KR20240067000A - Connector, connector with cable attached and connector apparatus - Google Patents

Abstract

(Problem) The characteristic impedance of a connector mounted on a cable equipped with a plurality of insulated wires and shields is brought close to or matches the characteristic impedance of the cable, and the shielding effect by the shield member of the connector is improved.
(Solution) The plug 8 mounted on the shielded twisted pair cable 2 includes a main shield member 21 that covers an insulating member 14 with a plurality of plug terminals formed therein from above, and an insulating member. It has a shield member (31) that covers the cable (14) from below, and in the shield member (21), a plurality of insulated wires (3) included in the cable (2) are exposed from the shield (4) of the cable (2). An inner wire shield portion 25 is formed to surround the exposed portion by caulking, and an outer wire shield portion 36 is formed to surround the inner wire shield portion 25 by caulking the shield member 31. .

Description

Connector, connector with cable attached, and connector device {CONNECTOR, CONNECTOR WITH CABLE ATTACHED AND CONNECTOR APPARATUS}

The present invention relates to a connector mounted on a cable equipped with a plurality of insulated wires and shields, a connector attached to a cable equipped with such a cable, and a connector device provided with the connector and a mating connector.

For example, shielded cables including an insulated wire and a shield covering the insulated wire, such as a twisted pair cable with a shield, are used for the transmission of high-frequency signals between electrical and electronic devices. The shield in a shielded cable has a function of suppressing noise (electromagnetic waves) from entering the electrical/electronic device through the cable and noise being radiated from the electrical/electronic device through the cable.

In addition, many of the connectors mounted on shielded cables have a terminal to which the insulated wire of the cable is connected, an insulating member that covers the outer peripheral side of the terminal, and a shell (or shield member) that covers the outer peripheral side of the insulating member. The shell is formed of a conductive material and is electrically connected to the shield of the shield cable. The shell has a function of suppressing noise from entering the electrical/electronic device through the connector and noise radiating from the electrical/electronic device through the connector.

Japanese Patent Application Laid-Open No. 2009-37826 (Patent Document 1) describes an example of a connector mounted on a shield cable and having a shell.

Japanese Patent Publication No. 2009-37826

When attaching a shielded cable to a connector, cut the sheath of one side of the shield cable to expose the insulated wire and one side of the shield from the sheath, and also cut the one side of the portion of the shield exposed from the sheath. , or by folding and bending the portion of the shield exposed from the sheath to the outer periphery of the sheath, the one side portion of the insulated wire is exposed from the shield. Additionally, by cutting the insulator on one side of the portion of the insulated wire exposed from the shield, the one side portion of the conductor of the insulated wire is exposed from the insulator. After that, the exposed one-side portion of the conductor of the insulated wire is connected to the terminal, and the exposed one-side portion of the shield is connected to the shell.

In a typical connector mounted on a shielded cable, the terminal is arranged on the front end side (tip side) of the connector. On the other hand, in the shell, the portion for connecting the shield of the shield cable is disposed on the rear end side (proximal end side) of the connector. Therefore, in the middle portion of the connector in the front-back direction, the insulated wire is disposed exposed from the shield (see Fig. 5 of Japanese Patent Application Laid-Open No. 2009-37826, etc.). In addition, in the connector, as shown in Fig. 5 of Japanese Patent Application Laid-Open No. 2009-37826, the outer peripheral side of the insulated wire disposed in a state exposed from the shield in the middle part of the front-back direction of the connector is protected by the shell of the connector. There is something that has a structure that covers space.

In the middle portion of the connector in the front-back direction, the insulated wire is disposed exposed from the shield, so the characteristic impedance of the connector becomes higher than the characteristic impedance of the shield cable. In this regard, a connector having a structure in which the outer circumferential side of the insulated wire exposed from the shield is placed in a state exposed from the shield in the middle part of the connector in the front-back direction is covered by a shell through a space is compared to a connector that does not have that structure. Therefore, it is thought that the characteristic impedance of the connector can be lowered to some extent and brought closer to the characteristic impedance of the shield cable to some extent. However, in order to suppress reflection of high-frequency signals and improve the efficiency of high-frequency signal transmission, it is desired to make the characteristic impedance of the connector closer to or match the characteristic impedance of the shield cable.

Moreover, in a shielded cable having a plurality of insulated wires, for example, a twisted pair cable with a shield, the plurality of insulated wires are bound by a shield and a sheath and are in close contact with each other. However, in the front-back direction middle part of the connector mounted on the shield cable having a plurality of insulated wires, the plurality of insulated wires of the shield cable are disposed in a state exposed from the shield, so in the front-back direction middle part of the connector, , these plurality of exposed insulated wires may bend, and the gap between these plurality of insulated wires may become larger compared to the gap between the plurality of insulated wires in the shield cable. As a result, in a connector mounted on a shielded cable having a plurality of insulated wires, the characteristic impedance of the connector may be higher than the characteristic impedance of the shielded cable due to bending of the plurality of exposed insulated wires.

In addition, in the connector described in Japanese Patent Application Laid-Open No. 2009-37826, the outer peripheral side of the insulated wire exposed from the shield in the middle portion of the connector in the front-back direction is covered through the space by the shell of the connector. If the space between the exposed insulated wire and the shell is large, there is a risk that the shielding effect, that is, the effect of suppressing noise radiation or intrusion, will be reduced compared to a shielded cable in which the shield and insulated wire are arranged in close contact with each other. There is.

The present invention was made in view of the problems described above, for example, and the object of the present invention is to make the characteristic impedance of a connector mounted on a cable with a plurality of insulated wires and shields close to the characteristic impedance of the cable. The object is to provide a connector, a connector with a cable attached, and a connector device that can match the connector shell (shield member) and increase the shielding effect by the shell (shield member) of the connector.

In order to solve the above problem, the connector of the present invention is a connector mounted on a cable equipped with a plurality of insulated wires and a shield covering the plurality of insulated wires, and includes a plurality of terminals to which the plurality of insulated wires are respectively connected, An insulating member covering an outer peripheral side of the plurality of terminals, and a first shield member and a second shield member each formed of a conductive material, wherein the first shield member covers an outer peripheral portion of the insulating member from one side. It has a terminal shield portion, a first wire shield portion that covers exposed portions of the plurality of insulated wires exposed from the shield, and a first shield connection portion connected to the shield, and the second shield member includes the insulator. a second terminal shield portion covering the outer peripheral portion of the member from the other side, a second electric wire shield portion covering the exposed portion of the plurality of insulated wires, and a second shield connection portion connected to the shield, the first electric wire shield One of the wire shield portion and the second wire shield portion brings the exposed portion of the plurality of insulated wires into contact with or is very close to the outer peripheral surface of the exposed portion of at least one insulated wire of the plurality of insulated wires. and surrounds the exposed portion of the plurality of insulated wires, wherein the other of the first and second wire shield parts covers the exposed portion of the plurality of insulated wires.

Additionally, in the connector of the present invention, the one wire shield portion may be a barrel for bundling and caulking the exposed portions of the plurality of insulated wires. Additionally, in the connector of the present invention, the other wire shield portion may be a barrel for caulking the one wire shield portion surrounding the exposed portion of the plurality of insulated wires. In addition, in the connector of the present invention, the length of the one wire shield portion in the front-back direction is equal to the length of the portion from the front end position of the shield to the rear end position of the terminal in the exposed portion of the plurality of insulated wires. It may be 1/2 or more.

In order to solve the above problems, the connector with a cable of the present invention is characterized by comprising a cable having a plurality of insulated wires and a shield covering the plurality of insulated wires, and the connector of the present invention.

In order to solve the above problem, the connector device of the present invention is a connector device including the connector of the present invention and a mating connector mounted on a board and fitted with the connector, wherein the mating connector includes the mating connector. When the connector is fitted, a first conductive part that contacts the first terminal shield part and connects the first terminal shield part to a ground part formed on a board, and when the connector is fitted into the mating connector, A second conductive portion is formed that contacts the second terminal shield portion and connects the second terminal shield portion to a ground portion formed on a substrate.

According to the present invention, the characteristic impedance of a connector mounted on a cable equipped with a plurality of insulated wires and shields can be approximated or matched to the characteristic impedance of the cable, and the shielding effect by the shield member of the connector can be increased. there is.

1 is an explanatory diagram showing a connector device according to an embodiment of the present invention.
Fig. 2 is a perspective view showing a plug as an embodiment of the connector of the present invention.
FIG. 3 is a perspective view showing a portion of the plug in FIG. 2 excluding the plug housing.
Fig. 4 is a perspective view showing the plug in Fig. 2 in an exploded state excluding the plug housing.
Fig. 5 is a cross-sectional view of a plug (excluding the plug housing) according to an embodiment of the present invention, (A) showing the plug cut on a plane that includes the axis of the plug and extends in the front-back and left-right directions. (B) shows a cross section of the plug cut along the cutting line VV in Fig. 5(A) viewed from the right.
Fig. 6 is an external view showing the part excluding the plug housing and shield member in the plug according to the embodiment of the present invention, and (A) is the part of the plug excluding the plug housing and shield member viewed from the right. The state is shown, and (B) shows the part of the plug, excluding the plug housing and shield member, viewed from below.
Fig. 7 is a cross-sectional view showing the plug excluding the plug housing and shield member in Fig. 6(A) cut along the cutting line VII-VII, and showing the cut cross section of the plug as viewed from the front.
Fig. 8 is a perspective view showing a receptacle, which is an embodiment of the mating connector in the connector device of the present invention, as seen from the left front.
FIG. 9 is a perspective view showing the receptacle in FIG. 8 as seen from the left, rear, and bottom.
Fig. 10 is a perspective view showing the receptacle in Fig. 8 in an exploded state.
Fig. 11 is a cross-sectional view of the receptacle in Fig. 8.
Fig. 12 is an explanatory diagram showing the connection between the plug's main shield member and shield member and the receptacle's shell when fitting the plug and the receptacle of the connector device according to the embodiment of the present invention.
Fig. 13 is an explanatory diagram showing a first modification of the plug according to the embodiment of the present invention.
Fig. 14 is an explanatory diagram showing a second modification of the plug according to the embodiment of the present invention.
Fig. 15 is an explanatory diagram showing a third modification of the plug according to the embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention will be described with reference to the drawings. When describing the front (Fd), back (Bd), top (Ud), bottom (Dd), left (Ld), and right (Rd) directions of the embodiment, arrows drawn on the lower part of FIGS. 1 to 15 are indicated. Follow.

(connector device)

Figure 1 shows a connector device 1. As shown in FIG. 1, the connector device 1 includes a plug 8 and a receptacle 51 fitted with the plug 8. Connector device 1 is an embodiment of the connector device of the present invention, plug 8 is an embodiment of the connector of the present invention, and receptacle 51 is an embodiment of the mating connector in the connector device of the present invention.

The plug (8) is mounted on the cable (2). Cable (2) is a twisted pair cable with a shield attached. The cable 2 is formed by two insulated wires 3 twisted together, a conductive material, a shield 4 covering the outer peripheral side of the two insulated wires 3, and an insulating material. It is provided with a sheath (5) that covers the outer peripheral side of the shield (4). Each insulated wire 3 is formed by covering the outer peripheral side of the conductor with an insulator. Receptacle 51 is mounted on substrate 6. The receptacle 51 is disposed on the mounting surface 6A of the substrate 6.

(plug)

Figure 2 shows the plug 8. Fig. 3 shows a portion of the plug 8 excluding the plug housing 41. Fig. 4 shows the disassembled portion of the plug 8 excluding the plug housing 41. FIG. 5(A) shows a cross-section of the plug 8 (excluding the plug housing 41) cut on a plane that includes the axis of the plug 8 and extends in the front-back and left-right directions, as viewed from above. It is showing. FIG. 5(B) shows a cross section of the plug 8 cut along the cutting line V-V in FIG. 5(A) as viewed from the right side (bottom in FIG. 5(A)). Fig. 6(A) shows the part of the plug 8, excluding the plug housing 41 and the shield member 31, as viewed from the right. FIG. 6(B) shows a portion of the plug 8 viewed from below, excluding the plug housing 41 and the shield member 31.

The plug 8 includes two plug terminals 10, an insulating member 14, a shield member 21, a shield member 31, and a plug housing 41. The plug terminal 10 is a specific example of a “terminal,” the outer shield member 21 is a specific example of a “first shield member,” and the shield member 31 is a specific example of a “second shield member.”

The plug housing 41 is formed of an insulating material such as resin. As shown in FIG. 2, the plug housing 41 has a barrel portion 42 and a protruding portion 44. The cylinder 42 is formed as a cylinder with a square cross-sectional outer shape. Inside the barrel portion 42, the rear portion of the upper shield member 21 (internal wire shield portion 25 and connection piece 27, etc.), the rear portion of the shield member 31 (lower terminal shield portion 32) ), the outer wire shield portion 36, the shield connection portion 38, etc.), and the one-side portion of the cable 2 are accommodated. Additionally, the cable 2 is pulled out rearward from within the barrel 42. Additionally, fixing pieces 43 for fixing the shield member 31 to the plug housing 41 are formed on the left and right wall portions of the cylinder portion 42.

The protrusion 44 protrudes forward from the front end of the upper wall portion of the cylinder 42. Below the protrusion 44, an insulating member 14, an upper-end shield portion 22, and a lower-end shield portion 32 are disposed. Additionally, an engaging convex portion 45 protruding downward is formed at the front end of the protruding portion 44. The front end portion of the protruding portion 44 is coupled to the front end portion of the insulating member 14 through the engaging convex portion 45. Additionally, a fitting portion 9 is formed by the protruding portion 44, the insulating member 14, the upper portion shield portion 22, and the lower portion shield portion 32. The plug 8 is connected to the receptacle 51 by fitting the fitting portion 9 into the fitting hole 59 of the receptacle 51. Additionally, a lock piece 46 is formed on the upper part of the plug housing 41 to prevent the plug 8 from falling out of the receptacle 51.

As shown in Fig. 5(A), the two plug terminals 10 are arranged so as to be aligned in the left and right directions inside the insulating member 14. Each plug terminal 10 is formed of a conductive material such as metal. Each plug terminal 10 has a contact portion 11, a conductor connection portion 12, and a wire fixing portion 13. As shown in Fig. 5(B), the contact portion 11 is formed on the front of the plug terminal 10 and extends in the front-back direction. The contact portion 11 is in contact with the contact portion 53 of the receptacle terminal 52 of the receptacle 51. In this embodiment, the contact portion 11 of the plug terminal 10 is formed normally, the contact portion 53 of the receptacle terminal 52 is formed in a pin shape, and the plug 8 is inserted into the receptacle 51. When aligned, the contact portion 53 of the receptacle terminal 52 is inserted into the contact portion 11 of the plug terminal 10. The conductor connection portion 12 is formed behind the contact portion 11. The conductor connecting portion 12 connects the plug terminal 10 and the conductor of the insulated wire 3 by caulking the end portion of the conductor of the insulated wire 3. The wire fixing portion 13 is formed behind the conductor connecting portion 12. The wire fixing portion 13 fixes the plug terminal 10 to the one side portion of the insulated wire 3 by caulking the insulator of the insulated wire 3.

The insulating member 14 is formed of an insulating material such as resin, and covers the outer peripheral side of the two plug terminals 10. The insulating member 14 is formed in a substantially rectangular parallelepiped shape. Inside the insulating member 14, two terminal accommodating portions 15 each accommodating two plug terminals 10 are formed. At the front end of the insulating member 14, two insertion holes 16 are formed that open forward and communicate with the inside of the terminal accommodating portion 15. When the plug (8) is fitted into the receptacle (51), the contact portion (53) of the receptacle terminal (52) is inserted into the contact portion (11) of the plug terminal (10) through the insertion hole (16) to make contact. Contact Jabu (11). Additionally, at the rear end of the insulating member 14, two wire insertion openings 17 are formed that open backward and communicate with the inside of the terminal accommodating portion 15. Each insulated wire 3 enters the terminal receiving portion 15 of the insulating member 14 from within the barrel portion 42 of the plug housing 41 through the wire insertion hole 17 .

Additionally, as shown in FIG. 2, an engaging concave portion 18 is formed in the upper portion of the front end portion of the insulating member 14. The front end of the insulating member 14 engages the engagement concave portion 18 with the engagement convex portion 45 formed on the front end of the projection 44 of the plug housing 41, thereby forming the projection of the plug housing 41. It is combined with the front end of (44).

Moreover, as shown in FIG. 4, two locking protrusions 19 are formed on the left outer surface of the insulating member 14 so as to be aligned in the front-back direction. Similarly, two locking convex portions 19 are formed on the right outer surface of the insulating member 14. The upper shield portion 22 of the upper shield member 21 is coupled to the insulating member 14 by the two locking projections 19 on the left and right disposed on the front side, out of a total of four locking protrusions 19. do. Additionally, the lower end shield portion 32 of the shield member 31 is coupled to the insulating member 14 by the two locking protrusions 19 on the left and right disposed at the rear.

The main shield member 21 is formed of a conductive material such as metal. The upper shield member 21 has an upper shield portion 22, a connecting portion 24, an inner wire shield portion 25, a connecting portion 26, and a connecting piece 27. The upper guard member 21 is formed by subjecting a plate made of a conductive material to press processing. Additionally, the upper terminal shield portion 22 is a specific example of the “first terminal shield portion.” The inner wire shield portion 25 is a specific example of the “first electric wire shield portion.” The connection piece 27 is a specific example of the “first shield connection portion.”

The upper end shield portion 22 surrounds the outer peripheral side of the insulating member 14 together with the lower end shield portion 32 of the shield member 31 to be described later, thereby forming two plug terminals within the insulating member 14. (10) It has the function of shielding. As shown in FIG. 3, the upper shield portion 22 covers the outer peripheral portion of the insulating member 14 from above. As shown in Fig. 4, the upper child shield portion 22 is a flat upper wall 22A that spreads in the front-back and left-right directions, and extends downward from the left edge of the portion near the front of the upper wall 22A in the front-back direction. and a flat left wall 22B that extends in the vertical direction, and a flat right wall 22C that extends downward from the right edge of the front portion of the upper wall 22A and widens in the anteroposterior and vertical directions. The upper wall 22A of the upper shield portion 22 covers substantially the entire upper outer surface of the insulating member 14. The left wall 22B of the upper child shield portion 22 covers the upper front portion of the left outer surface of the insulating member 14. The right wall 22C of the upper shield portion 22 covers the upper front portion of the right outer surface of the insulating member 14.

Additionally, locking holes 23 are formed on the front of the left wall 22B and the front of the right wall 22C of the upper child shield portion 22, respectively. These two locking holes 23 are respectively caught by the two locking convex portions 19 formed on the entire left and right outer surfaces of the insulating member 14, so that the upper member shield portion 22 is connected to the insulating member. It is combined with (14).

The inner wire shield portion 25 is a portion exposed from the shield 4 of the two twisted insulated wires 3 of the cable 2 (hereinafter, this is referred to as the “exposed portion of the insulated wire 3”). ) are bundled in parallel to each other to maintain the parallel state of the exposed portions of the insulated wires (3) and have the function of shielding the exposed portions of the two insulated wires (3). As shown in FIG. 6(A), the inner wire shield portion 25 is disposed behind the upper edge shield portion 22. In addition, the inner wire shield portion 25 is coupled to the rear end of the upper element shield portion 22 through a connection portion 24. The connection portion 24 is formed in a plate shape, extends rearward while sloping downward from the rear end of the upper arm shield portion 22, and is coupled to the front end of the inner wire shield portion 25.

The inner wire shield portion (25) covers the exposed portions of the two insulated wires (3). That is, when attaching the cable (2) to the plug (8), by cutting the sheath (5) of the one-side portion of the cable (2), each one-side portion of the two insulated wires (3) and the shield (4) is separated. Expose from sis (5). Additionally, the portion of the shield 4 exposed from the sheath 5 is folded back toward the outer periphery of the sheath 5, thereby exposing the end portions of the two insulated wires 3 from the shield 4. Additionally, by cutting the insulator on one side of the portion of each insulated wire 3 exposed from the shield 4, the one side portion of the conductor of each insulated wire 3 is exposed from the insulator. In the state where the plug 8 is attached to the cable 2, the exposed end portion of the conductor of each insulated wire 3 is connected to the conductor connection portion 12 of the plug terminal 10, as shown in FIG. 5(B). is connected to, the one side portion of the insulator of each insulated wire 3 is fixed to the wire fixing portion 13 of the plug terminal 10, and the one side portion where the shield 4 is folded is the shield member 31 described later. ) is connected to the shield connection portion 38, and one end portion of the cable 2 is fixed to the shield connection portion 38. Then, the portion of the two insulated wires 3 exposed from the shield 4 (exposed portion of the two insulated wires 3) is disposed within the barrel portion 42 of the plug housing 41. In addition, the two insulated wires (3) are twisted together within the cable (2), but when attaching the cable (2) to the plug (8), one end of the two insulated wires (3) is exposed from the shield (4). After doing so, the short side portions of the two insulated wires are untwisted and placed in the cylinder portion 42 of the plug housing 41 in a state in which they are stretched linearly and parallel to each other. The inner wire shield portion 25 covers exposed portions of the two insulated wires 3 disposed within the barrel portion 42 of the plug housing 41.

The inner wire shield portion 25 surrounds the exposed portions of the two insulated wires 3. The inner wire shield portion 25 covers the entire outer circumference of the exposed portions of the two insulated wires 3 stretched in a straight line parallel to each other so as to bind them while maintaining their parallel state. In addition, the inner wire shield portion 25 surrounds the exposed portions of the two insulated wires 3 and is in contact with the outer peripheral surface of the exposed portion of at least one of the two insulated wires 3. Doing it, or getting very close to it. Here, “very close” means that the exposed portions of the two insulated wires 3 are surrounded by the inner wire shield part 25, and the insulated wire 3 is exposed within the inner wire shield part 25. This means that the outer peripheral surfaces of the exposed portions of the inner wire shield portion 25 and the insulated wire 3 are close enough to sufficiently suppress bending of the portions and disruption of their parallel state.

As shown in Fig. 6(B), in the present embodiment, the inner wire shield portion 25 is a barrel for bundling and caulking the exposed portions of the two insulated wires 3. The inner wire shield portion 25 has a barrel base 25A and two barrel pieces 25B. As shown in Fig. 4, the barrel base 25A extends rearward from the rear end of the connecting portion 24. Before the plug 8 is assembled, of the two barrel pieces 25B, one barrel piece 25B extends to the left while inclining downward from the left edge of the barrel base 25A. The other barrel piece 25B extends to the right while sloping downward from the right edge of the barrel base 25A. When the plug 8 is assembled, the two barrel pieces 25B are bent to surround the outer peripheral side of the exposed portion of the two insulated wires 3. Thereby, the exposed portions of the two insulated wires 3 are caulked with the two barrel pieces 25B, as shown in Fig. 6(B).

FIG. 7 shows the plug 8 excluding the plug housing 41 and the shield member 31 in FIG. 6(A) being cut along the cutting line VII-VII, and the cross section of the cut plug 8 is shown in front. The state as seen from (left side in Fig. 6(A)) is shown. As shown in Fig. 7, in a state where the exposed portions of the two insulated wires 3 are caulked by the inner wire shield portion 25, a portion of the outer peripheral surface of the exposed portions of the two insulated wires 3 is in contact with each other. Doing it, or getting very close to it. Additionally, a portion of the inner surface of the barrel piece 25B on the left side of the inner wire shield portion 25 is in contact with, or is very close to, a portion of the outer peripheral surface of the exposed portion of the insulated wire 3 on the left side. Additionally, a portion of the inner surface of the barrel piece 25B on the right side of the inner wire shield portion 25 is in contact with, or is very close to, a portion of the outer peripheral surface of the exposed portion of the insulated wire 3 on the right side. When the caulking force when caulking the inner wire shield portion 25 is strong, a portion of the outer peripheral surface of the exposed portion of the two insulated wires 3 contacts each other, and also a portion of the inner surface of each barrel piece 25B There are many cases where a portion of the outer peripheral surface of the exposed portion of the insulated wire 3 is contacted. On the other hand, when the caulking force when caulking the inner wire shield portion 25 is weak, some of the outer peripheral surfaces of the exposed portions of the two insulated wires 3 are very close to each other, and also, each barrel piece 25B There are many cases where a portion of the inner surface comes very close to a portion of the outer peripheral surface of the exposed portion of the insulated wire 3. In addition, when the diameters of the two insulated wires 3 are equal to each other, in the state where the inner wire shield portion 25 is caulking the exposed portion of the two insulated wires 3, the inner wire shield portion 25 The inner diameter (D) in the left and right directions is approximately equal to twice the diameter of the insulated wire (3), and the inner diameter (E) in the up and down directions of the inner wire shield portion (25) is approximately equal to the diameter of the insulated wire (3). are equal

Additionally, the inner wire shield portion 25 covers the exposed portions of the two insulated wires 3 over a wide area in the front-back direction. As shown in FIG. 5(B), the length L of the inner wire shield portion 25 in the front-back direction (direction along the extension direction of the exposed portions of the two insulated wires 3) is the length of the insulated wire 3. It is more than one half of the length (M) of the exposed portion from the front end position of the shield 4 to the rear end position of the plug terminal 10. Additionally, the length (L) is less than the length (M).

The connection piece 27 has the function of electrically connecting the main shield member 21 to the shield 4 of the cable 2. The connection piece 27 is disposed behind the inner wire shield portion 25, as shown in FIG. 6(A). Additionally, the connecting piece 27 is coupled to the rear end of the inner wire shield portion 25 through the connecting portion 26. The connecting portion 26 is formed in a plate shape, extends rearward while slanting upward from the rear end of the inner wire shield portion 25, and is coupled to the front end of the connecting piece 27.

The connection piece 27 is formed in a plate shape that spreads in the front-back and left-right directions. Additionally, the connection piece 27 is curved so as to follow the outer peripheral surface of the shield 4. The lower surface of the connecting piece 27 is in wide contact with the upper part of the outer peripheral surface of the shield 4.

The shield member 31 is formed of a conductive material such as metal. As shown in FIGS. 3 and 4, the shield member 31 includes a lower end shield portion 32, a connecting portion 35, an external wire shield portion 36, a connecting portion 37, and a shield connecting portion 38. Have. The shield member 31 is formed by subjecting a plate made of a conductive material to press processing. Additionally, the lower terminal shield portion 32 is a specific example of the “second terminal shield portion.” The outer wire shield portion 36 is a specific example of the “second electric wire shield portion.” The shield connection portion 38 is a specific example of the “second shield connection portion.”

The lower end shield portion 32 surrounds the outer peripheral side of the insulating member 14 together with the upper end shield portion 22 of the upper shield member 21, thereby forming two plug terminals 10 within the insulating member 14. ) has the function of shielding. As shown in FIG. 3, the lower element shield portion 32 covers the outer peripheral portion of the insulating member 14 from below. As shown in Fig. 4, the lower element shield portion 32 is a flat lower wall 32A that spreads in the front-back and left-right directions, extends upward from the left edge of the lower wall 32A, and extends in the front-back and up-down directions. It has a flat left wall 32B that widens, and a flat right wall 32C that extends upward from the right edge of the lower wall 32A and widens in the front-back and up-down directions. The lower wall 32A of the lower end shield portion 32 covers substantially the entire lower outer surface of the insulating member 14. The left wall 32B of the lower end shield portion 32 covers the lower portion and the rear upper portion of the left outer surface of the insulating member 14. The right wall 32C of the lower end shield portion 32 covers the lower portion and the rear upper portion of the right outer surface of the insulating member 14.

Additionally, as shown in FIG. 3, the left wall 22B of the upper child shield portion 22 and the left wall 32B of the lower child shield portion 32 are on the left outer surface of the insulating member 14 (left side of the outer surface). ), the upper edge of the left wall 22B and the lower edge of the left wall 32B are arranged to face each other. In addition, the left wall 22B of the upper child shield portion 22 and the left wall 32B of the lower child shield portion 32 approach each other on the left outer surface of the insulating member 14 and face each other in the vertical direction. They are placed next to each other. Additionally, substantially the entire left outer surface of the insulating member 14 is covered by the left wall 22B of the upper child shield portion 22 and the left wall 32B of the lower child shield portion 32. Similarly, the right wall 22C of the upper child shield portion 22 and the right wall 32C of the lower child shield portion 32 are on the right outer surface (right side of the outer surface) of the insulating member 14, the right wall ( The upper edge of 22C) and the lower edge of right wall 32C are arranged to face each other. Additionally, the right wall 22C of the upper element shield portion 22 and the right wall 32C of the lower element shield portion 32 approach each other on the right outer surface of the insulating member 14, and are adjacent to each other in the vertical direction. They are placed next to each other. Additionally, approximately the entire right outer surface of the insulating member 14 is covered by the right wall 22C of the upper element shield portion 22 and the right wall 32C of the lower element shield portion 32.

Additionally, the upper edge of the middle portion of the left wall 32B of the lower child shield portion 32 in the front-back direction is in contact with, or is very close to, the rear left edge portion of the upper wall 22A of the upper child shield portion 22. . Likewise, the upper edge of the middle portion of the right wall 32C of the lower child shield portion 32 in the front-back direction is in contact with, or very close to, the rear right edge portion of the upper wall 22A of the upper child shield portion 22. there is.

Additionally, the left wall 32B and the right wall 32C of the lower end shield portion 32 each extend rearward than the rear end of the insulating member 14. As shown in FIGS. 5(A) and 5(B), the rear portion of the left wall 32B of the lower element shield portion 32 extended rearward in this way is the inner wire shield portion 25 of the upper shield member 21. ) covers the entire area from the left room. Similarly, the rear portion of the right wall 32C of the lower end shield portion 32 covers the entire inner wire shield portion 25 of the upper shield member 21 from the right side.

Additionally, as shown in FIG. 4 , locking holes 33 are formed in the front-back direction middle portion of the left wall 32B of the lower end shield portion 32 and the front-back middle portion of the right wall 32C, respectively. These two locking holes 33 are respectively caught by the two locking convex portions 19 formed at the rear of the left outer surface and the rear of the right outer surface of the insulating member 14, so that, as shown in FIG. 3, the lower end shield. Part 32 is coupled with insulating member 14.

In addition, a fixed convex portion 34 protruding to the left is formed at the rear of the left wall 32B of the lower element shield portion 32, and a fixed convex portion 34 is formed at the rear of the right wall 32C of the lower element shield portion 32 to protrude to the right. A fixed convex portion 34 is formed. The shield member 31 is fixed to the plug housing 41 by engaging the fixing convex portions 34 on the fixing pieces 43 formed on the left and right walls of the cylinder portion 42 of the plug housing 41, respectively.

The external wire shield portion 36 has a function of shielding the exposed portions of the two insulated wires 3. As shown in FIG. 3, the outer wire shield portion 36 covers the outer peripheral side of the inner wire shield portion 25 surrounding the exposed portions of the two insulated wires 3. That is, the outer wire shield portion 36 covers the portion surrounded by the inner wire shield portion 25 in the exposed portion of the two insulated wires 3 from the outer peripheral side of the inner wire shield portion 25. . As a result, the exposed portions of the two insulated wires 3 are doubly shielded by the inner wire shield portion 25 and the outer wire shield portion 36. The outer wire shield portion 36 is disposed behind the lower end shield portion 32. In addition, the outer wire shield portion 36 is coupled to the rear end of the lower end shield portion 32 through a connection portion 35. The connection portion 35 is formed in a plate shape, extends rearward while slanting upward from the rear end of the lower end shield portion 32, and is coupled to the front end of the outer wire shield portion 36.

In this embodiment, the outer wire shield portion 36 surrounds the outer peripheral side of the inner wire shield portion 25 surrounding the exposed portions of the two insulated wires 3. The outer wire shield part 36 is a barrel for caulking the inner wire shield part 25. The external wire shield portion 36 has a barrel base 36A and two barrel pieces 36B. As shown in Fig. 4, the barrel base 36A extends rearward from the rear end of the connecting portion 35. Before the plug 8 is assembled, of the two barrel pieces 36B, one barrel piece 36B extends to the left while inclining upward from the left edge of the barrel base 36A. The other barrel piece 36B extends to the right while sloping upward from the right edge of the barrel base 36A. When the plug 8 is assembled, the two barrel pieces 36B are bent to surround the outer peripheral side of the inner wire shield portion 25. Thereby, the inner wire shield portion 25 is caulked by the two barrel pieces 36B.

The shield connection portion 38 has the function of electrically connecting the shield member 31 to the shield 4 of the cable 2, and the connection piece 27 of the outer shield member 21 is in contact with the shield 4. It has the function of maintaining the state and fixing the cable (2) to the plug (8). The shield connection portion 38 is disposed behind the external wire shield portion 36. Additionally, the shield connection portion 38 is coupled to the rear end of the outer wire shield portion 36 through the connection portion 37. The connecting portion 37 is formed in a plate shape, extends rearward while slanting downward from the rear end of the outer wire shield portion 36, and is coupled to the front end of the shield connecting portion 38.

The shield connection portion 38 is a barrel for caulking the shield 4 and sheath 5 of the cable 2 and the connection piece 27 in contact with the shield 4. The shield connection portion 38 has a barrel base 38A and two barrel pieces 38B. As shown in Fig. 4, the barrel base 38A extends rearward from the rear end of the connecting portion 37. Before the plug 8 is assembled, of the two barrel pieces 38B, one barrel piece 38B extends to the left while inclining upward from the left edge of the barrel base 38A. The other barrel piece 38B extends to the right while sloping upward from the right edge of the barrel base 38A. When the plug 8 is assembled, the two barrel pieces 38B are bent to surround the shield 4, the connecting piece 27, and the sheath 5. Thereby, the shield 4, the connection piece 27, and the sheath 5 are caulked by the two barrel pieces 38B.

(receptacle)

Fig. 8 shows the receptacle 51 as seen from the left front view. Fig. 9 shows the receptacle 51 viewed from the left, rear, and bottom. Fig. 10 shows the disassembled state of the receptacle 51. FIG. 11 shows a state in which the vertical middle portion of the receptacle 51 is cut in a plane widening in the front-back and left-right directions, and the cross section of the cut receptacle 51 is viewed from above.

The receptacle 51 includes two receptacle terminals 52, a connection member 55, a receptacle housing 58, and a shell 61.

As shown in FIG. 10, the receptacle housing 58 is formed into a square pillar shape when viewed as a whole from an insulating material such as resin. The receptacle housing 58 is formed with a fitting hole 59 into which the fitting portion 9 of the plug 8 is fitted. The fitting hole 59 is open at the front of the receptacle housing 58 and extends rearward. The plug (8) and the receptacle (51) are made so that the entirety of the plug (8) and the entirety of the receptacle (51) face each other, and the fitting portion (9) of the plug (8) is fitted into the receptacle housing (58). It is connected by fitting into the ball 59. As a result, when the fitting portion 9 is fitted into the fitting hole 59, the inner surface on the left side of the fitting hole 59 faces the outer surface on the right side of the fitting portion 9, and The right inner surface of the ball 59 faces the left outer surface of the fitting portion 9.

Additionally, in the receptacle housing 58, a penetrating portion 60, which is a hole or notch penetrating the portion, is formed on the left portion of the outer peripheral portion of the fitting hole 59. The penetrating portion 60 on the left is a portion of the plug 8 in the receptacle housing 58 when the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51. A portion corresponding to the boundary between the right wall 22C of the upper child shield portion 22 and the right wall 32C of the lower child shield portion 32 of the plug 8 (hereinafter referred to as the “left boundary corresponding portion”). ) is placed in . In addition, the same penetrating portion 60 is formed on the right side of the outer peripheral portion of the fitting hole 59. The penetrating portion 60 on the right side is located in the receptacle housing 58 when the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51. A part corresponding to the boundary between the left wall 22B of the upper child shield part 22 and the left wall 32B of the lower child shield part 32 of the plug 8 (hereinafter, this is referred to as the “right border corresponding part”). ) is placed in . Additionally, the receptacle housing 58 is formed with holes, grooves, or locking structures for attaching each receptacle terminal 52 and the connecting member 55 to the receptacle housing 58. Additionally, on the outer peripheral side of the receptacle housing 58, a locking structure for attaching the shell 61 to the receptacle housing 58 is formed.

As shown in FIG. 11, the two receptacle terminals 52 are mounted on the receptacle housing 58 so as to be aligned in the left and right directions. Each receptacle terminal 52 is formed of a conductive material such as metal. Each receptacle terminal 52 has a contact portion 53 and a circuit connection portion 54. The contact portion 53 is formed in the shape of a pin extending in the front-back direction. The front end portion of the contact portion 53 is located within the fitting hole 59. The contact portion 53 is in contact with the contact portion 11 of the plug terminal 10 of the plug 8. The circuit connection portion 54 extends downward from the rear end of the contact portion 53, then bends, and then extends rearward. The circuit connection portion 54 is connected to a pad or the like for inputting or outputting a signal in a circuit formed on the mounting surface 6A of the substrate 6.

The connection member 55 is mounted on the lower part of the receptacle housing 58 so that its one end 56 is located within the fitting hole 59 . The connection member 55 is formed of a conductive material such as metal. One end 56 of the connecting member 55 contacts the lower surface of the shield member 31 of the plug 8 when the plug 8 is fitted into the receptacle 51. Additionally, the other end 57 of the connecting member 55 is connected to the ground portion of the substrate 6.

As shown in FIGS. 8 and 9, the shell 61 covers the outer peripheral side and the rear of the receptacle housing 58. The shell 61 is formed by press working a plate made of a conductive material such as metal. The shell 61 has a function of shielding the two receptacle terminals 52 and the fitting portion 9 of the plug 8 fitted into the fitting hole 59. In addition, the shell 61, when the plug 8 is fitted into the receptacle 51, connects the main shield member 21 and the shield member 31 of the plug 8 to the ground portion of the substrate 6. It has the ability to connect.

The shell 61 includes an upper wall 61A that covers the upper outer surface of the receptacle housing 58, a left wall 61B that covers the left outer surface of the receptacle housing 58, and a right wall that covers the right outer surface of the receptacle housing 58. (61C), and a rear wall (61D) covering the rear side of the receptacle housing (58).

Additionally, an upper contact piece 62, a lower contact piece 63, a ground connection portion 64, and two substrate connection portions 65 are formed on the left wall 61B of the shell 61. These are formed integrally with the left wall 61B of the shell 61.

The upper contact piece 62 and the lower contact piece 63 formed on the left wall 61B of the shell 61 are arranged at a portion corresponding to the left boundary of the left wall 61B of the shell 61. The positions of these upper contact pieces 62 and lower contact pieces 63 correspond to the positions of the penetrating portion 60 on the left side of the receptacle housing 58. Moreover, these upper contact pieces 62 and lower contact pieces 63 are arranged to approach each other and to be adjacent to each other in the vertical direction. Additionally, these upper contact pieces 62 and lower contact pieces 63 have substantially the same shape. 1 , when the receptacle 51 is viewed from the left side, the upper contact piece 62 and the lower contact piece 63 formed on the left wall 61B of the shell 61 each extend in a straight line in the front-back direction. , and are also extended parallel to each other. 8 and 11, the upper contact piece 62 and the lower contact piece 63 formed on the left wall 61B of the shell 61 are each inclined to the right from the shell 61. . These upper contact pieces 62 and lower contact pieces 63 enter the fitting hole 59 from the left wall 61B of the shell 61 through the penetration portion 60 on the left side of the receptacle housing 58. I'm doing it.

When the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51, the front end of the upper contact piece 62 formed on the left wall 61B of the shell 61 is, It contacts the outer surface of the right wall 22C of the upper shield portion 22 of the outer shield member 21 of the plug 8. Additionally, when the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51, the front end of the lower contact piece 63 formed on the left wall 61B of the shell 61 The portion contacts the outer surface of the right wall 32C of the lower end shield portion 32 of the shield member 31 of the plug 8.

Additionally, these upper contact pieces 62 and lower contact pieces 63 are each formed in the shape of an elongated plate and have spring properties. When the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51, the front end of the upper contact piece 62 and the front end of the lower contact piece 63 are connected to the plug. The upper contact piece 62 and the lower contact piece 63 contact the right wall 22C of the upper child shield portion 22 and the right wall 32C of the lower child shield portion 32 of (8), respectively, and are pushed to the left. ) are each elastically deformed. Accordingly, the front end portion of the upper contact piece 62 and the front end portion of the lower contact piece 63 are connected to the right wall 22C of the upper end shield portion 22 and the right wall of the lower end shield portion 32 of the plug 8 ( 32C) are in strong contact with each other.

In addition, in the plug 8, when the thickness of the plate forming the upper shield member 21 and the thickness of the plate forming the shield member 31 are equal to each other, the upper shield portion 22 The positions of the outer surface of the right wall 22C and the outer surface of the right wall 32C of the lower end shield portion 32 in the left and right directions are the same. On the other hand, when the thickness of the plate forming the upper shield member 21 and the thickness of the plate forming the shield member 31 are different from each other, the outer surface of the right wall 22C of the upper shield portion 22 and the positions of the outer surface of the right wall 32C of the lower end shield portion 32 in the left and right directions are offset from each other. In this case, a step is formed at the boundary between the outer surface of the right wall 22C and the outer surface of the right wall 32C. In this way, even when the positions of the outer surface of the right wall 22C and the outer surface of the right wall 32C in the left and right directions are shifted from each other, the upper contact piece 62 and the lower contact piece 63 each have spring properties. , the front end portion of the upper contact piece 62 and the front end portion of the lower contact piece 63 reliably contact the right wall 22C and the right wall 32C, respectively.

Additionally, the ground connection portion 64 formed on the left wall 61B of the shell 61 is disposed at the middle portion of the lower end of the left wall 61B of the shell 61 in the front-back direction, as shown in FIG. 9 . In addition, the ground connection portion 64 formed on the left wall 61B of the shell 61 is directly below, that is, perpendicular to, the upper contact piece 62 and the lower contact piece 63 formed on the left wall 61B of the shell 61. It is placed in the lower direction. Additionally, this ground connection portion 64 is extended downward from the middle portion in the front-back direction at the lower end of the left wall 61B of the shell 61, then bent, and then extended to the right.

The ground connection portion 64 formed on the left wall 61B of the shell 61 is connected to the ground portion of the substrate 6 by solder. Since the lower end portion of the ground connection portion 64 extends to the right, the outer surface of the lower end portion of the ground connection portion 64 faces the mounting surface 6A of the substrate 6. Therefore, by forming a pad with a large area as a ground portion on the mounting surface 6A of the substrate 6, the connection area between the ground connection portion 64 and the ground portion of the substrate 6 can be increased.

Additionally, in the left wall 61B of the shell 61, the two board connection portions 65 are disposed at the front and rear portions of the lower end of the left wall 61B of the shell 61, respectively. These board connection portions 65 protrude downward from the lower end of the left wall 61B of the shell 61. These board connection portions 65 are inserted into through holes formed in the board 6. Connected by solder. In this embodiment, the land around the through hole of the substrate 6 is electrically connected to the ground portion of the substrate 6. Therefore, by connecting the substrate connecting portion 65 to the through hole, the substrate connecting portion 65 is connected to the ground portion of the substrate 6.

The right wall 61C of the shell 61 also has an upper contact piece 62, a lower contact piece 63, a ground connection portion 64, and two substrate connection portions 65, similarly to the left wall 61B of the shell 61. ) is formed.

(Action when fitting)

When connecting the plug (8) and the receptacle (51), as shown in FIG. 1, the front of the plug (8) and the front of the receptacle (51) face each other, and the fitting portion (9) of the plug (8) is inserted into the fitting hole 59 of the receptacle 51 from the front of the receptacle 51, so that the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51. When the fitting portion (9) of the plug (8) is fitted into the fitting hole (59) of the receptacle (51), the contact portion (11) of the two plug terminals (10) of the plug (8) and the receptacle The contact portions 53 of the two receptacle terminals 52 of 51 each contact each other. As a result, the conductor of each insulated wire 3 of the cable 2 is connected to the circuit of the board 6 (for example, to input or output a signal) through the plug terminal 10 and the receptacle terminal 52. It is electrically connected to a pad formed on the mounting surface 6A.

Also, when the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51, the upper contact piece formed on the left wall 61B of the shell 61 of the receptacle 51 (62) A lower contact piece 63 is in contact with the outer surface of the right wall 22C of the upper shield portion 22 of the plug 8, and is formed on the left wall 61B of the shell 61 of the receptacle 51. The lower end of the plug (8) contacts the outer surface of the right wall (32C) of the shield portion (32). Also, at this time, the upper contact piece 62 formed on the right wall 61C of the shell 61 of the receptacle 51 contacts the outer surface of the left wall 22B of the upper end shield portion 22 of the plug 8. , the lower contact piece 63 formed on the right wall 61C of the shell 61 of the receptacle 51 contacts the outer surface of the left wall 32B of the lower end shield portion 32 of the plug 8. Also, at this time, one end 56 of the connecting member 55 mounted on the receptacle housing 58 of the receptacle 51 is on the outer surface of the lower wall 32A of the lower end shield portion 32 of the plug 8. Contact. Accordingly, the external shield member 21 of the plug 8 is connected to the substrate 6 through the upper contact piece 62 of the receptacle 51, the shell 61, the ground connection portion 64, and the substrate connection portion 65. It is electrically connected to the ground part of. Additionally, the shield member 31 of the plug 8 is connected to the substrate 6 through the lower contact piece 63 of the receptacle 51, the shell 61, the ground connection portion 64, and the substrate connection portion 65. It is electrically connected to the ground part of. Additionally, the shield member 31 is electrically connected to the ground portion of the substrate 6 also by the connection member 55.

In this way, in the connector device 1, when the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51, the male guard member 21 of the plug 8 ) is connected to the shell 61 of the receptacle 51 through the upper contact piece 62, and the shield member 31 of the plug 8 is connected to the shell 61 of the receptacle 51 through the lower contact piece 63. 61), when connecting the plug 8 and the receptacle 51, the length of the electric path from the main shield member 21 to the ground portion of the substrate 6 through the shell 61 and the The lengths of the electric paths from the cover member 31 through the shell 61 to the ground portion of the substrate 6 can be made equal to each other, and each of these electric paths can be shortened.

That is, if, on each of the left wall 61B and the right wall 61C of the shell 61 of the receptacle 51, the upper contact piece 62 and the lower shield portion 32 contact the upper shield portion 22. ) It is assumed that only the lower contact piece 63 is formed among the lower contact pieces 63 that contact the . In that case, when the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51, the shield member 31 of the plug 8 is connected to the lower contact piece 63. While it is directly connected to the shell 61 through, the upper shield member 21 of the plug 8 is connected to the shell 61 through the shield member 31 and the lower contact piece 63. . In this case, an electric path is formed between the upper shield member 21 and the shell 61 from the upper shield member 21 to the shell 61 via the shield member 31. Therefore, the length of the electric path from the shield member 21 through the shell 61 to the ground portion of the substrate 6 is the length of the electric path from the shield member 31 through the shell 61 to the ground portion of the substrate 6. It is longer compared to the length of the electrical path leading to the electrical path through the shell 61 between the shield member 21 and the ground portion of the substrate 6, and the electrical path through the shell 61 between the shield member 31 and the ground portion of the substrate 6. It becomes difficult to shorten the electrical path through the shell 61 between parts. When the electrical path through the shell 61 between the outer shield member 21 and the ground portion of the substrate 6 becomes longer, the inductance of the electric path increases, so that the potential of the outer shield member 21 increases with the shield member ( It becomes unstable compared to the potential of 31), and there is a risk that the shielding effect exerted by the main shield member 21 and the shield member 31 may be reduced. On the other hand, in the connector device 1 of the present embodiment, each of the left wall 61B and the right wall 61C of the shell 61 of the receptacle 51 has an upper contact with the upper end shield portion 22. Since the lower contact piece 63 is formed in contact with the piece 62 and the lower end shield portion 32, the fitting portion 9 of the plug 8 is inserted into the fitting hole 59 of the receptacle 51. When fitted, the shield member 31 is connected to the shell 61 directly through the lower contact piece 63, and the upper shield member 21 is directly connected to the shell 61 through the upper contact piece 62. ) is connected to. Accordingly, the length of the electrical path through the shell 61 between the shield member 21 and the ground portion of the substrate 6, and the length of the shell 61 between the shield member 31 and the ground portion of the substrate 6 The lengths of the electrical paths through become equal to each other, and as a result, the electrical paths through the shell 61 between the shield member 21 and the ground portion of the substrate 6 are the shield member 31 and the substrate 6. ) is shortened in the same way as the electric path through the shell 61 between the ground portions of the The potential can be stabilized.

In addition, in the receptacle 51, the upper contact piece 62, the shell 61, and the ground connection portion 64 (or substrate connection portion 65) are specific examples of the “first conductive portion”, and the lower contact piece ( 63), shell 61, and ground connection portion 64 (or substrate connection portion 65) are specific examples of the “second conductive portion.”

12 simplifies the receptacle 51 in the connector device 1 in FIG. 1 and shows it with a two-dot chain line, showing the upper contact piece ( 62) A lower contact piece 63 formed on the left wall 61B of the shell 61 of the receptacle 51 contacts the outer surface of the right wall 22C of the upper shield portion 22 of the plug 8. It is shown in contact with the outer surface of the right wall 32C of the lower end shield portion 32 of (8).

As shown in Fig. 12, in the plug 8, the right wall 22C of the upper element shield portion 22 and the right wall 32C of the lower element shield portion 32 are on the outer surface of the right side of the insulating member 14. They approach each other on the top (right side of the outer surface) and are arranged to be adjacent to each other in the vertical direction. Additionally, in the receptacle 51, the upper contact piece 62 and the lower contact piece 63 formed on the left wall 61B of the shell 61 are on the left wall 61B of the shell 61, as described above. In the left border corresponding portion in , they are arranged to approach each other and to be adjacent to each other in the vertical direction. Then, when the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51, the upper contact piece 62 formed on the left wall 61B of the shell 61 is at the upper end. The lower contact piece 63 formed on the left wall 61B of the shell 61 contacts the right wall 32C of the lower shield portion 32. In this way, in the connector device 1, the connection point between the shield member 21 and the left wall 61B of the shell 61 and the connection point between the shield member 31 and the left wall 61B of the shell 61 The points are not dispersed on the left wall 61B of the shell 61, but are gathered in a portion of the left wall 61B, specifically, approximately in the center of the left wall 61B when viewed from the left side of the receptacle 51. In addition, in the connector device 1, a ground connection portion 64 is provided immediately below (vertically lower) the upper contact piece 62 and the lower contact piece 63 on the left wall 61B of the shell 61. It is placed. Likewise, the connection point between the right wall 61C of the shield member 21 and the shell 61, and the connection point between the right wall 61C of the shield member 31 and the shell 61 are part of the right wall 61C. (approximately the central portion of the right wall 61C when viewed from the right side of the receptacle 51), and also the upper contact piece 62 and the lower contact piece 63 on the right wall 61C of the shell 61. A ground connection portion 64 is disposed immediately below. With this configuration of the connector device 1, an electrical path through the shell 61 between the shield member 21 and the ground portion of the substrate 6, and an electrical path between the shield member 31 and the substrate 6 are formed. The electrical paths through the shell 61 between the ground portions can be made uniform, and these electrical paths can be shortened. Thereby, the increase in inductance in both of these electric paths can be suppressed, and the electric potential of both the main shield member 21 and the shield member 31 can be stabilized.

In addition, in a state where the fitting portion 9 of the plug 8 is fitted into the fitting hole 59 of the receptacle 51, the straight line distance between each part of the outer shield member 21 and the ground portion of the substrate 6 is When considered, among these straight-line distances, the straight-line distance between the right wall 22C (or left wall 22B) of the upper shield portion 22 and the ground portion of the substrate 6 is the shortest. Therefore, by connecting the right wall 22C (or left wall 22B) of the upper shield portion 22 and the ground portion of the substrate 6 through the upper contact piece 62 and the shell 61, the upper shield member 21 ) and the ground portion of the board (6) can be shortened.

As described above, the plug 8, which is an embodiment of the connector of the present invention, has the exposed portion of the two insulated wires 3 disposed in the plug housing 41, and at least one of these two insulated wires 3 It has an inner wire shield portion (25) surrounding the outer peripheral surface of the exposed portion of the two insulated wires (3) while contacting or very close to it. According to this inner wire shield portion 25, a structure equivalent to the structure in which the two insulated wires 3 are surrounded by the shield 4 within the cable 2 can be formed within the plug housing 41. . Additionally, since the exposed portions of the two insulated wires 3 are within the plug housing 41, bending can be sufficiently suppressed. Accordingly, the characteristic impedance of the plug 8 can be matched to, or very close to, the characteristic impedance of the cable 2. According to the plug 8 of this embodiment, compared with the conventional connector described in Japanese Patent Laid-Open No. 2009-37826, the characteristic impedance of the plug 8 can be brought close to the characteristic impedance of the cable 2. I think so. As a result, reflection of the high-frequency signal transmitted through the plug 8 can be suppressed, and the transmission efficiency of the high-frequency signal can be improved.

Additionally, the inner wire shield portion 25 is a barrel for bundling and caulking the exposed portions of the two insulated wires 3. With this configuration, the two insulated wires 3 can be brought into close contact with each other while surrounding the exposed portions of the two insulated wires 3, and the insulated wire 3 and the inner wire shield portion 25 can be connected to each other. It can be adhered tightly. This makes it easy to match the characteristic impedance of the plug 8 to the characteristic impedance of the cable 2, or to make the characteristic impedance of the plug 8 closer to the characteristic impedance of the cable 2.

In addition, the workability of the assembly work of the plug 8 can be improved by using the inner wire shield portion 25 as a barrel. If copper tape is applied to the exposed portions of the two insulated wires (3) to bind them and shield the two insulated wires (3), copper tape is applied to the exposed portions of the two insulated wires (3). Since the work of winding the tape is complicated, it is difficult to improve the workability of the assembly work of the plug 8. In contrast, according to the plug 8 of the present embodiment, when assembling the plug 8, the exposed portions of the two insulated wires 3 are disposed between the barrel pieces 25B of the inner wire shield portion 25. By caulking the inner wire shield portion 25 using a caulking jig, etc., a shield structure surrounding the exposed portions of the two insulated wires 3 can be easily formed by binding them with the inner wire shield portion 25. Therefore, the workability of the assembly work of the plug 8 can be improved.

Additionally, the length L of the inner wire shield portion 25 in the front-back direction is the length of the portion from the front end position of the shield 4 to the rear end position of the plug terminal 10 in the exposed portion of the insulated wire 3. It is more than one-half of (M). Therefore, the exposed portions of the two insulated wires 3 can be widely surrounded in the front-back direction by the inner wire shield portion 25. This makes it easy to match the characteristic impedance of the plug 8 to the characteristic impedance of the cable 2, or to make the characteristic impedance of the plug 8 closer to the characteristic impedance of the cable 2.

Additionally, the plug 8 of the present embodiment has an outer wire shield portion 36 that covers the inner wire shield portion 25 surrounding the exposed portions of the two insulated wires 3. With this configuration, the exposed portions of the two insulated wires 3 can be double shielded by the inner wire shield portion 25 and the outer wire shield portion 36. As a result, the shielding effect of the main shield member 21 and the shield member 31 with respect to the insulated wire 3 in the plug housing 41 can be increased.

Additionally, the outer wire shield portion 36 is a barrel for caulking the inner wire shield portion 25. As a result, the shield effect can be increased. In addition, the outer circumferential side of the inner wire shield part 25 can be supported by the outer wire shield part 36, and the exposed portions of the two insulated wires 3 are surrounded by the inner wire shield part 25. can be maintained over a long period of time. Moreover, even when the cable 2 is twisted with respect to the plug 8, the exposed portions of the two insulated wires 3 can be maintained surrounded by the inner wire shield portion 25.

Moreover, in the connector device (1) of the embodiment of the present invention, when the fitting portion (9) of the plug (8) is fitted into the fitting hole (59) of the receptacle (51), the The upper shield member 21 is connected to the shell 61 of the receptacle 51 through the upper contact piece 62, and the shield member 31 of the plug 8 is connected to the receptacle through the lower contact piece 63. It is connected to shell (61) of (51). Additionally, the shell 61 is connected to the ground portion of the substrate 6. With this configuration, when connecting the plug 8 and the receptacle 51, the length of the electrical path through the shell 61 between the main shield member 21 and the ground portion of the substrate 6 and the shield The lengths of the electric paths through the shell 61 between the member 31 and the ground portion of the substrate 6 can be made equal to each other, and each of these electric paths can be shortened. Thereby, an increase in the inductance of both the two electric paths can be suppressed, and the potentials of both the main shield member 21 and the shield member 31 can be stabilized. Therefore, like the plug 8 of this embodiment, the member forming the structure for shielding the exposed portion of each plug terminal 10 and each insulated wire 3 includes the main shield member 21 and the shield member ( Even when divided into 31), the effect of shielding the exposed portions of each plug terminal 10 and each insulated wire 3 can be prevented from being reduced.

In addition, in the connector device 1 of this embodiment, the point where the upper shield member 21 and the shell 61 are connected through the upper contact piece 62, and the shield member 31 and the shell 61 Hereinafter, the points connected via the lower contact piece 63 are gathered on a part of the left wall 61B (or right wall 61C) of the shell 61. Additionally, a ground connection portion 64 is disposed immediately below the upper contact piece 62 and the lower contact piece 63 on the left wall 61B (or right wall 61C) of the shell 61. With this configuration, an electric path through the shell 61 between the shield member 21 and the ground portion of the substrate 6 and the shell 61 between the shield member 31 and the ground portion of the substrate 6 are formed. ), the electrical paths through them can be equalized, and their electrical paths can be shortened. Thereby, the electric potential of both the upper shield member 21 and the shield member 31 can be stabilized, and the shielding effect of the upper shield member 21 and the shield member 31 can be improved.

In addition, the outer wire shield portion 36 of the shield member 31 in the plug 8 of the above embodiment is a barrel for caulking the inner wire shield portion 25. However, like the plug 71 shown in FIGS. 13(A) and 13(B), the outer wire shield portion 73 of the shield member 72 has a lower wall, a left wall, and a right wall, and the inner wire shield has a lower wall, a left wall, and a right wall. It may be configured to cover the part 25 through space.

In addition, in the plug 8 of the above embodiment, an inner wire shield portion 25 that caulks and surrounds the exposed portions of the two insulated wires 3 is formed on the outer shield member 21, and the inner wire shield portion ( An external wire shield portion 36 that caulks and surrounds 25) is formed on the shield member 31. However, as in the plug 81 shown in FIGS. 14(A) and 14(B), the inner wire shield portion 85 surrounding the exposed portions of the two insulated wires 3 is caulked and the shield member 84 is formed. The outer wire shield part 83 may be formed on the outer wire shield member 82 by caulking the inner wire shield part 85.

In addition, as in the plug 91 shown in FIGS. 15(A) and 15(B), the inner wire shield portion 95 surrounding the exposed portions of the two insulated wires 3 by caulking is formed with the shield member 94. An outer wire shield part 93 that covers the inner wire shield part 95 through the space may be formed on the outer shield member 92.

In addition, in the above embodiment, the exposed portions of the two insulated wires 3 are bundled and caulked by the inner wire shield portion 25 (85, 95), so that the two insulated wires 3 are present in the cable 2. A structure equivalent to the structure covered by the shield 4 is formed within the plug 8. However, for example, by bending the inner wire shield portion into a small diameter having a diameter equal to the inner diameter of the shield 4 by press processing or the like, the two insulated wires 3 within the cable 2 are connected to the shield 4. A structure equivalent to the structure covered may be formed within the plug 8.

In addition, the receptacle 51 in the connector device 1 of the above embodiment is a right-angle receptacle in which the connector fitting direction and the board mounting direction are orthogonal, but the receptacle in the connector device of the present invention has a connector fitting direction. It may be a straight type receptacle in which the alignment direction and board mounting direction are the same.

In addition, the present invention is not limited to a connector mounted on a shielded twisted pair cable having two insulated wires (3) twisted together, but a shielded twisted pair cable having three or more insulated wires (3) twisted together. It can also be applied to connectors mounted on cables, or multi-core cables with shields having a plurality of untwisted insulated wires.

In addition, the present invention may be appropriately changed without departing from the gist or idea of the invention as can be read from the claims and the entire specification, and connectors, connectors with cables, and connector devices accompanying such changes can also be modified. It is included in the technical idea of the present invention.

1: Connector device
2: cable
3: insulated wire
4: Shield
6: substrate
8, 71, 81, 91: Plug (connector)
9: Fitting part
10: Plug terminal (terminal)
14: insulation member
21, 82, 92: Upper shield member (first shield member)
22: Upper terminal shield portion (first terminal shield portion)
25, 85, 95: inner wire shield part (1st wire shield part)
27: Connection section (first shield connection section)
31, 72, 84, 94: Shield member (second shield member)
32: Lower terminal shield portion (second terminal shield portion)
36, 73, 83, 93: External wire shield part (second wire shield part)
38: Shield connection part
51: Receptacle (relative connector)
61: Shell (first conductive part, second conductive part)
62: Upper contact piece (first conductive part)
63: Lower contact piece (second conductive portion)
64: Ground connection part (first conductive part, second conductive part)
65: Board connection portion (first conductive portion, second conductive portion)

Claims (6)

A connector mounted on a cable having a plurality of insulated wires and a shield covering the plurality of insulated wires,
A plurality of terminals to which the plurality of insulated wires are respectively connected,
an insulating member covering the outer circumference of the plurality of terminals;
It has a first shield member and a second shield member each formed of a conductive material,
The first shield member is,
a first terminal shield portion covering an outer peripheral portion of the insulating member from one side;
a first wire shield portion covering an exposed portion of the plurality of insulated wires exposed from the shield;
Provided with a first shield connection portion connected to the shield,
The second shield member,
a second terminal shield portion covering the outer peripheral portion of the insulating member from the other side;
a second wire shield portion covering the exposed portion of the plurality of insulated wires;
Provided with a second shield connection portion connected to the shield,
One of the first wire shield part and the second wire shield part contacts the exposed portion of the plurality of insulated wires with an outer peripheral surface of the exposed portion of at least one insulated wire among the plurality of insulated wires. Surround it or get very close to it,
A connector characterized in that the other of the first wire shield portion and the second wire shield portion covers the one wire shield portion surrounding the exposed portion of the plurality of insulated wires. According to claim 1,
A connector characterized in that the one wire shield portion is a barrel for bundling and caulking the exposed portions of the plurality of insulated wires. According to claim 1,
A connector characterized in that the other wire shield portion is a barrel for caulking the one wire shield portion surrounding the exposed portion of the plurality of insulated wires. According to claim 1,
A connector characterized in that the length of the one wire shield portion in the front-back direction is at least one half of the length of the exposed portion of the plurality of insulated wires from the front end position of the shield to the rear end position of the terminal. . A connector with a cable including a plurality of insulated wires and a shield covering the plurality of insulated wires, and the connector according to any one of claims 1 to 4. A connector device comprising the connector according to any one of claims 1 to 4, and a mating connector mounted on a board and fitted with the connector,
In the counterpart connector,
a first conductive portion that contacts the first terminal shield portion when the connector is fitted into the mating connector and connects the first terminal shield portion to a ground portion formed on a substrate;
A connector device characterized in that, when the connector is fitted into the mating connector, a second conductive portion is formed that contacts the second terminal shield portion and connects the second terminal shield portion to a ground portion formed on a substrate.

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