connector socket
By incorporating a panel, insulating mounting base, signal transmission components, and conductive components in the connector socket, and utilizing the detachable connection between the mounting platform and support base, along with structures such as snap-fit and positioning blocks, the reliability problem caused by loose fasteners is solved, achieving stable connection and efficient assembly and disassembly.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GUANGDONG FUYOUSI TECH CO LTD
- Filing Date
- 2025-08-22
- Publication Date
- 2026-07-14
AI Technical Summary
Existing connector sockets may experience loosening of fasteners due to vibration or thermal expansion and contraction after frequent plugging and unplugging or prolonged use, affecting the reliability of the connection.
The design incorporates a panel, an insulating mounting base, a signal transmission component, and a conductive component. The insulating mounting base includes a mounting platform and a support base. The mounting platform is detachably connected to the support base via a through hole and is stably connected by a first snap and a groove. It is further limited by a positioning block and a limiting block.
While ensuring ease of assembly and disassembly, it improves assembly stability and reliability, and avoids the problem of loose fasteners.
Smart Images

Figure CN224502446U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of socket technology, and in particular to a connector socket. Background Technology
[0002] Connectors and sockets are fundamental components of various electrical and electronic devices, used to realize detachable interfaces for current and signal transmission.
[0003] Existing connector sockets typically use screws or other fasteners to fix the insulating shell to the panel. While this connection method facilitates the installation and removal of the insulating shell from the panel and provides high stability, the fasteners may loosen due to vibration or thermal expansion and contraction after frequent plugging and unplugging or long-term use, affecting the reliability of the connection. Utility Model Content
[0004] The main objective of this invention is to provide a connector socket that ensures ease of installation and disassembly while improving assembly stability, thereby enhancing the reliability of the connector socket in use.
[0005] To achieve the above objectives, the connector socket proposed in this utility model includes:
[0006] The panel has through holes;
[0007] An insulating mounting base includes a mounting platform and a support base connected together. The mounting platform protrudes from one side of the support base and has a first mounting hole and a second mounting hole. The mounting platform passes through the through hole, and the support base is detachably connected to the through hole.
[0008] A signal transmission element is disposed within the first mounting hole; and
[0009] A conductive element is disposed within the second mounting hole.
[0010] In one embodiment, the connector socket further includes:
[0011] The mounting platform is provided with a groove, the groove is located near the through hole and communicates with the through hole; and
[0012] A first buckle is provided on the support base and extends toward the through hole. The first buckle is used to pass through the through hole to engage with the groove, thereby locking the panel between the first buckle and the support base.
[0013] In one embodiment, the first buckle has a first inclined surface at the end away from the support base, and the panel has a second inclined surface on the side facing the support base. The first inclined surface and the second inclined surface cooperate to guide the first buckle through the through hole.
[0014] In one embodiment, the support base has a positioning block on the side facing the panel, and the panel has a corresponding positioning groove, the positioning block being used to engage with the positioning groove.
[0015] In one embodiment, the insulating mounting base further includes:
[0016] An insulating bottom cover is provided, wherein the support base is provided with a receiving groove that communicates with both the first mounting hole and the second mounting hole, and the insulating bottom cover is detachably placed over the opening of the receiving groove.
[0017] In one embodiment, the outer periphery of the insulating bottom cover is provided with a second buckle, the second buckle extends toward the mounting platform, and the side wall of the support base is provided with a card interface communicating with the receiving groove, the second buckle being used to snap into the card interface.
[0018] In one embodiment, the inner wall of the receiving groove is provided with a limiting block, which is used to abut against the insulating bottom cover to restrict the movement of the insulating bottom cover.
[0019] In one embodiment, the panel is configured as metal.
[0020] In one embodiment, the signal transmission element has an elastic arm on its outer periphery, the elastic arm being inclined relative to the axis of the signal transmission element, and the elastic arm being used to abut against the inner wall of the first mounting hole.
[0021] In one embodiment, the first mounting hole is provided with a receiving hole and a limiting hole that are connected to each other. The limiting hole is coaxially arranged with the receiving hole, and the inner diameter of the limiting hole is smaller than the inner diameter of the receiving hole. The limiting hole is used to abut against the elastic arm.
[0022] In this embodiment of the technical solution, a panel, an insulating mounting base, a signal transmission component, and a conductive component are provided in the connector socket. The panel has a through hole; the insulating mounting base includes a mounting platform and a support base connected together. The mounting platform protrudes from one side of the support base and has a first mounting hole and a second mounting hole. The mounting platform passes through the through hole, and the support base is detachably connected to the through hole. The signal transmission component is located in the first mounting hole, and the conductive component is located in the second mounting hole. Compared with the prior art connector sockets that use fasteners to fix the insulating shell to the panel, the technical solution of this utility model provides a through hole in the panel, and the insulating mounting base has a corresponding mounting platform and support base. During installation, the mounting platform passes through the through hole, and the support base is connected to the through hole. During frequent insertion and removal or long-term use, the through hole can always limit the mounting platform, ensuring the installation stability of the insulating mounting base. During disassembly, only the support base needs to be removed from the panel, and the mounting platform needs to be pulled out of the through hole. In this way, while ensuring the ease of installation and disassembly of the connector socket, the assembly stability is improved, thereby improving the reliability of the connector socket in use. Attached Figure Description
[0023] 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 the structures shown in these drawings without creative effort.
[0024] Figure 1 A schematic diagram of a structure of an embodiment of the connector socket provided by this utility model;
[0025] Figure 2 for Figure 1 An exploded view of one embodiment;
[0026] Figure 3 for Figure 1 Exploded view of another embodiment;
[0027] Figure 4 A partial cross-sectional view of an embodiment of the signal transmission component and the first mounting hole provided by this utility model.
[0028] Explanation of icon numbers:
[0029] 100, Panel; 110, Through hole; 120, Positioning groove; 130, Groove; 140, Second inclined surface; 150, Enclosure; 151, First protrusion; 152, Second protrusion;
[0030] 210. Mounting platform; 211. First mounting hole; 2111. Receiving hole; 2112. Limiting hole; 212. Second mounting hole; 213. Limiting ring; 220. Support base; 221. Positioning block; 222. Snap-fit interface; 223. Limiting block; 230. Insulating bottom cover; 231. Protrusion;
[0031] 310. First buckle; 311. First extension; 312. First locking head; 313. First inclined surface; 320. Second buckle; 321. Second extension; 322. Second locking head; 323. Third inclined surface;
[0032] 400. Signal transmission component; 410. Flexible arm; 420. Clearance opening.
[0033] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0034] 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 scope of protection of the present utility model.
[0035] It should be noted that if the embodiments of this utility model involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.
[0036] Furthermore, if the embodiments of this utility model involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or" or "and / or" throughout the text includes three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where both A and B are satisfied simultaneously. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.
[0037] Connectors and sockets are fundamental components of various electrical and electronic devices, used to realize detachable interfaces for current and signal transmission.
[0038] Existing connector sockets typically use screws or other fasteners to fix the insulating shell to the panel. While this connection method can provide high stability, the installation and disassembly process is cumbersome and reduces the efficiency of assembly and disassembly.
[0039] This utility model proposes a connector socket that improves assembly stability while ensuring the ease of installation and disassembly of the connector socket, thereby improving the reliability of the connector socket in use.
[0040] Please see Figures 1 to 3In one embodiment, the connector socket includes a panel 100, an insulating mounting base, a signal transmission element 400, and a conductive element. The panel 100 has a through hole 110. The insulating mounting base includes a mounting platform 210 and a support base 220 connected to each other. The mounting platform 210 protrudes from one side of the support base 220 and has a first mounting hole 211 and a second mounting hole 212. The mounting platform 210 passes through the through hole 110. The support base 220 is detachably connected to the through hole 110. The signal transmission element 400 is disposed in the first mounting hole 211. The conductive element is disposed in the second mounting hole 212.
[0041] Panel 100 provides a mounting base for the connector socket. In one embodiment, a through hole 110 is provided at the center of panel 100 to provide a mounting position for a functional structure. In another embodiment, mounting holes are provided at the periphery of panel 100 for connection to an external mounting base, so as to mount the connector socket integrally onto the external mounting base. Of course, in other embodiments, panel 100 can also be connected to the external mounting base by means of snap-fit or magnetic connection, wherein the external mounting base can be a vehicle or other electrical equipment, etc., and is not limited here.
[0042] An insulating mounting base is used to mount functional structures. In one embodiment, the mounting platform 210 of the insulating mounting base protrudes from one side of the support base 220. The shape of the through hole 110 of the panel 100 is adapted to the shape of the mounting platform 210 to ensure that after the mounting platform 210 passes through the through hole 110 and the support base 220 is connected to the through hole 110, the inner circumference of the through hole 110 abuts against the outer circumference of the mounting platform 210, so that the through hole 110 limits the mounting platform 210. The outer diameter of the support base 220 is larger than the outer diameter of the through hole 110 and also larger than the outer diameter of the mounting platform 210, to ensure that after the mounting platform 210 passes through the through hole 110, the support base 220 does not protrude from the through hole 110, thus preventing the insulating mounting base from detaching from the panel 100. In one embodiment, the first mounting hole 211 and the second mounting hole 212 are spaced apart on the mounting platform 210. The first mounting hole 211 and the second mounting hole 212 are not connected, and the axial direction of both the first mounting hole 211 and the second mounting hole 212 is parallel to the axial direction of the through hole 110. The first mounting hole 211 and the second mounting hole 212 are the main locations for mounting functional structures. The material of the insulating mounting base can be polycarbonate, polyester, or other plastics or rubber, ensuring good insulation and structural strength; no limitations are imposed here.
[0043] The signal transmission component 400 is used to transmit signals. In one embodiment, the signal transmission component 400 is configured as a signal terminal, and the signal pin in the corresponding connector plug can be inserted into the first mounting hole 211 to mate with the signal terminal and make stable contact. Further, in one embodiment, the signal terminal is a stamped terminal, which has stable quality and can achieve a stable signal connection. In one embodiment, two first mounting holes 211 are provided at intervals, and a signal transmission component 400 is provided in each of the two first mounting holes 211 to mate with and make contact with different signal structures in the corresponding connector plug. Of course, in other embodiments, one or more signal transmission components 400 may be provided, and the signal transmission component 400 may also be configured as a coaxial inner conductor, etc., without limitation.
[0044] The conductive element is used to transmit current. In one embodiment, the conductive element is configured as a conductive terminal, and the conductive pin in the corresponding connector plug can be inserted into the second mounting hole 212 to mate with the conductive terminal and make stable contact. In one embodiment, there are two second mounting holes 212, and each of the two second mounting holes 212 has a conductive terminal for mate with different conductive structures in the corresponding connector plug. Of course, in other embodiments, only one or more conductive elements may be provided, and the conductive element may also be configured as a copper busbar, etc., without limitation.
[0045] In the technical solution of this utility model embodiment, a panel 100, an insulating mounting base, a signal transmission component 400, and a conductive component are provided in the connector socket. The panel 100 is provided with a through hole 110. The insulating mounting base includes a mounting platform 210 and a support base 220 connected to each other. The mounting platform 210 protrudes from one side of the support base 220 and is provided with a first mounting hole 211 and a second mounting hole 212. The mounting platform 210 passes through the through hole 110. The support base 220 is detachably connected to the through hole 110. The signal transmission component 400 is provided in the first mounting hole 211. The conductive component is provided in the second mounting hole 212. Compared to existing connector sockets that use fasteners to fix the insulating shell to the panel 100, the present invention provides a through hole 110 in the panel 100. The insulating mounting base has a mounting platform 210 and a support base 220. During installation, the mounting platform 210 passes through the through hole 110, and the support base 220 connects to the through hole 110. During frequent insertions and removals or prolonged use, the through hole 110 always limits the mounting platform 210, ensuring the installation stability of the insulating mounting base. During disassembly, simply remove the support base 220 from the panel 100 and pull the mounting platform 210 out of the through hole 110. Thus, while ensuring convenient installation and disassembly of the connector socket, it also improves assembly stability, thereby enhancing the reliability of the connector socket.
[0046] Please see Figures 1 to 3In one embodiment, the connector socket further includes a groove 130 and a first latch 310. The mounting platform 210 is provided with a groove 130, which is located near and connected to the through hole 110. The first latch 310 is located on the support base 220 and extends toward the through hole 110. The first latch 310 is used to penetrate the through hole 110 and engage with the groove 130 to lock the panel 100 between the first latch 310 and the support base 220.
[0047] In one embodiment, the first latch 310 includes a first extension 311 and a first latch head 312. The sidewall portion of the support base 220 is recessed inwards. One end of the first extension 311 is located in the recess, and the other end extends towards the through hole 110 in a direction parallel to the axial direction of the through hole 110. The first latch head 312 is located at the other end of the first extension 311 and extends outwards in a direction perpendicular to the axial direction of the through hole 110. In another embodiment, both opposite sidewalls of the support base 220 are provided with recesses, each recess having a first latch 310. The two first latches 310 are located on both sides of the mounting platform 210. The panel 100 is provided with two corresponding grooves 130, located at both ends of the through hole 110 and communicating with it. The first latches 310 are inserted into the corresponding grooves 130 to ensure the connection stability between the insulating mounting base and the panel 100. In one embodiment, the shape and size of the through hole 110 are adapted to the shape and size of the mounting platform 210, and both ends of the through hole 110 are additionally expanded away from the axial direction to engage with the groove 130, so that the first latch 310 can pass through the through hole 110. The inner wall of the expanded portion of the through hole 110 can abut against the outer wall of the first extension 311 to restrict the rotation of the first latch 310 about the axial direction of the through hole 110. The material of the first latch 310 can be engineering plastics such as polycarbonate or polypropylene, so that the first latch 310 has good insulation and structural strength while having a certain elastic deformation capability, ensuring that the first latch 310 can undergo a certain degree of elastic deformation in the direction perpendicular to the axial direction of the through hole 110 to pass through the through hole 110. Here, the specific material of the first latch 310 is not limited.
[0048] During installation, the mounting platform 210 and the first latch 310 simultaneously pass through the through hole 110, so that the first extension 311 engages with the expanded portion of the through hole 110, and the first latch 312 engages with the groove 130. At this time, the first latch 312 and the support base 220 are located on both sides of the through hole 110 and abut against the panel 100, thereby locking the panel 100 between the first latch 312 and the support base 220, thus achieving assembly. During disassembly, simply press the first latch 312 to move it in a direction close to the axial direction of the through hole 110 and pull the support base 220 to disengage the first latch 310 from the panel 100, thereby achieving disassembly.
[0049] In the technical solution of this utility model embodiment, by setting the first buckle 310 and the groove 130, on the one hand, the support base 220 and the panel 100 are detachably connected, and can be assembled and disassembled without the aid of external tools, making the operation simple; on the other hand, the first buckle 310 passes through the through hole 110 and is locked in a fixed position, which can further limit the mounting platform 210 and further improve the assembly stability.
[0050] Please see Figure 2 In one embodiment, the first buckle 310 has a first inclined surface 313 at the end away from the support base 220, and the panel 100 has a second inclined surface 140 on the side facing the support base 220. The first inclined surface 313 and the second inclined surface 140 cooperate to guide the first buckle 310 through the through hole 110.
[0051] In one embodiment, a first inclined surface 313 is disposed on the side of the first latch 312 facing the panel 100, and the side of the first inclined surface 313 away from the first extension 311 is inclined in a direction away from the through hole 110. A second inclined surface 140 is disposed opposite to the groove 130 on both sides of the through hole 110, and the end of the second inclined surface 140 away from the through hole 110 is inclined in a direction close to the support base 220. The end of the second inclined surface 140 close to the through hole 110 is connected to the expansion portion of the through hole 110. During the assembly and disassembly process, the second inclined surface 140 abuts against the first inclined surface 313, and the first inclined surface 313 can move along the second inclined surface 140 to guide the first latch 310 through the through hole 110.
[0052] The technical solution of this utility model embodiment, by setting the first inclined surface 313 and the second inclined surface 140, can guide the installation and removal of the insulating mounting base, thereby improving the installation and removal efficiency and convenience.
[0053] Please see Figure 2 In one embodiment, the support base 220 is provided with a positioning block 221 on the side facing the panel 100, and the panel 100 is provided with a corresponding positioning groove 120. The positioning block 221 is used to engage with the positioning groove 120.
[0054] In one embodiment, a positioning block 221 protrudes from the support base 220 and is located on the outer periphery of the mounting platform 210. A positioning groove 120 is located on the side of the panel 100 facing the support base 220, close to and connected to the through hole 110. When the mounting platform 210 penetrates the through hole 110, the positioning block 221 is correspondingly engaged in the positioning groove 120. In one embodiment, two positioning blocks 221 are provided, located on opposite sides of the mounting platform 210, and two positioning grooves 120 are correspondingly provided, allowing the positioning blocks 221 to be engaged one-to-one.
[0055] The technical solution of this utility model embodiment, by setting the positioning block 221 and the positioning groove 120, can limit the support base 220 after the insulating mounting base is installed on the panel 100, so as to avoid the support base 220 moving relative to the panel 100 and causing damage to the mounting platform 210, thereby improving the reliability of the connector socket.
[0056] Please see Figure 2 and Figure 3 In one embodiment, the insulating mounting base further includes an insulating bottom cover 230, and the support base 220 is provided with a receiving groove that communicates with both the first mounting hole 211 and the second mounting hole 212. The insulating bottom cover 230 is detachably placed over the opening of the receiving groove.
[0057] In one embodiment, the support base 220 is provided with a receiving groove that communicates with both the first mounting hole 211 and the second mounting hole 212, providing space for wiring of the conductive component and signal transmission component 400. The opening of the receiving groove is located on the side away from the mounting platform 210, and an insulating bottom cover 230 is provided at the opening of the receiving groove to protect the wires, conductive component, and signal transmission component 400 within the groove. In one embodiment, the insulating bottom cover 230 has a protrusion 231 on the side facing the receiving groove. The protrusion 231 is correspondingly provided with the first mounting hole 211 and the second mounting hole 212 to abut against the bottom of the conductive component and signal transmission component 400, thereby providing support for the conductive component and signal transmission component 400. In one embodiment, the protrusion 231 is hollow to facilitate wiring, allowing an external mounting base to extend a cable into the protrusion 231 to connect with the conductive component and signal transmission component 400. The insulating bottom cover 230 can be made of materials such as polycarbonate, polyester, or rubber to ensure that the insulating bottom cover 230 has good insulation and structural strength. No restrictions are imposed here.
[0058] The technical solution of this utility model embodiment improves installation convenience by providing a receiving groove in the support base 220, which allows the conductive component and signal transmission component 400 to be directly installed on the mounting platform 210 through the receiving groove; and by providing an insulating bottom cover 230, which is detachably connected to the support base 220, the structure inside the receiving groove is protected while ensuring ease of installation and disassembly, thus improving the reliability of the connector socket.
[0059] Please see Figure 2 In one embodiment, the outer periphery of the insulating bottom cover 230 is provided with a second buckle 320, which extends toward the mounting platform 210. The side wall of the support base 220 is provided with a card interface 222 that communicates with the receiving groove. The second buckle 320 is used to snap into the card interface 222.
[0060] In one embodiment, the insulating bottom cover 230 has second latches 320 at both opposite ends, and the support base 220 has locking interfaces 222 on both opposite sidewalls. The second latches 320 include a second extension 321 and a second locking head 322. One end of the second extension 321 is located on the insulating bottom cover 230, and the other end extends towards the mounting platform 210 with its extension direction parallel to the axial direction of the receiving groove. The second locking head 322 is located at the other end of the second extension 321 and protrudes outwards. The second locking head 322 is used to engage with the locking interface 222. In one embodiment, the side of the second locking head 322 facing the receiving groove has a third inclined surface 323. The side of the third inclined surface 323 away from the second extension 321 is inclined away from the receiving groove, so that the third inclined surface 323 can move along the inner wall of the receiving groove, facilitating the quick installation of the insulating bottom cover 230 onto the support base 220. The second buckle 320 can be made of engineering plastics such as polycarbonate or polypropylene, so that the second buckle 320 has good insulation and structural strength while having a certain elastic deformation capability, ensuring that the second buckle 320 can undergo a certain degree of elastic deformation in the direction perpendicular to the axial direction of the receiving groove. Here, no restrictions are placed on the specific material of the second buckle 320.
[0061] The technical solution of this utility model embodiment, by setting the second buckle 320 and the card interface 222, can realize the quick assembly and disassembly of the insulating bottom cover 230 and the support base 220, ensuring the assembly and disassembly efficiency of the connector socket; and can limit the movement of the insulating bottom cover 230 relative to the receiving groove, improving the reliability of use.
[0062] Please see Figure 3 In one embodiment, the inner wall of the receiving groove is provided with a limiting block 223, which is used to abut against the insulating bottom cover 230 to restrict the movement of the insulating bottom cover 230.
[0063] In one embodiment, a limiting block 223 protrudes inward from the inner wall of the receiving groove. The limiting block 223 is disposed on at least two opposite inner walls of the receiving groove to abut against at least two opposite ends of the insulating bottom cover 230, thereby further restricting the movement of the insulating bottom cover 230 relative to the receiving groove. The number and position of the limiting blocks 223 can be flexibly set according to actual needs, and are not limited here.
[0064] The technical solution of this utility model embodiment improves assembly stability by setting a limiting block 223, which, together with the second buckle 320, can simultaneously limit the insulating bottom cover 230.
[0065] In one embodiment, panel 100 is configured as metal.
[0066] Metals have good shielding properties. On the one hand, metals have good electrical conductivity. When electromagnetic waves encounter a metal surface, the metal will generate an induced current. This induced current will generate a reverse electromagnetic field on the metal surface, thereby canceling the external electromagnetic field and achieving the effect of shielding electromagnetic interference. On the other hand, metals have good magnetic permeability, which can change the distribution of the magnetic field to facilitate shielding from external electromagnetic fields.
[0067] In one embodiment, the panel 100 may be configured as a metallic material such as iron, nickel and its alloys, or copper, aluminum and its alloys, or AlNiCo alloys, without limitation. Among these, when the panel 100 is configured as copper or a copper alloy, the shielding effect of the panel 100 is better.
[0068] The technical solution of this utility model embodiment, by configuring the panel 100 as metal, can shield electromagnetic waves, thereby avoiding interference from external electromagnetic waves to conductive components and signal transmission components 400, and improving the reliability of the connector socket.
[0069] Please see Figure 2 In one embodiment, the panel 100 further includes a surrounding plate 150. The surrounding plate 150 protrudes from the side of the panel 100 opposite to the support base 220 and surrounds the through hole 110. The surrounding plate 150 abuts against the peripheral surface of the corresponding connector plug, thereby ensuring the stability of the connection between the corresponding connector plug and the connector socket. In one embodiment, the outer peripheral surface of the surrounding plate 150 has a first protrusion 151 protruding outward. The inner peripheral surface of one type of connector plug has a recess or a locking structure, and the first protrusion 151 is used to engage with the corresponding structure of that type of connector plug to prevent the corresponding connector plug from rotating relative to the connector socket. In one embodiment, the inner peripheral surface of the surrounding plate 150 has a second protrusion 152 protruding inward. The outer peripheral surface of another type of connector plug has a recess or a locking structure, and the second protrusion 152 is used to engage with the corresponding structure of that type of connector plug. In one embodiment, the surrounding plate 150 has both a first protrusion 151 and a second protrusion 152 to accommodate different types of connector plugs. The first protrusion 151 and the second protrusion 152 are both triangular in cross-sectional shape to improve the insertion stability and alignment accuracy of the connector socket and the connector plug. Of course, in other embodiments, the cross-sectional shape of the first protrusion 151 and the second protrusion 152 may also be trapezoidal or rectangular, etc.; or, the enclosure 150 may only be provided with the first protrusion 151 or the second protrusion 152, which is not limited here.
[0070] Thus, by setting the first protrusion 151 and the second protrusion 152, the insertion stability and alignment accuracy of the connector socket and the connector plug can be guaranteed, thereby improving the connection stability and reliability of use.
[0071] Please see Figure 2 and Figure 4In one embodiment, the outer periphery of the signal transmission member 400 is provided with an elastic arm 410, which is inclined relative to the axis of the signal transmission member 400 and is used to abut against the inner wall of the first mounting hole 211.
[0072] In one embodiment, a plurality of elastic arms 410 are spaced apart on the outer periphery of the signal transmission component 400. The signal transmission component 400 has a head and a tail disposed opposite to each other, and the plurality of elastic arms 410 are arranged around the axis of the signal transmission component 400 and located between the head and the tail. One end of the elastic arm 410 near the head is disposed on the signal transmission component 400, and the other end of the elastic arm 410 is inclined away from the axis of the signal transmission component 400 in the direction near the tail. In one embodiment, the signal transmission component 400 and the elastic arms 410 are integrally formed, and the signal transmission component 400 and the elastic arms 410 are configured to be made of materials with good conductivity and elasticity, such as copper alloy, aluminum alloy, or phosphor bronze. The signal transmission component 400 is provided with a clearance opening 420 to avoid the elastic arms 410. Under the action of external force, the elastic arms 410 can be received in the clearance opening 420; and after the external force is removed, they return to the inclined state under the action of their own elastic deformation. Of course, in other embodiments, the signal transmission element 400 and the elastic arm 410 can also be connected by snap-fit or welding, and the elastic arm 410 can also be configured as a material with good elasticity and strength, such as rubber, plastic or stainless steel. There are no restrictions here.
[0073] Please see Figure 4 In one embodiment, the first mounting hole 211 is provided with a receiving hole 2111 and a limiting hole 2112 that are connected to each other. The limiting hole 2112 is coaxially arranged with the receiving hole 2111. The inner diameter of the limiting hole 2112 is smaller than the inner diameter of the receiving hole 2111. The limiting hole 2112 is used to abut against the elastic arm 410.
[0074] In one embodiment, the head and tail of the signal transmitter 400 are coaxially arranged, with the outer diameter of the head being smaller than that of the tail. The inner diameter of the limiting hole 2112 is adapted to the outer diameter of the tail, and the inner diameter of the receiving hole 2111 is larger than that of the tail to provide tilting space for the elastic arm 410. The limiting hole 2112 is directly connected to the receiving groove. When the signal transmitter 400 is installed, the head of the signal transmitter 400 is aligned with the limiting hole 2112 and pushed, causing the elastic arm 410 of the signal transmitter 400 to pass through the limiting hole 2112 and extend into the receiving hole 2111. The elastic arm 410 returns to its tilted state within the receiving hole 2111, and the junction of the limiting hole 2112 and the receiving hole 2111 abuts against the elastic arm 410 to restrict the movement of the signal transmitter 400.
[0075] Please see Figure 1 , Figure 2 and Figure 4In one embodiment, the mounting platform 210 is further provided with a limiting ring 213, which is located at the end of the receiving hole 2111 away from the limiting hole 2112. The limiting ring 213 is used to abut against the head of the signal transmission component 400 to confine the signal transmission component 400 within the first mounting hole 211. In one embodiment, the outer periphery of the limiting ring 213 is connected to the inner periphery of the receiving hole 2111, so that a communication port communicating with the receiving groove is formed between the inner wall of the receiving hole 2111 and the outer wall of the limiting ring 213. In one embodiment, a fixing element such as a pin is installed at the communication port to further fix the signal transmission component 400. In another embodiment, a vibration damping element is installed at the communication port to reduce the impact of vibration on the signal transmission component 400. In yet another embodiment, the communication port is used to connect the receiving hole 2111 with the external environment to facilitate heat dissipation.
[0076] The technical solution of this utility model embodiment is to provide an elastic arm 410 in the signal transmission component 400. The elastic arm 410 is inclined, which facilitates installation and can abut against the inner wall of the first mounting hole 211 to position the signal transmission component 400. By setting the first mounting hole 211 as a receiving hole 2111 and a limiting hole 2112, and cooperating with the elastic arm 410, the signal transmission component 400 is self-locked, which can prevent the signal transmission component 400 from falling out of the first mounting hole 211 and improve the assembly stability.
[0077] The above description is merely an exemplary embodiment of the present utility model and does not limit the scope of protection of the present utility model. Any equivalent structural transformations made based on the technical concept of the present utility model and the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included within the scope of protection of the present utility model.
Claims
1. A connector socket, characterized in that, include: The panel has through holes; An insulating mounting base includes a mounting platform and a support base connected together. The mounting platform protrudes from one side of the support base and has a first mounting hole and a second mounting hole. The mounting platform passes through the through hole, and the support base is detachably connected to the through hole. A signal transmission element is disposed within the first mounting hole; and A conductive element is disposed within the second mounting hole.
2. The connector socket as described in claim 1, characterized in that, The connector socket also includes: The mounting platform is provided with a groove, the groove is located near the through hole and communicates with the through hole; and A first buckle is provided on the support base and extends toward the through hole. The first buckle is used to pass through the through hole to engage with the groove, thereby locking the panel between the first buckle and the support base.
3. The connector socket as described in claim 2, characterized in that, The first buckle has a first inclined surface at the end away from the support base, and the panel has a second inclined surface on the side facing the support base. The first inclined surface and the second inclined surface cooperate to guide the first buckle through the through hole.
4. The connector socket as described in claim 1, characterized in that, The support base has a positioning block on the side facing the panel, and the panel has a corresponding positioning groove. The positioning block is used to engage with the positioning groove.
5. The connector socket as described in claim 1, characterized in that, The insulating mounting base also includes: An insulating bottom cover is provided, wherein the support base is provided with a receiving groove that communicates with both the first mounting hole and the second mounting hole, and the insulating bottom cover is detachably placed over the opening of the receiving groove.
6. The connector socket as described in claim 5, characterized in that, The outer periphery of the insulating bottom cover is provided with a second buckle, which extends toward the mounting platform. The side wall of the support base is provided with a card interface that communicates with the receiving groove, and the second buckle is used to snap into the card interface.
7. The connector socket as described in claim 5, characterized in that, The inner wall of the receiving groove is provided with a limiting block, which is used to abut against the insulating bottom cover to restrict the movement of the insulating bottom cover.
8. The connector socket as claimed in claim 1, characterized in that, The panel is configured as metal.
9. The connector socket as claimed in claim 1, characterized in that, The signal transmission component has an elastic arm on its outer periphery. The elastic arm is inclined relative to the axis of the signal transmission component and is used to abut against the inner wall of the first mounting hole.
10. The connector socket as claimed in claim 9, characterized in that, The first mounting hole has a connected receiving hole and a limiting hole. The limiting hole is coaxially arranged with the receiving hole. The inner diameter of the limiting hole is smaller than the inner diameter of the receiving hole. The limiting hole is used to abut against the elastic arm.