EP0350835A2 - Electrical connector - Google Patents

Abstract

An electrical connector has a housing sleeve (1) and a plug contact housing (6), both of which are of one-piece design. The housing sleeve (1) has on the inner side at least one radially acting detent means (2) for latching with a correspondingly designed counter-detent means (14) of the plug contact housing (6) introduced into the housing sleeve (1). A crimping zone (3), onto which a crimping tool can be placed from outside, is formed on the housing sleeve (1). In the region of the crimping zone (3), the plug contact housing (6) is provided with a metal sleeve (11). A tube-like screen of the lever can be clamped firmly between metal sleeve (11) and crimping zone (3). <IMAGE>

Description

The invention relates to an electrical connector according to the preamble of claim 1.

A known connector, which is shown in FIGS. 1 and 2, has a housing sleeve, which consists of two sleeve parts 21 and 24, and a plug contact housing, which consists of two housing parts 26 and 30. One housing part 26 is produced from an insulating body 27 and has two through openings, a plug contact 28 being arranged in each through opening. The second housing part 30 is also made of an insulating body and has two through openings. To connect the two housing parts 26 and 30, the housing part 30 is pushed over the plug contacts 28, so that the housing parts 26 and 30 abut one another and the plug contacts 28 are contained in the openings of the housing part 30. The housing part 30 is designed such that when the plug contacts 28 are inserted, one plug contact end is exposed, while the other plug contact is completely surrounded by the housing part 30.

The sleeve parts 21 and 24 each have a through opening and can be screwed together by means of threads 23 and 25 located on both parts will. The assembly of the connector for connection to a shielded electrical cable with two electrical conductors takes place in such a way that the shield of the cable is removed from one end region and the ends of the electrical conductors exposed by stripping are stripped first from the cable insertion side through the sleeve part 21 and then are introduced into the plug contacts 28 located in the housing part 26, the shield removed from the cable end being located outside the sleeve part 21. The holes 29 provided on the plug contacts 28 can be used to introduce solder for soldering the electrical conductors to the plug contacts 28. It is very important that the amount of solder is precisely controlled so that solder is only present in the holes 29 and not on the outside of the plug contacts 28. After the soldering process, the housing part 26 is inserted into the housing part 30 with the plug contacts 28 first . For a precise fit, it is particularly important that no solder adheres to the outside of the plug contacts 28, since this would make it difficult to plug the two housing parts 26 and 30 together. The plug contact housing assembled in this way is then pushed through an opening 31 into the sleeve part 24. Then the sleeve part 21, through the opening of which the cable connected to the plug contact housing passes, is placed in the opening 31 of the second sleeve part 24, and by means of the thread 23 or 25, the two sleeve parts are screwed together, the plug contact housing 26, 30 in Inside the screwed housing parts 21, 24 (see. Fig. 2).

The screen removed from the cable end is placed over the outer part 22 of the sleeve part 21. A crimp sleeve 20 is pushed onto this screen, which is squeezed onto the screen with the aid of a crimping tool, so that a firm connection is created between the sleeve part 21 and the screen of the cable.

In damp environments, it is necessary to prevent water or condensation from entering the connection between the cable and the connector. For this purpose, a coating 32 is usually applied to the cable and the crimp sleeve 20. Such a coating 32, however, only extends to a screw head 23 'of the sleeve part 21 (see FIG. 2), so that water can penetrate inward through the screw head 23' of the crimp sleeve 20 towards the cable and into the interior of the connector .

The assembly of the connector described above is not only cumbersome and complex, but there is also the risk that the sleeve parts 21 and 24 are not firmly connected to one another due to poor screwing. A loose connection of these two sleeve parts leads to the fact that the plug contact housing also sits loosely in the interior of the housing sleeve, so that on the one hand the connection between the electrical conductors and the plug contacts 28 is exposed to unacceptable mechanical loads and on the other hand the plug connection with a mating connector can be inadequate. The inadequate and complex assembly of the known connector works are also disadvantageous during repair work.

From EP-0 183 587 A1 a connector is known which has a plurality of rectangular plug contact housings which are housed together in a rectangular housing receiving frame. In the housing frame, several rectangular metal brackets are housed, which have protruding latching tongues in their inner region, which can snap into corresponding latching recesses in the plug contact housings. The plug contact housings each have a multiplicity of contact receiving chambers for a corresponding number of contact elements, each of which is connected to an electrical conductor. Such a connector is composed of a relatively large number of individual parts, which increases the manufacturing outlay and thus the manufacturing costs. Contacting electrical screens is not intended.

From EP-0 163 473 A2 a connector is known which has a one-piece, cylindrical housing sleeve, into which a four-part plug contact housing is inserted and a locking spring ring which surrounds the circumference of the plug contact housing and spreads between a circumferential shoulder of the plug contact housing and a circumferential groove of the housing sleeve , so that the plug contact housing is locked in the housing sleeve. Here, too, the considerable number of individual parts increases the manufacturing outlay and the manufacturing costs, and contacting a cable shield is not provided.

A connector, in which both a housing sleeve and a plug contact housing accommodated therein are each in one piece, is known from US Pat. No. 4,413,875. Here, too, a spring washer is used to lock the housing sleeve and plug contact housing The circumference of the plug contact housing is pushed on, and spreads between a circumferential shoulder of the plug contact housing and a circumferential groove of the housing sleeve. With this connector fewer individual parts are required. However, there is no provision for the electrical contacting of a cable shield here either.

US 4,361,376 shows a quite similar connector, which has a latching device integrated with the connector housing in the form of a ring formed on the outer circumference of the connector housing with projecting latching tongues. The latching tongues interact with latching recesses in the inner wall of a housing sleeve. A pleasingly low number of individual parts has been achieved with this connector. However, it also has no device for making electrical contact with a cable shield.

From DE 81 09 532 U1 a connector of the type specified is known, which is designed for connection to a coaxial cable with braided shield, for example an antenna cable. A metallic housing sleeve receives a plug-in contact housing made of insulating material, in which there is a contact element, one end of which is designed with clamping arms for resilient engagement with the core of the coaxial cable and the other end with a plug-in contact area for contacting a mating contact element of a mating connector. The plug contact housing has a circumferential groove, in which an inwardly pointing annular projection of the housing housing engages in a latching manner. For connection to the connector, the coaxial cable is prepared in such a way that an end region of the braided shield is exposed, one between the core and the braided shield The insulation layer is cut to the same length as the braid shield. The conductor core protrudes a little from this cut surface so that it can be pushed between the clamping arms of the contact element. To connect the connector to the coaxial cable, the coaxial cable is pushed into the housing sleeve until the front end of the insulating layer and that of the braided screen abut the cable connection end of the plug contact housing. The housing sleeve is then crimped onto the plug contact housing, the shield and the insulating jacket by means of crimping pliers over a length that extends from the end region of the plug contact housing on the cable connection side through the exposed area of the shield braid to the end part of an insulating sheath surrounding the shield braid. The areas gripped by the crimping pliers are squeezed together to such an extent that a pinch fold is formed on diagonally opposite sides of the housing sleeve, which protrudes from the outer circumference of the housing sleeve.

Since a coaxial cable and in particular the insulating layers and insulating sleeves involved in its construction usually consist of resilient material, even in order to be able to lay such cables with curvatures, squeezing the metallic housing sleeve onto areas of the coaxial cable is an unsafe matter with regard to a good mechanical and electrical connection To ensure that the crimping process is not carried out too strongly and thereby cable parts are injured or even deformed, which would change the electrical properties of such a coaxial cable, for example its wave resistance, in an impermissible manner, the crimping pliers must be dimensioned so that they Only compress the housing sleeve to such an extent that such cable deformations and / or cable injuries certainly do not occur. To achieve this, you have to When dimensioning the crimping pliers or another crimping tool, set to maximum oversize with maximum tolerance deviation. However, if tolerance deviations from the minimum dimension values occur in individual cases, a sufficiently good mechanical connection and a sufficiently good electrical connection between the screen braid and the insulating jacket on the one hand and the housing sleeve on the other hand can no longer be ensured. In the event of a poor mechanical connection, the coaxial cable can then come loose from the electrical connector, in particular if a tensile force is exerted on the cable end.

There are standards, for example for the military field, according to which an electrical screen of a cable, which is fixed by crimping, has to be crimped between two metal layers. The crimping process must be carried out in such a way that the shield forms a gas-tight connection with the metallic component to which it is crimped. This is only possible if the crimping is carried out with such force that there is a cold flow of the metal layers involved in the crimp connection. With a construction in which the shield to be crimped rests on plastic, such a gas-tight crimping process is not possible. A connector as it is known from DE-81 09 532 U1 can therefore not meet the standards mentioned, because a sufficiently firm crimp connection cannot be produced.

In order to take the standard into account, in the known connector, as shown in FIGS. 1 and 2, the cable insertion end of the metallic housing is brought to such a small diameter that the electrical shield of the cable to be connected is via this end of the metallic Housing can be pulled. If the metal sleeve is then pushed over the screen, the condition is met that the screen is between two metal layers, so that a gas-tight crimp connection can be made. On the other hand, however, this means that the metallic housing on the cable insertion side must have a correspondingly small diameter, so that the plug contact housing made of insulating material cannot be inserted into the metallic housing from the cable insertion side. For this reason, the metallic housing must be formed in two parts.

The invention has for its object to ensure a good mechanical and electrical connection between the connector and the shielded cable to be connected to a connector of the type specified.

A solution to this problem is specified in claim 1 and can advantageously be developed according to the subclaims.

Characterized in that in the connector according to the invention a metal sleeve is applied to the cable inlet of the connector housing and the shield can be clamped between the outer periphery of the metal sleeve and the inner periphery of the metal housing, a secure electrical and mechanical connection for the shield of the cable can be achieved. This is particularly the case if, according to claim 2, the housing sleeve is designed as a crimp zone that can be pressed in in the area surrounding the metal sleeve. In this case, a cable area no longer forms an abutment for the crimping tool, but this abutment is formed by the metal sleeve. The shield of the cable is thus between two metal sleeve areas clamped, which leads to particularly good electrical contact. In addition, the metal sleeve, which is usually much harder than the cable structure or the insulating material of a plug contact housing, absorbs the forces that occur during the crimping process. Parts inside the metal sleeve, be it the cable or the plug contact housing made of insulating material, are protected from crimping forces. It is therefore no longer necessary to work within such narrow tolerance limits as with the known connector, whose metallic housing sleeve is crimped onto the braided shield of the coaxial cable.

The present invention has avoided the need for a two-part metallic housing sleeve. By pushing a metal sleeve onto the cable insertion end of the plug contact housing and bringing the electrical shield of the cable to be connected between the metal sleeve and the crimping zone of the metallic housing sleeve, the condition has been met that the shield can be crimped between two metal layers, with one one-piece metallic housing and a one-piece plug contact housing. This means that the one-piece construction of the connector housing and plug contact housing could now be created for the first time for connectors that have to meet the above-mentioned standards.

The connector according to the invention is particularly suitable for connection to a coaxial line or also to a so-called twin-axial line, which consists of two axially arranged conductors which are twisted together and an outer shield arranged above them. Such twin-axial lines are e.g. used as data bus lines, particularly in aircraft construction, for example for connecting on-board computers or measuring systems to the associated computing units.

The metallic housing sleeve according to the invention is formed in one piece and accommodates the plug contact housing in the interior, a tight fit of the plug contact housing being achieved by a latching or counter-latching device which is formed in the interior of the housing sleeve or on the outside of the plug contact housing.

This allows the assembly of the plug contact housing and housing sleeve by simply pushing them together until they snap into place.

A uniformly firm and secure fit of the plug contact housing in the housing sleeve is thus achieved, in a precisely defined position within the housing sleeve and without the risk that the screw connection loosens unintentionally, e.g. due to vibrations.

The latching device in the housing sleeve can be designed as a projection, the plug contact housing being provided with a corresponding recess. However, it is also possible to incorporate a recess in the housing sleeve and to form the projection on the plug contact housing. The locking device can be formed at one point on the inner circumference of the housing sleeve, it can also extend in a ring on the inner circumference. A spring ring projecting radially inwards is preferably formed in the inner wall, while the plug contact housing has a correspondingly designed circumferential groove on its outer circumference.

The plug contact housing is formed in one piece and serves to accommodate one or more plug contacts. In a preferred embodiment, the plug contact housing has one opening per plug contact receiving opening, which opening extends transversely thereto and is suitable for the access of a crimping tool to the respective plug contact. Thus, it is possible to connect the conductors to the plug contacts with the help of a crimping tool in a simple and quick manner, whereby a secure connection between leads and plug contacts. The necessary and problematic soldering process in the known connectors can thus be omitted.

For assembly, the metal sleeve is applied to the cable inlet of the plug contact housing, to which the tubular shield of the cable is applied after the electrical conductors of an electrical cable have been connected to the plug contacts. The plug contact housing with the connected cable is then pushed into the housing sleeve until the plug contact housing abuts stop shoulders provided in the housing sleeve and engages with the aid of the latching device. The shield applied to the metal sleeve then lies in the interior of the housing sleeve in the region of the crimping zone, and a crimping tool can act on the housing sleeve in the region of the crimping zone from the outside, so that a crimped connection between the shielding and the housing sleeve is produced.

It is also possible to provide the entire length of the plug contact housing with a metal sleeve, the electrical shield of the electrical cable is applied at least to the part of the metal sleeve located at the cable entry of the plug contact housing.

After assembling the connector, a sealing coating can be applied over the cable and part of the housing sleeve, which effectively prevents the ingress of water or condensed water. Any suitable material can be used as the coating material. Various methods have proven to be suitable for applying the coating, for example pushing on a tubular coating which is shrunk on, or spraying a suitable coating material directly onto the cable and housing sleeve. The covering advantageously extends over the entire crimping zone of the housing sleeve, as a result of which the penetration of water into the housing sleeve is particularly effectively prevented.

• Fig. 1 eine Darstellung, teilweise in Schnitt­ansicht, eines bekannten Steckverbinders in auseinandergezogener Form;
• Fig. 2 eine Darstellung, teilweise in Schnitt­ansicht, des bekannten Steckverbinders in zusammengesetzter Form;
• Fig. 3 eine Darstellung, teilweise in Schnitt­ansicht, eines Steckverbinders gemäß der Erfindung;
• Fig. 4 eine Darstellung, teilweise in Schnitt­ansicht, des zusammengesetzten Steckverbin­ders gemäß der Erfindung, und
  
• Fig. 5 eine Längsschnitt-Darstellung eines an an eine Twin-Axial-Leitung angeschlossenen Steckverbinders.

The invention and further developments of the invention are explained in more detail below with reference to an exemplary embodiment shown in the drawing. It shows:

• Figure 1 is an illustration, partially in section, of a known connector in an exploded form.
• Figure 2 is an illustration, partly in section, of the known connector in assembled form.
• Figure 3 is an illustration, partly in section, of a connector according to the invention.
• Fig. 4 is an illustration, partly in section, of the composite connector according to the invention, and
  
• Fig. 5 is a longitudinal sectional view of a connector connected to a twin axial line.

3 and 4, a particularly preferred embodiment of the invention is shown. The connector shown there comprises a metallic housing sleeve 1 and a plug contact housing 6, both of which are formed in one piece. The housing sleeve 1 has a continuous opening, the plug contact housing 6 being insertable into the housing sleeve 1 from one side. The housing sleeve 1 is provided on the inside with a spring ring 2 which engages in a circumferential groove 14 formed on the plug contact 6. The plug contact housing 6 serves to accommodate two plug contacts 7, which are each arranged in a through opening. The plug contact housing 6 is designed such that the end of a plug contact 7 is exposed, while the other end of the plug contact is completely covered by the insulating body 13 of the plug contact housing 6. The housing 6 also has two openings 12 which pass through the plug contact housing 6 and extend in the transverse direction to the through openings for the plug contacts 7. The openings 12 are used for the engagement of a crimping tool for crimping electrical conductors to the plug contacts 7. The cable entry 9 of the Plug contact housing 6 has a flange 10 which secures a metal sleeve 11 which is pulled over the cable insertion 9. So that the metal sleeve 11 can be easily pulled over the flange 10, the cable entry 9 is slotted crosswise in the longitudinal direction, so that the cable entry 9 is compressed and the metal sleeve 11 can be pulled over the cable entry 9. The area which is provided with the metal sleeve 11 has a reduced outer diameter compared to the rest of the plug contact housing 6, so that the outer diameter of this area with the metal sleeve 11 pushed onto the plug contact housing 6 and the screen 16 pushed over it is substantially equal to the outer diameter of the rest of the plug contact housing 6 is. If a cable 17 with two electrical conductors and an electrical shield 16 is now to be connected to the plug contact connector, the shield 16 is first removed from the end region of the two electrical conductors by pushing back and the two electrical conductors are inserted into the plug contacts 7 and with the aid of a Crimping tool that engages through the engagement openings 12 attached. The screen is then pulled over the metal sleeve 11. The plug contact housing 6 is thus connected to the electrical conductors of a cable and can now be pushed into the housing sleeve 1.

The one-piece, metallic housing sleeve 1 contains, in the vicinity of the opening for receiving the plug contact housing 6, the spring ring 2 for locking with the plug contact housing 6 and in the vicinity of the other, opposite opening a stop shoulder 4 for limiting the insertion depth of the plug contact housing 6. The housing sleeve 1 is shaped so that the stop shoulder 4 is ring-shaped, whereby the inner diameter of the housing sleeve 1 is gradually reduced towards the cable insertion side. The area in front of the stop shoulder 4, in which the inside diameter has not yet been reduced, is designed as a crimp zone 3. When the plug contact housing 6 is inserted into the housing sleeve 1 until the spring ring 2 locks in the circumferential groove 14, a crimping tool is placed on the housing sleeve 1 from the outside in the region of the crimping zone 3, as a result of which the shield 16, which is pulled onto the metal sleeve 11 of the plug contact housing 6, is also included the housing sleeve 1 is firmly connected or squeezed.

The housing sleeve 1 has, over an area 5 of enlarged outer diameter adjacent to the crimping zone 3, preferably a threaded sleeve that is axially displaceable to a limited extent and rotatable about the longitudinal axis of the connector, not shown in the figures, and extends as far as the insertion opening for the plug contact housing 6. After the plug-in contact housing 6 has been inserted and locked in the housing sleeve 1, the threaded sleeve (not shown in the figures) can be moved beyond the end of the insertion opening. Since the threaded sleeve has an internal thread, the housing sleeve 1 can thus be screwed to a mating connector, which has a corresponding mating thread.

After assembly of the connector, a covering 15 is pulled or shrunk over the cable 17 and the crimping zone 3 according to FIG. 4. As a result, the connection between the cable 17 and the housing sleeve 1 is sealed, so that no moisture can get into the interior of the cable and the interior of the connector.

Fig. 5 shows a longitudinal cross section through a connector according to the invention, which is connected to a twin-axial line. The individual components and their assignment to one another can be seen particularly well in this representation.

The one-piece plug contact housing 6 made of insulating material accommodates the two plug contacts 7, the lower plug contact 7 in FIG. 5 being designed as a pin contact at its front end protruding from the plug contact housing 6, while the upper plug contact 7 in FIG. 5 is entirely in the plug contact housing 6 is embedded and is formed in its front contact area as a pin receiving socket. The ends of the plug contacts 7 on the cable connection side each have an axial bore 21, into each of which the exposed end of a conductor 23 is inserted. Each of the conductors 23 is surrounded by an insulating dielectric 25. As shown at 27, the two conductors are twisted together to form a twin axial cable. The twin-axial conductors are surrounded by the shield 16, which in turn is surrounded by an outer insulating jacket 29 of the cable 17. As can be seen particularly well in FIG. 5, the front end of the screen 16 is located between the metal sleeve 11 and the crimping zone 3 of the metallic housing 1. By means of a crimping process with the aid of a crimping tool attached to the crimping zone 3, the three metallic layers, namely the metal sleeve 11, the shield 16 designed as a metallic braid and the metallic crimping zone 3, pressed so tightly against one another that there is a cold flow of the metals involved and thus to a gas-tight connection between the three metal layers.

Claims (18)

1. Electrical connector for connecting to an electrical cable that has a tubular electrical screen,
with a one-piece metallic housing sleeve (1) for receiving a one-piece plug contact housing (6) made of insulating material,
characterized,
that a metal sleeve (11) is applied to a cable entry (9) of the plug contact housing (6),
and that the screen (16) can be clamped between the outer circumference of the metal sleeve (11) and the inner circumference of the housing sleeve (1). 2. Electrical connector according to claim 1,
characterized,
that the housing sleeve (1) has at least one radially acting latching device (2) on the inner wall and the plug contact housing (6) has a counter-latching device (14) cooperating therewith. 3. Connector according to claim 1 or 2,
characterized,
that the housing sleeve (1) in the area surrounding the metal sleeve (11) is designed as a crimp zone (3) which can be pressed in. 4. Connector according to at least one of claims 1 to 3,
characterized,
that the inside of the housing sleeve (1) near the cable insertion end is provided with a stop shoulder (4) to limit the insertion depth of the plug contact housing (6). 5. Connector according to claim 4,
characterized,
that the stop shoulder (14) is formed by a step-like reduced inner diameter of the housing sleeve. 6. Connector according to at least one of claims 1 to 5,
characterized,
that the end of the plug contact (6) provided with the metal sleeve (11) has an outer diameter that is reduced compared to the adjacent area of the plug contact housing (6), the outer diameter of the adjacent area being substantially equal to the outer diameter of the shield (11) applied to the metal sleeve (11) 16) is. 7. Connector according to at least one of claims 1 to 6,
characterized,
that the area of the plug contact housing (6) provided with the metal sleeve (11) is provided at its free end (9) with a metal sleeve securing flange (10) and is slotted longitudinally in a crosswise manner such that the metal sleeve securing flange (10) except for the inside diameter of the metal sleeve (11 ) is compressible. 8. Connector according to at least one of claims 1 to 7,
characterized in that the plug contact housing (6) has at least one through opening (8) for receiving a plug contact (7) which can be connected to an electrical conductor and which has a crimp engagement opening (12) penetrating the plug contact housing (6) in the transverse direction for accessing a crimping tool the plug contact (7) is connected. 9. Connector according to at least one of claims 1 to 8,
characterized,
that a sealing coating (15) is applied to the transition region between the cable (17) and the housing sleeve (1). 10. Connector according to claim 9,
characterized,
that the sealing coating (15) extends over the crimping zone (3) of the housing sleeve (1). 11. Connector according to claim 9 or 10,
characterized,
that the sealing coating (15) is formed by a shrink tube. 12. Connector according to claim 9 or 10,
characterized,
that the sealing coating (15) is sprayed on. 13. Connector according to at least one of claims 1 to 12,
characterized,
that the latching device (2) is formed by a latching projection projecting inwards from the inner wall of the housing sleeve (1) for latching into a corresponding latching recess of the plug-in contact housing (6) forming the counter-latching device (14). 14. Connector according to at least one of claims 1 to 12,
characterized,
that the latching device (2) is formed by a spring ring projecting inwards from the inner wall of the housing sleeve (1) for latching into a correspondingly shaped circumferential groove (14) of the plug contact housing (6). 15. Connector according to at least one of claims 1 to 12,
characterized,
that the latching device (2) is formed by a latching recess formed in the inner wall of the housing sleeve (1) for latching a projection or spring ring projecting from the outer periphery of the plug-in contact housing (6). 16. Connector according to at least one of claims 1 to 15
for use as a connection to a twin axial line. 17. Connector according to at least one of claims 1 to 15 for use as a connection to a coaxial line. 18. Connector according to at least one of claims 1 to 15 for use as a connection to a triaxial line.

Images