The present technology relates to a socket for an electrical plug and socket connection, comprising a socket housing with a plug-in opening. The plug-in opening includes a contact support component for mating with a plug, wherein the contact support provides contacts extending into the plug-in opening. The contacts are preferably flat contacts with an elastically bent contact surface.
A previous type of socket is disclosed in U.S. Pat. No. 5,873,752, which describes an electrical connection for a trailer pulled by a vehicle. That patent discloses a unitary socket and contact insert, wherein the contact insert contains flat contacts with elastically bent contact surfaces that are inserted in corresponding openings of the contact support insert. To seal the socket, after the contacts are inserted, the plug-in openings are sealed with a liquid sealant. This method unnecessarily complicates production. Additionally, such sealants are typically not weather resistant. The use of such sealants is therefore undesirable in vehicle applications.
One object of the present technology, therefore, is to provide a reliably sealed socket that can be simply produced, which permits permanent and reliable sealing of the contacts extending from a contact insert.
The present technology task aims to achieve this objective by providing contacts that are preferably cast in an injection molding process into the contact support insert. The contact support insert is then incorporated into the plug-in opening of the socket housing, and a seal is provided between the two components. In contrast to prior sockets, the socket and contact support insert of the present technology, therefore, are no longer produced as a unitary component in a single manufacturing process. Instead, the contact support insert is preferably produced with the contacts fixed in it, and subsequently sealed into the socket housing. For design reasons, because flat contacts with an elastically bent contact surface are used, it is not possible to cast them directly into a socket housing. U.S. Pat. No. 5,873,752 discloses such an example, in which the elastically bent contact surfaces are produced within a plug-in opening of the socket housing. In that type of arrangement, the injection molding die for the socket cannot be removed.
On the other hand, it is possible, to provide a contact support insert according to the present technology, with cast-in flat contacts, since the injection molding die can be pulled to the side from the contact support insert, and is not locked behind the elastically bent contacts. Compared to sealing each individual contact, just sealing the contact support insert into the socket housing is much simpler. Consequently, the presently disclosed socket can be produced more effectively at a low cost.
According to one preferred embodiment of the presently disclosed socket, the contacts protrude from the plug-in side of the contact support insert, which is set in the plug-in opening. The surfaces of at least one part of the contacts are preferably bent outward, i.e., away from the center of the contact support insert. Between the bent end of the contact surface and the mounting end of the contact surface, a gap remains, which serves as an application point for the die gates during injection molding. The gap also preferably presses the contacts against a core arranged in the center of the contact insert, for fastening the contacts. The contacts (preferably flat contacts with elastically bent contact surfaces) are preferably arranged near the edge of the contact support insert, for example, in a circle around the center of the contact support insert.
Between these preferably circularly arranged contacts, protrusions that extend from the mounting side of the contact support insert can be provided, which serve to stabilize the contacts or injection molding dies during the injection molding process.
To allow the contact support insert to be inserted into the socket housing, the socket housing preferably comprises a step at the end of the plug-in opening, on which the contact support insert (with an optional seal) may be positioned. This arrangement permits the forces that occur during insertion of the plug into the plug-in opening to be reliably dealt with.
A seal is also preferably positioned in the socket housing, wherein the seal has a first sealing surface arranged in the plug-in opening for cooperation with the plug. The first sealing surface can preferably be moved in the plug-in direction of the socket housing. It is believed that this type of configuration provides good sealing of the contact space between the plug and socket.
The seal can also form a second sealing surface with the socket housing. Preferably, this second sealing surface is provided at the inside peripheral surface of the plug-in opening adjacent to the contact support insert. It is believed that this type of arrangement provides good sealing of the interior of the socket housing, even in the absence of a plug.
In order for the first sealing surface of the seal to provide sufficient sealing pressure against the housing of the inserted plug, and also to provide sealing even when different plugs with different dimensions are used, it is particularly preferable to provide a first sealing surface that can be adjusted in the plug-in direction of the socket via an elastic force. This type of configuration results in the seal, with its first sealing surface, defining the end position of a plug inserted into the socket, where the plug abuts the seal. This feature can be provided even when different plugs are used, having different dimensions, or when a plug is not completely inserted into the socket. When the sealing surface of the seal moves against an elastic force, the force between the two sealing surfaces can compensate to achieve good sealing.
According to a particularly preferred embodiment, the seal has an elastically deformable section for generation of the elastic force, which is distinct from the first sealing surface. This elastically deformable section preferably lies between the first sealing surface and second sealing surface (the surface for sealing between the contact insert and the socket housing). Preferably, the elastically deformable section(s) of the seal are provided adjacent to the sealing surfaces. Because the elastically deformable section is arranged separate from the first, and optionally second and third sealing surfaces, deformation of the seal, therefore, will have no negative effect on sealing properties of the sealing surfaces.
In one variation, the elastically deformable section can have at least two preferably V-shaped extensions, which are adjustable in a bellows-like fashion. By changing the angle between the V-shaped extensions during adjustment or shifting of the sealing surface, an elastic force is generated.
Alternatively, or in addition, the seal can have a separate spring element in the elastically deformable section. This type of configuration has the advantage of allowing the applied sealing force to be specifically adjusted. This separate spring element is preferably integrated into the seal and provided, for example, as a coil spring that supports the sealing surface. In addition, V-shaped, preformed leaf springs, distributed on the peripheral edge of the seal, can also be provided as spring elements. These leaf springs can add to the elastic effect of adjusting the angle of the V-shaped extensions in the seal. The spring element can be made from metallic or non-metallic material and be fully enclosed by the rubber-elastic material of the seal.
In order to achieve a reliable seal with the surface of the plug inserted into the plug-in opening, the first sealing surface is preferably aligned essentially perpendicular to the inner peripheral surface of the plug-in opening. It can also lie laterally against this peripheral surface, so that the seal, during adjustment, is guided through the internal peripheral surface of the plug-in opening.
According to a particularly preferred embodiment of the technology, the seal is arranged, at least in sections, around the contact support insert, to achieve a seal between the contact support insert and socket housing. This type of configuration aligns the seal relative to the contact support insert and socket housing.
In another embodiment, the seal can also form a third sealing surface with the contact support insert, in order to also seal the socket interior from moisture that may penetrate into the contact area of the plug-in opening.
In order to be able to easily mount the seal and simultaneously achieve a good sealing effect on the first, second and/or third sealing surface, the seal is preferably designed as a single component made of a rubber-elastic material.
In order to secure the seal between the socket housing and the contact support insert, the interior of the socket housing can also preferably include a step with a protrusion extending into the plug-in opening of the socket, wherein the protrusion mates with a corresponding groove/recess in the seal. The protrusion can run along the entire step in the socket housing or can be arranged in sections.
In order to secure the contact support insert into the socket housing, the contact support insert can preferably connect via a locking mechanism in the socket housing. For example, a snap-in clip can be provided on the contact support insert, which mates with a corresponding snap-in clip on the socket housing. The locking mechanism is preferably arranged in a positioning area provided between the plug-in opening and the contact opening situated on the opposite side of the socket. Other types of locking mechanisms suitable for purposes of this technology may also be used.
Additionally, instead of locking the contact support insert in the socket housing, the contact support insert can also be welded or glued into the socket. In that type of configuration, there is no need for a seal arranged between the contact support insert and the socket housing, since, by welding or gluing, the socket housing is sufficiently sealed. Therefore, only one seal would be provided relative to the plug being inserted into the socket, which can be configured, for example, similar to the seal just described and, in particular, be adjustable against an elastic force in the plug-in direction of the socket.
Yet another possibility of fastening the contact support insert into the socket involves molding the socket housing around the contact support insert in a second injection molding process. This method is also feasible with corresponding injection molding dies and represents a good possibility for cost-effective production of the presently described socket.
Additional features, advantages and application possibilities of the present invention are also apparent from the following exemplary drawings. All described and/or pictured features, alone or in any combination, illustrate exemplary embodiments of the present invention independently of their summary in the claims and/or specification.
In the drawings:
The contacts 4, 6 are preferably cast in an injection molding process into the contact support insert 3. The contact support insert 3 is then incorporated in the housing 2 of the socket 1 with sealing of the plug-in opening 10 by means of a seal 7. The contacts 4, 6 preferably protrude from the mounting side 8 of the contact support insert 3 arranged in the plug-in opening, and the bent contact surfaces 5 of the contacts 4 are bent outward so that a gap 9 is formed between the end of the bent contact surface 5 and the mounting side 8. This gap 9 is also illustrated in
The gap 9 also aids production of the contact support insert 3 with the cast-in contacts 4, 6. In the injection molding process, a negative mold of the contact support insert is preferably produced that is then injected. Due to the shape of the contacts 4 with outwardly bent contact surfaces 5, it is therefore preferable to provide gates in the injection mold that are pushed into the gap 9, and after injection molding, can be pulled radially outward. This configuration typically means that the contacts 4 cannot be injection molded into the interior of the socket housing 2 (i.e., the plug-in opening 10 shown in
As shown in
As shown in
Additionally, as shown in
Also as shown in
Such a plug can preferably then be pushed into the plug-in opening 10 of the socket 1 to, at most, an end position 26 on the end of a coding groove 27. Before reaching this end position 26, however, a sealing surface on the end of the plug will meet the first sealing surface 25 of seal 7. Further advancing the plug into the plug-in opening 10 will then compress V-shaped extensions 28 of an elastically deformable section of the seal 7, and the resulting elastic force will press the first sealing surface 25 of the seal 7 towards the contact support insert 3. Through deformation of the V-shaped extensions 28, an elastic force in seal 7 will adjust the first sealing surface 25 in the plug-in direction of the plug. Because of this elastic force, a pressure may be achieved between the sealing surface 25 of the seal 7 and the sealing surface of the plug, so that the contact between them is thus sealed.
In short, the present technology encompasses a socket 1, reliably sealed against penetration of moisture, which can be produced simply in an injection molding process, despite having flat contacts in the plug-in opening 10, by producing a contact support insert 3 with contacts 4, 6 in a first injection mold, and then sealing that contact insert 3 into the socket 1.
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Number | Date | Country | |
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20090142971 A1 | Jun 2009 | US |