Triple battery with heat dissipation and shock resistance

By using a triple-cell battery design, which utilizes separators to divide the space, clamping plate gaps, and shock-absorbing components, the problems of poor battery heat dissipation and easy damage are solved, achieving more efficient heat dissipation and stability.

CN224458211UActive Publication Date: 2026-07-03SENKE CHUANG NENG (JIANGSU) NEW ENERGY TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SENKE CHUANG NENG (JIANGSU) NEW ENERGY TECH CO LTD
Filing Date
2025-06-19
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing batteries have poor heat dissipation when clamped and fixed, and are easily damaged by impact, affecting their service life.

Method used

The battery adopts a triple battery design, which uses a separator to divide the internal space of the battery case, and sets up a support plate and clamping components. There is a gap between the clamping plate and the battery body. Combined with telescopic columns and shock-absorbing airbags, the screw drives the clamping plate to move. Heat dissipation holes and slots are added, and the stability is improved by using a motor and shock-absorbing components.

Benefits of technology

It improves battery heat dissipation efficiency and lifespan, reduces damage caused by impacts, and enhances battery stability and protection.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of triad batteries with heat dissipation shockproof, including battery shell, the inside of battery shell is equipped with two baffle, battery shell is divided into three placement spaces by three baffle, the bottom in three placement spaces is slidably cooperated with support plate, shock-absorbing component is equipped between three support plates and three placement spaces, the upper side of three support plates is equipped with battery body, the inside of battery shell is rotatably cooperated with screw rod.The utility model passes through gap, so that the heat generated at the periphery of battery body can be dissipated from gap, so that the close fit of clamping plate and battery body can be avoided, the condition of the periphery of battery body is poor heat dissipation, effectively improve the heat dissipation efficiency of battery body, and by being provided with multiple slots, so that the bottom and periphery of battery body can better exchange heat with air, improve the heat dissipation efficiency and service life of battery body.
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Description

Technical Field

[0001] This utility model relates to the field of triplet battery technology, specifically to a triplet battery with heat dissipation and shock resistance. Background Technology

[0002] A battery is a device that converts chemical energy into electrical energy. It contains an electrolyte solution and metal electrodes to generate an electric current. There are many types of batteries, mainly dry cell batteries, storage batteries, and small micro batteries.

[0003] Most batteries are held in place by clamping plates, but the tight fit between the clamping plates and the battery hinders heat dissipation from the sides and bottom, affecting battery life. Furthermore, external impacts can easily cause the battery to collide with the casing, damaging it. Therefore, there is an urgent need to design a triplet battery with heat dissipation and shock resistance to solve these problems. Utility Model Content

[0004] The purpose of this invention is to provide a triplet battery with heat dissipation and shock resistance to overcome the above-mentioned shortcomings in the prior art.

[0005] To achieve the above objectives, this utility model provides the following technical solution:

[0006] A triplet battery with heat dissipation and shock absorption includes a battery casing, two partitions inside the battery casing, the battery casing being divided into three placement spaces by the three partitions, a support plate slidingly fitted at the bottom of each of the three placement spaces, a shock-absorbing component installed between each of the three support plates and the three placement spaces, a battery body installed on the upper side of each of the three support plates, and a screw rotatably fitted on the inner side of the battery casing, with three clamping components threaded around the circumference of the screw;

[0007] The clamping assembly includes an L-shaped rod, a clamping plate mounted on one end of the L-shaped rod, and rubber pads mounted on the four opposite corners of the clamping plate and corresponding to the battery body. There is a gap between the clamping plate and the battery body. Multiple slots are passed through the opposite sides of the three support plates and the three clamping plates.

[0008] Furthermore, multiple heat dissipation holes are provided on both sides of the battery casing, and the multiple slots and multiple heat dissipation holes are connected and correspond to the three battery bodies.

[0009] Furthermore, the shock absorption assembly includes multiple telescopic columns and shock-absorbing airbags installed between the bottom of the placement space and the lower side of the support plate, with the multiple telescopic columns symmetrically arranged on opposite sides of the shock-absorbing airbags.

[0010] Furthermore, the telescopic column includes a column body installed at the bottom of the placement space, a slide rod slidably engaged with the middle of the upper end of the column body, and a spring installed between the bottom of the inner part of the column body and the lower end of the slide rod.

[0011] Furthermore, the upper end of the slide rod is fixed to the lower side of the support plate, and a motor is installed at one edge of the battery casing, with the output end of the motor fixed to one end of the screw.

[0012] Furthermore, a battery cover is installed at the upper end of the battery casing, and multiple mounting holes are symmetrically provided on both sides of the battery cover. Threaded grooves are provided in each of the multiple mounting holes, and a battery protective cover is installed at the upper end of the battery cover.

[0013] Furthermore, each of the plurality of mounting holes is fitted with bolts that are threaded into the plurality of threaded grooves, and the lower end of each of the plurality of bolts is fitted with a threaded terminal corresponding to the three battery bodies, and the plurality of bolts are located inside the battery protective cover.

[0014] In the above technical solution, the present invention provides a triplet battery with heat dissipation and shock resistance, which has the following advantages:

[0015] 1. By leaving a gap between the clamping plate and the battery body, the heat generated around the battery body can be dissipated through the gap, thus avoiding the situation where the clamping plate and the battery body are too tightly fitted, resulting in poor heat dissipation around the battery body, and effectively improving the heat dissipation efficiency of the battery body.

[0016] 2. By setting multiple slots, the bottom and sides of the battery body can better exchange heat with the air, thereby effectively expanding the heat dissipation area and further improving the heat dissipation efficiency and service life of the battery body.

[0017] 3. The screw is designed to engage with three L-shaped rods, thereby driving the three clamping plates to move synchronously and clamp and fix the three battery bodies. The shock absorption components can quickly absorb the impact force generated during squeezing and collision, buffering it and allowing the battery body to return to a stable state, thus protecting the battery body. Attached Figure Description

[0018] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this utility model. For those skilled in the art, other drawings can be obtained based on these drawings.

[0019] Figure 1 This is a front view of the structure of an embodiment of a triplet battery with heat dissipation and shock resistance according to the present invention.

[0020] Figure 2 This is a schematic diagram of the battery casing structure provided for an embodiment of a triplet battery with heat dissipation and shock resistance according to this utility model.

[0021] Figure 3 This is a schematic diagram of the support plate structure provided for an embodiment of a triplet battery with heat dissipation and shock absorption according to the present invention.

[0022] Figure 4 This is a schematic diagram of the screw structure provided for an embodiment of a triplet battery with heat dissipation and shock absorption according to the present invention.

[0023] 1. Battery casing; 2. Separator; 3. Placement space; 4. Support plate; 5. Battery body; 6. Screw; 7. L-shaped rod; 8. Clamping plate; 9. Rubber pad; 10. Groove; 11. Clamping assembly; 12. Heat dissipation hole; 13. Telescopic column; 14. Shock-absorbing airbag; 15. Column; 16. Slide rod; 17. Spring; 18. Motor; 19. Battery cover; 20. Mounting hole; 21. Battery protective cover; 22. Bolt; 23. Threaded terminal post. Detailed Implementation

[0024] To enable those skilled in the art to better understand the technical solution of this utility model, the present utility model will be further described in detail below with reference to the accompanying drawings.

[0025] like Figure 1-4 As shown in the figure, the present invention provides a three-cell battery with heat dissipation and shock absorption, including a battery casing 1. The battery casing 1 is equipped with two partitions 2 inside, and the battery casing 1 is divided into three placement spaces 3 by three partitions 2. The bottom of each of the three placement spaces 3 is slidably fitted with a support plate 4. A shock-absorbing component is installed between each of the three support plates 4 and the three placement spaces 3. A battery body 5 is installed on the upper side of each of the three support plates 4. A screw 6 is rotatably fitted on the inner side of the battery casing 1. Three clamping components 11 are threaded around the screw 6. The clamping components 11 include an L-shaped rod 7, a clamping plate 8 installed at one end of the L-shaped rod 7, and rubber pads 9 respectively installed at the four opposite corners of the clamping plate 8 and corresponding to the battery body 5. A gap is left between the clamping plate 8 and the battery body 5. Multiple slots 10 are passed through the opposite sides of the three support plates 4 and the three clamping plates 8.

[0026] In this embodiment, a battery casing 1 is included;

[0027] Specifically, a battery cover 19 is installed on the upper end of the battery casing 1. Multiple mounting holes 20 are symmetrically passed through the opposite sides of the battery cover 19. Threaded grooves are opened in the multiple mounting holes 20. A battery protective cover 21 is installed on the upper end of the battery cover 19. The battery protective cover 21 can isolate the bolts 22 and the battery body 5 from direct contact with the external environment, thereby protecting the battery body 5.

[0028] Specifically, each of the multiple mounting holes 20 is equipped with a bolt 22 that engages with the threads of the multiple threaded grooves, and the lower end of each bolt 22 is equipped with a threaded terminal 23 corresponding to the three battery bodies 5. The multiple bolts 22 are located inside the battery protective cover 21.

[0029] In this embodiment, the battery casing 1 is equipped with two partitions 2 inside, and the battery casing 1 is divided into three placement spaces 3 by the three partitions 2. The bottom of each of the three placement spaces 3 is slidably fitted with a support plate 4, and shock-absorbing components are installed between the three support plates 4 and the three placement spaces 3.

[0030] Specifically, the shock absorption assembly includes multiple telescopic columns 13 and shock-absorbing airbags 14 installed between the bottom of the placement space 3 and the lower side of the support plate 4. The multiple telescopic columns 13 are symmetrically arranged on opposite sides of the shock-absorbing airbags 14. Through the multiple telescopic columns 13 and shock-absorbing airbags 14, the impact force caused by the external force squeezing and colliding with the battery shell 1 and causing the battery body 5 to shake can be quickly buffered, reducing damage to the battery body 5 and effectively improving the stability of the battery body 5.

[0031] Specifically, the telescopic column 13 includes a column 15 installed at the bottom of the placement space 3, a slide rod 16 slidably engaged with the middle of the upper end of the column 15, and a spring 17 installed between the bottom of the column 15 and the lower end of the slide rod 16. Through the slide rod 16, the support plate 4 drives the slide rod 16 to extend and retract synchronously at the middle of the upper end of the column 15, thereby changing the distance between the slide rod 16 and the column 15, and better buffering the impact force generated when the battery body 5 collides.

[0032] In this embodiment, the upper side of each of the three support plates 4 is equipped with a battery body 5, the inner side of the battery shell 1 is rotatably fitted with a screw 6, and the circumferential side of the screw 6 is threaded with three clamping components 11. The clamping components 11 include an L-shaped rod 7, a clamping plate 8 installed at one end of the L-shaped rod 7, and rubber pads 9 respectively installed at the four opposite corners of the clamping plate 8 and corresponding to the battery body 5.

[0033] Specifically, the upper end of the slide rod 16 is fixed to the lower side of the support plate 4, and a motor 18 is installed on one side edge of the battery case 1. The output end of the motor 18 is fixed to one end of the screw rod 6. The motor 18 can drive the screw rod 6 to rotate, so that the screw rod 6 is threadedly engaged with the three L-shaped rods 7. Thus, the three L-shaped rods 7 drive the three clamping plates 8 to move synchronously, preparing for the next step of clamping and fixing the three battery bodies 5.

[0034] In this embodiment, there is a gap between the clamping plate 8 and the battery body 5, and multiple slots 10 are passed through the opposite sides of the three support plates 4 and the three clamping plates 8.

[0035] Specifically, multiple heat dissipation holes 12 are provided on both sides of the battery casing 1. The multiple slots 10 and the multiple heat dissipation holes 12 are connected and correspond to the three battery bodies 5. Through the multiple heat dissipation holes 12, the heat inside the battery casing 1 can be dissipated, thereby improving the heat dissipation effect of the device.

[0036] Working steps: 1. When it is necessary to clamp the three battery bodies 5, first place the three battery bodies 5 on top of the three support plates 4. At this time, the three battery bodies 5 drive the three support plates 4 to press down. At the same time, the three support plates 4 slide and cooperate with the bottom of the three placement spaces 3. Then, the shock absorption component absorbs the downward impact force on the three support plates 4 and dampens it, making the three support plates 4 more stable when pressing down. After placement, start the motor 18. The output end of the motor 18 drives the screw 6 to rotate, so that the screw 6 is threadedly engaged with the three L-shaped rods 7. Thus, the three L-shaped rods 7 drive the three clamping plates 8 and multiple rubber pads 9 to move horizontally in sync, realizing the clamping and fixing of the three battery bodies 5.

[0037] 2. When it is necessary to dampen the three battery bodies 5, the battery shell 1 drives the three battery bodies 5 to shake synchronously. At this time, the three battery bodies 5 drive the three support plates 4 to press down. At the same time, the three support plates 4 slide and engage with the bottom of the three placement spaces 3, so that the three support plates 4 drive multiple sliding rods 16 to slide and engage with the upper middle of multiple columns 15, thereby changing the distance between the multiple sliding rods 16 and the multiple columns 15. At the same time, the three support plates 4 drive multiple springs 17 to elastically compress synchronously. Thus, the multiple springs 17 and multiple telescopic columns 13 absorb the downward impact force on the three support plates 4 and dampen it, making the three support plates 4 more stable when pressing down, further enhancing the stability of the three battery bodies 5. At the same time, multiple shock-absorbing airbags 14 evenly distribute the impact force to the surface of the battery shell 1, thereby reducing the damage to the three battery bodies 5.

[0038] Third, when it is necessary to dissipate heat and cool down the three battery bodies 5, the heat generated on the periphery and bottom of the three battery bodies 5 can be dissipated into the interior of the battery case 1 through two gaps and multiple slots 10, and then discharged outside the battery case 1 through multiple heat dissipation holes 12. At the same time, the outside air can also enter the interior of the battery case 1 through multiple heat dissipation holes 12, and then cool down the periphery and bottom of the three battery bodies 5 through two gaps and multiple slots 10, thereby completing the heat dissipation and cooling work of the three battery bodies 5.

[0039] The foregoing description only illustrates certain exemplary embodiments of the present invention. Undoubtedly, those skilled in the art can modify the described embodiments in various ways without departing from the spirit and scope of the present invention. Therefore, the above drawings and descriptions are illustrative in nature and should not be construed as limiting the scope of protection of the claims of the present invention.

Claims

1. A triple battery with heat dissipation and shockproof, comprising a battery shell (1), characterized in that, The battery case (1) is equipped with two partitions (2) inside. The battery case (1) is divided into three placement spaces (3) by the three partitions (2). The bottom of each of the three placement spaces (3) is slidably fitted with a support plate (4). A shock-absorbing component is installed between the three support plates (4) and the three placement spaces (3). The upper side of each of the three support plates (4) is fitted with a battery body (5). The inner side of the battery case (1) is rotatably fitted with a screw (6). The circumferential thread of the screw (6) is fitted with three clamping components (11). The clamping assembly (11) includes an L-shaped rod (7), a clamping plate (8) installed at one end of the L-shaped rod (7), and rubber pads (9) respectively installed at the four opposite corners of the clamping plate (8) and corresponding to the battery body (5). There is a gap between the clamping plate (8) and the battery body (5). Multiple slots (10) are passed through the opposite sides of the three support plates (4) and the three clamping plates (8).

2. The triplet battery with heat dissipation and shock resistance according to claim 1, characterized in that, The battery casing (1) has multiple heat dissipation holes (12) on both sides. The multiple slots (10) and the multiple heat dissipation holes (12) are connected and correspond to the three battery bodies (5).

3. The triplet battery with heat dissipation and shock resistance according to claim 1, characterized in that, The shock absorption assembly includes multiple telescopic columns (13) and shock-absorbing airbags (14) installed between the bottom of the placement space (3) and the lower side of the support plate (4). The multiple telescopic columns (13) are symmetrically arranged on opposite sides of the shock-absorbing airbags (14).

4. The triple battery with heat dissipation and shock resistance according to claim 3, characterized in that, The telescopic column (13) includes a column (15) installed at the bottom of the placement space (3), a slide rod (16) slidably engaged with the middle of the upper end of the column (15), and a spring (17) installed between the bottom of the column (15) and the lower end of the slide rod (16).

5. The triple battery with heat dissipation and shock resistance according to claim 4, characterized in that, The upper end of the slide bar (16) is fixed to the lower side of the support plate (4), and a motor (18) is installed on one side edge of the battery case (1). The output end of the motor (18) is fixed to one end of the screw (6).

6. The triple battery with heat dissipation and shock resistance according to claim 1, characterized in that, The upper end of the battery casing (1) is provided with a battery cover (19). Multiple mounting holes (20) are symmetrically provided on both sides of the battery cover (19). Threaded grooves are provided in the multiple mounting holes (20). A battery protective cover (21) is provided on the upper end of the battery cover (19).

7. A triplet battery with heat dissipation and shock resistance according to claim 6, characterized in that, Each of the mounting holes (20) is fitted with a bolt (22) that is threaded to fit the threaded grooves. The lower end of each of the bolts (22) is fitted with a threaded terminal (23) corresponding to the three battery bodies (5). The bolts (22) are located inside the battery protective cover (21).