A fly ash cement-based network floor with a grooved structure
The rigid-flexible structure composed of guide rods and sliding plates solves the problems of easy deformation and cable entanglement in network floor cable trays, achieving stable cable positioning and protection.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIACHEN FLOOR CHANGZHOU
- Filing Date
- 2025-07-07
- Publication Date
- 2026-06-30
AI Technical Summary
The existing cable tray structure of network flooring is prone to denting and deformation due to unstable support from rubber pads. Cables are unrestrained and easily entangled, and friction with the pads can damage the sheath.
A rigid positioning structure consisting of a guide rod and a movable sleeve is used, combined with flexible support from a sliding plate and a support part. Silicone rings are used for buffering, and a partition plate isolates the cable space to avoid direct friction.
It improves the stability of the cable tray structure, prevents cable tangling, protects the cable sheath, and enhances the flexibility and durability of cable management.
Smart Images

Figure CN224431906U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of network flooring technology, and in particular to a fly ash cement-based network flooring with a grooved structure. Background Technology
[0002] In modern architecture, networked floors are widely used in data centers, server rooms, offices, and other environments with high requirements for cable management and space utilization. Traditional networked floors typically consist of a panel, supporting frame, and base, and their main function is to provide concealed space for cable laying, achieving a clean and easy-to-maintain environment. Current networked floors are mostly made of steel, aluminum alloy, wood, or fly ash cement-based materials.
[0003] For example, the utility model patent with publication number CN222721067U discloses a cable tray structure for GRC network floor, which includes a fixed support, a tray assembly, a fixing screw, an upper tray, a lower tray, and a rubber pad; thereby solving the problem that all cables in the cable tray need to be pulled out when disassembling and assembling the cable tray in the prior art.
[0004] The above-mentioned solution has several drawbacks in practical applications: First, the upper channel relies solely on rubber pads fixed to the lower channel for support. Due to the elastic fatigue characteristics of the rubber pads and their limited support area, concentrated loads from foot traffic or equipment handling can easily cause localized indentations at the edges of the upper channel, or even embed the cable into the lower channel, leading to cable channel deformation. Second, with cables running only through the space enclosed by the upper and lower channels and the rubber pads, multiple cables of different types are prone to tangling due to shaking and pulling in an unconstrained state. Furthermore, the direct contact between the cables and the rubber pads means that during temperature changes causing cable expansion and contraction or channel vibration, the edges of the pads continuously scrape against the cable sheath, potentially causing long-term damage. Therefore, a fly ash cement-based network floor with a cable channel structure is needed.
[0005] It should be noted that the information disclosed in this background section is only for understanding the background technology of this application concept, and therefore may include information that does not constitute prior art. Utility Model Content
[0006] This utility model provides a fly ash cement-based network floor with a cable trough structure to solve the problems that the upper trough is easily dented and deformed due to being supported only by rubber pads; the cables are easily tangled due to lack of positioning constraints, and the sheaths are damaged due to friction with the pads.
[0007] This utility model embodiment adopts the following technical solution: a fly ash cement-based network floor with a cable tray structure. It mainly includes a panel body; a cable tray assembly installed at the bottom of the panel body. The cable tray assembly includes four sets of support seats installed on the bottom surface of the panel body. A guide rod is horizontally fixed between two sets of support seats. At least one set of wiring units is slidably installed between two sets of guide rods. The wiring unit includes two sets of movable sleeves slidably installed on the guide rods. The side of the movable sleeve has two sets of hook portions. A rotating shaft rotates between the two sets of hook portions. The rotating shaft has a protrusion. An mounting block is fixedly installed on the side of the two sets of movable sleeves that are close to each other. A cable tray box is installed between the four sets of mounting blocks. A support unit for supporting cables is installed on the cable tray box.
[0008] Furthermore, the support unit includes two sets of right-angle plates fixedly installed at the bottom of the online slot box near both sides, and a slide plate is slidably provided at the vertical end of the right-angle plate, the slide plate being fixed to the right-angle plate by fasteners.
[0009] Furthermore, the slide plate is provided with equidistant support parts, each of which consists of a support rod and an open support ring to provide support for the cable, and a silicone ring is wrapped around the support ring.
[0010] Furthermore, a partition plate is fixedly installed between the two sets of right-angle plates on the bottom surface of the cable tray box.
[0011] Furthermore, ventilation holes are provided on the right-angle plate.
[0012] Furthermore, the number of sliding plates and the arrangement density of the supporting parts are configured according to the number, type and layout requirements of the cables.
[0013] The above-mentioned technical solutions adopted in the embodiments of this utility model can achieve the following beneficial effects:
[0014] A fly ash cement-based network floor with a cable tray structure achieves rigid positioning through the abutting friction between the protruding part of the pivot and the guide rod, improving the stability of the support structure. The support unit on the cable tray box achieves layered positioning of cables through the combination of sliding plates and support parts, changing the entanglement problem caused by the lack of constraints in traditional cable trays. The partition plate further isolates the wiring space to prevent interference between strong and weak currents. The silicone ring wrapped around the support ring of the support part forms a flexible buffer layer, replacing the direct contact between the traditional rubber pad and the cable, avoiding the edge of the pad scratching the cable sheath. At the same time, the number of sliding plates can be increased or decreased to adapt to different cable densities, solving the problems of fixed layout and inconvenient maintenance of traditional cable trays. Attached Figure Description
[0015] The accompanying drawings, which are provided to further illustrate the present invention and constitute a part of the present invention, illustrate exemplary embodiments of the present invention and are used to explain the present invention, but do not constitute an undue limitation of the present invention.
[0016] In the attached diagram:
[0017] Figure 1 This is an overall schematic diagram of a fly ash cement-based network floor with a grooved structure according to this application;
[0018] Figure 2 for Figure 1 A schematic diagram of the top surface structure;
[0019] Figure 3 for Figure 1 Exploded view;
[0020] Figure 4 for Figure 3 Enlarged view of point A;
[0021] Figure label:
[0022] 1. Floor assembly; 11. Support base; 12. Support surface; 13. Support body; 14. Support frame; 15. Panel body; 2. Cable tray assembly; 21. Support seat; 22. Guide rod; 23. Movable sleeve; 24. Hook; 25. Rotary shaft; 26. Protrusion; 27. Handle; 28. Cable tray box; 29. Right angle plate; 210. Sliding strip; 211. Support; 212. Silicone ring; 213. Mounting block; 214. Divider plate. Detailed Implementation
[0023] To further illustrate the technical means and effects adopted by this utility model in order to achieve the intended utility model purpose, the following detailed description of the specific implementation methods, structure, features and effects of this utility model is provided in conjunction with the accompanying drawings and preferred embodiments.
[0024] The technical solutions provided by the various embodiments of this utility model are described in detail below with reference to the accompanying drawings.
[0025] Reference Figures 1-2 As shown, this utility model embodiment provides a fly ash cement-based network floor with a groove structure, including a floor assembly 1. The floor assembly 1 includes a panel body 15 and supporting frame 14 with enclosures disposed on the four sides of the panel body 15. The supporting frame 14 is fixed to the panel body 15 by pre-embedded bolts or epoxy resin adhesive.
[0026] like Figures 2-4As shown, a cable tray assembly 2 is provided at the bottom of the panel body 15. The cable tray assembly 2 is used to hide power cables, network cables, optical fibers and other cables in the raised layer of the network floor. The cable tray assembly 2 includes four sets of support seats 21 fixedly installed on the bottom surface of the panel body 15, and a guide rod 22 is horizontally fixed between two sets of support seats 21. At the same time, at least one set of wiring unit is slidably installed between two sets of guide rods 22.
[0027] The wiring unit includes two sets of movable sleeves 23 slidably mounted on a guide rod 22. The movable sleeves 23 are adapted to slide along the straight direction of the guide rod 22. The movable sleeves 23 have two sets of hook portions 24 on their sides, and a rotating shaft 25 is rotatably arranged between the two sets of hook portions 24. The rotating shaft 25 has a protrusion 26, which allows the rotating shaft 25 to be stably limited between the two sets of hook portions 24 without slippage. In use, by rotating the rotating shaft 25, the protrusion 26 can be pressed against the surface of the guide rod 22. Through the squeezing action, the contact friction between the movable sleeve 23 and the guide rod 22 is increased, thereby fixing the movable sleeve 23 in the required position on the guide rod 22. In addition, handles 27 are connected near both ends of the rotating shaft 25, providing a convenient grip for rotating the rotating shaft 25 and facilitating operation to adjust the fixed state of the movable sleeves 23.
[0028] Furthermore, two sets of movable sleeves 23 slidably disposed on the same guide rod 22 are fixedly installed on their close sides with mounting blocks 213, and a cable tray box 28 is fixedly installed between the four sets of mounting blocks 213. The cable tray box 28 is used to provide basic space for cable storage. A support unit is installed on the cable tray box 28. The support unit includes two sets of right-angle plates 29 fixedly installed at the bottom of the cable tray box 28 near the two sides. A slide bar 210 is slidably disposed at the vertical end of the right-angle plate 29. The sliding disposal can be understood as (the inner side of the vertical end of the right-angle plate 29 is provided with a C-shaped guide rail, and the edge of the slide bar 210 is embedded in the guide rail to form a sliding pair. The guide rail has a cross section of "[" to ensure that the slide bar 210 does not derail when sliding). It should be noted that the slide bar 210 is fixed to the right-angle plate 29 by fasteners.
[0029] When it is necessary to inspect or assemble the cable engaged on the support 211, the slide bar 210 can be slid out along the vertical end of the right-angle plate 29 to fully expose the cable for easy operation. After the slide bar 210 is slid out, its position on the right-angle plate 29 can be adjusted as needed, or a slide bar 210 of different specifications can be replaced to meet the needs of different quantities or types of cables.
[0030] The slide bar 210 has support parts 211 evenly distributed on it. Each support part 211 consists of a support diagonal bar and an open support ring to provide support for the cable. A silicone ring 212 is wrapped around the support ring. The flexible buffering properties of the silicone ring 212 prevent the cable from making direct hard contact with the support ring, effectively preventing wear on the cable surface due to friction, and ensuring the cable's appearance and performance are intact.
[0031] Specifically, a partition plate 214 is fixedly installed between the two sets of right-angle plates 29 on the bottom surface of the cable tray box 28. Its function is to separate the two sets of opposite sliding plates 210 to form an independent wiring space.
[0032] Specifically, the right-angle plate 29 has ventilation holes (not shown in the figure) to enhance air circulation inside the cable tray box 28 and help dissipate heat from the cables.
[0033] Specifically, a support base 11 is provided near the four corners of the panel body 15. The support base 11 consists of a bottom fixing component and a top support surface 12. The bottom can be fixed to the bottom surface of the building. The top support surface 12 is horizontally set to support the panel body 15. A cross-shaped support body 13 is fixedly installed on the support surface 12. The support body 13 is located directly below the four corners of the panel. The panel body 15 is supported at four corners by resting on the right angles of the cross-shaped support body 13, forming a four-point support.
[0034] It should be noted that the number of sliding plates 210 and supporting parts 211 slidably mounted on the vertical end of the right-angle plate 29 can be flexibly adjusted according to the actual number, type, and layout requirements of the cables. When there are many cables or when they need to be classified and managed, the number of sliding plates 210 and supporting parts 211 can be increased; conversely, when there are few cables, the configuration can be reduced accordingly to maximize space utilization and optimize costs.
[0035] Working principle: When cables need to be laid out, first adjust the number and position of the slide plates 210 according to the number and type of cables, slide them along the guide rail of the right-angle plate 29 and fix them with fasteners. Different types of cables (such as power cords and network cables) are respectively inserted into the support part 211 of the corresponding slide plate 210. The silicone ring 212 provides flexible support to avoid cable wear. The partition plate 214 divides the inside of the cable tray box 28 into independent spaces to prevent cables from tangling. The vent holes enhance air convection and reduce the operating temperature of the cables. When it is necessary to inspect or adjust the cables, loosen the fasteners and pull out the slide plate 210 to directly contact the cables. After the operation is completed, reset it.
[0036] The panel body 15 is supported on the support base 11 by four cross-shaped supports 13 at the four corners, forming a stable four-point support structure to ensure that the load is evenly distributed to the building's bottom surface. The cable tray assembly 2 is connected to the panel body 15 through the support base 21. The wiring unit can slide along the guide rod 22 to adjust its position. By rotating the handle 27, the protrusion 26 is pressed against the guide rod 22, thus fixing the cable tray box 28. This design allows for flexible adjustment of the cable tray position according to the cable routing, while preventing the upper tray from denting due to stepping or uneven load, ensuring the integrity of the cable channel.
[0037] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any way. Although the present utility model has been disclosed above with reference to a preferred embodiment, it is not intended to limit the present utility model. Any person skilled in the art can make some modifications or alterations to the above-disclosed technical content to create equivalent embodiments without departing from the scope of the present utility model. Any simple modifications, equivalent changes and alterations made to the above embodiments based on the technical essence of the present utility model without departing from the scope of the present utility model shall still fall within the scope of the present utility model.
Claims
1. A fly ash cement-based network floor with a grooved structure, characterized in that: include Panel body (15); A cable tray assembly (2) is installed at the bottom of the panel body (15). The cable tray assembly (2) includes four sets of support seats (21) installed on the bottom surface of the panel body (15). A guide rod (22) is horizontally fixed between two sets of support seats (21). At least one set of wiring units is slidably installed between two sets of guide rods (22). The wiring unit includes two sets of movable sleeves (23) slidably installed on the guide rods (22). The side of the movable sleeve (23) has two sets of hook parts (24). A rotating shaft (25) is rotatable between the two sets of hook parts (24). A protrusion (26) is on the rotating shaft (25). An installation block (213) is fixedly installed on the side of the two sets of movable sleeves (23) that are close to each other. A cable tray box (28) is installed between the four sets of installation blocks (213). A support unit for supporting cables is installed on the cable tray box (28).
2. The fly ash cement-based network floor with a grooved structure according to claim 1, characterized in that: The support unit includes two sets of right-angle plates (29) fixedly installed at the bottom of the online slot box (28) near both sides, and a slide plate (210) is slidably provided at the vertical end of the right-angle plate (29), and the slide plate (210) is fixed on the right-angle plate (29) by fasteners.
3. The fly ash cement-based network floor with a grooved structure according to claim 2, characterized in that: The vertical end of the right-angle plate (29) is provided with a C-shaped guide rail, and the edge of the slide plate (210) is embedded in the guide rail to form a sliding pair.
4. The fly ash cement-based network floor with a grooved structure according to claim 3, characterized in that: The slide plate (210) has support parts (211) evenly distributed on it. Each support part (211) consists of a support diagonal bar and an open support ring to provide support for the cable. A silicone ring (212) is wrapped around the support ring.
5. A fly ash cement-based network floor with a grooved structure according to claim 2, characterized in that: A partition plate (214) is fixedly installed between the two sets of right-angle plates (29) on the bottom surface of the cable tray box (28).
6. A fly ash cement-based network floor with a grooved structure according to claim 3, characterized in that: The right-angle plate (29) has ventilation holes.
7. A fly ash cement-based network floor with a grooved structure according to claim 4, characterized in that: The number of sliding plates (210) and the arrangement density of the supporting parts (211) are configured according to the number, type and layout requirements of the cables.