EP2869405B1 - Connecting device for electrically connecting two circuit boards - Google Patents

Description

The invention relates to a connecting device for electrically connecting two printed circuit boards, having a first and a second coaxial connector and a coupling member, the two coaxial connector and the coupling member each having an outer conductor and an inner conductor and the outer conductor of the coaxial connector via the outer conductor of the coupling member and the inner conductor the coaxial connector are electrically connected to each other via the inner conductor of the coupling member, and wherein the coupling member from an aligned orientation tiltable and slidably disposed in the axial direction between the two Koaxialsteckverbindern.

In electrical systems often several printed circuit boards are used, the tracks must be electrically connected to each other. Here, coaxial connectors can be arranged on the circuit boards, which are then connected to each other, for example via a coaxial cable. The connection via a coaxial cable has the advantage that position inaccuracies and relative movements of the two circuit boards can be compensated. However, the connection by means of coaxial cable is relatively expensive and moreover has the disadvantage that the distances between the two printed circuit boards must be chosen to be relatively large.

Instead of connecting the coaxial connectors of the printed circuit boards via a coaxial cable, it has also been proposed to connect the two coaxial connectors to one another via a rigid coupling member. The coupling member is formed substantially cylindrical and makes it possible to arrange the two printed circuit boards and the coaxial connectors fixed thereon at a small distance from each other. The coupling member has a Inner conductor via which the inner conductor of the two coaxial connectors are connected together. In addition, the coupling member has an outer conductor, via which the outer conductor of the two coaxial connectors are interconnected. The coupling member is disposed between the two coaxial connectors and can be tilted from an orientation in which the coupling member is aligned with the two Koaxialsteckverbindern and moved in the axial direction. This makes it possible to arrange the two circuit boards while maintaining an electrical connection at a small distance from each other and to move to some extent relative to each other. In addition, position inaccuracies can be compensated by the tiltable and axially displaceable arrangement of the coupling member.

A connection device of the type mentioned is from the utility model DE 202 08 425 U1 known. In the connection device described therein, the coaxial connectors each have an inner conductor in the form of a contact pin, which can be brought into engagement with an end-side recess of the inner conductor of the coupling part. The outer conductors of the coaxial connectors each form an outer conductor socket into which the outer conductor of the coupling member can be inserted. The outer conductor of the coupling member has at its ends in each case a circumferential annular bead, which contacts the inside of the outer conductor bushing. The known connection device makes it possible to move the coupling member in the axial direction to some extent and to tilt out of alignment. For example, due to vibrations, however, micromovements, in particular vibrations, of the coupling member can result. The micro-movements can lead to abrasion, which can affect the electrical transmission properties of the connecting device.

In the publication WO 00/52788 A1 a connecting device is proposed in which the coupling member is mechanically connected via a fixed ball joint with one of the two coaxial connector. Although the fixed ball joint allows the coupling member relative to the coaxial connector to tilt, an axial movement is not possible with respect to this coaxial connector.

In the DE 100 57 143 C2 a connecting device is proposed in which the coupling member is also mechanically connected to one of the two coaxial connectors. For this purpose, a radial extension arranged on the outer side of the outer conductor of the coupling member engages in an annular groove which is arranged on the inner side on the outer conductor of a coaxial connector designed as an outer conductor bushing. The freedom of movement of the coupling member is thereby limited. In addition, it has been shown that the provision of a latching connection can affect the electrical transmission properties of the connecting device.

From the document US 2011/256760 A1 a connection device is known with a first coaxial connector which forms a plug part, and a second coaxial connector which forms a socket part. The plug part and the socket part each have an outer conductor and an inner conductor, which can be electrically connected to each other by the plug part is inserted into the socket part. The female part has a housing which comprises a stepped housing passage, which carries at its plug-side end an internal thread and at a distance from the internal thread via a radially inwardly directed stage merges into a passage area with a smaller diameter. The housing accommodates a coupling part which also has an inner conductor and an outer conductor and which can be pressed with a rear portion in the region of smaller diameter of the housing passage, wherein it is surrounded in the region of the stage by an elastic retaining ring. With its front portion of the outer conductor of the coupling part can be inclined to the longitudinal axis of the housing passage. With the help of a surrounding the front portion of the coupling part Einschraubhülse which can be screwed into the housing passage, the coupling part is held immovably in the housing passage.

From the document WO 2013/150059 A1 a connection device with the features of the preamble of claim 1 is known. To limit the maximum lateral deflection (tilting movement) of the coupling element is in the known connection device in at least one outer conductor of the two coaxial connector, a limiting element, preferably a limiting ring arranged, on which the coupling member comes upon reaching a maximum lateral deflection to the plant. The limiting element can be made of an elastic material.

Object of the present invention is to develop a connection device of the generic type such that it has improved electrical transmission properties and the risk of micro-movements of the coupling member can be reduced.

This object is achieved according to the invention in a connection device of the type mentioned above, that the coupling member is held on an elastically deformable, dielectric retaining ring which surrounds the coupling member in the circumferential direction and bears the outer conductors of both coaxial connector.

In the connection device according to the invention, the coupling member is supported via an elastically deformable, dielectric retaining ring on the outer conductors of both coaxial connectors. The retaining ring is made of a dielectric material and elastically deformable. The deformability of the retaining ring makes it possible to move the coupling member relative to the coaxial connectors in the axial direction and to tilt out of alignment, so that over the coupling member position inaccuracies and relative movements of the two circuit boards, which are electrically connected to each other via the connecting means, can be compensated , However, the elastically deformable retaining ring counteracts micro-movements of the coupling member, which could lead to abrasion and thus to an impairment of the electrical transmission properties of the connecting device. The mobility of the coupling member to compensate for position inaccuracies and relative movements of the two circuit boards is practically not limited by the elastically deformable retaining ring, but the retaining ring acts in particular against vibrations of the coupling member.

According to the invention, the retaining ring bears against the outer conductors of both coaxial connectors. The coupling member is supported via the retaining ring on both outer conductors of the coaxial connector. The retaining ring allows a structurally simple way of centering the coupling member. In addition, the retaining ring facilitates the positioning of the coupling member to the coaxial connectors and simplifies the assembly of the connecting device.

Conveniently, the retaining ring is positively connected to the coupling member.

It can be provided, for example, that the outer conductor of the coupling member has on its outside, preferably in the longitudinal direction of the coupling member centrally, an annular groove or an annular bead and the retaining ring has a complementary to the annular groove or the annular bead configured retaining ring portion which dips into the annular groove form fit or surrounds the annular bead in a form-fitting manner.

The retaining ring is made of a dielectric material. Preferably, the retaining ring is made of an elastomer.

It is particularly advantageous if the retaining ring is profiled. The profiling gives the retaining ring in addition to its material elasticity and a formula elasticity, which improves the deformability of the retaining ring and thus mobility of the coupling member to compensate for position inaccuracies and relative movements of the two circuit boards.

In a particularly preferred embodiment of the invention, the retaining ring on the coupling member and at least one coaxial connector splash-proof. The retaining ring thus forms a sealing element which prevents the penetration of spray water and impurities, for example dust, into the region between the coupling member and the at least one coaxial connector.

Preferably, the retaining ring is positioned between the outer conductors of the two coaxial connectors.

The retaining ring is advantageously non-positively and / or positively connected with at least one outer conductor of the coaxial connector. The retaining ring may, for example, dip into an annular groove of an outer conductor and / or may surround a radially inwardly or outwardly directed extension of an outer conductor.

It is advantageous if the coupling member has an insulating part, which is penetrated by the inner conductor of the coupling member and which is surrounded by an outer conductor of the coupling member and which limits a tilting movement and an axial movement of the coupling member relative to the Koaxialsteckverbindern. The insulating part of the coupling member serves, on the one hand, to electrically separate the inner conductor from the outer conductor of the coupling member. On the other hand, the insulating part of the coupling member forms a stop element, by means of which axial movements and tilting movements of the coupling member relative to the coaxial connectors can be limited.

It can be provided, for example, that the insulating part upon reaching an end position of the coupling member to the end face of an inner conductor of the coaxial connector can be applied. The insulating part thus forms a stop element, which comes to rest on the end face of an inner conductor of the coaxial connector when the coupling member has reached an end position relative to this coaxial connector.

The inner conductor of the coupling member is conveniently designed pin-shaped and held in resilient end-side recesses of the inner conductor of the coaxial connector.

The inner conductors of the coaxial connectors are advantageously identical in construction and each have an end-side recess into which the inner conductor of the coupling member dips with an end region.

Particularly good electrical transmission properties, in particular a very low intermodulation, is achieved in an advantageous embodiment of the invention in that the inner conductors of the coaxial connectors each have a frontal recess with a rotationally symmetrical inner surface, the inner diameter over the entire length or at least a portion of the length of Recess changed and a minimum, and that the inner conductor of the coupling member has opposite end portions with a cylindrical outer surface, wherein the end portions immerse each in a recess of an inner conductor of the coaxial connector and contact the recess in a line with a smallest inner diameter of the recess line. The combination of a cylindrical outer surface and a rotationally symmetrical inner surface whose inner diameter preferably continuously varies over the length or at least a portion of the length of the recess and has a minimum, allows a virtually linear contact of the inner conductor of the coupling member on the inner conductor of a coaxial connector. The coupling member can be tilted and axially displaced to compensate for position inaccuracies and relative movements of the printed circuit boards relative to the coaxial connectors. Upon movement of the coupling member relative to one or both coaxial connectors, there is no abrupt change in the geometry of the contact region in which the inner conductor of the coupling member contacts the inner conductors of the coaxial connectors. It is thereby prevented that substantially change in a movement of the coupling member, the electrical transmission properties of the connecting device. This counteracts in particular the formation of intermodulation.

It is advantageous if the inner conductors of the coaxial connector are slotted axially and form radially inwardly inclined spring tongues. When inserting an end portion of an inner conductor of the coupling member in the recess of an inner conductor of a Koaxialsteckverbinders the spring tongues can be deformed in the radial direction outwards, wherein they rest resiliently on an end portion of the inner conductor of the coupling member.

In a first longitudinal region of the spring tongues, for example, starting from the bottom of the recesses, the inner diameter of the recesses may decrease continuously, and the first longitudinal region may be followed by a second longitudinal region of the spring tongues in which the inner diameter of the recesses increases continuously. The pin-shaped inner conductor of the coupling member can with a cylindrical end portion in immerse a recess, wherein it can contact the recess in the area with the smallest inner diameter linear.

In an advantageous embodiment of the invention, the outer conductor of the coaxial connector each have an end recess with a cylindrical inner surface, and the outer conductor of the coupling member has opposite end portions with a rotationally symmetric outer surface whose outer diameter varies over the length or part of the length of the end portion and has a maximum, wherein each end portion dips into a recess of an outer conductor of a coaxial connector and in a region with the largest outer diameter of the end portion, the recess contacted linearly. The combination of a rotationally symmetrical outer surface, the outer diameter of which preferably continuously changes over the length or at least part of the length of the outer surface and has a maximum, and a cylindrical inner surface which contacts the outer surface in the region of the maximum outer diameter of the outer surface, allows a linear arrangement of the Outer surface on the inner surface and thus a linear contact of the outer conductor of the coupling member to the outer conductors of the coaxial connector. The coupling member can be tilted and axially displaced to compensate for position inaccuracies and relative movements of the printed circuit boards relative to the coaxial connectors. Upon movement of the coupling member relative to one or both coaxial connectors, there is no abrupt change in the geometry of the contact region in which the outer conductor of the coupling member contacts the outer conductors of the coaxial connectors. It is thereby prevented that substantially change in a movement of the coupling member, the electrical transmission properties of the connecting device. This counteracts in particular the formation of intermodulation.

It is advantageous if the end sections of the outer conductor of the coupling member are slotted axially and form radially outwardly inclined spring tongues. The radially outwardly inclined spring tongues can when plugging the outer conductor of the coupling member in the recess of an outer conductor of a coaxial connector are deformed inwards in the radial direction, wherein they rest resiliently on the inside of the recess.

Figur 1:

eine Schnittansicht einer ersten vorteilhaften Ausführungsform einer erfindungsgemäßen Verbindungseinrichtung, wobei ein Kupplungsglied eine fluchtende Ausrichtung bezogen auf zwei Koaxialsteckverbinder aufweist und in axialer Richtung mittig zwischen den beiden Koaxialsteckverbindern angeordnet ist;

Figur 2:

eine Schnittansicht der Verbindungseinrichtung aus Figur 1, wobei das Kupplungsglied verkippt und axial verschoben ist;

Figur 3:

eine Schnittansicht einer alternativen Ausgestaltung eines Halterings der Verbindungseinrichtung aus Figur 1;

Figur 4:

eine Schnittansicht einer zweiten vorteilhaften Ausführungsform einer erfindungsgemäßen Verbindungseinrichtung, wobei ein Kupplungsglied fluchtend zu zwei Koaxialsteckverbindern und mittig zwischen den beiden Koaxialsteckverbindern angeordnet ist.

The following description of advantageous embodiments of the invention is used in conjunction with the drawings for further explanation. Show it:

FIG. 1:

a sectional view of a first advantageous embodiment of a connecting device according to the invention, wherein a coupling member has an alignment with respect to two coaxial connector and is arranged centrally between the two coaxial connectors in the axial direction;

FIG. 2:

a sectional view of the connecting device FIG. 1 wherein the coupling member is tilted and axially displaced;

FIG. 3:

a sectional view of an alternative embodiment of a retaining ring of the connecting device FIG. 1 ;

FIG. 4:

a sectional view of a second advantageous embodiment of a connecting device according to the invention, wherein a coupling member is arranged in alignment with two coaxial connectors and centrally between the two coaxial connectors.

In the FIGS. 1 and 2 schematically a first advantageous embodiment of a connecting device according to the invention is shown, which is generally occupied by the reference numeral 10. The connecting device 10 makes it possible to electrically connect a first printed circuit board 12 to a second printed circuit board 14. For this purpose, the connecting device 10 has a first coaxial connector 16 and a second coaxial connector 18 and a coupling member 20 movably arranged between the two coaxial connectors 16, 18.

The first coaxial connector 16 is held on the first circuit board 12 and has a first outer conductor 22 which is formed in the manner of a socket and a first recess 24 having a cylindrical central portion 26 and a flared end portion 28 which extends in the direction the second circuit board 14 connects to the cylindrical central portion 26 of the first recess 24.

A first inner conductor 30 of the first coaxial connector 16 is arranged in the first recess 24, wherein a first annular space 32 extends between the first inner conductor 30 and the wall of the cylindrical middle section 26 of the first recess 24.

The first inner conductor 30 has an end-side recess 34 and is slotted starting from its the second circuit board 14 facing free end face 36 in the axial direction, so that it forms a plurality of identically formed spring tongues 38, starting from a bottom 40 of the recess 34 radially inwardly are inclined. The inner surface 42 of the recess 34 is formed rotationally symmetrical with respect to a longitudinal axis 44, wherein its inner diameter initially decreases continuously with increasing distance from the bottom 40 and continuously increases in one of the free end face 36 adjacent end region. At a small distance from the free end face 36, the inner diameter of the recess 34 has a minimum.

The second coaxial connector 18 is identical to the first coaxial connector 16. It has a second outer conductor 46, which is designed in the manner of a socket and a second recess 48 having a cylindrical central portion 50, in the direction of the first printed circuit board 12th a conically widening end portion 52 connects.

The second outer conductor 46 surrounds a second inner conductor 54 of the second coaxial connector 18, wherein between the second inner conductor 54 and the cylindrical central portion 50 of the second outer conductor 46, a second annular space 56 extends. The second inner conductor 54 has an end-side recess 58 and, starting from its first printed circuit board 12 facing free end face 60 slotted in the axial direction. The second inner conductor 54 forms identically formed spring tongues 62 which, starting from the bottom 64 of the recess 58, are inclined radially inwards. The inner surface 66 of the recess 58 is formed rotationally symmetrical, with its inner diameter initially decreases with increasing distance from the bottom 64 and increases continuously in one of the free end face 60 adjacent end region. At a small distance from the free end face 60, the inner diameter of the recess 58 has a minimum.

The arranged between the two coaxial connectors 16, 18 coupling member 20 has a pin-shaped inner conductor 68 which engages through an insulating member 70 in the longitudinal direction and dips with a first end portion 72 in the frontal recess 34 of the first inner conductor 30 and facing away from the first end portion 72 second End portion 74 dips into the front-side recess 58 of the second inner conductor 54. The two end regions 72, 74 each have cylindrical outer surfaces 76 and 78, respectively, which contact the rotationally symmetrical inner surfaces 42 and 66 of the recesses 34 and 58 in the region of the smallest inner diameter of the recesses 34, 58 in a linear manner.

The insulating part 70 of the coupling member 20 carries on its outer side an outer conductor 80, which dips with a first end portion 82 in the first recess 24 of the first outer conductor 22 and which dips with a second end portion 84 in the second recess 48 of the second outer conductor 46. The first end portion 82 is slotted in the axial direction as well as the second end portion 84 and has a plurality of spring tongues 86 and 88, respectively, which are inclined radially outwardly starting from a surrounding the insulating member 70 in the circumferential direction central portion 90 of the outer conductor 80.

The outer conductor 80 has at the level of the cylindrical central portion 26 of the first recess 24 has a rotationally symmetrical outer surface whose outer diameter changes continuously over the length of the first end portion 82. Starting from the free end of the end portion 82, the outer diameter increases first, to then reduce continuously. At a small distance from the free end, the outer diameter of the end portion 82 has a maximum. In the region of maximum outer diameter, the end portion 82 contacts the cylindrical central portion 26 in a line.

In a corresponding manner, the second end portion 84 at the level of the cylindrical central portion 50 of the second outer conductor 46 has a rotationally symmetrical outer surface whose outer diameter changes continuously over the length of the second end portion 84. Starting from the free end of the end portion 84, the outer diameter increases first, to then shrink continuously. At a small distance from the free end, the outer diameter of the end portion 84 has a maximum. In the region of maximum outer diameter, the end portion 84 contacts the cylindrical central portion 50 in a line.

In the longitudinal direction in the middle, the outer conductor 80 has on its outer side an annular bead 92, which is surrounded by an elastically deformable, dielectric retaining ring 94 in a form-fitting manner. The retaining ring 94 abuts the end portion 28 of the first outer conductor 22 and the end portion 52 of the second outer conductor 46 splash-tight and thereby forms a sealing element which seals the first annulus 32 and the second annulus 56 against splashing water and dust and other contaminants.

The retaining ring 94 is made of an elastomer and supports the coupling member 20 elastically on the first outer conductor 22 and the second outer conductor 46 from. The retaining ring 94 centers the coupling member 20 between the two coaxial connectors 16 and 18 and counteracts micro-movements of the coupling member 20, in particular vibration movements of the coupling member 20.

The two printed circuit boards 12, 14 can be moved relative to each other in the axial direction with respect to the longitudinal axis 44 and transversely to the longitudinal axis 44. This results in an axial movement and a tilting movement of the coupling member 20 relative to the coaxial connectors 16, 18 result. In FIG. 2 the connecting device 10 is shown schematically after an axial and radial relative movement of the two circuit boards 12, 14. It is clear that the coupling member 20 assumes a tilted position, wherein the retaining ring 94 is elastically deformed. After reaching an end position, the insulating part 70 of the coupling member 20, the free end face 36 of the first inner conductor 30 or the free end face 60 of the second inner conductor 54 contact and thereby prevent further relative movement of the coupling member relative to the Koaxialsteckverbindern 16, 18. The insulating part 70 thus forms a stop element, which limits the axial movement and the tilting movement of the coupling member 20.

Out FIG. 2 It is also clear that the inner conductors 30 and 54 of the coaxial connector 16, 18 even in a tilted position of the coupling member 20, the end portions 72 and 74 of the inner conductor 68 of the coupling member 20 contact only linearly and that the cylindrical central portions 26 and 50 of the outer conductor 22nd or 46 of the two coaxial connectors 16, 18, the end portions 82, 84 of the outer conductor 80 of the coupling member 20 contact only linear. This ensures that even in a tilted and / or axially offset position of the coupling member 20, the formation of intermodulation can be kept low.

In FIG. 3 schematically an alternative embodiment of a retaining ring 104 is shown, which can be used instead of the retaining ring 94 in the connecting device 10. The retaining ring 104 has on its outer side an annular groove 106, which gives the retaining ring 104 a formula elasticity. The retaining ring 104 can therefore be deformed with lower forces than that in the FIGS. 1 and 2 illustrated retaining ring 94th

In FIG. 4 a second advantageous embodiment of a connecting device according to the invention is shown, which is generally designated by the reference numeral 110. The connecting device 110 is designed substantially identical to the above with reference to the FIGS. 1 and 2 Therefore, for identical components are in FIG. 4 the same reference numerals as in the FIGS. 1 and 2 and with respect to these components, reference is made to the foregoing explanations to avoid repetition.

The connecting device 110 differs from the connecting device 10 in that instead of the retaining ring 94, a retaining ring 114 is used, which is not only positively connected to the annular bead 92 of the outer conductor 80 of the coupling member 20 but also with the outer conductor 22 of the first coaxial connector 16. For this purpose, the outer conductor 22 has a U-shaped annular groove 116 surrounding the outer conductor 22 in the circumferential direction, and the retaining ring 114 forms a form-locking connection both with the annular groove 116 and with the end region 118 of the first outer conductor 22 adjoining the annular groove 116.

The retaining ring 114 is at the end portions 28 and 52 of the two outer conductors 22 and 46 of the coaxial connector 16, 18 splash-tight and centered the coupling member 20 between the two Koaxialsteckverbindern 16 and 18. In addition, the elastically deformable dielectric retaining ring 114 also acts micro-movements, in particular vibrations, of the coupling member 20 against.

The coupling member 20 of the connecting device 110 can be moved in the same way as the coupling member 20 of the connecting device 10 in the axial direction relative to the coaxial connectors 16, 18 and from the in FIG. 4 tilted alignment shown tilted. The above statements on the coupling member 20 of the connecting device 10 apply in the same way to the coupling member 20 of the connecting device 110 and should therefore not be repeated again.

The connecting devices 10 and 110 are characterized by a high electrical transmission quality, with virtually no risk that the coupling member 20 micro-movements, in particular vibrations, performs, which could lead to abrasion and thus to a deterioration of the electrical transmission properties.

Claims (13)

1. Connecting device for electrically connecting two circuit boards (12, 14), the connecting device comprising a first and a second coaxial connector (16, 18) and a coupling member (20), wherein the two coaxial connectors (16, 18) and the coupling member (20) each have an outer conductor (22, 46, 80) and an inner conductor (30, 54, 68) and the outer conductors (22, 46) of the coaxial connectors (16, 18) are electrically interconnected via the outer conductor (80) of the coupling member (20) and the inner conductors (30, 54) of the coaxial connectors (16, 18) are electrically interconnected via the inner conductor (68) of the coupling member (20) and wherein the coupling member (20) is arranged between the two coaxial connectors (16, 18) so as to be tiltable from an axially aligned orientation and displaceable in an axial direction, characterized in that the coupling member (20) is held on an elastically deformable holding ring (94; 104; 114) which surrounds the coupling member (20) in a circumferential direction and is in contact against the outer conductors (22, 46) of both coaxial connectors (16, 18).
2. Connecting device in accordance with claim 1, characterized in that the holding ring (94; 104; 114) is connected to the coupling member (20) in form-locking engagement.
3. Connecting device in accordance with claim 1 or 2, characterized in that the holding ring (94; 104; 114) is made of an elastomer.
4. Connecting device in accordance with any one of the preceding claims, characterized in that the holding ring (94; 104; 114) is profiled.
5. Connecting device in accordance with any one of the preceding claims, characterized in that the holding ring (94; 104; 114) is in splash-proof contact against the coupling member (20) and at least one coaxial connector (16, 18).
6. Connecting device in accordance with any one of the preceding claims, characterized in that the holding ring (94; 104; 114) is connected to at least one outer conductor (22, 46) of the coaxial connectors (16, 18) in a force-locking manner and/or in a form-locking manner.
7. Connecting device in accordance with any one of the preceding claims, characterized in that the coupling member (20) has an insulation part (70) which has the inner conductor (68) of the coupling member (20) extending therethrough and which is surrounded by the outer conductor (80) of the coupling member (20) and which limits tilting movement and axial movement of the coupling member (20) relative to the coaxial connectors (16, 18).
8. Connecting device in accordance with claim 7, characterized in that the insulation part (70) is capable of being brought into contact against the end faces (36, 60) of the inner conductors (30, 54) of the coaxial connectors (16, 18).
9. Connecting device in accordance with any one of the preceding claims, characterized in that the inner conductor (68) of the coupling member (20) is of pin-shaped configuration and is held in resilient end-face recesses (34, 58) of the inner conductors (30, 54) of the coaxial connectors (16, 18).
10. Connecting device in accordance with any one of the preceding claims, characterized in that the inner conductors (30, 54) of the coaxial connectors (16, 18) each have an end-face recess (34, 58) having a rotationally symmetric internal surface (42, 66) whose inner diameter varies over the entire length, or over at least part of the length, of the recess (34, 58) and has a minimum and in that the inner conductor (68) of the coupling member (20) has end regions (72, 74) that face away from each other and have a cylindrical external surface (76, 78), wherein the end regions (72, 74) each extend into a recess (34, 58) of an inner conductor (30, 54) of the coaxial connectors (16, 18) and contact the recess (34, 58) in an area of smallest inner diameter of the recess (34, 58) in a line contact.
11. Connecting device in accordance with any one of the preceding claims, characterized in that the inner conductors (30, 54) of the coaxial connectors (16, 18) are axially slotted and form radially inwardly inclined resilient tongues (38, 62).
12. Connecting device in accordance with any one of the preceding claims, characterized in that the outer conductors (22, 46) of the coaxial connectors (16, 18) each have an end-face recess (24, 48) with a cylindrical internal surface and in that the outer conductor (80) of the coupling member (20) has end sections (82, 84) that face away from each other and have a rotationally symmetric external surface whose outer diameter varies over the entire length, or over at least part of the length, of the end section (82, 84) and has a maximum, with each end section (82, 84) extending into a recess (24, 48) of an outer conductor (22, 46) of a coaxial connector (16, 18) and contacting the recess (24, 48) in an area of largest outer diameter in a line contact.
13. Connecting device in accordance with any one of the preceding claims, characterized in that the end sections (82, 84) of the outer conductor (80) of the coupling member (20) are axially slotted and form radially outwardly inclined resilient tongues (86, 88).

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