A conductive rotating structure

The conductive rotating structure, designed with a split force structure and multiple toggle components, solves the problems of axial offset and wear caused by the unidirectional design of toggle components in existing socket adapters, thus improving operational flexibility and safety.

CN224400874UActive Publication Date: 2026-06-23QINGMI BEIJING SCI & TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
QINGMI BEIJING SCI & TECH
Filing Date
2025-05-27
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

The existing conductive rotating structure of the socket adapter has problems such as the unidirectional design of the toggle part which is prone to axial displacement, limited operational flexibility, and the rigid connection between the conductive arm and the rotating body which is prone to wear and short circuit risk.

Method used

It adopts a split force structure design, realizes torque decomposition and transmission through connectors, uses multiple toggle components to form a complementary angle layout, and combines elastic contact points to reduce axial offset and evenly distribute external force.

Benefits of technology

It improves operational flexibility and angle adaptability, reduces the risk of overload of the toggle component, and lowers the probability of wear and short circuit.

✦ Generated by Eureka AI based on patent content.

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Abstract

The novel conductive rotating structure comprises a conductive rotating body, which comprises a rotating part and a pushing part, and the rotating part is connected with the pushing part; the pushing part comprises a connecting piece connected with the rotating part, the upper part of the connecting piece is sleeved with the end of the rotating part; a pushing piece is sleeved with the connecting piece and located at the upper part of the connecting piece, the connecting piece and the rotating part are driven to rotate through the pushing piece; a conductive arm is located at the end of the connecting piece, and the conductive arm is provided with a polar conductive piece.
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Description

Technical Field

[0001] This invention relates to the field of electrical connection technology, and more specifically, to a conductive rotating structure. Background Technology

[0002] In existing technologies, the conductive rotating structure of socket adapters often uses a single rotating shaft in conjunction with a fixed conductive plate. This typically presents the following drawbacks: the toggle component is mostly a unidirectional design, with a single toggle rigidly connected to the rotating shaft; applying force from one side during operation can easily cause axial displacement. Furthermore, the fixed angle of the single toggle component cannot accommodate multi-angle toggle requirements, limiting operational flexibility. In addition, the rigid connection between the conductive arm and the rotating body lacks a buffer structure, making the contacts prone to wear after repeated rotation; and the rotary switch of the socket adapter often relies on a single conductive arm to synchronously control both poles, posing a short-circuit risk. Utility Model Content

[0003] The purpose of this invention is to provide a conductive rotating structure to overcome the shortcomings of the prior art.

[0004] To achieve the above objectives, this invention provides a conductive rotating structure, comprising:

[0005] A conductive rotating body includes a rotating part and a actuating part, wherein the rotating part and the actuating part are connected; wherein the actuating part includes:

[0006] A connector is connected to the rotating part, and the upper part of the connector is fitted onto the end of the rotating part;

[0007] A toggle element is sleeved on the connector and located at the upper part of the connector. The toggle element drives the connector and the rotating part to rotate.

[0008] A conductive arm is located at the end of the connector, and the conductive arm is provided with a polarized conductive element.

[0009] In one embodiment, the conductive arm is located at the end of the connector and includes:

[0010] The cavity structure is integrally connected to the lower end of the connector in an L-shape.

[0011] A polar conductive element is fixedly installed in the cavity of the cavity structure at one end and extends out of the cavity structure at the other end, and is provided with a contact point.

[0012] In one embodiment, the other end of the polar conductive element is a bent structure, and the contact is mounted on the protruding side of the bent structure.

[0013] In one embodiment, the actuating element includes a first actuating element and a second actuating element, wherein the first actuating element and the second actuating element are disposed opposite to the connecting element.

[0014] In one embodiment, the first and second actuating members are installed in an A-shape, and the actuating members are perpendicular to the connecting member.

[0015] In one embodiment, the upper surfaces of the first actuating member and the second actuating member are respectively provided with a protrusion, forming a stepped structure with the lower surface.

[0016] In one embodiment, the actuating element further includes a third actuating element and a fourth actuating element, the third actuating element and the fourth actuating element being located on both sides of the first actuating element and the second actuating element, respectively, and forming an angle with the first actuating element and the second actuating element, respectively.

[0017] In one embodiment, the rotating part has a threaded hole at its end, and the rotating part is threadedly connected to the upper part of the connector through the threaded hole.

[0018] In one embodiment, one end of the polar conductive element is provided with a threaded hole, and the bolt is used to fix the polar conductive element in the cavity of the cavity structure through the threaded hole.

[0019] As can be seen from the above solutions, the advantages of this new invention are:

[0020] This invention provides a conductive rotating structure that employs a split force structure, decomposing the rotating part and the actuating part into independent, socketed modules. Torque is decomposed and transmitted through connecting parts, reducing axial offset. Furthermore, multiple actuating parts are arranged in a complementary angle layout, resulting in a more even distribution of external force during rotation and preventing overload of any one actuating part. In the event of failure of any one actuating part, the other actuating parts engage to maintain limited rotation.

[0021] To provide a better understanding of the above and other aspects of this invention, specific embodiments are described below in conjunction with the accompanying drawings, but these are not intended to limit the scope of protection of this invention. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the conductive rotation structure provided in Embodiment 1 of the present invention;

[0023] Figure 2 for Figure 1 An exploded view of the conductive rotating structure in the illustrated embodiment;

[0024] Figure 3 This is a schematic diagram of the conductive rotation structure provided in Embodiment 2 of the present invention;

[0025] Figure 4 for Figure 3 An exploded view of the conductive rotating structure in the illustrated embodiment;

[0026] Figure 5 This is a schematic diagram of the structure of the socket adapter provided in Embodiment 3 of this invention;

[0027] Figure 6 This is a schematic diagram of the internal structure of the socket adapter in a power-off state.

[0028] In the attached figures, the following labels are used:

[0029] 1-Rotating outer casing;

[0030] 2-Base;

[0031] 3-Connector;

[0032] 4- Rotate the power-on assembly;

[0033] 40-Conductive Rotational Structure;

[0034] 41-Conductive rotating body;

[0035] 411 - Rotating part;

[0036] 412 - Actuating part;

[0037] 4121 - Connector;

[0038] 4122 - Toggle element;

[0039] 4122A - First toggle element;

[0040] 4122B - Second toggle element;

[0041] 4122C - Third toggle element;

[0042] 4122D - Fourth toggle element;

[0043] 4122' - Protrusion;

[0044] 42-Conductive arm;

[0045] 421 - Cavity structure;

[0046] 422 - Polarized conductive components;

[0047] 4221 - Bending structure;

[0048] 423 - Contact;

[0049] A1, A2 - Threaded holes;

[0050] A3 - Bolt;

[0051] 50-Linkage Rotation Structure;

[0052] 510, 511-end;

[0053] 512 - First rotating protrusion;

[0054] 513 - Second rotating protrusion. Detailed Implementation

[0055] To make the objectives, technical solutions, and advantages of this invention clearer, the invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that references to "an embodiment," "embodiment," "example embodiment," etc., in the specification refer to embodiments that may include specific features, structures, or characteristics, but do not necessarily include these specific features, structures, or characteristics. Furthermore, such expressions do not refer to the same embodiment. Moreover, when describing specific features, structures, or characteristics in conjunction with embodiments, whether or not explicitly described, it is indicated that incorporating such features, structures, or characteristics into other embodiments is within the knowledge scope of those skilled in the art.

[0056] It should be noted that in this specification, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Certain terms are used in the specification and subsequent claims to refer to specific modules, components, or parts. Those skilled in the art will understand that users or manufacturers may use different names or terms to refer to the same module, component, or part. This specification and subsequent claims do not distinguish modules, components, or parts by differences in name, but by differences in function. The terms "comprising" and "including" used throughout the specification and subsequent claims are open-ended and should be interpreted as "including but not limited to." Furthermore, the term "connection" here includes any direct and indirect electrical connection means. Indirect electrical connection means include connections via other means.

[0057] Furthermore, in the following description and claims, numerous terms will be used, which should be defined as having the following meanings. The singular forms “a” and “described” include plural referents unless the context clearly specifies otherwise. “Preferred” or “preferred” indicates that the event or situation described below may or may not occur, and the description includes both the case where the event occurs and the case where the event does not occur. In the description of this invention, terms such as “lateral,” “longitudinal,” “upper,” “lower,” “front,” “rear,” “left,” “right,” “vertical,” “horizontal,” “top,” “bottom,” “inner,” “outer,” and “about,” or “approximately,” “substantially,” “left and right,” etc., indicating orientation or positional relationships or parameters, are based on the orientation or positional relationships shown in the accompanying drawings, and are only for the convenience of describing this invention and simplifying the description. They do not indicate or imply that the device or element referred to must have a specific orientation, a specific size, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this invention.

[0058] Example 1

[0059] refer to Figure 1 , Figure 2 As shown in the figure, this embodiment provides a conductive rotating structure 40, comprising: a conductive rotating body 41, including a rotating part 411 and a toggle part 412, wherein the rotating part 411 is connected to the toggle part 412; and a conductive arm 42, connected to the end of the toggle part 412, wherein the conductive arm 42 is provided with a polarized conductive element 422.

[0060] As a preferred embodiment, please refer to the following: Figure 2 As shown, the actuating part 412 specifically includes: a connecting member 4121 connected to the rotating part 411, with the upper part of the connecting member 4121 sleeved over the end of the rotating part 411; and an actuating member 4122 sleeved on the connecting member 4121 and located at the upper part of the connecting member 4121, which drives the connecting member 4121 and the rotating part 411 to rotate. In one embodiment, the actuating member 4122 is arranged perpendicularly to the connecting member 4121.

[0061] In one specific embodiment, the rotating part 411 has a threaded hole A1 at its end, and the rotating part 411 is threadedly connected to the upper part of the connector 4121 through the threaded hole A1. Of course, this invention is not limited to threaded connections. In this embodiment, the rotating parts 411 are sleeved together to form a spatial constraint, which, together with the threaded locking mechanism, effectively suppresses axial displacement during rotation.

[0062] In one specific embodiment, the conductive arm 42 is located at the end of the connector 4121. The conductive arm 42 specifically includes: a cavity structure 421, which is integrally and L-shapedly fixedly connected to the lower end of the connector 4121; and a polar conductive element 422, one end of which is fixedly installed in the cavity of the cavity structure 421, and the other end extends out of the cavity structure 421 and is provided with a contact 423. In one embodiment, the polar conductive element 422 is configured as an N-polar conductive sheet and / or an L-polar conductive sheet.

[0063] In one specific embodiment, see detailed reference. Figure 2 As shown, one end of the polar conductive element 422 is provided with a threaded hole A2, and the polar conductive element 422 is fixedly installed in the cavity of the cavity structure 421 by a bolt A3 passing through the threaded hole A2. Of course, this invention is not limited to threaded connections.

[0064] In one specific embodiment, see detailed reference. Figure 2 As shown, the other end of the polar conductive element 422 is a bent structure 4221, and the contact 423 is installed on the protruding side of the bent structure 4221. The bent structure 4221 makes the contact 423 form a directional elastic contact.

[0065] Further reference Figure 1 , Figure 2 As shown, in one embodiment, the actuating member 4122 includes a first actuating member 4122A and a second actuating member 4122B, which are disposed opposite to the connecting member 4121. In a specific embodiment, the first actuating member 4122A and the second actuating member 4122B are installed in an A-shape. The first actuating member 4122A and the second actuating member 4122B are movably sleeved on the connecting member 4121, and the angle between them is adjustable. In this embodiment, the A-shaped structure of the first actuating member 4122A and the second actuating member 4122B disposed opposite to each other, combined with the adjustable-angle sleeve connection, forms a bidirectional force transmission path, significantly improving operational sensitivity and angle adaptability.

[0066] In one specific embodiment, the upper surfaces of the first actuating member 4122A and the second actuating member 4122B are respectively provided with a protrusion 4122', forming a stepped structure with the lower surface, and the protrusion 4122' plays a mechanical limiting role.

[0067] Example 2

[0068] refer to Figure 2 , Figure 3As shown in the figure, this embodiment provides a conductive rotating structure 40, comprising: a conductive rotating body 41, including a rotating part 411 and a toggle part 412, wherein the rotating part 411 is connected to the toggle part 412; and a conductive arm 42, connected to the end of the toggle part 412, wherein the conductive arm 42 is provided with a polarized conductive element 422.

[0069] As a preferred embodiment, please refer to the following: Figure 2 As shown, the actuating part 412 specifically includes: a connecting member 4121 connected to the rotating part 411, with the upper part of the connecting member 4121 sleeved over the end of the rotating part 411; and an actuating member 4122 sleeved on the connecting member 4121 and located at the upper part of the connecting member 4121, which drives the connecting member 4121 and the rotating part 411 to rotate. In one embodiment, the actuating member 4122 is arranged perpendicularly to the connecting member 4121.

[0070] In one specific embodiment, the rotating part 411 has a threaded hole A1 at its end, and the rotating part 411 is threadedly connected to the upper part of the connector 4121 through the threaded hole A1. Of course, this invention is not limited to threaded connections. In this embodiment, the rotating parts 411 are sleeved together to form a spatial constraint, which, together with the threaded locking mechanism, effectively suppresses axial displacement during rotation.

[0071] In one specific embodiment, the conductive arm 42 is located at the end of the connector 4121. The conductive arm 42 specifically includes: a cavity structure 421, which is integrally and L-shapedly fixedly connected to the lower end of the connector 4121; and a polar conductive element 422, one end of which is fixedly installed in the cavity of the cavity structure 421, and the other end extends out of the cavity structure 421 and is provided with a contact 423. In one embodiment, the polar conductive element 422 is configured as an N-polar conductive sheet and / or an L-polar conductive sheet.

[0072] In one specific embodiment, see detailed reference. Figure 2 As shown, one end of the polar conductive element 422 is provided with a threaded hole A2, and the polar conductive element 422 is fixedly installed in the cavity of the cavity structure 421 by a bolt A3 passing through the threaded hole A2. Of course, this invention is not limited to threaded connections.

[0073] In one specific embodiment, see detailed reference. Figure 2 As shown, the other end of the polar conductive element 422 is a bent structure 4221, and the contact 423 is installed on the protruding side of the bent structure 4221. The bent structure 4221 makes the contact 423 form a directional elastic contact.

[0074] Further reference Figure 1 , Figure 2As shown, in one embodiment, the actuating member 4122 includes a first actuating member 4122A and a second actuating member 4122B, which are disposed opposite to the connecting member 4121. In a specific embodiment, the first actuating member 4122A and the second actuating member 4122B are installed in an A-shape. The first actuating member 4122A and the second actuating member 4122B are movably sleeved on the connecting member 4121, and the angle between them is adjustable. In this embodiment, the A-shaped structure of the first actuating member 4122A and the second actuating member 4122B being disposed opposite to each other, combined with the adjustable-angle sleeve connection, significantly improves the operational sensitivity and angle adaptability.

[0075] In one specific embodiment, the upper surfaces of the first actuating member 4122A and the second actuating member 4122B are respectively provided with a protrusion 4122', forming a stepped structure with the lower surface, and the protrusion 4122' plays a mechanical limiting role.

[0076] The main difference from Embodiment 1 described above is that in this embodiment, the actuating element 4122 further includes a third actuating element 4122C and a fourth actuating element 4122D. The third actuating element 4122C and the fourth actuating element 4122D are located on either side of the first actuating element 4122A and the second actuating element 4122B, respectively, and are at an angle to the first actuating element 4122A and the second actuating element 4122B, respectively. That is, the third actuating element 4122C is located outside the first actuating element 4122A and maintains a certain angle with it; the fourth actuating element 4122D is located outside the second actuating element 4122B and maintains a certain angle with it. In this embodiment, the third actuating element 4122C and the fourth actuating element 4122D form a complementary angular arrangement with the first and second actuating elements, respectively. This design makes the external force distribution more even during rotational operation and avoids overload on one side of the actuating element. In addition, the third actuating element 4122C and the fourth actuating element 4122D can be used as auxiliary operating elements. When the first and second actuating elements are worn or jammed by foreign objects, the third and fourth actuating elements can still maintain the limit rotation function by cutting in at a lateral angle.

[0077] Example 3

[0078] This embodiment also provides a socket adapter, such as Figures 5-6 As shown, where Figure 5 A schematic diagram of the overall structure of the socket adapter is shown. Figure 6 A schematic diagram of the internal structure of the socket adapter in a power-off state is shown.

[0079] The socket adapter includes a rotating outer shell 1 and a base 2. The rotating outer shell 1 is rotatably fitted onto the base 2. A connector 3 is fixedly connected to the bottom of the base 2. A rotating power-on assembly 4, electrically connected to the connector structure, is provided on the rotating outer shell 1. The rotating power-on assembly 4 further includes two conductive rotating structures 40, which are disposed through the base 2 and respectively adopt the conductive rotating structures of Embodiment 1 and Embodiment 2 described above. One conductive rotating structure 40 has an N-pole conductive plate on its conductive arm 42, and the other conductive rotating structure 40 has an L-pole conductive plate on its conductive arm 42. The N-pole and L-pole conductive plates are located at the connector 3. The specific structure of the conductive rotating structure 40 will not be described in detail here. The rotating power-on assembly 4 also includes a linkage rotating structure 50, which is fixedly connected to the rotating outer shell 1. The linkage rotating structure 50 drives the conductive rotating structure 40 to rotate, causing the conductive arm 42 to rotate. The N-pole and L-pole conductive plates are located at the connector 3. The user rotates the rotating outer shell 1, causing the linkage rotating structure 41 to rotate, which in turn causes the rotating part 411 of the conductive rotating structure 40 to rotate, thereby placing the N-pole conductive plate and the L-pole conductive plate in a retracted or unfolded state relative to the connector 3. When the N-pole conductive plate and the L-pole conductive plate are in the retracted state, the power is off. When the N-pole conductive plate and the L-pole conductive plate are in the unfolded state, the power is on.

[0080] Please see Figure 6 In one specific embodiment, the linkage rotation structure 50 is an integral structure with two ends fixedly connected to the rotating housing 1. Specifically, one end 511 located on the left side of the linkage rotation structure 50 is fixedly connected to the rotating housing 1, while the other end 510 located on the right side of the linkage rotation structure 50 is fixedly connected to the rotating housing 1.

[0081] In a preferred embodiment, the linkage rotation structure 50 is provided with a first rotation protrusion 512 and a second rotation protrusion 513. The linkage rotation structure 50 abuts against the actuating member 4122 of the conductive rotation structure 40 through the first rotation protrusion 512 and the second rotation protrusion 513. The actuating member 4122 cooperates with the linkage rotation structure 50 to rotate the conductive arm 42. Furthermore, when the rotating housing 1 is rotated, the first rotation protrusion 512 and the second rotation protrusion 513 of the linkage rotation structure 50 rotate with the rotating housing 1, thereby driving the actuating member 4122 of the conductive rotation structure 40 to rotate. At the same time, the actuating member 4122 of the conductive rotation structure 40 drives the rotating part 411 and the conductive arm 42 to rotate. By rotating the conductive arm 421, the N-pole conductive sheet 4211 and the L-pole conductive sheet 4212 rotate relative to the plug-in member 3 between a retracted state and an unfolded state.

[0082] The conductive rotating structure and socket adapter provided by this invention have been described in detail above. The various embodiments in the specification are described in a progressive manner, with each embodiment focusing on its differences from other embodiments. Similar or identical parts between embodiments can be referred to interchangeably.

[0083] Of course, there may be other embodiments of this invention. Without departing from the spirit and essence of this invention, those skilled in the art can make various corresponding changes and modifications based on this invention, but these corresponding changes and modifications should all fall within the protection scope of the appended claims.

Claims

1. A conductive rotating structure, characterized in that, Include: A conductive rotating body includes a rotating part and a actuating part, wherein the rotating part and the actuating part are connected; wherein the actuating part includes: A connector is connected to the rotating part, and the upper part of the connector is fitted onto the end of the rotating part; A toggle element is sleeved on the connector and located at the upper part of the connector. The toggle element drives the connector and the rotating part to rotate. A conductive arm is located at the end of the connector, and the conductive arm is provided with a polarized conductive element.

2. The conductive rotating structure according to claim 1, characterized in that, The conductive arm comprises: The cavity structure is integrally connected to the lower end of the connector in an L-shape. A polar conductive element is fixedly installed in the cavity of the cavity structure at one end and extends out of the cavity structure at the other end, and is provided with a contact point.

3. The conductive rotating structure according to claim 2, characterized in that, The other end of the polar conductive element is a bent structure, and the contact is installed on the protruding side of the bent structure.

4. The conductive rotating structure according to claim 1, characterized in that, The actuating element is perpendicular to the connecting element.

5. The conductive rotating structure according to claim 1 or 4, characterized in that, The actuating element includes a first actuating element and a second actuating element, which are disposed opposite to the connecting element.

6. The conductive rotating structure according to claim 5, characterized in that, The first and second toggle components are installed in an A-shape.

7. The conductive rotating structure according to claim 5, characterized in that, The upper surfaces of the first and second actuating components are respectively provided with a protrusion, forming a stepped structure with the lower surfaces.

8. The conductive rotating structure according to claim 5, characterized in that, The actuating element further includes a third actuating element and a fourth actuating element, which are located on both sides of the first actuating element and the second actuating element, respectively, and are at an angle to the first actuating element and the second actuating element, respectively.

9. The conductive rotating structure according to claim 1, characterized in that, The rotating part has a threaded hole at its end, and the rotating part is threadedly connected to the upper part of the connector through the threaded hole.

10. The conductive rotating structure according to claim 2, characterized in that, One end of the polar conductive element is provided with a threaded hole, and the bolt is used to fix the polar conductive element in the cavity of the cavity structure through the threaded hole.