DE102023132400A1 - Shield transmission via release sleeve for shielded PushPull connector - Google Patents

Abstract

Plug connection, consisting of a plug connector (10) and a mating connector (20) that can be plugged together with it, wherein the plug connection is shielded against external high-frequency influences and the plug connector (10) is plugged together with the mating connector (20) in a push-pull plugging process, wherein the plug connector (10) has an unlocking sleeve (13) that is displaceable in the axial direction, wherein a circumferential surface of the unlocking sleeve (13) pointing in the direction of the mating connector (20) comes into contact with a circumferential surface of the mating connector (20) pointing in the direction of the plug connector (10) in the plugged state.

Description

The invention relates to a plug connection, consisting of a plug connector and a mating connector that can be plugged together, wherein the plug connection is shielded against external high-frequency influences, according to the features of the preamble of patent claim 1.

The connector is connected to the mating connector using a well-known push-pull connection method.

It is important for the plug connection that a shield against these external high-frequency influences is provided, starting from a cable that has a shield (such as a shielding braid, a shielding foil or the like), and is looped through the plug connection to another cable, an electronic device or the like. This is done in a known manner by a component of the plug connector consisting of an electrically conductive material, which is mechanically and electrically brought together with a component of the mating connector made of an electrically conductive material.

Due to the use of the PushPull plug-in method, components of the connector are suitable and designed to interact with corresponding components of the mating connector in order to facilitate the insertion process on the one hand and to hold the plugged-in connection together on the other hand and finally to enable the connector and mating connector to be separated by a simple manual process without great effort.

In the current state of the art, it often happens that the components of the connector and/or the components of the mating connector that implement the push-pull connection process become dirty when the connector is plugged in. The same can happen when the connector is not plugged in, for example when the connector and its mating connector are stored. However, such contamination has the disadvantage that the components are difficult to move during a disconnection process or, in the worst case, are even blocked, so that the connector can no longer be separated from its mating connector.

The invention is therefore based on the object of improving a plug connection of the type described at the outset in such a way that, on the one hand, the shielding is looped through the plug connection and, on the other hand, contamination of the components of the plug connector and/or the mating connector which implement the push-pull plug-in method is avoided.

This object is achieved in that the connector has a release sleeve which can be displaced in the axial direction, wherein a circumferential surface of the release sleeve pointing in the direction of the mating connector comes into contact with a circumferential surface of the mating connector pointing in the direction of the connector in the plugged-in state.

This system causes the shielding to be ground through the plug connection when the release sleeve of the connector, which is made of an electrically conductive material and is arranged at the end of a shielded cable, the shielding being electrically connected to the release sleeve, has come into contact with a corresponding component of the mating connector, which is also made of an electrically conductive material, in the plugged-in state.

At the same time, this prevents contamination of the internal components of the connector and the mating connector when they are plugged in. In particular, those components that implement the push-pull plug-in process are protected.

Alternatively, it is also conceivable that the release sleeve of the connector and the corresponding component of the mating connector are made of an electrically non-conductive material and that the shielding is ground through by means of further components of the connector and the mating connector, which then consist of an electrically conductive material.

• 1 zeigt einen Steckverbinder 10, der nach dem PushPull-Steckverfahren, beispielsweise nach DIN EN 61076-2-010, ausgebildet ist.
• 2 zeigt einen mit dem Steckverbinder 10 gemäß 1 zusammenwirkenden Gegenstecker 20 im ungesteckten Zustand.
• 3 zeigt das vordere, in Richtung des Gegensteckers 20 weisende Ende des Steckverbinders 10. Auf einer Schirmhülse 11, vorzugsweise aus einem elektrisch leitfähigen Material, innerhalb derer zumindest ein Kontakt des Steckverbinders 10 angeordnet ist, ist ein zumindest geringfügig axial verschiebbarer oder ggfs. auch festgelegter Schnappring 12, vorzugsweise aus einem elektrisch nicht leitfähigen Material, angeordnet. Über einen Teilbereich des Schnappringes 12 ist eine ebenfalls axial verschiebbare Entriegelungshülse 13, vorzugsweise aus einem elektrisch leitfähigen Material, angeordnet. Zwischen der äußeren Oberfläche des Schnappringes 12 und der nach innen weisenden Oberfläche der Entriegelungshülse 13 ist ein Federelement, vorzugsweise eine Spiralfeder 13 (oder ggfs. ein vergleichbar wirkendes, konstruktiv anders gestaltetes Element) angeordnet. Diese Spiralfeder 13 ist zwischen einem umlaufenden Absatz der Schirmhülse 11 und einem korrespondierenden umlaufenden Absatz der Entriegelungshülse 13 vorgespannt. Das in Richtung des Kabels weisende Ende der Entriegelungshülse 13 weist einen umlaufenden Rastvorsprung auf, der an einem Gehäuse, insbesondere einer Umspritzung, des Steckverbinders 10 zur Anlage kommen kann oder von dieser abheben kann.
• 4 zeigt den Steckverbinder 10 im ungesteckten Zustand. Dabei ist erkennbar, dass der umlaufende Rastvorsprung der Entriegelungshülse 13 an dem Anschlag des Gehäuses 15, vorzugsweise ausgebildet als Umspritzung (alternativ an einem Anschlag, der von der Schirmhülse gebildet wird), anliegt. Mit anderen Worten ist somit vorgesehen, dass sich ein umlaufendes Ende der Entriegelungshülse 13 an einem Gehäuse 15 des Steckverbinders 10 in einem Anlagebereich 16 abstützt.
• 5 zeigt den Steckverbinder 10 im gesteckten Zustand, d. h., dass er in den Gegenstecker 20 gemäß 2 eingesteckt worden ist. Dadurch kommt die Entriegelungshülse 13, genauer dessen vordere umlaufende Stirnseite, in Kontakt mit dem korrespondierenden Bauteil des Gegensteckers 20, insbesondere dessen vordere umlaufende Stirnseite seines Gehäuses. Bestehen Entriegelungshülse 13 und korrespondierendes Bauteil des Gegensteckers 20, aus elektrisch leitfähigem Material, wird die Abschirmung über die zusammengesteckte Steckverbindung durchgeschliffen. Auf jeden Fall ist es ergänzend oder alternativ dazu wichtig, dass die vordere umlaufende Stirnseite der Entriegelungshülse 13 zur Anlage kommt mit der umlaufenden vorderen Stirnseite des Gegensteckers 20. Durch diese Anlage im Bereich A wird das Eindringen von Verschmutzungen wie zum Beispiel kleineren Partikeln, gegebenenfalls aber auch Spritzwasser oder dergleichen, in das Innere der zusammengesteckten Steckverbindung wirksam verhindert. Alternativ oder ergänzend kann sich das vordere Ende der Entriegelungshülse 13 auch ein Stück weit koaxial über das korrespondierende vordere Ende des Gegensteckers erstrecken (überstülpen). Die axiale Verschiebbarkeit der Entriegelungshülse 13 auf der Schirmhülse 11 (beziehungsweise auf dem auf der Schirmhülse 12 angeordneten Schnappring 12, wird durch den in 4 und 5 als Anschlagbereich 16 bezeichnete Ausgestaltung begrenzt.
• 6 gezeigt den Steckverbinder 10 im gesteckten Zustand (links bei Betrachtung der 6 ist der Gegenstecker 20 erkennbar), ohne dass die Entriegelungshülse 13 in dieser Ansicht dargestellt ist. Dadurch wird die Anordnung und die sich daraus ergebende Funktionsweise der Spiralfeder 14 deutlich. Hier ist mit der Bezugsziffer 21 auch die vordere umlaufende Stirnseite 21 des Gegensteckers 20 erkennbar.
• 7 schließlich zeigt im Schnitt die gesteckte Steckverbindung, wobei erkennbar ist, dass zumindest ein elektrischer Leiter 18 (hier zwei elektrische Leiter 18 im Schnitt) des Kabels 17 zu Kontakten innerhalb der Schirmhülse 11, insbesondere im Bereich deren vorderen Endes, führt. Die Abschirmung 19 des Kabels 17, wie beispielsweise ein Abschirmungsgeflecht, wird auf geeignete Art und Weise zu der Entriegelungshülse 13 geführt und mit dieser elektrisch kontaktiert (vorzugsweise durch Anlage). Alternativ oder ergänzend dazu kann die Abschirmung 19 des Kabels 17 auch zu anderen Bauteilen des Steckverbinders 10 (wie beispielsweise der aus einem elektrisch leitfähigen Material bestehenden Schirmhülse 11) geleitet und dort elektrisch kontaktiert werden. Bestehen sowohl Entriegelungshülse 13 als auch Schirmhülse 11 aus einem elektrisch leitfähigen Material, kann eines dieser Bauteile oder es können beide Bauteile mit der Abschirmung 19 des Kabels 17 verbunden werden. Besteht nur eines der beiden Bauteile aus einem elektrisch leitfähigen Material, wird die Abschirmung 19 des Kabels 17 nur mit diesem Bauteil verbunden.

An embodiment of a plug connection according to the invention is briefly described below and is shown in the figures.

• 1 shows a connector 10 which is designed according to the PushPull plug-in method, for example according to DIN EN 61076-2-010.
• 2 shows a connector 10 according to 1 cooperating mating connector 20 in the unmated state.
• 3 shows the front end of the connector 10 pointing in the direction of the mating connector 20. On a shielding sleeve 11, preferably made of an electrically conductive material, within which at least one contact of the connector 10 is arranged, there is arranged an at least slightly axially displaceable or possibly also fixed snap ring 12, preferably made of an electrically non-conductive material. A axially displaceable release sleeve 13, preferably made of an electrically conductive material. A spring element, preferably a spiral spring 13 (or possibly a similarly acting, structurally differently designed element) is arranged between the outer surface of the snap ring 12 and the inward-facing surface of the release sleeve 13. This spiral spring 13 is pre-tensioned between a circumferential shoulder of the shield sleeve 11 and a corresponding circumferential shoulder of the release sleeve 13. The end of the release sleeve 13 pointing in the direction of the cable has a circumferential locking projection which can come into contact with a housing, in particular an overmolding, of the connector 10 or can lift off from it.
• 4 shows the connector 10 in the unplugged state. It can be seen that the circumferential locking projection of the release sleeve 13 rests against the stop of the housing 15, preferably designed as an overmolding (alternatively against a stop formed by the shielding sleeve). In other words, it is thus provided that a circumferential end of the release sleeve 13 is supported on a housing 15 of the connector 10 in a contact area 16.
• 5 shows the connector 10 in the plugged state, ie that it is inserted into the mating connector 20 according to 2 has been plugged in. As a result, the release sleeve 13, or more precisely its front circumferential face, comes into contact with the corresponding component of the mating connector 20, in particular the front circumferential face of its housing. If the release sleeve 13 and the corresponding component of the mating connector 20 are made of electrically conductive material, the shielding is ground through via the plugged-in connection. In any case, it is additionally or alternatively important that the front circumferential face of the release sleeve 13 comes into contact with the circumferential front face of the mating connector 20. This contact in area A effectively prevents dirt, such as small particles, but possibly also splash water or the like, from penetrating the interior of the plugged-in connection. Alternatively or additionally, the front end of the release sleeve 13 can also extend coaxially over the corresponding front end of the mating connector (pull over it) for a short distance. The axial displacement of the release sleeve 13 on the shield sleeve 11 (or on the snap ring 12 arranged on the shield sleeve 12) is determined by the 4 and 5 The design referred to as stop area 16 is limited.
• 6 shown the connector 10 in the plugged state (left when looking at the 6 the mating connector 20 is visible), without the release sleeve 13 being shown in this view. This makes the arrangement and the resulting function of the spiral spring 14 clear. Here, the front circumferential face 21 of the mating connector 20 can also be seen with the reference number 21.
• 7 finally, a cross-section of the plugged-in connector shows that at least one electrical conductor 18 (here two electrical conductors 18 in cross-section) of the cable 17 leads to contacts within the shielding sleeve 11, in particular in the area of its front end. The shielding 19 of the cable 17, such as a shielding braid, is guided in a suitable manner to the release sleeve 13 and electrically contacted therewith (preferably by contact). Alternatively or in addition to this, the shielding 19 of the cable 17 can also be guided to other components of the connector 10 (such as the shielding sleeve 11 made of an electrically conductive material) and electrically contacted there. If both the release sleeve 13 and the shielding sleeve 11 are made of an electrically conductive material, one of these components or both components can be connected to the shielding 19 of the cable 17. If only one of the two components consists of an electrically conductive material, the shield 19 of the cable 17 is only connected to this component.

Functions of the connector according to the invention:

1. 1. Transfer of the shield from the cable shield and from the shield sleeve via spiral spring and release sleeve to the housing of the mating connector, and/or
2. 2. Protection against the ingress of dirt, particularly in the locking area: The gap between the mating connector and the release sleeve is closed. This prevents dirt from penetrating the locking area and further into the interior.

List of reference symbols

10.

Connectors

11.

Shield sleeve

12.

Snap ring

13.

Release sleeve

14.

Spiral spring

15.

Housing

16.

Investment area

17.

shielded cable

18.

Line (alternatively referred to as conductor)

19.

shielding

20.

Mating connector

Claims (6)

Plug connection, consisting of a plug connector (10) and a mating connector (20) that can be plugged together with it, wherein the plug connection is shielded against external high-frequency influences and the plug connector (10) is plugged together with the mating connector (20) in a push-pull plugging process, characterized in that the plug connector (10) has an unlocking sleeve (13) that is displaceable in the axial direction, wherein a circumferential surface of the unlocking sleeve (13) pointing in the direction of the mating connector (20) comes into contact with a circumferential surface of the mating connector (20) pointing in the direction of the plug connector (10) in the plugged state. Plug connection according to Claim 1 , characterized in that the plug connector (10) has a shielding sleeve (11), wherein the unlocking sleeve (13) is arranged coaxially around the shielding sleeve (11) so as to be axially displaceable. Plug connection according to Claim 2 , characterized in that an axially effective spring element, in particular a spiral spring (14), is arranged between the shielding sleeve (11) and the unlocking sleeve (13). Plug connection according to Claim 1 , 2 or 3 , characterized in that a circumferential end of the unlocking sleeve (13) is supported on a housing (15) of the connector (10) in a contact area (16). Plug connection according to one of the preceding claims, characterized in that the plug connector (10) is arranged at one end of a shielded cable (17), wherein the cable (17) has at least one line (18) which is surrounded by a shield (19) of the cable (17), wherein the shield (19) is electrically contacted via the unlocking sleeve (13) of the plug connector (10) with a shield of the mating plug (20) in the plugged-in state of the plug connection. Plug connection according to Claim 5 , characterized in that a housing of the mating connector (20) made of an electrically conductive material is part of its shielding.