A stacked cable organizer

Abstract

The utility model discloses a kind of laminated cable arrangement devices, more specifically in the technical field of cable arrangement device, including base, the base top is fixedly connected with fixed frame, the base left side and right side top are fixedly connected with connecting plate, two The connecting plate top is fixedly connected with the bottom of fixed frame, the base upper portion is provided with adjusting assembly, the base upper portion is provided with dismounting assembly, the adjusting assembly includes several lifters. A kind of laminated cable arrangement device described in the utility model, by setting adjusting assembly, specifically is first pull rod is moved to pull two inserts and can remove the restriction of lifter to make it can move up and down to carry out height adjustment, not only can according to cable thickness flexible adjustment layer spacing, avoid the situation that cable deformation, insulation layer abrasion occurs, and flexible adjustment layer spacing can optimize air flow path, reduce the heat accumulation of cable dense area, reduce insulation aging and short-circuit risk.

Description

Technical Field

[0001] This utility model relates to the technical field of cable management devices, and in particular to a layered cable management device. Background Technology

[0002] With the rapid development of information technology, the number of cables in data centers, communication equipment rooms, industrial control and other scenarios has increased dramatically. The layout and management of cables have become key factors affecting system operating efficiency, maintenance costs and security.

[0003] Layered cable management devices are mainly used to solve problems such as tangling, heat dissipation, and electromagnetic interference caused by dense cables in scenarios such as data centers, communication equipment rooms, and industrial control.

[0004] The height of the placement plates in existing devices is mostly fixed and cannot be adjusted. Since different cables require different support heights, this may cause cable deformation and insulation wear. Moreover, when cables are densely stacked, the fixed-height plates can obstruct airflow and cause short circuit risks. Therefore, we propose a stacked cable management device to solve the above problems. Utility Model Content

[0005] The main purpose of this invention is to provide a layered cable management device that can effectively solve the above problems.

[0006] To achieve the above objectives, the technical solution adopted by this utility model is as follows:

[0007] A layered cable management device includes a base, a fixing frame fixedly connected to the top of the base, connecting plates fixedly connected to the top of the left and right sides of the base, the top of the two connecting plates being fixedly connected to the bottom of the fixing frame, an adjustment component provided above the base, and a disassembly component provided above the base.

[0008] Preferably, the adjustment component includes several lifting plates arranged in a linear array. Sliding blocks are fixedly connected to the left and right sides of each lifting plate, and the inner walls of the four sliding blocks are slidably connected to the outer surface of the bottom of the fixed frame.

[0009] Preferably, a pull rod is slidably connected to the inner wall of the front of the lifting plate, and a connecting block one is fixedly connected to the back of the pull rod. Two rotating rods are rotatably connected to the inner wall of the back of the connecting block one, and a connecting block two is rotatably connected to the outer surface of the two rotating rods on the side away from each other.

[0010] Preferably, the bottom of the lifting plate is fixedly connected to two fixing blocks, and the inner walls of the two fixing blocks are slidably connected to sliding rods. The ends of the two sliding rods that are close to each other are fixedly connected to the ends of the connecting block two that are close to the fixing blocks on the same side. The ends of the two sliding rods that are far apart from each other are fixedly connected to insert blocks. The left ends of the two connecting plates are provided with a plurality of positioning holes. The outer surfaces of the two insert blocks that are far apart from each other are inserted into the inner walls of the positioning holes on the same side. The outer surfaces of the two insert blocks are slidably connected to the inner wall of the lifting plate.

[0011] Preferably, springs are fitted onto the outer surfaces of both sliding rods, with the ends of the two springs that are close to each other being fixedly connected to the end of the fixing block near the insert block on the same side, and the ends of the two springs that are far apart from each other being fixedly connected to the end of the insert block near the fixing block on the same side.

[0012] Preferably, the disassembly assembly includes several sliding plates arranged in a linear array. Each of the several sliding plates has two sliding grooves at its top. The inner walls of the two sliding grooves are slidably connected to the outer surface of the bottom of the sliding plate on the same side. Several cable plates are fixedly connected to the top of the sliding plates. Several through holes are formed on the outer surface of the bottom of the several cable plates.

[0013] Preferably, the lifting plate has two fixed plates fixedly connected to its back side, and the inner walls of the two fixed plates are rotatably connected to a bidirectional threaded rod. The right end of the bidirectional threaded rod is fixedly connected to a rotating block, and the outer surface of the bidirectional threaded rod is threadedly connected to two movable plates. The ends of the two movable plates that are far apart from each other are fixedly connected to a plug rod.

[0014] Preferably, the two fixed plates are fixedly connected to a round rod at their close ends, and the bottom outer surfaces of the two movable plates are provided with round holes. The inner walls of the two round holes are slidably connected to the outer surface of the round rod. The top of the sliding plate is fixedly connected to two limiting blocks, and the outer surfaces of the two insert rods are inserted into the inner walls of the limiting blocks on the same side.

[0015] Compared with the prior art, the present invention has the following beneficial effects:

[0016] 1. This utility model, by setting an adjustment component, specifically, first pulls the lever to move the two plug blocks, which can release the restriction on the lifting plate and allow it to move up and down for height adjustment. This not only allows for flexible adjustment of the layer spacing according to the thickness of the cable, avoiding cable deformation and insulation wear, but also optimizes the air circulation path, reduces heat accumulation in dense cable areas, and lowers the risk of insulation aging and short circuits.

[0017] 2. This utility model, by setting up a disassembly component, specifically, when the cable board is damaged and needs to be replaced, firstly, the rotating block is rotated counterclockwise to drive the two plug rods to move and separate from the inner wall of the corresponding limit block, so that the sliding plate can be directly removed for replacement. This not only reduces downtime and business interruption losses, but also allows the damaged board to be removed directly without tools. Non-professionals can operate it after simple training, reducing reliance on technical personnel. 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 schematic diagram of the bottom structure of the lifting plate of this utility model;

[0020] Figure 3 This is a schematic diagram of the overall structure of the insert block of this utility model;

[0021] Figure 4 This is a schematic diagram of the overall structure of the sliding plate of this utility model;

[0022] Figure 5 This utility model Figure 4 A magnified structural diagram of A in the diagram.

[0023] In the diagram: 1. Base; 11. Fixing frame; 12. Connecting plate; 2. Adjusting assembly; 21. Lifting plate; 211. Sliding block; 22. Pull rod; 221. Connecting block one; 222. Rotating rod; 223. Connecting block two; 23. Fixing block; 231. Sliding rod; 232. Spring; 24. Insertion block; 3. Disassembly assembly; 31. Sliding plate; 311. Cable plate; 32. Fixing plate; 321. Bidirectional threaded rod; 322. Rotating block; 323. Moving plate; 324. Insertion rod; 33. Round rod; 34. Limiting block. Detailed Implementation

[0024] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.

[0025] Example 1, as Figure 1-5 As shown, a layered cable management device includes a base 1, a fixing frame 11 fixedly connected to the top of the base 1, connecting plates 12 fixedly connected to the top of the left and right sides of the base 1, the tops of the two connecting plates 12 being fixedly connected to the bottom of the fixing frame 11, an adjustment component 2 being provided above the base 1, and a disassembly component 3 being provided above the base 1.

[0026] Specifically, to achieve the goal of adjusting the height of the lifting platform, please refer to... Figure 2 and Figure 3In this embodiment, the adjustment component 2 includes several lifting plates 21 arranged in a linear array. Sliding blocks 211 are fixedly connected to the left and right sides of each lifting plate 21, and the inner walls of the four sliding blocks 211 are slidably connected to the bottom outer surface of the fixed frame 11.

[0027] Further reading Figure 3 In this embodiment, a pull rod 22 is slidably connected to the inner wall of the front of the lifting plate 21, and a connecting block 221 is fixedly connected to the back of the pull rod 22. Two rotating rods 222 are rotatably connected to the inner wall of the back of the connecting block 221, and a connecting block 223 is rotatably connected to the outer surface of the two rotating rods 222 on the side away from each other.

[0028] Further reading Figure 3 In this embodiment, two fixing blocks 23 are fixedly connected to the bottom of the lifting plate 21. Sliding rods 231 are slidably connected to the inner walls of the two fixing blocks 23. The ends of the two sliding rods 231 that are close to each other are fixedly connected to the ends of the connecting block 223 on the same side that are close to the fixing blocks 23. Insert blocks 24 are fixedly connected to the ends that are far apart from each other. Several positioning holes are opened on the left end of the two connecting plates 12. The outer surfaces of the two insert blocks 24 that are far apart from each other are inserted into the inner walls of the positioning holes on the same side. The outer surfaces of the two insert blocks 24 are slidably connected to the inner wall of the lifting plate 21.

[0029] Further reading Figure 3 In this embodiment, springs 232 are sleeved on the outer surfaces of the two sliding rods 231. The ends of the two springs 232 that are close to each other are fixedly connected to the end of the fixed block 23 on the same side that is close to the insertion block 24, and the ends of the two springs 232 that are far apart from each other are fixedly connected to the end of the insertion block 24 on the same side that is close to the fixed block 23.

[0030] During implementation, when the height of the lifting plate 21 needs to be adjusted, firstly, pull the corresponding lever 22 to slide it forward within the inner wall of the lifting plate 21. As the lever 22 slides, it also moves the connecting block 1 221 forward. Simultaneously, the movement of the connecting block 1 221 causes the two rotating rods 222 to rotate. The rotation of the two rotating rods 222 also causes the two connecting blocks 223 to move closer together. As the connecting blocks 223 move, they cause the sliding rod 231 to slide within the inner wall of the corresponding fixed block 23. The sliding rod 231, in turn, causes the insert block 24 to move closer to the fixed block 23. Simultaneously, the movement of the insert block 24 engages the spring 232. The compression causes the insertion block 24 to deform. After the insertion block 24 moves a certain distance, its outer surface can separate from the inner wall of the corresponding positioning hole, which can release the restriction on the lifting plate 21 and allow it to move up and down for height adjustment. After the height of the lifting plate 21 is adjusted, the spring of the pull rod 22 is released and pushed the insertion block 24 to move away from the fixed block 23, so that the two insertion blocks 24 can be reinserted into the inner wall of the corresponding positioning hole. This not only allows for flexible adjustment of the layer spacing according to the thickness of the cable, avoiding cable deformation and insulation wear, but also optimizes the air circulation path, reduces heat accumulation in dense cable areas, and reduces the risk of insulation aging and short circuit.

[0031] Example 2: This example is based on Example 1 and includes a disassembly component.

[0032] Specifically, to enable quick and easy removal of damaged sliding plates, please refer to... Figure 4 and Figure 5 In this embodiment, the disassembly assembly 3 includes several sliding plates 31 arranged in a linear array. Each of the several lifting plates 21 has two sliding grooves on its top. The inner walls of the two sliding grooves are slidably connected to the bottom outer surface of the sliding plate 31 on the same side. Several cable plates 311 are fixedly connected to the top of the sliding plate 31. Several through holes are opened on the bottom outer surface of the several cable plates 311.

[0033] Further reading Figure 4 In this embodiment, two fixed plates 32 are fixedly connected to the back of the lifting plate 21. The inner walls of the two fixed plates 32 are rotatably connected to a bidirectional threaded rod 321. A rotating block 322 is fixedly connected to the right end of the bidirectional threaded rod 321. Two moving plates 323 are threadedly connected to the outer surface of the bidirectional threaded rod 321. A plug rod 324 is fixedly connected to the ends of the two moving plates 323 that are far apart from each other.

[0034] Further reading Figure 5In this embodiment, the two fixed plates 32 are fixedly connected to a round rod 33 at their close ends. The bottom outer surfaces of the two movable plates 323 are provided with round holes. The inner walls of the two round holes are slidably connected to the outer surface of the round rod 33. The top of the sliding plate 31 is fixedly connected to two limiting blocks 34. The outer surfaces of the two insertion rods 324 are inserted into the inner walls of the limiting blocks 34 on the same side.

[0035] During implementation, when the cable board 311 is damaged and needs to be replaced, the rotating block 322 is first rotated counterclockwise to drive the bidirectional threaded rod 321 to rotate within the inner walls of the two fixed plates 32. As the bidirectional threaded rod 321 rotates counterclockwise, it also drives the two moving plates 323 to move closer to each other. When the moving plate 323 moves, the inner wall of the circular hole at its bottom slides on the outer surface of the circular rod 33, so that the moving plate 323 does not rotate with the bidirectional threaded rod 321. When the moving plate 323 moves, it drives the insertion rod 324 to move. After the insertion rod 324 moves a certain distance, its outer surface can separate from the inner wall of the corresponding limiting block 34, so that the sliding plate 31 can be directly removed for replacement. This not only reduces downtime and business interruption losses, but also allows the damaged board to be removed directly without tools. Non-professionals can operate it after simple training, reducing reliance on technical personnel.

[0036] After the cable board 311 is replaced, place the cable on top of the corresponding cable board 311 and secure the cable with cable ties through the through holes at the bottom of the cable board 311 to prevent the cables from getting tangled.

[0037] The working principle of this utility model is as follows: When it is necessary to adjust the height of the lifting plate 21, firstly, pull the corresponding lever 22 to drive it to slide forward in the inner wall of the lifting plate 21. While the lever 22 slides, it will drive the connecting block 1 221 to move forward. While the connecting block 1 221 moves, it will drive the two rotating rods 222 to rotate. While the two rotating rods 222 rotate, it will drive the two connecting blocks 223 to move closer to each other. When the connecting blocks 223 move, it will drive the sliding rod 231 to slide in the inner wall of the corresponding fixed block 23. When the sliding rod 231 slides, it will drive the insert block 24 to move closer to the fixed block 23. While the insert block 24 moves, it will stimulate the spring 23. 2. The compression causes deformation. After the insertion block 24 moves a certain distance, its outer surface can separate from the inner wall of the corresponding positioning hole, which can release the restriction on the lifting plate 21 and allow it to move up and down for height adjustment. After the height of the lifting plate 21 is adjusted, the spring of the released lever 22 will push the insertion block 24 to move away from the fixed block 23, so that the two insertion blocks 24 can be reinserted into the inner wall of the corresponding positioning hole. This not only allows for flexible adjustment of the layer spacing according to the cable thickness, avoiding cable deformation and insulation wear, but also optimizes the air circulation path, reduces heat accumulation in dense cable areas, and reduces the risk of insulation aging and short circuit.

[0038] When the cable board 311 is damaged and needs to be replaced, firstly, rotate the rotating block 322 counterclockwise to drive the bidirectional threaded rod 321 to rotate within the inner walls of the two fixed plates 32. As the bidirectional threaded rod 321 rotates counterclockwise, it will drive the two moving plates 323 to move closer to each other. When the moving plate 323 moves, the inner wall of the circular hole at its bottom will slide on the outer surface of the circular rod 33, so that the moving plate 323 will not rotate with the bidirectional threaded rod 321. When the moving plate 323 moves, it will drive the insertion rod 324 to move. After the insertion rod 324 moves a certain distance, its outer surface can separate from the inner wall of the corresponding limit block 34, so that the sliding plate 31 can be directly removed for replacement. This not only reduces downtime and business interruption losses, but also allows the damaged board to be removed directly without tools. Non-professionals can operate it after simple training, reducing reliance on technicians.

[0039] After the cable board 311 is replaced, place the cable on top of the corresponding cable board 311 and secure the cable with cable ties through the through holes at the bottom of the cable board 311 to prevent the cables from getting tangled.

[0040] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claims. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. A layered cable management device, comprising a base (1), wherein a fixing frame (11) is fixedly connected to the top of the base (1), and connecting plates (12) are fixedly connected to the top of the left and right sides of the base (1), wherein the tops of the two connecting plates (12) are fixedly connected to the bottom of the fixing frame (11), characterized in that: An adjustment component (2) is provided above the base (1), and a disassembly component (3) is provided above the base (1); The adjustment component (2) includes several lifting plates (21), which are arranged in a linear array. Each lifting plate (21) has a sliding block (211) fixedly connected to its left and right sides. The inner walls of the four sliding blocks (211) are slidably connected to the bottom outer surface of the fixed frame (11).

2. The layered cable management device according to claim 1, characterized in that: The lifting plate (21) is slidably connected to the inner wall of the front side with a pull rod (22), and the pull rod (22) is fixedly connected to the back side with a connecting block one (221). The inner wall of the back side of the connecting block one (221) is rotatably connected with two rotating rods (222), and the outer surfaces of the two rotating rods (222) on the opposite sides are rotatably connected to a connecting block two (223).

3. The layered cable management device according to claim 2, characterized in that: The bottom of the lifting plate (21) is fixedly connected to two fixing blocks (23). The inner walls of the two fixing blocks (23) are slidably connected to sliding rods (231). The ends of the two sliding rods (231) that are close to each other are fixedly connected to the ends of the connecting block two (223) on the same side that are close to the fixing blocks (23). The ends of the two sliding rods that are far apart from each other are fixedly connected to insert blocks (24). The left ends of the two connecting plates (12) are provided with several positioning holes. The outer surfaces of the two insert blocks (24) that are far apart from each other are inserted into the inner walls of the positioning holes on the same side. The outer surfaces of the two insert blocks (24) are slidably connected to the inner wall of the lifting plate (21).

4. The layered cable management device according to claim 3, characterized in that: Springs (232) are fitted onto the outer surfaces of both sliding rods (231). The ends of the two springs (232) that are close to each other are fixedly connected to the end of the fixed block (23) on the same side that is close to the insertion block (24). The ends of the two springs (232) that are far apart from each other are fixedly connected to the end of the insertion block (24) on the same side that is close to the fixed block (23).

5. The layered cable management device according to claim 1, characterized in that: The disassembly assembly (3) includes several sliding plates (31), which are arranged in a linear array. Each of the several lifting plates (21) has two sliding grooves on its top. The inner walls of the two sliding grooves are slidably connected to the bottom outer surface of the sliding plate (31) on the same side. Several cable plates (311) are fixedly connected to the top of the sliding plate (31), and several through holes are opened on the bottom outer surface of the several cable plates (311).

6. The layered cable management device according to claim 5, characterized in that: The lifting plate (21) has two fixed plates (32) fixedly connected to its back. The inner walls of the two fixed plates (32) are rotatably connected to a bidirectional threaded rod (321). The right end of the bidirectional threaded rod (321) is fixedly connected to a rotating block (322). The outer surface of the bidirectional threaded rod (321) is threadedly connected to two moving plates (323). The ends of the two moving plates (323) that are far apart from each other are fixedly connected to a plug rod (324).

7. A layered cable management device according to claim 6, characterized in that: Two fixed plates (32) are fixedly connected to a round rod (33) at their close ends. The bottom outer surfaces of the two movable plates (323) are provided with round holes. The inner walls of the two round holes are slidably connected to the outer surface of the round rod (33). Two limiting blocks (34) are fixedly connected to the top of the sliding plate (31). The outer surfaces of the two insert rods (324) are inserted into the inner walls of the limiting blocks (34) on the same side.

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