A wire slot positioning structure of a screen
By using a vertical lifting and pulling method and reinforcing component design, the problem of cable covers becoming loose along with power connectors in existing screen cable tray structures has been solved, achieving stable positioning of the cable tray and simplifying operation, making it suitable for cable management in office scenarios.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- FOSHAN FUTURISM FURNITURE TECH CO LTD
- Filing Date
- 2025-08-01
- Publication Date
- 2026-07-07
AI Technical Summary
The existing screen cable tray positioning structure causes the disassembly direction to be consistent with the insertion and unplugging direction when plugging and unplugging the power connector, which makes the cable cover easy to be pulled off along with the power connector, affecting the stability of use and the convenience of operation.
The cable tray is positioned and disassembled by vertically lifting and pulling. The combination of the "π"-shaped cable cover and the "I"-shaped upper and lower slots, along with the design of reinforcing components and positioning pins, forms a stable cable channel, preventing the cable cover from loosening with the power connector. The secondary locking of the positioning pin and the slot further enhances the stability.
It enables convenient and stable installation and removal of cable trays, preventing the cable cover from loosening when the power connector is plugged in or out, thus improving the stability and ease of operation. It is suitable for office scenarios where cables are frequently added or removed.
Smart Images

Figure CN224473002U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of screen cable tray technology, specifically a cable tray positioning structure for a screen. Background Technology
[0002] Screens, as common partition furniture in office spaces and public areas, serve multiple functions, including space division, privacy protection, and decoration. With the increasing popularity of smart offices, computers, printers, monitoring equipment, and other electrical devices often need to be placed around screens. The storage and management of cables (power cords, data cables, network cables, etc.) has become a critical need. The cable tray positioning structure of screens has emerged to address this need. Its core function is to hide and fix cables, preventing clutter and tangling, while ensuring electrical safety and a clean space. However, existing screen cable trays suffer from problems such as inconvenient installation and cumbersome operation.
[0003] To address the aforementioned shortcomings, existing technology (Chinese Patent No. CN217469350U, Publication Date 2022-09-20) provides a cable tray positioning structure for office partitions. This cable tray plate is designed to be detachably connected to the sleeve plate regardless of left or right orientation, allowing for both upright and inverted installation. During installation, the slot can be placed on the left or right side depending on the actual situation, facilitating assembly and disassembly, improving the flexibility of the partition's use, and avoiding the need to produce multiple cable tray plates with different slot positions for backup, thus reducing resource waste.
[0004] The above solution involves assembling and disassembling the cable tray by rotating it left and right. However, when plugging or unplugging the power connector, the disassembly direction is the same as the plugging / unplugging direction, which can cause the cable cover to be pulled off along with the power connector, thus affecting its use. Utility Model Content
[0005] The purpose of this utility model is to provide a wire channel positioning structure for a screen, so as to solve the problem mentioned in the background art that the existing wire channel positioning structure of the screen is assembled and disassembled by rotating left and right during use. When plugging and unplugging the power connector, the disassembly direction is consistent with the plugging and unplugging direction, which causes the wire cover to be easily pulled off along with the power connector, thus affecting the use.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a screen groove positioning structure, including an upper groove, a lower groove below the upper groove, and symmetrically arranged wire covers connecting the upper groove and the lower groove, wherein the upper groove, the lower groove and the wire covers constitute a complete screen groove.
[0007] The top and bottom of the line cover are provided with connectors, which are used to assemble with the locking components at the corresponding positions on the left and right sides of the upper and lower grooves. The connectors and locking components are disassembled and assembled by lifting and pulling.
[0008] The left and right sides of the upper groove are reinforced with reinforcing components to enhance the stability of the line cover after installation with the upper groove.
[0009] Furthermore, the connectors at the top and bottom of the wire cover are configured as snap-fit connectors, which are L-shaped and have semi-circular ends.
[0010] Furthermore, the engaging components on the left and right sides of the upper and lower grooves are configured as "U"-shaped fitting grooves, and the ends of the fitting grooves are configured as barbed edges, with the barbed edges misaligned and contacting the semi-circular ends of the fasteners.
[0011] Furthermore, the wire cover uses a vertical sliding method to position and connect the buckle and the fitting groove for disassembly and separation. The wire cover is generally designed with a "π" shaped structure, and the upper and lower grooves are generally designed with an "I" shaped structure.
[0012] Furthermore, the reinforcing components on the left and right sides of the upper groove include a through sliding connection pull plate, and a spring is connected between the pull plate and the upper groove.
[0013] Furthermore, a positioning pin is installed at the end of the pull plate, and the end of the positioning pin is set as a triangular structure. The positioning pin is slidably connected to the inner walls on both sides of the upper groove.
[0014] Furthermore, the end of the positioning pin engages with the slot, which is correspondingly located on the outer side of the top fastener of the wire cover.
[0015] Compared with the prior art, the beneficial effects of this utility model are:
[0016] The screen's cable tray positioning structure uses a vertical lifting and pulling method for positioning and opening the cable tray during use. Compared to existing left-right rotation and parallel disassembly methods, this method makes positioning and installation more convenient and stable. It is also perpendicular to the power supply plug-in direction, which can prevent the cable tray from becoming loose due to the plugging and unplugging of the power connector. In addition, the positioning pins and slots can further improve the firmness of the cable tray after positioning.
[0017] 1. Furthermore, the fitting grooves on both sides of the upper and lower slots provide precise guidance for the connectors. The "π"-shaped cable cover wraps around the sides of the upper and lower slots, forming a complete cable channel to prevent dust from entering. The vertical disassembly and assembly positioning, along with the cooperation of the reinforcing components, improves the stability of the cable cover after installation compared to traditional left-right rotating cable trays. The operation steps are simplified, requiring only lifting and pulling to complete disassembly and assembly. This is suitable for the frequent addition and removal of cables in office scenarios. When disassembling, lift the cable cover vertically upwards. The connector overcomes the constraint of the hook in the fitting groove and disengages from the fitting groove in a vertical direction, completing the separation. Since the disassembly and assembly direction is vertical, perpendicular to the horizontal insertion and removal direction of the power connector, it can prevent the cable cover from loosening when inserting and removing cables, thus improving the stability of use.
[0018] 2. Further, the positioning pin is inserted into the inner wall of the upper groove and finally engages with the slot on the outside of the buckle on the top of the wire cover. The triangular positioning pin can be quickly guided into the slot to form a secondary lock. Even if the wire cover is subjected to a slight horizontal external force, it can be prevented from loosening by the engagement of the positioning pin and the slot. When the wire cover needs to be removed, pull the pull plate outward to compress the spring and make the positioning pin disengage from the slot, so that the wire cover can be unlocked and pulled upward to complete the disassembly and separation. Attached Figure Description
[0019] Figure 1 This is a schematic diagram of the overall installation structure of this utility model;
[0020] Figure 2 This is a schematic diagram of the structure of the present invention when the wire groove is moved upward and disassembled;
[0021] Figure 3 This is a schematic diagram of the structure of the present invention when the wire groove rotates and separates;
[0022] Figure 4 This is a schematic diagram of the structure of the present invention when the wire groove is moved down and disassembled;
[0023] Figure 5 This is a schematic diagram of the reinforcing component at the connection between the upper groove and the wire cover of this utility model;
[0024] Figure 6 This is a cross-sectional structural diagram of the reinforcing component at the connection between the upper groove and the wire cover of this utility model.
[0025] In the diagram: 1. Upper groove; 2. Lower groove; 3. Wire cover; 4. Fastener; 5. Fitting groove; 6. Pull plate; 7. Positioning pin; 8. Spring; 9. Slot. 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] Example 1: Please refer to Figure 1 - Figure 3 The present invention provides the following technical solution: a screen wire groove positioning structure, including an upper groove 1, a lower groove 2 below the upper groove 1, and symmetrically arranged wire covers 3 connecting the upper groove 1 and the lower groove 2. The upper groove 1, the lower groove 2 and the wire covers 3 constitute a complete screen wire groove. Connectors are provided at the top and bottom of the wire covers 3, and the connectors are used to assemble with corresponding locking components on the left and right sides of the upper groove 1 and the lower groove 2. The connectors and locking components are disassembled and assembled by lifting and pulling. The left and right sides of the upper groove 1 are reinforced with reinforcing components to enhance the firmness of the wire covers 3 after installation with the upper groove 1.
[0028] In use, the upper slot 1 and lower slot 2 are designed with an "I" shape, and the cable cover 3 is a "π" shape. The three together form a closed cable channel space to realize the cable storage function. The "I" shaped upper slot 1 and lower slot 2 provide a stable installation base, and the fitting slots 5 on both sides provide precise guidance for the connectors 4. The "π" shaped cable cover 3 wraps around the sides of the upper slot 1 and lower slot 2 to form a complete cable channel and prevent dust from entering. The vertical disassembly and assembly positioning and the cooperation of the reinforcement components make the cable cover 3 more secure after installation than the traditional left and right rotating cable channel. The operation steps are simplified, and disassembly and assembly can be completed by simply lifting and pulling. It is suitable for the needs of frequent addition and removal of cables in office scenarios. Through the design of vertical sliding positioning and mechanical reinforcement, it not only solves the problem of traditional cable channels being prone to loosening due to cable plugging and unplugging, but also improves installation efficiency and stability. It is suitable for cable management scenarios of various office partitions.
[0029] Example 2:
[0030] Based on Embodiment 1, a rapid positioning and assembly mechanism is also disclosed, which is easy to operate and has a stable connection. (See reference) Figure 1 - Figure 4As shown, its specific structure is as follows: the connecting parts at the top and bottom of the wire cover 3 are set as snap-fit connectors 4, which are set as "L" shapes. The ends of snap-fit connectors 4 are set as semi-circular structures. The locking parts on the left and right sides of the upper groove 1 and the lower groove 2 are set as "U" shaped fitting grooves 5. The ends of the fitting grooves 5 are set as barbed edges, and the barbed edges are offset and abut against the semi-circular ends of snap-fit connectors 4. The wire cover 3 uses a vertical sliding method to position and connect snap-fit connectors 4 and fitting grooves 5 and separate them. The wire cover 3 as a whole is set as a "π" shaped structure, and the upper groove 1 and the lower groove 2 are both set as "I" shaped structures.
[0031] refer to Figure 1 - Figure 4 As shown, during use, the semi-circular connectors 4 at the top and bottom of the cable cover 3 ("L" shaped ends) connect to the locking slots 5 on the left and right sides of the upper and lower slots 1 and 2 ("U" shaped ends with barbed edges). During assembly, align the cable cover 3 with the locking slots 5 of the upper and lower slots 1 and 2, and push the cable cover 3 vertically downwards. The semi-circular end of the top connector 4 slides along the locking slot 5 and eventually contacts the barbed edge, forming a mechanical lock. The barb locks the connector 4, preventing it from falling off horizontally. During disassembly, pull the cable cover 3 vertically upwards. The connector 4 overcomes the constraint of the barb in the locking slot 5 and disengages from the locking slot 5 vertically, completing the separation. Since the disassembly and assembly direction is vertical, perpendicular to the horizontal insertion and removal direction of the power connector, it can prevent the cable cover 3 from loosening when plugging and unplugging cables, thus improving the stability of use.
[0032] Example 3:
[0033] Based on Embodiment 2, a reinforcement mechanism is also disclosed, as referenced. Figure 5 - Figure 6 As shown, its specific structure is as follows: The reinforcing components on the left and right sides of the upper groove 1 include a sliding pull plate 6 that is connected through the groove. A spring 8 is connected between the pull plate 6 and the upper groove 1. A positioning pin 7 is installed at the end of the pull plate 6. The end of the positioning pin 7 is set as a triangular structure. The positioning pin 7 is slidably connected to the inner walls on both sides of the upper groove 1. The end of the positioning pin 7 is engaged with the slot 9. The slot 9 is correspondingly opened on the outside of the buckle 4 at the top of the wire cover 3.
[0034] refer to Figure 5 - Figure 6As shown, during use, pull plates 6 are slidably connected to the outer sides of the upper groove 1 on both sides. A spring 8 is connected between the pull plate 6 and the upper groove 1. In the natural state, the elastic force of the spring 8 pushes the pull plate 6 to move inward, causing the positioning pin 7 at the end of the pull plate 6 to insert into the inner wall of the upper groove 1, and finally engage with the slot 9 on the outer side of the buckle 4 at the top of the wire cover 3. The triangular positioning pin 7 can be quickly guided into the slot 9 to form a secondary lock. Even if the wire cover 3 is subjected to a slight horizontal external force, it can be prevented from loosening by the engagement of the positioning pin 7 and the slot 9. When the wire cover 3 needs to be removed, pull the pull plate 6 outward, compress the spring 8 to make the positioning pin 7 disengage from the slot 9, and then the wire cover 3 can be unlocked and pulled upward.
[0035] The contents not described in detail in this specification are existing technologies known to those skilled in the art.
[0036] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A screen's groove positioning structure, comprising an upper groove (1), a lower groove (2) below the upper groove (1), and symmetrically arranged wire covers (3) connecting the upper groove (1) and the lower groove (2), wherein the upper groove (1), the lower groove (2) and the wire covers (3) constitute a complete screen groove; Its features are: The top and bottom of the line cover (3) are provided with connectors, and the connectors are used to dock and assemble with the corresponding locking parts on the left and right sides of the upper groove (1) and the lower groove (2). The connectors and locking parts are disassembled and assembled by lifting and pulling. The left and right sides of the upper groove (1) are reinforced with reinforcing components to enhance the stability of the wire cover (3) after it is installed with the upper groove (1).
2. The groove positioning structure for a screen according to claim 1, characterized in that: The connectors at the top and bottom of the wire cover (3) are configured as snap-fit connectors (4), which are L-shaped and have a semi-circular end.
3. The groove positioning structure for a screen according to claim 2, characterized in that: The engaging components on the left and right sides of the upper groove (1) and lower groove (2) are set as "U"-shaped fitting grooves (5), and the end of the fitting groove (5) is set as a barb-shaped edge, and the barb-shaped edge is misaligned and abuts against the semi-circular end of the fastener (4).
4. The groove positioning structure for a screen according to claim 3, characterized in that: The wire cover (3) uses a vertical sliding method to position and connect the buckle (4) and the fitting groove (5) for disassembly and separation. The wire cover (3) is generally set as a "π" shaped structure, and the upper groove (1) and lower groove (2) are generally set as "I" shaped structures.
5. The groove positioning structure for a screen according to claim 4, characterized in that: The reinforcing components on the left and right sides of the upper groove (1) include a through sliding connection of a pull plate (6), and a spring (8) is connected between the pull plate (6) and the upper groove (1).
6. The groove positioning structure for a screen according to claim 5, characterized in that: The end of the pull plate (6) is equipped with a positioning pin (7), the end of the positioning pin (7) is set as a triangular structure, and the positioning pin (7) is slidably connected to the inner walls on both sides of the upper groove (1).
7. The groove positioning structure for a screen according to claim 6, characterized in that: The end of the positioning pin (7) is engaged with the slot (9), which is located on the outside of the top fastener (4) of the wire cover (3).