FR2990069A1 - Connector assembly for connecting two printed circuit boards in e.g. space field, has connection including rigid body, and set of elastic contacts of masses is adapted to be in support against interior of rigid body of connection - Google Patents

Abstract

The assembly (1) has a connection (3) including a rigid body of solidified length, and a central contact (31) that is arranged with a rigid end (35). A set of insulators (32) is interposed between the central contact and the rigid body. A base plate (2) includes a rigid body (20). A central elastic contact (41) of another base plate (4) is adapted to be in support against a rigid end (35) of the central contact in a plane (P) defined by a centering surface (45). A set of elastic contacts of masses (22, 42) is adapted to be in support against interior of the rigid body of the connection. Independent claims are also included for the following: (1) a connection module (2) a connection module assembly.

Description

The present invention relates to a connection assembly and, a connection connection, bases, and an associated connection module. Such a connection assembly may allow in particular to connect two parallel printed circuit boards, usually called card-to-board connector, or a printed circuit board to another component such as a module or a filter. The invention applies for example to a connection assembly for connecting cards inside RRU / RRH transmitter modules (acronym for the expression "Remote Radio UnitRemote Radio Head") for the communications market without thread. The invention also relates generally to connection assemblies in the medical field, the aeronautical or transport field, the space domain or the telecommunications field. There already exist on the market and in the prior art examples of connection sets dedicated to the telecommunications sector for cellular radiotelephone infrastructures. Indeed, the tendency on this market is to minimize the losses of the RF part (acronym of the expression in English "Radio Frequeney") in order to reduce the amplification elements of the base stations. For this, on the one hand, the actual radio part of the stations is more and more delocalized closer to the transmitting-receiving antennas, in the RRU / RRH transmitter modules), and on the other hand, the RF cords. internal to the radio unit are replaced by direct interconnections.

So-called card-card connections have been developed in successive generations in the last decade. Thus, a first generation of connection sets for direct interconnection of cards, for example sold under the names SMP, SMP-Corn, MMBX by RADIALL, is known. Such connection assemblies are constituted respectively of a first snap-type base, a second base of the "sliding" type (smooth bore) with a guide cone ("slide"). it is called "receptaele" in English), and a connection connector, called adapter, at the ends of which are respectively fixed the first and second bases. The connection is therefore blind, by refocusing the connection connection by means of the guide cone of the sliding base. The major disadvantage is the strong limitation of axial and radial misalignments allowed for these connections. Indeed, the axial misalignment is limited to a few tenths of a millimeter, of the order of 0.3 mm to 0.6 mm, to maintain the impedance of the coaxial line at a value equal to 50 Ohm. The radial misalignment is made by a rotation of the connection in the groove of the snap-in base, this rotation being in fact relatively small to avoid damaging the central contact and the elastic means provided with the connection fitting.

A second generation of connection sets is also known, for example sold under the names SMP-MAX, by RADIALL or sold under the names MBX, by SUHNER or sold under the name AFI by Amphenol RF. , or also marketed under the name Long Wipe SMP and P-SMP by Rosenberger. Such connections, for connecting two printed circuit boards, generally consist of three elements, namely: a first slip-type base, a second snap-in or retention-type base and a connection connection at the ends of which are respectively fixed the first and second bases. The first and second bases are conventionally made of brass and have no elastic functions. The connection connection is typically made of a noble high cost elastic metal material, for example CuBe2 or BZ4, and provided at each of its ends elastic means (petals and slots for example) cooperating with the first and second bases. This second generation of connections has made it possible to increase the tolerated value of the axial misalignment. Thus, as described in particular in the patent application WO 2010/010524, this increase can result from an impedance compensation at the end of the connection, which makes it possible to obtain a compromise of mechanical and electrical performance regardless of the inclination of the connection relative to the bases. However, all known card-to-board connections have a significant number of disadvantages. On the one hand, because the connections of these connections have elastic means generally consisting of petals at their ends, they may be fragile. Thus, it is common during the blind connection that the connector is damaged during its contact with the guide cone of a sliding base.

On the other hand, the configuration of the connections does not allow to obtain a radial misalignment and / or axial misalignment sufficiently important. In particular, large angles of rotation, typically greater than 3.50, can not be achieved under penalty of causing undesired permanent deformation of the elastic means of the connection.

This permanent deformation leads to a significant degradation of electrical performance (electrical continuity), which in fact limits the radial misalignment allowed, especially for a distance between cards to be connected which is low. Finally, the cost of making these connections is relatively high, thus constituting a brake for this type of market. In particular, the realization of the connection connection of a noble material, especially when the connection has a significant length, and the realization of possible slots on this connection lead to significant production costs. There is therefore a need to further improve this type of connection, in particular to benefit from a connection that is simple and low-cost design and assembly, while allowing axial and / or radial misalignment and preservation of radio frequency properties. satisfactory. The invention aims to meet all or part of these needs. The invention thus has, according to one of its aspects, a connection assembly, intended in particular for connecting two printed circuit boards, comprising: a connection fitting comprising: a rigid body of fixed length, of which one end is of at least partially spherical external shape while the other end is of elongated external shape, 6 a central contact of which at least one end is rigid, - at least one insulator, interposed between the central contact and the body, a first base comprising: a rigid body provided with a housing whose inner peripheral surface is of at least partially spherical or frustoconical shape; a central contact, a peripheral contact disposed at the periphery of the central contact, forming a ground contact, the ground contact being elastic, an insulator interposed between the central contact and the ground contact, the central contact, the mass contact and insulation being received in the housing of the body, a second base comprising: a rigid body provided with a housing; - A centering cone, having a centering surface - a resilient central contact, has a peripheral contact disposed at the periphery of the. central contact, forming a mass contact, the mass contact being elastic, an insulator interposed between the central contact and the ground contact, the central contact, the mass contact and the insulator being received in the housing of the body connection assembly in which the spherical or frustoconical surface of the first base is adapted to cooperate with the spherical end of the coupling by defining a ball joint while the centering surface of the second base is adapted to cooperate with the rigid end. extending the connection by defining a sliding connection, and wherein the elastic central contact of the second base is adapted to bear against the rigid end of the central contact of the connector in a plane defined by the centering surface, wherein the The elastic ground contacts of the bases are adapted to bear against the inside of the rigid coupling body. In other words, according to the invention and unlike the connection assemblies according to the state of the art, the mechanical guiding and mechanical support functions between bases and the functions of electrical signal and electrical continuity are assigned to distinct mechanical elements. between bases. In other words, the outer end surfaces of the rigid connection connector body are assigned exclusively to the guiding and mechanical retention functions, one of these external surfaces being in ball joint connection and the other of them being in sliding connection with its corresponding base. This allows axial misalignment and / or radial misalignment of the connection much greater than that (those) obtained with the connections according to the state of the art. The electrical connection functions on the one hand between the central contacts to ensure the passage of the electrical signal and on the other hand between the ground contacts being provided by the elasticity that is imparted to these contacts.

The arrangement of the central contacts and elastic mass according to the invention implies that they are very little mechanically stressed, their elasticity being dimensioned only to establish points of electrical contact. The main advantages provided by the connection according to the invention are numerous and can be enumerated as follows: - obtaining significant axial and / or radial disalignernent (s) with in particular, a large inclination angle, typically greater than or equal to 50 allowing a large radial misalignment, typically of 0.5 mm, to be obtained for distances separating two printed boards to be connected which are small, typically less than 9 mm, - robustness of the coupling interface between the connection fitting ( adapter) and the second base due to the sliding connection, - reliability of the electrical contacts according to the invention because they can be deflected almost identically regardless of the angle of inclination of the connection connection, - constancy of the resistance of the electrical contacts and interrnodulation performances between two printed boards connected by the connection assembly according to the invention, whatever e is the angle of inclination of the connection connection, - obtaining very good radiofrequency performance of the connection 20 (power, loss, standing wave ratio (ROS or VSWR), - obtaining very good electromagnetic shielding performance, - Reduction of the manufacturing cost of the connection connection because it can be made of a less expensive material, not noble, for example brass, - Low variation in manufacturing cost according to the distances between two printed cards to connect, because the rigid body of the connection connector according to the invention: it can thus advantageously be made of free-cutting brass instead of copper-beryllium or high-strength bronze used for the connection connectors according to the state of the art; possible reduction of the two-component interconnection when the first base is assembled with the connection by constituting a module, which allows automatic installation for distances between printed boards to connect considered relatively low, possible realization of a sealed interconnection by the addition of O-rings in the bases. Indeed, having a connection without external openings (slots) allows this option. This seal may be a seal against fluids and / or electromagnetic radiation. This is advantageous especially for RRU / RRH having no forced convection cooling, which may be subject to problems of air condensation at certain times of the year. According to an advantageous embodiment of the invention, the connection assembly may further comprise an assembly element connected to the body of the first base, to mechanically assemble the connection connection and the first base.

According to an alternative embodiment, the connecting element is adapted to permanently assemble the connection connector and the first base. According to an alternative variant, the connecting element is adapted to removably assemble the connection connector and the first base. The assembly member may be an assembly cap attached to the body of the first base. It can also be a part of the body of the first base deformed by crimping around the connection fitting. According to an alternative embodiment, the coupling may comprise stop means and the connecting element may comprise complementary abutment means for limiting the angular displacement of the connection relative to the first base. Advantageously, the end of the spherical outer-shaped coupling body further comprises a spherical or frustoconical inner shape so as to have a spherical bearing whose center of rotation coincides with that of the ball joint connection. This makes it possible to obtain a constant deflection of the elastic mass contact of the first base whatever the angle of inclination of the connection fitting (adapter) according to the invention. Thus, according to this variant embodiment, the spherical inner surface can be simplified to a frustoconical surface tangent to the sphere, this making it possible to simplify machining while not significantly increasing the deflection variation of the elastic contacts. Also advantageously, the end of the central contact of the connector, disposed on the side of the spherical end of the coupling body, is a sphere and the central contact of the first base is a cylindrical socket, the sphere and the socket being arranged so as to have the center of rotation of the sphere coincides with that of the ball joint. This also makes it possible to obtain a constant deflection of the elastic central contact which is either the sphere of the connection or the socket of the first base, whatever the angle of inclination of the connection fitting (adapter) according to the invention. . According to a variant, the end of the central contact of the connector is a rigid solid sphere and the socket of the first base is elastic. According to an alternative variant, the end of the central contact of the connector is an elastic split sphere and the socket of the first base is rigid. The central elastic contact of the second base is advantageously a split socket forming a tulip contact whose petals are brought closer together at an angle greater than the angle of inclination of the rigid end of the central contact of the connector relative to the axis of the second base. A connection assembly according to the invention may further comprise two elements of toroidal electrical conductive material disposed one in peripheral contact with the spherical end of the rigid body of the connector and the other in peripheral contact with the end of elongated shape. These electrically conductive elements further improve the electromagnetic shielding of the connection according to the invention relates, in another of its aspects, a connection connection for connection assembly, including a connection assembly for connecting two printed circuit boards. and comprising two bases joined by a coupling, comprising a rigid body of fixed length, one end of which is of at least partially spherical external shape while the other end is of elongated external shape, a central contact of which at least one end is rigid at least one insulator interposed between the central contact and the rigid body.

According to a preferred variant of the invention, the rigid body is devoid of slots. The absence of slots can reduce radio frequency leaks, harmful to the installation and likely to occur in the connections of the prior art when a strong misalignment occurs. The absence of these fragile petals also increases the robustness of the connection connection.

According to one embodiment, an end of the central contact of the connector, disposed on the side of the spherical end of the coupling body, is a sphere and the other end of the central contact is a rigid pin.

The rigid body may be brass. The invention also relates, in another of its aspects, to a base for connection assembly, in particular a connection assembly for connecting two printed circuit boards and having two bases joined by a connection, comprising: a rigid body provided with a housing whose inner peripheral surface is of at least partially spherical or frustoconical shape; a central contact, a peripheral contact disposed at the periphery of the central contact, forming a mass contact, the ground contact being elastic, an insulator interposed between the central contact and the ground contact, the central contact, the mass contact and insulation being received in the housing of the body. The invention further relates, in another of its aspects, to a base for connection assembly, in particular a connection assembly intended to connect two printed circuit boards and comprising two bases joined by a coupling, comprising a rigid body provided with housing; - A centering tip comprising a centering surface, - a central contact, * a peripheral contact disposed at the periphery of the central contact, foimant a ground contact, the ground contact being elastic, - an insulator interposed between the central contact and the mass contact, the central contact, the ground contact and the insulator being received in the housing of the body. According to an alternative embodiment, the centering surface of the centering tip is of annular shape and of section in a portion of a circle. The elastic mass contact can be made of high-strength bronze.

The invention further relates, in another aspect, to a connection module (M) for a connection assembly, in particular a connection assembly for connecting two printed circuit boards and comprising two bases joined by a connection, comprising: a base described above, a connection connection described above, an assembly element connected to the body of the base, to permanently mechanically assemble the connection connector and the base.

According to one variant, the assembly element is an assembly cap attached to the body of the base. According to an alternative variant, the assembly element is a part of the body of the base deformed by crimping around the connection fitting.

Finally, the invention relates to an assembly comprising a plurality of connection modules (M) described above, the modules being packaged in honeycomb strips for their gripping and their individual laying on an electronic component, such as a printed circuit board , using an automatic laying machine.

The bodies of the bases, the body of the connection fitting and / or the central contact of the connection connector may be made of a metallic material, in particular brass. As a variant, the bodies of the bases, the body of the connection fitting and / or the central contact of the connection connector may be made of a plastic material, in particular of a polymeric material, for example chosen from PAA (polyaryl-amide), PAT (polyamide-imide), PPS (polyphenylene sulfide) and PES (polyether sulfone). Selective metallization, at least partial, may be performed, that is to say a selective application of a metallization layer on the surfaces of the part or parts requiring preservation of some of their functionalities, such as for example a good one. weldability or good electrical conductivity. The assembly element may be metallic or plastic. Similarly, the centering tip can also be metal or plastic. The insulators of the bases and / or the insulator of the connection connection may be made of a polymeric material, for example as described above and preferably made of polytetrafluoroethylene (PTFE). The invention will be better understood on reading the description which follows, examples of non-limiting implementation thereof, and on examining the appended figures among which: FIG. 1 is a view in longitudinal section of an example of a connection assembly that is in accordance with the invention, illustrating the radial misalignment obtained; FIG. 1A is a detailed view of the connection assembly of FIG. 1, at the central contact of the connection; connection and the second base according to - Figure 1B is a longitudinal sectional view of an example of a connection module 5 having a first base joined with a connection connector according to the invention, illustrating the angle of inclination 2 is a longitudinal sectional view of an exemplary connection fitting according to the invention; FIG. 3 is a longitudinal sectional view of an example of a second base according to the invention; invention, - Figure 4 is a longitudinal sectional view of an example of a first base according to the invention, FIGS. 5A to 5F are longitudinal sectional views illustrating the successive steps of coupling between connection connection and second base according to the invention, FIG. is a longitudinal sectional view of an example of a connection module comprising a first base joined with a connection connector according to the invention, illustrating an alternative embodiment of their central contacts, - Figures 7A and 7B are views of longitudinal section of an example of a connection module comprising a first base joined with a connection fitting according to the invention, illustrating two alternative embodiments of the connection of different length, FIG. 8 is a side view of an example connecting module comprising a first base joined with a connection connector according to the invention, illustrating an alternative embodiment, - Figure 8A is a longitudinal sectional view of the connection module according to FIG. 8, FIG. 9 is a longitudinal sectional view of an example of a connection module comprising a first base joined with a connection connector 30 according to the invention, illustrating an alternative embodiment of the connector of great length, FIG. 9A is a detailed view of a connection module according to FIG. 9, FIG. 10 is a longitudinal sectional view of an example of a connection assembly according to FIG. the invention, illustrating the radial misalignment obtained.

FIG. 1 shows an example of connection assembly 1 according to the invention, in radial misalignment configuration. This connection assembly 1 comprises, respectively from left to right in FIG. 1, a first base 2, a connection connection 3 and a second base 4. FIGS. 2, 3 and 4 show the connection connection respectively. 3, the second base 4 and the first base 2 of the connection assembly 1 according to Figure 1. The first base 2 X2 axis of the invention comprises a rigid body 20 provided with a housing, a central contact 21 a peripheral contact 22 disposed at the periphery of the central contact. The peripheral contact 22 is elastic and forms a ground contact. An insulator 23 is interposed between the central contact 21 and the earth contact 22. The housing of the body 20 houses the central contact 21, the ground contact 22 and the insulator 23. The housing has an internal peripheral surface 24 of shape at less partially spherical or frustoconical. As illustrated in FIG. 4, the central contact 21 is a rigid socket. The connection connector 3 of X3 axis according to the invention comprises a rigid body 30 of fixed length, a central contact 31, an insulator 32 interposed between the central contact 31 and the rigid body 30. As illustrated in Figure 2 the rigid body 30 has one end of spherical outer shape 33 while the other end 34 is of elongated outer shape. This end 34 may be a tube portion. As illustrated in FIG. 2, one end 25 of the central contact 31 is an elastic split sphere 36 and the other end is a solid rigid pin 35. The second base 4 of axis X4 according to the invention comprises a rigid body 40 provided with a housing, a central contact 41, a peripheral contact 42 disposed at the periphery of the central contact. The peripheral contact 42 is elastic and forms a ground contact. An insulator 43 is interposed between the central contact 41 and the earth contact 42. The housing of the body 40 houses the central contact 41, the ground contact 42 and the insulator 43. The second base 4 also comprises a centering tip 44 having a centering surface 45. As illustrated in FIG. 3, the central contact 41 is a split socket forming a tulip contact so the petals 47 are mutually reciprocated. As also illustrated in Figure 3, the centering surface 45 is annular in shape and circular in section. The top of this surface defines a plane P.

According to the invention, when the connection connector 3 is connected to the first base 2 and to the second base 4, as illustrated in FIG. 1, the spherical or frustoconical surface 24 of the first base 2 cooperates with the spherical end 33. fitting 3 by defining a ball joint. The centering surface 45 of the second base 4 cooperates with the elongated rigid end 34 of the coupling 3 by defining a sliding connection. The elastic central contact 41 of the second base 4 bears against the rigid end 35 of the central contact 31 of the connector 3 in the plane P defined by the centering surface 45. Finally, the elastic mass contacts 22, 42 are in contact with each other. bearing against the inside of the rigid coupling body 30. A significant radial misalignment of the connection assembly according to the invention can be obtained through the ball joint connection on the side of the first base 2. A significant axial misalignment of the connection assembly according to the invention can be obtained through the sliding connection on the side of the second base 3. This (s) misalignment (s) axial and / or radial allow a tolerance on the distance between the two elements to be connected by the connection assembly according to the invention, such as PCB printed circuit boards (acronym for "Printed Circuit Board").

As illustrated in FIG. 1A, the plane P passing through the top of the centering surface contains the points of contact between the rigid pin 35 of the central contact 3 and the resilient split socket 46 of the central contact 41 of the second base 41. The deflection of the Petals 47 of the sleeve 46 is thus constant whatever the angle of inclination of the connector 3 in the second base 4, that is to say the angle of inclination between the axes X3 and X4. In addition, the drilling diameter of the bushing 46, as well as the angle of the elastic petals 47 are sized to have the latter brought closer together at an angle greater than the angle of inclination of the rigid pin 35 of the central contact 31 of the connection relative to the axis X4 of the second base. In other words, the dimensioning is made to have the contacts in the plane P. In other words, even under the maximum inclination between connection 3 and second base 4, or between axes X3 and X4, there remains a clearance between the cylindrical end of the pin 35 and the inner surface of the sleeve 46. The mechanical forces on these areas that provide the electrical contacts are therefore low and almost constant, thus making the electrical contact points extremely reliable. As illustrated in FIG. 1B, the end of the spherical external-shaped connecting body 33 also has a spherical internal shape 37 so as to have a spherical bearing with the elastic mass contact 22. The spherical support thus has a 0 center of rotation coincides with that of the ball joint. Concomitantly, the end of the central contact 31 of the connector 3, disposed on the side of the spherical end 33 of the coupling body, is a sphere 36 and the central contact of the first base 2 is a cylindrical sleeve 21. The sphere 36 and the sleeve 21 are arranged so as to have the center of rotation 0 of the sphere 36 coincides with that of the ball joint. In other words, the spherical end 33 is in ball-and-socket connection on a first sphere of diameter C1, the electrical mass contact 22 is in spherical abutment on a second sphere of diameter C2 and the sphere 36 of the central contact 31 is in spherical bearing on a third sphere of diameter C3, the three diameters C1, C2 and C3 being concentric. This makes it possible to obtain a constant deflection of the elastic portions of the central contact 36 and of the ground contact 22 regardless of the angle of inclination of the connection 3 with respect to the first base 2, that is to say whatever the angle formed between the axes X2 and X3. FIGS. 5A to 5F show the different coupling steps between a connection module M, comprising the first base 2 previously assembled to the connection connection 3, and the second base 3 in the case of a defect. initially radial, typically of the order of 0.5mm (Figure 5A). FIG. 5B illustrates the first mechanical contact between the elongate end 34 of the coupling body 3 and a frustoconical surface of the centering bit 44, when the connection module M and the second base 4 are mutually close together. The connection fitting 3 is then rotated and slid on the frustoconical surface of the centering tip 44 (FIG. 5C). Then, the elongated end 34 of the coupling body 3 is centered in the second base 4, when it is slidingly connected to the centering surface 45 (FIG. 5D). There is then establishment of an electrical contact on the one hand between the elastic mass contact 42 of the second base 2 and the inside of the rigid body 30 of the connection 3 and on the other hand between the elastic central contact of the second base 2 and the rigid pin 35 of the connector 3 (Figure 5 E). Finally, we obtain the maximum insertion of the rigid body 31 and the rigid pin 35 of the connector 3 (Figure 5F). The electrical contacts are then established over a relatively large stroke, typically 2 mm. FIG. 6 shows an alternative embodiment in which the sphere 36 of the central contact 31 of the connector 3 is solid and rigid and cooperates with an elastic split bushing 25 as the central contact 21 of the first base 2. FIGS. 7A and 7B illustrate two variants of different length of the connection connection 3, namely respectively a length Li and a length L2. A fitting of length L2 comprises two insulators 32, 38 spaced from each other to support the central contact 31. For example, a connection connection with a length Li may advantageously be chosen for a card-to-board distance less than 9mm up to 13 mm. Similarly, by way of example, a connection connection with a length L2 may advantageously be chosen for a card-to-card distance of between 13 mm and 20 mm. FIGS. 8 and 8A illustrate an alternative embodiment of the connection module M in which the first base 2 is permanently assembled to the connection connector 3 by crimping a portion 26 of the body of the second base 2 around the body 30 of the connection. Alternatively, as shown on the 1, 1B, 5A 20 to 7B, the permanent assembly can be achieved by means of a cover 5 fixed in particular by screwing on the body 20 of the first base 2. Figures 9 and 9A illustrate an alternative embodiment of the connection module M in which the first base 2 is removably assembled to the connection connection 3 by a cover 5 'snapped onto the body 20 of the first base 2. In this variant, the connection 3 is of great length L3 comprises two insulators 32, 38 spaced from each other to support the central contact 31. The latching cover 5 'comprises a stop recess 50 which cooperates with a complementary abutment rib 39 made on the rigid body 30 of the connector 3. This makes it possible to limit limiting the axial displacement of the connection connector 3. According to this variant, the catch 5 is preferably snapped onto the body 20 of the first base 2 and then the meeting the connector 3 with the first base 2, only after welding the latter to one of the PCBs to be connected by the connection assembly. By way of example, a connection connection with a length L3 may advantageously be chosen for a card-to-card distance greater than 20 mm. FIG. 10 illustrates an example of a connection assembly according to the invention in which the two bases 2, 4 are perfectly aligned axially, that is to say that the axes X 2, X 3 and X 4 are aligned, but in which one axial misalignment is present. This FIG. 10 also illustrates an alternative embodiment making it possible to further improve the electromagnetic shielding of the connection according to the invention. Thus, there are provided two elements 6, 7 of toric-shaped electrical conductive material disposed one 7 in peripheral contact with the spherical end 33 of the rigid body 30 of the connector 3 and the other 6 in peripheral contact with the end These elements 6, 7 which may be designated as seals may also serve as fluid seals Other variants and improvements may be provided without departing from the scope of the invention .

The phrase "with one" should be understood as being synonymous with "having at least one" unless the contrary is specified.

Claims (22)

REVENDICATIONS1. Connection assembly (1), intended in particular for connecting two printed circuit boards, comprising: - a connection fitting (3) comprising: - a rigid body (30) of fixed length, one end of which is of external form (33) at least partially spherical while the other end (34) is of elongated outer shape, * a central contact (31) at least one end (35) is rigid, - at least one insulator (32, 38) interposed between the central contact (31) and the rigid body (30), a first base (2) comprising: - a rigid body (20) provided with a housing whose inner peripheral surface (24) is at least partially spherical in shape or truncated; - A central contact (21), a peripheral contact (22), disposed at the periphery of the central contact, forming a ground contact, the ground contact being elastic, - an insulator (23) interposed between the central contact and the mass contact, the central contact, the ground contact and the insulator being received in the housing of the body (20), a second base (4) comprising: - a rigid body (40) provided with a housing; - a centering tip (44), having a centering surface (45), - a central contact (41), a peripheral contact (42) disposed at the periphery of the central contact, forming a ground contact, the contact of mass being elastic, - an insulator (43) interposed between the central contact and the ground contact, the central contact, the ground contact and the insulator being received in the housing of the body (40), connection assembly in which the spherical or frustoconical surface (24) of the first base (2) is adapted to cooperate with the spherical end (33) of the coupling (3) by defining a ball joint, while the centering surface (45) of the second base (4) is adapted to cooperate with the elongate rigid end (34) of the coupling by defining a sliding connection, wherein the elastic central contact (41) of the second base (4) is adapted to bear against the rigid end (35) of the central contact (31) of the racco rd (3) in a plane (P) defined by the centering surface (45), wherein the elastic mass contacts (22, 42) are adapted to bear against the inside of the rigid joint body (30). (3). 2. Connection assembly according to claim 1, further comprising an assembly element (5) connected to the body of the first base (2) for mechanically joining the connection connection (3) and the first base (2). The connection assembly of claim 2, wherein the joining member is adapted to permanently assemble the connection fitting and the first base. 4. Connection assembly according to claim 2, wherein the connecting element is adapted to removably assemble the connection connection and the first base. 15 5. Connection assembly according to one of claims 2 to 4, wherein the connecting element is a cover (5, 5 ') assembly fixed to the body of the first base. 6. Connection assembly according to one of claims 2 to 4, wherein the connecting element is a portion (25) of the body (20) of the first base (2) 20 deformed by crimping around the connection connection (3). 7. Connection assembly according to one of claims 2 to 6, wherein the connector comprises stop means (39) and the connecting member comprises complementary abutment means (50) for limiting the angular movement of the fitting. relative to the first base. 25 8. Connection assembly according to any one of the preceding claims, wherein the end of the body (30) of connection (3) of spherical outer shape (33) further comprises a spherical (37) or frustoconical internal shape so to have a spherical bearing whose center of rotation coincides with that of the ball joint. 30 9. Connection assembly according to one of the preceding claims, wherein the end of the central contact of the connector, disposed on the side of the spherical end (33) of the coupling body, is a sphere (36) and the central contact the first base (2) is a cylindrical sleeve (21), the sphere and the sleeve being arranged so as to have the center of rotation of the sphere coincides with that of the ball joint. 10. Connection assembly according to one of the preceding claims, wherein the elastic central contact (41) of the second base is a sleeve (46) slotted forming a tulip contact whose petals (47) are mutually reconciled at an angle greater than the angle of inclination of the rigid end of the central contact of the connector relative to the axis X4 of the second base. 11. Connection assembly according to one of the preceding claims, further comprising two elements of toric-shaped electrical conductive material 10 disposed one in peripheral contact with the spherical end of the rigid body of the connector and the other in peripheral contact. with the end of elongated shape. 12. Connection connection (3) for connection set (1) according to one of claims 1 to 11, in particular a connection assembly for connecting two printed circuit boards and having two bases joined by a connection, comprising a 15 rigid body (30) of frozen length, one end of which is of at least partially spherical external shape (33) while the other end (34) is of elongated external shape, a central contact (31) of which at least one end ( 35) is rigid, at least one insulator (32, 38) interposed between the central contact (31) and the body (30) rigid. 13. Fitting (3) according to the preceding claim, the rigid body being devoid of slots. 14. Fitting (3) according to one of claims 12 or 13, wherein one end of the central contact of the connector, disposed on the side of the spherical end of the coupling body, is a sphere (36) and the other end the central contact is a rigid pin (35). 25 15. Base (2) for connection assembly (1) according to one of claims 1 to 11, including a connection assembly for connecting two printed circuit boards and having two bases joined by a connector, comprising: a rigid body (20) provided with a housing whose inner peripheral surface (24) is at least partially spherical or frustoconical in shape; A central contact (21), a peripheral contact (22) disposed at the periphery of the central contact, forming a ground contact, the ground contact being elastic, an insulator (23) interposed between the central contact (21) and the mass contact (22); the central contact, the ground contact and the insulator being received in the housing of the body (20). 16. Base (4) for connection assembly (1) according to one of claims 1 to 11, in particular a connection assembly for connecting two printed circuit boards and having two bases joined by a coupling, comprising: a body rigid (40) provided with a housing; a centering tip (44), having a centering surface (45), a center contact (41), a peripheral contact (42) disposed at the periphery of the central contact, forming a ground contact, the ground contact being elastic, an insulator (43) interposed between the central contact (41) and the mass contact (42); the central contact, the ground contact and the insulator being received in the housing of the body (40). 15 17. Base (4) according to claim 16, the centering surface (45) of the centering cap (44) being annular in shape and sectional in section of a circle. 18. Base (4) according to one of claims 16 or 17, the elastic mass contact (42) being made of high-resistance bronze. 19. Connection module (M) for connection assembly (1), in particular a connection assembly for connecting two printed circuit boards and having two bases joined by a connector, comprising: a base (2) according to claim 15 , a connector (3) according to one of claims 12 to 14, an assembly element (5) connected to the body of the base, to permanently mechanically assemble the connection connection and the base. 20. Connection module according to claim 19, the connecting element being an assembly cap (5) fixed to the body (20) of the base (2). 21. Connection module according to claim 19, the connecting element being a portion (26) of the body (20) of the base deformed by crimping around the connection connection (3). 22. An assembly comprising a plurality of connection modules (M) according to one of claims 19 to 21, the modules being packaged in honeycomb strips allowing their gripping and their individual laying on an electronic component, such as a printed circuit board , using an automatic laying machine.