JP6065968B2 - Coaxial electrical connector - Google Patents

Description

  The present invention relates to a coaxial electrical connector used by connecting a cable-shaped signal transmission medium such as a thin coaxial cable.

  In general, cable signal transmission media such as thin coaxial cables are widely used as signal transmission media used in various electronic devices or electric devices such as mobile phones and smartphones. A coaxial electrical connector for efficiently connecting to a printed wiring board is known. For example, in the coaxial electrical connector described in Patent Document 1 below, an outer conductor shell (shield shell) made of a substantially hollow cylindrical member is attached to the outer peripheral side of the insulating housing, and the outer conductor shell A shell lid is connected to the annular opening so as to be openable and closable. Then, the shell lid portion that was in an open state when connecting the terminal portions of the cable-shaped signal transmission medium is closed so as to be pushed down together with the inner conductor contact disposed in the inner region of the outer conductor shell. The inner conductor contact is plastically deformed so as to be bent, whereby the cable-shaped signal transmission medium is sandwiched and is electrically connected.

  According to the coaxial type electrical connector having such a configuration, the soldering work for connecting the cable-shaped signal transmission medium such as the coaxial cable to the internal conductor contact is omitted, so that the assembly workability is improved. Further, the problem of the environmental viewpoint due to the disposal of the solder material is solved, and there is also an advantage that the deviation of the characteristic impedance due to the difference in the amount of solder used is eliminated.

  However, in the conventional coaxial type electrical connector, the degree of matching (VSWR) of the characteristic impedance with respect to the transmission signal is low as the transmission signal becomes higher in frequency in recent years and the electrical connector is rapidly reduced in size or height. There is a tendency to be in a matched state, and it is becoming difficult to maintain good high frequency characteristics.

JP 2011-40262 A

  SUMMARY OF THE INVENTION An object of the present invention is to provide a coaxial electrical connector that can stably obtain good signal transmission characteristics with a simple configuration.

  To achieve the above object, according to the present invention, an outer conductor shell comprising an insulating housing to which a terminal portion of a cable-shaped signal transmission medium is coupled, and a substantially hollow cylindrical member mounted so as to cover the outer surface of the insulating housing. And an inner conductor contact disposed in a radially inner region of the outer conductor shell, and a connection portion between the terminal portion of the cable-shaped signal transmission medium and the inner conductor contact is a diameter of the outer conductor shell. And a shell lid that opens and closes the annular opening is openably and closably connected to the annular opening of the outer conductor shell, and the shell is connected to the insulating housing. An insulating pressing plate that is integrally opened and closed with the lid is provided, and the shell lid covers the annular opening of the outer conductor shell. When the insulating pressing plate is deformed so as to form a bent portion when closed, the tongue-like portion of the inner conductor contact is pressed against the cable-shaped signal transmission medium by the pressing force of the insulating pressing plate. In the coaxial electrical connector configured to be in contact with each other to form the connection portion, the connection portion between the end portion of the cable-shaped signal transmission medium and the inner conductor contact, which is a part of the surface of the insulating pressing plate Is provided with a space formed by an inner wall of a groove recessed in a step shape, the space being disposed in a radially inward region of the outer conductor shell, and the cable-shaped signal The inner diameter dimension W1 in the width direction perpendicular to the extending direction of the transmission medium is configured to be smaller than the outer dimension W2 in the width direction in the tongue-like portion of the inner conductor contact.

  According to the present invention having such a configuration, the connection portion in which the space portion formed by the inner wall of the groove recessed in a step shape in the insulating pressing plate is disposed in the radially inner region of the outer conductor shell. Therefore, the impedance adjustment air layer formed by the space is placed so as to face the connection part where impedance mismatching is likely to occur. By efficiently adjusting the degree of impedance matching (VSWR), which is an element, good transmission of high-frequency signals can be easily maintained while reducing the size or height of the electrical connector.

  Moreover, it is preferable that the space portion in the present invention is provided so as to extend along the cable-shaped signal transmission medium in a region from the connection portion to the bent portion.

  According to the present invention having such a configuration, even when the bent portion of the insulating pressing plate is opposed to the outer conductor shell in the radial direction, the space for the impedance adjustment is provided by the space provided in the insulating pressing plate. An air layer is formed, impedance matching is performed more efficiently, and rigidity at the bent portion of the insulating pressing plate is reduced by the space portion, so that the bending operation of the insulating pressing plate causes damage or the like. Easily done without.

  Further, in the present invention, the insulating pressing plate is configured to extend along an inner wall surface of the shell lid portion arranged to cover the annular opening of the shield shell, and the inner wall surface of the shell lid portion. Further, it is desirable that a shell-side concave groove portion facing the space portion is formed.

  If such a configuration is adopted, in addition to the impedance matching action by the space portion of the insulating pressing plate, impedance matching is also performed by the shell side concave groove portion provided on the inner wall surface of the shell lid portion. Matching is performed more efficiently and easily.

  Furthermore, in the present invention, it is desirable that the space portion is formed by a through hole.

  By adopting such a configuration, the space portion is configured by the through-holes that are easy to manufacture, and thus the manufacturing efficiency can be improved.

  As described above, according to the present invention, the space portion disposed so as to face the connection portion between the cable-shaped signal transmission medium and the internal conductor contact is provided in a part of the insulating pressing plate that is integrally opened and closed with the shell lid portion. By arranging the connecting portion and the space in the radially inner region of the outer conductor shell, the impedance adjustment air layer formed by the space of the insulating pressing plate is likely to cause impedance mismatch. Since it is arranged so as to face the connection part and the impedance matching degree (VSWR) can be adjusted efficiently, it is possible to stably achieve good signal transmission characteristics with a simple configuration. The reliability of the electrical connector can be inexpensively and greatly improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an external perspective explanatory view showing a single coaxial electrical connector (plug connector) connected to a coaxial cable according to an embodiment of the present invention from the upper front side. FIG. 2 is an external perspective explanatory view showing a single plug connector shown in FIG. 1 from the side surface side. FIG. 3 is an external perspective view illustrating the single plug connector shown in FIGS. 1 and 2 from the front lower side. It is a cross-sectional explanatory drawing along the IV-IV line in FIG. It is longitudinal cross-sectional explanatory drawing along the VV line in FIG. BRIEF DESCRIPTION OF THE DRAWINGS It is an external appearance perspective explanatory view showing the simple substance of the thin wire coaxial cable as an example of the signal transmission medium connected with the coaxial type electrical connector (plug connector) concerning one Embodiment of this invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an external perspective view illustrating an initial open state (cable disconnected state) of a coaxial electrical connector (plug connector) according to an embodiment of the present invention. It is front explanatory drawing of the coaxial type electrical connector (plug connector) shown by FIG. It is side surface explanatory drawing of the coaxial type electrical connector (plug connector) shown by FIG.7 and FIG.8. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an external perspective explanatory view showing an initial open state of a shield shell alone used in a coaxial electrical connector (plug connector) according to an embodiment of the present invention. It is front explanatory drawing of the shield shell single-piece | unit shown by FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an external perspective view illustrating an initial open state of a single insulating housing used in a coaxial electrical connector (plug connector) according to an embodiment of the present invention. It is side surface explanatory drawing of the insulation housing single-piece | unit shown by FIG. FIG. 14 is an explanatory plan view of a single insulating housing shown in FIGS. 12 and 13. FIG. 14 is an external perspective explanatory view showing a closed state after the insulating pressing plate provided on the insulating housing shown in FIGS. 12 to 13 is bent. It is side surface explanatory drawing of the insulation housing single-piece | unit shown by FIG. FIG. 5 is a cross-sectional explanatory view corresponding to FIG. 4 showing the configuration of a coaxial electrical connector (plug connector) according to another embodiment of the present invention. It is longitudinal cross-sectional explanatory drawing along the XVIII-XVIII line | wire in FIG. It is an external appearance perspective explanatory view showing the initial opened state of the insulated housing single-piece | unit used for the coaxial type electrical connector (plug connector) concerning other embodiment of this invention.

  Hereinafter, an embodiment in which the present invention is applied to a coaxial electrical connector using a thin coaxial cable as a signal transmission medium will be described in detail with reference to the drawings.

[Overall structure of coaxial type electrical connector]
First, the plug connector 10 as the coaxial electrical connector according to the first embodiment of the present invention shown in FIGS. 1 to 5 is connected to the terminal portion of a thin coaxial cable SC as a cable-shaped signal transmission medium. And is inserted into or removed from the other side of an electrical connector (not shown) such as a receptacle connector mounted on a predetermined printed wiring board (not shown). It is made the composition which becomes. The fitting / removing operation of the plug connector 10 with respect to the mating electrical connector (receptacle connector or the like) is performed in a direction substantially orthogonal to the plane of the printed wiring board.

  More specifically, the connector main body portion constituting the main fitting portion of the plug connector 10 is formed so as to have a cylindrical shape in a schematic shape, and the connector main body portion having the substantially cylindrical shape is formed. The end of the thin coaxial cable SC is connected from one direction radially outward, and the thin coaxial cable SC is connected to face the upper position of the mating electrical connector (receptacle connector or the like). The plug connector 10 is disposed on the side. Then, the entire plug connector 10 is lowered in a direction substantially perpendicular to the outer surface of the printed wiring board, so that the lower end portion of the plug connector 10 is fitted to the upper end portion of the mating electrical connector. It is made a joint state. In this way, the plug connector 10 is inserted into the mating electrical connector from above, so that the terminal portion of the thin coaxial cable SC is printed via the plug connector 10 and the mating electrical connector. It will be connected to the wiring pattern conductive path on the wiring board.

  Here, the direction in which the plug connector 10 is inserted into the mating electrical connector (receptacle connector or the like) is referred to as “downward”, and the removal direction opposite to that is referred to as “upward”. Further, in the plug connector 10 itself, an end edge portion to which a terminal portion of the thin coaxial cable SC is connected is referred to as a “front side edge portion”, and an opposite edge portion is referred to as a “back side edge”. The direction from the “back side edge portion” to the “front side edge portion” is “connector front direction”, and the opposite direction is “connector rear direction”. A direction orthogonal to both the “connector up-down direction” and the “connector front-back direction” is referred to as a “connector left-right direction”.

[About coaxial cable]
In particular, as shown in FIG. 6, a thin coaxial cable SC as a cable-shaped signal transmission medium has a cable center conductor (signal line) SCa and a cable outer conductor (shield wire) SCb formed of a plurality of conductive wires. The cable outer conductor (shield wire) SCb is exposed by stripping the outer sheath material SCd, and is configured to be coaxially laminated via the cable dielectric SCc. The cable center conductor (signal line) SCa is exposed by peeling the cable outer conductor (shield line) SCb and the cable dielectric SCc.

  The signal center is configured by connecting the cable center conductor SCa disposed along the center axis of the thin coaxial cable SC to the internal conductor contact (signal contact member) 12 attached to the insulating housing 11. Is done. Further, the cable outer conductor SCb disposed so as to surround the outer peripheral side of the cable center conductor SCa is connected to the outer conductor shell 13a of the shield shell 13, and the outer conductor shell 13a functions as a contact member for grounding. A ground circuit is configured.

[Insulating housing]
Here, as shown in FIG. 5, the above-described insulating housing 11 has a substantially disc-shaped insulating main body portion 11 a constituting a connector main body portion that is a main fitting portion, and the insulating main body portion. An insulating insertion portion 11b that is inserted into the inner side of an electrical connector (receptacle connector or the like) that is a mating partner is integrally provided at a lower portion of 11a. Of these, the terminal portion of the thin coaxial cable SC described above is set in a substantially central portion of the insulating main body portion 11a. The cable center conductor (signal line) SCa of the thin coaxial cable SC is connected to the insulation main body portion 11a. An internal conductor contact (signal contact member) 12 to be placed is attached to a portion formed in a concave shape at a substantially central portion of the upper surface of the insulating main body 11a.

  Further, the outer conductor shell 13a of the shield shell 13 as a ground contact is attached to the insulating main body 11a so as to surround the inner conductor contact 12 described above from the outer side. Further, a cable support portion 11c (see FIG. 7) formed of a concave groove having a substantially semicircular shape when viewed from the front is formed at the front edge portion of the insulating main body portion 11a. The end portion of the above-described thin coaxial cable SC is placed on the side wall surface so as to be received.

  Furthermore, the insulating main body 11a of the insulating housing 11 is integrally provided with an insulating pressing plate 11d made of a tongue-like member so as to cover the cable center conductor SCa of the thin coaxial cable SC from above. . The insulating pressing plate 11d is formed of an elongated flat plate-like member that protrudes along the thin coaxial cable SC in a cantilevered manner from the end of the insulating main body 11a on the connector rear end side. In an initial state before the end portion of the thin coaxial cable SC as shown in FIGS. 12 to 14 is placed, the insulating pressing plate 11d is in an open state in which it is raised upward. After the end portion of the thin coaxial cable SC is set in the insulating housing 11, it is bent downward together with a shell lid portion 13b provided on the shield shell 13 as will be described later, and a bent portion 11f formed at that time is formed. A portion extending in the form of a flat plate is arranged so as to overlap from above along the thin coaxial cable SC.

  Here, as described above, the region on the base side of the insulating pressing plate 11d that extends in a cantilever shape extends from a through hole extending in an elongated shape along the extending direction of the thin coaxial cable SC. A space portion 11e is provided. This space portion 11e is formed in a groove (a main groove) recessed in a step shape in the thickness direction from the surface of the insulating pressing plate 11d in a substantially central portion of the insulating pressing plate 11d in the width direction orthogonal to the extending direction of the thin coaxial cable SC. In the embodiment, it is formed by the inner wall surface of the through hole). As shown in FIGS. 15 and 16, when the insulating pressing plate 11d is bent downward and disposed on the upper side of the thin coaxial cable SC, the above-described space portion 11e becomes the insulating pressing plate 11d. The air layer formed in an elongated shape by the inner wall surface of the space portion 11e is located above the “connection portion” which is an electrical connection region between the cable center conductor (signal line) SCa and the internal conductor contact 12. It is arranged to face from the side.

  As described above, the space portion 11e formed of the through hole is disposed in the radially inner region of the outer conductor shell (ground contact member) 13, and as shown in FIG. 11e has an inner diameter W1 in the width direction (a direction orthogonal to the extending direction of the thin coaxial cable SC), and the upper beam portion (tongue piece-like portion) 12a forming a part of the inner conductor contact (signal contact member) 12 described above. Is formed smaller than the outer dimension W2 in the width direction (W1 <W2). The structure of the upper beam portion (tongue piece-like portion) 12a of the inner conductor contact 12 will be described in detail later, but the upper beam portion 12a forming the tongue piece-like portion presses and contacts the thin coaxial cable SC from above. As a result, a “connection portion” for the thin coaxial cable SC is formed.

  The insulating pressing plate 11d is moved downward by such a width relationship (W1 <W2) of the space portion 11e with respect to the upper beam portion (tongue-like portion) 12a of the inner conductor contact 12. When bent, the inner conductor contacts 12 are brought into contact with each other, whereby both the members 11d and 12 are bent together.

  Here, as described above, the space 11e provided in the insulating pressing plate 11d has a cable center conductor (signal line) SCa of the thin coaxial cable SC and the internal conductor contact 12 as shown in FIG. The “connection portion”, which is the electrical connection region of the connector, is disposed so as to face from the upper side, and further from the position facing the “connection portion” toward the root base side of the insulating pressing plate 11d on the rear side of the connector. After extending so as to bend along the bent portion 11f formed on the insulating pressing plate 11d, it extends downward.

  On the other hand, with respect to the insulating main body portion 11a of the insulating housing 11 constituting the main fitting portion including such an insulating pressing plate 11d, a substantially hollow cylinder protruding integrally downward from the insulating main body portion 11a. As described above, the insulating insertion portion 11b having a shape is configured such that the lower end side of the insulating insertion portion 11b is inserted toward the inner side of the mating electrical connector (receptacle connector or the like) that is the mating counterpart. Yes.

[About shield shell]
Further, as shown in FIGS. 10 and 11, the outer surface of the insulating housing 11 having the above-described insulating main body portion 11a and insulating insertion portion 11b is the main fitting of the shield shell 13 made of a sheet metal member. The outer conductor shell 13a constituting the portion is covered. The outer conductor shell 13a constitutes a substantially hollow cylindrical ground contact member formed so as to mainly cover the insulating main body 11a of the insulating housing 11 in an annular shape from the radially outer side. Further, the lower portion of the outer conductor shell (ground contact member) 13a is formed as a shell insertion portion 13a1 that covers the insulating insertion portion 11b in a ring shape from the radially outer side, and the outer conductor shell 13a A shell lid portion 13b that covers the upper surface side of the insulating main body portion 11a is connected to the annular opening portion on the upper end side so as to be openable and closable.

  At this time, the shield shell 13 in the initial state before connecting and fixing the terminal portion of the thin coaxial cable SC is a shell with respect to the above-described outer conductor shell 13a as shown in FIGS. The lid portion 13b is opened upward. That is, the shell lid portion 13b in the initial state is arranged to rise substantially vertically upward at the rear side edge portion of the external conductor shell 13a via the connecting member 13b1 made of a narrow plate-like member. Further, on the inner surface of the lid of the shell lid portion 13b, that is, the surface located inward when the shell lid portion 13b is closed, a tongue-like member that rises upward from the insulating main body portion 11a of the insulating housing 11 An insulating pressing plate 11d is arranged along the inner surface of the lid of the shell lid portion 13b. The installation position and the number of installation members 13b1 can be arbitrarily selected.

  Then, in the open state (initial state) of the shield shell 13 as described above, the terminal portion of the thin coaxial cable SC is placed and set so as to be received by the cable support portion 11c of the insulating housing 11, and then connected. When the shell lid portion 13b of the shield shell 13 is pushed down to a substantially horizontal state so that the member 13b1 is bent at a substantially right angle downward together with the insulating pressing plate 11d, the entire insulating main body portion 11a of the insulating housing 11 is thereby pushed. However, the shell cover portion 13b covers the shield shell 13 from the upper side.

  The shell lid portion 13b at this time is structured to be covered so as to cover the annular opening portion on the upper end side of the outer conductor shell 13a when being pushed down to the substantially horizontal state and closed as described above. The front cover portion 13b2 that covers the thin coaxial cable SC, in particular, the cable dielectric SCc and the cable outer conductor (shield wire) SCb from the upper side, is integrally formed on the front side portion of the shell lid portion 13b pushed down to the substantially horizontal state. It is connected to. The front cover portion 13b2 is configured to cover the pair of cable protection arms 13a2 and 13a2 protruding from the outer conductor shell 13a to the front side together with the thin coaxial cable SC from the outer side.

  At this time, the cable protection arms 13a2 and 13a2 described above are configured to extend along both the left and right sides across the thin coaxial cable SC, and the front side edge portion of the external conductor shell 13a described above. A pair of cables are provided so as to protrude forward along the terminal portion of the thin coaxial cable SC so as to face each other substantially in parallel.

  Further, as described above, on both side edges of the front cover portion 13b2 provided so as to protrude from the front side of the shell lid portion 13b, a first fixed holding plate 13b3 made of a pair of tongue-like members, a second fixed plate. The holding plate 13b4 and the third fixed holding plate 13b5 are provided so as to form a flange plate shape. Among them, the first fixed holding plate 13b3 is configured to be crimped and fixed by being bent so as to cover the thin coaxial cable SC and the cable protection arms 13a2 and 13a2 from the outer side.

  That is, the both side flange plates constituting the pair of first fixed holding plates 13b3 and 13b3 are formed on the outer sides of the cable protection arms 13a2 and 13a2 when the shell lid portion 13b is pushed down to a substantially horizontal state. And is bent inwardly of the connector along the outer wall surfaces on both sides of the cable protection arms 13a2 and 13a2 so as to be caulked from that state, and thereby the shell cover portion 13b with respect to the outer conductor shell 13a. Is fixed, and in particular, the cable dielectric SCc of the thin coaxial cable SC is fixed to the shell lid portion 13b.

  Further, the second fixed holding plate 13b4 and the third fixed holding plate 13b5 are provided so as to be adjacent to each other adjacent to the front side of the first fixed holding plate 13b3, and are formed from a relatively small flange plate. ing. The second fixed holding plate 13b4 and the third fixed holding plate 13b5 are bent and fixed by caulking so as to cover the cable outer conductor (shield wire) SCb and the outer covering material SCd in the thin coaxial cable SC from the outer side. It is made to the configuration.

  That is, the both side flange plates constituting the second fixed holding plate 13b4 and the third fixed holding plate 13b5 are the cable outer conductors in the thin coaxial cable SC when the shell lid portion 13b is pushed down to a substantially horizontal state. (Shield wire) Arranged so as to be located on both outer sides of SCb and outer covering material SCd, and bent from the state to the inner side of the connector so as to be caulked. As a result, the shell cover portion 13b is fixed to the cable outer conductor (shield wire) SCb and the outer sheath material SCd of the thin coaxial cable SC, and the cable outer conductor SCb comes into contact with the second fixed holding plate 13b4. A ground circuit is formed by the shield shell 13.

  On the other hand, as described above, the shell insertion portion 13a1 constituting the lower portion of the shield shell 13 is configured to be fitted over the radially outer side portion of the mating connector (receptacle connector or the like) that is the mating counterpart. The connector connecting portion is configured together with the insulating insertion portion 11b of the insulating housing 11 inserted on the radially inner side of the mating connector. More specifically, the shell insertion portion 13a1 is formed to have a substantially cylindrical shape, and an annular recess protruding toward the radially inward side at the lower end portion on the insertion side of the shell insertion portion 13a1. A connection engaging portion made of a groove is formed. As described above, after the shell lid portion 13b is pushed down to a substantially horizontal state, the connection engagement portion is elastic with respect to a connection locking portion (not shown) provided in the mating connector which is a mating counterpart. It is designed to have a fitting relationship.

[Signal contact materials]
Further, the inner conductor contact (signal contact member) 12 employed in the present embodiment is attached to the insulating main body portion 11a of the insulating housing 11 by press-fitting or insert molding or the like. It has a cable clamping part consisting of a pair of upper and lower beam parts 12a, 12b connected to the central conductor (signal line) SCa, and extends downward from the lower beam part 12b in the cable clamping part. The elastic spring portion 12c provided in this manner is configured to elastically contact a conductive contact (not shown) provided in a mating connector (receptacle connector or the like).

  The upper beam portion 12a and the lower beam portion 12b constituting the cable holding portion are formed of a strip-like member extending in a series, and have a substantially C shape or a substantially L shape in a side view. Thus, the clip beam structure is formed so as to be bent. Then, as will be described later, by bending and deforming the connecting portion in a direction in which the upper beam portion 12a is brought closer to the lower beam portion 12b, the cable center conductor (signal line) SCa of the thin coaxial cable SC is changed to the both beam portions 12a. , 12b are sandwiched in a clip shape from above and below to form a “connection portion” as used in the present invention.

  At this time, the upper beam portion 12a of the cable holding portion is obliquely upward as shown in FIGS. 7 to 9, particularly in an initial state before the end portion of the thin coaxial cable SC is connected. It is formed so as to form a raised tongue-shaped portion, and is separated upward from the lower beam portion 12b by the upper beam portion 12a serving as the tongue-shaped portion being opened upward. Has been made.

  On the other hand, the lower beam portion 12b of the cable holding portion is formed as a cable placement portion on which the cable center conductor SCa of the thin coaxial cable SC is placed, and the upper beam portion (tongue piece portion) 12a. From the connecting portion to the front side of the connector, it extends substantially horizontally. As described above, when the end portion of the thin coaxial cable SC is placed on the cable support portion 11c of the insulating housing 11, the cable center conductor SCa of the thin coaxial cable SC is connected to the lower beam portion of the cable holding portion. It is mounted on the surface of 12b from the upper side.

  After the end portion of the thin coaxial cable SC is thus placed on the cable support portion 11c of the insulating housing 11 and set, the shell lid portion 13b of the shield shell 13 together with the insulating pressing plate 11d described above. In this case, the upper beam portion (tongue piece-like portion) 12a of the cable holding portion pushed downward by the insulating pressing plate 11d is pushed down until it becomes substantially horizontal. The upper beam portion 12a is configured to press the cable center conductor (signal line) SCa from above as shown in FIG. 5 in particular.

  Here, an intermediate position in the extending direction of the upper beam portion (tongue piece portion) 12a constituting the cable clamping portion described above is formed in the upper electrode portion that presses the cable center conductor (signal line) SCa from above. ing. The upper electrode portion provided on the upper beam portion 12a of the signal contact member 12 is formed in a bent shape protruding downward to sandwich the thin coaxial cable SC, and the lower bent portion thereof is formed of the fine coaxial cable. It is made into the protruding contact part which protrudes toward SC side. As described above, this protruding contact portion is the cable center conductor (signal line) SCa of the thin coaxial cable SC set on the lower beam portion 12b when the shell lid portion 13b is pushed down to a substantially horizontal state. The cable center conductor (signal line) SCa is clamped between the two beam portions 12a and 12b and is electrically connected. It is made to the configuration.

  Thus, as described above, the electrical connection region where the cable center conductor (signal line) SCa of the thin coaxial cable SC is connected to the internal conductor contact (signal contact member) 12 is defined as a “connection portion” in the present invention. .

  Further, the lower beam portion 12b provided as the cable mounting portion of the inner conductor contact 12 described above is a plate that extends forward from the connecting portion with the upper beam portion 12a forming the tongue-like portion. The insulating member 11 is fixed on the upper surface of the insulating main body 11a of the insulating housing 11 described above. A connection monitoring hole 12b1 having a round hole shape is formed in a substantially central portion of the lower beam portion 12b. The connection monitoring hole 12b1 is substantially coaxial with the connection monitoring hole 12b1 so as to contact the mating connector. An insertion hole is formed through the insulating housing 11. The contact insertion hole of the mating connector also functions as a connection monitoring hole, and the arrangement state of the cable center conductor (signal line) SCa of the thin coaxial cable SC is visually observed from below through the connection monitoring hole 12b1. It is possible.

  Further, as described above, the lower beam portion 12b of the cable holding portion is formed of a strip-like member extending in the front-rear direction of the connector, but in the plate width direction (left-right direction) of the lower beam portion 12b. A pair of elastic spring portions 12c, 12c extend integrally at a predetermined interval from both side edge portions toward the lower side, and between the elastic spring portions 12c, 12c, A pin-shaped signal conductive contact (not shown) provided on a mating connector (receptacle connector or the like) is inserted and electrically connected in a pressure contact state.

  Here, as described above, when the shell cover portion 13b of the shield shell 13 that is in the open state in the initial state is pushed down downward, the insulation that is also in the open state in the initial state. The insulating pressing plate 11d of the housing 11 is pressed against a predetermined area on the inner surface of the lid of the shell lid portion 13b from below, and is then pushed down to the substantially horizontal state together with the shell lid portion 13b. The shell lid portion 13b and the insulating pressing plate 11d are connected to the upper side of the cable center conductor (signal line) SCa via the upper beam portion (tongue-like portion) 12a of the inner conductor contact (signal contact member) 12. Are arranged in a stack. At this time, an elongated shell side concave groove portion 14 extends in the longitudinal direction of the connector along the cable-shaped signal transmission medium SC in a facing area where the inner surface of the shell lid portion 13b and the insulating pressing plate 11d are pressed against each other. It is provided to do.

  The shell-side groove portion 14 in the present embodiment is configured such that a part of the inner surface of the shell lid portion 13b is recessed in a stepped shape in the plate thickness direction, and is formed by the inner wall surface of the shell-side groove portion 14. The air layer is disposed so as to face the air layer formed by the space portion 11e of the insulating pressing plate 11d described above from above. Then, an air layer for adjusting the impedance of the transmission signal is overlapped between the members 14 and 11e by the arrangement relationship in which the shell-side concave groove portion 14 and the space portion 11e overlap with each other in the vertical direction. It is formed in a state.

  The shell-side concave groove portion 14 in the present embodiment is formed by, for example, press working or the like, and is provided by reducing the plate thickness of the shell lid portion 13b by the depth of the shell-side concave groove portion 14. However, depending on the amount of adjustment of the impedance, the shell-side groove 14 may not be provided.

  In addition, as described above, the shell-side groove 14 extends along the cable-shaped signal transmission medium SC, but the extension range in the longitudinal direction of the shell-side groove 14 is the inner conductor contact ( The dielectric SCc of the cable-shaped signal transmission medium SC is exposed from a connecting portion between the lower beam portion (cable mounting portion) 12b and the upper beam (tongue piece-like portion) 12a which is the rear end portion of the signal contact member) 12. It is set in the range up to the upper position of the part.

  More specifically, as shown in FIGS. 10 and 11 in particular, the shell-side recessed groove portion 14 in the present embodiment is a region to which the cable center conductor SCa of the thin coaxial cable SC is electrically connected. A narrow-width groove portion 14a located above the connection portion and a wide-width groove portion 14b located above the dielectric SCc of the thin-line coaxial cable SC are provided so as to be continuous in a straight line. The groove width of the narrow groove portion 14a disposed in the connection portion that is the region is formed to be smaller than the plate width of the insulating pressing plate 11d described above in the electrical connection region.

  In addition, although the area | region corresponding to the groove width direction both sides of the shell side recessed groove part 14 is made | formed on the cover inner surface of the shell cover part 13b, the shell cover located in the both sides of the narrow groove part 14a arrange | positioned in the connection part mentioned above The inner surface of the lid of the portion 13b is a drop restraining portion 13b6 that comes into contact with the upper surface of the insulating pressing plate 11d from above. That is, the drop-inhibiting portion 13b6 is formed by the shell-side concave groove portion 14 because it is in a relationship of being laminated above the insulating pressing plate 11d by contacting the upper surface of the insulating pressing plate 11d. The insulating pressing plate 11d does not enter the narrow groove portion 14a arranged in the electrical connection region of the air layer, and the shell-side concave groove portion 14 is reliably formed in the electrical connection region.

  On the other hand, the groove width of the wide groove portion 14b is made larger than the plate width of the insulating pressing plate 11d, but the insulating pressing plate 11d in the present embodiment extends to the middle position of the narrow groove portion 14a in the extending length direction. However, it does not extend and does not face the wide groove portion 14b. Therefore, even in the closed state in which the shell lid portion 13b of the shield shell 13 is pushed down, the insulating pressing plate 11d does not enter the thick groove portion 14b, and the insulating pressing plate 11d extends over the entire length of the shell lid portion 13b. It is held in a laminated state in pressure contact with the inner surface. And while the shell cover part 13b is maintained on the upper side of the insulation press board 11d, the shell side ditch | groove part 14 is arrange | positioned in the position right above the insulation press board 11d.

  Further, as described above, the wide groove portion 14b that forms another region of the shell-side concave groove portion 14 that is slightly separated from the connection portion that is the electrical connection region is formed on the exposed portion of the dielectric SCc in the thin coaxial cable SC. Although arranged at corresponding positions, the groove width of the thick groove portion 14b is formed to be slightly larger than the outer diameter of the dielectric SCc of the thin coaxial cable SC. Accordingly, the dielectric SCc of the thin coaxial cable SC is accommodated in the thick groove portion 14b of the shell-side concave groove portion 14, thereby reducing the height of the connector.

  Further, as described above, the groove width of the wide groove portion 14b is set to be larger than the plate width of the insulating pressing plate 11d and set to be larger than the plate width of the internal conductor contact 12 in the electrical connection region. ing. Further, as described above, the groove width of the narrow groove portion 14a constituting a part of the shell side concave groove portion 14 is the cable center conductor (signal line) SCa of the cable-shaped signal transmission medium SC, that is, the inner conductor contact. (Signal contact member) It is set to be equal to or larger than the wire diameter of the portion in contact with 12. Furthermore, the groove width of the narrow groove portion 14a constituting the other portion of the shell side concave groove portion 14 is set to be smaller than the plate width of the upper beam portion 12a of the internal conductor contact (signal contact member) 12. .

  According to the present embodiment having such a configuration, the space portion 11e formed by the inner wall surface of the through hole provided in the insulating pressing plate 11d is a radially inward region in the outer conductor shell 13a of the shield shell 13. And a positional relationship facing a connection portion that is an electrical connection region between the cable center conductor (signal line) SCa and the internal conductor contact 12. For this reason, the air layer for impedance adjustment formed by the space portion 11e is disposed so as to face the connection portion where impedance mismatching is likely to occur, and the impedance matching degree which is an important design element of the electrical connector By adjusting (VSWR) efficiently, good transmission of high-frequency signals can be easily maintained while reducing the size or height of the electrical connector.

  In particular, in this embodiment, since the space portion 11e provided in the insulating pressing plate 11d extends to a region reaching the bent portion 11f of the insulating pressing plate 11d, the outer conductor shell of the shield shell 13 is used. An air layer for adjusting the impedance is also formed at a portion facing the radial direction with respect to 13a, and as a result, impedance matching is performed more efficiently and the insulating pressing plate 11d Since the rigidity in the bent portion 11f is reduced by the space portion 11e, the bending operation on the insulating pressing plate 11d is easily performed without causing damage or the like.

  Furthermore, according to this embodiment, in addition to the impedance matching action by the space portion 11e of the insulating pressing plate 11d, impedance matching is also performed by the shell side concave groove portion 14 provided in the shell lid portion 13b of the shield shell 13. Therefore, impedance matching can be performed more efficiently and easily.

  In addition, if the space part 11e is comprised by a through-hole like this embodiment, since the space part 11e is formed by the through-hole which is easy to manufacture, the manufacturing efficiency will be improved correspondingly.

  Next, the structure in 2nd Embodiment shown by FIGS. 17-19 is demonstrated. In the second embodiment, “1”, which is the tenth place of the member code given in the first embodiment described above, is replaced with “2”, but the second embodiment is applied. In the plug connector (coaxial connector) 20, a space portion 21e provided in a region on the base side of the insulating pressing plate 21d has a bottomed shape extending in an elongated shape along the extending direction of the thin coaxial cable SC. It is formed from a concave groove, and the configuration of other members is the same as that of the first embodiment.

  That is, the space portion 21e formed by the inner wall surface of the bottomed recessed groove according to the present embodiment is also recessed in a part of the surface of the insulating pressing plate 21d in a plate thickness direction (upward direction). Although formed, when the insulating pressing plate 21d is arranged so as to overlap above the thin coaxial cable SC, the concave groove constituting the space portion 21e becomes the cable center conductor (signal line) SCa. The “connection portion”, which is an electrical connection region between the internal conductor contact 12 and the internal conductor contact 12, is arranged so as to face from above. The space portion 21e formed of the concave groove is from the “connection portion (electrical connection region)” between the cable center conductor (signal line) SCa and the internal conductor contact 12 to the base side of the insulating pressing plate 21d, which is the rear side of the connector. After extending so as to bend along the bent portion 21f formed on the insulating pressing plate 21d, it extends downward.

  Also in the second embodiment including the space 21e formed of such a bottomed concave groove, the same operation and effect as in the first embodiment can be obtained.

  As mentioned above, although the invention made by the present inventor has been specifically described based on the embodiment, the present embodiment is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. Needless to say.

  For example, although the above-described embodiment is an application of the present invention to a vertical fitting type electrical connector, it can be similarly applied to a horizontal fitting type electrical connector.

  Further, the present invention is not limited to the single-core thin-wire coaxial cable connector as in the above-described embodiment, and there are a plurality of coaxial cable connectors arranged in a multipolar shape, and a plurality of coaxial cables and insulated cables. The same applies to mixed-type electrical connectors and the like.

  As described above, the present embodiment can be widely applied to a wide variety of electrical connectors used in various electrical devices.

10 Plug connector (coaxial electrical connector)
11 Insulating housing 11a Insulating body 11b Insulating insert 11c Cable support 11d Insulating pressing plate 11e Space (through hole)
11f bent part 12 inner conductor contact (signal contact member)
12a Upper beam (tongue piece)
12b Lower beam part (cable mounting part)
12b1 Connection monitoring hole 12c Elastic spring portion 13 Shield shell 13a External conductor shell (ground contact member)
13a1 Shell insertion portion 13a2 Cable protection arm 13b Shell lid portion 13b1 Connecting member 13b2 Front cover portion 13b3 First fixed holding plate 13b4 Second fixed holding plate 13b5 Third fixed holding plate 13b6 Drop restraining portion 14 Shell side concave groove portion 14a Narrow Width groove 14b Thick groove SC Thin coaxial cable (cable signal transmission medium)
SCa Cable center conductor (signal line)
SCb Cable outer conductor (shielded wire)
SCc Cable dielectric SCd Outer sheath 20 Plug connector (coaxial electrical connector)
21 Insulating housing 21a Insulating body part 21b Insulating insertion part 21c Cable support part 21d Insulating pressing plate 21e Space part (concave groove)
21f bent portion 22 inner conductor contact (signal contact member)
22a Upper beam (tongue piece)
22b Lower beam part (cable mounting part)
22b1 Connection monitoring hole 22c Elastic spring portion 23 Shield shell 23a External conductor shell (ground contact member)
23a1 Shell insertion portion 23a2 Cable protection arm 23b Shell lid portion 23b1 Connecting member 23b2 Front cover portion 23b3 First fixed holding plate 23b4 Second fixed holding plate 23b5 Third fixed holding plate 23b6 Drop restraining portion 24 Shell side concave groove portion 24a Narrow Wide groove 24b Wide groove

Claims (4)

An insulating housing to which a terminal portion of the cable-shaped signal transmission medium is connected, an outer conductor shell made of a substantially hollow cylindrical member mounted so as to cover the outer surface of the insulating housing, and a radially inner portion of the outer conductor shell An inner conductor contact disposed in the region,
The connecting portion between the terminal portion of the cable-shaped signal transmission medium and the inner conductor contact is disposed in the radially inner region of the outer conductor shell, and
A shell lid for opening and closing the annular opening is connected to the annular opening of the outer conductor shell so as to be openable and closable.
The insulating housing is provided with an insulating pressing plate that is integrally opened and closed with the shell lid portion,
When the shell lid is closed so as to cover the annular opening of the outer conductor shell, the insulating pressing plate is deformed so as to form a bent portion, whereby the pressing force of the insulating pressing plate causes the In the coaxial electrical connector configured to form the connection portion by pressing and contacting the cable-shaped signal transmission medium with the tongue-like portion of the inner conductor contact,
A part of the surface of the insulating pressing plate, which is formed by an inner wall of a groove recessed in a step shape at a position facing the connection portion between the terminal portion of the cable-shaped signal transmission medium and the inner conductor contact. A space is provided,
The space portion is disposed in a radially inward region of the outer conductor shell, and an inner diameter dimension W1 in a width direction perpendicular to the extending direction of the cable-shaped signal transmission medium has a tongue-like shape of the inner conductor contact. The coaxial electrical connector is characterized by being formed to be smaller than the outer dimension W2 in the width direction at the portion.   2. The coaxial type according to claim 1, wherein the space portion is provided so as to extend along the cable-shaped signal transmission medium in a region from the connection portion to the bent portion. Electrical connector. The insulating pressing plate is configured to extend along the inner wall surface of the shell lid portion arranged to cover the annular opening of the outer conductor shell,
The coaxial electrical connector according to claim 1, wherein a shell-side concave groove portion that is disposed to face the space portion is formed on an inner wall surface of the shell lid portion.   The coaxial electrical connector according to claim 1, wherein the space is formed by a through hole.

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