EP1861898A1

EP1861898A1 - Plug connector

Info

Publication number: EP1861898A1
Application number: EP06723586A
Authority: EP
Inventors: Willem Blakborn; Jens-Peter Freundt
Original assignee: Rosenberger Hochfrequenztechnik GmbH and Co KG
Current assignee: Rosenberger Hochfrequenztechnik GmbH and Co KG
Priority date: 2005-03-22
Filing date: 2006-03-21
Publication date: 2007-12-05
Anticipated expiration: 2026-03-21
Also published as: US7479034B2; CN100559664C; ATE468636T1; EP1861898B1; KR101210144B1; CN101142718A; DE502006006978D1; DE102005013282A1; WO2006100035A1; JP2008535152A; US20080227332A1; KR20070112151A

Abstract

The invention relates to a plug connector (100) with a housing (110) and with at least two electrical contact elements (112), which each have a longitudinal axis and which are arranged so that they are aligned on a plugging side of the housing (110) at predetermined positions and with a respective longitudinal axis parallel to a plugging direction (122) of the plug connector (100). Each electrical contact element (112) is placed inside the housing (100) in a manner that enables it to move in a plane perpendicular to the plugging direction (122), and is connected in an elastically resilient manner to at least one second electrical contact element (112) via at least one electrically non-conductive elastic spring element (114). The elastic spring element (114) is arranged and designed so that the electrical contact elements (112) are pre-positioned at the respective pre-positioned position up to tolerance allowances, and they can be displaced in an elastically resilient manner from this position in the plane perpendicular to the plugging direction (122).

Description

Connectors

The present invention relates to a connector having a housing and at least two electrical, each having a longitudinal axis having contact elements, which are arranged on a plug side of the housing at predetermined positions and with respective longitudinal axis aligned parallel to a plug-in direction of the connector, according to the preamble of claim 1.

For establishing an electrical connection between a plurality of cable ends on the one hand, which are respectively provided with corresponding contact elements, such as coaxial connectors, pin or socket contacts, and several cable ends with corresponding complementary contact elements, such as KoaxialsteckerAkuppler or socket / pin contact, or more complementary Contact elements on a housing of a device on the other hand, it has hitherto been necessary to manually plug each individual contact element pair together. The term "contact element" here refers to any type of plug contact with one, two or more conductors, such as coaxial connectors in the form of coaxial and coaxial jack and pin contacts and socket contacts. The term "complementary contact element" or "countercontact element" designates the respectively associated plug-in contact into which the "contact element" can be inserted, that is to say, for example, for the coaxial contact element. cker than "contact element" of the coaxial coupler, the "complementary contact element" or it is for the pin contact as a "contact element" of the socket contact the "complementary contact element". By "connector" herein is meant a component having two or more "contact elements" and the "complementary connector" has the corresponding "complementary contact elements" to the "contact elements" of the "connector". The several "contact elements" do not necessarily have to be the same. For example, coaxial connectors may also be mixed with pin contacts. The type "pin" or "socket" does not necessarily have to be identical for all "contact elements" of a "connector". Instead, coaxial couplers and coaxial connectors may be mixed in a "connector".

For electrically connecting, for example, a car roof antenna, which has a plurality of antennas, for example a mobile radio antenna and a GPS antenna, with corresponding devices, such as a mobile device and a GPS receiver, it is customary from the housing of the car roof antenna To lead out cable, which are provided at their free ends with corresponding contact elements. These contact elements are then connected separately and individually with complementary contact elements of cables leading to the devices. However, this type of electrical connection is complex and expensive.

The invention has for its object to provide a connector of o.g. Improve type of assembly and electrical contact.

This object is achieved by a connector of o.g. Art solved with the features characterized in claim 1. Advantageous embodiments of the invention are described in the further claims.

In a connector of the aforementioned type, it is inventively provided that each electrical contact element is arranged in a plane perpendicular to the insertion direction movable in the housing and is elastically resiliently connected via at least one electrically insulating, elastic spring element with at least one second electrical contact element, wherein the elastic spring element is arranged and designed such that the electrical contact elements are pre-positioned at the respective predetermined position to tolerance deviations and are elastically resiliently deflected from this point in the plane perpendicular to the insertion direction.

This has the advantage that the contact elements are suspended elastically floating and thereby tolerance-related deviations between the positions of the electrical contact elements of the connector and corresponding electrical complementary contact elements or mating contact elements in a complementary connector in which the electrical complementary contact elements or mating contact elements are rigidly arranged, upon mating connector and complementary connector by elastic deflection of the electrical contact elements of the connector are automatically compensated and despite tolerance-related deviations of the respective positions good electrical contact between the respective electrical contact elements of connectors and complementary connector is ensured.

In order to provide the most flexible tolerance compensation available, the electrical contact elements in the housing of the connector are arranged movable so that the mobility of the electrical contact elements in the plane perpendicular to the direction of insertion includes tilting and / or translational parallel displacement of the longitudinal axes of the electrical contact elements.

In a preferred embodiment, each electrical contact element is designed as a coaxial connector with an inner conductor and an outer conductor.

For relaying signals via the plug connector, each electrical contact element is connected to a signal conductor element, which in each case electrically connects an electrical contact element to a connection point for a cable.

For example, each signal conductor element is designed as a coaxial line or stripline and optionally has an electrical shield. In a particularly preferred embodiment, all signal conductor elements are arranged extending from the respective contact element in a plane perpendicular to the insertion direction, each signal conductor element formed as a rigid component and provided in the housing for each signal conductor element a recess and is formed such that each signal conductor element together with the associated contact element in a plane perpendicular to the direction of insertion is movable.

Conveniently, each electrical contact element is surrounded by an electrically insulating sleeve and each sleeve of an electrical contact element via a respective electrically insulating elastic spring element with a sleeve of an adjacent electrical contact element elastically resiliently connected, wherein the spring elements in a cross-sectional plane perpendicular to the insertion direction, for example, Ω-shaped and sleeves and spring elements are integrally formed with each other to form a spring housing.

On the housing first locking means and on each spring element second locking means are formed, which fix the spring elements cooperatively with the first locking means and with these the electrical contact elements on the housing.

In a preferred embodiment, each first latching means comprises an elastically resilient tab which rises in the direction of insertion of the housing and has a recess, wherein each second latching means comprises a detent which rises perpendicular to the direction of insertion of the respective spring element and into the recess of the resilient Tab of the first locking means fits.

A mechanical coding which prevents unwanted incorrect insertion of the connector according to the invention, is provided by the fact that at least one of the tabs of the first locking means of the housing has a different width than the other tabs.

For holding the connector in the inserted state rise from the housing in the insertion direction at least two, in particular three, from each other spaced latching pin with respective latching lug, which are designed to engage in a housing or plug-in interface, which carries complementary to the electrical contact elements of the connector contact elements.

The invention will be explained in more detail below with reference to the drawing. This shows in:

1 shows a first preferred embodiment of a connector according to the invention in a schematic plan view of the plug side,

2 shows a second preferred embodiment of a connector according to the invention in a perspective view,

3 shows a housing of the connector according to FIG. 2 in a perspective view, FIG.

4 contact elements, signal conductor elements and spring housing in exploded view,

5 contact elements, signal conductor elements and spring housing in the assembled state in a perspective view,

6 shows the connector according to FIG. 2 in partially assembled state in a perspective view, FIG.

7 shows the spring housing of the connector according to FIG. 2 in a perspective view from below, FIG.

Fig. 8, the spring housing of the connector of FIG. 2 in a perspective view from above and

Fig. 9, the spring housing of the connector of FIG. 2 in plan view. The schematically shown in Fig. 1, the first preferred embodiment of a connector 100 according to the invention comprises a housing 110 in which elongated socket contacts 112 are arranged, of which in the plan view of FIG. 1, only the end faces are visible. These socket contacts 112 are connected to each other by a network of elastic spring elements 114 and fixed by means of this network of spring elements 114 within the housing 110 at positions corresponding to a nominal dimension (nominal positions) for the socket contacts 112. These positions correspond to the positions of pin contacts within a housing of a mating connector or complementary plug-in connector, in which the connector is inserted. Although the socket contacts 112 are prepositioned by the network of spring elements 114 basically at the positions according to the nominal size, but can be elastically deflected from their respective desired position due to the elasticity of the spring elements 114 in the plane of the drawing, which is perpendicular to a direction of insertion 122 of the connector 100. In this case, each socket contact 112 can move away from this desired position in an arbitrary direction within the plane of the drawing independently of the other socket contacts 112. The network of spring elements 114 is designed in such a way that each socket contact 112 can move by the order of magnitude of tolerance deviations from the desired positions in accordance with the nominal dimension for the individual contacts. Now, if the connector 100 according to the invention is inserted into a mating connector or complementary plug connector with corresponding pin contacts, wherein the pin contacts are arranged rigidly in the mating connector, the socket contacts 112 may move slightly out of their respective desired position to adapt to corresponding pin contacts , which are rigidly fixed, ie fixed, with tolerance deviation from the target position according to the nominal dimension in the mating connector. This allows a mating arranged in a matrix contact elements, without the electrical contact negatively affecting mechanical stresses or damage within the contact elements during mating due to tolerance deviations of the position of contact plugs or pins or contact sockets result. It is understood that in the connector according to the invention also contact pins and accordingly can be provided in the mating connector contact sockets. Also, sockets and pins may be mixed in the connector, wherein then the mating connector has a correspondingly complementary mixture of sockets and pins.

The second preferred embodiment of a connector 200 according to the invention, shown in FIGS. 2 and 6, comprises a housing 210, three signal conductor elements 212, three contact elements 214 and a spring housing 216. Arrow 222 denotes an insertion direction into which the plug connector 200 according to the invention in FIG a complementary connector or its plug interface, for example, a device or a cable can be inserted. This plug-in direction 222 in this example is substantially perpendicular to a plane defined by the housing 210, so that it is an angle plug. However, this is just an example. The plug-in direction 222 could also be aligned with a longitudinal axis of the connector, so that it is not a right angle connector but a straight connector.

As can also be seen in particular from FIG. 4, the contact elements 214 are designed as coaxial plug connectors with inner conductor 218 and outer conductor 220. The signal conductor elements 212 are each formed as a strip line extending in a plane perpendicular to the plug-in direction 222 and each connect a Koaxial alsteckverbinder 214 with a cable connection 224 at a cable-side end 226 of the connector 200. For example, the strip lines 212 are formed with three interconnects stacked in a sandwich manner, wherein the middle interconnect transmits the electrical RF signal and the two outer paths for electrical shielding of the signal conductor are connected to ground.

The housing comprises, as shown particularly in FIG. 3, recesses 228 for receiving one of the strip lines 212. These recesses 228 are dimensioned such that the strip lines 212 can move in a plane perpendicular to the direction of insertion 222. From a bottom of the housing 200, first latching means 230 rise in the form of elastically resilient tabs with respective recess 232. Also from the bottom of the housing 200 are latching journals 234 with respective locking lugs 236, which (not shown for snapping into a plug-in interface of a mating connector or device housing ) out- are formed to mechanically connect the housing 200 with the mating connector or the device housing. Furthermore, elastically resilient latching tabs 238 are provided on the cable-side end 226 of the housing 210, which are provided for fastening the strip lines 212 to the housing 210 on the cable-side end 226, as can be seen in particular from FIG.

The spring housing 216, which can be seen in more detail from FIGS. 5 and 7 to 9, comprises three sleeves 240 made of electrically insulating material, each of which surrounds a coaxial connector 214. The sleeves 240 are provided at one of the plug-in direction 222 facing side at its periphery with a chamfer 242, which serve as a capture range for corresponding complementary coaxial connector when inserting the connector 200 according to the invention in the plug interface of a complementary mating connector. The sleeves 240 are connected to one another via elastically resilient spring elements 244 in such a way that the sleeves 240 together with the spring elements form the spring sleeve 216 which, on the one hand, holds the coaxial connectors 214 at a predetermined position according to the nominal dimension (nominal position) and, on the other hand, an elastic deflection of the sleeves 240 and thus allows the coaxial connector 214 relative to each other, so that the coaxial connector 214 to tolerance-related deviations of the position of the complementary coaxial connector from its nominal position, which are rigidly in the mating connector or the plug-in interface, in which the connector 200 according to the invention is to be inserted, are arranged , can adapt by appropriate movement of the target position according to the specified size away. In other words, the plug-in connector 200 according to the invention allows simultaneous insertion of three separate coaxial connectors into corresponding complementary coaxial connectors, without having to arrange these complementary coaxial connectors with excessive requirements for low tolerance of positioning in the mating connector. This saves costs and production costs due to lower tolerance requirements or larger permissible tolerance deviations from the nominal dimension or the nominal position of the coaxial connectors 214 and complementary coaxial connectors. The sleeves 240 and spring elements 244 form the spring housing 216 and are formed integrally with each other. The sleeves 240 elastically resiliently connecting spring elements 244 are formed in a cross-section perpendicular to the insertion direction 222 is substantially Ω-shaped and wear on its outer side second locking means 246 in the form of locking lugs which fit into the recesses 232 of the tabs 230. By virtue of this arrangement, the coaxial connectors 214 can indeed be elastically deflected out of the desired position in the plane perpendicular to the plug-in direction 222, but are fixed along the plug-in direction 222.

During assembly of the connector 200, the spring housing 216 is first pushed over the Koaxialsteckverbinder 214 so that each sleeve 240 receives a Koaxialsteckverbinder 214, as shown in FIGS. 4 and 5 can be seen. Thereafter, the strip lines 212 are inserted into the recesses 228 of the housing 210 opposite to the plug-in direction 222 until the latching tabs 238 of the housing 210 snap over the strip lines 212 and the detents 246 of the spring elements 244 of the spring housing 216 in the recesses 232 of the tabs 230, whereby the respective arrangements of coaxial connector 214, stripline 212 and cable terminal 224 are connected on the one hand to the housing 210, but on the other hand, the coaxial connectors 214 relative to each other by the clearance of the strip lines 212 in the recesses 228 and the elastic spring action of the spring elements 244 in a plane perpendicular can move to the direction of insertion 222 in the order of tolerance deviations away from the desired position.

As can be seen in particular from FIGS. 2 and 6, the tabs 230 have different widths. By corresponding recesses in the mating interface of the mating connector is characterized a mechanical coding available that prevents a twisted incorrect insertion of the connector 200 into the mating interface of the mating connector. This ensures that always the right coaxial connector 214 of the connector 200 meets the correct complementary coaxial connector in the plug-in interface of the complementary connector.

The plug-in interface is for example an arrangement of complementary coaxial connectors in the housing of a car roof antenna with multiple antennas, for example, a mobile radio antenna and a GPS antenna. Each antenna has its own coaxial connector. The electrical connection between the antenna and the respective terminal, in this example mobile telephone and GPS receiver, takes place directly by inserting the connector 200 according to the invention into the plug-in interface of the vehicle roof antenna. Here, the respective coaxial connector for mobile radio antenna and GPS antenna are plugged together. An additional cable connection can be omitted. The complementary coaxial connectors are each connected directly to the associated antenna. In addition to an improvement of the signal transmission by fewer impact points in the signal path results in a simplified assembly, since the respective pairs of coaxial connector / complementary coaxial connector for the various antennas must not be plugged together separately.

Claims

claims:

1. Connector (100, 200) having a housing (110, 210) and at least two electrical, each having a longitudinal axis having contact elements (112; 214) on a plug side of the housing (110; 210) at predetermined positions and with each electrical contact element (112; 214) is movable in a plane perpendicular to the plug-in direction (122; 222) in the housing (110) of the plug connector (100; 200) , 210) and is elastically resiliently connected to at least one second electrical contact element (112; 214) via at least one electrically insulating elastic spring element (114; 244), wherein the elastic spring element (114; 244) is arranged and configured in such a way in that the electrical contact elements (112; 214) are at the respective predetermined

Position are prepositioned to tolerance deviations and from this point in the plane perpendicular to the insertion direction (122; 222) are resiliently deflectable.

2. Connector (100, 200) according to claim 1, characterized in that the electrical contact elements (112; 214) in the housing (110; 210) are arranged such that the movability of the electrical contact elements (112; 214) in the plane perpendicular to the plug-in direction (222) tilting and / or a translational parallel displacement of the longitudinal axes of the electrical contact elements (112; 214).

3. Connector (200) according to claim 1 or 2, characterized in that each electrical contact element (214) is designed as a coaxial connector with an inner conductor (218) and an outer conductor (220).

4. Connector (100, 200) according to at least one of the preceding claims, characterized in that each electrical contact element (112; 214) is connected to a signal conductor element (212) which in each case has an electrical contact element (112; 214) with a connection point ( 224) for a cable connects electrically.

5. Connector (100; 200) according to claim 4, characterized in that each signal conductor element (212) is designed as a coaxial line or strip line.

6. Connector (100; 200) according to claim 4 or 5, characterized in that each signal conductor element (212) is formed with an electrical shield.

7. Connector (200) according to at least one of claims 4 to 6, characterized in that all signal conductor elements (212), starting from the respective contact element (214) in a plane perpendicular to the insertion direction (222) are arranged to extend.

8. Connector (200) according to at least one of claims 4 to 7, characterized in that each signal conductor element (212) formed as a rigid component and in the housing (210) for each signal conductor element (212) has a recess (228) and designed in that each signal conductor element (212) is movable together with the associated contact element (214) in a plane perpendicular to the plug-in direction (222).

9. Connector (200) according to at least one of the preceding claims, characterized in that each electrical contact element (214) by an electrically insulating sleeve (240) is surrounded and each

Sleeve (240) of an electrical contact element (214) via a respective electrically insulating, elastic spring element (244) with a sleeve (240) of an adjacent electrical contact element (214) is resiliently connected.

10. Connector (200) according to claim 9, characterized in that the spring elements (244) in a cross-sectional plane perpendicular to the insertion direction (222) are formed Ω-shaped.

11. Connector (200) according to claim 9 or 10, characterized in that sleeves (240) and spring elements (244) are integrally formed with each other to a spring housing (216).

12. Connector (200) according to at least one of the preceding claims, characterized in that on the housing (210) first latching means (230) and on each spring element (244) second latching means (246) are formed, which cooperating with the first latching means (230 ) Fix the spring elements (244) on the housing (210).

13. Connector (200) according to claim 12, characterized in that each first latching means (230) comprises an elastically resilient tab which rises in the insertion direction of the housing (210) and a recess (232), wherein each second latching means ( 246) comprises a detent which rises perpendicular to the direction of insertion (222) of the respective spring element (244) and in the recess (232) of the resilient tab (230) of the first locking means fits.

14. Connector (200) according to claim 13, characterized in that at least one of the tabs (230) of the first locking means of the housing

(210) has a different width than the remaining tabs (230).

15. Connector (200) according to at least one of the preceding claims, characterized in that from the housing (210) in the insertion direction (222) at least two, in particular three, spaced from each other

Latching pin (234) with respective latching lug (236) raise, which are designed to engage in a housing or plug-in interface, which carries to the electrical contact elements (214) of the connector (200) complementary contact elements.