The present disclosure relates to a ground coupling structure in a coaxial connector set.
For example, the coaxial connector disclosed in U.S. Patent Application Publication No. 2010/0041270 (US2010/0041270 A1) includes an insulating body, a central terminal, and a housing; and the housing has a cylindrical main portion, a plate member, and a cable-clamping member to clamp the coaxial cable, the cable-clamping member being positioned at an end portion of the plate member.
In the coaxial connector described in U.S. Patent Application Publication No. 2010/0041270 (US2010/0041270 A1), a side arm is provided between the main portion and the cable-clamping member, and the insulating body is wrapped by the side arm. Further, it is disclosed that an arc-shaped surface is provided on a front side of the side arm, and the arc-shaped surface is in contact with an outer end portion of the main portion.
U.S. Patent Application Publication No. 2010/0041270 (US2010/0041270 A1) only discloses a contact between the main portion constituting the housing and the side arm in the coaxial connector (first connector), that is, the contact in the housing of the coaxial connector; the relationship between the coaxial connector (first connector) and a housing of a mating connector (second connector) is not disclosed at all.
Incidentally, in a coupling structure of a first connector, to which coaxial cable is connected, and a second connector, generation of an unnecessary electrical potential difference may lead to radiation of noise, and stable signal transmission in a radio frequency band may be disturbed.
Accordingly, the present disclosure provides a ground coupling structure in a coaxial connector set that enables stable signal transmission in a radio frequency band.
A ground coupling structure in a coaxial connector set according to one aspect of the present disclosure is configured as follows. In the coaxial connector set including a first connector to which a coaxial cable having a center conductor and an outer conductor is connected and a second connector mounted on a circuit board having a ground coupling portion. The first connector has a first outer terminal connected to the outer conductor and the second connector has a second outer terminal to be coupled to the first outer terminal. The first outer terminal includes an outer conductor clamp portion clamping the outer conductor, a first outer contact portion to be coupled to the second outer terminal, and a tip surrounding portion positioned between the outer conductor clamp portion and the first outer contact portion and surrounding a tip portion of the center conductor. The second outer terminal includes a second outer contact portion to be coupled to the first outer contact portion and a second outer mount portion mounted on the ground coupling portion of the circuit board. A shortcut coupling path is formed between the tip surrounding portion and the second outer terminal or the ground coupling portion.
Further, a ground coupling structure in a coaxial connector set according to another aspect of the present disclosure is configured as follows. In the coaxial connector set including a first connector to which a coaxial cable having a center conductor and an outer conductor is connected and a second connector mounted on a circuit board having a ground coupling portion. The first connector has a first outer terminal connected to the outer conductor and the second connector has a second outer terminal to be coupled to the first outer terminal. The first outer terminal includes an outer conductor clamp portion clamping the outer conductor, a first outer contact portion to be coupled to the second outer terminal, a tip surrounding portion positioned between the outer conductor clamp portion and the first outer contact portion and surrounding a tip portion of the center conductor, and an outer conductor connection portion connecting the first outer contact portion and the tip surrounding portion. The second outer terminal includes a second outer contact portion to be coupled to the first outer contact portion and a second outer mount portion mounted on the ground coupling portion of the circuit board. A coupling portion coupling the tip surrounding portion and the second outer terminal or the ground coupling portion without using the outer conductor connection portion is provided. The coupling portion is positioned closer to the circuit board than the outer conductor connection portion.
According to an aspect of the present disclosure, since the shortcut coupling path couples the tip surrounding portion of the first outer terminal and the second outer terminal or the ground coupling portion of the circuit board with a short distance, stable signal transmission in a radio frequency band may be performed.
According to another aspect of the present disclosure, since the coupling portion connects the tip surrounding portion of the first outer terminal and the second outer terminal or the ground coupling portion of the circuit board with a short distance, stable signal transmission in a radio frequency band may be performed.
Hereinafter, embodiments of a ground coupling structure in a coaxial connector set 30 according to the present disclosure will be described with reference to the drawings. Note that, an X axis, a Y axis, and a Z axis that are orthogonal to each other are illustrated in the drawings for convenience of description.
In the present disclosure, a shortcut coupling path refers to a path that couples a tip surrounding portion 16m of a first outer terminal 16 and a second outer terminal 26 (including a second outer contact portion 26b and a second outer mount portion 26a), or a ground coupling portion 57 of a circuit board 50 with a distance as short as possible, that is, in a shorter route, by taking an elasticity and a contact structure into consideration. Further, in the present disclosure, a coupling portion refers to a separate member which is positioned closer to the circuit board 50 than an outer conductor connection portion 16a, in other words, positioned on a side opposite to the outer conductor connection portion 16a (that is, on a side closer to the circuit board 50); and the coupling portion electrically couples the tip surrounding portion 16m and the second outer terminal 26 or the ground coupling portion 57 without using the outer conductor connection portion 16a. Further, in the present disclosure, “surrounding” means that an object surrounds another object in a contact state or in a non-contact state.
[Coaxial Connector Set]
As illustrated in
[First Connector]
As illustrated in
The first inner terminal 14 is a terminal connected to a center conductor 42 of the coaxial cable 40. The first inner terminal 14 is electrically insulated from the first outer terminal 16 by the first insulation member 12.
The first inner terminal 14 is formed of a member having conductivity. The first inner terminal 14 is made of one metal plate such as a copper alloy material, for example, and is plated with nickel and gold on the surface thereof. The first inner terminal 14 is integrated with the first insulation member 12 by insert molding. With the use of the stated configuration, positioning between the first insulation member 12 and the first inner terminal 14 may accurately be performed. Further, although accuracy is required, the stated aspect of integration may be achieved by fitting the first inner terminal 14 into the first insulation member 12.
The first inner terminal 14 includes a first inner contact portion 14a and a center conductor connection portion 14b. As illustrated in
The first inner contact portion 14a extends in a direction orthogonal to the axial direction of the coaxial cable 40, that is, in the plug-unplug direction (Z axis direction). The first inner contact portion 14a has a substantially cylindrical shape partially cut out in a circumferential direction.
The first inner contact portion 14a electrically comes into contact with a second inner contact portion 24a of a second inner terminal 24 of the second connector 20. The first inner contact portion 14a illustrated in
The center conductor connection portion 14b extends in the axial direction of the coaxial cable 40, that is, in a lateral direction (X axis direction) orthogonal to the plug-unplug direction. The center conductor connection portion 14b is a plate-shaped terminal portion extending in the lateral direction from the first inner contact portion 14a. The center conductor connection portion 14b is electrically connected to a tip portion 42a of the center conductor 42 of the coaxial cable 40. The end portion of the center conductor connection portion 14b on a side of the coaxial cable 40 and the tip portion 42a of the center conductor 42 are fixed and electrically connected to each other by soldering. Note that a bifurcated portion may be formed on the end portion of the center conductor connection portion 14b on the side of the coaxial cable 40. In this case, sandwiching the tip portion 42a of the center conductor 42 by the bifurcated portion further strengthen the connection.
The first outer terminal 16 is a terminal connected to an outer conductor 41 of the coaxial cable 40. The first outer terminal 16 is formed of a member having conductivity. The first outer terminal 16 is made of one metal plate such as a copper alloy material, for example, and is plated with nickel and gold on the surface thereof.
The first outer terminal 16 includes the outer conductor connection portion 16a, a first outer contact portion 16b, an outer conductor clamp portion 16c, a retaining portion 16e, the tip surrounding portion 16m, and a cable clamp portion 16n.
The outer conductor connection portion 16a has a plate shape extending from the first outer contact portion 16b in a lateral direction (X axis direction). The outer conductor connection portion 16a is positioned along the first insulation member 12 and the coaxial cable 40, and holds the first insulation member 12 and the coaxial cable 40.
The first outer contact portion 16b has a cylindrical shape, and fits to the second outer terminal 26 of the second connector 20. The first outer contact portion 16b extends in the plug-unplug direction (Z axis direction). As viewed from the plug-unplug direction (Z axis direction), the first outer contact portion 16b has a cavity on a side of the coaxial cable 40. An inner holding portion 12a of the first insulation member 12 is inserted and fixed in the first outer contact portion 16b through the cavity of the first outer contact portion 16b. With the use of the stated configuration, deformation of the first outer contact portion 16b is less likely to occur than in a case where the outer terminal is configured of a plurality of spring pieces formed by a plurality of slits extending in the plug-unplug direction (Z axis direction), and therefore stable fitting may be achieved. The first inner contact portion 14a of the first inner terminal 14 is positioned inside the first outer contact portion 16b. At this time, the first outer contact portion 16b is positioned to be coaxial with the first inner contact portion 14a as viewed from the plug-unplug direction (Z axis direction).
The first outer contact portion 16b has a substantially cylindrical shape having a cut out portion in which a circumferential direction portion of the cylindrical shape on the side of the coaxial cable 40 is cut out in an arc shape. A center conductor holding portion 12b of the first insulation member 12 is inserted and mounted through the cutout portion.
The outer conductor clamp portion 16c extends from the outer conductor connection portion 16a in the plug-unplug direction (Z axis direction). The outer conductor clamp portion 16c is configured of a pair of plate-shaped members formed to face each other in a width direction (Y axis direction). The outer conductor clamp portion 16c is bent toward a virtual center line and crimped, and therefore, comes into contact with the outer conductor 41 of the coaxial cable 40. With this, the first outer terminal 16 and the outer conductor 41 are electrically connected, and the coaxial cable 40 is clamped (held and fixed) to the first outer terminal 16.
The retaining portion 16e is provided in a side extending portion extending from the first outer contact portion 16b toward the side of the coaxial cable 40. The retaining portion 16e extends from the side extending portion in the plug-unplug direction (Z axis direction). The retaining portion 16e is configured of a pair of plate-shaped members formed to face each other in the width direction (Y axis direction). By bending and crimping the retaining portion 16e toward the virtual center line, the tip portion of the retaining portion 16e engages with a retaining recessed portion 12e of the center conductor holding portion 12b. With the use of the stated configuration, the retaining portion 16e prevents the center conductor holding portion 12b of the first insulation member 12 from coming off in the plug-unplug direction (Z axis direction), and the first insulation member 12 is held and fixed to the first outer terminal 16.
The cable clamp portion 16n is positioned on an opposite side of the first outer terminal 16 from the first outer contact portion 16b and farther from the first outer contact portion 16b than the outer conductor clamp portion 16c, and extends from the outer conductor connection portion 16a in the plug-unplug direction (Z axis direction). The cable clamp portion 16n is configured of a pair of plate-shaped members formed to face each other in the width direction (Y axis direction). By bending and crimping the cable clamp portion 16n toward the virtual center line, the cable clamp portion 16n comes into contact with an outer skin 43 of the coaxial cable 40. With this, the coaxial cable 40 is clamped (held and fixed) to the first outer terminal 16.
The tip surrounding portion 16m is positioned between the first outer contact portion 16b and the outer conductor clamp portion 16c, and extends from the outer conductor connection portion 16a in the plug-unplug direction (Z axis direction). The tip surrounding portion 16m is configured of a pair of plate-shaped members formed to face each other in the width direction (Y axis direction). By bending toward the virtual center line, the tip surrounding portion 16m is formed in a rectangular shape in a sectional view in the width direction (Y axis direction). The rectangular shaped tip surrounding portion 16m surrounds the tip portion 42a being exposed to the outside, which is a portion of the center conductor 42 of the coaxial cable 40.
The first insulation member 12 is disposed between the first inner terminal 14 and the first outer terminal 16. The first insulation member 12 is made of electrical insulation resin (such as liquid crystal polymer, for example), and electrically insulates the first inner terminal 14 and the first outer terminal 16 from each other.
The first insulation member 12 includes the inner holding portion 12a and the center conductor holding portion 1b.
The inner holding portion 12a has a substantially circular shape as viewed from the plug-unplug direction (Z axis direction). The inner holding portion 12a is sized to be attachable to the inside of the first outer contact portion 16b through the cavity of the first outer contact portion 16b in the plug-unplug direction (Z axis direction). In the inner holding portion 12a, the first inner contact portion 14a of the first inner terminal 14 bulges in the plug-unplug direction (Z axis direction). The first inner contact portion 14a is integrated with the inner holding portion 12a to be coaxial with the inner holding portion 12a. For example, the first inner contact portion 14a is integrated with the inner holding portion 12a by insert molding, and part of the center conductor connection portion 14b is integrated with the inner holding portion 12a. With the use of the stated configuration, positioning between the first insulation member 12 and the first inner terminal 14 may accurately be performed.
The center conductor holding portion 12b extends from the inner holding portion 12a to the side of the coaxial cable 40. The center conductor holding portion 12b has a substantially rectangular shape as viewed from the plug-unplug direction (Z axis direction). The remaining portion of the center conductor connection portion 14b is embedded in the center conductor holding portion 12b, and is exposed from the center conductor holding portion 12b. The end portion of the exposed center conductor connection portion 14b is electrically connected to the tip portion 42a of the center conductor 42 as the above-described bifurcated portion. A pair of retaining recessed portions 12e are formed in an upper surface portion of the center conductor holding portion 12b in the width direction (Y axis direction). Note that, it is also possible to adopt an aspect in which the center conductor connection portion 14b extends in a planar shape in the axial direction of the coaxial cable 40, that is, in a lateral direction (X axis direction) orthogonal to the plug-unplug direction.
[Second Connector]
As illustrated in
As illustrated in
The second inner terminal 24 is configured of a member having conductivity. The second inner terminal 24 is made of one metal plate such as a copper alloy material, for example, and is plated with nickel and gold on the surface thereof. The second inner terminal 24 is integrated with the second insulation member 22 by insert molding. With the use of the stated configuration, positioning between the second insulation member 22 and the second inner terminal 24 may accurately be performed.
The second inner terminal 24 includes the second inner contact portion 24a and a second inner mount portion 24b. As illustrated in
The second inner contact portion 24a extends in the plug-unplug direction (Z axis direction). The second inner contact portion 24a has a substantially cylindrical shape. The second inner contact portion 24a is in contact with and is electrically coupled to the first inner contact portion 14a of the first inner terminal 14 of the first connector 10. The second inner contact portion 24a illustrated in
As illustrated in
The second outer terminal 26 includes the second outer mount portion 26a and the second outer contact portion 26b. As illustrated in
The second outer contact portion 26b extends in the plug-unplug direction (Z axis direction). The second outer contact portion 26b has a substantially cylindrical shape. The second outer contact portion 26b is coaxially disposed with the second inner contact portion 24a. The second outer contact portion 26b is in contact with and is electrically coupled to the first outer contact portion 16b of the first outer terminal 16 of the first connector 10. A fitting recessed portion 26h is formed on an outer peripheral surface of the second outer contact portion 26b. When the first connector 10 is fitted to the second connector 20, the fitting recessed portion 26h of the second outer contact portion 26b fits with a fitting projection portion 16h of the first outer contact portion 16b.
[First Embodiment]
Referring to
As illustrated in
The interposing member 60 is configured of a separate member having conductivity and elasticity, and is made of one metal plate such as a copper alloy material, for example. The surfaces of the contact portion 65 and the vicinity portion thereof are plated with nickel and gold. Since the contact portion 65 is provided on the elastic support portion 62 curved in an inverted J-shape, the contact portion 65 comes into contact by a curved surface.
As illustrated in
In the stated state, the fitting operation is performed by moving the first connector 10 toward the second connector 20 in the plug-unplug direction (Z axis direction). At this time, the first outer contact portion 16b of the first connector 10 and the second outer contact portion 26b of the second connector 20 are engaged with each other, and the first outer contact portion 16b and the second outer contact portion 26b are electrically coupled. At the same time, the tip surrounding portion 16m of the first connector 10 and the two elastic support portions 62 of the interposing member 60 are engaged with each other, and the two contact portions 65 of the interposing member 60 elastically come into contact with the side surfaces of the tip surrounding portion 16m. With this, the tip surrounding portion 16m and the two contact portions 65 are electrically coupled.
Incidentally, even when the first outer contact portion 16b and the tip surrounding portion 16m are connected to the same ground, a bypass connection path detouring along the first outer terminal 16 is formed between the first outer contact portion 16b and the tip surrounding portion 16m in a radio frequency band. With this, an electrical potential difference is generated between the first outer contact portion 16b and the tip surrounding portion 16m in the first outer terminal 16; and this may lead to radiation of noise, and stable signal transmission in a radio frequency band may be disturbed.
The interposing member 60 disposed as a separate member between the tip surrounding portion 16m of the first connector 10 and the ground land portion 57 of the circuit board 50 serves as a shortcut coupling path or a coupling portion that couples the tip surrounding portion 16m and the ground land portion (ground coupling portion) 57 of the circuit board 50. Accordingly, since the ground coupling portion 57 of the circuit board 50 and the tip surrounding portion 16m of the first outer terminal 16 are coupled with a short distance by the interposing member 60 serving as the shortcut coupling path or the coupling portion, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example). This is because the generation of the electrical potential difference between the tip surrounding portion 16m and the ground coupling portion 57 may be suppressed by the shortcut coupling path or the coupling portion.
[Second Embodiment]
Referring to
Since the contact portion 65 is provided at a line-shaped edge portion of the elastic contact portion 64 extending in the width direction (Y axis direction), the contact portion 65 may provide line-shaped contact. Accordingly, the contact pressure of the contact portion 65 may be increased. Further, it is possible to suppress an increase in the electrical resistance of the contact portion 65 because of the abrasion generated by the plug-unplug operation of the connector, as compared with the case that the contact portion 65 is provided in the elastic support portion 62.
The fitting operation is performed by moving the first connector 10 toward the second connector 20 in the plug-unplug direction (Z axis direction). At this time, the first outer contact portion 16b of the first connector 10 and the second outer contact portion 26b of the second connector 20 are engaged with each other, and the first outer contact portion 16b and the second outer contact portion 26b are electrically coupled. At the same time, the tip surrounding portion 16m of the first connector 10 and the two elastic support portions 62 of the interposing member 60 are engaged with each other. At this time, the three contact portions 65 of the interposing member 60 elastically come into contact with the bottom surface of the tip surrounding portion 16m. With this, a stable electrical coupling is achieved between the tip surrounding portion 16m and the three contact portions 65.
The interposing member 60 disposed as a separate member between the tip surrounding portion 16m of the first connector 10 and the ground land portion 57 of the circuit board 50 serves as a shortcut coupling path or a coupling portion that couples the tip surrounding portion 16m and the ground land portion (ground coupling portion) 57 of the circuit board 50. Accordingly, since the ground coupling portion 57 of the circuit board 50 and the tip surrounding portion 16m of the first outer terminal 16 are coupled with a short distance by the interposing member 60 serving as the shortcut coupling path or the coupling portion, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example). This is because the generation of the electrical potential difference between the tip surrounding portion 16m and the ground coupling portion 57 may be suppressed by the shortcut coupling path or the coupling portion.
[Third Embodiment]
Referring to
As illustrated in
A portion of the side of the second outer terminal 26 to be coupled to the bridge coupling portion 16s is positioned to face the tip surrounding portion 16m, and is electrically connected to the ground land portion (ground coupling portion) 57 of the circuit board 50. Specifically, the portion of the side of the second outer terminal 26 to be coupled to the bridge coupling portion 16s is the side surface of the second outer contact portion 26b on the side of the coaxial cable 40, or the upper surface of the second outer mount portion 26a on the side of the coaxial cable 40.
The bridge coupling portion 16s has an L-shape in a side view from the width direction (Y axis direction). The tip portion of the bridge coupling portion 16s on the side of the first outer contact portion 16b has a contact portion 16t; and the contact portion 16t is provided on the side surface of the tip portion on the side of the first outer contact portion 16b or on the lower surface of the tip portion on the side of the second outer mount portion 26a. The surfaces of the contact portion 16t and the vicinity portion thereof are plated with nickel and gold.
The bridge coupling portion 16s is supported in a cantilever manner at the side end surface of the tip surrounding portion 16m on the side of the first outer contact portion 16b, and therefore has an elastic urging force. The elastic urging force of the bridge coupling portion 16s acts in the plug-unplug direction (Z axis direction). The bridge coupling portion 16s having the contact portion 16t provides an elastic contact, and therefore provides a stable electrical coupling.
The fitting operation is performed by moving the first connector 10 toward the second connector 20 in the plug-unplug direction (Z axis direction). At this time, the first outer contact portion 16b of the first connector 10 and the second outer contact portion 26b of the second connector 20 are engaged with each other, and the first outer contact portion 16b and the second outer contact portion 26b are electrically coupled. At the same time, the contact portions 16t of the two bridge coupling portions 16s elastically come into contact with the side surface of the second outer contact portion 26b on the side of the coaxial cable 40. With this, a stable electrical coupling is achieved between the tip surrounding portion 16m and the second outer contact portion 26b.
The bridge coupling portion 16s disposed between the tip surrounding portion 16m of the first connector 10 and the second outer contact portion 26b of the second connector 20 serves as a shortcut coupling path coupling the tip surrounding portion 16m and the second outer contact portion 26b. Accordingly, since the second outer contact portion 26b and the tip surrounding portion 16m of the first outer terminal 16 are coupled with a short distance by the bridge coupling portion 16s serving as the shortcut coupling path, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example). This is because the generation of the electrical potential difference between the tip surrounding portion 16m and the second outer contact portion 26b may be suppressed by the shortcut coupling path.
Because of the shape of the bridge coupling portion 16s, even in a case where the first connector 10 is fitted to the second connector 20 such that the first connector 10 shifts in any direction in a direction (X-Y plane direction) orthogonal to the plug-unplug direction (Z axis direction), the connectivity of the shortcut coupling path is maintained.
Note that the following aspect may be adopted. The tip portion of the bridge coupling portion 16s on the side of the first outer contact portion 16b has the contact portion 16t on a lower surface thereof on the side of the second outer mount portion 26a, and elastically comes into contact with the upper surface of the second outer mount portion 26a on the side of the coaxial cable 40. With this, stable electrical coupling may be achieved between the tip surrounding portion 16m and the second outer mount portion 26a.
Further, it is also possible to adopt an aspect in which the two bridge coupling portions 16s are disposed to the second outer mount portion 26a. Specifically, the following aspect may be adopted. The two bridge coupling portions 16s extend in a plate shape in the lateral direction (X axis direction) from the upper surface of the second outer mount portion 26a on the side of the coaxial cable 40 to the tip surrounding portion 16m. That is, the bridge coupling portion 16s may be provided as part of the second outer mount portion 26a. The tip portion of the stated bridge coupling portion 16s on the side of the coaxial cable 40 may have a contact portion, and may elastically come into contact with the upper surface, the lower surface, or the side end surface of the tip surrounding portion 16m. The bridge coupling portion 16s serving as the shortcut coupling path or the coupling portion achieves a stable electrical coupling between the tip surrounding portion 16m and the second outer mount portion 26a.
Furthermore, it is also possible to adopt an aspect in which the two bridge coupling portions 16s are disposed to the second outer contact portion 26b. Specifically, the following aspect may be adopted. The two bridge coupling portions 16s extend in a plate shape in the lateral direction (X axis direction) from the side end portion of the second outer contact portion 26b on the side of the coaxial cable 40 to the tip surrounding portion 16m. That is, the bridge coupling portion 16s may be provided as part of the second outer contact portion 26b. The tip portion of the stated bridge coupling portion 16s on the side of the coaxial cable 40 may have a contact portion, and may elastically come into contact with the upper surface, the lower surface, or the side end surface of the tip surrounding portion 16m. Since the bridge coupling portion 16s serving as the shortcut coupling path electrically couples the tip surrounding portion 16m of the first outer terminal 16 and the second outer contact portion 26b of the second connector 20 with a short distance, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
[Fourth Embodiment]
Referring to
As illustrated in
The first elastic contact portion 73 and the second elastic contact portion 75 are disposed on the lower surface portion of the shield member 70. The first elastic contact portion 73 extends from a side end surface of the body 71 on the side of the first outer contact portion 16b, and has a shape curved in a J-shape. The first elastic contact portion 73 includes the first contact portion 74 on the surface thereof on the side of the first outer contact portion 16b. The surfaces of the first contact portion 74 and the vicinity portion thereof are plated with nickel and gold. The first elastic contact portion 73 is supported in a cantilever manner at the side end surface of the body 71 on the side of the first outer contact portion 16b, and therefore has an elastic urging force. The elastic urging force of the first elastic contact portion 73 acts in the lateral direction (X axis direction). The first elastic contact portion 73 including the first contact portion 74 provides a stable electrical coupling because of the elastic contact.
The second elastic contact portion 75 extends from the side end surface of the body 71 on the side of the coaxial cable 40, and has a shape curved in an S-shape. The second elastic contact portion 75 includes the second contact portion 76 on the surface thereof on the side of the circuit board 50. The surfaces of the second contact portion 76 and the vicinity portion thereof are plated with nickel and gold. The second elastic contact portion 75 is supported in a cantilever manner at the side end surface of the body 71 on the side of the coaxial cable 40, and therefore has an elastic urging force. The elastic urging force of the second elastic contact portion 75 acts in the plug-unplug direction (Z axis direction). The second elastic contact portion 75 including the second contact portion 76 provides a stable electrical coupling because of the elastic contact.
The fitting operation is performed by moving the first connector 10 toward the second connector 20 in the plug-unplug direction (Z axis direction). At this time, the first outer contact portion 16b of the first connector 10 and the second outer contact portion 26b of the second connector 20 are engaged with each other, and the first outer contact portion 16b and the second outer contact portion 26b are electrically coupled. Meanwhile, the first contact portion 74 of the first elastic contact portion 73 elastically comes into contact with the side surface of the second outer contact portion 26b on the side of the coaxial cable 40, and the second contact portion 76 of the second elastic contact portion 75 elastically comes into contact with the inner surface of the facing wall portion of the tip surrounding portion 16m on the side of the circuit board 50. With this, a stable electrical coupling is achieved between the tip surrounding portion 16m and the second outer contact portion 26b.
The shield member 70 disposed between the tip surrounding portion 16m of the first connector 10 and the second outer contact portion 26b of the second connector 20 serves as the shortcut coupling path coupling the tip surrounding portion 16m and the second outer contact portion 26b. Accordingly, since the tip surrounding portion 16m of the first outer terminal 16 and the second outer contact portion 26b of the second connector 20 are coupled with a short distance by the shield member 70 serving as the shortcut coupling path, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example). This is because the generation of the electrical potential difference between the tip surrounding portion 16m and the second outer contact portion 26b may be suppressed by the shortcut coupling path.
Due to the shape of the first elastic contact portion 73 of the shield member 70, even in a case where the first connector 10 is fitted to the second connector 20 such that the first connector 10 shifts in any direction in the direction (X-Y plane direction) orthogonal to the plug-unplug direction (Z axis direction), the connectivity of the shortcut coupling path is maintained.
Note that the following aspect may be adopted. The first elastic contact portion 73 of the shield member 70 may have the first contact portion 74 on the facing surface thereof on the side of the second outer mount portion 26a, and elastically come into contact with the upper surface of the second outer mount portion 26a on the side of the coaxial cable 40. Since the shield member 70 serving as the shortcut coupling path electrically couples the tip surrounding portion 16m of the first outer terminal 16 and the second outer mount portion 26a of the second connector 20 with a short distance, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
[Fifth Embodiment]
Referring to
As illustrated in
The bridge coupling portion 16s extends in a plate shape in the lateral direction (X axis direction) from the retaining portion 16e of the first outer contact portion 16b to the second outer contact portion 26b. One end portion of the bridge coupling portion 16s on the side of the tip surrounding portion 16m is sandwiched by the retaining portion 16e and the center conductor holding portion 12b of the first insulation member 12, and is crimped by the retaining portion 16e. With this, the bridge coupling portion 16s is fixed by the retaining portion 16e, and is electrically connected to the retaining portion 16e. The retaining portion 16e is crimped by the tip surrounding portion 16m, and is electrically connected to the tip surrounding portion 16m.
The other end portion of the bridge coupling portion 16s on the side opposite from the tip surrounding portion 16m (that is, the side of the second outer terminal 26) has a shape conforming to the outer shape of the second outer contact portion 26b, and serves as the contact portion 16t. For example, as illustrated in
The bridge coupling portion 16s is supported in a cantilever manner at the one end portion thereof on the side of the tip surrounding portion 16m, and therefore has an elastic urging force. The elastic urging force of the bridge coupling portion 16s acts in the plug-unplug direction (Z axis direction). The bridge coupling portion 16s having the contact portion 16t provides an elastic contact, and therefore provides a stable electrical coupling. Further, in a side view from the width direction (Y axis direction), a bent portion 16y bent in a stepped shape is provided to the bridge coupling portion 16s on the side of the tip surrounding portion 16m. With this, the elastic contact property and the electrical connectivity are improved.
The bridge coupling portion 16s couples the tip surrounding portion 16m and the second outer terminal 26 or the ground coupling portion 57 without using the outer conductor connection portion 16a, and is positioned closer to the circuit board 50 than the outer conductor connection portion 16a. The bridge coupling portion 16s, which is disposed between the tip surrounding portion 16m of the first connector 10 and the second outer contact portion 26b of the second connector 20 and is configured as a separate member, serves as the shortcut coupling path or the coupling portion coupling the tip surrounding portion 16m and the second outer contact portion 26b. Accordingly, since the second outer contact portion 26b and the tip surrounding portion 16m of the first outer terminal 16 are coupled with a short distance by the bridge coupling portion 16s serving as the shortcut coupling path or the coupling portion, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example). This is because the generation of the electrical potential difference between the tip surrounding portion 16m and the second outer contact portion 26b may be suppressed by the shortcut coupling path or the coupling portion.
Note that, in the above-described embodiment, the bridge coupling portion 16s formed of a separate member is crimped by the retaining portion 16e, and is electrically connected to the tip surrounding portion 16m using the retaining portion 16e. However, it is also possible to adopt a configuration in which the bridge coupling portion 16s formed of a separate member is directly electrically connected to the tip surrounding portion 16m. That is, it is also possible to adopt a configuration in which the bridge coupling portion 16s formed of a separate member is crimped by the tip surrounding portion 16m without using the retaining portion 16e and is electrically connected to the tip surrounding portion 16m. In this case, the bridge coupling portion 16s formed of a separate member serves as a coupling portion 16s coupling the tip surrounding portion 16m and the second outer terminal 26 or the ground coupling portion 57 without using the outer conductor connection portion 16a, and the bridge coupling portion 16s is positioned closer to the circuit board 50 than the outer conductor connection portion 16a. With this, since the bridge coupling portion 16s formed of a separate member couples the tip surrounding portion 16m of the first outer terminal 16 and the second outer terminal 26 or the ground coupling portion 57 of the circuit board 50 with a short distance, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Although specific embodiments of the present disclosure have been described, the present disclosure is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present disclosure.
The present disclosure and embodiments will be summarized as follows.
The ground coupling structure in the coaxial connector set 30 according to an aspect of the present disclosure is characterized as follows. In the coaxial connector set 30 including the first connector 10 to which the coaxial cable 40 having the center conductor 42 and the outer conductor 41 is connected and the second connector 20 mounted on the circuit board 50 having the ground coupling portion 57. The first connector 10 has the first outer terminal 16 connected to the outer conductor 41 and the second connector 20 has the second outer terminal 26 to be coupled to the first outer terminal 16. The first outer terminal 16 includes the outer conductor clamp portion 16c clamping the outer conductor 41, the first outer contact portion 16b to be coupled to the second outer terminal 26, and the tip surrounding portion 16m positioned between the outer conductor clamp portion 16c and the first outer contact portion 16b and surrounding the tip portion 42a of the center conductor 42. The second outer terminal 26 includes the second outer contact portion 26b to be coupled to the first outer contact portion 16b and the second outer mount portion 26a mounted on the ground coupling portion 57. The shortcut coupling paths 16s, 60, and 70 are formed between the tip surrounding portion 16m and the second outer terminal 26 or the ground coupling portion 57.
According to the configuration above, since the tip surrounding portion 16m of the first outer terminal 16 and the second outer terminal 26 or the ground coupling portion 57 of the circuit board 50 are coupled with a short distance by the shortcut coupling paths 16s, 60, and 70, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the shortcut coupling paths 16s and 70 are formed between the tip surrounding portion 16m and the second outer contact portion 26b.
According to the above-described embodiment, since the tip surrounding portion 16m and the second outer contact portion 26b are coupled with a short distance by the shortcut coupling paths 16s and 70, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the shortcut coupling path is formed between the tip surrounding portion 16m and the second outer mount portion 26a.
According to the above-described embodiment, since the tip surrounding portion 16m and the second outer mount portion 26a are coupled with a short distance by the shortcut coupling paths 16s and 70, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the interposing member 60 is disposed as the shortcut coupling path coupling the tip surrounding portion 16m and the ground coupling portion 57.
According to the above-described embodiment, since the tip surrounding portion 16m and the ground coupling portion 57 of the circuit board 50 are coupled with a short distance by the interposing member 60 functioning as the shortcut coupling path, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the tip surrounding portion 16m and the interposing member 60 are configured to elastically come into contact with each other.
According to the above-described embodiment, a stable electrical coupling of the interposing member 60 and the tip surrounding portion 16m is provided.
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the bridge coupling portion 16s is disposed as the shortcut coupling path coupling the tip surrounding portion 16m and the second outer contact portion 26b or the second outer mount portion 26a.
According to the above-described embodiment, since the tip surrounding portion 16m and the second outer contact portion 26b or the second outer mount portion 26a are coupled with a short distance by the bridge coupling portion 16s functioning as the shortcut coupling path, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the tip surrounding portion 16m and the bridge coupling portion 16s are configured to elastically come into contact with each other, or the second outer contact portion 26b or the second outer mount portion 26a and the bridge coupling portion 16s are configured to elastically come into contact with each other.
According to the above-described embodiment, a stable electrical coupling of the tip surrounding portion 16m and the bridge coupling portion 16s is provided, or a stable electrical coupling of the second outer contact portion 26b or the second outer mount portion 26a and the bridge coupling portion 16s is provided.
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the shield member 70 is disposed as the shortcut coupling path coupling the tip surrounding portion 16m and the second outer contact portion 26b or the second outer mount portion 26a.
According to the above-described embodiment, since the tip surrounding portion 16m and the second outer contact portion 26b or the second outer mount portion 26a are coupled with a short distance by the shield member 70 functioning as the shortcut coupling path, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the shield member 70 has the shield portion 72 covering the gap formed between the first outer contact portion 16b and the tip surrounding portion 16m.
According to the above-described embodiment, by covering the gap formed between the first outer contact portion 16b and the tip surrounding portion 16m with the shield portion 72, the noise go in and out of the gap may be reduced.
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the first connector 10 is an L-type coaxial connector.
According to the above-described embodiment, since the distance between the tip surrounding portion 16m of the first outer terminal 16 and the ground coupling portion 57 of the circuit board 50 is shortened, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
The ground coupling structure in the coaxial connector set 30 according to another aspect of the present disclosure is configured as follows. In the coaxial connector set 30 including the first connector 10 to which the coaxial cable 40 having the center conductor 42 and the outer conductor 41 is connected and the second connector 20 mounted on the circuit board 50 having the ground coupling portion 57. The first connector 10 has the first outer terminal 16 connected to the outer conductor 41 and the second connector 20 has the second outer terminal 26 to be coupled to the first outer terminal 16. The first outer terminal 16 includes the outer conductor clamp portion 16c clamping the outer conductor 41, the first outer contact portion 16b to be coupled to the second outer terminal 26, the tip surrounding portion 16m positioned between the outer conductor clamp portion 16c and the first outer contact portion 16b and surrounding the tip portion 42a of the center conductor 42, and the outer conductor connection portion 16a connecting the first outer contact portion 16b and the tip surrounding portion 16m. The second outer terminal 26 includes the second outer contact portion 26b to be coupled to the first outer contact portion 16b and the second outer mount portion 26a mounted on the ground coupling portion 57 of the circuit board 50. A coupling portion 16s coupling the tip surrounding portion 16m and the second outer terminal 26 or the ground coupling portion 57 without using the outer conductor connection portion 16a is provided. The coupling portion 16s is positioned closer to the circuit board 50 than the outer conductor connection portion 16a.
According to the above-described configuration, since the tip surrounding portion 16m of the first outer terminal 16 and the second outer terminal 26 or the ground coupling portion 57 of the circuit board 50 are coupled with a short distance by the coupling portion 16s, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the coupling portion 16s is formed between the tip surrounding portion 16m and the second outer contact portion 26b.
According to the above-described embodiment, since the tip surrounding portion 16m and the second outer contact portion 26b are coupled with a short distance by the coupling portion 16s, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the end portion of the coupling portion 16s on the side of the second outer contact portion 26b has a shape conforming to the outer shape of the second outer contact portion 26b.
According to the above-described embodiment, the other end portion of the coupling portion 16s is reliably electrically coupled to the second outer contact portion 26b.
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the second outer contact portion 26b has a circular shape as viewed from the plug-unplug direction (Z axis direction), and the end portion of the coupling portion 16s on the side of the second outer contact portion 26b has an arc shape as viewed from the plug-unplug direction (Z axis direction).
According to the above-described embodiment, the other end portion of the coupling portion 16s is reliably electrically coupled to the second outer contact portion 2b.
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the bent portion 16y is provided to the coupling portion 16s on the side of the tip surrounding portion 16m such that the end portion of the coupling portion 16s on the side of the second outer contact portion 26b elastically comes into contact with the second outer contact portion 26b.
According to the above-described embodiment, the elastic contact property and the electrical connectivity are improved.
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the coupling portion 16s is formed between the tip surrounding portion 16m and the second outer mount portion 26a.
According to the above-described embodiment, since the tip surrounding portion 16m and the second outer mount portion 26a are coupled with a short distance by the coupling portion 16s, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the interposing member 60 is disposed as the coupling portion 16s coupling the tip surrounding portion 16m and the ground coupling portion 57.
According to the above-described embodiment, since the tip surrounding portion 16m and the ground coupling portion 57 of the circuit board 50 are coupled with a short distance by the interposing member 60 functioning as the coupling portion 16s, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the tip surrounding portion 16m and the interposing member 60 are configured to elastically come into contact with each other.
According to the above-described embodiment, a stable electrical coupling of the interposing member 60 and the tip surrounding portion 16m is provided.
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the bridge coupling portion 16s is disposed as the coupling portion 16s coupling the tip surrounding portion 16m and the second outer mount portion 26a or the ground coupling portion 57.
According to the above-described embodiment, since the tip surrounding portion 16m and the second outer contact portion 26b or the second outer mount portion 26a are coupled with a short distance by the bridge coupling portion 16s functioning as the coupling portion 16s, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the tip surrounding portion 16m and the bridge coupling portion 16s are configured to elastically come into contact with each other, or the second outer mount portion 26a or the ground coupling portion 57 and the bridge coupling portion 16s are configured to elastically come into contact with each other.
According to the above-described embodiment, a stable electrical coupling of the tip surrounding portion 16m and the bridge coupling portion 16s is provided, or a stable electrical coupling of the second outer contact portion 26b or the second outer mount portion 26a and the bridge coupling portion 16s is provided.
Further, in the ground coupling structure in the coaxial connector set 30 of one embodiment, the first connector 10 is an L-type coaxial connector.
According to the above-described embodiment, since the distance between the tip surrounding portion 16m of the first outer terminal 16 and the ground coupling portion 57 of the circuit board 50 is shortened, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Further, the coaxial connector set 30 according to another aspect of the present disclosure is characterized in that the coaxial connector set 30 includes the first connector 10 to which the coaxial cable 40 having the center conductor 42 and the outer conductor 41 is connected and the second connector 20 capable of being fitted to the first connector 10. The first connector 10 includes the outer conductor clamp portion 16c clamping the outer conductor 41, the first outer contact portion 16b, the tip surrounding portion 16m positioned between the outer conductor clamp portion 16c and the first outer contact portion 16b and surrounding the tip portion 42a of the center conductor 42, and the outer conductor connection portion 16a connecting the first outer contact portion 16b and the tip surrounding portion 16m. The second connector 20 includes the second outer contact portion 26b. In a fitted state of the first connector 10 and the second connector 20, the first outer contact portion 16b and the second outer contact portion 26b are fitted to each other; and a coupling portion 16s coupling the tip surrounding portion 16m and the second outer contact portion 26b is formed.
According to the above-described configuration, since the tip surrounding portion 16m of the first connector 10 and the second outer contact portion 26b of the second connector are coupled with a short distance by the coupling portion 16s, stable signal transmission may be performed in a radio frequency band (megahertz band or gigahertz band, for example).
Number | Date | Country | Kind |
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2019-089868 | May 2019 | JP | national |
This application claims benefit of priority to International Patent Application No. PCT/JP2020/018712, filed May 8, 2020, and to Japanese Patent Application No. 2019-089868, filed May 10, 2019, the entire contents of each are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/JP2020/018712 | May 2020 | US |
Child | 17356159 | US |