The subject of the present invention is a connector for a printed circuit board.
The invention applies for example to a coaxial connector produced according to the FAKRA (Standards Commission for the Automotive Industry) standardization scheme.
In the context of the invention, a “coaxial connector according to the FAKRA standardization scheme” denotes a coaxial connector comprising a body, the mechanical dimensions of which in an axial cross section of said body, cooperating with the body of a complementary connector in order to establish a mechanical connection between the two bodies, are defined in the DIN 72594-1 standard. Such connectors are generally used in the automotive field for data transmission cables.
The invention may also apply to connectors for high rate transmission circuits (LVDS).
In the example shown in
Because of the way the body 2 is produced by machining or casting, such a connector is relatively expensive.
It is known to reduce the cost of manufacturing the parts, and especially the body, of a connector using what is called the “cut-and-rolled” technique. However, a connector body produced using this technique and having a small thickness, so as to meet the abovementioned constraints of the connection interface, would be too fragile owing to the abovementioned stresses exerted on said body.
There is a need to benefit from a connector comprising elements that can be manufactured for a reduced cost, while still being sufficiently robust.
The connector disclosed by the utility model US D456 355 S teaches the provision of a connector with an armature for taking up the tensile forces. This connector is a straight connector specific for “board edge” fitting, having a central contact extending in a plane parallel to that of the printed circuit board. The fitting of such a connector to the printed circuit board then requires a cavity to be provided in the board for accommodating the body of the connector. The benefit of such a connector may thus be limited by the constraints associated with its fitting and also by the use of an EMI (electromagnetic interference) shield.
There is a need to remedy the drawbacks of the known connectors according to
The aim of the invention is to meet this need and it succeeds in doing so, according to one of its aspects, by a connector comprising:
a body;
at least one contact accommodated in the body with an insulator being interposed;
a casing defining a housing designed to accommodate all or part of the body; and
an armature placed around at least one portion of the casing, at least one portion of the body being accommodated in said portion of the casing, the armature having feet for fastening the connector to a printed circuit board, wherein said feet project beyond that portion of the casing around which the armature is placed.
Thanks to the presence of the armature, the mechanical forces are taken up with the printed circuit board by the casing and the armature. Thus, the tensile forces on the casing are transmitted to the armature but not to the body of the connector.
The connector obtained may be an SMC (surface mount component) connector of the “pin-in-paste” type (that is to say one using solder paste for melt-soldering the components) or else of the “wave soldering” type.
The armature may be made of metal, especially brass or bronze, especially made as a single piece, in particular using the “cut-and-rolled” technique. In this way it is possible to reduce the cost of manufacturing the parts, despite the small thickness obtained since the forces are taken up over the entirety of the armature.
Advantageously, the casing is made of a plastic, for example a polyamide filled with glass fibers. The casing extends for example along a straight longitudinal axis.
The armature may comprise at least one contact arm extending beyond that portion of the casing around which the armature is placed. This contact arm may allow an electrical contact to be produced between the armature and one or more chassis located close to the connector.
The armature may have a substantially U-shaped cross section. The armature may thus comprise a back and two flanges. That portion of the casing around which the armature is placed may be of rectangular cross section, the armature especially extending only along all or part of three sides of this portion of the casing. The armature may be sandwiched in a groove of the casing or between two walls (or ends) of the casing. This configuration may allow the forces to be taken up by the armature.
According to a first embodiment of the invention, the connector is an elbow connector, that is to say it extends along two intersecting axes, especially perpendicular axes. One of the axes of the connector may correspond to the longitudinal axis of the casing.
The back of the armature may have at least one relief cooperating with a complementary relief provided by the face of the portion of the casing which is intended to be covered by the back. The armature includes for example a cavity and said face of the casing then includes a projecting portion, such as a key, designed to be accommodated in the cavity. As a variant, the armature has a projecting portion, such as a key, and said face of the casing includes a cavity into which the projecting portion of the armature is accommodated.
These complementary reliefs of the armature and of said face of the casing may promote retention by the armature of the connector on the printed circuit board on which it is mounted when a tensile force is exerted on the casing. Such a tensile force, together with the position of the center of gravity of the connector, not facing the printed circuit board, is capable of mainly tilting the casing relative to this printed circuit board.
Furthermore, these complementary reliefs may constitute polarizing means between the armature and the casing, so as to ensure that a given armature is properly mounted on the appropriate casing. These complementary reliefs may be of any dimension and shape and there may be any number thereof.
The armature may include a portion closing off a longitudinal end of the casing. By virtue of such a portion of the armature, high-frequency shielding is possible when the connector is fastened to the printed circuit board, the connector being imprisoned inside the casing.
According to this first embodiment of the invention, the feet of the armature may extend generally perpendicular to the longitudinal axis of the casing. The term “generally perpendicular” means that these feet may either include at least one part perpendicular to the longitudinal axis of the casing or include at least one curved part extending on either side of an axis perpendicular to the longitudinal axis of the casing. In the latter case, the thickness of the feet may be small enough to give them a flexible character and the curved part may promote retention of the armature on the printed circuit board, and therefore of the connector, despite forces exerted thereon and despite the position of the center of gravity thereof.
The armature may further include feet having a part perpendicular to the longitudinal axis of the casing and feet having a curved part extending on either side of an axis perpendicular to the longitudinal axis of the casing. The feet with the curved part may be the feet furthest away from the end of the casing, namely the end intended to be connected to a casing of a complementary connector.
According to a second embodiment of the invention, the connector is straight, that is say it extends only along a single axis, especially the longitudinal axis of the casing, and the feet of the armature extend parallel to said longitudinal axis of the casing.
The armature may include at least one tongue, and at least one catching foot may be provided on the outer surface of the body, it being possible for said tongue and said foot to be designed to keep the body in place in the casing.
As a variant, the casing comprises at least one tongue, and at least one catching foot is provided on the outer surface of the body, said tongue and said foot being designed to keep the body in place in the casing.
In the above two embodiments of the invention, the casing may extend longitudinally on either side of said armature, that is to say beyond each longitudinal end thereof. The armature may be placed in a set-in manner relative to the casing. In particular, the armature may be located longitudinally between at least two parts of the casing. This configuration may allow the tensile forces to be taken up along the axis of the body.
Yet another subject of the invention, according to another of its aspects, is a connection assembly comprising at least two connectors according to the first embodiment that has just been described, the armature of the first connector being connected to the armature of the second connector by a joining part carrying feet.
The armature of the first connector and the armature of the second connector and the joining part may be produced as a single piece, especially by virtue of the low-cost “cut-and-rolled” technique.
The feet provided on the joining part may be fastened by soldering to the printed circuit board. By virtue of such a connection assembly, it is possible for several casings to be soldered simultaneously.
Yet another subject of the invention, according to another of its aspects, is a connection assembly comprising at least two connectors according to the second connector embodiment according to the invention, the armature of the first connector being connected to the armature of the second connector by a joining part and/or the casing of the first connector and the casing of the second connector being made as a single piece.
When the armature of the first connector and the armature of the second connector are made as a single piece, the resulting armature of the connection assembly may have a U-shaped cross section with a back and flanges.
In all the abovementioned embodiments of the invention, the armature may be mechanically attached to the casing, for example by the cooperation of reliefs, by interlocking or snap-fastening, When the armature is placed around the casing, it cannot be in contact with the body of the connector. The connector is for example a coaxial connector. The connector may comprise a plurality of central contacts.
When the connector is an elbow connector, the contact(s) of the connector may be made as a single piece, or, as a variant, may be obtained by virtue of two straight contact portions connected together.
In all the above embodiments, the armature may be accommodated in the thickness of the casing, that is to say the wall of that portion of the casing around which the armature is placed may have recesses and the armature may be accommodated in these recesses when it is placed around said portion of the casing. Where appropriate, the thickness of the flanges and of the back of the armature may correspond to the thickness of said recesses.
Yet another subject of the invention, according to another of its aspects, is an elbow connector comprising:
a body;
at least one contact accommodated in the body with an insulator being interposed;
a casing extending along a longitudinal axis and defining a housing designed to accommodate all or part of the body; and
an armature surrounding, along the longitudinal axis, at least one portion of the casing in which at least one portion of the body is accommodated, the armature having feet for fastening the connector to a printed circuit board, in which the armature has a wall transverse to the longitudinal axis of the casing, said wall closing off a longitudinal end of the casing.
Yet another subject of the invention, according to another of its aspects, is a system comprising:
a connector having a body, at least one contact accommodated in the body with an insulator being interposed, a casing defining a housing designed to accommodate all or part of the body, and an armature placed around at least one portion of the casing, the armature having feet for fastening the connector to a printed circuit board; and
a printed circuit board, wherein the contact extends along a longitudinal axis, at least one portion of which is inclined, especially being perpendicular, to the plane defined by the printed circuit board.
The plane defined by the printed circuit board is that in which the width and the length of the printed circuit board are measured.
Thanks to the inclined, and especially perpendicular, portion of the contact of the connector relative to the plane defined by the printed circuit board, other ways of fitting the connector, that is to say other than those of the “board edge” type, may be envisioned.
The connector may be straight, in which case the contact is straight and may extend over its entire length so as to be inclined, especially perpendicularly, to the plane defined by the printed circuit board.
As a variant, the connector may be an elbow connector, in which case the contact is right-angled and may include a portion extending so as to be inclined, especially perpendicularly, to the plane defined by the printed circuit board.
The feet of the connector may extend so as to be inclined, especially perpendicularly, to the plane defined by the printed circuit board.
The connector, especially the body, the casing or the armature, may be as described above, comprising for example at least any one of the aforementioned features.
The invention will be better understood on reading the following description of nonlimiting exemplary embodiments thereof and by examining the appended drawing in which:
The connector 10 comprises in the example described a body 2 accommodated in a housing 6 of a casing 3.
The body 2 is for example made of metal, especially brass or bronze, using the “cut-and-rolled” technique. As may be seen in
The casing 3 extends in this example along a straight longitudinal axis X. The casing 3 is for example made of plastic, especially a polyamide filled with glass fibers. In the example illustrated, the casing 3 comprises a front portion 11 especially having reliefs for connection to a casing of a complementary connector, a tubular central portion 12, the inside diameter of which allows the body 2 to be accommodated therein, and a rear end portion 13 around which an armature 14 is placed.
As shown in
The armature 14 is made of metal, especially brass or bronze.
In the example of
In the example described, the back 16 has a substantially smooth surface.
As a variant, the back 16 may include, as shown in the example of
The armature 14 also includes feet 18 for fastening the connector 10 to a printed circuit board 19, visible in
In the example of
The feet 18 project from the rear portion 13 of the casing 3, for example by a distance h of between 0.5 mm and 1 cm, especially between 0.6 and 4 mm.
As may be seen in
Each flange 17 may extend from the back 16 of the armature 14 along a plane surface 20. This plane surface 20 is in the example described connected to each foot 18.
Each foot may have a distal part 22 extending parallel to the plane surface 20 and a proximal part 21, connected to the surface 20 and extending obliquely to the latter. Each proximal part 21 is for example turned toward the inside of the armature 14. The distal part 22 of each foot 18 is for example designed to pass through an opening provided in the printed circuit board 19.
However, the invention is not limited to feet having a distal part 22 parallel to the surface 20 of the armature.
In the variant shown in
As may be seen in
The holes 24 may be of any shape, being square in the example described. The armature 14 further includes, in the examples of
In the examples that have just been described, the flanges 17 and the back 16 of the armature 14 may be accommodated in the thickness of the rear portion 13 of the casing 3, that is to say in recesses provided in the flanges 17 and the back 16 of the armature 14. The armature 14 may be sandwiched between walls or ends 26 of the casing 3, as may be seen for example in
As shown in
The assembly comprises a joining part 31 connecting the armatures 14 of each of the connectors 10. In the example illustrated, this joining part 31 is plane and has feet 33 similar to the feet 18 described above. As may be seen in
In the example illustrated, the joining part 31 is made as a single piece with the armatures 14 of the two connectors, the connection between armatures 14 and the joining part 31 taking place by means of the feet 18 of the flanges 17 opposite the joining part 31, said feet 18 being curved and connected to the joining part 31.
The connection assembly 30 shown in
Connectors 10 according to a second exemplary embodiment of the invention will now be described with reference to
The connectors according to this second embodiment of the invention differ in particular from those that have just been described by the fact that they are straight, that is to say they extend only along a single straight longitudinal axis, the central contacts being straight.
In the examples shown in
As shown in
The body 2 of the connector 10 includes, as described above, returns 9 which in the example illustrated are folded against the longitudinal end 26 of the casing 3 at the rear portion 13 of the latter.
In the example of
In the example shown in
A connection assembly 30 comprising connectors according to
In these examples, the casings 3 of each of the connectors 10 are made as a single piece, forming a common casing in which two through-housings 6 are provided, each of these through-housings accommodating one of the connectors 10.
In the example of
In the example of
As may be understood in the view shown in
As may be understood in the view shown in
Furthermore, as may be understood in the view shown in
The invention is not limited to the examples that have just been described.
The presence of the reliefs 50 and 51 described with reference to
Number | Date | Country | Kind |
---|---|---|---|
1060607 | Dec 2010 | FR | national |