EP2783424A1 - Socket contact for photovoltaic applications - Google Patents

Abstract

Socket contact (1) with a contact region, in particular a crimping region (6), for an electrical conductor of a cable and a contact zone (5), with which the socket contact (1) can be brought into electrical contact with a mating plug-type connector, characterized in that a large number of laminations (2) is located between a first and a second ring-shaped end region (3, 4), with one end region (4) adjoining the contact region, which laminations have at least a single profile change in the axial profile of said laminations between the two ring-shaped end regions (3, 4).

Description

 DESCRIPTION

Socket contact for photovoltaic applications

The invention relates to a socket contact, in particular for photovoltaic applications or applications in the automotive sector, according to the features of the preamble of claim 1.

Socket contacts, for receiving a mating contact partner, such as a contact pin, are basically known. Such socket contacts have a receiving space in which the mating contact partner can be used. The existing of a metallic material socket contacts are preferably made in a stamping bending process, which can be carried out inexpensively in large quantities.

The socket contacts are hinged in an end region of a cable to an electrical conductor of the cable, for example soldered, caulked, crimped or the like. For this purpose, the socket contact has a contact area for the electrical conductor of the cable, preferably a contact spring with a crimp, wherein the Crimpflugees (usually two wings) are brought into operative connection with the electrical conductor, that is permanently and reliably contacted.

There are already known socket contacts for use in photovoltaics, in which a plurality of fins are arranged between a first and a second annular end region. These slats are distributed over the circumference and form a cylindrical bush, with all slats are aligned straight. However, this has the disadvantage that the mating connector, the is used in such a socket contact, over the life is not sufficiently contacted with the socket contact. This means that between the straight-aligned blades of the socket contact and the contact means of the mating connector can form small gaps, which are accessible just for use in the Photovoitaik for dirt, moisture and the like, so there is corrosion and thus high contact resistance whereby the contact reliability over the life of such a connector, consisting of female contact and mating connector, is not sufficiently guaranteed.

The invention is therefore based on the object to improve a socket contact for use in the Photovoitaik above all in terms of its contact reliability over its lifetime.

According to the invention, there is a multiplicity of lamellae between a first and a second annular end region, the one end region adjoining the contact region, which have an at least one change of course in their axial progression between the two annular end regions. First, the known basically cylindrical design is maintained for such a female contact, in which a contact pin can be inserted as a mating connector. This design has proven itself in practice due to its ease of installation. In order to increase the contact reliability over the life of such a connector, it is now provided according to the invention that the lamellae have in their axial course at least one-time course change, which takes place within a contact zone. This change of course results in a defined contact zone, wherein it is ensured that the lamellae in the region of the course change defined in the contact zone defined bias against the inserted mating connector. By this change in course and thus caused bias of the slats, a higher contact pressure is exerted on the mating connector used, so over the term of the connector is always ensured that the slats and thus the Contact zone of the socket contact is applied to the mating connector. It can form no gaps, penetrate into the dirt, moisture and the like and could hinder the contact between the socket contact and the mating connector. It is accepted that part of the lamellae outside the contact zone or outside of the course change not at all or as previously in planparallei abut the mating connector and it can still come in this area to undesirable contact resistance. However, this is negligible, because it is ensured with the at least one, preferably twice, course change in the contact zone, that the socket contact always defined on the mating connector is present and in this area no gaps are present.

In a further development of the invention, the contact zone is in the region of a course change of the slats. It is conceivable that only a single course change takes place, so that a single, preferably radially encircling contact zone is formed. In addition, however, it is also conceivable that the course change takes place several times, so that in the axial extent of the socket contact several consecutive contact zones are present. Preferably, the contact zone is formed by a respective lamella, wherein the course change U-shaped, sinusoidal or the like may be formed.

In a further development of the invention, a sleeve is arranged above the region between the two annular end regions. This sleeve has the advantage that the lamellae form a kind of projection, a bump or the like on the one hand in the direction of the mating connector and the other in the direction of the inner contour of the sleeve due to their at least one course change. Thus, by the presence of the sleeve, the contact force acting from the lamellae on the mating connector (for example, the contact pin) can be significantly increased, since the lamellae in their region of the course change both on the outer surface of the mating connector and on the inner Can support the surface of the sleeve. In a further development of the invention, the sleeve has at least one guide tab, preferably two guide tabs, furthermore preferably two guide tabs lying opposite one another. With the one guide tab or the plurality, preferably two opposite guide tabs ensures that the sleeve can be pushed in a defined position on the area between the two annular end portions.

In development of the invention, the sleeve has at least one cooperating with an opening of the socket contact locking lug. The locking lug of the sleeve is locked in the opening of the socket contact, so that the sleeve is fixed in a defined position to the socket contact. For this purpose, it is provided in a further development of the invention that the opening of the socket contact is arranged in the one annular end region, preferably the end region adjacent to the crimp region. This has the advantage that the sleeve is pushed from the front end region, starting on the socket contact and its end position is reached when its locking latches in the opening in the other ring portion locked. Of course, the reverse arrangement is also conceivable, namely that the one annular end region has a latching nose and the sleeve has an opening assigned to this latching nose.

An exemplary embodiment and an assembly sequence of the socket contact according to the invention will be explained and described below with reference to FIGS. 1 to 3.

Figure 1 shows a socket contact, distributed over its circumference a plurality of slats 2, for example 10 or more than 10 slats has. The fins 2 are arranged between a front end region 3 and a rear end region 4. In this case, the design of the socket contact 1 is cylindrical, so that the two end portions 3, 4 are designed annular. The lamellae 2 form in their at least one-time course change a contact zone 5, which is shown in Figure 1, that a contact zone 5 is present, the lamellae 2 form two contact areas due to their local three-course change, with which they on the mating connector, not shown here Plant come. Is a five changes of contact exist, three contact areas are formed and so on. It is therefore of course conceivable that more than one contact zone 5 and correspondingly more contact areas are present between the two end regions 3,4, which are then realized by a repeated change in the lamella 2 in its axial extent. In a single or double course change, a contact area is formed. The rear end region 4 is adjoined by a crimping region 6, which is formed in a manner known per se by two crimp blades 7, 8. In Figures 1 to 3 is not shown that an electrical conductor of a cable has been contacted in the crimping 6. This is the case with the finished socket contact 1, but is devoid of any description, as the crimped connection, as well as alternative contact options, are known.

Furthermore, a sleeve 9 is present, which can be pushed onto the area between the two end regions 3, 4. In Figure 1 it is shown that the sleeve 9 is prepared for sliding onto the socket contact 1, wherein in Figures 2 and 3 is shown that the sleeve 9 is already in its desired position on the socket contact 1.

The sleeve 9 has locking springs 10 which protrude from its outer surface. With these detent springs 10, a housing on the socket contact 1 and the sleeve 9 are fixed to realize an electrical insulation to the outside of the female contact 1 and the sleeve 9, which consist of electrically conductive materials.

Furthermore, the sleeve 9 has at least one latching lug 11 and at least one guide lug 12. In this case, the locking lug 11, as well as the guide plates 12, twice and in each case opposite in the sleeve 9 is present. With the locking lug 11, the sleeve 9 is fixed detent on the socket contact 1, preferably set in its final position. For this purpose, the sleeve 9 is pushed onto the socket contact 1, so that the at least one latching lug 11, preferably both opposing latching lugs 11, in at least one opening 13, preferably in two opposite openings 13, the socket contact, preferably in the rear end portion 4, can engage. When this is done (see Figure 2), the sleeve 9 is arranged in its desired position on the socket contact 1 and fixed in position. With the guide plates 12 ensures that the sleeve 9 postponed in a defined movement on the socket contact 1 and / or ensures that the socket contact 1 oriented (correctly positioned) can be pushed into a housing can be. This is particularly advantageous because it is ensured with the guide flaps 12 and the targeted Aufschiebebewegung that the locking lug 11 of the sleeve 9 passes into the region of the opening 13 and locked there, so that a locking of the detent spring 10 is optionally ensured. In other words, the locking lug 11 is latched in the opening 13 for the purpose of positioning and latching.

The components shown in Figures 1 to 3, namely the socket contact 1 and the sleeve 9, each consist either of a single component (preferably the sleeve 9) or are composed of several components (for example, the socket contact 1). In this design, it makes sense, the individual parts of which the socket contact 1 and / or the sleeve 9 are assembled or to produce these two components in a punch-roll process. Such a method is usually carried out automatically for the production of large quantities, so that a plurality of components are produced in succession on a belt or a belt or the like. In this case, an end portion 14 shown in the figures is part of this belt, with several end portions 14 (not shown here) one behind the other and form the belt. After manufacture, these strap-forming end portions 14 are singulated (shown in Figures 1 to 3), wherein it is finally still necessary to remove the socket contact 1 (and / or the sleeve 9) remaining end portion 14. This is done for example by a punching process. This means that then the crimping area 6 with its crimp wings 7, 8 is ready to be contacted with the electrical conductor of the cable. In the event that the end portion 14 is not removed, this can be placed in an advantageous manner around the outer sheath of the cable in an interference fit for the purpose of strain relief.

In other words, the invention is to be seen in that the socket contact according to the invention in addition to such a contact spring with a crimping a Contact zone has. This contact zone is formed by a first and a second annular end region, wherein the one end region adjoins the contact spring with crimp. Between the two annular end regions is a plurality of webs (lamellae), which have an at least one-time course change in their axial course between the two annular end regions. This course change is preferably present multiple times, so that the webs have in their axial course from the one annular end region to the other end-shaped annular region, for example, a hump-like course. The annular end portions and the webs extending therebetween are also advantageously produced in a stamping and bending process. If the contact area of the socket contact has a rotationally symmetrical cross section in the final state, it can also be produced in a stamped roll method.

An inventive socket contact with a contact spring with a crimp for abutting an electrical conductor of a cable and a contact region adjoining this contact spring with crimp is shown in FIG. Here it can be seen that radially around a plurality of webs with indentations (or bulges, depending on the point of view) between annular end regions are arranged. The mating face of the female contact is located on viewing the figure 1 on the right side.

In particular, for automotive applications as well as for applications in photovoltaics, it is necessary that on the one hand permanent contact forces are exerted by the socket contact on the mating contact therein therein (such as a contact pin or the like). On the other hand, the force to be applied should be tolerable in the mating of contact partners (= book contact) and mating contact. These two contradictory requirements are brought into harmony with the socket contact according to the invention in that over the contact zone an over-spring with Verrasteiement is arranged in the final assembled state. This Überfeder with Verrasteiement has a sleeve shape and preferably extends over the area between the two annular end portions. This over-spring with locking element is also a metallic component and is preferably made of a metal sheet in a stamping-bending process or a punch-roll process. The inner diameter of the over-spring is chosen so that it compresses after its assembly and fixing on the lamellar contact area in the bump-like area and thereby exerts a force of the lamellae on the arranged within the lamella mating contact. This means that the socket contact (initially without over-spring) can be plugged onto the mating contact partner, after which the over-spring is arranged over the contact zone and extending beyond, whereby the required contact forces between the two contact partners are applied.

This preassembled state is shown in FIG.

In order for the over-spring to remain in its position around and beside the contact zone after its arrangement, latching means for fixing the position are provided on the over-spring and / or the one or both annular end regions.

In Figure 3 it can be seen that as a locking means a caulking is provided, which is arranged between the one end region of the over-spring and the corresponding annular end portion of the socket contact. By this caulking the over-spring is fixed in position on the socket contact. Finally, in particular according to FIG. 2, guides and / or stops may also be present in order to fix the fully assembled socket contact, including the over-spring, in a housing of a connector, preferably a plastic housing. With the means for guiding the socket contact is guided into the housing of the connector moved into it. The at least one stop is required so that an end position can be taken when inserting the entire socket contact in the housing. Finally, with means for locking the final determination of the entire socket contact in the associated housing of the connector. The latching is formed, for example, as a projecting wing, which is led out of the over-spring. In Figure 3, the socket contact is finished with respect to its contact zone and shown fully assembled. Before or after the striking of the electrical conductor, not shown here takes place in the contact spring with crimp. Before this takes place, it is still necessary that the end part required for the production of the contact system according to FIG. 1, which is required in the stamping-bending or punch-rolling process, be cut off along the dashed line.

LIST OF REFERENCE NUMBERS

1. socket contact

2. fins

 3. Front end area

4. Rear end area

5. contact zone

 6. crimping area

7. Crimper

 8. Crimp wing

 9. sleeve

 10. detent spring

 11. latch

 12. Guide tab

13. opening

 14th end part

Claims

PATENT APPLICATIONS Socket contact for photovoltaic applications

1. socket contact (1), with a contact region, in particular a crimping region (6), for an electrical conductor of a cable and a contact zone (5) with which the socket contact (1) is electrically contacted with a mating connector, characterized in that between a first and a second annular end region (3, 4), wherein the one end region (4) adjoins the contact region, a plurality of lamellae (2), which in their axial course between the two annular end regions (3, 4) have an at least one course change.

2. socket contact (1) according to claim 1, characterized in that the contact zone (5) in the region of a Veriaufwechselsel of the slats (2).

3. socket contact (1) according to claim 1 or 2, characterized in that over the region between the two annular end portions (3, 4) a sleeve (9) is arranged.

4. socket contact (1) according to claim 3, characterized in that the sleeve (9) has at least one guide tab (12).

5. socket contact (1) according to claim 3 or 4, characterized in that the sleeve (9) has at least one with an opening (13) of the socket contact (1) cooperating latching lug (11).

6. socket contact (1) according to claim 5, characterized in that the

Opening (13) of the socket contact (1) in which an annular end portion (3, 4) is arranged.

7. socket contact (1) according to any one of the preceding claims, characterized in that the socket contact (1) is a stamped roll part.