EP0979945B1 - Magnetic coupling system and use of it for a gear pump - Google Patents

Description

The present invention relates to a device according to the preamble of claim 1 and a use the device.

Magnetic couplings are used for torque transmission between non-contacting waves, i. one to be sealed Rotary feedthrough, as for example from the Housing led out with a gear pump Drive shaft is necessary, is in a gear pump not needed with magnetic coupling. By magnetic couplings driven pumps have only static acting Seals on, which is why they are hermetically sealed apply and therefore especially for extreme environmentally hazardous or toxic fluids are suitable.

Known magnetic clutches consist of a bell-like Outer rotor, the single or double-walled containment shell and the Inner rotor. The outer rotor usually sits on one Motor shaft or a transmission output shaft and the Inner rotor is located on the out of the pump housing led out drive shaft of the gear pump. The Torque is transmitted by magnets, which are on the inner surface of the outer rotor as well as on the Outside surface of the inner rotor are located. magnetic couplings This known type are because of the mentioned Application benefits more often and preferably also used for ever larger services to be transmitted.

A disadvantage of this known embodiment are the high demands on the position of each other connecting components: So are both the Drive unit and the gear pump extremely precise to position each other. Since gear pumps also with Connection lines for the pumped medium to be transported to connect, here are more Restrictions or specifications regarding the desired Position, often with the first not mentioned to match. Remedy here creates the possibility that the drive unit can be flexibly mounted, which however, only practicable in the low-power range is.

For large transmission powers, the assembly of the Magnetic coupling difficult because the magnets are very strong - and that are difficult - trained. Merging the Components are designed so that each last mounted rotor must be pushed along the gap pot along. It splits very easily the corners of mostly brittle magnetic material manufactured driving magnets.

From US-5,165,868 such a magnetic coupling for non-contact transmission of torque between a first known on a second wave, wherein the first shaft is mounted in a housing that with a the magnetic coupling encompassing fixing connected which is over from the magnetic coupling axially spaced bearing units features the second shaft hold in position.

Furthermore, from US-1 913 633 a hinged Connection of waves known.

The present invention is therefore the task based, a device with a magnetic coupling indicate which does not have the aforementioned disadvantages having.

This object is achieved by the in the characterizing part of Patent claim 1 specified measures solved. Advantageous embodiments of the invention and a Use are specified in further claims.

The invention has the following advantages: driven by the drive unit shaft with the drive-side rotor is hingedly connected and by the Bearing units radially with respect to the drive side Rotor are arranged, the axes must be driven Shaft and that of the drive-side rotor not coincide. These can be a missing one Align without the function of the Entire facility is impaired. In addition, the Invention has the advantage that in the assembly of the Magnetic coupling whose outer rotor, guided by the Fixing elements, can be pushed over the containment shell, without a tilting is possible. In addition, the Outer rotor bearing closer to the containment shell and is therefore on the place where precise positioning, especially in radial direction, is critical to function.

Fig. 1

eine erste Ausführungsform einer erfindungsgemässen Magnetkupplung,

Fig. 2

eine weitere Ausführungsform der erfindungsgemässen Magnetkupplung und

Fig. 3

Wellenabschnitte der Antriebswelle und eine Antriebseinheit zum Antreiben der Welle in schematischer Darstellung.

The invention will be explained in more detail with reference to drawings, for example. Show

Fig. 1

A first embodiment of a magnetic coupling according to the invention,

Fig. 2

a further embodiment of the inventive magnetic coupling and

Fig. 3

Shaft sections of the drive shaft and a drive unit for driving the shaft in a schematic representation.

In Fig. 1 is a gear pump 1, a Magentkupplung. 2 and a universal joint 14, wherein for driving the Gear pump 1, a drive unit (in Fig. 1 not shown) is connected to the universal joint 14.

The gear pump 1 consists essentially of a Pump housing 21, of two intermeshing gears 3 and shaft bearings 6, in which the gears 3 bearing Shafts 4 are stored. One of the waves 4 is from the Pump housing 21 led out to drive the pump. On this extended shaft, in the following drive shaft 7 called, sitting to the magnetic coupling 2 belonging inner Rotor 17, which has magnets 18 on its surface. An outer rotor 12, on its inner surface as well equipped with magnets 19 is radially to the inner rotor 17 arranged, being between the inner and the outer Rotor 17 and 12, a so-called split pot 16 is provided is that allows a complete seal. Drive side, i. then to the outer rotor 12 and connected to this, a shaft portion 11 follows via a connectable to the pump housing 21 Fixing element 8 is held in position, d. H. the Mobility of the shaft portion 11 - and thus also the outer rotor 12 - is in the radial direction on the Bearing clearance of a preferably as a rolling bearing 10th trained bearing limited according to the invention.

The shaft portion 11 is further on a Universal joint 14 with a drive shaft 13, i. preferably initially with an inner part of a Drive shaft, which inner part over a second Universal joint (not shown in Fig. 1) with the Actual drive shaft of a drive unit (in FIG. 1 not shown).

Thus, the magnetic coupling 2 forms with respect to the radial Mobility a unit with the gear pump 1 or with whose housing 21, which achieved in an advantageous manner is that the drive shaft 7 of the gear pump 1 with the Drive shaft 13 of the drive unit is not exact must coincide.

Another advantage is achieved by at least one of the drive shaft sections, i. of the Drive shaft portion in front of the first universal joint 14th and / or between the two universal joints and / or after the second universal joint, is telescopically constructed and thus can be extended or shortened as needed. These further embodiments still allow one more flexible handling of the positioning of the gear pump with respect to the drive unit.

Instead of universal joints, it is also conceivable that others Joint types are used. It has been shown that in particular, gear couplings, rubber couplings or other flexible couplings excellent for realization the device according to the invention are suitable.

The fixing element 8 is by means of releasable Fasteners 15, preferably made of screws exist, attached to the pump housing 21. In a preferred embodiment is the fixing element. 8 tubular and closes the magnetic coupling 2 against the outside from, with ventilation holes 9 are provided.

2 shows a further embodiment of the invention, wherein in this the rolling bearing 10 radially to the split pot 16th are arranged. This is the storage of the outer rotor 12 closer to the split pot 16 and thus to the Place where precise positioning is critical to function is.

Fig. 2 shows substantially the magnetic coupling 2. From the Gear pump 1 are only individual parts, namely the Pump housing 21 and sections of the shaft passage of the Drive shaft 7, shown.

In addition to the mentioned advantage in terms of an ideal Force absorption at radially arranged bearings 10 has the further embodiment further has the advantage that the assembly can be made in a simple manner. So the outer rotor 12 becomes simple at the end of assemblage slid onto the containment shell 16 without touching it is because the bearings 10 ensure that the magnets 19 of the outer rotor 12 and the split pot 16 permanently are spaced.

Finally, in FIG. 3, in a schematic representation, three shaft sections 31, 32 and 33 of the drive shaft illustrated, wherein the first shaft portion 31 with the second shaft portion 32 via a first flexible Clutch 34 and the second shaft portion 32 with the third shaft portion 33 via a second flexible Coupling 35 are connected. The shaft section 33 corresponds to the rigid, out of a drive unit 30 out guided drive shaft. On the other side is the outer rotor 12 (FIGS. 1 and 2) of the magnetic coupling 2 (FIG. 1 and 2) connected to the first shaft portion 31. The flexible couplings 34 and 35 are in one of the explained Realized form.

In a preferred embodiment, the second one Shaft portion 32 formed telescopically.

Claims (9)

1. Device with a magnetic coupling (2) for the contactless transmission of a torque from a first shaft to a second shaft, with a first shaft (13) coupled to a drive unit and a second shaft (7) supported in a casing (21), one of the shafts (7) being provided with an inner rotor (17) having first magnets (18) and the other shaft (13) being provided with an outer rotor (12) having second magnets (19), the axis of the rotor (12) on the drive side being radially fixable via bearing units (10), via fixing elements (8), which are connectable to the casing (21), characterized in that the shaft (13) driven by the drive unit is jointedly connected to the rotor (12) on the drive side and that the bearing units (10) are arranged radially with respect to the rotor (12) on the drive side.
2. Device according to claim 1, characterized in that the connection between the rotor (12) on the drive side and the shaft (13) driven by the drive unit consist of one, preferably of two flexible couplings (14).
3. Device according to claim 2, characterized in that at least one of the flexible couplings (14) optionally is a rubber coupling, a curved teeth coupling or a cross joint or a combination of two or more of said kinds of couplings.
4. Device according to one of the preceding claims, characterized in that roller bearings as bearing units (10) are provided between the fixing elements (8) and the rotor (12) on the drive side.
5. Device according to one of the preceding claims, characterized in that the fixing element (8) is tubular.
6. Device according to claim 5, characterized in that ventilation bores (9) are provided in the fixing element (8).
7. Device according to one of the preceding claims, characterized in that a shaft portion (31,32,33) of the drive shaft (13) is designed telescope like.
8. Device according to one of the preceding claims, characterized in that a spacer can (16) is provided between the inner and the outer rotor (17; 12), by means of the spacer can (16) a complete sealing being achievable.
9. Usage of the device according to one of the claims 1 to 8 for driving a gear pump (1).

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