WO2016012006A1 - Plug-in connector having a low-wear sealing function - Google Patents

Abstract

A disadvantage in the prior art consists in the fact that the radial seals of plug-in connectors are exposed to a high degree of wear, in particular with high plug-in cycles. This wear is the result of friction which occurs in the plugging operation between the radial seal (14), in particular the sealing ring, and the mating plug housing (2). The object of the invention therefore consists in reducing the wear of the radial seals. This object is achieved in that the plug-in connector (1, 1') is first of all introduced with the radial seal (14) thereof into the mating plug housing (2) over a first path section, with the outside diameter of a radial seal (14) belonging to the plug-in connector (1, 1') first of all increasing as a result of the deformation of said seal, and in that the plug-in connector (1, 1') is subsequently finally introduced into the mating plug housing (2) over a second path section, with the radial seal (14), as a result of the progressive deformation thereof, coming into mechanical contact with the mating plug housing (2) only in the second path section, in order thereby to seal the plug-in connector (1, 1') with respect to the mating plug housing (2).

Description

 Connector with low-wear sealing function

description

The invention relates in a first aspect to a connector according to the preamble of independent claim 1.

In a second aspect, the invention relates to a method according to the preamble of independent method claim 18.

Such connectors are required, for example, in aerospace, in vacuum technology and in physical analysis technology, for example in high-pressure physics, and can also be used, for example, in shipping traffic.

State of the art

The document EP 1 703 599 A1 discloses a connector with a radially acting sealing ring having in cross-section three uniform, rounded lips. These lips, when mated in the radial direction, i. perpendicular to their direction of insertion, from the inside against the housing of the mating connector and thus seal the closed connector. These lips protrude in cross-section beyond the housing of the connector.

In particular, so-called "push-pull" connector, for example, from the document US 2007/02321 16 A1, known that allow locking and unlocking with a particularly high ease of use and also have a Radiaidichtung to seal against their mating connector. In these exemplified as well as in many other known devices, it is easy to see that the radial seal, in particular the sealing ring, the connector protrudes in the unplugged state in the radial direction on the housing to seal it in the inserted state effectively against the mating connector.

A disadvantage in the prior art is that thereby the radial seals, in particular the sealing rings, of connectors are exposed to high wear especially at high Sfeckzyklen. This wear, in particular the abrasion, is caused by friction, which occurs in the mating process between the Radiaidichtung, in particular the sealing ring, and the mating connector housing. Although the radial seals, in particular the sealing rings, can usually be changed. But the effort is undesirable and in some cases also problematic, for example in the field of deep sea and in space as well as in nuclear power plants and in clean rooms. Further areas of application are in particular in the field of high pressure and vacuum technology, where high demands are placed on the tightness, as well as in the industrial environment.

task

The object of the invention is therefore to reduce the wear of the radial seals, in particular the sealing rings.

The object is achieved in a first aspect with a connector of the type mentioned by the features of the characterizing part of independent claim 1. In a second aspect, the object is achieved by a method of the type mentioned by the features of the characterizing part of the independent method claim 18.

The connector, which may be, for example, a so-called "push-pull" connector, has over its mating connector in the inserted state a particularly good and durable seal and includes, for example waterproof and in particular airtight with the mating connector housing even after a high number Measurement series and simulations prove that, for example, in a push-pull connector according to the invention, this number amounts to at least 10,000 mating cycles and more In otherwise comparable push-pull connectors which correspond to the state of the art, the required tightness after 5,000 mating cycles was not Although their housings survived this load unscathed, however, the associated sealing rings were already finally destroyed after the 5,000 plug-in cycles Thus, the connector according to the invention thus has a particularly high maintenance friendliness and can be, for example, be particularly advantageous in the field of aerospace or in certain areas of physical metrology, such as high pressure physics, or in vacuum technology and industrial environments and in clean rooms and in protective atmospheres are used.

A significant advantage that is achieved by the invention, therefore, is that the wear, in particular the abrasion, the radial seals is significantly lower than in the prior art in comparable connectors is the case.

The connector has a connector housing with a plug-in end. The connector housing has, starting at its a plug-in end, an insertion area. The plug connector housing furthermore has a main area, wherein the main area can have a larger outer circumference than the insertion area in its cross section at right angles to the plugging direction. In a first embodiment, the main area can be connected to the lead in area via a funnel-shaped ramp area, the funnel-shaped ramp area being characterized It is characterized by the fact that its outer circumference continuously increases from the lead-in area to the main area. Adjacent to the ramp region, a completely circumferential or interrupted collar is formed on the main region, which has a larger outer circumference than the insertion region and preferably also has a larger outer circumference than the main region. This collar may also have a larger circumference than the funnel-shaped ramp portion in its cross-section adjacent the collar, thus preventing the radial seal from being pushed beyond the ramp portion to the main portion.

In a second embodiment, the main area may connect directly to the lead-in area, thereby having adjacent the lead-in area a right-angled edge which may be enlarged by the collar. Thus, in other words, the ramp area is missing.

The outer circumference of the radial seal in the relaxed state is less than or equal to the outer circumference of the collar of the connector. At the same time, however, the outer circumference of the radial seal is larger than the outer circumference of the insertion area.

The radial seal is elastically deformable, because it consists of an elastically deformable material, eg rubber. The radial seal may in particular be a sealing ring. For example, the radial seal, in particular the sealing ring, in Cross-section perpendicular to the insertion direction have a rectangular, a square or a circular shape, which substantially corresponds to the cross-sectional shape of the insertion of the connector housing and usually also the cross-sectional shape of the entire connector. A circular shape of the Radiaidichtung, in particular of the sealing ring, thus makes sense if it is the connector to a circular connector. On the other hand, if the connector housing has a rectangular cross section, the radial seal, in particular the sealing ring, should also have a rectangular cross section. The inner contour of the radial seal, in particular of the sealing ring, can advantageously correspond to the outer contour of the insertion area. Then, the inner circumference of the radial seal advantageously also corresponds to the outer circumference of the insertion area, so that it can easily be pushed over the insertion area.

If the connector is a circular connector, then its Haupfbereich may have a larger diameter than its insertion area. The outer diameter of the radial seal, in particular of the sealing ring is then less than or equal to the outer diameter of the collar in the unmated condition. Conversely, the outer diameter of the collar is then at least as large as the outer diameter of the Radiaidichtung. The inner diameter of the relaxed Radiaidichtung advantageously correspond to the outer diameter of the insertion, so that they can slide with little or no friction over the insertion.

Of course, the inner circumference, and with a circular connector, the inner diameter of the mating connector housing is at least as large as the outer circumference, and possibly also the outer diameter of the collar, because eventually the collar is in full constantly plugged state enclosed by mating connector housing. In particular, the inner circumference of the mating connector housing corresponds to the outer circumference of the collar. As a result, a mating connector housing can be pushed over the connector largely free of friction, for example over a first path section, or at least only with minimum friction. Conversely, within the first path section, the connector can be inserted into the mating connector housing without the mating connector housing coming into contact with the radial seal. Only during the last part of the insertion process, namely in a second path section, is the radial seal in mechanical contact with the mating connector housing. For this purpose, the radial seal is at least partially moved relative to the connector, ie, depending on the embodiment, the radial seal can be pushed onto the ramp area and / or pushed against the collar or against the right-angled edge of the main area and thereby compressed. In the second case, therefore, only a part of the radial seal is moved, that is, it is partially shifted, so that the Radiaidichtung bulges and increases its outer radius. In any case, the radial seal is increasingly stressed during the insertion process, deforms and thereby presses at the end of the insertion from the inside against a frame of the mating connector housing to seal the connector and the mating connector housing at the end of the insertion, namely in the second path section against each other. In this way, the radial seal undergoes only the lowest possible abrasion during the plugging operation, because it is only in the said second path section with the mating connector housing in mechanical effect, or the contact pressure continuously increases over the entire Einsfeckvorgang. The second path section is advantageously shorter than the sum of the first and second path sections. Preferably, the second path portion is also shorter than the first path portion. However, it is also an advantageous embodiment conceivable in which the radial seal is indeed in mechanical contact with the mating connector housing over the entire insertion process, but this initially with only a small contact pressure that the abrasion of the radial seal, compare with the prior art, at least over a first range is comparatively low. This has the advantage that the contact pressure of the radial seal against the mating connector housing increases continuously via the insertion process. Thus, the ratio between abrasion and the final contact pressure, which requires the plug in the plugged state, even in this embodiment is still much cheaper than it is known in the art, given in the prior art over the entire Wegiänge the same high contact pressure must be that is necessary in the final mated condition to the required seal.

Advantageous embodiments of the invention are specified in the subclaims.

In a preferred embodiment, as already described, the main area is connected to the insertion area via the funnel-shaped ramp area. In the ramp area, the outer circumference and, in the case of a circular connector, the diameter of the connector housing thus increases continuously from the lead-in area to the main area.

The seal between the connector and the mating connector housing then comes about that the radial seal is at least partially pushed onto the ramp area, whereby their outer circumference increases you will put it under tension. This has the advantage that the radial direction of the seal is only at the end of the plug-in operation, that is, when the piercing connector is located in the second path section opposite the mating connector housing, with the opposite direction. Plug housing is in mechanical contact and accordingly only in this second path section at all an abrasion of the radial seal is possible.

In other words, the radial seal is pressed against the mating connector housing from the inside only at the end of the insertion process. A friction of the mating connector on the radial seal thus occurs only at the end of the insertion process within the second path section. Thus, the abrasion is much lower than in the prior art corresponding arrangements in which the friction over the entire path length, in which the mating connector housing pushes over the radial seal, that is, over the sum of the first and the second path section takes place.

In addition, in the second path portion of the contact pressure between the Radiaidichtung and the frame of the mating connector steadily increases during the Einsfeckvorgangs so that it reaches only in the final genü tig inserted state, for example, at the moment of locking between connectors and mating connector, the amount required for the required seal. Thus, the abrasion is lower in the second Wegabschnitf, as it is known in the art.

In another embodiment, the main area of the connector connects directly to the insertion area, ie the connector has no ramp area, in this case results between the main area and the insertion a right-angled edge. When inserting the connector into the mating connector housing, the radial seal is first at least partially displaced in the direction of the main area, abuts against the right-angled edge of the main area and is then compressed in the insertion direction. As a result, the radial seal is placed under tension and bulges in such a way that its outer diameter moves in the direction of the frame of the mating connector housing and comes into contact with this in the second path section.

Furthermore, embodiments are also conceivable in which the radial seal is held only by the collar through the edge of the holding area. The outer diameter of the main area can then coincide with the outer diameter of the insertion area.

Thus, even in this embodiment, the mechanical contact of the radial seal with the mating connector housing only in the second path section is present and the abrasion is significantly lower than in arrangements in which the friction over the entire path length, in which pushes the mating connector housing on the radial seal, ie over the sum of the first and the second path section, takes place. Furthermore, in this embodiment also applies that the contact pressure in the second path section increases continuously, and the abrasion is correspondingly low.

Corresponds to the outer circumference of the radial seal the outer circumference of the collar, so for example in the case of a circular connector of the outer diameter of the radial seal the outer diameter of the collar, then the second path section begins with a deformation of the radial seal. This can be done in particular when the radial seal on the one hand with the collar and on the other hand either with the mating connector housing or with another component, for example with a sliding element explained below in mechanical contact and is compressed between these two components and thereby deformed. In an advantageous embodiment, the connector thus has the siding element. This is particularly advantageous in connection with a Pusb Puii locking and unlocking, because in this case the sealing element can not be located directly on the plug-side end of the connector, but always at a predetermined distance thereto.

The Siidingeiement consists of a hard material, such as a thermoset or a thermoplastic. The radial seal is thus more elastic than the siding element.

The Siidingeiement has in cross section a shape which substantially corresponds to the shape of the Radiaidichtung, in particular the sealing ring, and has in a preferred embodiment perpendicular thereto a length corresponding to the difference between the length of the insertion and the length of the Radiaidichtung in the relaxed state.

The Siidingeiement is intended to at least partially move the radial seal along the connector and thereby deform the radial seal in cooperation with the connector housing, in particular mil the ramp area and / or the collar.

This has the advantage that the radial seal can not be positioned at the plug-in end of the plug-in connector, but instead at a certain distance from the plug-side end, in particular at the other end of the lead-in area, and nevertheless in the abovementioned manner at the end of the plug-in end Plugging is deformed for the purpose of sealing.

In this case, it is advantageously ensured that the radial seal is at least partially displaced and deformed by the siding element along the insertion region and that the siding element becomes to the Radia! Dichiung thereby always in a designated position, ie regardless of whether the connector and the mating connector housing are optimally positioned in their axial alignment to each other. This advantageously ensures that even with a not quite optimal axial alignment of the connector when plugged into the mating connector housing, the required sealing function is still met.

Alierdings the mating connector housing in an alternative embodiment may also have an additional frame member which is integrally formed on the mating connector housing and which is able to move the sealing ring during the insertion process and to deform in cooperation with the connector housing. Such a device has the advantage that it can be assembled with little effort, because then the Siidingeiement is functionally replaced by this frame member, wherein the frame member is made integral with the mating connector housing.

As already mentioned, the radial seal may, if it is shorter than the insertion region, be arranged at a predetermined distance from the plug-side end of the connector. In this case, the radial seal is preferably arranged on the insertion area and in the vicinity of the main area. In particular, the radial direction of the radial direction at the end of the insertion region is located, which at the end of the insertion, which, depending on the design, adjacent to the main area or to the ramp area of the Sfeckverbindergehäuses. However, the radial seal can also be arranged at any other point of the insertion, because it is then automatically moved in the insertion process, for example by Siidingeiement along the insertion in the direction of the collar. In a further preferred embodiment, the mating connector housing has on the inner surface of its plug-in opening one or more stop elements as a means for stopping the sliding element. Such stop elements may be a continuous or interrupted circumferential web formed on the inner surface of the plug-in opening. Alternatively, however, a plurality of pins or webs running parallel to one another in the plug-in direction can be formed as stop elements directed inwards against the inner surface of the plug-in opening, which, according to the viewpoint, corresponds to the interrupted circumferential web.

When inserting the connector into the mating connector housing then the sliding element abuts against the stop element or against the plurality of stop elements. Upon further insertion of the connector into the mating connector housing, the sliding element thereby shifts relative to the connector along the insertion area in the direction of the collar and the main area and presses against the radial seal. According to the embodiment of the connector housing, the Radiaidichtung is thereby ultimately either pushed onto the ramp area and thereby increases its outer circumference or the radial seal is compressed between the sliding element and the rectangular edge of the holding portion and thereby deformed such that its outer circumference is also increased. Even if the Radiaidichtung, as in the first case, is pushed onto the ramp area, it can also be pressed against the adjacent to the ramp area collar. This can amplify both effects, ie the outer circumference of the radial seal increases on the one hand by pushing it onto the ramp area and also by the further deformation that occurs when the Radiaidichtung is further pressed against the collar. In any case, the radial seal is pressed in the second path portion from the inside against the mating connector housing, thus sealing the system of male and mating connector housing. In the first path section, however, there may still be no mechanical contact between the radial seal and the mating connector housing, and thus there is no abrasion in this first path section. This is a difference from the prior art and thus means a reduction in the abrasion of the radial seal.

It is also conceivable embodiment, in which the radial seal is indeed in the first path section with the mating connector housing in mechanical contact, but with only a small contact pressure that the abrasion of the radial seal compared with the prior art, at least in this path section comparatively is low. This has the advantage that the contact pressure of the radial seal against the mating connector housing increases continuously via the insertion process. Thus, the ratio between abrasion and the final contact pressure, the plug is required in the plugged state, much cheaper than in the prior art, in which the same high contact pressure must be given over the entire path length.

In a further embodiment, the outer circumference of the main region can also coincide with the outer diameter of the insertion region. In a further embodiment, the outer circumference of the main area may even be smaller than the outer circumference of the insertion area. Ausführyngsbeispief

An embodiment of the invention is illustrated in the drawings and will be explained in more detail below. Show it:

1 a shows a plug connector in the assembled state in a 3-D representation;

Figure 1 b shows the connector in an Expionsionsteilsteilung.

Fig. 2a, b a connector housing in a first embodiment in a side view and in a plan view;

Fig. 3a a Südingelement;

Fig. 3b a Radiaidichtung;

Fig. 4a the connector without Entriegeiungseiement in a 3 ~ D

 Presentation;

Fig. 4b the connector without Entriegeiungseiement in one

 Side view;

Fig. 4c the connector without Entriegeiungseiement in one

 Top view;

Fig. 5 a, b, c, the connector housing with Südingelement and

 a radial seal in the sealing process;

Fig. 5 d, e, f the connector housing without Südingelement but with a Radiaidichtung in the sealing process; Fig. 6 a, b a mating connector housing in a font and oblique view;

Fig. 7 a the connector with the mating connector housing

 in the assembled state in a 3-D representation;

Fig. 7 b, the connector with the mating connector housing

 in an exposition representation;

Fig. 8 a, b, c the connector with the mating connector housing in different phases of the mating;

Fig. 8d is an enlargement of Fig. 8b;

9 a, b a connector housing in a second embodiment in a side view and in a plan view;

Fig. 9 c, d, the connector housing in the first embodiment in a side view and in a plan view as a comparative representation;

10 a, b, c, the connector in the second embodiment with the mating connector housing in different phases of the mating;

Fig. 10 d is an enlargement of Fig. 10 c.

The figures contain partially simplified, schematic representations. In part, identical reference numerals are used for the same but possibly not identical elements. Different views of the same elements could be scaled differently.

1 a and FIG. 1 b show a connector 1 in the assembled put condition and in an exploded view. The connector 1 has a connector housing 1 1 in a first embodiment and an unlocking 12. Furthermore, the connector has a sliding element 13 and a Radiaidichtung 14, this connector housing 1 1 has an insertion portion 1 10, a funnel-shaped ramp portion 1 1 1 and a main area 1 12th , Wherein the main area 1 12 has adjacent to the ramp area 1 1 1 a collar 1 13. Furthermore, the connector housing 1 1 has on both sides two Verriege- ing arms 1 15, at their free-standing ends not designated latching hooks are formed.

Fig. 2a and 2b show the connector housing 1 1 in a side view and in a plan view, the first embodiment of the connector housing 1 1 is characterized by the ramp area 1 1 1, the funnel shape is particularly well seen in these two representations.

FIGS. 3a and 3b show the sliding element 13 and the associated radial seal. The radial seal 14 is a square section seal ring having three lips 141. The sliding element 13 is made of a hard material, such as a thermoset or a thermoplastic, and thus is less elastic than the radial seal 14, which consists of an elastic material, for example rubber.

Both the sliding element 13 and the radial seal 14 each have a passage opening with which they can be used in the assembled state, such as in the assembled state. in Fig. 4 a, Fig. 4 b and Fig. 4 c shown in different views, slidably on the insertion portion 1 10 of the connector housing 1 1 are inserted.

5 a, Fig. 5 b and Fig. 5 c show the sealing process on the separate connector 1 in three phases. Thereby the sliding element becomes 13 relative to the connector housing 1 1 along the insertion region 1 10 against the insertion direction. Accordingly, the Radi- aidichtung 14 is pushed onto the funnel-shaped ramp area 1 1 1. It is easily recognizable and comprehensible that its outer circumference is thereby increased and the Radiaidichtung, as shown in Fig. 5c, the collar 1 13 at the latest then surmounted as soon as it comes into contact with the collar 1 13.

FIGS. 6 a and 6 b show a mating connector housing 2 in a font and in an oblique view. The mating connector housing has a flange 21, e.g. for attachment to a housing. Furthermore, the housing has a non-designated, continuous plug-in opening.

To the inner surface of this insertion opening one or more Stoppeiemente 22 are formed as a means for stopping the sliding element 13 inwardly directed. These stop elements 22 are designed in the form of webs running parallel to each other in the plugging direction.

Furthermore, the mating connector housing has a running in the direction of insertion frame 23 with a latching recess 235 for latching with the latching hooks of Verriegeiungsarme 1 15th

FIGS. 7 a and 7 b show, analogously to FIGS. 1 and 2, the connector with the mating connector housing 2 both in the assembled state in a 3-D representation and in an exposition display. From this representation, it is already apparent how the connector 1 cooperates with the mating connector housing 2.

This is illustrated by the illustrations in FIGS. 8a, 8b and 8c. These show the connector 1 with the mating connector housing 2 in three different phases of mating. In Fig. 8a, this arrangement is to be seen in a still unplugged condition, wherein the Stopeiemente 22 of the mating connector housing 2, the Sli- dingelement 13 of the connector 1 already touch by their stop 221 abut against the rotating Siidingeiement 13. The sliding element 13 closes in this first phase still with the connector 1 at its plug-side end.

In Fig. 8b, a second phase is shown, in which the connector 1 is already inserted with its radial seal 14 around a first path portion in the mating connector housing 2. The radial seal 14 is partially already pushed onto the funnel-shaped ramp portion 1 1 1 and deforms accordingly, so that its outer radius increases and the Radiaidichtung 14 begins to contact the mating connector housing 2 at the frame 23 in contact.

In Fig. 8c, the connector 1 is completely inserted into the mating connector housing 2. The locking arms 1 15 of the connector 1 engage in the recess 235 of the frame 23 of the mating connector 2 with their latching hooks on the stop 1 16, wherein the recess 235 is not designated in this illustration for reasons of clarity. The radial seal 14 is completely pushed in this third phase on the ramp portion 1 1 1, is in mechanical contact with the collar 1 13 and is pressed with the pressure required for sealing from the inside against the frame 23 of the mating connector housing 2.

In this illustration, the overlap of the hatched areas of the radial seal 14 and the mating connector housing 2 on the frame 23 is a measure of the actual contact pressure.

It is readily apparent that the Radiaidichtung 14 at an even deeper insertion of the connector 1 in the mating connector housing 2 in addition to the deformation that it has already experienced in the third phase by pushing it onto the ramp area 1 1 1, also an additional deformation, namely a compression between the sliding member 13 and the collar 1 13, would learn. As a result, their outer radius would increase even further and thus increase the contact pressure against the mating connector housing 2 again. Such an arrangement can be formed in that, for example, the collar 1 13 and the ramp 1 1 1 are arranged displaced in the direction of the insertion area 1 10 in comparison to the preceding illustrations in accordance with the required contact pressure.

For a better understanding, the second phase of the insertion process is again shown in an enlarged section of the corresponding FIG. 8b in FIG. 8d. In this second phase, the connector 1 is already inserted with its Radiaidichtung 14 to a first path portion in the mating connector housing 2. It can be clearly seen that the radial seal 14 in this second phase is already partially pushed onto the ramp region 1 1 1 and just comes into contact with the frame 23 of the mating connector 2.

In Fig. 9 a and Fig. 9 b, a connector housing 1 1 ^{'is shown} in a second embodiment and is thereby contrasted with the connector housing 1 1 shown in FIGS. 9 c and 9 d in its first embodiment. In its first embodiment, the connector housing 1 1, as already described, a ramp portion 1 1 1, which is missing in the second embodiment of the connector housing.

The second embodiment of the connector 1 ^' is characterized accordingly by the fact that it has a connector housing 1 1 ^' in the second embodiment.

The interaction of this second embodiment of the connector 1 ^' with the Gegensieckergehäuse 2 is illustrated by the representations in Figs. 10 a, 10 b and Fig. 10 c. In this case, this connector 1 ^{'is shown} with the mating connector housing 2 in the three different phases of the mating.

In Fig. 10 a, this arrangement can be seen in a still unplugged condition, the stop elements 22 of the mating connector housing the sliding element 13 of the connector 1 ^' already touch by their stop 221 abut against the rotating sliding element 13. The sliding element 13 closes in this first phase still with the connector 1 at its plug-side end.

In Fig. 10 b, a second phase is shown, in which the connector 1 ^' with its radial seal 14 is already partially inserted into the mating connector housing 2. The sliding element 13 and the Radiaidichtung 14 located behind it are so far shifted relative to the preceding illustration along the insertion portion 1 10 against the insertion direction that the radial seal 14 with the collar 1 13 comes into contact, the outer circumference of the radial seal 14 is equal to that of the collar. 1 13, then corresponds to the displacement of the connector 1 ^' in this second phase of the first path, because the Radiaidichtung 14 begins to deform from the moment in which it is simultaneously in contact with the collar 1 13 and with the sliding member 13 in contact.

In an alternative embodiment, the radial seal 1 14 in the unmated condition could also already be arranged on the collar 1 13 or at any point between the collar 1 13 and the sliding element 14. In any case, the Radiaidichtung 14 begins to deform only from the moment in which it is geiichzeitig in contact with the sliding element 13 and the collar 1 13.

In Fig. 10c, the connector 1 ^'is completely in the mating connector Housing 2 inserted. The locking arms 1 15 of the connector 1 ^' engage in the Rastausnehrnung 235 of the frame 23 of the mating connector 2 with their locking hooks on the stop 1 16, wherein the Rastausnehrnung 235 is not designated in this illustration for reasons of clarity. The Radiaidichtung 14 is compressed in this third phase between the sliding element 13 and the collar 1 13, bulges and thereby increases its outer radius and presses so from the inside against the connector housing 23rd

In all of these Querschnisdarsteiiungen the overlap of the hatched areas of Radiaidichtung 14 and the frame 23 of the mating connector 2 is a measure of the actual contact pressure.

For a better understanding, the third phase of the insertion process is again shown in an enlarged section of the corresponding FIG. 10 c in FIG. 10 d. In this third phase, the connector 1 ^'is finally inserted into the mating connector housing 2. It can be clearly seen that the locking arm 1 15 in the Rastausnehrnung 235 of the frame 23 of the mating connector housing 2 on the stop 1 18 locked. The radial seal 14 is compressed between the sliding element 13 and the collar 1 13 and bulges. As a result, it pushes from the inside against the frame 23 with a final contact pressure.

Connector with low-wear sealing function

LIST OF REFERENCE NUMBERS

11 ^' connector

11,11 ^' connector housing

 110 insertion area

 111 ramp area

 112 main area

 113 collar

 115 locking arms

 116 Stop the locking arm

 12 unlocking element

 125 unlocking arms

 13 siding element

 14 radial seal

 141 Lips of Radiaidichtung

2 mating connector housing

 21 flange

 22 stop elements

 221 stop of the stop elements

 23 frames

 235 recess

Claims

 claims

Connector having a connector housing (11,11 ^') and a radial seal (14), wherein the radial seal (14) has a passage opening with which it on the connector housing ^(11,11' is installed), and wherein the connector housing (11,11 ^' ) has a circumferential or interrupted collar (113), characterized in that the radial seal (14) in Untocked state of the connector (1,1 ^' ) has only a smaller or equal outer circumference than the collar (113).

Connector according to claim 1, characterized in that the connector housing (11,11 ^' ) has a plug-side end and then an insertion region (110).

Connector according to claim 2, characterized in that the inner periphery of the relaxed Radiaidichtung (14) corresponds to the outer periphery of the insertion region (110).

Connector according to one of claims 2 to 3, characterized in that the insertion region (110) via a ramp region (111) with the collar (113) is connected.

Connector according to one of claims 2 to 3, characterized in that the insertion region (110) directly to the collar (113) connects.

Connector according to one of claims 2 to 5, characterized in that the Radiaidichtung (14) on the insertion region (110) is arranged and is shorter than the insertion region (110) and the insertion region (110) is thereby only partially covered by the radial seal (14).

Connector according to claim 6, characterized in that the Radiaidichtung (14) in the infected state at the end remote from the plug-side end of the insertion region (1 10) is arranged.

Connector according to claim 7, characterized in that the connector (1, 1 ^' ) has a sliding element (13) arranged between the radial seal (14) and the plug-side end of the connector (1, 1 ^' ) and displaceable against the insertion direction the insertion area (1 10) is held.

Connector according to claim 8, characterized in that the Radiaidichtung (14) is more elastic than the sliding element (13).

Connector according to claim 9, characterized in that the sliding element (13) directly adjoins the Radiaidichtung (14) and thereby is able by its own displacement, the Radiaidichtung (14) also at least partially to move and thereby in cooperation with the connector housing (1 1, 1 1 ^' ) to deform.

Device consisting of the connector (1, 1 ^' ) according to one of claims 1 to 10, and a mating connector housing (2) with a plug-in opening, characterized in that the device (1, 1 ^' ) has means for connecting the radial seal (14 ) of the connector (1, 1 ^' ) relative to the connector (1, 1 ^' ) at the end of the insertion at least partially against its insertion direction to move and thereby in cooperation with the connector housing (1 1, 1 1 ^' ) to deform. Apparatus according to claim 1 1, characterized in that said means comprise the sliding element (13) of the connector (1, 1 ^' ) arranged between the radial seal (14) and the plug-side end of the connector (1, 1 ^' ) is.

Device according to one of claims 1 1 to 12, characterized in that said means comprise one or more Stoppeiemente (22) of the mating connector housing (2).

Apparatus according to claim 13, characterized in that the stop elements (22) in the form of a continuous or interrupted circumferential web or individual pins in an inner surface of the plug opening of the mating connector housing (2) are integrally formed.

Device according to one of claims 10 to 14, characterized in that the collar (1 13) of the connector (1, 1 ^' ) in the fully constantly plugged state of the mating connector housing (2) is to schlössen.

Device according to one of claims 1 1 to 15, characterized in that the radial seal (14) in the fully mated state in direct mechanical contact with the mating connector housing (2).

Device according to one of claims 1 1 to 16, characterized in that the radial seal (14) in the fully mated state in direct mechanical contact with the collar (1 13)

18. Method for tightly plugging a connector (1) with a Gegensieckergehäuse (2), characterized in that the contact pressure between a radial seal (14) of the connector (1) and the mating connector housing (2), at least during the last part of the plugging operation, namely via a second path portion, steadily increased ,

A method according to claim 18, characterized in that the connector (1, 1 ^' ) with its Radiaidichtung (14) is first introduced over a first path portion in the Gegensieckergehäuse (2), wherein the outer diameter of the radial seal (14) by the deformation thereof first enlarged, and that the connector (1, 1 ^' ) is then finally introduced via the second path portion in the mating connector housing (2), wherein the radial seal (14) by their progressive deformation only in the second path section with the Gegensieckergehäuse

(2) comes into mechanical contact to thereby seal the connector (1, 1 ^' ) against the mating connector housing (2).

A method according to claim 19, characterized in that the first Wegabschnitf is at least as large as the second path section.

Method according to one of claims 19 to 20, characterized in that the deformation of the Radiaidichtung (14) by displacing a sliding element (13) along the insertion region (1 10) is effected against the insertion direction.

A method according to claim 21, characterized in that the sliding element (13) of the connector (1, 1 ^' ) is supported during the insertion process of stop elements (22) of the mating connector housing (2), whereby the sliding element (13) moves relative to the connector (1, 1 ^' ) along the insertion (1 10) opposite the plug-in direction shifts.

23. The method according to any one of claims 21 to 22, characterized in that the Siidingeiement (13) with the connector housing (1 1, 1 1 ^' ) cooperates to deform the radial seal (14).

24. The method according to claim 23, characterized in that the siding element (13) pushes the radial seal (14) to deform it onto a funnel-shaped ramp region (1 1 1) of the connector housing (1).

25. The method according to any one of claims 23 to 24, characterized in that the Siidingeiement (13) presses the radial seal (14) to its deformation against a collar (1 13).