CN117335206A - Outgoing line limiting assembly and connector - Google Patents

Abstract

The application provides an outgoing line limiting assembly and a connector, comprising a line passing structure and a blocking structure, wherein the line passing structure comprises a line inlet surface, a line outlet surface, and a power line via hole and a signal line via hole which penetrate through the line inlet surface and the line outlet surface, wherein the power line via hole is used for supplying power line outgoing lines, the signal line via hole is used for supplying signal line outgoing lines, the line passing structure is also provided with a limiting part, and the limiting part encloses the edge of at least part of the signal line via holes; the blocking structure is arranged on the wire outlet face and is at least positioned between one power line via hole and one signal line via hole or between one power line via hole and another power line via hole or between one signal line via hole and another signal line via hole, and the blocking structure is at least used for blocking the power line from contacting with at least part of the signal lines or other power lines positioned on one side of the wire outlet face when the power line positioned on one side of the wire outlet face rotates around the axial direction of the corresponding power line via hole. The power line damage prevention device can avoid damage to the signal line or other power lines as much as possible.

Description

Outgoing line limiting assembly and connector

Technical Field

The application relates to the technical field of connectors, in particular to an outgoing line limiting assembly and a connector.

Background

At present, the outlet positions of a power line and a signal line of an existing connector often depend on the structure of an outlet assembly, however, the existing outlet assembly often cannot avoid the damage of the power line to the signal line due to various reasons, so that the connector is damaged, and a safety accident is possibly caused. Therefore, how to avoid the damage of the power line to the signal line or other power lines as much as possible becomes a problem to be considered.

Disclosure of Invention

The utility model provides a spacing subassembly and connector are qualified for next round of competitions can avoid the power cord to cause the damage to signal line or other power cords as far as possible.

In a first aspect, an outgoing line limiting assembly is provided, and is used for limiting an outgoing line position of at least one power line and/or at least one signal line, the outgoing line limiting assembly comprises a line passing structure and a blocking structure, the line passing structure comprises a line inlet surface, a line outlet surface, and a power line via hole and a signal line via hole which penetrate through the line inlet surface and the line outlet surface, the power line via hole is used for supplying power line outgoing lines, the signal line via hole is used for supplying signal line outgoing lines, the line passing structure is further provided with a limiting part, and the limiting part encloses at least part of edges of the signal line via hole; the blocking structure is arranged on the outgoing line surface and is at least positioned between one power line via hole and one signal line via hole or between one power line via hole and another power line via hole or between one signal line via hole and another signal line via hole, and the blocking structure is at least used for blocking the power line from contacting with at least part of the signal lines or other power lines positioned on one side of the outgoing line surface when the power line positioned on one side of the outgoing line surface rotates around the corresponding axial direction of the power line via hole.

In one possible embodiment, the signal line via includes a first signal line via and a second signal line via, a portion of the signal line is routed from the first signal line via, another portion of the signal line is routed from the second signal line via, and the blocking structure includes a first blocking portion located between the first signal line via and the power line via and at least partially surrounding the first signal line via; the first blocking part is at least used for blocking the power line from contacting with the signal line which is led out from the first signal line through hole when the power line positioned on one side of the line outgoing surface rotates around the axial direction of the corresponding power line through hole.

In one possible implementation manner, the wire passing structure further comprises a wire outlet accommodating groove arranged on the wire outlet surface, the wire outlet accommodating groove is used for accommodating a signal wire which is led out from the second signal wire through hole, and the groove depth of the wire outlet accommodating groove is larger than or equal to the maximum outer diameter of the accommodated signal wire; the wire outlet accommodating groove is communicated with the second signal wire through hole and extends to the edge of the wire passing structure, so that a signal wire which is led out from the second signal wire through hole passes through the wire outlet accommodating groove to penetrate out from the edge of the wire passing structure, and the signal wire which is led out from the second signal wire through hole is prevented from being contacted with a power wire.

In one possible implementation manner, the first blocking portion surrounds the first signal line via hole, and surrounds the first signal line via hole to form a surrounding structure with a wire passing opening at one end, wherein the wire passing opening is at least used for allowing a signal line which is led out from the first signal line via hole to pass through; the wire outlet surface is also provided with a mounting groove, the mounting groove is communicated with the first signal wire through hole and the second signal wire through hole, and part of groove walls of the mounting groove are matched with edges of the first blocking part so as to install the first blocking part.

In one possible implementation manner, the blocking structure further comprises a fin connected with the first blocking portion, the second signal line via hole is located outside the surrounding area of the first blocking portion, the projection of the second signal line via hole on the fin is located in the covering area of the fin, the edge of the fin is matched with the groove wall of the other part of the mounting groove, and a gap is formed between the fin and the groove bottom of the mounting groove to be matched with the mounting groove to form a line passing channel from the second signal line via hole to the line passing opening, so that a signal line outgoing from the second signal line via hole sequentially passes through the line passing channel and the line passing opening.

In one possible implementation manner, the signal lines include a plurality of signal lines, the first signal line via includes a plurality of first signal line vias, the second signal line via includes a plurality of second signal line vias, the plurality of first signal line vias are arranged in a straight line, the blocking structure is disposed between the plurality of first signal line vias and the power line via, a part of the signal lines are led out from the corresponding first signal line vias and led out from one side of the line surface along a direction perpendicular to the line surface, the line accommodating groove includes a plurality of line accommodating grooves, and another part of the signal lines are led out from an edge of the line passing structure through the corresponding line accommodating groove after being led out from the corresponding second signal line vias and led out from one side of the line surface along a direction parallel to the line surface.

In one possible implementation manner, the signal lines include a plurality of signal lines, the first signal line via includes a plurality of first signal line vias, the second signal line via includes a plurality of second signal line vias, the plurality of first signal line vias are arranged in a straight line, the blocking structure is disposed between the plurality of first signal line vias and the power line via, part of the signal lines pass through the wire passing openings after being led out from the corresponding first signal line vias, and are led out from one side of the wire outgoing surface along a direction perpendicular to the wire outgoing surface, the fins include a plurality of fins, the wire passing channels from the second signal line vias to the wire passing openings are also formed in cooperation with the mounting groove, and the other part of the signal lines pass through the corresponding wire passing channels and the wire passing openings after being led out from the second signal line vias, and pass through one side of the wire outgoing surface along the direction perpendicular to the wire outgoing surface.

In one possible implementation manner, the blocking structure further includes a second blocking portion, where the second blocking portion is disposed on the wire outlet surface of the wire passing structure and is at least located on a rotation path of the power wire on one side of the wire outlet surface, where the second blocking portion is configured to limit rotation of the power wire to contact with at least a portion of a signal wire that is led out from the second signal wire via hole.

In a second aspect, a connector is further provided, where the connector includes a socket, a power line assembly, a signal line assembly, and the wire-outlet limiting assembly, the socket includes a substrate and a plug portion connected to each other, the wire-outlet limiting assembly is fixedly connected to the plug portion, the plug portion is used for plugging one ends of the power line assembly and the signal line assembly, and the other ends of the power line assembly and the signal line assembly correspond to the power line via hole and the signal line via hole of the wire-outlet structure through the wire-outlet limiting assembly. The wire outlet limiting assembly comprises a wire outlet structure and a blocking structure, wherein the wire outlet structure comprises a wire inlet surface, a wire outlet surface, and a power wire through hole and a signal wire through hole which penetrate through the wire inlet surface and the wire outlet surface, the power wire through hole is used for supplying power wires for wire outlet, and the signal wire through hole is used for supplying signal wires for wire outlet; the blocking structure is arranged on the outgoing line surface and is at least positioned between one power line via hole and one signal line via hole, and the blocking structure is at least used for blocking the contact between the power line and at least part of the signal lines positioned on one side of the outgoing line surface when the power line positioned on one side of the outgoing line surface rotates around the corresponding axial direction of the power line via hole.

In one possible implementation manner, the power line assembly comprises a power terminal, an OT terminal and a power line, wherein one end of the power terminal is plugged into the plugging part, the OT terminal is used for connecting the other end of the power terminal with one end of the power line, and the other end of the power line is led out through the power line through hole; the signal wire assembly comprises a signal terminal and a signal wire, one end of the signal terminal is inserted into the insertion part, the other end of the signal terminal is connected with one end of the signal wire, and the other end of the signal wire is led out through the signal wire through hole.

In one possible implementation, the projection of the power via of the wire passing structure in the axial direction includes two opposite straight sides and other sides connected between the two straight sides, and the two straight sides are matched with the peripheral edges of the power terminals so as to limit the power terminals in the power via.

The wire outlet limiting assembly and the connector can limit the wire outlet position of the power wire and/or the signal wire by arranging the wire outlet structure, and at least one blocking structure is arranged between the power wire through hole and the signal wire through hole or between the power wire through hole and the other power wire through hole or between the signal wire through hole and the other signal wire through hole, and can be used for blocking the power wire to be contacted with at least part of the signal wire or other power wires on one side of the wire outlet surface when the power wire on one side of the wire outlet surface is wound around the corresponding axial rotation of the power wire through hole, so that the damage to the signal wire or other power wires due to the rotation of the power wire is avoided as much as possible, and the damage to the connector and possible safety accidents are avoided.

Drawings

In order to more clearly describe the technical solutions in the embodiments or the background of the present application, the following description will describe the drawings that are required to be used in the embodiments or the background of the present application.

Fig. 1 is a schematic view of an outgoing line limiting assembly according to an embodiment of the present application.

Fig. 2 is a schematic diagram of a wire passing structure of a wire outlet limiting assembly according to an embodiment of the present application.

Fig. 3 is a schematic view of a blocking structure of an outgoing line limiting assembly according to an embodiment of the present application.

Fig. 4 is a schematic plan view of an outgoing line limiting assembly according to an embodiment of the present application.

Fig. 5 is a schematic cross-sectional view of the present application taken along section line A-A shown in fig. 4.

Fig. 6 is a schematic diagram of a connector according to an embodiment of the present application.

Fig. 7 is a schematic view of a connector according to another embodiment of the present application.

Fig. 8 is an exploded view of a connector according to an embodiment of the present application.

Fig. 9 is a schematic diagram of a wire passing structure of a wire outlet limiting assembly of a connector according to an embodiment of the present application.

Reference numerals illustrate: 1. connector, 10, wire-out limit assembly, 100, wire-through structure, 110, wire-in face, 120, wire-out face, 121, mounting slot, 130, power wire via, 131, straight side, 132, other side, 140, signal wire via, 141, first signal wire via, 142, second signal wire via, 150, wire-out housing slot, 151, fixing portion, 160, first blocking structure connecting portion, 170, second blocking portion, 180, limit portion, 190, first wire-through structure connecting portion, 200, blocking structure, 210, first blocking portion, 220, wire-through opening, 230, tab, 231, wire-through channel, 240, reinforcing portion, 250, second blocking structure connecting portion, 30, socket, 310, substrate, 320, plug-in portion, 321, second wire-through structure connecting portion, 40, power wire assembly, 410, power terminal, 420, OT terminal, 430, power wire, 440, connecting member, 50, signal wire assembly, 510, signal terminal, 520, signal wire, 60, gasket, 70, first ring, 80, second ring, and fixing member.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without undue burden, are within the scope of the present application.

In the description of the embodiments of the present application, it should be noted that, the directions or positional relationships indicated by the terms "upper", "lower", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, and are merely for convenience of describing the present application and simplifying the description, and do not imply or indicate that the apparatus or element referred to must have a specific direction, be configured and operated in a specific direction, and thus should not be construed as limiting the present application.

In the description of the embodiments of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

The terms "first" and "second" are used below for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the embodiments of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more.

Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or server that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed or inherent to such process, method, article, or apparatus, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Referring to fig. 1, fig. 1 is a schematic diagram of an outgoing line limiting assembly according to an embodiment of the present application. As shown in fig. 1, the present application provides an outgoing line limiting assembly 10, configured to limit an outgoing line position of at least one power line and/or at least one signal line, where the outgoing line limiting assembly 10 includes a wire passing structure 100 and a blocking structure 200, the wire passing structure 100 includes a wire inlet surface 110, a wire outlet surface 120, and a power line via hole 130 and a signal line via hole 140 penetrating through the wire inlet surface 110 and the wire outlet surface 120, the power line via hole 130 is configured to supply a power line for outgoing line, the signal line via hole 140 is configured to supply a signal line for outgoing line, and the wire passing structure 100 further includes a limiting portion 180, where the limiting portion 180 encloses an edge of at least part of the signal line via hole 140; the blocking structure 200 is disposed on the outgoing line surface 120 and is at least located between one power line via 130 and one signal line via 140 or between one power line via 130 and another power line via 130 or between one signal line via 140 and another signal line via 140, and the blocking structure 200 is at least used for blocking the power line from contacting at least part of the signal line or other power line located on one side of the outgoing line surface 120 when the power line located on one side of the outgoing line surface 120 rotates around the axial direction of the corresponding power line via 130.

Therefore, the wire outlet limiting assembly 10 in the present application can limit the wire outlet positions of the power wire and the signal wire by arranging the wire outlet structure 100, and prevent the power wire from contacting at least part of the signal wire or other power wires on the wire outlet surface 120 side by arranging the blocking structure 200 at least between one power wire through hole 130 and one signal wire through hole 140 or another power wire through hole 130 or between one power wire through hole 130 and another power wire through hole 130 or between one signal wire through hole 140 and another signal wire through hole 140, thereby avoiding damage to the signal wire or other power wires due to rotation of the power wire as much as possible, and avoiding damage to the connector and possible safety accidents when the power wire on the wire outlet surface 120 side rotates around the corresponding axial direction of the power wire through hole 130.

Specifically, the power line on the side of the wire outgoing surface 120 needs to avoid the signal line on the side of the wire outgoing surface 120, and the power line needs to be outgoing after switching, but the power line after switching often follows the switching component to rotate around the axial direction of the corresponding power line via hole 130, so that the power line may contact with at least part of the signal line or other power lines on the side of the wire outgoing surface 120, and cause damage to the signal line or other power lines.

It should be noted that, the contact between the power line and at least part of the signal line or other power line located on the side of the outgoing line face 120 may cause damage to the signal line or other power line due to impact caused by rotation of the power line, may cause degradation of the signal line or other power line due to high temperature of the power line during use, and may cause interference of transmission signals of the signal line or other power line due to contact between the two.

It should be noted that, the power line may directly be led out from the power line via hole 130, or may be led out from the side of the wire-outlet surface 120 through another connection structure of the power line passing through the power line via hole 130, or the signal line may directly be led out from the signal line via hole 140 through another connection structure of the signal line passing through the signal line via hole 140, or the signal line connected to another connection structure may be led out from the side of the wire-outlet surface 120.

In one or more embodiments, the blocking structure 200 also serves to block the signal line from contacting at least a portion of the signal line located on one side of the outlet face 120.

In one or more embodiments, the number of the power line vias 130 corresponds to the number of the power lines, the number of the power line vias 130 may be one or more, the number of the signal line vias 140 corresponds to the number of the signal lines, and the number of the signal line vias 140 may be one or more.

In one or more embodiments, the cross-sectional apertures and/or shapes of the power line via 130 and the signal line via 140 may be the same or different, and the cross-sectional shapes of the power line via 130 and the signal line via 140 may be circular, rectangular, irregular, etc.

In one or more embodiments, the blocking structure 200 may be integrally disposed on the wire outlet surface 120 of the wire passing structure 100, may be disposed on the wire outlet surface 120 of the wire passing structure 100 by any one or more of clamping, welding, bonding, riveting, magnetic attraction, and the like, or may be disposed on the wire outlet surface 120 of the wire passing structure 100 by other manners. For example, as shown in fig. 1, when the blocking structure 200 is integrally disposed on the outgoing line surface 120 of the wire passing structure 100, the outgoing line limiting assembly 10 has better integrity, simple and reliable structure, is not easy to damage, and can better block the contact between the power line and at least part of the signal line located on one side of the outgoing line surface 120. When the blocking structure 200 is detachably disposed on the outgoing line surface 120 of the wire passing structure 100 by any one or more combination modes such as clamping, magnetic attraction, etc., different blocking structures 200 can be replaced according to specific needs, so as to better block the contact between the power line and at least part of the signal lines located on one side of the outgoing line surface 120.

In one or more embodiments, the material of the blocking structure 200 may be a composite material including nylon, and the blocking structure 200 is further configured to thermally insulate at least a portion of the signal line located on the side of the outlet face 120 when the power line located on the side of the outlet face 120 is rotated around the corresponding axial direction of the power line via 130.

As shown in fig. 1, the signal line via 140 includes a first signal line via 141 and a second signal line via 142, a portion of the signal line is led out from the first signal line via 141, another portion of the signal line is led out from the second signal line via 142, and the blocking structure 200 includes a first blocking portion 210, where the first blocking portion 210 is located between the first signal line via 141 and the power line via 130 and at least partially surrounds the first signal line via 141; the first blocking portion 210 is at least configured to block the power line from contacting the signal line led out from the first signal line via 141 when the power line located on the side of the outgoing surface 120 rotates around the axial direction of the corresponding power line via 130.

Accordingly, a part of the signal lines are led out from the first signal line through holes 141, another part of the signal lines are led out from the second signal line through holes 142, and the blocking structure 200 comprises a first blocking portion 210, wherein the first blocking portion 210 is located between the first signal line through holes 141 and the power line through holes 130 and at least partially surrounds the first signal line through holes 141, and can prevent the power line from contacting with the signal line led out from the first signal line through holes 141 when the power line located on one side of the wire outlet surface 120 rotates around the axial direction of the corresponding power line through holes 130, so that damage to the signal line led out from the first signal line through holes 141 due to rotation of the power line is avoided, and damage to a connector and possible safety accidents are avoided.

In one or more embodiments, the number of the first signal line vias 141 may be one or more, and the number of the second signal line vias 142 may be one or more.

In one or more embodiments, the first blocking portion 210 may be disposed only between the first signal line via 141 and the power line via 130, partially surrounding the first signal line via 141, or may be disposed not only between the first signal line via 141 and the power line via 130, but also surrounding the first signal line via 141.

As shown in fig. 1, the wire passing structure 100 further includes a wire outlet accommodating groove 150 disposed on the wire outlet surface 120, the wire outlet accommodating groove 150 is configured to accommodate a signal wire that is led out from the second signal wire via hole 142, and a groove depth of the wire outlet accommodating groove 150 is greater than or equal to a maximum outer diameter of the accommodated signal wire; the wire-out receiving groove 150 is communicated with the second signal wire through hole 142 and extends to the edge of the wire-through structure 100, so that the signal wire which is wire-out from the second signal wire through hole 142 passes out from the edge of the wire-through structure 100 through the wire-out receiving groove 150, and the signal wire which is wire-out from the second signal wire through hole 142 is prevented from contacting with the power wire.

Accordingly, the signal wires led out from the second signal wire through holes 142 are accommodated by the wire-outlet accommodating groove 150, the groove depth of the wire-outlet accommodating groove 150 is larger than or equal to the maximum outer diameter of the accommodated signal wires, the signal wires led out from the second signal wire through holes 142 are ensured not to be higher than the wire-outlet surface 120, the wire-outlet accommodating groove 150 is communicated with the second signal wire through holes 142 and extends to the edge of the wire-outlet structure 100, the signal wires led out from the second signal wire through holes 142 can be led out from the edge of the wire-outlet structure 100 through the wire-outlet accommodating groove 150, the signal wires led out from the second signal wire through holes 142 are prevented from contacting with the power wires, damage to the signal wires led out from the second signal wire through holes 142 due to rotation of the power wires is prevented, and damage to connectors and possible safety accidents are avoided.

In one or more embodiments, the bottom width of the wire-out receiving groove 150 may be slightly smaller than the maximum outer diameter of the received signal wire, so that the signal wire, which is wire-out from the second signal wire via hole 142, can be interference-fitted with the wire-out receiving groove 150 when being pressed into the wire-out receiving groove 150, thereby having a certain fixing effect.

In one or more embodiments, the number of the wire-out receiving grooves 150 corresponds to the number of the second signal wire vias 142, and the number of the wire-out receiving grooves 150 may be one or more.

As shown in fig. 1, a fixing portion 151 is provided in the wire-outlet accommodation groove 150, and the fixing portion 151 abuts against the signal wire which is accommodated in the wire-outlet accommodation groove 150 and is wire-outlet from the second signal wire via hole 142, so as to fix the signal wire which is wire-outlet from the second signal wire via hole 142 better.

Accordingly, by providing the fixing portion 151 in the slot of the wire housing slot 150, the fixing portion 151 abuts against the signal wire received in the wire housing slot 150 and being led out from the second signal wire via hole 142, the signal wire led out from the second signal wire via hole 142 can be fixed.

In one or more embodiments, the fixing portion 151 may be integrally disposed in the slot of the outlet receiving slot 150, or may be disposed in the slot of the outlet receiving slot 150 by any one or more combination of welding, bonding, etc. For example, as shown in fig. 1, the fixing portion 151 is integrally provided in the wire housing groove 150, and can more stably fix the signal wire which is wire-led from the second signal wire via hole 142.

Referring to fig. 2 and 3, fig. 2 is a schematic diagram of a wire passing structure of a wire outlet limiting assembly according to an embodiment of the present application, and fig. 3 is a schematic diagram of a blocking structure of the wire outlet limiting assembly according to an embodiment of the present application. As shown in fig. 2 and 3, the first blocking portion 210 surrounds the first signal line via 141, and forms a surrounding structure with a wire through hole 220 at one end, and the wire through hole 220 is at least used for passing through a signal line led out from the first signal line via 141; the outlet face 120 further has a mounting groove 121, the mounting groove 121 communicates with the first signal line via 141 and the second signal line via 142, and a portion of a groove wall of the mounting groove 121 is matched with an edge of the first blocking portion 210 to mount the first blocking portion 210.

Thus, the first blocking portion 210 surrounds the first signal line via 141, and surrounds the surrounding structure having the via hole 220 at one end, the first signal line via 141 communicates with the surrounding structure having the via hole 220 formed by the first blocking portion 210, the first blocking portion 210 allows the signal line led out from the first signal line via 141 to pass through the via hole 220, and the mounting groove 121 is provided on the wire outlet surface 120 of the wire passing structure 100 to communicate with the first signal line via 141 and the second signal line via 142, and can cooperate with the edge of the first blocking portion 210 to mount the first blocking portion 210.

As shown in fig. 3, the barrier structure 200 may further include a reinforcement part 240 connected to the first barrier part 210, the reinforcement part 240 dividing the wire passing opening 220 for reinforcing the barrier structure 200.

Therefore, by the reinforcement portion 240 connected to the first blocking portion 210, the reinforcement portion 240 divides the wire passing opening 220, so that the stability of the blocking structure 200 can be enhanced, and deformation of the first blocking portion 210 is avoided, thereby causing deformation of the wire passing opening 220 and affecting the signal wire passing through the wire passing opening 220.

Referring to fig. 4 and 5, fig. 4 is a schematic plan view of an outgoing line limiting assembly according to an embodiment of the present application, and fig. 5 is a schematic sectional view of the outgoing line limiting assembly according to an embodiment of the present application, taken along a section line A-A shown in fig. 4. As shown in fig. 2-5, the blocking structure 200 further includes a fin 230 connected to the first blocking portion 210, the second signal wire via 142 is located outside the surrounding area of the first blocking portion 210, and the projection of the second signal wire via 142 on the fin 230 is located within the coverage area of the fin 230, the edge of the fin 230 is matched with the groove wall of the other part of the mounting groove 121, and the fin 230 and the groove bottom of the mounting groove 121 have a gap, so as to form a wire passing channel 231 from the second signal wire via 142 to the wire passing opening 220 in cooperation with the mounting groove 121, so that the signal wire outgoing from the second signal wire via 142 sequentially passes through the wire passing channel 231 and the wire passing opening 220.

Thus, by the tab 230 connected to the first blocking portion 210, the second signal wire via 142 is located outside the surrounding area of the first blocking portion 210, and the projection of the second signal wire via 142 on the tab 230 is located within the coverage area of the tab 230, the edge of the tab 230 cooperates with the other portion of the slot wall of the mounting slot 121, and the tab 230 and the slot bottom of the mounting slot 121 have a gap to cooperate with the mounting slot 121 to form the wire passing channel 231 from the second signal wire via 142 to the wire passing port 220, so that the signal wire outgoing from the second signal wire via 142 can pass through the wire passing channel 231 and the wire passing port 220 in sequence.

It should be noted that, as shown in fig. 5, the blocking structure 200 may be detachably disposed on the wire outlet surface 120 of the wire passing structure 100 by any one or more combination modes such as clamping, so as to facilitate the mold opening of the blocking structure 200 during the manufacturing process and improve the assembly efficiency due to the change of the wire outlet position of the signal wire which is led out from the second signal wire via hole 142.

In one or more embodiments, the tab 230 and the first blocking portion 210 may be integrally connected to form the blocking structure 200, or may be welded, glued, riveted, or any combination thereof to form the blocking structure 200. For example, as shown in fig. 4, the wing 230 is integrally connected with the first blocking portion 210 to form the blocking structure 200, and the blocking structure 200 has better integrity, simple and reliable structure, and is not easy to damage.

In one or more embodiments, the material of the tab 230 may be a composite material including nylon, and the tab 230 may also be capable of thermally insulating and protecting the signal line coming out of the second signal line via 142 when the power line on the side of the output wire face 120 is rotated around the axial direction of the corresponding power line via 130.

Please refer to fig. 1 again. As shown in fig. 1, the first signal line via 141 includes a plurality of first signal line vias 141, the second signal line via 142 includes a plurality of second signal line vias 142, the plurality of first signal line vias 141 are arranged in a straight line, the blocking structure 200 is disposed between the plurality of first signal line vias 141 and the power line via 130, and a portion of the signal lines are led out from the corresponding first signal line via 141 and are led out from one side of the lead-out surface 120 along a direction perpendicular to the lead-out surface 120.

Therefore, for the case of the plurality of first signal line vias 141 and the plurality of second signal line vias 142, the blocking structure 200 can be disposed between the plurality of first signal line vias 141 and the power line vias 130 arranged in a straight line, and part of the signal lines are led out from the corresponding first signal line vias 141, and can be led out from one side of the wire-out surface 120 along the direction perpendicular to the wire-out surface 120, so that part of the signal lines are prevented from contacting with the power line, damage to part of the signal lines caused by rotation of the power line is avoided, and damage to the connector and possible safety accidents are avoided.

Specifically, without changing the arrangement of the signal lines, the blocking structure 200 may be disposed between the plurality of first signal line vias 141 and the power line via 130 arranged in a straight line as much as possible, so that the blocking structure 200 protects the signal lines as much as possible, and further, more signal lines can be led out from one side of the line outgoing surface 120 along the direction perpendicular to the line outgoing surface 120, the line outgoing positions are more concentrated, and the signal lines are led out again from the external mounting holes.

In one or more embodiments, as shown in fig. 2 and 4, the power line via 130 includes two power line vias 130, the first signal line via 141 includes four first signal line vias 141, the second signal line via 142 includes four second signal line vias 142, the four first signal line vias 141 are arranged in a straight line, the blocking structure 200 is disposed between the four first signal line vias 141 and the two power line vias 130, and the four signal lines are led out from the corresponding first signal line vias 141 and led out from one side of the lead out plane 120 along a direction perpendicular to the lead out plane 120.

As shown in fig. 1, the wire-outlet receiving groove 150 includes a plurality of wire-outlet receiving grooves 150, and another part of the signal wires are led out from the corresponding second signal wire through holes 142, then are led out from the edge of the wire-outlet structure 100 through the corresponding wire-outlet receiving grooves 150, and are led out from one side of the wire-outlet surface 120 along the direction parallel to the wire-outlet surface 120.

Therefore, for the case of the plurality of wire-outlet accommodating grooves 150, after the other part of signal wires are led out from the corresponding second signal wire through holes 142, the other part of signal wires pass through the corresponding wire-outlet accommodating grooves 150 and come out from the edge of the wire-outlet structure 100, so that the wires can be led out from one side of the wire-outlet surface 120 along the direction parallel to the wire-outlet surface 120, the contact of the other part of signal wires with the power wires is avoided, the damage to the other part of signal wires caused by the rotation of the power wires is avoided, and the damage to the connector and possible safety accidents caused by the rotation of the power wires are avoided.

In one or more embodiments, as shown in fig. 1, the wire-outlet receiving groove 150 includes four wire-outlet receiving grooves 150, and four first signal wires are led out from the corresponding second signal wire through holes 142, then are led out from the edge of the wire-passing structure 100 through the corresponding wire-outlet receiving grooves 150, and are led out from one side of the wire-outlet surface 120 along a direction parallel to the wire-outlet surface 120.

Please refer to fig. 2-5 again. As shown in fig. 2 to 5, the signal lines include a plurality of signal lines, the first signal line via 141 includes a plurality of first signal line vias 141, the second signal line via 142 includes a plurality of second signal line vias 142, the plurality of first signal line vias 141 are arranged in a straight line, the blocking structure 200 is disposed between the plurality of first signal line vias 141 and the power line via 130, and a portion of the signal lines exit through the line port 220 after exiting from the corresponding first signal line via 141, and exit from one side of the line surface 120 along a direction perpendicular to the line surface 120.

Therefore, for the case of the plurality of first signal line vias 141 and the plurality of second signal line vias 142, the blocking structure 200 can be disposed between the plurality of first signal line vias 141 and the power line via 130 arranged in a straight line, and part of the signal lines are led out from the corresponding first signal line vias 141, and can be led out from one side of the wire-out surface 120 through the wire-through opening 220 after being led out along the direction perpendicular to the wire-out surface 120, so that the contact of part of the signal lines with the power line is avoided, the damage to part of the signal lines caused by the rotation of the power line is avoided, and the damage to the connector and possible safety accidents caused are avoided.

As shown in fig. 4 and 5, the fins 230 include a plurality of fins 230, and the wire passing channels 231 formed from the second signal wire through holes 142 to the wire passing openings 220 in cooperation with the mounting grooves 121 also include a plurality of wire passing channels 231, and another part of the signal wires are led out from the second signal wire through holes 142, sequentially pass through the corresponding wire passing channels 231 and the wire passing openings 220, and are led out from one side of the wire outlet surface 120 along the direction perpendicular to the wire outlet surface 120.

Therefore, for the case of the plurality of fins 230, the wire passing channel 231 formed by matching with the mounting groove 121 from the second signal wire through hole 142 to the wire passing port 220 also includes a plurality of wire passing channels 231, and the other part of signal wires sequentially pass through the corresponding wire passing channels 231 and the wire passing port 220 to be discharged after being discharged from the second signal wire through hole 142, so that the wires can be discharged from one side of the wire outlet surface 120 along the direction perpendicular to the wire outlet surface 120, the contact of the other part of signal wires with the power wires is avoided, the damage to the other part of signal wires caused by the rotation of the power wires is avoided, and the damage to the connector and possible safety accidents caused by the rotation of the power wires are avoided.

Meanwhile, under the condition that the arrangement of the signal wires is not changed, another part of the signal wires also pass through the wire passing port 220, so that the blocking structure 200 can protect all the signal wires, and further all the signal wires can be led out from one side of the wire outgoing surface 120 along the direction perpendicular to the wire outgoing surface 120, the wire outgoing positions are most concentrated, and the signal wires can be led out again from the external mounting holes more conveniently.

As shown in fig. 2-4, the wire outlet limiting assembly 10 further includes a first blocking structure connecting portion 160 disposed on the wire outlet surface 120 of the wire passing structure 100, the first blocking portion 210 includes a corresponding second blocking structure connecting portion 250, and the first blocking structure connecting portion 160 and the second blocking structure connecting portion 250 are buckled with each other, so that the blocking structure 200 is fixedly connected with the wire passing structure 100 through the first blocking portion 210.

Thus, through the first blocking structure connection portion 160 disposed on the outgoing line surface 120 of the wire passing structure 100, the first blocking portion 210 includes the corresponding second blocking structure connection portion 250, and the first blocking structure connection portion 160 and the second blocking structure connection portion 250 are fastened to each other, so that the blocking structure 200 can be fixedly connected with the wire passing structure 100 through the first blocking portion 210.

In one or more embodiments, the number of the first blocking structure connection parts 160 corresponds to the number of the second blocking structure connection parts 250, and the number of the first blocking structure connection parts 160 may be one or more, and the number of the second blocking structure connection parts 250 may be one or more. For example, as shown in fig. 2 to 4, the number of the first blocking structure connecting parts 160 is two, and the number of the second blocking structure connecting parts 250 is also two, so that the blocking structure 200 can be more firmly connected with the wire passing structure 100.

As shown in fig. 2 and 4, the blocking structure 200 further includes a second blocking portion 170, where the second blocking portion 170 is disposed on the outgoing surface 120 of the wire passing structure 100, and at least on a rotating path of the power line on one side of the outgoing surface 120 around the corresponding power line via 130 in an axial direction, and the second blocking portion 170 is configured to limit the power line from rotating until contacting at least a portion of the signal line outgoing from the second signal line via 142.

Accordingly, the second blocking portion 170 provided on the wire outlet surface 120 of the wire passing structure 100 and at least on the power wire on the wire outlet surface 120 side is rotated around the corresponding power wire via hole 130 in the axial direction, so that the power wire can be restricted from rotating to contact with at least a part of the signal wire which is led out from the second signal wire via hole 142.

In one or more embodiments, the location and number of second stops 170 may be set according to particular needs. For example, as shown in fig. 2 and 4, the number of the second blocking portions 170 may be two, and the number of the power line vias 130 may be two, where the second blocking portions 170 are disposed on one side of the wire-outlet surface 120 where the power line is axially rotated around the corresponding power line via 130, and the second blocking portions 170 limit the rotation of the power line only until the power line contacts with a portion of the signal line which is wire-outlet from the second signal line via 142, so that the limitation of the rotation path of the power line on the wire-outlet surface 120 side can be reduced, and the second blocking portions 170 do not block the rotation of the power line when the power line needs to be wire-outlet again from other positions in the rotation path from the external mounting hole. The number of the second blocking portions 170 may be four, the number of the power line vias 130 is still two, the second blocking portions 170 are disposed on two sides of the power line located on one side of the outgoing line surface 120 and axially rotate around the corresponding power line via 130, the second blocking portions 170 limit the power line from rotating to be in contact with the signal line outgoing from the second signal line via 142, so as to avoid damage to the signal line caused by rotation of the power line as far as possible, and damage to the connector and possible safety accidents caused by the rotation of the power line are avoided.

The wire outlet limiting assembly 10 of the present application, through the above structure, does not need to change the arrangement of the original power wire and the signal wire, and can prevent the power wire from contacting with part or all of the signal wires on one side of the wire outlet surface 120 when the power wire on one side of the wire outlet surface 120 rotates around the corresponding axial direction of the power wire through hole 130, so as to avoid damage to the signal wire caused by rotation of the power wire as much as possible, and avoid damage to the connector and possible safety accidents.

Referring to fig. 6, 7 and 8, fig. 6 is a schematic view of a connector according to an embodiment of the present application, fig. 7 is a schematic view of a connector according to another embodiment of the present application, and fig. 8 is an exploded schematic view of a connector according to an embodiment of the present application. As shown in fig. 6, 7 and 8, the present application further provides a connector 1, where the connector 1 includes a socket 30, a power cord assembly 40, a signal cord assembly 50 and an outgoing line limiting assembly 10 in any of the foregoing embodiments, the socket 30 includes a substrate 310 and a plug portion 320 that are connected, the outgoing line limiting assembly 10 is fixedly connected with the plug portion 320, the plug portion 320 is used for plugging one ends of the power cord assembly 40 and the signal cord assembly 50, and the other ends of the power cord assembly 40 and the signal cord assembly 50 correspondingly go out through a power cord via hole 130 and a signal cord via hole 140 of a wire passing structure 100 of the outgoing line limiting assembly 10.

The wire-outlet limiting assembly 10 comprises a wire-outlet structure 100 and a blocking structure 200, wherein the wire-outlet structure 100 comprises a wire-inlet surface 110, a wire-outlet surface 120, a power wire through hole 130 and a signal wire through hole 140, wherein the power wire through hole 130 is used for supplying a power wire 430 to be out, and the signal wire through hole 140 is used for supplying a signal wire 520 to be out; the blocking structure 200 is disposed on the outgoing line surface 120 and is at least located between one power line via 130 and one signal line via 140, and the blocking structure 200 is at least used for blocking the contact between the power line 430 and at least part of the signal line 520 located on one side of the outgoing line surface 120 when the power line 430 located on one side of the outgoing line surface 120 rotates around the corresponding axial direction of the power line via 130.

The more specific structure of the wire-outlet limiting assembly 10 can be seen from the related content of the wire-outlet limiting assembly 10 in any of the foregoing embodiments, and will not be described herein.

Accordingly, one ends of the power line assembly 40 and the signal line assembly 50 are plugged through the plugging portion 320, and the other ends of the power line assembly 40 and the signal line assembly 50 correspondingly complete the wire outgoing through the power line via 130 and the signal line via 140 of the wire-passing structure 100 of the wire-outgoing limiting assembly 10.

As shown in fig. 6, 7 and 8, the power cord assembly 40 includes a power cord 410, an OT Terminal 420 (OT Terminal) and a power cord 430, wherein one end of the power cord 410 is plugged into the plug portion 320, the OT Terminal 420 is used for connecting the other end of the power cord 410 with one end of the power cord 430, and the other end of the power cord 430 is wired out through the power cord via hole 130; the signal line assembly 50 includes a signal terminal 510 and a signal line 520, wherein one end of the signal terminal 510 is plugged into the plugging portion 320, the other end of the signal terminal 510 is connected with one end of the signal line 520, and the other end of the signal line 520 is led out through the signal line via hole 140.

Thus, by the power line assembly 40 including the power supply terminal 410 and the OT terminal 420 and the signal line assembly 50 including the signal terminal 510, connection of the power line assembly 40 and the signal line assembly 50 from the socket 320 to the power line or the signal line 520 can be achieved.

In one or more embodiments, as shown in fig. 6 and 8, the power cord assembly 40 further includes a connector 440, and the ot terminal 420 is connected to the power terminal 410 through the connector 440. Wherein the connection member 440 may be a screw.

Specifically, since the OT terminal 420 is connected to the other end of the power terminal 410 via the connector 440 and is connected to one end of the power wire 430, the other end of the power wire 430 is wired out through the power wire via 130, so that in use, the power wire 430 tends to follow the OT terminal 420 to rotate around the corresponding power wire via 130, and thus the power wire 430 may contact with at least a portion of the signal wire 520 located on one side of the wire outgoing surface 120, resulting in damage to the signal wire 520.

In one or more embodiments, the number of the power terminals 410 and the OT terminals 420 corresponds to the number of the power lines 430, and the number of the power terminals 410 and the OT terminals 420 may be one or more. The number of signal terminals 510 corresponds to the number of signal lines 520, and the number of signal terminals 510 may be one or more.

In one or more embodiments, the specification of the power terminal 410 may also be selected according to actual needs, which is not limited in this application. For example, the number of the power supply terminals 410 and the OT terminals 420 may be plural, and the number of the power supply terminals 410 may be 4.8 terminals.

In one or more embodiments, the specification of the signal terminal 510 may be selected according to actual needs, which is not limited in this application. For example, the number of the signal terminals 510 is plural, and the signal terminals 510 may be any one or a combination of 1.5 terminals and 2.4 terminals.

It should be noted that, as shown in fig. 6, a portion of the signal lines 520 are led out from the corresponding first signal line via holes 141, and are led out from one side of the wire outlet surface 120 along the direction perpendicular to the wire outlet surface 120, and another portion of the signal lines 520 are led out from the corresponding second signal line via holes 142, and then are led out from the edge of the wire passing structure 100 through the corresponding wire outlet receiving grooves 150, and are led out from one side of the wire outlet surface 120 along the direction parallel to the wire outlet surface 120. As shown in fig. 7, the power line 430 located at one side of the outgoing line surface 120 is not shown in fig. 7, so that the cooperation between the blocking structure 200 and the signal line 520 in another embodiment of the present application can be seen more clearly, a part of the signal line 520 is led out from the corresponding first signal line via hole 141 through the wire through hole 220, and is led out from one side of the outgoing line surface 120 along the direction perpendicular to the outgoing line surface 120, and another part of the signal line 520 is led out from the second signal line via hole 142 through the corresponding wire through channel 231 and the wire through hole 220, and is led out from one side of the outgoing line surface 120 along the direction perpendicular to the outgoing line surface 120. The smaller the size of the mounting hole of the outer housing in the energy storage element such as a battery, the better the signal wires 520 need to be re-wired from the external mounting hole, and in the connector 1 shown in fig. 7, the blocking structure 200 can protect all the signal wires 520, so that all the signal wires 520 can be wired from one side of the wire-out surface 120 in the direction perpendicular to the wire-out surface 120, the most concentrated wire-out positions are more convenient for re-wired the signal wires 520 from the external mounting hole, and the size of the external mounting hole can be set smaller, compared with the connector 1 shown in fig. 6.

As shown in fig. 6, 7 and 8, the connector 1 further includes a gasket 60, a first annular ring 70, and a second annular ring 80, the gasket 60 is sleeved on the outer periphery of the plug portion 320, the first annular ring 70 is sleeved on the outer periphery of the power terminal 410, and the second annular ring 80 is sleeved on the outer periphery of the signal terminal 510.

Accordingly, the gasket 60, the first annular ring 70, and the second annular ring 80 are provided, the gasket 60 is sleeved on the outer periphery of the plug-in portion 320, the first annular ring 70 is sleeved on the outer periphery of the power terminal 410, the second annular ring 80 is sleeved on the outer periphery of the signal terminal 510, the waterproof level of IPX7 on one side of the plug-in portion 320 can be achieved, and the plug-in portion 320 is plugged in cooperation with the power terminal 410 and the signal terminal 510.

In one or more embodiments, the connector 1 further includes a fixing member 90, and the substrate 310 is provided with a fixing hole corresponding to the gasket 60, and the fixing member 90 penetrates the fixing hole for fixing the gasket 60.

In one or more embodiments, the gasket 60, the first annular ring 70, and the second annular ring 80 may be made of rubber, and the first annular ring 70 and the second annular ring 80 may be circular in shape.

Please refer to fig. 1, fig. 2, fig. 4, fig. 7 again. As shown in fig. 1, 2, 4 and 7, the projection of the power via of the wire passing structure 100 in the axial direction includes two opposite straight sides 131 and other sides 132 connected between the two straight sides 131, and the two straight sides 131 cooperate with the peripheral edges of the power terminals 410 to limit the power terminals 410 in the power via 130.

Thus, by the two straight edges 131 being matched with the peripheral edges of the power supply terminal 410, the power supply terminal 410 in the power supply wire through hole 130 can be limited in the axial direction of the power supply terminal 410, and positioning of the power supply terminal 410 when passing through the power supply wire through hole 130 is facilitated.

In one or more embodiments, the other edge 132 may be two arcuate edges to accommodate the perimeter of the power terminal 410.

Referring to fig. 9, fig. 9 is a schematic diagram illustrating a wire passing structure of a wire outlet limiting assembly of a connector according to an embodiment of the disclosure. As shown in fig. 9, the wire passing structure 100 further has a limiting portion 180, where the limiting portion 180 encloses at least part of the edge of the signal wire via 140, and the limiting portion 180 is used for limiting the signal terminal 510 in the signal wire via 140.

Thus, the limiting portion 180 surrounds at least a part of the edge of the signal line via 140, so that the axial direction and the radial direction of the signal terminal 510 in the signal line via 140 can be limited.

In one or more embodiments, there are a plurality of signal terminals 510, wherein one signal terminal 510 is a 2.4 terminal, the other signal terminals 510 are 1.5 terminals, and the signal wire through holes 140 for outgoing the 2.4 terminals are too small in distance from the other signal wire through holes 140, and the signal terminals 510 with different specifications also have certain requirements on the thickness of the limiting portion 180, and generally speaking, the thickness of the limiting portion 180 is required to be thicker than that of the 1.5 terminals for the 2.4 terminals. Therefore, as shown in fig. 9, the limiting portion 180 encloses the edge of the signal wire via hole 140 for outgoing 2.4 terminals, and the limiting portion 180 encloses the edge of the signal wire via hole 140 for outgoing 1.5 terminals, so as to meet the thickness requirement of the signal terminals 510 with different specifications on the limiting portion 180 without changing the arrangement of the signal wires.

As shown in fig. 1, 2, 4, 6, 7, 8 and 9, the wire outlet limiting assembly 10 further includes a first wire passing structure connecting portion 190 disposed at an edge of the wire passing structure 100, the socket 30 further includes a second wire passing structure connecting portion 321 correspondingly disposed on an outer surface of the plug portion 320, and the first wire passing structure connecting portion 190 and the second wire passing structure connecting portion 321 are buckled with each other, so that the wire outlet limiting assembly 10 is fixedly connected with the plug portion 320 through the wire passing structure 100.

Accordingly, the socket 30 further includes the corresponding second wire passing structure connecting portion 321 through the first wire passing structure connecting portion 190 disposed at the edge of the wire passing structure 100, and the first wire passing structure connecting portion 190 and the second wire passing structure connecting portion 321 are fastened to each other, so that the wire outlet limiting assembly 10 can be fixedly connected with the plugging portion 320 through the wire passing structure 100.

In one or more embodiments, the number of the first wire passing structure connection parts 190 corresponds to the number of the second wire passing structure connection parts 321, and the number of the first wire passing structure connection parts 190 may be one or more, and the number of the second wire passing structure connection parts 321 may be one or more. For example, as shown in fig. 6, 7 and 8, the number of the first wire passing structure connecting portions 190 is four, and the number of the second wire passing structure connecting portions 321 is also four, so that the connection between the wire outlet limiting assembly 10 and the plugging portion 320 can be more stable.

According to the outgoing line limiting assembly 10 and the connector 1, through the structure, the arrangement of the original power line 430 and the signal line 520 is not required to be changed, and when the power line 430 located on one side of the outgoing line face 120 rotates around the axial direction of the corresponding power line through hole 130, the power line 430 is blocked from being contacted with part or all of the signal line 520 located on one side of the outgoing line face 120, the damage to the signal line 520 caused by the rotation of the power line 430 is avoided as much as possible, and the connector 1 is prevented from being damaged and possibly caused by safety accidents.

The foregoing description is merely specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present application, and should be covered in the scope of the present application; embodiments of the present application and features of embodiments may be combined with each other without conflict. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (11)

1. An outgoing line limiting assembly for limiting an outgoing line position of at least one power line and/or at least one signal line, the outgoing line limiting assembly comprising:

The wire passing structure comprises a wire inlet surface, a wire outlet surface, and a power wire through hole and/or a signal wire through hole penetrating through the wire inlet surface and the wire outlet surface, wherein the power wire through hole is used for supplying power wires for wire outgoing, and the signal wire through hole is used for supplying signal wires for wire outgoing, and the wire passing structure is also provided with a limiting part, and the limiting part surrounds at least part of edges of the signal wire through hole;

the blocking structure is arranged on the wire outlet face and is at least positioned between one power line via hole and one signal line via hole or between one power line via hole and another power line via hole or between one signal line via hole and another signal line via hole, and the blocking structure is at least used for blocking the power line from contacting with at least part of the signal lines or other power lines positioned on one side of the wire outlet face when the power line positioned on one side of the wire outlet face rotates around the corresponding axial direction of the power line via hole.

2. The wire-out limit assembly of claim 1, wherein the signal wire vias comprise a first signal wire via and a second signal wire via, a portion of the signal wires are routed from the first signal wire via, another portion of the signal wires are routed from the second signal wire via, the blocking structure comprises a first blocking portion, the first blocking portion is located between the first signal wire via and the power wire via and at least partially surrounds the first signal wire via;

The first blocking part is at least used for blocking the power line from contacting with the signal line which is led out from the first signal line through hole when the power line positioned on one side of the line outgoing surface rotates around the axial direction of the corresponding power line through hole.

3. The wire-out limit assembly of claim 2, wherein the wire-through structure further comprises a wire-out accommodating groove provided on the wire-out face, the wire-out accommodating groove is used for accommodating a signal wire which is wire-out from the second signal wire via hole, and a groove depth of the wire-out accommodating groove is greater than or equal to a maximum outer diameter of the accommodated signal wire;

the wire outlet accommodating groove is communicated with the second signal wire through hole and extends to the edge of the wire passing structure, so that a signal wire which is led out from the second signal wire through hole passes through the wire outlet accommodating groove to penetrate out from the edge of the wire passing structure, and the signal wire which is led out from the second signal wire through hole is prevented from being contacted with a power wire.

4. The wire outlet limit assembly according to claim 2, wherein the first blocking portion surrounds the first signal wire via hole and encloses a surrounding structure having a wire outlet at one end, and the wire outlet is at least used for passing a signal wire which is led out from the first signal wire via hole;

The wire outlet surface is also provided with a mounting groove, the mounting groove is communicated with the first signal wire through hole and the second signal wire through hole, and part of groove walls of the mounting groove are matched with edges of the first blocking part so as to install the first blocking part.

5. The wire-out limit assembly of claim 4, wherein the blocking structure further comprises a fin connected with the first blocking portion, the second signal wire via is located outside the surrounding area of the first blocking portion, the projection of the second signal wire via on the fin is located in the covering area of the fin, the edge of the fin is matched with the groove wall of the other part of the mounting groove, and a gap is formed between the fin and the groove bottom of the mounting groove so as to be matched with the mounting groove to form a wire-through channel from the second signal wire via to the wire-through opening, and a signal wire outgoing from the second signal wire via sequentially passes through the wire-through channel and the wire-through opening.

6. The wire-out limit assembly of claim 3, wherein the signal wire comprises a plurality of signal wires, the first signal wire via comprises a plurality of first signal wire vias, the second signal wire via comprises a plurality of second signal wire vias, the plurality of first signal wire vias are arranged in a line, the blocking structure is disposed between the plurality of first signal wire vias and the power wire via, a portion of the signal wires are wire-out from the corresponding first signal wire vias, and wire-out from one side of the wire-out face along a direction perpendicular to the wire-out face;

The wire outlet accommodating grooves comprise a plurality of wire outlet accommodating grooves, and the other part of signal wires penetrate out of the edge of the wire passing structure through the corresponding wire outlet accommodating grooves after being led out of the corresponding second signal wire through holes, and are led out from one side of the wire outlet surface along the direction parallel to the wire outlet surface.

7. The wire-out limit assembly of claim 6, wherein the signal wire comprises a plurality of signal wires, the first signal wire via comprises a plurality of first signal wire vias, the second signal wire via comprises a plurality of second signal wire vias, the plurality of first signal wire vias are arranged in a straight line, the blocking structure is arranged between the plurality of first signal wire vias and the power wire via, and a part of the signal wires exit from the corresponding first signal wire via through the wire-through openings after exiting from the corresponding first signal wire via, and exit from one side of the wire-out surface along a direction perpendicular to the wire-out surface;

the fin comprises a plurality of fins, the wire passing channels which are matched with the mounting grooves to form the wire passing channels from the second signal wire through holes to the wire passing ports also comprise a plurality of wire passing channels, and the other part of signal wires sequentially pass through the corresponding wire passing channels and the wire passing ports after being led out from the second signal wire through holes, and are led out from one side of the wire outlet surface along the direction perpendicular to the wire outlet surface.

8. The wire-out limiting assembly of claim 2, wherein the blocking structure further comprises a second blocking portion disposed on the wire-out surface of the wire-out structure and located at least on a rotational path of the power wire on one side of the wire-out surface around the corresponding power wire via hole, the second blocking portion being configured to limit the rotation of the power wire into contact with at least a portion of the signal wire that is routed out from the second signal wire via hole.

9. The connector is characterized by comprising a socket, a power line assembly, a signal line assembly and the outgoing line limiting assembly according to any one of claims 1-8, wherein the socket comprises a substrate and a plug-in part which are connected, the outgoing line limiting assembly is fixedly connected with the plug-in part, the plug-in part is used for plugging one ends of the power line assembly and the signal line assembly, and the other ends of the power line assembly and the signal line assembly are correspondingly led out through the power line through hole and the signal line through hole of the line passing structure of the outgoing line limiting assembly.

10. The connector of claim 9, wherein the power cord assembly comprises a power terminal, an OT terminal and a power cord, one end of the power terminal is plugged into the plugging portion, the OT terminal is used for connecting the other end of the power terminal with one end of the power cord, and the other end of the power cord is led out through the power cord via hole;

The signal wire assembly comprises a signal terminal and a signal wire, one end of the signal terminal is inserted into the insertion part, the other end of the signal terminal is connected with one end of the signal wire, and the other end of the signal wire is led out through the signal wire through hole.

11. The connector of claim 10, wherein the projection of the power via of the wire-through structure in the axial direction includes two opposing straight sides and a further side connected between the two straight sides, the two straight sides mating with the peripheral edges of the power terminals to limit the power terminals in the power via.