DE2260080C3 - Plain bearings with magnetizable lubricant - Google Patents

Description

a) are designed as pole shoes that are connected to the magnet at the front,

b) extend radially so far inward that they the rotating part with only a small encompass radial gap, and

c) consist of bimetal and the radially inner edge areas are from a certain temperature Apply a seal against the collars (76, 78) of the inner bearing part.

2. Plain bearing according to claim 1, characterized in that clamping screws (84, 86) are provided which apply an adjustable pressure to the disks (232, 234).

The invention relates to a plain bearing for operation with a magnetizable lubricant, the lubricant by the action of an annular magnet mounted in the outer part is held within the bearing axially delimiting annular discs.

From US-PS 34 39 961 a combined axial and radial plain bearing in the form of a hydrodynamic Bifluid bearing known in which the lubricant for a first bearing part, namely the axial slide bearing Gas, especially air, is, while a second bearing part, namely the radial bearing, is magnetized by a Liquid, esp. Mercury, is lubricated in a magnetic field, which forms a seal, which prevents the air trapped in a high pressure chamber from the first bearing part in a escapes through the radial bearing from this separate low-pressure chamber. The use of two separate flowing media complicates the design and construction of bearings; Bifluid bearing of this type have the inherent disadvantage of gas-lubricated bearings that wear and tear of the too lubricating surface is unavoidable due to the friction when starting and stopping. Known Gas bearings are only effective at high speeds, so that at low operating speeds, that is Especially during the start-up and stopping process, bearing noise, spatial contact between the Surfaces that need to be kept separate and pollution due to the formation of metal dust in the bearing gap, due to friction, must be accepted.

In addition, there are bearing seals in which two flat rings made of bimetal are the end terminations or form seals for the interior, from GB-PS 10 26 007 and GB-PS 5 90 139 known. The deformation of the rings takes place with increasing temperature in the sense of an enlargement of the space bounded by these rings and vice versa.

The object of the invention is to design a plain bearing of the generic type so that it is under Use of a magnetizable liquid as the only lubricant can be operated properly can.

This is achieved according to the invention in that the annular disks are designed as pole shoes are, which are connected at the end with the magnet that the ring-shaped disks move radially so far

ίο inside that they extend the rotating part with only encompass a small radial gap, and that the annular discs are made of bimetal and the radially inner edge areas from a certain temperature against collars of the inner bearing part create a seal.

With the embodiment according to the invention it is achieved that using a magnetizable Liquid as the only lubricant the structural complications of using magnetizable Liquid as a seal for another, in particular gaseous, lubricant is dispensed with. the Disadvantages that the known arrangements, e.g. B. adhere to gas-lubricated bearings, namely the rapid Destruction due to the bearing surface contact that occurs during operation at low speeds, for example during the run-up and run-out periods is unavoidable, and the resulting pollution as well the high starting power are thus switched off. It is also achieved with such a bearing that Changes in volume of the lubricant - caused by the effects of heat - are compensated; of Furthermore, such bearings represent self-contained bearings that do not require a supply of lubricant from the outside.

The invention is described below in conjunction with the drawing on the basis of two exemplary embodiments explained. The figures show

F i g. 1 shows an embodiment of a slide bearing according to the invention in a partial sectional view, and

"0 FIG. 2 shows another on a reduced scale Embodiment of a plain bearing in a partial sectional view.

Fig. 1 shows a combined radial-axial plain bearing

with a bearing part 62 which is fastened on a shaft 64. The rotating bearing part 62 has a central bearing part 66 which is formed between end parts 68 and 70 of the bearing part 62. Pressure plates 72 and 74 are mounted in a corresponding manner on the end portions 68 and 70 and are in the axial direction of the middle supporting part 66 of the bearing part 62 offset. The pressure plates 72 and 74 therefore run with the Bearing part 62 um. Two end flanges 76 and 78 mate with end portions 68 and 70 attached to one another so that the flanges also rotate with the bearing part 62. The so far The components mentioned form part of the rotor of the bearing arrangement according to FIG. 1.

The bearing arrangement according to FIG. 1 has a cylindrical support assembly 80 which is provided with a housing can be attached or form part of this housing. A magnet 82 is within the Support assembly 80 is arranged and held there by two tightened clamping screws 84 and 86, the are in engagement with the support assembly. Each of the clamp screws 84 and 86 hold one of two

f> ⁵ annular disks holding pole pieces 88 and 90 in direct contact with magnet 82 and being attached to it. The pole pieces 88 and 90, which extend inward in the radial direction, produce a

Path for the magnetic field that is built up by the magnet 82 and cause a concentration of the Magnetic flux at and across corresponding columns 92 and 94, so that a magnetic circuit is created because the Bearing part 62 is made of magnetic material

As in Fig. 1, there is further provided a stationary, central stabilizing element% which has the shape of a hollow cylinder made of non-magnetic material; The outer cylindrical surface is attached to the inner cylindrical surface of the magnet 82 The stabilizing element % 6 protrudes into the space that is defined by the central, supporting part 66 and each of the two pressure plates 72 and 74 The magnetic components 82 and 88, 90 together with the stabilizing element 96 constitute the stator of the bearing arrangement according to FIG. 1 represents.

Stator and rotor of the bearing arrangement according to FIG. 1 are through a continuous, meander-shaped Gap separated because they are held at a desired distance by a magnetizable liquid 98 which fills the gap practically completely, which is only open along the gaps 92 and 94. the magnetizable fluid 98 is the only lubricant present.

As can be seen from the representation according to FIG. 1 results, the bearing arrangement can be viewed as a combination of a plain bearing and a double-acting thrust bearing. The plain bearing is formed by the central, supporting part 66 and the opposing inner surface 97 of the central stabilizing element 96. When a radial load is applied to the walls 64, the bearing becomes eccentric so that the liquid diameter in the bearing gap 99 between the bearing part 66 and the inner surface 97 of the central stabilizing element 96 changes. The viscous resistance that the moving, load-bearing part 66 exerts on the liquid 98 drives the liquid within the bearing gap 99 and builds up a hydrodynamic pressure which counteracts the radial load applied to the shaft 64

However, hydrodynamic plain bearings, which are bearings lubricated with the aid of lubricants under pressure, are unstable. This instability can be avoided in that grooves 102 are cut in the surface of the supporting part 66, which have the effect that the liquid pressure distribution is evened out. When the grooves 102 have a spiral shape, as shown in FIG. 1, whereby a sense of rotation is assumed in the direction of the arrow, then they press the liquid 98 against the center plane of the bearing, ie against the center of the intermediate load-bearing part 66. This effect also prevents the bearing assembly from leaking at the seals along the gaps 92 and 94 by decreasing the liquid pressure along the gaps 92 and 94 by decreasing the liquid pressure in the zones in the vicinity of the gaps 92 and 94.

The double-acting pressure-absorbing ability of the bearing arrangement according to FIG. 1 results from the Presence of the pressure plates 72 and 74, their inwardly oriented surfaces near the End faces 73 and 75 of the central stabilizing element 96 lie.

Under an axial, i. H. Pressure load, the rotor of the bearing assembly is displaced in the axial direction, so that the distance on one side of the bearing between one of the pressure plates, either 72 or 74, and the adjacent end surface 73 or 75 of the stabilizing element 96 is smaller, while the distance on the other end increases This causes the end with the reduced distance to become more effective as a pump and generates a pressure increase while the pressure at the end with the greater distance decreases steady state is obtained when the difference between the pressures on one or

ίο the other end generated force equal and opposite the applied load becomes.

The flow channels, such as the flow channel 106, may be provided between the end surfaces 73 and 75 of the stabilizing element 96 to prevent load support pressures (from an axially applied load) from pushing the liquid out through the magnetic seal at one of the gaps 92 and 94. The channels also act to stabilize the bearing in the axial direction by preventing pressure differences that cause instability. A plurality of such flow channels 106 are expediently provided, which are arranged at the same distance from one another around the circumference of the stabilizing element 96; The number and size of these channels depend on the working conditions under which the bearing arrangement is to be operated. A leak-proof magnetic seal is formed along each of the gaps 92 and 94
Each of the two pole pieces 232 and 234 consists of strip-shaped bimetal material that changes its configuration as a function of temperature; as a result, the bimetal pole pieces 232 and 234 compensate for the expansion and contraction of the magnetizable liquid 98 over a wide temperature range. This means that the radially inwardly directed surfaces of the bimetallic pole pieces 232 and 234, which have the configuration of bimetallic shims, are deflected outwards against the expediently non-magnetic flanges 76 and 78 with increasing temperature, so that the change in volume of the channels and Gaps that accommodate the magnetizable liquid corresponds to the change in liquid volume caused by thermal expansion. Conversely, the bimetallic pole pieces 232 and 234 are deflected inward, ie away from the flanges 76 and 78, as the temperature decreases, in order to compensate for reductions in the volume of liquid. The extent of the temperature-related deflection of the bimetallic pole pieces 232 and 234 can be controlled within certain limits by a correspondingly selected setting of the pressure that is given to the corresponding pole pieces via the clamping screws 84 and 86, and / or by initial selection of the thickness or the material of the bimetallic pole pieces 232 and 234.

As mentioned above, such a bearing arrangement can be exposed to high temperatures, z. B. during a high vacuum bakeout treatment,

ie degassing prior to the actual use of the bearing, which would lead to the magnetizable liquid 98 boiling off. In order to prevent such a boil off, the flanges 76 and 78 serve as limit stops for the outward expansion of the bimetallic pole pieces 232 and 234 with increasing temperature. The resulting sealing of metal against metal largely prevents a loss of magnetizable liquid

5 6

speed during degassing. Flow concentration devices, but also as

In Fig. 2 has the plain bearing arrangement similar to the volume compensation devices similar to those in

FIG. 1 shows two flanges 122 and 124 made of a non-magnetic bond with the bearing arrangement according to FIG. 1. Des

shem material. Here, too, the pole pieces 236 and the pole pieces 236 and 238 produce the others

238 bimetallic annular discs. The bimetal) - ^r> prescribed sealing of metal with flanges

See pole pieces 236 and 238 not only act as 122 and 124, which act as stops.

1 sheet of drawings

Claims (1)

Patent claims: 1. Plain bearings for operation with a magnetizable lubricant, the lubricant by the action of an annular magnet placed in the outer part inside the bearing axially limiting annular discs is held, characterized in that the annular discs (232,234)