DE29923501U1 - Housing for receiving an electrical assembly with a pressure compensation device - Google Patents

Description

Heilbronn, July 27, 2000 FTP/H-Bü-P 303 229

Housing for accommodating an electrical assembly with a pressure compensation device

The invention relates to a housing for accommodating an electrical assembly with a pressure compensation device according to the preamble of claim 1.

Housings that house electronic components must be designed to be moisture-proof so that no corrosion can occur on the component, particularly on the contacts. Pressure compensation elements are used to adjust the pressure inside the housing to the pressure outside the housing, which is important for the correct functioning of some components, particularly sensors, but also prevents moisture, particularly water vapor, from penetrating and condensing due to a negative pressure building up inside the housing, for example due to the permeability of the material, cracks in the housing, particularly at the joints between two housing halves, or similar problems.

A housing of the generic type with all the features of the preamble of claim 1 can be found in DE 84 08 092 U1. The housing shown there has a pressure equalization device for air inside the housing that is heated by the assembly and causes excess pressure, in that housing through-openings are provided in a connector strip from the inside of the housing into the connector area and inside the connector through-openings from the connector area to the connector interior. A pressure-tight sealing element is provided between the connector and the connector area. Pressure equalization takes place via a connection area of the supply line in which, according to page 6, last paragraph, the air is led from the connector interior into a supply line nozzle that is designed in such a way that it allows the air heated inside the housing to escape unhindered into the surrounding air. The supply line nozzle must therefore be open to the housing environment so that the air can escape.

A disadvantage of this design, however, is that air and thus moisture can penetrate into the connector interior and from there possibly even into the housing interior to the module through the supply line nozzle, which is open to the housing environment, in particular in the event of a negative pressure inside the housing.

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This housing is only designed for overpressure inside the housing. A drop in temperature inside the housing as well as a change in air pressure in the surrounding area can also lead to a negative pressure in the housing, whereas the housing known from DE 84 08 092 U1 does not guarantee sufficient protection for the electronic assembly to be housed.

Another housing can be found in DE 32 48 715 A1, for example. The housing shown there for accommodating an electrical assembly provides ventilation openings in the cover of the housing as a pressure equalization device for pressure equalization between the interior of the housing and the surroundings of the housing, the assembly in this example being protected against moisture penetrating through the ventilation openings by a membrane arranged inside the housing. As can be seen in Figures 2 and 3 of DE 32 48 715 A1, the assembly has a plug area formed on the outside of the housing with contact elements leading through the housing, the contact elements being connected to the assembly inside the housing and being connected to an electrical connection cable outside the housing via a plug (not shown in detail). Inserting the membrane and sealing it are complex. In addition, with this design, moisture can collect inside the housing between the ventilation openings and the membrane.

A housing with a different pressure equalization element can be found, for example, in DE 91 07 992 U or DE 42 34 919 C2 in the form of an opening in the housing wall, which is covered with a water-repellent but air-permeable woven fabric cover. The applicant's unpublished DE 197 08 116 teaches a two-layer film arrangement, with one of the films also being made of water-repellent woven fabric, also known under the names Goretex or Sympatex. An accumulation of moisture in the housing is therefore impossible. The disadvantage of these pressure equalization elements is that the woven fabric cover used is expensive and has to be attached in additional processing steps, so that processing errors can occur, in particular a gap-free attachment through which moisture can still penetrate.

Furthermore, DE 195 33 723 A1 describes a housing arrangement with a plug connection in which the plug area is hermetically sealed using a sealant. However, pressure equalization is not possible in this way.

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DE 38 40 678 A1 also shows a connector with a vent channel through which the air between the connector and the housing escapes when the connector is inserted. However, pressure equalization is no longer possible after the connector has been attached.

The object of the invention is to present a further housing for accommodating an electrical assembly, which enables pressure equalization in an analogous manner via the plug area, but offers even more reliable protection against moisture.

This object is achieved by the characterizing features of claim 1. Advantageous further developments can be found in the subclaims.

The basic idea of the invention is that, starting from the interior of the plug, an electrical supply line with a pressure-elastic outer insulation jacket and a cavity remaining between the wires is used in order to enable pressure equalization with the housing environment by adjusting the volume of this cavity.

This volume adjustment of the cavity takes place via the pressure-tight outer insulation jacket, which is sealed against the housing environment and is itself impermeable to air and moisture, but pressure-elastic, which in turn enables pressure equalization from the connector interior via the connector through-openings into the connector area and from there via the connector through-openings with the housing interior.

The cavity in the supply cable is inevitable in almost every connecting cable due to the cylindrical shape of both the outer insulation jacket and the insulated wires. Otherwise, by choosing the cross-sectional size of the outer insulation jacket, it can be made so large that a particularly large cavity remains between the wires. If, for example, the outer insulation jacket is made by overmolding the wires, a hollow cylindrical elastic tube can be inserted to form this cavity and overmolded by the outer insulation jacket.

The plug is preferably overmolded around the connecting cable and the outer insulation of the connecting cable is stiffened in the area overmolded by the plug so that the cavity in the connecting cable cannot be constricted when the plug is overmolded.

The invention will be explained in more detail below using embodiments and figures. Brief description of the figures:

Figure 1 side section through the plug and the moisture-proof

loose housing in the connector area

Figure 2 partially cut open plug with view into the plug

interior and the supply line

Figure 1 shows a side section through the moisture-impermeable housing 1, the plug 2 and the supply line 3. The housing consists of a housing interior 14 in which an electrical assembly 12 is arranged, protected from the housing environment 18, in particular from moisture. The housing interior 14 is enclosed on all sides by the housing, although only the section directed towards the plug area 15 is shown in Figure 1. The plug area 15 is formed on the outside of the housing and in this example has a protruding wall 16 in the form of a plug shaft. Contact elements 13 are led through the housing 1, for example as an insert part overmolded with the housing material, which connect the electrical assembly 12 to the plug area 15. In addition, at least one housing through-opening 11, for example in the form of a bore or a hollow cylindrical insert part, is introduced from the housing interior 14 into the plug area 15. Through these housing opening(s) 11, pressure equalization initially takes place between the housing interior 14 and the connector area 15.

The plug area 15 is closed by the plug 2 by inserting the plug with its central area 21, which is precisely adapted to the plug area 15, into the plug area 15, which in this example is shaft-shaped. The plug 2 thus shields the plug area 15 from the housing environment 18. For the pressure-tight seal between the plug area 15 and the plug 2, an outer shield 22 is provided on the plug 2, which additionally encloses the wall 16 of the plug area 15 on the outside. In addition, to seal the plug area 15 between the plug 2 and the housing 1 against moisture to the outside, a sealing element 4 is provided in a press fit between the shield 22 of the plug and the wall 16 of the plug area and/or between the central area 21 of the plug and the wall 16 of the plug area, the latter variant being shown in Figure 1.

When inserting the plug 2 into the plug area 15, connection elements 23 of the plug 2 engage the contact elements 13 in the plug area 15, whereby

the connection elements 23 are fastened in the plug interior 26 via locking elements 29 and are electrically connected to the wires 32 of the supply line 3. The connection elements 23 thus ensure the electrical functions of the assembly 12 inside the housing 1, i.e. they supply the assembly 12 with current and voltage, for example, and enable signal transmission. The connection elements 23 can be seen particularly well in a conceivable embodiment in Figure 2.

The plug 2 in turn has at least one plug through opening 24 from the plug area 15 into the plug interior 26, so that pressure equalization is possible there. At least two alternatives are shown, namely the use of an opening 241 that also serves as a receiving chamber for the locking element 29 of the connection element 23, or the opening 242, in which the connection element 23 itself reaches the plug area 15, provided the latter has sufficient space for pressure equalization. In addition, the formation of a channel 28 is shown in Figures 1 and 2, which is either connected to the plug through opening 24 (Fig. 1) or forms it itself (Fig. 2). Of course, other alternative designs are also possible.

The supply line 3 opens into the plug interior 26, with the individual wires 32 of the supply line 3, which are insulated from one another by insulation 33, being led out of an outer insulation jacket 31 to the associated connection elements 23. There is an air-permeable connection between the plug interior 26 and the cavity 34 within the insulation jacket 31 of the supply line 3, which in the simplest case is formed by the insulation jacket 31 protruding into this plug interior 26. The insulation jacket 31 is impermeable to air and moisture, but is designed to be pressure-elastic, as is again illustrated in Figure 2 by a section through the connection cable 3. The pressure-elastic insulation jacket 31 thus enables the volume of this cavity 34 to be adjusted to counteract the pressure difference between the plug interior 26 and the housing environment 18 in order to equalize the pressure.

Preferably, the otherwise elastic outer insulation jacket 31 is stiffened in the region in which it is attached to the plug 2, for example thickened (35) or reinforced by an enveloping element, so that constriction of the cavity 34 by the preferably molded-over plug region 25 is prevented.

List of reference symbols :

I Housing of the electrical assembly

I1 Housing through hole 12 Electrical assembly

13 contact elements

14 Housing interior

15 Plug area

1 6 protruding wall on the housing in the connector area

1 7 Locking element on the housing 18 Housing environment

2 plugs

21 Middle range

22 Shielding which surrounds the outside wall of the connector area

23 connection elements on the plug for contacting the contact elements in the plug area

24 Connector through-opening from the connector area to the connector interior in variants 241 and

25 Connection area between plug and supply cable

26 Connector interior

27 Locking element on the plug outside

28 Notch in the middle area from the plug area to the opening in the plug

29 Locking element for locking the connection elements in the plug

3 Supply line

31 outer pressure-elastic insulation jacket

32 wires of the supply line

33 Isolation of the wires from each other

34 voids that form between the wires within the outer insulation sheath

35 Reinforcing the supply cable in the connection area of the plug

4 Sealing element

Claims (5)

1. Housing ( 1 ) for accommodating an electrical assembly ( 12 ) with a pressure compensation device, a) the housing has a plug area ( 15 ), contact elements ( 13 ) are led from the assembly ( 12 ) in the housing interior ( 14 ) through the housing ( 1 ) into the plug area ( 15 ) and are connected in the plug area via a plug ( 2 ) to an electrical supply line ( 3 ), b) at least one housing through-opening ( 11 ) is arranged from the housing interior ( 14 ) into the plug area ( 15 ), c) a pressure-tight sealing element ( 4 ) is provided between the plug ( 2 ) and the plug area ( 15 ), d) the plug ( 2 ) has at least one plug through opening ( 24 , 241 , 242 , 28 ) from the plug area ( 15 ) to the plug interior ( 26 ) and e) pressure equalization takes place from the interior of the plug ( 26 ) via a connection area of the supply line ( 3 ), characterized in that a) the plug ( 2 ) and the supply line ( 3 ) are pressure-tightly sealed against the housing environment ( 18 ) in the connection area, b) the supply line ( 3 ) has a pressure-elastic outer insulation jacket ( 31 ) and insulated ( 33 ) wires ( 32 ) guided therein, c) a cavity ( 34 ) remains within the outer insulation jacket ( 31 ) and this cavity ( 34 ) is connected to the plug interior ( 26 ) in an air-permeable manner, d) so that the pressure equalization by means of the pressure-elastic outer insulation jacket ( 31 ) takes place by a volume adjustment of this cavity ( 34 ). 2. Housing according to claim 1, characterized in that the cavity ( 34 ) in the outer insulation jacket ( 31 ) between the wires ( 32 ) is formed by a pressure-elastic hollow cylindrical tube which is open towards the plug interior ( 26 ). 3. Housing according to claim 1 or 2, characterized in that the plug ( 2 ) is molded ( 25 ) around the supply line ( 3 ) in the connection area and the outer insulation jacket ( 31 ) of the supply line ( 3 ) is stiffened ( 35 ) in the connection area. 4. Housing according to one of the preceding claims, characterized in that the plug ( 2 ) is locked to the housing ( 1 ) via locking elements ( 17 , 27 ). 5. Housing according to one of the preceding claims, characterized in that the supply line ( 3 ) has insulating material-coated stranded wires ( 32 ) and within these stranded wires ( 32 ) the air-permeable cavities ( 34 ).