Self-adaptive ambient temperature adjusting device of outdoor energy storage all-in-one machine

By using an adaptive ambient temperature regulation device, and utilizing components such as fans, heat dissipation fins, heating plates, and semiconductor cooling chips, the heat dissipation and heating problems of outdoor energy storage units in high and low temperature environments are solved, thereby improving the stability and reliability of the equipment.

CN224417835UActive Publication Date: 2026-06-26UPOWER ELECTRIC CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
UPOWER ELECTRIC CO LTD
Filing Date
2025-07-28
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing outdoor energy storage units have poor heat dissipation in high-temperature environments, which accelerates the aging of electronic components and affects stability and safety. In low-temperature environments, the internal resistance of the battery increases, the charging and discharging efficiency decreases, and the energy conversion efficiency and battery life are affected.

Method used

Design an adaptive ambient temperature regulation device, comprising a fan, heat sink fins, heating plate, thermoelectric cooler, and solar panel. Adaptive temperature regulation is achieved through fan ventilation, heat sink fin heat dissipation, thermoelectric cooler cooling, and heating plate heating, combined with power supply from solar panel.

Benefits of technology

It enables rapid heat dissipation and cooling or heating under different environmental conditions, extending equipment life, improving stability and reliability, and enhancing energy conversion efficiency and endurance.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to the field of outdoor energy storage integrated machine, especially an adaptive ambient temperature adjusting device of outdoor energy storage integrated machine, including energy storage box, fan, heat dissipation fin and temperature adjusting component etc., the fan is rotatably connected in the lower part of energy storage box, the heat dissipation fin is connected in the left and right two parts of energy storage box, and the temperature adjusting component for the adaptive adjustment temperature according to the environment is equipped in the middle part of energy storage box. The utility model discloses when the weather is hot, through the opening and closing board rotation and through the fan rotation and heat dissipation fin cooperation ventilation heat dissipation, through the semiconductor refrigeration piece heat absorption cooling, when the weather is cold, through the solar panel and opening and closing board rotation close, then through the heating plate operation heating, thereby can adapt to the environment and regulate temperature and use outdoor energy storage integrated machine, convenient quick heat dissipation and heating maintain stable, prolong the life, improve the use stability and reliability.
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Description

Technical Field

[0001] This utility model relates to the field of outdoor energy storage integrated machines, and in particular to an adaptive ambient temperature regulation device for outdoor energy storage integrated machines. Background Technology

[0002] Against the backdrop of global energy transition and sustainable development, outdoor energy storage units, as key equipment for energy storage and conversion, play an increasingly important role in many fields such as distributed energy systems and smart grids. They can effectively store electrical energy and release it stably when needed, providing reliable power support for various electrical devices. Existing outdoor energy storage units typically regulate temperature through on-board fans, which is ineffective. In high-temperature environments, if heat cannot be dissipated effectively, it accumulates inside the unit, leading to performance degradation of electronic components, accelerated aging, and affecting the overall stability and safety of the equipment. In low-temperature environments, the internal resistance of the battery increases, reducing charging and discharging efficiency, affecting the energy conversion efficiency of the energy storage unit, shortening battery life, and potentially causing stress due to uneven shrinkage of internal materials, leading to cracks or damage and shortening its lifespan.

[0003] Therefore, it is necessary to design an adaptive ambient temperature regulation device for outdoor energy storage units that can adapt to the environment and regulate temperature for use, so as to facilitate rapid heat dissipation and cooling, maintain stability during heating, extend service life, and improve the stability and reliability of use. Utility Model Content

[0004] To overcome the drawbacks of high-temperature environments where heat accumulates inside the device, leading to decreased performance of electronic components, accelerated aging, and impact on overall stability and safety, and low-temperature environments where increased battery internal resistance, decreased charging and discharging efficiency, reduced energy conversion efficiency, and shortened battery life, this invention provides an adaptive ambient temperature regulation device for outdoor energy storage units. This device facilitates rapid heat dissipation and cooling, maintains stability during heating, extends service life, and improves operational stability and reliability.

[0005] Technical solution: An adaptive ambient temperature regulation device for an outdoor energy storage integrated machine, comprising an energy storage box, a fan, heat dissipation fins, a temperature regulation component, and an energy storage component. The fan is rotatably connected to the lower part of the energy storage box, and heat dissipation fins are connected to both the left and right sides of the energy storage box. A temperature regulation component for adaptively adjusting the temperature according to the environment is provided in the middle of the energy storage box, and an energy storage component for converting light energy into electrical energy for power supply is provided on the energy storage box.

[0006] In one embodiment, the energy storage box has a double-layer structure.

[0007] In one embodiment, a dustproof net is also included, with dustproof nets connected to both the left and right sides of the middle of the energy storage box.

[0008] In one embodiment, the temperature regulation component includes a heating plate, a thermoelectric cooler, a connecting plate, a second rotating frame, a hinged plate, and a connecting rod. The heating plate is connected to the inner side of the upper part of the energy storage box, and thermoelectric coolers are connected to the inner sides of both the left and right parts of the energy storage box. Multiple hinged plates are rotatably connected to both the left and right sides of the energy storage box, and a second rotating frame is connected to each of the hinged plates. A connecting plate is movably connected to the uppermost second rotating frame, and a connecting rod is rotatably connected between the four second rotating frames at the same longitudinal position.

[0009] In one embodiment, the second rotating frame is L-shaped.

[0010] In one embodiment, the energy storage component includes a motor, a first rotating frame, and a solar panel. Two motors are connected to the lower part of the energy storage box, and the motors and the processor are electrically connected through a control module. The output shafts of the motors are each connected to a first rotating frame, and the first rotating frames are rotatably connected to the energy storage box. Two solar panels are rotatably connected to the upper part of the energy storage box, and the solar panels are movably connected to the first rotating frame on the same side. Connecting plates are rotatably connected to the solar panels on the same side.

[0011] The beneficial effects of this utility model are: 1. When the weather is hot, the opening and closing plate rotates and the fan rotates in conjunction with the heat dissipation fins to ventilate and dissipate heat, and the semiconductor cooling chip absorbs heat and cools down. When the weather is cold, the solar panel and the opening and closing plate rotate to close, and the heating plate operates to heat up. This allows the outdoor energy storage unit to adapt to the environment and adjust the temperature, which facilitates rapid heat dissipation and cooling and maintains stable heating, extends service life, and improves the stability and reliability of use.

[0012] 2. This utility model uses a rotating solar panel to absorb light energy and convert it into electrical energy for power supply. When the solar panel is unfolded, it will drive the connecting plate to move and rotate, causing the second rotating frame to move and rotate, which in turn drives the opening and closing plate to rotate and open for ventilation and heat dissipation. Thus, the solar panel can be rotated to unfold for energy storage while the opening and closing plate is rotated to open for heat dissipation, which is conducive to maximizing energy collection and power supply and enhancing the heat dissipation effect.

[0013] 3. When the weather is cold or the outdoor energy storage unit is not in use, the solar panel can be rotated and retracted, and the opening and closing plate can be rotated and closed to prevent dust. This allows the opening and closing plate and the solar panel to be rotated and retracted to prevent dust when the weather is cold or the device is not in use, thus protecting the equipment from the effects of severe weather, preventing dust accumulation, and further extending its service life. Attached Figure Description

[0014] Figure 1 This is a three-dimensional structural diagram of the present invention.

[0015] Figure 2 This is a three-dimensional cross-sectional view of the energy storage box and fan components of this utility model.

[0016] Figure 3 This is a three-dimensional cross-sectional view of the heat dissipation fins and dustproof mesh components of this utility model.

[0017] Figure 4 This is a three-dimensional cross-sectional view of the semiconductor cooling chip and solar panel components of this utility model.

[0018] Figure 5 This is a three-dimensional cross-sectional view of the motor and opening / closing plate components of this utility model.

[0019] The components in the diagram are labeled as follows: 1-Energy storage box, 2-Fan, 3-Heating plate, 4-Heat dissipation fins, 5-Semiconductor cooling chip, 6-Dustproof net, 7-Motor, 8-First rotating frame, 9-Solar panel, 10-Connecting plate, 11-Second rotating frame, 12-Opening and closing plate, 13-Connecting rod. Detailed Implementation

[0020] The following description is only a preferred embodiment of the present invention and does not limit the scope of protection of the present invention.

[0021] An adaptive ambient temperature regulation device for an outdoor energy storage integrated machine, such as Figures 1-5 As shown, it includes an energy storage box 1, a fan 2, heat dissipation fins 4, a dust filter 6, a temperature regulation component, and an energy storage component. The energy storage box 1 has a double-layer structure for easy isolation or insulation. The fan 2 is rotatably connected to the lower part of the energy storage box 1. Heat dissipation fins 4 are connected to both the left and right sides of the energy storage box 1. Dust filters 6 are connected to both the left and right sides of the middle part of the energy storage box 1 for dust prevention. A temperature regulation component for adaptively adjusting the temperature according to the environment is provided in the middle of the energy storage box 1. An energy storage component for converting light energy into electrical energy for power supply is provided on the energy storage box 1.

[0022] like Figures 1-5 As shown, the temperature regulation assembly includes a heating plate 3, a semiconductor cooling chip 5, a connecting plate 10, a second rotating frame 11, an opening and closing plate 12, and a connecting rod 13. The heating plate 3 is connected to the inner side of the upper part of the energy storage box 1. The semiconductor cooling chip 5 is connected to the inner side of both the left and right parts of the energy storage box 1. Four opening and closing plates 12 are rotatably connected to both the left and right sides of the energy storage box 1. The second rotating frame 11 is connected to each of the opening and closing plates 12. The second rotating frames 11 are all L-shaped to facilitate support and rotation. The connecting plate 10 is movably connected to the uppermost second rotating frame 11. The four second rotating frames 11 in the same longitudinal position are rotatably connected to each other by a connecting rod 13.

[0023] like Figure 1 , Figure 2 , Figure 4 and Figure 5 As shown, the energy storage component includes a motor 7, a first rotating frame 8, and a solar panel 9. The lower part of the energy storage box 1 is connected to two motors 7, one on the left and one on the right. The motors 7 and the processor are electrically connected through a control module. The output shaft of each motor 7 is connected to a first rotating frame 8, and the first rotating frame 8 is rotatably connected to the energy storage box 1. The upper part of the energy storage box 1 is rotatably connected to two solar panels 9, one on the left and one on the right. The solar panels 9 are movably connected to the first rotating frame 8 on the same side. The connecting plates 10 are rotatably connected to the solar panels 9 on the same side.

[0024] When the outdoor energy storage unit needs to adapt to the environment and regulate temperature, this device can be used. The energy storage box 1 is in contact with the ground. The energy storage box 1 has a double-layer structure. The outdoor energy storage unit is then placed inside the energy storage box 1, and the door on the energy storage box 1 is closed. When the weather is hot, the processor starts the motor 7 through the control module. The motor 7 drives the first rotating frame 8 to rotate, causing the solar panel 9 to rotate and unfold along the first rotating frame 8 and the energy storage box 1. The motor 7 is then turned off. The solar panel 9 absorbs light energy and converts it into electrical energy to power the semiconductor cooling chip 5, fan 2, motor 7, and heating plate 3. When the solar panel 9 unfolds, it causes the connecting plate 10 to move and rotate, causing the second rotating frame 11 to move and rotate, which in turn drives the opening and closing plate 1. 2. The rotating mechanism opens for ventilation and heat dissipation. Dust is intercepted by the dustproof net 6, and heat dissipation is achieved through the heat dissipation fins 4. The fan 2 is activated, and the fan 2 rotates to allow air to enter from the bottom of the energy storage box 1, flow to both sides of the energy storage box 1, flow through the heat dissipation fins 4, and then exit through the gap between the opening and closing plates 12, thus accelerating air circulation and heat dissipation. The second rotating frame 11 is L-shaped. Then, the semiconductor cooling chip 5 is activated. The semiconductor cooling chip 5 absorbs heat on the cold side and releases heat on the hot side, thereby achieving rapid cooling and heat dissipation of the outdoor energy storage unit. This allows the solar panel 9 to be rotated to unfold for energy storage while the opening and closing plates 12 are rotated to open for heat dissipation, maximizing energy collection and supply and enhancing the heat dissipation effect.

[0025] When the weather is cold or the outdoor energy storage unit is not in use, the motor 7 reverses its operation, causing the first rotating frame 8 to rotate and reset, allowing the solar panel 9 to rotate and retract. Simultaneously, the connecting plate 10 is pulled to move and rotate in the opposite direction, causing the second rotating frame 11 to move and rotate in the opposite direction, which in turn drives the opening and closing plate 12 to rotate and close, thus preventing dust. This allows the opening and closing plate 12 and the solar panel 9 to be retracted for dust prevention when the weather is cold or the device is not in use, protecting the equipment from the effects of severe weather, preventing dust accumulation, and extending its service life. Then, the semiconductor cooling chip 5 and fan 2 are turned off, and the heating plate 3 operates to heat the outdoor energy storage unit. The energy storage box 1 provides insulation, enabling the outdoor energy storage unit to adapt to the environment and adjust the temperature for use. This facilitates rapid heat dissipation and cooling, maintains stable heating, extends its service life, and improves its stability and reliability. After use, the heating plate 3 can be turned off.

[0026] The above embodiments are only for illustrating the technical concept and features of this utility model, and are intended to enable those skilled in the art to understand the content of this utility model and implement it accordingly. They should not be construed as limiting the scope of protection of this utility model. All equivalent changes or modifications made in accordance with the spirit and essence of this utility model should be included within the scope of protection of this utility model.

Claims

1. An adaptive ambient temperature regulation device for an outdoor energy storage integrated machine, characterized in that: It includes an energy storage box (1), a fan (2), heat dissipation fins (4), a temperature regulation component and an energy storage component. The fan (2) is rotatably connected to the lower part of the energy storage box (1). Heat dissipation fins (4) are connected to both the left and right sides of the energy storage box (1). A temperature regulation component for adaptively adjusting the temperature according to the environment is provided in the middle of the energy storage box (1). An energy storage component for converting light energy into electrical energy for power supply is provided on the energy storage box (1).

2. The adaptive ambient temperature regulation device for an outdoor energy storage integrated machine according to claim 1, characterized in that: The energy storage box (1) has a double-layer structure.

3. The adaptive ambient temperature regulation device for an outdoor energy storage integrated machine according to claim 1, characterized in that: It also includes a dustproof net (6), and the left and right sides of the middle part of the energy storage box (1) are connected with dustproof nets (6).

4. The adaptive ambient temperature regulation device for an outdoor energy storage integrated machine according to claim 1, characterized in that: The temperature control assembly includes a heating plate (3), a semiconductor cooling chip (5), a connecting plate (10), a second rotating frame (11), an opening and closing plate (12), and a connecting rod (13). The heating plate (3) is connected to the inner side of the upper part of the energy storage box (1). The semiconductor cooling chip (5) is connected to the inner side of both the left and right parts of the energy storage box (1). Multiple opening and closing plates (12) are rotatably connected to both the left and right sides of the energy storage box (1). The second rotating frame (11) is connected to each of the opening and closing plates (12). The connecting plate (10) is movably connected to the uppermost second rotating frame (11). The four second rotating frames (11) at the same longitudinal position are rotatably connected to each other by a connecting rod (13).

5. The adaptive ambient temperature regulation device for an outdoor energy storage integrated machine according to claim 4, characterized in that: The second rotating frame (11) is L-shaped.

6. The adaptive ambient temperature regulation device for an outdoor energy storage integrated machine according to claim 1, characterized in that: The energy storage component includes a motor (7), a first rotating frame (8), and a solar panel (9). The lower part of the energy storage box (1) is connected to two motors (7) on the left and right. The motors (7) and the processor are electrically connected through a control module. The output shaft of each motor (7) is connected to a first rotating frame (8). The first rotating frame (8) is rotatably connected to the energy storage box (1). The upper part of the energy storage box (1) is rotatably connected to two solar panels (9) on the left and right. The solar panels (9) are movably connected to the first rotating frame (8) on the same side. The connecting plate (10) is rotatably connected to the solar panel (9) on the same side.