EP0693800A1 - High frequency connector having a switching function - Google Patents

Abstract

The high frequency electrical connector includes a first connector element (1) with a first conductor (5) and an earth conductor, and a second connector element (2) which includes a second conductor (14), an earth conductor and a third conductor (16). The first and second conductors are connected when the two parts of the connector are linked together. When the connector parts are separated, the third conductor contacts the second. The first (5), second (14) and third (16) conductors are formed as lamellae, whilst the earth conductor consists of an outer sleeve (8). <IMAGE>

Description

The present invention relates to a high frequency electrical connector also performing a switching function.

There are already known connectors, in particular of the coaxial type, which make it possible to switch an electrical line forming a high frequency transmission path onto another electrical line forming a high frequency transmission path when the two elements of the connector are engaged one inside the other. .

Such connectors are in particular used to connect portable devices to their base while switching electronic functions of the portable device with those of the base, such as for example radio telephones in cars.

Known connectors are generally of a complex structure and most often have the significant drawback of not providing good radio-electric insulation between the two electric lines to be switched.

From EP-A-0590544, an electrical connector is known comprising a first connector element comprising a first conductor and a ground conductor, and a second connector element comprising a second conductor, a ground conductor and a third conductor which is located in electrical contact with the second conductor when the two connector elements are uncoupled, the first connector element being arranged to, when it is coupled with the second connector element, separate said second and third conductors from each other second connector element, the first (5), second (14) and third (16) conductors being made in the form of blades, the ground conductor of the first connector element (1) comprising an outer socket (8) and a blade (6,7) disposed substantially parallel to the blade (5) constituting the first conductor, said blades being separated from each other and relative to the outer sleeve by an insulator (3,4), the earth conductor of the second connector element (2) comprising an outer sleeve (17) and a blade (15) disposed between the blades (14,16) constituting the second and third conductors, said blades being separated from each other and relative to said outer sleeve by an insulator (11,12).

In this connector, the third conductor is separated from the second conductor during the coupling of the two connector elements, but remains unconnected while the second conductor comes into contact with the first conductor.

This could result in a coupling effect between the third conductor and the electrical line formed by the first and second conductors.

To avoid this drawback, in the connector described in EP-A-0590544, the two strips of ground conductors meet to form a continuous ground plane between the third conductor and the first and second conductors, when the two connector elements are mated.

This solution nevertheless has the drawback of requiring significant penetration of the first connector element into the second connector element.

It also has the drawback of involving a large radial deflection of the second and third conductors, which, on the one hand requires a sufficient diameter of the connector and, on the other hand, strongly bends the blades constituting the second and third conductors.

The present invention aims to provide a high-frequency electrical connector of particularly simple and economical construction and implementation, which performs a switching function between two electrical lines while ensuring good radio-electric insulation between them and which does not have in particular the drawbacks mentioned above.

The high frequency electrical connector according to the invention comprises a first connector element comprising a first conductor and a ground conductor and a second connector element comprising a second conductor, a ground conductor and a third conductor which is in electrical contact with the second conductor when the two connector elements are uncoupled, the first connector element being arranged to, when coupled with the second connector element, separate one on the other, said second and third conductors of the second connector element.

According to the invention, the first, second and third conductors are made in the form of blades, the earth conductor of the first connector element comprises an outer conductive socket and a blade disposed substantially parallel to the blade constituting the first conductor, and the conductor earth of the second connector element comprises an outer socket and a blade disposed between the blades constituting the second and third conductors.

This electrical connector is characterized in that the blade of the ground conductor of the first connector element is arranged so as to be in contact with the third conductor of the second connector element, when the two connector elements are coupled.

It is understood that thus, when the two connector elements are coupled, the third conductor does not remain unconnected and therefore that the risk of coupling with the electric line formed by the first and second conductors is eliminated, without it being necessary to use blades of mass conductors joining to form a continuous ground plane between the third conductor and the first and second conductors.

In fact, in the assembled position, the blade of the ground conductor of the first connector element is in contact with the third conductor of the second connector element. This third conductor is then placed outside the high frequency signal transmission line defined by the second conductor and the ground conductor blade of the second connector element, which provides good radio-electric insulation between the electric lines. trained.

Preferably, insulators are provided between the blades constituting the first, second and third conductors and between these blades and the corresponding outer sleeve.

In a preferred embodiment, the end of the blade of the ground conductor of the first connector element, the end of the blade of the first conductor and an insulator separating these blades, constitute an assembly forming a male connector and capable of engage, in spreading them apart, between the ends of the blades constituting the second and third conductors of the second connector element.

In a particular embodiment of the invention, the second and third conductors each have two contact zones, namely a first contact zone by which they bear against each other when the two connector elements are uncoupled, and a second contact zone by which they bear respectively on the first conductor and on the blade of the ground conductor of the first connector element when the two connector elements are coupled.

In this embodiment, the first contact zones are located in the median plane of the connector, plane which also contains the ground blades, while the second contact zones are set back relative to this median plane, when the two connector elements are uncoupled.

This results in a lower radial clearance of the second and third conductors, during the coupling of the two connector elements, which makes it possible to give a smaller diameter to the connector and to limit the bending stresses of the blades constituting the second and third conductors.

The outer sockets of the first and second connector elements are advantageously dimensioned so as to be in mutual contact when the two connector elements are assembled. Preferably, the sockets are arranged so that, during assembly, at least one of the sockets deforms radially.

The outer sockets provide a shielding function vis-à-vis the environment.

The strips of the ground conductors of the first and second connector elements are advantageously arranged so as to be in contact by their longitudinal edges with the corresponding external sockets.

These blades, forming ground planes, advantageously have slots giving them elasticity in their plane to ensure good electrical contact with the sockets surrounding them.

The strips constituting the second and third conductors are further preferably shaped so as to be in elastic support against each other in the uncoupled position of the connector elements.

To this end, at least one of the blades constituting the second and third conductors has a curved portion projecting in the direction of the other blade.

• a) les sections des lames constituant les premier, second et troisième conducteurs,
• b) la constante diélectrique de l'isolant séparant les conducteurs entre eux et par rapport aux conducteurs de masse,
• c) les distances séparant les lames constituant les premier, second et troisième conducteurs des lames des conducteurs de masse correspondants.

The impedance of each power line can be precisely determined by determining:

• a) the sections of the blades constituting the first, second and third conductors,
• b) the dielectric constant of the insulator separating the conductors from one another and relative to the ground conductors,
• c) the distances between the blades constituting the first, second and third conductors of the blades of the corresponding ground conductors.

• la figure 1 est une vue en coupe axiale d'un connecteur selon l'invention en position désaccouplée,
• la figure 2 est une vue en coupe axiale du connecteur selon l'invention en position accouplée,
• les figures 3 à 6 sont des vues en coupe longitudinale des éléments du connecteur selon l'invention, selon A-A, B-B, C-C et respectivement D-D de la figure 1.

In order to better understand the invention, we will now describe a particular embodiment given by way of non-limiting example with reference to the accompanying drawing in which:

• FIG. 1 is a view in axial section of a connector according to the invention in the uncoupled position,
• FIG. 2 is a view in axial section of the connector according to the invention in the coupled position,
• FIGS. 3 to 6 are views in longitudinal section of the elements of the connector according to the invention, according to AA, BB, CC and respectively DD of FIG. 1.

B-B defines the median plane of the connector.

The high-frequency electrical connector according to the invention consists of a first connector element generally designated by 1 and by a second connector element generally designated by 2.

We will now describe successively these two connector elements.

The first connector element 1 comprises several insulators constituted by a one-piece essentially cylindrical block 3 extended at its front part by a projecting part of rectangular section 4.

In grooves formed in the insulator 3 are arranged, on the one hand a blade 5 constituting a first conductor, and on the other hand a blade 6 of ground conductor.

The shape of the blades 5 and 6 is best seen in Figures 6 and 5 respectively.

The blade constituting the first conductor 5 is formed of a ribbon having a substantially constant section over the entire length of the insulating block 3 and ends, at the end of the projecting part 4 of the insulator.

The rear part 5 has of the blade 5 projecting from the insulating block 3, forms an external connection zone.

The ground conductor strip 6 has, over the major part of the length of the insulating block 3, a large width and is extended by a projecting part of narrower width 7 to the end of the projecting insulating part 4 At its rear end, the ground conductor strip 6 has a reduced width portion 6 a forming an external connection area.

The ground conductor of the connector element 1 further comprises an outer socket 8 surrounding the insulating block 3 while being fixed to it by any suitable means, and extending towards the front of the connector element. A cavity 9 is defined in the front part of the outer sleeve 8, a cavity into which an assembly forming a male end opens and constituted by the insulating protruding part 4, the end 7 of the blade 6 of the ground conductor and the end of the blade 5 constituting the first conductor.

The front end of this assembly forming a male end piece is advantageously chamfered. As can be seen in FIG. 5, the blade 6 is provided with slots 10, four in number in the example illustrated, giving it elasticity in its plane so as to produce along the longitudinal edges of the blade 6 bulges contact with the outer sleeve 8.

As can be seen in FIG. 1, the blades 5 and 6 are arranged symmetrically with respect to a diametrical plane of the outer sleeve 8.

The second connector element, generally designated by 2, comprises an insulating block 11 extended by a tubular part 12 provided with an opening 13 of substantially rectangular section. In grooves of the insulating block 11 are arranged a strip 14 constituting a second conductor and whose rear end 14 a constitutes an external connection area, a ground conductor strip 15 whose rear end 15 a constitutes an external connection area, and a blade 16 constituting a third conductor and the rear end 16 a of which also constitutes an external connection area.

The ground conductor blade 15 is disposed between the blades 14 and 16 constituting the second and respectively third conductors of the connector according to the invention.

As can be seen in FIGS. 1 and 2, each of the blades 14 and 16 comprises, beyond the end of the blade 15 and of the part of insulation which surrounds it, a curved part 14 b , and respectively 16 b , protruding and turned towards the other blade. These curved parts constitute first contact zones within the meaning of the invention.

As can be seen in FIG. 1, in the uncoupled position, the first contact zones 14 b and 16 b ensure close elastic contact between the blades 14 and 16. Beyond their curved part, each of the blades 14 and 16 has a flared-shaped portion 14c spatula and respectively 16c which constitutes a second contact zone in the sense of the invention.

The first contact zones are located in the median plane of the connector, while the second contact zones are set back relative to this plane when the connector is coupled.

The blades 14 and 16 are formed from a ribbon having a substantially constant section over the entire length of the connector element.

Like the blade 6 of the first connector element, the ground conductor blade 15 of the second connector element 2 has a significantly greater width than that of the blades 14 and 16 to come into elastic contact with a peripheral socket 17 surrounding the insulator 11, 12 of the second connector element over most of its length up to the vicinity of its end face comprising the opening 13.

The outer sleeve 17 is fixed to the insulator 11, 12 by any suitable means. Sockets 8 and 17 of the first and second connector elements are dimensioned so as to cause a radial deformation of the socket 8 during coupling so that, in the coupled position illustrated in FIG. 2, good electrical contact is made between said sockets.

Like the ground conductor blade 6 of the first connector element, the ground conductor blade 15 of the second connector element has slots 18, two in number in the example illustrated, giving it elasticity in its plane to come into contact with the inner wall of the outer bush 17.

The blade 15 is arranged in a diametral plane of the outer sleeve 17 and the blades 14 and 16 are arranged symmetrically with respect to this diametrical plane.

During coupling, the male end assembly, and described above, of the first connector element penetrates into the orifice 13 and engages between the end parts of the blades 14 and 16 by moving the latter apart. one from the other so that the first contact zones 14b and 16b are no longer in contact.

The electrical continuity between the blades 14 and 16 is then interrupted and electrical continuity is ensured by the second contact zones, on the one hand between the blades 5 and 14 and, on the other hand, between the end 7 of the blade 6 and the blade 16.

During uncoupling, we find the arrangement of Figure 1 in which, as regards the second connector element, electrical continuity is ensured between the blades 14 and 16 by the first contact zones.

Although the invention has been described in connection with a particular embodiment, it is obvious that it is in no way limited thereto and that it can be made different variants and modifications without departing from its scope or its mind.

Claims (8)

High frequency electrical connector comprising a first connector element (1) comprising a first conductor (5) and a ground conductor (6,7,8), and a second connector element (2) comprising a second conductor (14), a ground conductor (15,17) and a third conductor (16) which is in electrical contact with the second conductor (14) when the two connector elements are uncoupled, the first connector element (1) being arranged for, when it is coupled with the second connector element (2), separate said second (14) and third (16) conductors from the second connector element, the first (5), second (14) and from each other third (16) conductors being produced in the form of strips, the ground conductor of the first connector element (1) comprising an outer socket (8) and a strip (6,7) arranged substantially parallel to the strip (5) constituting the first conductor, the conductor of m base of the second connector element (2) comprising an external socket (17) and a blade (15) disposed between the blades (14,16) constituting the second and third conductors, characterized in that the blade (5 a ) of the the ground conductor of the first connector element is arranged so as to be in contact with the third conductor (14) of the second connector element when the two connector elements are coupled. Connector according to Claim 1, characterized in that the end (7) of the strip (6) of the ground conductor of the first connector element, the end of the strip (5) constituting the first conductor and an insulator ( 4) separating said blades constitute an assembly forming a male end piece and capable of engaging by spreading them between the ends of the blades (14, 16) constituting the second and third conductors of the second connector element. Connector according to claim 1 or 2, characterized in that the strips (6,15) of the ground conductors of the first and second connector elements are arranged so as to be in contact by their longitudinal edges with the corresponding external sockets (8 , 17). Connector according to Claim 3, characterized in that the said blades of the ground conductors of the first and second connector elements have slots (10,18) giving them elasticity in their plane to ensure good electrical contact with the sockets (8 , 17) surrounding them. Connector according to any one of the preceding claims, characterized in that the blades (14,16) constituting the second and third conductors of the second connector element are shaped so as to be in elastic support against one another in the uncoupled position of the connector elements. Connector according to Claim 5, characterized in that the strips (14, 16) constituting the second and third conductors each have a first contact zone (14 b , 16 b ) by which they bear one against the another blade when the two connector elements are uncoupled and a second contact zone (14 c , 16 c ) by which they rest, one on the first conductor (5), the other on the blade (6,7 ) of the first connector element, when the two connector elements are coupled. Connector according to Claim 6, characterized in that the first contact zones ( 14b , 16b ) lie in the median plane of the connector while the second contact zones ( 14c , 16c ) are set back from this median plane, when the two connector elements are uncoupled. Connector according to either of Claims 6 and 7, characterized in that the first and / or the second contact zones (14 b , 16 b , 14 c , 16 c ) consist of a curved part projecting in the direction of the connector median plane.

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