DE102013210073A1 - Vacuum-tight bakeable rotary union for vacuum applications - Google Patents

Abstract

The invention relates to a vacuum-tight, heatable rotary leadthrough, such as is used, for example, in vacuum process plants for coating substrates. The object of the invention to provide a suitable robust and bakeable rotary leadthrough that can withstand temperatures in a wide range from −20 ° C. to + 200 ° C. is achieved with a vacuum-tight bendable rotary leadthrough for receiving a rotating machine element, comprising a fixed one or movable first flange and a movable second flange, wherein the movable second flange is non-positively connected to the rotating machine elements in a vacuum-tight manner via an O-ring and the two flanges are connected to one another via a primary sealing element and a secondary sealing element via a contact pressure.

Description

The invention relates to a vacuum-tight bakeable rotating union, as used for example in vacuum process equipment for coating substrates.

Rotary feedthroughs are required to provide rotating parts, such as e.g. Shafts to pass through chamber walls and the like, when the driving machine element, such as a drive means, is arranged on one side of the chamber wall and the driven machine element, such as a rotating hollow shaft, is arranged on the other side of the chamber wall.

If a pressure difference must be maintained between the two sides of the chamber wall (eg atmospheric pressure on one side, high vacuum on the other side) or / and the atmospheres on both sides of the chamber wall are differently composed (eg air on one side, inert gas on the other side) or / and different media are on both sides of the chamber wall (eg water on one side, vacuum on the other side), then it is necessary to make the rotary feedthrough so that an unintentional pressure equalization or gas exchange between both sides of the chamber wall, which are caused by leakage of the rotary feedthrough prevented.

Rotary feedthroughs for vacuum systems may, for example, have two successive seals, one seal being arranged to seal to the atmosphere and the other seal to seal to the vacuum or process atmosphere. For example, between these two seals may be provided with a barrier medium, i. a barrier gas or a barrier liquid, a complete separation of the media can be achieved. Alternatively, a separation of atmosphere and process space can be achieved with an intermediate vacuum generated between the two seals.

In order to achieve a sufficient sealing effect, sealing elements of the sealing device can be provided, for example, with a sealing lip. Such sealing lips can be produced, for example, by using a shaft sealing ring as the sealing element, the inner diameter of which is smaller than the outer diameter of the rotating machine element, which protrudes through the rotary leadthrough. This results in a self-stressing sealing gap between the sealing lip and the rotating machine element.

For example, ferrofluids can also be used as a sealing element that react to magnetic fields without solidifying.

A disadvantage of the previously used materials in vacuum-tight rotary joints is that they are basically not thermally stable, but are designed only for temperatures up to about 80 ° C.

In many applications, these rotary joints must reliably withstand large temperature fluctuations and remain vacuum-tight due to the process. It is therefore an object of the invention to provide a suitable robust and heatable rotary feedthrough which can withstand temperatures in a wide range of -20 ° C to + 200 ° C.

The object of the invention is achieved with a vacuum-tight bakeable rotary feedthrough for receiving a rotating machine element comprising a first flange and a second flange, which are movable relative to each other, wherein the second flange non-positively connected to the rotating machine element vacuum-tight over an O-ring is, and the two flanges are connected to each other via a respective primary sealing element and a secondary sealing element via a contact pressure.

Movable relative to each other may mean, for example, that a first flange is fixed or movable and a second flange is designed to be movable. Furthermore, the first and the second flange can be designed to rotate in opposite directions and / or in the same direction of rotation, but at different angular speeds.

In this case, the secondary sealing element fixes the primary sealing element.

The primary sealing element consists of hardened and lapped carbon steel, which makes high temperatures of + 200 ° C uncritical.

In order to compensate for an angular and axial offset in small dimensions, the secondary sealing element is elastic. Thus, a uniform axial contact pressure can be formed and, for example, manufacturing tolerances of the male machine element can be compensated and the vacuum tightness can be ensured.

In one embodiment of the invention, the primary sealing element may be formed as a metal sliding ring and the secondary sealing element as an O-ring.

To produce a permanent contact pressure, the invention has a spring element, wherein the spring element is arranged on the atmosphere side on the machine element and the movable flange.

The primary and secondary sealing element can be used for temperatures of at least -20 ° C to at least + 150 ° C.

Optionally, the primary and secondary sealing elements can be lubricated on the atmosphere side with a vacuum grease via a grease nipple. In this case, a sealing disc between the movable and fixed flange is arranged such that the atmosphere side, a leakage of vacuum grease is prevented.

If the rotary feedthrough is mounted in a chamber wall of a vacuum processing system, the movable flange is on the atmosphere side and the fixed flange is arranged on the vacuum side of the chamber wall and the contact pressure is generated by the pressure difference between the atmosphere and vacuum.

The invention will be explained in more detail with reference to an embodiment. The drawing below shows an embodiment of the vacuum-tight rotary feedthrough according to the invention with a movable flange and a fixed flange, wherein the seal is ensured by a drive seal.

In one embodiment of the rotary feedthrough according to the invention, the vacuum tightness by a drive seal 41 . 42 produced, consisting of two metal slip rings 10 and two round seals 11 exists, with the round seals 11 the metal slip rings 10 fix and a static tightness to the flanges ( 1 . 2 ) produce. The round seals 11 are designed as O-rings, so that an angular offset and an axial offset can be compensated to a small extent and the rotary feedthrough remains vacuum-tight. The rotary union is used in a vacuum process plant. The contact pressure is generated by the differential pressure between atmosphere A and vacuum V. When servicing the system, the minimum necessary contact pressure is achieved by a spring element 6 made available. The spring element 6 is on the atmosphere side A on the hollow shaft 3 , For example, a cooling roller of a vacuum coating system attached and with the movable flange 2 connected. At the atmosphere side A can the drive seal 41 . 42 via a grease nipple 8th or the like with vacuum grease, which can be used in a wide temperature range, for example, between -60 ° C to + 200 ° C, optionally lubricated. The sliding surfaces of the drive seal 41 . 42 consist of tool steel with hardened and lapped carbon steel contact surfaces. These contact surfaces alone should ensure the vacuum tightness of the rotary feedthrough. By using the metal sealing rings 10 and temperature-stable elastomers for round seals 11 the rotary feedthrough is bakeable and temperature stable up to 200 ° C, so that the function of the rotary feedthrough is guaranteed even at coating processes at high temperatures. This rotary feedthrough can be used for speeds of up to 150 rpm.

LIST OF REFERENCE NUMBERS

1

fixed flange

2

movable flange

3

Machine element, e.g. a hollow shaft

41

first partial drive seal

42

second partial drive seal

5

Sealing washer, e.g. NILOS ring

6

spring element

7

O-ring

8th

grease nipple

9

Screw

10

primary sealing element

11

secondary sealing element

12

chamber wall

A

atmosphere side

V

vacuum side

Claims (11)

Vacuum-tight bakeable rotating union for receiving a rotating machine element ( 3 ), comprising a first flange ( 1 ) and a second flange ( 2 ) which are movable relative to each other, wherein the second flange ( 2 ) non-positively with the rotating machine elements ( 3 ) vacuum-tight over an O-ring ( 7 ), and the two flanges ( 1 . 2 ) via a respective primary sealing element ( 10 ) and a secondary sealing element ( 11 ) are connected to each other via a contact pressure. Rotary feedthrough according to claim 1, characterized in that the secondary sealing element ( 11 ) the primary sealing element ( 10 ) fixed. Rotary feedthrough according to claim 1 or 2, characterized in that the primary sealing element ( 10 ) consists of hardened and lapped carbon steel. Rotary feedthrough according to one of claims 1 to 3, characterized in that the secondary sealing element ( 11 ) is formed elastically, wherein a uniform axial contact pressure can be formed. Rotary feedthrough according to one of the preceding claims, characterized in that the primary sealing element ( 10 ) as a metal slip ring and the secondary sealing element ( 11 ) is formed as an O-ring. Rotary feedthrough according to one of the preceding claims, characterized in that it for generating a permanent contact pressure, a spring element ( 6 ) having Rotary feedthrough according to one of the preceding claims, characterized in that the primary ( 10 ) and secondary sealing element ( 11 ) can be used at temperatures of at least -20 ° C to at least +150 ° C. Rotary feedthrough according to one of the preceding claims, characterized in that the primary ( 10 ) and secondary sealing element ( 11 ) with a vacuum grease via a grease nipple ( 8th ) are lubricated. Rotary feedthrough according to one of the preceding claims, characterized in that a sealing disc ( 5 ) between moving ( 2 ) and fixed flange ( 1 ) is arranged such that an escape of vacuum grease can be prevented. Vacuum process system with one on a chamber wall ( 12 ) of the vacuum chamber mounted rotary feedthrough according to the preceding claims, characterized in that the first flange ( 1 ) on the atmosphere side (A) and the second flange (A) 2 ) vacuum side (V) of the chamber wall ( 12 ) is arranged and the contact pressure, the differential pressure between the atmosphere and vacuum. Vacuum process system according to the preceding claims, characterized in that the spring element ( 6 ) for generating a permanent contact pressure on the atmosphere side (A) on the machine element ( 3 ) and the movable flange ( 2 ) is arranged.

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