A wall hanging structure and an energy storage inverter comprising the same

By designing a wall-mounted structure that utilizes the bends of the bracket to engage with the grooves of the energy storage inverter fins, combined with flexible plug-in components and extrusion components, the energy storage inverter can be installed quickly and stably, solving the problem of cumbersome installation in existing technologies.

CN224418762UActive Publication Date: 2026-06-26安徽大恒新能源技术有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
安徽大恒新能源技术有限公司
Filing Date
2025-08-08
Publication Date
2026-06-26

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Abstract

The utility model relates to the technical fields of energy storage inverter related, specifically is a wall -hanging structure and including the energy storage inverter of wall -hanging structure, including support, the first bending part and second bending part of symmetrical setting of support's end part are equipped with the reinforcing fin of energy storage inverter bottom radiator's both sides are equipped with, and two reinforcing fins all are equipped with two cut -in formula groove, first bending part and second bending part can respectively insert cut -in formula groove, still including the locating plate of setting on second bending part, and the locating plate is equipped with elastic plug -in spare, and the mounting hole is formed to reinforcing fin, extruding piece sets up on the locating plate, connects elastic plug -in spare, the utility model is in elastic plug -in spare and mounting hole alignment and automatic insertion after, through the control extruding piece moves to elastic plug -in spare can change its deformation, makes elastic plug -in spare can further insert mounting hole, to realize the stable connection of support and energy storage inverter.
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Description

Technical Field

[0001] This utility model relates to the technical field of energy storage inverters, specifically a wall-mounted structure and an energy storage inverter including the wall-mounted structure. Background Technology

[0002] Solar energy, as a new and renewable energy source, is favored by countries around the world for its clean, environmentally friendly, and inexhaustible characteristics. As a core component of photovoltaic power generation systems, energy storage inverters are facing increasing demand, and the labor costs of installation are becoming increasingly significant. Furthermore, customers are placing higher demands on the safety and convenience of wall-mounted inverters.

[0003] Currently, energy storage inverters generally adopt the same wall-mounted structure as photovoltaic inverters: the wall mount is fixed to the wall with expansion bolts, the energy storage inverter is then installed on the wall mount, and finally the energy storage inverter and the wall mount are locked together with screws. It is necessary to ensure that the threaded holes on the wall mount and the energy storage inverter are aligned with each other, and external tools are needed to complete the installation. This restricts the installation conditions, making the installation cumbersome and reducing the installation efficiency. Utility Model Content

[0004] The purpose of this utility model is to provide a wall-mounted structure to solve the problems mentioned in the background art.

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

[0006] A wall-mounted structure includes a bracket, the ends of which are symmetrically provided with a first bent portion and a second bent portion. The bottom heat sink of the energy storage inverter is provided with reinforcing fins on both sides, and each of the two reinforcing fins is provided with two indented grooves. The first bent portion and the second bent portion can be inserted into the indented grooves respectively.

[0007] It also includes a positioning plate disposed on the second bending portion, and the positioning plate is provided with an elastic plug-in. The reinforcing fin has a mounting hole formed on it. After alignment, the elastic plug-in can automatically align with the mounting hole and be inserted.

[0008] An extrusion member is disposed on the positioning plate, connects to the elastic connector, and is capable of extruding the elastic connector further into the mounting hole.

[0009] The wall-mounted structure described above has a socket formed on the positioning plate, and the elastic connector is disposed in the socket and can extend out of the socket.

[0010] The wall-mounted structure described above: the elastic connector includes a locking pin, one end of which is slidably disposed in the connector cavity, and the other end extends out of the connector cavity and can be inserted into the mounting hole;

[0011] It also includes a spring, which is disposed in the insertion cavity, with one end of the spring abutting against the locking pin and the other end abutting against the pressing member.

[0012] The wall-mounted structure as described above: the extrusion member includes an extrusion disc slidably disposed within the insertion cavity, one end of the extrusion disc abutting against the spring, and the movement of the extrusion disc is controlled by a pusher disposed on the positioning plate.

[0013] The wall-mounted structure as described above: at least one set of strip blocks are provided on the outer ring of the extrusion disc, and a strip groove is formed on the side wall of the insertion cavity to slide and adapt to the strip blocks.

[0014] The wall-mounted structure as described above: the pusher includes a threaded rod arranged axially along the extrusion plate and threadedly connected to the positioning plate. One end of the threaded rod is inserted into the insertion cavity and rotatably connected to the extrusion plate, and a knob is fixedly installed on the other end.

[0015] An energy storage inverter including a wall-mounted structure, comprising any one of the wall-mounted structures described above.

[0016] Compared with the prior art, the beneficial effects of this utility model are:

[0017] When installing via an energy storage inverter, after aligning the grooves on the reinforcing fins of the energy storage inverter with the first and second bends respectively, the energy storage inverter can automatically move downwards under the action of gravity, allowing the first and second bends to be inserted into the grooves and the elastic connector to be automatically inserted when aligned with the mounting hole. By controlling the extrusion member to move toward the elastic connector, its deformation can be changed, allowing the elastic connector to be further inserted into the mounting hole, thus achieving a stable connection between the elastic connector and the reinforcing fins without the need for auxiliary tools for fastening. This allows the bracket and the energy storage inverter to be installed quickly while effectively increasing the connection stability during installation.

[0018] The bracket and energy storage inverter are installed on the side, which solves the problem that the existing energy storage inverters will obstruct the operator's view during the installation process, causing inconvenience to the installation, fastening and disassembly of the energy storage inverter and maintenance of the whole unit, while improving the installation efficiency of the energy storage inverter. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the wall-mounted structure.

[0020] Figure 2 This is a schematic diagram of the energy storage inverter and its support structure in a wall-mounted configuration.

[0021] Figure 3 This is a schematic diagram of the bracket and the first and second bends in the wall-mounted structure.

[0022] Figure 4 This is a schematic diagram of the positioning plate and elastic connector in a wall-mounted structure.

[0023] Figure 5 This is a schematic diagram of the extruded parts and elastic connectors in a wall-mounted structure.

[0024] In the figure: 1. Bracket; 101. First bend; 102. Second bend; 2. Positioning plate; 201. Insertion cavity; 202. Strip groove; 3. Knob; 4. Threaded rod; 5. Extrusion plate; 501. Strip block; 6. Spring; 7. Locking pin; 701. Conical surface; 8. Reinforcing fin; 801. Cut-in groove. Detailed Implementation

[0025] Various exemplary embodiments, features, and aspects of this application will now be described in detail with reference to the accompanying drawings. The same reference numerals in the drawings denote elements that have the same or similar functions. Although various aspects of the embodiments are shown in the drawings, they are not necessarily drawn to scale unless specifically indicated otherwise.

[0026] The term “exemplary” as used herein means “serving as an example, embodiment, or illustration.” Any embodiment illustrated herein as “exemplary” is not necessarily to be construed as superior to or better than other embodiments.

[0027] Furthermore, to better illustrate this application, numerous specific details are provided in the following detailed embodiments. Those skilled in the art should understand that this application can be implemented even without certain specific details. In some instances, methods, means, and elements well-known to those skilled in the art have not been described in detail in order to highlight the main points of this application.

[0028] Please see Figures 1-5 In this embodiment of the utility model, a wall-mounted structure and an energy storage inverter including the wall-mounted structure are provided, including a bracket 1. The bracket 1 is symmetrically provided with a first bending portion 101 and a second bending portion 102 at its end. The bottom heat sink of the energy storage inverter is provided with reinforcing fins 8 on both sides, and each of the two reinforcing fins 8 is provided with two indented grooves 801. The first bending portion 101 and the second bending portion 102 can be inserted into the indented grooves 801 respectively.

[0029] It also includes a positioning plate 2 disposed on the second bending portion 102, and the positioning plate 2 is provided with an elastic plug-in. The reinforcing fin 8 is provided with a mounting hole. After alignment, the elastic plug-in can automatically align with the mounting hole and be inserted.

[0030] An extrusion member is disposed on the positioning plate 2, connects to the elastic connector, and is capable of extruding the elastic connector further into the mounting hole.

[0031] It should be noted that the back of the energy storage inverter has multiple indented grooves 801, and the first bend 101 and the second bend 102 can be inserted into the indented grooves 801 respectively.

[0032] In this embodiment, when the energy storage inverter is installed, after the groove 801 on the reinforcing fin 8 of the energy storage inverter is aligned with the first bend 101 and the second bend 102 respectively, the energy storage inverter can automatically move downward under the action of gravity, so that the first bend 101 and the second bend 102 can be inserted into the groove 801 and the elastic plug can be automatically inserted when aligned with the mounting hole. By controlling the extruder to move toward the elastic plug, its deformation can be changed, so that the elastic plug can be further inserted into the mounting hole, so as to achieve a stable connection between the elastic plug and the reinforcing fin 8 without the need for auxiliary tools for fastening. This allows the bracket 1 and the energy storage inverter to be installed quickly, while effectively increasing the connection stability of the bracket 1 and the energy storage inverter during installation.

[0033] The positioning plate 2 has a insertion cavity 201, and the elastic insertion member is disposed in the insertion cavity 201 and can extend out of the insertion cavity 201.

[0034] For further solutions to this utility model, please refer to [link / reference]. Figure 4 The elastic connector includes a locking pin 7, one end of which is slidably disposed in the insertion cavity 201, and the other end extends out of the insertion cavity 201 and can be inserted into the mounting hole;

[0035] It also includes a spring 6, which is disposed in the insertion cavity 201. One end of the spring 6 abuts against the locking pin 7, and the other end abuts against the pressing member.

[0036] It should be noted that the end of the locking pin 7 away from the insertion cavity 201 has a tapered surface 701.

[0037] In the initial state, when the first bent portion 101 and the second bent portion 102 are aligned with the cut-in groove 801, the conical surface 701 is squeezed by the reinforcing fin 8, causing the reinforcing fin 8 to give way. At this time, the spring 6 is compressed. When the energy storage inverter automatically moves down to the mounting hole and aligns with the locking pin 7, the locking pin 7 loses its compression and is inserted into the mounting hole under the elastic action of the spring 6. At this time, the connection between the locking pin 7 and the mounting hole is not stable. By changing the deformation of the spring 6, the locking pin 7 can be further inserted into the mounting hole, thus achieving the connection stability between the bracket 1 and the energy storage inverter.

[0038] For further solutions to this utility model, please refer to [link / reference]. Figure 4 and Figure 5 The extrusion member includes an extrusion disc 5 slidably disposed in the insertion cavity 201. One end of the extrusion disc 5 abuts against the spring 6, and the movement of the extrusion disc 5 is controlled by a pusher disposed on the positioning plate 2.

[0039] At least one set of strip blocks 501 are provided on the outer ring of the extrusion disc 5, and a strip groove 202 is formed on the side wall of the insertion cavity 201 to slide and adapt to the strip blocks 501.

[0040] The pusher includes a threaded rod 4 that is axially arranged along the extrusion plate 5 and threadedly connected to the positioning plate 2. One end of the threaded rod 4 is inserted into the insertion cavity 201 and rotatably connected to the extrusion plate 5, and a knob 3 is fixedly installed on the other end.

[0041] Specifically, after the locking pin 7 is initially inserted into the mounting hole, the rotation of the control knob 3 causes the threaded rod 4 to rotate synchronously. The threaded rod 4 moves along its own axis towards the insertion cavity 201, causing the pressing disc 5 to move towards the spring 6 within the insertion cavity 201. This allows the locking pin 7 to penetrate further into the mounting hole, while the deformation of the spring 6 changes. The spring 6 exerts pressure on the locking pin 7 towards the mounting hole, thus achieving a stable connection between the locking pin 7 and the reinforcing fin 8, thereby ensuring that the bracket 1 and the energy storage inverter can be installed quickly.

[0042] An energy storage inverter including the wall-mounted structure, comprising the wall-mounted structure described in any one of the above.

[0043] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0044] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A wall mounting structure comprising a bracket (1), characterized in that, The support (1) is symmetrically provided with a first bending part (101) and a second bending part (102) at its end. The bottom heat sink of the energy storage inverter is provided with reinforcing fins (8) on both sides, and each of the two reinforcing fins (8) is provided with two cutting grooves (801). The first bending part (101) and the second bending part (102) can be inserted into the cutting grooves (801) respectively. It also includes a positioning plate (2) disposed on the second bending portion (102), and the positioning plate (2) is provided with an elastic plug-in, and the reinforcing fin (8) is provided with a mounting hole. After alignment, the elastic plug-in can automatically align with the mounting hole and be inserted. An extrusion member is disposed on the positioning plate (2), connects to the elastic plug, and is capable of extruding the elastic plug further into the mounting hole.

2. A wall mounting structure according to claim 1, wherein The positioning plate (2) has a plug cavity (201) formed thereon, and the elastic plug is disposed in the plug cavity (201) and can extend out of the plug cavity (201).

3. A wall mounting structure according to claim 2, wherein The elastic connector includes a locking pin (7), one end of which is slidably disposed in the insertion cavity (201), and the other end extends out of the insertion cavity (201) and can be inserted into the mounting hole; It also includes a spring (6), which is disposed in the insertion cavity (201). One end of the spring (6) abuts against the locking pin (7), and the other end abuts against the pressing member.

4. A wall mounting structure according to claim 3, wherein The extrusion member includes an extrusion disc (5) that is slidably disposed in the insertion cavity (201), one end of the extrusion disc (5) abutting against the spring (6), and the movement of the extrusion disc (5) is controlled by a pusher disposed on the positioning plate (2).

5. A wall mounting structure according to claim 4, wherein At least one set of strip blocks (501) are provided on the outer ring of the extrusion plate (5), and a strip groove (202) is formed on the side wall of the insertion cavity (201) to slide and adapt to the strip block (501).

6. A wall mounting structure according to claim 5, wherein The pusher includes a threaded rod (4) arranged axially along the extrusion plate (5) and threadedly connected to the positioning plate (2). One end of the threaded rod (4) is inserted into the insertion cavity (201) and rotatably connected to the extrusion plate (5), and a knob (3) is fixedly installed on the other end.

7. An energy storage inverter including a wall-mounted structure, characterized in that, The wall-mounted structure includes any one of claims 1-6 above.