EP0757409A1 - Electrical connector - Google Patents

Abstract

The connector includes a pin-strip housing containing pin contacts (2). A multi-chamber socket housing with socket contacts connectable to electric lines (42) is inserted on the housing and locked by means of a snap connection. In order to provide an extremely compact structural design for the connector and effective securing of the socket contact inside the socket housing, a cover cap (20) is pulled on the plug contact side of the socket housing (30). It is pushed or pulled back on to the socket housing (30) orthogonally to the plug-in direction.

Description

The invention relates to a connector with a pin connector-containing pin connector housing, to which a multi-chamber socket housing with socket contacts connected to electrical lines can be plugged and locked by means of a snap connection, so that the pin contacts are electrically connected to the socket contacts.

Such a connector is described for example in EP 0 592 102 A2. The entire connector essentially consists of a pin header housing with an annular wall within which a multiplicity of pin contacts is arranged. These pin contacts are connected to a corresponding plug, in which a multiplicity of socket contacts, for example so-called spring contacts, are arranged. The socket contacts are housed within their own socket housing, the socket housing being constructed in several parts. The socket housing has a rear cover part, an intermediate part and a front part, a sealing plate being fitted between the rear part and the front part for sealing purposes. The entire socket housing is assembled by axially plugging the individual components together. The rear part, the intermediate part and the front part are held together by means of snap connections.

The problem with this known solution is the relatively complicated structure and the axial stacking of the individual components of the socket housing, which makes snap connections essential in the direction of insertion indispensable. Furthermore, it is not apparent from this document how the individual socket contacts are locked in the chambers of the socket housing in order to prevent them from being pulled out to be effectively secured from the socket housing.

The present invention has for its object to provide a lockable connector, which is characterized by an extremely compact structure, enables effective securing of the socket contacts within the socket housing and can be carried out waterproof only by additional insertion of sealing elements if necessary without structural changes.

This object is achieved by a connector of the type mentioned by additionally providing that the plug contact side of the socket housing is fitted with a cover cap with openings in the contact area, that the cover cap can be pushed onto the socket housing orthogonally to the direction of insertion with latching elements for securing the socket contacts within of the socket housing, that the pin header housing has an annular wall which completely engages over the covering cap and is located on the end face in a circumferential recess of the socket housing, and that the pin header housing has at least one snap hook on its outside, which engages in an opening of the socket housing.

Such a connector is characterized by a relatively small design, can be securely locked thanks to the snap connections provided and, thanks to the cover cap pushed orthogonally to the plug-in direction onto the socket housing with the latching elements provided there, is secured against unintentional pulling out of the socket contacts together with the connected lines from the socket housing. An unintentional pulling out of the lines or loosening of the plug connection is not possible or only possible with extreme exertion of force, so that the connector according to the invention is ideally suited for use as an electrical coupling in automotive engineering. Finally, the plug connector according to the invention, without having to be structurally changed, can be made watertight and dustproof by adding sealing elements, in particular a sealing plate and two sealing rings.

In a further development of the invention it is provided that the socket housing has on approximately one of its broad sides approximately in the middle a latching lever having an opening, which engages over the wall of the pin header housing so that its snap hook snaps into the opening. The snap connection and thereby achieved locking of the socket housing with the pin header housing and thus with the plug part and socket part of the connector can be solved by pressing with a predetermined force on the opposite end of the latching lever, whereby the latching lever slightly over the snap hook of the Socket housing is lifted and so that the pin header housing or the socket housing can be removed. The lever stroke necessary for this is expediently dimensioned such that it is not possible for the hinge, which is preferably made of plastic, to be overstretched, via which the latching lever is fastened to the socket housing. Preferably, a rib is attached to each side of the locking lever, which prevents the cables from possibly becoming jammed under the locking lever.

Another development of the invention provides that the locking lever engages about half the length of the annular wall of the pin header housing. This provides a relatively long locking lever that only requires a small lever stroke at the end opposite the snap connection in order to release the snap connection.

According to another development of the invention, the socket housing can be covered with a cover cap on its side facing away from the plug side, the cover cap being snapped onto the socket housing by means of a snap connection is. The cover cap and the socket housing are expediently matched to one another and provided with openings and latching hooks in such a way that the cover cap can be snapped onto the socket housing in a first position and in a second position rotated by 180 degrees. By simply turning the cover cap, which has an opening for cable entry on one side, the cable outlet of the connector can be realized on the left or right side. In this way, a high degree of flexibility of the connector according to the invention is achieved. Furthermore, such a connector is easy to manufacture because, regardless of whether the cable outlet is to be arranged to the left or right of the connector, only a single injection mold is required for the socket housing or the associated cover cap.

A holding plate with openings can be inserted into the socket housing on the side facing away from the plug-in side, through which the electrical lines for the socket contacts are inserted. This holding plate serves as a guide for the lines and keeps them at a distance from each other thanks to the openings provided.

The cover cap of the connector preferably has a T-shaped rib which engages between resilient inner walls of the socket housing, the T-shaped end piece of the rib engaging behind edges of the socket contact. The T-shaped end piece of the rib forms an independent secondary fuse for the socket contacts inserted in the socket housing. The T-shaped rib of the cover cap secures the socket contacts of two adjacent rows of chambers within the socket housing.

The socket housing is preferably provided with three rows of adjacent chambers, the socket contacts being arranged rotated by 180 degrees to one another in the middle row and an outer row. In the remaining one third row, short-circuit bridges for short-circuiting the adjacent socket contacts can be arranged in the middle row. The aforementioned T-shaped rib of the cover cap secures the socket contacts of the middle chamber and the socket contacts of the adjacent outer chamber.

Another development of the invention provides that the pin header housing is provided on its end face facing away from the plug side with projections of different lengths, on which the pin contacts are at least partially in contact and at the end of the projections are each angled by 90 degrees in the same direction. This measure allows simple installation of the plug pins in the pin header housing. The pin contacts rest on the protrusions so that they are effectively protected from damage.

The connector presented so far can be made dust and waterproof in a simple manner by arranging a plurality of sealing elements within the connector.

The socket housing is expediently provided with a sealing plate through which the lines for the socket contacts are guided. Furthermore, a sealing ring can be arranged in the end extension of the walls of the cover cap, which is arranged between the annular wall of the pin header housing and a circumferential wall of the socket housing. The sealing plate fulfills the function that both the lines to which the socket contacts are connected and the individual chambers of the socket housing are sealed.

Furthermore, the pin contacts are expediently guided in a watertight manner by the pin header housing, for example by pressing the pin contacts into the pin header housing or by overmolding after assembly.

In order to be able to mount the pin header housing in a watertight manner, the outer wall of the pin header housing is expediently provided with an annular groove in which a further sealing ring is arranged.

Figur 1

Den Steckverbinder nach der Erfindung in auseinandergebautem Zustand in Draufsicht auf die einzelnen Komponenten,

Figur 2

das Buchsenteil des Steckverbinders nach der Erfindung mit Buchsengehäuse, auf das Buchsengehäuse aufgeschobene Abdeckkappe sowie aufgeschnappter Deckelplatte,

Figur 3

den in Figur 2 dargestellten Buchsenteil entlang der Schnittlinie A-A von Figur 2,

Figur 4

das Stiftleistengehäuse in Schnittdarstellung mit eingesetzten Stiftkontakten,

Figur 5

den kompletten Steckverbinder nach den Figuren 1 bis 4 in zusammengestecktem Zustand in Schnittdarstellung und

Figur 6

einen weiteren Steckverbinder ähnlich zur Darstellung von Figur 1.

The invention is explained in detail below on the basis of a specific exemplary embodiment in connection with several figures. Show it:

Figure 1

The connector according to the invention in a disassembled state in plan view of the individual components,

Figure 2

the socket part of the connector according to the invention with socket housing, cover cap pushed onto the socket housing and snap-on cover plate,

Figure 3

the socket part shown in Figure 2 along the section line AA of Figure 2,

Figure 4

the pin header housing in a sectional view with inserted pin contacts,

Figure 5

the complete connector of Figures 1 to 4 in the assembled state in a sectional view and

Figure 6

another connector similar to the illustration of Figure 1.

In the following figures, unless otherwise stated, the same reference symbols designate the same parts with the same meaning.

In Figure 1, an embodiment of a connector according to the invention is shown in plan view, the individual components of the connector are shown disassembled one above the other. The plug connector has a pin header housing 1 which acts as a plug part and which contains an annular wall, in the interior of which a large number of pin contacts which cannot be seen in FIG. 1 are arranged. On its broad side facing the viewer in FIG. 1, the wall of the pin header housing 1 is provided with a snap hook 10 to be explained. This snap hook 10 is located approximately in the middle of half the width of the pin header housing 1. From the end of the pin header housing 1 facing away from the plug-in side, a multiplicity of pin contacts 2 protrude, each arranged parallel to one another and at their lower end in the same direction by 90 degrees into the plane of the drawing are angled into it. The ends of these pin contacts 2 protrude through corresponding openings 13, preferably a guide 5 made of insulating material, for example ceramic or ferrite material. Although this guide is not absolutely necessary for the mechanical construction of the plug connector, it is advantageous for its electromagnetic shielding. The pin contacts 2 can be soldered to the pin contact ends, which cannot be seen in FIG. 1, for example on a circuit board of an electrical circuit arrangement. Furthermore, the pin header housing 1 is provided with an annular groove in which a sealing ring 12 is arranged.

The socket part of the connector shown in Figure 1 consists essentially of a socket housing 30, a cover cap 20 is slipped over on its side facing the plug side and a cover cap 70 which is snapped onto the socket housing 30 on the opposite side. Arranged between the cover cap 70 and the socket housing 30 is a holding plate 62, which is shown in more detail in the following figures and which has openings 63 for inserting electrical lines. A sealing plate 60 preferably bears on the broad side of the holding plate 62 facing the socket housing 30 in order to make the connector watertight.

In order to be able to insert the socket part 70 of the connector according to the invention sealingly into the pin header housing 1, a sealing ring 50 is provided, which is pushed over the lower part of the socket housing 30 facing the plug side, namely to the extent that the lower part of the socket housing 30 emerges from the sealing ring 50. Subsequently, the cover cap 20 is pushed orthogonally to the direction of insertion of the connector onto this protruding lower part of the socket housing 30.

On its broad side facing the viewer in FIG. 1, the socket housing 30 has, approximately in the center, a latching lever 39 which extends along the plug-in direction of the connector and is provided with an opening 36 approximately in the center on its end facing the plug-in side. The locking lever 39 is about a quarter of the entire width of the socket housing 30 wide and connected to a circumferential collar 34 of the socket housing 30 via two integrally molded webs 47. The locking lever 39 can be pivoted about these webs 47 by pressing on the end of the locking lever 39 facing away from the plug side. As a result, the locking lever 39 is raised with its end facing the plug side, so that the opening 36 is lifted from the snap hook 10 of the pin header housing 1 when the plug connector is plugged together.

In addition, a further latching hook 37 is arranged in the part of the socket housing 30 facing away from the plug-in side, which engages with a corresponding opening 71 of the cover cap 70 as a snap connection. On the broad side of the socket housing 30 facing away from FIG. 1 there is also a Snap hook 37 is arranged, which cooperates with a corresponding second opening in the cap 70 as a snap connection, so that the connector according to the invention can be equipped on the left or right side with a cable outlet 80.

As FIG. 1 also shows, the cover cap 70 is provided in the center with a U-shaped cutout 72, so that the cover cap 70 can be snapped onto the socket housing 30 without covering the locking lever 39 of the socket housing 30.

FIG. 2 shows the assembled socket part of the connector presented in FIG. 1. The snap-in of the latching hook 37 into the associated opening 71 of the cover cap 70 can be clearly seen. In addition, it is clear that the cover cap 70 does not cover the locking hook 39 thanks to its U-shaped cutout 72. The cover cap 20 is shown pushed onto the socket housing 30 by previously pushing on the sealing ring 50 shown in FIG. 1 onto the lower part of the socket housing 30.

In the exemplary embodiment in FIG. 2, the socket part has a cable outlet 80 on its right side. This cable outlet 80 also has a cable fixation 81, through which the individual lines of the cable outlet 80 are held.

In Figure 3, the socket part shown in Figure 2 is shown in a sectional view along the section line AA of Figure 2. The already known reference symbols again stand for the same parts. As can be seen, the socket part consists of a multi-chambered socket housing 30, which in the present exemplary embodiment has three rows of chambers 31. The individual rows of the chambers 31 are arranged parallel to one another. In the chamber 31 shown at the top in FIG. 3, a socket contact 40, e.g. B. a contact spring used by a front Opening of a pin contact 2 of the pin header housing 1 can be contacted. The socket contact 40 is connected to an electrical line 42 via a contact zone 41. In the middle chamber 31 of the socket housing 30 there is a similar socket contact 40 with a contact zone 41 and a connected line 42. The two socket contacts 40 are arranged rotated to one another by 180 degrees. The socket contacts 40 have recesses 48 pointing towards one another, into which latching hooks 33 of resilient inner walls 45 of the socket housing 30 engage for primary latching. These latching hooks 33 form the primary fuse for the socket contacts 40. In the lowermost chamber 31 of the socket housing 30, a short-circuit bridge 55, known per se, is used, which, for safety reasons, short-circuits adjacent socket contacts 40 when the connector is not mounted, ie the plug part is not placed on the socket part. This short-circuiting is shown in FIG. 3, in that a bulge 56 of the short-circuit bridge 55 contacts the contact zone 41 of the middle socket contact 40. For this purpose, an intermediate wall 49 of the socket housing 30 is inserted into the between the lower contact chamber 41 and the middle chamber 41, which is provided with an opening 51 in the region of the recess 56 of the short-circuit bridge 55.

For secondary securing of the short-circuit bridge 50 and the socket contacts 40, a cover cap 20 with a cup-shaped outer contour is placed over the part of the socket housing 30 facing the plug side. This is done by pushing the cover cap 20 orthogonally to the plugging direction onto the part of the socket housing 30 shown on the right in FIG. 3. The cover cap 20 has openings 24 on its front side facing the plug side, which in the assembled state are aligned with the openings of the socket housing 30. The outside walls and the walls of the cover cap 20, which are placed over the socket housing 30, are provided with secondary hooks 23 which extend into the interior of the socket housing through openings provided there. When the cover cap 20 is pushed on, any attempt to detach the cover cap 20 from the socket housing 30 in the plugging direction is excluded. Furthermore, the cover cap 20 is provided with a T-shaped rib 21 which slides between the resilient inner walls 45 of the socket housing 30 and forms a hook 22 with its T-shaped end, which engages behind contours of the upper socket contact 40 and the lower socket contact 40 . The T-shaped rib 21 is designed with its longitudinal leg so that the resilient inner walls 45 can engage in the openings 48 of the socket contacts 40 mentioned with their latching hooks arranged at the distal end. These latching hooks 33 serve for primary latching of the socket contacts 40.

The socket contacts 40 are thus secured in the chambers 41 of the socket housing 30 in three ways. The primary securing of the socket contacts 40 is produced by the elastic swiveling back of the resilient inner walls 45 of the socket housing 30. In the case of a release test in which the force which the primary latching can withstand is determined, the corresponding test would be carried out without a cap 20.

The orthogonal pushing on of the cap 20 then mechanically checks whether all resilient inner walls 45 are pivoted back (dependent secondary securing or "backup securing") and on the other hand produces an independent secondary securing by means of the T-shaped end piece of the rib 21 of the covering cap 20.

The cover cap 20 is intentionally not designed so that it presses the resilient primary latching hooks 32 into the socket contacts 40. If a primary latching hook 32 does not spring into the recess of a socket contact 40 by itself, this is generally due to the fact that the socket contact 40 is not complete is stuck. This error should be noted, inter alia, that the cover cap 20 cannot be pushed on without the use of force.

As shown in FIG. 3, the socket housing 30 has an L-shaped collar 34 which is integrally formed on the wall 46 of the socket housing 30 and which runs around the socket housing 30. This collar 34, which is L-shaped in cross section, is arranged approximately at the level of the transition from the contact zone 41 to the lines 42, in that the wall 46 is initially followed by a wall part which projects orthogonally away from the outer wall of the socket housing 30 and then in a direction towards the plug side of the connector recessed straight part ends. This results in a U-shaped recess running around the outside of the socket housing, into which, as will be explained later, the annular wall of the pin header housing 1 engages when the plug connector is plugged together.

The inner wall section 46 opposite the collar 34 of the socket housing 30 has an L-shaped recess 53 in which the sealing ring 50 known from FIG. 1 is inserted. This sealing ring 50 lies with its inner annular surface flat on the outside against the L-shaped wall 46 of the socket housing 30. Furthermore, the sealing ring 50 also bears with its end face shown on the left in FIG. 3 on the L-shaped wall 46. On the collar 34 of the socket housing 30 facing the outer ring surface of the sealing ring 50, a bulge-shaped bulge is arranged, seen in cross section, which, as will be explained in connection with FIG. 5, bears against the pin strip housing 1 for sealing purposes. The sealing ring 50 has at its front end approximately a height which corresponds to the height of the L-shaped recess in the wall 46 of the socket housing 30. As can also be seen from FIG. 3, the sealing ring 50 on its right end face is covered by the end wall of the cover cap 20 limited. The L-shaped wall 46 of the socket housing forms, together with the end wall of the cover cap 20, a U-shaped recess into which the sealing ring 50 can be inserted and adjusted in a simple manner.

As can also be seen from FIG. 3, the socket housing 30 has, in the axial extension of the rib 21, a U-shaped wall 38, seen in cross section, which delimits the chambers 41 via the socket contacts 40.

The socket housing 30 is further provided with an annular wall 54 which, in the opposite direction to the plug direction, extends approximately further on the wall 46 of the socket housing 30 and which is provided with openings 58 in order to receive a holding plate 62. The holding plate 62 also has openings 63 in order to be able to pass the lines 42 for the socket contacts 40.

A sealing plate 60, which serves to seal the lines 42 and the chambers 41 of the socket housing 30, is arranged adjacently on the surface of the holding plate 62 facing the plug side. The sealing plate 60 consists of a suitable, flexible plastic material and preferably has several, here two, ribs on its outer circumferential surface. For reasons of assembly, the annular wall 54 in the area of the sealing plate 60 is cut out in an L-shape on the inside, so that the sealing plate 60 can sit in this recess.

On the side facing away from the plug-in side of the annular wall 54 of the socket housing 30, latching hooks 37 are integrally formed on the outside. These latching hooks 37 cooperate with openings in the cover cap 70, so that the cover cap 70 can be snapped onto the socket housing 30. The latching hooks 37 and openings 71 are designed so that the cover cap 70 can also be snapped onto the socket housing 30 when rotated by 180 degrees.

As can also be seen from FIG. 3, the socket housing is provided with the already known locking lever 39, which extends over the collar 34 of the socket housing 30 in both directions. Furthermore, the opening 37, which has also already been explained, for the latching mounting of the pin header housing 1 can be seen.

In Figure 4, the sectional view of the pin header housing 1 is shown. The pin header housing 1 has a plate-like base 13, from which cup-shaped walls 8 extend on a surface. This forms a cavity 7 which is open towards the plug side and into which the pin contacts 2 protrude with their pin contact tips 3. In addition, a plug body 9 protrudes into this plug-in space 7, which is integrally formed on the bottom 13 of the pin strip housing 1 and which serves to cancel the short-circuit connection which is produced by the short-circuit bridge (cf. FIG. 3) with the socket contacts.

On the outside of the pot-shaped wall 8, a snap hook 10 is arranged, which is provided for snap connection to the socket housing 30.

The pin contacts 2 are preferably watertight through the bottom 13 of the pin header housing 1. This can be done, for example, by pressing in the pin contacts 2 or overmolding the pin contacts 2. The bottom 13 has, on its side facing away from the plug-in space 7, three projections 11 of different lengths, the surface of which, as shown in FIG. 4, serves to guide the pin contacts 2. The pin contacts 2 lie flat on these projections 11 in order to be angled at the ends of the projections 11 by 90 degrees each in the same direction, here downward. The projections 11 are designed so long that the pin contacts angled by 90 degrees next to each other come to rest and can be guided through holes in a guide, preferably a ceramic or ferrite guide 5.

In addition, the annular groove in the pin header housing 1 can be seen in FIG. 4, in which a sealing ring 12 is inserted.

Figure 5 shows the previously presented connector in the assembled state. The pin header housing 1 is inserted into the socket housing 3 together with the pin contacts 2 contained therein. The snap hook 10 comes to rest in the opening 36 of the locking lever 9 and thus ensures a secure connection of the pin header housing 1 and the socket housing 2. This snap connection can be released in a simple manner by light pressure on the end region of the locking lever 39 provided with the reference symbol P. .

In addition, the function of the plug body 9 can be seen. The plug body 9 of the pin header housing 1 engages behind the short-circuit bridge 55 and lifts the bulge 56 there from the contact zone 41 of the socket contact 40, as a result of which the short circuit is canceled.

Furthermore, it can be clearly seen in FIG. 5 that the front part of the pot-shaped wall 8 of the pin strip housing 1 engages in the space formed by the wall 46 and the collar 34 of the socket housing 30 and the ring seal 50 at the bulge provided there in a radial direction Direction presses.

The connector according to the invention is preferably suitable for use as a connector in the automotive industry, since it is characterized by a very small design, by a secure locking and when using the sealing elements mentioned by its waterproof design. Furthermore, the connector according to the invention is through a double contact lock, namely a primary lock and a secondary lock, which work independently of each other.

For the sake of completeness, a further exemplary embodiment of a connector according to the invention is shown in FIG. The illustration largely corresponds to the illustration in FIG. 1. In contrast to the illustration in FIG. 1, the lid cap 70 now has two openings 71. The socket housing 30 is also provided with two latching hooks 37 which cooperate with the openings 71 of the cover cap 70 and which are located on each side to the left and right of the latching lever 39. Finally, this socket housing 30 is provided both on the right and on the left with a molded-on tubular extension 80 serving as a cable outlet 80, so that a construction of the connector rotated by 180 ° is possible without further ado.

Claims (13)

Plug connector with a pin connector housing (2) containing a pin connector housing (1) to which a multi-chamber socket housing (30) with socket contacts (40) connected to electrical lines (42) can be plugged on and locked by means of a snap connection, so that the pin contacts (2) with the socket contacts (40) can be electrically connected, characterized in that on the plug contact side of the socket housing (30) a cover cap (20) with openings (24) present in the contact area is put over, that the cover cap (20) is orthogonal to the plug direction on the socket housing ( 30) can be pushed on with locking elements (37, 39) for securing the socket contacts (40) within the socket housing (30) that the pin header housing (1) has an annular wall (1a) which completely engages over the cover cap (20) and on the end face a circumferential recess of the socket housing (30) and that the pin header housing (1) at least has a hook (10) on its outside, which engages in an opening (36) of the socket housing (30). Plug connector according to claim 1, characterized in that the socket housing (30) is provided approximately approximately centrally on one of its broad sides with a latching lever (39) which has an opening (36) and which engages over the wall of the pin header housing (1) in such a way that its snap hooks (10) can be snapped into the opening (36). Connector according to claim 2, characterized in that the latching lever (39) engages approximately half the length of the annular wall (1a) of the pin header housing (1). Connector according to one of claims 1 to 3, characterized in that the socket housing (30) is covered on its side facing away from the plug side with a cover cap (70), and in that the cover cap (70) by means of a snap connection (37, 41) to the socket housing (30) is snapped on. Plug connector according to one of Claims 1 to 4, characterized in that a holding plate (62) with openings (63) is fastened in the socket housing (30) on the side facing away from the plug-in side, through which the electrical lines (42) for the socket contacts ( 40) are inserted. Connector according to one of claims 1 to 5, characterized in that the cover cap (20) has a T-shaped rib (21) which engages between the springs of the inner wall (45) of the socket housing (30) and which is provided distally with latching hooks (33), Press resilient inner walls (45) of the socket housing (30) into recesses in the socket contacts (40) for primary locking, the T-shaped end piece of the rib (21) engaging behind the edges of the socket contacts (40). Plug connector according to one of Claims 1 to 6, characterized in that the multi-chamber socket housing (30) has chambers (31) lying next to one another in three rows and in the middle row and an outer row the socket contacts (40) are arranged rotated by 180 degrees to one another and short-circuit bridges (55) for short-circuiting the adjacent socket contacts (40) are arranged in the remaining third row. Connector according to one of claims 1 to 7, characterized in that the pin header housing (1) is provided on the side facing away from the plug side with protrusions (11) of different lengths on which the Pin contacts (2) lie at least partially and are angled 90 degrees in the same direction at the end of the projections (11). Connector according to one of claims 1 to 8, characterized in that the socket housing (30) is provided on the end face facing away from the plug side with a sealing plate (60) through which the lines (42) for the socket contacts (40) are guided. Connector according to one of claims 1 to 9, characterized in that a sealing ring (50) is arranged in the end extension of the walls of the cover cap (20), which is between the annular wall (1a) of the pin header housing (1) and one inside the connector circumferential wall (46) of the socket housing 30 is arranged. Connector according to one of claims 1 to 10, characterized in that the pin contacts (2) are guided watertight through the pin header housing (1). Connector according to one of claims 1 to 11, characterized in that the pin header housing (1) is provided with an annular, circumferential groove in which a sealing ring (12) is arranged. Plug connector according to one of Claims 1 to 12, characterized in that the cover cap (70) and the socket housing (30) are provided with openings (71) and latching hooks (37) which snap on the first and a second snap on which is rotated by 180 degrees Allow the cover cap (70) on the socket housing (30).

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