EP3867980A1 - Electrical contact element for electrical contacting with a counterpart contact element - Google Patents

Abstract

An electrical contact element (1) for electrical contacting with a counterpart contact element (2) comprises a multiplicity of contact lamellae (11), which lamellae are arranged around a plug-in opening (15) into which a counterpart contact element (2) can be plugged in along a plugging-in direction (E) and which lamellae form a groove (13) which encircles the contact lamellae (11) around the plugging-in direction (E). A spring element (14) is arranged at the groove (13) and engages around the contact lamellae (11) in order to provide an elastic clamping force on the contact lamellae (11). The contact lamellae (11) each have an inner surface (117) which faces toward the plug-in opening (15) and which is of straight form in a cross section transverse with respect to the plugging-in direction (E).

Description

 Electrical contact element for electrical contact with a mating contact element

The invention relates to an electrical contact element for making electrical contact with a mating contact element according to the preamble of claim 1.

Such a contact element comprises a plurality of contact lamellae, which are arranged around a plug opening into which a mating contact element can be inserted along a plugging direction and together form a groove running around the plugging direction around the plugging direction. A spring element is arranged on the groove and engages around the contact blades to provide an elastic clamping force on the contact blades.

In the case of such a contact element, which forms a contact socket with its plug opening, the electrical contact is made via the contact lamellae. To establish an electrical contact, a mating contact element with a contact pin can be inserted into the plug opening, so that the contact pin can make electrical contact with the contact blades and an electrical current can be transmitted.

In order to provide a sufficient contact force on the contact lamellae, which is maintained over the life of the electrical contact element, a spring element is arranged on the contact lamellae, which is also referred to as a spring, and engages around the outside of the contact lamellae in such a way that the contact lamellae are elastically preloaded radially inwards.

The spring element serves as a mechanical element (exclusively) for providing the elastic contact force and can, for example, consist of a material that does not relax under the influence of heat, which can ensure that the contact force is maintained over the service life of the contact element.

A conventional spring element bent from a stamped sheet metal part is comparatively expensive to manufacture. There is therefore a need for a contact element with a spring element, which can be produced simply and inexpensively, while still providing an elastic pretensioning force in a cost-effective manner.

In a contact element known from GB 218324 A, a spring element is arranged on contact lamellae, which is formed by a spring wire wound around the contact lamellae. From FR 1234270 A a contact element is known in which a spring element formed from a stamped sheet metal part engages around contact lamellae.

In a contact element known from DE 10 2013 001 836 B3, an over-spring is formed by a stamped sheet metal part.

Contact elements of the type in question here can be manufactured, for example, as stamped and bent parts from a metal sheet. In this case, the contact elements are punched out of sheet metal as solid parts and bent into their desired, in particular cylindrical, shape by means of round bending.

In the case of round bending, a body element from which the contact lamellae extend is conventionally bent, and in addition the contact lamellae are brought into a curved shape, so that the lamellae lined up together form an (approximately) cylindrical plug-in opening.

When producing such a contact element by punching and round bending, burrs can possibly occur on the contact lamellae as a result of the punching. If such burrs are not removed, burrs on the contact lamellae can come into contact with the mating contact element when the contact element is plugged into connection with an associated mating contact element and thereby contribute to wear. Such wear should be avoided if possible.

In addition, it is desirable to hold the spring element securely in engagement with the groove on the contact lamellae in such a way that the spring element cannot be removed from the contact lamella easily, at least not unintentionally.

Contact elements are known from DE 20 2016 106 663 U1, DE 10 2007 042 194 A1, JP 2008-013153 A and EP 2 833 385 B1 which have rounded contact lamellae for jointly forming a plug-in opening.

The object of the present invention is to provide a contact element for plug-in connection with an associated mating contact element, which is simple to manufacture and has an advantageous operating behavior during operation, in particular also with View of wear when plugging in connection with an associated mating contact element.

This object is achieved by an object with the features of claim 1.

Accordingly, the contact lamellae each have an inner surface facing the plug-in opening, which is just formed in cross section transversely to the plug-in direction.

The contact lamellae are therefore not curved on their inner surfaces facing the plug-in opening, but are straight. The contact lamellae thus extend flat and are grouped around the plug-in opening in such a way that they form the plug-in opening together.

The fact that the contact lamellae are flat in the area of their inner surfaces results in simple production on the one hand. For example, the contact element can be manufactured as a stamped and bent part by rolling up the contact element from a stamped surface element. The contact element is thus produced by punching from a solid, flat sheet metal element and then bending it round (in the sense of rolling it up), so that a contact element with an essentially cylindrical basic shape results. The contact element rolled up in this way by round bending is joined in sections on a joining line extending along the plug-in direction to a part extending circumferentially around the plug-in direction and is thus closed at least in sections circumferentially.

Because the contact lamellae are flat, the manufacture is simplified because the individual contact lamellae do not have to be bent round. The round bending can thus be limited, for example, to a body element from which the contact lamellae extend and on which the contact lamellae are arranged in a row.

Because the contact lamellae are flat (at least in sections in the area of the inner surface), lateral edges of the contact lamellae are spaced apart from the mating contact element (for example in the form of a cylindrical contact pin) in a position in which the contact element is connected to a mating contact element. Even if burrs occur on the lateral edges of the contact lamella during stamping and may not be completely removed during production, there is a risk of wear when the contact element is plugged in with an associated counter-contact element at least reduced because such burrs cannot come into direct contact with the associated counter-contact element.

Thirdly, the formation of the contact lamellae enables a defined contact of the contact lamellae with the associated mating contact element, in that when the connector is plugged in, the contact lamellae come into contact with the associated mating contact element in a defined contact area. A defined electrical contact with sufficient contact force is thus produced even with existing tolerances. This enables favorable operating behavior with low contact resistance, for example for the transmission of large currents.

The flat design of the contact lamellae also makes it possible to apply a coating to the contact lamellae before forming than before bending. Because the contact lamellae are not bent during forming, the risk of the coating on the contact lamellae being damaged, in particular flaking off, is low.

The groove on the contact lamella is formed, for example, by stamping. A groove section is embossed in each contact lamella in such a way that the groove sections are lined up on the contact lamella when the contact element is bent and together form the groove. The shaping of the groove by embossing makes it possible to limit the groove in the axial direction by means of sharp edges oriented approximately perpendicular to the direction of insertion. Because the contact lamellae are flat, the groove can also be deeper in the region of the lateral edges of the contact lamellae, so that the spring element is held in the groove in a form-fitting, secure manner and cannot easily disengage from the groove. The risk that the spring element is inadvertently stripped from the contact element during operation is at least reduced.

Each contact lamella is preferably rounded in cross-section to the direction of insertion in the area of the groove and forms a support section on which the spring element rests. Due to the fact that the shape of the support section is rounded by rounding the extension of the spring element around the contact lamella, there is in particular a recess in the groove on the lateral edges of the contact lamellae with comparatively sharp, axial boundary edges, which securely accommodates the spring element in the Ensure groove. The support section, viewed axially along the plug-in direction, is preferably delimited on both sides of each contact lamella by an edge molded into the respective contact lamella. Such edges arise during embossing and are preferably approximately perpendicular to the direction of insertion, so that a sharp-edged boundary for the groove and thus for the retention of the spring element on the groove is created.

The support section of each contact lamella, viewed in cross-section transversely to the direction of insertion, follow a circular contour in such a way that a circular, circumferential groove results in the row of contact lamellae in which the spring element can be received.

In order to exert a defined spring force on each contact lamella, it may be advantageous to round off the contact section on each contact lamella so that there is a defined, reduced effective range for the spring element to act on the respective contact lamella, and accordingly the spring element on the contact lamella has a defined, in provides in a predetermined manner, as possible tolerance-independent spring force. For this purpose, the support section, viewed in cross-section transversely to the direction of insertion, can have a central area, to which a secondary area connects on each side. The curvature on the support section can have a radius of curvature that is smaller than the radius of curvature of the spring element (viewed in cross section transverse to the direction of insertion), so that the spring element only rests on the respective contact lamella in the central region of the support section, but not in the adjoining areas . The spring force is thus introduced into the contact lamella via the central region, so that a defined spring force is provided on each contact lamella and is introduced into the respective contact lamella in a defined manner.

In one configuration, the contact element has more than two, preferably more than four contact lamellae, for example six contact lamellae or eight contact lamellae, which are lined up along a circular line extending around the insertion direction to form the insertion opening. The contact element thus has an essentially cylindrical basic shape, in which the plug opening is approximately cylindrical and is formed by the contact lamellae lined up along a circular line. The contact lamellae together form the plug opening and surround the plug opening in such a way that Inserting an associated mating contact element each contact lamella comes into electrically contacting contact with the mating contact element.

The contact element preferably has a body element, from which the contact lamellae extend along the plug-in direction. The body element and the contact lamellae can, for example, be formed in one piece and consist of an electrically conductive (metal) material.

The spring element is preferably arranged at ends of the contact lamellae which lie away from the body element. The contact lamellae are separated from one another, for example, by slots extending longitudinally along the plug-in direction and can be radially expanded when plugged into a mating contact element. Characterized in that the spring element is arranged at the ends of the contact lamellae remote from the body element, the spring element provides a favorable contact force at these remote ends for electrical contacting with a contact pin inserted into the plug-in opening.

The body element can preferably be bent round when producing the contact element. The body element can thus have a cylindrical shape. In the manufacture of the contact element, the contact element is, for example, first punched out of a flat sheet metal element and then bent round, so that a cylindrical shape is established on the body element. In this case, however, the contact lamellae are not curved (viewed in cross section transversely to the direction of insertion), but instead extend in a flat manner along the direction of insertion from the body element.

In one configuration, the contact lamellae each have a curved contour on the inside in the region of their ends remote from the body element, viewed along a cross-sectional plane spanned by the plug-in direction and a radial direction directed radially to the plug-in direction. The contour can have a convex basic shape at the ends of the contact lamellae such that an associated mating contact element can be brought into engagement with the plug-in opening in a simple, easily insertable manner and in contact with the contact lamellae surrounding the plug-in opening.

The contour can in particular form a convexly curved contact section for abutment against a mating contact element inserted into the plug opening. In the area of the contact section, each contact lamella, viewed in the cross-sectional plane spanned by the plug-in direction and the radial direction, is convexly curved, so that a defined point contact of each contact lamella arises on the associated mating contact element when the mating contact element is inserted into the plug-in opening of the contact element.

A first convexly curved contour section can each connect to the contact section and a second convexly curved contour section can in turn connect to the first convexly curved contour section. The first convexly curved contour section and the second convexly curved contour section are arranged on a side of the contact section facing away from the body element and form an insertion contour which enables an associated mating contact element to be easily inserted into the insertion opening via the ends of the contact lamellae remote from the body element.

The first convexly curved contour section can, for example, have a first radius of curvature, while the second convexly curved contour section has a second radius of curvature. The fact that the second radius of curvature is smaller than the first radius of curvature results in a curvature at the ends of the contact lamellae which lie away from the body element and thus form the entrance of the plug-in opening for the mating contact element, so that the mating contact element increases in can be easily inserted into the plug-in opening of the contact element, with (slight) radial widening of the contact lamellae to one another.

The contact section and the adjoining first convexly curved contour section can, for example, have the same radius of curvature.

In one embodiment, a concavely curved contour section can adjoin the contact section on a side facing the body element. This concavely curved contour section, viewed along a cross-sectional plane spanned by the plug-in direction and the radial direction, can extend axially from the contact section to the body element. Each contact lamella, starting from the body element, is thus curved inwards in an arc shape, which has the effect that the plug opening at the ends of the contact lamellae remote from the body element is slightly narrowed and is thus widened when the mating contact element is inserted. The electrical contact is thereby in particular provided at the ends of the contact lamellae remote from the body element, on which the spring element also acts to provide an elastic tensioning force.

In one embodiment, the contact lamellae each have at their ends remote from the body element in the region of an outer side facing away from the inner surface a bevel inclined to the direction of insertion. Such a chamfer enables the spring element to be simply pushed onto the contact lamellae for engagement in the groove. Such a chamfer can thus simplify the assembly of the contact element, in particular for attaching the spring element.

In this case, the chamfer can extend from the end lying away from the body element to an edge which delimits the groove and is formed in the respective contact lamella. The chamfer thus forms a run-up slope, by means of which the spring element can be pushed onto the respective contact lamella in such a way that the spring element surrounds the contact lamella in the mounted position and lies in the groove formed on the contact lamella.

Alternatively, the spring element can also be wound by winding a spring wire around the contact lamellae and thus be produced directly on the contact lamellae.

The spring element can e.g. be formed by a spring wire which extends around the contact lamellae. The spring wire can preferably have a (circular) round, an oval or a polygonal (e.g. a rectangular) cross section. A spring wire is generally characterized by a length that is comparatively large compared to the cross-sectional size. The spring wire can be made of spring steel, for example (so-called spring steel wire).

If the spring element is formed by a coiled spring wire, this results in a particularly simple, inexpensive production which can be automated in a particularly advantageous manner.

The use of a spring element which is formed by a winding spring wire offers the further advantage that spring elements of the same type can be used for differently dimensioned contact elements with the same manufacture. So the spring element can be scaled with the diameter of the contact element without changing the manufacture of the spring element - by winding the spring wire in advance or directly on the contact blades. Spring elements of the same type can thus be used on differently dimensioned contact elements.

If the spring body of the spring element is formed by a spring wire, it is advantageous to select the number of turns so that, on the one hand, a sufficient contact force is provided on the contact lamellae and uniform over the circumference of the plug-in opening, and on the other hand, the counter-contact element is inserted into the plug-in opening is possible in a reliable and simple manner by expanding the spring element. Simulations and tests have shown that it can be advantageous if the spring element has more than one turn, for example between 1, 5 and 3 turns, preferably between 1, 8 and 2.2 turns, for example 1, 9 turns. On the one hand, a uniform contact force can be achieved in this area. On the other hand, the circumferential length of the spring body is not excessively large, so that self-locking is avoided when it is expanded (which could otherwise exist if the wire length is too long due to the frictional contact with the outside of the contact lamellae).

In principle, a spring wire of the same thickness can be used with differently dimensioned contact elements, that is to say with different socket geometries. However, it may also be possible to use a spring wire of larger diameter in the case of larger bush geometries and a spring wire of smaller diameter in the case of smaller bush geometries.

The contact element can be part of a connector part, for example, which is designed, for example, as a charging plug or as a charging socket of a charging device for charging an electric vehicle. However, the contact element can also be part of a connector part of a solar module or another electrical device in order to connect electrical lines to one another in an electrically contacting manner.

The idea on which the invention is based will be explained in more detail below with reference to the exemplary embodiments illustrated in the figures. Show it:

Fig. 1 is a perspective view of an embodiment of a

Contact element; 2 shows a frontal view of the contact element;

Fig. 3 is a perspective view of the contact element, illustrating a

 Body member and contact blades extended from the body member;

FIG. 4 shows an enlarged view in section X1 according to FIG. 3;

Fig. 5 is a sectional view taken along line A-A in Fig. 2;

FIG. 6 is an enlarged view in section X2 according to FIG. 5;

Fig. 7 is a sectional view taken along line B-B of Fig. 2;

FIG. 8 is an enlarged view in section X3 according to FIG. 7;

Fig. 9 is a side view of the arrangement of FIG. 3, with the plugged in

 Mating contact element;

FIG. 10 is an enlarged view in section X4 according to FIG. 9;

Fig. 11 is a sectional view taken along the line C-C of Fig. 7;

FIG. 12 is an enlarged view in section X5 according to FIG. 11;

Fig. 13 is a sectional view taken along the line D-D of Fig. 5; and

14 is a sectional view taken along line E-E of FIG .. 5

1 to 14 show an embodiment of a contact element 1, which can be part of a connector part 2 in the form of a charging plug of a charging device for charging an electric vehicle or in the form of a plug for a solar module, for example.

The contact element 1 of the exemplary embodiment according to FIGS. 1 to 14 is designed as a contact socket and has a plurality (six in the exemplary embodiment shown) of contact blades 11, which are grouped around a plug-in opening 15 and thereby define the plug-in opening 15. The contact blades 1 1 extend axially from a body element 10 along a plug-in direction E, are connected to the body element 10 at ends 11 1 and lie at ends 1 10 from the body element 10. The contact blades 11 are made in one piece with the body element 10 from an electrically conductive material, in particular a metal material.

To establish an electrical contact, a mating contact element 2 (see FIG. 5) can be inserted in the plugging direction E into the plug opening 15 between the contact lamellae 11. As a result, the mating contact element 2, which has a contact pin, comes into contact with the contact lamella 11 on the inside, so that a current can flow between the mating contact element 2 and the contact element 1.

The contact blades 11 extend along the plug-in direction E from the body element 10 and are separated from one another by slots 12. A slot 12 is arranged between each two adjacent contact lamellae 11, so that adjacent contact lamellae 11 are cut free from one another by the slot 12 extending therebetween. When the mating contact element 2 is inserted, the contact blades 11 are expanded (slightly), in particular at their ends 110, which are remote from the body element 10, so that the contact blades 11 bear against the mating contact element 2 with mechanical prestress and thus a contact force for producing an electrical contact of low resistance between the contact blades 1 1 and the counter-contact element 2 acts.

In order to improve the contact force, in particular in order to ensure a sufficient contact force over the life of the contact element 1, a spring element 14 (also referred to as a spring) engages around the contact lamella 11 on its outer sides 118, so that the spring element 14 in the area of the ends 110 causes radially inward biasing force on the contact plates 11. The spring element 14 lies in a groove 13, which is created in the region of the ends 110 of the contact lamella 11 and runs around the outside 118, and is thereby axially fixed to the contact lamella 11.

The spring element 14, as can be seen for example from FIGS. 3 and 6, is formed by a spring wire 140, which is formed by a wound spring wire arranged on the contact lamellae 11. The spring element 14 formed in this way has the shape of a helical tension spring and has a comparatively small pitch, so that adjacent turns of the spring element 14 touch. When the contact element 1 is plugged in with an associated mating contact element 2, the contact blades 11 are pressed radially outward, as a result of which the spring element 14 expands. After removal of the counter-contact element 2, the contact lamellae 11 are also returned to their starting position under the action of the prestressing force of the spring element 14.

When designing the spring element 14, it must be taken into account - in particular when selecting the number of turns - that the spring element 14 provides an at least approximately uniform contact force over the circumference and that the plugging process should be possible in a smooth manner. Experiments and simulations have shown that an optimum can be in a range between 1.5 and 3 turns, in particular in a range between 1.8 and 2.2 turns, for example 1.9 turns. In general, if there are too few turns, no uniform contact force can be achieved over the circumference. If, on the other hand, too many turns are used, self-locking can occur due to the frictional contact on the outside of the contact lamellae 11 when plugging in with an associated mating contact element, which can make the plugging extremely difficult or even impossible.

In the contact element 1, the contact lamella 1 1 extends from the body element 10. The body element 10 has a cylindrical shape which is circular in cross section (see FIG. 14), whereas the contact blades 11 are each formed flat and each has a flat cross section (see FIG. 13). The contact lamella 1 1 each point inwards with an inner surface 11 17 facing the plug-in opening 15 and come into contact with the counter-contact element 2 via the inner surfaces 11 17 when plugged in with an associated mating contact element 2.

The contact element 1 can be designed, for example, as a stamped and bent part. During manufacture, the contact element 1 is punched out of a sheet metal element, which is initially flat, and then formed by bending it round (also referred to as “rolling up”), so that an approximately cylindrical shape results on the body element 10, as is shown in FIGS. 1 and 3 can be seen. In the case of round bending, a surface section forming the body element 10 is formed in such a way that the surface section is bent along a joining line 17 to form the circumferentially closed, cylindrical body element 10. When reshaping, a connection section 16 is also created on a side of the body element 10 facing away from the contact lamella 11, which has side legs 160 and an intermediate space 161 formed between the legs 160 and thus inserting and crimping an electrical line wire for connection to the contact element 1 enables.

On the body element 10, as can be seen from FIG. 1, fastening elements 100 can be formed in the form of radially outwardly projecting locking lugs, by means of which the contact element 1 can be fixed, for example, on a contact carrier of a connector part.

The fact that the body element 10 is shaped round during the round bending, but the contact blades 11 remain flat, simplifies the production. In particular, the contact lamellae 1 1 do not have to be individually round-shaped.

Because the contact lamellae 11 have a flat shape in cross section transverse to the plugging direction E, the wear behavior of the contact element 1 can also be improved. In particular, burrs on the lateral edges of the contact lamella 11 extending along the slots 12 cannot easily lead to wear, because the lateral edges of the contact lamella 11 are radially spaced from the cylindrical contact pin of the mating contact element 2 when the mating contact element 2 is inserted, and thus are not immediate There is contact between the lateral edges of the contact blades 11 and the counter-contact element 2.

The fact that the contact lamella 1 1 is flat also results in a defined contact when the mating contact element 2 is inserted. Thus, the contact lamella 11, in cross section transverse to the plugging direction E, bear against the mating contact element 2 at a defined contact point when the mating contact element 2 is in the plug-in opening 15 is inserted, which in particular ensures that a sufficient contact force can be provided at a defined system at the transition between the contact blades 11 and the counter-contact element 2.

In cross-section along a cross-sectional plane spanned by the plug-in direction E and a radial direction R, each contact lamella 1 1 on the inner surface 1 17 is curved into a contour which is defined by different contour sections 1 13-116. The contact is made at each contact lamella 1 1 in the by the plug-in direction E and the radial direction R spanned cross-sectional plane convex contact section 115, as can be seen in particular from FIGS. 7 and 8. As a result of the convex curvature of the contact section 115, there is also a defined, approximately punctiform contact of each contact lamella 11 with the mating contact element 2 in the axial direction, so that a defined contact exists with a defined contact force, which is caused, among other things, by the spring element 14.

7 and 8, the convexly curved contact section 115 is shaped in such an axial region of each contact lamella 11, in which the groove 13 is also formed on the outside of the contact lamella 11, so that the spring element 14 has an elastic clamping force precisely in the area of the contact section 1 15 causes each contact lamella 11.

On a side facing away from the body element 10, the contact section 115 of each contact lamella 1 1 is adjoined by contour sections 1 13, 114 which are convexly curved, but have different radii of curvature R2, R3. Thus, the contact section 115 and the contour section 114 directly adjoining the contact section 115 have a (same) first radius of curvature R3 which is (significantly) larger than the radius of curvature R2 of the contour section 113 adjoining them. Together, the contour sections 114, 113 thus an inlet geometry, which causes the plug opening 15 to widen toward the end of the plug opening 15 remote from the body element 10 and thus enables simple, smooth insertion of a mating contact element 2 in the plug direction E.

On a side facing the body element 10, the contact section 115 of each contact lamella 11 is followed by a concavely curved contour section 116, as can be seen from FIG. 7. Each contact lamella 1 1 is thus (slightly) curved inwards, starting from the body element 10, which has the effect that the contact lamella 11 come into contact with an inserted mating contact element 2 at their ends 1 10 remote from the body element 10 and thus a defined one Installation of the contact blades 1 1 under a defined contact force is made possible.

The spring element 14 lies in the groove 13 formed on the outside of the contact lamella 11. The groove 13 is jointly formed by groove sections on the contact lamella 1 1, the groove 13 on each contact lamella 11, viewed in the axial direction along the plug-in direction E, is delimited by edges 130, 131, as can be seen in particular from FIGS. 5 and 6.

The groove sections are formed, for example, by embossing on the individual contact blades 11. During embossing, sharp edges 130, 131 are formed on the individual contact blades 11, which extend approximately perpendicular to the insertion direction E, so that the spring element 14 can be securely received between the edges 130, 131 and held on the contact blades 11 in the mounted position.

As can be seen from the cross-sectional views according to FIGS. 11 and 12 in conjunction with FIGS. 5 and 6, a support section 132 is formed in the region of the groove 13 on each contact lamella 11, which provides a support for the spring element 14 on the contact lamella 11. The support section 132 is here curved in a cross-sectional plane transverse to the plug-in direction E, which in particular has the effect that the groove 13 on the lateral edges of the contact lamellae 11 is deeper and thus the spring element 14 is held securely in the groove 13 on the contact lamellae 11 ( see in particular also FIGS. 3 and 4).

The support section 132 of each contact lamella 1 1 has a curvature that is greater than the curvature of the spring element 14. The support section 132 thus forms a central region 133 to which secondary regions 134 adjoin on both sides. The central region 133 can have a radius of curvature R6 that is smaller than the radius of curvature of the spring element 14. In addition, the adjoining secondary regions 134 each have a radius of curvature R5 that is (significantly) smaller than the radius of curvature of the spring element 14 and possibly also less than the radius of curvature R6 of the central region 133. This has the effect that the spring element 14 lies essentially in the central region 133 on the support section 132 and thus essentially centrally (viewed in the cross-sectional plane transverse to the plug-in direction E according to FIGS. 11 and 12) respective contact lamella 11 acts.

The secondary regions 134 are bounded on the outside by edge regions 135, which have a curvature with a small radius of curvature R4. The radius of curvature R4 is in this case significantly smaller than the radii of curvature R5, R6 in the areas 133, 134. Via the edge areas 135, the support section 132 is rounded on its lateral, outer edges, so that sharp-edged transitions are avoided. Each contact lamella 11 has, as can be seen from FIGS. 9 and 10, a bevel 112 in the exemplary embodiment shown, which allows the spring element 14 to be simply pushed along the plug-in direction E over the ends 110 of the contact lamellae 11. When pushed on, the spring element 14 runs onto the chamfers 112 on the contact lamella 11 and is thereby (slightly) expanded radially until the spring element 14 comes into engagement with the groove 13 and thus lies between the edges 130, 131 delimiting the groove.

The chamfer 112 at the end 110 of each contact lamella 11 extends up to the edge 131 of the groove 13 remote from the body element 10 and thus provides a guide for the spring element 14 up to the groove 13. The contact blades 11 are also bevelled at their ends 110 in the region of the outside 118 to form two lateral radii which are set obliquely to the circumferential direction, as can be seen from FIGS. 9 and 10, so that the flat shape of the contact blades 11 and in particular radially projecting lateral edges of the contact lamella 1 1 do not hinder the spring element 14 from being pushed onto the contact lamella 1 1 in the plug-in direction E.

In principle, the same contact lamella shapes and the same spring elements 14 can be used in the case of contact elements 1 of very different dimensions, the spring elements 14 being able to use a spring wire of the same diameter or also a spring wire which is scaled as a function of the socket geometry. In general, in the case of a spring element 14 formed by a spring wire, the attachment of the spring element 14 to the contact element 11 can be automated in a simple manner, so that attachment of the spring element 14 by hand can be avoided and similar spring elements 14 can be used for different socket geometries.

The idea on which the invention is based is not limited to the exemplary embodiments described above, but can in principle also be implemented in a completely different manner.

A contact element of the type described here can be used in particular in the case of a charging plug or a charging socket for a charging device for charging an electric vehicle. However, this is in no way limiting. Such a contact element can also be part of a connector, for example a solar module or another electrical device. The number of contact blades can also vary, depending on the socket geometry. Smaller socket geometries can use fewer contact lamellae than larger socket geometries.

The contact lamellae can be lined up circumferentially to create a substantially cylindrical insertion opening. However, this is also not restrictive. In principle, other geometries can also be created by contact lamellae, for example square or rectangular plug-in openings in cross section.

Reference list

1 contact element

10 body element

100 fastener

1 1 contact lamella

1 10, 1 1 1 end

 1 12 chamfer

 1 13-1 16 contour section

1 17 inner surface

 1 18 outside

12 slot

 13 groove

 130, 131 edge

 132 support section

133 Middle area

134 secondary area

135 edge area

14 spring element 140 spring wire

 15 plug opening

 16 connecting section 160 legs

161 space 17 joining line

2 counter contact element

E direction of insertion

 R radial direction

R1-R6 radius

Claims

Claims

1. Electrical contact element (1) for making electrical contact with a mating contact element (2), with a plurality of contact lamellae (11) around a plug opening (15) into which a mating contact element (2) can be inserted along a plug direction (E), are arranged and together form a groove (13) running around the insertion direction (E) on the contact lamellae (11), and a spring element (14) which is arranged on the groove (13) and the contact lamellae (11) for providing a embraces elastic clamping force on the contact lamellae (11), characterized in that the contact lamellae (11) each have an inner surface (117) facing the plug-in opening (15), which is straight in cross section transverse to the plug-in direction (E).

2. Contact element (1) according to claim 1, characterized in that the

Contact element (1) is made as a stamped and bent part.

3. Contact element (1) according to claim 1 or 2, characterized in that the contact element (1) rolled up from a stamped surface element and on a along the plug-in direction (E) extending joint line (17) to a circumferentially around the plug-in direction (E) Part is added.

4. Contact element (1) according to one of claims 1 to 3, characterized in that the groove (13) is formed by embossing in the contact lamellae (1 1).

5. Contact element (1) according to one of the preceding claims, characterized in that each contact lamella (11) in the region of the groove (13) has a support section (132) which is rounded in cross section transversely to the direction of insertion (E).

6. Contact element (1) according to claim 5, characterized in that the

Support section (132), viewed axially along the plug-in direction (E), is delimited on both sides of each contact lamella (11) by an edge (130, 131) molded into the respective contact lamella (11).

7. Contact element (1) according to claim 5 or 6, characterized in that the support section (132), viewed in cross section transversely to the insertion direction (E), a central region (133) and adjoining the central region (133) on both sides Has secondary areas (134), the spring element (14) resting only in the central area (133) of the support section (132) on the respective contact lamella (11).

8. Contact element (1) according to one of the preceding claims, characterized in that the electrical contact element (1) has more than two contact lamellae (11) which extend along a circular line extending around the plug-in direction (E) to form the plug-in opening (15 ) are strung together.

9. Contact element (1) according to one of the preceding claims, characterized by a body element (10), of which the contact lamellae (1 1) extend along the plug-in direction (E).

10. Contact element (1) according to claim 9, characterized in that the spring element (14) in the region of the body element (10) remote ends (1 10) of the contact blades (1 1) is arranged.

1 1. Contact element (1) according to claim 9 or 10, characterized in that the body element (10) is round in cross section transverse to the plugging direction (E).

12. Contact element (1) according to one of claims 9 to 1 1, characterized in that the contact lamellae (11) in the region of their ends remote from the body element (10) (1 10), viewed along one through the insertion direction (E) and a cross-sectional plane spanned radially to the plug-in direction (E) and having a curved contour on the inner surface (11).

13. Contact element (1) according to claim 12, characterized in that the contour forms a convexly curved contact section (115) for abutment against a mating contact element (2) inserted into the plug-in opening (15).

14. Contact element (1) according to claim 13, characterized in that on the contact section (1 15), on a side facing away from the body element (10), a first convexly curved contour section (114) and on the first convexly curved contour section (1 14) a second convexly curved contour section (1 13) connects.

15. Contact element (1) according to claim 14, characterized in that the first convexly curved contour section (114) has a first radius of curvature (R3) and the second convexly curved contour section (113) has a second radius of curvature (R2), the second radius of curvature ( R2) is smaller than the first radius of curvature (R3).

16. Contact element (1) according to one of claims 13 to 15, characterized in that a concavely curved contour section (116) adjoins the contact section (1 15) on a side facing the body element (10).

17. Contact element (1) according to one of claims 9 to 16, characterized in that the contact lamellae (1 1) each at their end remote from the body element (10) (110) in the region of an outer side facing away from the inner surface (117) ( 1 18) have a bevel (1 12) which is inclined to the insertion direction (E).

18. Contact element (1) according to claim 17, characterized in that the chamfer (1 12) of each contact lamella (11) starting from the end of the body element (10) (1 10) to one of the groove (13) delimiting edge (131) formed in the respective contact lamella (11).

19. Contact element (1) according to one of the preceding claims, characterized in that the spring element (14) is formed by a spring wire (140) which is wound around the contact lamellae (1 1).

20. Contact element (1) according to claim 19, characterized in that the spring element (14) forms more than one turn, for example 1, 9 turns.