WO2011072827A1

WO2011072827A1 - Electric connector and method for producing an electric connector

Info

Publication number: WO2011072827A1
Application number: PCT/EP2010/007550
Authority: WO
Inventors: Oliver Grabherr; Anton Huber; Stefan Stoeckl; Anton Fuchs
Original assignee: Bayerische Motoren Werke Aktiengesellschaft
Priority date: 2009-12-19
Filing date: 2010-12-10
Publication date: 2011-06-23
Also published as: EP2514044B1; DE102009059679A1; EP2514044A1

Abstract

The invention relates to an electric connector (10), in particular an electric plug contact having a contact region (10a) for producing an electrically conductive connection, a sealing region (10b) for producing a sealed connection to a housing that at least partially surrounds the electric connector (10), characterized in that the electric connector (10) has at least in some sections a smaller cross section in the sealing region (10b) than in the contact region (10a). The invention further relates to a method for producing such a connector.

Description

Electrical connection and method for making an electrical connection

The present invention relates to an electrical connection, in particular an electrical plug-in contact having a contact region for producing an electrically conductive connection and a sealing region for producing a sealing connection, to a housing which at least partially surrounds the electrical connection, and to a method for producing this electrical connection ,

Nowadays, electrical components that can be connected via contact elements with other electrical components, placed in a plastic housing. These components are produced in mass production, wherein the basic electrical construction unit, for example an electrical coil, is encapsulated with its connection contacts with a plastic, which thus simultaneously forms the enclosing housing. The terminal contacts then extend outwardly from the interior of the housing and are completely enclosed by the housing wall at the exit point from the housing. These connection contacts thus represent the electrical connection of the coil located inside the housing to the outside.

However, these electrical components have the disadvantage that, despite the tight enclosure of the metal contacts through the plastic housing the Exit point of the connection contacts is leaking. This leakage is defined in terms of gaseous media by an air leakage rate. Also

However, enclosures with a high density and consequently a good air leak rate allow the leakage of oil or other liquid media.

Capillary action supported the leakage effect, so that, for example, oil or corrosive water can get past the outlet points of the connections in the interior of the housing and there leads to corrosion effects on the electrical components. It is also conceivable that corrosive liquids emerge from the housing interior along the Lackagepfades at the exit points and penetrate into electrically connected neighboring components. Such constructions are therefore unsuitable when low air or oil leakage is required.

This is especially true for the use of electromagnetic valves, which are housed in a plastic housing and are used as diverter valves of a turbocharger. The venting of the crankcase takes place directly into the exhaust tract of an engine. For motors with

Exhaust gas turbochargers, the exhaust gas is used to operate the turbine of the turbocharger. This leads to an oil wetting of the interior of the electric diverter valve. Due to long running times of the engine as well as by temperature fluctuations, leakage paths result in the

Diverter valve, which has a plug contact with the

Diverter valve is connected to a wiring harness at the

Wire harness along to the engine control unit can run. This has the consequence that corrosion damage to electrical components can take place and, moreover, due to this also initially uninvolved, electrical components are also affected by leakage currents or short circuits.

It is therefore an object of the present invention to provide an electrical connection of the type mentioned in the introduction, which overcomes the disadvantages of the prior art and a method for producing a specify such electrical connection. This object is achieved by a device or a method having the features of the main claims. Particularly preferred embodiments and modifications of the invention are the subject of the dependent claims, which are based on the main claims.

According to the invention, an electrical connection, in particular an electrical plug-in contact, a contact region for producing an electrically conductive connection and a sealing region for producing a sealed connection to a housing which at least partially surrounds the electrical connection. Furthermore, the sealing region may at least partially have a smaller cross section than the

Contact area. This results in the advantage that in the sealing area only relatively smaller surfaces are sealed relative to the housing and thereby the leakage path is reduced.

Furthermore, a sealing part may be provided in the sealing region, which completely surrounds the sealing region in its longitudinal direction at least in sections and in its circumferential direction.

In addition, a holding region, which is connected to the contact region via the sealing region, may be provided, wherein the sealing region is formed from at least one web element, for connecting the contact region to the holding region. This results in the advantage that the cross-section in the sealing region of the electrical connection can be reduced to a minimum, whereby the risk of the formation of leaks is almost eliminated.

Furthermore, a protective part may be provided which is positively and / or non-positively connected with the sealing part and thereby completely surrounds the sealing part in the circumferential direction. In addition, the housing may positively and / or non-positively in connection with an outer peripheral portion of the protective part, wherein the protective part has a higher and / or same melting temperature as the housing and the melting temperature of the sealing part is lower than the melting temperature of the protective part.

In a further aspect, the invention comprises a method for producing an electrical connection, comprising the steps of: producing a sealing region and a contact region in an electrically conductive material, in particular by means of a stamping method, applying a sealing part in the sealing region, wherein the sealing part has a first elastic material value comprising applying a protective part having a second elastic material value to the sealing part and applying or generating a housing which at least partially surrounds a peripheral region of the protective part and at least partially surrounds the electrical connection. Furthermore, the method may be characterized in that the first elastic material value is lower than the second elastic material value, so that the sealing part is softer than the protective part.

Furthermore, the method may be characterized in that the sealing part is applied by means of an injection molding process.

In addition, the method may be characterized in that the protective part is positively and / or non-positively connected with the sealing part in connection.

In addition, the method may be characterized in that the housing is applied by means of a second injection molding process.

Furthermore, the method may be characterized in that the melting temperature of the protective part higher or equal to the Melting temperature of the housing is, wherein the melting temperature of the sealing part is lower than the melting temperature of the protective part.

In summary, the advantages of the present invention will be mentioned below. Since the sealing part used is made of a softer, i. more elastic material is constructed as the protective part or the housing, it may thermal expansions of the electrical connection

compensate without a leakage path between the terminal and the protective part or the housing is released. To avoid the soft seal, which has a low melting and / or

Having Vergießtemperatur point, is softened during the later housing spraying, the protective part is provided, which during the

Casting process of the housing acts as a thermal insulator. As a result, the preservation of the shape of the sealing part and its position in the sealing area can be ensured in a particularly simple manner. The heat transfer to the sealing part, during the housing to be cast, is prevented by the protective part long enough so that the seal is applied thermally lower. If the protective part and the housing are made of the same material, it can be ensured in a particularly simple manner that a particularly good thermal fusion of the housing with the outer peripheral region of the protective part

Connection of the two parts is achieved.

An exemplary embodiment of the invention is explained in more detail below with reference to the figures, wherein the figures show by way of example, schematically and not by way of limitation:

Figure 1 a is a plan view of a plug assembly with an electrical connection according to the invention;

FIG. 1b shows a cross section through the electrical connection in the sealing region along the section line AA from FIG. 1a; a perspective view of a connector assembly with electrical connections according to the invention; a perspective view of the protective part, a perspective view of a connector assembly with electrical connections according to the invention, wherein the protective part is applied, and a perspective view of a connector assembly with electrical connections according to the invention, wherein the

Housing is applied.

FIG. 1 shows a plan view of a plug arrangement with two electrical connections 10 according to the invention. Each electrical connection 10 has a substantially elongated, flat external shape and extends longitudinally along the longitudinal axis X, which is represented by the arrow shown in FIG , The electrical connection 10 has a contact region 10a for producing an electrically conductive connection to another electrical component. Here is the

electrical connection made by mechanical contact. In this mechanical contact, the contact region 10a touches an electrically conductive region of the other component, for example a line or a cable. Immediately following the contact area 10a follows

Seal portion 10b, which connects the contact portion 10a with a holding portion 10c. The connection 10 is fastened to a carrier part 4 via the holding region 10c. The carrier part 4 may be a structural component in the form of a circuit board or a holding frame of an electrical element, for example an electrical coil. The coil windings are conductively connected to the electrical terminals 10. In the sealing region 10b, the electrical connection 10 has a constriction of the cross section, as shown in FIG. 1a. This constriction involves two web elements 12 which connect the contact region 10a to the holding region 10c. The length of the web elements 12 does not have to correspond completely to the length of the sealing region 10b, but may be shorter or longer. In other words, the

Sealing region 10 b may comprise 12 regions of non-constricted cross-section of the electrical connection 10 on both longitudinal ends of the webs. Between the longitudinally extending X.

Web elements 12 of a terminal 10 are openings 15 are provided. In this embodiment, the outbreaks 15 in the form of

Long hole bores formed. In further, not shown

Embodiments, the outbreaks 15 as a circular

Holes or be designed as outbreaks with angular cross-sectional shape. The outbreaks 15 can be provided in all embodiments optionally as a blind hole or as a through hole.

In a further, not shown embodiment of the present invention, optionally only a single web 12 may be provided for connection of the contact region and the holding region or a plurality of more than two webs 2. In order to find the appropriate number of connecting webs 12, the Carry out professional experiments. It is desirable to provide as few webs 12 as possible with as small a cross section as possible in order to prevent leakage paths as well as possible. On the other hand, the webs 12 must meet the requirements of the electrical conductivity, without permissible heating in the webs 12 are exceeded. In other words, the cross section of the webs 12 and their number must be chosen sufficiently large, so that a required current of a predetermined strength can flow through it, without the webs 12 inadmissible to heat or even destroy. A sectional view along the section line AA of Figure 1a is shown in Figure b. It can be seen that the webs 12 have a circular cross-sectional shape. In further, not shown embodiments of the present invention, however, the webs 12 may also have an oval, triangular or polygonal cross-sectional shape. However, circular or oval cross-sectional shapes are preferred, since they represent an optimum in the protection against leakage.

FIG. 2 a shows a plug arrangement according to the invention with electrical connections 10 according to the invention in a perspective view. In the sealing region 10b of the electrical connections 10, a sealing part 11 is provided. This sealing member 11 is in the form of a soft, i. elastic plastic seal formed. In this case, a polyamide sealing material may preferably be used.

By way of example and not limitation, in FIG. 2 a the sealing region 10 b is formed in such a way that the web elements 12 extend over a cross-sectional area of the contact region 10 a, in a transverse direction of the terminal 10, which is substantially perpendicular to the longitudinal direction X,

protrude. Between two web elements 12 of a terminal 10 at least one outbreak 15 is provided. Due to this eruption, the sealing region 10b has a smaller cross-sectional area than the

Contact area 10a. The sealing part 11 completely surrounds the sealing area 10b of the electrical connections 10 in the circumferential direction. In

Longitudinal direction of the electrical connection, the sealing member 11 extends only partially over the sealing region 10b. In a further, non-illustrated embodiment of the invention, the sealing part 11 can extend completely over the sealing region 10b also in the longitudinal direction X of the electrical connection and thereby also cover edge zones of the contact region 10a or of the holding region 10c. FIG. 2b shows a protective part 13 in a perspective view. The protective part 13 has a recess 13b which extends through the entire component and consequently gives the protective part 13 a frame-like shape. The shape of the inner recess 13b is exemplary and not

limiting shown with a rectangular cross-section.

It is essential to the invention, however, that the cross-sectional shape of the recess 13b matches the outer cross-sectional shape of the sealing part 11, so that the protective part 13 can be positively applied to the sealing part 11. The cross-sectional shape of the protective part 13 may be, for example, round, oval or rectangular with rounded edges.

Such a composite assembly is shown in FIG. This shows the support member 14, on which the electrical connections 10 are supported. At the sealing portion 10 b of the electrical connections 10, the sealing part 1 is provided. Around the sealing part 11 around the protective part 13 is arranged. Such a preassembled electrical connector is then inserted into a housing, which is not shown.

Figure 4. shows a plug arrangement according to the invention in which two substantially parallel extending terminals 10 protrude from the housing 16. The housing 16 has an opening through which at

Connections 10 are led together out of an inner region of the housing to the outside. The terminals 10 are surrounded by a sealing part 11, which in turn is enclosed in a protective part 13. The sealing part 11 thus acts as a seal against the protective part 13. The housing 16 surrounds the protective part 13 in a form-fitting manner. The thus formed plug has a high density and is therefore particularly resistant to leakage. In the housing 16, an electromagnetic valve is further integrated, which is used as a diverter valve in an exhaust gas turbocharger. The housing 16 may have a flange with which it can be screwed to the turbocharger. A method for producing a plug 15 or an electrical connection 10 according to the invention will be explained below with reference to FIGS. 1a to 4. To produce an electrical connection 10, initially an elongate, substantially rectangular flat printed circuit board is produced. Subsequently, the sealing portion 10 b is generated, wherein the recesses 15 are punched out. In this case, constrictions in the sealing region 10b can also be produced by punching, sawing or milling. Thus, the sealing portion 10b has a substantially smaller cross section than the contact portion 10a and the holding portion 10c, respectively.

Subsequently, in a second method step, the sealing part 11 is generated. This can be done for example by encapsulation of the sealing region 10b. As a result of the cross-sectional constriction in the sealing region 10b, large-area, wide metal surfaces do not have to be encapsulated, which due to different thermal expansion coefficients of the metal and the overmoulded plastic tend to separate from one another and thus release leakage paths. The small, largely circular shaped web elements 12 reduce this tendency to detach. By spraying the sealing part 11, the sealing regions 10b of the connection contacts can be completely enclosed in the circumferential direction. This seal has no mechanical support property and can thus be formed soft and elastic.

After the application of the sealing part 11, the protective part 13 is mounted. The protective part 13 is designed as a protective frame and is pushed onto the sealing part 11 in such a way that it is in positive contact with it. Finally, a housing is sprayed around a peripheral region 13a of the protective frame 13 in a second spraying process, wherein the housing 16 contains the electrical components such as, for example, coils, control devices,

Contains resistors, etc. in itself. This results in a component whose electrical components are encapsulated in a plastic housing, from which essentially only the contact regions 10a of the electrical Stick out connections 10. The openings in the housing 16, through which the contact regions 10a extend to an outer region of the housing 16, are advantageously designed so that thermal

Thermal expansion between the metallic, electrical terminals 10 and the housing 16 can be compensated by the sealing member 11. At the same time, the protective member 13 prevents the soft, resilient gasket, i. the sealing part 11 is melted. The sealing member 11 has a much lower melting or Vergießtemperatur point than the housing material and would soften due to the thermal heating by the housing spraying and in particular form bubbles due to its smaller, more filigree dimensions. As a result, a tightness of the housing 16 at the exit points of the electrical connections 10 would no longer be guaranteed. By enclosing the pre-molded seal 11 by means of the pushed-plastic frame 13, the hot plastic can no longer melt the seal during spraying, since the

Heat transfer through the protective frame 13 sufficiently long

is interrupted. The seal, i. the sealing member 11 is thus applied thermally lower, whereby the shape, position and nature of the seal can be obtained.

The aforementioned features of the embodiment may be provided in particular at a plug contact of a diverter valve. According to the invention, a diverter valve is proposed, the plug-in area is provided with connections according to the invention and thereby can achieve a long service life even when used in corrosive media.

The above-mentioned features and embodiments of the present invention can be arbitrarily combined with each other.

Claims

claims

1. Electrical connection (10), in particular electrical plug-in contact with:

a contact region (10a) for producing an electrically conductive connection,

a sealing region (10b) for making a sealed connection to a housing which at least partially surrounds the electrical connection (10),

characterized in that

the electrical connection (10) in the sealing region (10b) at least in sections has a smaller cross section than in

Contact area (10a).

2. Apparatus according to claim 1, characterized in that

in the sealing region (10b) a sealing part (11) is provided, which is the

Sealing region (10b), in its longitudinal direction at least partially and in its circumferential direction completely surrounds.

3. Device according to one of the preceding claims, characterized by

a holding region (10c) which is connected to the contact region (10a) via the sealing region (10b), the sealing region (10b) being formed from at least one web element (12) for connecting the contact region (10a) to the holding region (10a) 10b).

4. Device according to one of the preceding claims, comprising:

- A protective part (13) with the sealing part (1 1) positive and / or non-positively in communication, and thereby the sealing part (11) in

Completely surrounds circumferential direction.

5. Device according to one of the preceding claims, characterized

marked that

- The housing positive and / or non-positive with an outer

Peripheral region of the protective part (13) is in communication, wherein the protective part (13) has a higher and / or same melting temperature as the housing and the melting temperature of the sealing part (11) is lower than the melting temperature of the protective part (13).

6. A method for producing an electrical connection, with the

steps:

Generating a sealing region (10b) and a contact region (10a) in an electrically conductive material, in particular by means of a

Stamping process

- applying a sealing part (11) in the sealing region (10b), wherein the sealing part (11) has a first elastic material value,

- Applying a protective part (13) on the sealing part (11) and

- Apply or create a housing that has a

Peripheral region of the protective part (13) comprises at least partially or completely and at least partially surrounds the electrical connection.

7. The method according to claim 6, characterized in that

- The sealing part (11) is applied by means of an injection molding process.

8. The method according to any one of the preceding claims, characterized

marked that

- The protective part (13) positively and / or non-positively with the sealing part (11) is brought into connection.

9. The method according to any one of the preceding claims, characterized

marked that

- Applied the housing by means of a second injection molding process becomes.

10. The method according to any one of the preceding claims, characterized

marked that

- The melting temperature of the protective part (13) is higher than or equal to the melting temperature of the housing, wherein the melting temperature of the sealing part (11) is lower than the melting temperature of the protective part (13).