An installation spacing adjustment structure and a corresponding energy storage coordination control chassis

By introducing an adjustable mounting mechanism into the energy storage coordination control chassis, the problem of non-adjustable circuit board mounting spacing is solved, enabling flexible adjustment of circuit board spacing and improving the chassis's usability and adaptability.

CN224439432UActive Publication Date: 2026-06-30SHENZHEN JIAERXING TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN JIAERXING TECH CO LTD
Filing Date
2025-08-12
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

The existing energy storage coordination and control chassis circuit board mounting spacing is fixed and cannot be adjusted, resulting in reduced usage flexibility and an inability to adapt to the circuit board size requirements of different users.

Method used

An installation spacing adjustment structure including an adjustable mounting mechanism was designed. The spacing between circuit boards can be flexibly adjusted by the cooperation of locking screws and threaded holes. The combination of guide rail rods and sliders can achieve precise positioning and stable clamping of circuit boards.

Benefits of technology

It enables flexible adjustment of the circuit board mounting spacing, improves the usability of the energy storage coordination control chassis, can adapt to circuit boards and electronic components of different thicknesses and specifications, and enhances the chassis's adaptability and stability.

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Abstract

This utility model discloses an adjustable installation spacing structure and a corresponding energy storage coordination control chassis. The mounting frame of the adjustable installation spacing structure is fixedly connected to an adjustable installation mechanism. Guide rails are provided on the vertical sidewalls of the mounting frame, and multiple adjustable frames are slidably connected between two guide rails. Each adjustable frame includes a first frame and a second frame. A first limiting plate is fixedly connected to the first frame, and a second limiting plate is fixedly connected to the second frame. Two U-shaped guide plates are symmetrically fixedly connected to the first frame. This allows for rapid adjustment of the installation spacing between circuit boards according to the user's actual installation size requirements. This enables the two adjustable frames to clamp circuit boards of different thicknesses, and allows for adjustment of the space between the two circuit boards. This space can accommodate power supplies or other electronic components of different sizes on the circuit boards, effectively improving the flexibility of the energy storage coordination control chassis.
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Description

Technical Field

[0001] This utility model relates to the field of energy storage enclosure technology, specifically to an installation spacing adjustment structure and a corresponding energy storage coordination control enclosure. Background Technology

[0002] An energy storage coordination control chassis is a device that can store electrical energy. The energy storage coordination control chassis stores electrical energy through an energy storage power supply installed on an internal circuit board. When needed, the stored electrical energy can be released through the energy storage power supply, thereby realizing the storage and utilization of electrical energy.

[0003] When installing circuit boards in existing energy storage coordination control enclosures, the dimensions of components on the circuit boards vary due to the different energy storage power requirements of different users. Consequently, the required installation spacing between adjacent circuit boards also differs. However, the installation spacing of the circuit boards in existing energy storage coordination control enclosures is fixed and cannot be adjusted, which reduces the flexibility of using the energy storage coordination control enclosure. Utility Model Content

[0004] The purpose of this invention is to provide an installation spacing adjustment structure and a corresponding energy storage coordination control chassis to solve the problems mentioned in the background art.

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

[0006] This utility model provides an installation spacing adjustment structure, including an energy storage chassis, wherein two mounting brackets are symmetrically fixedly connected to the vertical inner wall of the energy storage chassis, and an adjustable installation mechanism is fixedly connected to each of the two mounting brackets;

[0007] The adjustable mounting mechanism includes two guide rails symmetrically fixedly connected to the vertical sidewall of the mounting frame. Multiple adjustable frames are slidably connected between the two guide rails. Multiple sliders are fixedly connected to each adjustable frame, and the sliders are movably sleeved outside the guide rails. Each adjustable frame includes a first frame and a second frame. A first limiting plate is fixedly connected to the first frame, and a second limiting plate is fixedly connected to the second frame. Two U-shaped guide plates are symmetrically fixedly connected to the first frame, and two insert plates are symmetrically fixedly connected to the second frame. The two insert plates are movably inserted between the two U-shaped guide plates, and the insert plates are slidably connected to the U-shaped guide plates. Corresponding threaded holes are opened on the first limiting plate and the U-shaped guide plates, and locking screws are threaded into the threaded holes.

[0008] Furthermore, the insert plate is evenly provided with scale grooves, the U-shaped guide plate is fixedly connected with an mounting plate, and the mounting plate is fixedly connected with a triangular indicator block corresponding to the scale groove.

[0009] Furthermore, a limiting slide bar is fixedly connected to the insert plate, and a limiting slide groove corresponding to the limiting slide bar is provided on the U-shaped guide plate, and the limiting slide bar is slidably connected in the limiting slide groove.

[0010] Furthermore, the slider includes a connector fixedly connected to the adjustable frame, and a sliding block is fixedly connected to one end of the connector near the guide rail rod. The sliding block has a sliding hole, the guide rail rod passes through the sliding hole through the sliding block, and the sliding block is connected to the guide rail rod by bolts.

[0011] Furthermore, two reinforcing blocks are symmetrically fixedly connected to the second frame, and the reinforcing blocks are fixedly connected to the insert plate.

[0012] Furthermore, both ends of the guide rail are fixedly connected to connecting blocks, the connecting blocks are fixedly connected to the mounting bracket, and a gap is provided between the guide rail and the mounting bracket.

[0013] Furthermore, the mounting bracket has multiple perforated holes, which are evenly distributed on the mounting bracket.

[0014] This utility model also includes an energy storage coordination control chassis, which includes the above-mentioned installation spacing adjustment structure. A control panel is fixedly connected to the upper side of the energy storage chassis. An electrical interface is installed on the control panel. Two L-shaped plates are symmetrically fixedly connected to the vertical side wall of the energy storage chassis. Multiple mounting holes are opened on the L-shaped plates.

[0015] Compared with the prior art, the beneficial effects of this utility model are:

[0016] This utility model, through its adjustable mounting mechanism, allows for adjustments to the mounting spacing of the circuit board. By tightening the locking screw, the screw is moved away from the insert plate via the threaded engagement with the threaded hole, releasing the locking screw's constraint on the insert plate. This allows the insert plate to slide freely within the U-shaped guide plate. Pressing or pulling the first and second frames adjusts the distance between them, thus allowing for adjustment of the adjustable frame's size. Furthermore, adjusting the slider position adjusts the overall position of the adjustable frame, enabling flexible adjustment of the distance between adjacent adjustable frames.

[0017] Since the circuit board is installed in the gap between two adjustable frames, the installation spacing of the circuit board can be flexibly adjusted by adjusting the adjustable frames. The installation spacing between the circuit boards can be quickly adjusted according to the user's actual needs, so that circuit boards of different thicknesses can be clamped between the two adjustable frames. At the same time, the space between the two circuit boards can be adjusted to accommodate power supplies or other electronic components of different sizes on the circuit boards, effectively improving the flexibility of the energy storage coordination control chassis. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0019] Figure 2 This is a top view of the present invention;

[0020] Figure 3 for Figure 2 Sectional view along the middle AA direction;

[0021] Figure 4 for Figure 3 A partial structural diagram of the adjustable frame;

[0022] Figure 5 for Figure 4 A structural diagram of section B;

[0023] Figure 6 for Figure 4 A structural diagram of section C;

[0024] Figure 7 This is a schematic diagram of the structure when the circuit board is set between the adjustable frames.

[0025] In the diagram: 1. Energy storage chassis; 2. Mounting bracket; 3. Guide rail; 4. Slider; 5. First frame; 6. Second frame; 7. First limiting plate; 8. Second limiting plate; 9. U-shaped guide plate; 10. Insert plate; 11. Threaded hole; 12. Locking screw; 13. Scale groove; 14. Mounting plate; 15. Triangular indicator block; 16. Limiting slide bar; 17. Limiting slide groove; 18. Connector; 19. Sliding block; 20. Sliding hole; 21. Reinforcing block; 22. Connecting block; 23. Hole; 24. Control panel; 25. Electrical interface; 26. L-shaped plate; 27. Mounting hole; 28. Bolt; 29. ​​Circuit board; 30. Adjustable frame. Detailed Implementation

[0026] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0027] Please see Figure 1-4 as well as Figure 7 This utility model provides an installation spacing adjustment structure, including an energy storage box 1. Two mounting brackets 2 are symmetrically fixedly connected to the vertical inner wall of the energy storage box 1, and an adjustable installation mechanism is fixedly connected to each of the two mounting brackets 2.

[0028] The adjustable mounting mechanism includes two guide rails 3 symmetrically fixed to the vertical sidewall of the mounting frame 2. Multiple adjustable frames 30 are slidably connected between the two guide rails 3, and both ends of the circuit board 29 are clamped between the two adjustable frames 30. Electrical connections can be made between different circuit boards 29 or between electronic components on different circuit boards using wires with plug-in terminals. The wires can be pre-lengthened to accommodate variations in the spacing between the circuit boards 29.

[0029] Multiple sliders 4 are fixedly connected to the adjusting frame. The sliders 4 are movably sleeved outside the guide rail rod 3. The adjustable frame 30 includes a first frame 5 and a second frame 6. A first limiting plate 7 is fixedly connected to the first frame 5, and a second limiting plate 8 is fixedly connected to the second frame 6. Two U-shaped guide plates 9 are symmetrically fixedly connected to the first frame 5, and two insert plates 10 are symmetrically fixedly connected to the second frame 6. The two insert plates 10 are movably inserted between the two U-shaped guide plates 9, and the insert plates 10 are slidably connected to the U-shaped guide plates 9. Corresponding threaded holes 11 are opened on the first limiting plate 7 and the U-shaped guide plates 9, and locking screws 12 are threaded into the threaded holes 11.

[0030] In the above embodiment, when it is necessary to adjust the mounting spacing of the circuit board 29, the locking screw 12 is turned. Through the threaded engagement between the locking screw 12 and the threaded hole 11, the locking screw 12 is moved away from the insert plate 10, releasing the locking screw 12 from limiting and fixing the insert plate 10. This allows the insert plate 10 to slide freely within the U-shaped guide plate 9. By pressing or pulling the first frame 5 and the second frame 6, the spacing between the first frame 5 and the second frame 6 can be adjusted, thereby adjusting the size of the adjustable frame 30. Furthermore, by adjusting the position of the slider 4, the overall position of the adjustable frame 30 can be adjusted, thus flexibly adjusting the spacing between two adjacent adjustable frames 30. Since the circuit board 29 is installed in the gap between the two adjustable frames 30, adjusting the adjustable frames 30 can flexibly adjust the mounting spacing of the circuit board 29. The mounting spacing between the circuit boards 29 can be quickly adjusted according to the user's actual usage needs, effectively improving the flexibility of the energy storage coordination control chassis.

[0031] Please refer to Figure 5 and Figure 6 The insert plate 10 is evenly provided with scale grooves 13, and the U-shaped guide plate 9 is fixedly connected with a mounting plate 14. The mounting plate 14 is fixedly connected with a triangular indicator block 15 corresponding to the scale groove 13. By cooperating with the scale groove 13, the adjustment accuracy of the adjustable frame 30 can be improved.

[0032] A limiting slide bar 16 is fixedly connected to the insert plate 10. A limiting groove 17 corresponding to the limiting slide bar 16 is provided on the U-shaped guide plate 9. The limiting slide bar 16 is slidably connected in the limiting groove 17. The cooperation between the limiting slide bar 16 and the limiting groove 17 can improve the stability of the insert plate 10 moving in the U-shaped guide plate 9 and improve the structural stability of the adjustable frame 30.

[0033] The slider 4 includes a connector 18 fixedly connected to the adjustable frame 30. A sliding block 19 is fixedly connected to one end of the connector 18 near the guide rail rod 3. A sliding hole 20 is provided on the sliding block 19. The guide rail rod 3 passes through the sliding hole 20 and the sliding block 19 is connected to the guide rail rod 3 by a bolt 28. The slider 4 can be locked and unlocked by adjusting the bolt 28.

[0034] Two reinforcing blocks 21 are symmetrically fixedly connected to the second frame 6. The reinforcing blocks 21 are fixedly connected to the insert plate 10. The reinforcing blocks 21 can improve the stability of the connection between the insert plate 10 and the second frame 6, and improve the structural stability of the mechanism.

[0035] Please refer to Figure 3 and Figure 5Both ends of the guide rail rod 3 are fixedly connected to connecting blocks 22. The connecting blocks 22 are fixedly connected to the mounting bracket 2. There is a gap between the guide rail rod 3 and the mounting bracket 2. The connecting blocks 22 can make the gap between the guide rail rod 3 and the mounting bracket 2, thereby improving the smoothness of the sliding of the slider 4.

[0036] The mounting bracket 2 has multiple perforated holes 23, which are evenly distributed on the mounting bracket 2. The perforated holes 23 can improve the airflow around the mounting bracket 2, thereby improving the heat dissipation efficiency of the circuit board.

[0037] Please refer to Figure 1 This embodiment also includes an energy storage coordination control chassis, which includes the above-mentioned installation spacing adjustment structure. A control panel 24 is fixedly connected to the upper side of the energy storage chassis 1. An electrical interface 25 is installed on the control panel 24. Two L-shaped plates 26 are symmetrically fixedly connected to the vertical side wall of the energy storage chassis 1. Multiple mounting holes 27 are provided on the L-shaped plates 26. The control panel 24 can control the energy storage coordination control chassis. The L-shaped plates 26 and mounting holes 27 can improve the convenience of installing the energy storage coordination control chassis.

[0038] Working principle: When the mounting spacing of the circuit board 29 needs to be adjusted, tighten the locking screw 12. Through the threaded engagement between the locking screw 12 and the threaded hole 11, the locking screw 12 is moved away from the insert plate 10, releasing the locking screw 12 from limiting and fixing the insert plate 10. This allows the insert plate 10 to slide freely within the U-shaped guide plate 9. By pressing or pulling the first frame 5 and the second frame 6, the spacing between the first frame 5 and the second frame 6 can be adjusted, thereby adjusting the size of the adjustable frame 30. Furthermore, by adjusting the position of the slider 4, the overall position of the adjustable frame 30 can be adjusted, so that the spacing between two adjacent adjustable frames 30 can be flexibly adjusted.

[0039] Since the circuit board 29 is installed in the gap between the two adjustable frames 30, the installation spacing of the circuit board 29 can be flexibly adjusted by adjusting the adjustable frames 30. The installation spacing between the circuit boards can be quickly adjusted according to the user's actual needs, so that circuit boards of different thicknesses can be clamped between the two adjustable frames. At the same time, the space between the two circuit boards can be adjusted to accommodate power supplies or other electronic components of different sizes on the circuit boards, effectively improving the flexibility of the energy storage coordination control chassis.

[0040] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0041] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. An installation pitch adjustment structure comprising an energy storage case (1), characterized by: The energy storage unit (1) has two mounting brackets (2) symmetrically fixedly connected to its vertical inner wall, and each of the two mounting brackets (2) is fixedly connected to an adjustable mounting mechanism; The adjustable mounting mechanism includes two guide rails (3) symmetrically fixedly connected to the vertical sidewall of the mounting frame (2). Multiple adjustable frames (30) are slidably connected between the two guide rails (3). Multiple sliders (4) are fixedly connected to each adjustable frame. The sliders (4) are movably sleeved outside the guide rails (3). Each adjustable frame (30) includes a first frame (5) and a second frame (6). A first limiting plate (7) is fixedly connected to the first frame (5), and a... The second limiting plate (8) has two U-shaped guide plates (9) symmetrically fixedly connected to the first frame (5) and two insert plates (10) symmetrically fixedly connected to the second frame (6). The two insert plates (10) are respectively movably inserted between the two U-shaped guide plates (9). The insert plates (10) are slidably connected to the U-shaped guide plates (9). The first limiting plate (7) and the U-shaped guide plates (9) are provided with corresponding threaded holes (11). The threaded holes (11) are threaded with locking screws (12).

2. The mounting pitch adjusting structure according to claim 1, characterized by: The insert plate (10) is uniformly provided with scale grooves (13), and the U-shaped guide plate (9) is fixedly connected with an mounting plate (14). The mounting plate (14) is fixedly connected with a triangular indicator block (15) corresponding to the scale groove (13).

3. The mounting pitch adjusting structure according to claim 2, characterized by: A limiting slide bar (16) is fixedly connected to the insert plate (10), and a limiting groove (17) corresponding to the limiting slide bar (16) is provided on the U-shaped guide plate (9). The limiting slide bar (16) is slidably connected in the limiting groove (17).

4. The mounting pitch adjusting structure according to claim 1, characterized by: The slider (4) includes a connector (18) fixedly connected to the adjustable frame (30). A sliding block (19) is fixedly connected to one end of the connector (18) near the guide rail rod (3). A sliding hole (20) is provided on the sliding block (19). The guide rail rod (3) passes through the sliding block (19) through the sliding hole (20). The sliding block (19) is connected to the guide rail rod (3) by bolts (28).

5. The mounting pitch adjusting structure according to claim 1, characterized by: Two reinforcing blocks (21) are symmetrically fixedly connected to the second frame (6), and the reinforcing blocks (21) are fixedly connected to the insert plate (10).

6. The mounting pitch adjusting structure according to claim 1, characterized by: Both ends of the guide rail rod (3) are fixedly connected to connecting blocks (22), the connecting blocks (22) are fixedly connected to the mounting frame (2), and a gap is provided between the guide rail rod (3) and the mounting frame (2).

7. The mounting pitch adjusting structure according to claim 6, characterized by: The mounting bracket (2) has multiple perforated holes (23), which are evenly distributed on the mounting bracket (2).

8. An energy storage coordinating control cabinet, characterized in that: Including the installation spacing adjustment structure described in any of claims 1-7, the upper side of the energy storage chassis (1) is fixedly connected to a control panel (24), the control panel (24) is equipped with an electrical interface (25), and the vertical sidewall of the energy storage chassis (1) is symmetrically fixedly connected to two L-shaped plates (26), the L-shaped plates (26) are provided with multiple mounting holes (27).