EP3185256A1 - Electromagnet - Google Patents

Abstract

The invention relates to an electromagnet, in particular a Umkehrhubmagneten, which is adapted to hold an armature of the electromagnet in its end positions without power.

Description

The invention relates to an electromagnet, in particular a Umkehrhubmagneten.

Electromagnets are often used to drive equipment. Such electromagnets are designed for certain purposes so that a respective armature is held in respective end positions, so that a force up to a certain height does not move the armature out of the respective end position. For this example, springs may be provided. However, these can typically only act in one direction and also involve the risk that they may become due to prolonged use from wear or breakage fail. An alternative to this is to let at least one coil of the electromagnet energized to hold the anchor. However, this consumes significant amounts of energy.

It is therefore an object of the invention to provide an electromagnet which is adapted to hold the armature in an alternative manner in an end position.

This is inventively achieved by an electromagnet according to claim 1. Advantageous embodiments can be taken, for example, the dependent claims.

The invention relates to an electromagnet, in particular an electromagnetic Umkehrhubmagneten having a yoke and an armature. The armature is movable in an armature space along an armature movement direction between a first end position and a second end position. The yoke surrounds the anchor space at least partially.

The electromagnet has a coil with current-carrying windings which at least partially surrounds the armature space.

In a first operating position, the coil can be supplied with current in a first current direction such that the armature is moved into the first end position. In a second operating position, the coil can be acted upon by a current flowing in a direction opposite to the first current direction, and the armature is moved into the second end position.

The armature has a permanent magnet. Furthermore, the armature is kept de-energized in the respective end position.

By means of the electromagnet according to the invention, it is possible to keep the armature in both end positions, without the need for this power needs to be expended or the provision of susceptible to wear mechanisms such as springs is required. Rather, up to a certain force acting on the armature, the armature automatically remains in its respective end position. For this purpose, in particular the permanent magnet, which generates a magnetic circuit through other parts of the electromagnet and thus applies the required holding force.

According to a preferred embodiment, the armature between the permanent magnet and a pointing in the direction of the first end position axial end of the armature is formed of non-permanent magnetic material.

According to a further preferred embodiment, the armature between the permanent magnet and an axial end of the armature pointing in the direction of the second end position is formed from non-permanent-magnetic material.

Due to the non-permanent magnetic materials, in particular magnetic field lines of the permanent magnet can run in order to form a magnetic circuit.

In each end position, the permanent magnet preferably generates a magnetic circuit which in each case generates a holding force on the armature. This allows the use of the advantageous effect of the permanent magnet to generate a holding force.

According to a preferred embodiment it is provided that the yoke and the armature space seen in the axial direction of the coil axis, extend beyond the end of the coil and the yoke forms a Jochtopf, and in the first end position of the magnetic circuit of the Permanent magnets on the Jochtopf takes place. This has proven to be advantageous for typical uses.

Cleverly, the yoke has a yoke collar extending radially with respect to the coil axis, and the armature space is delimited on the end remote from the yoke pot by a magnetic core. The magnetic closure of the permanent magnet in the second end position preferably takes place via the yoke collar, the yoke and the magnetic core. In this case, the magnetic circuit can in particular also take place around the coil. Such a design achieves a meaningful conduction of magnetic field lines, which leads to a magnetic force which advantageously holds the armature in an end position.

According to a preferred embodiment, the yoke on the coil and / or takes them up and the coil is located in the interior of the yoke on the yoke collar. This leads to an advantageous magnetic closure.

The permanent magnet is preferably in the first end position between the yoke collar and the yoke bottom of the Jochtopfes. This allows a magnetic circuit adjacent to the coil and thus particularly directly.

The permanent magnet is preferably located in the second end position in the region of a contact surface described between the coil edge and yoke collar. This favors the formation of the magnetic closure described above via the yoke collar and the magnetic core.

Preferably, the electromagnet has only one coil. This allows the saving of components and a more compact design.

The permanent magnet may in particular be disc-shaped. This advantageously allows the above-mentioned formation of magnetic circuits.

The permanent magnet preferably extends over less than 50%, less than 30%, less than 20%, less than 10% or less than 5% of the axial extent of the armature. Such values have proven to be advantageous in practice.

The permanent magnet is preferably axially magnetized parallel to the armature movement direction. This advantageously allows the formation of the magnetic circuits mentioned above.

The permanent magnet is preferably radially smaller than the remaining part of the armature. The permanent magnet material used is sufficiently strong, which is why mass can be saved by reducing the diameter of the permanent magnet and the holding force can be set.

The armature is skillfully guided by means of an armature tube located in the yoke, the bottom of which is touched by the armature in the first end position being designed to prevent sticking and / or of non-magnetizable material. This facilitates the intentional detachment of the anchor from the ground, as the holding force is reduced. Of course, the necessary force for moving the armature can be adjusted from the end position by the choice of the material or the thickness of the material.

The yoke, in particular the yoke collar, is preferably formed of a material whose thickness is smaller than the stroke of the armature between the two end positions thereof. By such a configuration is basically achieved that in a switching operation, ie a change of the anchor position from a first to a second end position (and back), the permanent magnet can get from one to the other side of the yoke covenant.

Preferably, an outer circumferential, axially projecting collar is formed on a pointing in the direction of the first end position axial end of the armature. This prevents or reduces any adhesion of the armature to other components, in particular to the bottom of the armature tube, as the contact area is reduced. Again, the necessary force for moving the armature from the end position is adjustable.

The yoke is preferably formed of soft magnetic steel. This improves the magnetic field guidance and has proved to be advantageous for the formation of the mentioned magnetic circuits.

According to a preferred embodiment, the yoke and the armature transversely to the armature movement direction have a respective outer cross section, wherein a surface of the outer cross section of the armature between 10% and 50%, in particular between 15% and 35%, particularly preferably 20% ± 5% of the surface of Outside cross-section of the yoke makes up.

For the parameter External cross section of the armature to outer cross section of the yoke, an interval is specified, which is described by an upper and lower limit. For example, the upper limit is the following values: 60%, 55%, 50%, 45%, 40%, 35%, 30%, 25%, 20%.

The lower limits are, for example, the following values: 5%, 10%, 15%, 20%, 25%. The disclosure of this application encompasses the set of all intervals consisting of all possible, consistent combinations of the aforementioned upper and lower limits.

The permanent magnet preferably has an axial extent which is smaller than or equal to the thickness of the yoke material in the region of the yoke collar. In interaction with the stroke of the electromagnet It is achieved that, depending on the end position of the permanent magnet, this is either on one or the other side of the yoke collar and accordingly optimizes the magnetic closure in the respective end position.

The electromagnet may in particular be a bistable reversing stroke magnet. This is designed so that the armature is kept de-energized in both end positions.

The armature is preferably movable over a stroke, which is between 3 mm and 5 mm, in particular 4 mm.

The yoke is preferably formed of a material having a thickness between 2 mm and 4 mm, in particular 3 mm.

The yoke may be formed in particular from VA steel. It may advantageously have a round outer cross section.

The permanent magnet preferably has an axial extension between 2 mm and 4 mm, in particular 3 mm.

Such values or embodiments have proved to be advantageous in practice.

Fig. 1

einen Elektromagneten gemäß der Erfindung mit Anker in einer ersten Endstellung, und

Fig. 2

den Elektromagneten< gemäß der Erfindung mit Anker in einer zweiten Endstellung.

In the drawing, the invention is shown schematically in particular in one embodiment. Show it:

Fig. 1

an electromagnet according to the invention with armature in a first end position, and

Fig. 2

the electromagnet <according to the invention with armature in a second end position.

In the figures, the same or corresponding elements are denoted by the same reference numerals and therefore, if not appropriate, will not be described again. The disclosures contained in the entire description are mutatis mutandis to the same parts with the same reference numerals or identical component names transferable. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and are to be transferred to the new situation mutatis mutandis when a change in position. Furthermore, individual features or combinations of features from the illustrated and described different embodiments may represent for themselves, inventive or inventive solutions.

FIG. 1 shows an electromagnet 10.

The electromagnet 10 has a yoke 20 which limits a part of the electromagnet 10 on the outside.

In the interior of the electromagnet 10, an armature 30 is arranged, which is limitedly movable along an armature movement direction 36. Within the armature 30, a permanent magnet 35 is arranged, which occupies only a fraction of the extension of the armature 30 along the armature movement direction 36. On the left side of the permanent magnet 35, a first non-permanent magnetic material 33 is arranged. On the right side of the permanent magnet 35, a second non-permanent magnetic material 34 is arranged. The importance of the permanent magnet 36 and the non-permanent magnetic materials 33, 34 will be discussed in more detail below.

On the right side, the armature 30 has a circumferential projection 38, which is arranged radially on the outside. This leads to, that the armature 30 has no flat contact surface on the right side, but only the projection 38 can abut against a corresponding surface.

Around the armature 30, a coil 40 is arranged, which can be traversed by a coil current and thereby generates a magnetic field. This magnetic field can drive the armature 30 along the armature movement direction 36. The electromagnet 10 with its coil 40 is in particular designed such that through the coil 40 coil currents can flow in both directions, wherein depending on the direction of the coil current, the armature 30 is moved in opposite directions. In other words, the electromagnet 10 is designed so that it only needs a coil 40 and can be dispensed with the provision of a further coil, which is common in the prior art.

The permanent magnet 35 is formed with a slightly smaller diameter compared to the surrounding part of the armature 30.

The coil 40 is formed symmetrically about a coil axis 41. This coil axis 41 is aligned parallel to the armature movement direction 36. On the right side, the coil 40 has a coil edge 42. In addition, it has an abutment surface 47 towards the armature 30.

The armature 30 surrounds an armature tube 50, which extends along the armature movement direction 36. The anchor tube 50 has a bottom 52, which in the in FIG. 1 State shown by the armature 30 is touched. The anchor tube 50 is partially within the coil 40, and further looks to the right beyond the coil 40. Slightly, the anchor tube 50 also looks to the left beyond the coil 40. The anchor tube 50 is used in particular for more precise guidance of the armature 30th

The armature 30 moves along the armature movement direction 36 in an armature space 60, which is formed in the interior of the electromagnet 10. The armature space 60 is bounded on the left side by a magnetic core 70.

In the yoke 20, a yoke pot 26 is formed, which has a yoke bottom 27. Adjacent to the Jochtopf 26, a yoke collar 28 is formed in the yoke 20, which adjoins the coil 40.

In the in FIG. 1 illustrated state, the armature 30 is in a first end position, where he was moved as far as possible to the right. Thus, the projection 38 of the armature 30 directly adjoins the bottom 52 of the anchor tube 50.

The permanent magnet 35 is located outside the coil 40 adjacent to the yoke collar 28. This allows a magnetic circuit which extends over the second non-permanent magnetic material 34, the yoke bottom 27, the Jochtopf 26, the yoke 28 and the first non-permanent magnetic material 33. The permanent magnet 35 is magnetized to support the formation of such a magnetic circuit axially parallel to the armature movement direction 36.

The magnetic closure just described ensures that the armature 30 in the in FIG. 1 shown position, in particular even when the current flowing through the coil 40 coil current is turned off. Thus, a certain force can be exerted on the armature 10 without it moving. It should be noted that this effect is particularly supported by the fact that the magnetic circuit can be formed on the right side of the coil 40.

FIG. 2 shows the electromagnet 10 of FIG. 1 in another state, with the armature 30 in a second end position. This second end position is directly opposite to the first end position, this means in particular that the armature 30 is as far to the left, as this is possible due to the design.

In this case, a magnetic circuit is formed, which passes through the second non-permanent magnetic material 34, the yoke collar 28, the yoke 20, the magnetic core 70 and the first non-permanent magnetic material 33. The magnetic circuit is therefore in this case around the coil 40 around. This magnetic closure also causes the armature 30 in its second end position, which in FIG. 2 is shown, is held so that a force does not move the armature 30 up to a certain height.

By energizing the coil 40 in a suitable direction, a force can be exerted on the armature 30, which is sufficient to move the armature 30 from the respective end position in the direction of the other end position. However, if the armature 30 is to remain in its final position, the coil current can typically be turned off, thus saving energy. On the provision of other common measures that hold an anchor 30 in an end position, such as a spring, can be dispensed with.

It should be noted that the bottom 52 of the anchor tube 50 is coated such that adhesion of the anchor 30 to the bottom 52 is prevented. For this purpose, it is formed in particular of non-magnetic material. This facilitates the operation of the electromagnet 10.

Below, possible features of the proposal are displayed in a structured manner. The following structured reproduced features can be combined with each other and can be included in any combination in the claims of the application become. It is clear to the person skilled in the art that the invention already results from the article with the fewest features. In particular, below advantageous or possible embodiments, but not the only possible embodiments of the invention are shown.

• Ein Elektromagnet, insbesondere elektromagnetischer Umkehrhubmagnet, welcher ein Joch (20) und einen Anker (30) aufweist, der Anker (30) in einem Ankerraum (60) entlang einer Ankerbewegungsrichtung (36) zwischen einer ersten Endstellung und einer zweiten Endstellung beweglich ist, das Joch (20) den Ankerraum (60) zumindest teilweise umgibt und der Elektromagnet (10) eine Spule (40) mit stromführenden Windungen aufweist, die den Ankerraum (60) zumindest teilweise umgibt und die Spule (40) in einer ersten Betriebsstellung so mit Strom in einer ersten Stromrichtung beaufschlagbar ist, dass der Anker (30) in die erste Endstellung bewegt wird und die Spule (40) in einer zweiten Betriebsstellung mit einem, zur ersten Stromrichtung entgegengesetzten zweiten Stromrichtung fließenden Strom beaufschlagbar ist und der Anker (30) in die zweite Endstellung bewegt wird, der Anker (30) einen Permanentmagneten (35) aufweist und der Anker (30) in der jeweiligen Endstellung stromlos gehalten ist.

The invention comprises:

• An electromagnet, in particular electromagnetic Umkehrhubmagnet having a yoke (20) and an armature (30), the armature (30) in an armature space (60) along an armature movement direction (36) between a first end position and a second end position is movable, the Yoke (20) at least partially surrounds the armature space (60) and the electromagnet (10) has a coil (40) with current-carrying windings which at least partially surrounds the armature space (60) and the coil (40) in a first operating position so with electricity in a first current direction can be acted upon, that the armature (30) is moved to the first end position and the coil (40) in a second operating position with a, opposite to the first current direction second current direction current is acted upon and the armature (30) in the second end position is moved, the armature (30) has a permanent magnet (35) and the armature (30) is held de-energized in the respective end position.

The above-mentioned electromagnet, wherein the armature (30) between the permanent magnet (35) and an axial end of the armature (30) pointing in the direction of the first end position of non-permanent magnetic material (34) is formed.

The above-mentioned electromagnet, wherein the armature (30) is formed between the permanent magnet (35) and an axial end of the armature (30) pointing in the direction of the second end position of non-permanent magnetic material (33).

The above-mentioned electromagnet, wherein the permanent magnet (35) generates in each end position a magnetic circuit, which in each case generates a holding force on the armature (30).

The above-mentioned electromagnet, wherein the yoke (20) and the armature space (60) extend in the axial direction of the coil axis (41) over the end of the coil (40) and the yoke (20) forms a yoke pot (26), and in the first end position of the magnetic closure of the permanent magnet (35) via the Jochtopf (26).

The above-mentioned electromagnet, wherein the yoke (20) has a yoke collar (28) extending radially relative to the coil axis (41), and the armature space (60) is disposed on the end remote from the yoke pot (26) by a magnetic core (70). is limited and the magnetic closure of the permanent magnet (35) in the second end position via the yoke collar (28), the yoke (20) and the magnetic core (70).

The above electromagnet, wherein the yoke (20) the coil (40) has / receives and the coil (40) in the interior of the yoke (20) on the yoke collar (28).

The above-mentioned electromagnet, wherein the permanent magnet (35) is in the first end position between the yoke collar (28) and the yoke bottom (27) of the yoke cup (26).

The above-mentioned electromagnet, wherein the permanent magnet (35) in the second end position in the region of, between the coil edge (42) and yoke collar (28) described bearing surface (47).

The above-mentioned electromagnet, wherein the electromagnet (10) has only one coil (40).

The above-mentioned electromagnet, wherein the permanent magnet (35) is disc-shaped.

The aforesaid solenoid, wherein the permanent magnet (35) extends over less than 50%, less than 30%, less than 20%, less than 10% or less than 5% of the axial extent of the armature (30).

The above electromagnet, wherein the permanent magnet (35) is axially magnetized in parallel to the armature moving direction (36).

The above-mentioned electromagnet, wherein the permanent magnet (35) is radially smaller than the remaining part of the armature (30).

The above-mentioned electromagnet, the armature (30) being guided by means of an armature tube (50) located in the yoke (20), the bottom (52) touched by the armature (30) in the first end position being adhesive-preventing and / or non-magnetisable material is trained.

The above electromagnet, wherein the yoke (20), in particular the yoke collar (28) is formed of a material whose thickness is smaller than the stroke of the armature (30) between the two end positions thereof.

The above-mentioned electromagnet, wherein an outer circumferential, axially projecting collar (38) is formed on an axial end of the armature (30) pointing in the direction of the first end position.

The above electromagnet, wherein the yoke (20) is formed of soft magnetic steel.

The aforesaid electromagnet, wherein the yoke (20) and the armature (30) have a respective one transverse to the armature movement direction (36) Have outer cross section, wherein a surface of the outer cross section of the armature (30) between 15% and 25%, in particular 20%, the area of the outer cross section of the yoke (20).

The above-mentioned electromagnet, wherein the permanent magnet (35) has an axial extent which is smaller than or equal to the thickness of the yoke material in the region of the yoke collar (28).

The claims now filed with the application and later are without prejudice to the attainment of further protection.

If, on closer examination, in particular also of the relevant prior art, it appears that one or the other feature is beneficial for the purpose of the invention, but not crucial, it is of course already desired to have a formulation which is such a feature , in particular in the main claim, no longer having. Such a sub-combination is also covered by the disclosure of this application.

It should further be noted that the embodiments and variants of the invention described in the various embodiments and shown in the figures can be combined with one another as desired. Here, one or more features are arbitrarily interchangeable. These feature combinations are also disclosed with.

The references cited in the dependent claims indicate the further development of the subject matter of the main claim by the features of the respective subclaim. However, these are not to be understood as a waiver of obtaining independent, objective protection for the features of the dependent claims.

Features which have been disclosed only in the description or also individual features from claims which comprise a plurality of features can at any time be taken over as being of essential importance for the purpose of differentiation from the prior art in the independent claim (s), even then, if such features have been mentioned in connection with other features or achieve particularly favorable results in connection with other features.

Claims (15)

Electromagnet, in particular electromagnetic Umkehrhubmagnet having a yoke (20) and an armature (30), the armature (30) in an armature space (60) along an armature movement direction (36) between a first end position and a second end position is movable, the yoke (20) surrounds the armature space (60) at least partially and the electromagnet (10) has a coil (40) with current-carrying windings which at least partially surrounds the armature space (60) and the coil (40) in a first operating position with so in a first current direction can be acted upon, that the armature (30) is moved into the first end position and the coil (40) in a second operating position with a, opposite to the first current direction second current direction current is acted upon and the armature (30) in the second End position is moved, the armature (30) has a permanent magnet (35) and the armature (30) is held de-energized in the respective end position. Electromagnet according to claim 1, characterized in that the armature (30) is formed between the permanent magnet (35) and an axial end of the armature (30) pointing in the direction of the first end position of non-permanent magnetic material (34) and / or the armature (30). 30) between the permanent magnet (35) and a pointing in the direction of the second end position axial end of the armature (30) is formed of non-permanent magnetic material (33). Electromagnet according to one of the preceding claims, characterized in that the permanent magnet (35) generates in each end position a magnetic circuit, which in each case generates a holding force on the armature (30). Electromagnet according to one of the preceding claims, characterized in that the yoke (20) and the armature space (60) seen in the axial direction of the coil axis (41) extend over the end of the coil (40) and the yoke (20) a Jochtopf (26) forms, and in the first end position of the magnetic closure of the permanent magnet (35) via the Jochtopf (26) takes place and / or the yoke (20), with respect to the coil axis (41) radially extending yoke collar (28) and the armature space (60) is delimited on the end facing away from the yoke pot (26) by a magnetic core (70) and the magnetic closure of the permanent magnet (35) in the second end position via the yoke collar (28), the yoke (20) and the magnet core (70). Electromagnet according to one of the preceding claims, characterized in that the yoke (20) the coil (40) has / receives and the coil (40) in the interior of the yoke (20) on the yoke collar (28). Electromagnet according to one of the preceding claims, characterized in that the permanent magnet (35) in the first End position between the yoke collar (28) and the yoke bottom (27) of the Jochtopfes (26) is located and / or the permanent magnet (35) in the second end position in the area between the coil edge (42) and yoke collar (28) described contact surface (47 ) is located. Electromagnet according to one of the preceding claims, characterized in that the electromagnet (10) has only one coil (40). Electromagnet according to one of the preceding claims, characterized in that the permanent magnet (35) is disc-shaped and / or the permanent magnet (35) is less than 50%, less than 30%, less than 20%, less than 10% or less than 5% of the axial extent of the armature (30). Electromagnet according to one of the preceding claims, characterized in that the permanent magnet (35) is axially magnetized parallel to the armature movement direction (36). Electromagnet according to one of the preceding claims, characterized in that the permanent magnet (35) is radially smaller than the remaining part of the armature (30). Electromagnet according to one of the preceding claims, characterized in that the armature (30) is guided by means of an armature tube (50) located in the yoke (20), whose base (52) touched by the armature (30) in the first end position obstructs adhesion and / or or is formed of a non-magnetizable material. Electromagnet according to one of the preceding claims, characterized in that the yoke (20), in particular the yoke collar (28) is formed of a material whose thickness is smaller is as the stroke of the armature (30) between the two end positions. Electromagnet according to one of the preceding claims, characterized in that an outer circumferential, axially projecting collar (38) is formed on an axial end of the armature (30) pointing in the direction of the first end position. Electromagnet according to one of the preceding claims, characterized in that the yoke (20) is formed of soft magnetic steel. Electromagnet according to one of the preceding claims, characterized in that the yoke (20) and the armature (30) transversely to the armature movement direction (36) have a respective outer cross section, wherein a surface of the outer cross section of the armature (30) between 15% and 25%, in particular 20%, the area of the outer cross section of the yoke (20) makes up and / or the permanent magnet (35) has an axial extent which is smaller than or equal to the thickness of the yoke material in the region of the yoke collar (28).

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