CN118589242A - Fast Ethernet Connectors - Google Patents

Abstract

The invention relates to the technical field of electric connection, in particular to a high-speed Ethernet connector, which comprises a shell, an electric connection assembly, a fixing piece and an electric connection elastic piece, wherein one end of the fixing piece is inserted into a fixing slot, and the fixing piece is provided with a limit column which is used for being matched with a limit table so as to fix the electric connection assembly in the connecting slot; the electric connection spring piece comprises an assembling part and an elastic contact part, one end of the assembling part is arranged in the spring piece clamping groove, the elastic contact part is provided with a first contact and a second contact, one end of the elastic contact part is connected with the assembling part, the first contact is contacted with the electric connection assembly, and the second contact extends towards the spring piece slotting and is positioned outside the connecting plug. The invention enables the first contact to make reliable electrical contact with the electrical connection assembly by the design of the elastic contact portion. The reliable electrical connection ensures stability and reliability of data and power transmission.

Description

Fast Ethernet Connectors

Technical Field

The present invention relates to the technical field of electrical connection, and in particular to a high-speed Ethernet connector.

Background Art

The vehicle connector is an electronic component used to connect the internal and external devices of the vehicle. With the rapid development of the automotive industry. With the trend of automobile intelligence and networking, the number and types of vehicle connectors are also increasing. The vehicle Ethernet connector is an interface used to connect vehicle electronic devices, used to support high-speed Ethernet communication, and meet the requirements of vehicle electronic devices for data transmission speed.

Most of the existing in-vehicle Ethernet connectors are single-headed. When multiple connectors are required for connection, multiple single-headed connectors need to be combined together for use. The existing multiple connectors are not stable when used together, which affects the plug-in and is inconvenient for maintenance. Therefore, it is necessary to make new improvements to the existing Ethernet connector structure.

Summary of the invention

To solve the above problems, the present invention enables the first contact to make reliable electrical contact with the power connection assembly through the design of the elastic contact portion. The reliable electrical connection ensures the stability and reliability of data transmission and power transmission of the high-speed Ethernet connector.

The technical solution adopted by the present invention is: a high-speed Ethernet connector, including a shell, a power connection component, a fixing part and a power connection spring, the shell includes a fixing part and a plurality of connection plugs arranged at one end of the fixing part, the plurality of connection plugs are arranged side by side, each of the connection plugs is provided with a connection slot, one end of the connection slot extends and passes through the fixing part; a fixing slot is provided on one side of the fixing part, one end of the fixing slot passes through a plurality of connection slots in sequence; spring card slots are provided on both sides of the connection slot close to the fixing slot; spring slot slots are provided on both sides of the connection slot, the spring slot slots are close to the spring card slots; the connection There are multiple groups of electrical components, and the multiple groups of power connection components are respectively arranged in each connecting slot, and the power connection components are provided with a limiting platform; one end of the fixing piece is inserted into the fixing slot, and the fixing piece is provided with a limiting column, and the limiting column is used to cooperate with the limiting platform to fix the power connection component in the connecting slot; the power connection spring comprises an assembly part and an elastic contact part, one end of the assembly part is installed in the spring clip slot, and the elastic contact part is provided with a first contact and a second contact, one end of the elastic contact part is connected to the assembly part, the first contact contacts the power connection component, and the second contact extends toward the spring clip slot and is located outside the connecting plug.

A further improvement to the above solution is that the plurality of connection plugs are arranged in two rows, with three connection plugs in each row, and reinforcing ribs are arranged between the plurality of connection plugs to connect them to each other.

A further improvement to the above scheme is that a plug-in guide strip is provided on the outer side of the connecting plug; a guiding slope is provided between two rows of the connecting plugs; a plug-in platform is provided at the top of the connecting plug of the shell, and a plug-in buckle is provided at the top of the plug-in platform.

A further improvement to the above scheme is that the connection slot includes a plug-in end, a fixed end and a wiring end arranged in sequence, a plug-in gap is formed between the plug-in end and the power connection component, the fixed end is used to fix the power connection component, and the wiring end is provided with a connecting wire, one end of the connecting wire is connected to the power connection component.

A further improvement to the above solution is that an insertion guide slope is provided at the opening of the plug-in end, and the insertion guide slope is inclined toward the plug-in gap.

A further improvement to the above scheme is that an assembly guide groove, an end fixing platform and a fixing buckle are provided in the fixed end, the assembly guide groove is used for inserting the guide when assembling the power connection component, the fixing buckle is used to cooperate with the end fixing platform to clamp and fix the two sides of the power connection component, and the fixing buckle is an elastic buckle.

A further improvement to the above scheme is that the power connection assembly includes an insulator, a power connection terminal and a wire clamp, the power connection terminal is arranged in the insulator, the wire clamp is arranged at one end of the insulator and is used to fix the connecting wire, one end of the connecting wire is connected to the power connection terminal, and the fixed end is used to fix the insulator.

A further improvement to the above scheme is that a terminal groove is provided in the insulator, a terminal clamping groove is provided on one side of the terminal groove, the power terminal is provided in the terminal groove, the power terminal is provided with a terminal buckle, and the terminal buckle is used to cooperate with and be clamped on the terminal clamping groove.

A further improvement to the above scheme is that assembly sliders are provided on both sides of the insulator, a stopper is provided on one side of the assembly slider, the assembly slider is used to slide and fit on the assembly guide groove, and the stopper is used to fit on the end fixing platform.

A further improvement to the above solution is that a covering groove is provided on the rear side of the insulator, one end of the wire clamp is covered on the covering groove by riveting, and the other end is riveted to the connecting wire.

A further improvement to the above scheme is that the fixed slot includes a through slot and a limit platform, one end of the through slot passes through a plurality of connecting slots in sequence, and the limit platform is arranged at one end of the through slot; the limit platform is arranged at one end of the through slot; a pressing part is arranged at one end of the limit column, the pressing part is used to cooperate on the limit platform, and the limit column is used to be inserted into the through slot.

A further improvement to the above solution is that a limiting slot is provided on one side of the limiting platform, and a limiting buckle is provided on one side of the pressing portion, and the limiting buckle is used to fit on the limiting slot.

A further improvement to the above solution is that a through slot is provided at one end of the fixing portion, and one end of the through slot is connected to the limiting slot.

A further improvement to the above scheme is that the assembly part is provided with a positioning block and a tight-fitting block, the tight-fitting block is used for the assembly part to be tightly fitted in the spring clip slot, and the positioning block is used for assembly and positioning of the assembly part; the assembly part and the power connection spring clip are formed by integral stamping; the power connection spring clip is S-shaped, and the first contact and the second contact are respectively arranged on the inner side and outer side of the power connection spring clip.

The beneficial effects of the present invention are:

Compared with the existing connectors, the present invention is used for vehicle-mounted high-speed Ethernet connection, and adopts a plurality of connection plugs arranged side by side, through which high-speed data transmission is achieved. This design can support faster data transmission rates and meet the requirements of new energy vehicles for large data transmission and high bandwidth. For example, it can be used to transmit vehicle status information, navigation data, multimedia content, etc. in real time. The design of the connection slot and the fixing slot enables the connector to be stably fixed in the fixing part during installation. The cooperation between the limit column and the limit platform of the fixing further enhances the stability of the connector. This stable connection can effectively prevent the plug from loosening or disconnecting during vehicle driving, ensuring the reliability of data transmission.

The structural design of the present invention makes it more convenient during installation and maintenance. The side-by-side arrangement of the connecting plugs and the arrangement of the connecting slots and the spring card slots make the assembly and disassembly of the connectors simpler. This design can reduce the working time and labor costs during installation and maintenance. The elastic contact portion of the power connection spring contacts the power connection component through the first contact and the second contact, ensuring a stable and reliable electrical connection. The design of this elastic contact portion can effectively reduce the disconnection or loosening of the connector in a shock and vibration environment, and improve the stability and reliability of data transmission. The present invention is applicable to a variety of application scenarios of new energy vehicles. Whether it is used for data transmission inside the vehicle, such as in-vehicle entertainment systems, navigation systems, etc., or for communication connections outside the vehicle, such as vehicle networking, charging pile communications, etc., this connector solution can be used for high-speed data transmission and stable connection.

The assembly part of the power connection spring of the present invention is installed in the spring card slot to ensure a stable connection with the connector. The design of the elastic contact part enables the first contact to make reliable electrical contact with the power connection component. This reliable electrical connection ensures the stability and reliability of data transmission and power transmission. The design of the elastic contact part enables the power connection spring to have excellent elastic properties. The second contact extends toward the spring slot and is located outside the connecting plug, which can provide appropriate elastic force to ensure close contact between the power connection spring and the connecting plug. This elastic property can resist the influence of shock, vibration and other external environmental factors and maintain a stable electrical connection. The assembly part of the power connection spring is installed in the spring card slot, making the assembly and disassembly of the connector more flexible. This design facilitates the installation and maintenance of the connector and reduces labor costs and working time. The first contact of the elastic contact part contacts the power connection component and can adapt to different types of power connection components. Whether it is transmitting data or power, the power connection spring can be reliably connected to the power connection component to meet the needs of different application scenarios. The design of the power connection spring enables the second contact to extend toward the spring slot and be located outside the connecting plug. This design allows the second contact to contact the opposing connector, improving the reliability of the connector.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a perspective schematic diagram of a high-speed Ethernet connector of the present invention;

FIG2 is a schematic front view of the high-speed Ethernet connector in FIG1 ;

Fig. 3 is a cross-sectional view taken along line A-A in Fig. 2;

Fig. 4 is a cross-sectional view taken along line B-B in Fig. 4;

FIG5 is an enlarged schematic diagram of point A in FIG4 ;

FIG6 is a front view of the housing of the high-speed Ethernet connector in FIG1 ;

Fig. 7 is a cross-sectional view taken along line A-A in Fig. 6;

Fig. 8 is a cross-sectional view taken along line B-B in Fig. 6;

FIG9 is a perspective view of a power connection assembly of the high-speed Ethernet connector in FIG1 ;

FIG10 is an exploded view of the power connection assembly of the high-speed Ethernet connector in FIG1 ;

FIG11 is a perspective view of a power connection assembly of the high-speed Ethernet connector in FIG1 ;

FIG12 is a perspective view of a fixing member of the high-speed Ethernet connector in FIG1 ;

FIG. 13 is a perspective view of the power connection spring of the high-speed Ethernet connector in FIG. 1 .

Description of reference numerals: housing 1, fixing portion 11, through slot 111, connecting plug 12, reinforcing rib 121, plug-in guide strip 122, guide slope 123, plug-in platform 124, plug-in buckle 125, connecting slot 13, plug-in end 131, insertion guide slope 1311, fixing end 132, assembly guide slot 1321, end fixing platform 1322, fixing buckle 1323, wiring terminal 133, plug-in gap 134, connecting line 135, spring clip slot 136, fixing slot 14, through slot 141, limiting platform 142, limiting card slot 1421, spring clip card slot 15;

The power connection assembly 2, the insulator 21, the terminal groove 211, the terminal clamping groove 212, the assembly slide 213, the stopper 214, the covering groove 215, the limiter 216, the power connection terminal 22, the terminal buckle 221, and the wire clamp 23;

The fixing member 3, the limiting column 31, the pressing portion 311, and the limiting buckle 3111;

The electrical connection spring 4 , the assembly portion 41 , the positioning block 411 , the tight fitting block 412 , the elastic contact portion 42 , the first contact point 421 , and the second contact point 422 .

DETAILED DESCRIPTION

In order to facilitate the understanding of the present invention, the present invention will be described more fully below with reference to the relevant drawings. The preferred embodiments of the present invention are given in the drawings. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. On the contrary, the purpose of providing these embodiments is to make the understanding of the disclosure of the present invention more thorough and comprehensive.

It should be noted that when an element is referred to as being "fixed to" another element, it may be directly on the other element or there may be an intermediate element. When an element is considered to be "connected to" another element, it may be directly connected to the other element or there may be an intermediate element at the same time.

Unless otherwise defined, all technical and scientific terms used herein have the same meaning as those commonly understood by those skilled in the art of the present invention. The terms used in the specification of the present invention herein are only for the purpose of describing specific embodiments and are not intended to limit the present invention.

As shown in FIGS. 1 to 13 , in one embodiment of the present invention, a high-speed Ethernet connector is provided, comprising a housing 1, a power connection assembly 2, a fixing member 3 and a power connection spring 4. The housing 1 comprises a fixing portion 11 and a plurality of connection plugs 12 arranged at one end of the fixing portion 11. The plurality of connection plugs 12 are arranged side by side, and each of the connection plugs 12 is provided with a connection slot 13, one end of which extends and passes through the fixing portion 11; a fixing slot 14 is provided at one side of the fixing portion 11, and one end of the fixing slot 14 passes through the plurality of connection slots 13 in sequence; spring card slots 15 are provided on both sides of the connection slot 13 close to the fixing slot 14; spring slots 136 are provided on both sides of the connection slot 13, and the spring slots 136 are close to the spring card slots 15; There are multiple groups of power connection components 2, and the multiple groups of power connection components 2 are respectively arranged in each connection slot 13, and the power connection components 2 are provided with a limiting platform 216; one end of the fixing member 3 is inserted into the fixing slot 14, and the fixing member 3 is provided with a limiting column 31, and the limiting column 31 is used to cooperate with the limiting platform 216 to fix the power connection component 2 in the connection slot 13; the power connection spring 4 includes an assembly part 41 and an elastic contact part 42, one end of the assembly part 41 is installed in the spring card slot 15, and the elastic contact part 42 is provided with a first contact 421 and a second contact 422, one end of the elastic contact part 42 is connected to the assembly part 41, the first contact 421 contacts the power connection component 2, and the second contact 422 extends toward the spring slot 136 and is located outside the connection plug 12. This embodiment is used for vehicle-mounted high-speed Ethernet connection, and adopts a plurality of connection plugs 12 arranged side by side, and high-speed data transmission is achieved through these connection plugs 12. This design can support faster data transmission rates and meet the requirements of new energy vehicles for large data transmission and high bandwidth. For example, it can be used to transmit vehicle status information, navigation data, multimedia content, etc. in real time. The design of the connecting slot 13 and the fixing slot 14 enables the connector to be stably fixed in the fixing portion 11 during installation. The cooperation between the limit column 31 of the fixing member 3 and the limit platform 216 further enhances the stability of the connector. This stable connection can effectively prevent the plug from loosening or disconnecting during vehicle driving, ensuring the reliability of data transmission.

The structural design of this embodiment makes it more convenient during installation and maintenance. The side-by-side arrangement of the connecting plug 12 and the arrangement of the connecting slot 13 and the shrapnel slot 15 make the assembly and disassembly of the connector easier. This design can reduce the working time and labor costs during installation and maintenance. The elastic contact portion 42 of the power connection shrapnel 4 contacts the power connection component 2 through the first contact 421 and the second contact 422, ensuring a stable and reliable electrical connection. The design of this elastic contact portion 42 can effectively reduce the disconnection or loosening of the connector in a vibration and vibration environment, and improve the stability and reliability of data transmission. This embodiment is applicable to a variety of application scenarios of new energy vehicles. Whether it is used for data transmission inside the vehicle, such as an in-vehicle entertainment system, a navigation system, etc., or for communication connections outside the vehicle, such as vehicle networking, charging pile communications, etc., this connector solution can be used for high-speed data transmission and stable connection.

The assembly portion 41 of the power-connecting spring 4 of this embodiment is installed in the spring card slot 15 to ensure a stable connection with the connector. The design of the elastic contact portion 42 enables the first contact 421 to make reliable electrical contact with the power connection component 2. This reliable electrical connection ensures the stability and reliability of data transmission and power transmission. The design of the elastic contact portion 42 enables the power-connecting spring 4 to have excellent elastic properties. The second contact 422 extends toward the spring slot 136 and is located outside the connecting plug 12, which can provide appropriate elastic force to ensure close contact between the power-connecting spring 4 and the connecting plug 12. This elastic property can resist the influence of shock, vibration and other external environmental factors and maintain a stable electrical connection. The assembly portion 41 of the power-connecting spring 4 is installed in the spring card slot 15, making the assembly and disassembly of the connector more flexible. This design facilitates the installation and maintenance of the connector and reduces labor costs and working time. The first contact 421 of the elastic contact portion 42 contacts the power connection component 2, which can adapt to different types of power connection components 2. Whether transmitting data or power, the power connection spring 4 can be reliably connected to the power connection assembly 2 to meet the needs of different application scenarios. The design of the power connection spring 4 allows the second contact 422 to extend toward the spring slot 136 and be located outside the connection plug 12. This design allows the second contact to contact the opposite connector, thereby improving the reliability of the connector.

The plurality of connection plugs 12 are arranged in two rows, with three plugs in each row. Specifically, the plurality of connection plugs 12 are connected to each other by reinforcing ribs 121. In this embodiment, a double-row connection plug 12 is designed, with three connectors in each row, and the connection is made by providing reinforcing ribs 121, so as to ensure the stability of the connection plug 12, and the structure is reliable, and the stability is good during insertion. Since the housing 1 is formed by plastic injection molding, it also has a certain floating force when the connection plug 12 is inserted into each other.

Referring to FIGS. 6 and 7 , a plug-in guide strip 122 is provided on the outer side of the connection plug 12; a guide slope 123 is provided between two rows of the connection plugs 12; a plug-in platform 124 is provided at the top of the connection plug 12 of the housing 1, and a plug-in buckle 125 is provided at the top of the plug-in platform 124. In this embodiment, the plug-in guide strip 122 and the guide slope 123 are used to guide the plug-in of the connectors to ensure the plug-in accuracy and the stable contact of the connectors. The plug-in buckle 125 on the plug-in platform 124 is used to cooperate with the clamping and fixing of the opposite connectors, so that the two connectors remain plugged after connection.

The connection slot 13 includes a plug-in end 131, a fixed end 132 and a wiring end 133 which are arranged in sequence. A plug-in gap 134 is formed between the plug-in end 131 and the power connection component 2. The fixed end 132 is used to fix the power connection component 2. The wiring end 133 is provided with a connecting wire 135, one end of which is connected to the power connection component 2. Specifically, an insertion guide slope 1311 is provided at the opening of the plug-in end 131, and the insertion guide slope 1311 is inclined toward the plug-in gap 134. In this embodiment, a plug-in gap 134 is formed between the plug-in end 131 and the power connection component 2. This design provides a certain elastic connection. The plug-in gap 134 can absorb minor errors and deformations during the connection process, ensure good contact between the plug-in end 131 and the power connection component 2, and reduce contact impedance and signal loss. The fixed end 132 is used to fix the power connection component 2 to ensure that the position of the power connection component 2 in the connector is stable. The design of the fixed end 132 can prevent the power connection component 2 from loosening or shifting during use, thereby improving the reliability and stability of the connector. The connection terminal 133 is provided with a connecting wire 135, one end of which is connected to the power connection component 2. Such a design allows the connector to be easily connected to other devices or systems. The other end of the connecting wire 135 can be connected to an external power source, a signal source or other device to achieve functions such as data transmission and power supply.

The fixed end 132 is provided with an assembly guide groove 1321, an end fixing platform 1322 and a fixing buckle 1323. The assembly guide groove 1321 is used for inserting guide when assembling the power connection component 2. The fixing buckle 1323 is used to cooperate with the end fixing platform 1322 to clamp and fix the two sides of the power connection component 2. The fixing buckle 1323 is an elastic buckle. In this embodiment, the assembly guide groove 1321 is used for inserting guide when assembling the power connection component 2 to ensure that the power connection component 2 can be accurately inserted into the fixed end 132. The guide groove provides reliable guidance, making the assembly process of the component more convenient and accurate. The fixing buckle 1323 is used in conjunction with the end fixing platform 1322 to clamp and fix the two sides of the power connection component 2. This design can ensure that the power connection component 2 is firmly fixed inside the connector to prevent it from loosening or shifting. The fixing buckle 1323 adopts the form of an elastic buckle, which has a certain elasticity and is convenient for assembling the power connection component 2.

Referring to FIGS. 9 to 11 , the power connection assembly 2 includes an insulator 21, a power connection terminal 22 and a wire clamp 23. The power connection terminal 22 is arranged in the insulator 21, and the wire clamp 23 is arranged at one end of the insulator 21 and used to fix the connecting wire 135. One end of the connecting wire 135 is connected to the power connection terminal 22, and the fixed end 132 is used to fix the insulator 21. In this embodiment, the insulator 21 is used as a part of the power connection assembly 2 to provide an electrical isolation function. It can effectively isolate the circuit inside the connector from the external environment, prevent the occurrence of electrical interference and short circuit problems, and improve the safety and reliability of the connector. The power connection terminal 22 is arranged in the insulator 21 to achieve a reliable electrical connection with the connecting wire 135. Through the power connection terminal 22, the connector can be connected to an external power supply or signal source to achieve data transmission and power supply. This design ensures the stability and reliability of the electrical connection and reduces contact resistance and signal loss. The wire clamp 23 is arranged at one end of the insulator 21 and is used to fix the connecting wire 135. The wire clamp 23 provides a reliable fixing force, so that the connection wire 135 can be tightly connected to the power terminal 22. Such a design ensures the stability of the connection wire 135, which is not easy to loosen or fall off during use, thereby improving the reliability and durability of the connector. The fixed end 132 is used to fix the insulator 21 to ensure that the position of the power connection component 2 in the connector is stable. The design of the fixed end 132 can prevent the insulator 21 from loosening or shifting during use, thereby improving the reliability and stability of the connector.

The insulator 21 is provided with a terminal slot 211, one side of the terminal slot 211 is provided with a terminal clamping slot 212, the power terminal 22 is provided in the terminal slot 211, and the power terminal 22 is provided with a terminal buckle 221, and the terminal buckle 221 is used to be clamped on the terminal slot 212. Specifically, the insulator 21 is provided with assembly sliders 213 on both sides, and one side of the assembly slider 213 is provided with a stopper 214, the assembly slider 213 is used to slide on the assembly guide groove 1321, and the stopper 214 is used to be matched on the end fixing platform 1322; the rear side of the insulator 21 is provided with a covering slot 215, one end of the wire clamp 23 is covered on the covering slot 215 by riveting, and the other end is riveted to the connecting wire 135. In this embodiment, the insulator 21 is provided with a terminal slot 211 for installing the power terminal 22. The cooperation of the terminal buckle 221 and the terminal card slot 212 enables the power terminal 22 to be firmly fixed inside the insulator 21. This design realizes reliable isolation of electrical connection and prevents short circuit or interference between different lines. Assembly sliders 213 and stop platforms 214 are provided on both sides of the insulator 21. The assembly slider 213 is slidably matched on the assembly guide groove 1321, so that the insulator 21 can be flexibly assembled and disassembled. The cooperation of the stop platform 214 and the end fixing platform 1322 further increases the stability of the connector. This design facilitates the installation and maintenance of the connector and reduces labor costs and working time. A coating groove 215 is provided on the rear side of the insulator 21, and the wire clamp 23 is coated on the coating groove 215 by riveting and riveted with the connecting wire 135. This design enables the wire clamp 23 to be reliably fixed on the connector, ensuring the stability and reliability of power transmission. The setting of the terminal groove 211 and the terminal card slot 212 enables the power terminal 22 to be firmly fixed inside the insulator 21. This design can effectively prevent the line from loosening in a shock and vibration environment and maintain a stable connection of the connector.

As shown in FIG. 12 , the fixed slot 14 includes a through slot 141 and a limiting platform 142. One end of the through slot 141 sequentially penetrates a plurality of connection slots 13. The limiting platform 142 is disposed at one end of the through slot 141. The limiting platform 142 is disposed at one end of the through slot 141. A pressing portion 311 is disposed at one end of the limiting column 31. The pressing portion 311 is used to fit on the limiting platform 142. The limiting column 31 is used to be inserted into the through slot 141. Specifically, a limiting card slot 1421 is disposed at one side of the limiting platform 142. A limiting buckle 3111 is disposed at one side of the pressing portion 311. The limiting buckle 3111 is used to fit on the limiting card slot 1421. A through slot 111 is disposed at one end of the fixed portion 11. One end of the through slot 111 is connected to the limiting card slot 1421. In this embodiment, one end of the through slot 141 sequentially penetrates multiple connection slots 13, so that the connector can connect multiple power connection components 2 or devices at the same time. This design can improve the connection density and expansibility of the connector and meet the needs of multi-way connection. The limiting platform 142 is set at one end of the through slot 141, and the limiting column 31 is inserted into the through slot 141 and used in conjunction with the limiting platform 142. Such a design can achieve accurate positioning of the power connection component 2 or device in the connector, ensure the correct alignment between the plug end 131 and the power connection component 2, and avoid incorrect insertion or loose connection. A limiting card slot 1421 is set on one side of the limiting platform 142, and a limiting buckle 3111 is set on one side of the pressing part 311. The limiting buckle 3111 is matched with the limiting card slot 1421 to fix the limiting column 31. Such a design provides a stable fixing force to ensure that the connection components inside the connector are stably fixed and reduce the risk of loosening or falling off. One end of the fixing portion 11 is provided with a through slot 111, and one end of the through slot 111 is connected to the limiting clamping slot 1421. The limiting clamping buckle 3111 can be pressed on the through slot 111 by a tool so as to disassemble the fixing element.

As shown in FIG. 13 , the assembly part 41 is provided with a positioning block 411 and a tight fitting block 412. The tight fitting block 412 is used for the assembly part 41 to be tightly fitted in the spring clip slot 15, and the positioning block 411 is used for assembling and positioning the assembly part 41; the assembly part 41 and the power connection spring clip 4 are formed by integral stamping; the power connection spring clip 4 is S-shaped, and the first contact 421 and the second contact 422 are respectively arranged on the inner side and the outer side of the power connection spring clip 4. In this embodiment, the assembly part 41 is provided with a positioning block 411 and a tight fitting block 412, and the assembly part 41 is tightly assembled in the spring clip slot 15 by the tight fitting block 412. The positioning block 411 is used to ensure the accurate positioning of the assembly part 41. This design makes the assembly process of the connector more accurate, ensures the accurate alignment between the assembly part 41 and the power connection spring clip 4, and improves the stability and reliability of the connector. The assembly part 41 and the power connection spring clip 4 are formed by integral stamping. This integrated stamping manufacturing method simplifies the production process and improves production efficiency. At the same time, the structure formed by integrated stamping also increases the structural strength and stability of the connector. The power connection spring 4 is set in an S shape, and the first contact 421 and the second contact 422 are respectively arranged on the inner side and the outer side of the power connection spring 4. This optimized contact design enables the power connection spring 4 to achieve better contact with the power connection component 2. The inner side of the first contact 421 contacts the power connection component 2 to provide a stable electrical connection; the outer side of the second contact 422 extends toward the spring slot 136 to ensure close contact with the connecting plug 12. This design improves the stability and reliability of data transmission and power transmission. The structural design of the assembly part 41 and the S-shaped power connection spring 4 enables the connector to have reliable connection performance. The cooperation of the tight fitting block 412 of the assembly part 41 and the spring card slot 15 ensures the stable fixation of the assembly part 41. At the same time, the elastic characteristics of the S-shaped power connection spring 4 and the optimized contact design ensure the stable electrical connection of the connector and prevent the plug from loosening or disconnecting in a vibration and vibration environment.

The above embodiments only express several implementation methods of the present invention, and the descriptions thereof are relatively specific and detailed, but they cannot be understood as limiting the scope of the present invention. It should be pointed out that, for a person of ordinary skill in the art, several modifications and improvements can be made without departing from the concept of the present invention, and these all belong to the protection scope of the present invention. Therefore, the protection scope of the present invention patent shall be subject to the attached claims.

Claims (10)

1. A high-speed Ethernet connector, characterized in that: A shell, the shell comprising a fixing portion and a plurality of connection plugs arranged at one end of the fixing portion, the plurality of connection plugs being arranged side by side, each of the connection plugs being provided with a connection slot, one end of the connection slot extending and penetrating the fixing portion; a fixing slot being provided at one side of the fixing portion, one end of the fixing slot sequentially penetrating a plurality of connection slots; spring clip slots being provided at both sides of the connection slot close to the fixing slot; spring clip slots being provided at both sides of the connection slot, the spring clip slots being close to the spring clip slots; A power connection assembly, wherein the power connection assembly is provided in multiple groups, and the multiple groups of the power connection assembly are respectively arranged in each connection slot, and the power connection assembly is provided with a limit platform; A fixing member, one end of which is inserted into the fixing slot, and the fixing member is provided with a limiting column, and the limiting column is used to cooperate with the limiting platform to fix the power connection component in the connection slot; and The power connection spring comprises an assembly portion and an elastic contact portion, one end of the assembly portion is mounted in the spring slot, the elastic contact portion is provided with a first contact and a second contact, one end of the elastic contact portion is connected to the assembly portion, the first contact contacts the power connection component, and the second contact extends toward the spring slot and is located outside the connection plug. 2. The high-speed Ethernet connector according to claim 1, characterized in that: the plurality of connecting plugs are arranged in two rows, with three connecting plugs in each row, and reinforcing ribs are arranged between the plurality of connecting plugs to connect them to each other; The outer side of the connecting plug is provided with a plug-in guide strip; a guiding slope is provided between two rows of the connecting plugs; the shell is provided with a plug-in platform at the top of the connecting plug, and a plug-in buckle is provided at the top of the plug-in platform. 3. The high-speed Ethernet connector according to claim 1, characterized in that: the connection slot comprises a plug-in end, a fixed end and a wiring end which are arranged in sequence, a plug-in gap is formed between the plug-in end and the power connection component, the fixed end is used to fix the power connection component, the wiring end is provided with a connecting wire, and one end of the connecting wire is connected to the power connection component; An insertion guide inclined surface is arranged at the opening of the plug-in end, and the insertion guide inclined surface is inclined toward the plug-in gap. 4. The high-speed Ethernet connector according to claim 3 is characterized in that: the fixed end is provided with an assembly guide groove, an end fixing platform and a fixing buckle, the assembly guide groove is used for inserting and guiding when assembling the power connection component, the fixing buckle is used to cooperate with the end fixing platform to clamp and fix the two sides of the power connection component, and the fixing buckle is an elastic buckle. 5. The high-speed Ethernet connector according to claim 3 is characterized in that: the power connection component includes an insulator, a power connection terminal and a wire clamp, the power connection terminal is arranged in the insulator, the wire clamp is arranged at one end of the insulator and is used to fix the connecting wire, one end of the connecting wire is connected to the power connection terminal, and the fixed end is used to fix the insulator. 6. The high-speed Ethernet connector according to claim 5 is characterized in that: a terminal slot is provided in the insulator, a terminal clamping slot is provided on one side of the terminal slot, the power terminal is provided in the terminal slot, the power terminal is provided with a terminal buckle, and the terminal buckle is used to cooperate with and be clamped on the terminal clamping slot. 7. The high-speed Ethernet connector according to claim 5, characterized in that: assembly sliders are provided on both sides of the insulator, a stopper is provided on one side of the assembly slider, the assembly slider is used to slide and fit on the assembly guide groove, and the stopper is used to fit on the end fixing platform; A covering groove is arranged on the rear side of the insulator, one end of the wire clamp is covered on the covering groove by riveting, and the other end is riveted to the connecting wire. 8. The high-speed Ethernet connector according to claim 1, characterized in that: the fixed slot comprises a through slot and a limiting platform, one end of the through slot sequentially penetrates a plurality of connection slots, and the limiting platform is arranged at one end of the through slot; the limiting platform is arranged at one end of the through slot; one end of the limiting column is provided with a pressing portion, the pressing portion is used to fit on the limiting platform, and the limiting column is used to be inserted into the through slot; A limiting slot is disposed on one side of the limiting platform, and a limiting buckle is disposed on one side of the pressing portion, wherein the limiting buckle is used to fit in the limiting slot. 9 . The high-speed Ethernet connector according to claim 8 , wherein a through slot is provided at one end of the fixing portion, and one end of the through slot is connected to the limit slot. 10. The high-speed Ethernet connector according to claim 1 is characterized in that: the assembly part is provided with a positioning block and a tight-fitting block, the tight-fitting block is used for the assembly part to be tightly fitted in the spring clip slot, and the positioning block is used for assembly and positioning of the assembly part; the assembly part and the power connection spring clip are formed by integral stamping; the power connection spring clip is S-shaped, and the first contact and the second contact are respectively arranged on the inner side and the outer side of the power connection spring clip.