The present invention relates to an outer conductor terminal and a shield connector.
Patent Document 1 discloses a shield terminal with an inner conductor terminal, an outer conductor terminal surrounding the outer periphery of the inner conductor terminal and a dielectric interposed between the outer conductor terminal and the inner conductor terminal. Patent Document 1 also discloses a shield connector with the shield terminal and a connector housing for accommodating the shield terminal. The outer conductor terminal is composed of an outer conductor terminal body for covering the inner conductor terminal, and a lid body for covering a back surface side of the outer conductor terminal body. The outer conductor terminal body includes base plate assembly tabs projecting downward on four corners. The lid body is fit to a rear part of the outer conductor terminal body from outside.
In the above case, a special lock structure is not provided between the lid body and the outer conductor terminal body. However, a lock structure is preferably provided to ensure further reliability in retaining the shape of the outer conductor terminal. Such a structure that the lid body is formed with a U-shaped slit, an inner part of the slit is bent inward to form a projection and the outer conductor terminal body is formed with a locking edge to be locked to the projection with the outer conductor terminal body covered with the lid body is, for example, considered as a lock structure of this type.
However, a return current in response to an electrical signal transmitted by the inner conductor terminal is generated in the outer conductor terminal and flows to a ground pattern of a circuit board via the base plate assembly tabs. Thus, a path of the return current may be blocked by the U-shaped slit formed in the lid body. If the return current flows to an outer surface side (surface side) of the outer conductor terminal through the U-shaped slit, a problem occurs in which the return current becomes a new noise source.
The present invention was completed on the basis of the above situation and aims to provide an outer conductor terminal capable of ensuring a good shielding property and a shield connector using the outer conductor terminal.
The present invention is directed to an outer conductor terminal with a terminal body capable of surrounding an outer periphery of an inner conductor terminal, a back plate portion for closing a back surface opening of the terminal body in a closed state by being displaced from an open state to the closed state with respect to the terminal body, and a side plate portion connected to the back plate portion, the side plate portion constituting a part of a side surface part of the terminal body in the closed state, wherein the back plate portion includes a board connecting piece projecting toward a circuit board and to be electrically connected to the circuit board, and the side plate portion includes a linear slit extending toward the circuit board and a locking portion bent via the slit, the locking portion holding the back plate portion in the closed state by locking the body portion.
Since both the board connecting piece of the back plate portion and the slit of the side plate portion are formed to extend toward the circuit board, it can be prevented that a path of a return current flowing to a ground pattern of the circuit board through the board connecting piece is blocked by the slit, and the leakage of the return current to an outer surface side of the outer conductor terminal through the slit can be hindered. As a result, noise can be reliably emitted to the ground pattern and good shielding performance can be exhibited.
Preferred embodiments of the present invention are described below.
(1) The board connecting piece is capable of contacting along a surface of the circuit board. If the board connecting piece is for surface mounting in this way, assemblability with the circuit board can be improved. Further, since the board connecting piece is provided on the back plate portion, a part capable of contacting along the surface of the circuit board can be easily formed by bending.
(2) A shield connector using the outer conductor terminal having the above configuration is provided with a shield terminal including the outer conductor terminal, the inner conductor terminal and a dielectric interposed between the outer conductor terminal and the inner conductor terminal, and a connector housing for accommodating the shield terminal. According to the above configuration, a good shielding property can be realized, wherefore this shield connector is suitably used, for example, as a shield connector for high speed communication of an automotive vehicle.
Hereinafter, one embodiment is described with reference to the drawings. A shield connector 10 mounted in an unillustrated vehicle such as an electric or hybrid vehicle and used for high speed communication between in-vehicle electrical components is shown in this embodiment. This shield connector 10 is mounted on a surface of a circuit board 90 as shown in
As shown in
The inner conductor terminal 21 is formed, such as by bending a conductive metal plate. The inner conductor terminal 21 includes a tab 24 projecting forward. The tab 24 is electrically connected to an unillustrated mating terminal fitting provided in a mating connector when the shield connector 10 is connected to the unillustrated mating connector. The inner conductor terminal 21 includes one connecting piece 25 bent downward at an intermediate position in a length direction and further extending rearward from a lower end part. The connecting piece 25 is in contact with and electrically connected to a conductive pattern (conductive path) for signal transmission formed on the surface of the circuit board 90.
The dielectric 23 is made of an insulating synthetic resin material having a predetermined relative permittivity and includes a terminal accommodation chamber 26 penetrating in the front-rear direction inside. The inner conductor terminal 21 is accommodated in the terminal accommodation chamber 26. The inner conductor terminal 21 is held in the dielectric 23 with the tab 24 projecting forward from a front end opening of the terminal accommodation chamber 26. The inner conductor terminal 21 and the outer conductor terminal 22 are kept insulated from each other by the dielectric 23.
The outer conductor terminal 22 is formed, such as by bending a conductive metal plate. The outer conductor terminal 22 is composed of a tubular portion 27 penetrating in the front-rear direction and a back unit 28 arranged behind the tubular portion 27. A specific structure of the outer conductor terminal 22 is described in detail later.
The connector housing 60 is made of synthetic resin and includes, as shown in
As shown in
The base wall portion 61 includes a mounting hole 65 having a substantially circular cross-section and penetrating in the front-rear direction (wall thickness direction) at a position slightly below a vertical center in a lateral center. The tubular portion 27 of the outer conductor terminal 22 is inserted into the mounting hole 65 of the base wall portion 61. The outer conductor terminal 22 is mounted into the connector housing 60 with a front part of the tubular portion 27 projecting into the receptacle 62 and the back unit 28 exposed behind the base wall portion 61 (see
The tubular portion 27 of the outer conductor terminal 22 has a circular tube shape (tube shape having a circular cross-section) and includes, as shown in
As shown in
As shown in
A space below the coupling portion 39 and the lock receiving portions 41 and behind the tubular portion 27 serves as a space portion 36 which is open downward and rearward when the back plate portion 43 is in an open state and is open downward when the back plate portion 43 is in a closed state.
As shown in
As shown in
The back plate portion 43 is rotationally displaceable via the fulcrum portion 42 with respect to the coupling portion 39 to the open state (see
As shown in
As shown in
As shown in
Next, functions and effects of this embodiment are described.
When the back plate portion 43 is in the open state, the dielectric 23 carrying the inner conductor terminal 21 is inserted into the outer conductor terminal 22. Subsequently, the back plate portion 43 is rotationally displaced from the open state to the closed state via the fulcrum portion 42. In the process of displacing the back plate portion 43 to the closed state, the locking portions 54 of the both side plate portions 44 interfere with the corresponding lock receiving portions 41 and the both side plate portions 44 are expanded and deformed (resiliently deformed) with parts coupled to the back plate portion 43 as fulcrums.
When the back plate portion 43 reaches the closed state, a back surface opening of the terminal body 45 is closed by the back plate portion 43 and the both resiliently returned side plate portions 44 cover the entire corresponding lock receiving portions 41 from outside to constitute parts of side surface parts of the terminal body 45. Further, the locking portions 54 of the both side plate portions 44 lock the corresponding lock receiving portions 41 and the locking edges 56 of the locking portions 54 come into contact with the lock receiving edges 47 of the lock receiving portions 41 (see
When the back plate portion 43 is in the closed state, front end lower parts of the lock receiving portions 41 are facing upper parts of the slits 53 of the side plate portions 44 and the front ends of the side plate portions 44 are vertically arranged along the rear end of the tubular portion 27 in a side view.
Subsequently, the outer conductor terminal 22 is inserted into the mounting hole 65 of the base wall portion 61 of the shield connector 10 to be assembled. Thereafter, the shield connector 10 is disposed on the surface of the circuit board 90. In this way, the connecting piece 25 is conductively connected to a conductive pattern formed on the surface of the circuit board 90 and the connecting tip parts 52 of the both board connecting pieces 49 are conductively connected to the ground pattern formed on the surface of the circuit board 90. Here, the both board connecting pieces 49 are arranged at both left and right sides of the connecting piece 25 (see
If an electrical signal flows in the inner conductor terminal 21, a return current in response to the electrical signal is generated in the outer conductor terminal 22. The return current flows from the coupling portion 39 to the circuit board 90 through the back plate portion 43 along the inner surface of the outer conductor terminal 22, and is dropped to the ground pattern of the circuit board 90 via the both board connecting pieces 49.
In this case, the slits 53 formed as the locking portions 54 are bent linearly extend along the vertical direction, which is a flowing direction of the return current toward the circuit board 90, similarly to the connecting base end parts 51 of the both board connecting pieces 49. Thus, the slits 53 do not substantially impede the flow of the return current. Further, if the slits 53 are shaped to linearly extend in the vertical direction, the leakage of the return current to the outer surface side of the outer conductor terminal 22 can be reduced and noise emitted to the outside of the shield connector 10 can also be reduced.
As described above, since the both board connecting pieces 49 of the back plate portion 43 and the slits 53 of the both side plate portions 44 are all formed to extend toward the circuit board 90 according to this embodiment, it can be prevented that a path of the return current is blocked by the slits 53 when the return current flows to the ground pattern of the circuit board 90 through the both board connecting pieces 49 and the leakage of the return current to the outer surface side of the outer conductor terminal 22 through the slits 53 can be hindered. As a result, noise can be reliably discharged to ground and good shielding performance can be exhibited.
Further, since the board connecting pieces 49 are for surface mounting by including the connecting tip parts 52 capable of contacting along the surface of the circuit board 90, assemblability with the circuit board 90 can be improved. Further, since the board connecting pieces 49 are provided on the back plate portion 43, the connecting tip parts 52 of the board connecting pieces 49 can be easily formed by bending.
Other embodiments are briefly described below.
(1) The tubular portion of the outer conductor terminal may be in the form of a rectangular tube. Further, the tubular portion may be shaped to be open on the circuit board side.
(2) The number of the board connecting pieces is arbitrary. One, three or more board connecting pieces may be provided.
(3) The back plate portion may be constituted by a separate member removable from the terminal body.
(4) The board connecting pieces may be of a through hole type that are formed along the vertical direction as a whole and inserted into through holes of the circuit board to be connected.
Number | Date | Country | Kind |
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JP2018-064187 | Mar 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/013725 | 3/28/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/189629 | 10/3/2019 | WO | A |
Number | Name | Date | Kind |
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4580858 | Daberkoe | Apr 1986 | A |
10566741 | Maesoba | Feb 2020 | B2 |
Number | Date | Country |
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2005-209423 | Aug 2005 | JP |
2008-192474 | Aug 2008 | JP |
2011-049118 | Mar 2011 | JP |
Entry |
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International Search Report dated May 14, 2019 for WO 2019/189629 A1 (4 pages). |
Number | Date | Country | |
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20210028584 A1 | Jan 2021 | US |