DE4229727A1 - Vehicle electrical switch or control device - uses PCB with flexible part rolled into coil and accommodated in insulating jacket or envelope - Google Patents

Abstract

The device has at least one PCB (11) which is flexible over part of its length carrying a printed circuit and electrical/electronic components (29) with a multi-pin contact terminal (12) fitting through the wall of the housing (10) of the device. The flexible part (31) of the PCB is tensioned so that it rolls up into a coil, the rolled length being enclosed in an insulating sleeve (35). The tensioning may be provided by thermal stressing of the flexible part of the conductor foil. USE/ADVANTAGE - For vehicle switching or control unit with protection against moisture ingress, corrosion and vibration. Reduced overall length of device for relatively large surface area circuit.

Description

State of the art

The invention is based on an electrical device, in particular a switching or control device for motor vehicles, according to the genus of the main claim.

Such electrical devices are in one large variety of embodiments known. Especially at Use in automotive electronics are under exposed to various environmental influences, such as B. moisture, penetrating salt, vibrations and much more, against which they are resistant should. At the same time, the space requirement of such devices must be as possible be small, since often only a limited installation space for ver is standing. It also becomes as simple and easy as possible Desired cost-effective construction. Nevertheless, the electrical device a partly very extensive and complex electronic Record circuit, especially with regard to the mechani loads (vibration resistance) meets the requirements that through use in a motor vehicle (e.g. when installed in the engine space) occur.

Advantages of the invention

The electrical device with the distinctive features of the head In contrast, has the advantage that a particularly space Saving structure is given because the circuit board, which is an electro African circuit carries, at least over most of its length flexibly trained and rolled up in a housing is arranged. The resulting curvature of the circuit board ver this borrows - despite the flexible design - a relatively high Stability. The electrical device according to the invention stands out through a simple, compact structure, but can still have complex, complex circuits that, for example, on a printed circuit board which is a very big reason has area. The dimensions of the circuit board, especially the Length, can be a multiple of the length of the case be.

Further advantages of the invention emerge from the subclaims and the description.

drawing

An embodiment of the invention is explained in more detail in the following description and drawing. The latter shows in Fig. 1 a cross section through an electrical device in simplified representation and in Fig. 2 shows a detail of the electrical device according to Fig. 1 in an enlarged view.

Description of the embodiment

The electrical device shown in FIGS. 1 and 2 essentially has a housing 10 , a circuit board 11 which carries an electronic circuit, and a power strip 12 . The housing 10 consists of a housing base body 14 , a side wall (not shown) and an end wall 16 . The basic housing body 14 is composed of a base part 17 , a side wall 18 and a rear wall 19 and a cover 20 , and is made of plastic as a single, coherent component. The transition 21 between rear wall 19 and cover 20 is rounded, the radius corresponds approximately to half the distance between cover 20 and base part 17 . In the area of the rear wall 19 , the base part 17 is extended so that a fastening section 22 is formed which has a bore 23 which serves to fasten the housing at the installation site. The also made as a single part made of plastic - not shown - side wall is so verbun with the housing body 14 , the z. B. glued or ultrasonically welded, that it is opposite its side wall 18 approximately parallel.

The open side of the housing 10 is closed by the end wall 16 ver. This has an opening 25 into which the plug connector 12 is inserted. The end wall 16 is provided on the inside with latching tongues 26 which cooperate with appropriately trained latching lugs 27 in the housing base body 14 . By means of the locking lugs 27 and locking tongues 26 , the basic housing body 14 and the side wall are firmly but releasably connected to the end wall 16 . To fasten the housing at the installation location, the end wall 16 in the region of the base part 17 has an attachment section 28 which runs approximately parallel to the latter and points outwards.

The circuit board 11 , which carries an electronic circuit, of which only a discrete component 29 is shown, is arranged in the interior of the housing. The circuit board 11 is composed of a rigid connecting circuit board 30 and a flexible conductor film 31st The flexible conductor foil 31 is rolled up approximately in a spiral. A section 32 of the conductor film 31 extends to the connecting circuit board 30 and is attached to the top, z. B. glued. The connecting circuit board 30 is connected to the plug strip 12 , which is known per se, and which carries a multiplicity of plugs 36 which are arranged next to one another and in two rows below one another. For the electrically conductive connection to the connection circuit board 30 , the contact pins 33 of the plug 36 penetrate the connection circuit board 30 and are soldered to the latter. In order to isolate the spiral-wound flexible conductor foil 31 , it is surrounded by an insulating sleeve 35 . This insulating sleeve 35 is approximately tubular and closed on one side. It is pulled from the free side of the flexible conductor foil 31 over this, so that both the top and bottom of the conductor foil 31 are covered. The open end of the insulating sleeve 35 also receives the connection circuit board 30 , and is connected to it in the edge region of the connector strip 12 , for example glued, welded or clamped. The entire circuit board 11 or the connecting circuit board 30 and the flexible circuit film 31 are covered over their entire length on their top and bottom by the insulating sleeve 35 , so that no short circuits can occur even when the flexible circuit film 31 is rolled up. Instead of the tubular design of the insulating sleeve 35 , this can also consist of a strip-shaped upper part 35 a and a likewise strip-shaped lower part 35 b. During assembly, the stretched flexible conductor film 31 is placed on the lower part 35 b and covered with the upper part 35 a. Upper part 35 a and lower part 35 b of the insulating sleeve 35 protrude beyond the conductor foil 31 and are welded to one another in their edge regions. In the area of the connector strip 12 , the insulating sleeve 35 is expanded accordingly and also tightly connected to the connector strip 12 .

The insulating sleeve 35 can be a tubular or strip-shaped electrically insulating (plastic) film, which is smooth, or can be provided with spacer elements, for example air nubs. These spacer elements prevent two adjacent spiral layers from lying directly against one another on the rolled flexible conductor foil 31 , so that effective heat dissipation is possible. To improve the electromagnetic compatibility (EMC) of the circuit, the insulating sleeve 35 can also be metallized on the outside, which means that corresponding protective measures on the housing can be reduced or eliminated entirely.

The flexible conductor film 31 is treated in the production so that it is biased on one side, on its top and bottom, so that it automatically rolls up in the relieved state. This one-sided pre-tensioning of the flexible conductor foil can take place, for example, by a targeted heat or cold treatment of the top or bottom during manufacture. It is also possible to form the flexible conductor foil 31 from at least two superimposed layers which are firmly connected to one another, in which case, for example, one of the two layers is pre-stressed by stretching before binding. If this stretching of one of the layers takes place in the elastic region of the material, this layer contracts after the connection, so that the flexible conductor foil 31 curves or rolls up.

The flexible conductor foil 31 can also consist of a carrier foil to which a solid, thin layer is applied, which contains the conductor tracks of the circuit. This solid, thin layer has in the transverse direction, at a short distance from each other running defined linear break or break points, so that the flexible conductor film 31 can be rolled up.

To assemble the electrical device, the end wall 16 with the circuit board 11 attached to it is attached to the open side of the housing 10 , so that latching lugs 26 and latching tongues 27 lie opposite one another. The connector 12 connected to the end wall 16 of the rolled-up printed circuit board 11 is introduced into the interior of the housing 10 . By pressing in the end wall 16 or the latching tongues 26 , it locks with the latching lugs 27 , so that the housing 10 is closed. These latching connections also allow easy opening of the housing, so that the circuit board 11 can be pulled out of the housing 10 for maintenance or for subsequent adjustment. To seal the housing 10 , a circumferential groove can be provided, into which a corresponding sealing ring is inserted. It is also possible to tightly glue the end wall 16 to the basic housing body 14 , but this makes subsequent opening of the housing 10 more difficult.

In contrast to the assembly of the electrical control device described above, the end wall 16 can also be attached to the housing 10 or the housing base body 14 without a plug connector 12 and printed circuit board 11 . Since the rolled-up circuit board 11 is much larger in diameter than the opening height of the opening 25 , the flexible conductor film 31 is pulled apart and with its free end through the opening 25 into the interior of the housing 10 . Due to the one-sided prestressing of the flexible conductor foil 31 , it is spirally wound up after being inserted into the interior of the housing 10 . When the flexible conductor foil 31 has been completely rolled up, the connecting circuit board 30 and the connector strip 12 can be attached to the opening 25 and connected tightly to the latter.

In contrast to the previously described, the printed circuit board 11 can also consist entirely of a flexible printed circuit film 31 . The outer free end of the flexible conductor foil 31 wound spirally in the final state is then connected directly to the connector strip 12 or the contact pins 33 . The end of the flexible conductor film 31 is then advantageously placed flat on the back of the connector strip 12 and glued to it, for example. The contact pins 33 are then not bent at right angles, but rather only as short pins which penetrate the connector strip 12 .

The discrete components 29 are preferably arranged in rows which run approximately parallel to the end wall 16 (from side wall to side wall). In addition, they are expediently directed so that their longitudinal extension also extends in this direction. Furthermore, it is advantageous to carry out the assembly or the layout of the printed circuit board 11 such that wide discrete components 29 are arranged relatively close to the section 32 of the printed circuit board 11 , ie in areas of the printed circuit board 11 with a small curvature.

By rolling up the circuit board 11 or the resulting curvature, the vibration resistance is very high, that is, the mechanical strength is much greater than with flat arranged or folded flexible circuit boards, so that a compact, mechanically loadable circuit arrangement is possible without the flexible part 31 of the circuit board 11 must be supported, guided or hung up. Due to the insulating sleeve 35 , the risk of a short circuit due to unwanted contact between adjacent circuit board sections is very low or excluded. When using spacer elements, good heat dissipation is also ensured.

The printed circuit board 11 with the plug connector 12 can also be used in another device, since a closed assembly is formed by the insulating sleeve 35 . It is advantageous if this receiving device has a housing filled with liquid.

In order to form the housing 10 shielding, ie to improve the electromagnetic compatibility (EMC) of the circuit, its plastic parts can be coated on the inside or outside with a metallic or an electrically and / or magnetically well-conductive coating. The housing 10 and its end wall 16 can also be made of aluminum injection molding or another electrically and / or magnetically conductive material (eg a suitable metal) if the electromagnetic compatibility is particularly high. In addition, the connector strip 12 can also consist of an electrically and / or magnetically conductive material (eg a suitable metal), the connectors 36 being carried out in an insulated manner. It is also possible to provide the connector strip 12 with a conductive layer (metallization), with an (insulating) area being left out of the connector 36 . Furthermore, the housing 10 can be filled with a suitable liquid for damping and / or insulation.

Claims (13)

1. Electrical device, in particular switching or control device for motor vehicles, with an at least over part of its length flexible circuit board ( 11 , 30 , 31 ) with electrical / electronic components ( 29 ) which are connected by a circuit, and which has a multipole Plug contact element ( 12 ) is assigned, which penetrates a housing ( 10 ) accommodating the printed circuit board, characterized in that the flexible part ( 31 ) of the printed circuit board ( 11 ) is prestressed over the major part of its length in such a way that it rolls up approximately in a spiral and that the printed circuit board ( 11 ) is accommodated in an insulating sheath ( 35 ) at least over the rolled-up part of its length. 2. Electrical device according to claim 1, characterized in that the flexible part ( 31 ) of the circuit board ( 11 ) is biased by one-sided heat or cold treatment of one of its flat sides during manufacture. 3. Electrical device according to claim 1, characterized in that the flexible part ( 31 ) of the printed circuit board ( 11 ) is constructed in several layers, at least one of the layers being stretched before the individual layers are joined to produce the pretension. 4. Electrical device according to claim 1, characterized in that the flexible part ( 31 ) of the printed circuit board ( 11 ) is constructed in several layers, the layer receiving the conductor tracks having linear kinks. 5. Electrical device according to one of claims 1 to 4, characterized in that the insulating sleeve ( 35 ) is approximately tubular. 6. Electrical device according to one of claims 1 to 5, characterized in that the insulating sleeve ( 35 ) from a strip-shaped upper part ( 35 a) and a strip-shaped lower part ( 35 b) is composed. 7. Electrical device according to one of claims 1 to 6, characterized in that the insulating sleeve ( 35 ) with the plug contact element ( 12 ) is connected. 8. Electrical device according to one of claims 1 to 7, characterized in that between the flexible part ( 31 ) of the circuit board ( 11 ) and the plug contact element ( 12 ), a rigid connection circuit board ( 30 ) is formed. 9. Electrical device according to one of claims 1 to 8, characterized in that a section ( 30 ) of the printed circuit board ( 11 ) with a the plug-in contact element ( 12 ) receiving part ( 16 ) of the housing ( 10 ) is connected flat. 10. Electrical device according to one of claims 1 to 9, characterized in that strongly heating components ( 29 ) are arranged on that section ( 30 ) of the printed circuit board ( 11 ) which with the plug-in contact element ( 12 ) receiving part ( 16 ) of the housing is connected. 11. Electrical device according to one of claims 1 to 10, characterized in that the plug-in contact element ( 12 ) receiving part of the housing ( 10 ) is designed as an end wall ( 16 ). 12. Electrical device according to one of claims 1 to 11, characterized in that the insulating sleeve ( 35 ) is provided on its outside with an electrically and / or magnetically conductive layer. 13. Electrical device according to one of claims 1 to 12, characterized in that the housing ( 10 ) is a component of an electrical device receiving further device.