Battery pack and electrical apparatus
By opening through holes for glue filling in the side plate extension, the problem of insufficient glue filling in the gap between the battery pack and the side beam was solved, thereby improving the structural strength and stability of the battery pack and ensuring a firm connection between the battery pack and the side beam.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- SUNWODA MOBILITY ENERGY TECHNOLOGY CO LTD
- Filing Date
- 2025-11-10
- Publication Date
- 2026-07-02
AI Technical Summary
The gap between the battery pack and the side beam could not be fully filled with glue, affecting the structural stability and bonding effect, resulting in insufficient overall structural strength.
A through-hole for filling adhesive is made in the extension of the side plate, allowing the adhesive to flow between the filling sub-spaces, ensuring that the gap between the battery pack and the side beam is completely filled, thereby enhancing the bonding effect and structural stability.
The design of the through-holes allows the adhesive to flow effectively into all the gaps, improving the bonding strength and structural stability between the battery pack and the side beam, reducing the impact of vibration, preventing battery displacement, and enhancing the mechanical protection of the overall battery pack.
Smart Images

Figure CN2025133864_02072026_PF_FP_ABST
Abstract
Description
Battery packs and electrical devices
[0001] Cross-reference to related applications
[0002] This application claims priority to Chinese Patent Application No. 202423227857.5, filed on December 25, 2024, entitled "Battery Pack and Power-Using Device", the entire contents of which are incorporated herein by reference. Technical Field
[0003] This application relates to the field of battery technology, specifically to battery packs and electrical devices. Background Technology
[0004] A battery pack is an assembly of multiple batteries that can achieve higher capacity, better safety, and more stable performance. Battery packs are widely used in electric vehicles, energy storage systems, portable electronic products, and other fields.
[0005] A battery pack typically includes a housing and batteries. The batteries are the core component of the battery pack, responsible for storing and releasing electrical energy. The batteries are housed inside the housing, which protects the internal components from external environmental influences, providing mechanical protection and dust and water resistance.
[0006] Injecting adhesive into the casing secures the internal batteries. The process involves installing the batteries first, followed by adhesive injection. Ideally, all gaps should be filled with adhesive to ensure a strong bond. However, to maintain the strength of the battery pack's side structure, the side panels extend into the gaps between the battery packs and the side beams. During adhesive injection, the ends of these side panels obstruct the flow of adhesive, hindering its movement within the gaps. This prevents proper filling of the gaps between the battery packs and the side beams, ultimately affecting the overall structural stability, bonding effectiveness, and strength. Summary of the Invention
[0007] In view of this, this application provides a battery pack and an electrical device to solve the problem that the end of the side plate blocks the flow of adhesive, causing the adhesive to not be properly filled between the battery pack and the side beam.
[0008] This application provides a battery pack having a first direction, a second direction, and a third direction that intersect each other. The battery pack includes: a housing and a cover. The housing has a receiving cavity, and the cover seals the receiving cavity and is connected to the housing. The housing includes a bottom plate, two first side beams, and two second side beams. The two first side beams are spaced apart on the bottom plate along the third direction, and the two second side beams are spaced apart on the bottom plate along the second direction. The two first side beams, the two second side beams, and the bottom plate form the receiving cavity. Multiple batteries are disposed in the receiving cavity and arranged along the third direction to form a battery pack. Multiple battery packs are provided and arranged along the second direction. Multiple side plates are provided between two adjacent battery packs along the second direction. A filling gap exists between the side of the multiple battery packs near the first side beam and the first side beam. Along the third direction, at least one end of the side plate has an extension that extends beyond the edge of the battery pack. The extension is connected to the first side beam near it and divides the filling gap into filling sub-spaces. The extension has a potting through hole that connects two adjacent filling sub-spaces.
[0009] Beneficial effects: By creating a potting hole on the extension of the side plate to the filling gap, the glue flows into one filling sub-space and then through the potting hole to another filling sub-space during potting. This accelerates the flow of the glue, ensuring that the filling gap between the battery pack and the first side beam is completely filled with glue. This enhances the bonding effect and strength between the battery pack and the first side beam, thereby improving the structural strength and stability of the entire battery pack. Furthermore, the glue has a certain degree of flexibility, which can absorb vibration to a certain extent, reduce the impact of external impacts on the battery pack, and protect the battery from damage. The glue can also fix the battery position, preventing displacement during use and ensuring a stable and reliable connection.
[0010] In one alternative implementation, the potting through-hole is located close to the base plate in the first direction.
[0011] Beneficial effects: Placing the glue-filling hole close to the base plate facilitates glue flow, increases glue-filling speed, and thus improves glue-filling efficiency.
[0012] In one alternative embodiment, the side plate has a surface facing the base plate, and in a first direction, the ratio of the distance from the center of the potting hole to the surface to the height of the side plate is 1 / 3 to 1 / 2.
[0013] Beneficial effects: Setting the distance from the center of the glue-filling hole to the surface in a ratio of 1 / 3 to 1 / 2 to the height of the side plate facilitates glue flow, resulting in faster glue strip flow and higher glue injection efficiency.
[0014] In one optional embodiment, the glue-filling through-hole is funnel-shaped along the second direction; or, the glue-filling through-hole includes a first funnel segment, a cylindrical segment, and a second funnel segment arranged sequentially along the second direction, with one end of the first funnel segment near the cylindrical segment connected to one end of the cylindrical segment, and the other end of the cylindrical segment connected to one end of the second funnel segment near the cylindrical segment, the aperture of the first funnel segment gradually decreasing along the second direction, and the aperture of the second funnel segment gradually increasing along the second direction.
[0015] Beneficial effects: The funnel-shaped design facilitates unidirectional flow, guiding the glue to flow smoothly, reducing air bubble formation, and ensuring more uniform and dense glue filling. The larger inlet accelerates glue flow, shortens dispensing time, and improves production efficiency. The first funnel section guides the glue to flow smoothly, while the second funnel section guides the glue to flow out, accelerating the glue flow rate.
[0016] In one optional embodiment, there are multiple potting through holes, which are staggered along a first direction.
[0017] Beneficial effects: The multiple glue-filling holes are sloped relative to the height direction, which facilitates unidirectional flow of glue. Unidirectional flow can accelerate the flow of glue, shorten the glue-filling time, and improve production efficiency.
[0018] In one alternative embodiment, the surface of the potting through hole is an arc-shaped surface that arches and curves toward or away from the interior of the potting through hole.
[0019] Beneficial effects: The arc-shaped glue-filling through-hole also facilitates unidirectional flow of glue. Unidirectional flow can accelerate the flow of glue, shorten the glue-filling time, and improve production efficiency.
[0020] In one optional embodiment, there are multiple potting through holes, which are arranged in a straight line, a double-line, an S-shape, or an M-shape.
[0021] Beneficial effects: When multiple glue-filling through-holes are arranged in a straight line, the glue flows along a straight path, which is easy to control and monitor, ensuring uniform glue distribution. The straight path reduces dead zones in glue flow, ensuring that all areas are fully filled, and also facilitates continuous glue flow, reducing air bubble formation. When multiple glue-filling through-holes are arranged in a U-shape, the two parallel rows of through-holes can achieve bidirectional flow, ensuring uniform glue distribution in both directions. It can also achieve multi-path distribution, covering a larger area, reducing unfilled areas, and reducing air bubble formation when glue is injected at a single point, ensuring a denser glue filling. When multiple glue-filling through-holes are arranged in an S-shape, the S-shaped path ensures uniform glue distribution in a tortuous path, reducing local over- or under-thickness. The tortuous path can cover a larger area, ensuring that all corners are fully filled. When multiple glue-filling through-holes are arranged in an M-shape, the M-shaped path can achieve multi-directional flow, ensuring uniform glue distribution in multiple directions. It can also achieve multi-path distribution, covering a larger area, reducing unfilled areas.
[0022] In one alternative embodiment, the side plate has a side surface close to the battery pack, and the contour pattern formed by the potting through holes on the side surface is one or more of polygons, circles, and ellipses.
[0023] Beneficial effects: Polygonal, circular, and elliptical potting holes are easy to process and manufacture, reducing manufacturing difficulty.
[0024] In one alternative embodiment, the portion of the first side beam near the bottom plate forms a protrusion that extends toward the battery pack, and the corner of the side plate near the bottom plate has a clearance opening, into which the protrusion is inserted.
[0025] Beneficial effects: The protrusion can increase the cross-sectional area of the first side beam, improving its bending and shear resistance, thereby enhancing the structural rigidity and stability of the entire battery box. By providing clearance openings at the corners of the side plates near the bottom plate, interference between the side plates and the first side beam can be avoided.
[0026] Secondly, this application also provides an electrical device, including the battery pack as described above. Attached Figure Description
[0027] To more clearly illustrate the technical solutions in the specific embodiments of this application or the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this application. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.
[0028] Figure 1 is a perspective view of a battery pack according to an embodiment of this application;
[0029] Figure 2 is a perspective view of the battery pack housing shown in Figure 1;
[0030] Figure 3 is a magnified view of part A in Figure 2;
[0031] Figure 4 is a perspective view of the battery pack shown in Figure 1 without the cover;
[0032] Figure 5 is a magnified view of part B in Figure 4;
[0033] Figure 6 is a top view of the battery pack shown in Figure 4;
[0034] Figure 7 is a cross-sectional view of the battery pack shown in Figure 6 along the CC direction;
[0035] Figure 8 is a schematic diagram of the right side of the battery pack shown in Figure 7;
[0036] Figure 9 is a structural schematic diagram of the side plate shown in Figure 6;
[0037] Figure 10 is a schematic cross-sectional view of the side plate shown in Figure 9 along the EE direction.
[0038] Explanation of reference numerals in the attached drawings: 1. Box body; 101. Receiving cavity; 102. Bottom plate; 103. First side beam; 1031. Protrusion; 104. Second side beam; 2. Battery; 4. Side plate; 401. Extension; 402. Glue-filling through hole; 4021. First funnel section; 4022. Cylindrical section; 4023. Second funnel section; 403. Surface; 404. Side; 405. Clearance opening; 5. Cover; 6. Filling gap; 7. Structural adhesive layer; 8. Sealing strip. Detailed Implementation
[0039] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.
[0040] The embodiments of this application are described below with reference to Figures 1 to 10.
[0041] According to an embodiment of this application, a battery pack is provided, having a first direction Z and a second direction X intersecting each other and a third direction Y. The battery pack includes: a housing 1, a cover 5, a plurality of batteries 2 and a plurality of side plates 4.
[0042] Specifically, the box body 1 has a receiving cavity 101, and the cover 5 covers the receiving cavity 101 and is connected to the box body 1. The box body 1 includes a bottom plate 102, two first side beams 103 and two second side beams 104. The two first side beams 103 are spaced apart on the bottom plate 102 along a third direction Y, and the two second side beams 104 are spaced apart on the bottom plate 102 along a second direction X. The two first side beams 103, the two second side beams 104 and the bottom plate 102 form the receiving cavity 101.
[0043] Multiple batteries 2 are disposed in the receiving cavity 101. The multiple batteries 2 are arranged along the third direction Y to form a battery pack. There are multiple battery packs, and the multiple battery packs are arranged along the second direction X.
[0044] Multiple side plates 4 are provided between two adjacent battery packs along the second direction X. The side of the multiple battery packs near the first side beam 103 and the first side beam 103 have a filling gap 6. Along the third direction Y, at least one end of the side plate 4 is provided with an extension 401 that extends beyond the edge of the battery pack. The extension 401 is connected to the first side beam 103 it is near. The extension 401 divides the filling gap 6 into filling sub-spaces. The extension 401 is provided with a potting through hole 402 that connects two adjacent filling sub-spaces.
[0045] In the battery pack of this embodiment, a potting hole 402 is provided on the extension 401 of the side plate 4 extending to the filling gap 6. During potting, the glue flows into one filling sub-space and then flows from the potting hole 402 to another filling sub-space, accelerating the flow of the glue. This allows the filling gap 6 between the battery pack and the first side beam 103 to be filled with glue, enhancing the bonding effect and bonding strength between the battery pack and the first side beam 103, thereby improving the structural strength and stability of the entire battery pack. Furthermore, the glue has a certain degree of flexibility, which can absorb vibration to a certain extent, reduce the impact of external impact on the battery pack, and protect the battery 2 from damage. The glue can also fix the position of the battery 2, preventing the battery 2 from shifting during use and ensuring a stable and reliable connection.
[0046] It should be noted that the adhesive can be a potting compound, which provides protection against water, dust, shock, and insulation, and enhances physical strength. Potting compounds can be epoxy resin potting compounds or polyurethane potting compounds, etc.
[0047] It is understandable that adhesives can also be expanding foam, which offers advantages such as lightweight, good insulation properties, excellent thermal conductivity, reduced stress concentration, and improved mechanical stability. Expanding foam can be made of polyurethane foam, among others.
[0048] Furthermore, the side plate 4 can effectively isolate the battery pack, prevent the battery packs from contacting each other, reduce the risk of short circuits and thermal runaway, enhance the overall structural strength of the battery pack, provide additional mechanical support, protect the battery 2 from external impacts and vibrations, and reduce the failure of the battery 2 unit due to physical damage.
[0049] Specifically, the side plate 4 is usually made of insulating material, which can prevent electrical short circuits between the battery cells 2 and ensure circuit safety.
[0050] It should be noted that the first direction Z is the height direction of the battery pack, the second direction X can be the length direction of the battery pack, and the third direction Y can be the width direction of the battery pack.
[0051] In one embodiment, as shown in FIG9, the potting through-hole 402 is disposed close to the base plate 102 in the first direction Z. In the height direction of the battery pack, if the position of the potting through-hole 402 is too high, it will not be conducive to the flow of adhesive. Therefore, the potting through-hole 402 is disposed close to the base plate 102, which facilitates the flow of adhesive, increases the injection speed, and thus improves the injection efficiency.
[0052] Furthermore, the side plate 4 has a surface 403 facing the base plate 102. In the first direction Z, the ratio X of the distance from the center of the glue-filling through hole 402 to the surface 403 to the height of the side plate 4 is 1 / 3 to 1 / 2. If the position of the glue-filling through hole 402 is too low, when the glue exceeds the glue-filling through hole 402, the glue can no longer flow through the glue-filling through hole 402. Therefore, setting the glue-filling through hole 402 such that the ratio of the distance from its center to the surface 403 to the height of the side plate 4 is 1 / 3 to 1 / 2 is more conducive to the flow of glue, resulting in faster glue flow and higher glue injection efficiency.
[0053] Furthermore, the injection speed was tested by setting the center of the injection hole 402 at different locations. The test results are shown in Table 1 below.
[0054] Table 1
[0055] In one embodiment, the glue-filling through-hole 402 is funnel-shaped along the second direction X. The funnel-shaped design facilitates unidirectional flow, guides the glue to flow smoothly, reduces the formation of air bubbles, ensures more uniform and dense glue filling, and the larger inlet can accelerate the flow of glue, shorten the glue-filling time, and improve production efficiency.
[0056] Understandably, in another embodiment, as shown in FIG10, the glue-filling through-hole 402 includes a first funnel section 4021, a cylindrical section 4022, and a second funnel section 4023 arranged sequentially along the second direction X. One end of the first funnel section 4021 near the cylindrical section 4022 is connected to one end of the cylindrical section 4022, and the other end of the cylindrical section 4022 is connected to the end of the second funnel section 4023 near the cylindrical section 4022. The aperture of the first funnel section 4021 gradually decreases along the second direction X, and the aperture of the second funnel section 4023 gradually increases along the second direction X. The first funnel section 4021 can guide the glue to flow smoothly in, and the second funnel section 4023 can guide the glue to flow out, accelerating the flow rate of the glue.
[0057] It is understood that in other embodiments, the potting through-hole 402 is cylindrical or the like.
[0058] In one embodiment, as shown in FIG9, there are multiple glue-filling through holes 402, which are staggered along the first direction Z. In other words, the multiple glue-filling through holes 402 are sloped relative to the height direction, which is conducive to the unidirectional flow of glue. Unidirectional flow can accelerate the inflow of glue, shorten the glue-filling time, and improve production efficiency.
[0059] In one embodiment, the surface of the glue-filling through-hole 402 is an arc-shaped surface that arches and curves towards or away from the interior of the glue-filling through-hole 402. In other words, the surface of the glue-filling through-hole 402 is a convex arc-shaped surface or a concave arc-shaped surface. The arc-shaped glue-filling through-hole 402 also facilitates the one-way flow of glue. One-way flow can accelerate the inflow of glue, shorten the glue-filling time, and improve production efficiency.
[0060] In one embodiment, there are multiple potting through holes 402, which are arranged in a straight line, a double line, an S-shape, or an M-shape.
[0061] When multiple glue-filling through-holes 402 are arranged in a straight line, the glue flows along a straight path, which is easy to control and monitor, ensuring that the glue is evenly distributed. The straight path reduces dead corners in the glue flow, ensuring that all areas are fully filled, and also facilitates continuous glue flow and reduces the formation of air bubbles.
[0062] When multiple potting holes 402 are arranged in a U-shape, the two parallel rows of potting holes 402 can achieve bidirectional flow, ensuring that the glue is evenly distributed in both directions. They can also achieve multi-path distribution, covering a larger area, reducing unfilled areas, and reducing the formation of air bubbles when injecting glue at a single point, ensuring that the glue is filled more densely.
[0063] When multiple potting through-holes 402 are arranged in an S-shape, the S-shaped path can ensure that the glue is evenly distributed in the tortuous path, reducing the situation of local excessive thickness or thinness. The tortuous path can cover more areas, ensuring that all corners are fully filled.
[0064] When multiple potting holes 402 are arranged in an M-shape, the M-shaped path can achieve multi-directional flow, ensuring that the glue is evenly distributed in multiple directions. It can also achieve multi-path distribution, covering a larger area and reducing unfilled areas.
[0065] It should be noted that the glue-filling through holes 402 on the left side of Figure 9 are arranged in a staggered manner along the first direction Z, while the glue-filling through holes 402 on the right side of Figure 9 are arranged in a straight line along the first direction Z.
[0066] It is understandable that the arrangement of the potting through holes 402 is not limited to this, and the arrangement of the potting through holes 402 can be set according to specific needs.
[0067] In one embodiment, as shown in FIG9, the side plate 4 has a side surface 404 close to the battery pack, and the contour shape formed by the potting through hole 402 on the side surface 404 is one or more of polygons, circles, and ellipses. Polygonal, circular, and elliptical potting through holes 402 are convenient to process and manufacture, reducing manufacturing difficulty. Optionally, the polygon is rectangular.
[0068] It is understood that, in another embodiment, the shape of the potting through-hole 402 may also be irregular.
[0069] In one embodiment, as shown in FIG8, the portion of the first side beam 103 near the bottom plate 102 forms a protrusion 1031 protruding toward the battery pack, and the corner of the side plate 4 near the bottom plate 102 has a clearance opening 405, into which the protrusion 1031 is inserted. The protrusion 1031 can increase the cross-sectional area of the first side beam 103, improve its bending resistance and shear resistance, thereby enhancing the structural rigidity and stability of the entire battery 2 housing 1. By providing a clearance opening 405 at the corner of the side plate 4 near the bottom plate 102, interference between the side plate 4 and the first side beam 103 can be avoided.
[0070] In one embodiment, the battery pack further includes a structural adhesive layer 7 and a plurality of sealing strips 8. The structural adhesive layer 7 is bonded between the side plate 4 and the battery pack. The sealing strips 8 are arranged at both ends of the side plate 4 along the first direction Z. Sealing strips 8 are arranged on both sides of the side plate 4 along the second direction X. The sealing strips 8 are in contact with the battery pack. The structural adhesive layer 7 is arranged in the space enclosed by the sealing strips 8, the side plate 4 and the battery pack.
[0071] When applying adhesive between the side panel 4 and the battery pack, the sealing strip 8 allows the adhesive to flow in the filling cavity, preventing the adhesive from flowing out from the top and bottom between the battery pack and the side panel 4, thus preventing adhesive leakage. This allows the adhesive to be evenly filled between the side panel 4 and the battery pack. At the same time, the upper sealing strip 8 can divide the space between the side panel 4 and the battery pack into upper and lower spaces, so that the two spaces will not affect each other when applying adhesive separately.
[0072] According to an embodiment of this application, another aspect provides an electrical device including a battery pack as described above.
[0073] Specifically, the electrical device can be used for devices that require battery packs for power supply, such as electric vehicles and electric bicycles. The aforementioned battery pack facilitates the assembly of the electrical device and also helps to improve its safety performance.
[0074] Although embodiments of this application have been described in conjunction with the accompanying drawings, those skilled in the art can make various modifications and variations without departing from the spirit and scope of this application, and all such modifications and variations fall within the scope defined by the appended claims.
Claims
1. A battery pack having a first direction (Z) and a second direction (X) and a third direction (Y) intersecting each other in pairs, wherein, The battery pack includes: The box (1) and the cover (5) are provided. The box (1) has a receiving cavity (101). The cover (5) covers the receiving cavity (101) and is connected to the box (1). The box (1) includes a bottom plate (102), two first side beams (103) and two second side beams (104). The two first side beams (103) are spaced apart on the bottom plate (102) along the third direction (Y). The two second side beams (104) are spaced apart on the bottom plate (102) along the second direction (X). The two first side beams (103), the two second side beams (104) and the bottom plate (102) form the receiving cavity (101). Multiple batteries (2) are disposed in the receiving cavity (101), and the multiple batteries (2) are arranged along the third direction (Y) to form a battery pack. The battery pack is provided in multiple ways, and the multiple battery packs are arranged along the second direction (X). Multiple side plates (4) are provided between two adjacent battery packs along the second direction (X). The multiple battery packs have a filling gap (6) between the side of the battery packs near the first side beam (103) and the first side beam (103). Along the third direction (Y), at least one end of the side plate (4) is provided with an extension (401) that extends beyond the edge of the battery pack. The extension (401) is connected to the first side beam (103) near it. The extension (401) divides the filling gap (6) into filling sub-spaces. The extension (401) is provided with a potting through hole (402) that connects two adjacent filling sub-spaces.
2. The battery pack of claim 1, wherein, In the first direction (Z), the potting through hole (402) is located close to the base plate (102).
3. The battery pack of claim 2, wherein, The side plate (4) has a surface (403) facing the base plate (102), and in the first direction (Z), the ratio of the distance from the center of the potting hole (402) to the surface (403) to the height of the side plate (4) is 1 / 3 to 1 / 2.
4. The battery pack according to claim 3, wherein, Along the second direction (X), the potting through-hole (402) is funnel-shaped; Alternatively, the potting through-hole (402) includes a first funnel section (4021), a cylindrical section (4022), and a second funnel section (4023) arranged sequentially along the second direction (X). The first funnel section (4021) is connected to one end of the cylindrical section (4022) near one end of the cylindrical section (4022), and the other end of the cylindrical section (4022) is connected to the second funnel section (4023) near one end of the cylindrical section (4022). The diameter of the first funnel section (4021) gradually decreases along the second direction (X), and the diameter of the second funnel section (4023) gradually increases along the second direction (X).
5. The battery pack of any one of claims 1-4, wherein, The number of the glue-filling through holes (402) is multiple, and the multiple glue-filling through holes (402) are staggered along the first direction (Z).
6. The battery pack of any one of claims 1-4, wherein, The surface of the potting through hole (402) is an arc-shaped surface that arches and curves toward or away from the interior of the potting through hole (402).
7. The battery pack of any one of claims 1-4, wherein, The number of the glue-filling through holes (402) is multiple, and the multiple glue-filling through holes (402) are arranged in a straight line, a double line, an S-shape or an M-shape.
8. The battery pack of any one of claims 1-4, wherein, The side plate (4) has a side (404) close to the battery pack, and the contour pattern formed by the potting through hole (402) on the side (404) is one or more of polygons, circles, and ellipses.
9. The battery pack of any one of claims 1-4, wherein, The portion of the first side beam (103) near the bottom plate (102) forms a protrusion (1031) that protrudes toward the battery pack. The corner of the side plate (4) near the bottom plate (102) has a clearance opening (405), and the protrusion (1031) is inserted into the clearance opening (405).
10. The battery pack of any one of claims 1-9, wherein, The battery pack also includes a structural adhesive layer (7), which is bonded between the side plate (4) and the battery pack.
11. The battery pack of claim 10, wherein, The battery pack also includes a plurality of sealing strips (8), which are arranged at both ends of the side plate (4) along the first direction (Z) and on both sides of the side plate (4) along the second direction (X). The sealing strips (8) are in contact with the battery pack.
12. The battery pack of claim 11, wherein, The structural adhesive layer (7) is arranged within the space enclosed by the sealing strip (8), the side plate (4), and the battery pack.
13. The battery pack of any one of claims 1-9, wherein, The adhesive used to fill the gap (6) is a potting compound, which is an epoxy resin potting compound or a polyurethane potting compound.
14. The battery pack of any one of claims 1-9, wherein, The adhesive used to fill the gap (6) is a foam adhesive, and the foam adhesive is polyurethane foam adhesive.
15. The battery pack of any one of claims 1-9, wherein, The side plate (4) is made of insulating material.
16. The battery pack of any one of claims 1-9, wherein, The first direction (Z) is the height direction of the battery pack, the second direction (X) is the length direction of the battery pack, and the third direction (Y) is the width direction of the battery pack.
17. An electrical device, comprising: Includes the battery pack as described in any one of claims 1 to 16.