Split type via conductive slip ring

The conductive slip ring, with its split design, utilizes threaded connections and snap-fit ​​structures to achieve adjustable wire diameter, solving the problem of existing devices being unable to adjust it, thus expanding its applicability and reducing maintenance costs.

CN224458892UActive Publication Date: 2026-07-03SHENZHEN JIACHI ELECTROMECHANICAL TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN JIACHI ELECTROMECHANICAL TECH CO LTD
Filing Date
2025-06-26
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing conductive slip ring devices are integral structures, which cannot be adjusted according to the diameter of the internal wires, resulting in significant limitations.

Method used

It adopts a split design, including a shell, a storage mechanism, a clamping mechanism, a connecting component, and a bonding component. The wire diameter can be adjusted through threaded connection and snap-fit ​​structure, ensuring close contact between the carbon block and the wire. It has a wide range of applications and facilitates the individual replacement of worn parts.

Benefits of technology

It enables flexible adjustment based on wire diameter, avoiding non-conductivity, improving applicability and utilization, and reducing maintenance costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a split-type through-hole conductive slip ring, relating to the field of conductive technology. The split-type through-hole conductive slip ring includes a housing, a placement mechanism, and a clamping mechanism. A snap-fit ​​pin is provided on the top of the housing. The placement mechanism includes a fixing ring on the housing and a threaded shaft inside the fixing ring. An internal threaded groove is formed in the fixing ring, and the threaded shaft is threadedly connected to the internal threaded groove. The fixing ring is also threadedly connected to the threaded shaft. The clamping mechanism includes a connecting component inside the housing and a fitting component on the connecting component. The connecting component and the fitting component are snap-fitted together. This mechanism can be adjusted according to the diameter of the internally installed wire, allowing the two sets of carbon blocks to fit against the outer wall of the wire, preventing non-conductivity. It also has a wide range of applications and higher utilization. Furthermore, the fitting component can be detached from the connecting component, facilitating the individual replacement of worn parts and reducing maintenance costs.
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Description

Technical Field

[0001] This utility model relates to the field of conductive technology, and in particular to a split-type through-hole conductive slip ring. Background Technology

[0002] Chinese patent document CN219917855U discloses a conductive slip ring brush device. This utility model relates to the field of brush technology and discloses a conductive slip ring brush device, including a brush holder, a spring installed inside the brush holder, a carbon block mounting seat slidably installed inside the brush holder, a replaceable carbon block mounted on the carbon block mounting seat, one end of the spring connected to the inner wall of the brush holder, and the other end of the spring connected to the carbon block mounting seat. The carbon block mounting seat and the brush holder are connected by a limiting component, and the brush holder is provided with a warning component. When the brush of this utility model is in use, when the carbon block is worn to a certain thickness, conductive block one and conductive block two will come into contact with each other. At this time, the closed circuit formed by the light strip, conductive block one, and conductive block two is in a closed state, the light strip will be energized and illuminate, the illuminated light strip can serve as a reminder to the operator, facilitating timely replacement of the carbon block, ensuring the normal operation of the brush, and improving the practicality of the brush.

[0003] The aforementioned device is constructed as a single unit, thus it cannot be adjusted according to the diameter of the internal wires, which is a significant limitation. To address this issue, improvements have been made. Utility Model Content

[0004] The purpose of this invention is to provide a split-type through-hole conductive slip ring, which can solve the problem that the above-mentioned device is constructed as a single piece, and therefore cannot be adjusted according to the diameter of the internal wires, which is a significant limitation.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a split-type through-hole conductive slip ring, comprising a housing, a placement mechanism, and a clamping mechanism. The top of the housing is provided with a snap fastener. The placement mechanism includes a fixing ring disposed on the housing and a threaded shaft disposed within the fixing ring. An internal thread groove is provided in the fixing ring, and the threaded shaft is threadedly connected to the internal thread groove. The fixing ring is threadedly connected to the threaded shaft. The clamping mechanism includes a connecting component disposed within the housing and a fitting component disposed on the connecting component. The connecting component and the fitting component are snap-fitted together.

[0006] Preferably, the placement mechanism further includes an arc-shaped frame and a torsion bar. The top of the threaded shaft is rotatably connected to the arc-shaped frame, and the bottom of the threaded shaft is fixedly connected to the torsion bar. This mechanism can support the bottom of the wire, preventing the wire from slipping and causing the device to fail to conduct electricity normally.

[0007] Preferably, the connecting assembly includes a U-shaped fixing frame, a fixing rod, a bidirectional threaded rod, and a handle. The U-shaped fixing frame is housed within the outer casing. A fixing rod is fixedly connected to one inner wall of the U-shaped fixing frame, and a bidirectional threaded rod is rotatably connected to one inner wall of the fixing rod. A handle is rotatably connected to one side of the U-shaped fixing frame. The bonding assembly includes a T-shaped moving block, a connecting plate, a T-shaped locking block, and a carbon block. The T-shaped moving block is threadedly connected to the outer wall of the bidirectional threaded rod. The connecting plate is housed within the outer casing. A T-shaped locking block is fixedly connected to the top of the connecting plate, and a carbon block is fitted onto the outer wall of the connecting plate. This mechanism can be adjusted according to the diameter of the internally installed wire, allowing the two sets of carbon blocks to adhere to the outer wall of the wire, preventing non-conductivity. It also has a wide range of applications and higher utilization. Furthermore, the bonding assembly can be detached from the connecting assembly, facilitating the individual replacement of worn parts and reducing maintenance costs.

[0008] Preferably, the T-shaped moving block has a T-shaped slot, and the T-shaped card block is snapped into the T-shaped slot, thus the T-shaped moving block and the T-shaped card block are snapped into each other.

[0009] Preferably, there are two sets of the T-shaped moving block, connecting plate, T-shaped card block and carbon block, which are arranged symmetrically.

[0010] Preferably, one side of the bidirectional threaded rod passes through the U-shaped fixing frame and is fixedly connected to the throttle handle. The T-shaped moving block has a hole, the fixing rod is located in the hole, and the T-shaped moving block and the fixing rod are slidably connected.

[0011] Compared with the prior art, the beneficial effects of this utility model are:

[0012] (1) This split-type through-hole conductive slip ring, through the cooperation of the outer shell, the placement mechanism, the buckle, the clamping mechanism, the connecting component, the U-shaped fixing frame, the fixing rod, the bidirectional threaded rod, the throttle, the bonding component, the T-shaped moving block, the connecting plate, the T-shaped card block and the carbon block, addresses the shortcomings of the above-mentioned devices which are built as a whole and therefore cannot be adjusted according to the diameter of the internal wires, thus having a large limitation. This mechanism can be adjusted according to the diameter of the internal wires, so that the two sets of carbon blocks can be bonded to the outer wall of the wires, avoiding non-conductivity. At the same time, it has a wider range of applications and higher utilization rate. In addition, the bonding component can be removed from the connecting component, which facilitates the individual replacement of worn parts and reduces maintenance costs.

[0013] (2) The split-type through-hole conductive slip ring, through the cooperation of the outer shell, the placement mechanism, the fixing ring, the threaded shaft, the arc frame, the torsion bar, the snap pin and the clamping mechanism, can support the bottom of the wire and prevent the wire from slipping and causing the equipment to fail to conduct electricity normally. Attached Figure Description

[0014] The present invention will be further described below with reference to the accompanying drawings and embodiments:

[0015] Figure 1 This is a perspective view of the present utility model;

[0016] Figure 2 This is a perspective view of the storage mechanism of this utility model;

[0017] Figure 3 This is a perspective view of the clamping mechanism of this utility model;

[0018] Figure 4 This is an enlarged view of part A of this utility model.

[0019] Reference numerals: 1. Outer shell; 2. Storage mechanism; 201. Fixing ring; 202. Threaded shaft; 203. Arc-shaped frame; 204. Torsion bar; 3. Snap pin; 4. Clamping mechanism; 41. Connecting assembly; 411. U-shaped fixing frame; 412. Fixing rod; 413. Bidirectional threaded rod; 414. Turn handle; 42. Fitting assembly; 421. T-shaped moving block; 422. Connecting plate; 423. T-shaped locking block; 424. Carbon block. Detailed Implementation

[0020] This section will describe in detail the specific embodiments of the present utility model. The preferred embodiments of the present utility model are shown in the accompanying drawings. The purpose of the drawings is to supplement the textual description with graphics, so that people can intuitively and vividly understand each technical feature and the overall technical solution of the present utility model, but they should not be construed as limiting the scope of protection of the present utility model.

[0021] Please see Figure 1-4 This utility model provides a technical solution: a split-type through-hole conductive slip ring, including a housing 1, a placement mechanism 2, and a clamping mechanism 4. The top of the housing 1 is provided with a snap pin 3. The placement mechanism 2 includes a fixing ring 201 disposed on the housing 1 and a threaded shaft 202 disposed in the fixing ring 201. The fixing ring 201 has an internal thread groove. The threaded shaft 202 is threadedly connected to the internal thread groove. The fixing ring 201 is threadedly connected to the threaded shaft 202. The clamping mechanism 4 includes a connecting component 41 disposed in the housing 1 and a fitting component 42 disposed on the connecting component 41. The connecting component 41 and the fitting component 42 are snapped together.

[0022] Furthermore, the storage mechanism 2 also includes an arc-shaped frame 203 and a torsion bar 204. The top of the threaded shaft 202 is rotatably connected to the arc-shaped frame 203, and the bottom of the threaded shaft 202 is fixedly connected to the torsion bar 204. Twisting the torsion bar 204 causes the threaded shaft 202 to rotate clockwise, which in turn causes the arc-shaped frame 203 to move upward. The arc-shaped frame 203 supports the bottom of the wire. This mechanism can support the bottom of the wire and prevent the wire from slipping and causing the equipment to fail to conduct electricity normally.

[0023] Furthermore, the connecting assembly 41 includes a U-shaped fixing bracket 411, a fixing rod 412, a bidirectional threaded rod 413, and a handle 414. The U-shaped fixing bracket 411 is housed inside the outer casing 1. A fixing rod 412 is fixedly connected to one inner wall of the U-shaped fixing bracket 411, and a bidirectional threaded rod 413 is rotatably connected to one inner wall of the fixing rod 412. A handle 414 is rotatably connected to one side of the U-shaped fixing bracket 411. The bonding assembly 42 includes a T-shaped moving block 421, a connecting plate 422, a T-shaped locking block 423, and a carbon block 424. The T-shaped moving block 421 is threadedly connected to the outer wall of the bidirectional threaded rod 413. The connecting plate 422 is housed inside the outer casing 1. A T-shaped locking block 423 is fixedly connected to the top of the connecting plate 422, and a carbon block 424 is fitted onto the outer wall of the connecting plate 422. In use, the U-shaped fixing bracket 411 is connected to the outer shell 1 by the buckle 3. The handle 414 is rotated according to the diameter of the wire. The forward rotation of the handle 414 drives the bidirectional threaded rod 413 to rotate. The bidirectional threaded rod 413 drives the T-shaped moving block 421 to converge. The T-shaped moving block 421 drives the connecting plate 422 to converge through the T-shaped locking block 423. The carbon blocks 424 of the connecting plate 422 converge. The two sets of carbon blocks 424 contact the wire. This mechanism can be adjusted according to the diameter of the wire set inside, so that the two sets of carbon blocks 424 can fit against the outer wall of the wire to avoid non-conductivity. At the same time, it has a wide range of applications and higher utilization rate. In addition, the bonding component 42 can be removed from the connecting component 41, which facilitates the individual replacement of worn parts and reduces maintenance costs.

[0024] Secondly, a T-shaped slot is provided in the T-shaped moving block 421, and a T-shaped locking block 423 is locked in the T-shaped slot. The T-shaped moving block 421 and the T-shaped locking block 423 are locked in place. There are two sets of T-shaped moving blocks 421, connecting plates 422, T-shaped locking blocks 423 and carbon blocks 424, which are arranged symmetrically. One side of the bidirectional threaded rod 413 passes through the U-shaped fixing frame 411 and is fixedly connected to the throttle 414. A hole is provided on the T-shaped moving block 421, and the fixing rod 412 is located in the hole. The T-shaped moving block 421 and the fixing rod 412 are slidably connected.

[0025] Working principle: In use, the U-shaped fixing bracket 411 is connected to the outer shell 1 by the buckle 3. The handle 414 is rotated according to the diameter of the wire. The forward rotation of the handle 414 drives the bidirectional threaded rod 413 to rotate. The bidirectional threaded rod 413 drives the T-shaped moving block 421 to converge. The T-shaped moving block 421 drives the connecting plate 422 to converge through the T-shaped locking block 423. The carbon blocks 424 of the connecting plate 422 converge. The two sets of carbon blocks 424 contact the wire. The torsion bar 204 is twisted. The torsion bar 204 drives the threaded shaft 202 to rotate forward. The forward rotation of the threaded shaft 202 drives the arc frame 203 to move upward. The arc frame 203 supports the bottom of the wire.

[0026] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.

Claims

1. A split via conductive slip ring, characterized in that, include: The outer casing (1) has a snap fastener (3) on the top; The storage mechanism (2) includes a fixing ring (201) disposed on the outer shell (1) and a threaded shaft (202) disposed in the fixing ring (201). The fixing ring (201) has an internal thread groove, the threaded shaft (202) is threadedly connected to the internal thread groove, and the fixing ring (201) is threadedly connected to the threaded shaft (202). The clamping mechanism (4) includes a connecting component (41) disposed in the housing (1) and a fitting component (42) disposed on the connecting component (41), wherein the connecting component (41) and the fitting component (42) are snapped together.

2. The split-via conductive slip ring of claim 1, wherein: The storage mechanism (2) also includes an arc frame (203) and a torsion bar (204). The top of the threaded shaft (202) is rotatably connected to the arc frame (203), and the bottom of the threaded shaft (202) is fixedly connected to the torsion bar (204).

3. The split-via conductive slip ring of claim 2, wherein: The connecting assembly (41) includes a U-shaped fixing frame (411), a fixing rod (412), a bidirectional threaded rod (413), and a throttle (414). The U-shaped fixing frame (411) is provided inside the outer shell (1). The fixing rod (412) is fixedly connected to one inner wall of the U-shaped fixing frame (411). The bidirectional threaded rod (413) is rotatably connected to one inner wall of the fixing rod (412). The throttle (414) is rotatably connected to one side of the U-shaped fixing frame (411). The bonding component (42) includes a T-shaped moving block (421), a connecting plate (422), a T-shaped locking block (423), and a carbon block (424). The outer wall of the bidirectional threaded rod (413) is threaded with the T-shaped moving block (421). The connecting plate (422) is provided inside the outer shell (1). The top of the connecting plate (422) is fixedly connected with the T-shaped locking block (423). The outer wall of the connecting plate (422) is fitted with a carbon block (424).

4. The split-via conductive slip ring of claim 3, wherein: The T-shaped moving block (421) has a T-shaped slot, and the T-shaped card block (423) is snapped into the T-shaped slot. The T-shaped moving block (421) and the T-shaped card block (423) are snapped into each other.

5. The split-via conductive slip ring of claim 4, wherein: The number of the T-shaped moving block (421), connecting plate (422), T-shaped card block (423) and carbon block (424) are in two sets and are arranged symmetrically.

6. The split-via conductive slip ring of claim 5, wherein: One side of the bidirectional threaded rod (413) is fixedly connected to the handle (414) through the U-shaped fixing frame (411). A hole is opened on the T-shaped moving block (421), and the fixing rod (412) is located in the hole. The T-shaped moving block (421) and the fixing rod (412) are slidably connected.