Patent Grant
9276364
1. Field of the Invention
The invention relates to a receptacle connector including a central terminal mechanically and electrically connecting with a core wire of a coaxial cable connected to a plug connector, and an outer terminal mechanically and electrically connecting with an external conductor surrounding the core wire with an internal electrical-insulator being sandwiched therebetween.
The invention relates further to a terminal used for the receptacle connector.
2. Description of the Related Art
As one of connectors used for connecting a coaxial cable to a printed circuit board, there is known a receptacle connector into which a plug connector connected to a coaxial cable is fit. A receptacle connector is used for transmission of video-camera signals, and transmission of signals for connecting an antenna used for radio-signal communication such as to a printed circuit board, for instance. A coaxial cable having a diameter of about 0.5 mm is connected to a receptacle connector. Various receptacle connectors have been suggested as follows.
The illustrated receptacle connector 1000 includes a central terminal 1001, and an external terminal 1002 located around the central terminal 1001 in electrically insulating condition with the central terminal 1001.
The central terminal 1001 stands at a distal end 1004 of a plate-shaped connector 1003. The external terminal 1002 not entirely, but partially surrounds the central terminal 1001. The connector 1003 includes a strip 1005 having a first portion 1005A located closer to the distal end 1004, and a second portion 1005B located away from the distal end 1004. The first portion 1005A is smaller in width than the second portion 1005B. The strip 1005 is connected at the second portion B to a strip line 1007 formed on a surface of a circuit board 1006. As illustrated in
The illustrated receptacle connector 1100 includes a housing 1101 made from an electrically insulating plate and having a substantially rectangular cross-section, a central terminal 1102, and an external terminal 1103. The central terminal 1102 and the external terminal 1103 are fixed to the housing 1101 by insert molding such that they are coaxial with each other. The central terminal 1102 is solid, and the external terminal 1103 is in the form of a cylinder such that the central terminal 1102 is located at a center of the external terminal 1103. Contact supports 1104 and 1105 extend almost horizontally in the housing 1101 along a lower surface of the housing 1101. The contact supports 1104 and 1105 have lower surfaces extending on a level with a lower surface of the housing 1101, and exposed downwardly.
In the receptacle connector 1000 illustrated in
If the connector 1003 extends below the external terminal 1002, even if an impedance were adjusted between the first and second portions 1005A and 1005B, a capacitance to be generated between the external terminal 1002 and the central terminal 1001 would exert harmful influence on the impedance adjustment.
An electric connector used for connecting a coaxial cable with a printed circuit board is recently required to be smaller and smaller in size, and hence, a distance between the external terminal 1002 and the central terminal 1001 is smaller and smaller. Thus, the impedance adjustment becomes more and more difficult.
In view of the above-mentioned problem in the conventional electric connectors, it is an object of the present invention to provide a receptacle connector capable of readily carrying out the above-mentioned impedance adjustment, and further, of being down-sized.
It is further an object of the present invention to provide a terminal used for the above-mentioned receptacle connector.
In one aspect of the present invention, there is provided a receptacle connector including a central terminal mechanically and electrically connecting with a core wire of a coaxial cable connected to a plug connector, and an outer terminal mechanically and electrically connecting with an external conductor surrounding the core wire with an internal electrical-insulator being sandwiched therebetween, the central terminal including a first contact making contact with the core wire, and a second contact electrically connected to the first contact, passing through under the outer terminal and extending to the outside of the outer terminal, the second contact being formed with at least one of a cut-out and an opening in an area where the second contact overlaps the outer terminal.
In the receptacle connector in accordance with the present invention, a cut-out and/or an opening is(are) formed in an area where the second contact overlaps the outer terminal. Thus, an area in which the outer terminal and the second contact face each other can be reduced, ensuring that a capacitance defined by an area in which the outer terminal and the second contact face each other can be reduced.
It is preferable that the second contact is formed at one of side edges or both of side edges thereof with the cut-out.
Even if the second contact had a small width, a cut-out can e formed at a side edge or side edges.
It is preferable that the area is thinner than other areas.
By designing the area to be thinner than other areas, a distance between the outer terminal and the second contact can be increased, even if the outer terminal and the second contact had to be located close to each other because of the necessity of designing the receptacle connector to be low in height.
For instance, the second contact may be formed on at least one of upper and lower surfaces thereof in the area with a recess.
It is preferable that the outer terminal is formed with a recess in an area facing the second contact.
A distance between the outer terminal and the second contact can be increased, even if the outer terminal and the second contact had to be located close to each other because of the necessity of designing the receptacle connector to be low in height.
It is preferable that the outer terminal is ring-shaped coaxially with the central terminal.
By designing the outer terminal to be ling-shaped, the outer terminal can have an increased area with which the outer terminal makes contact with a TO plug connector. Furthermore, since the central terminal and the outer terminal are located coaxial with each other, electric relation between the central terminal and the outer terminal can be enhanced, and reliability to electrical connection between the receptacle connector and a plug connector can be enhanced. Since the second contact is designed to be formed with a cut-out and/or an opening in an area in which the second contact overlaps the outer terminal, even if the second contact extends in any direction, a capacitance defined by an area in which the second contact and the outer terminal overlap each other can be reduced.
In another aspect of the present invention, there is provided a terminal electrically connecting with a coaxial cable including a core wire, and an external conductor surrounding the core wire with an internal electrical-insulator being sandwiched therebetween, the terminal being mechanically and electrically connected to the core wire, and being used together with a second terminal mechanically and electrically connected to the external conductor, the terminal including a first contact making contact with the core wire, and a second contact being in the form of a plate, the second contact having a length sufficient to pass through under said second terminal and extend to the outside of the second terminal when the terminal is used together with the second terminal, the second contact being formed with at least one of a cut-out and an opening in an area where the second contact overlaps the second terminal.
The advantages obtained by the aforementioned present invention will be described hereinbelow.
A capacitance defined by an area in which the second contact and the outer terminal overlap each other can be reduced by means of the cut-out and/or the opening formed at the second contact. Accordingly the impedance adjustment can be readily accomplished, and further, the receptacle connector can be readily down-sized.
The above and other objects and advantageous features of the present invention will be made apparent from the following description made with reference to the accompanying drawings, in which like reference characters designate the same or similar parts throughout the drawings.
Preferred embodiments in accordance with the present invention will be explained hereinbelow with reference to drawings.
The receptacle connector 10 includes a housing 20, a central terminal 30, and an outer terminal 40.
The housing 20 is rectangular when viewed vertically. The central terminal 30 and the outer terminal 40 are fixed on the housing 20 by insert molding such that the outer terminal 40 is located around a center of a later-mentioned first contact of the central terminal 30.
As illustrated in
As illustrated in
As illustrated in
The cut-outs 33b are formed at opposite sides of the second contact 33. The cut-out 33b may be formed at one of sides of the second contact 33.
The outer terminal 40 includes an annular terminal 41 to make mechanical and electrical contact with to plug connector, and an outer contact 42 obliquely and downwardly extending from the annular terminal 41 towards a printed circuit board (not illustrated).
The annular terminal 41 is coaxial with the first contact 31. The annular terminal 41 is cylindrical and open at opposite ends. As illustrated in
The outer contact 42 includes a first contact portion 43 extending from the annular terminal 41 in a direction opposite to the direction in which the second contact 33 extends, and a pair of second contact portions 44 extending from a bottom of the annular terminal 41 and located facing each other.
Each of the first and second contact portions 43 and 44 includes a leg 43a, 44a obliquely and downwardly extending towards a printed circuit board (not illustrated), and a contact 43b, 44b making mechanical and electrical contact with a metal pad mounted on a printed circuit board. The contact 43b has a with equal to the same of the leg 43a. The contact 44b has a width almost equal to a diameter of the annular terminal 41, as illustrated in
The cut-outs 33b of the second contact 33 are explained in detail hereinbelow.
The second contact 33 extends below and beyond the annular terminal 41, of the outer terminal 40 from the first contact 21, and is exposed externally of the annular terminal 41. Since the first contact 31 passes below the annular terminal 41, there is formed an area in which the first contact 33 and the annular terminal 41 face each other. A capacitance defined in the area exerts harmful influence on the impedance adjustment between the receptacle connector 10 and a coaxial cable connected to a plug connector.
In the receptacle connector 10 in accordance with the first embodiment, the second contact. 33 is formed with the cut-outs 33b at an area in which the second contact 33 faces the annular terminal 41 of the outer terminal 40. The cut-outs 33b formed at the second contact 33 reduce an area in which the second contact 33 faces the annular terminal 41 of the outer terminal 40, and thus, a capacitance defined with the area can be reduced.
Accordingly, it is possible to adjust the impedance between the outer terminal 40 and the central terminal 30 by controlling a width and/or a length of the cut-outs 33b, and hence, the impedance adjustment between the receptacle connector 10 and a coaxial cable connected to a plug connector can be preferably accomplished.
Furthermore, since the cut-outs 33b are formed only in an area in which the second contact 33 faces the annular terminal 41, the cutouts 33b exert almost no or merely a slight influence on parameters defining an impedance between the second contact 33 and the annular terminal 41. When a receptacle connector not including the cut-outs 33b is designed to be low in height, and hence, down-sized entirely, the first contact 33 and the annular terminal 41 cannot avoid from being situated in the vicinity of each other, resulting in that a capacitance defined with an area in which the first contact 33 and the annular terminal 41 face each other unavoidably increases. However, by designing the second contact 33 to have the cut-outs 33b, it is possible to prevent the capacitance from increasing. Accordingly, even if the receptacle connector 10 is designed to be down-sized or low in height to thereby cause the first contact 33 and the annular terminal 41 of the outer terminal 40 to be located close to each other, the impedance adjustment between the first contact 33 and the annular terminal 41 can be preferably accomplished by means of the cut-outs 33b. Thus, the receptacle connector 10 is capable of readily accomplishing the above-mentioned impedance adjustment, and further, being down-sized.
Since the cut-outs 33b are formed at the opposite sides of the second contact 33, even if the second contact 33 had a small width, the cut-out or cut-outs 33b can be surely formed at the second contact 33.
Since the annular terminal 41 is formed with the recess 41b at an area in which the annular terminal 41 faces the second contact 33, a gap between the annular terminal 41 and the second contact 33 can be sufficiently lengthy, even if the annular terminal 41 is designed to be low in height, and hence, the annular terminal 41 and the second contact 33 are unavoidably located close to each other.
In the receptacle connector 10 in accordance with the first embodiment, the annular terminal 41 is located entirely around the first projection 31. In the receptacle connector 1000 illustrated in
The second contact 33 of the central terminal 30x in the second embodiment, illustrated in
Furthermore, even if a shearing force acts on the second contact 33 in a widthwise direction across the opposite ends located in a length-wise direction, it is possible to avoid reduction in a strength in comparison with the second contact 33 formed with the cut-outs 33b, because the opening 33c reduces an area in which the second contact 33 overlaps the annular terminal 41.
The second contact 33 may be designed to be formed with both the opening 33c and the cut-outs 33b.
The second contact 33 of the central terminal 30y in the third embodiment, illustrated in
Since the second contact 33 is formed with the recessed portion 33d as well as the cut-outs 33b, it is possible to reduce an area in which the second contact 33 faces the annular terminal 41, and to make a gap between the annular terminal 41 and the second contact 33 sufficiently lengthy, even if the annular terminal 41 is designed to be low in height, and hence, the annular terminal 41 and the second contact 33 are unavoidably located close to each other. Thus, the receptacle connector can be designed to be further down-sized or low in height to such a degree as an increase in the gap caused by the recessed portion 33d.
The recessed portion 33d is formed by reducing a thickness at upper and lower surfaces of the second contact 33 in the third embodiment. It should be noted that the recessed portion 33d may be formed by reducing a thickness at one of upper or lower surfaces of the second contact 33.
The receptacle connector in accordance with the third embodiment is designed to include both the cut-outs 33b and the recessed portion 33d. As an alternative, the receptacle connector may be designed to include both the openings 33c (see
The receptacle connector in accordance with the present invention can be used in an electric connector to be employed in fields such as an electric/electronic device industry and an automobile industry, as a part to be fit into a plug connector to mechanically and electrically connect with the plug connector.
While the present invention has been described in connection with certain preferred embodiments, it is to be understood that the subject matter encompassed by way of the present invention is not to be limited to those specific embodiments. On the contrary, it is intended for the subject matter of the invention to include all alternatives, modifications and equivalents as can be included within the spirit and scope of the following claims.
The entire disclosure of Japanese Patent Application No. 2013-233291 filed on Nov. 11, 2013 including specification, claims, drawings and summary is incorporated herein by reference in its entirety.
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| 2013-233291 | Nov 2013 | JP | national |
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