CN220553615U - Female seat and high-speed cable connector on board - Google Patents

Abstract

The utility model relates to the technical field of conductive connecting devices specially suitable for high frequency, in particular to an on-board female seat and a high-speed cable connector. The female seat on the board comprises a ring-shaped shell, two ends of the ring-shaped shell are opened to form an inserting cavity for inserting the high-speed cable connector inside, one opening end of the ring-shaped shell is provided with an on-board connecting structure for fixedly connecting with the printed board, the opening of the other opening end forms an inserting port for inserting the high-speed cable connector in an adapting mode and directly attaching the high-speed cable connector to the printed board, and the ring-shaped shell is further provided with a locking structure for locking the adapting high-speed cable connector at the inserting position. The high-speed cable connector is inserted into the upper female seat of the board and then directly connected with the surface paste of the printed board, and is kept in the upper female seat of the board by the locking structure, so that the upper female seat of the board is simpler in structure, and the high-speed cable connector is directly inserted into and connected with the printed board, thereby reducing occupied space, reducing the switching between the high-speed cable and the printed board and improving the reliability of conductive connection.

Description

Female seat and high-speed cable connector on board

Technical Field

The utility model relates to the technical field of conductive connecting devices specially suitable for high frequency, in particular to an on-board female seat and a high-speed cable connector.

Background

With the continuous development of communication information technology, various high-speed connectors are continuously presented in the market. At present, high-speed interconnection technology is commonly used in large-scale data communication centers, and high-speed data transmission is realized by adopting a mode that a high-speed cable is connected with a printed board. The existing high-speed interconnection mode is mainly implemented by installing an end socket on a printed board, an adaptive plug is connected to the end of a high-speed cable, and data transmission between the high-speed cable and the printed board is realized by plug-in mounting of the plug on the socket. The high-speed IO connector and connector assembly that can improve terminal coplanarity that chinese patent of publication number CN113422234B disclosed can improve, its connector assembly includes plug and socket, and the socket is fixed on the printed plate, includes at least two rows of insulating shell that the interval set up, is used for holding the terminal and cladding in the shielding shell of insulating shell periphery, and the one end of terminal is the table subsides end for with the corresponding terminal butt laminating realization conductive connection of printed plate, the other end of terminal is the grafting end, is used for inserting the fit end with the plug and is connected. The connector assembly is relatively complex in structure, occupies a large space, and comprises at least two switching parts before the high-speed cable and the printed board, so that the reliability of conductive connection is reduced.

Disclosure of Invention

The utility model aims to provide an on-board female seat, which is used for solving the problems of complex structure and large occupied space of the existing on-board female seat and high-speed cable plug inserting and combining mode. Meanwhile, the utility model also aims to provide a high-speed cable connector matched with the on-board female socket, so as to solve the problems of complex structure and large occupied space of the conventional inserting and combining mode of the on-board female socket and the high-speed cable plug.

The on-board female seat comprises a ring-shaped shell, two ends of the ring-shaped shell are opened to form an inserting cavity for inserting the high-speed cable connector, one opening end of the ring-shaped shell is provided with an on-board connecting structure for fixedly connecting with the printed board, the opening of the other opening end of the ring-shaped shell forms an inserting port for inserting the matched high-speed cable connector and directly connecting with the printed board in a surface-mounted manner, and the ring-shaped shell is further provided with a locking structure for locking the matched high-speed cable connector at the inserting position.

The utility model provides a brand-new on-board female seat which is adapted to a high-speed cable connector, the on-board female seat is fixed on a printed board when in use, an opening at the other end of the on-board female seat forms an inserting port for inserting the adapted high-speed cable connector, the on-board female seat is directly connected with a printed board surface mount after the high-speed cable connector is inserted and is kept in the on-board female seat by a locking structure, the on-board female seat has a simpler structure, the high-speed cable connector is directly inserted and connected with the printed board, the occupied space is reduced, the switching between the high-speed cable and the printed board is reduced, and the reliability of conductive connection is improved.

Further, a fixing leg is extended on the wall of the annular casing at an opening end thereof, and the fixing leg constitutes the connection structure. The fixing feet are adopted as the connecting structure, so that the fixing feet are simpler, the mounting holes are formed in the printed board conveniently, and the fixing feet and the printed board are matched to realize fixed connection, so that the manufacturing cost is reduced, and the connecting operation is simpler.

Further, the annular shell is a thin-wall shell. Thus, the space on the board can be further saved, which is beneficial to miniaturization and high density.

Further, the annular shell is a circumferential closed shell which is bent integrally. The shell has high overall structural strength, is reliable in plugging and fixing of the high-speed cable connector, and ensures reliable contact between the high-speed cable connector and the printed board.

Furthermore, the opening of the annular sleeve-shaped shell is in a convex shape surrounded by a small rectangular part and a large rectangular part, and a clamping hole for clamping the locking spring piece of the high-speed cable connector is formed in the shell wall of the small rectangular part, which is opposite to the large rectangular part. The space occupied by the high-speed cable connector and the on-board female seat can be reduced as much as possible.

Further, the height of the three-side shell wall corresponding to the small rectangular part is lower than that of the shell wall corresponding to the large rectangular part, so that the annular shell forms an avoidance notch for avoiding the force application tail end of the locking spring piece on the high-speed cable connector at the position of the shell wall corresponding to the small rectangular shell. Therefore, the height of the female seat on the plate can be reduced while the position of the force application tail end of the locking elastic piece is adapted, and miniaturization is facilitated.

The utility model discloses a high-speed cable connector, which comprises an insulating shell, wherein a connecting module is arranged in the insulating shell, the connecting module comprises a differential terminal module, the differential terminal module comprises contact pieces which are arranged in a row, each contact piece comprises a differential contact piece and a grounding contact piece, each contact piece is provided with a wire connecting end used for being connected with a corresponding wire of a high-speed cable and a board surface pasting end used for being in abutting contact with a corresponding contact part on a printed board, the wire connecting ends and the board surface pasting ends are respectively positioned at two opposite sides of an inserting direction, when the high-speed cable connector is inserted into an matched board female seat, the board surface pasting ends are in abutting contact with the corresponding contact part on a printed board, the matched board female seat comprises a ring-shaped shell, two ends of the ring-shaped shell are opened to form an inserting cavity for inserting the high-speed cable connector inside, one opening end of the contact piece is provided with a board upper connecting structure used for being fixedly connected with the printed board, the opening of the other opening end forms a board surface pasting end used for inserting the matched high-speed cable connector and is directly connected with the printed board, and the ring-shaped shell is further provided with a locking structure used for locking the high-speed cable connector on the position of the ring-shaped shell.

The utility model provides a brand-new high-speed cable connector, one end of the high-speed cable connector is connected with a high-speed cable, and the other end of the high-speed cable connector is provided with a board surface-mounted end which is in direct surface-mounted contact with a printed board.

Further, the wire connecting end is a welding connecting end. Because the number of the contact pieces of the differential terminal module is often more, the same welding construction is convenient to realize by adopting welding connection, the process difficulty is reduced, and the connection reliability is higher.

Further, the insulating housing is a slot-shaped housing with an opening facing backwards, the connecting module is arranged at the front side position in the inner cavity of the slot-shaped housing, the front end of the slot-shaped housing is plugged by the connecting module when the surface pasting end of the board extends out of the front side of the insulating outer side, the wire connecting end is positioned in the slot-shaped housing, and the inner cavity of the slot-shaped housing forms an upward glue injection cavity to solidify the connecting module and the slot-shaped housing after glue injection. The structure can seal the connection position between the high-speed cable and the connector by glue injection, plays a role in protection, and simultaneously conveniently realizes the fixed connection between the insulating shell and the internal structure.

Drawings

FIG. 1 is a cross-sectional view of a high-speed cable connector of the present utility model shown in engagement with an on-board female receptacle;

FIG. 2 is a schematic diagram of a high-speed cable connector according to the present utility model;

FIG. 3 is a schematic view of the structure of the on-board female socket of the present utility model mounted to a printed board;

FIG. 4 is a front view of the female on board mount of the present utility model when mounted to a printed board;

fig. 5 is a left side view of fig. 4.

In the figure: 1. a collar-like housing; 10. a first partial shell wall; 11. a second partial shell wall; 111. a clamping hole; 110. avoiding the notch; 12. a fixed foot; 20. an insulating housing; 21. an insulating fixing seat; 22. an insulating fixing member; 23. a shield; 200. terminal avoiding holes; 201. a glue injection cavity; 29. a locking spring plate; 291. the tail end of the force application; 7. a high-speed cable; 9. and (3) a printed board.

Detailed Description

The features and capabilities of the present utility model are described in further detail below in connection with the examples.

The utility model provides the high-speed cable connector and the on-board female seat respectively, realizes the surface-mounted connection with the high-speed cable connector and the printed board 9 in a simpler and quicker way through a brand-new inserting and combining mode of the high-speed cable connector and the on-board female seat, and compared with the prior art, the utility model not only is simpler in structure, but also reduces the occupied space of a connector assembly for realizing the connection between the high-speed cable 7 and the printed board 9, thereby being beneficial to realizing miniaturization.

In the following, embodiments of the high-speed cable connector and embodiments of the on-board female socket are described, respectively, for the purpose of more clearly embodying the innovation of the present utility model.

Example 1 of female on board:

the specific structure of the high-speed cable connector is shown in figures 1 and 3-5, the high-speed cable connector comprises a ring-shaped shell 1, the two ends of the ring-shaped shell 1 are opened to form an inserting cavity for inserting the high-speed cable connector inside, one opening end of the high-speed cable connector is provided with an on-board connecting structure for fixedly connecting the high-speed cable connector with a printed board 9, the opening of the other opening end forms an inserting port for inserting the high-speed cable connector which is matched with the high-speed cable connector and directly connects the high-speed cable connector with the printed board 9 in a surface-mounted mode, and based on the structure, after the ring-shaped shell 1 is fixed on the printed board 9 through the connecting structure, the high-speed cable connector can be directly inserted into the inserting cavity to be directly connected with the surface-mounted printed board 9. Of course, in order to be able to reliably hold the high-speed cable connector in the plugging position inconveniently to ensure a reliable contact with the printed board 9, the annular housing 1 is also provided with a locking structure.

The annular housing 1 is mainly used for restraining and limiting the high-speed cable connector in a direction parallel to the printed board 9, so that the annular housing 1 is essentially required to be provided with a mechanism for restraining the high-speed cable connector in four directions parallel to the printed board 9, and the mechanism can be realized by a circumferentially closed annular sleeve structure or a circumferentially open annular sleeve structure, such as a circumferentially open C-shaped annular sleeve or a circumferentially closed annular sleeve structure as shown in fig. 3-5.

Moreover, in this embodiment, the annular housing 1 is a thin-walled housing, so that the space occupied in the plane parallel to the printed board 9 is reduced as much as possible, and meanwhile, due to the housing structure, the annular housing 1 can be a circumferential closed housing which is bent integrally, so that the processing difficulty and cost are reduced.

As for the arrangement of the connection structure on the annular housing 1, since the connection holes are arranged on the printed board 9 in a relatively convenient and common structure arrangement, in order to reduce the manufacturing difficulty and cost, the connection structure of the annular housing 1 for connecting with the printed board 9 in this embodiment adopts the fixing legs 12 formed by directly extending the shell wall of the housing, and the fixing legs 12 can be inserted into the connection holes on the printed board 9 and connected with the printed board 9. The fixing leg 12 may be straight extending along the wall of the housing, or may be a fold line extending obliquely or bending, which is specifically adapted to the position of the fixing hole on the printed board 9.

The projection shape of the insertion cavity of the annular housing 1 on the printed board 9 is mainly based on the outer shape of the high-speed cable connector, and may be circular in other embodiments besides the approximately rectangular shape in the present embodiment. In this embodiment, the "approximate rectangle" means that the projection shape of the insertion cavity of the annular casing 1 on the printed board 9 or the opening shape of the annular casing 1 is a convex shape surrounded by a small rectangular part and a large rectangular part, the casing wall of the small rectangular part facing away from the large rectangular part is provided with a clamping hole 111 for clamping the locking spring 29 of the high-speed cable connector, and the height of the three casing walls corresponding to the small rectangular part, namely the second part casing wall 11, is lower than the height of the casing wall corresponding to the large rectangular part, namely the first part casing wall 10, so that the annular casing 1 forms an avoidance notch 110 for avoiding the force application tail end 291 of the locking spring 29 on the high-speed cable connector at the position of the casing wall corresponding to the small rectangular casing. By means of the structure, the high-speed cable connector and the locking spring piece 29 mounted on the high-speed cable connector can be matched with the position of the force application tail end 291 of the locking spring piece 29, meanwhile occupied space of the female seat on the board is reduced, and miniaturization is facilitated.

The locking structure is mainly used for limiting and maintaining the high-speed cable connector in the plugging direction, and the locking matching relationship between the high-speed cable connector and the on-board female seat in the embodiment is the same as that between the plug and the socket in the document cited in the background art, and is realized by adopting the elastic snap fit mode of the locking elastic sheet 29 and the clamping hole 111, so that plugging is convenient to realize. Of course, in other embodiments, the locking spring buckle may be disposed on the female seat on the board, the clamping groove is disposed on the high-speed cable connector, the locking spring buckle is pulled outwards to unlock the high-speed cable connector, and the locking spring buckle rebounds inwards to lock and hold the high-speed cable connector.

Embodiments of high speed cable connectors:

as shown in fig. 1-2, the high-speed cable connector mainly includes an insulating housing 20 and an inner component fixedly mounted in the insulating housing 20, where the insulating housing 20 is used for plugging and locking a female socket on a board, so that a corresponding contact terminal of the inner component is abutted and conducted with a corresponding contact terminal on a printed board 9. The internal assembly comprises a connection module, wherein the connection module comprises an insulation fixing seat 21, a differential terminal module and a shielding piece 23, and the insulation fixing seat 21 is mainly used for fixedly mounting the differential terminal module and the shielding piece 23 corresponding to the differential terminal module through a mounting groove arranged on the insulation fixing seat, so that the components are assembled and fixed together.

The differential terminal module is similar to the existing differential terminal module and comprises a plurality of differential pairs which are uniformly arranged at intervals along a straight line, and insulating fixing pieces 22 for fixing the differential pairs together in an injection molding mode, so that the small contact pieces can be held in relatively fixed positions and form a whole, and subsequent assembly is facilitated. Each differential pair includes two differential contacts, and the differential contacts of the same pair are arranged side by side in the arrangement direction of the differential pairs.

The differential contact is generally "J-shaped" with the insulating fixture 22 being injection molded in approximately the middle of the differential contact. The front end bending section of the differential contact integrally extends out of the front side of the insulating fixing piece 22 in an overhanging manner, has certain elasticity and forms a signal surface-mounted end for abutting and bonding the printed board 9, and the rear end vertical section exposes out of the insulating fixing piece 22 and forms a welding connection end for welding connection with the high-speed cable 7.

The shield 23 includes a main sheet body extending in the arrangement direction of the plurality of differential pairs of the differential terminal module, a ground surface mount terminal is provided at the front side edge of the main sheet body at positions corresponding to both sides of each differential pair, and a rear side welding portion for welding with the high-speed cable 7 is provided at the rear side of the main sheet body. The extending directions of the ground surface-mounted terminal and the signal surface-mounted terminal are basically consistent, so that the ground surface-mounted terminal and the signal surface-mounted terminal are more easily aligned. The main sheet body is formed by punching and cutting the whole sheet, can be a straight sheet body as a whole and has a length enough to cover each differential pair, and of course, in order to play better electric shielding effect, in the embodiment, a plurality of U-shaped shielding surrounding grooves are punched on the extending direction of the main sheet body, the number of the U-shaped shielding surrounding grooves is equal to that of the differential pairs of the differential terminal module, and the width of the U-shaped shielding surrounding grooves is enough to enclose the corresponding differential pairs inside, so that a form which is almost surrounded by three faces is formed, and electric shielding among the differential pairs is realized. Correspondingly, the side shape of the insulating fixing member 22 is matched with the side shape of the shielding member 23, the supporting arms formed on the insulating fixing member 22 are just accommodated in the U-shaped shielding surrounding groove, and the shielding member 23 can be fit and attached to the side surface of the insulating fixing member 22 to keep a proper position and distance with the corresponding differential pair.

The main sheet body of the shield 23 is stamped to form a bent portion having a cross section of approximately n-shape between two adjacent U-shaped shield surrounding grooves, the top plane of the n-shaped bent portion constitutes the groove edge of the U-shaped shield surrounding groove, the rear side portion of the groove edge constitutes a rear side welding portion for welding with the shield wire of the high-speed cable 7, and the ground surface-mount terminal extends forward from the front side of the groove edge. Because after the shielding sheet and the insulating fixing member 22 are assembled together, the positions of the groove edges are approximately flush with the tail connection ends of the differential contact members in the arrangement direction of the differential pairs, so that the differential lines and the shielding lines of the high-speed cable 7 are conveniently and orderly arranged and respectively welded with the tail connection ends and the rear side welding parts, and better electric shielding is formed between the adjacent differential pairs.

In this embodiment, the insulating fixing base 21 is a rectangular base, the cross-section is inverted T-shaped, the portion corresponding to the vertical side of the inverted T-shape forms a vertical plate section, the portion corresponding to the horizontal side of the inverted T-shape forms a horizontal plate section, and two mounting grooves are respectively provided on two sides of the vertical plate section on such insulating fixing base 21 for respectively mounting the differential terminal module and the corresponding shielding member 23. Wherein the mounting groove is arranged at the connecting position of the horizontal plate section and the vertical plate section and is communicated with the horizontal plate section from front to back, the differential terminal module is arranged in the mounting groove from the front side of the insulating fixing seat 21 to back in a posture that the supporting arm is close to the vertical plate section, and the signal surface-mounted end is positioned at the front side of the insulating fixing seat 21 and extends in a suspending way from one side back to the vertical plate section. The shielding piece 23 is attached to the side face of the insulating fixing piece 22 and is located between the insulating fixing piece 22 and the vertical plate section, in order to ensure that the differential terminal module and the shielding piece 23 are convenient to position when being inserted into the mounting groove, the whole structural property is relatively stable after the insertion is completed, and the groove wall of the mounting groove on the vertical plate section is in a shape matched with the side face of the shielding piece 23, which is back to the insulating fixing piece 22, namely, an adapting groove matched with the back side of the U-shaped shielding surrounding groove is formed. After the differential terminal module and the shielding sheet are respectively arranged in the two mounting grooves, the signal surface-mounted ends and the ground surface-mounted terminals of the differential terminal module and the shielding sheet which are arranged in the two mounting grooves are bent and extended towards the opposite sides.

The insulating housing 20 is a slot-shaped housing with a rearward opening, the inner cavity of the slot-shaped housing is used for loading the internal components from the rear to the front, and covers the position of the connecting module welded with the high-speed cable 7 inside, the slot bottom of the slot-shaped housing is blocked with the connecting module and is positioned and assembled between the connecting module and the connecting module, and the slot bottom of the slot-shaped housing is provided with a terminal avoiding hole 200 for allowing a grounding surface-mounted terminal on the connecting module to pass through and expose from the front side and a terminal avoiding hole 200 for allowing a confidence surface-mounted terminal to pass through and expose from the front side. The groove-shaped shell is used for accommodating the connecting module and fixedly assembling the connecting module, the high-speed cable 7 connected with the connecting module extends out of the rear side groove opening of the groove-shaped shell, and the shell wall of the groove-shaped shell plays a role in protecting the welding position of the high-speed cable 7 and the connecting module. In this embodiment, the fixing between the insulating housing 20 and the connection module is guaranteed by positioning and assembling between the two on one hand, on the other hand, the terminal avoiding hole 200 at the bottom of the groove-shaped housing is plugged after the connection module is installed into the groove-shaped housing, the cavity of the groove-shaped housing forms the glue injection cavity 201 with an upward opening, and the insulating glue is injected into the glue injection cavity to integrally bond and fix the connection module and the insulating housing 20 after the insulating glue is solidified, so that the welding position between the high-speed cable 7 and the connection module can be basically and absolutely guaranteed to be free from damage, and the service life of the high-speed cable connector is guaranteed.

A locking spring piece 29 is clamped and installed on one side surface of the insulating shell 20, and the locking spring piece 29 is used for clamping with a bayonet on an on-board female seat on the printed board 9 so as to ensure that the high-speed differential connector is stably inserted and combined with the on-board female seat after being inserted and installed on the on-board female seat.

Based on the above description of the structure of the high-speed cable connector, during manufacturing and assembling, two shielding sheets are respectively assembled with two differential terminal modules in a fitting way and are respectively inserted into two mounting grooves of the insulation fixing base 21 from front to back, at this time, tail connecting sections of differential pairs of the differential terminal modules and rear welding parts of the shielding sheets are exposed from the rear side of a horizontal plate section and opposite sides of a vertical plate section of the insulation fixing base 21, then shielding wires and differential wires of a plurality of bundles of high-speed cables 7 are aligned with corresponding rear welding parts and tail connecting sections respectively and are welded and connected to form a connecting module, then the connecting module is integrally assembled into the insulation housing 20, the horizontal plate section of the insulation fixing base 21 is positioned in a position blocked with the bottom of the insulation housing 20, after positioning and assembling, insulating glue solution is injected into a glue injection cavity 201 of the insulation housing 20, and manufacturing and assembling of the high-speed cable connector is completed after curing.

The front end of the insertion direction of the high-speed cable connector forms a surface-mounted end for being directly abutted and conducted with the printed board 9, and the rear end of the high-speed cable connector is provided with a connecting end directly connected with the high-speed cable 7, so that the high-speed cable connector can be directly inserted and matched with the on-board female seat to realize the surface-mounted connection of the high-speed cable connector and the printed board 9, and the conduction connection of the high-speed cable 7 and the printed board 9 is realized with a simpler structure and a smaller volume.

The above embodiments exemplify a specific embodiment of the high-speed cable connector, and are not limited to the above-described embodiments. In other embodiments, the wire connection end of the wire for connecting the high-speed cable 7 in the high-speed cable connector is a crimp connection end, and the corresponding wire of the high-speed cable 7 is connected with the corresponding contact of the high-speed cable connector by crimping; alternatively, in other embodiments, the insulating housing 20 may be in a block shape, and have a mounting groove therein for mounting the connection module from front to back, and after the connection module is mounted in the mounting groove, the connection module is fixedly connected with the insulating housing 20 by bonding or clamping or connecting with a threaded connection piece, and then the connection between the high-speed cable 7 and the connection module is performed; still alternatively, it is readily contemplated that in other embodiments, the insulating holder 21 may have an L-shaped cross-section with the horizontal side corresponding to the L-shape forming the horizontal segment and the vertical side corresponding to the vertical segment, where the mounting slot is only one and located at the location where the horizontal segment meets the vertical segment, again as can be done in accordance with the present utility model.

The above description is only a preferred embodiment of the present utility model, and the patent protection scope of the present utility model is defined by the claims, and all equivalent structural changes made by the specification and the drawings of the present utility model should be included in the protection scope of the present utility model.

Claims (9)

1. The utility model provides a female seat on board, characterized by, including ring cover form casing (1), the both ends opening of ring cover form casing (1) forms high-speed cable connector male and closes the chamber in inside, and its open end has the board connection structure that is used for with printed board (9) fixed connection, and the opening of another open end constitutes the grafting mouth that supplies the high-speed cable connector of adaptation to insert and directly be connected with printed board (9) surface by surface, still is equipped with the locking structure that is used for locking the high-speed cable connector of adaptation in the grafting position on ring cover form casing (1).

2. Female on board seat according to claim 1, characterized in that the shell wall of the collar-like housing (1) is provided with a fixing foot (12) extending at one open end thereof, the fixing foot (12) constituting the connection structure.

3. Female on-board seat according to claim 1, characterized in that the ring-shaped housing (1) is a thin-walled housing.

4. A female on-board seat according to claim 3, characterized in that the annular shell (1) is an integrally folded circumferential closed shell.

5. The female seat on board according to any one of claims 1 to 4, wherein the opening of the annular shell (1) is a convex shape surrounded by a small rectangular part and a large rectangular part, and a clamping hole (111) for clamping a locking spring piece (29) of the high-speed cable connector is formed in the shell wall of the small rectangular part facing away from the large rectangular part.

6. The female on-board seat according to claim 5, wherein the three-sided wall corresponding to the small rectangular portion is lower than the wall corresponding to the large rectangular portion, so that the annular shell (1) forms an avoidance notch (110) for avoiding the force application tail end (291) of the locking spring piece (29) on the high-speed cable connector at the wall position corresponding to the small rectangular shell.

7. The high-speed cable connector comprises an insulating housing (20), and is characterized in that a connecting module is installed in the insulating housing (20), the connecting module comprises a differential terminal module, the differential terminal module comprises contacts arranged in rows, the contacts comprise differential contacts and grounding contacts, the contacts are provided with wire connecting ends for being connected with corresponding wires of a high-speed cable (7) and board surface-mounted ends for being in pressing contact with corresponding contact parts on a printed board (9), the wire connecting ends and the board surface-mounted ends are respectively positioned on two opposite sides of an inserting direction, and when the high-speed cable connector is inserted into a female seat on the board according to any one of claims 1-6, the board surface-mounted ends are in pressing contact with the corresponding contact parts on the printed board (9).

8. The high-speed cable connector of claim 7, wherein the wire connection end is a solder connection end.

9. The high-speed cable connector according to claim 8, wherein the insulating housing (20) is a slot-like housing with an opening facing rearward, the connection module is mounted in a front side position in an inner cavity of the slot-like housing, the connection module blocks a front end of the slot-like housing while the panel surface mount end extends from a front side of the insulating outer side, the wire connection end is positioned in the slot-like housing, and an inner cavity of the slot-like housing forms an adhesive injection cavity (201) with an opening facing upward to consolidate the connection module and the slot-like housing after the adhesive injection.