EP3226263A1 - Electromagnetic holding magnet, method for producing the same, electromagnetic locking element and use of the same - Google Patents

Abstract

The invention relates to an electromagnetic pressure magnet (2) and a method for producing the same, an electromagnetic locking element and the use thereof. The electromagnetic pressure magnet 2 comprises a yoke 6 and an adhesion plate 4 cooperating with the yoke 6 as anchor. At least one permanent magnet 14, 16 generates a magnetic holding flux in the yoke 6, which comprises a first yoke leg 8 and a second yoke leg 10 and a center pole 12 , The center pole 12 is partially surrounded by a magnetic coil 18. The first and second yoke legs 8, 10 are arranged symmetrically with respect to the center pole 12 and the magnet coil 18.

Description

The invention relates to an electromagnetic holding magnet, comprising a yoke, an adhesive plate cooperating with the yoke, at least one permanent magnet and a magnetic coil which surrounds the yoke in regions, wherein the magnetic coil is adapted to one of the permanent magnet in the yoke in the energized state and at least reduce the magnetic holding flux generated by the adhesion plate so as to at least reduce or release a holding force generated by the permanent magnet and release the anchor. Furthermore, the invention relates to an electromagnetic locking element, comprising a base element, an opening element movable relative to the base element and an electromagnetic holding magnet. The invention also relates to the use of such an electromagnetic locking element. Furthermore, the invention relates a method for producing an electromagnetic holding magnet, comprising a yoke, an adhesive plate cooperating with the yoke, at least one permanent magnet and a magnetic coil which surrounds the yoke in regions, wherein the magnetic coil is adapted to one of the permanent magnet in the energized state Yoke and the adhesive plate produced at least reduce magnetic flux retention, so as to at least reduce or cancel a holding force generated by the permanent magnet and release the armature.

Electromagnetic magnets are used for example in locking devices. Such is for example in DE 41 31 156 C1 described. The locking device is used in a container which comprises a door pivotable about a hinge and receives in its interior a Sauerstoffnotversorgungssystem. Such containers are used in aircraft, for example in commercial aircraft.

Known locking devices consist of an electromagnet and a parallel-connected permanent magnet and a rotatably mounted rocker arm. The rocker arm is held on the one hand by the permanent magnet in a horizontal locking position and in turn holds a tubular locking piston in a closed position. The locking piston presses on a spring on a ball cage, which holds the balls inside a positive fit in an undercut of a coupling pin. The coupling pin is connected to the pivotable door as a locking part. To open the door, for example when activating the oxygen emergency supply system, the electromagnet of the locking device is energized, so that the holding force generated by the permanent magnet is canceled or at least reduced. This releases the rocker arm from the pole pieces of the permanent magnet, is brought by a spring in an open position and releases the locking piston. The balls are disengaged from the coupling pin, the door of the container is unlocked and swings open.

Known electromagnetic holding magnets, as they are widely used in the locking device described, have an asymmetric structure and, accordingly, also an asymmetric field distribution. To trigger such a holding device, relatively high currents in the switching coil of the electromagnet are required to effectively compensate for the magnetic holding force of the permanent magnet. The required release power of the locking device or the electromagnetic holding magnet is therefore relatively high.

Furthermore, in many cases a complex shaping of its components, in particular of the yoke, is required for the construction of electromagnetic holding magnets in such known locking devices. This requires, on the one hand, a large number of assembly and production steps and, on the other hand, regular reworking of various components during the manufacturing process.

It is an object of the invention to provide an electromagnetic pressure-sensitive magnet, an electromagnetic locking element, the use of an electromagnetic locking element and a method for producing an electromagnetic pressure magnet, wherein the electromagnetic pressure magnet or the electromagnetic locking element with low power to be switched and also be structurally simple ,

The object is achieved by an electromagnetic holding magnet, comprising a yoke, an adhesive plate cooperating with the yoke, at least one permanent magnet and a magnetic coil which surrounds the yoke in regions, wherein the magnetic coil is adapted, at least in the energized state, a magnetic holding flux generated by the permanent magnet in the yoke and the adhesive plate so as to at least reduce or cancel a holding force generated by the permanent magnet and release the holding plate, the electromagnetic holding magnet being formed by the yoke comprising a first yoke leg, a second yoke leg and a center pole, the yoke legs each having a partial flow lead the magnetic holding flux and are arranged symmetrically with respect to the center pole and this at least partially surrounding the magnetic coil.

The electromagnetic pressure-sensitive magnet according to aspects of the invention is symmetrical with respect to the magnetic flux guide. Advantageously, the triggering power of the magnet is reduced or minimized by this symmetrical structure. In other words, therefore, a small current is necessary to excite the magnetic coil so that the magnetic flux generated by it compensates for the magnetic flux of the at least one permanent magnet. The magnetic holding flux is reduced by the magnetic coil so far that a particular coupled to the adhesive plate spring is able to lift them from the yoke. For this it may not be necessary to completely compensate for the magnetic holding flux. However, it is also provided in particular that the magnetic holding flux is completely compensated by the magnetic field generated by the magnetic coil. Conventional electromagnetic holding magnets often include only a single permanent magnet for reasons of cost. However, this leads to an asymmetrical structure, in particular of the yoke, and a corresponding asymmetric magnetic field distribution within the yoke. The compensation of such an asymmetrical magnetic holding flux during the tripping operation requires a high tripping power. Due to the symmetrical structure of the electromagnetic pressure magnet this disadvantage is eliminated.

In the yoke of the electromagnetic holding magnet, the magnetic holding flux flows in the central center pole in the direction of the adhesive plate, enters into this and branches into two separate magnetic partial flows, which flow back through the first yoke leg or the second yoke leg. When the magnet coil surrounding the center pole at least partially is energized, this reduces or completely stops the magnetic holding flux in the central center pole. However, at least the magnetic holding flux is reduced so much that the holding force generated by the permanent magnet is reduced or even completely canceled. The acting as an anchor adhesive plate is released. Due to the symmetrical field distribution, a lower current or tripping current is necessary in comparison to conventional electromagnetic holding magnets with an asymmetric structure, in order to reduce the holding flux present in the center pole by means of the magnetic coil to the extent that the adhesive plate is released.

According to an advantageous embodiment, it is further provided that the first yoke leg, the second yoke leg, the center pole and the adhesive plate consist of flat parts. In particular, a magnetic bypass, which will be explained in more detail later, made of flat parts or consists of these. The flat parts are preferably made of pre-annealed, heavy-rusting or stainless sheet metal.

According to a preferred embodiment, the electromagnetic holding magnet, at least as far as the abovementioned components are concerned, is constructed or manufactured exclusively from flat parts. The flat parts are preferably stamped flat parts. On a complex shape when punching, bending tight radii, as well as a post-processing of the stampings including a subsequent demanding assembly can be advantageously dispensed with.

Since the flat parts are produced in particular from pre-annealed, heavy-rusting or stainless sheet metal, it is possible to dispense with reworking, in particular the subsequent magnetic soft annealing of the individual parts and the associated post-processing processes, for example a straightening process. It is also not necessary to apply a surface protection on the sheets.

It is particularly advantageous if it is provided according to a further embodiment that the first end face of the first yoke leg, the second end face of the second yoke leg and the central end face of the middle pole are ground surfaces. By grinding the front sides, a forced flatness of these end faces is effected. In other words, therefore, the first end face, the second end face and the central end face extend after grinding in a common plane. It is also possible to dispense with the conventionally widely used surfaces. These always require a small forced air gap between the stop plate abutting the end faces and the end faces of the yoke, which results in a reduction in the magnetic force acting on the retaining plate.

Preferably, the unground sheet metal parts of the magnet are arranged sturdily in a mounting process with a relatively large tolerance and then fixed, for example, by casting with a curable substance (for example, synthetic resin). In the subsequent grinding process then receives the Blechrohkörper the magnet a flat face with very high accuracy. Alternatively, the ground individual parts can be positioned or aligned in a device and then fixed, for example, by casting with a synthetic resin. In the latter case, it is also possible to use a material which differs from the abovementioned materials, for example is not rustproof or has a heavy rusting effect. A surface coating is then provided as protection for the ground surfaces.

1. a) der erste und der zweite Jochschenkel flach sind, wobei
   • der Mittenpol zentral zwischen dem ersten Jochschenkel und dem zweiten Jochschenkel angeordnet ist,
   • der erste Jochschenkel, der zweite Jochschenkel und der Mittenpol jeweils ein erstes und ein gegenüberliegendes zweites Ende umfassen und
   • eine von dem ersten Ende des ersten Jochschenkels umfasste erste Stirnseite, eine von dem ersten Ende des zweiten Jochschenkels umfasste zweite Stirnseite und eine von dem ersten Ende des Mittenpols umfasste zentrale Stirnseite gemeinsam eine Anschlagfläche für die Haftplatte bilden,
2. b) die Magnetspule den Mittenpol zwischen seinem ersten Ende und seinem zweiten Ende abschnittsweise umgibt und
3. c) ein erster Permanentmagnet zwischen dem zweiten Ende des ersten Jochschenkels und dem zweiten Ende des Mittenpols und ein zweiter Permanentmagnet zwischen dem zweiten Ende des zweiten Jochschenkels und dem zweiten Ende des Mittenpols angeordnet sind.

According to a further advantageous embodiment, the electromagnetic magnet is further developed in that

1. a) the first and second yoke legs are flat, wherein
   • the center pole is arranged centrally between the first yoke leg and the second yoke leg,
   • the first yoke leg, the second yoke leg and the center pole each comprise a first and an opposite second end, and
   • a first end side encompassed by the first end of the first yoke leg, a second end side encompassed by the first end of the second yoke leg and a central end side encompassed by the first end of the center pole together forming a stop surface for the adhesion plate,
2. b) the magnetic coil surrounds the center pole between its first end and its second end in sections and
3. c) a first permanent magnet between the second end of the first yoke leg and the second end of the center pole and a second permanent magnet between the second end of the second yoke leg and the second end of the center pole are arranged.

It is provided in particular that the first permanent magnet and the second permanent magnet are polarized in opposite directions. In other words, therefore, the north-south directions of the two permanent magnets are arranged opposite to each other. Due to the opposite arrangement of the two permanent magnets of the symmetrical magnetic holding flux is generated in the yoke. In this case, the costs required for conventional additional systems for the additional (second) magnet is overcompensated by the lower production costs for the yoke and the coil. The yoke is advantageously made exclusively of flat parts, which is very cost-effective, the coil can be made smaller due to the lower currents required for triggering.

The electromagnetic pressure magnet is further adapted to include a magnetic bypass extending between the second end of the first yoke leg and the second end of the center pole and between the second end of the second yoke leg and the second end of the center pole.

The magnetic bypass further reduces the triggering power required for the tripping process. In other words, the current required to energize the magnetic coil, which is required in order to reduce the electromagnetic holding flux to such an extent that the adhesive plate acting as an armature, is reduced even further. The magnetic holding flux escapes into the magnetic bypass and no longer passes through the adhesive plate.

According to an advantageous development is further provided in that the magnetic bypass is fixedly connected to the second end of the middle pole and a second air gap between the second end of the first yoke leg and a first end face of the bypass facing it and a second air gap between the second end of the second yoke leg and a second end face of the bypass facing it Air gap are present. The provided air gaps ensure that the magnetic holding flux does not escape into the magnetic bypass without the magnetic coil being activated. The bypass air gap may be provided not only between the bypass and the yoke legs, but also alternatively between the bypass and the center pole of the yoke.

Preferably, the first end face of the first yoke leg, the second end face of the second yoke leg and the central end face of the center pole lie in a common plane. This Zwangsebenheit is preferably prepared by the fact that the relevant faces are ground smooth. The upper side of the magnetic coil is preferably below the front side of the middle pole. Thus, the coil maintains a predetermined minimum distance to the plane in which abuts the adhesive plate acting as an anchor on said end faces.

The electromagnetic magnet, in particular its yoke and its adhesive plate, furthermore the first yoke limb, the second yoke limb and the center pole, the same applies to the bypass, are preferably produced exclusively from flat parts. These are also in particular flat parts that are punched out of sheets. Suitable examples are steel sheets of the type 1.4016.

The center pole is in particular L-shaped, with the long leg protrudes through the coil. The short leg is in particular a part of the second end of the middle pole. The permanent magnets are in contact with the short leg. The bypass is especially U-shaped. The second end of the center pole is picked up by the U.

The object is further achieved by an electromagnetic locking element, comprising a base element, an opening element which can be moved relative to the base element and an electromagnetic holding magnet according to one or more of the abovementioned aspects. The electromagnetic locking element is further developed in that the yoke, which comprises at least one permanent magnet and the magnetic coil of the base body and the adhesive plate is covered by the opening body, wherein the magnetic coil is adapted to one of the permanent magnet in the yoke in the energized state and at least reduce the magnetic holding flux generated in the adhesion plate so as to at least reduce or cancel a holding force generated by the permanent magnet and release the adhesion plate.

The electromagnetic locking element is characterized by a low triggering power. At the same time, it can be produced easily and cost-effectively, since exclusively flat parts are used for producing the electromagnetic holding magnet encompassed by the electromagnetic locking element, apart from the permanent magnets and the coil.

Furthermore, the object is achieved by an advantageous use of the electromagnetic locking element as a closure in a container of an emergency oxygen supply system of an aircraft.

The required low release performance of the electromagnetic pressure magnet is particularly advantageous for the container of the oxygen emergency supply system of an aircraft. In an aircraft, a large number of such containers is provided, so that even small triggering power adds up to a considerable overall performance. In order to keep these as low as possible even with large aircraft, a low release performance of the individual unit is particularly important.

The object is further achieved by a method for producing an electromagnetic holding magnet, comprising a yoke, an adhesive plate cooperating with the yoke, at least one permanent magnet and a magnetic coil which surrounds the yoke in regions, wherein the magnetic coil is adapted, in the energized state at least reduce a magnetic holding flux generated by the permanent magnet in the yoke and the adhesion plate so as to at least reduce or release a holding force generated by the permanent magnet and release the adhesion plate, the method being further comprising the steps of: arranging of flat parts for producing a yoke with a first yoke leg, a second yoke leg and a center pole, and arranging the magnetic coil such that it at least partially surrounds the center pole, wherein the yoke legs each lead a partial flow of the magnetic holding flux and be arranged symmetrically with respect to the center pole and this at least partially surrounding magnetic coil.

The production of the electromagnetic holding magnet made of flat parts enables a highly efficient manufacturing process. With reduced technical effort electromagnetic magnets can be produced in high quality. Elaborate reworking steps are dispensable. Further, the method according to aspects of the invention have the same or similar advantages as already mentioned with regard to the electromagnetic pressure magnet itself, so that it is not necessary to repeat.

The method is particularly developed by the fact that the flat parts before they are arranged, made of a pre-annealed, heavy-rusting or stainless sheet metal, in particular punched out, are.

1. a) Anordnen von Flachteilen zum Herstellen eines ersten flachen Jochschenkels,
2. b) Anordnen von Flachteilen zum Herstellen eines zweiten flachen Jochschenkels und
3. c) Anordnen von Flachteilen zum Herstellen eines Mittenpols, wobei der erste Jochschenkel, der zweite Jochschenkel und der Mittenpol jeweils ein erstes und ein gegenüberliegendes zweites Ende umfassen,
4. d) Anordnen des Mittenpols zentral zwischen dem ersten Jochschenkel und dem zweiten Jochschenkel, derart, dass eine von dem ersten Ende des ersten Jochschenkels umfasste erste Stirnseite, eine von dem ersten Ende des zweiten Jochschenkels umfasste zweite Stirnseite und eine von dem ersten Ende des Mittenpols umfasste zentrale Stirnseite gemeinsam eine Anschlagfläche für die Haftplatte bilden,
5. e) Fixieren der Jochschenkel und des Mittenpols,
6. f) Anordnen eines ersten Permanentmagneten zwischen dem zweiten Ende des ersten Jochschenkels und dem zweiten Ende des Mittenpols und eines zweiten Permanentmagneten zwischen dem zweiten Ende des zweiten Jochschenkels und dem zweiten Ende des Mittenpols,
7. g) Anordnen der Magnetspule auf dem Mittenpol zwischen seinem ersten Ende und seinem zweiten Ende, so dass die Magnetspule den Mittenpol abschnittsweise umgibt.

According to a further advantageous embodiment, the method is developed in that it comprises the following steps:

1. a) arranging flat parts for producing a first flat yoke leg,
2. b) arranging flat parts for producing a second flat yoke leg and
3. c) arranging flat parts for producing a center pole, wherein the first yoke leg, the second yoke leg and the center pole each comprise a first and an opposite second end,
4. d) arranging the center pole centrally between the first yoke leg and the second yoke leg such that a first end side encompassed by the first end of the first yoke leg comprises a second end side encompassed by the first end of the second yoke leg and one of the first end of the center pole central end face together form a stop surface for the adhesive plate,
5. e) fixing the yoke legs and the center pole,
6. f) arranging a first permanent magnet between the second end of the first yoke leg and the second end the center pole and a second permanent magnet between the second end of the second yoke leg and the second end of the center pole,
7. g) arranging the magnetic coil on the center pole between its first end and its second end, so that the magnetic coil surrounds the center pole in sections.

The fixing of the flat parts, for example, by casting the flat parts with a curable substance, such as a synthetic resin.

Furthermore, the method is developed in that the first end face, the second end face and the central end face are smoothed to provide a flat stop surface for the adhesion plate.

The grinding of the end faces creates a forced flatness, so that the holding plate is held with an extremely small gap to the end faces and thus with high holding power. The grinding takes place, for example, on the fixed yoke. The end faces are therefore preferably ground smooth together in a single step. It is also possible to grind the sheets smooth, then to stack, align and then fix.

Further, the method is arranged by arranging, and in particular fixing, flat parts for producing a magnetic bypass, and the magnetic bypass between the second end of the first yoke leg and the second end of the middle pole and between the second end of the second yoke leg and the second end the center pole is arranged, wherein in particular the magnetic bypass is firmly connected to the second end of the center pole and between the second end the first yoke leg and a first end face of the bypass facing this, a first air gap and between the second end of the second yoke leg and a second end face of the bypass facing this, a second air gap is provided.

Further features of the invention will become apparent from the description of embodiments according to the invention together with the claims and the accompanying drawings. Embodiments of the invention may satisfy individual features or a combination of several features.

Fig. 1

einen elektromagnetischen Haftmagneten in schematisch vereinfachter perspektivischer Darstellung,

Fig. 2

den elektromagnetischen Haftmagneten in vereinfachter perspektivischer Darstellung, wobei die Haftplatte nicht dargestellt ist,

Fig. 3

den elektromagnetischen Haftmagneten in vereinfachter perspektivischer Darstellung, wobei die Haftplatte und die Magnetspule nicht dargestellt sind,

Fig. 4

den elektromagnetischen Haftmagneten aus Fig. 3 in einer Draufsicht und

Fig. 5

ein Mittenpol mit angesetztem magnetischem Bypass des elektromagnetischen Haftmagneten in einer schematisch vereinfachten perspektivischen Darstellung.

The invention will be described below without limiting the general inventive idea by means of embodiments with reference to the drawings, reference being expressly made to the drawings with respect to all in the text unspecified details of the invention. Show it:

Fig. 1

an electromagnetic holding magnet in a schematically simplified perspective view,

Fig. 2

the electromagnetic holding magnet in a simplified perspective view, wherein the adhesive plate is not shown,

Fig. 3

the electromagnetic holding magnet in a simplified perspective view, wherein the adhesive plate and the magnetic coil are not shown,

Fig. 4

the electromagnetic holding magnet Fig. 3 in a plan view and

Fig. 5

a center pole with attached magnetic bypass of the electromagnetic holding magnet in a schematically simplified perspective view.

In the drawings, the same or similar elements and / or parts are provided with the same reference numerals, so that apart from a new idea each.

Fig. 1 shows an electromagnetic holding magnet 2 in a schematically simplified perspective view. The electromagnetic pressure magnet 2 comprises an adhesive plate 4 which cooperates as an armature with a yoke 6. The yoke 6 comprises a first yoke leg 8, a second yoke leg 10 and a center pole 12. The adhesive plate 4, the first yoke leg 8, the second yoke leg 10 and the center pole 12 are preferably made of flat parts. These flat parts are, for example, punched parts. They are also preferably punched out of a pre-annealed, heavy rusting or stainless sheet metal.

The electromagnetic pressure magnet 2 further comprises a first permanent magnet 14, a second permanent magnet 16 and a magnetic coil 18. The permanent magnets 14, 16 generate in the yoke 6 and in the adhesive plate 4 a magnetic holding flux that holds the adhesive plate 4 on the yoke 6. The magnet coil 18 is configured to reduce, or even cancel, this magnetic holding flux generated by the permanent magnets 14, 16 at least to the extent that a holding force acting on the adhesive plate 4 is reduced or eliminated at least to the extent that the adhesive plate 4 is released.

If the electromagnetic magnet 2 is integrated, for example, in an electromagnetic locking element, so includes This example, a base element and a relative to this base element movable opening element. The electromagnetic locking element is used, for example, as a closure in a container of an emergency oxygen supply system of an aircraft. Such a container and a corresponding locking element are for example from the DE 41 31 156 C1 whose contents are fully incorporated into the present description.

For example, the primitive is the one in this document Fig. 1 shown container, with respect to this movable opening element, for example, the pivotable door shown in the same figure. It is provided in particular that the opening element is biased relative to the base element, for example by means of a spring in the opening direction of the opening element. The flux to be generated by the magnetic coil 18, which compensates for the magnetic holding flux of the permanent magnets 14, 16, must therefore be just so large that the holding force on the adhesive plate 4 is reduced so much that such a spring is able to open the opening element So, for example, a door to open. Of course, it is also provided that the magnetic holding flux is compensated so far that no holding force acts on the adhesive plate 4.

If the electromagnetic locking element is integrated, for example, in a container of the oxygen emergency supply system of an aircraft, then the base body, ie, for example, the container, the yoke 6, the permanent magnets 14, 16 and the magnetic coil 18. The opening body, so for example a door, comprises the adhesive plate 4th The magnet coil 18 is now set up, in the energized state, if a triggering current is applied thereto, that of the permanent magnets 14, 16 in FIG the yoke 6 and the magnetic holding flux generated in the adhesive plate 4 to reduce so far that the holding force generated by the permanent magnets 14, 16 is reduced so much that the adhesive plate 4 and thus, for example, the door is released. Such an event occurs, for example, when the emergency oxygen supply system is triggered in an aircraft.

The electromagnetic pressure magnet 2 is characterized by a particularly low triggering power. This is achieved by the symmetrical structure of the electromagnetic pressure magnet 2. The yoke legs 8, 10 each carry a partial flow of the magnetic holding flux generated by the permanent magnets 14, 16 and are arranged symmetrically with respect to the center pole 12 and the magnetic coil 18 at least partially surrounding it.

Fig. 2 shows the electromagnetic pressure magnet 2 from Fig. 1 in a simplified perspective view, in contrast to Fig. 1 the adhesive plate 4 is not shown.

The first yoke leg 8 and the second yoke leg 10 are flat components. They are, as already mentioned, made of flat parts, for example, stacked sheets manufactured. The center pole 12 is arranged centrally between the first yoke leg 8 and the second yoke leg 10. The first yoke leg 8 and the second yoke leg 10 and the center pole 12 each have a first and an opposite second end. A first end face 20 encompassed by the first end of the first yoke leg 8, a second end face 22 encompassed by the first end of the second yoke leg 10 and a central end face 24 encompassed by the first end of the center pole 12 form a common stop face for the adhesive plate 4 for the end faces 20, 22, 24 produce a forced flatness, these pages are preferably ground surfaces. For this purpose, for example, the flat parts from which the first yoke leg 6, the second yoke leg 10 and the center pole 12 are constructed, aligned and fixed. Subsequently, the components are ground together. Alternatively, the flat parts are first ground and then positioned and fixed. To protect the ground surfaces can be provided or applied in this case, a surface.

The magnetic coil 18 surrounds part of the yoke 6 in sections. The magnet coil 18 is namely arranged on the center pole 12, which passes through them centrally. In other words, therefore, the magnet coil 18 surrounds the middle pole 12 between its first end 26 and its second end 28 (cf. Fig. 5 , which will be discussed in more detail later).

The first permanent magnet 14 is disposed between the second end of the first yoke leg 8 and the second end 28 of the center pole 12. The second permanent magnet 16 is disposed between the second end 28 of the second yoke leg 10 and the second end 28 of the center pole 12. For the definition of the first and second end of the yoke legs 8, 10, the same orientation applies as for the first and second ends 26, 28 of the center pole 12. In Fig. 2 So are the first ends of the yoke legs 8, 10 as well as the first end 26 of the center pole 12 above, while the second ends as well as the second end 28 of the center pole 12 are below.

The first permanent magnet 14 and the second permanent magnet 16 are polarized in opposite directions. So they have opposite north-south directions N1, N2, which by way of example with arrows in Fig. 2 are shown. N1 denotes the north-south direction of the first permanent magnet 14 and N2, the north-south direction of the second permanent magnet 16. The magnetic north pole of the permanent magnet 14, 16 is for example in the arrow direction.

The permanent magnets 14, 16 generate a magnetic holding flux which enters the center pole 12 at the second end 28. The magnetic holding flux flows in the middle pole 12 in the direction of its first end 26, that is, through the magnet coil 18. At the central end face 24, the magnetic holding flow enters into the adhesive plate 4. It branches in the adhesive plate in the direction of the first yoke leg 8 and in the direction of the second yoke leg 10. These two partial flows of the magnetic holding flow flow in the adhesive plate 4 laterally in the direction of the first end face 20 of the first yoke leg 8 and in the direction of the second end face 22nd of the second yoke leg 10 at the first end face 20 enters a first partial flow in the first yoke leg 8 and flows in this in the direction of its second end. It thus finally comes back to the first permanent magnet 14. Analogously, the second partial flow enters the second yoke leg 10 at the second end face 22 and likewise flows in the direction of its second end. There it returns to the second permanent magnet 16. If now the magnetic coil 18 is energized, then in the middle pole 12 in the region which is surrounded by the magnetic coil 18, a magnetic flux is generated, which is the holding flux, as just described, is opposite. The holding flow therefore deviates into a lower region of the yoke 6. Im in Fig. 2 vertical part of the center pole 12, the magnetic holding flux comes at least largely to a standstill. Thus, the holding force generated by the permanent magnets 14, 16 on the adhesive plate 4 is compensated and the adhesive plate 4 is released.

Fig. 3 shows the electromagnetic pressure magnet 2 in a simplified perspective view, wherein the adhesive plate 4 and the magnetic coil 18 were not shown. In addition, the electromagnetic pressure magnet 2 of the in Fig. 2 not visible back side forth.

It includes a magnetic bypass 30 extending between the second end of the first yoke leg 8 and the second end 28 of the center pole 12 and between the second end of the second yoke leg 10 and the second end 28 of the center pole 12. In Fig. 3 the second end 28 of the center pole is not visible, since the magnetic bypass 30 is U-shaped and surrounds the second end 28 of the center pole 12 (see also FIG Fig. 5 ). The magnetic bypass 30 as well as the first yoke leg 8, the second yoke leg 10 and the center pole 12 are made of flat parts. For this purpose, preferably preflighted, heavy rusting and stainless sheet metal parts are used.

The magnetic bypass 30 is fixedly connected to the second end 28 of the center pole 12, for example, pressed onto this. Between the second end of the first yoke leg 8 and a first end face of the bypass 30 facing this, a first air gap 32 is present. Between the second end of the second yoke leg 10 and a second end face of the bypass 30 facing this, a second air gap 34 is present. The air gaps 32, 34 ensure that the magnetic holding flux generated by the permanent magnets 14, 16 does not easily dodge into the bypass 30. If, therefore, the magnet coil 18 is not energized, the air gaps 32, 34 ensure that the magnetic holding flux runs as described above and does not escape into the bypass 30.

According to a further embodiment, it is provided that, differing from the illustration in FIG Fig. 3 Air gaps between the second end 28 of the center pole 12 and the bypass 30 are provided. The bypass 30 is in this case to the first and second yoke legs 8, 10 directly to and there is also preferably attached.

Fig. 4 shows the electromagnetic pressure magnet 2 in a plan view, wherein the adhesive plate 4 and the magnetic coil 18 are not shown. The representation in Fig. 4 corresponds to the orientation in the Fig. 1 and 2 , The permanent magnets 14, 16 are, unlike in the illustration of Fig. 3 , again shown in front (below). With dashed arrows, the magnetic flux is indicated, as it flows through the bypass 30 and the air gaps 32, 34 between the permanent magnets 14, 16, the yoke legs 8, 10 and the center pole 12 when the magnetic coil 18 is energized. The magnetic flux is pressed into the lower region of the yoke 6 and no longer passes through the middle pole 12 in the direction of the adhesive plate 4.

Fig. 5 shows in a simplified schematic perspective view of the center pole 12 and the U-shaped magnetic bypass 30 attached thereto.

In a method of manufacturing an electromagnetic pressure magnet 2, as previously described with reference to FIGS FIGS. 1 to 5 For example, the following steps are performed.

There are flat parts for making the yoke 6, so in particular the first yoke leg 8, the second yoke leg 10 and the center pole 12 are arranged. The flat parts, which are previously punched in particular from a pre-annealed, heavy-rusting or stainless sheet, are joined together. It is also provided to arrange the flat parts initially in the form of the yoke 6 and then connect. In addition, the magnet coil 18 is arranged such that it at least partially surrounds the center pole 12. The yoke legs 8, 10, each leading a partial flux of the magnetic holding flux, are arranged symmetrically with respect to the center pole 12 and to this at least partially bypassing the magnetic coil 18. It is also provided that first the yoke legs 8, 10 and the center pole 12 and the magnetic coil 18 and the permanent magnets 14, 16 are arranged and then these components are fixed.

The first end face 20 of the first yoke leg 8, the second end face 22 of the second yoke leg 10 and the central end face 24 of the center pole 12 are then smoothed together, for example, so as to produce a Zwabsebenheit. It is provided a completely flat stop surface for the adhesive plate 4. It is also provided that the bypass 30 is made of flat parts. This is pressed, for example, on the center pole 12 in the region of its second end 28. Subsequently, the center pole 12 can be fixed together with the two yoke legs 8, 10 and the permanent magnets 14, 16 and the magnetic coil 18, for example, shed.

It is also provided that ground flat parts are first positioned and then fixed, for example, shed. On the ground surfaces, a surface coating can be applied.

All mentioned features, including the drawings alone to be taken as well as individual features that are disclosed in combination with other features are considered alone and in combination as essential to the invention. Embodiments of the invention can be fulfilled by individual features or a combination of several features. In the context of the invention, features which are identified by "particular" or "preferably" are to be understood as optional features.

LIST OF REFERENCE NUMBERS

2

electromagnetic magnet

4

adhesive plate

6

yoke

8th

first yoke leg

10

second yoke leg

12

center pole

14

first permanent magnet

16

second permanent magnet

18

solenoid

20

first end face

22

second end face

24

central front

26

first end

28

second end

30

bypass

32

first air gap

34

second air gap

N1

North-South direction of the first permanent magnet

N2

North-South direction of the second permanent magnet

Claims (14)

Electromagnetic detent magnet (2), comprising a yoke (6), an adhesive plate (4) cooperating with the yoke (6) as an armature, at least one permanent magnet (14, 16) and a magnetic coil (18) in regions of the yoke (6) wherein the magnetic coil (18) is adapted to at least reduce a magnetic flux generated by the permanent magnet (14, 16) in the yoke (6) and the adhesion plate (4) in the energized state so as to remove a magnetic flux from the permanent magnet (14). 14, 16) to at least reduce or cancel and release the adhesive plate (4), characterized in that the yoke (6) comprises a first yoke leg (8), a second yoke leg (10) and a center pole (12) the yoke legs (8, 10) each lead a partial flow of the magnetic holding flux and in relation to the center pole (12) and this at least partially surrounding the magnetic coil (18) are arranged symmetrically. Electromagnetic detent magnet (2) according to claim 1, characterized in that the first yoke leg (8), the second yoke leg (10), the center pole (12) and the adhesive plate (4) consist of flat parts, in particular the flat parts of pre-annealed, heavy are made of stainless or stainless sheet metal. Electromagnetic detent magnet (2) according to claim 1 or 2, characterized in that a) the first and second yoke legs (8, 10) are flat, wherein the center pole (12) is arranged centrally between the first yoke limb (8) and the second yoke limb (10), - The first yoke leg (8), the second yoke leg (10) and the center pole (12) each comprise a first and an opposite second end, and - one of the first end of the first yoke leg (8) included first end face (20), one of the first end of the second yoke leg (10) included second end face (22) and one of the first end (26) of the center pole (12) comprising central end face (24) together form a stop surface for the adhesive plate (4), b) the magnetic coil (18) the center pole (12) between its first end (26) and its second end (28) partially surrounds and c) a first permanent magnet (14) between the second end of the first yoke leg (8) and the second end (28) of the center pole (12) and a second permanent magnet (16) between the second end of the second yoke leg (10) and the second end (28) of the center pole (12) are arranged. Electromagnetic adhesion magnet (2) according to claim 3, characterized in that the first permanent magnet (14) and the second permanent magnet (16) are polarized in opposite directions. An electromagnetic magnet (2) according to any one of claims 2 to 4, characterized by a magnetic bypass (30) extending between the second end of the first yoke limb (8) and the second end (28) of the center pole (12) and between the second End of the second yoke leg (10) and the second end (28) of the center pole (12) extends. Electromagnetic detent magnet (2) according to claim 5, characterized in that the magnetic bypass (30) with the second end (28) of the center pole (12) is fixedly connected and between the second end of the first yoke leg (8) and a first facing this Front side of the bypass (30), a first air gap (32) and between the second end of the second yoke leg (10) and a second end face of the bypass (30) facing this, a second air gap (34) are present. Electromagnetic detent magnet (2) according to one of claims 2 to 5, characterized in that the first end face (20) of the first yoke limb (8), the second end face (22) of the second yoke limb (10) and the central end face (24) of Mittenpols (12) ground surfaces are. Electromagnetic locking element comprising A basic element, an opening element movable relative to the base element and an electromagnetic holding magnet (2) according to one of claims 1 to 7, characterized in that the yoke (6), the at least one permanent magnet (14, 16) and the magnetic coil (18) of the Base body are included and the adhesive plate (4) is covered by the opening body, wherein the magnetic coil (18) is adapted to one of the permanent magnet (14, 16) in the yoke (6) and the adhesive plate (4) generated in the energized state at least reduce magnetic holding flux, so as to at least reduce or cancel a holding force generated by the permanent magnet (14, 16) and release the adhesive plate (4). Use of the electromagnetic locking element according to claim 8 as a closure in a container of an oxygen emergency supply system of an aircraft. A method of manufacturing an electromagnetic pressure magnet (2) comprising a yoke (6), an adhesive plate (4) cooperating with the yoke (6) as anchor, at least one permanent magnet (14, 16) and a magnetic coil (18) forming the yoke (6) surrounds in regions, wherein the magnetic coil (18) is adapted to at least reduce a magnetic flux generated by the permanent magnet (14,16) in the yoke (6) and the adhesive plate (4) in the energized state, so as to at least reduce or cancel the holding force generated by the permanent magnet (14, 16) and release the adhesive plate (4),
characterized by the following steps: Arranging flat parts for producing a yoke (6) with a first yoke leg (8), a second yoke leg (10) and a center pole (12), and arranging the magnetic coil (18) so that it at least partially surrounds the center pole (12), wherein the yoke legs (8, 10) each carry a partial flux of the magnetic holding flux and with respect Mittenpol (12) and these at least partially surrounding magnetic coil (18) are arranged symmetrically. A method according to claim 10, characterized in that the flat parts, before they are arranged, made of a pre-annealed, heavy-rusting or stainless sheet metal, in particular punched, are. Method according to claim 10 or 11, characterized by the following steps: a) arranging flat parts for producing a first flat yoke leg (8), b) arranging flat parts for producing a second flat yoke leg (10) and c) arranging flat parts for producing a center pole (12), wherein the first yoke leg (8), the second yoke leg (10) and the center pole (12) each comprise a first and an opposite second end, d) arranging the center pole (12) centrally between the first yoke leg (8) and the second yoke leg (10) such that a first end face (20) encompassed by the first end of the first yoke leg (8) is one of the first end the second yoke leg (10) comprises a second end face (22) and a central end face (24) encompassed by the first end (26) of the center pole (12) together form a stop face for the adhesion plate (4), e) fixing the yoke legs (8, 10) and the center pole (12), f) disposing a first permanent magnet (14) between the second end of the first yoke limb (8) and the second end (28) of the center pole (12) and a second permanent magnet (16) between the second end of the second yoke limb (10) and second end (28) of the center pole (12), g) arranging the magnetic coil (18) on the center pole (12) between its first end (26) and its second end (28), so that the magnetic coil (18) surrounds the center pole (12) in sections. A method according to claim 12, characterized in that the first end face (20), the second end face (22) and the central end face (24) are smooth ground to provide a flat abutment surface for the adhesive plate (4). Method according to one of claims 11 to 13, characterized in that arranged flat parts for producing a magnetic bypass (30), and in particular fixed, and the magnetic bypass (30) between the second end of the first yoke leg (8) and the second end (28) of the center pole (12) and between the second end of the second yoke limb (10) and the second end (28) of the center pole (12) is arranged, wherein in particular the magnetic bypass (30) with the second end (28) of the A center pole (12) is fixedly connected and between the second end of the first yoke leg (8) and a first end face (20) of the bypass (30) facing it, a first air gap (32) and between the second end of the second yoke leg (10) and a second air gap (34) is provided for this purpose facing a second end face (24) of the bypass (30).

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