CN117673797A - Connector and electronic equipment - Google Patents

Abstract

The invention relates to the technical field of high-speed transmission of 5G and 6G signals, solves the technical problems of complex wiring and poor wire performance of the traditional connector in the prior art, and provides a connector and electronic equipment, wherein the connector comprises a plug and a socket; the plug comprises a plug insulator and plug conducting fixing frames respectively arranged at two ends of the plug insulator, wherein the plug insulator is also provided with plug metal conducting frames and plug metal conducting frames which are distributed among the plug conducting fixing frames, and at least one end of the plug insulator is provided with a plug buckling groove or a plug elastic contact arm; the socket comprises a socket insulator, a socket conducting fixing frame, a socket metal conducting frame and a socket metal conducting frame are further arranged on the socket insulator, and at least one end of the socket metal conducting frame, which is matched with the plug, is provided with a socket elastic contact arm matched with the plug buckling groove or a socket buckling groove matched with the plug elastic contact arm. The plug and the socket of the connector provided by the invention are reliably connected, and have good electric conduction and communication effects.

Description

Connector and electronic equipment

Technical Field

The invention relates to the technical field of high-speed transmission of 5G and 6G signals, in particular to a connector and electronic equipment.

Background

With the rapid development of electronic technology, society gradually enters into 5G and 6G times, the requirements of 5G and 6G signals on transmission signals are higher, the transmission speed is required to be higher, and a connector is used as an indispensable component in electronic equipment and plays a very important role in the process of high-speed transmission of 5G and 6G signals.

The existing 5G and 6G signal high-speed transmission connectors generally comprise a socket and a plug, the socket is welded on a socket circuit board of an electronic device such as a mobile phone through a socket soldering leg, the plug is welded on a plug circuit board such as a signal processing component through a plug soldering leg, after the plug is in plug-in fit with the socket, communication signals processed by the signal processing component are transmitted to the circuit board of the mobile phone through the plug and the socket in sequence, and the fixing stability degree after the plug is plugged into the socket plays an important role in the working stability of the connector and the quality of high-speed transmission of the 5G and 6G signals.

However, in the prior art, when the plug and the socket are fixed in a mutually plugging manner, only an interference fit manner is generally adopted, and a structure in a corresponding locking and fixing state is lacking, so that the situation of infirm plugging exists, and therefore, in the working process, the plug is easy to relatively shake or even separate from the socket, so that the plug cannot be firmly plugged with the socket, the plug cannot work stably and perform signal transmission with the socket, and the high-speed transmission effect of 5G and 6G signals is poor due to the reduction of signal transmission capability; furthermore, for the existing connector and Type-C interface of the electronic device such as a mobile phone, the structural design of the existing connector is not reasonable enough, so that the length of the plug and the socket which are mutually embedded is longer, thus increasing the unnecessary wiring length, and the electrical connection with the Type-C interface requires longer wiring on the circuit board, so that the difficulty of wiring is increased, and meanwhile, the unnecessary cost is increased.

Disclosure of Invention

The invention aims to solve the technical problem that the traditional plug and the socket are not firmly spliced, and provides a connector and electronic equipment with the reliable plug and the reliable socket.

The present invention provides a connector comprising: a plug and a socket; the plug comprises a plug insulator and plug conducting fixing frames respectively arranged at two ends of the plug insulator, wherein the plug insulator is also provided with plug metal conducting frames and plug metal conducting frames which are distributed among the plug conducting fixing frames, and the plug conducting fixing frames, the plug metal conducting frames and the plug metal conducting frames are used for arranging plug buckling grooves or plug elastic contact arms at least one end matched with the socket; the socket comprises a socket insulator, the socket insulator is further provided with a socket conduction fixing frame, a socket metal conduction frame and a socket metal conduction frame which correspond to the plug conduction fixing frame, the plug metal conduction frame and the plug metal conduction frame respectively, and at least one end of the socket conduction fixing frame, the socket metal conduction frame and the socket metal conduction frame, which are matched with the plug, is provided with a socket elastic contact arm matched with the plug buckling groove, or a socket buckling groove matched with the plug elastic contact arm. Preferably, the width of the receiving slot and the angle of the receiving slot and the pusher block relative to the horizontal are adjustable.

Preferably, the socket metal conducting frame comprises a first conducting frame contact part and a pair of second conducting frame contact parts arranged on two opposite sides of the first conducting frame contact part, the second conducting frame contact parts extend towards the same side direction far away from the first conducting frame, an acute angle is formed between the extending directions of the second conducting frame contact parts, and a socket conducting frame contact arm which is used for being buckled with the plug buckling groove and conducting electrically is formed at the tail end of at least one extending second conducting frame contact part.

Preferably, the second conducting frame contact part comprises a first side plate, a top connection plate and a second side plate, the first side plate and the second side plate are oppositely arranged, the top connection plate is connected with one end of the first side plate and one end of the second side plate, the other end of the first side plate is connected with the first conducting frame contact part, a hollow groove which is communicated with each other is formed in the first side plate and the top connection plate, and a socket conducting frame contact arm is connected with the first conducting frame contact part and extends in the hollow groove, and a first spring contact end which is matched with the plug metal conducting frame is formed at the free end of the socket conducting frame contact arm; the first side plate protrudes to the other second conduction frame contact part at two sides of the empty groove to form a second spring contact end and a third spring contact end matched with the plug metal conduction frame.

Preferably, the end of the second conducting frame contact part extending protrudes or bends towards the second conducting frame contact part, and a through groove is formed in the second conducting frame contact part so as to form a fourth ejecting point and a fifth ejecting end which are matched with the plug metal conducting frame.

Preferably, the plug conducting and fixing frame comprises a first plug inserting part and a pair of second plug inserting parts arranged on two opposite sides of the first plug inserting part, the pair of second plug inserting parts extend in the same direction along a first direction far away from the first plug inserting part, and a pair of opposite through openings are arranged on the pair of second plug inserting parts; the plug further comprises a pair of clamping pieces which are correspondingly arranged between the pair of plug conducting fixing frames and the plug insulator, and when the plug is in plug-in fit with the socket, the clamping pieces protrude out of the corresponding through openings and are used for being clamped with the socket conducting fixing frames in an elastic deformation mode and in conductive contact with the socket conducting fixing frames.

Preferably, the fastener comprises a fastener body, a fixing arm and a pair of elastic arms, wherein the fixing arm and the pair of elastic arms are bent and extended by the fastener body, the pair of elastic arms are symmetrically arranged relative to the fixing arm, the fastener body comprises a main connecting plate, a first vertical plate and a pair of second vertical plates, the first vertical plates are parallel at equal intervals and are respectively perpendicular to the main connecting plate, the second vertical plates are respectively positioned at two sides of the first vertical plates, each elastic arm comprises a connecting plate and an elastic buckle which are sequentially connected with the second vertical plates, the two elastic buckles are oppositely extended far away from each other, the fixing arm is bent and connected with the first vertical plates, the fastener further comprises a first plug welding pin which is connected with the main connecting plate and is oppositely extended far away from each other, and a concave arc groove is formed at the connection part of the first plug welding pin and the main connecting plate.

Preferably, the plug insulator is provided with a fixing hole, a containing groove, a pair of through grooves and a pair of protruding tables, the clamping member body is arranged in the containing groove, the fixing arm is fixedly inserted in the fixing hole, one protruding table is respectively arranged between each through groove and the fixing hole, the elastic buckle is elastically deformable and located in the through groove, the through groove is communicated with the through notch, the clamping member body and the first plug inserting portion are respectively located on two opposite sides of the plug insulator, the pair of elastic buckles respectively protrude out of the through notch through the through grooves, and in the plug inserting matching process, the socket and the plug are correspondingly moved relatively far away from each other after the through notch and the pair of clamping grooves are mutually staggered, so that each elastic buckle correspondingly protrudes out of the through groove and the through notch.

Preferably, the number of the socket metal conducting frames is two, the socket metal conducting frames are respectively close to the socket conducting fixing frames at two ends of the socket, one socket metal conducting frame is arranged between the two socket metal conducting frames, and the socket metal conducting frames are separated from each other through socket insulators.

A split type electronic device includes the connector described above.

Preferably, the electronic device includes a Type-C interface, and the Type-C interface is implemented through a connector as described above.

In summary, compared with the prior art, the invention has the following beneficial effects:

1. the present invention provides a connector comprising: a plug and a socket; the plug comprises a plug insulator and plug conducting fixing frames respectively arranged at two ends of the plug insulator, wherein the plug insulator is also provided with plug metal conducting frames and plug metal conducting frames which are distributed among the plug conducting fixing frames, and the plug conducting fixing frames, the plug metal conducting frames and the plug metal conducting frames are used for arranging plug buckling grooves or plug elastic contact arms at least at one end matched with the socket; the socket comprises a socket insulator, and a socket conduction fixing frame, a socket metal conduction frame and a socket metal conduction frame which correspond to the plug conduction fixing frame, the plug metal conduction frame and the plug metal conduction frame respectively are further arranged on the socket insulator, and socket elastic contact arms matched with the plug buckling grooves or socket buckling grooves matched with the plug elastic contact arms are arranged on at least one end of the socket conduction fixing frame, the socket metal conduction frame and the socket metal conduction frame, which is matched with the plug. It will be appreciated that the connector in this solution is first more resistant to loosening than a conventional connector by interference fit, and the connection between the plug and the socket is more secure due to the use of the resilient contact arms. This means that the connector is more difficult to loosen during vibration, impact or movement, thereby improving the stability of the connection; second, with better signal transmission stability, conventional interference connections may introduce some degree of mechanical stress between the plug and socket of the connector, which may adversely affect signal transmission. The mechanical stress can be reduced by the cooperation of the elastic contact arms, so that the stability of signal transmission is maintained, and the risk of signal interference is reduced; furthermore, due to the fact that connection is firmer, abrasion between the plug and the socket can be reduced due to the design of the elastic contact arms, and accordingly the service life of the connector is prolonged. In summary, by using a mating of resilient contact arms, such a connector provides a more stable and reliable connection, making it more suitable for 5G, 6G signal-to-signal applications requiring a high degree of reliability and stability.

2. In the connector provided by the invention, the socket metal conducting frame comprises a first conducting frame contact part and a pair of second conducting frame contact parts arranged on two opposite sides of the first conducting frame contact part, wherein the pair of second conducting frame contact parts extend towards the same side direction far away from the first conducting frame, the extending directions of the second conducting frame contact parts form an acute angle, and the tail end of at least one second conducting frame contact part extends to form a socket conducting frame contact arm which is used for being buckled with a plug buckling groove and electrically conducted. It can be appreciated that the structure of the metal conducting frame has the following advantages in connection stability and signal transmission stability: the connection stability, the first conductive frame contact provides a firm center support point in the receptacle, ensuring a stable axis of rotation for the plug and receptacle when connected. This helps ensure that the plug is accurately aligned with the receptacle, reducing misalignment and offset during connection; the pair of second conductive frame contacts extend in the same side direction away from the first conductive frame, which increases the support area of the connector relative to conventional connectors. This means that the mechanical stability of the connector is higher and is more resistant to external impacts or vibrations; the acute angle structure between the second conductive frame contact portions helps to prevent rotation or twisting of the connector. This enables the connector to be more securely held in connection without being easily loosened or separated; the socket conducting frame contact arm is positioned at the tail end of the second conducting frame contact part and is used for being buckled with the plug buckling groove and electrically conducted. This design ensures a very reliable electrical connection between the plug and the socket; in signal transmission, reliable electrical contact reduces the risk of resistance and signal interference; the location and configuration of the contact arms of the receptacle contact frame makes it difficult to externally interfere. This design ensures that the signal transmission between the plug and the receptacle remains stable even in a vibrating or moving environment, reducing the likelihood of signal distortion or disruption. The structural improvement of the metal conductive frame increases the connection stability and signal transmission stability of the connector by providing stronger support and more reliable electrical contact. This is important for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connections. Such improvements help reduce failure and maintenance costs, improving the performance and life of the connector.

3. In the connector provided by the invention, a second conducting frame contact part comprises a first side plate, a jacking plate and a second side plate, wherein the first side plate and the second side plate are oppositely arranged; the first side plate protrudes to the contact part of the other second conduction frame at two sides of the empty groove to form a second spring contact end and a third spring contact end which are matched with the plug metal conduction frame. It will be appreciated that the second conductive frame contact has the following advantages in connection stability and signal transmission stability: the structure of the second conduction frame contact part comprises a first side plate, a top connection plate and a second side plate, and the first side plate, the top connection plate and the second side plate jointly provide a plurality of supporting points. These support points form a multi-point support system by cooperation with the plug metal lead-through frame. Such a multi-point support can more evenly distribute the forces between the connectors, ensuring a more stable connection, compared to conventional connectors; the spring contact ends (the second spring contact end and the third spring contact end) on the first side plate and the second side plate are matched with the plug metal conducting frame, so that elastic contact is formed. This design allows the connector to have some elasticity when connected, absorbing possible minor deflections or shocks to ensure that the connector remains secure; the socket conducting frame contact arm is connected with the first conducting frame contact part and extends in the empty slot, and meanwhile a first spring contact end is formed at the free end of the socket conducting frame contact arm. In addition, the spring contact ends on the first side plate and the second side plate form a second spring contact end and a third spring contact end. This means that there are multiple electrical contact points between the plug metal conducting frame and the socket conducting frame contact arm, forming a multi-channel signal transmission path; the resilient contact points of the contact arms of the receptacle contact frame ensure a secure electrical connection with the plug metal contact frame. This helps to reduce the resistance, improve the reliability of the signal transmission, and reduce the risk of signal distortion or interruption. The structural arrangement of the second conductive frame and the improvement of the combination of the multipoint support and the elastic contact improve the performance of the connector in connection stability and signal transmission stability. The electrical connection of the multichannel signal transmission paths and the resilient contact reduces the resistance and reduces the risk of signal interference, making the connector suitable for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connection. These advantages help reduce connector failure and maintenance costs, improving performance and life.

4. In the connector provided by the invention, the tail end of the extending part of the other second conducting frame protrudes or bends towards the contact part of the second conducting frame, and the contact part of the other second conducting frame is provided with a through groove so as to form a fourth ejecting point and a fifth ejecting end which are matched with the metal conducting frame of the plug. It will be appreciated that the end of the second conductive frame contact extending has an outwardly protruding or bent feature, which makes it an additional support point. These support points cooperate with the plug metal lead-through frame when connected, providing a plurality of support points that help to distribute forces between the connectors, thereby increasing the stability of the connection; the ends of the second leadframe contacts increase the contact area with the plug metal leadframe by protruding or bending the ends outward, providing additional resistance to twisting or deflection. This helps to prevent the connector from being disturbed by external twisting forces or vibrations in use; the tail end of the contact part of the second conduction frame is provided with a through groove, so that an additional elastic contact point, namely a fourth ejection point and a fifth ejection end, is formed. This increases the number of electrical contacts between the plug metal lead-through and the receptacle lead-through contact arms. The electrical contact points of the multiple channels are beneficial to improving the reliability of signal transmission, reducing the resistance and reducing the risk of signal interference; the through slots at the ends allow more contact surface for the resilient contact points of the plug metal lead-through and the receptacle lead-through contact arms, thereby improving the reliability of the electrical connection. This helps to ensure stability of signal transmission, reducing the likelihood of signal distortion or disruption. The structural improvement of the second conductive frame contact improves the performance of the connector in connection stability and signal transmission stability through multi-point support and additional electrical contact points. In particular, the special configuration of the tip increases the anti-kink capability of the connector, which is important in applications requiring highly reliable connection and stable signal transmission. These advantages help reduce connector failure and maintenance costs, improving performance and life.

5. In the connector provided by the invention, the plug conducting and fixing frame comprises a first plug inserting part and a pair of second plug inserting parts arranged on two opposite sides of the first plug inserting part, wherein the pair of second plug inserting parts extend in the same direction along a first direction far away from the first plug inserting part, and a pair of opposite through openings are arranged on the pair of second plug inserting parts; the plug further comprises a pair of clamping pieces which are correspondingly arranged between the pair of plug conducting and fixing frames and the plug insulator, and when the plug is in plug-in fit with the socket, the clamping pieces protrude out of the corresponding through openings and are used for being clamped with the socket conducting and fixing frames in an elastic deformation mode and conducting contact. It is understood that the plug-on fixing frame is composed of a first plug-in portion and a pair of second plug-in portions, which provide a plurality of support points when connected. The multipoint support system ensures that the connection between the plug and the socket evenly distributes force, and improves the stability of connection; the clamping piece is correspondingly arranged between the plug conducting fixing frame and the plug insulator. When the plug is in plug-in fit with the socket, the clamping piece protrudes out of the through notch and is clamped with the socket conduction fixing frame in an elastic deformation mode. The design ensures that the clamping piece firmly locks the socket to conduct the fixed frame when in connection, thereby further improving the stability of connection; when the plug is in plug-in fit with the socket, the clamping piece not only plays a role in fixing, but also is clamped with the socket conduction fixing frame in an elastic deformation mode, and conductive contact is realized. The design ensures reliable electrical connection between the plug and the socket, reduces resistance and reduces interference in signal transmission; the through notch on the plug conducting fixing frame is used for accommodating the clamping piece, so that the clamping piece can be in conductive contact with the socket conducting fixing frame. This structure ensures that the electrical connection between the fastener and the receptacle conductive fixing frame is firm, helping to maintain the stability of signal transmission. The structure of the plug conducting fixing frame and the arrangement of the clamping piece are improved through multi-point support and reliable electric contact, and the performance of the connector in the aspects of connection stability and signal transmission stability is improved. This design is more suitable for 5G, 6G signaling applications. These advantages help reduce connector failure and maintenance costs, improving performance and life.

6. The invention provides a connector, which comprises a clamping body, a fixed arm and a pair of elastic arms, wherein the fixed arm and the pair of elastic arms are bent and extended by the clamping body, the pair of elastic arms are symmetrically arranged relative to the fixed arm, the clamping body comprises a main connecting plate, a first vertical plate which is parallel at equal intervals and is respectively vertical to the main connecting plate, and a pair of second vertical plates which are respectively positioned at two sides of the first vertical plate, each elastic arm comprises a connecting rotating plate and an elastic buckle which are sequentially connected with the second vertical plate, the two elastic buckles are oppositely extended far away from each other, the fixed arm is bent and connected with the first vertical plate, the clamping body also comprises a first plug welding leg which is connected with the main connecting plate and is oppositely extended far away from each other, and a concave arc groove is formed at the connecting part of the first plug welding leg and the main connecting plate. It is understood that the fastener is composed of a fastener body, a fixing arm and a pair of elastic arms. This structure can provide reliable connection and fixing functions. The fixing arm is connected with the first vertical plate in a bending way, so that the clamping piece can be firmly locked on the connector. This helps to ensure connection stability between the plug and the socket, avoiding loosening or falling off; the resilient arm includes a rotation plate and a resilient catch extending opposite away from each other. The structure allows the clamping piece to be clamped with the socket conducting fixing frame in an elastic deformation mode and electrically contacted with the socket conducting fixing frame. The reliable electrical connection is ensured, the resistance is reduced, and the stability of signal transmission is improved; the clamping piece also comprises a first plug welding pin which is connected with the main connecting plate. The structure plays a guiding role in installation, so that the clamping piece can be accurately fixed on the connector. The presence of the concave arc slot also facilitates easier installation of the fastener. This simplifies the mounting process of the connector; the structure of the clamping piece enables the clamping piece to be stably locked on the connector, so that the mechanical stability of the connector is improved. This helps the connector to be less susceptible to external shock or vibration in use. The structural design of the clamping piece provides reliable connection, fixation and electrical contact, and is beneficial to improving the connection stability and signal transmission stability of the connector. This is important for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connections. These advantages help reduce connector failure and maintenance costs, improving performance and life.

7. In the connector provided by the invention, the plug insulator is provided with a fixing hole, a containing groove, a pair of concave through grooves and a pair of protruding tables, the clamping firmware body is arranged in the containing groove, the fixing arms are fixedly inserted in the fixing holes, the protruding tables are respectively arranged between the concave through grooves and the fixing holes, the elastic buckles are elastically deformable and are positioned in the concave through grooves, the concave through grooves are communicated with the through notch, the clamping firmware body and the first plug inserting part are respectively positioned at two opposite sides of the plug insulator, the pair of elastic buckles respectively protrude out of the through notch through the concave through grooves, and in the process of inserting and matching the socket and the plug, the pair of elastic buckles correspondingly move relatively far away after relatively approaching each other along with the mutual staggering of the pair of through notch and the pair of clamping grooves, so that the elastic buckles correspondingly protrude out of the concave through grooves and the through notch. It will be appreciated that the plug insulator includes a securing aperture, a receiving slot, a female through slot, and a boss. The clamping piece body is arranged in the accommodating groove, the fixing arm is inserted and fixed in the fixing hole, and the protruding table is respectively arranged between the concave through groove and the fixing hole. This arrangement provides a secure fixing and positioning mechanism that ensures proper positioning of the connector assembly during connection. This helps to avoid mis-alignment or loosening of the connector; the elastic buckle is positioned in the concave through groove, and the concave through groove is communicated with the through notch. In the plug and socket plugging and matching process, when the through notch is staggered with the clamping groove, the elastic buckle can move in an elastic deformation manner so as to ensure reliable electrical contact. This helps to reduce resistance, maintaining stability of signal transmission; the structure on the plug insulator allows for bi-directional positioning because the pair of through-slots and the pair of slots are offset from each other to be opposite each other, and the resilient catch can correspondingly be relatively close and then relatively far apart. This ensures that the plug is correctly positioned in the socket, regardless of the orientation at which it is connected; the structure of the plug insulator helps to improve the reliability of the connector. It ensures correct positioning, fixing and electrical contact during connection, reducing the risk of connection failure or signal transmission interruption. The structure of the plug insulator is beneficial to the reliability, correct positioning and electrical contact of the connector, thereby improving the performance of the connector in connection stability and signal transmission stability. This is of great value for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connections. These advantages help reduce connector failure and maintenance costs, improving performance and life.

8. In the connector provided by the invention, two socket metal conducting frames are respectively arranged at two ends close to the socket conducting fixing frame, one socket metal conducting frame is arranged between the two socket metal conducting frames, and the socket metal conducting frames are mutually separated through socket insulators. It can be appreciated that the arrangement of the receptacle metal conductive frame is near both ends of the receptacle conductive fixing frame, and the presence of the receptacle metal fixing frame helps to form an effective electromagnetic shield. The metal conducting frames can effectively block external electromagnetic interference, reduce interference in signal transmission and improve the anti-interference performance of the connector; the socket metal conducting frame and the socket metal conducting frame are separated from each other through a socket insulator. The structure effectively isolates signal transmission of different channels and prevents mutual interference. This is important for applications where multiple signal channels are transmitted simultaneously or where signal cross-talk is prevented; the multiple placement of the receptacle metal lead frame helps to enhance the mechanical stability of the connector. They provide additional support points during connection, dispersing the force between connectors, ensuring the stability of connection; the presence of the receptacle metal conductive frame also helps to ensure reliable electrical contact. They are separated from the receptacle metal conductive frame by receptacle insulators to prevent unwanted shorting or electrical interference. This is important for the stability of the signal transmission. The number and placement of receptacle metal lead frames provides multiple advantages including electromagnetic shielding, interference immunity, separation and isolation, mechanical stability, and reliable electrical contact. These benefits help to improve the performance of the connector in terms of connection stability and signal transmission stability, especially for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connection. These advantages help reduce connector failure and maintenance costs, improving performance and life.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present invention, the drawings required to be used in the embodiments of the present invention will be briefly described, and it is within the scope of the present invention to obtain other drawings according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of an exploded structure of a connector according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of an explosion structure of a connector according to an embodiment of the present invention.

Fig. 3 is a schematic view of a metal conductive frame of a socket of a connector according to an embodiment of the present invention.

Fig. 4 is a schematic diagram of a metal conductive frame of a socket of a connector according to an embodiment of the present invention.

Fig. 5 is a schematic diagram of an internal structure of a plug of a connector according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of a fastener of the connector according to an embodiment of the present invention.

Fig. 7 is a schematic diagram of an exploded structure of a connector according to an embodiment of the present invention;

fig. 8 is a schematic cross-sectional view of a connector according to an embodiment of the present invention;

fig. 9 is a schematic cross-sectional view of a connector according to an embodiment of the invention.

Parts and numbers in the figures:

1. a socket; 2. a plug;

12. the socket is communicated with the fixed frame; 13. a socket metal conducting frame; 14. a socket metal conduction frame; 20. a plug insulator; 21. a socket insulator; 22. the plug is communicated with the fixed frame; 23. a clamping piece; 24. a plug metal conduction frame; 25. a plug metal conduction frame; 26. a plug buckling groove; 27. a socket elastic contact arm;

130. a first conductive frame contact; 131. a second conductive frame contact; 211. a fixing hole; 212. a receiving groove; 213. a concave through groove; 214. a boss; 221. a first plug insertion portion; 222. a second plug insertion portion; 231. a main connecting plate; 232. a first vertical plate; 233. a second vertical plate; 234. a fixed arm; 235. an elastic arm; 236. a first plug leg; 237. a concave arc groove; 250. a plug contact arm;

1221. a first side plate; 1222. a second side plate; 1223. a top connection plate; 1225. a hollow groove; 1226. the first spring contact end; 1227. the second spring contact end; 1228. the third spring contact end; 1229. a fourth spring contact end; 1310. socket conducting frame contact arm; 1331. a through groove; 2221. a through notch; 2351. a rotating plate; 2352. an elastic buckle;

12210. and a fifth spring contact end.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. In the description of the present invention, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the present application and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising … …" does not exclude the presence of other like elements in a process, method, article or apparatus that comprises the element. If not conflicting, the embodiments of the present invention and the features of the embodiments may be combined with each other, which are all within the protection scope of the present invention.

Referring to fig. 1 and 2, an embodiment of the present invention provides a connector 1, including: a plug 2 and a socket 1; the plug 2 comprises a plug insulator 20 and plug conducting fixing frames 22 respectively arranged at two ends of the plug insulator 20, wherein the plug insulator 20 is also provided with plug metal conducting frames 24 and plug metal conducting frames 25 distributed among the plug conducting fixing frames 22, and the plug conducting fixing frames 22, the plug metal conducting frames 24 and the plug metal conducting frames 25 are used for arranging plug buckling grooves 26 or plug elastic contact arms (not shown) at least at one end matched with the socket 1; the socket 1 comprises a socket insulator 21, a socket conducting fixing frame 12, a socket metal conducting frame 13 and a socket metal conducting frame 14 which are respectively corresponding to a plug conducting fixing frame 22, a plug metal conducting frame 24 and a plug metal conducting frame 25 are further arranged on the socket insulator 21, and socket elastic contact arms 27 matched with plug buckling grooves 26 or socket buckling grooves (not shown) matched with plug elastic contact arms (not shown) are arranged on at least one end of the socket conducting fixing frame 12, the socket metal conducting frame 13 and the socket metal conducting frame 14 matched with a plug.

It will be appreciated that the connector in this solution is first more resistant to loosening than a conventional connector by interference fit, and the connection between the plug and the socket is more secure due to the use of the resilient contact arms. This means that the connector is more difficult to loosen during vibration, impact or movement, thereby improving the stability of the connection; second, with better signal transmission stability, conventional interference connections may introduce some degree of mechanical stress between the plug and socket of the connector, which may adversely affect signal transmission. The mechanical stress can be reduced by the cooperation of the elastic contact arms, so that the stability of signal transmission is maintained, and the risk of signal interference is reduced; furthermore, due to the fact that connection is firmer, abrasion between the plug and the socket can be reduced due to the design of the elastic contact arms, and accordingly the service life of the connector is prolonged. In summary, by using a mating of resilient contact arms, such a connector provides a more stable and reliable connection, making it more suitable for 5G, 6G signal-to-signal applications requiring a high degree of reliability and stability. Meanwhile, the positions of the plug conducting fixing frame 22, the plug metal conducting frame 24 and the plug metal conducting frame 25 can be electrically connected with each connecting terminal corresponding to the circuit board of the type-c interface in a manner of saving the wiring length most, so that the wiring difficulty is reduced, and meanwhile, the wiring space is saved.

Referring to fig. 2 and 3, in some embodiments, the receptacle metal conductive frame 13 includes a first conductive frame contact 130 and a pair of second conductive frame contacts 131 disposed on opposite sides of the first conductive frame contact 130, the pair of second conductive frame contacts 131 extend in the same direction away from the first conductive frame contact 130, and the extending directions of the second conductive frame contacts 131 form an acute angle therebetween, and receptacle conductive frame contact arms 1310 for being buckled and electrically connected with the plug buckling slots 26 are formed at the end of at least one of the second conductive frame contacts 131 extending.

It can be appreciated that the structure of the metal conducting frame has the following advantages in connection stability and signal transmission stability: the connection stability, the first conductive frame contact 130 provides a strong center support point in the socket 1, ensuring a stable rotational axis for the plug 2 and socket 1 when connected. This helps ensure that the plug is accurately aligned with the receptacle, reducing misalignment and offset during connection; the pair of second conductive frame contact portions 131 extend in the same side direction away from the first conductive frame contact portion 130, which increases the supporting area of the connector relative to the conventional connector. This means that the mechanical stability of the connector is higher and is more resistant to external impacts or vibrations; the acute angle structure between the second conductive frame contact portions 131 helps to prevent rotation or twisting of the connector. This enables the connector to be more securely held in connection without being easily loosened or separated; the socket conducting frame contact arm 1310 is located at the end of the second conducting frame contact portion 131, and is used for being buckled and electrically conducted with the plug buckling groove 26. This design ensures a very reliable electrical connection between the plug and the socket; in signal transmission, reliable electrical contact reduces the risk of resistance and signal interference; the location and configuration of the receptacle contact arms 1310 makes them less susceptible to external interference. This design ensures that the signal transmission between the plug and the receptacle remains stable even in a vibrating or moving environment, reducing the likelihood of signal distortion or disruption. The structural improvement of the metal conductive frame increases the connection stability and signal transmission stability of the connector by providing stronger support and more reliable electrical contact. This is important for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connections. Such improvements help reduce failure and maintenance costs, improving the performance and life of the connector.

In some embodiments, a second conductive frame contact 131 includes a first side plate 1221, a top plate 1223 and a second side plate 1222, where the first side plate 1221 and the second side plate 1222 are disposed opposite to each other, the top plate 1223 is connected to one end of the first side plate 1221 and one end of the second side plate 1222, the other end of the first side plate 1221 is connected to the first conductive frame contact 130, a hollow slot 1225 is formed on the first side plate 1221 and the top plate 1223, a socket conductive frame contact arm 1310 is connected to the first conductive frame contact 130 and extends in the hollow slot 1225, and a first spring contact end 1226 that mates with the plug metal conductive frame 24 is formed at a free end of the socket conductive frame contact arm 1310; the first side plate 1221 protrudes to the other second conductive frame contact portion 131 at both sides of the empty groove 1225 to form a second spring contact end 1227 and a third spring contact end 1228 that are engaged with the header metal conductive frame 24.

As can be appreciated, the second conductive frame contact 131 has the following advantages in connection stability and signal transmission stability: the structure of the second conductive frame contact 131 includes a first side plate 1221, a top plate 1223, and a second side plate 1222, which together provide a plurality of support points. These support points form a multi-point support system by mating with the plug metal lead frame 24. Such a multi-point support can more evenly distribute the forces between the connectors, ensuring a more stable connection, compared to conventional connectors; the spring contact ends (second spring contact end 1227 and third spring contact end 1228) on the first side plate 1221 and the second side plate 1222 cooperate with the plug metal lead-through frame 24 to form a spring contact. This design allows the connector to have some elasticity when connected, absorbing possible minor deflections or shocks to ensure that the connector remains secure; the receptacle contact arm 1310 is connected to the first contact 130 and extends in the hollow 1225 while forming a first spring contact 1226 at its free end. In addition, the snap ends on the first side plate 1221 and the second side plate 1222 form a second snap end 1227 and a third snap end 1228. This means that there are multiple electrical contacts between the plug metal contact frame 24 and the receptacle contact frame contact arms 1310, forming a multi-channel signal transmission path; the resilient contact points of the receptacle contact arms 1310 ensure a secure electrical connection with the plug metal contact frame 24. This helps to reduce the resistance, improve the reliability of the signal transmission, and reduce the risk of signal distortion or interruption. The structural arrangement of the second conductive frame and the improvement of the combination of the multipoint support and the elastic contact improve the performance of the connector in connection stability and signal transmission stability. The electrical connection of the multichannel signal transmission paths and the resilient contact reduces the resistance and reduces the risk of signal interference, making the connector suitable for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connection. These advantages help reduce connector failure and maintenance costs, improving performance and life.

Referring to fig. 4, further, the extending end of the second conductive frame contact 131 protrudes or bends towards the second conductive frame contact 131, and a through slot 1331 is formed in the second conductive frame contact 131 to form a fourth spring contact end 1229 and a fifth spring contact end 12210 that are matched with the plug metal conductive frame 24.

It will be appreciated that the end of the second conductive frame contact 131 extending has an outwardly protruding or bent feature, which makes it an additional support point. These support points cooperate with the plug metal lead-through 24 when connected, providing a plurality of support points that help to distribute forces between the connectors, thereby increasing the stability of the connection; the ends of the second leadframe contacts 131 increase the contact area with the header metal leadframe 24 by protruding or bending the ends outward, providing additional resistance to twisting or deflection. This helps to prevent the connector from being disturbed by external twisting forces or vibrations in use; the second conductive frame contact 131 has a through slot formed at its end, which forms additional elastic contact points, namely a fourth spring contact 1229 and a fifth spring contact 12210. This increases the number of electrical contact points between the plug metal lead-through 24 and the receptacle lead-through contact arms 1310. The electrical contact points of the multiple channels are beneficial to improving the reliability of signal transmission, reducing the resistance and reducing the risk of signal interference; the terminal through slots allow more contact surface for the spring contact points of the header metal lead-through 24 and the receptacle lead-through contact arms 1310, thereby improving the reliability of the electrical connection. This helps to ensure stability of signal transmission, reducing the likelihood of signal distortion or disruption. The structural improvement of the second conductive frame contact 131 improves the performance of the connector in connection stability and signal transmission stability through multi-point support and additional electrical contact points. In particular, the special configuration of the tip increases the anti-kink capability of the connector, which is important in applications requiring highly reliable connection and stable signal transmission. These advantages help reduce connector failure and maintenance costs, improving performance and life.

Referring to fig. 5, in some embodiments, the plug conducting and fixing frame 22 includes a first plug inserting portion 221 and a pair of second plug inserting portions 222 disposed on opposite sides of the first plug inserting portion 221, the pair of second plug inserting portions 222 extend in the same direction along a first direction away from the first plug inserting portion 221, and a pair of opposite through openings 2221 are provided on the pair of second plug inserting portions 222; the plug 2 further includes a pair of fastening members 23 correspondingly disposed between the pair of plug conducting and fixing frames 22 and the plug insulator 20, and when the plug 2 is mated with the socket 1, the fastening members 23 protrude out of the corresponding through openings 2221 and are used for being fastened to and electrically contacted with the socket conducting and fixing frame 12 in an elastic deformation manner.

It will be appreciated that the plug conductive mounting frame 22 is comprised of a first plug receptacle 221 and a pair of second plug receptacles 222 that provide a plurality of support points when connected. The multipoint support system ensures that the connection between the plug and the socket evenly distributes force, and improves the stability of connection; the locking piece 23 is correspondingly disposed between the plug conductive fixing frame 22 and the plug insulator 20. When the plug 2 is in plug-in fit with the socket 1, the fastening member 23 protrudes out of the through notch 2221 and is fastened to the socket conducting and fixing frame 12 in an elastic deformation manner. This design ensures that the fastener 23 firmly locks the receptacle conductive fixing frame 12 when connected, further improving the stability of connection; when the plug 2 is in plug-in fit with the socket 1, the clamping piece 23 not only plays a role in fixing, but also is clamped with the socket conduction fixing frame 12 in an elastic deformation mode to realize conductive contact. The design ensures reliable electrical connection between the plug and the socket, reduces resistance and reduces interference in signal transmission; the through notch 2221 of the plug conductive fixing frame 22 is used to accommodate the fastener 23, so that it can make conductive contact with the socket conductive fixing frame 12. This structure ensures that the electrical connection between the fastener 23 and the receptacle conductive fixing frame 12 is firm, which helps to maintain the stability of signal transmission. The arrangement of the plug conductive fixing frame 22 and the clamping member 23 improves the performance of the connector in connection stability and signal transmission stability through multi-point support and reliable electrical contact. This design is more suitable for 5G, 6G signaling applications. These advantages help reduce connector failure and maintenance costs, improving performance and life.

Referring to fig. 6, further, the fastening member 23 includes a fastening member body, a fixing arm 234 extending from the fastening member body in a bending manner, and a pair of elastic arms 235, wherein the pair of elastic arms 235 are symmetrically disposed with respect to the fixing arm 234, the fastening member body includes a main connecting plate 231, a first vertical plate 232 and a pair of second vertical plates 233 respectively disposed at two sides of the first vertical plate 232 in parallel at equal intervals and respectively perpendicular to the main connecting plate 231, each elastic arm 235 includes a connecting plate 2351 and an elastic buckle 2352 connected to the second vertical plate 233 in sequence, the two elastic buckles 2352 extend relatively far from each other, the fixing arm 234 is connected to the first vertical plate 232 in a bending manner, the fastening member 23 further includes a first plug welding leg 236 connected to the main connecting plate 231 and extending relatively far from the first vertical plate 232, and a concave arc welding groove 237 is disposed at a connection position of the first plug welding leg 236 and the main connecting plate 231.

It will be appreciated that the clip 23 is comprised of a clip body, a fixed arm 234 and a pair of resilient arms 235. This structure can provide reliable connection and fixing functions. The fixing arm 234 is pivotally connected to the first vertical plate 232 to allow the fastener 23 to be securely locked to the connector. This helps to ensure connection stability between the plug and the socket, avoiding loosening or falling off; the resilient arm 235 includes a rotating plate 2351 and a resilient catch 2352, the resilient catches 2352 extending opposite away from each other. This structure allows the clip 23 to be snapped into and electrically conductive contact with the receptacle conductive mounting frame 12 by way of elastic deformation. The reliable electrical connection is ensured, the resistance is reduced, and the stability of signal transmission is improved; the fastener 23 further includes a first plug leg 236 connected to the main link plate 231. This structure serves as a guide when installed, enabling the clip 23 to be accurately secured to the connector. The presence of the concave arc groove 237 also facilitates easier installation of the fastener 23. This simplifies the mounting process of the connector; the structure of the catch 23 enables it to lock stably on the connector, thereby increasing the mechanical stability of the connector. This helps the connector to be less susceptible to external shock or vibration in use. The structural design of the clamping member 23 provides reliable connection, fixation and electrical contact, which helps to improve the connection stability and signal transmission stability of the connector. This is important for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connections. These advantages help reduce connector failure and maintenance costs, improving performance and life.

Referring to fig. 7, in some embodiments, the plug insulator 20 is provided with a fixing hole 211, a receiving slot 212, a pair of through slots 213 and a pair of bosses 214, the fastener body is disposed in the receiving slot 212, the fixing arm 234 is inserted into the fixing hole 211, a boss 214 is disposed between each of the through slots 213 and the fixing hole 211, the elastic buckle 2352 is elastically deformable in the through slot 213, the through slot 213 is in communication with the through opening 2221, the fastener body and the first plug inserting portion 221 are respectively located on opposite sides of the plug insulator 20, the pair of elastic buckles 2352 respectively protrude out of the through opening 2221 through the through slots 213, and during the process of matching the socket 1 with the plug inserting 2, as the pair of through openings 2221 and the pair of clamping slots are staggered from each other to each other, the pair of elastic buckles 2352 respectively move relatively close and relatively far away from each other, so that each elastic buckle 2352 correspondingly protrudes out of the through slots 213 and the through opening 2221.

As will be appreciated, the plug insulator 20 includes a securing aperture 211, a receiving slot 212, a recessed channel 213, and a boss 214. The fastener body is disposed in the receiving groove 212, and the fixing arm 234 is inserted into the fixing hole 211, and the bosses 214 are disposed between the recess 213 and the fixing hole 211, respectively. This arrangement provides a secure fixing and positioning mechanism that ensures proper positioning of the connector assembly during connection. This helps to avoid mis-alignment or loosening of the connector; the elastic buckle 2352 is located in the through groove 213, and the through groove 213 is communicated with the through notch 2221. During the plug-socket mating process, when the through notch 2221 is staggered from the card slot, the elastic buckle 2352 can move elastically in a deformation manner, so as to ensure reliable electrical contact. This helps to reduce resistance, maintaining stability of signal transmission; the structure on plug insulator 20 allows for bi-directional positioning because the pair of through-slots 2221 and the pair of slots are offset relative to each other such that the resilient tabs 2352 are correspondingly relatively closer together and then relatively farther apart. This ensures that the plug is correctly positioned in the socket, regardless of the orientation at which it is connected; the structure of the plug insulator 20 helps to improve the reliability of the connector. It ensures correct positioning, fixing and electrical contact during connection, reducing the risk of connection failure or signal transmission interruption. The structure of the plug insulator 20 is beneficial for reliability, proper positioning and electrical contact of the connector, thereby improving the performance of the connector in connection stability and signal transmission stability. This is of great value for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connections. These advantages help reduce connector failure and maintenance costs, improving performance and life.

Further, two receptacle metal conducting frames 14 are respectively arranged close to the receptacle conducting fixing frames 12 at two ends of the receptacle, one receptacle metal conducting frame 13 is arranged between the two receptacle metal conducting frames 14, and the receptacle metal conducting frames 14 and the receptacle metal conducting frames 13 are mutually separated through receptacle insulators 21.

It will be appreciated that the location of the receptacle metal lead-through frame 14 near the ends of the receptacle metal lead-through frame 12 and the presence of the receptacle metal lead-through frame 13 helps to form an effective electromagnetic shield. The metal conducting frames can effectively block external electromagnetic interference, reduce interference in signal transmission and improve the anti-interference performance of the connector; the receptacle metal conduction frame 14 and the receptacle metal conduction frame 13 are separated from each other by a receptacle insulator 21. The structure effectively isolates signal transmission of different channels and prevents mutual interference. This is important for applications where multiple signal channels are transmitted simultaneously or where signal cross-talk is prevented; the multiple placement of the receptacle metal bezel 14 helps to enhance the mechanical stability of the connector. They provide additional support points during connection, dispersing the force between connectors, ensuring the stability of connection; the presence of the receptacle metal lead-through frame 14 also helps to ensure reliable electrical contact. They are separated from the socket metal conduction frame 13 by a socket insulator 21 to prevent unnecessary short circuits or electrical interference. This is important for the stability of the signal transmission. The number and placement of receptacle metal lead frames 14 provides multiple advantages including electromagnetic shielding, interference immunity, separation and isolation, mechanical stability, and reliable electrical contact. These benefits help to improve the performance of the connector in terms of connection stability and signal transmission stability, especially for applications requiring highly reliable connections and stable signal transmission, such as data transmission and power connection. These advantages help reduce connector failure and maintenance costs, improving performance and life.

In some embodiments, the plug conductive mounting frame 22, the plug metal conductive frame 25, and the plug metal conductive frame 24 are of a split design or integrally formed.

It will be appreciated that integrally formed means that these critical components are seamlessly joined, with no additional connection points or seams. The structural integrity of the connector is improved, the risk of loosening or breaking of parts is reduced, and the stability of the connector is improved; integral molding generally reduces the overall size of the connector, making it more compact. This is important for applications with space constraints, such as in small devices or electronic devices, where reducing the size of the connector helps to better accommodate the confined space. Reducing connector complexity: the integrated forming simplifies the structure of the connector and reduces the number of parts. This reduces the complexity of the connector, helps reduce the potential source of failure, and simplifies maintenance and repair; since these components are integrally or tightly integrated, the interaction between them is more reliable and the stability of the connection can be better maintained. This is important for applications in high vibration or high impact environments; the split design is beneficial to reducing signal distortion in signal transmission, and the contact between the components is more reliable, and the quality of electric connection is higher, so that the stability of signal transmission is improved. And the split Type design can meet the shortest wiring requirement of Type-C.

Referring to fig. 8, in some embodiments, when the plug 2 is inserted into the socket 1, the plug contact arms 250 of the plug 2 are electrically connected to the first spring contact end 1226 and the fourth spring contact end 1229 of the socket 1.

Further, referring to fig. 9, in some embodiments, when the plug 2 is inserted into the socket 1, the elastic buckle 2352 of the locking member 23 is electrically connected to the socket 1.

The second embodiment of the present invention further provides an electronic device, which may be, for example, a 5G mobile phone, and includes any of the above connectors, and has any of the above plugs and the effects of the connectors, which are not described herein.

Further, the electronic device includes a Type-C interface, and the Type-C interface is implemented through the connector provided by the above embodiment.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims (10)

1. A connector, characterized in that: comprising the following steps:

a plug and a socket;

the plug comprises a plug insulator and plug conducting fixing frames respectively arranged at two ends of the plug insulator, wherein the plug insulator is also provided with plug metal conducting frames and plug metal conducting frames which are distributed among the plug conducting fixing frames, and the plug conducting fixing frames, the plug metal conducting frames and the plug metal conducting frames are used for arranging plug buckling grooves or plug elastic contact arms at least one end matched with the socket;

the socket comprises a socket insulator, the socket insulator is further provided with a socket conduction fixing frame, a socket metal conduction frame and a socket metal conduction frame which correspond to the plug conduction fixing frame, the plug metal conduction frame and the plug metal conduction frame respectively, and at least one end of the socket conduction fixing frame, the socket metal conduction frame and the socket metal conduction frame, which are matched with the plug, is provided with a socket elastic contact arm matched with the plug buckling groove, or a socket buckling groove matched with the plug elastic contact arm.

2. The connector according to claim 1, wherein: the socket metal conducting frame comprises a first conducting frame contact part and a pair of second conducting frame contact parts arranged on two opposite sides of the first conducting frame contact part, wherein the second conducting frame contact parts extend towards the same side direction far away from the first conducting frame, an acute angle is formed between the extending directions of the second conducting frame contact parts, and socket conducting frame contact arms which are used for being buckled with the plug buckling grooves and electrically conducted are formed at the tail end of at least one of the extending ends of the second conducting frame contact parts.

3. The connector according to claim 2, wherein: the second conducting frame contact part comprises a first side plate, a top connection plate and a second side plate, the first side plate and the second side plate are oppositely arranged, the top connection plate is connected with one end of the first side plate and one end of the second side plate, the other end of the first side plate is connected with the first conducting frame contact part, a hollow groove communicated with the first side plate and the top connection plate is formed in the first side plate, and a socket conducting frame contact arm is connected with the first conducting frame contact part and extends in the hollow groove, and a first spring contact end matched with the plug metal conducting frame is formed at the free end of the socket conducting frame contact arm;

the first side plate protrudes to the other second conduction frame contact part at two sides of the empty groove to form a second spring contact end and a third spring contact end matched with the plug metal conduction frame.

4. A connector according to claim 3, wherein: the tail end of the second conducting frame contact part extends to protrude or bend towards the second conducting frame contact part, and a through groove is formed in the second conducting frame contact part so as to form a fourth ejection point and a fifth ejection end which are matched with the plug metal conducting frame.

5. The connector according to claim 1, wherein: the plug conducting fixing frame comprises a first plug inserting part and a pair of second plug inserting parts which are arranged on two opposite sides of the first plug inserting part, wherein the pair of second plug inserting parts extend in the same direction along a first direction away from the first plug inserting part, and a pair of opposite through openings are formed in the pair of second plug inserting parts;

the plug further comprises a pair of clamping pieces which are correspondingly arranged between the pair of plug conducting fixing frames and the plug insulator, and when the plug is in plug-in fit with the socket, the clamping pieces protrude out of the corresponding through openings and are used for being clamped with the socket conducting fixing frames in an elastic deformation mode and in conductive contact with the socket conducting fixing frames.

6. The connector of claim 5, wherein: the clamping piece comprises a clamping piece body, a fixing arm and a pair of elastic arms, wherein the fixing arm and the pair of elastic arms extend from the bending of the clamping piece body, the pair of elastic arms are symmetrically arranged relative to the fixing arm, the clamping piece body comprises a main connecting plate, a first vertical plate and a pair of second vertical plates, the first vertical plates are parallel at equal intervals and are respectively perpendicular to the main connecting plate, the second vertical plates are respectively positioned at two sides of the first vertical plates, each elastic arm comprises a connecting rotating plate and an elastic buckle, the connecting rotating plates are sequentially connected with the second vertical plates, the two elastic buckles extend relatively far away from each other, the fixing arm is connected with the first vertical plates in a bending mode, the clamping piece further comprises a first plug welding pin, the first plug welding pin is connected with the main connecting plate and extends relatively far away from each other, and a concave arc groove is formed in the connecting position of the first plug welding pin and the main connecting plate.

7. The connector of claim 6, wherein: the plug insulator is provided with a fixing hole, a containing groove, a pair of concave through grooves and a pair of protruding platforms, the clamping piece body is arranged in the containing groove, the fixing arms are fixedly inserted in the fixing holes, the protruding platforms are respectively arranged between the concave through grooves and the fixing holes, the elastic buckles are elastically deformed and located in the concave through grooves, the concave through grooves are communicated with the through openings, the clamping piece body and the first plug inserting portion are respectively located on two opposite sides of the plug insulator, the elastic buckles respectively protrude out of the through openings through the concave through grooves, and in the plug inserting and matching process, the through openings and the clamping grooves are mutually staggered to be opposite, the elastic buckles correspondingly move relatively close to each other and relatively far away from each other, and accordingly protrude out of the concave through grooves and the through openings.

8. The connector according to claim 1, wherein: the socket metal conduction frames are arranged between the two socket metal conduction frames, and are separated from the socket metal conduction frames through socket insulators.

9. An electronic device, characterized in that: comprising a connector according to any of claims 1-8.

10. The electronic device of claim 9, wherein: the electronic equipment comprises a Type-C interface, and the Type-C interface is electrically connected with the connector.