DE4439852A1 - HF plug connector with built-in push=pull locking mechanism - Google Patents

Abstract

The high frequency (HF) plug connector has a push-pull action built into it as a means of locking the system into engagement. One part of the coupler has a plug (5) with a centrally positioned pin that aligns with a contact bush in the other half (1). Located on the plug section is a rigid cap (6) that can be moved axially. Between the cap and the plug is a sleeve (7) that has a series of radial slots to form fingers that can be deflected by axial movement of the cap. A threaded section (3) on the other part of the coupler engages an elastomer ring (8) in the plug body. When the cap is pushed axially the radial fingers compress the ring to securely grip the thread.

Description

The invention relates to an RF connector with a mechanism for locking with an RF coupler of the same system External thread.

There are numerous different HF plug connections Construction where the RF connector with the RF coupler of the same system or type using a screw sleeve is locked, which sits on the plug as a sleeve while the coupler has the corresponding external thread. In Cases in which it must be inserted very frequently, e.g. B. in Test fields, this screw lock is made up of several Disadvantageous reasons. On the one hand, there is the manufacture and dissolution the screw connection is much more time consuming than a simple one Inserting and pulling the plug. The other are not rarely the space so narrow that the Screw sleeve only laboriously and in small angular steps can rotate.

The invention has for its object an RF connector to create the genre specified in the introduction, the particular which is easy to use, without this at the expense of HF technical properties of the connector goes.

This task is according to the invention with an HF connector solved the features specified in claim 1. Erfin According to the invention, an RF connector is therefore basically arbitrary Type, i.e. B. an N plug or a 7/16 plug, without Abge changing its RF technical characteristics changes that a so-called push-pull lock  results. This means a lock, which is in the Stuck, i.e. when pushing, produces itself and itself vice versa, when pulling the plug again automatically solves. This is the form engagement between the sliding sleeve and to design the sleeve so that the radial together press the sleeve and thus the solution of the mold engagement only occur when the outer conductor of the plug is connected has face contact with the outer conductor of the coupler.

A complicated coupling mechanism between the slides to avoid sleeve and the radially elastic sleeve and nevertheless ensure that the latch is self active releases as soon as the sliding sleeve to separate the plug connection is drawn, it is appropriate if according to Claim 2 the sleeve on the connector body between two Stops axially displaceable and in the direction of the dome ler facing stop is spring-loaded. When pulling the sliding sleeve is then followed by the radially elastic sleeve the former automatically, which released the lock becomes.

The aforementioned spring loading of the radially elastic sleeve can be realized according to claim 3 in such a way that the latter encloses a prestressed helical compression spring, which with its coupler side end against a ring collar the plug body supports and with its other end against the bottom surface of the sleeve rests.

According to claim 4, the radially elastic sleeve in particular their pot-shaped and be from each other spaced segments exist. Suitable resilient Materials are generally known in connector technology.

The locking security is thereby increased if according to claim 5 of the radially compressible, durable tical ring wider than the length of the thread on the  Coupler is and so positio in the radially elastic sleeve is niert that he the male thread of the male Coupler partially engages behind.

The limit to the axial displacement of the sleeve Strikes can according to claim 6 by the respective pages flank an annular groove in the outer peripheral surface of the Plug body are formed.

Analogously, it is useful if according to claim 7 Push the sliding sleeve in the unlocking direction limited an annular shoulder formed on the plug body is.

The shape engagement between the sliding sleeve and the radial elastic sleeve, which ensures that the latter at axial Moving the former radially into the locking position is compressed, can ver according to claim 8 Realize that the sliding sleeve with a transition trained their inner peripheral surface in their end face ten chamfer against one in the outer peripheral surface of the radially elastic sleeve formed, beveled ring shoulder fits.

Known by the proposed redesign HF connector to achieve a push-pull lockable The length of the connector does not need to be changed enlarge. In particular, according to claim 9 the coupler series term end edge of the radially elastic sleeve in the con tactical front edge of the connector outer conductor containing Level.

The invention is explained below with reference to the drawing tert. This shows - only as an embodiment and in schematic simplification - a so-called N connector and the associated coupler, etc.

• - In Fig. 1 before making the connector and
• - In Fig. 2 after establishing the connector.

The illustrated coupler 1 has the usual and in the re standardized structure. Its outer conductor 2 carries a Außenge thread 3 , which is normally used to produce a locking by screwing a screw sleeve provided with a corresponding internal thread of the corresponding HF connector (not shown).

The connector 4 shown does not differ from such a conventional connector with regard to its design features that are essential for the HF technical properties. Instead of a screw cap sleeve, however, the plug body 5 carries a sliding sleeve 6 which, in the unlocked position shown in FIG. 1, bears against an annular shoulder 5 a of the plug body 5 . The outer peripheral surface of the sliding sleeve 6 is profiled for reasons of grip security.

On the plug body 5 is also a pot-shaped, radially elastic sleeve 7 , which comprises a Topfbo the 7 a and generated by axial slitting and accordingly speaking in the radial direction spring-elastic compressible segments 7 b. The forward coupler-side portion of the segments 7 is formed thickened and b provided on the inside with a flat and wide groove, which may optionally be undercut (not shown). A rubber-elastic ring 8 sits in this groove, the thickness of which is dimensioned such that it projects somewhat into the interior of the sleeve 7 . In the position shown in FIG. 1, the inside diameter of the rubber-elastic ring 8 is slightly larger than the diameter of the external thread 3 of the coupler 1 . In addition, the width of the ring 8 is slightly larger than the thread length of the external thread 3 of the coupler 1st

In the same thickened portion, the segments have 7 b at its outer periphery a bevelled annular shoulder 7c, against which is applied the sliding sleeve 6 with a groove formed in its end face at the junction of its inner periphery chamfer 6 a and, therefore, with the radially resilient sleeve 7 in a form of engagement stands, which releases when the sliding sleeve 6 is pressed in the direction of the coupler 1 and thereby the segments 7 b of the sleeve 7 are radially compressed.

Furthermore, the sleeve 7 is arranged to be displaceable by a small axial path on the plug body 5 and is spring-loaded in the direction facing away from the coupler 1 . For this purpose, the plug body 5 has on its outer circumference a flat annular groove 10 which is somewhat wider than the thickness of the pot bottom 7 a of the sleeve 7 , so that the two groove flanks act as axial stops for the displacement path of the sleeve 7 . The spring load of the sleeve 7 is generated by a person sitting on the plug body 5, prestressed helical compression spring 11, the collar with its coupler-side end against a projection formed on the plug body 5, projecting ring supports 5 b and ground with its other end against the pot 7 a of the sleeve 7 abuts.

The push-pull locking mechanism designed in this way works as follows: the plug 4 is inserted into the coupler 1 via the sliding sleeve 6 . By appropriate dimensioning of the-abutting ring surfaces of the abge beveled annular shoulder 7 c of the sleeve 7 on the one hand and the chamfer 6 a of the sliding sleeve 6 on the other hand, it is ensured that the positive connection is maintained until the outer conductor 5 c of the connector 4 forehead contact the radial annular surface 2 a of the outer conductor 2 of the coupler 1 . Then the sleeve 7 moves under compression of the coil spring 11 in the axial direction until the counterforce of the coil spring 11 is so great that the further displacement of the sliding sleeve 6 to the radial compression of the sleeve 7 and thus to solve the positive locking between 7 c and 6 a leads. The rubber-elastic ring 8 , which is positioned relative to the end edge of the plug outer conductor 5 c so that it is partly above and partly behind the external thread 3 of the coupler 1 when the end contact is made, is increasingly radially compressed. The locking process is complete when the parts assume the position shown in FIG. 2. Here remains between the coupler-side, inner end face of the pot bottom 7 a of the sleeve 7 and the opposite side flank of the annular groove 10, a gap 12 in the order of the plug gap. As a result, the reflection behavior of the plug-in connection is not significantly changed, even with large axial forces acting on the cable.

To release the connector, the sliding sleeve 6 is pulled in the opposite direction until it rests against the ring shoulder 5 a of the connector body 5 . Once the On chamfer 6 a of the sliding sleeve 6 in the unlocking direction behind the bevelled annular shoulder 7c of the sleeve 7 comes to rest, allowing the coil spring 11, the sleeve 7 of the sliding sleeve follow 6 until the pot bottom 7 a of the sleeve 7 against the other side edge of the Ring groove 10 is present. The elasticity of both the rubber-elastic ring 8 and the segments 7 b of the sleeve 7 cause their radial expansion, so that the positive connection with the external thread 3 of the coupler 1 is canceled again.

Claims (9)

1. RF connector ( 4 ) with a mechanism for locking with a system-identical RF coupler ( 1 ) with external thread de ( 3 ), characterized in that on the outer connector body ( 5 ) is a sliding sleeve ( 6 ), against its coupler side , Inner peripheral surface area is a radially elastic sleeve ( 7 ) with an area ih rer outer peripheral surface and engages in such a form ( 7 c, 6 a) that it axially displaces the sliding sleeve ( 6 ) in the direction of the coupler ( 1 ) radially is pressed together and then with a rubber-elastic ring ( 8 ) held on the inner circumference of the sleeve ( 7 ) and projecting into the interior of the sleeve, the inside diameter of which is at least equal to the diameter of the external thread ( 3 ) of the coupler ( 1 ), this external thread ( 3 ) of the coupler ( 1 ) engages. 2. Plug according to claim 1, characterized in that the sleeve ( 7 ) on the plug body ( 5 ) between two stops axially displaceable and in the direction of the stop facing away from the coupler ( 1 ) is spring-loaded ( 11 ). 3. Plug according to claim 2, characterized in that the radially elastic sleeve ( 7 ) encloses a prestressed helical compression spring ( 11 ) which is supported with its coupler-side end against an annular collar ( 5 b) of the plug body ( 5 ) and with its other end a bottom surface ( 7 a) of the sleeve ( 7 ). 4. Plug according to one of claims 1 to 3, characterized in that the radially elastic sleeve ( 7 ) is pot-shaped and comprises spaced segments ( 7 b). 5. Plug according to one of claims 1 to 4, characterized in that the radially compressible, permanent elastic ring ( 8 ) is wider than the length of the external thread of ( 3 ) on the coupler ( 1 ) and so in the radially elastic sleeve ( 7 ) is positioned so that it partially engages behind the external thread ( 3 ) of the coupler ( 1 ) in the inserted state. 6. Plug according to one of claims 2 to 5, characterized in that the axial displacement of the sleeve ( 7 ) delimiting stops by the respective side flanks of an annular groove ( 10 ) in the outer peripheral surface of the plug body ( 5 ) are formed. 7. Plug according to one of claims 1 to 6, characterized in that the sliding path of the sliding sleeve ( 6 ) is limited in the unlocking direction by an on the plug body by ( 5 ) formed annular shoulder ( 5 a). 8. Plug according to one of claims 1 to 7, characterized in that the sliding sleeve ( 6 ) with a chamfer formed at the transition of its inner peripheral surface in its end face che ( 6 a) against one in the outer peripheral surface of the radially elastic sleeve ( 7 ) trained, bevelled ring shoulder ( 7 c). 9. Plug according to one of claims 1 to 8, characterized in that the coupler-side end edge of the radially elastic sleeve ( 7 ) in the contacting end edge of the plug outer conductor ( 5 c) containing plane (I).