DE1749610U - ELECTROMAGNET, IN PARTICULAR AC MAGNET. - Google Patents

Description

Electromagnet, in particular alternating current magnet.

The innovation relates to an electromagnet, as it is in particular for Operation of stamp devices on control clocks or used for similar purposes will.

For such devices and facilities were previously primarily DC magnets are used, as these are in contrast to AC magnets when Respond less strongly "pop" (hit hard) and also do not hum and therefore the work to be carried out much more evenly and with less noise than would be possible with conventional AC magnets. These had a performance curve that rises sharply at the end of the stroke, what causes the hard hitting with constant power extraction., On the other hand, will If the lifting speed is reduced by increasing the power take-off, a slab becomes a slab caused, which stems from the fact that over a certain period of time an even noticeable There is an air gap, its air mass from the pole faces of the Magnets, which swing in the rhythm of the exciting alternating current, is excited.

On the other hand, however, the use of AC magnets would Make it easier and cheaper because the AC magnet has the same power in and of itself cheaper than a DC magnet and, above all, no rectifier requires, as is the case for direct current magnets in today's commonly used alternating current networks is required.

For these reasons, attempts have already been made to improve the properties of the alternating current magnets by providing additional mechanical, hydraulic or pneumatic damping devices on these magnets, which are intended to dampen the hard impact of the armature. Apart from the fact that the hum of the mag- nuibh not only upset, but even reinforced de, the additional effort was mostly disproportionate to the advantages achieved, so that in many cases the DC magnet was used again.

The present innovation aims to address the disadvantages mentioned To fix alternating current magnets and to train them without additional equipment in such a way that that they one uniform suit and the hum of the Magnets is limited to a minimum.

For this purpose, according to the innovation, they are usually used as anchors and yoke or core designated iron parts of the electromagnet designed in such a way, that these partially interlock and thereby cause the anchor to tighten, magnetic lines of force running through the air gap with increasing approach of the anchor to the yoke run more and more transversely to the direction of pull and so that for the force on the armature no longer effective magnetic field with decreasing air gap gets stronger. The performance curve resulting from this arrangement can be compared to the required power requirement, e.g. Easily adjust for control clocks.

In this way, the well-known process that the pulling force of a AC magnet with the reduction of the air gap between armature and yoke increases sharply, counteracts and thereby the hard hitting or "popping" of the Ankers substantially mitigated respectively. eliminated. Because the air gap for the transverse to the direction of pull running field lines evenly throughout the last part of the stroke remains very small! this part of the magnetic field provides practically none Contribution to the hum of the Magneterm when the armature is not in contact.

The total hum of the magnet is also according to the invention and no longer occurs, especially if the magnet responds for a short time on.

The object of the innovation is in several embodiments shown schematically in comparison to the previously common magnet shapes.

Fig. 1 shows a solenoid of the previous type.

Fig. 2 shows a similar magnet in the novel design.

FIG. 3 is a view from above of the magnet according to FIG. 2.

Fig. 4 shows a multi-legged magnet of previous design.

Fig. 5-Fig. 8 show several embodiments of multi-legged Magnets in the new design.

Figs. 9-12 are different embodiments for each other Interlocking of anchor and yoke.

The novel solenoid shown in FIG. 2 consists. how common from a core or yoke 1, a magnetic coil 2 and an armature 3. The lower one The end of the armature 3 is formed into a pin 4 or the like, which in a corresponding to the Cross section of the pin-shaped cutout 5 of the yoke 1 engages more or less.

As a result of this design, in contrast to the course of the force lines of the previous type of magnet shown in FIG. 1 not all by the Air gap S running lines of force in the pulling direction of the anchor, rather run partially in a direction perpendicular to the direction of pull of the anchor lies what comes about because a certain part of the lines of force lead the way selects between the pin 4 and the inner surface of the cutout 5 (Fig. 2). This The proportion is greater, the further the pin 4 engages in the cutout, that is greatest at the end of the anchor stroke. By choosing the appropriate form and Cross section of the pin and the cutout can be the degree of division of the magnetic Depending on the working stroke and thus the performance curve of the electromagnet can be designed in any desired manner.

9-12 are various embodiments for the pin 4 and the section 5 shown. So the tenon and the cutout can be in their Shape cylindrical or prismatic (Fig. 2) or also conical (Fig. 9) or pyramidal be and thereby creaSrmigen (Fig. 10) elliptical or rectangular (Fig. 11) cross-section have, in the latter case the cutout (5) also has the shape one continuous slot in the yoke 1, so this at this point is interrupted.

In a similar way, the iron parts of the previously usual, designed multi-legged magnets shown in FIG. The anchor, as can be seen from FIG. 5, only one pin 4, preferably on the central leg 6 have. However, two or three such pins 4 can also be provided as shown in Figs. Shape and cross-section of this Tenons and the associated cutouts, in these cases in the form of holes are executed in the legs, are designed in the same way as in previous example has already been described.

As shown in Fig. 8 of the drawing, are instead of the pin 4 and Cutouts 5 also overlapping steps 7 and 8 possible, each of which fits into one another be provided on the armature 3 and on the yoke 1. The mode of action is the same as with the embodiments described above, it being noted that the Steps are not only right-angled, but also obtuse-angled or rounded can be and thus to achieve any desired line of force is. Of course, the invention is not only limited to those described and in Examples shown in the drawing are limited, but can be used in the same way even to other electromagnets with other embodiments z. Bb hinged armature magnets or the like can be used. It is also noted that not only AC magnets can be designed in the form according to the innovation, but as well as DC magnets, for example if there is a falling force curve the same is required.

Claims (7)

Protection claims: 1. Electromagnet, especially AC magnet, characterized in that the armature (3) and yoke (1) or in some other way designated iron parts of the magnet (1,2,3) partially inside or on top of each other grip in such a way that the air gap (S) between the armature and the yoke the force lines causing the anchor (3) to be tightened as the size of the air gap decreases (S) run more and more transversely to the pulling direction of the anchor and thereby that of the The force line field causing the armature to tighten is correspondingly weakened. 2. Electromagnet according to claim 1, characterized in that the The armature (3) of the magnet is provided with a peg-like extension (4) or the like, which engages in a correspondingly shaped cutout (5) of the yoke (1). 3. Electromagnet according to claims 1 and 2, characterized in that that the pin-like approach (4) and the cutout (5) according to the desired Degree of deflection of the lines of force in their shape parallel or oblique or are limited by curved surfaces. 4. Electromagnet according to claims 1-3, characterized in that that the pin-like approach (4) and the cutout (5) circular, oval or rectangular-like Have cross-sections. 5. Electromagnet according to claims 1-4, characterized in that that the cutout (5) in the form of a, the yoke (1) interrupting, continuous Transverse slot is formed. 6Electromagnet according to claim 1, characterized in that the yoke (1) and the anchor part (3) are provided with steps (8 or 7) or the like, which are mutually exclusive grab one another. 7. Electromagnet, especially AC magnet, as described and shown on the drawing.