DE3843852A1 - Plug connector - Google Patents

Abstract

A plug connector having a socket housing which is constructed for insertion of an insert part in the axial direction, latching means for locking the insert part with respect to the socket housing in the axial direction being provided between the outer circumference of the insert part and the inner circumference of the socket housing.

Description

The innovation concerns a connector with a for inserting a slide-in part (e.g. insulation body) formed in the axial direction can housing. The generic subject also includes analog formed connector housing.

Such connectors are in use in numerous areas of technology, esp especially in electrical engineering and electronics next to fluid connections, hydraulic connections, Pneumatic connections and the like are used. At such plug-in connector is the insert part the actual connecting elements, for example electrical contact pins and / or electrical contact bushings, pre-assembled and then in the axial direction in the Inserted box housing. For final assembly, the Slide-in part opposite the socket housing, which is why the insertion part is primarily used there sticks. It is therefore no longer removable. Known connections by means of screws are also complicated and time-consuming to assemble and moreover not always sure.

The innovation is therefore based on the task of such Further develop connectors and a connector to provide at which the attachment  of the insert part in the socket or connector Housing is improved to the extent that it is firm, simple and lies there safely and preferably detachably.

According to the innovation, the task is solved by a Connector with one for inserting an insert part designed in the axial direction can housing, in which between the outer circumference of the insert and the inner circumference catch of the can housing locking means for locking the Insert part in relation to the socket housing in the axial direction are provided.

According to the innovation, therefore, the definition of the on now compared to the can housing by im Latching means fitted inside the connector. It can therefore no longer happen that as mentioned State of the art separate fasteners from the outside need to be introduced that loosen or even get lost can go. Locking means proposed according to the innovation can be trained in a variety of configurations.

In addition, the arrangement of locking means inside the can housing achieved that this locks elements do not act on the can housing from the outside are subject to certain influences, for example one Impact, corrosive influences or the like. The innovation therefore increases the safety of Steck connectors significantly increased.

According to a particularly simple embodiment of the innovation is at least one on the inner circumference of the can housing orderly locking projection provided radially inwards protrudes into the socket housing and with an inclined surface is provided, which is in the direction of insertion of the insert the free cross-section of the can housing in the can housing gradually decreased. Such is preferably one  Locking projection formed in one piece with the socket housing. When inserting the insert, it runs on the inclined surface, whereby the cross section of the Insert according to the radial extent of the slope area is currently being reduced. This is preferable the insert part from a relative, based on the can housing, soft and / or elastic material manufactured. The through the inclined surface of the locking projection deformation of the insert during insertion ben in the axial direction is therefore only temporary, and in the slot in the direction behind the locking projection Pushed in by the locking projection Material of the insert part again in the radial direction and thus ensures that the insert slides out partly safely avoided against the direction of insertion becomes. For this purpose, the can housing can, for example a relatively hard plastic or metal and the Insert made from a relatively soft, elastic synthesis be made of rubber, such as under the name neoprene is commercially available.

Of particular importance with the innovation is that this basically the shape of the can housing respectively no restrictions are imposed on the insert. So can the can housing has practically any shape in cross-section have the shape of a circle, rectangle, Triangles, oval or the like. The shape of the plug connector can therefore be optimally the jewei intended purpose, in particular the type of connection Adjust parts.

During the embodiment described above is particularly suitable for those cases in which a proportionate without providing additional funds  good sealing between the insert and the can to reach the house, there are numerous uses cases where the insert part is similarly rigid is like the can housing and does not deform lets or in particular should be detachable. Then another advantageous off is recommended management form of the innovation, in which a ring part is provided, which is partially in a first recess in the box housing and partly in a second recess sits in the insert. Such a ring part is advantageously from an at least slightly resilient Material manufactured, which for assembly either in the Recess in the box housing or in the recess in Insert part is pushed and held there. At the Inserting the insert into the socket housing snaps into place then the ring part in the corresponding one Recess of the other part and prevented so, after snapping in, another axial shift. If necessary, further measures can be taken can also be achieved with such a ring part that the axial locking can be released again. this will explained in more detail below.

A particularly simple design, which is a main part that actually covers the intended purposes, arises when the can housing is hollow cylindrical and the insert is cylindrical.

The first recess is preferably in the can housing provided with abutment surfaces that correspond to the corresponding Interact surfaces of the ring part and this in axial Determine the direction of the can housing.  

If the outer circumference of the ring part is smaller than that Inner circumference of the first recess in the can housing, see above can also be a rigid, radially inflexible insert be inserted into the socket housing, because then at Insert the insert part of the ring part into the free Dodge the space of the first recess in the box housing can. For this purpose, the ring part is advantageously with one at the back in the direction of insertion of the insert arranged sloping surface, which the free cross-section of the ring part is gradually reduced in the direction of insertion. When inserting the insert, it therefore runs on the inclined surface and thus presses the ring part radially outwards and into the first recess in the box housing into it, causing the interior of the can housing as far is released that the insert continues in axial direction can be inserted until the ring is back in the recess in the insert part springs back and the insert part against the can. The insertion will still be further relieved when the insert part at its front section in the direction of insertion taper the insertion part has inclined surface. Then act when shooting ben of the insert, the inclined surface of the insert and the inclined surface of the ring part together. This is preferably the angle between the axial direction, that is the direction of insertion, and the inclined surface of the ring part larger than the angle between the axial direction and the inclined surface of the insert.

The ring part is preferably radial with one of these penetrating slot and by change the slot width variably in its diameter det. This change in diameter is necessary thus the ring part, for example, inserted into the box housing can be pushed. To insert the ring part in the Recess of the can housing is first merged presses, inserted into the can and then in the area of  released radial inner groove in the can wall, the ring part due to its own elasticity expands again and initially lies loosely in the groove. It can no longer fall out of this recess. Enlarged again when inserting the insert the slot of the ring part (due to the expansion through the insert part with a larger diameter), whereby is achieved that the insert part as far as in the ring part can be inserted until the second recess of the Insert part reaches the ring part. Then he snaps Ring part back together a bit and is also in the second recess of the insert part, whereby the axial locking of the insert part in relation to the cans housing is reached.

To the required expansion of the ring part in the to accomplish the first recess of the can housing , as mentioned above, is the outer circumference of the ring part in the rest position less than the inner circumference the first recess in the box housing. this leads to a relatively loose fit of the ring part in the first recess of the can housing. To here one to achieve a firmer fit and still at the same time an expansion of the ring part in this first recess of the can housing, the ring part is on his Outer circumference advantageously with at least one spring part provided which the ring part against the bottom of the Ausneh the socket housing resiliently supported. If there is an tion of the ring part therefore presses the spring part somewhat together and thus enables the enlargement of the clear Width of the ring part for inserting the insert part. Advantage fortunately there are several over the outer circumference of the ring part distributed spring parts provided, preferably in the same Dimensions spaced apart. The ring part and the spring part or the spring parts is or are preferably carried out in one piece. For this the spring part as oblique from the outer circumference of the ring part  standing spring rib be formed.

In a particularly advantageous embodiment of the innovation it is provided that the ring part with an insert direction of the insert at the front is provided, which is the free cross section of the ring part gradually expanded in the direction of insertion that the use partly in its front section a smaller diameter has than the inner diameter of the can housing is so that a ring in the region of the front section gap formed between insert and box housing and that the area in front in the direction of insertion the can housing is open to one in the annular gap insertable unlocking tool on the front arranged to press the inclined surface of the ring part and so loosen the ring part from the recess of the insert part. This can easily unlock the Insert part can be achieved compared to the can housing. In one embodiment of the connector, in which the insert part is cylindrical and the socket housing is hollow cylindrical is drisch, the resulting annular gap is therefore also hollow cylindrical, and the unlocking tool can easily be a piece of pipe that is adapted to the annular gap and whose wall thickness is preferably somewhat less than the width of the ring gap.

The innovation is shown below using drawings illustrated embodiments explained in more detail, from which there are further advantages and features. It shows

Figure 1 is a longitudinal section of a partial view of a connector according to the innovation.

Figs. 2a and 2b in cross-section two embodiments of a ring portion for the connector shown in Figure 1. and

Fig. 3 shows a further embodiment of a connector according to the innovation, which is particularly simple, in longitudinal section.

Since the embodiment of the innovation shown in FIG. 3 has a special structure, it should first be discussed. Fig. 3 shows a longitudinal section of a fastex binder 70 with a substantially hollow cylindrical socket housing 74 , in which an insert part 72 (here an insulating body) is inserted in an insertion direction indicated by an arrow 84 .

The insert part is provided, for example, with an electrical contact plug 80 which extends further through the insert part 72 and has a connecting lug 82 at the opposite end, to which a line can be fastened, for example by a screw connection, solder connection or the like.

Inside the can housing 74 locking means are provided, which are formed in the embodiment shown in Fig. 3 as a circumferential around the inner circumference of the can housing 74 locking nose 76 . The locking lug 76 has, in a pushing direction 84 of the insert part 72 on the input side, an inclined surface 78 , which gradually reduces the cross section of the socket housing 74 in the insertion direction 84 and then ends on a surface which springs back vertically onto the inner wall of the socket housing 74 .

The can housing 74 is made of aluminum, while the one part 72 made of rubber, on the other hand, is relatively soft and, in particular, elastic in the radial direction. When inserting insert 72 into socket housing 74 , the front end face of insert 72 runs onto inclined surface 78 at a certain point in time. This results in a compression in the radial direction in the relevant area of the insert part 72 , which is reduced again with a further advance in the insertion direction 84 , since after passing the locking lug 76 the insert part 72 expands radially outward again.

The insertion of the insert part 72 in the insertion direction 84 is continued until the insert part 72 abuts an unspecified ring flange at the end of the canned housing 74 and the insulating body 72 engages in a form-fitting manner with a circumferential groove corresponding to the catch. The insert part 72 is prevented from moving backward (in the opposite direction of the arrow 84 ) by the circumferential locking projection 76 . The elasticity of the insert part 72 , which leads to the fact that it nestles closely everywhere on the inner wall of the can housing 74 , ensures a relatively good seal and thus prevents foreign bodies between the inner surface of the can housing 74 and the outer surface of the Insert part 72 can penetrate.

Since in the embodiment shown in Fig. 3 of the connector according to the innovation, the locking is accomplished by the cooperation of the locking projection 76 and the elasticity of the insert part 72 , a solution to this locking is practically only possible by damage to the outer circumference of the insert part 72 . Such an embodiment is therefore recommended for those cases in which a particularly simple and therefore inexpensive construction is required and it is intended to prevent the insert and the can housing from being detached from one another.

In contrast, in the embodiment of the innovation shown in Fig. 1, the possibility of a solution to the axial locking of an insert part against a Dosenge housing is possible.

The connector 10 shown in Fig. 1 has an essentially hollow cylindrical socket housing 14 , in which an insert part 12 is arranged with a substantially cylindrical shape. The insert part 12 is in the illustration according to FIG. 1 in its locked end position in the socket housing 14 .

The locking of the insert part 12 in the socket housing 14 is accomplished by a first groove 16 in the socket housing 14 , a second groove 32 in the insert part 12 , and a locking device which engages in part in both grooves 16, 32 , namely a ring part 24 . The ring part 24 has the shape of a circular ring interrupted by a gap (not shown) with the approximately double trapezoidal cross-section recognizable in the sectional view in FIG. 1. The outer circumference of the ring part 24 is less than the inner circumference of the first recess 16 of the can housing 14 , which becomes clear in FIG. 1 on the basis of the distance between the bottom 18 of the recess 16 and the ring part 24 . The axial extent of the ring part 24 is slightly less than the distance between two stop surfaces 20, 22 of the recess 16 , so that the ring part 24 is axially securely fixed in the recess 16 . The axial extent and the depth of the recess 32 from the insert part 12 is in each case less than the corresponding dimensions of the recess 16 of the can housing 14 . In particular, the depth of the recess 32 in the insert part 12 is less than the distance between the ring part 24 and the bottom 18 of the first recess 16 . Therefore, if the ring part is pressed so far (downwards in FIG. 1), the diameter of the ring part 24 is expanded, until the ring part 24 with its outer circumference touches the bottom 18 of the recess 16 in the can housing 14 , the ring part 24 is no longer seated in the Recess 32 of a set part 12 , so that it is now unlocked.

The direction of insertion of the insert 12 into the Dosenge housing 14 is indicated by an arrow 44 in Fig. 1. At the front end of the insert part 12 , an electrical plug contact 40 is provided, which continues through the insulating body 12 in an electrically conductive manner and opens at the opposite end into a connecting lug 42 , to which an electrical line can be connected by a suitable fastening type. The plug contact 40 is designed to engage in an electrical socket, not shown, of a corresponding counterpart of the connector 10 .

At its front end, the insert is tapered by an oblique surface 34 . Furthermore, the front portion of the insert 12 to form an annular gap 46 in its front portion of smaller diameter than the inner diameter of the can housing 14 is in this area. The resulting annular gap 46 between insert 12 and socket housing 14 serves, as will be explained in more detail below, for inserting an unlocking tool. This interacts with an inclined surface 26 of the ring part 24 in the manner specified below.

Starting from a detent 30, which accomplishes the locking of the ring portion 24 in the recess 32 of the insert 12, a further inclined surface 32 is provided on the ring part 24th

When inserting insert 12 into socket housing 14 in insertion direction 44 , insert 12 can first be freely pushed into socket housing 14 until the front edge of inclined surface 34 of insert 12 runs onto inclined surface 28 of ring part 24 . The interaction of the two inclined surfaces 34, 28 expands the ring part 24 and thus provides a larger clear width, so that the insert part 12 can be advanced further in the direction of the arrow 44 . As soon as the front edge of the groove 32 of the insert part reaches the latching lug 30 of the ring part 24 , the ring part 24 snaps back and presses into the recess 32 of the insert part. A further forward movement (in the direction of arrow 44 ) is prevented in that a stop surface 38 of the insert part 12 comes to rest against a corresponding stop surface 36 of the can housing 14 . The insert part is now prevented from moving backwards (against the direction of arrow 44 ) by the wall of the groove 32 and the latching lug 30 of the ring part 24 resting thereon.

A seal of the insert 12 relative to the Dosenge housing 14 is done by a housing in a groove 48 of the can 14 imprisoned O-ring 50th

For unlocking, an unlocking tool adapted to the shape of the annular gap 46 , that is to say a tubular unlocking tool in the embodiment shown in FIG. 1, is inserted into the annular gap 46 against the direction of the arrow 44 . As soon as the unlocking tool (not shown) acts on the inclined surface 26 of the ring part 24 , the ring part 24 deviates outwards accordingly and thus increases its diameter, namely until the outer circumference of the ring part 24 comes to rest approximately on the bottom 18 of the recess 16 . This leads to the fact that correspondingly the locking projection 30 of the ring part 24 slides out of the recess 32 of the insert part 12 and releases it. The insert part 12 can then be pulled out of the can housing 14 against the insertion direction 44 . After removal of the unlocking tool from the area 46 , the ring part 24 springs back into its rest position and the entire device is ready for insertion of an insert part 12 (or another insert part) in the insertion direction 44 .

The ring part 24 shown in Fig. 1 is relatively simple. To form the free area between the ring part 24 and the bottom 18 of the groove 16 , the ring part 24 sits radially displaceably in the groove 16 . This ring part is shown again in Fig. 2a.

If a firmer fit of the ring part in the groove 16 is achieved and the unlocking function is to be maintained, an embodiment of a ring part shown in FIG. 2b is recommended. A ring part designated there with the reference number 54 is formed in its inner region as well as the ring part 24 , as can be clearly seen from the comparison of FIGS. 2a, 2b. As 54, the ring part has a slanted surface 56 (corresponding to the inclined surface 26) for engagement by a release tool to a latching lug 60 (corresponding to the locking lug 30) and an inclined surface 58 (corresponding to the inclined surface 28) to cooperate with the inclined surface 34 of in FIG. 1 insert 12 shown .

In addition, the ring part 54 shown in Fig. 2b is provided with a resilient projection 62 which projects outward from the body of the ring part 54 . The Fe-reducing projection 62 is designed so that it touches the bottom 18 of the recess 16 of the can housing 14 in the rest position of the ring part 54 and thus lies centrally and securely in the groove. If the diameter of the ring part 54 is expanded by inserting the insert part 12 (inclined surface 34 ), the distance between the free end of the resilient projection 62 and the body of the ring part 54 is reduced. As a result of the resilient support from the ring part 54 by the resilient projection 62 , the ring part 54 is now held virtually free of play in the groove 16 of the can housing 14 even in the radial position.

The ring part 54 can be made of plastic or metal, the resilient radial projection preferably being made in one piece with the other parts.

Claims (14)

1. Connector with a for inserting a slide part formed in the axial direction Dosenge housing, characterized in that between the outer periphery of the insert part ( 72, 12 ) and the inner periphery of the socket housing ( 74, 14 ) locking means ( 76; 16, 24, 32 ) for locking the insert part ( 72, 12 ) in relation to the socket housing ( 74, 14 ) are provided in the axial direction. 2. Connector according to claim 1, characterized in that at least one on the inner circumference of the socket housing ( 74 ) arranged locking projection ( 76 ) is provided, which projects radially inwards into the socket housing ( 74 ) and is provided with an inclined surface ( 78 ), which in the insertion direction (84) of the insert part (72) in the socket housing (74) the free cross section of the socket housing (74) is gradually reduced. 3. Connector according to claim 1, characterized in that an annular part ( 24, 54 ) is provided, which is partially in a first recess ( 16 ) in the Dosenge housing ( 14 ) and partially in a second recess ( 32 ) in the insert part ( 12 ) sits. 4. Connector according to one of claims 1 to 3, characterized in that the socket housing ( 14, 74 ) is hollow cylindrical and the insert ( 12, 72 ) is cylindrical. 5. Connector according to claim 3 or 4, characterized in that the first recess ( 16 ) in the socket housing ( 14 ) is provided with stop faces ( 20, 22 ) which fix the ring part ( 24 ) in the axial direction of the socket housing ( 14 ). 6. Connector according to one of claims 3 to 5, characterized in that the outer circumference of the ring part ( 24, 54 ) is smaller than the inner circumference of the first recess ( 16 ) in the socket housing ( 14 ). 7. Connector according to claim 6, characterized in that the ring part ( 24, 54 ) with a in the insertion direction ( 44, 84 ) of the insert part ( 12, 72 ) rearward inclined surfaces ( 28, 58 ) is provided, which the free cross-section of the ring part gradually reduced in a direction of insertion. 8. Connector according to claim 6 or 7, characterized in that the insert part ( 12 ) at its front portion in the insertion direction has the insertion part ( 12 ) ver tapered surface ( 34 ). 9. Connector according to claim 8, characterized in that the angle between the axial direction and the inclined surface ( 28, 58 ) of the ring part ( 24, 54 ) is greater than the angle between the axial direction and the inclined surface ( 34 ) of the insert part ( 12 ) . 10. Connector according to one of claims 6 to 9, characterized in that the ring part ( 24, 54 ) has a radial through this slot. 11. Connector according to claim 10, characterized in that the ring part ( 54 ) is provided on its outer circumference with at least one spring part ( 62 ) which the ring part ( 54 ) against the bottom ( 18 ) of the recess ( 16 ) of the socket housing ( 14th ) resiliently supported. 12. Connector according to claim 11, marked by a lot about the circumference of the ring part in Distance between spring parts. 13. Connector according to claim 11 or 12, characterized in that the ring part ( 54 ) and the spring part ( 62 ) (the spring parts) is made in one piece (are). 14. Connector according to one of claims 10 to 13, characterized in that the ring part ( 24, 54 ) with a in the insertion direction ( 44, 84 ) of the insert part ( 12 ) at the front arranged th inclined surface ( 26, 56 ) is provided, which the free cross section of the ring part ( 24, 54 ) in the insertion direction ( 44, 84 ) gradually expanded that the insert part ( 12 ) has a smaller diameter in its front section than the inside diameter of the box housing ( 14 ), so that in the region of the front section an annular gap ( 46 ) is formed, and that the area of the socket housing ( 14 ) located at the front in the direction of insertion is open for pushing an unlocking tool over the annular gap ( 46 ) onto the inclined surface ( 26, 56 ) of the ring part ( 24, 54 ).