FR2514455A1 - Bearing for rotary shaft - has magnetically applied friction bearing surfaces between rotating shaft and fixed crank case - Google Patents

Abstract

The rotary bearing has a roughened bush (B) with a friction surface (b) fixed to the turning shaft (13) by a sealed entraining O-ring (15). It also has a smooth section (A) with a friction surface (a) connected to the fixed crank case (12) via a sealed O-ring (14). The force attracting the two friction surfaces is provided by a cylindrical magnet (18) fixed to either the smooth or rough sections, and the magnet has only this function.

Description

MAGNETIC ROTATING JOINT
The invention relates to a magnetic rotating joint. It relates more precisely to a gasket without spring or bellows, comprising only a fixed part called glass and a rotating part called grain. The connections with the housing and with the shaft are directly ensured by rubber seals.

 it is known from French patent 1341412 to obtain the application force between the ice and the grain only by means of a magnet having a polished surface and then playing the role of ice.

Such an arrangement is shown diagrammatically in FIG. 1.

The rotary joint 1 is constituted by a magnet 2 made integral with the fixed casing 3 while a rubber joint 4 ensures the sliding and the sealing. This rotary joint 1 also comprises a support 5 made of magnetic material linked to the shaft 6 by means of a rubber seal 7 which provides both the drive and the seal between this shaft 6 and this support 5. The latter carries a ring 8 made of friction material, for example carbon. The force of attraction between the magnet 2 and the support 5 ensures the attraction and therefore the friction between the two friction surfaces (b) and (a) respectively of the grain B constituted by the carbon ring S and its support 5 (rotating parts) and glass (A) constituted by the magnet (2) (fixed part).

 A number of problems arise in the production of such rotating magnetic seals. It is notably not easy to machine a groove to receive a seal in a magnet, or to polish the face of this magnet intended to 'rub against the grain.

 The present invention aims to overcome these drawbacks and as a magnetic rotating joint have the advantages inherent in the use of a magnet, namely: the application of surfaces (a) and (b), one against 1 'other by a magnetic force and this without it being necessary neither to polish, nor to machine the magnet under complicated forms.

 It relates more precisely to a magnetic seal intended to ensure sealing between a rotating shaft and a fixed casing consisting on the one hand of a grain provided with a friction surface (b) and integral in movement with the rotating shaft by means of '' a seal and drive, on the other hand of a fixed glass provided with a uniform friction surface (a) and connected to the fixed casing, by means of a seal and slip, l 'application of the two friction surfaces against each other being provided by a magnetic force, characterized in that this magnetic force is provided by a magnet having a cylindrical shape inserted either in the ice or in the grain so that 'it only performs its function of applying the two surfaces (a) and (b) without itself presenting a friction surface and without serving as a seal support.

The invention will be better understood with the aid of the explanations which follow and of the appended figures among which:
Figure 1 shows a magnetic rotating joint of the known art.

 Figures 2 to 6 schematically show alternative embodiments of a magnetic rotary joint according to the present invention. The same elements have the same references in all these Figures 2 to 6.

As shown in Figure 2, such a rotating joint It ensures
Sealing between a fixed casing 12 and a rotating shaft 13. It consists of a fixed part A (glass) and a moving part B (grain) having two friction surfaces referenced respectively (a) and (b). The seal between the fixed part (A) and the casing 12 is ensured by means of a seal, called a seal 14 and a sliding seal which provides the sealing functions on the one hand and that of translation on the other. go.

 The moving part B (grain) is secured to the shaft 13 by means of a seal 15 which drives this moving part B as a function of the movement of the shaft 13 as well as the seal. This moving part comprises a support 16 made of magnetic material into which is inserted a ring 17 made of friction material such as carbon. According to the invention, the fixed part (A) consists of a cylindrical magnet 18 inserted in a ring 19 itself made of a material which has machining qualities such that it is easy to machine a groove 20 therefor. to receive the seal 14 and to polish the face (a) which must rub against the face (b) of the ring 17.

 This material can for example be stainless steel.

The magnet 18 then plays its function of attraction of the two friction surfaces (a) and (b) but does not need to undergo delicate machining operations to be implemented.

 In the case of FIG. 3, the magnet 18 is installed in the movable part B linked to the shaft 13 by means of the seal 15. The latter is inserted in a ring 21 made of material that is easy to machine as well for obtain a groove 23 than a polished surface (b).

It is for example, as before, stainless steel.

 On the other hand, the fixed part (A) consists of a support 22 made of magnetic material in which is machined a groove 20 intended to receive the sealing and sliding seal 14. This support 22 carries a ring 24 made of friction material ( carbon), one side (a) of which is polished and rubs, as has been said above, against the side (b) of the moving grain.

 The following figure (Figure 4) schematically represents another alternative embodiment of a magnetic rotary joint according to the invention. Here the moving part (B) connected to the shaft 13 by the seal 15 and drive is constituted by the magnet 18 and the ring 30 of friction material whose surface (b) is polished to rub against the polished face (a) of the fixed part (A). The latter comprises a ring 31 of magnetic material in one or more parts in which is machined the groove 20 intended to receive the seal and sliding 14. It further comprises a polished surface (a) having to rub against the surface ( b).

 In Figure 5 the elements are identical to those described by means of the previous figure but their arrangement is different. We thus find the ice (A) and the grain (3). The latter consists of a piece 40 of magnetic material in which the groove 23 is machined intended to receive the seal and drive 15.

 This part 40 is provided with a polished surface (b) intended to rub against the friction surface (a) of the ring 41 made of friction material in which the groove 20 is machined intended to receive the seal 14 and slip.

 The cylindrical magnet 18 secured to the ring 41 ensures the application of the two friction surfaces (a) and (b) one against the other.

 A final embodiment of a magnetic rotary joint according to the invention is shown diagrammatically in FIG. 6. The grain B is formed by the combination of a piece of magnetic material 51 carrying the seal 15 and drive and a ring 52 made of friction material, the polished face (b) of which rubs against the polished face (a) of a metal part 56 carrying the seal 14 for sealing and sliding. Solid with this metal part 56, the magnet 18 ensures the application of the two surfaces (a) and (b) one on the other.

 Examination of all these alternative embodiments of a magnetic rotary joint according to the invention shows a common characteristic, namely the arrangement of the magnet 18 in all the ice-grain arrangements, such that this ensures its application function one against the other of the two friction surfaces (a) and (b), whether these surfaces consist of a friction material, rubbing against a metal surface or by two metal surfaces rubbing one against each other. In no case does this magnet serve to hold any joint in place, whether it is the sealing and sliding seal 14 or the sealing and driving seal 15.

 In addition, this magnet does not participate in the actual friction, it only ensures the force of application of the friction surfaces. The difficulties of machining and polishing the magnets are thus avoided.

 Such magnetic rotating seals according to the invention are applicable in all applications where sealing problems arise at the level of the function of a rotating part and a fixed part.

Claims (6)

 1. Magnetic rotating joint intended to seal between a rotating shaft 13 and a fixed casing 12 consisting on the one hand of a grain B provided with a friction surface (b) and integral in movement with the rotating shaft (13) by means of a seal and drive (15), on the other hand of a fixed glass A provided with a friction surface (a) and connected to the fixed casing (12), by means of a sealing and sliding joint (14), the application of the two friction surfaces (a) and (b) against each other being ensured by a magnetic force, characterized in that this force magnetic is provided by a magnet 18 having a cylindrical shape inserted indifferently in the glass (A) or in the grain (B) so that it plays only its function of application of the two surfaces (a) and (b) without present itself with a friction surface and without serving as a seal support.  2. Magnetic rotating joint according to claim 1, characterized in that the glass (A) is constituted by a cylindrical magnet (18) inserted in a metal part (19) comprising on the one hand a groove (20) intended to receive the seal and slip 14, on the other hand a polished friction surface (a).  3. Magnetic rotating joint according to claim 1 characterized in that the grain (B) comprises a cylindrical magnet (18) integral with a metal part (21) comprising on the one hand a groove (23) intended to receive the joint d 'sealing and drive (15), on the other hand the friction surface (b).  4. magnetic rotating joint according to claim l, characterized in that the grain (B) comprises the cylindrical magnet 18 secured to a part 30 of friction material comprising on the one hand a groove (23) intended to receive the seal sealing and drive (15), on the other hand the friction surface (b).  5. Magnetic rotating joint according to claim 1, characterized in that the glass A comprises the cylindrical magnet 18 secured to a part 41 of friction material comprising on the one hand a groove 20 intended to receive the seal and sliding 14, on the other hand the friction surface (a).  6. magnetic rotating joint according to claim 1, characterized in that the glass A comprises the cylindrical magnet 18 secured to a metal part 56 comprising on the one hand a groove 20 intended to receive the seal and sliding 14 , on the other hand a friction surface (a).