FR2823606A1 - Low voltage female connector having holder receiving male connector and first circuit board contact pins/contact zone connected/second printed circuit board shorter path contact zone connected. - Google Patents

Abstract

The low voltage female connector (1) has a holder (14) receiving a male connector having contact pads (30) connected to contact zones (21). A first printed circuit board (11) has contact pins (12) for the connection cable. The circuit is connected to the contact zone. A second printed circuit board (15) is connected to the contact zones by a shorter contact path than the first board.

Description

The present invention relates to a low voltage female connector

  comprising a housing intended to receive a male connector provided with contact pads, said housing being provided with contact blades defining contact zones adapted to come into contact with the contact pads of the male connector, and a first printed circuit board provided of contact pins adapted to receive wires from a connection cable, the printed circuit board being electrically connected to the contact zones by a first path

electrical connection.

  In low voltage connections, we very often encounter interference phenomena known as crosstalk. This phenomenon of crosstalk is all the more amplified as the crimes are important. At the connectors, the wires of the power cables which are most often in the form of twisted pairs, usually four in number (thus making a total of eight conductive wires), are connected to contacts or pins often produced in the form of self-stripping contacts with slits in which the individual wires are inserted so as to cut their insulating sheaths up to their conductive cores. Conventionally, the pins or contacts extend in parallel, which induces a considerable magnetic field at the origin of the phenomenon of crosstalk. It should be noted that this phenomenon of crosstalk is present both in the female connectors and in the male connectors. However, a male connector is intended to be plugged into a female connector which produces at the connection of the

  two male and female connectors a phenomenon of considerable crosstalk.

  The object of the present invention is to reduce, or even eliminate, this phenomenon of crosstalk at a low voltage female connector. I1 already exists in the prior art low voltage female connectors incorporating devices or arrangements for reducing crosstalk. I1 is for example the use of blades or pins forming at one of their ends contact points for the connection of the power cable, for example in the form of self-stripping contacts, and at their other ends of the contact areas suitable for coming into electrical contact with the contact pads of the plugged-in low-voltage male connector. To reduce crosstalk in such a female connector equipped with blades or pins, it is known to interlock certain blades to create a compensating magnetic field which opposes and totally or partially cancels the field at the origin of crosstalk. It is also known to use a printed circuit board between the connection points of the power cable and the areas of contact with the male connector. This printed circuit includes inductive elements adapted to compensate for crosstalk. The present invention relates more particularly to this second technique using a printed circuit board to reduce, or even eliminate, the crosstalk inside the connector.

low voltage female.

  However, there is an equivalent crosstalk phenomenon at the level of the low-voltage male connector to be inserted into the female connector. More particularly, the male connector is provided with conductive contact pads adapted to come into electrical contact with the flexible contact blades of the female connector. These contact pads are made of solid metal and must be strong enough to withstand repeated friction against the flexible contact blades when inserting the male connector into the housing of the female connector. As a result, the contact pads constitute relatively large masses of metal aligned one next to the other. This regular alignment of the pads also induces crosstalk-generating fields. The object of the present invention is to partially or totally compensate for the crosstalk generated by the contact pads of the male connector by

  : 5 of the internal provisions of the female connector.

  To achieve this object, the present invention provides a second printed circuit board also electrically connected to the contact areas by a second electrical connection path, the second path being shorter in distance than said first path. The second printed circuit board is therefore located in close proximity to the contact pads of the male connector when the latter is inserted in the female connector. This second printed circuit board can integrate inductive tracks making it possible to compensate for the crosstalk generated by the alignment of the contact pads of the male connector. It should be noted that it is the female connector which compensates for the crosstalk of the male connector in the present invention. It is particularly important that if the crosstalk compensation system is located as close as possible to the crosstalk source. In other words, it is very important that the second printed circuit board is located as close as possible to the contact pads of the

  male connector. This has been demonstrated experimentally.

  It can be said that the female connector of the invention comprises a first printed circuit board which makes it possible to compensate for the crosstalk phenomenon induced by the contact pins and a second printed circuit board intended to compensate for the crosstalk induced by the contact pads. contact of

male connector.

  n should be understood here under the term "blade", any elongated element in the form of a profiled wire having a rectangular, square or even round cross section. The blades advantageously have a flexibility and a configuration allowing their engagement with the contact pads of the male connector. In fact, when the male connector is plugged in, the contact pads slide along the blades, urging them elastically so as to create a contact pressing the blades against the pads. This ensures good plugging and good electrical contact between the male connector and the female connector. All this is perfectly classic in the field of low voltage connections. There are even standards relating to the inclination of the flexible blades.

  According to one embodiment, the first path is formed by the blades.

  Advantageously, the blades are in contact with support against the first printed circuit board. There are other techniques for establishing electrical contact between the blades and the first printed circuit board: in fact, it is frequent to use techniques of welding or force insertion into holes made in the first board. printed circuit board. However, the technique of the invention, that is to say by contact, has advantages since it is not necessary to use a particular technique such as welding

  or the fitting to make the electrical contact.

  According to another characteristic of the invention, the second path is formed by the blades. The blades can therefore directly connect the second printed circuit board from their contact area with the contact pads.

of the male connector.

  According to a practical embodiment, the blades each define a substantially fixed end and a movable free end between which is located is a respective contact area, the fixed end being substantially in contact with support against the first printed circuit board and the free end being adapted to come into bearing contact against the second printed circuit board when a male connector is inserted in the housing. The blades can therefore from their contact zones connect on one side the first

  printed circuit board and on the other side the second printed circuit board.

  In addition, the flexibility of the blades is used to make the electrical contact by pressing against the two printed circuit boards. Contact with the first printed circuit board may be slight, or even non-existent, before insertion of the male connector, and contact with the second printed circuit board is non-existent before insertion of the male connector. Contact pins of the male connector are used to press the electrical contact at the first printed circuit board and make the electrical contact at the second printed circuit board. Advantageously, the blades are pivotally supported by elastic deformation on a stop element, said element

  stop being located between the substantially fixed ends and the contact zones.

  : 5 On the other hand, the movable free ends are supported on a rest member away from the second printed circuit board in the absence of a

  male connector inserted in said housing.

  It should be noted that such contact blades can be used

  in a female connector without a second printed circuit board.

  Indeed, if the crosstalk phenomena induced by the contact pads of the male connector are weak or particularly weak, it is then not necessary to implement a second printed circuit board in the female connector. In this case, the insertion of the male connector has the effect of deforming the flexible blades, pressing the contact against the first printed circuit board, and raising the other end of the blades which then does not come into contact with any element. According to another embodiment of the invention, the second path is formed by the blades, and the first path is formed by the blades, the second printed circuit board and conductive fittings connecting the second printed circuit board to the first printed circuit board. In this case, the second printed circuit board forms part of the first electrical connection path connecting the contact areas to the first printed circuit board. This is not the case in the first embodiment in which the second printed circuit board is, so to speak, placed off-circuit at a

end of flexible blades.

  According to another aspect of the invention, the second printed circuit board is resiliently biased towards the contact areas. The second printed circuit board can therefore move elastically, which makes it possible to use flexible blades having a lower elasticity. This then makes it possible to further reduce the second electrical connection path between the contact zones and the

  o second printed circuit board.

  The invention will now be described more fully with reference to the accompanying drawings which give two embodiments by way of non-limiting examples.

of the invention.

  In the figures: - Figure 1 is a vertical cross-sectional view through a low-voltage female connector according to a first embodiment of the invention to which a conventional male connector is connected, and - Figure 2 is a view similar to that of figure 1 for a second

  embodiment of a low female connector of the invention.

  In the two embodiments of Figures 1 and 2, the female connector, generally designated by the digital reference 1, comprises a housing 10, advantageously in one piece, made of molded plastic or metal. The housing 10 comprises a front face forming a housing 14 intended for the reception by insertion / insertion of a male connector designated as a whole by the digital reference 3. In the housing 14 are provided several flexible blades 2, conventionally the number of eight, which can move between a rest position shown in dotted lines in FIG. 1 and to an electrical contact position shown in solid lines in FIG. 1. These blades 2 are intended to come into electrical contact at the level of zones of contact 21 with contact pads 30 formed by the male connector 3. Contact of the pads 30 with the respective flexible blades 2 establishes electrical contact between the male connector 3 and the female connector 1. The pads

  contact 30 are also conventionally eight in number.

  s When the connector 3 is plugged into the connector 1, the flexible blades 2 are elastically deformed upward in FIG. 1 by the contact pads 30 of the connector 3. When the connector 3 is plugged in, the pads contact 30 dissent on the respective blades 2 over a certain distance and at the same time move them upwards. This ensures good electrical contact o between the pads 30 and the blades 2. All of this is perfectly conventional for

low voltage connectors.

  The housing 10 also comprises an open rear face at the level of which the wires of a power cable can be connected. To this end, the open rear face is provided with contact pins 12, conventionally in the form of self-stripping slotted contacts in which the individual wires of the power cable are inserted so as to cut their insulating sheaths up to their conductive souls. The contact pins 12 are inserted with a tight fit into a first printed circuit board 11 mounted on a plate support 13 fixed inside the housing 10, for example by snap-fitting. The plate support 13 also serves to improve the stability and the fixing of the pins 12. This first printed circuit plate 11 advantageously incorporates a crosstalk compensation circuit making it possible to partially or totally compensate for the crosstalk induced by the pins of

  contact 12. This is already known from the prior art.

  In the first embodiment shown in FIG. 1, the flexible blades 2, which define the contact areas 21 with the contact pads of the male connector 3, extend until contact with the first printed circuit board 11 for establishing electrical contact between the studs 30 and the printed circuit 11. The flexible blades 2 can be shaped or profiled so as to come into pivoting abutment by elastic deformation on a stop element 18 o fixedly mounted inside the housing 10. This abutment element 18 serves as a sort of axis of rotation or pivoting for the flexible blades 2, particularly at the level where they define their contact zone 21 with the pads 30 of the connector 3. Referring to FIG. 1, we can see that the blades 2 form a bend 22 which extends around the stop element 18. Beyond this bend 22, the flexible blades 2 form a substantially fixed end 23 which comes in contact pressed against the first printed circuit board 11 when the male connector 3 is inserted in the housing 14 so as to move the blades 2 by elastic deformation upwards. In the absence of the connector 3, the substantially fixed ends 23 come into light contact, or are even detached from the printed circuit board 11. It is the displacement of the flexible blades 2 at their contact zone 21 by pivoting elastic around the stop element 18 which bears the substantially fixed ends 23 against the first printed circuit board 11. It is therefore the insertion of the male connector 3 which establishes the electrical contact between the blades 2 and the plate o5 of printed circuit 11, or at least improves its quality. I1 should be noted that in the absence of the male connector 3 plugged into the connector 1, the flexible blades 2 adopt a rest position shown in dotted lines in Figure 1, in which they are subjected to virtually no stress. The free end 24 opposite the end 23 comes into rest contact on a rest surface 165 which will be detailed below. By cons, as soon as the male connector 3 is plugged into the female connector 1, the flexible blades are energized, while maintaining a perfect balance due to the support on the stop element 18. The configuration and arrangement of these flexible blades 2 constitute a characteristic which can be implemented in any connector

  low voltage female fitted with a printed circuit board.

  According to the invention, the female connector 1 also comprises a second printed circuit plate 15 integrating a crosstalk compensation circuit. This second printed circuit board 15 is electrically connected to the contact zones 21 of the blades 2 intended to come into electrical contact with the contact pads 30 of the male connector 3. This characteristic is common to the two embodiments of FIGS. 1 and 2 Another particularly advantageous common characteristic resides in the fact that the electrical connection path between the contact zones 21 and the first printed circuit board 11 is longer in distance than the electrical connection path between these same contact zones 21 and the second printed circuit board 15. It is indeed important that the second printed circuit board 15 is located as close as possible to the contact pads 30 of the male connector 3 which induce crosstalk. The crosstalk compensation circuit integrated in the second printed circuit board 15 is intended to partially or

  completely the crosstalk induced by the contact pads 30 of the male connector 3.

  Qo Experiments have shown that the distance between the compensation circuit

  crosstalk from the crosstalk source should be as short as possible.

  Ideally, the second printed circuit board could come into direct electrical contact with the contact pads 30 of the connector 3. However, this is in practice only very difficult since the insertion Q5 of the male connector causes displacement contact areas but also friction along the blades 2. However, one can imagine a printed circuit board incorporating contact blades for supporting friction, the printed circuit board being mounted so as to be able

  be moved when inserting the male connector 3 into the housing 14.

  The embodiment of Figure 1 is a practical embodiment easily achievable. As mentioned above, the blades 2 are flexible blades having a substantially fixed end 23 in contact or adapted to come into contact with the printed circuit board 11, an elbow 22 in engagement with the stop element 18 and an opposite free end 24 resting rest against a rest member 165 when the housing 14 is empty. With this embodiment of the blades 2, it is easy to make electrical contact with the second printed circuit board 15 by placing it appropriately so that the movable free ends 24 come into contact with the plate 15 when the male connector 3 is inserted into the housing 14, which has the effect of moving the blades 2 at their contact areas 21 upwards in FIG. 1. The printed circuit board 15 can be held in a board support 16 which advantageously forms a return which defines the rest member 165 on which comes

  refit the free ends 24 of the plates in the absence of the male connector 3.

  Thus, the insertion of a male connector 3 into the housing 14 of the female connector 1 has the effect of pressing the ends 23 of the blades against the first printed cTrcuit plate 11 and of establishing contact with the free ends 24 of the blades with the second printed circuit board 15. It should be noted that the blades always remain perfectly balanced due to their abutment on the

stop 18.

  It can easily be seen in FIG. 1 that the electrical connection path connecting the contact areas 21 with the free ends 24 is considerably shorter than the electrical connection path connecting these same contact areas 21 with the substantially fixed ends 23. We thus meet the aforementioned requirements related to the positioning of the second printed circuit board in order to be able to compensate for the crosstalk induced by the pads of: 5 contact 30. With this arrangement, it is possible to integrate or not a second printed circuit board 15 in the female connector 1 as a function of the level of crosstalk induced by the contact pads 30 of the male connector 3 intended to be used in conjunction with the female connector 1. In fact, the elimination of the second printed circuit board 15 does not does not alter the operation of the female connector 1 at all, since the second printed circuit board 15 is not placed in the che min of electrical connection connecting the contact zones 21 to the first printed circuit board 11. On the contrary, it can be noted that the second printed circuit board 15 in FIG. 1 is placed outside the electrical path of the current passing from the male connector 3 to female connector 1 or vice versa. This does not however prevent it from fulfilling its function of crosstalk compensation induced by the pads 30. The inoperative removal of the second printed circuit board 15 makes it possible to obtain a modular female connector in two versions, one not incorporating one printed circuit board and the other incorporating two circuit boards. , imprlme. o We will now refer to FIG. 2 which shows a second embodiment in which the second printed circuit board 15 is mounted in series in the electrical connection path connecting the contact zones 21 to the first printed circuit board 11. The arrangement of the first printed circuit board 11, of the contact pins 12, of the plate support 13 as well as the male connector 3 can be strictly identical to that of FIG. 1. On the other hand, the blades 2 extend here only between the contact areas 21 and the second printed circuit board 15 with a geometric configuration which may be substantially identical or similar to that of the blades 2 of FIG. 1 between the contact areas 21 and the free ends 24. In the figure 2, the flexible blades 2 are fixed to the second printed circuit board 15 by any fixing technique, for example by welding or tight fitting insertion. However, it is also possible, as shown in FIG. 2, that the blades 2 partially envelop the second printed circuit board using tightening loops formed by the blades. I1 is thus possible to extend the blades by flexible tails 26 which come to bear against the housing 10. The blades 2 between the contact zones 21 and the loops 25 are elastically deformable, but the quenes 26 are also elastically deformable so that the second printed circuit board 15 is caused to move when the male connector 3 is inserted into the housing 14. The second printed circuit board 15 is however held resiliently to the first printed circuit board 11 by fittings electrically conductive 17 which establishes the electrical connection between the first and the second printed circuit board. Thus, the electrical connection path connecting the contact areas 21 to the second printed circuit board is obviously shorter than the electrical connection path connecting the contact areas to the first printed circuit board 11 since the electric current flows through through the second printed circuit board 15 and through

  the connections 17 to join the first printed circuit board 11.

  The requirement related to the proximity of the second printed circuit board is therefore

also fulfilled.

  o Alternatively, one can imagine that the blades 2 extend along the printed circuit board 15 and not in distance as is the case in FIG. 2. In this case, the blades would be in contact with the surface of the printed circuit board 15. The elasticity necessary for the displacement of the contact zones would then be completely filled by the flexible tails 26. There would thus be a female connector 1 in which the second printed circuit board 15 would be practically in direct contact with the contact pads 30, simply by means of blades arranged below the plate, or even integrated

in the plate.

  Thanks to the invention, the crosstalk induced by the male connector at its contact pads is optimally compensated by the

  female connector into which it is inserted.

Claims (11)

claims   1.- Low voltage female connector (1) comprising: - a housing (14) intended to receive a male connector (3) provided with contact pads (30), said housing (14) being provided with contact blades (2) defining contact zones (21) adapted to come into contact with the contact pads (30) of the male connector (3), and - a first printed circuit board (11) provided with contact pins (12) adapted to receive wires of a connection cable, the printed circuit board (11) being electrically connected to the contact areas (21) by a first electrical connection path, characterized in that a second printed circuit board is provided (15) also electrically connected to the contact zones (21) by a second electrical connection path, the second path being shorter in distance than said first path.  2. A female connector according to claim 1, in which the   first path is formed by the blades (2).   3. A female connector according to claim 2, in which the flexible blades (2) are in contact with support against the first circuit plate. printed (11).   4.- Female connector according to any one of claims   previous, in which the second path is formed by the blades (2).   5.- Female connector according to the preceding claims, in   which blades (2) each define a substantially fixed end: 5 (23) and a movable free end (24) between which is located is a respective contact area (21), the substantially fixed end (23) being in contact bearing against the first printed circuit board (11) and the free end (24) being adapted to come into bearing contact against the second printed circuit board (15) when a male connector (3) is inserted into the housing (14).   6. A female connector according to claim 1, in which the second path is formed by the blades (2), and the first path is formed by the blades (2), the second printed circuit board (15) and conductive connections. (17) connecting the second printed circuit board (15) to the   first printed circuit board (11).   7.- Female connector according to any one of claims   previous, in which the second printed circuit board (15) is   o resiliently biased (26) towards the contact areas (21).   8.- Female connector according to any of the claims   previous, in which the second printed circuit board (15)   includes a cross-talk compensation circuit.   9.- female connector according to any one of claims   previous, in which the first printed circuit board (11)   understands crosstalk compensation.   10.- female connector according to claim 5, wherein the blades (2) are pivotally supported by elastic deformation on a stop element (18), said stop element being located between the ends   substantially fixed (23) and the contact zones (21).   11.- female connector according to claim 10, wherein the movable free ends (24) are supported on a rest member (165) away from the seeonde printed eireuit plate (1 5) in the absence of a   male connector (3) inserted in said housing (14).