A data decentralized plug

By combining the slider, card slot, and magnetic metal plate of the data-distributed plug, the problems of messy wiring and unstable data transmission caused by centralized plugs are solved, realizing the integrity and stability of the connection cable and improving the ease of operation and aesthetics of the equipment.

CN224342683UActive Publication Date: 2026-06-09SHANXI JIAYE WADE TECHNOLOGY DEVELOPMENT CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANXI JIAYE WADE TECHNOLOGY DEVELOPMENT CO LTD
Filing Date
2025-09-18
Publication Date
2026-06-09

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  • Figure CN224342683U_ABST
    Figure CN224342683U_ABST
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Abstract

The utility model discloses a kind of data decentralized plug, specifically related to plug technical field, including main line board, the side of main line board is sequentially connected with first connecting wire, second connecting wire, third connecting wire, fourth connecting wire, fifth connecting wire from top to bottom, first connecting wire, second connecting wire, third connecting wire, fourth connecting wire, fifth connecting wire middle part is equipped with slider, the middle part of slider is equipped with extrusion hole.The utility model first through the cooperation of the card strip and the card slot of being set, adjacent connecting wire can be fixed together, further enhance the integrity between connecting wire, prevent relative displacement between connecting wire too large due to external force pulling during use, affect data transmission or cause structural damage, and by the slider along connecting wire sliding being set, by extrusion hole to each connecting wire exert certain constraint force, the connecting wire of dispersion is gathered together, prevent it swing and scatter at will, improve use effect.
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Description

Technical Field

[0001] This utility model relates to the field of plug technology, and more specifically, to a data distribution plug. Background Technology

[0002] In today's digital age, data transmission equipment is being used more and more widely, and the demand for data interaction between various electronic devices is growing. However, existing data plugs have many problems in practical use. Traditional data plugs often adopt a centralized design, with multiple plugs integrated together. When connecting multiple devices, this not only occupies a lot of space, but also easily leads to plugs getting tangled and interfering with each other, causing great inconvenience to operation. For example, in places with dense equipment such as server rooms, the centralized layout of plugs will lead to messy cabling, increasing maintenance difficulty and troubleshooting time.

[0003] During data transmission, connection cables are often scattered, which not only affects aesthetics but may also loosen due to accidental pulling, affecting the stability and reliability of data transmission. In scenarios where mobile devices are frequently moved, such as connecting projection equipment in a conference room, tangled connection cables are easily stepped on or tripped over, causing data transmission interruptions and affecting the normal conduct of the meeting. Therefore, a data-distributed plug is proposed. Utility Model Content

[0004] In order to overcome the above-mentioned defects of the prior art, the present invention provides a data distribution plug to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a data distribution plug, comprising a main board, on one side of which a first connecting line, a second connecting line, a third connecting line, a fourth connecting line, and a fifth connecting line are sequentially connected from top to bottom. A slider is fitted into the middle of each of the first, second, third, fourth, and fifth connecting lines. A compression hole is formed in the middle of the slider, allowing it to slide along the connecting lines. The compression hole applies a certain constraint force to each connecting line, bringing the dispersed connecting lines together and preventing them from swinging or scattering randomly. Simultaneously, the suitable cross-sectional shape ensures that the slider provides uniform constraint to each connecting line, preventing any single connecting line from being damaged due to excessive compression.

[0006] One end of the first connecting line, the second connecting line, the third connecting line, the fourth connecting line, and the fifth connecting line is respectively connected to a first plug, a second plug, a third plug, a fourth plug, and a fifth plug;

[0007] The bottom of the first and second connecting lines, and the top of the fourth and fifth connecting lines are all fixedly connected with locking strips. The opposite sides of the second and fourth connecting lines, and the upper and lower sides of the third connecting line are all provided with locking slots. The circular cross-section of the locking strips facilitates insertion into the slots and reduces frictional resistance during insertion and removal. The cooperation between the locking strips and the slots can fix adjacent connecting lines together, further enhancing the integrity between the connecting lines and preventing excessive relative displacement between the connecting lines due to external force during use, which could affect data transmission or cause structural damage. The bottom of the first and second plugs, and the top of the fourth and fifth plugs are all embedded with metal plates. The opposite sides of the second and fourth plugs, and the upper and lower sides of the third plug are all embedded with magnetic plates. The magnetic plates and metal plates can be used to position multiple plugs when not in use.

[0008] Preferably, one end of the locking strip has a circular cross-sectional shape, and the locking strip is adapted to the locking slot. The locking strip, with its circular cross-section positioned in the middle of the locking slot, facilitates insertion into the slot and reduces frictional resistance during insertion and removal. The cooperation between the locking strip and the locking slot can fix adjacent connecting wires together, further enhancing the overall integrity between the connecting wires and preventing excessive relative displacement between the connecting wires due to external pulling during use, which could affect data transmission or cause structural damage.

[0009] Preferably, the combined cross-sectional shape of the first connecting line, the second connecting line, the third connecting line, the fourth connecting line, and the fifth connecting line is adapted to the extrusion hole.

[0010] Preferably, the first, second, third, fourth, and fifth connecting lines are all located in the middle of the extrusion hole. The slider can slide along the connecting lines, applying a certain constraint force to each connecting line through the extrusion hole, thus gathering the dispersed connecting lines together and preventing them from swinging or scattering randomly. At the same time, the suitable cross-sectional shape ensures that the slider exerts uniform constraint on each connecting line, avoiding damage to any connecting line due to excessive extrusion.

[0011] Preferably, the metal plate and the magnetic plate correspond to each other and are attached together, so that multiple plugs can be attached and positioned when not in use.

[0012] Preferably, the outer surfaces of the first, second, third, fourth, and fifth connecting lines are all made of rubber. The rubber material has good flexibility, which allows the connecting lines to be bent at will without breaking easily, adapting to different connection angle requirements.

[0013] Preferably, the data transmission pin in the middle of the main board is connected to one end of the wire in the middle of the first connecting line, the second connecting line, the third connecting line, the fourth connecting line, and the fifth connecting line. One end of the main board is connected to a data port for data connection. As the core control and connection component of the entire plug, the main board can integrate the data transmitted by each plug and interact with external devices through the data port, realizing the data concentration and distribution of multiple plugs.

[0014] The technical effects and advantages of this utility model are as follows:

[0015] 1. This utility model firstly uses the combination of the set clips and slots to fix adjacent connecting wires together, further enhancing the integrity between the connecting wires and preventing excessive relative displacement between the connecting wires due to external force during use, which could affect data transmission or cause structural damage. Furthermore, by using the set slider to slide along the connecting wires and applying a certain constraint force to each connecting wire through the extrusion holes, the scattered connecting wires are gathered together, preventing them from swinging and scattering randomly, thus improving the usage effect.

[0016] 2. This utility model also utilizes the combination of magnetic plates and metal plates to ensure that multiple plugs fit tightly together when not in use, preventing damage from collisions. Furthermore, by making the outer surfaces of the first, second, third, fourth, and fifth connecting lines all rubber, the locking effect of the locking strips and slots can be improved, and damage can be avoided, thus affecting the performance. The main board, as the core control and connection component of the entire plug, can integrate the data transmitted by each plug and interact with external devices through the data port, realizing the centralization and distribution of data from multiple plugs.

[0017] In summary, through the interaction of the above-mentioned multiple functions, adjacent connecting lines can be fixed together, further enhancing the overall integrity between the connecting lines. This prevents excessive relative displacement between the connecting lines due to external force during use, which could affect data transmission or cause structural damage, and prevents them from swinging and scattering at will. 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 structure of this utility model from another angle.

[0020] Figure 3 This is a schematic diagram of the cross-sectional structure of the slider of this utility model.

[0021] Figure 4 This is a schematic diagram showing the disassembled structure of the slider and multiple connecting lines of this utility model.

[0022] The attached diagram is labeled as follows: 1. Main board; 2. First plug; 3. Second plug; 4. Third plug; 5. Fourth plug; 6. Fifth plug; 7. Magnetic plate; 8. Metal plate; 9. First connecting wire; 10. Second connecting wire; 11. Third connecting wire; 12. Fourth connecting wire; 13. Fifth connecting wire; 14. Slider; 15. Locking strip; 16. Locking slot; 17. Compression hole. Detailed Implementation

[0023] 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.

[0024] As attached Figure 1-3 The data distribution connector shown includes a main board 1. From top to bottom, a first connecting line 9, a second connecting line 10, a third connecting line 11, a fourth connecting line 12, and a fifth connecting line 13 are sequentially connected to one side of the main board 1. A slider 14 is fitted around the middle of each of the connecting lines 9, 10, 11, 12, and 13. A compression hole 17 is formed in the middle of the slider 14. The slider 14 can slide along the connecting lines, applying a certain constraint force to each connecting line through the compression hole 17, thus gathering the dispersed connecting lines together and preventing them from swinging or scattering randomly. Simultaneously, the suitable cross-sectional shape ensures that the slider 14 provides uniform constraint to each connecting line, preventing any connecting line from being damaged due to excessive compression.

[0025] One end of the first connecting wire 9, the second connecting wire 10, the third connecting wire 11, the fourth connecting wire 12, and the fifth connecting wire 13 are respectively connected to the first plug 2, the second plug 3, the third plug 4, the fourth plug 5, and the fifth plug 6;

[0026] The bottom of the first connecting line 9 and the second connecting line 10, as well as the top of the fourth connecting line 12 and the fifth connecting line 13, are all fixedly connected with locking strips 15. The opposite sides of the second connecting line 10 and the fourth connecting line 12, as well as the upper and lower sides of the third connecting line 11, are provided with slots 16. The circular cross-section of the locking strip 15 facilitates insertion into the slot 16 and reduces frictional resistance during insertion and removal. The cooperation between the locking strip 15 and the slot 16 can fix adjacent connecting lines together, further enhancing the integrity between the connecting lines and preventing excessive relative displacement between the connecting lines due to external force during use, which could affect data transmission or cause structural damage. The bottom of the first plug 2 and the second plug 3, as well as the top of the fourth plug 5 and the fifth plug 6, are all embedded with metal plates 8. The opposite sides of the second plug 3 and the fourth plug 5, as well as the upper and lower sides of the third plug 4, are all embedded with magnetic plates 7. The magnetic plates 7 and the metal plates 8 can be used to position multiple plugs when not in use.

[0027] As attached Figure 1-4 As shown, one end of the card strip 15 has a circular cross-sectional shape. The card strip 15 is adapted to the card slot 16 and is located in the middle of the card slot 16. The combined cross-sectional shape of the first connecting line 9, the second connecting line 10, the third connecting line 11, the fourth connecting line 12, and the fifth connecting line 13 is adapted to the extrusion hole 17. The first connecting line 9, the second connecting line 10, the third connecting line 11, the fourth connecting line 12, and the fifth connecting line 13 are all located in the middle of the extrusion hole 17. The metal plate 8 and the magnetic plate 7 correspond to each other and are in contact. The outer surfaces of the first connecting line 9, the second connecting line 10, the third connecting line 11, the fourth connecting line 12, and the fifth connecting line 13 are all made of rubber. The circular cross-section of the card strip 15 facilitates insertion into the card slot 16 and reduces frictional resistance during insertion and removal. The cooperation between the clip 15 and the slot 16 secures adjacent connecting wires together, further enhancing the overall integrity of the connecting wires and preventing excessive relative displacement between them due to external pulling during use, which could affect data transmission or cause structural damage. The slider 14 can slide along the connecting wires, applying a certain constraint force to each connecting wire through the compression hole 17, gathering the scattered connecting wires together and preventing them from swinging and scattering randomly. At the same time, the suitable cross-sectional shape ensures that the slider 14 provides uniform constraint to each connecting wire, avoiding damage to any connecting wire due to excessive compression. The magnetic plate 7 and the metal plate 8 can be used to position multiple plugs when not in use. The rubber material has good flexibility, allowing the connecting wires to be bent freely without breaking easily, adapting to different connection angle requirements.

[0028] As attached Figure 1 , 2As shown, the data transmission pins in the middle of the main board 1 are connected to one end of the wires in the middle of the first connecting line 9, the second connecting line 10, the third connecting line 11, the fourth connecting line 12, and the fifth connecting line 13. One end of the main board 1 is connected to a data port for data connection. As the core control and connection component of the entire plug, the main board 1 can integrate the data transmitted by each plug and interact with external devices through the data port, realizing the data concentration and distribution of multiple plugs.

[0029] The working principle of this utility model is as follows: When in use, the data port at one end of the main board 1 interacts with the external device. After selecting a suitable plug, the multiple connecting cables can be dispersed by sliding the slider 14 and pulling the connecting cable, which makes it convenient to connect the multiple plugs to the corresponding positions, thereby realizing the data concentration and distribution of multiple plugs.

[0030] When not in use, the sliding slider 14 can be used to press the multiple connecting wires together, causing the locking strips 15 of the multiple connecting wires to be inserted into the slots 16, thereby fixing the multiple connecting wires and enhancing the overall integrity between the connecting wires. Furthermore, the magnetic attraction of the metal plate 8 and the magnetic plate 7 can make the multiple plugs fit together tightly, preventing them from swinging or scattering.

[0031] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A data distributed connector, comprising a main board (1), characterized in that: The main line plate (1) is connected from top to bottom to one side with a first connecting line (9), a second connecting line (10), a third connecting line (11), a fourth connecting line (12), and a fifth connecting line (13). A slider (14) is sleeved in the middle of the first connecting line (9), the second connecting line (10), the third connecting line (11), the fourth connecting line (12), and the fifth connecting line (13). A pressing hole (17) is opened in the middle of the slider (14). One end of the first connecting line (9), the second connecting line (10), the third connecting line (11), the fourth connecting line (12), and the fifth connecting line (13) is respectively connected to the first plug (2), the second plug (3), the third plug (4), the fourth plug (5), and the fifth plug (6); The bottom of the first connecting line (9) and the second connecting line (10) and the top of the fourth connecting line (12) and the fifth connecting line (13) are fixedly connected with a clip (15). The opposite sides of the second connecting line (10) and the fourth connecting line (12) and the upper and lower sides of the third connecting line (11) are provided with a slot (16). The bottom of the first plug (2) and the second plug (3) and the top of the fourth plug (5) and the fifth plug (6) are provided with a metal plate (8). The opposite sides of the second plug (3) and the fourth plug (5) and the upper and lower sides of the third plug (4) are provided with a magnetic plate (7).

2. The data distribution plug according to claim 1, characterized in that: The cross-sectional shape of one end of the card strip (15) is set to be circular. The card strip (15) is adapted to the card slot (16). The card strip (15) is located in the middle of the card slot (16).

3. The data distribution plug according to claim 1, characterized in that: The combined cross-sectional shape of the first connecting line (9), the second connecting line (10), the third connecting line (11), the fourth connecting line (12), and the fifth connecting line (13) is adapted to the extrusion hole (17).

4. A data distribution plug according to claim 1, characterized in that: The first connecting line (9), the second connecting line (10), the third connecting line (11), the fourth connecting line (12), and the fifth connecting line (13) are all located in the middle of the extrusion hole (17).

5. A data distribution plug according to claim 1, characterized in that: The metal plate (8) and the magnetic plate (7) correspond to each other and are attached together.

6. A data distribution plug according to claim 1, characterized in that: The outer surfaces of the first connecting line (9), the second connecting line (10), the third connecting line (11), the fourth connecting line (12), and the fifth connecting line (13) are all made of rubber.

7. A data distribution plug according to claim 1, characterized in that: The data transmission pin position in the middle of the main board (1) is connected to one end of the middle wire of the first connecting line (9), the second connecting line (10), the third connecting line (11), the fourth connecting line (12), and the fifth connecting line (13). One end of the main board (1) is connected to a data port for data connection.