EP0523004A2 - Seal for a rotating part - Google Patents

Abstract

For sealing off a medium on rapidly rotating bodies (3) of large diameter from an enclosing housing (11) a packing ring (8) is pressed by its peripheral surface (9) with a limited spring force against the housing (11) so that it cannot be displaced by the pressure of the medium to be sealed off, whilst by coming in direct contact with the lateral surfaces (13, 14) of a tightly dimensioned groove (7) enclosing it, it can be transversely displaced into a centred position inside the groove (7) so that friction losses on the seal and wear of the latter are prevented and in addition minimum sealing gaps (15, 16) achieved without loss of the medium to be sealed off. <IMAGE>

Description

The invention relates to a seal on a rotating body and a housing enclosing it, with a sealing ring enclosed in the rotating body or the housing, which rests with its inner or outer circumference on the rotating body or the housing, the space enclosing the sealing ring being wider is than the sealing ring, so that it is axially displaceable in the enclosing space and is held displaceably on the rotating body or the housing by static friction on its inner or outer peripheral surface.

A known seal of the type mentioned, the arrangement of which is shown schematically, for example, in FIG. 6 of DE-B-34 32 915 (US Pat. No. 4,714,417) on the outer rotor of a rotary lobe machine, has the disadvantage that its sealing ring is separated by the Pressure of the gaseous medium to be sealed is pressed against a sealing counter surface, so that friction losses occur and high wear occurs on the unlubricated or only minimally lubricated sealing surfaces. This disadvantage has an effect particularly on very fast rotating bodies with peripheral speeds of more than 20 m / sec. The sealing of very fast rotating bodies is therefore usually done contact-free using sealing gaps or labyrinth seals. However, the tight sealing gaps that produce a good seal require a high level of manufacturing complexity and their dimensions cannot be chosen small enough due to the thermal expansions and manufacturing tolerances to be taken into account, especially in the case of a large diameter on the circumference to be sealed, in order to obtain an adequate gap seal. The well-known labyrinth seals therefore have numerous sealing ribs arranged side by side in the axial direction and projecting into them. In order to be able to take into account axial movements of the rotating parts, also rotating, axially displaceable, split carbon rings are known for sealing gas turbines with respect to their oil-lubricated bearings. In order to prevent their rapid wear due to their pressure under the pressure of the medium to be sealed against a sealing counter surface, FR-A-2 602 847 proposed to largely compensate for the pressure of the medium to be sealed on the sealing ring and also to build up a hydrodynamic pressure on both sides of the sealing ring so that it is pushed into a middle position and held there. This hydrodynamic pressure is achieved by a suitable, for example spiral surface profiling on the rapidly rotating surfaces, which enclose the sealing ring between them at a distance. However, the sealing effect of such a seal is incomplete in spite of its high construction effort, so that losses of compressed gas and lubricant are inevitable.

The invention has for its object to find a seal for rotating bodies that allows particularly tight sealing gaps without significant wear, that can be realized with little manufacturing effort, that can nevertheless be carried out advantageously for large diameters and that has a good effect in a small space, so that the efficiency of the machine having the seal is increased.

This object is achieved according to the invention in that the static friction force is greater than the resulting axial force of the pressure of the medium to be sealed acting on the side faces of the sealing ring, so that an annular gap space is present between these two side faces and the surfaces of the enclosing space opposite them and the sealing ring is flowed around in the manner of a labyrinth seal from the medium to be sealed, the sealing ring automatically opening one through brief mechanical contact with the surfaces of the enclosing space between these surfaces centered non-contact position.

The method for solving this problem is characterized in that the radial spring force acting on the sealing ring is determined such that the resulting axial force of static friction on the outer or inner circumference of the sealing ring is always greater than the pressure acting on the sealing ring in the axial direction medium to be sealed, but the sealing ring is axially displaceable to overcome the adhesive force when it comes into contact with a housing surface, so that the sealing takes place without contact in the manner of a labyrinth seal at sealing gaps between the sealing strip and the housing.

Based on the invention, it results that the sealing ring is automatically pushed into a centered ideal position between these adjacent surfaces by the relative rotation between it and the adjacent surfaces of the enclosing space by brief start-up with direct mechanical contact, which would not be achievable by measurement and precision assembly . The relatively strong static friction on the adhesive circumference of the sealing ring is overcome, while it cannot be overcome by the pressure of the medium to be sealed. The space enclosing the sealing ring can thus be dimensioned more narrowly than was previously possible, and a start-up resulting from the manufacturing tolerances and / or thermal expansions occurs only briefly as a result of the sealing ring evading, without the risk of seizing on the sealing ring or of continuing Wear is given. The seal can thus be called a self-adjusting or dynamic labyrinth seal, and the sealing ring accordingly forms a labyrinth element.

It goes without saying that, similar to a conventional labyrinth seal, a plurality of sealing rings can also follow one another in the axial direction, each of which is assigned an enclosing space. It also goes without saying that the part referred to as the housing can also rotate at a different rotational speed, because a seal according to the invention is general suitable for sealing between two bodies rotating relative to each other.

The sealing ring can be produced in the manner of a conventional piston ring made of cast iron, steel or other metallic or non-metallic materials without or with an overlap joint or also without a joint. As a sealing ring with a joint, it is preferably provided with a higher cross section in the radial direction and with means for pressure compensation between the two ring sides in order to achieve sufficient spring force. The sealing ring can also have a slight excess compared to the space surrounding it or the housing, i.e. be held by a slight press fit. The sealing ring can also enclose the rotating body with a preload which enables the displacement, if it can be mounted in this way, for example by means of a divided housing of the enclosing space.

Further preferred embodiments of the seal are defined in the dependent claims.

• Fig.1 einen Axialschnitt durch eine innenachsige Drehkolbenmaschine an sich bekannter Art,
• Fig.2 eine vergrösserte Querschnittsdarstellung einer erfindungsgemässen Abdichtung der Drehkolbenmaschine nach Fig.1, mit am Gehäuse gehaltenem Dichtring
• Fig.3 eine Seitenansicht eines Umfangsbereiches der Abdichtung nach Fig.2,
• Fig.4 eine vergrösserte querschnittsdarstellung einer Abdichtung mit am rotierenden Körper gehaltenem Dichtring,
• Fig.5 eine Seitenansicht eines Umfangsbereiches der Abdichtung nach Fig.4,
• Fig.6-9 Querschnittsdarstellungen weiterer Ausführungsformen erfindungsgemässer Abdichtungen und
• Fig.10,11; Fig.13-14; Fig.16-18: Querschnittsdarstellung und Darstellung eines zugehörigen Umfangsbereiches weiterer Ausführungsformen erfindungsgemässer Abdichtungen,
• wobei Fig.15 einen engbegrenzten Teil eines Dichtringes zeigt, zur Darstellung einer Ausführungsform einer Profilierung an einer Seitenfläche eines Dichtringes.

The invention is explained below with reference to exemplary embodiments shown in the drawings. The drawings are only schematic in that the cross-sectional representations of the sealing rings are shown without lateral boundary lines of the sealing ring. In the drawings:

• 1 shows an axial section through an inner-axis rotary lobe machine of a type known per se,
• 2 shows an enlarged cross-sectional view of a seal according to the invention of the rotary piston machine according to FIG. 1, with a sealing ring held on the housing
• 3 shows a side view of a peripheral region of the seal according to FIG. 2,
• 4 shows an enlarged cross-sectional view of a seal with sealing ring held on the rotating body,
• 5 shows a side view of a peripheral region of the seal according to FIG. 4,
• Fig. 6-9 cross-sectional representations of further embodiments of seals according to the invention and
• Fig. 10,11; Fig. 13-14; 16-18: cross-sectional representation and representation of an associated circumferential area of further embodiments of seals according to the invention,
• 15 shows a narrowly limited part of a sealing ring, to illustrate an embodiment of a profile on a side surface of a sealing ring.

1 is described in detail in the aforementioned DE-B-34 32 915 (US-A-4,714,417 or US-A-4,801,255), which is intended to be part of the present description. Due to the bearing of its inner rotor 1 and outer rotor 2 around fixed geometric axes, it is suitable for very high rotational speeds, so that 2 peripheral speeds of e.g. 20 to 50 m / sec occur. The invention realizes a non-contact sealing e.g. on the outer circumference of the side parts 3 and 4 of the outer rotor. The seals 5, 6 provided for this purpose have a sealing ring 8 enclosed in a groove 7 in the form of a groove 7 of these side parts 3, 4 of the outer rotor 2, which with its outer circumferential surface 9 lies firmly against the circular cylindrical inner surface 10 of the machine housing 11 with frictional engagement.

The lateral, radially directed, annular surfaces 13, 14 of the space 7 surrounding the sealing ring or other identically arranged ring surfaces forming a corresponding enclosing space 7 for a sealing ring 8 are spaced apart from each other, which is just sufficient to enable a contactless relative rotary movement when the sealing ring 8 is ideally centered and the wobble movements are aligned, so that correspondingly minimal gap spaces are available for the gap seal. This position of the sealing ring 8 could not be achieved by an exact assembly of the sealing ring 8, but rather is achieved automatically by starting on both sides against the enclosing groove surfaces 13, 14 at the start of the relative rotary movement, by the frictional engagement or the press fit between the surfaces 9, 10 on the circumference of the sealing ring is temporarily overcome by the corresponding mechanical forces.

In order to limit the differential pressure of the gas acting on the sealing ring 8, the ring surfaces 17, 18 delimiting the sealing gaps 15, 16 are preferably limited to a narrow area and on the remaining part of the sealing ring sides there are free spaces 20, 21 for pressure compensation between the two sealing ring sides.

In the exemplary embodiment according to FIGS. 2 to 5, the free spaces 20, 21 are formed by undercuts of the sealing ring sides forming a shoulder 19 on both sides. In the exemplary embodiment in FIG. 6, a free space 21 is provided only on one side and on the low-pressure side of the sealing ring 8.

Instead of an undercut forming a shoulder 19, free spaces 20 ′, 21 ′ can be formed according to FIG. 7 by inclined surfaces 22, 23 or conical surfaces on one or both sides of the sealing ring 8.

According to the embodiment according to FIG. 8, a circumferential groove 25 with a radially directed cross section is provided in the surface 24 held by static friction. This causes a reduction in the contact surface of the static friction, so that the surface pressure is increased. In addition, the formation of a lubricating film that changes the static friction force is made more difficult, which could reach the sealing ring (8), for example, from the bearing and gearwheel lubrication of the machine according to FIG. In this case, discharge openings preferably lead 26 out of the groove space to the low pressure side of the sealing ring (8) so that no pressure of gas or lubricant can build up in the groove space.

FIG. 9 shows an embodiment of the seal, in which a sealing ring 8 is used, which itself has no profiling of its side surfaces to form free spaces, because there free spaces 20˝, 21˝ are formed in the side surfaces 31, 32 of the enclosing space.

In the exemplary embodiment according to FIGS. 10 and 11, the sealing ring 8 has a wider cross-sectional area 31 that is laterally delimited by contact surfaces 29, 30, so that a contact on the narrow ring surfaces 17, 18 delimiting the sealing gap 15, 16 on the surfaces 13, 14 of the surrounding groove space 7 and thus its damage is prevented. In order to rule out that the contact surfaces 29, 30 contribute to the sealing and consequently the pressure of the medium can cause an uncontrolled displacement against a surface 13, 14 of the enclosing groove space, the two sides of the sealing ring 8 are through ducts 32, 33 and / or ducts 34 connected to each other.

Furthermore, wedge-shaped, sliding shoe-like elevations 35 can be provided on the contact surfaces 29, 30, as shown in FIG. 12, which support the formation of a sliding film on contact with the surfaces 13, 14 of the enclosing space 7 and thus the automatic centering of the sealing ring 8 in enclosing space 7 without significant wear or even an erosion, facilitate.

In the exemplary embodiment in FIGS. 13 to 15, the side surfaces 36, 37 of a sealing ring were subsequently provided with a circular tool 38 with radially directed grooves 39 of shallow depth, such as, for example, by means of a cup-shaped grinding wheel 38 indicated by the circular lines in FIG. 14 or by means of a Such milling tool can be produced. These grooves 39 enable pressure equalization, similar to, for example, the free spaces 20, 21 according to FIG. 2. Here too the Sealing in the manner of a labyrinth seal achieved by the tight play between the sealing ring 8 and the surrounding groove space 7. The avoidance of flat side surfaces of the sealing ring 8 in the narrowly dimensioned groove space 12 eliminates the risk of the sealing ring 8 seizing when it strikes against a side surface 13, 14 of the groove space 7.

16 to 18 show an embodiment in which an effect comparable to that of FIGS. 13 to 15 is achieved by slight bending deformations of the sealing ring 8, as shown by the exaggerated bends 40, 41, 42. Such a wave-shaped sealing ring 8 also brings about an improved sealing in the circumferential direction of the sealing ring 8.

As the illustrated examples illustrate, the sealing ring 8 can either with its outer circumferential surface 9 in accordance with FIGS. 2, 3 and 6 to 18, or with its inner circumferential surface 12 in accordance with FIG. 4, 5 on one of the bodies to be sealed against one another with static friction abut, the body to which the sealing ring 8 adheres preferably the stationary body, ie 1 is the machine housing 11, although it can also be provided as adhering to the rotating body. In the latter case, however, the centrifugal forces acting on the sealing ring 8 should be taken into account in order to ensure that the sealing ring 8 can shift into a centered position even at high rotational speeds. Furthermore, it is irrelevant to the function of the invention whether the sealing ring 8 encloses a rotating body or is enclosed by it and whether it adheres to it or is enclosed by it without contact forming the space 7.

It goes without saying that only a limited number of possible embodiments of a seal according to the invention could be shown in the drawings and that the shape of the sealing ring 8 and the associated enclosing space 7 permits numerous variants.

Claims (11)

Sealing on a rotating body and a housing enclosing it, with a sealing ring (8) enclosed in the rotating body (2) or the housing (11), the inner or outer circumference of which rests on the rotating body or the housing, the the sealing ring (8) enclosing space (7) is wider than the sealing ring (8), so that it is axially displaceable in the enclosing space (7) and by static friction on its inner or outer peripheral surface on the rotating body (2) or the Housing (11) is held displaceably, characterized in that the static friction force is greater than the resulting axial force of the pressure of the medium to be sealed acting on the side surfaces of the sealing ring (8), so that between these two side surfaces and the surfaces (13, 14) of the surrounding space (7) there is an annular gap (15, 16) and the sealing ring (8) according to A The medium to be sealed flows around a labyrinth seal, the sealing ring (8) automatically taking a centered, contact-free position between these surfaces (13, 14) due to brief mechanical contact with the surfaces (13, 14) of the enclosing space (7). Sealing according to claim 1, characterized in that on at least one of the side surfaces of the sealing ring (8) or of the space (7) enclosing it at a distance from the circumferential surface (9) of the sealing ring (8) bearing with static friction, a free space (20 , 21; 20˝, 21˝) is provided, which is formed by an undercut which, via a shoulder (19, 19˝), adjoins an annular sealing gap surface (17, 18) delimiting the gap (15, 16), the Width corresponds to this distance. Sealing according to claim 1, characterized in that the sides of the sealing ring encircling contact surfaces (29, 30) for centering the sealing ring (8) in the enclosing space (7) and for protecting the sealing gap surfaces (17, 18) (Fig. 15, 16) which laterally delimit a wider cross-sectional area (31) of the sealing ring (8). Seal according to one of claims 1 to 3, characterized in that the two ring sides opposite each other in the axial direction of the sealing ring (8) for pressure equalization through channels (34) extending transversely through the sealing ring (8) or through the sides of the sealing ring (8) radially extending recesses (32) are connected to one another (FIG. 10). Seal according to one of claims 3 or 4, characterized in that wedge-shaped elevations (35) are provided on the contact surfaces (29) for the formation of a sliding film. Seal according to claim 1, characterized in that the side surfaces (36,37) of the sealing ring (8) have radially directed, continuous grooves (39). Sealing according to claim 1, characterized in that the sealing ring (8) has successive bends (40, 41, 42) in the circumferential direction to form individual contact surfaces (Fig. 16-18). Seal according to one of claims 1 to 7, characterized in that the sealing ring (8) with at least one annular inner or outer circumferential surface rests on the rotating body or the housing, which is narrower than the sealing ring (8). Sealing according to claim 8, characterized in that the contact surface (24) of the sealing ring (8) for holding it is reduced by static friction through a circumferential groove (25). Seal according to claim 9, characterized in that the space of the groove (25) is connected to an outside of the sealing ring (8) by means of discharge openings (26). Method for sealing on a rotating body enclosed in a housing, in particular on the outer rotor (2) of an inner-axis rotary piston machine, by means of a sealing ring (8) surrounding the rotating body (2), the inner or outer circumference of which rests radially resiliently on one of these parts , characterized in that the radial spring force acting on the sealing ring (8) is determined such that the resulting axial force of static friction on the inner or outer circumference of the sealing ring is always greater than the pressure of the medium to be sealed acting on the sealing ring in the axial direction, however the sealing ring is axially displaceable on contact-forming start on a surface (13, 14) of the housing (7) enclosing it, so that the sealing in the manner of a labyrinth seal on sealing gaps (15, 16) between the sealing strip (8) and the housing (7 , 11) takes place.

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