DE20109891U1 - Ring seal - Google Patents

Description

A 56 219 f Applicant: ElringKlinger AG

June 13, 2001

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RING SEAL

The present invention relates to an annular seal for sealing an intermediate space between a first body and a second body, wherein the first body and the second body are rotatable and/or displaceable relative to one another and the annular seal comprises a sealing element in the form of an open ring with an overlapping joint, which has a first sealing surface for abutting against a contact surface of the first body and a second sealing surface for abutting against a contact surface of the second body.

Such ring seals are known from the state of the art.

However, the known ring seals, which comprise a sealing element in the form of an open ring with an overlapping joint, only have a one-sided sealing effect; that is, the ring seal only reliably seals the gap if the pressure of the medium to be sealed (for example air or a liquid) on the side facing away from the first sealing surface and the second sealing surface of the sealing element is greater than the media pressure acting on the first sealing surface and on the second sealing surface, because only then is the total force acting on the sealing element from the medium to be sealed directed in such a way that the first sealing surface is pressed against the contact surface of the first body and the second sealing surface is pressed against the contact surface of the second body.

However, if the media pressure fluctuates in such a way that temporarily or locally the pressure acting on the first sealing surface and the

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If the media pressure acting on the second sealing surface of the sealing element is greater than the media pressure acting on the side of the sealing element facing away from the first sealing surface and the second sealing surface, the first sealing surface and the second sealing surface are lifted off their respective contact surfaces and the ring seal cannot function properly. A particularly large leakage can occur in the area of the overlapped joint.

The present invention is therefore based on the object of creating a ring seal of the type mentioned at the outset, in which a perfect fit of the first sealing surface on the contact surface of the first body and the second sealing surface on the contact surface of the second body is always ensured, even if the media pressure acting on the sealing element fluctuates depending on time or depending on location.

This object is achieved according to the invention in a ring seal with the features of the preamble of claim 1 in that the ring seal comprises a prestressing element which prestresses the sealing element in the assembled state of the ring seal against the first body and against the second body such that the first sealing surface rests on the contact surface of the first body and the second sealing surface rests on the contact surface of the second body.

Since, due to the effect of the pre-tensioning element, the first sealing surface always rests against the contact surface of the first body and the second sealing surface always rests against the contact surface of the second body, the sealing element is always in the

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correct position to reliably seal the gap between the first body and the second body.

The leakage in the region of the overlapped joint of the sealing element of the ring seal according to the invention is only slight, since the axial and radial forces exerted by the prestressing element on the sealing element also press the overlapping end regions of the sealing element against each other.

The ring seal according to the invention can also be used in particular when the difference between the media pressures on both sides of the sealing element varies along the circumference of the ring seal or even changes sign, which means that at one point on the circumference of the ring seal the media pressure on the side of the sealing element facing away from the sealing surfaces is greater than the media pressure acting on the sealing surfaces, while at another point on the circumference the media pressure on the side of the sealing element facing away from the sealing surfaces is smaller than the media pressure acting on the sealing surfaces.

Since the sealing element of the ring seal according to the invention has the shape of an open ring with an overlapped joint, thermal expansion of the sealing element can also be compensated for by a greater overlap of the end regions of the sealing element without the outer radius of the sealing element increasing.

Since the outer radius of the sealing element does not increase substantially, the force with which the sealing surfaces are pressed against the contact surfaces remains the same even at a temperature

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temperature increase of the sealing element is essentially constant, so that the friction between the sealing element and a body moving relative to it also remains essentially constant and the sealing element can be moved relative to this body, i.e. rotated or displaced, without an increased force or an increased torque having to be applied due to the temperature increase.

An increase in the temperature of the sealing element can occur, particularly in the case of ring seals with a large diameter, due to the heat generated by the friction during the relative movement between the sealing element and the body moving relative to it. This heat generation is particularly great for seal diameters of more than approximately 50 cm, which is why the design of a ring seal according to the invention is particularly suitable for ring seals with a diameter of more than approximately 50 cm.

No further details have yet been provided regarding the type of prestressing element.

Thus, it can be provided that the prestressing element is designed as an element separate from the sealing element.

In a preferred embodiment of the ring seal according to the invention, it is provided that the prestressing element acts directly on the sealing element.

In particular, it can be provided that the prestressing element lies directly on the sealing element in order to transfer the required prestressing force to the sealing element.

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In order to be able to arrange the pre-tensioning element, which is designed as a separate element, on the sealing element in a simple manner and to be able to mount it together with the sealing element, it is advantageous if the sealing element has a receptacle for the pre-tensioning element.

This receptacle for the prestressing element is preferably arranged on the side of the sealing element facing away from the sealing surfaces and is designed as an annular recess.

As an alternative to designing the pre-tensioning element as a separate part from the sealing element, it can also be provided that the pre-tensioning element is designed as one piece with the sealing element. This makes assembly of the ring seal particularly simple and time-saving, since the ring seal only comprises a single part that needs to be assembled.

No further details have yet been provided on the manner in which the preload element generates the preload force.

For example, it can be provided that the prestressing element comprises an elastic spring element, for example a ring-shaped bent helical spring, which applies the prestress to the sealing element.

In a preferred embodiment of the ring seal according to the invention, it is provided that the prestressing element comprises a cavity which can be subjected to a higher pressure (compared to the media pressure in the vicinity of the prestressing element). The increased pressure in the cavity of the prestressing element acts directly or indirectly on the sealing element, so

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that the sealing element is preloaded against the contact surfaces of the first body and the second body.

Preferably, the cavity of the prestressing element has an elastically deformable wall.

In particular, the elastically deformable wall can be formed as a tube made of an elastically deformable material, preferably an elastomer.

The pressure in the cavity of the prestressing element can be varied in a simple manner if the cavity is provided with at least one connection for supplying a pressure fluid to the cavity.

In a preferred embodiment of the ring seal according to the invention, the cavity is essentially annular, whereby the prestressing force is distributed as evenly as possible over the circumference of the prestressing element.

It is particularly advantageous if the pressure prevailing in the cavity can be set to a predetermined value. In this way, the contact force with which the sealing surfaces of the sealing element are pressed against the contact surfaces of the first body and the second body can be influenced in a simple manner. In particular, this makes it possible to select a contact force which, on the one hand, ensures an adequate sealing function of the ring seal and, on the other hand, does not allow the frictional force to be overcome during a relative movement between the sealing element and the contact surfaces to become too great.

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It is particularly advantageous if the pressure prevailing in the cavity can be changed over time. This makes it possible to always set an optimal contact pressure for the sealing element, even if the media pressure on the side of the sealing element facing away from the sealing surfaces of the sealing element and/or the media pressure acting on the sealing surfaces of the sealing element varies over time.

Furthermore, it can be provided that the prestressing element comprises a plurality of cavities which can be subjected to different pressures in order to achieve different prestressing forces acting on the sealing element along the circumference of the prestressing element.

In order to ensure that the ring seal moves without slipping with the first body or with the second body during the relative movement between the first body and the second body, it can be provided that the ring seal comprises at least one positioning element for fixing the position of the ring seal relative to the first body or relative to the second body.

In particular, it can be provided that the ring seal comprises at least one positioning element which is designed as a substantially precisely fitting receptacle for a driving pin. The interaction of such a receptacle with a driving pin on the first body or on the second body ensures that the ring seal always moves with the body on which the driving pin is arranged during the relative movement.

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It is particularly advantageous if the ring seal comprises at least one positioning element which accommodates a driving pin in the radial direction of the ring seal with a substantially precise fit and in the circumferential direction of the ring seal with play. This ensures that even when using a positioning element, the overlap of the end areas of the sealing element of the ring seal is variable and thus thermal expansion of the sealing element when the temperature increases, for example due to friction between the sealing element and the body moving relative to it, can be compensated for without increasing the outer radius of the sealing element.

In principle, the positioning element can be arranged at any point on the ring seal, for example on the pre-tensioning element.

However, in a preferred embodiment of the ring seal according to the invention, it is provided that at least one positioning element is arranged on the first sealing surface or on the second sealing surface of the sealing element.

In principle, any material which has a sufficient sealing effect on the sealing surfaces and a sufficiently low friction during the relative movement between the sealing element and the first body or the second body can be considered as the material for the sealing element.

These requirements are particularly well met if the sealing element comprises polytetrafluoroethylene (PTFE), modified polytetrafluoroethylene, a polytetrafluoroethylene compound or a modified polytetrafluoroethylene compound.

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A "modified polytetrafluoroethylene" is a PTFE-like substance in which the molecular structure of the PTFE has been chemically modified by partially replacing the fluorine atoms of the PTFE with substituents.

Such a modified PTFE is known, for example, under the name TFM and can be obtained from the company Dyneon.

A "polytetrafluoroethylene compound" is a mixture of PTFE and at least one organic or inorganic filler. Such fillers include, in particular, glass fibers, carbon fibers, carbon, graphite, molybdenum disulfide, bronze or organic fillers, in particular high-temperature-resistant thermoplastics and thermosetting plastics.

To distinguish it from a PTFE compound, pure PTFE, i.e. PTFE that is not mixed with a filler, is also called "virginal" PTFE.

A "modified polytetrafluoroethylene compound" is understood to mean a mixture which comprises a modified polytetrafluoroethylene, for example TFM, and at least one organic or inorganic filler.

With regard to good sealing properties, a low coefficient of friction and low abrasion, a PTFE compound, which contains graphite as a filler in a proportion of up to 50% by weight, has proven to be particularly suitable as a material for the sealing element.

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A sealing element made of PTFE, modified PTFE, a PTFE compound or a modified PTFE compound can be easily manufactured from a disk or plate of this material by machining, for example by turning and/or milling.

Further features and advantages of the invention are the subject of the following description and drawings of embodiments.

The drawings show:

Fig. 1 is a schematic cross-section through a first embodiment of an annular seal intended for sealing a gap between a cylindrical rotor and a housing, the annular seal comprising a sealing element and a prestressing element formed separately from the sealing element;

Fig. 2 is a schematic longitudinal section through the ring seal of Fig. 1 parallel to the ring plane;

Fig. 3 is a schematic plan view from below of the sealing element of the ring seal from Figs. 1 and 2;

Fig. 4 is an enlarged view of area I of Fig. 3;

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Fig. 5 is a plan view of one of the ends of the sealing element designed as an open ring from Fig. 4, looking along the arrows 5 in Fig. 4;

Fig. 6 is a plan view of the other end of the sealing element designed as an open ring from Fig. 4, looking along the arrows 6 in Fig. 4;

Fig. 7 is a side view of the sealing element from Figs. 3 to 6;

Fig. 8 is a schematic cross-section through a second embodiment of an annular seal intended for sealing a gap between a cylindrical rotor and a housing, the annular seal comprising positioning elements for fixing the position of the annular seal relative to the rotor;

Fig. 9 is a schematic longitudinal section through the ring seal of Fig. 8, parallel to the ring plane;

Fig. 10 is a schematic plan view from below of the sealing element of the ring seal from Figs. 8 and 9;

Fig. 11 is an enlarged view of area II of Fig. 10;

Fig. 12 is a cross-section through the sealing element of Fig. 11 along the line 12-12 in Fig. 11;

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Fig. 13 is a cross-section through the sealing element of Fig. 11 along the line 13-13 in Fig. 11;

Fig. 14 is a schematic cross-section through a third embodiment of a ring seal intended for sealing a gap between a cylindrical rotor and a housing, wherein the ring seal comprises a prestressing element formed integrally with the sealing element; and

Fig. 15 is a schematic longitudinal section through the ring seal of Fig. 14, parallel to the ring plane.

Identical or functionally equivalent elements are designated by the same reference numerals in all figures.

A first embodiment of an annular seal shown in Figs. 1 to 7 and designated as a whole by 100 serves to seal an intermediate space between a substantially cylindrical rotor 102, which is rotatable about its cylinder axis 104, and a stationary housing 106 enclosing the rotor 102. The annular gap 108 remaining between the rotor 102 and the housing 106 forms the intermediate space to be sealed by the annular seal 100.

The rotor 102 comprises a cylindrical rotor upper part 110 and a substantially cylindrical rotor lower part 112, which is provided with an annular recess 116 with a rectangular cross-section on the outer edge of its upper side 114. The recess 116 forms a receptacle for the ring seal 100, which is closed at the top by the rotor upper part 110.

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which is fixed to the rotor lower part 112 by means of suitable fastening means, for example screwed thereto.

The ring seal 100 comprises an annular sealing element and a likewise annular prestressing element 120.

The structure of the sealing element 118 is described in more detail below with reference to Figs. 3 to 7. In these figures, the sealing element 118 is shown with the end regions pulled apart for reasons of clarity; when the sealing element is installed, these end regions overlap one another and form an overlapped joint.

As can best be seen from Fig. 3, the sealing element 118 has the shape of an open ring with a substantially rectangular cross-section, which is provided with a recess 126 with a substantially rectangular cross-section at a first end region 122 on the outer edge of its underside 124. The second end region 128 of the annular sealing element 118 is designed to be complementary to the first end region 122 and has a projection 130 extending in the circumferential direction of the sealing element 118, the cross-section of which essentially corresponds to the cross-section of the recess 126 in the first end region 122 and which rests on the bottom 132 of the recess 126 when the ring seal 100 is in the assembled state.

Furthermore, in the assembled state of the ring seal 100, the projection 130 lies with its radially inner side wall 134 on the side wall 136 of the recess 126 of the first end region

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so that the first end portion 122 and the second end portion 128 of the sealing element 118 overlap with each other.

As can be seen from Fig. 3, the radially inner side wall 134 of the projection 130 ends in a wall region 138 curved towards the inside of the sealing element. Likewise, the bottom 132 of the recess 126 ends in a downwardly curved wall region 139, which can best be seen from Fig. 7.

The underside 124 of the sealing element 118 including the underside of the projection 130 forms a first sealing surface 140 of the sealing element 118 directed perpendicular to the axis of rotation 104.

The outer surface of the sealing element 118 including the outside of the projection 130 forms a second sealing surface 142 of the sealing element 118 directed coaxially to the axis 104.

On the inner edge of the upper side 144 of the sealing element 118, an annular recess with a substantially rectangular cross-section is provided, which serves as a receptacle 146 for the prestressing element 120.

As can be seen from Figs. 1 and 2, the prestressing element 120 is designed as a ring-shaped closed tube with a wall 150 surrounding a cavity 152.

The hose 148 is, as can be seen from Fig. 2, provided with a connecting piece 154, via which the cavity

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152 of the preloading element 120 is connected to a compressed air supply (not shown).

As can be seen from Fig. 1, the hose 148 is inserted into the receptacle 146 of the sealing element 118 in the assembled state of the ring seal 100 in such a way that the wall 150 of the hose 148 rests against the bottom 156 and the side wall 158 of the receptacle 146 and is supported on the underside of the rotor upper part 110 and on the side wall 160 of the recess 116 in the rotor lower part 112.

In order to achieve a perfect seal by means of the ring seal 100, the internal pressure P ₁ in the cavity 152 of the prestressing element 120 is set such that the axial force exerted by the prestressing element 120 on the sealing element 118 (i.e. the force acting parallel to the axis 104), regardless of the difference between the pressures p ₀ in the space 162 above the rotor 102 and the pressure p _u in the space 164 below the rotor 102, is always sufficiently large to bring the first sealing surface 140 into contact with the underside of the recess 116 in the rotor lower part 112, which serves as the contact surface 166 of the rotor 102, and to hold the sealing element 118 in this axial position.

Furthermore, the internal pressure P ₁ in the cavity 152 of the prestressing element 120 is adjusted by means of the compressed air supply so that the radial force acting from the prestressing element 120 on the sealing element 118 (i.e. the force acting radially to the axis 104) is always sufficiently large, regardless of the difference between the pressures p ₀ and p _u , to bring the second sealing surface 142 of the sealing element 118 into contact with the inner wall of the housing 106, which serves as the contact surface 168 of the housing

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106 and to hold the sealing element 118 in this radial position.

Since, due to the effect of the preloading element 120, the first sealing surface 140 always rests against the contact surface 166 of the rotor 102 and the second sealing surface 142 always rests against the contact surface 168 of the housing 106, the sealing element 118 is always in the correct position to reliably seal the gap 108 between the rotor 102 and the housing 106.

The leakage in the area of the overlapped joint of the sealing element 118 is only slight, since the axial and radial forces exerted by the prestressing element 120 on the sealing element 118 also press the overlapping end regions 120 and 128 of the sealing element 118 against each other.

If the rotor 102 is rotated about the rotation axis 104 relative to the housing 106 by means of a rotary movement device (not shown), the ring seal 100 clamped between the rotor upper part 110 and the rotor lower part 112 rotates with the rotor 102, wherein the second sealing surface 142 of the sealing element 118 slides on the contact surface 168 of the housing 106.

Due to the friction between the second sealing surface 142 of the sealing element 118 and the contact surface 168 of the housing 106, the sealing element 118 heats up, which results in thermal expansion of the sealing element 118.

Since the sealing element 118 is designed as an open ring with an overlapping joint, this thermal expansion is compensated by a

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stronger overlap of the two end regions 122 and 128 without increasing the outer radius of the sealing element 118.

Since the outer radius of the sealing element 118 does not increase, the force with which the second sealing surface 142 is pressed against the contact surface 168 of the housing 106 remains essentially constant even if the temperature of the sealing element 118 increases, so that the friction between the second sealing surface 142 and the contact surface 168 of the housing 106 also remains essentially constant. The development of heat due to the friction between the second sealing surface 142 and the contact surface 168 therefore does not result in an increase in the power required to generate the rotary movement. The rotor 102 can therefore be rotated relative to the housing 106 by means of a rotary movement device with comparatively low power.

Since in the ring seal 100 according to the invention the axial and radial contact pressure of the sealing element 110 are adjusted by means of the pre-tensioning element 120 so that the sealing element 118 always rests against the contact surfaces 166, 168 of the rotor 102 or the housing 106 under a sufficiently high contact pressure, regardless of the pressures p _o and p _u , this ring seal 100 can also be used in particular when the difference between the pressures p _o and p _u varies along the circumference of the ring seal 100 or even changes sign, which means that at one point on the circumference the pressure p _o is greater than the pressure p _u , while at another point on the circumference the pressure p _o is less than the pressure p _u in the space 164 below the rotor 102.

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Such a situation can arise, for example, if one of the spaces adjacent to the rotor 102, for example the space 164 below the rotor, is divided into several sectors by partition walls (not shown) running radially to the axis of rotation 104 of the rotor, which are connected via different access openings 170a, 170b of the housing 106 (see Fig. 2) to different chambers in which different pressures prevail, so that the pressures in the successive sectors of the space 164 below the rotor along the circumference of the ring seal 100 are also different.

The space 162 above the rotor 102 can be undivided and thus be under a uniform pressure p _o .

Alternatively, it is also possible for the space 162 above the rotor 102 to be divided by partition walls into several subspaces with different pressures.

In each of the above-mentioned cases, the interior space p _t in the cavity 152 of the prestressing element 120 is adjusted such that the sealing element 118 with its sealing surfaces 140, 142 also comes to bear against the bearing surfaces 166 and 168 at those points on the circumference of the ring seal 100 at which the pressure p _u in the space 164 below the rotor 102 assumes its maximum value and at the same time the pressure p ₀ in the space 162 above the rotor 102 assumes its minimum value.

When setting the internal pressure P _1, it should be noted that the areas of the receptacle 146 of the sealing element 118, on which the pre-tensioning element 102 acts, are smaller than the areas of the sealing element 118, on which the pressures p _o and

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p _u act so that the pressure P ₁ in the cavity 152 of the prestressing element 120 must generally be selected to be greater than the pressure difference p _o - p _u in order to compensate for a high pressure p _u , which results in a reduction in the contact force of the sealing element 118, and to ensure correct alignment of the sealing element 118 and full contact of the sealing surfaces 140, 142 on the contact surfaces 166 and 168, respectively.

A second embodiment of a ring seal 100 shown in Figs. 8 to 13 differs from the first embodiment described above only in that the rotor lower part 112 is additionally provided with cylindrical driving pins 172 which protrude from the contact surface 166 of the rotor 102 in the axial direction against the sealing element 118 of the ring seal 100.

As can best be seen from Fig. 9, a first driver pin 172a of the rotor 102 is received in a substantially precisely fitting manner by a cylindrical driver blind hole 174 which is arranged in the first sealing surface 140 of the sealing element 118.

A second driving pin 172b of the rotor 102, which is arranged at an angular distance from the first driving pin 172a with respect to the axis 104, engages in a driving slot 176 arranged in the first sealing surface 140 of the sealing element 118, which receives the second driving pin 172b in a substantially precise fit in the radial direction and with play along the circumferential direction of the sealing element 118.

Due to the interaction of the first driver pin 172a with the driver blind hole 174, in the second embodiment

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The form of a ring seal 100 ensures that the sealing element 118 always rotates together with the rotor 102 when the rotor 102 rotates about the axis 104.

The play of the second driver pin 172b in the driver slot 176 ensures that the overlap of the end regions 122 and 128 of the sealing element 118 is variable even in the second embodiment of a ring seal 100 and thus a thermal expansion of the sealing element 118 in the event of an increase in temperature, for example due to the friction between the sealing element 118 and the housing 106, can be compensated without increasing the outer radius of the sealing element 118.

Otherwise, the second embodiment of a ring seal 100 corresponds in terms of structure and function to the first embodiment, to the above description of which reference is made in this respect.

A third embodiment of a ring seal 100 shown in Figs. 14 and 15 differs from the first embodiment described above only in that the prestressing element 120 is not formed as a separate part from the sealing element 118, but rather the prestressing element 120 is formed integrally with the sealing element 118.

As can best be seen from Fig. 14, in the third embodiment, a wall 178 made of an elastic material is attached on the one hand to the inner edge of the bottom 156 of the receptacle 146 and on the other hand to the lower edge of the side

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wall 158 of the receptacle 146 of the sealing element 118 is formed, for example vulcanized.

The elastic wall 178, together with the sealing element 118, encloses a cavity 152 which is connected to the compressed air supply (not shown) via a connecting piece 154.

The cavity 152, the elastic wall 178 and the areas of the sealing element 118 adjacent to the cavity 152 thus form the prestressing element 120 of the third embodiment of a ring seal 100. If the cavity 152 is subjected to an internal pressure P ₁ , the ring seal 100 is supported with the outside of the wall 178 on the rotor upper part 110 and the rotor lower part 112, and the reaction forces exerted by the rotor upper part 110 and the rotor lower part 112 press the first sealing surface 140 and the second sealing surface 142 of the sealing element 118 against the contact surface 166 of the rotor 102 and against the contact surface 168 of the housing 106, respectively, just as in the first and second embodiments of a ring seal 100.

The one-piece design of sealing element 118 and pre-tensioning element 120 in the third embodiment of a ring seal 100 results in a particularly simple and time-saving assembly of the ring seal 100, since only a single part has to be inserted into the recess 116 of the rotor lower part 112.

In all other respects, the third embodiment of a ring seal 100 corresponds in structure and function to the first embodiment.

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form of implementation, to the above description of which reference is made in this respect.

Of course, the third embodiment of a ring seal 100 described above can also be modified by providing driver pins 172 on the rotor 102 and a driver blind hole 174 and a driver elongated hole 176 on the sealing element 118, as in the second embodiment.

Claims (17)

1. Ring seal for sealing an intermediate space ( 108 ) between a first body ( 102 ) and a second body ( 106 ), wherein the first body ( 102 ) and the second body ( 106 ) are rotatable and/or displaceable relative to one another, comprising a sealing element ( 118 ) in the form of an open ring with an overlapping joint, which has a first sealing surface ( 140 ) for contact with a contact surface ( 166 ) of the first body ( 102 ) and a second sealing surface ( 142 ) for contact with a contact surface ( 168 ) of the second body ( 106 ), characterized in that the ring seal ( 100 ) comprises a prestressing element ( 120 ) which, in the assembled state of the ring seal ( 100 ), presses the sealing element ( 118 ) against the first body ( 102 ) and against the second body ( 106 ) such that the first sealing surface ( 140 ) rests against the contact surface ( 166 ) of the first body ( 102 ) and the second sealing surface ( 142 ) rests against the contact surface ( 168 ) of the second body ( 106 ). 2. Ring seal according to claim 1, characterized in that the prestressing element ( 120 ) is designed as a separate element from the sealing element ( 118 ). 3. Ring seal according to claim 2, characterized in that the prestressing element ( 120 ) acts directly on the sealing element ( 118 ). 4. Ring seal according to one of claims 2 or 3, characterized in that the sealing element ( 118 ) has a receptacle ( 146 ) for the prestressing element ( 120 ). 5. Ring seal according to claim 4, characterized in that the receptacle ( 146 ) for the prestressing element ( 120 ) is designed as an annular recess. 6. Ring seal according to claim 1, characterized in that the prestressing element ( 120 ) is formed integrally with the sealing element ( 118 ). 7. Ring seal according to one of claims 1 to 6, characterized in that the prestressing element ( 120 ) comprises a cavity ( 152 ) which can be subjected to an increased pressure. 8. Ring seal according to claim 7, characterized in that the cavity ( 152 ) has an elastically deformable wall ( 150 ; 178 ). 9. Ring seal according to one of claims 7 or 8, characterized in that the cavity ( 152 ) is provided with at least one connection ( 154 ) for supplying a pressure fluid to the cavity ( 152 ). 10. Ring seal according to one of claims 7 to 9, characterized in that the cavity ( 152 ) is substantially annular. 11. Ring seal according to one of claims 7 to 10, characterized in that the pressure prevailing in the cavity ( 152 ) is adjustable to a predetermined value (p1). 12. Ring seal according to claim 11, characterized in that the pressure prevailing in the cavity ( 152 ) is variable over time. 13. Ring seal according to one of claims 1 to 12, characterized in that the ring seal ( 100 ) comprises at least one positioning element for fixing the position of the ring seal ( 100 ) relative to the first body ( 102 ) or relative to the second body ( 106 ). 14. Ring seal according to claim 13, characterized in that the ring seal ( 100 ) comprises at least one positioning element ( 174 ) which is designed as a substantially precisely fitting receptacle for a driving pin ( 172 ). 15. Ring seal according to one of claims 13 or 14, characterized in that the ring seal ( 100 ) comprises at least one positioning element ( 176 ) which receives a driver pin ( 172 ) in the radial direction of the ring seal ( 100 ) with a substantially precise fit and in the circumferential direction of the ring seal ( 100 ) with play. 16. Ring seal according to one of claims 13 to 15, characterized in that at least one positioning element ( 174 , 176 ) is arranged on the first sealing surface ( 140 ) or on the second sealing surface ( 142 ). 17. Ring seal according to one of claims 1 to 16, characterized in that the sealing element ( 118 ) comprises polytetrafluoroethylene, modified polytetrafluoroethylene, a polytetrafluoroethylene compound or a modified polytetrafluoroethylene compound.