DE20008322U1 - Electromagnetic drive system - Google Patents

Description

Description
Electromagnetic drive system

The innovation concerns an electromagnetic drive system for a consumer located within a chamber that is at least partially separated from the environment by a wall made of magnetic field-permeable material.

Magnetic stirring devices with a device base containing a magnetic field generation system are well known. A stirring vessel is placed on the device base, in which there is a liquid to be stirred or mixed, into which a magnetic stirring rod is inserted. By exciting the magnetic coils with phase-shifted currents, an electromagnetic rotating field is formed above the surface of the device base that supports the stirring vessel, which penetrates the wall of the stirring vessel and interacts with the stirring rod in the stirring vessel. The drive system formed by the device base and the stirring rod thus represents a synchronous motor, the magnet wheel of which has the shape of the magnetic stirring rod. This stirring rod is therefore both the drive rotor and the consumer of the drive system.

Consumers that require higher drive torques, such as pumps, fan wheels or agitator blades located in a chamber, are generally driven by a drive motor located outside the chamber by means of a shaft that extends into the chamber to the consumer in question via a gas- or liquid-tight passage. However, the secure sealing of the rotating drive shaft can sometimes be difficult.

A tight passage of the drive shaft for the consumer located in a chamber could be avoided by a drive system that is described in the German laid-open specification 197 39 785. This known drive system for a

[File: 100276283 // HK01K04] Description * $JM*ai &Idigr;&thgr;0&thgr;1 &Igr; Electromagnetic drive system H+P Labortechnik GmbH

Consumer, which is located inside a chamber which is at least partially separated from the environment by a wall made of material permeable to magnetic fields, contains excitation coils located outside the chamber which are cyclically phase-shifted and energized to generate a rotating magnetic field which passes through areas of the chamber interior and interacts with a rotor located inside the chamber and mounted there for rotation, and a magnetic pole wheel equipped with permanent magnets which, on the one hand, generates a primary magnetic field which interacts with the magnetic field of the excitation coils and, on the other hand, generates the rotating magnetic field which passes through areas of the chamber interior as a secondary magnetic field. In this drive system, the magnetic pole wheel equipped with permanent magnets is therefore to be regarded on the one hand as the rotor of a synchronous motor located outside the chamber and on the other hand as the part outside the chamber of a magnetic coupling which acts through the chamber wall, the part of which located inside the chamber is the rotor coupled to the consumer.

Based on this state of the art, the aim of the present innovation is to design an electromagnetic drive system of the type defined at the outset in such a way that the structure is simplified, the dimensions in the axial direction are reduced, the achievable drive torques are increased and the efficiency is improved.

This aim is achieved according to the invention by the features specified in claim 1. Advantageous embodiments and further developments are the subject of the claims subordinate to claim 1.

The principle underlying the innovation is to achieve a minimum value of magnetic resistance for the magnetic closure circuit guided over the rotor within the chamber by moving the air gaps in this circuit into the interior of the chamber and allowing them to be made relatively narrow, since they do not have to simultaneously provide space for the magnetic field-permeable wall between the interior of the chamber and the free environment.

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Electromagnetic drive system
H+P Laboratory Technology GmbH

The following embodiments are explained in more detail using the drawings. They show:

Figure 1 is a perspective view, partly in axial section, of an electromagnetic drive system of the type specified here, with some parts omitted for reasons of clarity; and

Figure 2 is a bottom view, i.e. a view from the interior of the chamber, of the drive system according to Figure 1.

In the drawings, a magnetic field-permeable wall of a container or chamber is designated by 1. The wall 1 separates an interior space 2 of the container or chamber in question from the free environment 3. A vacuum or an increased pressure, a low or high temperature, an aggressive atmosphere and the like can be maintained in the interior space 2.

Inside the chamber interior 2 there is a consumer (not shown) which is set in rotation by the drive system specified here and which is coupled to the drive system via a hollow shaft 4. The end of the hollow shaft 4 facing the drive system is supported by a bearing 5, for example a ball bearing, on an axle 6 attached to the wall 1 and is connected in a rotationally fixed manner to the rotor 7 of the drive motor. Details of the rotor 7 will be discussed in more detail below. It is sufficient to state here that the rotor 7 interacts with a moving magnetic field, in particular a rotating field, and is carried along by it.

The rotor 7 is, as can be seen particularly from the bottom view of Figure 2, surrounded by a ring of pole pieces 8, which have a circular sector shape. Cylindrical cores 9 provided with outer walls protrude upwards from the pole pieces 8 through holes 10 in the wall 1, whereby the holes 10 lie on a pitch circle which has a larger diameter than the outer diameter of the rotor 7. The outer circumference of the rotor 7, which is surrounded by the inward-facing surfaces of the

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H+P Laboratory Technology GmbH

Pole pieces 8 limited cylinder surface and the pitch circle of the bores 10 are coaxial to the hollow shaft 4 and to the axis 6.

The pole pieces 8 are clamped and tightened against the inside of the wall 1 by means of nuts 11 screwed onto the core 9 and resting on the outside of the wall 1 with sealing rings 12 interposed. According to a modification indicated in Figure 2, instead of the individual sealing rings 12 surrounding the edge of a hole 10, a large, continuous sealing ring with holes or openings aligned with the holes 10 can also be provided.

After tightening the nuts 11 on the cores 9, excitation coils 14 are pushed onto all of these cores. These excitation coils 14 are connected together via lines 15, which are only shown schematically in Figure 1, to form a stator winding which can be cyclically supplied with current in a phase-shifted manner, such that a resulting moving magnetic field, in particular a rotating magnetic field, is generated within the chamber interior.

After the excitation coils 14 have been pushed on, a yoke ring 16 is pushed over all the protruding cores 9, which has holes 17 aligned with the holes 10 in the wall 1 for receiving the cores 9. Finally, the yoke ring 16 is fastened by nuts 18 screwed onto the sections of the cores 9 that still protrude above the yoke ring 16. It is understood that, as already mentioned, the wall 1 consists of a magnetically non-active, magnetic field-permeable material, while the pole pieces 8, the cores 9 and the yoke ring 16 consist of a magnetically active material, in particular a magnetically soft material, whereby the pole pieces 8 are in any case made of such a material while simultaneously fulfilling the requirement that the pole pieces 8 must withstand the conditions prevailing in the chamber interior.

If the pole pieces 8 are formed in one piece with the cores 9, then the cores 9 are of course also made of a corresponding material, for example of a non-rusting, magnetically active material. However, if the pole pieces 8 and the cores 9 are

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Electromagnetic drive system
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Because they are separate components, only the pole pieces 8 have to be made of a material that can withstand the conditions in the chamber interior, and the cores 9, which are screwed into threaded blind holes in the pole pieces 8, can then be made of a different material that may be less thermally and/or chemically resistant.

According to a modification of the construction shown in Figure 1, the cores 9 can be firmly connected to the yoke ring 16, for example welded, so that for assembly the yoke ring and the cores are first equipped with the excitation coils and then inserted with the ends facing the pole pieces 8 into the holes 10, after which pole pieces 8 provided with threaded blind holes are screwed onto the cores from the chamber interior 2, which in turn takes place with the interposition of sealing rings or a single, appropriately large sealing ring in the manner of the sealing ring 13.

Permanent magnet pieces 19 are embedded in the rotor 7, each of which has a changing orientation of its magnetization, so that a synchronous machine pole wheel is formed, the number of pole pairs of which is 2 in the present example.

It is understood that other numbers of pole pairs and other numbers of excitation coils 14 can be selected by a person skilled in the art depending on the requirements of the drive for a specific consumer.

Deviating from the embodiment shown in Figure 2, the rotor 7 can also be designed as an asynchronous squirrel-cage rotor, which interacts with the rotating magnetic field generated by the excitation coils 14 and acting between the pole pieces 8.

Finally, the rotor can also be a soft iron rotor that aligns itself with the moving magnetic field and follows it, for example a rotor made of cross-shaped blades

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A composite laminated core which has a certain offset between the individual sheets in the circumferential direction in order to improve the starting properties.

It should be mentioned at this point that with a larger number of poles of the stationary magnetic field generation system, the moving magnetic field can also be simulated by applying current to neighboring excitation coils or neighboring excitation coil groups with alternating current direction.

An electromagnetic drive system of the type specified here can also be understood, as the person skilled in the art will see from the above, as an electromagnetic rotary stepper motor.

In order to prevent the rotor from falling out of step with respect to the moving magnetic field in the case of larger torques to be generated by the electromagnetic drive system, according to a further modification it can also be provided to detect the respective relative rotational position of the rotor and to control the current application to the excitation coils depending on the detection result, which is, however, known per se.

It can be seen that the drive specified here has minimal dimensions in the axial direction and is free of passages for rotating shafts that need to be sealed. With a simple design of the entire sealing structure for the passage of the cores of the magnetic field generation system, a minimal magnetic resistance of the magnetic closure circuit guided over the rotor is achieved and an intensive magnetic field is generated directly in the area between the pole pieces within the chamber space.

If the wall part consisting of magnetic field permeable material has the shape of a container lid made of plastic, the arrangement of cores can also be cast into the plastic, wherein the cores 9 in the section embedded in the plastic are provided with corresponding collars to improve the sealing.

Claims (11)

1. Electromagnetic drive system for a consumer which is located inside a chamber ( 2 ) which is at least partially separated from the environment by a wall ( 1 ) made of a material permeable to a magnetic field, with excitation coils ( 14 ) located outside the chamber and energized in a phase-shifted manner, and with means for generating a moving magnetic field which passes through regions of the chamber interior ( 2 ) and which interacts with a rotor ( 7 ) located in the chamber interior and rotatably mounted there, which drives the consumer, characterized in that cores ( 9 ) wrapped around by the excitation coils ( 14 ) are led from the region outside the chamber in which the excitation coils ( 14 ) are located, tightly through the chamber wall ( 1 ) to pole pieces ( 8 ) located inside the chamber, from which the field lines of the moving magnetic field emanate. 2. Drive system according to claim 1, characterized in that the cores ( 9 ) on the side of the excitation coils ( 14 ) remote from the chamber wall ( 1 ) are connected by a yoke ring ( 16 ). 3. Drive system according to claim 1 or 2, characterized in that the cores ( 9 ) and/or the pole pieces ( 8 ) are each sealed relative to the chamber wall ( 1 ) via sealing rings ( 12 ) or surfaces resting on a common sealing ring ( 13 ). 4. Drive system according to claim 3, characterized in that the cores are clamped against the chamber wall ( 1 ) by pole pieces ( 8 ) screwed onto them. 5. Drive system according to claim 1 or 2, characterized in that the cores ( 9 ) are cast into the chamber wall ( 1 ) in the region of the passage through the chamber wall, which consists of castable plastic. 6. Drive system according to one of claims 1 to 5, characterized in that the consumer is a fan wheel. 7. Drive system according to one of claims 1 to 5, characterized in that the consumer is an agitator. 8. Drive system according to one of claims 1 to 7, characterized in that the rotor ( 7 ) is a pole wheel equipped with permanent magnet pieces ( 19 ). 9. Drive system according to one of claims 1 to 7, characterized in that the rotor is an asynchronous motor squirrel-cage rotor. 10. Drive system according to one of claims 1 to 7, characterized in that the rotor is a soft tissue rotor which aligns with the moving magnetic field and follows it. 11. Drive system according to claim 8 or 10, characterized in that the relative rotor position is detectable and the moving magnetic field is controllable depending on the detection result.