The present invention relates to a socket contact to be connected to a counterpart pin contact and a connector having the socket contact.
A socket contact 10 has a cylindrical portion 11 that can be fitted onto a pin contact 20. The cylindrical portion 11 includes a base portion 12 provided on the opposite side of the front end to be fitted onto the pin contact 20, and a plurality of terminal pieces 13, arranged side by side at intervals in the circumferential direction of the cylindrical portion 11, that extend in the axial direction of the cylindrical portion 11 from the base portion 12 toward the pin contact 20. In addition, the base portion 12 is provided with a plurality of elasticity retaining pieces 14 that project in the radial direction of the cylindrical portion 11 toward the pin contact 20.
When the pin contact 20 is fitted to the socket contact 10, the pin contact 20 is inserted into the cylindrical portion 11 of the socket contact 10 and the plurality of terminal pieces 13 of the socket contact 10 is pressed apart by the pin contact 20. This brings the terminal pieces 13 into elastic contact with the outer peripheral surface of the pin contact 20 and makes an electric connection between the pin contact 20 and the socket contact 10. In addition, the elasticity retaining pieces 14 make contact or elastic contact with the outer peripheral surface of the pin contact 20 and hold the front end portion of the pin contact 20.
As described above, the conventional socket contact 10 makes an electric connection with the pin contact 20 by bringing the plurality of terminal pieces 13 into elastic contact with the pin contact 20 and holds the pin contact 20 by bringing the plurality of the elasticity retaining pieces 14 into contact or elastic contact with the pin contact 20.
Accordingly, the dimension of the inner diameter surrounded by the plurality of terminal pieces 13 is set smaller than the outer dimension (dimension of the outer diameter) of the pin contact 20 and the dimension of the inner diameter surrounded by the plurality of the elasticity retaining pieces 14 is set smaller than or equal to the dimension of the outer diameter of the pin contact 20.
When a higher contact force or retaining force is obtained to improve connection reliability in the conventional socket contact 10, the dimensions of the inner diameters surrounded by the plurality of terminal pieces 13 and the plurality of elasticity retaining pieces 14 need to be further reduced. Accordingly, when the pin contact 20 is inserted into the socket contact 10, a large force is necessary, thereby degrading connection operability.
The present invention addresses this problem with an object of providing a socket contact capable of connecting to a pin contact easily and obtaining a high contact force and a high retaining force and providing a connector having the socket contact.
The socket contact is connected to a counterpart pin contact. A first socket contact according to the present invention includes a cylindrical sleeve, a plurality of cantilever-shaped spring pieces arranged in rotational symmetry with respect to a central line of the sleeve as a symmetric axis, and a base portion to which fixed ends of the plurality of spring pieces are fixed. The sleeve is movably mounted to the base portion. The plurality of spring pieces has bent portions between free ends and the fixed ends. The plurality of spring pieces is elastically deformed so that the free ends come close to each other when the sleeve is moved and covers the free ends. The pin contact inserted among the plurality of spring pieces is sandwiched by the bent portions of the plurality of spring pieces elastically deformed by the moved sleeve, electrically connected, and held by the socket contact.
A second socket contact according to the present invention includes a cantilever-shaped spring piece, a base portion to which a fixed end of the spring piece is fixed, an opposed portion extended from the base portion and opposed to the spring piece, and a cylindrical sleeve movably mounted to the base portion. The spring piece has a bent portion between a free end and the fixed end. The spring piece is elastically deformed so that the free end comes close to the opposed portion when the sleeve is moved and covers the free end. The pin contact inserted between the spring piece and the opposed portion is sandwiched by the bent portion of the spring piece elastically deformed by the moved sleeve and the opposed portion, electrically connected, and held by the socket contact.
A connector according to the present invention includes the first or second socket contact of the present invention and a housing. The housing holds the socket contact. The housing is provided with a slider that moves in conjunction with the sleeve.
According to the present invention, when the sleeve is moved and covers the free end, the bent portion located between the free end and the fixed end of the elastically deformed spring piece is pushed against the inserted counterpart pin contact. Accordingly, a connection to the pin contact is easy and a high contact force and a high retaining force can be obtained by the principle of a lever.
Embodiments of the present invention will be described using examples with reference to the drawings.
The spring component 40 includes four cantilever-shaped spring pieces 41 and an annular joint portion 42. The four spring pieces 41 are arranged in rotational symmetry with respect to the central line of the annular joint portion 42 as a symmetric axis. In the example in
Each of the spring pieces 41 has a shape that extends from a fixed end 41a supported by the joint portion 42 along the central line of the joint portion 42, is slightly bent outside, and extends so that the bent end is turned back inside and returned to the vicinity of the fixed end 41a (see
The base portion 50 is cylindrical and one end side thereof is provided with projecting portions 51 recessed toward the inner peripheral side and projecting from the inner peripheral surface. The two projecting portions 51 are provided in each of four positions arranged at intervals of 90 degrees on the inner peripheral surface and the spacing between the two projecting portions 51 arranged along the central line of the base portion 50 matches the width along the central line of the joint portion 42 of the spring component 40.
The spring components 40 are mounted to the base portion 50 as illustrated in
The sleeve 60 has a cylindrical shape that is one size larger than the base portion 50. The socket contact 30 illustrated in
In this socket contact 30, the sleeve 60 is movable with respect to the base portion 50. When the sleeve 60 is moved, the sleeve 60 covers the free ends 41b of the four spring pieces 41 and elastically deforms the four spring pieces 41 so that the free ends 41b come close to each other. That is, coverage with the sleeve 60 reduces the dimension of the inner diameter surrounded by the free ends 41b of the four spring pieces 41. It should be noted that
The material of the spring component 40 may be, for example, a phosphor bronze plate and the material of the base portion 50 and the sleeve 60 may be, for example, stainless steel. Regarding the spring component 40, the joint portion 42 may be fixed to the base portion 50 by welding after the joint portion 42 is fitted between the projecting portions 51 of the base portion 50.
As illustrated in
The dimension d1 of the inner diameter surrounded by the free ends 41b of the four spring pieces 41, the dimension d2 of the inner diameter surrounded by the bent portions 41c, and the outer dimension (dimension of the outer diameter) D of the pin contact 70 have the following relationship.
D<d2<d1
Accordingly, the pin contact 70 can be inserted among the four spring pieces 41 with no insertion force in this example. That is, the pin contact 70 can be inserted with zero insertion force (ZIF). Alternatively, d2 may be slightly less than D when D is set to be less than d1. Also in this case, the pin contact 70 can be inserted with a slight insertion force. That is, the pin contact 70 can be inserted with low insertion force (LIF).
When the fixed ends 41a, the free ends 41b, and the bent portions 41c of the spring pieces 41 are assumed to be the fulcrums, the points of force, and the points of application of a lever, since the bent portions 41c are located between the free ends 41b and the fixed ends 41a, the bent portions 41c can be brought into contact with the pin contact 70 with a force larger than the force for displacing the free ends 41b based on the principle of a lever. Accordingly, a large contact force and a large retaining force can be obtained with a relatively small force for displacing the free ends 41b.
In addition, the front ends 41d of the spring pieces 41 make contact with the spring pieces 41 in this example, as described above. Accordingly, the bent portions 41c can hold the pin contact 70 using both of the force applied to the free ends 41b and the force applied to the front ends 41d. Accordingly, it is possible to obtain the socket contact 30 that has better connection reliability and better connection operability and can be connected to the pin contact 70 with a low operational force.
The counterpart connector 200 includes the two pin contacts 70 and a housing 210 which is made of resin and houses the pin contacts 70. The housing 210 is provided with a fitting hole 211 to which the fitting portion 111 of the connector 100 is fitted and the two pin contacts 70 are disposed in this fitting hole 211. In this example, the counterpart connector 200 also has screwing holes 212 used for screwing to the cabinet. Although not illustrated in detail, the pin contacts 70 may have a shape that allows crimp terminals crimped to cables to be screwed from the lower surface side of the housing 210.
In the connector 100, the sleeves 60 of the two socket contacts 30 may be moved in conjunction with the sliding movement of the slider 120. The sleeves 60 of the socket contacts 30 are provided with projections 61 as illustrated in
When, for example, the connector having the socket contact 30 is a one-contact connector, the sleeve 60 may be moved by directly operating the projection 61 provided on the sleeve 60 as illustrated in
The socket contact in the second embodiment has a contact component 80 obtained by integrally forming the spring component 40 and the base portion 50 in the first embodiment. That is, a socket contact 30′ includes the contact component 80 and the sleeve 60.
The contact component 80 may have a shape as illustrated in
It should be noted that the shape of the sleeve 60 is not limited to a cylinder and may be a hollow column having a polygonal cross section. In addition, the outer shape of the sleeve 60 may be asymmetric. In addition, although the socket contacts 30 and 30′ in the first embodiment and the second embodiment have the four spring pieces 41, the number of spring pieces 41 is not limited to four. For example, the two spring pieces 41 may be arranged in twofold symmetry positions or the three spring pieces 41 may be arranged in threefold symmetry positions with respect to the central line of the sleeve 60 as a symmetric axis. The outer shape of the pin contact 70 is not limited to a cylinder and may be a column having a polygonal cross section.
The socket contact 30″ has a contact component 90 and a sleeve 65.
The base portion 91 is shaped like a flat column with a substantially rectangular cross section and the spring piece 41 is extended from an upper surface portion 91a thereof. It should be noted that an extension piece 93 is extended from the upper surface portion 91a on the side of the upper surface portion 91a opposite to the spring piece 41. The opposed portion 92 is extended from a lower surface portion 91b of the base portion 91. Side wall portions 94 and 95 are provided on both sides in the width direction of the opposed portion 92. The side wall portions 94 and 95 are formed by extending side surface portions 91c and 91d of the base portion 91.
The sleeve 65 is shaped like a flat column with a substantially rectangular cross section one size larger than in the base portion 91. The sleeve 65 is mounted to the outside of the base portion 91 so as to be movable with respect to the base portion 91. The sleeve 65 elastically deforms the spring piece 41 when the sleeve 65 moves and covers the free end 41b of the spring piece 41, as the sleeve 60 in the first embodiment. At this time, the spring piece 41 is elastically deformed so that the free end 41b comes close to the opposed portion 92. The material of the contact component 90 may be, for example, a phosphor bronze plate and the contact component 90 may be formed by bending the phosphor bronze plate. The material of the sleeve 65 may be, for example, stainless steel.
T<d4<d3
Alternatively, d4 may be equal to or slightly less than T when T is set to be less than d3. It should be noted that T, d3, and d4 are indicated in
When the sleeve 65 is moved, the spring piece 41 is elastically deformed and the free end 41b comes close to the opposed portion 92. The pin contact 75 inserted between the spring piece 41 and the opposed portion 92 is sandwiched and held by the bent portion 41c of the elastically deformed spring piece 41 and the opposed portion 92 as illustrated in
Since the spring piece 41 in the socket contact 30″ also functions as the spring piece 41 in the first embodiment, the connection reliability and connection operability have good characteristics.
Although the spring piece of the socket contact suitably has a shape that is turned back inside from the free end 41b so that the front end 41d is returned to the fixed end 41a as described above, the shape of the spring piece 41 is not limited to this. A shape other than this may have a certain level of effects. For example, the spring piece may have a shape in which a turnback is not present at the free end, the free end is the front end, and the bent portion in contact with the pin contact is provided between the free end and the fixed end. In this case, a V-shape projecting toward the pin contact by the bent portion may be formed by the whole spring piece 41.
The foregoing description of the embodiments of the invention has been presented for the purpose of illustration and description. It is not intended to be exhaustive and to limit the invention to the precise form disclosed. Modifications or variations are possible in light of the above teaching. The embodiment was chosen and described to provide the best illustration of the principles of the invention and its practical application, and to enable one of ordinary skill in the art to utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. All such modifications and variations are within the scope of the invention as determined by the appended claims when interpreted in accordance with the breadth to which they are fairly, legally, and equitably entitled.
Number | Date | Country | Kind |
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2019-184700 | Oct 2019 | JP | national |
The present application is a divisional application of U.S. patent application Ser. No. 16/918,417, filed Jul. 1, 2020, which claims the benefit of Japanese Patent Application No. 2019-184700, filed Oct. 7, 2019. The disclosure of each of the above-mentioned applications is expressly incorporated herein by reference in its entirety.
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Number | Date | Country | |
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Parent | 16918417 | Jul 2020 | US |
Child | 17832125 | US |