A weak current wiring rack structure capable of hierarchical zoning management

Abstract

The utility model relates to the field of weak current wiring frame, concretely relates to a weak current wiring frame structure of layered and zoned management, including wiring frame main part for weak current wiring, first placing plate, even install in wiring frame main part inside both sides. The utility model relates to a weak current wiring frame structure of layered and zoned management, through the setting of wiring frame main part, first placing plate, baffle, moving plate, first pressboard, connecting plate, second placing plate, second pressboard and label frame, through placing weak current cable respectively in first placing plate in wiring frame main part inside, utilizing moving plate and first pressboard to hold fixed it, strengthen stability, again place another two groups weak current cable in second placing plate in connecting plate inside above moving plate, and there is baffle between both sides in wiring frame main part, carry out zoned management to both sides, and add a layer second placing plate above, realize and carry out layering, finally again through second pressboard to hold fixed weak current cable on second placing plate.

Description

Technical Field

[0001] This utility model relates to the field of low-voltage cabling racks, specifically to a low-voltage cabling rack structure that can be managed in layers and zones. Background Technology

[0002] Low-voltage cabling racks are structured devices specifically designed to organize, support, and manage low-voltage communication lines (such as network, telephone, surveillance, and fiber optic lines), and are a core component of integrated cabling systems. Through modular design, they enable layered and zoned management of cabling, ensuring the efficient, secure, and scalable operation of the low-voltage system.

[0003] Traditional low-voltage cabling racks lack hierarchical and zoned management designs, revealing numerous drawbacks during cabling system construction and maintenance. Traditional racks mix all low-voltage lines (such as network cables, telephone lines, TV cables, and surveillance cables) together without clear classification labels or zoned storage. Due to the lack of hierarchical and zoned management, cable laying often lacks systematic planning, resulting in haphazard cable routing and phenomena such as crossings and overlaps. This not only increases cable loss and interference but also affects the overall aesthetics of the cabling system.

[0004] Therefore, it is necessary to invent a low-voltage cabling rack structure that can be managed in a hierarchical and partitioned manner to solve the above problems. Utility Model Content

[0005] The purpose of this utility model is to provide a low-voltage cabling rack structure with hierarchical and zoned management. Different low-voltage cables are placed in the first placement plates on both sides of the main body of the cabling rack, and clamped and fixed by a moving plate and a first pressure plate to enhance stability. Two more groups of low-voltage cables are placed in the second placement plates inside the connecting plate above the moving plate. A partition between the two sides of the main body of the cabling rack allows for zoned management, and the addition of a second placement plate on top achieves layered management. Finally, the second pressure plate clamps and fixes the low-voltage cables on the second placement plate, ensuring stability when multiple low-voltage cables are distributed. This addresses the shortcomings of traditional low-voltage cabling rack structures mentioned in the background art, which lack hierarchical and zoned management design and exhibit numerous drawbacks during cabling system construction and maintenance. Traditional cabling racks mix all low-voltage lines together without clear classification labels or zoned storage. Due to the lack of hierarchical and zoned management, cable laying often lacks systematic planning, resulting in arbitrary cable routing, intersections, and overlaps. This not only increases line loss and interference but also affects the overall aesthetics of the cabling system.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a low-voltage cabling frame structure that can be managed in layers and zones, including a cabling frame body for low-voltage cabling;

[0007] The first placement plates are installed on both sides inside the main body of the wiring rack. Each of the first placement plates has a placement slot inside. A partition is fixedly connected between the first placement plates. Heat dissipation holes are opened on the lower surface of the main body of the wiring rack. A movable plate is slidably connected inside the main body of the wiring rack. A first pressure plate is slidably connected below the movable plate. A connecting plate is fixedly connected above the movable plate. A second placement plate is fixedly connected above the connecting plate. A cover plate is threadedly connected to the top of the main body of the wiring rack. A second pressure plate is fixedly installed below the cover plate. A label frame is opened on the front side of the top of the cover plate.

[0008] Preferably, the wiring rack body has sliding grooves on both sides inside, and threaded rods are rotatably connected to both sides of the wiring rack body, with the movable plate threadedly connected to the threaded rods.

[0009] Preferably, sliders are fixedly connected to both sides of the movable plate, and the sliders are used in conjunction with the sliding groove.

[0010] Preferably, telescopic rods extend through the front and rear sides of the upper part of the movable plate, the first pressure plate is fixedly connected to the lower end of the telescopic rods, and a spring is sleeved on the outside of the telescopic rods, with the spring located between the movable plate and the first pressure plate.

[0011] Preferably, a limiting groove is provided below each of the first pressure plates, and the internal size of the limiting groove is smaller than the internal size of the placement groove.

[0012] Preferably, the upper two sides of the main body of the wiring rack are provided with docking grooves, the front and rear ends of the docking grooves are provided with threaded holes, the lower two sides of the cover plate are fixedly connected with docking blocks, the docking blocks are used in conjunction with the docking grooves, and bolts pass through the outside of the cover plate.

[0013] The technical effects and advantages provided by this utility model in the above technical solution are as follows:

[0014] This utility model, through the arrangement of a cabling frame main body, a first placement plate, a partition, a movable plate, a first pressure plate, a connecting plate, a second placement plate, a second pressure plate, and a label frame, enables layered and zoned management. The addition of a label frame facilitates classification by maintenance personnel. Different low-voltage cables are placed in the first placement plates on both sides of the cabling frame main body, and clamped and fixed by the movable plate and the first pressure plate to enhance stability. Two more groups of low-voltage cables are placed in the second placement plate inside the connecting plate above the movable plate. A partition between the two sides of the cabling frame main body allows for zoned management, and the addition of a second placement plate on top achieves layered management. Finally, the second pressure plate clamps and fixes the low-voltage cables on the second placement plate, ensuring stability when multiple low-voltage cables are distributed. Attached Figure Description

[0015] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this invention. For those skilled in the art, other drawings can be obtained based on these drawings.

[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0017] Figure 2 This is a schematic diagram of the placement plate structure of this utility model;

[0018] Figure 3 This is a schematic diagram of the movable plate structure of this utility model;

[0019] Figure 4 This is a schematic diagram of the first pressure plate structure of this utility model;

[0020] Figure 5 This is a schematic diagram of the second placement plate and the second pressure plate structure of this utility model;

[0021] Figure 6 For the present utility model Figure 4 Enlarged view of the structure at point A in the middle.

[0022] Explanation of reference numerals in the attached figures:

[0023] 1. Wiring rack body; 2. First placement plate; 3. Placement slot; 4. Partition plate; 5. Heat dissipation hole; 6. Slide groove; 7. Connecting slot; 8. Threaded hole; 9. Threaded rod; 10. Moving plate; 11. Slider; 12. Telescopic rod; 13. First pressure plate; 14. Spring; 15. Limiting slot; 16. Connecting plate; 17. Second placement plate; 18. Cover plate; 19. Connecting block; 20. Bolt; 21. Second pressure plate; 22. Label frame. Detailed Implementation

[0024] To enable those skilled in the art to better understand the technical solution of this utility model, the present utility model will be further described in detail below with reference to the accompanying drawings.

[0025] This utility model provides, for example Figure 1-6 The diagram shows a layered and zoned low-voltage cabling frame structure, including a cabling frame body 1 for low-voltage cabling;

[0026] First placement plates 2 are installed on both sides inside the main body 1 of the wiring rack. Placement slots 3 are provided inside each of the first placement plates 2. Partitions 4 are fixedly connected between the first placement plates 2. Heat dissipation holes 5 are provided on the lower surface of the main body 1 of the wiring rack. A movable plate 10 is slidably connected inside the main body 1 of the wiring rack. A first pressure plate 13 is slidably connected below the movable plate 10. A connecting plate 16 is fixedly connected above the movable plate 10. A second placement plate 17 is fixedly connected above the connecting plate 16. A cover plate 18 is threadedly connected to the top of the main body 1 of the wiring rack. A second pressure plate 21 is fixedly installed below the cover plate 18. The front side of the top of the cover plate 18... Each cable is equipped with a label frame 22. Different low-voltage cables are placed in the first placement plates 2 on both sides of the inside of the main body 1 of the cabling rack. The moving plate 10 and the first pressure plate 13 are used to clamp and fix them to enhance stability. Then, two other sets of low-voltage cables are placed in the second placement plate 17 inside the connecting plate 16 above the moving plate 10. There is a partition 4 between the two sides of the inside of the main body 1 of the cabling rack to manage the two sides separately. A second placement plate 17 is added on top to achieve layering. Finally, the low-voltage cables on the second placement plate 17 are clamped and fixed by the second pressure plate 21 to ensure the stability of the distribution of multiple low-voltage cables.

[0027] like Figure 2 and Figure 3 As shown, the wiring rack body 1 has sliding grooves 6 on both sides inside. Threaded rods 9 are rotatably connected to both sides of the wiring rack body 1. The moving plate 10 is threadedly connected to the threaded rods 9. By rotating the threaded rods 9 on both sides of the wiring rack body 1, the threaded rods 9 are rotatably connected to the connecting blocks on both sides of the wiring rack body 1. Thus, when the threaded rods 9 are rotated, the external moving plate 10 will be driven to adjust up and down inside the wiring rack body 1, which facilitates the placement and distribution of low-voltage cables.

[0028] like Figure 3 and Figure 4 As shown, sliders 11 are fixedly connected to both sides of the movable plate 10. The sliders 11 cooperate with the slide grooves 6. When the movable plate 10 moves inside the wiring rack body 1, the sliders 11 on both sides slide in the slide grooves 6 on both sides inside the wiring rack body 1, which enhances stability.

[0029] like Figure 4 and Figure 5 As shown, telescopic rods 12 extend through the front and rear sides of the upper part of the movable plate 10. The first pressure plate 13 is fixedly connected to the lower end of the telescopic rod 12. A spring 14 is sleeved on the outside of the telescopic rod 12. The spring 14 is located between the movable plate 10 and the first pressure plate 13. When the first pressure plate 13 below the movable plate 10 presses up and down on the surface of the low-voltage cable inside the first placement plate 2, the telescopic rod 12 above the first pressure plate 13 moves within the movable plate 10. The spring 14 sleeved on the telescopic rod 12 acts as a rebound, thereby strengthening the firmness of the low-voltage cable branch.

[0030] like Figure 2 and Figure 6 As shown, a limiting groove 15 is provided below each of the first pressure plates 13. The internal size of the limiting groove 15 is smaller than the internal size of the placement groove 3. By the fact that the size of the limiting groove 15 inside the first pressure plate 13 is smaller than the internal size of the placement groove 3, the limiting groove 15 can better compress the weak current cable inside the placement groove 3, thereby enhancing the stability of the cable.

[0031] like Figure 2 and Figure 5 As shown, the upper two sides of the main body 1 of the wiring rack are provided with mating grooves 7, and the front and rear ends of the mating grooves 7 are provided with threaded holes 8. The lower two sides of the cover plate 18 are fixedly connected with mating blocks 19. The mating blocks 19 are used in conjunction with the mating grooves 7. Bolts 20 pass through the outside of the cover plate 18. The cover plate 18 is inserted into the mating grooves 7 on the upper two sides of the main body 1 of the wiring rack through the mating blocks 19 on the lower two sides, so that the two are mated. Then, the bolts 20 are passed through the cover plate 18 and the main body 1 of the wiring rack to strengthen the connection between them.

[0032] The working principle of this utility model is as follows: First, the entire wiring rack body 1 is installed on the wall or underground where low-voltage wiring is required. Then, different groups of low-voltage cables are placed in the first placement plates 2 and placement slots 3 on both sides inside the wiring rack body 1. After they are neatly arranged, the threaded rods 9 on both sides of the wiring rack body 1 are rotated to drive the internal moving plate 10 to rise and fall within the wiring rack body 1. This causes the first pressure plate 13 and limiting slot 15 below the moving plate 10 to press against the low-voltage cables inside the first placement plate 2. The telescopic rod 12 above the first pressure plate 13 moves within the moving plate 10, and the spring 14 sleeved on the telescopic rod 12 provides a rebound effect, thereby strengthening the firmness of the low-voltage cable distribution. Then, the ungrouped low-voltage cables are placed in the moving plate 10. The cables are further distributed in the second placement plate 17 inside the connecting plate 16 above the plate 10. This design allows for layered and zoned management. Finally, the connecting blocks 19 on both sides below the cover plate 18 are inserted into the connecting grooves 7 on both sides above the main body of the cabling rack 1. A second pressure plate 21 is also set below the cover plate 18 to clamp and position the low-voltage cables. Finally, bolts 20 are used to limit and fix the cover plate 18 to the main body of the cabling rack 1. Finally, the label is inserted into the label frame 22 above the cover plate 18. The frontmost label frame 22 corresponds to the innermost two first placement plates 2, and the two sets of label frames 22 behind correspond to the second placement plates 17. In this way, the use of the low-voltage cabling rack structure with layered and zoned management is completed.

[0033] The foregoing description only illustrates certain exemplary embodiments of the present invention. Undoubtedly, those skilled in the art can modify the described embodiments in various ways without departing from the spirit and scope of the present invention. Therefore, the above drawings and descriptions are illustrative in nature and should not be construed as limiting the scope of protection of the claims of the present invention.

Claims

1. A low-voltage cabling frame structure with hierarchical and zoned management, characterized in that: Includes a wiring frame body (1) for low-voltage wiring; The first placement plate (2) is installed on both sides inside the main body of the wiring rack (1). The first placement plate (2) is provided with a placement groove (3). The first placement plate (2) is fixedly connected with a partition plate (4). The lower surface of the main body of the wiring rack (1) is provided with heat dissipation holes (5). The inside of the main body of the wiring rack (1) is slidably connected with a moving plate (10). The lower part of the moving plate (10) is slidably connected with a first pressure plate (13). The upper part of the moving plate (10) is fixedly connected with a connecting plate (16). The upper part of the connecting plate (16) is fixedly connected with a second placement plate (17). The upper part of the main body of the wiring rack (1) is threadedly connected with a cover plate (18). The lower part of the cover plate (18) is fixedly provided with a second pressure plate (21). The upper front side of the cover plate (18) is provided with a label frame (22).

2. The low-voltage cabling frame structure with hierarchical and zoned management according to claim 1, characterized in that: The wiring frame body (1) has sliding grooves (6) on both sides inside. The wiring frame body (1) is rotatably connected to threaded rods (9) on both sides. The moving plate (10) is threadedly connected to the threaded rods (9).

3. The low-voltage cabling frame structure with hierarchical and zoned management according to claim 1, characterized in that: Both sides of the movable plate (10) are fixedly connected to sliders (11), and the sliders (11) are used in conjunction with the slide groove (6).

4. The low-voltage cabling frame structure with hierarchical and zoned management according to claim 1, characterized in that: Telescopic rods (12) are inserted through the front and rear sides of the upper part of the movable plate (10). The first pressure plate (13) is fixedly connected to the lower end of the telescopic rod (12). A spring (14) is sleeved on the outside of the telescopic rod (12). The spring (14) is located between the movable plate (10) and the first pressure plate (13).

5. A layered and zoned low-voltage cabling frame structure according to claim 1, characterized in that: Each of the first pressure plates (13) has a limiting groove (15) below it, and the internal size of the limiting groove (15) is smaller than the internal size of the placement groove (3).

6. The low-voltage cabling frame structure with hierarchical and zoned management according to claim 1, characterized in that: The wiring frame body (1) has a docking groove (7) on both sides above. The docking groove (7) has a threaded hole (8) at both ends. The cover plate (18) has a docking block (19) fixedly connected to both sides below. The docking block (19) works in conjunction with the docking groove (7). The cover plate (18) has a bolt (20) penetrating through its exterior.

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