EP0393695A2 - Connector case - Google Patents

Abstract

A connector case (13) with contact element chambers (15, 17), in which contact elements (37, 39) are located, one of which is connected to a signal conductor (57) and the other to a screening conductor (61), which is tapped off the signal conductor. A side wall, bounding the contact element chamber (15) for the contact element (37) for the screening conductor (61), of the connector case (13) has a strap (31) which is connected to the remaining longitudinal side wall (21) by means of a film hinge (36). The strap (31) has a covering part (33) with cut-outs for feeding out at least one coaxial cable (55) from the connector case (13), and a stress-relieving projection (35) which, when the strap (31) is closed, presses against the tapping (65) of the screening conductor (61), in a stress-relieving manner. <IMAGE>

Description

The invention relates to a connector housing according to the preamble of claim 1 and a connector assembly with such a connector housing.

Electrical connectors for connection to one or more coaxial cables are known which have an inner conductor, an insulating jacket applied thereon, a shielding conductor surrounding the insulating jacket, generally in the form of a braided hose, and an outer insulating jacket surrounding the shielding conductor. Contact is made in the contact element chambers of the connector housing elements housed, the inner conductor and the shielding conductor of the coaxial cable are connected to different contact elements. A pair of adjacent contact element chambers is assigned to each coaxial cable. Two-pole connectors of this type have a rectangular shape, which receives the two adjacent contact element chambers. Four-pole connectors of this type have an essentially square outer cross section in which two pairs of contact element chambers are accommodated. An inner conductor contact element and an associated shield conductor contact element are accommodated in each pair of contact element chambers. To connect to the contact elements for the inner conductor and shielding conductor, the outer insulating jacket is removed from the coaxial cable end to be connected to the connector, and the shielding conductor is thus exposed. The shielding conductor is then bent away from the insulating jacket of the inner conductor and connected to the associated contact element.

The branch points between the inner conductor and the shielding conductor are exposed outside of the connector housing after the contact elements connected to the cable conductors have been inserted into the associated contact element chambers. In order to provide electrical insulation of the exposed shielding conductors from one another and from external conductors on the one hand and to provide strain relief for the ends of the cable conductors guided into the connector housing on the other hand, in this known connector the end of the cable entry end is connected to the or the coaxial cable connected connector housing with a potting compound, such as a polyacrylic adhesive, closed. This is done in such a way that cast material in hill form extends from the cable insertion end of the connector housing to the junction of the shielding conductor and the inner conductor.

Care must be taken to prevent potting material from running down the outside of the side walls of the connector housing. This would prevent multiple connectors from e.g. to put a circuit board directly next to each other.

Such connectors are mainly used in the field of telecommunications, particularly in the case of telephone systems. The mating contacts of such connectors are pins on printed circuit boards. In accordance with the density on printed circuit boards common today, the connection pins are close together and the connectors have correspondingly small dimensions.

The contact elements often have locking springs which protrude obliquely from the contact element body towards the cable connection end. Their free ends engage behind locking shoulders, which are formed by windows in the corresponding walls of the contact element chambers. Pulling out a contact element from its contact element chamber is only possible against overcoming the locking force of the locking spring.

Since the contact elements and thus also the locking springs are quite delicate due to the small dimensions of such connectors, securing the contact elements in the contact element chambers with the aid of the locking springs is generally not sufficient. Therefore, the additional strain relief is required by potting the cable entry end of the connector or by similar closing.

From DE-PS 21 13 365 a connector housing of the type specified is known, in which a number of contact elements are arranged side by side in a row. A tab, which is arranged on a side wall of the connector housing by means of a film hinge running transversely to the direction in which the contact elements line up, so that it is a continuation of this side wall in the closed position, has vertically protruding locking ribs on its inside, each with a tab in the closed position reach behind the contact elements inserted into the connector housing and release the contact elements when the tab is pivoted open. When the tab is open, the contact elements can therefore be inserted into or removed from the associated contact element chambers without hindrance. In the closed position of the tab, the locking ribs secure the contact elements inserted into the connector housing against being pulled out of the end of the connector housing at the cable entry end. The tab can be locked in the closed position with the rest of the connector housing by means of a locking device.

The known connector housing is open even when the tab is closed on the cable entry side. The locking function of the locking ribs on its tab requires that contact elements are inserted into the connector housing, which shoulders can be gripped by the locking ribs.

In the case of multi-pole connectors with two rows of contact elements one above the other, only the row of contact elements adjacent to the tab can be secured by the locking ribs located on this tab. In the event that the row of contact elements located above are to be secured against being pulled out of the cable insertion end of the connector, connectors of this type are known which each have a tab with locking ribs on two opposite longitudinal sides. To secure two rows of contact elements, two tabs with locking ribs must be provided.

From US-PS 3 293 591 a two-pole connector is known, the housing of which is open at the cable inlet, so that pin-shaped contact elements which are connected to the free ends of two electrical cables can be inserted through a common contact element cavity into outlet openings on the connector side of the connector housing . The cables connected to the contact elements then initially protrude from the rear opening of the connector housing. On a narrow side wall of this connector housing, a closure lid is attached by means of a film hinge, which is closed by pivoting after inserting the contact elements into the connector housing. The cable ends connected to the contact elements are pushed into a recess in a side wall of the connector housing opposite the film hinge, so that after the cover is closed they are led out laterally from the connector housing. A clamping rib is provided on the inside of the cover, by means of which the regions of the cables which are led out of the contact elements are clamped in the connector housing.

This type of clamping may be unproblematic for conductors whose only function is to conduct electrical energy. The situation is different for cables with signal conductors. In the case of coaxial cables which are connected to connectors for the telephone systems mentioned above, pinching for the purpose of strain relief leads to a deformation of the cable geometry in the signal conductor area, which causes a change in the electrical properties of the cable and thus an undesirable change in the characteristic impedance of the cable.

From DE-29 34 953-A1 a connector for multi-pole electrical connections is known, which has a connector housing with a tab on a side wall, which not only has strain relief projections that secure inserted contact elements in the connector housing when the tab is closed, but the also has at its free end a cover which extends into the housing cavity and has an opening for the passage of electrical conductors. In this known connector, too, the strain relief projections are adapted to a special shape of contact elements, so that in this known case, too, contact elements of a special shape are required which have to be inserted into the contact chambers in a certain angle of rotation position.

The invention makes available for connectors with which coaxially shielded signal conductors are used, which are mainly used for telephone systems, a connector housing of the type specified which, while maintaining the basic configuration of such connectors, offers a strain-relieving fuse which makes a specialized form of the contact elements superfluous , does not require fastening by casting compound, does not impair the electrical properties of the cables connected to such connectors, manages with as little additional effort as conventional connectors of this type and enables easy and simple installation.

A connector housing according to the invention is specified in claim 1 and can advantageously be further developed according to claims 2 to 12. It should be noted that the measures according to claims 10 and 11 each have independent inventive character independent of the measures of the preceding claims. A Connector arrangement, which uses the solution according to the invention, is specified in claim 13 and can advantageously be further developed according to claim 14.

Due to the fact that according to the invention the or each strain relief projection only extends into the area of the contact element chamber for the shielding conductor of a coaxial cable, but no strain relief projection projects into the area of the contact element chamber for the associated signal conductor, a strain relief attack is only exerted on the branched area of the shielding conductor of the coaxial cable. The signal conductor, on the other hand, is only held indirectly in the housing by the fact that its associated shielding conductor is held by the associated strain relief projection. Since the branched area of the shielding conductor continues into the part of the shielding conductor lying coaxially around the signal conductor, this type of strain relief on the signal conductor is carried out essentially uniformly around the insulating jacket of the signal conductor. This type of holding of the signal conductor therefore takes place without deforming crushing of the signal conductor on its insulation. Therefore, there is no change in the electrical properties and the wave resistance.

In the case of a four- or higher-pole connector of the type according to the invention, the shielding conductor regions of adjacent coaxial cables branched off from the respective coaxial cable are separated from one another by separating webs between the individual strain relief projections Cut. Therefore, they cannot come into electrical contact with one another. The separating webs are preferably dimensioned such that when the tab is closed they practically extend as far as the respective contact element chamber partition wall, essentially only a distance which takes into account the manufacturing tolerances remains.

Since the strain relief takes place by gripping the branched area of the shielding conductor, and not by gripping a specially provided shoulder on a contact element, this type of strain relief is independent, on the one hand, of the special shape of the contact element used in each case and, on the other hand, of the rotational position about the longitudinal axis with which the contact element is inserted into the associated contact element chamber.

In the event that contact elements with obliquely projecting locking springs are used, conventional connectors of the type under consideration are provided with locking windows at corresponding locations on housing walls, in which the free ends of the locking springs can engage in a supportive manner. Such windows allow the penetration of dirt and foreign bodies, so that the plug connection produced with such a connector can be impaired.

In a preferred embodiment of the invention, locking shoulders are therefore used instead of locking windows, which are preferably by Recesses are formed in those housing walls which, when the contact elements are completely inserted into the connector housing, the free ends of their locking springs are opposite. During the insertion process, the locking springs snap into the recess and then engage behind the locking shoulder opposite them.

If the locking shoulder is only provided in one wall of each contact element chamber, the associated contact element must be inserted into the contact element chamber in a corresponding axial rotational position. This need can be freed from by providing the locking shoulder in all side walls of the contact element chamber, for example all around. The locking spring then always finds a locking shoulder, regardless of the axial rotational position with which the contact element is inserted into the contact element chamber.

According to another preferred embodiment, the contact elements can also be made independent of a specific axial rotational position in the contact element chambers by not allowing the locking spring on the respective contact element to interact with a locking shoulder on an opposite inner wall of the associated contact element chamber, but rather the end on the plug side of the contact element is centered on the plug-in opening of the contact element chamber by means of bevels in the plug-side end of the associated contact element chamber and thereby the contact element urges all around against contact element chamber walls, so that the free end of the locking spring can hook onto the adjacent inner wall of the contact element chamber, regardless of the rotational position with which the contact element has been inserted into the contact element chamber.

Due to these measures according to the invention, both the locking of the contact element within the contact element chamber with the aid of the locking spring and the strain relief with the help of the strain relief projection are independent of the axial rotational position with which the contact element is inserted into the contact element chamber. This is a considerable advantage, which manifests itself in an easy installation option that does not require any special attention and frees from insertion errors.

The fact that the cover part is provided at the free end of the tab prevents external conductors from coming into contact with the shielding conductors exposed from the junction. Only one or more cutouts for the signal conductor (s) of the coaxial cable or cables are provided in the cover part. In the frequent case that the coaxial cables have a diameter which is practically as large as the clear width of the contact element chambers, this means that the cutouts for the coaxial cables practically leave the contact element chambers free for the signal conductors. However, if the coaxial cables have a smaller cross-section than the clear width of the associated contact element chambers, it is preferable to use the recess or recesses in the cover Part to adapt to the diameter of the coaxial cable and in this case to make the recesses for the coaxial cable smaller than the clear width of the associated contact element chambers.

Due to the strain relief according to the invention with a strain relief projection on the pivotable tab and by the cover part arranged at the free end of the tab with cutouts for the signal conductors, it is possible to dispense with the sealing compound used in the known connectors of this type, that the strain relief for the signal conductor not by attacking the signal conductor itself, but on the branched area of its shielding conductor, and that despite two adjacent rows of contact element chambers, a single tab with strain relief projections on only one side of the connector housing is sufficient.

The separating webs can preferably be provided at their free ends with latching projections which are provided in correspondingly positioned latching recesses at a corresponding point on the connector housing, so that the tab can be releasably latched in its closed position.

According to the invention, the dividing walls which separate the individual contact element chambers from one another end at such a distance from the cover part of the closed tab that between the ends of the contact element chambers and the cover part of the closed tab there is sufficient space for the branches of the Shielding cables exist, into which the strain relief projections also protrude.

Independence from the casting compound and, if desired, independence from the axial rotational position of the contact elements in the contact element chambers has resulted in a connector which can be assembled very easily and with correspondingly little effort.

• Figur 1 eine Längsschnittansicht eines Steckver­binders mit einer ersten Ausführungsform eines erfindungsgemäßen Steckverbinder­gehäuses;
• Figur 2 eine Draufsicht von unten auf den in Fig. 1 gezeigten Steckverbinder in vierpoliger Ausbildung mit geschlossener Lasche;
• Figur 3 eine Seitenansicht der Lasche des vier­poligen Steckverbinders;
• Figur 4 eine Draufsicht von unten auf das Steck­verbindergehäuse des in Fig. 1 gezeigten Steckverbinders in vierpoliger Aus­führung mit geöffneter Lasche;
• Figur 5 eine Draufsicht von unten auf den in Fig. 1 gezeigten Steckverbinder in zwei­poliger Ausführung mit geschlossener Lasche;
• Figur 6 eine Seitenansicht der Lasche des zwei­poligen Steckverbinders;
• Figur 7 eine Ansicht von unten auf das Steckver­bindergehäuse des in Fig. 1 gezeigten Steckverbinders bei zweipoliger Aus­bildung mit geöffneter Lasche; und
• Figur 8 eine Längsschnittansicht eines Steckver­binders mit einer zweiten Ausführungs­form eines erfindungsgemäßen Steckver­bindergehäuses.

The invention will now be explained in more detail by means of embodiments. In the accompanying drawings:

• Figure 1 is a longitudinal sectional view of a connector with a first embodiment of a connector housing according to the invention;
• FIG. 2 shows a plan view from below of the connector shown in FIG. 1 in a four-pole configuration with a closed tab;
• Figure 3 is a side view of the tab of the four-pin connector;
• Figure 4 is a bottom plan view of the connector housing of the four-pin connector shown in Figure 1 with the tab open;
• FIG. 5 shows a plan view from below of the plug connector shown in FIG. 1 in a two-pole design with a closed tab;
• Figure 6 is a side view of the tab of the two-pin connector;
• FIG. 7 is a bottom view of the connector housing of the connector shown in FIG. 1 with a two-pole design with the tab open; and
• Figure 8 is a longitudinal sectional view of a connector with a second embodiment of a connector housing according to the invention.

The embodiment of the invention shown in FIG. 1 shows a longitudinal sectional view of a connector 11 with a connector housing 13, in which two contact element chambers 15 and 17 are arranged side by side, which are separated from one another by means of a partition 19. The partition 19 is shorter than the opposing longitudinal side walls 21 and 23, so that between the lower end of the contact element chambers 15 and 17 in FIG. 1 and the lower end 25 of the connector housing 13 in FIG. 1, a via the contact element chambers 15 and 17 downward projecting housing space 29 is present. The right longitudinal side wall 21 in FIG. 1 is formed at its lower end in FIG. 1 by a tab 31, at the lower free end thereof The end of a cover part 33 protruding at right angles to the opposite longitudinal side wall 23 is formed in one piece. A strain relief projection 35 projects into the housing space on the inside of the tab 31. The tab 31 is pivotally articulated on the remaining part of the longitudinal side wall 21 by means of a film hinge 36. Around this film hinge 36, the tab 31 can be pivoted from a closed or closed position, which is shown in FIG. 1 with solid lines, and an open or open position, which is shown in FIG. 1 with dashed lines.

A contact element 37 and 39 is located in each of the two contact element chambers 15 and 17. Each contact element has a connection area 41 and a plug contact area 43. The plug contact area is designed as a contact socket which is designed for the resilient reception of a contact pin projecting from a mating connector or a printed circuit board. The connection area 41 has a conductor crimping part 45 and a holding crimping part 48. The contact elements 37 and 39 each have a locking spring 47 in the contact area 43, which projects obliquely from the actual body of the contact area 43 to the cable entry side and claws into the adjacent longitudinal inner wall 49 of the connector housing 13. Each contact element chamber 15 has, in the inner wall area located in FIG. 1 below the locking spring 47, a conically narrowing constriction 51, to each of which there is an opening on each of the four inner walls of the contact element chamber 15, which is rectangular in cross section rib 53 which extends into the interior of the contact element chamber 15 at a point of the contact element chamber 15 beginning in FIG. 1 below the constriction 51. The contact element chamber 15 is narrower above the constriction 51 than below the constriction 51.

The end of a coaxial cable 55 is inserted into the cable entry end 25 of the connector housing 13, which has a signal conductor 57, a signal conductor sheath 59 made of insulating material coaxially surrounding it, a shield conductor 61 coaxially surrounding the signal conductor sheath 59, and an outer sheath 63 coaxially surrounding the shield conductor 61. From the point where the outer sheath 63 ends, the shield conductor 61, which is generally a tubular braid made of electrical wires, is bent from the signal conductor sheath 59 into a lateral branch 65 and is guided into the contact element chamber 15. The signal conductor 57, however, is guided into the contact element chamber 17. While in the case of the right contact element 37 in FIG. 1, both the conductor crimping part 45 and the holding crimping part 48 are crimped on the branched shielding conductor 67, in the case of the left contact element 39 in FIG. 1, the conductor crimping part 45 is on the signal conductor 57 and the holding crimping part 48 squeezed onto the signal conductor jacket 59. In the closed state of the tab 31, the strain relief projection 35 in FIG. 1 presses against the branch 65 of the shielding conductor 61 from below. In this way, the shielding conductor is protected against being pulled out of its contact element chamber 15 and finds strain relief for the ab shield conductor 61 instead. Since the shielding conductor is fixed on the coaxial cable 55, this strain relief indirectly acts as a strain relief for the signal conductor 59 through the strain relief projection 35. With this indirect strain relief, no pinch pressure is exerted on signal conductor 57 and signal conductor jacket 59, so that the electrical properties of the signal conductor remain unchanged.

If the tab 31 is pivoted into its open position (shown in dashed lines in FIG. 1), the contact elements 37 and 39 struck on the shielding conductor 61 and the signal conductor 57 can be inserted unhindered into their contact element chambers 15 and 17, respectively. During this insertion, the run-on ribs 53 act as centering elements, by means of which the plug-in contact areas 43 of the contact elements 37 and 39 are centered on the one hand with respect to the plug-in plug openings at the plug-side end 27 of the connector housing 13 and on the other hand the plug-in contact areas 43 are pressed sufficiently against all side walls of the respective contact element chamber 15, to ensure that the free end of the locking spring 47 comes to rest on one of the inner walls of the contact element chamber 15 or 17. If an attempt is subsequently made to pull the contact element 37 or 39 out of the associated contact element chamber 15 or 17, the free end of the locking spring 47 claws into the opposite inner wall of the associated contact element chamber 15 or 17, so that there is a certain locking which is at least preventing the contact elements from falling out of the contact element chambers. A stronger one However, the locking springs 47 have not grown in tensile force, which is why the additional strain relief is provided with the aid of the strain relief projection 35.

Since the strain relief projection 35 interacts with the branch 65 of the shielding provider 61 and not with any shoulders of a contact element, the strain relief effect is independent of the axial rotational position in which the contact element is inserted into the associated contact element chamber. Furthermore, since it is ensured with the aid of the run-up ribs 53 and the narrowed part of the contact element chamber that the locking spring 47 can always spread against the inner wall of the contact element chamber which the locking spring 47 is opposite, locking with the aid of the locking spring 47 is also ensured independently of this in which axial rotational position the contact element is inserted into the contact element chamber.

Details, in particular the tab 31, are shown in FIGS. 2 to 4 for a four-pole connector and in FIGS. 5 to 7 for a two-pole connector.

FIG. 2 shows the bottom plan view of the connector shown in FIG. 1 in a four-pole design with a closed tab 31. The cover part 33 of this tab covers the two right contact element chambers 15 in FIG. 2, into which contact elements (not shown) for shielding conductors, not shown, are inserted are. In the two shown on the left in Fig. 2 Contact element chambers 17, contact elements (not shown) are used, to which the signal conductors of a coaxial cable 55, which is indicated in each case, are connected. The cover part 33 has cutouts above the contact element chambers 17, so that the coaxial cables 55 can be led out of the plug connector housing 13 through the cover part 33. Between the cutouts, the cover part 33 runs out into a separating web 69, which extends up to the longitudinal side wall 23 on the left in FIG. 2. The separating web 69 ensures that the branches 65 of the shielding conductors 61 of the two coaxial cables 55 remain mechanically separated from one another and cannot come into electrical contact with one another. The cover part 33 also ensures that the exposed parts of the shielding conductors 61 cannot come into contact with external conductors.

At its free end, the separating web 69 is provided with a latching projection 71, which latches into a latching opening 73 in the longitudinal side wall 23 on the left in FIG. 2 when the tab 31 is in its closed position.

The dividing wall 19 and a dividing wall 75 running transversely thereto are indicated in dashed lines in FIG. 2. These partitions 19 and 75 divide the interior of the connector housing 13 into four contact element chambers.

FIG. 3 shows a side view of the tab 31 according to FIG. 2. There, the separating web 69 and the Ver arranged on the dividing web 69 are particularly clear to see projection 71.

Fig. 4 shows a bottom view of the connector housing 13 shown in Fig. 1 with the tab 31 open. In this Fig. It can be seen that at the free ends of the strain relief projections 35 cross webs 75 are arranged, which increase the stability of the strain relief projections 35.

The details of a two-pole connector housing shown in FIGS. 5 to 7 are similar to the details shown in FIGS. 2 to 4. The difference is that only two contact element chambers 15 and 17 are provided, which is why only a strain relief projection 35 is arranged on the tab 31, specifically in the middle of the tab 31. The cover part 33 of the tab 31 only extends over the right contact element chamber in FIG. 5 15 in order to leave space for the passage of the coaxial cable 55 over the contact element chamber 15 on the left in FIG. 5.

Since, in the case of this embodiment, the cover part 33 does not extend as far as the longitudinal side wall 23 on the left in FIG. 5, a laterally projecting latching projection 71 is arranged on the longitudinal sides of the cover part 33, which latch into corresponding latching openings 77 in the associated side walls of the connector housing 13, when the tab 31 is closed.

Another embodiment of a connector arrangement according to the invention is shown in FIG. 8. This embodiment differs from the embodiment 1 on the one hand in that the separating web 69 is extended so far in the axial direction of the connector housing that when the tab 31 is closed it practically extends to the cable insertion end of the adjacent partition 19 of the contact element chambers 15 and 17. For reasons of manufacturing tolerance, when the tab 31 is closed, there remains a slight distance between the separating web 69 and the dividing wall 19. As can be seen in FIG. 8, in which the tab 31 is drawn continuously both in the closed position and in the open position, there remains between the dividing wall 19 and the dividing web 69 only such a small gap that practically an absolutely safe separation between the shielding conductors 67 in adjacent contact element chambers 15 is ensured, even with respect to individual wires of the shielding conductors 67 projecting sideways. Ensuring such an absolute separation of adjacent shielding conductors is necessary in the case of coaxial cables because touching adjacent shielding conductors would change the electrical behavior (wave impedance) of the coaxial line and thus the signal transmission behavior. The embodiment shown in FIG. 8 also differs from the embodiment shown in FIG. 1 in the way in which the locking springs 47 are locked in the connector housing. The outer side walls of the two contact element chambers 15 and 17 in FIG. 8 are each provided with a locking recess 77, at the lower end of which a locking shoulder 79 is formed. Below the locking shoulder 79, this contact element chamber wall is provided with an inward bevel. When inserting a contact element in a contact element chamber, the free End of the locking spring 47 is initially pressed due to the ramp 81 toward the contact element. As soon as the free end of the locking spring 47 has overflowed the locking shoulder 79, the locking spring 47 can relax (at least partially) into the locking recess 77. Therefore, the free end of the locking tongue 47 engages behind the locking shoulder 79. When attempting to pull the contact element out towards the cable insertion side of the contact element chamber, the locking spring 47 spreads out on the locking shoulder 79 and prevents the contact element from being pulled out further from the contact element chamber.

Preferably, the contact element fully inserted into the connector housing is allowed to have a slight axial play within the contact element chamber. If a contact pin is inserted obliquely via a pin insertion opening 83 at the mating connector-side end of the connector housing, either because the associated mating connector is inserted obliquely or the contact pin itself is bent obliquely, the contact element 37 or 39 can deviate somewhat axially, which leads to the contact pin becoming bent can erect in the axial direction of the contact element before contact spring tongues of the contact element are subjected to excessive stress.

In the embodiment shown in FIG. 8, it is necessary to insert the contact elements into the connector housing in a prescribed axial rotational position so that the locking between the locking spring 47 and the locking shoulder 79 can take effect. But you can featured from this be written free axial rotational position of the contact element by providing the locking recess 77 and thus the locking shoulder 79 in all four side walls of the contact element chamber, preferably in the form of a circumferential locking recess and associated locking shoulder.

Claims (14)

1. connector housing (13) made of insulating material, with a plurality of contact element chambers (15, 17) for receiving one contact element (37, 39) each connected to an electrical conductor (57, 61), the connector housing (13) on a side wall (21 ) is provided with a tab (31) which is connected to the rest of this side wall (21) by means of a hinge (36) and between a releasably lockable closed position in which it essentially forms a continuation of this side wall (21) and an open position in which it protrudes from the side wall (21), can be pivoted,
wherein in the area of a cable entry side (25) of the connector housing (13) at least one strain relief projection (35) protrudes from the inside of the tab, which pulls out a contact element (37) in the tab closed position, which is located in a contact element chamber (15) adjacent to the tab (31) , from the cable entry side (25) of the connector housing (13) and in the open tab position the insertion of the contact element (37) into the contact element chamber (15) and the removal of the contact element (37) from the contact element chamber (15) via the cable insertion side (25) of the connector housing (13),
and wherein at the free end of the tab (31) a protruding from the inside of the lid part (33) is arranged, which closes the cable insertion side (25) of the connector housing (13) in the tab closed position, with the exception of a conductor lead-through opening for an electrical cable (55),
characterized by
that the connector housing (13) has at least one pair of contact element chambers (15, 17) for receiving a signal conductor contact element (39) connected to a signal conductor (59) of a coaxial cable (55) or a shield conductor contact element connected to a shield conductor (61) of the coaxial cable (55) (37), which are arranged next to one another in the direction of extension of the strain relief projection (35), the contact chamber (15) adjacent to the tab (31) being provided for the shielding conductor contact element (37) and the other contact chamber (17) being provided for the signal conductor contact element (39) ,
that the strain relief projection (35) only narrows or covers the contact element chamber (15) adjacent to the tab (31) and leaves the other contact element chamber (17) open,
that the connector housing (13) on the cable entry side (25) has a projecting beyond the contact element chambers (15, 17) housing space (29) in which one of a signal conductor insulating jacket bent shielding conductor branch (65) has space, and that the strain relief projection (35) protrudes into the housing space (29) in the tab-closed position. 2. Connector housing according to claim 1,
characterized,
that the tab (31) is connected by means of a film hinge (36) to the associated side wall (21) of the connector housing (13). 3. Connector housing according to at least one of claims 1 or 2,
characterized,
that the cover part (33) is provided with at least one latching projection (71) which projects from a free edge of the cover part (33) and engages in the latched closed position in an associated latching recess (73) in an opposite wall of the connector housing (13). 4. Two-pole connector housing according to claim 3,
characterized,
that the cover part (13) has a latching projection (71) on each of its two opposite side edges and the connector housing (13) is provided with latching engagement openings (73) at points corresponding to the latched closing position. 5. Four-pin connector housing according to at least one of claims 1 to 3,
characterized,
that two pairs of contact element chambers (15, 17) are provided, each having a contact element chamber (15) adjacent to the tab (31) and a contact element chamber (17) remote from the tab (31),
that the cover part (33) covers the two contact element chambers (15) adjacent to the tab (31) and leaves the two contact element chambers (17) remote from the tab (31), and
that from the center of the free end of the cover part (33) a separating web (69) to the side wall (23) opposite the tab (31) of the connector housing (13) protrudes. 6. Multipole connector housing according to at least one of claims 1 to 3,
characterized,
that a plurality of pairs of contact element chambers (15, 17) are provided, each having a contact element chamber (15) adjacent to the tab (31) and a contact element chamber (17) remote from the tab (31),
that the cover part (33) covers all contact element chambers (15) adjacent to the tab (31) and leaves all contact element chambers (17) lying away from the tab (31) open,
that from the free end of the cover part (33) in places, the partitions (75) between each adjacent pair of contact element chambers (15, 17), each have a separating web (69) protruding from the side wall (23) of the connector housing (13) opposite the tab (31). 7. Connector housing according to claim 5 or 6,
characterized,
that the separating web (69) or the dividing webs extend up to a manufacturing tolerance distance to the contact element chamber partition (75) or partitions. 8. Connector housing according to at least one of claims 5 to 7,
characterized,
that a latching projection (71) protrudes from the free end of the separating web (69) or each of the dividing webs and that the connector housing (13) is provided with a latching engagement opening (73) or latching engagement openings at a position or locations corresponding to the latched closing position. 9. Connector housing according to at least one of claims 5 to 8,
characterized,
that each of the tab (31) adjacent contact element chamber (15) is assigned a strain relief projection (35). 10. connector housing with a number of adjacent contact element chambers (15, 17), in particular according to at least one of claims 1 to 9,
characterized,
that each contact element chamber (15, 17) has a substantially rectangular cross section for receiving a contact element (15, 17) with a likewise substantially rectangular cross section, and that the contact element chambers (15, 17) are provided with run-on bevels on the mating plug-in contact element insertion side (27) are the ends of which a narrowed area of the respective contact element chambers (15, 17) adjoins, whereby the contact element (37, 39) belonging to the respective contact element chamber (15, 17) during its insertion into the associated contact element chambers (15, 17) is centered in relation to a counter-contact insertion opening of the contact element chambers (15, 17),
and that each contact element (37, 39) to be inserted into the connector housing (13) is provided with an obliquely projecting locking spring (47) which, as a result of the centering process, is independent of the coaxial rotational position in which the contact element (37, 39) is in the associated contact element chamber (15, 17) is inserted, in which the locking spring (47) opposite inner wall of the contact element chamber (15, 17) engages. 11. connector housing with a number of adjacent contact element chambers (15, 17), in particular according to at least one of claims 1 to 9,
characterized,
that the contact element chambers (15, 17) on the mating plug-in contact element insertion side (27) have in at least one side wall a locking shoulder (79) which extends essentially transversely to the longitudinal axis of the contact chamber,
and that each contact element (37, 39) to be inserted into the connector housing (13) is provided with an obliquely projecting locking spring (47), the free end of which, after the contact element (37, 39) has been fully inserted into the connector housing (13), has the locking shoulder ( 79) engages behind. 12. Connector housing according to claim 11,
characterized,
that all side walls of each contact element chamber (15, 17) are provided with a locking shoulder (79). 13. Connector assembly
marked by
a connector housing (13) according to at least one of claims 1 to 12,
a contact element (37, 39) in each of the contact element chambers (15, 17) of the connector housing (13), and at least one coaxial cable (55), which has an electrical inner conductor as a signal conductor (57) and one of the signal conductor (57) through a signal conductor jacket (59) has separate electrical shielding conductors (61),
at the free end of a shield conductor branch bent away from the signal conductor jacket (59) (65) the contact element (37) accommodated in the contact element chamber (15) adjacent to the tab (31) and to the signal conductor (57) the contact element (39), which is accommodated in the contact element chamber (17) remote from the tab (31) , connected,
and wherein the strain relief projection (35) presses on the shielding conductor branch (65) in the tab-closed position. 14. Connector arrangement according to claim 13,
characterized,
that the shield conductor branch (65) is accommodated in the housing space (29) projecting beyond the contact element chambers (15, 17) and the strain relief projection (35) presses into the housing conductor (29) in protruding position on the shield conductor branch (65).

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