WO1988005141A1

WO1988005141A1 - Sealing device with ferrous fluid

Info

Publication number: WO1988005141A1
Application number: PCT/DE1987/000605
Authority: WO
Inventors: Manfred Diesing
Original assignee: Manfred Diesing
Priority date: 1986-12-30
Filing date: 1987-12-23
Publication date: 1988-07-14
Also published as: DE3644697C1; EP0294452A1

Abstract

A hollow sealing element built in a housing, composed of a plastic block filled with magnetic particules, has a rotating shaft of magnetizable material, the interferric gap between the pole shoes and the shaft being filled with a ferrous fluid, thus forming a gastight seal between the left and the right-hand sides of the hollow sealing element. In comparison with the state of the art, the device can be economically manufactured, eliminating sealing problems with adhesive joints running out of truth due to shifting of the bonding material.

Description

B e s e r e i b u n g

Sealing device with ferrofluid

From DE-PS 31 45 460 a sealing device with ferrofluid is known, which consists of a ring magnet to which pole rings are glued to both end faces.

Based on this, the mode of operation of the sealing devices on the market with ferrofluid is explained in FIG. 1 of the illustration part:

Two ring-shaped pole rings (2) made of magnetizable stainless steel are glued to the two end faces of an annular permanent magnet (1). A rotating shaft made of magnetizable stainless steel is guided through this sealing device. The air gap between the shaft and the pole rings is filled with a magnetic liquid, the ferrofluid (4). The sealing device is glued into a housing (5) for static sealing.

This sealing device has the following disadvantages:

1. To achieve a static seal, the magnet and the pole rings must be glued. This gluing is often incomplete and therefore not tight. It is also a cost-intensive process.

2. The magnet and pole rings are axially centered by the adhesive to achieve the best possible concentricity. This centering is often incorrect and there is a blow that can be so large that ferrofluid is sprayed off. Devices that cause costs are required for the centering adhesive. 3. Remnants of the adhesive used can adhere to the inner diameter of the pole rings and cause ferrofluid to be sprayed off.

4. The adhesive connection between the magnet and the pole ring can come loose during transport or when inserting the sealing device into the housing. The seal is no longer statically sealed.

5. For static sealing, the sealing device must be glued into the housing (5). This static seal may be faulty, so the seal will not work.

6. These sealing devices with ferrofluid are mainly used for sealing against microscopic particles in systems requiring extreme cleanliness, e.g. Magnetic disk drives for computers. The adhesive processes described above as additional work steps in the manufacture of the sealing devices can lead to contamination of the seals by fingerprints or accumulation of particles located in the manufacturing room. A complex cleaning procedure is required.

7. Ferrofluid can be drawn into the microscopic cavities between permanent magnet and pole rings, which are never completely filled with adhesive, which is then missing in the air gap and can lead to premature failure of the seal. S umma

The production of the sealing device with ferrofluid from individual parts according to the current state of the art is technically complex, expensive and can lead to contamination.

The object of the invention is to overcome the disadvantages described above and to achieve the advantages stated below.

The object is achieved by the features specified in claim 1.

V e r t e i l e d e r E r f i n d u n g

Instead of the three parts magnet and two pole rings, a single plastic part, the hollow sealing element (1) according to FIG. 2, is used. It consists of a plastic block. It is made of permanently magnetizable plastic, for example by injection molding or compression molding. Such permanent magnetic plastics are numerous on the market. They usually consist of magnetic particles such as magnetite, barium ferrite or strontium ferrite etc., which are bound by plastics.

Any ferrofluid can be used, but the carrier fluid of the ferrofluid used, which has a low vapor pressure and is mostly a synthetic hydrocarbon, diester or a triester, must be compatible with the plastic binder used.

This single plastic part has the following advantages:

1) It is inexpensive to manufacture.

2) There are no centering problems due to adhesive misalignment of individual parts.

3) The problem of the static tightness of individual parts is eliminated. 4) Contamination due to the assembly of individual parts is eliminated.

5) No ferrofluid can be drawn through capillary action between individual pole rings and the magnets.

6) Due to the plastic deformability of the plastic, the adhesive connection between the sealing device and the housing can be omitted, which was previously required for static sealing.

7) The only plastic part results in a larger one

Magnetic volume, ie more magnetic energy can be accommodated in the sealing device.

B e s b h e i b u n g d e r A b b i l d u n g e n

Figure 2 shows the basic embodiment of the invention, characterized by the hollow sealing element consisting of a permanent magnet plastic, a single block of plastic.

3 shows an embodiment in which an axially magnetized permanent magnet (2. is inserted in a plastic block forming the hollow sealing element made of permanent magnetic plastic. This inserted permanent magnet does not have to be a plastic magnet, transmitters can be, for example, a ceramic magnet to reinforce the magnetization. In In this, as in all other axially magnetized versions, the north pole can be left or right.

Figure 4 shows an embodiment in which two ring-shaped permanent magnets (3) are inserted. In contrast to FIG. 3, these are magnetized radially. Only an annular permanent magnet can also be inserted. In this case too, the inserted permanent magnet does not have to consist of a plastic magnet, but can be Alnico, a ceramic magnet or another magnetic material. The direction of magnetization can be reversed.

Figure 5 shows the plastic block forming the hollow sealing element made of magnetizable material with e.g. by means of adhesion or diffusion glue attached pole ring (4. made of magnetizable material, such as magnetizable stainless steel, plastic-encapsulated magnetizable metal or magnetic plastic.

FIG. 6 shows the plastic block forming the hollow sealing element with pole rings attached on both sides as described in FIG. 5. Designs according to FIGS. 5 and 6 have advantages with small dimensional tolerances and when high magnetic flux rotations are achieved in the pole rings.

FIG. 7 shows an embodiment in which two pole rings made of magnetisable material (5) are inserted into the plastic block forming the hollow sealing element. This version stiffens the pole pieces and increases the magnetic flux density in the air gap.

FIG. 8 shows an embodiment in which the plastic block of permanent magnetic plastic forming the hollow sealing element is surrounded by a bushing (6) made of non-magnetic material. This version is particularly suitable for installation in magnetically conductive housings because it prevents a magnetic short circuit.

Figure 9 shows an embodiment in which, in addition to Figure 8, the bushing (6a) made of non-magnetic material is extended over one side of the plastic block forming the hollow sealing element by a distance of e.g. To achieve ball bearings. This distance extension can also be on both sides.

Figure 10 shows the plastic block (1) forming the hollow sealing element with an inserted spiral spring (7) for elastic contact and thus static sealing of the hollow sealing element to the non-magnetic socket or directly to the housing.

FIG. 11 shows the plastic block forming the hollow sealing element with inserted reinforcing rings (8). These can have different profiles. One or more reinforcement rings can be inserted. At the same time, Figure 10 and Figure 11 show the possibility of filling only one air gap between a pole piece and the shaft. The magnetic circuit closes due to the unfilled air gap between the other pole piece and the shaft.

FIG. 12 shows the plastic block forming the hollow sealing element with two different pole pieces. One pole piece has a small inner diameter and thus forms a smaller air gap than the other pole piece, which has a larger inner diameter and thus forms a larger air gap to the shaft. The advantage lies in the lower viscous friction of the ferrofluid. This results in a longer life of the ferrofluid due to less heating and the possibility of allowing higher peripheral speeds of the shaft.

Figure 13 shows a wider pole piece on the right. The advantage lies in the greater pressure holding capacity, because the differential pressure that can be achieved increases with the width of the pole piece.

FIG. 14 shows the plastic block of permanent magnetic plastic forming the hollow sealing element with a fastening device with screw countersinks.

FIG. 15 shows an exemplary embodiment with a fastening device protruding beyond the flange of the pole piece. This will keep the right pole piece at a distance. The ferrofluid cannot be wiped off and the magnetic stray field of the right pole shoe does not affect any ball bearings. The risk of a magnetic short circuit is also reduced.

FIG. 16 shows sealing profiles (9) attached to the fastening device of the plastic block forming the hollow sealing element for static sealing. FIG. 17 shows a device (10) attached to the fastening device of the plastic block forming the hollow sealing element for receiving an O-ring (11), which is used for static sealing.

FIG. 18 shows a fastening device (12) which, with the plastic block forming the hollow sealing element (1), does not form a material unit, but is a separately manufactured component. This separately manufactured fastening device (12) can be made of plastic or metal and with the hollow sealing element (1) made of permanent magnetic plastic by e.g. Adhesion or diffusion bonding. It can also be simply pressed on using the plastic deformability of plastic.

Claims

Expectations :

1. Sealing device in the form of a hollow magnetized sealing element, which surrounds a rotatable shaft made of magnetizable material in an annular manner, the areas located on the end faces of the sealing element acting as a pole piece and forming gaps with the shaft surface via which a magnetic circuit closes and at least one of which with Ferrofluid is filled, characterized in that the sealing element consists of a closed block of magnetizable plastic, that is, of magnetic particles such as magnetite, barium ferrite or strontium ferrite, which are bound by plastics.

2. Sealing device according to claim 1, characterized in that an axially magnetized permanent magnet ring is inserted into the hollow sealing element made of magnetizable plastic.

3. Sealing device according to claim 1, characterized in that one or two radially magnetized permanent magnet rings are inserted into the hollow sealing element made of magnetizable plastic.

4. Sealing device according to claim 1, characterized in that a pole shoe is formed by a separate ring made of magnetizable material.

5. Sealing device according to claim 1, characterized in that the two pole pieces are formed by separate rings made of material which can be made manisable.

6. Sealing device according to claim 1, characterized in that one or two rings made of magnetizable material are inserted.

7. Sealing device according to claims 1 to 6, characterized in that around the hollow sealing element made of magnetisrerbarem

Plastic a ring made of non-magnetic material is attached.

8. Sealing device according to claims 1 to 6, characterized in that a ring made of non-magnetic material is attached to the hollow sealing element made of permanent magnetic plastic, which protrudes on one or both sides as a spacer over the hollow sealing element.

9. Sealing device according to claims 1 to 8, characterized in that an annular spiral spring is inserted into the hollow sealing element.

10. Sealing device according to claim 1, characterized in that one or more reinforcing rings of different profile shapes are inserted into the hollow sealing element, the recessing rings optionally additionally in the hollow sealing elements according to claims 2, 3, 4, 5, 6, 7, 8 or 9 are inserted.

11. Sealing device according to claims 1 to 10, characterized in that only one of the two air gaps is filled with ferrofluid.

12. Sealing device according to claims 1 to 11, characterized in that a pole piece has a larger diameter and thereby a larger air gap is formed under a pole piece.

13. Sealing device according to claims 1 to 12, characterized in that one pole piece is wider than the other.

14. Sealing device according to claims 1 to 13, characterized in that the hollow sealing element is provided with a fastening device with countersunk screws.

15. Sealing device according to claim 14, characterized in that the fastening device protrudes as a spacer ter over the flange of a pole piece.

16. Sealing device according to claims 1 to 15, characterized in that the fastening device is provided with profiles for static sealing.

17. Sealing device according to claims 1 to 15, characterized in that the fastening device is provided with a device for receiving an O-ring for static sealing.

18. Sealing device according to claims 1 to 17, characterized in that the fastening device is not a part of the hollow sealing element, but a second part.