DE19948454A1 - Foil conductor for electrical and electronic control devices used in vehicles, has coupling region with winding ferrite paths on spatially arranged conductor paths for inductive transmission on two main areas - Google Patents

Abstract

The foil conductor (2) has a coupling region (1) comprising of winding ferrite paths (3) on spatially arranged conductor paths (4) for inductive transmission on two main areas. The coupling region has a carrier portion for transferring electrical signals or electrical energy to or from an assigned counterpiece.

Description

The present invention is based on one according to the preamble of Main claim designed foil conductor with a counterpart defines the coupling area to be assigned.

Such foil conductors are provided by means of their coupling areas for the purpose of transmitting electrical signals and / or electrical Energy to create a releasable connection to a counterpart. By using such foil conductors, for. B. in a simple manner and Preformed circuit carriers for electrical / electronic Control units or preformed wiring harnesses are formed, which are at the Assembly quick and easy assemble or lay and over your Allocate coupling areas to corresponding counterparts. Because of their easy handling and space-saving and robust training are as areas of application in motor vehicles, in particular Instrument area, the headlining, the doors, the steering column module and to name electrical / electronic control units.  

EP 0 443 655 B1 is a preamble of the main claim Corresponding foil conductor with several coupling areas known. Each coupling area can be used for the purpose of Transmission of electrical signals and / or electrical energy, one assigned according to the executed counterpart. Everyone is there Coupling area assigned a housing, which cooperates with a appropriately trained housing of the counterpart plugged together becomes. For the transmission of electrical signals and / or electrical energy metallic conductor lines of the coupling area come under Spring action directly on the metal connector pins of the counterpart Investment. Such an assignment of coupling area and counterpart in Art However, a connector coupling does not only require a precisely small one Execution of tolerances in operative connection with each other upcoming components, their handling is time consuming and complicated. Especially with poorly accessible coupling points therefore there are often incorrect couplings, which ultimately leads to Failure of the transmission links in question.

The present invention is therefore based on the object Foil conductor with a counterpart defined to be assigned To create coupling area with simple and inexpensive Easy to set up even with poorly accessible Coupling points enabled.

According to the invention, the task is performed in the characterizing part of Main claim specified features solved.

An advantage of such a configuration is that all functions are fulfilled Components in the form of printed or laminated webs or Stretch areas are available directly on the film conductor, and a safe  Coupling to form a reliably functioning transmission link is guaranteed even with large tolerances.

Further advantageous refinements designed in this way Coupling areas of film conductors are specified in the subclaims. Using two exemplary embodiments shown in the drawings the subject of the invention explained in more detail, namely show

Fig. 1 in principle a coupling area of a film conductor without a carrier part according to a first embodiment

Fig. 2 shows in principle a second embodiment of the coupling area of a film conductor without a carrier part

Fig. 3 in principle a carrier part with a coupling area attached to it according to the first or second embodiment

Fig. 4 in principle a coupling area in association with a counterpart.

Similar components are provided with the same reference numbers.

As is apparent from the figures, the function fulfilled components consist of such a coupling region 1 of foil conductors 2 consisting essentially of coated surface on at least one major surface to adjacent Ferritbahnen 3 extending in spatial association, each having at least arranged in one turn of a coil conductor paths. 4 In order to be able to bring the coupling area 1 into a defined assignment with a counterpart, this is fixed on a carrier part 5 .

As can be seen in particular from FIG. 1, the coupling region 1 has three conductor paths 4 which are connected to one another in an electrically conductive manner via conductor bridges 6 . Each of the three flat conductor sections 4 is in turn applied spirally to form a plurality of turns on one of the two main surfaces of the film conductor 2 . The ferrite tracks 3, which are also applied flat, also run spirally, while maintaining a small insulation distance adjacent to the conductor paths 4 , so that a total of three winding arrangements are formed. The coupling region 1 therefore has three winding arrangements which are electrically connected to one another in order to form a coil. In order to arrive at a compact winding package, two of the three winding arrangements are each bent through 180 ° in accordance with a predetermined bending line 7 , so that the winding arrangements are combined in three layers one above the other. In order to be protected against short circuit or damage, the conductor paths 4 and the ferrite tracks 3 are covered by a protective layer consisting of insulating lacquer. In order to be able to carry out the predetermined bends more easily, the two bend lines 7 each have perforations in their course. The folding of the foil conductor 2 is of course carried out in such a way that the direction of current flow for the coil is retained. As can further be seen in particular from Fig. 1, the sheet conductor 2 may be both part of an electrical / electronic device as well as a component of a wire harness structure. As shown, for example, such foil conductors 2 are used in electrical / electronic devices or wiring harnesses of a door 9 or a steering column module 8 of motor vehicles, the end or branch points of these foil conductors 2 being designed accordingly as coupling area (s) 1 .

As is apparent in particular from Fig. 2, five conductor tracks 4 are applied evenly on the one major surface 21 and four conductor paths 4 flat on the other major surface 22 of the coupling region of the film conductor 1 2. The conductor paths 4 are each designed in the manner of an almost closed outer ring and the associated ferrite tracks 3 are each designed as completely closed inner rings. In order to connect the directly opposite conductor paths 4 of the two main surfaces 21 , 22 to one another in an electrically conductive manner, plated-through holes 10 are provided at corresponding points in the coupling region 1 . Each of the four conductor paths 4 which are connected to one another in pairs thus each form a winding arrangement consisting of two turns. The coupling region 1 therefore has four winding arrangements and a single winding to form a coil. In order to arrive at a compact winding package, the four winding arrangements, each consisting of two conductor paths 4, are bent by 180 ° in accordance with a predetermined bending line 7 , so that the winding arrangements or the individual winding are combined in five layers one above the other. Except for contact fields 11 which are not subject to change, the nine conductor tracks 4 and the nine ferrite tracks 3 are covered with a protective layer of insulating lacquer. Due to the multiple bending of the foil conductor 2 within the coupling area 1 , the corresponding contact fields 11 of the conductor paths 4 come into contact with one another in an electrically conductive manner, so that a continuous electrical connection between the nine conductor paths 4 within the compact winding package is ensured. Thus, the coupling region 1 , which is designed as a compact winding package, has a coil consisting of nine windings. In order to be able to carry out the predetermined bends more easily, the two bend lines 7 each have perforations in their course. The folding of the foil conductor 2 is of course carried out in such a way that the direction of current flow for the coil is retained. The foil conductor 2 can be part of an electrical / electronic device as well as part of a wiring harness structure. For example, the use of these foil conductors 2 in electrical / electronic devices or wiring harnesses of a door 9 or a steering column module 8 of motor vehicles is provided. The end or branch points of this foil conductor 2 are designed accordingly as coupling area (s) 1 .

Of course, a coupling area 1 to form a plurality of transmission links can also have a plurality of coils formed by conductor links 4 .

3 as is apparent especially from FIG., The support part 5 of the coupling region 1 integral part of a control unit housing. In this carrier part 5 , the film conductor 2 is only fixed with its end point designed as a compact winding package within a molded-in pocket 30 of the control unit housing. For the defined coupling with a counterpart, the carrier part 5 has position and holding means which come into operative connection with corresponding elements of the counterpart and are not shown in detail for the sake of simplicity.

As can be seen in particular from FIG. 4, the carrier part 5 is designed as a coupling housing to be handled separately. On the one hand, the film conductor 2, with its end point designed as a compact winding package, is accommodated within a pocket 30 in the carrier part 5 . On the other hand, the film conductor 2 with its further extension is led out of the pocket 30 of the carrier part 5 in the manner of a cable harness structure. For simple, defined coupling to a defined counterpart 14, the carrier part 5 has positioning means 12 and holding means 13 designed as latching elements. When coupling, the coupling area 1 need only be approximately assigned to the corresponding area of the counterpart 14 . That is, the coupling area 1 and the corresponding area of the counterpart 14 do not come into contact with one another but are assigned to one another without contact. Larger tolerances in the direction of assignment, as well as transversely thereto, can easily be tolerated without there being any disturbing impairments in the transmission quality of electrical signals and / or electrical energy between the coupling region 1 and the corresponding region of the counterpart 14 .

As can further be seen from FIG. 4, the coupling area 1 of the carrier part 5 has spring means 15 for its alignment when coupling with the corresponding area of the counterpart 14 . The spring means 15 are designed in the manner of leaf springs and are essentially provided as compensating elements. To the support member 5 on a support structure 16 z. B. the inner wall of a door 9 , the housing of a steering column module 8 , etc., this also has fastening means 17 designed in the manner of locking elements.

Claims (16)

1. Foil conductor with a counterpart defined to be assigned coupling area, which for the transmission of electrical signals and / or electrical energy to or from the counterpart has the function-fulfilling components in the correct position supporting part, characterized in that at least the function-fulfilling components of the coupling area ( 1 ) for the purpose Inductive transmission is embodied as conductor paths ( 4 ), which are applied directly to at least one of the two main surfaces ( 21 , 22 ) of the foil conductor ( 2 ) and are arranged in the form of at least one turn of a coil and run in spatial association with neighboring ferrite tracks ( 3 ). 2. Foil conductor with coupling area according to claim 1, characterized in that at least the conductor paths ( 4 ) of two turns are electrically connected to each other and are combined to form a coil having a plurality of turns. 3. Foil conductor with coupling area according to claim 1 or 2, characterized in that at least the conductor paths ( 4 ) of two turns are connected to one another in an electrically conductive manner via a conductor bridge ( 6 ). 4. Foil conductor with coupling area according to one of claims 1 to 3, characterized in that at least one conductor path ( 4 ) is arranged spirally to form a plurality of turns 5. foil conductor with coupling area according to one of claims 1 to 4, characterized in that at least the conductor paths ( 4 ) of two turns via two mutually abutting contact fields ( 11 ) are electrically conductively connected to each other. 6. Foil conductor with coupling area according to one of claims 1 to 5, characterized in that at least the conductor paths ( 4 ) of two turns are electrically conductively connected to one another via vias ( 10 ) and that the conductor paths ( 4 ) forming the turns of a coil both on one main surface ( 21 ) and also on the other main surface ( 22 ) of the film conductor ( 2 ). 7. foil conductor with coupling area according to one of claims 1 to 6, characterized in that by folding the foil conductor ( 2 ) within the coupling area ( 1 ) at least the conductor paths ( 4 ) of two turns can be electrically connected to one another and thus to one more Coils having turns are summarized. 8. foil conductor with coupling area according to one of claims 1 to 7, characterized in that to form a plurality of transmission paths, several coils are present within at least one coupling area ( 1 ) on the foil conductor ( 2 ). 9. foil conductor with coupling area according to one of claims 1 to 8, characterized in that on the support part ( 5 ) of the coupling area ( 1 ) and on the counterpart ( 14 ) with each other engageable positioning means ( 12 ) are present. 10. foil conductor with coupling area according to one of claims 1 to 9, characterized in that on the support part ( 5 ) of the coupling area ( 1 ) and on the counterpart ( 14 ) cooperating holding means ( 13 ) are present. 11. foil conductor with coupling area according to claim 10, characterized in that at least one of the holding means ( 13 ) is designed as a shielded magnet. 12. Foil conductor with coupling area according to claim 10, characterized in that at least two holding means ( 13 ) are designed as locking elements which can be brought into operative connection with one another. 13. foil conductor with coupling area according to one of claims 1 to 12, characterized in that the carrier part ( 5 ) of the coupling area ( 1 ) has fastening means ( 17 ) for stationary coupling to a support structure. 14. Foil conductor with coupling area according to one of claims 1 to 13, characterized in that the carrier part ( 5 ) has spring means ( 15 ) for alignment with the counterpart ( 14 ). 15. Foil conductor with coupling area according to one of claims 1 to 14, characterized in that shielding means are present at least on the carrier part ( 5 ) to prevent malfunctions due to external influences. 16. Foil conductor with coupling area according to one of claims 1 to 15, characterized in that the support part ( 5 ) and the counterpart ( 14 ) are associated with each other in operable connection cooperating housing parts.