base 111 of the pressure balancer 100 comprises a button portion 214 in the form of a generally cylinder, the mounting member 109 of the button portion 214 in a snap-fit manner. ), the cover 112 covers the upper side of the button portion 214 and is connected to the upper side. In this way, the cover 112 , the base 111 and the mounting member 109 can be connected together.

Four plates 219 on which the mounting members 109 are arranged at intervals in the circumferential direction, four side walls 217 formed to extend downwardly from the inner side surfaces of each plate 219 , and the bottom of the side walls 217 . and a bottom 107 connected to the end. Four screw fastening holes 216 are provided in respective plates 219, respectively. Four elastic arms 115 are formed to extend upwardly from the periphery of the bottom 107 , and are disposed at corresponding intervals between adjacent plates 219 . An elastic arm 115 may extend into a locking hole 271 of the base 111 to mate with the base 111 . As a specific example, in the circumferential direction of the mounting member 109 , four elastic arms 115 and four screw fastening holes 216 are spaced apart so that each elastic arm 115 is adjacent to two screw fastening holes. It is located between 216 .

In the embodiment shown in FIG. 2 , the diameter of the plate 219 is smaller than the diameter of the bottom of the base 111 . In the radial direction, an annular seal ring 218 surrounding the circumference of the plate 219 is disposed between the bottom of the base 111 and the plate 219 and provides a seal between the pressure balancer 100 and the battery pack housing. To achieve this, a seal ring 218 is configured to abut the top surface of the plate 101 (see FIGS. 6A and 6B ).

3A and 3B are structural exploded perspective views of the pressure balancing device 100 viewed from two viewpoints to show general shapes and relative positions of internal components of the pressure balancing device 100 . 3A and 3B, in addition to the cover 112, the base 111 and the mounting member 109, a pressure balancing device 100 is disposed inside the pressure balancing device 100 and the cover ( 112 ) and a breathable assembly positioned in a receiving space defined by base 111 (see receiving cavity 580 as shown in FIGS. 6A and 6B ). The breathable assembly allows air from the external environment to enter the battery pack, prevents liquid from the external environment from entering the battery pack, and quickly communicates the internal and external environments of the battery pack when the internal pressure of the battery pack is excessively high. configured to do In this embodiment, the breathable assembly includes a breathable film 320 , a spacer 321 , a lid member 322 , and a drying component 323 . In other embodiments, the breathable assembly may also be any other structure that achieves the same function.

3A and 3B , the upper side 351 of the cover 112 faces the external environment, and the vent 113 passes through the upper side 351 . A vent 113 is configured to exhaust gas from the receiving cavity 580 to the external environment. The inner surface of the upper side 351 of the cover 112 is further provided with a spike portion 325 protruding inward. The sidewall 352 of the cover 112 is provided with a plurality of engaging portions 353 and recessed portions 355 disposed corresponding to the engaging portions 353, each recessed portion 355 having an upper side 351 and It is disposed on the sidewall 352 between the corresponding locking portions 353 and is recessed inwardly from the outer surface of the sidewall 352 . The button portion 214 of the base 111 has a corresponding number of inwardly projecting bosses 362 , the boss 362 matching the recess 355 in size. Boss 362 cooperates with catch 353 and recess 355 to allow cover 112 to be coupled together with base 111 in a snap-fit manner. For example, the number of the engaging portions 353 , the number of the concave portions 355 , and the number of the bosses 362 are each four. In the present embodiment, when the base 111 rotates with respect to the cover 112 , the boss 362 enters the recess 355 above the locking portion 353 , the boss 353 having the corresponding locking portion 353 . may move along the upper surface of the , at this time, the base 111 cannot rotate further with respect to the cover 112, and thus the cover 112 and the base 111 can be connected together.

The breathable film 320 is a substantially circular thin sheet, located under the upper side 351 of the cover 112 , and disposed close to the upper side 351 . Breathable film 320 is formed of a waterproof and breathable material. The breathable film 320 may prevent the liquid from the external environment from entering the battery pack to achieve dustproof, waterproof and breathable effects, and at the same time ensure gas communication between the battery pack interior and the external environment. In one example, the breathable film 320 is formed of a composite material of a plastic material and a nonwoven material. In this embodiment, the breathable film 320 is formed of a composite of an ePTFE material and a nonwoven material. Compared to the air-permeable film formed of the ePTFE material alone, the air-permeable film 320 formed of the composite of the ePTFE material and the non-woven fabric may have better air permeability.

A spacer 321 is positioned under the breathable film 320 and divides the receiving cavity 580 between the cover 112 and the base 111 into an upper receiving cavity 581 and a lower receiving cavity 582 ( 6a and 6b). The spacer 321 includes a connecting flange 331 , an elastic portion 332 , and a support portion 333 . A support portion 333 is disposed on the elastic portion 332 , and a connecting flange 331 is formed to protrude outward from the outer surface of the elastic portion 332 . In this embodiment, the elastic part 332 is formed of an elastic material, so that the elastic part 332 can be elastically deformed to move the supporting part 333 relative to the cover 112 . As a specific example, the elastic portion 332 is formed of a rubber material. In this embodiment, the resilient portion 332 is generally cylindrical with a cylindrical wall having a wavy portion 327 that can be expanded or contracted. The wavy portion 327 may expand or contract in the elastic deformation direction to further move the support portion 333 relative to the cover 112 .

The support portion 333 is provided with a ventilation hole 335 penetrating the support portion 333 , and a breathable film 320 is disposed on the support portion 333 to cover the ventilation hole 335 . For example, there is a certain connection strength between the breathable film 320 and the support portion 333 , so that the breathable film 320 may move together with the support portion 333 . In this embodiment, the breathable film 320 is molded on the support part 333 by injection molding or other processes, so that not only is it easy to machine, but also the breathable film 320 and the spacer 321 are connected therebetween. allow strength. The support portion 333 further has a receiving hole 336 passing through the support portion 333 approximately at its center. The receiving hole 336 is configured to receive the spiked portion 325 on the cover 112 when the support portion 333 moves to a specific position relative to the cover 112 . For example, the support portion 333 closes the upper end of the cylindrical resilient portion 332 .

A connecting flange 331 is in the form of a ring extending outwardly around the outer surface of the elastic part 332 , and is connected to the bottom end of the elastic part 332 . The bottom surface of the connecting flange 331 is provided with an annular sealing perimeter 338 protruding toward the base 111 . The connecting flange 331 is configured to be connected to the base 111 . In this embodiment, a spacer 321 is in sealing connection with the base 111 by an annular sealing perimeter 338 .

In order to facilitate machining, in this embodiment, the connecting flange 331 of the spacer 321, the elastic portion 332 and the supporting portion 333 are integrally formed of a rubber material. When the connecting flange 331 is formed of an elastic material, the annular sealing perimeter 338 may function as an elastic seal. Of course, in other embodiments, only the elastic portion 332 may be formed of an elastic material.

A lid member 322 is generally umbrella-shaped and is disposed between the spacer 321 and the base 111 to prevent the drying component 323 from flowing with the gas flow through the drying component 323 . The cover member 322 includes a top plate 345 and an insertion portion 346 , and one end of the insertion portion 346 is connected under the top plate 345 and the other end is connected to the base 111 . In this embodiment, the top plate 345 has a hollow passageway 347 that allows the passage of gas flow but prevents the passage of the drying component 323 .

A sealing groove 342 and a locking hole 271 are provided on the inner side of the bottom of the button portion 214 of the base 111 , and the position of the sealing groove 342 is an annular sealing edge 338 of the spacer 321 . Corresponding to the position of the spacer 321 is adapted to be mounted on the base 111 in correspondence thereto. A locking hole 271 is formed in a position and size corresponding to the elastic arm 115 of the mounting member 109 , so that the mounting member 109 is mounted to the base 111 correspondingly. A step portion 339 protruding inwardly toward the hole is provided on the wall of the locking hole 271 , and a hook 383 is provided on the upper side of the elastic arm 115 correspondingly, and the hook 383 is a step portion 339 is configured to connect the mounting member 109 below the base 111 . In this embodiment, the hook 383 is formed of an elastic piece 372 connected to the elastic arm 115 . The specific configuration of the elastic piece 372 on the elastic arm 115 and the stepped portion 339 of the locking hole 271 will be described in detail with reference to FIGS. 4A and 4B .

The base 111 further includes a cylindrical portion 375 , the cylindrical portion 375 is formed extending downwardly from the center of the button portion 214 , and the cylindrical portion 375 is generally formed of the button portion 214 . It is in the form of a cylinder coaxial with the side wall. In this embodiment, in order to facilitate machining, the cylindrical portion 375 and the button portion 214 of the base 111 are integrally formed. An accommodating space 341 is formed inside the cylindrical portion 375 , and the accommodating space 341 is closed from above by the upper plate 345 of the cover member 322 . The receiving space 341 is configured to receive the drying component 323 . A fluid inlet 379 is provided at the bottom of the cylindrical portion 375 , and the bottom 107 of the mounting member 109 covers the fluid inlet 379 from below, so that the air inside the battery pack preferentially moves the mounting member 109 . After passing through the vent 108 of . As a more specific example, a cylinder 340 is provided at the center of the cylindrical portion 375 , the cylinder 340 being formed with a mounting opening 343 configured to be connected to the insertion portion 346 of the cover member 322 . . A plurality of vents 378 are provided around the cylinder 340 of the cylindrical portion 375 , these vents 378 defining a fluid inlet 379 . Vents 378 are generally partially annular and arranged in a plurality of spaced circles, each circle including a plurality of vents 378 spaced apart from one another.

In the receiving space 341 between the wall of the cylinder 340 and the cylindrical portion 375 , a plurality of partition plates 349 are further provided, and a drying component 323 is disposed between the adjacent partition plates 349 . Accepted. As a specific example, the number of partition plates 349 is four. In this embodiment, four partition plates 349 are arranged around the cylinder 340 and extend outward. One end of each partition plate 349 is connected to the cylinder 340 , and the other end penetrates the wall of the cylindrical portion 375 and projects outwardly from the outer surface of the wall to form a rib 376 . Four ribs 376 are configured to abut against the sidewall 217 of the mounting member 109 to strengthen the connection between the mounting member 109 and the base 111 .

A plurality of blind holes 344 are provided at the bottom of the button portion 214 of the base 111 , and the positions of the blind holes 344 correspond to the positions of the screw fastening holes 216 of the mounting member 109 . As an example, an avoidance hole 389 is additionally formed on the outer side of the locking hole 271 , and the avoiding hole 389 is a locking hole 271 when the elastic arm 115 is inserted into the locking hole 271 . may be configured to allow the walls of the In this embodiment, both the blind hole 344 and the avoid hole 389 are formed concave upwardly from the bottom of the button portion 214 , and need not extend through the bottom of the button portion 214 .

The plate 219 of the mounting member 109 is provided with a number of sleeves 373 corresponding to the screw fastening holes 216 , and each sleeve 373 is formed to extend upwardly from the upper surface of the plate 219 . . Threaded holes 216 are disposed on the inner surface of the respective sleeve 373 . A sleeve 373 may be inserted into the blind hole 344 of the base 111 to facilitate a secure connection between the mounting member 109 and the base 111 .

The drying component 323 is formed of a silica gel desiccant, an alumina gel desiccant, or a molecular sieve desiccant, and is configured to absorb moisture from the pressure balance device 100, wherein moisture in the gas of the external environment flows into the interior of the battery pack. it can be prevented In this embodiment, drying component 323 includes a plurality of desiccant particles that are spherical or hemispherical. In other embodiments, drying component 323 may also be formed into other shapes and structures.

A blind hole 344 , a locking hole 271 , and an avoidance hole 389 are disposed at the bottom of the button portion 214 with the cylindrical portion 375 as the center. In the embodiment shown in the drawings, the blind hole 344 and the locking hole 271 are spaced apart in the circumferential direction of the cylindrical portion 375 , and the avoiding hole 389 is provided for deformation of the locking hole 271 . It is disposed close to the locking hole 271 to leave a space. In the present embodiment, the stepped portion 339 is formed to extend radially inwardly of the cylindrical portion 375 from the inner surface of the outer sidewall of the locking hole 271 , and the avoiding hole 389 is also formed by the locking hole 271 . ) is placed outside the In this way, when the elastic arm 115 of the mounting member 109 is inserted into the locking hole 271 , the elastic arm 115 presses the stepped portion 339 so that the sidewall of the locking hole 271 is the avoidance hole. 389 , so that the elastic arm 115 can be easily and smoothly inserted into the locking hole 271 , and the hook 383 is snap-fitted to the step 339 .

4A and 4B show a structural perspective view of the mounting member 109 viewed from two different viewpoints. 4A shows the mounting member 109 viewed from the top down, and FIG. 4B shows the mounting member 109 viewed from the bottom up. 4A and 4B , the vents 108 in the bottom 107 of the mounting member 109 are generally partially annular and are arranged in a plurality of spaced circles, each circle being one from the other. and a plurality of spaced apart vents 108 . In this embodiment, the position of the vent 108 corresponds to the position of the vent 378 on the bottom of the base 111, so that when the mounting member 109 is connected to the base, air is not obstructed with the vent 108 and It can flow through the vent 378 .

The four plates 219 of the mounting member 109 are generally sector-shaped, and one of the four sleeves 373 is disposed on the upper surface of each plate 219 , one of the four screw holes 216 . One is disposed on the inner surface of each sleeve 373 . Four resilient arms 115 are each disposed between adjacent plates 219 . For example, the screw fastening hole 216 and the elastic arm 115 are disposed at substantially uniform intervals in the circumferential direction of the mounting member 109 . The positions of the four sleeves 373 correspond to the positions of the four blind holes 344 of the base 111 , so that the sleeves 373 may be inserted into the corresponding blind holes 344 .

The four elastic arms 115 are connected to the bottom of the side wall 217 , and the positions of the four elastic arms 115 correspond to the positions of the four locking holes 271 of the base 111 , the elastic arms 115 . ) can be snap-fitted to the corresponding locking hole 271 . The bottom 107 of the side wall 217 is provided with partition slots 463 respectively on the left and right sides of each resilient arm 115 . Each resilient arm 115 includes a bottom 464 and an arm 465 , the bottom 464 is formed extending outwardly from the edge of the bottom 107 of the sidewall 217 , the arm 465 having It is formed by bending the outer edge of the bottom 464 upward. Providing compartment slots 463 only connects the bottom 464 of each resilient arm 115 to the bottom 107 and the upper end of the arm 465 away from the bottom 464 forms a free end, so that the elastic Arm 115 may have some elasticity with arm 465 able to expand and contract relative to sidewall 217 . Four hooks 383 are each disposed above the arms 465 of the respective resilient arms 115 . In this embodiment, the hook 383 is formed of the elastic piece 372 . Specifically, the upper end of the arm 465 of each resilient arm 115 has a window 484, and the upper end of each resilient piece 372 has a window ( 484, the bottom end of each elastic piece 372 forms a free end, and each elastic piece extends outwardly obliquely from the upper end toward the bottom end. According to this configuration, the elastic piece 372 may also have some elasticity, and its bottom end may be expanded and contracted with respect to other parts of the arm 465 to move in and out of the window 484 .

In the present embodiment, the number of blind holes 344 of the base 111, the number of sleeves 373 of the mounting member 109, and the number of screw fastening holes 216 are each four, and their positions are correspondingly arranged so that the mounting member 109 can be positioned and mounted at an intended location below the base 111 , such that the vent 378 of the base 111 and the vent 108 of the mounting member 109 are positioned in terms of location. Corresponding to each other can be ensured, thereby ensuring that the interior of the battery pack can be in fluid communication with the external environment through the vent 108 , the vent 378 , and the receiving cavity 580 sequentially. In other embodiments, the number of blind holes 344 , sleeve 373 , and screwing holes 216 may also vary.

5A and 5B show a cross-sectional view of the pressure balance device 100 mounted to the plate 101 shown in FIG. 1B along the lines A-A and B-B, respectively. 5A and 5B , the pressure balancing device 100 may be firmly connected to the plate 101 of the battery pack housing by fasteners. The plate 219 of the mounting member 109 and the bottom of the button portion 214 of the base 111 abut against the upper surface of the plate 101 , and the sidewall 217 and the bottom 107 of the mounting member 109 are and a cylindrical portion 375 of the base 111 extends at least partially into the mounting opening 102 . The seal ring 218 is in close contact with the upper surface of the plate 101 so that external dust particles or liquids are introduced into the battery pack under the plate 101 through the gap between the pressure balancer 100 and the plate 101 . to prevent The circular hole 105 of the plate 101 is aligned with the threaded hole 216 of the sleeve 373 of the mounting member 109 so that the plate 101 is firmly connected to the pressure balancer 100 by the fastener. do.

5B, the sleeve 373 of the mounting member 109 is inserted into the blind hole 344 of the base 111, and the hook 383 of the elastic arm 115 of the mounting member 109 is connected to the base ( 111 , the mounting member 109 is snap-fitted to the base 111 .

When the mounting member 109 is mounted to the base 111 , the elastic arm 115 is inserted into the corresponding locking hole 271 of the base 111 from bottom to top. After the outer surface of the elastic piece 372 of the elastic arm 115 comes into contact with the step 339 of the locking hole 271, when the elastic arm 115 is further inserted into the locking hole 271, the locking hole ( The stepped portion 339 of 271 presses the elastic piece 372, and a force is applied to the elastic piece 372 until the bottom end of the elastic piece 372 passes over the stepped portion 339, so that the elastic piece is contracted. and is transformed inward. When the step portion 339 no longer pushes the elastic piece 372, the elastic piece 372 returns to its original state as shown in FIG. 5B, and the bottom end of the elastic piece 372 is separated from the step portion 339 ), the mounting member 109 cannot move downward relative to the base 111 . Further, the bottom 107 of the mounting member 109 abuts against the bottom of the base 111 , so that the mounting member 109 cannot also move upward with respect to the base 111 . During the elastic deformation of the elastic piece 372 , the avoiding hole 389 leaves a space for the deformation of the locking hole 271 , so that the sidewall of the locking hole 271 can be deformed toward the avoiding hole 389 , the step difference The compression force applied to the elastic piece 372 by the portion 339 is reduced. In the present embodiment, both the arm 465 and the elastic piece 372 of the elastic arm 115 may be elastically deformed to some extent, and the wall of the locking hole 271 may also be elastically deformed to some extent, so that the elastic arm 115 may be elastically deformed to some extent. Allowing it to be smoothly inserted into this locking hole 271 , thereby making it possible to mount the mounting member 109 under the base 111 .

When the mounting member 109 is removed from the base 111 , the operator presses the arm 465 of the elastic arm 115 of the mounting member 109 , so that the bottom end of the elastic piece 372 no longer has a stepped portion 339 . ) to allow the arm 465 to deform inward until it does not abut against the upper surface of the . The elastic arm 115 can be pulled out of the locking hole 271 under the action of an external force, whereby the mounting member 109 can be removed from the base 111 .

Continuing to refer to FIG. 5A , a receiving cavity 580 closed by the cover 112 is formed inside the base 111 , and a spacer 321 connects the receiving cavity 580 with the upper receiving cavity 581 . divided into a lower receiving cavity 582 , an upper receiving cavity 581 configured to be in fluid communication with an external environment, and a lower receiving cavity 582 configured to be in fluid communication with an interior of the battery pack. Also, the upper receiving cavity 581 is in fluid communication with the lower receiving cavity 582 through the air permeable film 320 and the receiving hole 336 and the vent 335 of the support portion 333 .

Specifically, the bottom end face of the side wall of the cover 112 of the pressure balancing device 100 abuts against the upper surface of the connecting flange 331 of the spacer 321 so that the annular sealing edge 338 of the spacer 321 is It is closely pressed against the inner side of the bottom of the button portion 214 of the base 111 and is sealingly connected to the sealing groove 342 . In this manner, a spacer 321 defines a receiving cavity 580 substantially between the interior of the button portion 214 of the base 111 and the exterior side of the spacer 321 and the top closed by the cover 112 . It can be divided into a receiving cavity 581 and a lower receiving cavity 582 formed by the interior of the substantially cylindrical portion 375 and the spacer 321 . A breathable film 320 is connected over the support portion 333 and is also located in the upper receiving cavity 581 . The upper receiving cavity 581 communicates with the external environment through the vent 113 of the cover 112 so that the gas pressure in the upper receiving cavity 581 is substantially equal to the pressure of the external environment. A lower receiving cavity 582 of the battery pack through a vent 108 at the bottom of the sidewall 217 of the mounting member 109 and a fluid inlet 379 at the bottom of the cylindrical portion 375 of the base 111 . In communication with the interior, the pressure in the lower receiving cavity 582 is substantially equal to the gas pressure inside the battery pack.

When the gas pressure inside the battery pack is lower than the pressure of the external environment (ie, the gas pressure in the lower accommodating cavity 582 is lower than the gas pressure in the upper accommodating cavity 581), the air from the external environment is It will flow into the battery pack through 100. Specifically, air from the external environment is first introduced into the upper accommodating cavity 581 of the pressure balancer 100 through the vent 113 of the cover 112, and then of the breathable film 320 and the spacer 321. It flows through the vent 335 of the support portion 333 and the receiving hole 336 in sequence toward the lower receiving cavity 582 . The air introduced into the lower receiving cavity 582 then flows into the receiving space 341 through a hollow channel 347 in the upper plate 345 of the cover member 322, and comes into contact with the drying component 323 and , and finally flows into the battery pack through fluid inlet 379 and vent 108 .

When the battery cells inside the battery pack are in an operating state, the temperature inside the battery pack rises, causing the gas pressure inside to increase to be greater than the gas pressure in the external environment (that is, when the gas pressure in the lower receiving cavity 582 is greater than the gas pressure in the upper receiving cavity 581), in which case the hot gas inside the battery pack will pass through the pressure balancer 100 in the opposite direction to the flow direction, i.e. the gas will first pass through the lower receiving cavity ( 582 , and then flows into the upper accommodating cavity 581 through the support portion 333 , passes through the breathable film 320 in the upper accommodating cavity 581 , and then is discharged to the external environment.

Depending on the circumstances, when the gas pressure inside the battery pack increases to a certain extent, that is, when the pressure difference between the upper accommodating cavity 581 and the lower accommodating cavity 582 is equal to or greater than a predetermined value, the elastic portion 332 of the spacer 321 . This elastically deformed and stretched elastic portion 332 extends until the spike portion 325 on the inner side of the cover 112 penetrates the breathable film 320 and is received by the receiving hole 336 . ) to move upward. In this case, the pressure inside the battery pack is rapidly relieved through the hole in the breathable film 320 , so that the pressure balance between the upper accommodating cavity 581 and the lower accommodating cavity 582 is quickly achieved. As an example, a predetermined pressure difference value may be set according to specific needs, and the requirement of the predetermined value determines the elastic deformation height of the elastic portion 332 of the spacer 321 and the distance between the spike portion 325 and the breathable film. It is satisfied by controlling.

Those skilled in the art may also know that the elastic part 332 of this embodiment may not have a corrugated deformable structure, instead, the support part 333 and the breathable film when the pressure difference between the upper accommodating cavity and the lower accommodating cavity is greater than a predetermined value. It will be appreciated that 320 may be configured in other deformable structures as long as it can be driven to move towards the spike portion 325 .

In this embodiment, in order to ensure that the pressure balancing device 100 can balance the pressure inside the battery pack and the pressure of the external environment so that the inside of the battery pack is approximately atmospheric pressure under normal circumstances, the breathable film 320 is It should have good ventilation. In some special circumstances, the pressure balancing device 100 also rapidly relieves pressure inside the battery pack, for example, by providing a spike portion 325 for penetrating the breathable film 320 to quickly relieve pressure. should be able to do When the pressure difference between the inner side and the outer side of the breathable film 320 is relatively large due to the limitation given by the material of the breathable film 320, it may be deformed to some extent and protrude toward the spike portion 325, but in general, breathable The film 320 is relatively difficult to deform when the air permeability is excellent.

The pressure balancing device 100 of this embodiment includes a spacer 321 , and moves the breathable film 320 by using elastic deformation of the elastic portion 332 of the spacer 321 , the breathable film is the breathable film 320 . ) so that the spike portion 325 can be penetrated without relying on its own elastic deformation. Thus, under certain requirements, the pressure balancing device 100 can quickly relieve the pressure inside the battery pack. Moreover, the breathable film 320 may also be formed of a material having excellent breathability. In one embodiment of the present disclosure, the breathable film 320 may be formed of a composite of a plastic material and a non-woven material, to meet the breathability requirement.

Although in this embodiment a drying component 323 and a deformable spacer 321 and other members are provided in the receiving cavity 580 , depending on the particular type of battery pack, the pressure balancer 100 may be mounted on the plate 101 . When mounted, air from the upper and lower sides of the plate 101 can communicate through the receiving cavity 580 and the pressure balance device 100 is excessively large in pressure difference between the upper and lower sides of the plate 101 This member may also not be provided in the receiving cavity 580, or another member may be provided, as long as it is ensured that the pressures on both sides can be quickly balanced.

6A and 6B are structural perspective views of a pressure balancing device 600 mounted to a battery pack housing according to another embodiment of the present disclosure from two viewpoints. 6C is a bottom view of the pressure balancing device 600 . 6A to 6C, the pressure balancer 600 is generally in the form of a prism, and is also configured to be mounted on a plate 601 of the battery pack housing, so that the internal space of the battery pack is reduced to the pressure balancer ( 600) may be in fluid communication with the external environment. The pressure balancing device 600 includes a cover 612 and a base 611 connected together, and a mounting member 609 and a heat insulating member 691 connected below the base 611 , wherein the heat insulating member 691 is a plate Located below the 601 , the remaining parts of the pressure balancing device 600 are located above the plate 601 .

A plurality of vents 613 are provided on the cover 612 , and a plurality of vents 699 are provided on a sidewall of the base 611 , and the external environment above the plate 601 is provided with the vents 613 and vents 699 . It may be in fluid communication with the inside of the pressure balance device 600 through. The base 611 also has a fluid inlet 779 (see FIG. 7B ), a mounting member 609 and an insulating member 691 covering the fluid inlet 779 from below, and the mounting member 609 is A plurality of vents 608 are provided, and the thermal insulation member 691 also has a plurality of additional vents 692 . Accordingly, the interior of the battery pack under the plate 601 may also be in fluid communication with the interior of the pressure balancer 600 .

Four circular holes 693 are provided at the four corners of the heat insulating member 691, and the positions of the four circular holes 693 are the screw fastening holes 716 of the mounting member 609 (see FIGS. 7A and 7B). ) corresponding to the position of the heat insulating member 691 and the mounting member 609 may be firmly connected by a fastener (not shown).

In this embodiment, the pressure balancing device 600 is further provided with a heat insulating member 691 generally in the shape of a square plate, compared with the pressure balancing device 100 . The base 611 and the mounting member 609 no longer have a downwardly projecting shape, the mounting member 609 is generally in the form of a flat plate and is located on the plate 601 , and the heat insulating member 691 is the plate 601 . ) is located below (see FIG. 8). Further, the heat insulating member 691, the mounting member 609, and the fastener are all formed of a metal material. With this configuration, an isolation effect is also achieved by the heat insulating member 691 and the mounting member 609 on the premise that gas communication between the upper and lower sides of the plate 601 is ensured by the pressure balancing device 600 . can be used to prevent negative thermal effects or consequences caused by hot gases or the environment inside the battery pack and to prevent affecting other parts of the pressure balancer 600 located outside the battery pack. It is advantageous.

In this embodiment, the vent 608 of the mounting member 609 and the additional vent 692 of the heat insulating member 691 are each a square hole, and the vent 608 and the additional vent 692 are staggered. In this way, on the premise of ensuring the ventilation effect, it is possible to better prevent the hot gas inside the battery pack from flowing into the pressure balancer 600 .

7A and 7B are structural exploded perspective views of the pressure balancing device 600 of FIG. 6A viewed from two viewpoints. Fig. 7a shows the pressure balancer as viewed from above, and Fig. 7b shows the pressure balancer as seen from the bottom up. 7A and 7B , the base 611 of the pressure balancer 600 is generally in the form of a vertical through-square cylinder, a cover 612 covers the base 611 , and a mounting member 609 ) and the heat insulating member 691 are connected under the base 611 . In this embodiment, the cover 612 and the base 611 are connected together by a receiving hole 755 provided in the cover 612 and the boss 762 disposed outside the side wall of the base 611 by snap fit. do. A mounting member 609 and a base 611 are snap-fitted to an elastic arm 715 disposed on the mounting member 609 and a step 739 disposed on the transverse wall 786 of the base 611. connected together by Further, the heat insulating member 691 and the mounting member 609 are firmly connected by fasteners. In this way, the cover 612 , the base 611 , the mounting member 609 and the thermal insulation member 691 can be connected together to form the pressure balancer 600 .

Specifically, a transverse wall 786 is provided in the interior of the base 611 , and a square hole 787 passing therethrough is provided in the transverse wall 786 , and the square hole 787 is provided in the transverse wall 786 . ) define a fluid inlet 779 on the bottom surface of the The base 611 includes a rim 785 extending downwardly around the perimeter of the transverse wall 786 , the bottom of which is provided with a seal ring 718 . With the mounting member 609 positioned substantially above the rim 785 and the insulating member 691 positioned substantially at the bottom of the rim 785 , the mounting member 609 and the insulating member 691 are transversely It covers the fluid inlet 779 from below the directional wall 786 . In this way, the mounting member 609 may be positioned at a distance from the heat insulating member 691, so that even if the vents of the mounting member 609 and the heat insulating member 691 are staggered, fluid communication is not disturbed and the ventilation effect is not disturbed. can be guaranteed.

Mounting member 609 is generally in the form of a square plate, and mounting member 609 is a sleeve 773 disposed at four corners and a plurality of resilient arms 715 disposed around its perimeter, for example 6 four resilient arms 715 . A sleeve 773 protrudes toward the inside of the square hole 787 , and each sleeve 773 is provided with an internally threaded hole 716 . A resilient arm 715 also protrudes toward the interior of the square hole 787 and has a hook 783 on its upper side, a step where the hook 783 is disposed in the transverse wall 786 of the base 611 . 739 and is configured to engage the hook. That is, when the mounting member 609 covers the fluid inlet 779 from below, on the one hand, the hook 783 of the elastic arm 715 hooks the step 739 with the hook, so that the mounting member 609 is the base It cannot move downward relative to 611 , on the other hand the mounting member 609 is blocked by the transverse wall 786 and cannot move upward. In this way, the mounting member 609 can be snap-fitted to the base 611 . In this embodiment, the hook 783 is formed by bending the upper end of the elastic arm 715 outward.

Similar to pressure balancer 100 , pressure balancer 600 is also a breathable assembly disposed in the receiving space between cover 612 and base 611 (see receiving cavity 880 shown in FIG. 8 ). wherein the breathable assembly allows air from the external environment to enter the battery pack, prevents liquid from the external environment from entering the battery pack, and if the internal pressure of the battery pack is excessively high, the internal and external environment of the battery pack is configured to communicate quickly. Unlike the pressure balancer 100 , in this embodiment, two sets of breathable assemblies are arranged side by side, each set of breathable assemblies comprising a spacer 721 , a breathable film 720 , and a spring 732 .

Spacers 721 are generally square and cover square apertures 787 from above. A seal 738 is provided at the bottom edge of the spacer 721 . The seal 738 abuts the transverse wall 786 of the edge of the square hole 787 such that the spacer 721 closes the receiving cavity 880 between the cover 612 and the base 611 to the upper receiving cavity 881 . ) and a lower receiving cavity 882 (see FIG. 8 ), the upper receiving cavity 881 being configured to be in fluid communication with an external environment, and the lower receiving cavity 882 being configured to be in fluid communication with the transverse wall 786 . It is in fluid communication with the inlet 779 and thus is configured to be in fluid communication with the interior of the battery pack. A vent 735 is provided in the spacer 721, and the upper accommodating cavity 881 and the lower accommodating cavity 882 communicate with each other through the vent 735, and the breathable film 720 covers the vent 735 to cover the dust , to prevent the passage of water, etc.

A spring 732 is supported between the cover 612 and the spacer 721 . Under normal circumstances, the spring 732 is in a compressed state to provide downward support to the spacer 721 , such that the spacer 721 can be covered with a square hole 787 and the seal 738 is attached to the transverse wall 786 . maintained in abutting position. If a large upwardly acting force is applied to the spacer 721 , the spring 732 may further compress and move the spacer 721 upward away from the position where the square hole 787 is covered, resulting in the upper receiving cavity 881 . ) and the lower receiving cavity 882 directly communicate with the vent 735 of the spacer 721 through the square hole 787 rather than the breathable film 720 .

To better guide the direction of movement of the spacer 721 , two downwardly extending posts 798 are provided on the inner side of the upper side of the cover 612 . Two springs 732 are each disposed on a corresponding one of the posts 798 . A downwardly extending post 796 is also provided on the lower side of each spacer 721 , with two sleeves 795 disposed side by side in the square hole 787 , the inner wall of each sleeve 795 having a post A hole 794 is formed for receiving a corresponding one of 796 . Also, the post 796 can move up and down relative to the hole 794 . Male and female structures 797 may also be provided corresponding to posts 796 and holes 794 to prevent the spacers 721 from being displaced except for up and down movement relative to the square holes 787 .

FIG. 8 shows a cross-sectional view of the pressure balancer 600 mounted to the plate 601 shown in FIG. 6A taken along line C-C in FIG. 6C . As shown in FIG. 8 , after the pressure balancing device 600 is mounted to the plate 601 , a mounting member 609 and a heat insulating member 691 are positioned on the upper and lower sides of the plate 601 , respectively. The seal ring 718 on the base 611 abuts against the upper surface of the plate 601 so that external dust particles or liquids pass through the gap between the pressure balancer 600 and the plate 601 under the plate 601 . Prevents from entering the battery pack.

A receiving cavity 880 closed by a cover 612 is formed in the base 611 . A spacer 721 divides the receiving cavity 880 into an upper receiving cavity 881 and a lower receiving cavity 882 . The upper receiving cavity 881 is configured to be in fluid communication with an external environment, the lower receiving cavity 882 is configured to be in fluid communication with the interior of the battery pack, and the upper receiving cavity 881 is configured to have a vent 735 and a breathable film 720 . ) in fluid communication with the lower receiving cavity 882 .

Similar to the pressure balancer 100 , when the gas pressure inside the battery pack is lower than the gas pressure of the external environment (ie, the gas pressure in the lower receiving cavity 882 is lower than the gas pressure in the upper receiving cavity 881 ) ), the air from the external environment sequentially passes through the vent 613 of the cover 612 and the vent 699 of the base 611 and flows into the upper receiving cavity 881, the breathable film 720 and the vent 735 ) into the lower receiving cavity 882 , and then flows out of the fluid inlet 779 , through the vent 608 of the mounting member 609 and the additional vent 692 of the thermal insulation member 691 . flow into the pack.

When the battery cells inside the battery pack are in an operating state, the temperature inside the battery pack rises, causing the internal gas pressure to increase to be greater than the gas pressure of the external environment (that is, the gas pressure in the lower receiving cavity 882 is higher than the upper greater than the gas pressure in the receiving cavity 881), the hot gas inside the battery pack passes through the pressure balancing device 600 in the opposite direction to the flow direction, that is, the gas is first introduced into the lower receiving cavity 882. Next, it flows into the upper receiving cavity 881 through the breathable film 720 and the ventilation hole 735, and is discharged to the external environment through the ventilation hole 699 of the base 611 and the ventilation hole 613 of the cover 612. .

Depending on the situation, when the gas pressure inside the battery pack increases to some extent, that is, when the pressure difference between the lower accommodating cavity 882 and the upper accommodating cavity 881 increases to some extent, for example, the When the force is increased above the set force, the spacer 721 may move upward as the spring 732 is compressed to open the square hole 787 . In this case, the pressure of the battery pack is rapidly released through the square hole 787, so that the pressure balance between the upper receiving cavity 881 and the lower receiving cavity 882 is quickly achieved.

In some embodiments of the present disclosure, the cover and the base of the pressure balance device are formed of plastic, which not only reduces the weight of the pressure balance device but also simplifies the manufacturing procedure of the pressure balance device, and the pressure balance device is produced by a molding process. Also, the production cost is reduced. The mounting member and fastener of the pressure balancer are formed of a metal material such as sheet metal. The mounting member may snap fit to the base to facilitate removal of the mounting member. The mounting member and the battery pack are firmly connected by the fastener to prevent the mounting member from falling off the battery pack. Therefore, when the temperature inside the battery pack is high, the mounting member and the battery pack can also be firmly connected, whereby a hole in the battery pack for mounting the pressure balancer due to the component formed of plastic coming off from the battery pack exposure can be prevented.

In addition, the mounting member formed of metal may also have some degree of isolation and heat dissipation effect, so that heat build-up is reduced and thus hot gases are better prevented from being transferred to the pressure balancer. Thus, it is useful to prevent negative thermal effects or consequences due to the hot gases/environment in the battery.

In some embodiments of the present disclosure, the pressure balancing device further comprises a thermal insulation member made of metal connected to the mounting member by a fastener made of metal, so that the heat insulating member is also firm with respect to the mounting member and the battery pack. can remain connected. Insulation members provided with vents staggered with respect to the vents of the mounting member may additionally have isolating and heat dissipation effects without affecting the venting effectiveness, resulting in negative thermal effects or consequences due to the hot gas/environment inside the battery pack. It is advantageous to avoid influencing other parts of the pressure balancer located outside the battery pack.

While the present invention has been described with reference to specific embodiments shown in the accompanying drawings, it should be understood that many modifications may be made to the pressure balancing device of the present disclosure without departing from the spirit, scope and background of the teachings of the present disclosure. . Those skilled in the art will also understand that the structure of the embodiments disclosed in the present disclosure may be modified in different ways, and that all modifications are within the spirit and scope of the present disclosure and claims.

Claims (10)

A pressure balancer configured to be assembled into a battery pack, comprising:
cover;
a base having a receiving cavity formed between the base and the cover, the base provided with a fluid inlet, the fluid inlet being located below the receiving cavity and in fluid communication with the receiving cavity; and
A mounting member formed of metal and covering the fluid inlet from below, wherein the mounting member is provided with a plurality of vents to allow gas inside the battery pack to flow into the fluid inlet through the plurality of vents. absence
includes;
and the mounting member is snap-fitted to the base and connected to the battery pack by a fastener. The method of claim 1,
the mounting member comprises at least one resilient arm comprising a hook and the base comprises at least one step;
and the mounting member and the base are configured to achieve a snap-fit connection by the hook and the corresponding step. 3. The method of claim 2,
The hook is formed of an elastic piece connected to an elastic arm, the elastic arm including a window, an upper end of the elastic piece is connected to the upper side of the window, and a bottom end of the elastic piece forms a free end, the and the elastic piece is configured to be deformable relative to the other portion of the elastic arm to move in and out of the window. 3. The method of claim 2,
and the hook is formed by bending the upper side of the elastic arm outward. 3. The method of claim 2,
and the mounting member includes at least one screw fastening hole for securely connecting to the battery pack by a fastener. 6. The method of claim 5,
wherein the mounting member comprises at least one sleeve and the at least one screwing hole is disposed in the at least one sleeve. 6. The method of claim 5,
wherein the mounting member is in the form of a flat plate, and the resilient arm and the at least one screw fastening hole are disposed close to a peripheral edge of the mounting member. 8. The method of claim 7,
It further comprises a heat insulating member formed of metal and positioned below the mounting member, the heat insulating member being configured to cover the fluid inlet, the heat insulating member being provided with a plurality of additional vents to ventilate the inside of the battery pack. A pressure balancing device allowing gas to enter the fluid inlet through the plurality of additional vents and the plurality of vents. 9. The method of claim 8,
and the plurality of additional vents and the plurality of vents are staggered. 9. The method of claim 8,
and the battery pack is configured to be sandwiched between the mounting member and the heat insulating member, the heat insulating member being connected to the mounting member by the fastener.

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