DE10032721A1 - sealing system - Google Patents

Abstract

Sealing system for thermal engines or processing machines comprises a closed slip ring (15), a sealing ring (5) provided with an open gap (12), and a device (6) pressing the sealing ring with its surface (10) against the surface (14) of the slip ring. The slip ring is pressed with its slip surface (4) against the contact surface (3) of the body (2) to be sealed. The slip ring is guided along a vertical axis (1) passing through the center of gravity of the slip surface into a recess (18) in a fixed housing (13). The radial wall thickness of the sealing ring is not dependent on the outer diameter of the slip ring and is guided in the housing coaxially to the slip ring. The device presses the sealing ring against the slip ring with a constant or adjustable force independent of the gas pressure. Preferred Features: The slip ring has a surface which matches the contour of the contact surface of the body to be sealed. The contact surface is flat, spherical, or cylindrical.

Description

The invention relates to a sealing system, the one with gas ge filled space, with the gas pressure pulsating in that space (i.e. swelling or fluctuating) or constant against one moving or resting body, with part of its order catches or surface surrounds this gas space, seals and all The design disadvantages listed below already exist avoiding the sealing systems.

This sealing system can be used in heat engines (Piston engines, turbines) and working machines (compressors), de  a gas-filled room according to the above criteria to be sealed.

Sealing systems for the above-mentioned purposes are known, for example, in slide control systems for internal combustion engines and in the publications DE 37 20 082 A1 (Krüger), DE 37 20 084 A1 (Krüger), EP 0 624 718 A1 (Coates), FR-A-2 429 323 ( Honda), NSU-Dichtung, Automobiletechnische Zeitung, No. 6, 1954, page 146, Figure 7c, and DVL-WVW rotary valve control, Motortechnische Zeitschrift, No. 9, 1960, page 363.

These known sealing systems can be characterized by the following features describe:

Geometric properties

• - Rotationally symmetrical or mirror-symmetrical sliding seal systems me with frontal sliding surface (flat, spherical or cylindrical drisch concave).
• - Opposed to the sliding surface by the combustion pressure struck frontal surface, the size of the same amount or less than the sliding surface. Depending on the size ratio the sliding surface to the pressure face, the area is reduced pressure on the sliding surface, but this is always proportions tional to gas pressure.

Functional properties

• - The contact pressure of the seal on the slide is on the one hand by the pressure in the combustion chamber, which ge on the sliding surface opposite end face acts, causes, on the other hand through possibly existing springs, which the sealing system with a press constant force on the slide. Add both forces themselves and lead to fluctuations of the type depending on the gas pressure pressing force of the seal against the slide.
• - The Krüger sealing system is an exception (DE 37 20 082 A1), where the pressure of the sliding surface on the slide only  is caused by spring forces and thus one of the gas pressure independent but constant pressure is achieved.

The following table shows the functional disadvantages for each of the sealing systems mentioned above.

These disadvantages of sealing systems listed here have the following effects in motor operation:

• - The large height of the sealing system has great heat absorption surfaces and fissures of the combustion chamber (quench effect te) result.
• - The low axial elasticity of the sealing system prevents an adaptation of the sliding sealing surface to mechanical or thermal cal deformations of the slide tread during loading drive.
• - In terms of amount, it has the same sliding surface and pressure face give very high surface pressures on the sliding surface with the As a result of high friction and wear.
• - The proportional increase in the gas pressure generated area press solution on the mechanical seal caused by increasing gas pressure does not wishes high slide ring pressures on the slide with the consequence ho forth friction and wear.

In contrast, and especially in contrast to the NSU seal strikes the invention before a sealing system consisting of a closed  its sliding ring, an open-ended sealing ring and egg ner device that the sealing ring with its surface against the Flä che of the slide ring, causing the slide ring with its slide surface pressed against the tread of the body to be sealed is, the slide ring along a perpendicular through the surfaces center of gravity of the sliding surface in a recess in the fixed housing is guided, the sealing ring in its radial Wall thickness designed regardless of the outer diameter of the slide ring is and is guided coaxially to the slide ring in the housing, as well as the Device the sealing ring with a constant or in its amount freely adjustable force against the gas pressure Slide ring presses.

Advantageous further developments of the invention are in the Unteran Sayings and the description of the figures described and explained in more detail tert. In the figures, the invention is based on several embodiments examples are shown without being limited to this. It shows:

Fig. 1A is a section through a first embodiment of the sealing system according to the invention, in which the running surface of the sealed body ku gel-like or cylindrical,

Fig. 1B is an enlarged view of the area shown in FIG. 1A with A,

Of the area marked in Fig. 1B with B Fig. 1C is an enlarged representation,

Fig. 2A shows a section through a second embodiment of the sealing system according to the invention, in which the running surface of the sealed body is flat,

FIG. 2B an enlarged view of area marked in FIG. 2A with C,

Fig. 2C is an enlarged view of the area marked D in Fig. 2A and

Fig. 3, 4 and 5 sliding rings, which are rotationally symmetrical, elliptical or point-symmetrically.

The sealing system shown in FIGS. 1A to 1C consists of a sliding ring 15 , a sealing ring 5 and a device 6 which presses the sealing ring 5 against the sliding ring 15 with a constant or arbitrarily adjustable force which is independent of the gas pressure. This device 6 is shown here by way of example by a spring.

The slide ring 15 is a closed ring, which can be rotationally symmetrical, elliptical or arbitrarily point-symmetrical with respect to the axis 1 , which leads perpendicularly through the center of gravity of the sliding surface 4 , as illustrated in FIGS . 3 to 5. The contour of the end face 4 is adapted to the running surface 3 of the body 2 to be sealed.

The sealing ring 5 has a radial joint 12 and is thus an open ring. The sealing ring 5 bears with its end face 10 against the end face 14 of the slide ring and its inner surface 9 is flush with the inner surface 11 of the slide ring 15 .

The sealing system described so far works as follows:
The gas pressure acts on the end face 8 and the inner surface 9 of the sealing ring 5 , as a result of which it presses axially with its end face 10 against the end face 14 of the slide ring 15 and this is pressed with its end face 4 against the running surface 3 of the body 2 to be sealed. During a possible movement of the body 2 ver its tread 3 pushes only tangentially to the sliding surface 4 of the sliding ring 15th The pressure acting on the surface 9 spreads the sealing ring 5 radially, so that its outer circumferential surface 7 rests gas-tight on the housing 13 and the axial mobility of the sealing ring 5 is hindered. As a result, the transmission of the gas force exerted on the end face 8 of the sealing ring 5 to the slide ring 15 is reduced.

The force that results from the gas pressure acting on the end face 8 is superimposed on the force of the device 6 that also acts on the sealing ring 5 .

The axial displaceability of the sealing ring 5 and the sliding ring 12 in the recess 18 of the housing 13 ensures continuous contact with the surface 3 of the body 2 to be sealed and compensates for thermal expansion and wear on the running surfaces 3 and 4 .

The embodiment of FIGS. 2A, 2B and 2C is based on the embodiment of FIGS . 1A, 1B and 2B, with the difference that instead of the spherical or cylindrical tread 3 of the body 2 to be sealed, a flat tread 3 is provided. In their structure and operation in these figures, matching parts are designated for the sake of simplicity with the same reference numerals.

In Figs. 1A to 1C and 2A to 2C, a collar 19 is illustrated on the housing 13, which limits the axial displaceability of the sealing ring 5 in the direction away from the sealed body 2 direction. The fulcrum of the body 2 is designated by the reference number 20 .

Claims (10)

1. Sealing system, consisting of a closed sliding ring ( 15 ), a sealing ring ( 5 ) provided with an open joint ( 12 ) and a device ( 6 ) which seals the sealing ring ( 5 ) with its surface ( 10 ) against the surface ( 14 ) of the sliding ring ( 15 ) presses, whereby the sliding ring ( 15 ) with its sliding surface ( 4 ) against the running surface ( 3 ) of the body to be sealed ( 2 ) is pressed, the sliding ring ( 15 ) along a perpendicular through the surfaces center of gravity of the sliding surface ( 4 ) outgoing axis ( 1 ) is guided in a recess ( 18 ) in the fixed housing ( 13 ), the sealing ring ( 5 ) is designed in its radial wall thickness regardless of the outer diameter of the slide ring ( 15 ), and in the Ge housing ( 13th ) is guided coaxially to the slide ring ( 15 ), and the device ( 6 ) presses the sealing ring ( 5 ) with a force that is constant or freely adjustable, independent of the gas pressure, against the slide ring ( 15 ). 2. Sealing system according to claim 1, wherein the sliding ring ( 15 ) has an end face ( 4 ) which is adapted to the contour of the tread ( 3 ) of the body to be sealed ( 2 ), the tread ( 3 ) of the body to be sealed ( 2 ) even , spherical or cylindrical ( Fig. 1A, Fig. 2A). 3. Sealing system according to claim 1 or 2, wherein the sliding ring ( 15 ) with respect to the axis ( 1 ) is rotationally symmetrical ( Fig. 3), elliptical ( Fig. 4) or arbitrarily point symmetrical ( Fig. 5). 4. Sealing system according to one of claims 1 to 3, wherein the sliding ring ( 15 ) in the housing ( 13 ) is guided axially movable. 5. Sealing system according to one of claims 1 to 4, wherein the end face ( 4 ) of the sliding ring ( 15 ) has a material coating or a material insert with good sliding properties or the sliding ring ( 15 ) consists entirely of a material with good sliding properties. 6. Sealing system according to one of claims 1 to 5, wherein the sealing ring ( 5 ) in the housing ( 13 ) is axially movable. 7. Sealing system according to one of claims 1 to 6, wherein the end face ( 8 ) of the sealing ring ( 5 ) is dimensioned smaller than the circumferential sealing surface ( 7 ). 8. Sealing system according to one of claims 1 to 7, wherein the sealing ring ( 5 ) and / or the housing ( 13 ) has a shape (z. B. a collar ( 19 )) that the axial displacement of the sealing ring ( 5 ) in a direction from the body to be sealed ( 2 ) is limited. 9. Sealing system according to one of claims 1 to 8, wherein the force exerted by the device ( 6 ) on the sealing ring ( 5 ) constant, and also, in accordance with the changing pressure in the gas space to be sealed, fluctuates cyclically. 10. Sealing system according to one of claims 1 to 9, wherein the force exerted by the device ( 6 ) on the sealing ring ( 5 ) is generated mechanically and / or pneumatically and / or hydraulically and / or electromagnetically by a corresponding design of the device ( 6 ) ,