EP3244427A1 - Method of fixing a coil winding - Google Patents

Abstract

The method comprises the method steps: applying a thermally conductive and curable polymer material to at least a portion of the coil carrier; Attaching the electrically conductive coil wire to the coil support such that the coil wire is at least partially covered by the polymeric material; and curing the polymeric material to fix the coil wire by means of the cohesion and / or adhesion of the polymeric material.

Description

The present invention relates to methods of fixing an electrically conductive coil wire to a coil carrier.

Electromagnetic machines or components, such as electric motors, electromagnets, relays, transformers, measuring coils, loudspeakers or the like, have coils, i. wound wire, to generate or detect magnetic fields. The coils or the wire of the coil is for this purpose acted upon by an electric current.

Current-loaded coils have energy losses, which lead to unwanted heating of the coils.

This heat can be dissipated only bad to the outside, ie to the outer surface of the coil, since the wire turns to each other do not have large-area contact. In addition, undesirable air gaps always remain between the wires after the winding process with the previously existing winding method. To eliminate these problems, only winding wires with higher quality or significantly better properties can be used so far. However, this leads to increased creation costs.
Furthermore, it would be possible for larger volumes to be provided for the windings. However, larger volumes are to be avoided for economic as well as ergonomic considerations.

As elaborate and cost-intensive measures hitherto, thermally conductive substances are sometimes applied or introduced in upstream and / or downstream working steps and in the winding process. In this case, only superficially heat is dissipated, as for example in the German patent application DE 102010064072 A1 described, or very costly introduced thermally conductive materials, for example, by applying in the winding process, casting, dipping, trickling, pressing or the like.

It is therefore an object of the present invention to solve the problems described above and in particular to provide a method for producing an improved coil.

This object is achieved according to the invention by the subject matter of independent claim 1. Further embodiments of the inventive subject matter can be found in the dependent subclaims.

For this purpose, a method for fixing an electrically conductive coil wire on a bobbin is to provide, with which eliminates the above problems, a coil wire mounted as effectively as possible on a bobbin and the largest possible heat dissipation can be achieved from a coil out.

A method for fixing an electrically conductive coil wire on a coil carrier is provided for this purpose.

• Auftragen eines wärmeleitfähigen und aushärtbaren Polymerwerkstoff auf wenigstens einen Teilbereich des Spulenträgers;
• Anbringen des elektrisch leitfähigen Spulendrahts auf den Spulenträger, sodass der Spulendraht wenigstens teilweise von dem Polymerwerkstoff bedeckt ist; und
• Aushärten des Polymerwerkstoffs zum Fixieren des Spulendrahts mittels der Kohäsion und/oder Adhäsion des Polymerwerkstoffs.

According to the invention, the method comprises the method steps

• Applying a thermally conductive and curable polymer material on at least a portion of the bobbin;
• Attaching the electrically conductive coil wire to the coil support such that the coil wire is at least partially covered by the polymeric material; and
• Curing the polymer material to fix the coil wire by means of the cohesion and / or adhesion of the polymer material.

Coils produced in this way improve the thermal conductivity (> 0.3 Wm / K) and facilitate the fixation of the coil wire on the coil carrier. The heat loss of the coil winding can be increasingly dissipated to the outer surface of the coil, whereby a longer life with a higher resistance to temperature, vibration and erosion can be achieved. With the method according to the invention, coils with more compact dimensions, ie with a higher power density, are possible. At the same time, the cost can be achieved by choosing a cheaper coil wire quality. The simplified dosage of the fixing or thermally conductive material, the cost can be further reduced.

According to a further advantageous embodiment, it may be possible that the curing of the polymer material takes place by polymerization, polyaddition or polycondensation. The curing can also be referred to as solidification.

According to an advantageous embodiment of the present invention it can be provided that the polymer material is both a thermoset material and a thermoplastic material or elastomer material. As a result, a particularly good thermal conductivity can be achieved. It may be advantageous that the thermoset material a Thermal conductivity of greater than 0.3 Wm / K (> 0.3 Wm / K) has. It has been shown that a particularly good heat removal from the coil can be achieved by using a thermosetting material having a thermal conductivity of greater than 0.3 Wm / K (> 0.3 Wm / K).

It could also be a thermoplastic (e.g., applying a hot melt adhesive) or elastomer (e.g., applying a silicone) as needed (e.g., when only the coil is to be fixed / dampened).

Furthermore, the polymer material may also be an adhesive. As a result, the winding wires can be fixed in a particularly fast and efficient manner.

According to a further embodiment, the polymer material may also be a thermoplastic or an elastomer. The thermoplastic may be a hot-melt adhesive. The elastomer may be silicone.

Further advantages will become apparent from the following description of the figures. In the figures, various embodiments of the present invention are shown. The figures, the description and the claims contain numerous features in combination. The skilled person will conveniently consider the features individually and summarize meaningful further combinations.

Fig. 1a

eine schematische Vorderansicht auf einen Spulenträger mit einem Spulendraht während des Wickelverfahrens;

Fig. 1b

eine schematische Seitenansicht auf den Spulenträger mit dem Spulendraht während des Wickelverfahrens;

Fig. 2a

eine erste Detailansicht auf einen Teilbereich des Spulenträgers mit dem Spulendraht; und

Fig. 2b

eine zweite Detailansicht auf einen Teilbereich des Spulenträgers mit dem Spulendraht.

Show it:

Fig. 1a

a schematic front view of a bobbin with a coil wire during the winding process;

Fig. 1b

a schematic side view of the bobbin with the coil wire during the winding process;

Fig. 2a

a first detail view of a portion of the bobbin with the coil wire; and

Fig. 2b

a second detail view of a portion of the bobbin with the coil wire.

Embodiment:

Fig. 1 and 2 show a schematic representation of a bobbin 1 with a coil wire 2 during the winding process.

The bobbin 1 essentially comprises a carrier element 3 and a first limiting element 4 and a second limiting element 5.

The carrier element 3 has a substantially cylindrical shape.

The coil wire 2 consists of at least one metal. The coil wire 2 has a circular diameter cross-section. However, it is also possible that the average cross section of the coil wire 2 has any other possible shape.

The first limiting element 4 is configured substantially as a first circular disk 4a, and the second limiting element 5 is designed essentially as a second circular disk 4b. As shown in the figures, the second disc 4b has a slightly larger diameter than the first disc 4a. As indicated in the figures, the first disc 4a has a through hole 6, through which the coil wire 2 can be guided.

However, the bobbin 1 or the coil wound from the coil wire 2 can also have any other possible design.

In accordance with the method according to the invention for fixing an electrically conductive coil wire to a coil carrier 1, in a first method step a most uniform layer of thermally conductive and curable polymer material 7 is applied to the cylindrical surface 8 of the carrier element 3. The polymer material 7 has the function of an adhesive.

Even before this thermally conductive and curable polymer material 7 can harden or solidify, the coil wire 2 is wound onto the carrier element 3 of the coil carrier 1 to form a coil or coil winding.

As shown in the figures, the coil wire 2 completely immersed in the still soft polymer material 7, so that the coil wire 2 is completely covered by the polymer material 7. The free end of the coil wire 9 is guided through the through hole 6 in the first disc 4a (see. Fig. 1b ). The amount or the height H of the polymer material 7 on the bobbin 1 is chosen so that the wound to the coil coil wire 2 is still covered exactly by the polymer material 7.

However, according to an alternative embodiment, it may also be possible that significantly less polymer material 7 has been applied to the bobbin 1 than would be necessary to cover the bobbin wound coil wire 2 and to be fed to a further processing step (for example transfer molding, injection molding or the like).

However, according to an alternative embodiment, it may also be possible that significantly more polymer material 7 was applied to the bobbin 1 than would be necessary to cover the bobbin wound to the coil 2. The excess polymeric material 7 may serve to provide additional components, such as e.g. e.g. Cooling elements, bearing shells, components for fixing the coil or bobbin 1 or the like to connect to the bobbin 1. The additional components are not shown in the figures.

Furthermore, in the first limiting element 4 and / or second limiting element 4, different through-holes, e.g. Channels, be provided. Additional polymer material 7 can flow through these through-holes or channels for attaching further components or components. In addition, the connection between bobbin 1 and other components and components, e.g. Laminated core or its base insulation, can be further improved by a previous filling of existing holes or channels. The improvement relates in particular to mechanical and thermal connection. Neither the different through holes nor the other components or components are shown in the figures.

Before, during or after the coil wire 2 and / or further components or components are connected to the coil carrier 1, the polymer material 7 can harden or solidify. The curing or solidification can be carried out for example by polymerization, polyaddition or polycondensation.

Furthermore, the hardening process by adding a hardener (eg 2-component polymer / adhesive) before, during or after application as well as before, during or after application by using a trigger (eg UV, visible light and / or heat radiation , Humidity, etc.) are started.

It is also possible to fix the polymer material 7 in a previous working step in order to allow it to be cured after this work step (for example in the case of dual-curing polymer materials / adhesives). As a result, a permanent, fixing and protective connection is made.

Claims (3)

Method for fixing an electrically conductive coil wire 2 on a coil carrier (1),
characterized by the method steps, - Applying a thermally conductive and curable polymer material (7) on at least a portion of the bobbin (1); - Attaching the electrically conductive coil wire (2) on the bobbin (1), so that the coil wire (2) is at least partially covered by the polymer material (7); and - Curing of the polymer material (7) for fixing the coil wire (2) by means of the cohesion and / or adhesion of the polymer material (7). Method according to claim 1,
characterized in that the curing of the polymer material (7) by polymerization, polyaddition or polycondensation take place. Method according to claim 1 or 2,
characterized in that the polymer material (7) is both a thermoset material and a thermoplastic material or elastomer material.

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