A partitionable wire core
By designing partitioned layers and partitioned components, the problems of signal distortion and crosstalk of multiple wire cores under electromagnetic interference environments are solved, enabling partitioned placement and adjustment of wire cores and improving communication quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DONGGUAN TOYA ELECTRONIC TECH CO LTD
- Filing Date
- 2025-06-13
- Publication Date
- 2026-06-16
AI Technical Summary
When multiple wires are exposed to electromagnetic interference or generate interference themselves, signal distortion and crosstalk occur, affecting communication quality.
By employing partitioned layers and partitioned components, and through the design of a central rotating rod and multi-group partitioned plates, the core can be placed in partitions. The sliding connection of the protrusions and concave blocks and the elastic connection of the springs allow the partitioned plates to rotate and adjust the size and number of partitioned areas.
It effectively prevents mutual interference between wire cores, improves communication quality, and enables convenient partitioning settings and adjustments.
Smart Images

Figure CN224361629U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of wire cores, and more particularly to a partitionable wire core. Background Technology
[0002] A wire core is a series of single yarns, filaments, or fillers arranged in the center of a braided or multi-stranded yarn, and is wrapped with a cable to form a complete wire.
[0003] Electric wires generally consist of an outer cable and multiple inner cores, hence the name multi-core cable. Since the multiple cores within a multi-core cable are usually distributed together, with no direct separation between the cores or between some cores, differences in some cores can lead to signal distortion or increased bit error rate. This can occur in special environments or under specific usage conditions, such as when the wire is located in an environment with high electromagnetic interference or when it contains cores that generate interference. For example, high-speed signal lines may experience electromagnetic interference (EMI) from nearby power lines or high-current cables, leading to signal distortion or increased bit error rate. Capacitive / inductive coupling between adjacent cores (such as in unshielded twisted pairs) can also cause crosstalk, affecting communication quality. Therefore, a partitioned core design is needed to address these issues. Utility Model Content
[0004] The purpose of this invention is to provide a partitionable wire core, which solves the problem that it is inconvenient to partition multiple wire cores when placing them.
[0005] To achieve this objective, the present invention adopts the following technical solution:
[0006] A partitionable wire core, comprising:
[0007] Partition layer;
[0008] The partitioning component includes a central rotating rod located in the middle of the partitioning layer and a multi-group partitioning plate located on the outer surface of the central rotating rod. A second sliding groove is formed on the outer surface of the central rotating rod at the position of the partitioning plate. A protrusion and a concave block are slidably connected inside the second sliding groove. The protrusion and the concave block are movably inserted into each other. A first spring is provided inside the concave block. The other end of the first spring is connected to the protruding part of the protrusion. The concave block is fixedly connected to the partitioning plate.
[0009] Furthermore, the number of partition plates in each group is set to two, and the partition plates rotate clockwise or counterclockwise around the center of the centerline rotating rod.
[0010] Furthermore, the protruding part of the protrusion is inserted into the recessed part of the concave block, forming a square block that slides inside the second groove.
[0011] Furthermore, a first groove is provided in the inner ring of the partition layer at the position of the partition plate, and a slider connected to the partition plate slides inside the first groove.
[0012] Furthermore, the outer ring of the partition layer is fitted with a cable plating layer, and both the partition layer and the cable plating layer are cylindrical tube structures.
[0013] Furthermore, partitioned regions are formed within the partitioned layers and among multiple sets of partitioned layers, and wire cores are provided within the partitioned regions.
[0014] Furthermore, the interior of the cable plating layer is provided with a cavity, and a plug is movably inserted into the exterior of the cable plating layer above the cavity. One end of the plug passes vertically through the cavity and is inserted into the interior of the partition layer.
[0015] Furthermore, a movable block is located inside the cavity and moves up and down. A second spring is sleeved on the outer surface of the insertion rod, and the two ends of the second spring abut against the movable block and the cable plating, respectively.
[0016] Furthermore, the partition layer has a socket at the position of the plug rod, and the plug rod is movably inserted into the socket.
[0017] Furthermore, a limiting groove is longitudinally formed in the inner ring of the cable plating layer, and a limiting block connected to the partition layer slides inside the limiting groove.
[0018] Compared with the prior art, the present invention has the following beneficial effects:
[0019] 1. Through layered zones and partitioning components, multiple wire cores can be placed in separate areas to prevent mutual interference. Each group of partitioning boards consists of two boards, and the spacing between the boards forms the partitioned areas. Different wire cores can be placed in different areas. Simultaneously, workers can push and pull the partitioning boards, causing them to rotate along the center of the rotating rod via a recessed block. This rotates one of the partitioning boards in each group, creating a gap between the two partitioning boards in each group, thus forming the partitioned areas. The size and number of partitioned areas can be changed according to the needs of the wire cores, achieving a convenient partitioning effect and ensuring the proper placement of multiple wire cores.
[0020] 2. By using partition layers, cable plating, and insert rods, along with limiting grooves and limiting blocks, when it is necessary to pull the partition layer out of the cable plating, the insert rod can be pulled out of the partition layer, allowing the worker to grasp the partition layer and pull it out of the cable plating. This also causes the limiting block to slide inside the limiting groove. After the partition layer is pulled out, the worker can easily rotate the partition plate and adjust the partition area. Attached Figure Description
[0021] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0022] The structures, proportions, sizes, etc., shown in the accompanying drawings of this specification are only for the purpose of assisting those skilled in the art in understanding and reading the content disclosed in the specification, and are not intended to limit the implementation conditions of this utility model. Therefore, they have no substantial technical significance. Any modifications to the structure, changes in the proportions, or adjustments to the size, without affecting the effects and purposes that this utility model can produce, should still fall within the scope of the technical content disclosed in this utility model.
[0023] Figure 1 This is a schematic diagram of the overall frontal sectional view;
[0024] Figure 2 This is a schematic diagram of the overall side sectional view;
[0025] Figure 3 A 3D schematic diagram of the partition components;
[0026] Figure 4 for Figure 1 Enlarged view of point A in the middle;
[0027] Figure 5 for Figure 2 Enlarged diagram of point B in the middle.
[0028] Illustration: 1. Partition layer; 2. Cable plating; 3. Central rotating rod; 4. Partition plate; 5. First slide groove; 501. Slider; 6. Second slide groove; 7. Protrusion; 701. Concave block; 702. First spring; 8. Cavity; 9. Movable block; 10. Insert rod; 11. Second spring; 12. Wire core; 13. Limiting groove; 1301. Limiting block. Detailed Implementation
[0029] To make the utility model's objectives, features, and advantages more apparent and understandable, the technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the embodiments described below 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 skilled in the art without creative effort are within the scope of protection of the present utility model.
[0030] In the description of this utility model, it should be understood that the terms "upper," "lower," "top," "bottom," "inner," and "outer," etc., indicating the orientation or positional relationship are based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model. It should be noted that when a component is considered to be "connected" to another component, it can be directly connected to the other component or there may be a component centrally located at the same time.
[0031] The technical solution of this utility model will be further described below with reference to the accompanying drawings and specific embodiments.
[0032] The partitionable wire core provided in this utility model embodiment is suitable for handling scenarios where multiple wire cores are used in electromagnetic interference environments or where multiple wire cores themselves can generate interference. By improving the structure of the partitionable wire core, it has the advantages of allowing multiple wire cores to be placed in different partition areas as needed to prevent interference.
[0033] This utility model embodiment provides a partitionable wire core; please refer to [link / reference]. Figures 1-4 The system includes: a partition layer 1 and a partitioning component. The partitioning component includes a central rotating rod 3 located in the middle of the partition layer 1 and a multi-partition partitioning plate 4 located on the outer surface of the central rotating rod 3. A second groove 6 is formed on the outer surface of the central rotating rod 3 at the position of the partitioning plate 4. A protrusion 7 and a concave block 701 are slidably connected inside the second groove 6. The protrusion 7 and the concave block 701 are movably inserted into each other. A first spring 702 is provided inside the concave block 701. One end of the first spring 702 is connected to the groove of the concave block 701, and the other end of the first spring 702 is connected to the protrusion of the protrusion 7. The concave block 701 is fixedly connected to the partitioning plate 4. The protrusion of the protrusion 7 is inserted into the concave block 701 and forms a square block that slides inside the second groove 6.
[0034] like Figures 1-4As shown, partition layer 1 serves as the base structure for partitioning the wire core 12, providing physical support and the basis for area division. The central rotating rod 3 acts as the axis for the rotation and sliding of partition plate 4. The radial position adjustment of partition plate 4 is achieved through the second sliding groove 6, and the hollow structure design reduces weight. Simultaneously, as the core component for dynamic adjustment, it supports fine-tuning of the position of partition plate 4. Multiple partition plates 4 directly participate in the physical isolation of the wire core 12 partitions. Each group of two partition plates 4 forms an angle, and the width of the partition area is adjusted by pushing the partition plate 4 to rotate. The modular design allows for flexible configuration of the number of partitions to adapt to different wire core 12 specifications. The second sliding groove 6 provides a sliding track for the protrusion 7 and concave block 701, realizing the radial extension and retraction of partition plate 4. The sliding connection design allows partition plate 4 to adjust according to the wire core 12. The dynamic adjustment of the position enhances compatibility. The protrusion 7 and the concave block 701 (movably connected) slide stably in the groove through the square block structure. The concave block 701 is fixed to the partition plate 4, and the protrusion 7 is elastically connected by the first spring 702. The spring buffer mechanism reduces mechanical wear and allows the partition plate 4 to finely adjust its position when under force, avoiding hard collisions. The first spring 702 connects the protrusion 7 and the concave block 701, providing elastic restoring force, absorbing the stress generated by cable bending or vibration, extending the life of the partition structure, and assisting the partition plate 4 to automatically reset to the preset position. At the same time, the partition plate 4 is set along the length of the wire core, and the longitudinal length of the partition plate 4 is the same as the length of the wire core. The partition plate 4 can be made of flexible material to ensure that it can bend when the cable plating layer 2 needs to be bent.
[0035] Specifically, the partition plate 4 is connected to the first slide groove 5 of the partition layer 1 via the slider 501, the protrusion 7-concave block 701 mechanism is embedded in the second slide groove 6 of the central rotating rod 3, and the first spring 702 is in its natural state.
[0036] Radial adjustment: Push the partition plate 4 to slide along the second slide groove 6, the protrusion 7 and the concave block 701 move synchronously in the slide groove, and at the same time drive the slider 501 to slide inside the first slide groove 5, thereby changing the radius of the partition area.
[0037] Angle rotation: Rotate partition plate 4 clockwise / counterclockwise to adjust the partition angle.
[0038] In terms of overall usage, the spacing between each group of partition plates 4 forms a partition area. When each group of partition plates 4 is pushed and rotated along the center point of the rotating rod 3, the state between each group of partition plates 4 changes from being close together to being open, and an angle is formed between them, and a gap is formed between them, which is a new partition area. At the same time, when the partition plate 4 is rotated, the size of other partition areas will be adjusted. When the partition plate 4 is rotated, the protrusion 7 and the concave block 701 will slide inside the second slide groove 6, providing a support base for the partition plate 4.
[0039] Please see Figure 1 and Figure 2The number of partition plates 4 in each group is set to two, and the partition plates 4 rotate clockwise or counterclockwise along the center of the center rod.
[0040] like Figure 1 and Figure 2 As shown, each group has two partition plates 4. The two partition plates 4 are symmetrically distributed about the central rotating rod 3, forming an adjustable angle structure. The partition plates 4 rotate clockwise or counterclockwise along the central rotating rod 3. The movement mechanism is that the partition plates 4 are adjusted in angle by the protrusions 7 and concave blocks 701 on the second slide groove 6 about the central rotating rod 3, so as to adjust the size and number of partition areas.
[0041] Please see Figure 1 , Figure 2 and Figure 3 The inner ring of partition layer 1 is provided with a first groove 5 at the position of partition plate 4, and a slider 501 connected to partition plate 4 slides inside the first groove 5.
[0042] like Figure 1 , Figure 2 and Figure 3 As shown, the inner ring of partition layer 1 is provided with an arc-shaped first groove 5 at the position of partition plate 4. The groove is provided according to the number of partition plates 4 to ensure that partition plates 4 are more stable during movement and rotation, further improving stability and fixation, and making it easier for partition plates 4 to block and isolate wire core 12.
[0043] Please see Figure 1 and Figure 2 The outer ring of partition layer 1 is fitted with cable plating layer 2, and both partition layer 1 and cable plating layer 2 are cylindrical tube structures.
[0044] like Figure 1 and Figure 2 As shown, the cable plating layer 2 is wrapped around the outside of the partition layer 1, which can improve the protection and safety of the wire core 12, and also ensure that the partition board 4 is more stable inside the partition layer 1.
[0045] Please see Figure 1 The partitioned area is formed within the partitioned layer 1 and between multiple partitioned layers 1, and the wire core 12 is set in the partitioned area.
[0046] like Figure 1 As shown, the spacing between each partition plate 4 can form a partition area, and the size and number of partition areas are determined by the rotation angle between the two partition plates 4.
[0047] Please see Figure 2The inside of the cable plating layer 2 is provided with a cavity 8. A plug rod 10 is movably inserted into the outside of the cable plating layer 2 above the cavity 8. One end of the plug rod 10 passes vertically through the cavity 8 and is inserted into the interior of the partition layer 1. A movable block 9 moves up and down inside the cavity 8. A second spring 11 is sleeved on the outer surface of the plug rod 10. The two ends of the second spring 11 abut against the movable block 9 and the cable plating layer 2, respectively. A socket is provided in the partition layer 1 at the position of the plug rod 10. The plug rod 10 is movably inserted into the interior of the socket.
[0048] like Figure 2 As shown, the inner cavity 8 of the cable plating layer 2 has an opening at the top for the insertion of the plug rod 10, providing movement space for the movable block 9 and the second spring 11, ensuring that the plug rod 10 is inserted vertically into the socket of the partition layer 1, avoiding deflection. The plug rod 10 passes vertically through the cavity 8 and its end is inserted into the socket of the partition layer 1, mechanically locking the partition layer 1 and the plating layer to prevent relative rotation or axial displacement. The movable block 9 slides up and down in the cavity 8 and contacts the surface of the plug rod 10. The second spring 11 is sleeved on the plug rod 10, with both ends abutting against the movable block 9 and the plating layer, providing continuous thrust to prevent the plug rod 10 from loosening due to vibration.
[0049] Specifically, during the unlocking process, in the pull-out stage: pulling out the plug rod 10 compresses the spring of the movable block 9, and the plug rod 10 exits the socket; the spring stores energy, and the plug rod 10 quickly returns to the top of the cavity 8. In the adaptive stage: after unlocking, the partition layer 1 can rotate or slide freely to adjust the angle or position of the partition plate 4; when the plug rod 10 is reinserted, the spring buffer ensures the alignment accuracy of the plug rod 10 with the socket.
[0050] Please continue reading. Figure 2 A limiting groove 13 is longitudinally formed in the inner ring of the cable plating layer 2, and a limiting block 1301 connected to the partition layer 1 slides inside the limiting groove 13.
[0051] like Figure 2 As shown, partition layer 1 is located at the open end of cable plating layer 2, and partition layer 1 at the open end is disconnected from the overall partition layer. This allows the portion of partition layer 1 at the open end of cable plating layer 2 to be pulled out from within cable plating layer 2, thereby moving the partition component. When partition layer 1 is pulled out, the limiting block 1301 slides inside the limiting groove 13, preventing partition layer 1 from rotating. At the same time, the section of partition layer 1 pulled out is disconnected from the overall partition layer 1. Thus, after partition layer 1 and partition component are pulled out, it is easier for workers to grasp the partition plate 4 and push it to rotate, adjusting the partition area.
[0052] The above-described embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit it. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of this utility model.
Claims
1. A partitionable wire core, characterized in that, include: Partition layer (1); The partitioning component includes a central rotating rod (3) located in the middle of the partitioning layer (1) and a multi-group partitioning plate (4) located on the outer surface of the central rotating rod (3). A second sliding groove (6) is provided on the outer surface of the central rotating rod (3) at the position of the partitioning plate (4). A protrusion (7) and a concave block (701) are slidably connected inside the second sliding groove (6). The protrusion (7) and the concave block (701) are movably inserted together. A first spring (702) is provided inside the concave block (701). The other end of the first spring (702) is connected to the protrusion of the protrusion (7). The concave block (701) is fixedly connected to the partitioning plate (4).
2. The partitionable wire core according to claim 1, characterized in that, The number of partition plates (4) in each group is set to two, and the partition plates (4) rotate clockwise or counterclockwise along the center of the center rod.
3. A partitionable wire core according to claim 1, characterized in that, The protruding part of the protrusion (7) is inserted into the recess of the concave part (701) and forms a square block that slides inside the second groove (6).
4. A partitionable wire core according to claim 1, characterized in that, The inner ring of the partition layer (1) is provided with a first groove (5) at the position of the partition plate (4), and a slider (501) connected to the partition plate (4) slides inside the first groove (5).
5. A partitionable wire core according to claim 1, characterized in that, The outer ring of the partition layer (1) is provided with a cable plating layer (2), and both the partition layer (1) and the cable plating layer (2) are cylindrical tube structures.
6. A partitionable wire core according to claim 1, characterized in that, The partition layer (1) forms a partitioned region within itself and between multiple partition layers (1), and a wire core (12) is provided in the partitioned region.
7. A partitionable wire core according to claim 5, characterized in that, The inside of the cable plating layer (2) is provided with a cavity (8), and a plug (10) is movably inserted at a position above the cavity (8) on the outside of the cable plating layer (2). One end of the plug (10) passes vertically through the cavity (8) and is inserted into the inside of the partition layer (1).
8. A partitionable wire core according to claim 7, characterized in that, The cavity (8) has a movable block (9) that moves up and down inside. The outer surface of the plug (10) is fitted with a second spring (11). The two ends of the second spring (11) abut against the movable block (9) and the cable plating (2) respectively.
9. A partitionable wire core according to claim 7, characterized in that, The partition layer (1) has a socket at the position of the plug rod (10), and the plug rod (10) is movably inserted into the socket.
10. A partitionable wire core according to claim 5, characterized in that, The inner ring of the cable plating layer (2) has a longitudinally spaced limiting groove (13), and a limiting block (1301) connected to the partition layer (1) slides inside the limiting groove (13).