DE212021000535U1 - Battery pack housing and battery pack - Google Patents

Abstract

Battery pack housing (100), characterized in that it comprises:
a lower case (1);
a liquid cooling plate (2), and the liquid cooling plate (2) is installed in the lower housing (1), and the liquid cooling plate (2) is provided with the cooling flow channels (21) and the upper escape grooves (22) spaced from the cooling flow channels (21), and the Upper escape grooves (22) are open at the bottom;
a sub-protection plate assembly (3), and the sub-protection plate assembly (3) is installed on the bottom of the lower case (1) and is supported under the liquid cooling plate (2), and the sub-protection plate assembly (3) has upwardly projecting buffer projections (32), and the buffer projections (32) and the upper escape grooves (22) are vertically opposite and offset from the cooling flow channels (21), and the buffers (4) which rest against the buffer projections (32) are provided in the upper escape grooves (22).

Description

This application claims priority over a Chinese patent application with application number 202023256402.8 and the title “Battery Pack Case and Battery Pack” filed with the Chinese Patent Office on December 29, 2020, and the entire contents thereof are hereby incorporated by reference into this application.

Technical part

The present application relates to the technical field of battery production and in particular to a battery pack housing and a battery pack with the battery pack housing.

State of the art

In related technologies, most battery packs are mounted to the bottom of the vehicle as chassis parts at this point. The operating environment is relatively harsh. The liquid cooling plate is located on the underside of the vehicle as the base plate of the battery pack. When the chassis hits the ground, the flow channels of the liquid cooling plate are easy to be deformed and damaged, which will negatively affect the thermal management performance of the battery pack and may even lead to safety accidents. There is room for improvement.

Content of this application

The aim of this application is to solve at least one of the technical problems existing in the prior art. Therefore, an object of the present application is to provide a battery pack case that can effectively absorb the impact force from the bottom of the vehicle, avoid damage to the structure of the liquid cooling plate, and provide high safety.

The battery pack case according to the embodiment of the present application includes: a lower case; a liquid cooling plate, and the liquid cooling plate is installed in the lower case and is provided with cooling flow channels and upper escape grooves spaced apart from the cooling flow channels, and the upper escape grooves are open downward; a lower guard plate assembly, and the lower guard plate assembly is installed at the bottom of the lower case and is supported under the liquid cooling plate, and the lower guard plate assembly has upwardly projecting buffer projections, and the buffer projections and the upper escape grooves are vertically opposed and offset from the cooling flow channels, and in the upper escape grooves are the buffers resting against the buffer projections are provided.

According to the battery pack case of the embodiment of the present application, by arranging the buffers between the undershield assembly and the liquid cooling plate and the escape structures at the joints between them, it is possible to reduce the impact effect on the liquid cooling plate when the external force hits the undershield assembly and also the to reduce damage to the cooling flow channels caused by the underprotection plate assembly, which is advantageous to ensure the safety of the battery pack case and a stable cooling effect in the battery pack case.

According to the battery pack case of some embodiments of the present application, there are a plurality of buffer projections and upper escape grooves, and the plurality of buffer projections correspond one-to-one to the plurality of upper escape grooves, and a lower escape groove is defined between two adjacent buffer projections, and the lower escape grooves are open upwardly to provide the cooling flow channels (21 ) to avoid.

According to the battery pack housing of some embodiments of the present application, the vertical depth of the sub-escape grooves is greater than the vertical height of the cooling flow channels.

According to the battery pack housing of some embodiments of the present application, the opening width of the sub-escape grooves is larger than the bottom width of the cooling flow channels.

According to the battery pack housing of some embodiments of the present application, the vertical height of the buffers is greater than the vertical depth of the top escape grooves.

According to the battery pack housing of some embodiments of the present application, the height of the upwardly projecting buffer projections is greater than the vertical depth of the upper deflection grooves.

According to the battery pack case of some embodiments of the present application, the under-protection plate assembly includes wave plates and a protection plate, the protection plate being installed at the bottom of the sub-case and connected to the sub-case. The wave plates are installed on the top of the protection plate, and the wave plates have a plurality of buffer projections and define a sub-escape groove between two adjacent buffer projections.

According to the battery pack housing of some embodiments of the present application, the lower surfaces of the bottom walls of the sub-escape grooves press against the upper surface of the protective plate, and the lower surfaces of the tops of the buffer projections are spaced from the protective plate and define the reinforcing cavities with the protective plate.

According to the battery pack case of some embodiments of the present application, there are a plurality of wave plates, and the plurality of wave plates are spaced on the upper surface of the protection plate.

The present application also proposes a battery pack.

According to the battery pack of the embodiment of the present application, a battery pack case described in one of the above-mentioned embodiments is provided.

Compared with the prior art, the battery pack has the same advantages as the battery pack case described above, and the details are not repeated here.

Additional aspects and advantages of the application are set forth in part in the following description and in part will be apparent from the description or can be learned from the teachings of the application.

Description of the drawings

• 1 ist eine Explosionsansicht eines Batteriepackgehäuses gemäß einer Ausführungsform der vorliegenden Anmeldung;
• 2 ist eine schematische Strukturansicht einer Unterschutzplattenbaugruppe des Batteriepackgehäuses gemäß einer Ausführungsform der vorliegenden Anmeldung;
• 3 ist eine Querschnittsansicht der Anordnung der Unterschutzplattenbaugruppe und der Flüssigkeitskühlplatte des Batteriepackgehäuses gemäß einer Ausführungsform der vorliegenden Anmeldung.

The above and/or additional aspects and advantages of the present application will be clear and readily understood from the description of the embodiments taken in conjunction with the following drawings, in which:

• 1 is an exploded view of a battery pack housing according to an embodiment of the present application;
• 2 is a schematic structural view of a battery pack housing undershield assembly according to an embodiment of the present application;
• 3 is a cross-sectional view of the arrangement of the undershield assembly and the liquid cooling plate of the battery pack housing according to an embodiment of the present application.

Reference symbol:

battery pack housing 100,

lower housing 1,

Liquid cooling plate 2, cooling flow channels 21, upper escape grooves 22, upper plate 23, lower plate 24,

Under protection plate assembly 3, wave plates 31, buffer projections 32, under escape grooves 33, protection plate 34, reinforcing cavities 35,

Buffer 4.

Detailed embodiments

Embodiments of the present application are described in detail below, examples of which are shown in the drawings, with the same or similar reference numerals throughout denoting the same or similar elements or elements with the same or similar functions. The embodiments described below by reference to the drawings are exemplary and serve only to explain the present application and should not be construed as limiting the present application.

The following is with reference to the 1-3 a battery pack housing 100 according to an embodiment of the present application is described. The undershield assembly 3 of the battery pack case 100 is independent of the underbody 1, and buffers 4 are provided between the undershield assembly 3 and the liquid cooling plate 2 to cushion the impact force from the bottom of the vehicle, and the undershield assembly 3 will cause severe damage to the cooling flow channels 21 when deformed due to the impact force of the liquid cooling plate 2, which has a positive effect on the safety of the battery pack housing 100.

As in 1 As shown, the battery pack case 100 according to an embodiment of the present application includes: a sub-case 1, a liquid cooling plate 2, and a sub-protection plate assembly 3.

As in 1 As shown, the lower case 1 is a circumferentially closed frame structure, and the upper and lower ends of the lower case 1 are open, and the liquid cooling plate 2 is installed in the lower case 1, and the sub-protection plate assembly 3 is installed at the bottom of the lower case 1 and is installed under the liquid cooling plate 2, that is, the liquid cooling plate 2 and the under-protection plate assembly 3 are installed together on the bottom of the sub-case 1 to form an under-wall structure of the battery pack case 100. The underprotection plate assembly 3 can be used to protect the liquid cooling plate 2 to protect against the impact caused by gravel splashing on the ground, and can withstand the impact force on the bottom of the battery pack when the chassis hits the ground.

2 cooling flow channels 21 are integrated into the liquid cooling plate. As in 3 shown, the liquid cooling plate 2 includes a top plate 23 and a bottom plate 24, wherein the top plate 23 is a flat plate and the bottom plate 24 is a corrugated plate, that is, the bottom plate 24 is formed with an upwardly open flow channel groove, so that at the Flow channel grooves cooling flow channels 21 are formed for coolant circulation when the upper plate 23 is firmly connected to the lower plate 24. That is, as in 3 shown, the liquid cooling plate 2 is provided with the cooling flow channels 21, and the cooling flow channels 21 protrude downward on the underside of the liquid cooling plate 2, and the liquid cooling plate 2 is provided with the upper deflection grooves 22 spaced from the cooling flow channels 21, and the upper deflection grooves 22 are open downward . As in 3 shown, the liquid cooling plate 2 is provided with a plurality of cooling flow channels 21, and a downwardly open upper escape groove 22 is formed between two adjacent cooling flow channels 21. The upper escape grooves 22 are open at the bottom.

This shows, as in 3 shown, the lower protection plate assembly 3 has upwardly projecting buffer projections 32, and the buffer projections 32 and the upper escape grooves 22 are vertically opposite and the buffer projections 32 offset the cooling flow channels 21. The buffers 4 resting against the buffer projections 32 are provided in the upper escape grooves 22.

That is, when the bottom of the battery pack case 100 is subjected to an impact force, the external force may act on the undershield assembly 3 first, and the undershield assembly 3 deforms upward when subjected to the impact force, with the buffer projections 32 over the buffers 4 with it the liquid cooling plate 2 are connected, so that the buffer projections 32 press on the buffers 4 to absorb the impact force, thereby gradually absorbing the impact force from below.

It should be noted that the buffers 4 may be buffer foams, so that the undershield assembly 3 compresses the buffer foams when the bottom of the battery pack is subjected to an impact force, and after the compression reaches a certain level, the buffer projections 32 and the bottom walls of the upper escape grooves 22 form a force transmission channel, and the buffer projections 32 and the undershield assembly 3 begin to absorb external impact energy and begin to deform further, so that during deformation, the impact from the undershield assembly 3 to the liquid cooling plate 2 is weakened and the structural stability of the liquid cooling plate 2 is ensured, and excessive deformation of the liquid cooling plate 2 into the cavity of the lower case 1 is avoided and the safety of the battery pack is improved.

Here, the buffer projections 32 are separated from the cooling flow channels 21 during the upward movement, so that the buffer projections 32 do not directly impact the outer walls of the cooling flow channels 21, thereby avoiding that the undershield assembly 3 excessively compresses the cooling flow channels 21 during the upward movement and the cooling flow channels 21 because of of the compression and causing the seal to break. This ensures the structural stability of the cooling flow channels 21, so that the battery pack housing 100 still has good cooling performance when it hits the ground.

According to the battery pack case 100 of the embodiment of the present application, by arranging the buffers 4 between the undershield assembly 3 and the liquid cooling plate 2 and the escape structures at the joints between the two, it is possible to reduce the impact on the liquid cooling plate 2 when external forces are applied Under protection plate assembly 3 act, and to reduce the damage caused by the under protection plate assembly 3 to the cooling flow channels 21, which is conducive to ensuring the safety of the battery pack case 100 and stable cooling performance in the battery pack case 100.

In some embodiments, there are a plurality of buffer projections 32 and upper escape grooves 22, and the plurality of buffer projections 32 correspond one-to-one to the plurality of upper escape grooves 22.

That is, by arranging a plurality of buffer projections 32 on the top of the underguard plate assembly 3 and arranging buffers 4 between the plurality of buffer projections 32 and the upper escape grooves 22, the plurality of buffers 4 can simultaneously absorb and buffer the impact force from the bottom of the underguard plate assembly 3, thereby achieving the buffering effect on the impact force of the undershield assembly 3 and the buffering performance of the battery pack housing 100 can be improved.

It should be noted that the buffer projections 32 are as shown in FIGS 1 and 2 shown are elongated projections that extend on the underprotection plate assembly 3, and that a plurality of buffer projections 32 are spaced apart from one another in rows perpendicular to their direction of extension. Similarly, the upper escape grooves 22 are also elongated grooves extending on the lower surface of the liquid cooling plate 2, so that by installing and fitting a plurality of buffer projections 32 and a plurality of upper escape grooves 22 and arranging a strip-shaped buffer 4 on each buffer projection 32 and in each upper escape groove 22, the Under protection plate assembly 3 and the liquid cooling plate 2 at different positions in the width direction of the battery pack case 100 and at different positions in the longitudinal direction of the battery pack case 100 can absorb the impact force by the buffers 4 to ensure that the battery pack case 100 has good energy absorption performance at different positions, thereby improving the structural safety of the battery pack housing 100.

A sub-escape groove 33 is limited between two adjacent buffer projections 32. The sub-escape grooves 33 are open at the top and serve to avoid the cooling flow channels 21, that is, when the sub-protection plate assembly 3 deforms upwards, the cooling flow channels 21 can accordingly extend into the sub-escape grooves 33, so that the sub-protection plate assembly 3 forms the outer wall of the cooling flow channels 21 is not touched directly, thereby preventing the cooling flow channels 21 from being compressed. The structural stability of the cooling flow channels 21 is guaranteed.

In some embodiments, as in 3 As shown, the vertical depth of the sub-escape grooves 33 is greater than the vertical height of the cooling flow channels 21, that is, while the sub-protection plate assembly 3 is deformed upward due to the impact, the cooling flow channels 21 gradually extend into the sub-escape grooves 33, and after the sub-protection plate assembly 3 continues has been deformed due to the impact, the cooling flow channels 21 are located in the sub-escape grooves 33 and the bottom surfaces of the cooling flow channels 21 will not come into contact with the inner wall of the sub-escape grooves 33, so that even if the sub-protection plate assembly 3 is subjected to a very large impact force, no Impact and no extrusion will occur on the cooling flow channels 21, ensuring that the cooling flow channels 21 always remain in a safe and stable condition.

In some embodiments, as in 3 shown, the opening width of the sub-escape grooves 33 is larger than the bottom width of the cooling flow channels 21. It should be noted that, as in 3 shown, the two inner walls of the sub-escape grooves 33 run obliquely, and the outer side walls of the cooling flow channels 21 are also designed as inclined side walls, the side walls of the sub-escape grooves 33 always maintaining a distance from the side walls of the cooling flow channels 21, so that the cooling flow channels 21 during deformation of the sub-protection plate assembly 3 can smoothly enter the sub-avoidance grooves 33 without directly touching the side walls of the sub-avoidance grooves 33, thereby ensuring that the structure of the cooling flow channels 21 does not collide.

In some embodiments, as in 3 As shown, the vertical height of the buffers 4 is greater than the vertical depth of the upper escape grooves 22. That is, when the buffers 4 are installed in the upper escape grooves 22, the upper end and the main body of the buffers 4 are in the upper escape grooves 22 and the lower The end and a small part of the buffers 4 extend below the upper deflection grooves 22, so that the part of the buffers 4 protruding from the upper deflection grooves 22 can effectively come into contact with the buffer projections 32.

When the undershield assembly 3 is not subjected to any external force, the buffer projections 32 are already in contact with the buffers 4, so that when the undershield assembly 3 is initially deformed upward due to the impact, the buffers 4 can cushion the impact, that is, a Such adjustment is advantageous to increase the compression stroke of the buffers 4, so that with a larger compression stroke, the buffers 4 absorb more impact energy and improve the energy absorption effect of the battery pack housing 100.

In some embodiments, the upwardly projecting height of the buffer projections 32 is greater than the vertical depth of the upper escape grooves 22, that is, while the bottom guard plate assembly 3 is deformed upward, the buffer projections 32 can fully extend into the upper escape grooves 22, and when the buffer projections 32 are in come into contact with the bottom walls of the upper escape grooves 22, other parts of the lower protection plate assembly 3 are still not in contact with the liquid cooling plate 2, so that the lower protection plate assembly 3 can transmit the received impact force to the liquid cooling plate 2 via the buffers 4 instead of the liquid cooling plate 2 to come into direct contact with the undershield assembly 3 and transmit the impact force to reduce the impact force received by the liquid cooling plate 2.

In some embodiments, such as in the 2 and 3 As shown, the under-protection plate assembly 3 includes the wave plates 31 and a protection plate 34, the protection plate 34 being installed at the bottom of the sub-case 1 and connected to the sub-case. The wave plates 31 are installed on the top of the protection plate 34, and the wave plates 31 have a plurality of buffer projections 32 and a sub-escape groove 33 is defined between two adjacent buffer projections 32.

It should be noted that the protective plate 34, as in 2 shown is formed as a flat plate and the outline shape of the protective plate 34 is formed to match that of the lower case 1, so that the lower part of the lower case 1 can be effectively sealed when the protective plate 34 is attached to the bottom of the lower case 1 is, thereby ensuring the sealing of the battery pack housing 100.

In some embodiments, as in 3 shown, the lower surfaces of the lower walls of the sub-escape grooves 33 press against the upper surface of the protective plate 34 and the lower surfaces of the upper part of the buffer projections 32 are spaced from the protective plate 34 and delimit the reinforcing cavities 35 with the protective plate 34.

The wave plates 31 can be firmly connected to the protective plate 34, for example the wave plates 31 and the protective plate 34 can be connected by welding or gluing. The wave plates 31 are designed as a corrugated plate, and as in 3 As shown, the wave crests of the wave plates 31 are formed in the above-mentioned buffer projections 32, and the wave troughs of the wave plates 31 are formed in the above-mentioned sub-escape grooves 33. As in 3 shown, the upper surfaces of the wave crests of the wave plates 31 have support planes, the support planes being used to support the lower surfaces of the buffers 4. The bottom surface of the troughs of the wave plates 31 have connection planes, and the connection planes press against the upper surface of the protective plate 34 and can be connected by welding or gluing.

As in 3 shown, the lower surfaces of the wave crests of the wave plates 31 are spaced from the protective plate 34 and form a reinforcing cavity 35 between two wave troughs in the lower space of a wave crest. Thereby, the wave plates 33 and the skid plate 34 are connected and define a plurality of reinforcing cavities 35, which contribute to improving the structural strength of the skid plate assembly 3, can increase the rigidity of the skid plate assembly 3, and increase the performance of the skid plate assembly 3 to resist deformation.

In some embodiments, there are a plurality of wave plates 31, and the plurality of wave plates 31 are spaced apart on the upper surface of the protection plate 34, and the plurality of wave plates 31 can be separately installed on the upper surface of the protection plate 34 so that a plurality of wave plates 31 can be flexibly replaced individually and it is advantageous to reduce the cost of developing the wave plates 31.

The present application also proposes a battery pack.

According to the battery pack of the embodiment of the present application, the battery pack case 100 of one of the above-mentioned embodiments is provided, and by arranging the buffers 4 between the under-protection plate assembly 3 and the liquid cooling plate 2 and arranging the escape structures at the joints between the two, it is possible to achieve the same To reduce the impact effect on the liquid cooling plate 2 when external forces act on the undershield assembly 3, and to reduce the damage to the cooling flow channels 21 caused by the undershield assembly 3, which is conducive to ensuring the safety of the battery pack case 100 and stable cooling performance in the battery pack case 100.

In the description of the present application it is to be understood that the terms "center", "longitudinal", "transverse", "length", "width", "thickness", "on", "under", "before", " behind", "left", "right", "vertical", "horizontal", "top", "floor", "inside", "outside", "clockwise", "counterclockwise", "axial" , "Radial", "perimeter" and other specified orientations or positional relationships are based on the orientations or positional relationships shown in the drawings and are intended only for the convenience of describing the application and to simplify the description, rather than to indicate or imply that the devices or elements mentioned are specific have orientations, must be trained and function in certain orientations and should therefore not be construed as a limitation on registration.

In the description of this application, “first feature” and “second feature” may include one or more of these features.

In the description of this application, “multiple” means two or more.

In the description of the present application, the expression that a first feature is "on" or "under" a second feature may include that the first and second features are in direct contact, and may also include that the first and second features are not in direct contact but are connected by other characteristics between them.

In the description of the present application, the expression that the first feature is "on", "above" and "above" the second feature includes, or simply means that the first feature is directly above and obliquely above the second feature first feature is in a higher horizontal position than the second feature.

In the description of this specification, the reference terms “an embodiment,” “some embodiments,” “exemplary embodiments,” “example,” “specific examples,” or “some examples,” and so on shall mean those described by that embodiment or example specific features, structures, materials or properties may be included in at least one embodiment or example of the present application. In this specification, the exemplary descriptions of the above terms do not necessarily refer to the same embodiment or example. Additionally, the specific features, structures, materials, or properties described may be suitably combined in any one or more embodiments or examples.

Although the embodiments of the present application have been shown and described, those skilled in the art will understand that various changes, modifications, substitutions and variations may be made to these embodiments without departing from the principle and spirit of the present application. The scope of protection of the application is defined by the claims and their equivalents.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• CN202023256402 [0001]

Claims (10)

A battery pack case (100) characterized in that it comprises: a sub-case (1); a liquid cooling plate (2), and the liquid cooling plate (2) is installed in the lower housing (1), and the liquid cooling plate (2) is provided with the cooling flow channels (21) and the upper escape grooves (22) spaced from the cooling flow channels (21), and the Upper escape grooves (22) are open at the bottom; a sub-protection plate assembly (3), and the sub-protection plate assembly (3) is installed on the bottom of the lower case (1) and is supported under the liquid cooling plate (2), and the sub-protection plate assembly (3) has upwardly projecting buffer projections (32), and the buffer projections (32) and the upper escape grooves (22) are vertically opposite and offset from the cooling flow channels (21), and the buffers (4) which rest against the buffer projections (32) are provided in the upper escape grooves (22). Battery pack housing (100). Claim 1 , characterized in that there are a plurality of buffer projections (32) and upper escape grooves (22), and the plurality of buffer projections (32) correspond one-to-one to the plurality of upper escape grooves (22), and between two adjacent buffer projections (32) there is a lower escape groove (33) limited, and the sub-avoidance grooves (33) are open at the top in order to avoid the cooling flow channels (21). Battery pack housing (100). Claim 2 , characterized in that the vertical depth of the sub-escape grooves (33) is greater than the vertical height of the cooling flow channels (21). Battery pack housing (100) according to one of the Claims 2 until 3 , characterized in that the opening width of the sub-avoidance grooves (33) is larger than the bottom width of the cooling flow channels (22). Battery pack housing (100). Claim 1 , characterized in that the vertical height of the buffers (4) is greater than the vertical depth of the upper deflection grooves (22). Battery pack housing (100) according to one of the Claims 1 until 5 , characterized in that the height of the upwardly projecting buffer projections (32) is greater than the vertical depth of the upper escape grooves (22). Battery pack housing (100) according to one of the Claims 2 until 6 , characterized in that the under-protection plate assembly (3) comprises wave plates (31) and a protection plate (34), the protection plate (34) being installed on the bottom of the lower housing (1) and connected to the lower housing (1), and the wave plates ( 31) are installed on the top of the protective plate (34), and the wave plates (31) have a plurality of buffer projections (32) and define a sub-escape groove (33) between two adjacent buffer projections (32). Battery pack housing (100). Claim 7 , characterized in that the lower surfaces of the lower walls of the sub-escape grooves (33) press against the upper surface of the protective plate (34) and the lower surfaces of the upper sides of the buffer projections (32) are spaced from the protective plate (34) and border with the protective plate (34) the reinforcing cavities (35). Battery pack housing (100). Claim 7 , characterized in that there are a plurality of wave plates (31), and the plurality of wave plates (31) are spaced on the upper surface of the protection plate (34). A battery pack, characterized in that it has a battery pack housing (100) according to one of the Claims 1 until 9 is provided.

Images