EP0811995A1 - Magnet coil and method for manufacturing the same - Google Patents

Abstract

The electromagnet/solenoid has a housing Ä18Ü within which a coil Ä2Ü wound on a former Ä1Ü is located. At the centre of the coil is a core Ä3Ü and armature (4). The ends of the coils are brought out to a pair of metal connector blades Ä7Ü. The blades are embedded in the housing and connect with the ends of round pins Ä5Ü that are connected to the ends of the coils. The coil ends are wound and soldered to the pins. The pins are a press fit into shaped holes in the connector blades.

Description

The invention relates to a magnetic coil and a method for its production.

• einem Spulenkörper aus gewickeltem Spulendraht, dessen beide Enden nach außen geführt sind,
• zwei Kontaktstiften, die jeweils mit einem Ende des Spulendrahts umwickelt sind,
• zwei mit den Kontaktstiften koppelbare Anschlußzungen sowie
• einer Kunststoffummantelung.

Magnetic coils consisting of are known from practice

• a coil body made of wound coil wire, the two ends of which are led outwards,
• two contact pins, each wrapped with one end of the coil wire,
• two connecting tongues that can be coupled with the contact pins and
• a plastic jacket.

The electrical connection between the contact pins and the coil wire, which is usually insulated with lacquer, is produced by suitable mechanical or electrical energy application. From DE-A-43 13 608, the contact pin and the coil wire are excited by coupling vibrations in the ultrasound range, contacting being produced by the friction between the coil wire held under pretension and individual regions of the contact pins that come into contact with the wound coil wire. The connecting tongues are usually welded to the contact pins. The resulting relatively rigid connection leads to a relatively high failure rate in the mass production of such magnetic coils by tearing off the usually very thin coil wire, which may be only 0.04 mm thick. This demolition is caused by the inevitable Relative movements of the connecting tongues to the coil body when inserting and processing in the plastic coating form.

The invention is therefore based on the object of improving the magnet coil and the method for its production with a view to a lower failure rate and thereby simplifying the production.

This object is solved by the features of claims 1 and 6.

Further embodiments of the invention are the subject of the dependent claims.

By coupling the connecting tongues to the contact pins in such a way that on the one hand an electrical connection and on the other hand a displaceability of the connecting tongue with respect to the contact pin in its longitudinal direction is ensured, a relatively flexible connection between the contact pin and connecting tongues results. This connection catches the inevitable relative movements of the connecting tongues with respect to the coil body, without the coil wire tearing off on the contact pin.

In a particularly advantageous embodiment, the connection between the connecting tongue and the contact pin not only permits a relative displacement in the longitudinal direction of the contact pin, but also additionally transversely to this direction. This provides an additional degree of freedom, which ensures an even more flexible connection between the connecting tongue and the contact pin or coil body.

According to the invention, the coil wire, which is usually coated with an insulating lacquer layer, is contacted with the contact pins by dip soldering. For this purpose, the area of the contact pins, which is wrapped with the coil wire, is immersed in a solder bath, the temperature of which is so high that the insulating lacquer dissolves and an electrical connection between the contact pin and the coil wire results from the solder.

Further advantages and refinements of the invention are explained in more detail on the basis of the following description of an exemplary embodiment and the drawing.

Fig.1

eine Schnittdarstellung einer erfindungsgemäßen Magnetspule,

Fig.2

eine Schnittdarstellung längs der Linie II-II der Fig.1,

Fig.3

eine vergrößerte Detailansicht im Bereich der Kontaktierung zwischen Anschlußzunge und Kontaktstift,

Fig.4

eine Schnittdarstellung an der Linie IV der Fig.1;

Fig.5

eine Aufsicht auf einen Anschlußzungenträger sowie

Fig.6

eine Schnittdarstellung eines zweiten Ausführungsbeispieles.

Show in the drawing

Fig. 1

2 shows a sectional illustration of a magnetic coil according to the invention,

Fig. 2

2 shows a sectional illustration along the line II-II of FIG. 1,

Fig. 3

an enlarged detail view in the area of contact between the connecting tongue and contact pin,

Fig. 4

a sectional view on the line IV of Figure 1;

Fig. 5

a supervision of a tongue carrier as well

Fig. 6

a sectional view of a second embodiment.

The magnetic coil shown in FIG. 1 essentially consists of a coil body 1 with a wound coil wire 2, a magnetic core 3 and an armature 4.

Furthermore, two contact pins 5, 6 are provided, around each of which one end of the coil wire 2 is wound. These contact pins 5, 6 are inserted at one end into the coil body 1 and are each coupled at their other end to a connecting tongue 7, 8.

The two connecting tongues 7, 8 are arranged on a tongue carrier 9 which is held on a magnet yoke 10 of the magnet coil.

The connecting tongues 7, 8 have clamping means for coupling to the contact pins 5, 6, which on the one hand ensure an electrical connection and on the other hand a displaceability of the connecting tongues relative to the contact pins in the longitudinal direction thereof. In the preferred exemplary embodiment shown in the figures, these clamping means also allow the connecting tongues to be displaced relative to the contact pins transversely to the longitudinal direction of the contact pins.

In the exemplary embodiment shown, these clamping means are designed as slots 11, 12 in the connecting tongues 7, 8, the contact pins 5, 6 being held between the flanks 11a, 11b and 12a, 12b delimiting the slot 11, 12. The two flanks 11a, 11b and 12a, 12b are slightly bent, the resulting slot width being slightly smaller than the width of the contact pins, which are preferably square in cross section. The two flanks of a slot have a resilient effect, so that a secure electrical connection is ensured when plugged onto a contact pin. Even after plugging in, the connecting tongues can be moved in the longitudinal direction of the contact pins (double arrow 13).

As can be seen in particular from FIG. 4, this type of coupling also enables a relative mobility transversely to the longitudinal direction of the contact pins, as is indicated by the double arrow 14. The contact pins are displaced in the direction of the slots 11, 12.

The two connecting tongues 7, 8 are arranged on the connection carrier 9 shown in FIG. 5, this connection carrier 9 having two snap hooks 15, 16 which can be coupled to the magnetic yoke 10. At the same time, an electrical contact is made between a grounding tongue 17 and the magnetic yoke 10. While the individual connecting tongues consist of electrically conductive material, in particular metal, the connection carrier 9 is made of non-conductive material, preferably plastic.

6 shows a second exemplary embodiment according to the invention, which differs from the previously described variant only in that the connecting tongues 7, 8 are not arranged on a connecting carrier.

The individual process steps in the manufacture of the magnetic coils according to the invention are explained in more detail below:

In a first process step, the two ends of the coil wire 2 are automatically wound onto one of the two contact pins 5, 6. The contact pins are then pressed deeper into the coil body 1 in order to relieve the wound coil wire.

Since the coil wire is usually covered with an insulating varnish layer, there is still no electrical connection between the coil wire and the contact pin at this stage of manufacture. This is now produced according to the invention in that the end of the contact pin wound with the coil wire is immersed in a solder bath which has a temperature of more than 350 ° C., preferably more than 450 ° C. At this temperature, the insulation layer of the coil wire 2 is dissolved and the solder establishes an electrical connection between the coil wire and the contact pin.

In a next step, the connecting tongues 7, 8 are plugged onto the contact pins 5, 6. In the exemplary embodiment described in FIGS. 1 to 5, the connecting tongues are held on the connecting carrier, so that the push-on operation for both connecting tongues takes place simultaneously. The holder of the connection carrier is ensured via the snap hooks 15, 16.

In a final step, the magnetic coil is encased in a suitable form with plastic.

The special type of coupling of contact pins 5, 6 and connecting tongues 7, 8 results in a relatively flexible connection. As a result, the inevitable relative movements between the connecting tongues and the coil take place without a relative movement between the contact pin and the coil taking place. These inevitable relative movements occur in particular in the last method step, namely in the plastic casing 18. The extremely thin coil wire, which may only has a diameter of 0.04 mm, is thus protected much more reliably against tearing off at this stage of the process.

In addition, the type of connection of coil wire 2 and contact pins 5, 6, on the one hand, and the clamping means of the connecting tongues represent means which considerably simplify the manufacturing process itself. A welding process can thus be dispensed with, in particular when contacting the connecting tongues. Thus, the magnetic coils according to the invention can be produced not only with less effort but also with a lower reject rate.

Solenoid coils of this type are used, for example, in connection with solenoid valve coils with which valves of fluid lines can be controlled.

Claims (7)

Magnetic coil consisting of - a coil former (1) with a wound coil wire (2), the two ends of which are led outwards, - two contact pins (5, 6), each of which is wrapped with one end of the coil wire (2), - Two with the contact pins (5, 6) connectable connecting tongues (7, 8) and - a plastic casing (18),
characterized in that - The coil wire (2) wound on the contact pins (5, 6) is dip-soldered and - The connecting tongues (7, 8) for coupling to the contact pins (5, 6) have clamping means which, on the one hand, ensure an electrical connection and, on the other hand, a displaceability of the connecting tongue with respect to the contact pin in its longitudinal direction. Magnetic coil according to Claim 1, characterized in that the clamping means also allow the connecting tongues (7, 8) to be displaced with respect to the contact pins (5, 6) transversely to the longitudinal direction of the contact pins. Magnetic coil according to Claim 1, characterized in that the clamping means are formed by a slot (11, 12) in the connecting tongue (7, 8), the contact pin (5, 6) between the flanks (11a, 11b; 12a delimiting the slot) , 12b) is held. Magnetic coil according to claim 3, characterized in that the flanks (11a, 11b; 12a, 12b) of the slots (11; 12) are bent. Magnetic coil according to Claim 1, characterized in that the connecting tongues (7, 8) are provided on a connecting tongue carrier (9) which is held on a magnetic yoke (10) of the magnetic coil by means of snap hooks (15, 16). Process for producing a magnetic coil, characterized by the combination of the following process steps: - The ends of a coil wire (2) of a coil body (1) are automatically wound onto a contact pin (5, 6), - The contact pins (5, 6) are pressed deeper into the coil body (1) to relieve the wound coil wire (2), - the wound coil wire (2) is dip-soldered, - On the contact pins (5, 6) connecting tongues (7, 8) are plugged in such a way that on the one hand an electrical connection between the contact pin and connecting tongue and on the other hand a relative mobility of the connecting tongue (7, 8) in the longitudinal direction of the contact pin (5, 6) is guaranteed and - The magnetic coil is covered with plastic. A method according to claim 6, characterized in that the wound coil wire (2) is dip-soldered in a solder bath at a temperature of more than 350 ° C, preferably more than 450 ° C.

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