EP1157448A1

EP1157448A1 - Coaxial connection for a printed circuit board

Info

Publication number: EP1157448A1
Application number: EP00904792A
Authority: EP
Inventors: Christian Garbini
Original assignee: Huber and Suhner AG
Current assignee: Huber and Suhner AG
Priority date: 1999-03-02
Filing date: 2000-02-29
Publication date: 2001-11-28
Anticipated expiration: 2020-02-29
Also published as: EP1157448B1; CA2365404C; AU2656400A; ES2204511T3; ATE244943T1; US6497579B1; WO2000052788A1; DE50002830D1; CA2365404A1

Abstract

The invention relates to a coaxial connection for a printed circuit board comprising an essentially cylindrical adapter (4; 104) which, with a first end (5; 105), is electrically connected to a first connector element (2; 102) and which, with a second end (6; 106), is electrically connected to a second connector element (3; 103). At least the first connector element (2; 102) is fastened to a printed circuit board (A). The adapter (4; 104) is connected, with the first end (5; 105) thereof, to the first connector element (2; 102) by means of a ball-and-socket joint (22; 122) in such a way that the adapter (4; 104) can be tilted around the center (Z) of the fixed ball-and-socket joint (22; 122) in a limited manner and without the application of forces thereon.

Description

PCB coaxial connection

The invention relates to a printed circuit board coaxial connection with a substantially cylindrical adapter, which is electrically connected with a first end to a first connector and with a second end to a second connector, at least the first connector element being fastened to a printed circuit board.

After the assembly of printed circuit boards with SMD components and the subsequent soldering, the printed circuit boards are contacted with each other in terms of high frequency. In this case, position and position inaccuracies of the SMD (Surface Mounted Device) components must be compensated for in the radial and axial directions so that the high-frequency properties are retained. Hitherto, two circuit board cable sections have been used for the aforementioned electrical connection, each of which has been fastened at the ends to the circuit boards with a connector. The flexibility of the coaxial cable sections ensured the compensation of the position and positional accuracy of the SMD components. However, this connection is comparatively expensive and also has the disadvantage that the Distances between two connected circuit boards are comparatively large.

Printed circuit board coaxial connections are known which have a substantially cylindrical adapter which engages with its two ends in a connector element. Such connectors allow a comparatively small distance between the two interconnected circuit boards. Due to the elasticity of the adapter and the connector elements, a certain compensation is also possible in the axial and radial directions. With such a compensation, however, a tension is exerted on the connector elements, which can lead to a breakage of the solder joints. Such a break is possible in particular if the further plates are subject to vibrations or shocks or other, unfavorable influences.

The invention has for its object to provide a circuit board coaxial connection of the type mentioned, which avoids the disadvantages mentioned and which is still comparatively inexpensive to manufacture and reliable.

The invention is achieved in a generic printed circuit board coaxial connection in that the adapter is connected at its first end by means of a fixed ball joint to the first connector element, in such a way that the adapter can be inclined to a limited extent around the center of the fixed ball joint in a substantially non-stressed manner. In the connection according to the invention, the adapter can be tilted in a comparatively large area essentially without building up a voltage. It is essential that, due to the ball joint, the contact force remains essentially constant when the adapter is tilted. The solder joints are thus much less stressed than before and essentially no stresses are exerted on the inner conductor either. The connection according to the invention enables a very compact construction of printed circuit boards with a distance of, for example, five to ten Millimeters. For example, two printed circuit boards can be electrically connected to one another with ten connections, the tolerances that arise in particular during soldering being able to be absorbed essentially without force.

If, according to a development of the invention, the adapter has its second end connected to the second connector element by means of a loose ball joint, then comparatively high axial tolerances can also be absorbed essentially without force, the contact force also remaining essentially constant at the second end of the adapter .

According to a further development of the invention, the fixed ball joint has joint parts which are detachably locked together. The adapter can then be snapped onto the first connector element with its first end in the manner of a push button. This pre-assembly is comparatively easy to automate and safe.

The inner conductor of the adapter is particularly unloaded when, according to a development of the invention, the two ends of the adapter each have an electrical contact surface in the form of a spherical section. The two ends of the adapter preferably engage in a sleeve-shaped part of a connector element. This ensures in a special way that the inner conductor is always unloaded and the contact force is essentially constant.

According to a preferred embodiment, the fixed ball joint is formed by the insulator of the adapter and the insulator of the first connector element. This results in a particularly cheap and permanent snap connection between two joint parts. The connection of the first ball joint can easily be released several times without damage. Further advantageous features result from the dependent claims, the following description and redrawing.

Two exemplary embodiments of the invention are explained in more detail below with reference to the drawing. Show it:

FIG. 1 shows a section through a connection according to the invention,

FIG. 2 shows the connection according to FIG. 1, but after an axial and ratial displacement of the two connector elements,

FIG. 3 shows a section through a variant of the connection according to the invention,

Figure 4. the connection according to Figure 3, however, after an axial and ratial displacement of the two connector elements to each other and

Figure 5. a partially sectioned further variant of the connection.

The connection 1 shown in FIGS. 1 and 2 has two connector elements 2 and 3 and an essentially cylindrical adapter 4. The connector elements 2 and 3 are connected to soldering points 8 with a printed circuit board A and B, respectively. Different types of connection, in particular using SMD connection technology, are suitable here and are known per se to the person skilled in the art.

The first connector element 2 forms a plug with the adapter 4, while the second connector element 3 forms a socket. In design terms, however, the first connector element 2 and the second connector element 3 are identical. However, the two ends 5 and 6 of the adapter 4 are designed differently. The first end 5 forms a fixed ball joint 22 with the first connector element 2, while the second end 6 forms a loose ball joint 23 with the second connector element 3. The first connector element 2 has an outer conductor 10 with an inner circumferential contact surface 10a, an inner conductor 11 with an inner substantially cylindrical contact surface 11a, and a plate-shaped insulator 12. The inner conductor 11 is firmly connected to the insulator 12 and forms with it a hinge pin 19 which has a spherical hinge surface 12a. This articular surface 12a is evidently formed by the insulator 12, which is formed, for example, from polytetrafluoroethylene or another suitable plastic.

The insulator 11 has at its first end 5 an inner spherical segment-shaped joint surface 21 which is designed to correspond to the joint surface 12a. As can be seen, the first end 5 engages around the pivot pin 19 and engages in an annular recess 25 of the insulator 12 with lateral play.

The outer conductor 7 of the adapter 4 is sleeve-shaped and has a circumferential, curved contact surface 7a (FIG. 2) which bears against the contact surface 10a of the outer conductor 10. The contact surface 10a is essentially cylindrical in the area of contact with the contact surface 7a and, as can be seen, widens outwards in a funnel shape.

The inner conductor 8 is provided at both ends with axial slots 8b and likewise has spherical contact surfaces 8a at both ends. The lower end of the inner conductor 8 engages in the sleeve-shaped inner conductor 11 so as to be axially displaceable, the spherical segment-shaped contact surface 8a abutting the cylindrical contact surface 11a. The outer conductor 7 is also slit axially.

As mentioned, the end 6 of the adapter 4 forms a loose ball joint 23 with the connector element 3. The outer conductor 7 contacts the second connector element 3 via a contact surface 7b which is also slightly curved in cross section (Figure 2) with a contact surface 13a. The inner conductor 8 is axially displaceable with the upper contact surface 8a in contact with the cylindrical inner contact surface 14a of the inner conductor 14. The end 6 engages in FIG. As can be seen, a spherical outer surface 15a of the insulator 15 is at a distance from a trough-shaped recess 6a of the insulator.

The adapter 4 is fastened to the first connector element 2 by inserting its end 5 into the annular recess 25 from above. The adapter 4 is snapped or snapped onto the hinge pin 19. This latching connection can be released by an axial pull-out force on the adapter 4. The snap-on adapter 4 forms with the first connector element 2 a plug which can be connected to the second connector element 3 by axially pushing the element 6 onto it. However, the connection between the adapter 4 and the second connector element 3 is loose and the end 6 is axially displaceable and radially tiltable in the annular recess 26. However, the contact of the inner conductor and outer conductor is guaranteed.

The first ball joint 2 enables the adapter 4 to be inclined to the vertical 24 around the center Z. When the adapter 4 is inclined, the distance between the center Z and the printed circuit board A remains constant. The loose ball joint 23, on the other hand, enables an inclination in all directions as well as an axial change in distance relative to the second connector element 3. Because of these two ball joints 22 and 23, the connector 1 can accommodate a relatively large offset between the two printed circuit boards A and B in the radial and axial directions. The offset that can be accommodated is comparatively large in relation to the distance between the two circuit boards A and B. With a distance of, for example, 7 mm between the two circuit boards A and B, the possible axial is Compensation for example 0.6 mm and the radial compensation for example 0.4 mm.

FIG. 2 shows the two printed circuit boards A and B which, with reference to FIG. 1, are offset axially and radially from one another. As can be seen, the adapter 4 is inclined with respect to the vertical 24. The end 6 of the adapter also engages deeper into the annular recess 26. The contacts of the inner conductor 8 to the two connector elements 2 and 3 as well as the contacts of the outer conductor 7 are ensured with essentially the same contact force. It is essential that the adapter 4 exerts essentially no tension on the two connector elements 2 and 3 and thus on the soldering points 18.

The connection 101 shown in FIGS. 3 and 4 likewise has a plug with a first connection element 102 and an adapter 104 and a socket with a second connector element 103. A fixed ball joint 122 and a loose ball joint 123 are also formed here. Here, however, the hinge pin is formed by the lower end 105 of the adapter 104 and the joint socket by a cup-shaped part 119 of the first connector element 102. The main difference to connection 1 here is that not the insulator, but the outer conductor 107 of the adapter 104 and the outer conductor 110 of the first connector element 102 form the fixed ball joint 122. The sliding surfaces of the fixed ball joint 122 also form the electrical contact of the outer conductor.

In the case of the loose ball joint 123, the electrical contact of the outer conductor is formed by a cylindrical part 107a of the outer conductor 107 and a spherical outer surface 113a of the outer conductor 113. The inner conductor 108 of the adapter 104 is likewise provided with contact surfaces 108a in the form of spherical sections. FIG. 4 shows the connection 101, the two printed circuit boards A and B being offset axially and radially with respect to FIG. 3. Here, too, essentially no force is exerted on the two connector elements 102 and 103 with essentially the same contact force.

In connection 101, too, the two connector elements 102 and 103 are of identical design. However, an embodiment is also conceivable in which the second connector element 103 is configured differently from the first connector element 102. The second connector element 103 can be designed, for example, as an angle piece which is connected to the second printed circuit board B via a further connecting part. The second connector element 103 can thus be connected indirectly to the printed circuit board B. This also applies to connection 1.

FIG. 5 shows a connection 1 ′ which essentially corresponds to that according to FIGS. 1 and 2. With connection 1 ', however, the hinge pin 19' and the hinge surface 21 'are designed such that the adapter 4' sits on the insulator 12 'with radial and axial play. The adapter 4 ', like the adapter 4', is movable and fixed to the insulator 12 '. The game mentioned enables inexpensive production, since the requirements for precision are lower. Tests have shown that the connection 1 'is also functionally reliable.

Claims

claims

1. PCB coaxial connection with a substantially cylindrical adapter (4; 104), which has a first end (5; 105) with a first connector element (2; 102) and a second end (6; 106) with a second connector element (3 ; 103) is electrically connected, at least the first connector element (2; 102) being fastened to a printed circuit board (A), characterized in that the adapter (4; 104) is connected at its first end (5; 105) by means of a Ball joint (22; 122) is connected to the first connector element (2; 102) in such a way that the adapter (4; 104) can be tilted to a limited extent in a substantially non-stressed manner.

2. Connector according to claim 1, characterized in that the adapter (4; 104) with its second end (6; 106) is connected to the second connector element (3; 103) by means of a loose ball joint (23; 123), such that that the two connector elements (2; 3; 102; 103) are axially and radially displaceable relative to each other essentially without force.

3. Connector according to claim 1 or 2, character- ized in that a fixed ball joint (22; 122) releasably latched joint parts (5; 19; 105; 110).

4. Connector according to one of claims 1 to 3, characterized in that the inner conductor (8; 108) of the adapter (4; 104) has at least one of its two ends a contact surface (8a; 108a) in the form of a spherical section .

5. Connector according to claim 4, characterized in that the two ends of the inner conductor (4; 104) each engage in a sleeve-shaped part of a connecting element (11; 111).

6. Connector according to one of claims 1 to 5, characterized in that the outer conductor (7; 107) of the adapter (4; 104) has at least one of its ends a contact surface (7a; 107a) in the form of a spherical section.

7. Connector according to one of claims 1 to 6, characterized in that the fixed ball joint (22) by the insulator (9) of the adapter (4) and the insulator (12) of the first connector element (2) is formed.

8. Connector according to claim 7, characterized in that the ball socket (21) is formed by the insulator (9) of the adapter (4).

9. Connector according to claim 8, characterized in that the insulator (12) of the first connector element (2) is cup-shaped and forms a hinge pin (19) in which the inner conductor (11) of the first connector element (2) is fastened .

10. Connector according to claim 1, characterized in that the joint socket (119) of the fixed ball joint (122) is formed by the outer conductor of the first connector element (102).