WO2015106773A1 - Charge air duct - Google Patents

Abstract

The invention relates to a sealing device which has a U-shaped cross-sectional profile (171) and comprises a base (172) and two limbs (173, 173') connected to said base (172), the base (172) spanning, in the circumferential direction (174), a base ring (150) to which two sealing lip rings (160, 160') are attached each spanned by a limb (173, 173') in the circumferential direction (174). Between said two limbs (173, 173') or between said two sealing lip rings (160, 160'), an expansion device (170) is arranged that exerts an expansion force onto said two limbs (173, 173') or two sealing lip rings (160, 160'). In the event of at least one radially-directed annular spring (340) of a groove-spring system (330, 340) being provided, extending in the circumferential direction (174), this can then advantageously be held in position, in the installation position, by means of said sealing device (140).

Description

 Turbo pipe

The invention relates to a sealing device with a U-shaped cross-sectional profile. Furthermore, the invention relates to a charge air line, which is arranged in the installed position between a charging device and a charge air cooler.

Charge air ducts, which are arranged between a charging device and a charge air cooler, can be designed, for example, as plug-in pipe connections. As a plug-in pipe connection formed, for example, the charging device side and intercooler side each have a sleeve may be formed, in which a plug-in tube is inserted. This has the advantage that such, designed as a plug connection charge air duct does not have to be produced accurately, but that with respect to the installation has a certain tolerance in the axial direction of the plug pipe. In addition, such a charge air line in the installation position of the plug pipe in the sleeves compensate for a tilting of the plug pipe to the sleeves to a certain extent. As a result, such charge air ducts can be produced more cheaply and, moreover, individual components of the charge air duct can be used equally for different embodiments, for example different lengths.

So are currently charge air ducts, which are designed as plug-in pipe connections, known in which the plug pipes are terminally equipped with O-rings, which can be arranged in a single groove or a double groove. The terminal plug pipe sections are formed in such a way to the sleeves that an axial displacement of the plug pipe is also possible, as a slight tilting of the plug pipe in the sleeve. Usually, O-rings made of fluororubber (FPM) are used. However, fluororubber has the disadvantage that even at temperatures above 200 ° C sticking of the O-rings with the

Muff or the pipe section can take place. To overcome this disadvantage, O-rings made of perfluorinated rubber (FFPM) can be used. Such a selection of materials is also suitable for temperatures higher than 200 ° C, but does not meet the requirements for a temperature range below -10 ° C, since in the low temperature range, the elasticity of the perfluorinated rubber O-rings decreases so much that the seal does not can be sufficiently ensured. In addition, O-rings of perfluorinated rubber are so expensive that this embodiment is difficult to represent economically. Furthermore, embodiments are still known in which silicone sleeves are used, so that a sufficient axial and radial flexibility of the charge air line is ensured in this case. But even with the use of silicone as a socket material, a tight operation for the desired very high temperatures can not be ensured.

Furthermore, even thin-walled tubes with an integrated compensator are conceivable, which are welded or flanged directly to the intercooler, the charging device or the manifold, wherein the compensator allows a certain axial, and possibly radial compensation. However, these charge air lines are susceptible to impact from the outside, so that protectors must be used during assembly, which must be dismantled before the test run, resulting in an increased cost.

In one aspect of the invention, a sealing device with a U-shaped cross-sectional profile, comprising a base and two legs connected to the base, is proposed, wherein the base spans a base ring in the circumferential direction, on the two each tightened by a leg in the circumferential direction sealing lip rings are connected, wherein between the two legs or between the two sealing lips rings a spreading device is arranged which exerts an expanding force on the legs or the two sealing lip rings, wherein at least one radially extending circumferentially annular spring of a tongue and groove system is provided, with which the sealing device can be held in position in position.

The advantage of using a sealing device with a U-shaped cross-sectional profile is the ability to use other, more temperature resistant materials than those usual with an O-ring. Such materials can have a poorer elastic behavior, which speaks against the use as an O-ring. Since the elasticity of the sealing device with a U-shaped cross-sectional profile is advantageously produced by the legs or sealing lip rings, wherein the elastic behavior can be changed or adjusted by a corresponding spreading device, the desired temperature-resistant materials can be used. In this case, simple sealing devices, which consist only of a base ring and sealing lip rings, have the disadvantage that they can be poorly held in position, since in principle an axial displacement of the sealing devices on / in the respective component, on / in which the sealing device is arranged is possible by the shape of the sealing device. Advantageously, in turn, by forming a circumferentially extending the radially directed annular spring a possible axial slippage can be prevented when the annular spring is part of a tongue and groove system, wherein the annular spring fixed by cooperation with the groove of the tongue and groove system, the sealing device in the installed position. In addition, can advantageously by using various spreading devices, such as a ring spring, a meander, a V-spring, a coil spring, a coil spring or the like with possibly round, rectangular, elliptical or trapezoidal cross section and additionally or alternatively with obliquely wound winding, each desired elasticity behavior of the sealing device are produced for the respective field of application. For example, an unfavorable elasticity of the leg material or of the sock material can be at least partially compensated by the spreading device.

Under a U-shaped cross-sectional profile is a perpendicular to the center line of the sealing device extending sectional profile of the sealing device to understand, wherein the base with the two legs in the shape of a "U". In this case, the legs may be straight or have a curved course. This is likewise conceivable for the base, so that a U-shaped cross-sectional profile can also be understood as meaning a profile which is circular or ellipsoid, the circle or ellipsoid being interrupted at one point. In this case, the base and the legs can have a different thickness to one another. A variation of the thickness within the base or a leg is also conceivable.

Under circumferential direction is to be understood that direction in which the base ring or the sealing lip rings in the installed position around the component to which the sealing device is attached run. In this case, the base ring or the sealing lip rings can be circular or ellipsoidal in the circumferential direction. But it is also conceivable that the sealing lip rings or the base ring in the circumferential direction are triangular, square, pentagonal or hexagonal or otherwise irregular.

The clamping lips formed by the legs in the circumferential direction essentially produce the sealing effect of the sealing device. Accordingly, one of the sealing lip rings bears against at least one component, so that a seal is produced between the components against which the sealing lip rings abut. Thus, for example, when tilting the components to each other a sufficiently high density can be ensured, in addition, a spreading device can be used between the two sealing lips, the Press apart the two sealing lip rings and press against the respective component. In the case of tilting of the components relative to each other, sufficient leak-tightness can thus be ensured even in the area at which the components continue to diverge due to the tilting. Under ring spring, which extends in the circumferential direction, the spring of a tongue and groove system is to be understood, which is formed on the sealing device. Accordingly, the term annular spring is a bulge, a step, a projection or a paragraph to understand that extends in the circumferential direction of the sealing device, so prevented in installation position by engaging the annular spring in a groove of the tongue and groove system slipping the sealing device or At least it can be reduced. In this case, the annular spring is radially directed, which in turn means that the annular spring has at least one extension in the radial direction. Here, radial direction is to be understood as meaning a direction perpendicular to the center line, starting from the center line. The annular spring has a substantially similar shape in the circumferential direction, as the base ring and the sealing lip rings, so that the annular spring does not necessarily have to be annular. In this case, the annular spring in the circumferential direction may also be formed simply or repeatedly interrupted. In the interruptions of the annular spring can turn ribs of the groove of the tongue and groove system intervene, so that slipping of the sealing device in the circumferential direction can be prevented. It can also be provided two, three four or more such annular springs,

Under the installation position is that position to understand in which the sealing device is installed relative to the components, such as the sleeve and the Einsteckrohrabschnitt, so that the annular spring is in operative connection with a tongue and groove system. Furthermore, at least two components of the sealing device can be formed integrally with one another: the base, at least one of the two legs, the base ring, at least one of the two sealing lip rings, at least one annular spring, the spreading device.

Here, an integral training is understood to mean a cohesive training, a training of the same material, possibly without joint seams or an enveloping training. Thus, for example, the base ring and at least one of the two sealing lip rings can be formed integrally with each other. Advantageously, the sealing device can thereby be produced with regard to these components in one method step, for example by casting, forming, pressing or the like. It is advantageous if base ring and the two sealing lip rings are formed integrally with each other. In this case, only the spreading device, which may consist of a different material, must be subsequently inserted into the sealing device in order to produce the desired elasticity. It is also conceivable that the base ring and the two sealing lip rings are made of the same material, in which material the spreading device, for example. A meandering V-spring, is embedded, so that the spreading device of the material of the base or the sealing lip rings wrapped is. Advantageously, by such an embodiment, the spreading device, which may be made of metal, for example, are protected from a corrosive environment. In addition, in this integral training variant, the sealing device is integrally formed, so that it can be used as an integral component.

In this case, the annular spring can be formed integrally with the base ring or one of the two sealing lip rings. But it is also conceivable that the annular spring is formed in the base ring or in the sealing lip rings embedded as a separate component.

But it is also conceivable that, for example, reinforcements are embedded in the base ring or that the base ring is made of a material deviating from the sealing lip rings, so that, for example, the base ring has a higher resistance to hot, corrosive and / or abrasive environments. In this way, the operating life of the sealing device can also be increased in the field of application of hot, corrosive and / or abrasive environments. In a corresponding installation position, the base ring can act as protection against these environments for the sealing lip rings, when the same is oriented to these environments. Furthermore, at least two components of the sealing device can be at least partially made

PTFE be formed: the base ring, at least one of the two sealing lip rings, the at least one annular spring.

By using the plastic polytetrafluoroethylene (PTFE) can advantageously be used a material that can ensure a sufficient sealing effect of the sealing device at a desired permanent temperature range of -60 to +270 ° C. For a short time, a sealing device made of PTFE can ensure a sufficient sealing effect even in a temperature range of up to + 300 ° C. In this case, this material is clearly superior to the previously mentioned fluororubber or perfluorinated rubber, since it over the Whole desired temperature range without the disadvantages described above can sealingly. In this case, the unfavorable elasticity of the plastic can advantageously be compensated or even exceeded by the use of the U-shaped cross-sectional profile and possibly the spreading device. Thus, for example, the base ring and both sealing lip rings may be made of PTFE and possibly even the annular spring. But it is also conceivable that the annular spring is made of a different material, is molded or in the material PTFE, for example. As a metallic annular spring, is embedded.

If polyimide (PI) is used as the material, then a sufficient sealing effect of the sealing device can be ensured permanently from -60 ° C. to + 300 ° C. and up to 480 ° C. in the short term. If polybenzimidazole (PBI) is used as the material, a sufficient sealing effect of the sealing device can be ensured permanently from -60 ° C to + 310 ° C and up to 500 ° C in the short term. Furthermore, at least one annular spring can have at least one arrangement selected from the following group:

 An arrangement on the base ring, an arrangement at the transition between the base ring and one of the two sealing lip rings, a central arrangement on one of the two sealing lip rings, a terminal arrangement on one of the two sealing lip rings, a radially outward arrangement, a radially inwardly directed arrangement ,

Advantageously, by the previously enumerated arrangements, the annular spring can be arranged such that it ensures a sufficiently stable positioning of the sealing device in the installed position in cooperation with the tongue and groove system. In particular, the arrangement of the annular spring on the base ring is particularly advantageous if the base ring in the axial direction has a sufficient material thickness. In this case, at least one annular spring may be directed radially inwards. As a result, a groove would be provided on the component, for example on the push-in tube section, onto which the sealing device is slipped. This has the consequence that the radially outwardly directed sealing lip must primarily ensure the sealing effect with tilting, so that if necessary, the radially outwardly directed sealing lip can be reinforced or formed with a desired elasticity profile. But it is also conceivable that at least one annular spring is directed radially outward. Accordingly, a groove would be provided on the component, for example on the inside of the sleeve, into which the sealing device is introduced. This has the consequence that the radially inwardly directed sealing lip primarily the sealing effect must ensure at tilt, so if necessary, the radially inwardly directed sealing lip can be reinforced or formed with a desired elasticity profile.

In a further aspect of the invention, the use of a sealing device, as described above, is proposed, wherein the sealing device is used for sealing a sliding seat of a charge air duct in plug-pipe construction.

Advantageously, by the use of a sealing device, as described above, a charge air duct in plug-tube design permanently sealed in a temperature range from -60 to +270 ° C and short term in a temperature range up to + 300 ° C when using PTFE as the material sealing device.

In a further aspect of the invention, a charge air line arranged in an installed position between a charging device and a charge air cooler is proposed, which has at least one sliding fit, comprising at least one sleeve and at least one insertion tube section inserted in the installation direction in the insertion direction, at least one for sealing the sliding seat Sealing device, in particular as described above, is arranged between the sleeve and the push-in pipe section. Advantageously, as described above, such a charge air line can be used in a temperature range of -60 to +270 ° C, without over the required duration of the charge air line away the sealing device fails appreciably. In addition, in this temperature range, a cheaper charge air duct in plug-pipe design can be used as a sealing device is used, even in these extreme temperature ranges of below -10 ° C and above 200 ° C, a sufficient seal even at peak temperatures of up to 300 ° C ensures when using PTFE as a material. This can be ensured on the one hand by, for example, U-shaped cross-sectional profiles of the sealing device and / or by the use of the PTFE material, wherein the unfavorable elasticity behavior of the PTFE material is compensated for or exceeded by the U-shaped cross-sectional profile and possibly the spreading device can be. When using other materials such as PI or PBI, temperature ranges as described above can be achieved. The term "charge air line" is understood to mean that line which is arranged in the installed position between one or more charging devices and one or more charge air coolers. In this case, at least one elbow, at least one flange and / or at least one plug-in tube may also be included in the term charge air duct. The plug-in tube can consist of several Teileinsteckrohren, which in turn are connected to each other, for example via a sliding seat. In this case, by charging device is meant, for example, an exhaust gas turbocharger and under an intercooler, for example, an air-cooled radiator, with which the charge air coming from the charging device is cooled before it is introduced into the combustion chamber.

Under a sliding seat is the Einstecksitz of two components to understand, with one component is inserted into the other. The region in which both components are arranged is referred to as a sliding seat when, to a certain extent, an axial displacement of the two components relative to one another is made possible. In addition, a sliding seat can also allow tilting of the two components relative to one another, so that the charge air duct is designed to be flexible in the region of the sliding seat not only partially in the axial direction but also partially in the radial direction. This has the advantage in the assembly of the charge air line that to a certain extent constructive tolerances can be absorbed by the charge air line. As a result, the charge air duct does not have to be manufactured precisely for the respective installation position.

A sleeve is understood to mean a section of the charge air line which has a widening, so that a push-in tube section can be inserted into the sleeve. In this case, a plug-in pipe section is to be understood, for example, as the section of a plug-in pipe which is inserted into the socket in the installed position so that the socket surrounds the plug-in pipe section. In this respect, the term plug-in tube section is to be understood that section of the plug-in tube which can be surrounded by the sleeve in the installed position, taking into account the axial and radial movement of the push-in tube section in the sliding seat.

In this case, the sleeve can be welded to a manifold or be formed integrally therewith. In addition, the sleeve may have a flange with which it can be connected to the charging device or to the intercooler or the manifold. Also, the sleeve may be formed as a casting, in particular of cast iron with lamellar graphite, which is optionally post-processed in the region of the sealing device. Furthermore, the sleeve may have at least one section selected from the following group, wherein the sections, if present, are listed in the plug-in direction: A first sleeve ring stage, comprising a first sleeve ring segment, a second sleeve ring stage, comprise a second sleeve Step transition and a second sleeve ring segment, a third sleeve ring stage comprising a third sleeve step transition and a third sleeve ring segment.

Advantageously, by means of such a ring-segment-like design of the sleeve in cooperation with the insertion tube section, a desired embodiment of the sliding seat can be produced, which permits both an axial displacement and a controlled tilting of the center lines of the sleeve and insertion tube section.

In this case, the sleeve ring segments may be formed such that the cross-sectional area of the sleeve ring segments is formed decreasing in the insertion direction to each other. The respective sleeve step transition can be formed as a plateau in the manner of a step as in a normal step, sloping off, or rounded at the edges. The sleeve ring segments may be cylindrical, a truncated cone or with a larger or smaller in the insertion direction cross-sectional area. In this case, the first sleeve ring stage can also have a first sleeve stage transition, wherein the first sleeve stage transition is formed terminal on the sleeve as an end face. In this case, the end face of the sleeve may be round, conical, plateau-like or the like.

Furthermore, the insertion tube section may comprise at least one section selected from the following group, wherein the sections, if present, are listed in the insertion direction: a first insertion tube annular step, comprising a first Einsteckrohr- ring segment and a first Einsteckrohr step transition, a second Einsteckrohr- Ring stage comprising a second Einsteckrohr-ring segment and a second Einsteckrohr- step transition, a third Einsteckrohr ring stage, comprising a third Einsteckrohr- ring segment.

Advantageously, by such a design of the Einsteckrohrabschnittes the charge air line can be formed cheaper, since a Einsteckrohr can be used, which has a Einsteckrohrabschnitt at least at one end, which can be conveniently formed by cold forming of the insert tube. By such a structural simplification of the Einsteckrohrabschnittes the charge air duct can be made structurally simpler and cheaper. In addition, the damage potential during transport or assembly due to the rigid geometry of both the Einsteckrohrabschnittes, the plug-in tube and the sleeve can be reduced. Due to the design with at least one sliding seat, which allows axial and radial displacement of the push-in tube section, a higher excitation frequency is also permissible without damage being possible by resonance excitation.

In this case, a Einsteckrohr-ring segment has a cylindrical or frustoconical design and is understood by a Einsteckrohr step transition, a plateau-like or rising or plugging in the direction step or transition between two Einsteckrohr- ring segments.

In this case, the respective cross-sectional area of the Einsteckrohr ring segments may be formed sloping in the insertion, so that the first Einsteckrohr ring segment identifies the largest cross-sectional area and the third Einsteckrohr ring segment, the smallest cross-sectional area. Advantageously, owing to such an embodiment of the push-in tube section formed with a plurality of plug-in tube segments, the push-in tube can be displaced in the axial direction and, in addition, a controlled tilting of the push-in tube section in the sleeve is made possible.

In order for the sealing device of the charge air duct to be positionally displaceable in the axial direction, at least one annular spring of the sealing device can be arranged in the at least one annular groove to form a tongue and groove system.

Furthermore, at least one annular groove can be arranged in / at a position selected from the following group: on the inside of the sleeve, on the outside on the pipe section, in the second plug-in pipe segment, in the first plug-in pipe step transition, in the second plug-in pipe step transition in which first sleeve step transition, in the first sleeve ring segment.

By such an arrangement of the annular groove, the sealing device can be held in position particularly securely. For example, the annular spring on the base ring terminally disposed opposite the sealing lip rings, and the annular groove on the outside of the Einsteckrohrabschnitt in the second Einsteckrohr-ring segment or in the first Einsteckrohr-step transition, the sealing device with its base ring, for example, the first Einsteckrohr- step transition is formed, for example, plateau-like support, so that a high fitting strength can be produced. In this case, further advantageous embodiments are conceivable, which aim that even with axial movement of the Einsteckrohrabschnittes relative to the sleeve no slippage or displacement of the sealing device relative to the Einsteckrohrabschnitt can occur. In addition, it is conceivable that an outer ring spring is arranged on the sealing device, which comes into operative connection with an inner side of the sleeve arranged annular groove in installation position, so that upon axial movement of the Einsteckrohrabschnittes relative to the sleeve no slippage or displacement of the sealing device relative to the sleeve can occur.

Furthermore, the sealing device can be arranged in the installed position between the first sleeve ring segment and the second Einsteckrohr ring segment.

Advantageously, therefore, the seal between the first sleeve ring segment and the second Einsteckrohr ring segment can be generated so that, for example, the first Einsteckrohr ring segment in cooperation with the first sleeve ring segment, for example, to limit the tilting of the Einsteckrohrabschnittes in the sleeve. In addition, it is conceivable that the first sleeve ring segment and the second plug-in tube ring segment can be reworked with respect to the sealing surfaces.

Furthermore, in a parallel installation position, the axial outer surface profile of the first single-tube ring segment and the axial inner surface profile of the first sleeve ring segment can be arranged at least in sections at an angle of 0.1 degrees to 4 degrees relative to one another. It is also conceivable that the axial outer surface profile of the first Einsteckrohr ring segment and the axial Innenoberflächenverlauf the first sleeve ring segment at least partially at an angle of 0.5 to 3.5 degrees, in particular at an angle of 1 to 3 degrees, if necessary at an angle of 1.5 to 2.5 degrees, for example at an angle of 1.9 to 2.1 degrees to each other.

Advantageously, the maximum tilt of the push-in tube section in the sleeve can be limited by such a surface course, so that a seal of the sealing device can be ensured by the limitation. In this case, a respective surfaces as Conical jacket, be designed as a ball or cylindrical. It is conceivable, for example, that the first sleeve ring segment is cylindrical, while the first Einsteckrohr- ring segment is frustoconical. There are also any combinations of cylindrical, frustoconical, spherical or elliptical configurations of the ring segments conceivable.

In this case, the installation position is to be understood by a parallel mounting position, in which the center lines of sleeve and plug-in tube are aligned parallel to each other. Due to such a design, although a tilting of the push-in tube section to the sleeve is possible, however, this tilting can be maximally limited by the corresponding, possibly complementary surface profile.

Furthermore, an annular bead can be formed on the push-in tube section in the insertion direction after the third push-in tube ring segment. By means of this annular bead can advantageously be formed a stop element, with which the movement in the axial direction of the Einsteckrohrabschnittes in the sleeve in cooperation with the third sleeve step transition are limited. It can be advantageously largely reduced by such a design of the annular bead damage to the third sleeve stage transition. In addition, by means of the annular bead, which is arranged for example in the installed position in the third sleeve ring segment, also a maximum tilt of the Einsteckrohrabschnittes be limited in the sleeve, since at maximum tilt the annular bead abuts the second sleeve ring segment, thereby limiting the movement. Furthermore, at least one annular gap can be arranged in a parallel installation position between pairs of sections selected from the following group:

 Between the first sleeve ring segment and the first plug-in tube ring segment, between the first sleeve ring segment and the second plug-in tube ring segment, between the first sleeve ring segment and the third plug-in tube ring segment, between the second sleeve ring segment and the third tube segment Ring segment, between the second sleeve ring segment and the annular bead.

The annular gaps between the first sleeve ring segment and the first Einsteckrohr ring segment and between the second sleeve ring segment and the annular bead of the serve Possibility of tilting the Einsteckrohrabschnittes in the sleeve, in particular, the annular gap between the second sleeve ring segment and the annular bead permits a tilting until the annular bead abuts the second sleeve ring segment. The annular gap between the first sleeve ring segment and the second Einsteckrohr ring segment serves primarily the arrangement of the sealing device, so that the seal is made between these two ring segments. The annular gap between the first sleeve ring segment and the third plug-in tube ring segment serves the possibility that the Einsteckrohrabschnitt can be inserted into the sleeves, wherein the axial displacement is limited by the annular bead and the third sleeve step transition. In this case, the third sleeve ring segment, which generally has a smaller cross-sectional area than the second sleeve ring segment, on the one hand intended to limit the movement of the Einsteckrohrabschnittes in the sleeve and on the other to form the fluid flow channel for the charge air. In this case, the annular gap between the second sleeve ring segment and the annular bead may be formed smaller than the annular gap between the first sleeve ring segment and the third Einsteckrohr ring segment and the second Einsteckrohr ring segment. The annular gap between the first sleeve ring segment and the first Einsteckrohr ring segment is advantageously formed opposite to the insertion with an increasing cross-sectional area, so on the one hand, a tilting of the Einsteckrohrabschnittes in the sleeve is made possible, but this is limited by the respective formation of the annular gap. This limitation of the tilt can also occur in cooperation with the annular gap between the second sleeve ring segment and the annular bead.

Furthermore, the sliding seat can be designed such that in the maximum deflected installation position, the center line of the Einsteckrohrabschnittes and the center line of the sleeve are arranged to each other at an angle of 0.1 to 4 degrees. It is also conceivable, in the maximum deflected mounting position, the center line of the insertion tube section and the center line of the sleeve to each other at an angle of 0.5 to 3.5 degrees, in particular at an angle of 1 to 3 degrees, optionally at an angle of 1, 5 to 2.5 degrees, for example, at an angle of 1.9 to 2, 1 degrees to each other.

Advantageously, by such a design of the sliding seat a high tolerance in terms of not only the axial displacement of the Einsteckrohres, but also the tilting of the Einsteckrohres are made in the sleeve, whereby the charge air line has a very high installation tolerance during assembly. It is under the term tilting such a non-parallel arrangement of the center lines of the push-in tube section and the sleeve, so that the center lines are arranged at an angle as described above.

The figures show each schematically:

1 is a sliding seat in parallel mounting position,

 2 shows a sliding seat in the maximum deflected installation position,

Fig. 3 is a charge air line with two sliding seats.

A sliding seat 100, as shown in Fig. 1, has a sleeve 110 and a Einsteckrohrabschnitt 120. The insertion tube portion 120 may be connected to a plug-in tube 130 or formed from the same, for example by cold forming. Between the Einsteckrohrabschnitt 120 and the sleeve 1 10, a sealing device 140 may be arranged, which has a base ring 150 and two sealing lip rings 160, 160 '. Between the sealing lip rings 160, 160 ', a spreading device 170, as shown in Fig. 2, be arranged, which exerts an expanding force on the two sealing lips 160, 160', so that the sealing lip rings 160, 160 'to the sleeve 110 and the Einsteckrohrabschnitt 120 are pressed. As a result, the seal can be produced by means of the sealing device 140 between the sleeve 110 and the insertion tube section 120. In this case, the sealing device 140 has a U-shaped cross-sectional profile 171, with a base 172 and two legs 173, 173 'connected to the base 172. In the circumferential direction 174, the base 172 clamps the base ring 150 and the legs 173, 173 'clamp the sealing lip rings 160, 160'.

The sleeve 110 can, as shown in Fig. 1, a first sleeve ring stage 175 with a first sleeve ring segment 180, a second sleeve ring stage 185 with a second sleeve ring segment 190 and a third sleeve ring stage 195 with a third sleeve Ring segment 200 have. In this case, the third sleeve ring segment 200 with its third sleeve stage transition 210 serves on the one hand the fluid guidance of the charge air and on the other hand as a stop element. A second sleeve step transition 220 of the second sleeve ring stage 185, as well as the third sleeve step transition 210 may be formed plateau-like, and define the first sleeve ring segment 180 relative to the second sleeve ring segment 190. A first sleeve step transition 230 may be formed through a terminal portion of the sleeve 110, and for ease of insertion of the insertion tube portion 120, the first sleeve step transition 230 may be chamfered, as shown, or rounded. In the plug-in direction 240, the sleeve ring segments 180, 190, 200 can be designed in such a way that that their Querschnittsfiäche from sleeve ring segment to sleeve ring segment decreases. Alternatively or additionally, the sleeve ring segments 180, 190, 200 may be cylindrical. The insertion tube section 120, as shown in Fig. 2, in the insertion direction 240 enumerated also a first Einsteckrohr ring step 245 with a first Einsteckrohr- ring segment 250, a second Einsteckrohr ring step 255 with a second Einsteckrohr- ring segment 260 and a third Einsteckrohr- Ring stage 265 have a third Einsteckrohr- ring segment 270. In this case, the Einsteckrohr ring segments 250, 260, 270 in the insertion direction 240 of Einsteckrohr ring segment to Einsteckrohr ring segment also have a sloping Querschnittsfiäche.

In a parallel installation position, as shown in FIG. 1, a center line 280 of the insertion tube section 120 is oriented parallel to a center line 290 of the sleeve 110. In this parallel mounting position, at least between an annular bead 300 which is connected terminally in Einsteckrichtuhg 240 after the third Einsteckrohr ring segment 270 on the Einsteckrohrabschnitt 120 and between the second sleeve ring segment 190, an annular gap 310 is disposed. Between the first Einsteckrohr ring segment 250 and the first sleeve ring segment 180, an annular gap 320 is also formed in this parallel mounting position. This annular gap 320 may be formed due to the formation of the first Einsteckrohr ring segment 250 and the first sleeve ring segment 180 such that opposite to the insertion direction 240 of the annular gap 320 has a rising Querschnittsfiäche. Both annular gaps 310, 320, possibly in cooperation with one another, permit a tilting of the push-in tube section 120 in the sleeve 110, wherein the tilting is limited at least by the annular bead 300 in cooperation with the second sleeve-ring segment 190. The cylindrical configuration of the first sleeve ring segment 180 and of the conical or frustoconical profile of the first plug-in tube ring segment 250 can also limit the tilting of the push-in tube section 120 in the sleeve 110. Between the first Einsteckrohr ring segment 250 and the second Einsteckrohr- ring segment 260, a first Einsteckrohr step transition 324 may be arranged, which may be formed as shown in FIG. 1, plateau-like. Between the second Einsteckrohr- ring segment 260 and the third Einsteckrohr ring segment 270, a second Einsteckrohr- step transition 326 may be provided, the only as a processing transition between see the two Einsteckrohr annular stages 260, 270 is formed. Here, the Einsteckrohr step transitions 324, 326 and the stiffening of the Einsteckrohrabschnittes 120 serve. In addition, an annular groove 330 may be formed on the first plug-in tube step transition 324 or on the second plug-in tube ring stage 260, in which an annular spring 340 of the sealing device 140 engages in the installed position. This tongue-and-groove system 330, 340 formed from annular groove 330 and annular spring 340 can at least reduce or prevent slippage of the sealing device 140 in the axial direction 350. As a result, the sealing device 140 can also be prevented from slipping into the region of an annular gap 355 which is arranged between the third plug-in tube segment 270 and the first sleeve-ring segment 180. This annular gap 355 is larger in the radial direction 360 than the annular gap 365 between the second plug-in tube ring segment 260 and the first sleeve-ring segment 180, in which the sealing device 140 is arranged. Thus, by the tongue and groove system 330, 340 slipping of the sealing device 140 in the annular gap 355 between the first sleeve ring segment 180 and the third Einsteckrohr-ring segment 270 and a concomitant failure of the seal can be prevented.

In the maximum deflected installation position, as shown in Fig. 2, the center line 280 of the push-in tube section 120 is tilted to the center line 290 of the sleeve 110 at an angle α tilted. Accordingly, on one side of the sliding seat 100, the annular gap 320, as shown, expanded, while the annular gap 310 is almost completely reduced, as the

Ring bead 300 abuts the second sleeve ring segment 190. Thus, by the annular gap 310 and the annular gap 320, as well as by these the annular gaps 310, 320 forming components 180, 250, 190, 300, the maximum tilt of the sleeve 1 10 limited to the Einsteckrohrabschnitt 120.

In Fig. 3, a charge air line 370 is shown having two sliding seats 100, 100 '. In this case, a plug-in tube 130 with its respective terminal insertion tube section 120, 120 'inserted into the sleeve 110, 110' of the respective sliding seat 100, 100 ', so that a movement of the Einsteckrohres 130 is possible both in the axial direction 350 and in the radial direction 360. In this case, the sleeve 1 10 'integrally with a pipe section 380, for example in cast construction, be formed, or as a separate component 1 10 on a piece of pipe 390 attachable and formed, for example, welded to it. It is also conceivable that the charge air duct 370 also has only one such sliding seat 100, 100 '. The charge air line 370 is arranged in the installation position between a loading air cooler 400 and a charging device 410.

Claims

A sealing device having a U-shaped cross-sectional profile (171) comprising a base (172) and two legs (173, 173 ') connected to the base (172), the base (172) having a base ring (150) in the circumferential direction (174). spans, are attached to the two in each case by a leg (173.173 ') in the circumferential direction (174) clamped sealing lip rings (160,160'), between the two legs (173,173 ') and between the two sealing lip rings (160,160') a spreading device (170 ) is arranged, which exerts an expanding force on the two legs (173.173 ') and the two sealing lip rings (160,160'), wherein at least one radially directed in the circumferential direction (174) extending annular spring (340) of a tongue and groove system (330,340 ) is provided, with which the sealing device (140) can be held in position in position.

2. Sealing device according to claim 1,

 wherein at least two components selected from the following group are formed integrally with each other:

 the base (172), at least one of the two legs (173, 173 '), the base ring (150), at least one of the two sealing lip rings (160, 160'), the at least one annular spring (340), the spreading device (170).

3. Sealing device according to one of the preceding claims,

 wherein at least two components, selected from the following group, are formed at least partially from polytetrafluoroethylene (PTFE):

 the base ring (150), at least one of the two sealing lip rings (160,160 '), the at least one annular spring (340).

4. Sealing device according to one of the preceding claims,

 wherein at least one annular spring (340) has at least one arrangement selected from the following group:

 an arrangement on the base ring (150),

 an arrangement at a transition between the base ring (150) and one of the two sealing lip rings (160, 160 '),

 a central arrangement on one of the two sealing lip rings (160, 160 '),

a terminal arrangement on one of the two sealing lip rings (160, 160 '), a radially outward arrangement,

a radially inward arrangement.

Use of a sealing device according to one of the preceding claims,

wherein the sealing device (140) is used to seal a sliding seat (100, 100 ') of a charge-air duct (370) in a plug-and-socket construction.

Charge air line, in the installed position between a charging device (410) and a charge air cooler (400) arranged, with at least one sliding seat (100,100 ') comprising at least one sleeve (110,110') and at least one in installation position in the insertion direction (240) in the sleeve (110 , 1 10 ') insert tube portion (120,120'), wherein for sealing the sliding seat (100,100 ') at least one sealing device (140), in particular according to one of the preceding claims, between the sleeve (110,110') and the Einsteckrohrabschnitt (120,120 ') is.

Charge air line according to claim 6,

wherein the sleeve (110, 110 ') has at least one section selected from the following group, wherein the sections, if present, in the insertion direction (240) are listed below:

a first sleeve ring stage (175) comprising a first sleeve ring segment (180), a second sleeve ring stage (185) comprising a second sleeve step transition

(210) and a second sleeve ring segment (190),

a third sleeve ring stage (195) comprising a third sleeve step transition (220) and a third sleeve ring segment (200).

Charge air line according to one of the preceding claims,

wherein the insertion tube section (120, 120 ') has at least one section selected from the following group, wherein the sections, if present, in the insertion direction (240) are listed as follows:

a first plug tube ring stage (245) comprising a first plug tube ring segment (250) and a first plug tube step transition (324),

a second plug tube ring step (255) comprising a second plug tube ring segment (260) and a second plug tube step transition (326), a third shank ring stage (265) comprising a third shank ring segment (270).

9. charge air line according to one of the preceding claims,

 wherein in the installed position at least one annular spring (340) of the sealing device (140) in at least one annular groove (330) to form a tongue and groove system (330,340) is arranged.

Charge air line according to one of the preceding claims,

 wherein at least one annular groove (330) is arranged in / at a position selected from the following group:

 on the inside of the sleeve (110, 110 '),

 on the outside of the push-in tube section (120, 120 '),

 in the first sleeve step transition (230),

 in the first sleeve ring segment (180),

 in the second plug-in tube ring segment (250),

 in the first plug-in stage step transition (324),

 in the second plug-in stage step transition (326). 11. Charge air line according to one of the preceding claims,

 wherein the sealing device (140) in the installed position between the first sleeve ring segment (180) and the second Einsteckrohr ring segment (260) is arranged.

Charge air line according to one of the preceding claims,

 wherein in parallel mounting position, the axial outer surface profile of the first Einsteckrohr- ring segment (320) and the axial inner surface profile of the first sleeve ring segment (180) are at least partially arranged at an angle α of 0.1 to 4 degrees to each other. 13. Charge air line according to one of the preceding claims,

 wherein on the Einsteckrohrabschnitt (120,120 ') in the insertion direction (240) after the third Einsteckrohr ring segment (270) an annular bead (300) is formed.

14. Charge air line according to one of the preceding claims, wherein, in a parallel mounting position, at least one annular gap (310, 320) is arranged between pairs of sections selected from the following group:

between the first sleeve ring segment (180) and the first plug tube ring segment (250),

between the first sleeve ring segment (180) and the second plug tube ring segment (260),

between the first sleeve ring segment (180) and the third socket tube ring segment (270),

between the second sleeve ring segment (190) and the third sleeve ring segment (270),

between the second sleeve ring segment (190) and the annular bead (300). Charge air line according to one of the preceding claims,

 Wherein the sliding seat (100,100 ') is formed such that in the maximum deflected mounting position, the center line (280) of the Einsteckrohrabschnitts (120,120') and the center line (290) of the sleeve (1 10,110 ') to each other at an angle α from 0.1 to 4 degrees are arranged.