EP2357706A1 - Contact element and method of contacting a wire with such a contact element - Google Patents

Abstract

The element (2) has a head part (4) widened opposite to a section (2a), which is adjacent to the head, where the element is made of a material such as chromium-nickel steel material with higher melting temperature in comparison to a melting temperature of a strand-like medium (3) i.e. copper wire. The section is wound with the copper wire, and the head part is curved on a side turned towards the section and/or tapered from the section. The head part comprises a middle section (4a) and a lateral section that is limited transverse to longitudinal extension of the section. An independent claim is also included for a method for contacting a strand-like medium.

Description

The present invention relates to a contact element according to the preamble of claim 1, as well as a contacting method according to the preamble of claim 9.

In particular, the invention relates to contacting copper enameled wire by arc welding to components. Copper enamel wire is usually contacted on components or sections of carrier materials. The carrier material is usually copper or bronze, since this material can be welded particularly well with copper enameled wire.

In the processing of enamelled copper wire, it is often necessary to galvanically connect the enamel-insulated wire without prior complex selective stripping with a connection element, for which purpose, in particular, the arc welding has proven to be a suitable method. It breaks thermally the paint insulation of the wire at the contact point and produces in molten phase a galvanic connection of the mating materials.

In arc welding, the aim is to form a melt bead containing a mixing zone of the paired materials.

The component support points to be contacted with the enamelled copper wire used here as connection elements advantageously produced stamped and bent parts of suitable strip material as a carrier material. The general trend for miniaturization results in such stamped and bent parts in particular bending radii, which are so small that they fall below the permissible minimum values of conventional carrier materials. As a well-known example, reference may be made to contact springs of e.g. Beryllium bronze referenced.

It can be found alternative carrier materials that allow smaller bending radii in stamped and bent parts, as it allows, for example beryllium bronze. These alternative carrier materials include e.g. Stainless steel sheet. A welded joint of two substances with very different melting temperatures, such as stainless steel sheet and copper wire, but so far is not possible.

The object of the invention is to provide a component and a method for contacting the aforementioned type, with which the described disadvantage does not occur and allow greater flexibility in the selection of materials to be contacted with each other.

This object is achieved by a contact element with the features of claim 1 and a method having the features of claim 9. Advantageous embodiments can be found in the subclaims.

According to the invention the object is achieved via the geometry of the contact element for contacting the strand-shaped conductive medium. In this case, the contact element has two sections: a head part and a section adjoining the head part, which connects the head part of the contact element to the component.

According to the invention, the head part of the contact element is widened in relation to the adjoining section. In this case, widened design means that the cross section of the contact element towards the component tapers in the region of the section adjoining the head part in relation to the cross section of the head part.

This ensures that when contacting the conductive strand-shaped medium with the contact element by welding, as the point of the welding device, the head part is selected, due to the geometry resulting transient heating processes, the head part, which has a higher melting point than the strand-like conductive medium, melts in time before the strand-shaped conductive medium.

This results in an electrically conductive weld between the contact element and stranded conductive medium, since the melted at a higher temperature material of the weld joint resulting material combination is first melted and so on a-alloying of both materials in the molten phase, which in particular in the use of lacquer-insulated stranded conductive media from Significance for the establishment of a durable electrical connection is, can be ensured.

The characteristic geometry of the contact element may advantageously represent a T-shape, in which the upper crossbar of the T represents the head part. Such a geometry is particularly advantageous if the contact element is to be produced from a flat material, for example a sheet, because of its essentially two-dimensional shape.

As a material for the contact element, for example, offer steel materials, in which in particular the group of chromium-nickel steels is advantageous due to their low Korosionsanfälligkeit. Advantageously, the portion of the contact element connecting the head part to the component is intended to be wound with the strand-shaped medium.

Advantageously, the head part can be designed in such a way that the side of the head part facing away from the section connecting the head part with the component is arched or has a taper. The taper is designed so that there is a vertex or a crest line facing away from the section connecting the head part with the component and thus represents a physically preferred zone for the attack of the skipping arc in a welding process. This is how the vertex area of the curvature or the rejuvenation works during the contacting process similar to a lightning rod.

The effect can also be achieved by connecting lateral sections to a middle section of the head part transversely to the extension direction of the section connecting the head section to the component. In this case, the middle section on the side remote from the section intended for connecting the head part to the component is advantageously substantially vertically flattened relative to its longitudinal extension, while the sections adjoining the side have an area running at an angle to the central section. As a result, the lateral sections preferably taper away in the direction away from the central section, so that the lateral sections have, for example, the shape of a wedge which points away from the central section of the head section with its acute-angled edge. Alternatively, another tapered geometry may be provided, such as a Gothic pointed arch, which tapers away from the central portion or which may be ajar to a parabola pointing outwardly away from the central portion with its apex.

Figur 1A

- zeigt schematisch ein erfindungsgemäßes Kontaktelement an einem elektrischen Bau-

Figur 1B

- teil, bei dem es sich beispielhaft um eine Kontaktfeder handelt, zeigt schematisch das Baueil mit dem erfindungsgemäßen Kontaktelement aus Figur 1A in Seitenansicht,

Figur 1C

- zeigt das beispielhafte Bauteil mit dem beispielhaften erfindungsgemäßen Kontaktelement schematisch in einer Draufsicht,

Figur 1D

- zeigt schematisch eine vergrößerte Ansicht des beispielhaften erfindungsgemäßen Kontaktelements aus den vorstehenden Figuren,

Figur 2A

- zeigt schematisch ein erfindungsgemäßes Kontaktelement an einer Kontaktfeder, wobei das Kopfteil des Kontaktelements eine alternative beispielhafte Form aufweist und beispielhaft eine mögliche Umwicklung des das Kopfteil mit dem Bauteil verbindenden Abschnitts mit einem strangförmigen leitenden Medium dargestellt ist,

Figur 2B

- zeigt schematisch ein erfindungsgemäßes Kontaktelement an einer beispielhaften Kontaktfeder nach dem Kontaktierungsvorgang mit dem strangförmigen leitenden Medium.

The invention will be described below with reference to the FIGS. 1A to 2B schematically explained in more detail:

Figure 1A

schematically shows a contact element according to the invention on an electrical construction

FIG. 1B

- Part, which is an example of a contact spring, schematically shows the Baueil with the contact element according to the invention Figure 1A in side view,

Figure 1C

FIG. 2 shows schematically the exemplary component with the exemplary contact element according to the invention in a top view,

FIG. 1D

FIG. 2 shows schematically an enlarged view of the exemplary contact element according to the invention from the preceding figures, FIG.

FIG. 2A

schematically shows a contact element according to the invention on a contact spring, wherein the head part of the contact element has an alternative exemplary shape and by way of example a possible wrapping of the section connecting the head part with the component is shown with a strand-shaped conductive medium,

FIG. 2B

schematically shows an inventive contact element on an exemplary contact spring after the contacting process with the strand-shaped conductive medium.

The contact element 2 according to the invention adjoins the component 1 with one end of the portion 2a, in the case illustrated an exemplary contact spring selected. At the other end of the section 2 a, the contact element 2 has the head part 4. In the example shown, contact element 2 and component 1 are made in one piece. However, there are others, For example, cohesive connections between contact element 2 and component 1 possible. Characteristic of the inventive geometry of the contact element 2 is the course of the vertical axis X to the cross-sectional area of the contact element 2. Characteristic is that this cross-sectional area along the axis X of the component 1 coming from the transition from section 2a to the head part 4 increases. In the example shown, this is achieved by a geometry similar to the letter T, which has a substantially two-dimensional structure in the case of the contact element 2 shown by way of example as a result of the production as a sheet metal stamped part. It is advantageous to optimize the design of the facing away from the component 1 surface of the head part 4 with respect to the welding process, in particular the ignition of an arc.

This is achieved by the side facing away from the component 1 side of the head part 4 is designed such that it has a vertex area. The apex region can be punctiform, linear or planar in shape and represents the furthest removed from the component 1 zone of the contact element 2. Thus forms the end face of the head part 4 in Figure 1C due to the mutually angled surfaces 4d a vertex 4c in the form of an obtuse angle. In the spatial view, the vertex 4c represents a line in the direction of the image plane. It is likewise possible for the surfaces 4d to merge into one another in a curvature or for a flat region extending at right angles to the axis X to be from the component 1 along the plane Axle X has farthest zone. Advantageously, the area of the end face of the head part 4, which is furthest along the axis X from the point of contact of the contact element 2 on the component 1, is located in the middle region of the head part 4 along the axis Y. Advantageously, this middle region 4a closes on both sides along the axis Y lateral portions 4b. These are advantageously designed so that they represent a kind of wedge facing away from the central region of the head part 4. In this planar embodiment, the width B1 of the head part 4 in the direction of the axis Y is greater than the width of the region 2a in the direction of the axis Y. The lateral portions 4b can at their from the central region 4a of the head part 4 facing away in the end through the Axis X and Y formed plane at an acute angle converge α at an angle. In this case, it is possible to round off the acute-angled edge of the lateral regions 4b pointing away from the middle region 4a of the head part 4, whereby the shape is formed similar to a parabola with a vertex facing away from the middle region 4a of the head part 4.

In particular, the widths B1 and B2 and the height H of the head part 4 in relation to the length L of the contact element 2 in the direction of the axis X are to be dimensioned such that during the welding operation, the melting of the head part 4 takes place temporally before the stranded medium 3 melts. This is preferably wound around the region 2a. In this case, in an advantageous embodiment, the wire before the welding of the contact element 2 to parking pins be guided a winding machine. During the welding process, the welding bead 5 forms, which preferably takes the form of a three-quarter ball or a similar, substantially spherical structure. In an advantageous embodiment of the method, the dimensions of the weld bead 5, for example, the diameter can be used for the purpose of quality control. In this case, the design of the weld bead is determined with a suitable device and deduced from the design of the weld bead on the melt produced during the welding process. If the dimensioning of the weld bead is within a predefinable tolerance range, this is the criterion for the proper execution of the welding process. If this is not the case, then the rejection of the classified as defective component can be done by a screening device.

Claims (12)

Contact element (2) for contacting a strand-shaped conductive medium (3), in particular enameled copper wire, wherein the contact element (2) essentially consists of a material with a higher melting temperature than the melting temperature of the stranded medium (3),
characterized,
that the contact element (2) has a head part (4) is formed which is opposed to a to the head part (4) adjoining the portion (2a) of the contact element (2) is widened. Contact element (2) according to claim 1,
characterized,
that it is approximately T-shaped. Contact element (2) according to one of the preceding claims,
characterized,
that it is formed from a steel material, in particular a chromium-nickel-steel material. Contact element (2) according to one of the preceding claims,
characterized,
in that the section (2a) is provided for winding with the strand-like medium (3). Contact element (2) according to one of the preceding claims,
characterized,
in that the head part (4) is arched on the side facing away from the section (2a) and / or is tapered away from the section (2a). Contact element (2) according to claim 5,
characterized,
in that the head part (4) has a central section (4a) and lateral sections (4b) adjacent thereto in a direction transverse to the longitudinal extent of the section (2a). Contact element (2) according to claim 6,
characterized,
in that the middle section (4a) on the side facing away from the section (2a) extends approximately perpendicular to the longitudinal extent of the section (2a), while the lateral sections (4b) adjoining thereto have surfaces running at an angle to the central section. Contact element (2) according to one of the preceding claims,
characterized,
in that the head part (4) is tapered outwards in a direction transverse to the longitudinal extent of the section (2a) adjoining the head part. Contact element (2) according to one of the preceding claims,
characterized,
that the contact element (2) is made of a sheet material, in particular a sheet metal. Method for contacting a conductive strand-like medium (3) with a contact element (2), in particular according to one of the preceding claims, wherein the strand-shaped medium (3) is wound around the contact element (2) and connected thereto by welding,
characterized,
in that the strand-shaped medium (3) is wound around a section (2a) of the contact element (2) with the recess of a head part (4) of the contact element (2) adjoining the wound section (2a), the recessed head part (4) acting as a Point of application of the welding device is used, so that the time required for the production of the weld fusion of the head part (4) takes place before the melting of the strand-shaped medium (3). Method according to claim 10,
characterized,
that the contact element (2) is higher melting temperature of a material with a melting temperature compared to the strand-like medium (3). Method according to claim 10 or 11,
characterized,
that the welding operation is carried out by arc welding, wherein the head part (4) is used as an arc ignition point.

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