CN223157466U - A radiator structure for energy storage equipment that is easy to maintain - Google Patents

Abstract

The utility model relates to the technical field of heat dissipation of energy storage equipment, and in particular to a radiator structure for energy storage equipment that is easy to maintain. It includes a mounting plate, a box body, a box door, a mounting frame, a placement frame, and a guide plate, etc.; the top of the mounting plate is fixedly connected to the box body, and the front and rear sides and the upper and lower sides of the box body are all open, the front side of the box body is hingedly connected to the box door, the top of the box body is fixedly connected to the mounting frame, the inside of the box body is fixedly connected to a placement frame for placing energy storage equipment, and the left and right sides of the box body are fixedly connected to guide plates. The utility model can slide the heat dissipation component on the movable frame backward by arranging a movable frame, a guide plate, and a slider, etc., so that the heat dissipation component is separated from the box body, thereby facilitating the maintenance of the heat dissipation component, and air holes are opened on the placement frame, and a pad rod is provided on the top of the placement frame, which can increase the distance between the energy storage device and the placement frame, and facilitate the removal and maintenance of the energy storage device.

Description

A radiator structure for energy storage equipment that is easy to maintain

Technical Field

The utility model relates to the technical field of heat dissipation of energy storage equipment, in particular to a radiator structure for energy storage equipment which is easy to maintain.

Background Art

The heat sink in the energy storage device is mainly used to manage the operating temperature of the device and prevent overheating from affecting performance and life. It transfers the heat generated by the energy storage device from the high temperature area to the low temperature area through physical contact, ensuring uniform temperature distribution and avoiding local overheating. Effective heat dissipation helps keep the energy storage device within the optimal operating temperature range and improves energy conversion efficiency. In addition, the heat sink can also reduce safety risks caused by overheating. Depending on the design and use environment, the cooling methods used by the radiator include air cooling and liquid cooling.

The radiator in the existing energy storage device is usually tightly integrated inside the energy storage system, and is closely combined with the energy storage device and other components, so the radiator in the energy storage device is not convenient to maintain. Although this design helps to improve the heat dissipation efficiency and the compactness of the system, it also makes the radiator difficult to easily disassemble and replace. This increases the complexity and cost of maintenance, because maintaining or replacing the radiator may require disassembling the entire energy storage system.

Utility Model Content

In order to overcome the shortcoming that the radiator in the existing energy storage device is inconvenient to maintain due to its integrated design, the purpose of the utility model is to provide a radiator structure for energy storage device that is easy to maintain.

A radiator structure for energy storage equipment that is easy to maintain, comprises a mounting plate, a box body, a box door, a mounting frame, a placement frame, a movable frame, a guide plate, a slider, a screw and a heat dissipation component, wherein the top of the mounting plate is fixedly connected to the box body, the front and rear sides and the upper and lower sides of the box body are all open, the box door is hingedly connected to the front side of the box body, the mounting frame is fixedly connected to the top of the box body, the placement frame for placing energy storage equipment is fixedly connected to the inside of the box body, the left and right sides of the box body are fixedly connected to the guide plates, the rear side of the box body is slidably connected to the movable frame, the rear side of the movable frame is installed with a heat dissipation component, the left and right sides of the movable frame are fixedly connected to the sliders, the sliders are slidably connected to the box body through the guide plates, the guide plates are threadedly connected to the screws, and the screws are in contact with the sliders.

Optionally, the box is made of hollow material, the hollow parts on the left and right sides of the box are connected to each other, heat dissipation holes are opened on the left and right sides of the box and the front side of the movable frame, the heat dissipation holes are connected to the hollow parts of the box, and the heat dissipation assembly is connected to the heat dissipation holes on the movable frame.

Optionally, ventilation holes are provided at the bottom of the placement frame.

Optionally, a pad rod is also included, and at least one pad rod is fixedly connected to the top of the placement frame.

Optionally, a rain shield and a fan are also included. The top of the installation frame is fixedly connected with the rain shield, and exhaust holes are opened on both sides of the rain shield. The fan is installed on the installation frame and is connected to the inside of the box.

Optionally, the middle portion of the rain shield is higher than the left and right sides thereof, and the left and right sides of the rain shield both exceed the installation frame.

The beneficial effects of the utility model are as follows: the utility model can slide the heat dissipation component on the movable frame backward by arranging the movable frame, the guide plate and the slider, so that the heat dissipation component is separated from the box body, thereby facilitating the maintenance of the heat dissipation component, and air holes are opened on the placement frame, and a pad is provided on the top of the placement frame, which can increase the distance between the energy storage device and the placement frame, and facilitate the removal and maintenance of the energy storage device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the three-dimensional structure of the utility model.

FIG. 2 is a schematic cross-sectional view of the installation frame and guide plate of the present invention.

FIG3 is a sectional view of the three-dimensional structure of the practical guide plate, slider, movable frame and other components.

FIG. 4 is a schematic diagram of the three-dimensional structure of the components such as the placement frame and the pad rod of the utility model.

Figure 5 is a sectional view of the three-dimensional structure of the heat sink, electric drive fan and mounting base of the utility model. The symbols in the figure are: 1-mounting plate, 2-box, 21-heat dissipation hole, 3-box door, 4-mounting frame, 5-rain shield, 51-exhaust hole, 6-fan, 7-placement frame, 71-air vent, 8-pad, 9-movable frame, 10-guide plate, 11-slider, 12-screw, 13-heat dissipation component.

DETAILED DESCRIPTION

The present invention will be further described below in conjunction with specific embodiments. The illustrative embodiments and descriptions of the present invention are used to explain the present invention but are not intended to limit the present invention.

A radiator structure for energy storage equipment that is easy to maintain, as shown in Figures 1 to 5, includes a mounting plate 1, a box body 2, a box door 3, a mounting frame 4, a placement frame 7, a movable frame 9, a guide plate 10, a slider 11, a screw 12 and a heat dissipation component 13. The top of the mounting plate 1 is fixedly connected to the box body 2, and the front and rear sides and the upper and lower sides of the box body 2 are all open. The front side of the box body 2 is hingedly connected to the box door 3, and the front side of the box door 3 is installed with a handle, which can facilitate the opening and closing of the box door 3. The top of the box body 2 is fixedly connected to the mounting frame 4, and the box body 2 A placement frame 7 for placing energy storage equipment is fixedly connected inside, guide plates 10 are fixedly connected to the left and right sides of the box body 2, a movable frame 9 is slidably connected to the rear side of the box body 2, and a heat dissipation component 13 is installed on the rear side of the movable frame 9 to prevent the energy storage equipment from overheating. Two sliders 11 are fixedly connected to the left and right sides of the movable frame 9, and the two sliders 11 are symmetrically arranged up and down. The sliders 11 are slidably connected to the box body 2 through the guide plates 10, and the guide plates 10 are threadedly connected with screws 12 for locking the sliders 11, and the screws 12 are in contact with the sliders 11.

During use, the screw 12 squeezes the slider 11. When the heat dissipation component 13 of the energy storage device needs to be maintained, the screw 12 is loosened and the movable frame 9 is moved backward to slide along the guide plate 10, thereby separating the heat dissipation component 13 from the box body 2, which is convenient for maintenance of the heat dissipation component 13. After the maintenance is completed, the movable frame 9 is moved forward to slide in the opposite direction along the guide plate 10, and then the screw 12 is tightened to squeeze the slider 11, thereby fixing the movable frame 9, thereby facilitating the maintenance of the heat dissipation component 13.

As shown in Fig. 2, Fig. 3 and Fig. 5, the box body 2 is made of hollow material, the hollow parts on the left and right sides of the box body 2 are connected to each other, the left and right sides of the box body 2 and the front side of the movable frame 9 are provided with heat dissipation holes 21, the heat dissipation holes 21 are connected to the hollow parts of the box body 2, and the heat dissipation component 13 is connected to the heat dissipation holes 21 on the movable frame 9. When the radiator structure dissipates heat, the cold air is blown from the hollow part of the box body 2 to the heat dissipation holes 21 through the heat dissipation component 13, and then blown into the inside of the box body 2 from the heat dissipation holes 21, thereby reducing the internal temperature of the box body 2, thereby ensuring the heat dissipation efficiency of the radiator structure.

As shown in FIGS. 2 to 4 , two ventilation holes 71 are provided at the bottom of the placement frame 7, and the energy storage device can be lifted and taken out through the heat dissipation holes 21, so that the energy storage device can be taken out for maintenance. When the energy storage device on the placement frame 7 is cooled, the ventilation holes 71 can cool the bottom of the energy storage device, thereby further improving the heat dissipation efficiency of the heat dissipation structure.

As shown in Figures 2 to 4, it also includes pads 8. Six pads 8 for raising the energy storage device are fixedly connected to the top of the placement frame 7. The pads 8 are made of rubber. The pads 8 can increase the space between the energy storage device and the placement frame 7, allowing air to circulate at the bottom of the energy storage device, further improving the heat dissipation efficiency of the heat dissipation structure, and can grab the front side of the energy storage device to take it out of the placement frame 7 for maintenance, further facilitating the removal of the energy storage device for maintenance.

As shown in Figures 1 and 2, a rain shield 5 and a fan 6 are also included. The top of the mounting frame 4 is fixedly connected with a rain shield 5 for protecting against rain. Twelve exhaust holes 51 are provided on both sides of the rain shield 5. The mounting frame 4 is provided with a fan 6, which is connected to the inside of the box 2 and has a heat conducting sheet installed on the fan 6. While the heat dissipation assembly 13 is dissipating heat from the energy storage device, the fan 6 is used to absorb the hot air in the box 2, and then the absorbed hot air is discharged from the exhaust holes 51, thereby further improving the heat dissipation efficiency of the radiator structure.

As shown in Fig. 1 and Fig. 2, the rain shield 5 is arranged in a herringbone shape, the middle part of the rain shield 5 is higher than the left and right sides thereof, and the left and right sides of the rain shield 5 are both higher than the mounting frame 4. When it rains, rainwater can fall from the top of the rain shield 5 to the left and right sides, which can prevent rainwater from entering the exhaust hole 51 and causing water ingress and damage to the fan 6, and prevent rainwater from entering the box body 2 from the fan 6 and causing water ingress to the energy storage device.

Although the present disclosure has been shown and described with reference to specific exemplary embodiments of the present disclosure, it should be understood by those skilled in the art that various changes in form and details may be made to the present disclosure without departing from the spirit and scope of the present disclosure as defined by the appended claims and their equivalents. Therefore, the scope of the present disclosure should not be limited to the above-mentioned embodiments, but should be determined not only by the appended claims, but also by the equivalents of the appended claims.

Claims (6)

1. A heat sink structure for energy storage equipment that is easy to maintain, comprising a mounting plate (1), a box body (2) and a box door (3), wherein the top of the mounting plate (1) is fixedly connected to the box body (2), the front and rear sides and the upper and lower sides of the box body (2) are open, and the front side of the box body (2) is hingedly connected to the box door (3), wherein the structure further comprises a mounting frame (4), a placement frame (7), a movable frame (9), a guide plate (10), a slider (11), a screw (12) and a heat dissipation component (13), wherein the top of the box body (2) is fixedly connected to the mounting frame (4 ), a placement frame (7) for placing an energy storage device is fixedly connected inside the box body (2), guide plates (10) are fixedly connected to the left and right sides of the box body (2), a movable frame (9) is slidably connected to the rear side of the box body (2), a heat dissipation component (13) is installed on the rear side of the movable frame (9), and sliders (11) are fixedly connected to the left and right sides of the movable frame (9), the sliders (11) are slidably connected to the box body (2) through the guide plates (10), and screw rods (12) are threadedly connected to the guide plates (10), and the screw rods (12) are in contact with the sliders (11). 2. According to claim 1, a radiator structure for energy storage equipment that is easy to maintain is characterized in that: the box body (2) is made of hollow material, the hollow parts on the left and right sides of the box body (2) are connected to each other, the left and right sides inside the box body (2) and the front side of the movable frame (9) are provided with heat dissipation holes (21), the heat dissipation holes (21) are connected to the hollow parts of the box body (2), and the heat dissipation component (13) is connected to the heat dissipation holes (21) on the movable frame (9). 3. A heat sink structure for energy storage equipment that is easy to maintain according to claim 2, characterized in that: ventilation holes (71) are opened at the bottom of the placement frame (7). 4. A radiator structure for energy storage equipment that is easy to maintain according to claim 3, characterized in that it also includes a pad rod (8), and at least one pad rod (8) is fixedly connected to the top of the placement frame (7). 5. A radiator structure for energy storage equipment that is easy to maintain according to claim 4, characterized in that it also includes a rain shield (5) and a fan (6), the top of the mounting frame (4) is fixedly connected to the rain shield (5), exhaust holes (51) are opened on both sides of the rain shield (5), the mounting frame (4) is installed with a fan (6), and the fan (6) is connected to the inside of the box body (2). 6. A radiator structure for energy storage equipment that is easy to maintain according to claim 5, characterized in that the middle of the rain shield (5) is higher than its left and right sides, and both the left and right sides of the rain shield (5) exceed the installation frame (4).