CZ2007781A3 - System for sealing dynamic connection of two sequential parts with through hole - Google Patents

Abstract

The assembly is formed by a shaped sealing membrane (1) which is in its central region firmly connected to the sealing sleeve (2) and on the outer periphery the sealing membrane (1) is fixedly connected to the static part (3), wherein the sealing sleeve (2) in the axial direction, it is permanently supported on the whole dynamic parts (4) by means of a planar sealing surface (5). Preferably, a spring (6) is provided between the sealing sleeve (2) and the static part (3), which in the axial direction is supported on the rear sealing sleeve (2) and on the recess in the static part (3). The sealing membrane (1) can be fixedly connected to the static part (3) by means of a fastening nut (7) with a washer (8) and an inserted external static seal (9), with the sealing sleeve (2) then firmly connected to the housing nut (10) with an internal static seal (11). The sealing membrane (1) can be, for example, rubber, composite, plastic, metal. The sealing sleeve (2) is mostly metal, plastic or ceramic. It may be provided with lubricating and / or cooling channels, relief recesses and / or fins.

Description

System for sealing the dynamic connection of two interconnected parts with a through cavity

Technical field

The invention relates to a system for sealing a dynamic connection of two components, each having at least one through cavity, the components adjoining each other and movable relative to each other. In practice, it is usually the pivotal movement of the components with through-flow fluid cavities, one of which is incorporated into the stator and the other into the rotor, or the parts of which one is fixed with one or more cavities facing each other and the other moves linearly between also with one or more cavities. Both cavities can be of different cross-section.

BACKGROUND OF THE INVENTION

The prior art designs for sealing fluid chambers or temporarily separating two compartments at different pressures are based on the use of sealing rings made of materials of appropriate elasticity and stiffness, strung with bias between the fluid inlet opening and the fluid supply core - a radial seal. In other cases, sealing rings located between the chamber face and the inlet pipe are used, which are pressed against the chamber face by a spring - an axial seal. In cases where both types of movement occur between the inlet and the chamber, the seal has to be solved by a combined radial-axial seal.

The disadvantages of all these design solutions of the seals are in their limited use - pressure, temperature or movement dynamics of the sealing surfaces. In other words, these sealing rings or their assemblies are tailored to the application and largely lack greater versatility. Another disadvantage is also the sensitivity of these systems to the presence of impurities in the fluid on both sides of the seal, deteriorating the tightness and increasing wear of the sealing rings. By obtaining the necessary deformation characteristics - elasticity / stiffness - the choice of materials for these seals is largely limited, which then often fails to achieve, for example, the required resistance to abrasion, high temperatures or pressures, dynamic stresses, and in particular in more exposed applications.

SUMMARY OF THE INVENTION

These disadvantages and drawbacks of the prior art solutions for sealing fluid flow between two passage cavity components and relative motion, in particular sealing the fluid supply to the chambers, are largely eliminated by the dynamic coupling seal assembly.

Ί two interconnected cavity parts according to the invention. SUMMARY OF THE INVENTION The invention is characterized in that the assembly is formed by a shaped sealing membrane which is rigidly connected in its central region to the sealing sleeve and on the outer periphery the sealing membrane is rigidly connected to a static component. components through a planar sealing surface.

Preferably, a spring is positioned between the sealing sleeve and the static component, which in the axial direction bears against the rear face of the sealing housing and the recess in the static component.

The sealing diaphragm can be firmly connected to the static component by a sliding washer fastening nut and an external static seal inserted, and the sealing sleeve can be firmly connected to the sealing nut with the internal static seal inserted. The sealing membrane can be, for example, rubber, composite, plastic, metal.

The sealing sleeve is usually metal or plastic. The sealing sleeve may be provided with lubrication and / or cooling channels. The sealing bushing may be provided with a relief recess and / or deflecting ribs.

An advantage of the system for sealing the dynamic connection of two interconnected parts with a through cavity according to the invention is that the static part with the sealing membrane and the sealing sleeve forms a single sealing unit, yet dynamically adaptable at the sealing membrane location so that the outlet part of the assembly - sealing sleeve - there is no longer an apparent axial movement with respect to the dynamic component with which it is in continuous and continuous contact by means of a planar sealing surface. As a result, the gasket of two mutually movable parts is transformed into a gasket in a single planar sealing surface, which is metal, ceramic, plastic, but always perfectly straight and perfectly smooth. This implies another important advantage of the design of the sealing system according to the invention - the smoothness and hence the tightness is further increased during operation in contrast to conventional systems, where the reliability decreases with the wear of the sealing rings.

In addition, the seal assembly of the present invention is advantageous in view of the wide range of material choices for the sealing membrane and the sealing sleeve, which further extends the field of application to extreme temperature, pressure and dynamic conditions. It is therefore a highly versatile sealing system, applicable in a wide variety of applications.

BRIEF DESCRIPTION OF THE DRAWINGS

Examples of using a system for sealing the dynamic connection of two interconnected parts with a through cavity according to the invention are shown in the accompanying drawings, where:

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In · · · · ·

- Fig. 1 - Set of sealing sleeves and sealing membranes in the high-pressure hydraulic directional valve Fig. 2 - Sealing sleeve and sealing membrane for rotary coolant supply Fig. 3 - Sealing sleeve with sealing membrane for rotating orifice plate for high temperature fluids Fig. 4 - system of sealing bushes and sealing membranes in high-pressure shut-off valve fig. 5 - system of sealing bushings and sealing membranes in high-pressure hydraulic valve with flow control option fig. 6 (fig.6.1, fig.6.2, fig.6.3, fig.6.4, fig. .6.5) - shape solutions of the sealing sleeve.

Examples of technical solution

Example 1

As can be seen from FIG. 1, the assembly for sealing two mutually movable components is formed by a shaped sealing membrane 1 firmly connected on its inner circumference to the sealing sleeve 2 and on the outer circumference to the static component 3. The sealing membrane 1 is connected to the sealing sleeve 2. is provided via the internal static seal 11 by the sleeve nut 10. The connection of the sealing diaphragm 1 to the static component 3 is effected via an external static seal 9 by a fastening nut Z with a sliding washer 8. The sealing sleeve 2, with its face in the axial direction, rests permanently on the face of the dynamic component 4. 2, the spring 6 is supported in the axial direction.

This assembly is formed in triplicate between the static component 3 and the dynamic component 4, spaced above the first and second directional channels A and B and the inlet channel P on a pitch circle at 90 ° as shown in FIG. 1a. The dynamic component 4, on the face of which the faces of the sealing sleeves 2 are supported, is provided with a left interconnecting channel X and a right interconnecting channel Y, as shown in Figures 1b, 1c, 1d. The face of the dynamic component 4, like the faces of the sealing sleeves 2, is formed by planar surfaces that are perfectly straight and smooth. The left and right connection channels X and Y are arranged such that their inlet and outlet openings are in plan view on the same pitch circle as the two directional channels A, B, and the feed channel P. The dynamic component 4 is rotatable relative to the static component 3 around the axis of rotation in plan view coincides with the center of the pitch circle seen in FIG. 1c.

«4« ·; A * a a 4 * a a 4 a * a a 4 * a a 4 *

An exemplary embodiment is a metal sealing sleeve 2 with a metal sealing membrane in a high-pressure hydraulic directional valve. Figures 1b, 1e, 1f show the relative positions of the dynamic component 4 relative to the static component 3.

Giant. 1b shows the position of the dynamic component 4, where the openings of the left connecting channel X and the right connecting channel Y are not open against the sealing sleeves 2 and the high-pressure hydraulic directional valve is closed.

Giant. 1e shows the position of the dynamic component 4, where the left connecting channel X in the dynamic component 4 and the sealing sleeves 2 of the inlet channel P and the second directional channel B in the static component are openings against the sealing sleeve 2 of the first directional channel A and the waste channel R in the static component 3 3 the openings of the right connection channel Y in the dynamic component 4. The central channel Z then has openings in contact with the planar surface of the static component 4, one of them in the central region, the other near the waste channel R of the static component 3. Directional duct B and drain R are connected to the first directional duct A. The high-pressure hydraulic directional valve is set to the flow position in direction B.

Giant. 1f shows the position of the dynamic component 4, with openings of the left connecting channel X in the dynamic component 4 opposite the sealing sleeves 2 of the first directional channel A and the inlet channel P and opposite the sealing sleeves 2 of the second directional channel B and the waste channel R The central channel Z then, as in the previous case, has holes in contact with the planar surface of the static component 4, one of them in the central region, the other near the waste channel R of the static part 3. and the drain port R is connected to the second direction channel B. The high-pressure hydraulic direction valve is set to the flow position in direction A.

This high-pressure hydraulic directional valve operates in such a way that in the middle position of the dynamic component 4 (see Fig. 1b), both the left connection channel X and the right connection channel Y are closed because all of their openings are out of reach the first and second directional ducts A, B of the static component 3, so that all openings in the static component 1 and the dynamic component 4 are only a planar surface without holes. This prevents the flow of fluid. The sealing bushings 2 are pressed by their planar sealing surfaces 5 towards the planar surface of the dynamic component 4 by the force of the springs 6 and the pressure forces of the fluid on the parts of the sealing membranes 1 resting on the static component 3 and the circumferences of the sealing bushings 2. the pressure of the fluid is greater.

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By rotating the dynamic component 4 clockwise (see Fig. 1 f), the first connection channel X and the right connection channel Y first extend over the inner edge of the sealing sleeves 2 of the first directional channel A and the second directional channel B, at the same time channel X begins to connect the first directional channel A to the supply channel P. The connection is completed by a 45 ° rotation, flowing in the first directional channel A and the fluid from the space between the sealing bushes 2 between the static component 3 and the dynamic component 4 is discharged into the drain R both directly and by means of the central channel Z. This allows switching even at high pressure without hydraulic shock and flow control. The sealing membrane 1 performs two functions - it seals the space between the static component 3 and the sealing sleeve 2 and at the same time allows the necessary movement of the sealing sleeve 2 so that its flat sealing surface 5 is in constant contact with the face of the dynamic component 4.

By rotating the dynamic component 4 from the basic position "closed" (Fig. 1b) in the opposite direction by 45 ° (see Fig. Le), then the supply channel P is connected analogously to the second direction channel B and thus the flow in the second direction channel B. channel A is connected to the waste channel R as well as the middle channel Z.

Example 2

The reinforced rubber sealing membrane 1 shown in FIG. 2 is firmly and tightly connected to the metal sealing sleeve 2 by vulcanization. The assembly thus formed is inserted into the annular recess of the static component 3 on the spring 6 and, via the sliding washer 8, the sealing membrane 1 is firmly and tightly anchored by the fastening nut 7 in the static component 3. The dynamic component 4 consists of a stepped tube on which the roller bearing is mounted 17, which is simultaneously fixed by its outer diameter in the static component 3. The planar sealing surface 5 of the sealing sleeve 2 rests on the planar surface of the pipe shoulder - the dynamic component 4. Both contact planar surfaces are perfectly flat and smooth.

This embodiment represents a sealing sleeve 2 with a sealing membrane 1 for rotary coolant supply. The described system operates in such a way that the planar sealing surface 5 of the sealing sleeve 2 is permanently pressed by the spring 6 to the planar surface of the dynamic component 4, so that the joint still seals independently of the pressure and movement of the system.

By applying pressure fluid to the through cavity of the static component 3 in the direction of the arrow, the pressure of the fluid on the lower annulus of the sealing sleeve 2 and the available (domed) bottom surface of the sealing diaphragm 1 creates a thrust that further pushes the sealing sleeve 2 towards. 4. This implies that in response to the pressure of the liquid the applied sealing force is exerted - the higher the pressure, the better the seal.

By rotating the dynamic component 4, the planar sealing surface 5 of the sealing sleeve 2 moves along the planar surface of the dynamic component 4 with which it is in continuous contact. Movement under permanent contact is in favor of the smoothness of the planar sealing surface 5, that is, the longer the system is running, the better the seal.

Example 3

The stainless steel sealing membrane 1 of FIG. 3 is firmly and tightly connected to the stainless steel sealing sleeve 2 by welding. This assembly is inserted into the recess of the opening in the static component 3 on the spring 6, wherein the sealing membrane 1 lying on the outer static seal 9 is firmly and tightly fastened through the sliding washer 8 to the static component 3. rest on the planar surface of the dynamic part

4. The dynamic component 4 is rotatably supported in the rolling element 17 mounted in the cover 18 relative to the static component 3. The shaft 25 of the dynamic component is connected to the closure 20 by a threaded connection and secured against rotation by a locking pin 23.

The sealing membrane 1 is at the same time firmly and tightly welded to the sealing sleeve 2, which is permanently supported on the closure 20. The sealing membrane 1 is pressed to the cover 18 which lies on the duster 22 by the fastening nut 7 described above. backrests 24.

The described embodiment shows a sealing sleeve 2 with a sealing membrane 1 for a rotating orifice plate for high temperature fluids. The assembly operates in a closed position (see Fig. 3a) in the dynamic component 4 against the through cavity in the sealing sleeve 2 with a flat surface without holes against which the flat sealing surface 5 of the sealing sleeve 2 is pressed by a spring 6. perfectly flat and smooth surfaces, the assembly of the dynamic part 4 (rotary orifice plate) and the sealing sleeve 2 perfectly seals.

By supplying the fluid to the inlet channel P, the sealing sleeve 2 is pressed against the dynamic member 4 - by the rotary orifice - in addition to the spring 6, by force from the fluid pressure exerted on the lower annulus of the sealing sleeve 2 and the available area of the sealing membrane 1 similar to Example 2.

By rotating the dynamic member 4 so that the opening in the rotary orifice member is above the through cavity in the sealing sleeve 2, the "open" position (see Fig. 3 b) fluid is discharged through the directional channel A. aperture - from all sides and the resulting force is captured in the rolling bearing 17. Fluid is

It now also enters the space of the second sealing sleeve 2 with the sealing membrane 1, located in the upper part of the lid. 18 below the closure 20. The flat sealing surface 5 of this sealing sleeve 2 is pressed against the closure 20 in addition to the spring force 6, also by the force of the fluid acting on the sealing sleeve 2 and the sealing membrane 1 analogously to Example 2. The supports 24 are supported on the cover 18 and thereby strengthen the bearing of the dynamic part 4 of the rotary orifice.

When rotating, the planar surface of the dynamic component 4 (rotary orifice plate) is in continuous contact with the planar sealing surface 5 of the seal housing 2, and both contact surfaces are constantly polished and cleaned. This further increases the sealing capability of the rotary orifice system.

Example 4

The non-metallic material sealing sleeve 2 is rigidly and tightly connected to the composite sealing membrane 1, and this assembly is inserted into the recess in the static component 3 of the spring 6, the sealing membrane 1 lying on the external static seal 9 and over the sliding washer 8 The planar sealing surface 5 of the sealing sleeve 2 rests on the planar surface of the dynamic component 4. The described assembly is located above the supply channel P and the first directional channel A. In the dynamic component 4, the connection channel X is formed. The dynamic component 4 is rotatably mounted from the inside in the lid 18 over a rolling bearing 17, sealed by an external static seal 9.

In the upper part of the lid 18 the assembly of the sealing membrane 1 with the sealing sleeve 2 is again inserted, firmly and tightly pressed against the external static seal 9 by the fastening nut 7. The spindle of the dynamic component 4 passes through the cavity of the sealing sleeve. 23. The planar sealing surface 5 of the sealing sleeve 2 is in contact with the planar surface of the closure 20, both surfaces being perfectly flat and smooth.

This embodiment illustrates the use of the seal housing 2 with the sealing membrane 1 for a high-pressure shut-off valve. Here again, the sealing sleeve 2 is pressed against the closure 20 in addition to the force of the spring 6 during operation also by the force from the fluid pressure acting on the available parts of the sealing sleeve 2 and the sealing membrane 1 as in the previous examples. The individual phases of the system operation are shown in Figs. 4a, 4b, 4c.

Giant. 4a shows a set of sealing sleeves 2 with sealing membranes L located in the static component 3 above the directional channel A and the supply channel P and the position of the dynamic component 4 "open" in plan view only indicates the position of the connecting channel X whose openings are opposite the openings of the supply channel P and The system operates in such a way that in the "open" position the fluid is fully allowed to flow from the supply channel P • · · upstream of the interconnection channel X to the directional channel A and further into the system. The planar sealing surfaces 5 of the sealing sleeves 2 are pressed against the planar surface of the dynamic component 4 by the spring force 6 and by the pressure of the fluid acting on the sealing sleeves 2 and the sealing membranes.

1. The contact surfaces between the sealing sleeves 2 and the dynamic component 4 are perfectly straight and smooth, therefore the joints seal perfectly. The specific pressure on the flat sealing surfaces 5 of the sealing sleeves as well as on the corresponding surfaces of the dynamic component 4 is small and thus the relatively small torque can be rotated by the dynamic component 4 even at high operating fluid pressure. This allows easy operation. The flexible sealing membranes 1 and the manner of mounting the sealing sleeves 2 in the static component 3 give the possibility to fully adapt to the relative movement of the contact surfaces so that the joints constantly ensure the necessary sealing effect. The tightness again increases with increasing fluid pressure. As the dynamic part 4 moves relative to the static part 3, the quality of the contact surfaces and thus the tightness further increase over time. The flow through the high pressure valve has a minimum hydraulic resistance.

Giant. Fig. 4b shows the same static component 3 as Fig. 4a, again indicating the dynamic component by means of the connection channel X in the "closed" position - the openings of the connection channel X only partially overlap with the openings of the feed channel P and the directional channel A. the fluid from the inlet channel P partially reaches the connection channel X and through it into the directional channel A, but also partly into the space between the static component 3 and the dynamic component 4. The axial force - in the axis of rotation of the dynamic component 4 - is absorbed by the roller bearing 17 and cover 18. The pressure chamber is sealed from above by the sealing sleeve assembly 2 with the sealing membrane 1, whereby the spindle of the dynamic component 4 with the screw 20 is screwed through the cavity of this sealing sleeve 2, to which the flat sealing surface 5 of the sealing sleeve 2 is springed. and fluid pressure in the syst emu. Again, the higher the pressure in the system, the better the seal is.

Giant. Fig. 4c shows again the same static component 3 as Fig. 4a, the dynamic component is then indicated by the interconnecting channel X in the closed position - the interconnecting channel X is completely out of the ports of the supply channel P and the directional channel A - centered between the two sealing bushes 2 - the connecting channel X thus interconnects only the space between the static component 3 and the dynamic component 4. The openings in the sealing sleeves 2 are covered by the planar surface of the dynamic component 4. The planar sealing surfaces 5 of the sealing housings 2 are pressed against the planar surface of the dynamic component 4 6, by force from the fluid pressure in the system. Thanks to the perfectly flat and smooth contact surfaces, all sealing bushings 2 seal perfectly.

* 'I *

Example 5

Both the sealing sleeve 2 and the sealing membrane 1 are made of stainless steel and are welded together tightly and tightly. The assemblies thus formed are inserted into recesses in the static component 3 formed above the first, second, third and fourth directional ducts A, B, C, D. Each of the sealing membranes 1 is pressed by a fastening nut 7 over a sliding washer 8 onto an external static seal 9 and the static component 3. The planar sealing surfaces 5 of the sealing bushings 2 are pressed against the planar surface of the dynamic component 4. In the dynamic component 4, a connection channel X is formed, the dynamic component 4 being rotatably supported in the rolling bearing 17 relative to the static component 3. The part 4 is sealed in the cover 18 by the sealing ring 26.

The described exemplary embodiment represents the use of the whole of the sealing sleeve 2 with the sealing diaphragm 6 for a high pressure hydraulic valve with flow control capability. The individual phases of operation of this valve are shown in Figures 5a, 5b, 5c.

Giant. 5 and illustrates a set of sealing sleeves 2 with sealing membranes 1 located in the static component 3 above the first to fourth directional ducts AB, C, D. The dynamic component 4 is only indicated by a position of the interconnecting channel X "closed" in plan view - against all openings in the sealing In the housing 2, the planar surface of the dynamic component 4 is free of apertures, thereby preventing fluid flow. Fluid inlet ducts are connected in parallel to the first and third directional ducts A and C, and fluid outlet ducts are connected in parallel to the second and fourth directional ducts B and D such that an adjustable hydraulic resistance R is engaged in the ducts of second duct. The sealing sleeves 2 are pressed against the planar surface of the dynamic component 4 by their spring force 6 as well as by the pressure of the fluid and their joints with their plane sealing surfaces 5, and the joints seal perfectly.

Giant. 5b illustrates the same static component 3 with the position of the dynamic component 4 "fast" where the connection channel X is through its holes exactly opposite the holes of the third and fourth directional channels C and D. By interconnecting the fluid flows through the valve with minimal hydraulic resistance, i.e. a large flow factor Kv. The perfectly flat and smooth planar sealing surfaces 5 of the sealing sleeves 2 and the planar surface of the dynamic component 4 guarantee perfect tightness of the joints. Tightness again increases with fluid pressure and system lifetime.

Giant. 5c illustrates the position of the dynamic component 4 "slowly", where the connection channel X is through its openings exactly opposite to the openings of the first and second directional channels A and B. By interconnecting them fluid flows through a valve with adjustable hydraulic resistance R. Flow factor Kv is significantly smaller. If it is not necessary to change the flow on the hydraulic resistance

Λ »* <

R, the same effect can also be achieved by reducing the flow diameters above the first and second directional channels A, B.

Example 6

This example shows the shape solutions of the sealing sleeve 2:

Giant. 6.1 shows the shape solutions of the transition of the planar sealing surface 5 into the cavity of the sealing sleeve 2 - fig. 6.1 a, b, d - depending on the used material of the sealing sleeve 2 and its production technology. Furthermore, here we can see the shape solutions of the relief of the sealing sleeve 2 on the outer diameter by means of the relief recess 14, which may be below and above the sealing membrane 1 - see Fig. 6.1 c, e.

Giant. 6.2 shows a solution of a planar sealing surface 5 with reinforcement combined with greater relief of the sealing sleeve 2 suitable for viscous and contaminated fluids.

Fig. 6.3 shows the shape of the inner cavity of the sealing sleeve 2 provided with deflecting ribs 15 if the fluid flow needs to be rectified.

Giant. 6.4 shows a sealing sleeve 2 for non-lubricating and high-temperature fluids.

In Fig. 6.4.a, the sealing sleeve 2 is provided in the upper part above the sealing membrane 1 with a flexible tube 27 for the supply of lubricating fluid and is also provided with lubricating channels 12.

In Fig. 6.4.b a second flexible tube 28 is provided for the coolant supply, and the coolant drain is also provided. In this case, cooling channels 13 are formed inside the sealing sleeve 2.

Giant. 6.5 It shows different designs of sealing sleeves with sealing membrane

Giant. 6. 5. and represents the connection of the sealing membrane 1 to the sealing sleeve 2 by means of the sleeve nut 10 via the internal static seal 11

Giant. 6. 5. b represents the connection of the steel sealing membrane 1 to the steel sealing sleeve 2 by welding.

Giant. 6. 5. c represents the bonding of the rubber sealing membrane 1 to the sealing sleeve 2 by curing.

· T 4 ··· · · · ·

6.5. E represents the bonding of the composite sealing membrane 1 to the steel sealing sleeve 2 by resin.

Industrial applicability

The dynamic joint seal assembly of two interconnected parts with a through cavity can be used wherever sufficient sealing of the transition between a static and a dynamic component between which fluid of a wide range of properties is passed, even under exposed pressure and temperature conditions. In practice, these are mainly directional valves, shut-off valves, control valves, rotary fluid inlets, rotary orifices and other similar systems.

Claims (11)

PATENT CLAIMS W - W System for sealing the dynamic connection of two interconnected parts with a through cavity, characterized in that it is formed by a shaped sealing membrane (1), which in its central region is firmly connected to the sealing sleeve (2) and on the outer periphery is a sealing the diaphragm (1) is rigidly connected to the static component (3), the sealing sleeve (2) being permanently supported in the axial direction on the face of the dynamic component (4) by means of a planar sealing surface (5). A system for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that a spring (6) is arranged between the sealing sleeve (2) and the static part (3) and is supported in the axial direction by the rear face of the gasket (2) and the recess in the static component (3). System for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the sealing diaphragm (1) is firmly connected to the static part (3) by a fixing nut (7) by a sliding washer (8) and an interposed an external static seal (9). System for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the sealing membrane (1) is firmly connected to the sealing sleeve (2) by a nut (10) of the sleeve with an inserted internal static seal (11). ). System for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the metal sealing membrane (1) is fixedly welded to the metal sealing sleeve (2). System for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the rubber sealing membrane (1) is firmly connected to the metal sealing sleeve (2) by vulcanization. • · * r System for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the composite sealing membrane (1) is firmly connected to the metal sealing sleeve (2) by resin. System for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the plastic sealing membrane (1) forms an integrated whole with the plastic sealing sleeve (2). System for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the metal sealing sleeve (2) is provided with at least one lubrication channel (12). A system for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the sealing sleeve (2) is provided with cooling channels (13). System for sealing the dynamic connection of two interconnected parts with a through cavity according to claim 1, characterized in that the sealing sleeve (2) is provided with a relief recess (14) and / or deflecting ribs (15).