This application claims benefit of priority to Japanese Patent Application Nos. 2014-116840 filed Jun. 5, 2014, and 2015-080716 filed Apr. 10, 2015, the entire content of each of which is incorporated herein by reference.
The present disclosure relates to connector sets and connectors, and particularly relates to connector sets and connectors used to transmit high-frequency signals.
A first connector in a board-to-board connector disclosed in Japanese Unexamined Patent Application Publication No. 2012-79684 is known as an example of a past disclosure related to connector sets. The first connector includes a first housing, a plurality of first terminals, and two first reinforcing fittings. The first housing is manufactured from a resin, for example, and is a plate-shaped member having a rectangular shape. The plurality of first terminals are provided along the two longer sides of the first housing. The two first reinforcing fittings are provided at both ends of the first housing in the longer direction thereof.
The stated first connector is used by being coupled to a second connector. The first terminals are connected to a signal potential or a ground potential, and the first reinforcing fittings are connected to the ground potential.
Incidentally, in the first connector disclosed in Japanese Unexamined Patent Application Publication No. 2012-79684, the first reinforcing fittings are only provided at both ends of the first housing in the longer direction thereof. Accordingly, in the first connector disclosed in Japanese Unexamined Patent Application Publication No. 2012-79684, there has been a problem in noise-resistance properties.
Accordingly, it is an object of the present disclosure to provide a connector set and a connector capable of improving noise-resistance properties.
A connector set according to an aspect of the present disclosure is a connector set including a first connector and a second connector. The first connector has a plurality of first connection terminals, each having a first contact portion, and a first anchoring terminal connected to a ground potential. The second connector has a plurality of second connection terminals, each having a second contact portion, and a second anchoring terminal connected to a ground potential. When the first connector and the second connector are coupled, the plurality of first connection terminals and the plurality of second connection terminals respectively make contact at the first contact portions and the second contact portions. The first anchoring terminal and the second anchoring terminal make contact with each other to maintain the coupling between the first connector and the second connector, and have, when viewed in plan view from a first direction, a ring shape that encircles a periphery of the first contact portions and the second contact portions when the first connector and the second connector are coupled.
A first connector according to another aspect of the present disclosure is a first connector that couples with a second connector having a plurality of second connection terminals and a second anchoring terminal. The first connector includes a plurality of first connection terminals, and a first anchoring terminal that makes contact with the second anchoring terminal in order to maintain the coupling between the first connector and the second connector and that is connected to a ground potential. When the first connector and the second connector are coupled, the plurality of first connection terminals make contact with the respective second connection terminals at first contact portions. When viewed in plan view from the first direction, the first anchoring terminal has portions that follow the four sides of a rectangular ring that encircles the plurality of first contact portions, and has a shape in which a part of the rectangular ring is cut out.
According to the present disclosure, noise-resistance properties can be improved.
Other features, elements, characteristics and advantages of the present disclosure will become more apparent from the following detailed description of preferred embodiments of the present disclosure with reference to the attached drawings.
A male connector, a female connector, and a connector set according to an embodiment of the present disclosure will be described hereinafter.
The configuration of a female connector (a first connector) in the connector set will be described first with reference to the drawings.
In the following, a direction of a center axis of the substantially ring-shaped anchoring terminal 12 shown in
The female connector 10 is mounted on a circuit board, a flexible wire, or the like, for example, and includes the anchoring terminal 12, the connection terminals 14a-14c, and the insulative member 16, as illustrated in
The anchoring terminal 12 is a conductor that is connected to a ground potential, and as illustrated in
The anchoring terminal 12 includes a main body portion 21, projection portions 24a and 24b, and a connecting portion 26. The main body portion 21 has a lower portion 20 and upper portions 22a-22d. The lower portion 20 is a substantially band-shaped conductor that encircles the perimeter of the center axis that extends in the up-down direction, and when viewed in plan view from above, has a shape in which part of a substantially rectangular ring has a part thereof cut out. In the present embodiment, the lower portion 20 has a shape in which part of the front-side longer side is cut out. However, the lower portion 20 still has a right-side shorter side, a left-side shorter side, a rear-side longer side, and part of the front-side longer side. In other words, the lower portion 20 has portions that follow the four sides of the substantially rectangular ring shape. In addition, the four corners of the lower portion 20 are rounded.
The upper portion 22a is connected to the top of the rear-left corner of the lower portion 20, and configures an upper end portion of the main body portion 21. When viewed in plan view from above, the upper portion 22a is substantially L-shaped. Note that the corner of the upper portion 22a is rounded. An inner peripheral surface of the upper portion 22a includes a surface S11 that faces the upper-front, and a surface S12 that faces the upper-right. Furthermore, the surface S11 and the surface S12 configure a convex curved surface.
Meanwhile, the surface S11 and the surface S12 project toward an inner side portion of the substantially rectangular ring shape, relative to the lower portion 20. As a result, a protruding portion Pa is provided at the rear-left corner of the inner peripheral surface of the main body portion 21.
The upper portion 22b is connected to the top of the rear-right corner of the lower portion 20, and configures an upper end portion of the main body portion 21. When viewed in plan view from above, the upper portion 22b is substantially L-shaped. Note that the corner of the upper portion 22b is rounded. An inner peripheral surface of the upper portion 22b includes a surface S13 that faces the upper-front, and a surface S14 that faces the upper-left. Furthermore, the surface S13 and the surface S14 configure a convex curved surface.
Meanwhile, the surface S13 and the surface S14 project toward the inner side portion of the substantially rectangular ring shape, relative to the lower portion 20. As a result, a protruding portion Pb is provided at the rear-right corner of the inner peripheral surface of the main body portion 21.
The upper portion 22c is connected to the top of the front-left corner of the lower portion 20, and configures an upper end portion of the main body portion 21. When viewed in plan view from above, the upper portion 22c is substantially L-shaped. Note that the corner of the upper portion 22c is rounded. An inner peripheral surface of the upper portion 22c includes a surface S15 that faces the upper-rear, and a surface S16 that faces the upper-right. Furthermore, the surface S15 and the surface S16 configure a convex curved surface.
Meanwhile, the surface S15 and the surface S16 project toward the inner side portion of the substantially rectangular ring shape, relative to the lower portion 20. As a result, a protruding portion Pc is provided at the front-left corner of the inner peripheral surface of the main body portion 21.
The upper portion 22d is connected to the top of the front-right corner of the lower portion 20, and configures an upper end portion of the main body portion 21. When viewed in plan view from above, the upper portion 22d is substantially L-shaped. Note that the corner of the upper portion 22d is rounded. An inner peripheral surface of the upper portion 22d includes a surface S17 that faces the upper-rear, and a surface S18 that faces the upper-left. Furthermore, the surface S17 and the surface S18 configure a convex curved surface.
Meanwhile, the surface S17 and the surface S18 project toward the inner side portion of the substantially rectangular ring shape, relative to the lower portion 20. As a result, a protruding portion Pd is provided at the front-right corner of the inner peripheral surface of the main body portion 21.
The projection portion 24a is connected to a lower end portion of the left shorter side of the lower portion 20, and is bent toward the right, relative to the lower portion 20. The projection portion 24b is connected to a lower end portion of the right shorter side of the lower portion 20, and is bent toward the left, relative to the lower portion 20. Accordingly, when viewed in plan view from above, the projection portions 24a and 24b project toward the inner side portion of the substantially rectangular ring.
The connecting portion 26 is connected to a lower end portion of the rear longer side of the lower portion 20, and is bent toward the rear relative to the lower portion 20.
The insulative member 16 is a block having a substantially octagonal shape when viewed in plan view from above, and is manufactured from an insulative resin such as a liquid-crystal polymer or the like. The insulative member 16 holds the anchoring terminal 12 and the connection terminals 14a-14c. Grooves G1-G3 that extend in the front-rear direction are provided in an upper surface of the insulative member 16. The grooves G1-G3 are arranged in that order from the left side to the right side. The grooves G1-G3 pass through the insulative member 16 in the up-down direction. As illustrated in
Each of the connection terminals 14a-14c is a conductor that is connected to a signal potential or a ground potential. In the present embodiment, the connection terminals 14a and 14c located on both ends in the left-right direction are signal terminals to which a signal is supplied. Meanwhile, the connection terminal 14b is a ground terminal that is connected to a ground potential. Accordingly, with the connection terminals 14a-14c, the signal terminals and the ground terminal are disposed in an alternating manner. As illustrated in
When viewed in plan view from the right, the contact portions 32a-32c have substantially U shapes whose upper sides are open. End portions of the contact portions 32a-32c on the upper rear are bent slightly toward the rear. End portions of the contact portions 32a-32c on the upper front are bent slightly toward the front. The connection portions 30a-30c are connected to end portions on the upper fronts of the contact portions 32a-32c, respectively. The connection portions 30a-30c are each substantially L-shaped when viewed in plan view from the right, and extend downward from the upper-front end portions of the contact portions 32a-32c before extending toward the front. In other words, the connection terminals 14a-14c extend toward the front from the contact portions 32a-32c, respectively, when viewed in plan view from above.
The connection terminals 14a-14c configured as described above are attached to the grooves G1-G3, respectively. Specifically, the connection terminals 14a-14c are inserted into the grooves G1-G3, respectively, from below. As a result, the contact portions 32a-32c of the connection terminals 14a-14c are arranged in that order, in a single row, from the left to the right within the substantially rectangular ring, when viewed in plan view from above.
Meanwhile, the connection portions 30a-30c of the connection terminals 14a-14c project toward the front below the insulative member 16. Here, when viewed in plan view from above, part of the longer side on the front of the anchoring terminal 12 is cut out. As illustrated in
Meanwhile, as illustrated in
The female connector 10 configured as described thus far is mounted on a circuit board. Specifically, the projection portions 24a and 24b, the connecting portion 26, and the connection portions 30a-30c are soldered to land electrodes provided on the circuit board.
Next, a method for manufacturing the female connector 10 will be described with reference to the drawings.
First, as illustrated in
Next, as illustrated in
Next, as illustrated in
The configuration of a male connector (a second connector) in the connector set will be described next with reference to the drawings.
In the following, a direction in which the male connector 50 illustrated in
The male connector 50 is mounted on a circuit board, a flexible wire, or the like, for example, and includes the anchoring terminal 52, the connection terminals 54a-54c, and the insulative member 56, as illustrated in
The anchoring terminal 52 is a conductor that is connected to a ground potential, and as illustrated in
The anchoring terminal 52 includes a main body portion 61, projection portions 64a and 64b, and a connecting portion 66. The main body portion 61 has an upper portion 60 and lower portions 62a-62d. The upper portion 60 is a substantially band-shaped conductor that encircles the perimeter of the center axis that extends in the up-down direction, and when viewed in plan view from above, has a shape in which part of a substantially rectangular ring has a part thereof cut out. In the present embodiment, the upper portion 60 has a shape in which part of the rear-side longer side is cut out. However, the upper portion 60 still has a right-side shorter side, a left-side shorter side, a front-side longer side, and part of the rear-side longer side. In other words, the upper portion 60 has portions that follow the four sides of the substantially rectangular ring shape. In addition, the four corners of the upper portion 60 are rounded.
Meanwhile, as illustrated in
The lower portion 62a is connected to the bottom of the rear-left corner of the upper portion 60, and configures a lower end portion of the main body portion 61. The lower portion 62a has a substantially oval shape obtained by combining two quarter-circles, when viewed in plan view from below. An outer peripheral surface of the lower portion 62a includes a surface S1 that faces the lower-rear and a surface S2 that faces the lower-left. Furthermore, the surface S1 and the surface S2 configure a single convex curved surface.
The lower portion 62b is connected to the bottom of the rear-right corner of the upper portion 60, and configures a lower end portion of the main body portion 61. The lower portion 62b has a substantially oval shape obtained by combining two quarter-circles, when viewed in plan view from below. An outer peripheral surface of the lower portion 62b includes a surface S3 that faces the lower-rear and a surface S4 that faces the lower-right. Furthermore, the surface S3 and the surface S4 configure a single convex curved surface.
The lower portion 62c is connected to the bottom of the front-left corner of the upper portion 60, and configures a lower end portion of the main body portion 61. The lower portion 62c has a substantially oval shape obtained by combining two quarter-circles, when viewed in plan view from below. An outer peripheral surface of the lower portion 62c includes a surface S5 that faces the lower-front and a surface S6 that faces the lower-left. Furthermore, the surface S5 and the surface S6 configure a single convex curved surface.
The lower portion 62d is connected to the bottom of the front-right corner of the upper portion 60, and configures a lower end portion of the main body portion 61. The lower portion 62d has a substantially oval shape obtained by combining two quarter-circles, when viewed in plan view from below. An outer peripheral surface of the lower portion 62d includes a surface S7 that faces the lower-front and a surface S8 that faces the lower-right. Furthermore, the surface S7 and the surface S8 configure a single convex curved surface.
The projection portion 64a is connected to an upper end portion of the left shorter side of the upper portion 60, and is bent toward the right, relative to the upper portion 60. The projection portion 64b is connected to an upper end portion of the right shorter side of the upper portion 60, and is bent toward the left, relative to the upper portion 60. Accordingly, when viewed in plan view from above, the projection portions 64a and 64b project toward the inner side portion of the substantially rectangular ring.
The connecting portion 66 is connected to the upper end portion of the front longer side of the upper portion 60, and is bent toward the front relative to the upper portion 60.
The insulative member 56 is a block having a substantially octagonal shape when viewed in plan view from above, and is manufactured from an insulative resin such as a liquid-crystal polymer or the like. The insulative member 56 holds the anchoring terminal 52 and the connection terminals 54a-54c. A substantially strip-shaped projection 57 that extends in the left-right direction is provided in a bottom surface of the insulative member 56. Furthermore, grooves G11-G13 that extend in the front-rear direction are provided in the projection 57. The grooves G11-G13 are arranged in that order from the left side to the right side. As illustrated in
Each of the connection terminals 54a-54c is a conductor that is connected to a signal potential or a ground potential. In the present embodiment, the connection terminals 54a and 54c located on both ends in the left-right direction are signal terminals to which a signal is supplied. Meanwhile, the connection terminal 54b is a ground terminal to which a ground potential is connected. Accordingly, with the connection terminals 54a-54c, the signal terminals and the ground terminal are disposed in an alternating manner. As illustrated in
When viewed in plan view from the right, the contact portions 72a-72c have substantially U shapes whose upper sides are open. The connection portions 70a-70c are connected to end portions on the upper rears of the contact portions 72a-72c, respectively. The connection portions 70a-70c each have substantially straight line shapes when viewed in plan view from the right, and extend rearward from the upper-rear end portions of the contact portions 72a-72c, respectively. In other words, the connection terminals 54a-54c extend toward the rear from the contact portions 72a-72c, respectively, when viewed in plan view from below.
The connection terminals 54a-54c configured as described above are attached to the grooves G11-G13, respectively. Specifically, the connection terminals 54a-54c are attached to the insulative member 56 so that following end portions of the connection portions 70a-70c and the outer peripheral surfaces of the contact portions 72a-72c are exposed from the insulative member 56. As a result, the contact portions 72a-72c of the connection terminals 54a-54c are arranged in that order, in a single row, from the left to the right within the substantially rectangular ring, when viewed in plan view from below.
Meanwhile, the connection portions 70a-70c of the connection terminals 54a-54c project toward the rear below the insulative member 56. Here, when viewed in plan view from above, part of the longer side on the rear of the anchoring terminal 52 is cut out. As illustrated in
Meanwhile, as illustrated in
The male connector 50 configured as described thus far is mounted on a circuit board. Specifically, the projection portions 64a and 64b, the connecting portion 66, and the connection portions 70a-70c are soldered to land electrodes provided on the circuit board.
Next, a method for manufacturing the male connector 50 will be described with reference to the drawings.
First, as illustrated in
Next, as illustrated in
Next, as illustrated in
Next, the configuration of a connector set 100 will be described with reference to the drawings.
The connector set 100 includes the female connector 10 and the male connector 50, and relays the transmission of high-frequency signals (approximately 6 GHz) between circuit boards. As illustrated in
The contact portions 72a-72c of the connection terminals 54a-54c are inserted into the contact portions 32a-32c of the connection terminals 14a-14c, respectively. Specifically, the contact portions 72a-72c are inserted into the contact portions 32a-32c from above, via respective upward-facing openings in the contact portions 32a-32c. As described earlier, the insulative member 16 is not formed integrally with the contact portions 32a-32c. Accordingly, when the contact portions 72a-72c are inserted into the contact portions 32a-32c, respectively, the contact portions 32a-32c are able to elastically deform and widen slightly in the front-rear direction. As a result, the inner peripheral surfaces of the contact portions 32a-32c press against the outer peripheral surfaces of the contact portions 72a-72c, respectively.
As described above, the connection terminal 14a and the connection terminal 54a make contact at the contact portions 32a and 72a when the female connector 10 and the male connector 50 are coupled. Likewise, the connection terminal 14b and the connection terminal 54b make contact at the contact portions 32b and 72b when the female connector 10 and the male connector 50 are coupled. Furthermore, the connection terminal 14c and the connection terminal 54c make contact at the contact portions 32c and 72c when the female connector 10 and the male connector 50 are coupled.
Meanwhile, the anchoring terminal 12 and the anchoring terminal 52 have substantially rectangular ring shapes that enclose the contact portions 32a-32c and 72a-72c when the female connector 10 and the male connector 50 are coupled, when viewed in plan view from above. More specifically, when viewed in plan view from above, the main body portion 21 of the anchoring terminal 12 has a shape in which part of the longer side on the front of the substantially rectangular ring is cut out. On the other hand, when viewed in plan view from above, the main body portion 61 of the anchoring terminal 52 has a shape in which part of the longer side on the rear of the substantially rectangular ring is cut out. In other words, the cut-out portion of the anchoring terminal 12 and the cut-out portion of the anchoring terminal 52 are provided in different positions so as not to overlap when viewed in plan view from above. Accordingly, when the anchoring terminal 52 is inserted into the anchoring terminal 12, the anchoring terminal 12 and the anchoring terminal 52 configure a substantially rectangular ring. Meanwhile, the contact portions 32a-32c are arranged in that order, in a single row, from the left to the right within the substantially rectangular ring, when viewed in plan view from above. The contact portions 72a-72c are arranged in that order, in a single row, from the left to the right within the substantially rectangular ring, when viewed in plan view from above.
Next, the attachment of the male connector 50 to the female connector 10 will be described with reference to the drawings.
It is preferable for the male connector 50 to be lowered from directly above the female connector 10 and inserted into the female connector 10. However, there are also cases where the male connector 50 is lowered from a position that is skewed from the position corresponding to directly above the female connector 10. With the connector set 100 according to the present embodiment, the male connector 50 can be inserted into the female connector 10 even in the case where the male connector 50 is lowered from a position that is skewed from the position corresponding to directly above the female connector 10. A case in which the male connector 50 is lowered from a position skewed to the rear relative to the female connector 10 will be given as an example hereinafter, as illustrated in
When the male connector 50 is lowered from the state illustrated in
Note that the male connector 50 can be inserted into the female connector 10 for the same reasons as described above even in the case where the male connector 50 is lowered from a position skewed toward the front relative to the female connector 10, the case where the male connector 50 is lowered from a position skewed toward the right relative to the female connector 10, and the case where the male connector 50 is lowered from a position skewed toward the left relative to the female connector 10.
The connector set 100 according to the present embodiment can improve noise-resistance properties. More specifically, the anchoring terminal 12 and the anchoring terminal 52 have substantially rectangular ring shapes that enclose the contact portions 32a-32c and 72a-72c when the female connector 10 and the male connector 50 are coupled, when viewed in plan view from above. Meanwhile, the anchoring terminals 12 and 52 are connected to a ground potential. As such, the connection terminals 14a-14c and 54a-54c are shielded in the front-rear and left-right directions. Accordingly, noise is suppressed from entering the connection terminals 14a-14c and 54a-54c from the front-rear and left-right directions. As such, the connector set 100 can improve noise-resistance properties.
Meanwhile, in the connector set 100, the connection terminals 14a-14c and 54a-54c are shielded in the front-rear and left-right directions. As such, according to the connector set 100, noise can be suppressed from radiating from the connection terminals 14a-14c and 54a-54c from the front-rear and left-right directions.
In addition, the noise-resistance properties can be improved by the male connector 50 as well, due to the following reasons. Specifically, when viewed in plan view from above, the lower portion 20 of the anchoring terminal 12 has portions that follow the four sides of the substantially rectangular ring that encloses the contact portions 32a-32c, and has a shape in which part of the substantially rectangular ring has been cut out. Accordingly, with the male connector 50, the anchoring terminal 52 that is connected to a ground potential is present in the front-rear and left-right directions of the contact portions 32a-32c. As a result, the connection terminals 54a-54c are shielded in the front-rear and left-right directions. Accordingly, noise from the front-rear and left-right directions is suppressed from entering the connection terminals 54a-54c. As such, the male connector 50 can improve noise-resistance properties. Note that the female connector 10 can also improve noise-resistance properties for the same reasons.
Meanwhile, in the male connector 50, the connection terminals 54a-54c are shielded in the front-rear and left-right directions. As such, according to the male connector 50, noise can be suppressed from radiating from the connection terminals 54a-54c in the front-rear and left-right directions. Note that in the female connector 10 as well, the connection terminals 14a-14c can be suppressed from radiating noise in the front-rear and left-right directions for the same reason.
Meanwhile, according to the female connector 10, the male connector 50, and the connector set 100, the connection terminals 14a-14c and 54a-54c can be suppressed from being damaged when the female connector 10 and the male connector 50 are coupled. Specifically, the anchoring terminal 12 of the female connector 10 has the upper portions 22a and 22d. The upper portion 22a is connected to the top of the rear-left corner of the lower portion 20, and configures an upper end portion of the main body portion 21. Furthermore, an inner peripheral surface of the upper portion 22a includes the surface S11 that faces the upper-front, and the surface S12 that faces the upper-right. The upper portion 22d is connected to the top of the front-right corner of the lower portion 20, and configures an upper end portion of the main body portion 21. Furthermore, an inner peripheral surface of the upper portion 22d includes the surface S17 that faces the upper-rear, and the surface S18 that faces the upper-left.
On the other hand, the anchoring terminal 52 of the male connector 50 has the lower portions 62a and 62d. The lower portion 62a is connected to the bottom of the rear-left corner of the upper portion 60, and configures a lower end portion of the main body portion 61. Furthermore, the outer peripheral surface of the lower portion 62a includes the surface S1 that faces the lower-rear and the surface S2 that faces the lower-left. The lower portion 62d is connected to the bottom of the front-right corner of the upper portion 60, and configures a lower end portion of the main body portion 61. Furthermore, the outer peripheral surface of the lower portion 62d includes the surface S7 that faces the lower-front and the surface S8 that faces the lower-right.
When the male connector 50 as described thus far is inserted into the female connector 10 from above, the surface S1 and the surface S11 make contact, the surface S2 and the surface S12 make contact, the surface S7 and the surface S17 make contact, and the surface S8 and the surface S18 make contact. Accordingly, the female connector 10 and the male connector 50 are positioned in the front-rear direction by the surfaces S1, S2, S11, and S12. Likewise, the female connector 10 and the male connector 50 are positioned in the left-right direction by the surfaces S7, S8, S17, and S18. In other words, the anchoring terminals 12 and 52 contribute greatly to the positioning of the female connector 10 and the male connector 50 in the front-rear and left-right directions, whereas the connection terminals 14a-14c and 54a-54c do not contribute greatly to this positioning. As such, according to the female connector 10, the male connector 50, and the connector set 100, the connection terminals 14a-14c and 54a-54c can be suppressed from being damaged when the female connector 10 and the male connector 50 are coupled.
Note that the anchoring terminal 52 has the lower portions 62b and 62c and the anchoring terminal 12 has the upper portions 22b and 22c. Accordingly, the upper portions 22b and 22c and the lower portions 62b and 62c also position the female connector 10 and the male connector 50 in the front-rear and left-right directions. As such, according to the female connector 10, the male connector 50, and the connector set 100, the connection terminals 14a-14c and 54a-54c can be suppressed from being damaged when the female connector 10 and the male connector 50 are coupled.
In addition, according to the male connector 50 and the connector set 100, the male connector 50 can be manufactured with ease. Specifically, the insulative member is formed by injecting a resin into a plastic injection mold. Accordingly, when manufacturing the insulative member 56, it is necessary to enclose the periphery of the space in which the insulative member 56 is manufactured with the plastic injection mold. However, the insulative member 56 is formed integrally with the anchoring terminal 52. As such, the anchoring terminal 52 acts as an obstacle and makes it difficult to dispose the plastic injection mold.
Accordingly, as illustrated in
In addition, according to the male connector 50 and the connector set 100, it is easy to set the characteristic impedance of the connection terminals 54a-54c to a predetermined characteristic impedance (50Ω, for example). More specifically, as illustrated in
In addition, according to the male connector 50 and the connector set 100, the anchoring terminal 52 and the connection terminals 54a-54c can be given a coplanar structure. Specifically, the anchoring terminal 52 and the connection terminal 54b are connected to a ground potential. On the other hand, the connection terminals 54a and 54c are connected to a signal potential. Through this, the anchoring terminal 52 is located to the left of the connection terminal 54a and the connection terminal 54b is located to the right of the connection terminal 54a, when viewed in plan view from above. As such, the anchoring terminal 52 and the connection terminals 54a and 54b have a coplanar structure. Likewise, the anchoring terminal 52 is located to the right of the connection terminal 54c and the connection terminal 54b is located to the left of the connection terminal 54c, when viewed in plan view from above. As such, the anchoring terminal 52 and the connection terminals 54b and 54c have a coplanar structure. By giving the anchoring terminal 52 and the connection terminals 54a-54c a coplanar structure, it is easy to set the characteristic impedance of the connection terminals 54a and 54c to a predetermined characteristic impedance. In addition, noise is suppressed from entering the connection terminals 54a and 54c from the left-right direction and noise is suppressed from radiating from the connection terminals 54a and 54c in the left-right direction. Note that for the same reasons, it is easy to set the characteristic impedance of the connection terminals 14a and 14c to a predetermined characteristic impedance in the female connector 10 as well. In addition, noise is suppressed from entering the connection terminals 14a and 14c from the left-right direction and noise is suppressed from radiating from the connection terminals 14a and 14c in the left-right direction.
In addition, according to the male connector 50 and the connector set 100, it is easy to bring the characteristic impedance of the connection terminals 54a and 54c close to uniform across the entirety thereof. Specifically, as illustrated in
In addition, in the male connector 50, the connection terminals 54a-54c are drawn out to the exterior of the ring, when viewed in plan view from above. As a result, it is easy to bring a terminal into contact with the connection terminals 54a-54c and carry out inspections. Furthermore, the connection terminals 54a-54c can easily be soldered to the land electrodes on the circuit board. For the same reasons, it is easy to bring a terminal into contact with the connection terminals 14a-14c and carry out inspections with the female connector 10 as well. Furthermore, the connection terminals 14a-14c can easily be soldered to the land electrodes on the circuit board.
In addition, according to the connector set 100, signal interference is suppressed. Specifically, in the board-to-board connector disclosed in Japanese Unexamined Patent Application Publication No. 2012-79684, the first terminal and the second terminal take on a substantially U shape when connected to each other, and thus overlap in the up-down direction. Accordingly, there is a risk that signal interference will occur due to a capacitance component or an induction component produced between the first terminal and the second terminal that have approached each other.
On the other hand, according to the connector set 100, the connection terminals 14a-14c extend toward the front from the contact portions 32a-32c when viewed in plan view from above. In addition, the connection terminals 54a-54c extend toward the rear from the contact portions 72a-72c, respectively, when viewed in plan view from above. The contact portions 32a-32c are connected to the connection terminals 54a-54c, respectively. As a result, the connection terminal 14a and the connection terminal 54a extend in a straight line in the front-rear direction, the connection terminal 14b and the connection terminal 54b extend in a straight line in the front-rear direction, and the connection terminal 14c and the connection terminal 54c extend in a straight line in the front-rear direction. Accordingly, the connection terminals 14a-14c are suppressed from overlapping with the connection terminals 54a-54c, respectively, in the up-down direction. As a result, according to the connector set 100, signal interference is suppressed.
In addition, according to the connector set 100, it is easy to improve the noise-resistance properties. Specifically, in the board-to-board connector disclosed in Japanese Unexamined Patent Application Publication No. 2012-79684, the first terminal and the second terminal take on a substantially U shape when connected to each other. In other words, the first terminal and the second terminal are disposed in two steps in the up-down direction. Accordingly, it is difficult to secure a space for disposing a conductor for shielding in the vicinity of one of the longer sides of the first housing. As a result, it is difficult to enclose the periphery of the first terminal and the second terminal with a conductor for shielding.
On the other hand, according to the connector set 100, the connection terminal 14a and the connection terminal 54a extend in a straight line in the front-rear direction, the connection terminal 14b and the connection terminal 54b extend in a straight line in the front-rear direction, and the connection terminal 14c and the connection terminal 54c extend in a straight line in the front-rear direction. As such, the connection terminals 14a-14c and the connection terminals 54a-54c are not disposed in two steps in the up-down direction. Accordingly, the anchoring terminal 52 can be disposed above the connection terminals 14a-14c and the anchoring terminal 12 can be disposed below the connection terminals 54a-54c. In other words, the contact portions 32a-32c and 72a-72c can be enclosed with the anchoring terminals 12 and 52, when viewed in plan view from above. As a result, according to the connector set 100, it is easy to improve the noise-resistance properties. In addition, according to the connector set 100, noise can be suppressed from radiating to the exterior.
In addition, according to the connector set 100, the connection terminals 14a-14c and the connection terminals 54a-54c are arranged in a single row, and thus the size of the connector set 100 can be reduced. Furthermore, because the connection terminals 14a-14c and the connection terminals 54a-54c are arranged in a single row, the influence of pitch skew is reduced, which suppresses changes in coupling force, fluctuations in engagement force, and so on between the female connector 10 and the male connector 50.
In addition, according to the connector set 100, the anchoring terminals 12 and 52 contribute greatly to the coupling of the female connector 10 and the male connector 50, whereas the connection terminals 14a-14c and 54a-54c contribute almost not at all. Accordingly, the strength of the coupling between the female connector 10 and the male connector 50 does not fluctuate greatly even if the number of the connection terminals 14a-14c and 54a-54c is changed.
In addition, according to the connector set 100, the insulative members 16 and 56 are suppressed from being subjected to wear when the female connector 10 and the male connector 50 are coupled. Specifically, in the case where the male connector 50 is lowered from a position skewed in the front-rear and left-right directions relative to the female connector 10, the female connector 10 and the male connector 50 are positioned in the front-rear and left-right directions due to the anchoring terminal 12 and the anchoring terminal 52 making contact with each other. During the positioning, the insulative member 16 does not make contact with the anchoring terminal 52, and the insulative member 56 does not make contact with the anchoring terminal 12. Furthermore, the insulative member 16 and the insulative member 56 do not make contact during the positioning. As a result, the insulative members 16 and 56 are suppressed from being subjected to wear.
A female connector 10A of a connector set according to a variation differs from the female connector 10 of the connector set according to the embodiment in that two coaxial cables can be connected to the female connector 10A of the connector set of the variation as shown in
The projection portions 24a and 24b are not present in the anchoring terminal 12 of the female connector 10A. In place of them, a bottom plate 27 formed substantially in a plate shape and extending from the lower end portion on the rear side of the lower portion 20 toward the front side is provided as shown in
When the crimping section 27a is viewed from the front in a state in which a coaxial cable is not attached thereto, the crimping section 27a is formed substantially in an L shape. Further, a plurality of projections are formed on an inner side surface of the crimping section 27a so as to prevent the coaxial cable from being pulled off when the coaxial cable is attached. The coaxial cable is pushed into the crimping section 27a from above, and an upper portion of the L-shaped area of the crimping section 27a is bent in the right direction and then bent in the lower direction, whereby the circumference of the coaxial cable is covered by the crimping section 27a and the coaxial cable is fixed to the female connector 10A.
When the crimping section 27b is viewed from the rear in a state in which a coaxial cable is not attached thereto, the crimping section 27b is formed substantially in an L shape. A plurality of projections are also formed on an inner side surface of the crimping section 27b so as to prevent the coaxial cable from being pulled off when the coaxial cable is attached. The coaxial cable is pushed into the crimping section 27b from above, and an upper portion of the L-shaped area of the crimping section 27b is bent in the left direction and then bent in the lower direction, whereby the circumference of the coaxial cable is covered by the crimping section 27b and the coaxial cable is fixed.
A cutout Q is provided in an approximately central portion of the flat plate portion 27c. The cutout Q has a shape such that an X shape is extended in the front-rear direction. An extended portion R which is adjacent to the front side of the cutout Q and extends toward the center of the cutout Q in the flat plate portion 27c, is bent so as to be pushed out toward the upper side. This makes the extended portion R be placed at a higher position than other portions of the flat plate portion 27c. Further, a substantially circular projection is provided on an upper surface in the vicinity of a rear end portion of the extended portion R. This projection makes contact with the connection terminal 14b. Note that the extended portion R is positioned between two coaxial cables in the left-right direction when the coaxial cables are attached to the female connector 10A.
When the anchoring terminal 12 of the female connector 10A is viewed from above, the lower portion 20 is positioned on a half of the rear-side region of the flat plate portion 27c, and the crimping sections 27a, 27b are connected to a front end portion of a region T which is a half of the front-side region. End portions of the flat plate portion 27c in the left-right direction in the region T (hereinafter, these end portions are called “side walls”) are each bent toward the upper side in a state in which coaxial cables are not attached. Then, when the coaxial cables are attached to the anchoring terminal 12, the side walls of the region T in the left-right direction are bent toward the center of the anchoring terminal 12, whereby the two coaxial cables are fixed along with the crimping sections 27a and 27b. Arms 99 are provided at the positions on the rear side of the region T in the bottom plate 27 of the anchoring terminal 12 and in the vicinity of the side walls of the region T in the left-right direction (only the arm on the right side is illustrated in
The female connector 10A of the connector set according to the variation also includes three connection terminals 14a-14c. The roles of the three connection terminals 14a-14c are the same as those of the female connector 10 of the connector set according to the embodiment. In other words, the connection terminals 14a and 14c positioned on both the sides in the left-right direction are signal terminals, and the connection terminal 14b positioned in the center is a ground terminal. Note that, however, the shape of each of the connection terminals 14a-14c of the female connector 10A is partially different from the shape of each of the connection terminals 14a-14c of the female connector 10, respectively.
In each of the connection terminals 14a-14c of the female connector 10A, an end portion on the front side thereof is more extended in the front direction than an end portion on the front side of each of the connection terminals 14a-14c of the female connector 10. Further, the end portion on the front side of each of the connection terminals 14a and 14c of the female connector 10A is bent toward the upper side, and grooves N1 and N2 extending in the up-down direction are provided in the center of each of the bent portions. The grooves N1 and N2 are grooves for fitting inner conductors of the coaxial cables therein when the coaxial cables are attached to the anchoring terminal 12. Further, the portion of the connection terminal 14b of the female connector 10A that is extended in the front direction is connected to the extended portion R of the anchoring terminal 12 by attaching the connection terminal 14b to the anchoring terminal 12.
The insulative member 16 of the female connector 10A of the connector set according to the variation can be divided into a terminal holding portion 16a, the coaxial cable holding portion 16b, and an insulation bottom portion 16c. Although the insulative member 16 is divided into the three portions and described hereinafter, the three portions are, in reality, manufactured as a unit member through insert-molding.
The terminal holding portion 16a is provided at a portion enclosed by the lower portion 20 of the anchoring terminal 12, and formed substantially in a parallelepiped shape. The shapes of the grooves G1-G3 in which the connection terminals 14a-14c are set are the same as those of the female connector 10 of the connector set according to the embodiment.
The coaxial cable holding portion 16b is connected to an outer edge on the front side of the terminal holding portion 16a, and is formed, when viewed in the up-down direction, in a substantially rectangular shape with one side open, that is, a shape having a cavity in the front direction. In the case where two coaxial cables are attached to the female connector 10A, the respective coaxial cables are set inside the above rectangular shape with one open side of the coaxial cable holding portion 16b.
The insulation bottom portion 16c is formed substantially in a flat plate shape, and positioned between the flat plate portion 27c of the anchoring terminal 12 and the connection terminals 14a-14c. With this, the anchoring terminal 12 and the connection terminals 14a, 14b are isolated and insulated. Note that, however, a part of the insulation bottom portion 16c is cut out, and the connection terminal 14b and the extended portion R of the anchoring terminal 12 make contact with each other at the above cutout part. In addition, a projection M1 extending toward the upper side and formed substantially in a parallelepiped shape is provided at an end portion on the front side of the insulation bottom portion 16c. The projection M1, when two coaxial cables are attached to the female connector 10A, is disposed between those coaxial cables in the left-right direction. As such, a constant distance is maintained between the two attached coaxial cables by the projection M1 included in the insulation bottom portion 16c.
To the female connector 10A of the connector set according to the variation configured as described above, two coaxial cables can be connected.
Further, in the female connector 10A, the connection terminal 14b kept at the ground potential and the anchoring terminal 12 are connected at the extended portion R. With this, a volume connected to the ground potential is increased by the volume of the anchoring terminal 12. As such, the potential of the connection terminal 14b becomes stable in comparison with a case where the connection terminal 14b is not connected to the anchoring terminal 12.
In the case where two coaxial cables are attached to the female connector 10A, the extended portion R of the anchoring terminal 12 is positioned between the two coaxial cables. Further, the extended portion R is part of the anchoring terminal 12 and kept at the ground potential. In other words, the extended portion R kept at the ground potential is positioned between the two coaxial cables attached to the female connector 10A. This makes it possible to suppress crosstalk between the two coaxial cables in the female connector 10A of the connector set according to the variation. The other constituent elements of the variation are the same as those in the embodiment. Therefore, descriptions of portions other than the above-discussed portions in the variation are the same as those in the embodiment.
The connectors and connector set according to the present disclosure are not limited to the female connector 10, the male connector 50, and the connector set 100, and can be changed without departing from the essential scope of the present disclosure. Although the female connector 10 is set as the first connector and the male connector 50 is set as the second connector, the male connector 50 can be set as the first connector and the female connector 10 can be set as the second connector.
The female connector 10 and the male connector 50 can be positioned in the front-rear and left-right directions as long as the anchoring terminal 12 has the upper portions 22a and 22d and the anchoring terminal 52 has the lower portions 62a and 62d. In other words, the upper portions 22b and 22c are not absolutely necessary in the anchoring terminal 12, and the lower portions 62b and 62c are not absolutely necessary in the anchoring terminal 52. Likewise, the anchoring terminal 12 may have the upper portions 22b and 22c and the anchoring terminal 52 may have the lower portions 62b and 62c instead. In this case, the upper portions 22a and 22d are not absolutely necessary in the anchoring terminal 12, and the lower portions 62a and 62d are not absolutely necessary in the anchoring terminal 52.
In addition, although the anchoring terminal 12 and the anchoring terminal 52 have a substantially rectangular ring shape when viewed in plan view from above, these terminals may have a ring shape aside from substantially rectangular, such as a substantially oval or substantially elliptical shape.
In addition, although a space is provided between the anchoring terminal 12 and the insulative member 16, the space may be filled with a material having a lower relative permittivity than the insulative member 16. Through this, the strength of the female connector 10 can be increased. Likewise, the space between the anchoring terminal 52 and the insulative member 56 may be filled with a material having a lower relative permittivity than the insulative member 56.
In addition, it is sufficient for two or more of the connection terminals 14a-14c to be provided. Likewise, it is sufficient for two or more of the connection terminals 54a-54c to be provided.
In addition, the connection terminals 14a-14c and 54a-54c may be configured only of signal terminals to which a signal potential is applied.
As described thus far, the present disclosure is useful in connector sets and connectors, and is particularly advantageous in that noise-resistance properties can be improved.
While preferred embodiments of the disclosure have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the disclosure. The scope of the disclosure, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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2014-116840 | Jun 2014 | JP | national |
2015-080716 | Apr 2015 | JP | national |