DE8717339U1 - Electromagnet with a single coil body - Google Patents

Description

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PHILIPS PATENT ADMINISTRATION GMBH PHD 87-084

DESCRIPTION

Electromagnet with a single coil body

The innovation relates to an electromagnet with a single coil body and two U-shaped, magnetically separated, Λ yoke irons arranged one above the other, each of which passes through the coil body with one leg, whereby the free ends of the yoke irons serve as pole shoes.

Electromagnets are known in countless designs. Basically, they consist of a coil in whose cavity an electromagnetic field is formed when excited. In certain types of electromagnets, this coil is wound on a coil body. The coil body itself has a cavity running in the direction of the coil axis, through which a generally soft magnetic piece of iron extends. At the two axial

Electromagnetic poles \ ) of opposite polarity are then formed at the ends of the iron. The iron parts protruding from the coil can also be angled in such a way that the two electromagnetic poles of opposite polarity lie next to each other. Such electromagnets are also called excitable horseshoe magnets.

Depending on their strength, electromagnets are used as actuating magnets or holding magnets.

Holding magnets are not able to/ to a certain

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Distance to have an attractive effect * Their advantage, however, is that they require relatively little current-

The known modes of operation of electromagnets are always based on the fact that each electromagnet can only act on a specific part, whether by attracting or holding. However, there are precisions in technology where multiple magnetic effects are required next to each other. These multiple magnetic effects are usually served by individual magnets arranged next to each other. However, several individual magnets next to each other require separate control and an independent mechanical structure.

The aim of the innovation is to create an electromagnet that makes it possible to control two device functions with one magnet.

The task is solved by the fact that the yoke irons pass through the coil with one leg each in such an opposite manner that two pole shoes are located in the area of both axial coil ends, with one pole shoe being connected to a first and the other pole shoe being connected to a second armature plate.

work together.

The electromagnet can also perform two device functions via the two anchor plates; it is possible to pull either one or the other or both anchor plates towards itself, depending on whether these anchor plates are enabled for pulling. If the electromagnet

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only designed as a holding magnet; then it can hold the anchor plate that is moved towards it or release it.

According to a further development of the innovation, the yoke irons are arranged in planes that run parallel to each other. This leads to a very compact arrangement.

iö According to a further embodiment of the innovation, it is provided that a yoke iron is designed to be permanently magnetic. In such an embodiment, when the coil is excited, for example, one armature plate can be drawn in and the other armature plate can be repelled or released. In this way, practically opposing functional sequences can be controlled.

According to a further development of the innovation, the electromagnet is designed as a holding magnet. In this case, the coil draws very little current and even a permanent hold of two armature plates does not lead to excessive heating. Here too, opposing movements can be controlled by using permanent magnetic material in one of the yokes.

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The innovation is explained in more detail using examples. They show:

Fig. 1 an embodiment of an electromagnet with two yoke irons and two armature plates and

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Fig. 2 shows an embodiment within the framework of a special example of an electrical device, in particular a magnetic tape recorder, whereby the function control can be held at two different distances. 5

An electro-magnetic holding device 15 shown in Fig. 1 has a magnetic coil 20 wound on a coil body 16. The coil body is attached to a carrier 12 from which connecting wires 13, 14 are led out. The coil body 16 has flanges 20a, 20b which delimit the respective axial ends of the coil 20. One leg of U-shaped yoke irons 22, 23 is inserted into the axial cavity 21 of the coil body. The yoke irons 22, 23 are provided with yokes 22b, 23b outside the coil flanges 20a and 20b respectively. When the yoke irons 22, 23 are placed one above the other, pairs of legs 22a, 23a of the yoke irons 22, 23 are placed one above the other*. The pole shoes 22c, 23c that form at the ends of the legs are then placed next to each other, with two pole shoes 22c in the example above the yoke 23b and two pole shoes 23c below the yoke 22b each lying next to each other.

An anchor plate 25 with an anchor surface 25b is located opposite the pole shoes 22c. The anchor plate 25 can be moved in the direction of a double arrow 25c. An anchor plate 24 with an anchor surface 24b is located opposite the pole shoes 23c. The anchor plate 24 can be moved in the direction of

a double arrow 24c movable relative to the Pölschuhe 23c.

5 PMD87-084

Assuming that the yoke irons 22 and 23 are both made of soft magnetic material and the magnetic coil is designed as a holding coil, then the armature plates 24 and 25 which are brought up to the pole shoes 22c and 23c respectively can adhere to the pole shoes 22c and 23c when the coil is excited.

After de-energizing the magnetic coil 20, the armature plates 24, 25 can be removed depending on the device mechanisms assigned to them. If one of the yokes 22 or 23 is designed to be permanently magnetic and the permanent magnetization runs against the field of the magnetic coil 20, then when the coil 20 is excited, the armature plate interacting with the iron poles of the yoke irons can be held in place, while the other armature plate falls off as a result of the cancellation or reduction of the magnetic effect by the reverse permanent magnetic excitation of the yoke iron.

The general functional sequence shown in Fig. 1 can be made more specific for a specific application area,

^ 20 for example in a magnetic tape recorder. It is important to hold a head plate in two working positions, for example, with one functional part for

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however, it can also be a shortening of a functional part in general, matching parts of Fig. 1 and are provided with the same reference numerals.

In the embodiment according to Fig. 2, a functional part 11 is arranged in front of a diagrammatically illustrated electro-magnetic holding device 15. The electro-magnetic holding device 15 has a magnetic coil 20 which is axially delimited by coil body surfaces 20a and 20b.

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One leg of each U-shaped yoke iron 22, 23 is inserted into the coil cavity 21 of the coil body 16. The two magnetically separated yoke irons 22,

23 are located on top of each other, with the respective

Pairs of legs 22a, 23a overlap in pairs. The yokes 22b, 23b lie on opposite coil body flanges 20a, 20b. The electro-magnetic holding device 15 is fixedly mounted on a chassis plate (not shown).

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f With pole shoes 23c and 22c work a first anchor plate

24 and a second anchor plate 25. The first anchor plate 24 is arranged rotatably on a carriage 26 by means of a pin 24a. This carriage 26 engages with a guide pin 26a in a guide groove 27 of the functional part 11. A guide pin 26b of the carriage 26 can be guided along in a curved groove 28 of the functional part 11. The arcuate groove 28 runs at an oblique angle, beginning transversely to the groove 27, in an arc in the direction of the electro-holding magnet device.

tung 15. A tension spring 29 ensures that the !

Guide pin 26b normally in the end area 28a of the |i

arched groove. In this position j.

( the slide 26 above the functional part 11 parallel

to this.

The second anchor plate 25 is arranged on an arm 30 so that it can rotate by means of a pin 25a. The arm 30 itself is L-shaped and has a shorter arm part 30a, which also carries the second anchor plate 25 and which can be rotated at its free end 30b about an axis of rotation 31 in the direction of a double arrow 32. A longer arm part 30c

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extends parallel to the magnetic coil 20 to a side surface 33 of the carriage 26, where it ends in front of a nose 34 of the carriage with an inclined run-on surface 35.

The armature plates 24 and 25, when they are placed on the pole shoes 23c and 22c respectively, can adhere to these pole shoes when the magnetic coil 20 is excited. This adhesion allows them to determine two working positions of the head plate as long as the magnetic coil 20 is excited. Only when the magnetic coil 20 is de-excited do both or only one armature plate, depending on whether both or only one were applied, fall off and the spring 19 can pull the functional part 11 into a rest position against a spring 37 on the functional part 11.

The interaction of a functional part 11, for example the head plate of a magnetic tape recorder (not shown) with the electromagnet device is now described in more detail based on its function. The magnetic coil 20 is de-energized and the armature plate 24 has moved away from the pole shoes 23c of the yoke 23 because the functional part Ii has withdrawn from the electromagnet device in the direction of an arrow 11a under the pretension of the spring 37a. The armature plate 25 rests on the pole shoes 22c because a tension spring 36 on the arm part 30c ensures constant contact. If the functional part is to be transferred to a first working position, for example for playing, and remain in this first working position, then a not shown

itO actuator the functional part 11 in the direction of an arrow 11b against the electro-magnetic holding device. The magnetic coil 20 remains unexcited. By moving the

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When the functional part 11 is moved in the direction of the electro-magnetic holding device 15, the nose 34 of the carriage 26 strikes the inclined surface 35 of the longer arm part 30c. The tension spring 36 is so weak that the nose 34 presses the surface 35 and thus the longer arm part 30c outwards in an anti-clockwise direction. The guide pin 26b remains in the groove end 28a. The functional part 11 guides the first armature plate 24 against the pole shoes 23c. The magnetic coil 20 is now excited and the armature plate 24 is held firmly on the pole shoes 23c. The functional part 11 is thus held in the first working position. If the magnetic coil 20 is de-energized, the functional part 11 returns to its starting position. From this starting position, a second working position, for example for fast winding, can also be approached.

In order to get into the second working position for fast winding, the magnetic coil 20 is first excited. The second armature plate 25 is already resting on the pole shoes 22c, and the pulling force of the tension spring 36 is now joined by the magnetic holding force. It has therefore become more difficult to swing the longer arm part 30c away in an anti-clockwise direction. If the functional part 11 moves in the direction of the

arrow 11b, then the nose 34 of the slide 26 is not able to pivot the longer arm part 30c away. This means that the nose 34 has to give way in front of the surface 35 of the longer arm part 30c. The guide pin 26b is therefore pushed in the direction of the arrow 28c to the other end 28b of the arcuate groove 28. Due to this movement, the slide 26 slides while simultaneously

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Turning in the direction of an arrow 26b with the guide pin 26a in the groove 27 in the direction of the electro-magnetic holding device 15. This means that the functional part 11 is practically extended in the direction of the electro-magnetic holding device 15. This extension results in the functional part 11 not being able to advance as far in the direction of the electro-magnetic holding device 15 as was previously described with respect to the first working position. The first working position is thus obtained in which the electro-magnetic holding device holds the functional part 11.

If the functional part 11 is to return to its rest or initial position, the magnetic coil 20 is de-energized. This causes the armature plate 24 to detach from the pole shoes 23c. The tension spring 37a pulls the functional part 11 back to its rest or initial position. The overall advantage of the device is that only very few components are required and in particular only a single electromagnet. This makes the entire functional structure significantly simpler.

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Claims (4)

&bull; · · ■ · · ·1 11 1| I · · J BHl (11) 1 > ■ · t till ti > 1 » ·» ■ ■ B 11 tit Jl ■ ■ IC »I Il Il 10 PHD 87-084 CLAIMS 1. Electromagnet with a single coil body (16) and two U-shaped yoke irons (22, 23) arranged one above the other in a magnetically separated manner, each of which passes through the coil body (16) with a leg, the free ends of the yoke irons (22, 23) serving as pole shoes ( 22c, 23c), characterized in that the yoke irons (22, 23) pass through the magnetic coil (20) in such an opposite manner with a leg (22a, 23a) each such that two pole shoes (22c, 23c) are located in the region of both axial coil ends, one pole shoe (23c) interacting with a first armature plate (24) and the other pole shoe (22c) interacting with a second armature plate (25). 2. Electromagnet according to claim 1j, characterized in that the yoke irons (22, 23) lie in planes parallel to one another. 3. Electromagnet according to claim 1, characterized in that a yoke iron (22 or 23) is permanently magnetic. 4. Electromagnet according to one of claims 1 to 3, characterized in that it is designed as a holding magnet. 25