DE102015005736A1 - Magnetic coupling and stirring device with magnetic coupling - Google Patents

Abstract

To reduce the overall height of a magnetic coupling (1), which is particularly suitable for use in a magnetic stirrer, at least one magnet (4) of the rotor (3), which acts as a driving magnet for a counter-coupling piece of the magnetic coupling, in particular for a stirring magnet of a magnetic stirrer, arranged such that it at least partially or completely in one of a rotor-stator unit (5) of the magnetic coupling (1) encompassed space (7) protrudes and / or at least partially or completely in this space (7) is arranged.

Description

The invention relates to a magnetic coupling, in particular for use in a magnetic stirrer or other stirring device, comprising a rotor-stator unit comprising an electric motor, wherein on a rotor of the rotor-stator unit at least one magnet is arranged, which is for driving a with the Magnetic coupling to be coupled, at least one counter-magnet or magnetic material having Gegenkupplungsstücks is set, and with a stator having a plurality of induction coils.

Furthermore, the invention also relates to a stirring device, in particular a magnetic stirrer with such a magnetic coupling.

Magnetic couplings of this type are used, for example, in magnetic stirrers known from the prior art, but also in other stirring devices, as the drive unit in order to contactlessly drive a generally rod-shaped stirring magnet which can be inserted into a vessel filled with media to be stirred.

In this case, the at least one magnet arranged on the rotor of the electric motor carries the stirring magnet as counter-coupling piece and thus enables the mixing of liquids even in closed vessels. The at least one magnet of the rotor can therefore also be referred to as a driving magnet.

The previously known from the prior art magnetic clutches, especially those that are used in magnetic stirrers, have been proven. Depending on the application, however, it may be considered to be disadvantageous that the previously known from the prior art magnetic clutches have a comparatively large height, which is also further increased when the stirring device, in which the magnetic coupling is installed, additional elements, such as a heater or the like, which should be arranged as close to a footprint of the stirring device.

The object of the invention is therefore to provide a magnetic coupling and a stirring device, in particular a magnetic stirrer, of the type defined above, which are each characterized by a lower axial height.

To solve this problem, a magnetic coupling with the features of claim 1 is proposed. The object is achieved, in particular, by the fact that the at least one magnet of the rotor in the position of use extends at least partially or completely into a space encompassed by the rotor-stator unit and / or is arranged at least partly or completely in this space.

In this way, a particularly flat overall height of the magnetic coupling can be achieved, since the at least one magnet arranged on the rotor is arranged at least partially within the previously described space of the rotor-stator unit.

If a stator of the rotor-stator unit has a plurality of induction coils, which are arranged within the previously defined space, and the at least one magnet of the rotor in the position of use extend at least partially or completely into a space extending between the induction coils and / or at least partially or are completely arranged in this space, an even more compact magnetic coupling with even lower axial height can be created.

A further reduction in the overall height of the magnetic coupling can be achieved if, alternatively or additionally, the rotor in the position of use reaches at least partially or completely into a gap extending between the induction coils of the stator, for example in the previously mentioned, and / or at least partially or completely is arranged in this.

It may be expedient if a clear height of the space and / or the gap corresponds to a measured in the direction of a rotation axis of the rotor dimension of the induction coil of the stator.

In a particularly advantageous embodiment of the magnetic coupling according to the invention can be provided that the at least one magnet of the rotor has such a dimension, so that it fits completely into the space and / or space of the magnetic coupling. It is therefore possible that the at least one magnet of the rotor is arranged in the position of use within the space and / or the interspace of the magnetic coupling and can preferably be arranged in this.

Furthermore, it can be provided that a height of the at least one magnet of the rotor is at most as large as one, for example the one already mentioned above, in the direction of the axis of rotation of the rotor Rotor is the measured dimension of the induction coils of the stator. This means that such a magnet of the stator can also fit from its height into the gap defined by the induction coils of the stator, since its height is not greater than the dimension of the induction coils measured in the direction of the axis of rotation of the rotor whose size is decisive for the can be clear height of the said space and / or space and thus can be decisive for the overall for the accommodation of the rotor and its at least one magnet in the space and / or space.

In a particularly advantageous embodiment of the invention can also be provided that an axial dimension or height of the rotor is at most as large as an axial dimension or height of the stator and / or that a radial dimension of the rotor is dimensioned so that this completely in the Space between the induction coils fits. Thus, a particularly compact magnetic coupling can be provided, since such a rotor can be arranged completely in the intermediate space between the induction coils of the stator, which does not have to project beyond the stator in the axial direction.

It may be expedient if the rotor has at least two magnets which, in the position of use, extend at least partially or completely into the space and / or into the intermediate space and / or are recessed therein. With at least two magnets on the rotor, it is possible to reliably entrain and drive a counter-coupling piece having at least one counter-magnet with the magnetic coupling.

It may be advantageous if the rotor has a recess for receiving the at least one magnet, in which the at least one magnet of the rotor is arranged in the position of use. In this way, it is possible to integrate the at least one magnet of the rotor in the rotor and so on the one hand to minimize the height of the rotor and thus to keep the overall height of the entire coupling as low as possible.

When using more than one magnet on the rotor, it may be advantageous if the rotor has a respective recess for each magnet of the rotor. In a preferred embodiment of the magnetic coupling according to the invention, these several depressions for a plurality of magnets of the rotor can then expediently be distributed uniformly around one, for example, the rotation axis of the rotor already mentioned above.

Furthermore, the rotor can be cup-shaped and the at least one magnet can be arranged at least partially or completely within a pot formed by the cup-shaped rotor. In this case, a depth of, for example, the previously mentioned, pot of the cup-shaped rotor be dimensioned such that the at least one magnet at least partially or completely sunk in the pot-shaped rotor can be arranged or arranged. This means that the at least one magnet in such a rotor does not project beyond a pot edge of the rotor, but can preferably terminate flush therewith.

A particularly low overall height of the magnetic coupling can be achieved if the at least one magnet at least partially or even completely within the rotor and / or at least partially or completely between an aligned transversely to the axis of rotation of the rotor top and a parallel thereto and / or transverse to the axis of rotation of Rotor-oriented bottom of the rotor is arranged. The underside of the rotor described above may in particular be a rotor bottom which closes the rotor downwards in the position of use.

Furthermore, it can be provided that the rotor has a ring magnet, via which the rotor can be driven by the induction coils of the stator, wherein the ring magnet can be arranged on the rotor so that it surrounds the at least one magnet of the rotor at least partially or completely laterally.

In a further advantageous embodiment of the invention may also be provided that the rotor has a rotor bottom, which is adapted to amplify a magnetic field of the at least one magnet of the rotor, in this way to improve the magnetic coupling force of the magnetic coupling.

This may be particularly important when the magnetic coupling is used in a magnetic stirrer used for processing and mixing particularly viscous media in which a sufficiently large coupling force is required to avoid tearing of the magnetic coupling.

Furthermore, it can be provided that the magnetic coupling has a cover plate, in the position of use of the magnetic coupling below the at least the rotor of the electric motor of the magnetic coupling can be arranged together with the at least one magnet of the rotor. It is possible that a rotor facing away from the outside of this cover plate is designed as a footprint for a vessel.

In particular, when integrating the magnetic coupling into a magnetic stirrer, a particularly compact construction on the one hand of the magnetic coupling and, on the other hand, and consequently also of the magnetic stirrer can result.

In this case, the cover plate of the magnetic coupling of a sheet, in particular made of stainless steel. But it is also conceivable to provide a cover plate made of glass or plastic. A cover plate made of sheet metal, glass or plastic can favor a flat design of the magnetic coupling according to the invention, since such a cover plate can be kept very thin.

Conveniently, the magnetic coupling, in particular one, for example, the aforementioned, cover plate of the magnetic coupling, a heating device for heating a vessel erected on her have.

In this case, the heating device can be arranged below a, for example, the previously mentioned, cover plate of the magnetic coupling. The heating device may also include within a, for example, the previously mentioned, cover plate of the magnetic coupling embedded or arranged below this heating wires. Additionally or alternatively, it is also possible that the heating device has a, preferably coated, heating coil, which can expediently be arranged on a serving as a footprint outside of, for example, the already mentioned, cover plate of the magnetic coupling.

If the magnetic coupling has a, for example, the cover plate of the magnetic coupling opposite arranged base plate, which is designed as a printed circuit board, the base plate of the magnetic coupling may have a dual function:
On the one hand, it can thus complete the coupling and on the other hand be carriers for circuit parts and / or sensors and / or tracks, which in turn can favor the flat design of the magnetic coupling.

In the above-defined stirring device, in particular if it is designed as a magnetic stirrer, the aforementioned object is achieved in that the magnetic coupling used in the stirring device is a magnetic coupling according to one of claims 1 to 16.

In this way, the overall height of the stirring device, in particular of the magnetic stirrer, can be reduced and thus a particularly compact stirring device can be created.

An exemplary embodiment of the invention is described in more detail below with reference to the drawing. In a partially highly schematic representation:

1 a side view of a magnetic coupling according to the invention and

2 a top view of the in 1 illustrated magnetic coupling according to the invention.

The 1 and 2 show a whole with 1 designated magnetic coupling, which is particularly suitable for use in a magnetic stirrer, not shown in the figures or in another stirring device.

The magnetic coupling 1 has an electric motor 2 with a rotor-stator unit 5 on. The rotor-stator unit 5 has a rotor 3 on, in the present embodiment, a total of two magnets 4 are arranged. The two magnets 4 are to drive one with the magnetic coupling 1 to be coupled, at least one counter-magnet or magnetic material, such as steel or ferrite, having Gegenkupplungsstücks, which is not shown in the figures, set up. Such a counter-coupling piece may be, for example, a stirring magnet, which is usually rod-shaped and is used together with a magnetic stirrer for mixing media in a vessel. The vessel can be placed for this purpose on a footprint of the magnetic stirrer.

The figures show that the two magnets 4 of the rotor 3 in use position completely in one of the rotor-stator unit 5 included space 7 are arranged and therefore neither on the rotor 3 still the stator 5a survive to the top.

Especially 1 shows that the rotor 3 is cup-shaped and that the at least one magnet 4 , In the present embodiment, the two magnets 4 , inside of the rotor 3 formed pot 3a is / are arranged. Both are magnets 4 from a rotating rotor wall 3b surround.

The rotor-stator unit 5 of the electric motor 2 also has a stator 5a with a total of twelve induction coils 6 all of them inside the room 7 are arranged.

Especially 2 clearly shows that the induction coils 6 are arranged such that there is a gap between them 7a extends, the induction coils 6 define, limit and surround. The two magnets 4 of the rotor 3 range according to the in 1 shown use position of these magnets 4 not just in this space 7a into it, but are also completely submerged in this.

The side view of the magnetic coupling 1 according to 1 clearly shows that a clear height of the room 7 and also the gap 7a one in the direction of a rotation axis R of the rotor 3 measured dimension of the induction coils 6 of the stator 5 equivalent. In other words, this means that the available clear height of the room 7 or the gap 7a between the induction coils 6 is as big as the height of the induction coils 6 of the stator 5 of the electric motor 2 the magnetic coupling 1 ,

According to the figures, the rotor 3 of the electric motor 2 at its the induction coils 6 in the use position facing peripheral side, which is an outer side of the rotating rotor wall 3b is, also a ring magnet 8th on. The ring magnet 8th surrounds the cup-shaped rotor 3 and has one with the number of induction coils 6 corresponding number of magnetic poles, for example, twelve to 16 poles, in which the ring magnet 8th is divided.

The ring magnet 8th allows the rotor 3 using one of the induction coils 6 of the stator 5 generated magnetic rotating field can be driven.

Both figures show that the two magnets 4 of the rotor 3 each having such a dimension so that they both together completely in the room 7 fit. Both figures also show that the two magnets 4 of the rotor 3 in use position completely within this room 7 are arranged.

This is possible because both magnets 4 of the rotor 3 have a height which is at most as large as that in the direction of the axis of rotation R of the rotor 3 measured dimension of the induction coils 6 of the stator 5 are. In other words, this means that the magnets shown in the figures 4 of the rotor 3 a slightly lower height than the induction coils 6 of the stator 5 exhibit.

Both magnets 4 of the rotor 3 can thereby completely in the position of use in the room 7 the magnetic coupling 1 extend into it and be sunk into it.

As well as the clear height of the gap 7a between the induction coils 6 Determined by their height, the two magnets fit 4 also in the gap 7a and can be arranged in this fully sunk.

At this point it should be noted that the gap 7a completely inside of the rotor-stator unit 5 covered space 7 lies and is surrounded by this.

A depth of the rotor 3 formed pot 3a is the magnetic coupling in the present embodiment 1 so that the at least one magnet 4 , here are the two magnets 4 completely in the pot 3a of the rotor 3 sunk is arranged / are and in the use position does not have a pot edge 3c extends / transcend.

From the figures can also be seen that an axial dimension or height of the rotor 3 at most as large as an axial dimension or height of the stator 5a is. A radial dimension of the rotor 3 is sized so that this is completely in the gap 7a between the induction coils 6 fits and is arranged in this. Thus, a very compact magnetic coupling 1 to be provided.

Both figures show that the rotor 3 for each of the two magnets 4 one recess each 9 which shows the inclusion of the two magnets 4 serve. From the position of use shown in the two figures, it is clear that each of the two magnets 4 of the rotor 3 in the use position in each case one of the two on the rotor 3 existing wells 9 is arranged.

According to 1 it becomes clear that each of the two magnets 4 while inside the wells assigned to them 9 of the rotor 3 is arranged. The two wells 9 in the rotor 3 serve the location of the magnets 4 to define and better this on the rotor 3 to be able to determine.

The wells 9 have a depth of only about one tenth of the height of the magnets 4 equivalent. That means that about nine-tenths or more of the magnets 4 not within the wells 9 arranged but are free. This is for the function of the magnetic coupling 1 favorable, because in this way a magnetic shielding of the magnets 4 through the depressions 9 can be prevented.

The two wells 9 are doing according to 2 evenly distributed about the axis of rotation R of the rotor 3 arranged distributed. Since there are only two wells in the present embodiment 9 for a total of two magnets 4 of the rotor 3 are, these are logically offset by 180 ° to each other and at the same distance from the axis of rotation R of the rotor 3 on the rotor 3 positioned. The side view according to 1 shows that both magnets 4 inside the rotor 3 and between a transverse to the axis of rotation R of the rotor 3 aligned top 10 and a parallel thereto and also transverse to the axis of rotation R of the rotor 3 aligned bottom 11 of the rotor 3 are arranged.

The top 10 of the rotor 3 is in the in the 1 and 2 illustrated embodiment of the magnetic coupling 1 through the top edge of the pot 3c of the rotor 3 Are defined.

The bottom 11 is doing one of 12 designated rotor bottom formed.

The rotor bottom 12 of the rotor 3 is set up to a magnetic field of the two magnets 4 of the rotor 3 to reinforce the coupling effect of the magnetic coupling 1 to improve.

The magnetic coupling 1 also has a cover plate 13 on, under the in use position of the magnetic coupling 1 at least the rotor 3 of the electric motor 2 the magnetic coupling 1 together with the two magnets 4 of the rotor 3 is arranged. One is the rotor 3 opposite outside fourteen the cover plate 13 as a footprint 15 designed for a vessel.

Said cover plate 13 the magnetic coupling 1 can depending on the embodiment of the magnetic coupling 1 in this case consist of a sheet metal, in particular of stainless steel, or of glass or plastic and so be made very thin, which in turn favors the compact design of the magnetic coupling.

The magnetic coupling 1 also has a heater 16 for heating one on the cover plate 13 set up vessel. This heater 16 can do this with the cover plate 13 the magnetic coupling 1 be connected or integrated into this.

In one embodiment of the magnetic coupling 1 is provided that the heater 16 below the cover plate 13 the magnetic coupling 1 is arranged. In this case, the heating device comprises 16 inside the cover plate 13 recessed or below the cover plate 13 arranged and not shown in the figures heating wires.

In another embodiment of the magnetic coupling 1 indicates the heater 16 a, preferably coated heating coil on the as a footprint 15 serving outside fourteen the cover plate 13 is arranged. Of course it is also possible, this heating spiral within the cover plate 13 or below the cover plate 13 to arrange.

The magnetic coupling 1 also has one of the cover plate 13 the magnetic coupling 1 oppositely arranged base plate 17 on, which further reduces the overall height of the magnetic coupling 1 as a circuit board 18 is trained. Thus, the base plate 17 assigned a double function, on the one hand, the magnetic coupling 1 closes down and on the other hand acts as a carrier for circuit parts and / or sensors and / or traces.

The magnetic coupling shown in the figures can be integrated in various, not shown in the figures stirring devices. Particularly advantageously, the magnetic coupling can be 1 thereby integrate into a magnetic stirrer (also not shown in the figures) and thus provide a magnetic stirrer with reduced overall height.

The figures also show that the rotor 3 by means of a first lower bearing 19 and a second upper bearing 20 around an axis 21 rotatable in the rotor-stator unit 5 is stored. With a recessed middle section 22 is the rotor 3 while on the lower camp 19 on. The upper bearing 20 lies in position of use on the middle section 22 on. The axis 21 is each through a hole in the rotor 3 and in the two camps 19 and 20 Box Type. The two camps 19 and 20 are designed as plain bearings, in another embodiment of the magnetic coupling 1 but also be designed as a rolling bearing.

To reduce the height of the magnetic coupling 1 , which is particularly suitable for use in a magnetic stirrer, is the at least one magnet 4 of the rotor 3 acting as a driving magnet for a counter-coupling piece of the magnetic coupling, in particular for a stirring magnet of a magnetic stirrer, arranged such that it at least partially or completely in the of the rotor-stator unit 5 included space 7 protrudes and / or at least partially or completely in this room 7 is arranged.

Claims (17)

Magnetic coupling ( 1 ), in particular for use in a magnetic stirrer or other stirring device, with a rotor-stator unit ( 5 ) comprehensive electric motor ( 2 ), wherein on a rotor ( 3 ) of the rotor-stator unit ( 5 ) at least one magnet ( 4 ) arranged to drive one with the magnetic coupling ( 1 ) is arranged to be coupled, at least one counter-magnet or magnetic material having Gegenkupplungsstücks, characterized in that the at least one magnet ( 4 ) of the rotor ( 3 ) in the position of use at least partially or completely in one of the rotor-stator unit ( 5 ) included space ( 7 ) and / or at least partially or completely arranged in this. Magnetic coupling ( 1 ) according to claim 1, characterized in that a stator ( 5a ) of the rotor-stator unit ( 5 ) several induction coils ( 6 ) within the room ( 7 ) are arranged, and that the at least one magnet ( 4 ) of the rotor ( 3 ) and / or the rotor ( 3 ) in the position of use at least partially or completely in a between the induction coils ( 6 ) extending Gap ( 7a ) and / or at least partially or completely arranged in this. Magnetic coupling ( 1 ) according to claim 1 or 2, characterized in that a clear height of the space ( 7 ) and / or the space ( 7a ) one in the direction of an axis of rotation (R) of the rotor ( 3 ) measured dimension of the induction coil ( 6 ) of the stator ( 5 ) corresponds. Magnetic coupling ( 1 ) according to one of claims 1 to 3, characterized in that the at least one magnet ( 4 ) of the rotor ( 3 ) has a dimension such that it is completely in the room ( 7 ) and / or in the intermediate space ( 7a ) of the magnetic coupling ( 1 ), in particular that a height of the at least one magnet ( 4 ) not more than one axial dimension or height of the stator ( 5 ) and / or at most as large as a dimension or height of the induction coils measured in the direction of the axis of rotation (R) ( 6 ). Magnetic coupling ( 1 ) according to one of claims 1 to 4, characterized in that an axial dimension or height of the rotor ( 3 ) not more than one axial dimension or height of the stator ( 5a ) and / or that a radial dimension of the rotor ( 3 ) is dimensioned so that this completely into the space ( 7a ) between the induction coils ( 6 ) fits. Magnetic coupling ( 1 ) according to one of claims 1 to 5, characterized in that the rotor ( 3 ) at least two magnets ( 4 ) in the position of use at least partially or completely in the space ( 7 ) and / or in the intermediate space ( 7a ) and / or sunk into it. Magnetic coupling ( 1 ) according to one of claims 1 to 6, characterized in that the rotor ( 3 ) a recess ( 9 ) for receiving the at least one magnet ( 4 ), in which the at least one magnet ( 4 ) of the rotor ( 3 ) is arranged in the use position and / or that the rotor ( 3 ) for each magnet ( 4 ) of the rotor ( 3 ) each have their own well ( 9 ), preferably wherein a plurality of depressions ( 9 ) for several magnets ( 4 ) of the rotor ( 3 ) evenly about the axis of rotation (R) of the rotor ( 3 ) are arranged distributed. Magnetic coupling ( 1 ) according to one of claims 1 to 7, characterized in that the rotor ( 3 ) cup-shaped and the at least one magnet ( 4 ) at least partially or completely within one of the rotor ( 3 ) formed pot ( 3a ), preferably wherein a depth of a or of the cup-shaped rotor ( 3 ) formed pot ( 3a ) is dimensioned such that the at least one magnet ( 4 ) at least partially or completely submerged in the pot ( 3a ) can be arranged or arranged. Magnetic coupling ( 1 ) according to one of claims 1 to 8, characterized in that the at least one magnet ( 4 ) at least partially or completely within the rotor ( 3 ) and / or at least partially or completely between a transverse to the axis of rotation (R) of the rotor ( 3 ) oriented top ( 10 ) and a parallel thereto and / or transversely to the axis of rotation (R) of the rotor ( 3 ) oriented underside ( 11 ), in particular a rotor bottom ( 12 ), of the rotor ( 3 ) is arranged. Magnetic coupling ( 1 ) according to one of claims 1 to 9, characterized in that the rotor ( 3 ) a ring magnet ( 8th ), over which the rotor ( 3 ) from the induction coils ( 6 ) of the stator ( 5a ) is drivable, wherein the ring magnet ( 8th ) so on the rotor ( 3 ) is arranged, that he at least one magnet ( 4 ) of the rotor ( 3 ) at least partially or completely laterally surrounds. Magnetic coupling ( 1 ) according to one of claims 1 to 10, characterized in that the rotor ( 3 ) a rotor bottom ( 12 ), which is adapted to a magnetic field of the at least one magnet ( 4 ) of the rotor ( 3 ) to reinforce. Magnetic coupling ( 1 ) according to one of claims 1 to 11, characterized in that the magnetic coupling ( 1 ) a cover plate ( 13 ), under the in use position of the magnetic coupling ( 1 ) at least the rotor ( 3 ) of the electric motor (R) of the magnetic coupling ( 1 ) together with the at least one magnet ( 4 ) of the rotor ( 3 ), wherein one of the rotor ( 3 ) facing away from outside ( fourteen ) of the cover plate ( 13 ) as a footprint ( 15 ) is designed for a vessel. Magnetic coupling ( 1 ) according to claim 12, characterized in that the cover plate ( 13 ) of the magnetic coupling ( 1 ) consists of a sheet metal, in particular of stainless steel, or glass or plastic. Magnetic coupling ( 1 ) according to one of claims 1 to 13, characterized in that the magnetic coupling ( 1 ), in particular one or the cover plate ( 13 ) of the magnetic coupling ( 1 ), a heating device ( 16 ) for heating a vessel erected on it. Magnetic coupling ( 1 ) according to claim 14, characterized in that the heating device ( 16 ) below one or the cover plate ( 13 ) of the magnetic coupling ( 1 ) and / or that the heating device ( 16 ) within one or the cover plate ( 13 ) embedded or below one or the cover plate ( 13 ) arranged heating wires and / or that the heating device ( 16 ) has a, preferably coated, heating coil, which at one as a footprint ( 15 ) serving outside ( fourteen ) one or the cover plate ( 13 ) of the magnetic coupling ( 1 ) is arranged. Magnetic coupling ( 1 ) according to one of claims 1 to 15, characterized in that the magnetic coupling ( 1 ) one or the cover plate ( 13 ) of the magnetic coupling ( 1 ) oppositely arranged base plate ( 17 ), which is used as a printed circuit board ( 18 ) is formed, in particular on which circuit parts and / or sensors and / or conductor tracks are arranged. Stirring device, in particular magnetic stirrer, with a magnetic coupling ( 1 ) according to one of claims 1 to 16.

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