EP3394936A1

EP3394936A1 - Plug connector

Info

Publication number: EP3394936A1
Application number: EP17718335.7A
Authority: EP
Inventors: Martin Wimmer; Florian Fraunhofer; Josef Krautenbacher; Franz Manser; Claude Brocheton
Original assignee: Huber and Suhner AG; Rosenberger Hochfrequenztechnik GmbH and Co KG; Radiall SA
Current assignee: Huber and Suhner AG; Rosenberger Hochfrequenztechnik GmbH and Co KG; Radiall SA
Priority date: 2016-04-15
Filing date: 2017-04-18
Publication date: 2018-10-31
Anticipated expiration: 2037-04-18
Also published as: CN111293494B; DE102016006598A1; US10148047B2; CN109155493A; WO2017178118A1; CN111293494A; TWM553508U; US20180205191A1; CN109155493B; WO2017178118A9; EP3394936B1

Abstract

The invention relates to a plug connector (2), in particular a high-frequency plug connector, comprising a first connector (4), in particular a coaxial connector, which has a first inner conductor parts (14), a first outer conductor part (28) and a first insulating part (26) for holding the first inner conductor part (14) radially inside and coaxially with respect to the first outer conductor part (28), and comprising a second connector (6), in particular a coaxial connector, designed to be plugged axially into the first connector (4) in a joining direction (F), which connector has a second inner conductor part (34), a second outer conductor part (38) and a second insulating part (36) for holding the second inner conductor part (34) radially inside and coaxially with respect to the second outer conductor part (38), wherein, when the first and second connector (4, 6) are plugged in, the first inner conductor part (14) contacts the second inner conductor part (34) electrically and mechanically, and the first outer conductor part (28) contacts the second outer conductor part (38) electrically and mechanically, wherein the first outer conductor part (28) has a first outer conductor contact section (32) for making electrical and mechanical contact with a second outer conductor contact section (40) on the second outer conductor part (38), wherein the first outer conductor part (28) has a first guide face (20) and the second outer conductor part (38) has a second guide face (18) which, when the first connector (4) is plugged into the second connector (6), are designed to slide on one another mechanically. The first guide face (20) and the first outer conductor contact section (32) of the first connector (4) are arranged to be spaced apart from one another in the axial direction with respect to a longitudinal axis (50) of the plug connector (2), and the second guide face (18) and the second outer conductor contact section (14) of the second connector are arranged to be spaced apart from one another in the axial direction with respect to the longitudinal axis (50) of the plug connector (2). The first connector (4) has a further third guide face (44) for guiding the second connector (6) by interacting with a further fourth guide face (42) of the second connector (6) as the first connector (4) is joined together with the second connector (6).

Description

Connectors

The invention relates to a connector, in particular high-frequency connector, according to the preamble of patent claim 1.

A similar connector is e.g. known from EP 2 304 851 B1. The

External conductor contacts can be designed as resilient contact elements. However, in a joining operation in which a joining movement connects the first connector to the second connector, such external conductor contact can easily be damaged, in particular if the first connector is not precisely aligned with the second connector.

The invention has for its object to provide ways how the connection or assembly of the first connector can be improved with the second connector of a connector. This object is achieved by a connector of o.g. Art solved with the features characterized in claim 1. Advantageous embodiments of the invention are described in the further claims.

It is with a connector of o.g. Art according to the invention provided that the first connector further comprises a third guide surface for guiding the second connector by cooperation with a further fourth guide surface of the second connector during assembly of the first connector with the second connector. Thereby, an improvement of the aligned guide is achieved by the first and second connector during the mating of the first with the second connector.

The first guide surface and the first outer conductor contact portion of the first connector are axially spaced from each other with respect to a longitudinal axis of the connector, and the second guide surface and the second outer conductor contact portion of the second connector are spaced apart in the axial direction with respect to the longitudinal axis of the connector.

This has the advantage that, by cooperating the first guide surface with the second guide surface, the second connector has a predetermined position and orientation with respect to the first connector during assembly. This avoids misalignments during assembly, which could otherwise damage the outer conductor contacts. By the spacing of the first guide surface and the first outer conductor contact section and the second guide surface and the second contact section, the outer conductor contacts are selectively protected during the joining process.

According to an embodiment, the first guide surface and the first outer conductor contact portion are as like-oriented surfaces with a respective one Surface normal vector formed, wherein the surface normal vectors of both surfaces each have at least one component perpendicular to the longitudinal axis of the connector, which are directed radially the same. A normal vector, also normal vector, is understood to mean a vector which is orthogonal, ie perpendicular or perpendicular, on a plane or surface. A straight line that has this vector as a direction vector is called a normal. An oriented surface is understood to mean a surface that has been determined which of its two sides is the outside or inside. The orientation of a surface is determined by the choice of one of the two possible surface normal vectors. The outside of the surface is the one from which the chosen normal vector leads away. Thus, a particularly good guidance can be achieved while at the same time functionally reliable contacting of the outer conductor parts.

According to a further embodiment, the first guide surface and the first outer conductor contact portion are formed as radially outwardly oriented surfaces, wherein the surface normal vectors of both surfaces each have at least one component perpendicular to the longitudinal axis of the connector, which are directed radially outward. Thus, a particularly good guidance can be achieved with a functionally reliable contacting of the outer conductor parts with a particularly simple structure.

According to a further embodiment, the first guide surface is formed on an outer surface of the first outer conductor part and the second guide surface is formed on an inner surface of the second outer conductor part. Thus, the first and second guide surfaces form an inner and outer surface pair. Thus, the connector may have a particularly simple structure.

According to a further embodiment, the first guide surface is a cylinder jacket-shaped surface of the first outer conductor part and the second guide surface is a cylinder jacket-shaped surface of the second outer conductor part. By the respective cylinder jacket-shaped design of the two guide surfaces a particularly well aligned guide is provided. According to a further embodiment, the further third guide surface is formed by an inner surface of an axially displaceable sleeve on the first connector and the fourth guide surface by an outer surface on the second outer conductor part. Thus, a connector with a third and fourth guide surface can be provided with a particularly simple structure.

According to a further embodiment, the third guide surface is a cylinder jacket-shaped inner surface and the fourth guide surface is a cylinder jacket-shaped outer surface. By the respective cylinder jacket-shaped design of these two guide surfaces a particularly well aligned second guide is provided.

According to a further embodiment, the first guide surface of the first connector and the second guide surface of the second connector are arranged and formed such that during assembly of the first connector with the second connector first, the first guide surface mechanically contacts the second guide surface and thereafter upon further assembly of the first Connector with the second connector, the first contact portion mechanically and electrically contacted the second contact portion. Thus, a particularly good protection of the outer conductor contact sections is achieved during mating. This ensures that the first and second connectors are aligned with each other before the outer conductor contact portions mechanically and electrically contact each other. According to a further embodiment, the first outer conductor part and the first outer conductor contact section are formed in one piece and / or of the same material. Thus, a particularly easy to manufacture connector can be provided.

According to a further embodiment, the first outer conductor contact section is a separate component with respect to the first outer conductor part, which is pressed into the first outer conductor part. Thus, an optimization of the first outer conductor contact portion with respect to material properties is possible independently of the first outer conductor part. According to a further embodiment, the first guide surface is formed on an additional sleeve, which is pressed onto the first outer conductor part. Thus, an optimization of the first guide surface with respect to material properties can be achieved independently of the first outer conductor part.

Furthermore, the invention includes a first connector and a second connector for such a connector.

The invention will be explained in more detail below with reference to the drawing. This shows in

1 is a schematic representation of an embodiment of a connector according to the invention in an exploded view, in a schematic representation of a first embodiment of a first connector of the connector shown in Fig. 1, in a schematic representation of a second embodiment of a first connector of the connector shown in Fig. 1, in a schematic A third embodiment of a first connector of the connector shown in Fig. 1, in a schematic representation a first step for connecting the first connector to the second connector, in a schematic representation, the continuation of the joining process shown in Fig. 1, in a schematic representation of a second step for connecting the first connector to the second connector,

5 is a schematic representation of a third step for connecting the first connector to the second connector, Fig. 6 shows the connector shown in Fig. 1 in the assembled state. Reference is first made to FIG. 1 reference.

Shown is a connector 2 having a first connector 4 and a second connector 6.

The connector 2 in the present embodiment is a coaxial connector and high-frequency connector, wherein the first connector 4 can be connected to the second connector 6 by forming a latching connection with each other. Such coaxial connectors or coaxial snap connectors are also referred to as quick-lock connectors or push-pull connectors.

Coaxial connectors are used for the detachable connection of coaxial cables. Coaxial connectors, such as coaxial cables, are coaxial to have the advantages of coaxial cable, namely low electromagnetic interference and radiation, and good electrical shielding and impedance equal to that of the coaxial cable connected, to reflect reflections at the interface between coaxial connectors and coaxial cable avoid. A coaxial cable, or coax cable for short, is understood here to mean a two-pole cable with a concentric structure, which has an inner conductor (also called a core) which is surrounded at a constant distance by a hollow-cylindrical outer conductor. The outer conductor shields the inner conductor from electromagnetic interference. In the space between the inner conductor and the outer conductor, an insulator or dielectric is arranged.

The first connector 4 is formed in the present embodiment as a plug, while the second connector 6 is formed as a socket. Further, in the present embodiment, the first connector 4 and the second connector 6 are each formed as Koxialverbinder, for example as a coaxial and coaxial jack. The first connector 4 has a first inner conductor part 14, which in the present exemplary embodiment is formed by an inner conductor contact pin which is surrounded by a first insulating part 26. The first insulating member 26 has in the present embodiment, a substantially cylindrical basic shape, in particular hollow cylindrical basic shape, and is inserted into a first outer conductor part 28, which also in the present embodiment has a substantially cylindrical basic shape, in particular hollow cylindrical basic shape, and in an axially displaceable sleeve 30 is used, which in the present embodiment has a substantially cylindrical basic shape, in particular hollow cylindrical basic shape.

The first outer conductor part 28 may be made of an electrically conductive material and thus form a portion of an outer conductor of the connector 2. It is thus formed in the present embodiment as a plug guide body. The sleeve 30 may form an outer housing of the first connector 4 and at the same time have the function of an unlocking element, with which the latching connection between the first connector 4 and the second connector 6 can be solved. In the present exemplary embodiment, the first outer conductor part 28 likewise has a substantially cylindrical basic shape, in particular a hollow cylindrical basic shape, and, in the present exemplary embodiment, a groove or shoulder 10. The groove or shoulder 10 provides in the present embodiment, a plane portion which forms a first surface 11, which, as will be explained later, causes a compression of a seal 8, which is partially inserted into the groove or shoulder 10 or is supported there. The seal 8 may be an O-ring, for example. Furthermore, the first outer conductor part 28 has on its outer side a latching element 22 for forming a latching connection with the second connector 6, as will be explained in detail later. In the present exemplary embodiment, the latching element 22 is a resilient latching hook for a counter-latching element 24 formed as latching surface on the second connector 6. Furthermore, the first connector 4 has a first outer conductor contact section 32, which in the present exemplary embodiment is formed by a plug outer conductor contact, which is partly between the first insulating part 26 and the first outer conductor part 28 is arranged and has a free contact surface, for example in the form of contact fingers. Furthermore, in the present embodiment, the first connector 4 has a first guide surface 20, which cooperates with a second guide surface 18 of the second connector 6, as will be described in detail later. The first guide surface 20 is, for example, an outer surface. The outer surface is in the present embodiment, a cylinder jacket outer surface. Furthermore, the first guide surface 20 is arranged in the axial direction with respect to a longitudinal axis 50 of the connector 2 from the first outer conductor contact portion 32 spaced. In the present exemplary embodiment, the first guide surface 20 is formed on an outer surface of the first outer conductor part 28. Furthermore, the first guide surface 20 and the first outer conductor contact portion 32 are formed as radially outwardly oriented surfaces.

In the present embodiment, the first connector 4 has a third guide surface 44 for cooperation with a fourth guide surface 42 of the second connector 6, as will also be explained in detail later. The third guide surface 44 is formed by an inner surface of the sleeve 30 on the first connector 4. Further, the third guide surface 44 in the present embodiment, a cylinder jacket inner surface.

The second connector 6 has a second inner conductor part 34 corresponding to the first inner conductor part 14, which in the present exemplary embodiment is designed as an inner conductor contact bush and has a substantially cylindrical basic shape, in particular a hollow cylindrical basic shape, and is surrounded by a second insulating part 36. The second insulating member 36 also has in the present embodiment, a substantially cylindrical basic shape, in particular hollow cylindrical basic shape, and is in a substantially cylindrical in the present embodiment basic body, in particular hollow cylindrical body, e.g. a second outer conductor part 38, used. The second outer conductor part 38 may be made of an electrically conductive material and thus form a portion of the outer conductor of the connector 2.

Further, the second connector 6, the second guide surface 18 and a second outer conductor contact portion 40, in the present embodiment by According to a further embodiment, the further third guide surface is formed by an inner surface of an axially displaceable sleeve on the first connector and the fourth guide surface by an outer surface on the second outer conductor part. Thus, a connector with a third and fourth guide surface can be provided with a particularly simple structure.

According to a further embodiment, the first outer conductor contact section is a separate component with respect to the first outer conductor part, which is pressed into the first outer conductor part. Thus, an optimization of the first outer conductor contact portion with respect to material properties is possible independently of the first outer conductor part. Embodiment, a sleeve 21 which is formed as a spring basket with resilient contact tongues.

In Fig. 1 b, however, it is shown that the first outer conductor part 28 with the spring cage having resilient contact tongues having sleeve 21 of the first outer conductor contact portion 32 are formed integrally and of the same material.

In Fig. 1c is shown that the sleeve 21 is at least partially surrounded by the formed as a separate element first guide surface 20. The first guide surface 20 is pressed onto the first outer conductor part 28 and the sleeve 21.

In addition, reference will now also be made to FIGS. 2 to 6. In Fig. 2, a first step of mounting the connector 2 is shown, in which the first connector 4 in the joining direction F (see Fig. 1) is moved by axial insertion along the longitudinal axis 50 of the connector 2 on the second connector 6, until this contact. It enters the second outer conductor part 38 in the sleeve 30 a. It can be seen that the second guide surface 18 of the second outer conductor part 38 comes into contact with the first guide surface 20 of the first outer conductor part 28. Further, in the present embodiment, at the same time, the fourth guide surface 42 of the second outer conductor part 38 comes into contact with the third guide surface 44 of the sleeve 30. Alternatively, the fourth guide surface 42 of the second outer conductor part 38 and the third guide surface 44 of the sleeve 30 of the second guide surface 18 of the second outer conductor part 38 and the first guide surface 20 of the first outer conductor part 28 lead or lag. The first guide surface 20 of the first outer conductor part 28, together with the second guide surface 18, in the present embodiment, the inner surface of the second outer conductor part 38, a first guide for guiding the second connector 6, during further assembly of the first connector 4 with the second connector 6. Due to the respective cylindrical surface formation, the first guide forms a first cylinder guide.

Further, the third guide surface 44 of the sleeve 30 together with the fourth guide surface 42, in the present embodiment, an outer surface of the second outer conductor 38, a second guide for guiding the second connector 6, while further joining the first connector 4 with the second connector. 6 Due to the respective cylindrical surface formation forms the second guide is a second cylinder guide.

In Fig. 3, a progress of the joining movement is shown.

4, a second step is shown. Now, the first inner conductor part 14 enters the second inner conductor part 34 and thus forms an inner conductor. In addition, the free contact surface of the first outer conductor contact portion 32 of the first outer conductor part 28 makes electrical and mechanical contact with the second outer conductor contact portion 40 of the second outer conductor part 38, thus forming an outer conductor. Thus, the second guide surface 18 and the first guide surface 20 of the first guide and the third guide surface 44 and the fourth guide surface 42 of the second guide come before the electrical contacts, namely the first inner conductor part 14 and the second inner conductor part 34 and the first outer conductor contact portion 32 and the second Outgoing conductor contact portion 40, mechanically in contact. In other words, the guides of the connector 2 rush its electrical contacts ahead.

In Fig. 5, a third step is shown. After the second surface 12 has reached the on the first surface 11 supporting seal 8, and the locking element 22 is deflected elastically in the radial direction.

As a result, by continuing the joining movement in the axial direction along the longitudinal axis 50 (joining direction F, see FIG. 1), the seal 8 is compressed until the locking element 22 is in the radial direction out of engagement with the counter-latching element 24 and can snap back in the radial direction.

Furthermore, by forming the chamfer of the second surface 12, the seal 8 is compressed radially inwardly. Thus, the seal 8 is secured in position and the friction between the second surface 12 and the seal 8 on the one hand and the friction between the first face 11 and the seal 8 on the other hand prevents rotation of the second connector 6 by rotation about the longitudinal axis 50. In Fig. 6 of the assembled connector 2 is shown. After completion of the joining movement and the elimination of the joining force, the gasket 8 relaxes a little and pushes the second connector 6 in a direction opposite to the direction of the joining movement F (see Fig. 1), e.g. by 0.05 mm to 0.4 mm. The compressed seal 8 provides a restoring force that forces the first connector 4 and the second connector 6 apart. Thus, the latching element 22 and the counter-latching element 24 come into contact in the axial direction and are secured by the pressure acting in the axial direction due to the compression of the seal 8. Furthermore, there is no play, i. the connection is free of play in the axial direction.

Thus, by the cooperation of the first guide surface 20 with the second guide surface 18 of the first guide and the third guide surface 44 with the fourth guide surface 42 of the second guide misalignments during assembly avoided, which could otherwise lead to damage of the first outer conductor contact portion 32.

Claims

claims:

Connector (2), in particular high-frequency connector, comprising a first connector (4), in particular coaxial connector, which has a first inner conductor part (14), a first outer conductor part (28) and a first insulating part (26) for holding the first inner conductor part (14) radially inside and coaxial with the first outer conductor part (28), and with a second connector (6), in particular a coaxial connector, which has a second inner conductor part (34), a second outer conductor part, for axial insertion into the first connector (4) in a joining direction (F) (38) and a second insulating part (36) for holding the second inner conductor part (34) radially inside and coaxial with the second outer conductor part (38), wherein in a plugged state of the first and second connectors (4, 6), the first inner conductor part (14 ) the second inner conductor part (34) electrically and mechanically contacted and the first outer conductor part (28) the second outer conductor part (38) electrically and mechanically sch, wherein the first outer conductor part (28) has a first outer conductor contact portion (32) for electrically and mechanically contacting a second outer conductor contact portion (40) on the second outer conductor part (38), wherein the first outer conductor part (28) has a first guide surface (20) and the second outer conductor part (38) has a second guide surface (18), which are formed mechanically slidable upon insertion of the first connector (4) into the second connector (6),

wherein the first guide surface (20) and the first outer conductor contact portion (32) of the first connector (4) are spaced apart in the axial direction with respect to a longitudinal axis (50) of the connector (2) and the second guide surface (18) and the second outer conductor contact portion (4). 40) of the second connector (6) in the axial direction with respect to the longitudinal axis (50) of the connector (2) are arranged spaced from each other,

characterized in that the first connector (4) comprises a further third guide surface (44) for guiding the second connector (6) by cooperation with a further fourth guide surface (42) of the second Connector (6) during assembly of the first connector (4) with the second connector (6).

2. Connector (2) according to claim 1, characterized in that the first guide surface (20) and the first outer conductor contact portion (32) are formed as like-oriented surfaces with a respective surface normal vector, wherein the surface normal vectors of the first guide surface (20) and the first outer conductor contact portion (32) each have at least one component perpendicular to the longitudinal axis (50) of the connector (2), which are directed radially the same.

3. Connector (2) according to claim 2, characterized in that the first guide surface (20) and the first outer conductor contact portion (32) are formed as radially outwardly oriented surfaces, wherein the surface normal vectors of the first guide surface (20) and the first outer conductor contact portion (32 ) each have at least one component perpendicular to the longitudinal axis of the connector, which are directed radially outward.

4. Connector (2) according to at least one of the preceding claims, characterized in that the first guide surface (20) on an outer surface of the first outer conductor part (28) and the second guide surface (18) on an inner surface of the second outer conductor part (38) is formed ,

5. Connector (2) according to at least one of the preceding claims, characterized in that the first guide surface (20) is a cylinder jacket-shaped surface of the first outer conductor part (28) and the second guide surface (18) is a cylinder jacket-shaped surface of the second outer conductor part (38).

6. Connector (2) according to claim 1, characterized in that the further third guide surface (44) by an inner surface of an axially displaceable sleeve (30) on the first connector (4) and the fourth guide surface (42) by an outer surface on the second outer conductor part (38) is formed.

7. Connector (2) according to claim 6, characterized in that the third guide surface (44) is a cylinder jacket-shaped inner surface and the fourth guide surface (42) is a cylinder jacket-shaped outer surface.

5 8. Connector (2) according to at least one of the preceding claims,

characterized in that the first guide surface (20) of the first connector (4) and the second guide surface (18) of the second connector (6) are arranged and configured such that during assembly of the first connector (4) with the second connector (Fig. 6) first the first

0 guide surface (20) the second guide surface (18) contacted mechanically and then further joining the first connector (4) with the second connector (6), the first outer conductor contact portion (32) the second outer conductor contact portion (40) mechanically and electrically contacted.

5 9. Connector (2) according to at least one of the preceding claims,

characterized in that the first outer conductor part (28) and the first outer conductor contact portion (32) are formed in one piece and / or of the same material.

! 0

10. Connector (2) according to at least one of the preceding claims,

characterized in that the first outer conductor contact portion (32) with respect to the first outer conductor part (28) is a separate component, which is pressed into the first outer conductor part (28).

: 5

11. Connector (2) according to at least one of the preceding claims,

characterized in that the first guide surface (20) is formed on an additional sleeve (21) which is pressed onto the first outer conductor part (28).

Ό

12. First connector (4) for a connector (2) according to one of claims 1 to

11th

13. Second connector (6) for a connector (2) according to one of claims 1 to 11.