JP7268388B2 - connector - Google Patents

Description

The present disclosure relates to connectors.

Patent Document 1 discloses a coaxial connector plug having a tubular first outer conductor, a tubular first central conductor, and an insulator fixing the first central conductor to the first outer conductor. A connector is disclosed. The first center conductor and insulator are shown to be integrally formed by insert molding.

JP 2013-098122 A

In recent years, miniaturization of electrical connectors used for connecting coaxial cables to circuit boards has been demanded. However, in the structure described in Patent Document 1, depending on how the insulating material forming the insulator enters the periphery of the first central conductor during insert molding, burrs or the like may occur at the edge of the insulator. may cause poor connection, etc.

The present disclosure describes a connector in which the occurrence of poor connection is suppressed.

In order to achieve the above object, a connector according to one aspect of the present disclosure includes a signal contact conductor, a ground contact conductor, and a housing that integrates the signal contact conductor and the ground contact conductor while insulating them. 1. A connector configured to be matable with a mating connector and mounted on a wiring board, wherein the ground contact conductor includes a tubular main body portion extending along a predetermined axis; and an external terminal portion provided at one end edge in the axial direction, wherein the signal contact conductor extends in the axial direction inside the body portion and has a substantially cylindrical shape having a slit extending in the axial direction. a contact portion that contacts the signal contact conductor of the mating connector; and a conductor portion that extends from one edge of the contact portion in the axial direction in an extending direction that intersects the axial direction. and the housing is in contact with the edge of the contact portion of the signal contact conductor on which the lead wire portion is provided, and is located between the contact portion and the body portion and between the contact portion. The height position of the surface along the axial direction inside the contact portion is higher than the height position of the surface along the axial direction between the contact portion and the body portion. It is located near the bottom surface of the housing facing the wiring board.

In the connector according to the present disclosure, the height position of the surface along the axial direction of the housing entrapped inside the contact portion of the signal contact conductor is interposed between the contact portion of the signal contact conductor and the main body portion of the ground contact conductor. However, it is positioned closer to the bottom surface of the housing facing the wiring board than the height position of the surface of the housing. Therefore, even if burrs or the like occur during molding of the housing, the risk of the burrs affecting contact with the mating signal contact conductor can be reduced. Therefore, it is possible to suppress the occurrence of poor connection resulting from the molding of the housing.

Here, in at least a partial region between the contact portion and the main body portion that is continuous with the slit, the height position of the surface of the housing along the axial direction is equal to the above-described contact portion inside the contact portion. A mode in which the height position of the surface along the axial direction is substantially the same can be employed.

When the housing is formed by insert molding, the material that forms the housing, such as a resin material, moves between the inside and outside of the slit during molding. be. As in the above configuration, by setting the height position of at least a part of the housing continuous from the slit to be substantially the same height position as the inside of the contact portion, even if burrs or the like occur around the slit, , the risk of this burr affecting contact with the mating signal contact conductor can be reduced. Therefore, it is possible to further suppress the occurrence of connection failures caused during molding of the housing. Also, when manufacturing a connector, after the signal contact conductor is set in the mold, the signal contact conductor can be accurately positioned by bringing the parts in the mold into contact with the outside of the slit when injecting the insulating material. can. Furthermore, since the part in the mold abuts against the outside of the slit, it is possible to prevent the insulating material from leaking out from the part.

A notch portion is provided continuously with the conductor portion at an end edge of the contact portion of the signal contact conductor where the conductor portion is provided, and the housing is provided between the contact portion and the body portion at the notch portion. and the housing inside the contact portion are continuous.

Since the housing between the contact portion and the main body portion and the housing inside the contact portion are continuous at the notch portion, the tightness between the housing and the signal contact conductor is enhanced. Therefore, damage to the connector can be prevented.

According to the present disclosure, a connector is provided in which the occurrence of poor connection is suppressed.

1 is a perspective view of a connector assembly according to one embodiment of the present disclosure; FIG. 2 is a perspective view of a receptacle connector included in the connector assembly of FIG. 1; FIG. 3 is a cross-sectional view of the receptacle connector of FIG. 2 taken along line III--III. 4 is a perspective view of a ground contact conductor included in the receptacle connector; FIG. 5A and 5B are views showing signal contact conductors included in the receptacle connector, where (a) is a perspective view, (b) is a right side view, and (c) is a left side view. 6 is a perspective view of a plug connector included in the connector assembly of FIG. 1; FIG. 7 is a cross-sectional view of the plug connector of FIG. 6 taken along line VII--VII. 8 is a bottom view of the plug connector of FIG. 6; FIG. 9 is a perspective view of a signal contact conductor included in the plug connector; FIG. FIG. 10 is a perspective view of a housing included in the plug connector; 11 is a bottom view of the housing of FIG. 10; FIG. FIG. 12 is a view for explaining the mating state of the connector assembly, and is a cross-sectional view taken along line XII-XII in FIG.

Embodiments according to the present disclosure will be described below, but the present disclosure should not be limited to the following. In the following description, the same elements are denoted by the same reference numerals, and overlapping descriptions are omitted.

[Overview of connector assembly]
An overview of the connector assembly will be described with reference to FIG. As shown in FIG. 1, connector assembly 1 includes receptacle connector 2 and plug connector 3 . The connector assembly 1 is a connector, such as an RF (Radio Frequency) connector, for electrically connecting a cable-shaped signal transmission medium to an electric circuit on a wiring board. A signal transmission medium is a medium for transmitting signals of various electronic devices such as a mobile phone, and is, for example, a coaxial cable SC. The wiring board is, for example, a printed wiring board PB. That is, the connector assembly 1 of this embodiment is a coaxial connector that electrically connects the coaxial cable SC to the electrical circuit of the printed wiring board PB. In the connector assembly 1, the coaxial cable SC and the printed wiring board PB are connected by fitting the plug connector 3 attached to the end portion of the coaxial cable SC to the receptacle connector 2 mounted on the printed wiring board PB. It electrically connects with an electric circuit (details will be described later).

In the following description, the axial direction of the coaxial cable SC is the "X direction", and the fitting direction of the receptacle connector 2 and the plug connector 3 when they are mated is the "Z direction". , the direction orthogonal to the X direction and the Z direction may be described as the “Y direction”. Also, regarding the Z direction, the plug connector 3 side in the state shown in FIG. In the description of the plug connector 3 in particular, regarding the X direction, the end of the coaxial cable SC to which the plug connector 3 is attached is referred to as the "front end", and the opposite end is referred to as the "rear end (base end)". sometimes.

[Receptacle connector]
Details of the receptacle connector 2 will be described with reference to FIGS. 2 to 5. FIG. As shown in FIGS. 2 and 3 , the receptacle connector 2 has ground contact conductors 10 , signal contact conductors 20 and a housing 30 . The receptacle connector 2 is mounted on the printed wiring board PB (see FIG. 1) by soldering, for example.

(ground contact conductor)
The ground contact conductor 10 is a member for grounding made of, for example, a thin metal member. The ground contact conductor 10 is arranged so as to surround the contact portion 21 (details of which will be described later) of the signal contact conductor 20 . As shown in FIG. 4, the ground contact conductor 10 includes a ground main body portion 11 (main body portion) formed in a cylindrical shape (tubular shape) and one edge of the ground main body portion 11 (lower end in FIG. 4). and an external terminal portion 12 extending outward from the terminal.

The gland main body 11 is a cylindrical member and extends along the central axis C in the vertical direction (Z direction). That is, the direction of the central axis C of the ground main body 11 corresponds to the vertical direction (Z direction). The ground main body 11 is connected to a ground contact conductor (described later) of the plug connector 3 from the other edge (upper end in FIG. 4). A groove 11 a used for fitting with the plug connector 3 is provided in the outer peripheral surface of the ground main body 11 along the circumferential direction.

The external terminal portion 12 is a plate-like member extending along the horizontal direction (XY direction). It extends outward from the lower end portion of the ground body portion 11 . The external terminal portion 12 includes a pair of terminal portions 121 and 122 facing each other across the center axis C of the ground body portion 11 extending in the vertical direction. The pair of terminal portions 121 and 122 protrude outward so as to be separated from the central axis C, respectively. The terminal portions 121 and 122 have substantially the same rectangular shape, and are connected to the lower end of the ground body portion 11 so that their longitudinal directions extend along the X direction while being spaced apart from each other across the central axis C. be. Therefore, a facing surface 121a of the terminal portion 121 facing the terminal portion 122 and a facing surface 122a of the terminal portion 122 facing the terminal portion 121 extend below the ground body portion 11 along the X direction. . A space S1 extending along the longitudinal direction (X direction) of the terminal portions 121 and 122 is formed between the facing surface 121a and the facing surface 122a. filled by

A facing surface 121a of the terminal portion 121 extends generally in the vertical direction (Z direction), and is partially formed with an inclined portion 121b that is inclined with respect to the vertical direction. The inclined portion 121b is inclined so that a part of the facing surface 121a of the terminal portion 121 is notched toward the upper surface 121u. Similarly to the inclined portion 121b, the opposite surface 122a of the terminal portion 122 is also formed with an inclined portion 122b that is inclined with respect to the vertical direction. The inclined portion 122b is inclined so that a part of the facing surface 122a of the terminal portion 122 is notched toward the upper surface 122u. The provision of the inclined portions 121b and 122b enhances the adhesion between the ground contact conductor 10 and the housing 30, which will be described later. Details will be described later.

The ground contact conductor 10 described above can be manufactured, for example, by pressing and bending a thin metal material, but it may be manufactured by a method different from those. Further, the ground contact conductor 10 is soldered to a ground conductive path (not shown) for ground connection formed on the printed wiring board PB (see FIG. 1).

(signal contact conductor)
The signal contact conductor 20 is a conductor for signal transmission made of, for example, a thin metal member.

As shown in FIG. 5, the signal contact conductor 20 includes a contact portion 21 formed in a cylindrical shape, and a conductor portion 22 extending outward from the lower end, which is one edge of the contact portion 21 . have.

The contact portion 21 has a substantially cylindrical shape and extends along the central axis C in the vertical direction (Z direction). The outer diameter of the contact portion 21 is smaller than the inner diameter of the ground body portion 11 of the ground contact conductor 10 . Further, the contact portion 21 has a slit 211 extending along the extending direction of the central axis C (vertical direction: Z direction). The slit 211 extends to both ends of the cylindrical contact portion 21 . Therefore, the contact portion 21 has a substantially C shape with a slit 211 in plan view along a plane orthogonal to the central axis C. As shown in FIG. The contact portion 21 is connected to a signal contact conductor (described later) of the plug connector 3 from the other edge (upper end in FIG. 5).

The conductor portion 22 is formed in a flat plate shape extending along the horizontal direction (XY direction). Conductive wire portion 22 extends outward from the lower end portion of contact portion 21 , that is, in a direction away from central axis C. As shown in FIG. In the example shown in FIG. 5, the conductor portion 22 extends in the -X direction with respect to the central axis C so that the X direction is the longitudinal direction. Although the main surface of the conductor portion 22 extends in the horizontal direction, it is not limited to the horizontal direction as long as it intersects with the central axis C at least.

The conducting wire portion 22 has a first region 221, a second region 222, and a third region 223 arranged in this order along the extending direction (X direction) from the side closer to the contact portion 21. As shown in FIG. The first region 221 is a region connected to the contact portion 21 . The third region 223 is a region including the end portion of the conductor portion 22 on the side opposite to the end portion on the side of the contact portion 21 . The second area 222 is an area sandwiched between the first area 221 and the third area 223 .

The width of the conductor portion 22 varies depending on the position in the longitudinal extension direction. Specifically, the first region 221, the second region 222, and the third region 223 have different widths among adjacent regions. Specifically, the first region 221 and the third region 223 are narrower than the second region 222 . In addition, the first region 221 has two regions 221a and 221b having different widths in order from the side closer to the contact portion 21 . The region 221a is narrower than the region 221b and is the smallest portion of the conductive wire portion 22 with the narrowest width. Also, the second region 222 includes the widest portion of the conductor portion 22 . As shown in FIG. 5(a), from the widest part of the second region 222 toward the contact part 21, that is, from the largest part of the second region 222 to the region 221b of the first region 221. , 221a, the width of the conductor portion 22 is gradually reduced. Also, the width of the conductor portion 22 is reduced from the widest portion of the second region 222 toward the third region 223 .

The change in width according to the position in the longitudinal extension direction of the conductor portion 22 makes it possible to suppress a decrease in the characteristic impedance of the receptacle connector 2 . Impedance matching in connectors is required in the high frequency region. In the receptacle connector 2 , the characteristic impedance of each part changes depending on the shape of the ground contact conductor 10 , the shape of the signal contact conductor 20 , and the distance between the ground contact conductor 10 and the signal contact conductor 20 . As described above, by adopting a structure in which the width of the conductor portion changes depending on the position in the extending direction, it is possible to finely adjust the characteristic impedance and reduce the change in the characteristic impedance. Further, when the extending direction of the main surface of the conductor portion 22 is the direction intersecting with the central axis C, the characteristic impedance can be adjusted more appropriately by changing the width. As described in the above embodiment, the width of the conducting wire portion 22 may be changed stepwise along the longitudinal direction. good too.

A through hole 225 is provided in the second region 222 of the conductor portion 22 . As shown in FIG. 5A , the through hole 225 extends along the extension direction (X direction) of the conductor portion 22 . In addition, the through hole 225 has a region 225a with a smaller hole diameter near the center along the extending direction. However, the shape of through-hole 225 is not particularly limited. The width of the through hole 225 (the width along the Y direction) can be about 30% to 70% of the width of the maximum portion of the second region 222, but can be changed as appropriate. In addition, a part of the housing 30 to be described later enters inside the through hole 225 . The through hole 225 is provided at a position overlapping the ground body portion 11 of the ground contact conductor 10 when viewed from the direction along the central axis C (see FIG. 3). This suppresses a decrease in the characteristic impedance of the receptacle connector 2 .

The contact portion 21 and the conducting wire portion 22 are connected by providing a first region 221 of the conducting wire portion 22 to the lower (−Z side) edge of the contact portion 21 . Two cutouts 213 are provided around the connection portion 212 with the conductor portion 22 in the contact portion 21 so as to sandwich the connection portion 212 . The lower surface 21s of the contact portion 21 and the lower surface 22s of the conductor portion 22 are formed to be on the same plane (XY plane) as shown in FIGS. 3 and 5(c). As shown in FIG. 5C, the notch 213 cuts the inside and outside of the contact portion 21 above the height position where the lower end faces of the contact portion 21 and the conductor portion 22 are provided in the vertical direction (Z direction). A communicating opening is formed.

The signal contact conductor 20 can be made, for example, by bending a metal plate. By preparing a metal plate having a shape corresponding to the signal contact conductor 20, bending the metal plate at the connection portion 212 between the conductor portion 22 and the contact portion 21, and further bending the area to be the contact portion 21 into a circle. , a signal contact conductor 20 can be obtained.

As shown in FIGS. 2 and 3 , the signal contact conductor 20 is arranged such that the contact portion 21 of the signal contact conductor 20 is inside the ground body portion 11 of the ground contact conductor 10 . At this time, the conductor portion 22 connected to the contact portion 21 of the signal contact conductor 20 is placed in the space S1 provided between the terminal portions 121 and 122 of the ground contact conductor 10 and extending along the longitudinal direction (X direction). placed. At this time, the lower surfaces 121s and 122s of the terminal portions 121 and 122 of the ground contact conductor 10, the lower surface 21s of the contact portion 21 of the signal contact conductor 20, and the lower surface 22s of the wire portion 22 of the signal contact conductor 20 are flush with each other ( XY plane). In this state, the ground contact conductor 10 and the signal contact conductor 20 are integrated by injecting an insulating resin, which will be described later, to form the housing 30 .

The shapes of the contact portion 21 and the conductor portion 22 can be changed. Moreover, the contact portion 21 and the conductor portion 22 may not be formed from one metal plate, and may be configured by combining a plurality of members.

(housing)
The housing 30 serves as an insulating member placed on the printed wiring board PB.

As shown in FIGS. 2 and 3, the housing 30 is provided to fill a gap S1 provided between terminal portions 121 and 122 included in the external terminal portion 12 of the ground contact conductor 10. As shown in FIGS. As shown in FIG. 2, the upper surface 30u of the housing 30 provided between the terminal portions 121 and 122 is substantially flush with the upper surfaces 121u and 122u of the terminal portions 121 and 122, and the lower surface 30s of the housing 30 is It is substantially flush with the lower surfaces 121s and 122s of the terminal portions 121 and 122 .

Further, as shown in FIG. 3, the housing 30 is also connected to the lower end of the ground body portion 11 of the ground contact conductor 10 . As a result, both the ground body portion 11 and the external terminal portion 12 of the ground contact conductor 10 are connected to the housing 30 . Furthermore, the housing 30 is connected to inclined portions 121b and 122b provided on the facing surfaces 121a and 122a of the terminal portions 121 and 122, respectively. Thereby, the contact area between the housing 30 and the terminal portions 121 and 122 is increased, and the adhesion between the housing 30 and the ground contact conductor 10 is enhanced.

As shown in FIGS. 2 and 3, the housing 30 contacts the lower end of the contact portion 21 of the signal contact conductor 20 and fills the periphery of the conductor portion 22 except for the lower surface 22s. It is At this time, a portion of the housing 30 also enters the through hole 225 provided in the second region 222 of the conductor portion 22 to fill the through hole 225 . As a result, the adhesion between the housing 30 and the signal contact conductors 20 is enhanced. The end portion of the conductor portion 22 of the signal contact conductor 20 opposite to the contact portion 21 , that is, the end portion of the third region 223 is not covered with the housing 30 and is exposed to the outside.

The housing 30 is formed so as to enter the inside of the contact portion 21 and the outside of the contact portion 21 and the inside of the ground body portion 11 as well. The housing 30 is provided so as to cover the periphery of the connection portion 212 with the contact portion 21 and the lower end of the contact portion 21 . As shown in FIG. 3, the upper surface 31u of the housing 30 inside the ground body portion 11 of the ground contact conductor 10 and outside the contact portion 21 is the upper surface 30u of the housing 30 provided between the terminal portions 121 and 122. are assumed to be approximately the same. On the other hand, the upper surface 32u of the housing 30 inside the contact portion 21 is lower in the vertical direction (Z direction) than the upper surfaces 30u and 31u. That is, in the vertical direction (Z direction), the height position of the upper surface 32u is closer to the bottom surface (lower surface 30s) of the housing 30 facing the printed wiring board PB than the height positions of the upper surfaces 30u and 31u. are doing. By setting the height of the upper surface 32u of the housing 30 inside the contact portion 21 lower than the upper surfaces 30u and 31u in this way, the insulating material remains particularly on the outer peripheral surface of the contact portion 21, and the mating connector does not function properly. It is possible to prevent the deterioration of the electrical connectivity when connecting the wires.

As shown in FIGS. 2 and 3, a portion of the upper surface 31u of the housing 30 inside the ground body portion 11 of the ground contact conductor 10 and outside the contact portion 21 has a surface height position higher than the upper surface 31u. has a low recess 33 . The recess 33 is formed in a region around the slit 211 provided in the contact portion 21 of the signal contact conductor 20 and continuing from the slit 211 . The height position of the surface of the recess 33 is the same as the height position of the upper surface 32 u of the housing 30 inside the contact portion 21 . The shape and size of the recess 33 are not particularly limited. However, at least, the height position of the surface of the housing 30 around the slit 211 outside the contact portion 21 is substantially the same as the height position of the upper surface 32u of the housing 30 inside the contact portion 21. The shape and size of the recess 33 can be set. It should be noted that the above-mentioned "the same height positions" does not only mean that the height positions are exactly the same, but the difference in height between the upper surface 32u and the recess 33 is greater than the difference in height between the upper surface 31u and the upper surface 32u. Also includes cases where is smaller than

[Assembly process of receptacle connector]
An assembling process of the receptacle connector 2 will be described. First, the ground contact conductor 10 and the signal contact conductor 20 are prepared. As described above, the ground contact conductor 10 and the signal contact conductor 20 can be produced, for example, by pressing and bending a plate made of a metal material.

Next, after setting the ground contact conductor 10 and the signal contact conductor 20 in the mold, an insulating material (for example, insulating resin) is injected into the mold and cooled to solidify. That is, the housing 30 is produced by insert molding, and thereby the receptacle connector 2 in which the ground contact conductor 10, the signal contact conductor 20, and the housing 30 are integrally molded can be produced.

The insulating material injected into the mold fills the space S1 between the terminal portions 121 and 122 of the ground contact conductor 10 and fills the through-holes provided in the conductor portion 22 of the signal contact conductor 20 arranged in the space S1. It also enters into the hole 225 . In addition, it enters inside the contact portion 21 of the signal contact conductor 20 through the notch portion 213 provided below the contact portion 21 . As a result, the insulating material inside the contact portion 21 and the insulating material outside the contact portion 21 are molded in an integrated state.

When manufacturing the receptacle connector 2 , after the signal contact conductor 20 is set in the mold, the recess 33 is formed outside the slit 211 of the signal contact conductor 20 , specifically, in the housing 30 when the insulating material is injected. The area can be abutted by a part in the mold. With such a configuration, the signal contact conductor 20 can be accurately positioned. Also, the injected insulating material is prevented from leaking from the portion where the mold is in contact.

[Plug connector]
Next, details of the plug connector 3 will be described with reference to FIGS. 6 to 12. FIG. As shown in FIGS. 6-8, the plug connector 3 comprises signal contact conductors 40, ground contact conductors 60 and an insulating housing 50. As shown in FIGS. A plug connector 3 is attached to the terminal portion TP of the coaxial cable SC.

The coaxial cable SC is used to transmit high-frequency signals between various signal processing elements (e.g., antennas, control chips for controlling antennas, substrates, etc.) built into small terminals such as mobile phones. Wiring used in As shown in FIG. 7, the coaxial cable SC includes a signal line SC1 made of a conductor, a shield line SC3 made of a conductor provided around the signal line SC1, and interposed between the signal line SC1 and the shield line SC3. and an insulating coating SC4 covering the shield line SC3.

The plug connector 3 is attached to the terminal portion TP where the signal line SC1 and the shield line SC3 are partially exposed. More specifically, the plug connector 3 removes the insulation coating SC4, the shield line SC3, and the dielectric layer SC2 so that the exposed portion of the signal line SC1 and the exposed portion of the shield line SC3 are arranged in order from the tip. It is attached to the processed terminal portion TP. In the plug connector 3 attached to the terminal portion TP, the signal contact conductor 40 is electrically connected to the signal line SC1, the ground contact conductor 60 is electrically connected to the shield line SC3, and the housing 50 connects the signal contact conductor 40 and the ground contact conductor 60. intervene between

A plug connector 3 attached to the terminal portion TP is connected to a receptacle connector 2 mounted on the printed wiring board PB. Specifically, the plug connector 3 is attached to the receptacle connector 2 along the thickness direction (Z direction) of the printed wiring board PB. When the plug connector 3 is attached to the receptacle connector 2 , the signal contact conductors 40 are electrically connected to the signal contact conductors 20 of the receptacle connector 2 and the ground contact conductors 60 are electrically connected to the ground contact conductors 10 of the receptacle connector 2 . Connected. The plug connector 3 attached to the receptacle connector 2 can be removed from the receptacle connector 2 along the thickness direction (Z direction) of the printed wiring board PB.

Specific configurations of the ground contact conductor 60, the signal contact conductor 40, and the housing 50 will be described in order below.

(ground contact conductor)
The ground contact conductor 60 is made of, for example, a thin plate-shaped metal material, and has a first portion 60A, a second portion 60B, and a connecting portion 60C. The first portion 60A has a fitting portion 61 and two arm portions 62 . The fitting portion 61 fits into the ground contact conductor 10 of the receptacle connector 2 . For example, the fitting portion 61 is tubular (cylindrical) and fits around the outer periphery of the gland body portion 11 . The central axis of the fitting portion 61 is substantially orthogonal to the axial direction of the coaxial cable SC.

A narrowed portion 611 with a partially reduced inner diameter is formed at one end (hereinafter referred to as “tip”) of the fitting portion 61 in the central axis direction. The narrowed portion 611 fits into the groove 11a of the ground body portion 11 of the ground contact conductor 10 of the receptacle connector 2 (see FIG. 12). A plurality of cutouts 612 are formed in the fitting portion 61 at the other end (hereinafter referred to as the “base end”) in the central axis direction of the fitting portion 61 . A plurality of protrusions 512 (described later) of the housing 50 are fitted into the plurality of notches 612 respectively. Note that the “cylindrical shape” is not necessarily limited to a cylindrical shape. For example, the “cylindrical shape” may be a polygonal cylindrical shape. In addition, the “cylindrical shape” includes a semi-cylindrical shape in which a part in the circumferential direction is notched. For example, the fitting portion 61 has a semi-cylindrical shape with the coaxial cable SC side cut away.

The two arm portions 62 are connected to both ends of the fitting portion 61 in the circumferential direction, and extend outward from the fitting portion 61 while facing each other. Both of the two arm portions 62 are along the axial direction of the coaxial cable SC.

The second portion 60B has a lid portion 63 , a clamp portion 64 and a barrel portion 65 . The lid portion 63 closes the proximal end of the fitting portion 61 without overlapping the outer peripheral surface of the fitting portion 61 . Specifically, the lid portion 63 has a substantially flat plate shape over the entire area, and no folds or the like that overlap the fitting portion 61 are formed on the peripheral portion thereof. Hereinafter, the surface of the lid portion 63 facing the proximal end of the fitting portion 61 is referred to as "inner surface", and the surface opposite to the inner surface is referred to as "outer surface".

The clamp portion 64 holds a portion of the terminal portion TP of the coaxial cable SC from which the insulation coating SC4 has been removed (hereinafter referred to as "holding target portion of the terminal portion TP") and contacts the shield wire SC3. For example, the clamp portion 64 is aligned with the fitting portion 61 along the axial direction of the coaxial cable SC.

For example, the clamping portion 64 includes a clamping base 641 and two clamping arms 642 . The clamp base 641 is a plate-like portion connected to the lid portion 63 . Note that the term “connected” here includes not only direct connection but also connection via another portion.

The two clamp arms 642 are connected to both side surfaces of the peripheral edge of the clamp base 641 along the axial direction of the coaxial cable SC, and protrude from the inner surface of the clamp base 641 (the surface connected to the inner surface of the lid portion 63). The two clamp arms 642 are opposed to each other across the holding target portion of the terminal portion TP, and are bent so as to wrap the holding target portion of the terminal portion TP between itself and the clamp base 641 and come into contact with the shield wire SC3. ing.

The clamp portion 64 is located at the farthest end from the fitting portion 61 in the ground contact conductor 60 . More specifically, in the ground contact conductor 60 , two clamp arms 642 are located at the farthest ends from the central axis of the fitting portion 61 . In other words, the ground contact conductor 60 does not have a portion that contacts the insulating coating SC4 at a position farther from the central axis of the fitting portion 61 than the two clamp arms 642.

Barrel portion 65 holds housing 50 between fitting portion 61 and clamp portion 64 . As will be described later, the housing 50 has a first portion 51 housed within the fitting portion 61 and a second portion 52 arranged between the two arm portions 62 . The barrel portion 65 holds the second portion 52 together with the two arm portions 62 .

For example, barrel portion 65 includes barrel base 651 and two barrel arms 652 . The barrel base 651 is a plate-like portion interposed between the lid portion 63 and the clamp base 641 to connect them.

The two barrel arms 652 are connected to both side surfaces of the peripheral edge of the barrel base 651 along the axial direction of the coaxial cable SC, and protrude from the inner surface of the barrel base 651 (the surface connected to the inner surface of the lid portion 63). The two barrel arms 652 face each other with the two arm portions 62 and the second portion 52 interposed therebetween, and are bent so as to wrap the two arm portions 62 and the second portion 52 between the barrel base 651 and the barrel base 651 . there is Hereinafter, of the barrel arm 652, the portion between the bent portion and the barrel base 651 will be referred to as the "base portion of the barrel arm 652", and the tip side of the bent portion will be referred to as the "tip portion of the barrel arm 652". .

A contact claw portion 654 protruding inward is formed at the base of the barrel arm 652 . The contact claw portion 654 presses the arm portion 62 toward the second portion 52 side. This strengthens the electrical connection between the barrel portion 65 and the arm portion 62 .

The length of the barrel portion 65 (width of the barrel arm 652) in the axial direction of the coaxial cable SC may be set such that a gap GP1 is created between the housing 50 and the clamp portion 64. In this case, arm portion 62 may be configured to further hold dielectric layer SC2 and shield line SC3 between housing 50 and clamp portion 64 (gap GP1). In this case, the ground contact conductor 60 may further have a holding claw portion 653 . The holding claw portion 653 protrudes inward from the barrel portion 65 between the housing 50 and the clamp portion 64 and presses the shield wire SC3 toward the dielectric layer SC2. The holding claw portion 653 may be positioned closer to the clamp portion 64 between the housing 50 and the clamp portion 64 . In other words, the distance from the clamp portion 64 to the holding claw portion 653 may be smaller than the distance from the housing 50 to the holding claw portion 653 . For example, the holding claw portion 653 is formed at the distal end portion of each barrel arm 652 (near the proximal end of the coaxial cable SC).

The ground contact conductor 60 may have a gap GP2 between the fitting portion 61 and the barrel portion 65 (that is, between the fitting portion 61 and the barrel arm 652). Further, ground contact conductor 60 may have a gap GP3 between barrel portion 65 and clamp portion 64 (ie, between barrel arm 652 and clamp arm 642).

The connecting portion 60C connects the first portion 60A and the second portion 60B. For example, the connecting portion 60C connects the proximal end of the fitting portion 61 and the lid portion 63 on the opposite side of the coaxial cable SC. Before assembly of the plug connector 3 , the connecting portion 60</b>C connects the first portion 60</b>A and the second portion 60</b>B with the lid portion 63 aligned with the central axis of the fitting portion 61 . The connecting portion 60</b>C is bent substantially at a right angle so that the lid portion 63 is orthogonal to the central axis of the fitting portion 61 and closes the proximal end of the fitting portion 61 during assembly of the plug connector 3 .

(signal contact conductor)
The signal contact conductor 40 is made of, for example, a thin metal member and is accommodated in the ground contact conductor 60 . As shown in FIGS. 7-9, the signal contact conductor 40 has a contact portion 41, a connection portion 42, an intermediate portion 43, and extension portions 44 and 45. As shown in FIGS. The contact portion 41 is located within the fitting portion 61 and contacts the signal contact conductor 20 of the receptacle connector 2 .

For example, the contact portion 41 includes a contact base 411 and two contact arms 412 . The contact base 411 is arranged so as to be substantially perpendicular to the central axis of the fitting portion 61 . The two contact arms 412 are connected to both side surfaces of the contact base 411 along the axial direction of the coaxial cable SC and protrude toward the tip of the fitting portion 61 . The two contact arms 412 face each other and sandwich the contact portion 21 of the signal contact conductor 20 with the fitting portion 61 fitted into the ground body portion 11 of the ground contact conductor 10 of the receptacle connector 2 (see FIG. 12). ).

The connection portion 42 is located inside the barrel portion 65 and is connected to the signal line SC1. The connecting portion 42 is a plate-like portion that is arranged perpendicular to the center axis of the fitting portion 61 . The connecting portion 42 has a first major surface 421 facing the barrel base 651 of the barrel portion 65 and a second major surface 422 opposite to the first major surface 421 . A signal line SC1 is connected to the first main surface 421 (connection main surface). Specific examples of the method of connecting the signal line SC1 include soldering, caulking, ultrasonic bonding, and the like. As an example, the signal line SC1 is connected to the first main surface 421 by ultrasonic bonding.

The intermediate portion 43 is a flat portion that connects the contact base 411 of the contact portion 41 and the connection portion 42 . The intermediate portion 43 has a first major surface 431 facing the lid portion 63 and the barrel base 651 and a second major surface 432 opposite to the first major surface 431 . The first principal surface 431 (intermediate principal surface) is continuous with the first principal surface 421 , and the second principal surface 432 is continuous with the second principal surface 422 . The intermediate portion 43 extends from the fitting portion 61 to the barrel portion 65 , that is, in a direction connecting the contact portion 41 and the connection portion 42 , and connects the contact base 411 and the connection portion 42 .

The width of the intermediate portion 43 varies depending on the position in the direction (X direction) connecting the contact portion 41 and the connection portion 42 . The width here means the width in the direction (Y direction) orthogonal to the axial direction of the coaxial cable SC. The width of the intermediate portion 43 is set so as to suppress the characteristic impedance change between the signal contact conductor 40 and the ground contact conductor 60 according to the position in the direction (X direction) connecting the contact portion 41 and the connection portion 42. ing. When the width of the intermediate portion 43 is constant, the characteristic impedance between the intermediate portion 43 and the ground contact conductor 60 changes according to the position in the direction (X direction) connecting the contact portion 41 and the connection portion 42 . For example, the characteristic impedance is low at a position close to the ground contact conductor 60 . In addition, the characteristic impedance is also low at positions surrounded by more metal of the ground contact conductor 60 . Thus, the width of the intermediate portion 43 is larger at the position where the characteristic impedance is low due to the relationship with the ground contact conductor 60 compared to the position where the characteristic impedance is high.

For example, in the gap GP2 (the gap between the fitting portion 61 and the barrel portion 65), the amount of metal of the ground contact conductor 60 surrounding the intermediate portion 43 (for example, unit length (because there is no barrel arm 652). Therefore, in the portion of the intermediate portion 43 located in the gap GP2, a widened portion 433 having a width larger than that of the portion located in the barrel portion 65 and the portion located in the fitting portion 61 of the intermediate portion 43 is provided. is provided.

The width of the connecting portion 42 is greater than the width of the intermediate portion 43 . The width of the connecting portion 42 should be at least larger than the average width of the intermediate portion 43, and may be larger than the maximum width of the intermediate portion 43 (for example, the width of the widened portion 433). In order to accurately define the average value of the width of the intermediate portion 43, it is necessary to specify the boundary between the contact portion 41 and the connecting portion 42 and the boundary between the connecting portion 42 and the intermediate portion 43. , the contact portion 41, the connection portion 42, and the intermediate portion 43 are formed of a single metal member, so there is no visible boundary. Therefore, the edge 412 a of the contact arm 412 near the connecting portion 42 is defined as the boundary between the contact portion 41 and the intermediate portion 43 . An edge 42a close to the contact portion 41 and having the same width as the portion where the signal line SC1 is connected is defined as the boundary between the intermediate portion 43 and the connection portion 42. FIG. Note that the portions having the same width include portions where the corners are chamfered or the like.

The signal contact conductor 40 has a boundary portion (portion near the boundary) between the intermediate portion 43 and the connection portion 42 such that the first principal surface 421 (connection principal surface) is recessed with respect to the first principal surface 431 (intermediate principal surface). It may be bent at

The extension portion 44 is a flat plate-like portion projecting from the contact base 411 to the opposite side of the intermediate portion 43 . The extension portion 45 is a flat plate-like portion projecting from the connection portion 42 to the opposite side of the intermediate portion 43 . The extensions 44 , 45 function as retention allowances by the housing 50 .

(housing)
As shown in FIG. 7, the housing 50 holds the signal contact conductors 40 and is housed within the ground contact conductors 60 . For example, housing 50 has a first portion 51 and a second portion 52 . The first portion 51 is accommodated in the fitting portion 61 and holds the contact portion 41 and a portion of the intermediate portion 43 on the contact portion 41 side.

The first portion 51 has a concave portion 511 for exposing the contact portion 41 toward the tip of the fitting portion 61 . Thereby, the contact portion 41 can be brought into contact with the contact portion 21 of the signal contact conductor 20 in the receptacle connector 2 . In addition, the outer diameter of the distal end portion of the first portion 51 (the portion on the distal end side of the fitting portion 61 ) is smaller than the inner diameter of the fitting portion 61 . This allows the ground body portion 11 of the ground contact conductor 10 to be introduced between the fitting portion 61 and the first portion 51 .

The second portion 52 protrudes from the first portion 51 in the direction in which the two arm portions 62 extend, and holds the connecting portion 42 and a portion of the intermediate portion 43 located near the connecting portion 42 . At least a portion of the second portion 52 is held by the barrel portion 65 together with the two arm portions 62 as described above.

The second portion 52 may be configured to form a cavity between the connecting portion 42 and the ground contact conductor 60 . The second portion 52 may have an opening for ultrasonically bonding the signal line to the connecting portion 42, and at least part of the cavity may be formed by the opening. The second portion 52 may have openings on both the first major surface 421 side and the opposite side of the first major surface 421 . The opening here means an opening that exposes at least part of the first main surface 421 or the second main surface 422 of the connecting portion 42 to the outside of the housing 50 .

For example, the second portion 52 has a recess 521 that exposes the first major surface 421 toward the barrel base 651 (see FIG. 10). Thus, the second portion 52 is formed with an opening OP<b>1 that exposes a portion of the first main surface 421 to the outside of the housing 50 . The concave portion 521 is also open on the opposite side of the first portion 51 (closer to the proximal end of the coaxial cable SC) in the second portion 52 . The opening OP1 is used to press the signal line SC1 against the first main surface 421 with an ultrasonic welding tool. A cavity CC1 is formed between the first main surface 421 and the barrel base 651 by the opening OP1.

In addition, a through hole 523 is formed in a portion of the second portion 52 that constitutes the bottom surface of the recess 521 to expose the second main surface 422 toward the tip portion of the arm portion 62 (see FIG. 11). . As a result, the second portion 52 has an opening OP<b>2 that exposes a portion of the second main surface 422 to the outside of the housing 50 . The opening OP2 is used to press a tool for supporting the connecting portion 42 against the second main surface 422 from the opposite side of the ultrasonic bonding tool. A cavity CC2 is formed between the second main surface 422 and the distal end of the barrel arm 652 by the opening OP2.

As shown in FIGS. 10 and 11 , a plurality of protrusions 512 are provided in the circumferential direction on the outer circumference of the base end portion of the first portion 51 (the portion on the base end side of the fitting portion 61 ). As described above, the plurality of protrusions 512 are fitted into the plurality of cutouts 612 of the fitting portion 61 (see FIG. 6). The convex portion 512 fitted in the notch portion 612 may protrude outward from the peripheral edge of the lid portion 63 (see FIG. 12). In other words, the protrusion amount of the lid portion 63 with respect to the outer periphery of the fitting portion 61 may be smaller than the protrusion amount of the convex portion 512 with respect to the outer periphery of the fitting portion 61 .
[Plug connector assembly process]

An assembling process of the plug connector 3 will be described. First, the signal contact conductor 40 is prepared, and the signal contact conductor 40 is set in a mold, then an insulating material (for example, insulating resin) is injected into the mold and cooled and solidified. That is, by insert molding, the housing 50 is produced while holding the signal contact conductor 40 . Next, the ground contact conductor 60 is prepared, and the housing 50 is set on the ground contact conductor 60 by fitting the projections 512 into the cutouts 612 of the fitting portion 61 . The signal contact conductor 40 and the ground contact conductor 60 can be produced by punching out a metal member having a predetermined shape from a thin metal plate and subjecting the metal member to plastic working such as bending. As described above, the ground contact conductor 60 is in a state in which the first portion 60A and the second portion 60B are connected by the connecting portion 60C while the lid portion 63 is aligned along the central axis of the fitting portion 61. there is Also, neither the two barrel arms 652 nor the two clamp arms 642 are bent.

Next, the signal line SC1 is ultrasonically bonded to the first main surface 421 of the connecting portion 42 at the opening OP1 of the housing 50 . Specifically, a tool for supporting the connecting portion 42 is inserted into the opening OP2 and pressed against the second main surface 422, and a tool for ultrasonic bonding is inserted into the opening OP1 to connect the signal line SC1 to the first main surface 422. It is pressed against the surface 421 . In this state, an ultrasonic bonding tool is used to apply ultrasonic waves to the signal line SC<b>1 to melt the plating or the like, thereby bonding the signal line SC<b>1 to the first main surface 421 .

Next, the connecting portion 60</b>C is bent to cover the proximal end of the fitting portion 61 with the lid portion 63 . At this time, the two arm portions 62 and the second portion 52 of the housing 50 are housed in the two barrel arms 652 , and the portion to be held of the terminal portion TP is housed in the two clamp arms 642 .

Next, the two clamp arms 642 are bent so as to wrap the holding target portion of the terminal portion TP with the clamp base 641, and the two arms 62 and the second portion 52 are wrapped with the barrel base 651. bends the two barrel arms 652 to . This completes the process of assembling the plug connector 3 .

[Effect]
Next, the effects of the connector assembly 1 described above will be described.

(receptacle connector)
In the receptacle connector 2 included in the connector assembly 1, the ground contact conductor 10 includes a cylindrical ground body portion 11 extending along a central axis C, which is a predetermined axis, and a cylindrical ground body portion 11 extending along the central axis C direction of the ground body portion 11. and an external terminal portion 12 provided on one edge along the edge. In the receptacle connector 2, the signal contact conductor 20 extends in the central axis C direction inside the ground main body 11, and has a contact portion 21 that contacts the contact conductor of the mating connector, and a contact portion 21 that extends in the central axis C direction. A substantially flat conductor portion 22 extending in an extending direction intersecting the direction of the central axis C from one edge of the ground main body portion 11 (the edge on the same side as the side where the external terminal portion 12 is provided in the ground body portion 11) ,have. The conducting wire portion extends with its pair of main surfaces intersecting in the direction of the central axis C, and its width varies depending on the position in the extending direction. High-precision impedance matching in connectors is required in the high-frequency region. As in the receptacle connector 2 described above, by adopting a structure in which the width of the conductor portion 22 changes depending on the position in the extending direction, it is possible to finely adjust the characteristic impedance, and it is possible to reduce the change in the characteristic impedance. . In addition, since the pair of principal surfaces extend across the axial direction, the height of the receptacle connector 2 can be reduced. Further, by changing the width of the conductor portion 22, in which the pair of main surfaces extend in the axial direction to intersect each other, according to the position in the extending direction, the characteristic impedance can be preferably adjusted.

A region 221a, which is a minimum portion where the width of the conductive wire portion 22 is the smallest, is provided at a position of the conductive wire portion 22 that is closest to the contact portion 21, and a region 221a is provided at a position spaced from the minimum portion in the extension direction of the conductive wire portion. A second region 222 is provided that includes a maximum portion of maximum width. The width of the conductor portion 22 gradually increases from the minimum portion to the maximum portion. If the width of the conductor portion 22 closest to the contact portion 21 among the conductor portions 22 is increased, the characteristic impedance will be reduced due to the influence of the ground contact conductor 10, and thus the variation width of the characteristic impedance may increase. There is On the other hand, by minimizing the width of the conductor portion 22 in the region as described above, the change in the characteristic impedance with respect to the contact portion 21 can be reduced. In addition, the maximum width of the conductor portion 22 is separated from the minimum width portion, and the width gradually changes, thereby reducing the change in the characteristic impedance caused by the change in the width of the conductor portion 22. can be done. Note that the change in width for achieving the above effect may be stepwise or gradual.

A through hole 225 is provided at the largest portion of the conductor portion 22, and a portion of the housing 30 is inserted into the through hole 225. As shown in FIG. It is conceivable that the characteristic impedance may decrease in the widened region of the conductor portion 22 . On the other hand, by providing the through hole 225 in the widest portion, the decrease in the characteristic impedance in that region is suppressed. Furthermore, since a part of the housing 30 is inserted into the through hole 225, the adhesion between the housing 30 and the signal contact conductor 20 is enhanced.

Further, the through-hole 225 is provided at a position overlapping the ground body portion 11 of the ground contact conductor 10 when viewed from the central axis C direction. Since the position where the ground main body portion 11 of the ground contact conductor 10 and the wire portion 22 of the signal contact conductor 20 overlap is a region where the two are close to each other, there is a possibility that the characteristic impedance will be lowered. On the other hand, by providing the through hole 225 in the conductor portion 22, the number of signal contact conductors 20 in the vicinity of the ground body portion 11 of the ground contact conductor 10 can be reduced, thereby suppressing the decrease in the characteristic impedance. .

The receptacle connector 2 also includes a signal contact conductor 20, a ground contact conductor 10, and a housing 30 that integrates the signal contact conductor 20 and the ground contact conductor 10 while insulating them. Further, the ground contact conductor 10 includes a cylindrical ground main body portion 11 extending along a predetermined central axis C, and an external terminal portion 12 provided at one edge of the ground main body portion 11 in the central axis C direction. ,have. The signal contact conductor 20 extends in the central axis C direction inside the ground main body 11 and has a substantially cylindrical shape having a slit 211 extending in the central axis C direction, and is a contact portion that contacts the signal contact conductor of the mating connector. 21 and an extension that intersects the central axis C direction from one edge of the contact portion 21 in the central axis C direction (an edge on the same side as the external terminal portion 12 of the ground body portion 11). and a conductor portion 22 extending in the direction in which it is present. The housing 30 comes into contact with the edge of the contact portion 21 of the signal contact conductor 20 where the conductor portion 22 is provided, and also enters between the contact portion 21 and the ground body portion 11 and inside the contact portion 21. , the height position of the surface along the direction of the central axis C inside the contact portion 21 is higher than the height position of the surface along the direction of the central axis C between the contact portion 21 and the ground main body portion 11, and the housing It is positioned closer to the bottom face facing the printed wiring board PB of 30 . With the above structure, even if burrs or the like are generated by the material forming the housing 30 when the housing 30 is formed by insert molding as described above, the burrs do not affect the contact with the mating contact conductor. You can reduce the risk you give. Therefore, it is possible to suppress the occurrence of poor connection resulting from the molding of the housing.

Further, in at least a partial region between the contact portion 21 and the ground main body portion 11, which is continuous with the slit 211, the height position of the surface of the housing along the axial direction is the same as the above-mentioned inside of the contact portion. It can be the same as the height position of the surface along the axial direction. When the housing 30 is formed by insert molding, a material forming the housing, such as a resin material, moves inside and outside the slit 211 during molding. Therefore, burrs and the like may occur due to the material moving inside and outside the slit 211 . As in the above configuration, by setting the height position of the housing 30 in the area continuous from the slit 211 to the same height position as the inside of the contact portion 21, even if burrs or the like are generated around the slit 211, this The risk of burrs affecting contact with the mating signal contact conductor can be reduced. Therefore, it is possible to further suppress the occurrence of poor connection caused when the housing 30 is molded. When manufacturing the receptacle connector 2, after the signal contact conductors 20 are set in the mold, the signal contact conductors are placed inside the mold by bringing the part inside the mold into contact with the outside of the slit when injecting the insulating material. 20 can be positioned accurately. Furthermore, since the part in the mold abuts against the outside of the slit 211, it is possible to prevent the insulating material from leaking out from the part.

A notch portion 213 is provided continuously from the conductor portion 22 at the edge of the contact portion 21 of the signal contact conductor 20 where the conductor portion 22 is provided. The housing 30 between and the housing 30 inside the contact portion 21 are continuous. Since the contact portion 21 and the ground body portion 11 and the housing 30 inside the contact portion 21 are continuous through the notch portion 213, the housing 30 and the ground contact conductor 10 and the signal contact conductor 20 are connected. Adhesion is enhanced. Therefore, damage to the receptacle connector 2 can be prevented.

(plug connector)
In the plug connector 3, the ground contact conductor 60 holds a fitting portion 61 to be fitted to the ground contact conductor 10 of the receptacle connector 2 and a portion of the terminal portion TP of the coaxial cable SC from which the insulation coating SC4 has been removed. and a clamp portion 64 that contacts the shield wire SC3, and the clamp portion 64 is located at the farthest end from the fitting portion 61 in the ground contact conductor 60. As shown in FIG. When a part of the ground contact conductor 60 faces the shield wire SC3 through the insulating coating SC4, the stability of the characteristic impedance in the high-frequency signal transmission path is lowered due to the electrostatic capacity of that part. On the other hand, according to the plug connector 3, since the clamp portion 64 that contacts the shield wire SC3 is located at the farthest end from the fitting portion 61, the ground contact conductor 60 has the shield wire SC3 through the insulation coating SC4. is reduced. Therefore, it is effective in improving the stability of the characteristic impedance in the transmission path of the high frequency signal.

The ground contact conductor 60 may further have a barrel portion 65 that holds the housing 50 between the mating portion 61 and the clamp portion 64. The barrel portion 65 further includes the dielectric layer SC2 and the shield wire SC3. It may be configured to hold. In the configuration in which the clamp portion 64 is located at the farthest end from the fitting portion 61, it is difficult to separately provide a portion (hereinafter referred to as a "skin clamp") that holds the coaxial cable SC from the outside of the insulation coating SC4. On the other hand, according to the structure in which the barrel portion 65 further holds the dielectric layer SC2 and the shield wire SC3 between the housing 50 and the clamp portion 64, the ground contact conductor 60 is clamped by the barrel portion 65 instead of the outer clamp. and the coaxial cable SC can be reinforced.

The ground contact conductor 60 may further have a holding claw portion 653 that protrudes inward from the barrel portion 65 and pushes the coaxial cable SC toward the dielectric layer SC2. In this case, the reinforcing effect of the barrel portion 65 of the connecting portion between the ground contact conductor 60 and the coaxial cable SC can be further enhanced. In addition, the barrel portion 65 and the shield wire can be connected more firmly, and the characteristic impedance can be further improved.

The holding claw portion 653 may be positioned closer to the clamp portion 64 between the housing 50 and the clamp portion 64 . In this case, the reinforcing effect can be further enhanced by the holding claw portion 653, and the connection between the barrel portion 65 and the shield wire SC3 can be more firmly established.

The housing 50 may have openings OP<b>1 and OP<b>2 for ultrasonically bonding the signal line SC<b>1 to the connecting portion 42 . According to the configuration in which the signal line SC1 is ultrasonically bonded to the connecting portion 42, the posture of the signal line SC1 after bonding is stabilized compared to soldering or the like, so it is possible to further improve the stability of the characteristic impedance. be. In addition, since the thermal damage to the dielectric layer SC2 during bonding is small compared to solder bonding or the like, it is possible to shorten the exposed length of the signal line SC1 and bring the tip of the dielectric layer SC2 closer to the connection portion 42. can. Therefore, the holding margin of the dielectric layer SC2 and the shield line SC3 by the barrel portion 65 can be increased, and the reinforcing effect of the barrel portion 65 can be further enhanced.

The ground contact conductor 60 may further have a lid portion 63 that closes one end of the fitting portion 61 without overlapping the outer peripheral surface of the fitting portion 61 . In this case, the structure in which the lid portion 63 does not overlap the outer peripheral surface of the fitting portion 61 further reduces locations where capacitance is likely to occur. Therefore, it is more effective for improving the stability of the characteristic impedance in the transmission path of the high frequency signal.

In the signal contact conductor 40, the contact portion 41 and the connection portion are arranged so as to suppress the characteristic impedance change between the signal contact conductor 40 and the ground contact conductor 60 according to the position between the contact portion 41 and the connection portion 42. The width of the intermediate portion 43 may vary depending on the position between it and 42 . In this case, the width of the intermediate portion 43 suppresses the characteristic impedance change from the connection portion 42 to the contact portion 41 . Therefore, it is effective in improving the stability of the characteristic impedance in the transmission path of the high frequency signal.

The portion of the intermediate portion 43 located in the gap GP2 between the fitting portion 61 and the barrel portion 65 has a gap between the portion of the intermediate portion 43 located within the fitting portion 61 and the portion located within the barrel portion 65. A widened portion 433 having a greater width than any other may be provided. Between the fitting portion 61 and the barrel portion 65, the amount of metal on the ground contact conductor 60 side is smaller than that in the barrel portion 65 and the like. Therefore, the characteristic impedance between the signal contact conductor 40 and the ground contact conductor 60 tends to be higher than in the barrel portion 65 or the like. On the other hand, by providing the intermediate portion 43 with the widened portion 433 , it is possible to suppress the characteristic impedance from increasing in the path from the connection portion 42 to the contact base 411 .

The width of the connection portion 42 may be greater than the width of the intermediate portion 43 , and the housing 50 may be configured to form cavities CC<b>1 and CC<b>2 between the connection portion 42 and the ground contact conductor 60 . In this case, by increasing the width of the connection portion 42, the workability of connecting the signal line to the connection portion 42 is improved. On the other hand, as the width of the connecting portion 42 increases, the characteristic impedance of the connecting portion 42 decreases. On the other hand, since the housing 50 forms the cavities CC1 and CC2 between the connecting portion 42 and the ground contact conductor 60, the dielectric constant between the connecting portion 42 and the ground contact conductor 60 is lowered. Therefore, it is possible to prevent the characteristic impedance from being lowered due to the increased width of the connecting portion 42 . Therefore, it is possible to achieve both workability in connection of the signal line SC1 and suppression of changes in characteristic impedance.

At least part of the cavities CC1 and CC2 may be configured by the openings OP1 and OP2 for ultrasonically bonding the signal line SC1 to the connection portion 42 . In this case, the openings OP1 and OP2 contribute to both suppression of characteristic impedance change and improvement of the workability of ultrasonic bonding. Therefore, it is possible to more reliably achieve both workability in connecting the signal lines and suppression of changes in the characteristic impedance.

The connection portion 42 has a first main surface 421 for connecting the signal line SC1, the intermediate portion 43 has a first main surface 431 connected to the first main surface 421, and the signal contact conductor 40 has a first main surface 431 connected to the first main surface 421. The boundary portion between the intermediate portion 43 and the connecting portion 42 may be bent so that the first main surface 421 is recessed with respect to the first main surface 431 . In this case, since the balance between the distance between the connection portion 42 and the ground contact conductor 60 and the distance between the signal line SC1 connected to the connection portion 42 and the ground contact conductor 60 is adjusted, the change in characteristic impedance is more reliably controlled. can be suppressed.

DESCRIPTION OF SYMBOLS 1... Connector assembly 2... Receptacle connector 3... Plug connector 10... Ground contact conductor 11... Ground body part 12... External terminal part 20... Signal contact conductor 21... Contact part 22... Wire part DESCRIPTION OF SYMBOLS 30... Housing, 33... Recessed part, 40... Signal contact conductor, 41... Contact part, 42... Connection part, 43... Intermediate part, 50... Housing, 60... Ground contact conductor, 61... Fitting part, 63... Lid part, DESCRIPTION OF SYMBOLS 64... Clamp part 65... Barrel part 421, 431... 1st main surface 433... Widened part CC1, CC2... Cavity OP1, OP2... Opening SC... Coaxial cable SC1... Signal wire SC3... Shield wire , SC2...dielectric layer, SC4...insulating coating, TP...terminal part.

Claims (3)

A signal contact conductor, a ground contact conductor, and a housing that integrates the signal contact conductor and the ground contact conductor while insulating them. a connector that is
The ground contact conductor is
a tubular body extending along a predetermined axis;
an external terminal portion provided at one edge in the axial direction of the body portion;
The signal contact conductor is
a contact portion extending in the axial direction inside the body portion and having a substantially cylindrical shape having a slit extending in the axial direction, the contact portion coming into contact with a signal contact conductor of the mating connector;
a conductor portion extending from one end edge in the axial direction of the contact portion in an extending direction that intersects the axial direction;
The housing is
a bottom surface facing the wiring board;
a first surface facing away from the bottom surface between the contact portion and the body portion;
a second surface facing away from the bottom surface inside the contact portion;
a third surface facing opposite to the bottom surface in a partial area continuous from the slit between the contact portion and the body portion;
The connector , wherein the height positions of the second surface and the third surface are positioned closer to the bottom surface than the height position of the first surface in the axial direction. The connector according to claim 1 , wherein the height position of the third surface is the same as the height position of the second surface in the axial direction. A notch portion is provided continuously with the conductor portion at an end edge of the contact portion of the signal contact conductor where the conductor portion is provided, and the housing is provided between the contact portion and the body portion at the notch portion. 3. The connector according to claim 1, wherein the housing inside the contact portion is continuous with the housing.

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