Indoor 5g energy storage cabinet

Abstract

This utility model discloses an indoor 5G energy storage cabinet, including a cabinet body. The cabinet body is thickened on both sides, with a positioning groove on one side of the thickened portion and a recess on the other. A positioning opening is located on the inner wall of the recess, directly opposite the positioning groove. A main board is positioned in the positioning opening, with one end of the main board inserted into the positioning groove. A side plate is located in the recess to press and position the main board. A sub-board is located on the surface of the main board, with multiple screw holes for fixing equipment. The main board has multiple connecting grooves, each containing a connecting strip. This utility model has a simple structure. The main board can enter the cabinet through the positioning opening and be inserted into the positioning groove, eliminating the need for internal disassembly and assembly. Multiple main boards can be positioned at once via the sliding side plate. The sub-board is detachably mounted on the main board, and the equipment is installed on the sub-board. The sub-board can be disassembled by lifting it, without the need for screws, greatly increasing the convenience of disassembly and assembly.

Description

Technical Field

[0001] This utility model relates to the field of cabinet technology, specifically to an indoor 5G energy storage cabinet. Background Technology

[0002] 5G energy storage cabinets are innovative devices that combine 5G communication technology with energy storage systems. They are mainly used to support the stable operation of 5G base stations, especially in situations where power supply is unstable or there is a sudden power outage.

[0003] Currently, 5G energy storage cabinets are equipped with multiple partitions to divide the cabinet into multiple chambers for installing different numbers of devices. However, the current partition structure is simple and its installation is relatively troublesome. Screws are generally used for fixing, and the installation and removal of screws must be completed inside the mechanism. Since the internal space of the cabinet is small, collisions may occur during the installation and removal process, affecting the efficiency of assembly and disassembly. Summary of the Invention

[0004] The technical problem to be solved by this utility model is to provide an indoor 5G energy storage cabinet, in which the motherboard can be installed by inserting from the outside to the inside, and the equipment is installed on the sub-board. The sub-board can be quickly removed from the motherboard, so as to solve the problems mentioned in the background art.

[0005] This utility model is achieved through the following technical solution: an indoor 5G energy storage cabinet, including a cabinet body, the two sides of the cabinet body are thickened, one side of the thickened part of the cabinet body is provided with a positioning groove, the other side is provided with a groove, the inner wall of the groove is provided with a positioning port opposite to the positioning groove, a main board is provided in the positioning port, one end of the main board is inserted into the positioning groove, and the other end is flush with the inner wall of the groove, a side plate is provided in the groove to press and position the main board, a sub-plate is provided on the surface of the main board, the sub-plate is provided with multiple screw holes for fixing the equipment, the main board is provided with multiple connecting grooves, each connecting groove is provided with a connecting strip, multiple elastic connectors are installed between the connecting strips and the sub-plate, and limit strips are installed on both sides of the main board surface along the length direction of the sub-plate.

[0006] As a preferred technical solution, the elastic connectors all include positioning pins and first compression springs. Multiple positioning holes are provided on the bottom surface of the sub-plate. One end of each positioning pin is inserted into the positioning hole and is fixedly connected to the first compression spring. The other end of each first compression spring is installed on the inner wall of the positioning hole, and the other end of each positioning pin is installed on the connecting strip.

[0007] As a preferred technical solution, one end of the groove is provided with a limiting opening, one end of the side plate extends to the outside along the limiting opening and bends to form a limiting part, the inner side of the limiting part is fitted to the outer wall of the cabinet, the inner side of the limiting opening is provided with multiple limiting grooves, and multiple limiting blocks are installed on the side plate away from the limiting opening, all of which are set opposite to the limiting opening.

[0008] As a preferred technical solution, a rectangular opening is provided on the top surface of the groove, and a limiting post is provided in the rectangular opening. One end of the limiting post is set to abut against the limiting block, and the other end extends to the outside and is equipped with a handle. A second compression spring is sleeved on the outside of the limiting post. One end of the second compression spring is installed on the cabinet and the other end is installed on the handle.

[0009] As a preferred technical solution, the inner wall of the groove is recessed on both sides of the positioning opening to form a handheld groove.

[0010] As a preferred technical solution, the height of the positioning groove and the positioning port are matched with the thickness of the motherboard, and the width of the positioning groove and the positioning port are matched with the width of the motherboard.

[0011] As a preferred technical solution, the vertical cross-sections of both the connecting strip and the connecting groove are trapezoidal.

[0012] The beneficial effects of this utility model are: the utility model has a simple structure. After the side panel is removed, the main board can enter the interior of the cabinet along the positioning port and be inserted into the positioning slot, so that the main board does not need to be disassembled inside. Moreover, multiple main boards can be positioned at one time by sliding the side panel. The sub-board is detachably installed on the main board, and the equipment is installed on the sub-board. The sub-board can be disassembled after lifting it up without the need for screws, which greatly increases the convenience of disassembly and assembly. Attached Figure Description

[0013] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0014] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0015] Figure 2 This is a side view of the present invention;

[0016] Figure 3 This is a schematic diagram of the structure of this utility model after the side plates have been removed;

[0017] Figure 4 This is a schematic diagram of the main board and sub-board of this utility model;

[0018] Figure 5 This is a schematic diagram of the structure of the motherboard of this utility model.

[0019] The components are as follows: 1. Cabinet body; 2. Main board; 3. Sub-board; 4. Connecting strip; 5. Limiting strip; 6. Groove; 7. Side panel; 8. Limiting groove; 9. Limiting post; 10. Second compression spring; 11. Handle bar; 12. Positioning groove; 13. Limiting part; 14. Limiting block; 15. Limiting opening; 16. Positioning opening; 17. Hand grip groove; 18. Positioning post. Detailed Implementation

[0020] The embodiments of this utility model are described in detail below. Examples of these embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and are only used to explain this utility model, and should not be construed as limiting this utility model.

[0021] All features disclosed in this specification, or all steps in all disclosed methods or processes, may be combined in any way, except for mutually exclusive features and / or steps.

[0022] Any feature disclosed in this specification (including any appended claims, abstract, and drawings) may be replaced by other equivalent or similar features, unless specifically stated otherwise. That is, unless specifically stated otherwise, each feature is merely one example of a series of equivalent or similar features.

[0023] like Figure 1 , Figure 2 , Figure 3 , Figure 4 and Figure 5 As shown, this utility model discloses an indoor 5G energy storage cabinet, including a cabinet body 1. The cabinet body 1 is thickened on both sides. One side of the thickened part of the cabinet body 1 is provided with a positioning groove 12, and the other side is provided with a groove 6. The inner wall of the groove 6 is provided with a positioning port 16 opposite to the positioning groove 12. A main board 2 is provided in the positioning port 16. One end of the main board 2 is inserted into the positioning groove 12, and the other end is flush with the inner wall of the groove 6. The groove 6 is provided with a side plate 7 for pressing and positioning the main board 2. A sub-plate 3 is provided on the surface of the main board 2. The sub-plate 3 is provided with multiple screw holes for fixing equipment. The main board 2 is provided with multiple connecting grooves. Each connecting groove is provided with a connecting strip 4. Multiple elastic connectors are installed between the connecting strip 4 and the sub-plate 3. Limiting strips 5 are installed on both sides of the main board 2 along the length direction of the sub-plate 3.

[0024] In this embodiment, each elastic connector includes a positioning post 18 and a first compression spring. Multiple positioning holes are provided on the bottom surface of the sub-plate 3. One end of each positioning post 18 is inserted into the positioning hole and is fixedly connected to the first compression spring. The other end of each first compression spring is installed on the inner wall of the positioning hole, and the other end of each positioning post 18 is installed on the connecting strip 4.

[0025] In this embodiment, a limiting opening 15 is provided at one end of the groove 6, and one end of the side plate 7 extends to the outside along the limiting opening 15 and bends to form a limiting part 13. The inner side of the limiting part 13 is fitted to the outer wall of the cabinet 1. Multiple limiting grooves 8 are provided on the inner side of the limiting opening 15. Multiple limiting blocks 14 are installed at the end of the side plate 7 away from the limiting opening 15. The limiting blocks 14 are all arranged opposite to the limiting opening 15.

[0026] As the side plate moves outward along the limiting opening, it simultaneously drives the limiting block until the limiting block is inserted into the limiting groove, thus preventing the side plate from detaching from the groove.

[0027] In this embodiment, a rectangular opening is provided on the top surface of the groove 6, and a limiting post 9 is provided in the rectangular opening. One end of the limiting post 9 is set to abut against the limiting block 14, and the other end extends to the outside and is equipped with a handle 11. A second compression spring 10 is sleeved on the outside of the limiting post 9. One end of the second compression spring 10 is installed on the cabinet 1, and the other end is installed on the handle 11. The side panel can be positioned by the limiting post, avoiding the side panel from moving along the limiting opening.

[0028] In this embodiment, the inner wall of the groove 6 is recessed on both sides of the positioning port 16 to form a hand grip 17. When disassembling the motherboard, fingers can enter the hand grip and grasp the motherboard, making it easy to pull the motherboard outward and remove it outward along the positioning port to complete the disassembly.

[0029] In this embodiment, the height of the positioning groove 12 and the positioning port 16 are matched with the thickness of the motherboard 2, and the width of the positioning groove 12 and the positioning port 16 are matched with the width of the motherboard 2, so as to ensure the stability of the motherboard after insertion and avoid the situation of swinging.

[0030] In this embodiment, both the connecting strip 4 and the connecting groove have trapezoidal cross-sections, which allows the connecting strip to move back and forth along the connecting groove, thus preventing the connecting strip from detaching directly from the connecting groove.

[0031] During installation, first pull the limiting post upwards using the handle. After the limiting post moves away from the outside of the limiting block, the side panel can move outwards along the limiting opening until the limiting block is inserted into the limiting slot. At this time, the positioning opening is open, and the main board can enter the cabinet through the positioning opening until it is inserted into the positioning slot. After the side panel returns to its original position, multiple main boards can be positioned at once. The rebound of the second compression spring can drive the handle and the limiting post until the limiting post moves to the outside of the limiting block, thereby positioning the side panel.

[0032] Next, insert the connecting strip into the connecting groove and lift the sub-plate along the positioning post so that the sub-plate is higher than the limit strip. After the sub-plate moves between the limit strips, slowly lower the sub-plate. The rebound energy of the first compression spring will cause the sub-plate to descend until the sub-plate moves between the limit strips. The limit strip can position the sub-plate front and back, while the positioning post can position the sub-plate left and right. The equipment is installed on the sub-plate.

[0033] Therefore, during disassembly, the sub-plate can be lifted directly. Once the sub-plate is above the limit bar, it can be taken out directly along the connecting groove. After pushing the side plate again, the main plate can be taken out directly along the positioning port without the need for screws, which greatly facilitates disassembly and assembly.

[0034] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any changes or substitutions conceived without inventive effort should be included within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the scope defined in the claims.

Claims

1. An indoor 5G energy storage cabinet, characterized in that: The cabinet (1) is thickened on both sides. A positioning groove (12) is provided on one side of the thickened part of the cabinet (1), and a groove (6) is provided on the other side. A positioning port (16) is provided on the inner wall of the groove (6) opposite to the positioning groove (12). A main board (2) is provided in the positioning port (16). One end of the main board (2) is inserted into the positioning groove (12), and the other end is flush with the inner wall of the groove (6). A side plate (7) is provided in the groove (6) to press and position the main board (2). A sub-plate (3) is provided on the surface of the main board (2). A number of screw holes for fixing the equipment are provided on the sub-plate (3). A number of connecting grooves are provided on the main board (2). A connecting strip (4) is provided in each connecting groove. A number of elastic connectors are installed between the connecting strip (4) and the sub-plate (3). Limiting strips (5) are installed on both sides of the surface of the main board (2) in the length direction of the sub-plate (3).

2. The indoor 5G energy storage cabinet according to claim 1, characterized in that: Each elastic connector includes a positioning post (18) and a first compression spring. Multiple positioning holes are provided on the bottom surface of the sub-plate (3). One end of each positioning post (18) is inserted into the positioning hole and is fixedly connected to the first compression spring. The other end of each first compression spring is installed on the inner wall of the positioning hole. The other end of each positioning post (18) is installed on the connecting strip (4).

3. The indoor 5G energy storage cabinet according to claim 1, characterized in that: One end of the groove (6) is provided with a limiting port (15). One end of the side plate (7) extends outward along the limiting port (15) and bends to form a limiting part (13). The inner side of the limiting part (13) is fitted to the outer wall of the cabinet (1). The inner side of the limiting port (15) is provided with multiple limiting grooves (8). Multiple limiting blocks (14) are installed on the side plate (7) away from the limiting port (15). The limiting blocks (14) are all set opposite to the limiting port (15).

4. The indoor 5G energy storage cabinet according to claim 1, characterized in that: A rectangular opening is provided on the top surface of the groove (6), and a limiting post (9) is provided in the rectangular opening. One end of the limiting post (9) is in contact with the limiting block (14), and the other end extends to the outside and is equipped with a handle (11). A second compression spring (10) is sleeved on the outside of the limiting post (9). One end of the second compression spring (10) is installed on the cabinet (1), and the other end is installed on the handle (11).

5. The indoor 5G energy storage cabinet according to claim 1, characterized in that: The inner wall of the groove (6) is recessed on both sides of the positioning port (16) to form a hand grip groove (17).

6. The indoor 5G energy storage cabinet according to claim 1, characterized in that: The height of the positioning groove (12) and the positioning port (16) are matched with the thickness of the motherboard (2), and the width of the positioning groove (12) and the positioning port (16) are matched with the width of the motherboard (2).

7. The indoor 5G energy storage cabinet according to claim 1, characterized in that: The vertical cross-sections of the connecting strip (4) and the connecting groove are both set in a trapezoidal structure.

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