DE102017115707A1 - sealing arrangement - Google Patents

Abstract

The invention relates to a sealing arrangement (1) for sealing between a cylindrical inner part (2) and an outer part (3) with a cylindrical receiving bore (4), in which the cylindrical inner part (2) is arranged, wherein in the cylindrical inner part (2). a first annular groove (6) with a first groove bottom (7) is provided for receiving an O-ring (8), which bears radially inwardly against the first groove bottom (7) and radially outward on the receiving bore (4) and wherein the cylindrical inner part (2) a second annular groove (9) having a second groove base (10) is arranged, for receiving a support disc (11), wherein the support disc (11) engages radially inwardly into the second annular groove (9).

Description

The invention relates to a sealing arrangement.

In the prior art it is known that an O-ring is used as a sealing element for a gas or Flüssigkeitsmedienübertritt between a cylindrical inner part and an outer part with a cylindrical receiving bore, see for example the 1 of the DE 20 29013 002 731 U1 ,

In such a radial installation of the O-ring, however, the gap width S of the gap between the cylindrical inner part and the cylindrical receiving bore of the outer part must not be arbitrarily large, otherwise the O-ring would press under the influence of the prevailing pressure p in the gap which could lead to damage of the O-ring. The maximum permissible gap width S of the gap in particular also depends on the height of the prevailing pressure p, the cord thickness D as the diameter of the round cross section of the O-ring and the material hardness of the O-ring material.

In general, the gap width S is limited by appropriate manufacturing tolerances of the inner member diameter and the bore in the outer part to the maximum permissible level in practice. In such sealing arrangements, the use of O-rings is typical.

However, if this limitation of the manufacturing tolerances is not possible, so-called support disks are used which bridge the gap between the inner part and the bore and thus prevent a migration of the O-ring in the gap. Such support disks are also by the DE 20 2013 002 731 U1 and the DE 10 2013 217 131 A1 known.

These solutions are suitable, for example, for sealing arrangements with only one media transfer.

However, if two parts are connected to one another via two or more media passages, then the gap S for joining can be greater than the O-ring specification permits since the receiving bore has to be made correspondingly large. The use of a known in the prior art support disk usually does not help, since their inner diameter d may not be much larger than the groove diameter D of the inner part and thus only a limited tolerance compensation is possible. This can lead to the O-ring no longer lying flat against the counter-pressure side and thus being able to deform unduly, which can result in damage to the O-ring.

It is therefore the object of the present invention to provide a seal assembly which is simple in construction and reduces or avoids the above problems. It is also the object to provide a component assembly, which allows an improved seal.

The object of the sealing arrangement is achieved by the features of claim 1.

An embodiment of the invention relates to a sealing arrangement for sealing between a cylindrical inner part and an outer part with a cylindrical receiving bore, in which the cylindrical inner part is arranged, wherein in the cylindrical inner part a first annular groove is provided with a first groove base for receiving an O-ring, which engages sealingly radially inward on the first groove base and radially outward on the receiving bore and wherein in the cylindrical inner part a second annular groove is arranged with a second groove base for receiving a support disk, wherein the support disk engages radially inwardly into the second annular groove. It is thereby achieved that the gap is securely blocked as far as possible, even at very different tolerance positions, or at least that the gap width is reduced, so that damage to the O-ring can be avoided.

It when the first annular groove passes through a gradation in the second annular groove is particularly advantageous. Thereby, a secure production of the annular grooves and the direct contact between the O-ring in the first annular groove and the support plate in the second annular groove is allowed.

Also, it is advantageous if the diameter D of the first groove bottom is greater than the diameter D2 of the second groove bottom. Thereby, the second annular groove is deeper than the first annular groove, so that the support plate can be securely arranged. The appropriate depth of the second annular groove of the support disk is assigned a certain tolerance, which may be provided without causing problems.

It is also expedient if the support disk has a radially inward diameter d2 having, wherein the diameter d2 larger than the diameter D2 of the second groove bottom and smaller than the diameter D of the first groove bottom. As a result, the support disk can be displaced slightly in the second annular groove, because it does not abut radially on the inside. For example, it can abut radially on the outer part and secure the O-ring there.

It is also expedient if a gap with the gap distance exists radially between the inner part and the outer part S is present, the second Ring groove has an axial width b, wherein b is greater than S , This ensures that the tolerance compensation can take place safely and the support disk is still securely arranged in the second annular groove.

It is also advantageous if the support disk radially outside a diameter D3 having, wherein the diameter D3 larger than the outer diameter D4 of the inner part and / or the inner diameter D5 the receiving bore of the outer part substantially corresponds. As a result, the gap can be safely covered or even closed. In this case, the support plate is advantageously radially on the outside of the outer surface.

It is also advantageous if the support disk has an axial width B having substantially the axial width b corresponds to the second annular groove. As a result, the support disk is received displaceably in the second annular groove, which ensures the tolerance compensation.

It is also particularly advantageous if the support disk consists of a plastic material. As a result, it can be made stable enough and yet it has good sliding properties in the second annular groove.

The object of the sealing arrangement is achieved with the features of claim 9 and 10, respectively.

An embodiment of the invention relates to a component arrangement with a cylindrical inner part and with an outer part with a cylindrical receiving bore, in which a cylindrical inner part is arranged and with a sealing arrangement according to the invention.

An embodiment of the invention also relates to a component assembly having a plurality of cylindrical inner parts and having a plurality of outer parts, each having a cylindrical receiving bore, in each of which one of the cylindrical inner parts is arranged and with at least one or with a respective sealing arrangement according to the invention.

• 1 einen schematischen Teilschnitt einer erdfindungsgemäßen Dichtungsanordnung.

In the following the invention will be explained in detail by means of an embodiment with reference to the drawing. In the drawing shows:

• 1 a schematic partial section of a sealing arrangement according to the invention.

The 1 shows a schematic representation of a seal assembly 1 in a half cut. The seal arrangement 1 is shown only partially, with the seal assembly 1 is arranged rotationally symmetrical to the axis II.

The seal arrangement 1 serves to seal between a cylindrical inner part 2 and an outdoor part 3 with a cylindrical receiving bore 4 in which the cylindrical inner part 2 is arranged. It prevails in the space between the inner part 2 and the outer part 3 a pressure p with a pressure difference in the axial direction with respect to the axis II, see arrow 5 , The axis 1 - 1 is also used to define a radial or axial direction or circumferential direction.

In the cylindrical inner part 2 is a first ring groove 6 with a first groove bottom 7 intended for receiving an O-ring 8th which is located radially inward on the first groove bottom 7 and radially outside of the receiving bore 4 tightly fitting. Furthermore, in the cylindrical inner part 2 a second annular groove 9 with a second groove bottom 10 arranged for receiving a support disk 11 , The support disk engages 11 radially inward into the second annular groove 9 one.

As in 1 It can be seen, is the O-ring 8th axially adjacent to the support disk 11 arranged and supported on the support disk 11 also axially, because he by the pressure p towards the support disk 11 is charged.

The support disk 11 protrudes radially outward from the second annular groove 9 out and extends at least almost to the outer part 3 or to the receiving bore 4 or its wall. This will ensure that the gap 12 between the inner part 2 and the outer part 3 securely locked as far as possible even at different tolerance levels or at least the gap width S is reduced, causing damage to the O-ring 8th can be avoided.

In 1 it can be seen that the first annular groove 6 through a gradation 13 in the second ring groove 9 passes.

The first ring groove 6 and the second annular groove 9 are dimensioned such that the diameter D of the first groove bottom 7 larger than the diameter D2 of the second groove bottom 10 , This will cause the second ring groove 9 formed deeper than the first annular groove 6 so that the support disk 11 safe in the second ring groove 9 can be arranged. By the appropriate depth of the second annular groove 9 becomes the support disk 11 also assigned a certain tolerance in their mobility. Thus, depending on the tolerance position of the outer part, inner part and / or second annular groove, the support plate may or may not intervene further in the second annular groove.

Also shows the 1 that the support disk 11 radially inside a diameter d2 having, wherein the diameter d2 is bigger than that diameter D2 of the second groove bottom and d2 smaller than the diameter D of the first groove bottom.

Furthermore, the shows 1 that radially between the inner part 2 and the outer part 3 A gap 12 with the gap distance S is present, wherein the second annular groove 9 an axial width b having, b is greater than S ,

Furthermore, the shows 1 that the support disk 11 radially outside a diameter D3 having, wherein the diameter D3 larger than the outer diameter D4 of the inner part 2 and / or the inside diameter D5 the receiving bore 4 of the outer part 3 essentially corresponds. This allows the gap 12 safely covered or even closed. This is the support disk 11 when closing the gap 12 advantageously radially outward on the outer part 3 in the circumferential direction flat. This is the support disk 11 with its annular outer circumference 14 flat on the outer part 3 at.

Also shows the 1 that the support disk 11 an axial width B having substantially the axial width b the second annular groove 9 equivalent. This will make the support disk 11 in the second annular groove 9 displaced taken, which ensures the tolerance compensation.

The support disk 11 is preferably made of a plastic material. The O-ring is advantageously made of an elastomer or rubber material.

An embodiment of the invention relates to a component arrangement with a cylindrical inner part 2 and with an outdoor part 3 with a cylindrical receiving bore 4 in which the one cylindrical inner part 2 is arranged and with a sealing arrangement described above. Alternatively, an embodiment of the invention can also provide a component arrangement with a plurality of cylindrical inner parts and with a plurality of outer parts each having a cylindrical receiving bore, in each of which one of the cylindrical inner parts is arranged, wherein at least one sealing arrangement described above is provided or wherein one each is provided above described sealing arrangement.

LIST OF REFERENCE NUMBERS

1

sealing arrangement

2

inner part

3

outer part

4

cylindrical receiving bore

5

arrow

6

first ring groove

7

first groove bottom

8th

O-ring

9

second annular groove

10

second groove bottom

11

support disc

12

gap

13

gradation

14

annular outer circumference

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 2029013002731 U1 [0002]
• DE 202013002731 U1 [0005]
• DE 102013217131 A1 [0005]

Claims (10)

Sealing arrangement (1) for sealing between a cylindrical inner part (2) and an outer part (3) with a cylindrical receiving bore (4), in which the cylindrical inner part (2) is arranged, wherein in the cylindrical inner part (2) has a first annular groove ( 6) with a first groove bottom (7) is provided for receiving an O-ring (8), which radially inwardly on the first groove bottom (7) and radially outside of the receiving bore (4) sealingly engages and wherein in the cylindrical inner part ( 2) a second annular groove (9) with a second groove base (10) is arranged, for receiving a support disc (11), wherein the support disc (11) engages radially inwardly into the second annular groove (9). Seal arrangement (1) according to Claim 1 , characterized in that the first annular groove (6) passes through a step (13) in the second annular groove (9). Seal arrangement (1) according to Claim 1 or 2 , characterized in that the diameter D of the first groove bottom (7) is greater than the diameter D2 of the second groove bottom (10). Seal arrangement (1) according to Claim 1 . 2 or 3 , characterized in that the support disk (11) has a radially inner diameter d2, wherein the diameter d2 is greater than the diameter D2 of the second groove bottom (10) and smaller than the diameter D of the first groove bottom (7). Seal arrangement (1) according to Claim 1 . 2 . 3 or 4 , characterized in that radially between the inner part (2) and the outer part (3), a gap with the gap distance S is present, wherein the second annular groove (9) has an axial width b, where b is greater than S. Seal arrangement (1) according to Claim 1 . 2 . 3 . 4 or 5 , characterized in that the support disk (11) has a radially outer diameter D3, wherein the diameter D3 is greater than the outer diameter D4 of the inner part (2) and / or the inner diameter D5 of the receiving bore (4) of the outer part (3) substantially equivalent. Sealing arrangement (1) according to one of the preceding Claims 5 or 6 , characterized in that the support disc (11) has an axial width B which corresponds substantially to the axial width b of the second annular groove (9). Sealing arrangement (1) according to one of the preceding claims, characterized in that the support disc (11) consists of a plastic material. Component arrangement with a cylindrical inner part (2) and with an outer part (3) with a cylindrical receiving bore (4), in which the one cylindrical inner part (2) is arranged and with a sealing arrangement (1) according to one of the preceding claims. Component arrangement with a plurality of cylindrical inner parts (2) and with a plurality of outer parts (3) each having a cylindrical receiving bore (4), in each of which one of the cylindrical inner parts (2) is arranged and with at least one or a respective sealing arrangement (1 ) after one of the preceding ones Claims 1 to 8th ,

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