DE102011009284A1 - Electrically conductive lead-through structure for supplying power to heating element in vacuum container, has sealing element arranged in auxiliary housing, to separate vacuum in interior space of housing relative to container - Google Patents

Abstract

The electrically conductive lead-through structure (1) has auxiliary housing (7) with guide elements (5,6) that are inserted into vacuum container (2), to connect and disconnect auxiliary housing with vacuum container. A sealing element (8) for vacuum separation, is arranged in wall (18) of auxiliary housing, so as to separate vacuum in interior space of auxiliary housing with respect to the container, and to maintain both auxiliary housing and container in air-tight state.

Description

The invention relates to an electrically conductive passage in a vacuum housing, which is suitable for example for the power supply of heating elements used in coating processes.

By vacuum housing is meant a type of container that is both leak-proof and sufficiently stable to withstand the atmospheric pressure of the environment. Conceptually, instead of vacuum chamber is familiar, which are named depending on the function and arrangement in larger vacuum systems lock, transfer, buffer or process chambers.

Various bushings in vacuum housings or vacuum chambers are known. To those, are transmitted via the mechanical movements in the chamber, include more for gas-conducting and electrical cables and heating rods or quartz glass heater. For the latter, bushings for fixed or non-moving components, there are constructive means such as pressed seals compared to implementation for moving components. If high temperatures of more than 300 ° C stress the seals, this considerably restricts the choice of suitable means and, in particular, the choice of material.

Such problems to spotlight tubes, in particular also rod-shaped heating means of quartz glass, are after DE 10 2008 063 677 A1 insofar solved proposed that by means of a tube surrounding the radiator tube in the area of implementation of the mechanical pressure necessary for sealing of the sensitive material (glass) is kept away and the better thermally conductive material of the cladding tube, in contact with the chamber wall, the thermal discharge of the sealing material favored.

The claim to the invention does not help the previous approach, since heating means such as radiator tubes - usually made of quartz glass - are limited in terms of their maximum temperature. Rather, it is held in the effort to introduce the power supply, albeit thermally conductive, in the chamber housing to provide in the chamber active CFC heating means, these heating means can significantly exceed the 600 ° C due to their nature. If the desired temperature range is around 600 ° C or below 800 ° C, the single CFC heater requires high currents in the kilo-ampere range.

A feedthrough module for electrical lines according to DE 103 10 070 A1 comes very close to the desire for tightness mentioned at the beginning. When heated conductor, which is not considered here, there is generally the problem of thermally stressed seal continues.

As far as can be seen, known feedthroughs do not limit themselves to heated electrical conductors which are to be guided separately through a chamber wall and are connected to active heating elements in the chamber.

Coolants especially for pipes, accessible from the prior art.

Coating processes accompanying constructions as well as adjoining ones usually wear out as a result of their functions due to unfavorable deposits from the coating. The last but not least locally on sealants and the particular disadvantage where the sealants have an electrical insulator function. It comes after deposits of particles to fault currents or short circuits.

By means of thin-walled shields to keep away interfering heat or particles of sealants is also known, but only so that the sealants of the actual process environment are only partially withdrawn.

The invention has for its object to provide an electrically conductive passage in a vacuum housing with preferably rigid conductive elements, which overcomes the previously known problems, wherein the heated conductive element long-term stable in the implementation close to atmospheric pressure from the outside and vacuum from the inside and to achieve that its insulation to the chamber wall also resistant to the effect of a coating process.

The object is achieved by carrying out the features of patent claim 1. Advantageous embodiments of the invention are the subject of dependent claims.

The subject invention of carrying out in a vacuum housing comprising an electrically conductive guide element guided in the housing and sealing means which functionally separate the vacuum within the housing from atmospheric pressure conditions outside the housing-vacuum separation-is characterized in that the passage also comprises a secondary housing which is guided through the guide element from the secondary housing into the housing - housing separation - that the sealing means for vacuum separation are arranged in the secondary housing wall and that with respect to the vacuum, the separate interior of the secondary housing is gas-conductively connected to that of the housing and both equally outward - against the atmospheric environment - are dense. Alone through the secondary housing gives degrees of freedom with regard to the spatial arrangement of the sealing means as well as with respect to the below-mentioned advantageous embodiments. Significantly reduced the spatial requirements in the vacuum vessel, since previously usual shields or sheets no longer need to be arranged in the container. Streudampfeinflüsse minimizes the opening between the vacuum vessel and sub-tank and determines their direction of propagation.

Conveniently, the guide element should be rigid. In effect, the guide element is thus spatially securely positioned and can fulfill mechanical holding and carrying functions.

In a further embodiment of the invention, both the vacuum separation and the housing separation is repeatedly carried out in a secondary housing. With a depending on the perspective of multiple use of control and sealing elements in a sub-housing or merging the sub-housing multiple feedthroughs simplifies the design effort considerably.

In a preferred embodiment of the invention, the position of the sealing means descriptively two levels - a housing separation plane and a vacuum parting plane - are set at an angle to each other, wherein the housing separation plane is plane-parallel to the outer surface of the housing wall and the vacuum parting plane is the axial plane to the guide element in the vacuum separation, after which the guide element angled and guided vertically through both the housing separation plane and through the vacuum parting plane. The concept of the invention of the secondary chamber significantly counteracts this, since it is precisely the sensitive sealants that are no longer directly exposed to the stray steam and heat influences of the sources. Angled towards the direction of direction Asked sealants elude the aforementioned adverse effects.

Advantageously, the housing separation plane and vacuum separation plane are set at right angles to each other.

It is particularly useful if the sealing means are spatially offset laterally from the location of the passage of the guide element from the secondary chamber into the housing. The thus removed from the location of the passage of the guide element sealant benefits from the effect of further reduced adverse effects with respect to scattering steam and heat.

Further, it should be provided that the sub-housing is detachably connected to the housing wall. The background to this idea is a simplified construction. To what extent the secondary housing should be better one-piece or almost completely closed, remains expertly to solve.

In a preferred embodiment of the invention means for cooling are provided on the guide element. This preferably causes a temperature which is below critical values with respect to the material of the sealant in the region where the guide element and the sealant lie against each other. Further details are explained in the exemplary embodiment.

It also makes sense that means for cooling are provided at the secondary housing floor. With the use of coolant, it is preferably possible to concentrate the condensation of the scattering steam entering the secondary housing on selected wall areas in the secondary chamber. The secondary housing floor offers itself gravitationally.

In a preferred embodiment of the invention, at the vacuum separation in the vacuum parting plane, a first sealing surface is formed by the secondary housing wall and the second opposing sealing surface being provided by the guide element, between which insulating sealing means are arranged. Providing a sealing surface through the baffle itself has the advantages of relatively stably connecting it to the minor housing wall and reducing the number of material transitions (wall-sealant wall) to one.

Conveniently, the sealing surfaces are releasably pressed firmly against each other by clamping means. Such an embodiment favors the sealing behavior as a result of the force effect.

Based on this, it is advantageous that the clamping means have means for isolation from the guide element. As far as next to the guide element secondary housing wall and clamping means are electrically conductive, could unfavorably be electrically connected to each other via the clamping element guide element and secondary housing wall. Insulating sealing means or insulation means, which are explained in more detail in the embodiment, do not allow such a disadvantage.

In a further embodiment of the invention, means for contacting the guide element are provided. Ultimately, to connect a flexible electrical conductor from the outside to the guide element.

In an advantageous embodiment of the invention, a particle reservoir is provided for the particles depositing in front of the sealants in the secondary housing as a free space above the secondary housing floor. If scattering fumes in the secondary housing are condensed and particles are deposited there, a free space promotes longer maintenance cycles in this regard; the interfering particles must be removed less often.

Based on this, it is advantageous that the particle reservoir is accessible via a vacuum-safe, separate closure. The simplified mentioned maintenance.

Furthermore, it is recommended that the guide element consists of at least two parts, the guide element within the vacuum separation - cooled guide element - and a continuing guide element within the housing separation - uncooled guide element -, and both are detachably connected together within the secondary housing. As a result, in addition to a simplified production and assembly, materials suitable for use can also be used.

Appropriately, is that the uncooled guide element consists of a high temperature resistant material and is at least indirectly connected to at least one heating element. The heated to over 600 ° C heating element passes a portion of the heat to the associated with him uncooled guide element. The choice of material made in this way counteracts the service life.

It may be said from the foregoing that the materials used for the cooled guide element are stainless steel, the uncooled guide element molybdenum and the heating element CFC. This combination is suitable for high temperatures (even above 600 ° C).

In a preferred embodiment of the invention, a reducing piece is arranged between the uncooled guide element and the cooled guide element. After the foregoing, the two materials contact molybdenum and stainless steel, with similar large contact areas applied. By means of the reducer, the uncooled guide element can be made into a smaller cross-section, which saves material or costs.

In a further embodiment of the invention, at least one contact surface located within the secondary housing between cooled guide element and non-cooled guide element is formed as an adjustment surface, slightly bevelled on both sides for axial correction by rotation. Such favors during assembly, guiding elements for heating elements or to align these with those of other bushings in a housing to each other.

In a further embodiment of the invention, guide elements are preferably round in cross section.

In a further embodiment of the invention, the secondary housing is round in at least one cross section.

In a further embodiment of the invention, the secondary housing is shaped like a T-piece of pipe.

In a further embodiment of the invention, the coolant on the cooled guide element coolant inlet, coolant outlet and a tube-like coolant guide in a bore. Via the inlet, the coolant enters the coolant guide and thus in the interior of the cooled guide element in the vicinity of the sealant. The coolant flows from there on the other side of the coolant guide to the drain.

Due to the choice of material and the executable cross sections of the guide elements, the bushing is suitable for high currents; single-digit kilo-amperes.

The invention will be described in more detail with reference to an embodiment. This is in the 1 a cross section with the implementation of the invention 1 on a part of a (vacuum) housing 3 shown attached outside. To the interior of the case 2 towards a housing wall separates 4 ; In addition, the atmospheric pressure from the outside 3 from the vacuum inside 2 , A connection between execution 1 and housing 2 is there where the execution 1 on the housing 3 is attached. A line with corners indicates this. The implementation 1 is at the bottom of the container 3 attached. The secondary housing 7 is by Nebengehäusewand 18 and secondary housing floor 19 limited. At the latter, with its cooled part 20 , on the inside borders the passage 1 the particle reservoir 15 ; a space for the deposition of particles. Functionally, the focus is on the cooled guide element for electrical power 5 to which the reducer 17 with the adjustment surface 14 connects between the two. On the reducer 17 Rising passes through a breakthrough in the vessel wall 4 Guided uncooled guide element 6 the current to the heating element 16 , The insulating sealant 8th are five times available. Two of them are located between the sealing surfaces, where secondary housing wall 18 and cooled guide element 5 meet. The clamping means 9 separate from the cooled guide element 5 and from the contact terminal 13 electrically three insulating sealants 8th , The guiding element 5 stay that way from the other walls 4 . 18 and 19 electrically isolated. An essential part of the cooled guide element 5 make its coolant 10 . 11 and 12 out. The latter cause the cooled part of the implementation 21 , About the coolant inlet 11 the coolant enters the coolant guide 10 and so inside the cooled baffle 5 near the sealant 8th , The coolant flows from there on the other side of the coolant guide 10 towards the coolant outlet 12 ,

LIST OF REFERENCE NUMBERS

1

execution

2

Housing (inside)

3

Housing (outside)

4

housing wall

5

Guide element (cooled)

6

Guide element (uncooled)

7

In addition to housing

8th

Sealant (insulating)

9

clamping means

10

Coolant circulation

11

Coolant inlet

12

Coolant flow

13

contact terminal

14

adjustment surface

15

particle reservoir

16

heating element

17

reducer

18

Besides housing wall

19

In addition to housing bottom

20

Cooled part of the secondary housing

21

Chilled part of the passage

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 102008063677 A1 [0004]
• DE 10310070 A1 [0006]

Claims (20)

Implementation in a vacuum housing comprising an electrically conductive guide element guided in the housing and sealing means which functionally separate the vacuum within the housing from atmospheric pressure conditions outside the housing - vacuum separation -, characterized in that the passage ( 1 ) also a secondary housing ( 7 ), through which the guide element ( 5 . 6 ) from the secondary housing ( 7 ) in the housing ( 2 ) - housing separation - that the sealant ( 8th ) for vacuum separation in the secondary housing wall ( 18 ) are arranged as well as that with respect to the vacuum, the separate interior of the secondary housing ( 7 ) with the housing ( 2 ) is connected gas-conducting and both equally to the outside ( 3 ) - against the atmospheric environment - are tight. Bushing according to claim 1 or 2, characterized in that the guide element ( 5 . 6 ) is rigid. Bushing according to claim 1 or 2, characterized in that in a secondary housing ( 7 ) is performed repeatedly both the vacuum separation and the housing separation. Feedthrough according to one of claims 1 to 3, characterized in that the position of the sealing means ( 8th ) descriptively two levels - a housing separation plane and a vacuum parting plane - are set at an angle to each other, wherein the housing separation plane plane-parallel to the outer surface of the housing wall ( 4 ) and the vacuum parting plane is the axial plane to the guide element ( 5 ) in the vacuum separation, after which the guide element ( 5 . 6 ) Angled and guided vertically through both the housing separation plane and through the vacuum parting plane. Feedthrough according to claim 4, characterized in that housing separation plane and vacuum separation plane are set at right angles to each other. Feedthrough according to one of claims 1 to 5, characterized in that the sealing means ( 8th ) spatially from the location of the passage of the guide element ( 6 ) from the secondary chamber ( 7 ) in the housing ( 2 ) are arranged laterally offset. Bushing according to one of claims 1 to 6, characterized in that the secondary housing ( 7 ) detachable with the housing wall ( 4 ) connected is. Feedthrough according to one of claims 1 to 7, characterized in that the guide element ( 5 ) Means for cooling ( 10 . 11 . 12 ) are provided. Feedthrough according to one of claims 1 to 8, characterized in that at the secondary housing floor ( 19 ) Means are provided for cooling. Feedthrough according to one of claims 1 to 9, characterized in that at the vacuum separation in the vacuum parting plane a first sealing surface through the secondary housing wall ( 18 ) and second opposing sealing surface by the guide element ( 5 ), between which insulating sealing means ( 8th ) are arranged. Bushing according to claim 10, characterized in that the sealing surfaces releasably fixed by clamping means ( 9 ) are pressed against each other. Bushing according to claim 11, characterized in that the clamping means ( 9 ) Means for isolation from the guide element ( 5 ) exhibit. Feedthrough according to one of claims 1 to 12, characterized in that means for contacting ( 13 ) on the guide element ( 5 ) are provided. Feedthrough according to one of claims 1 to 13, characterized in that for particles deposited in front of the sealing means in the secondary housing ( 7 ) as clearance above the secondary housing floor ( 19 ) a particle reservoir ( 15 ) is provided. Bushing according to claim 14, characterized in that the particle reservoir ( 15 ) is accessible via a vacuum-safe separate closure. Feedthrough according to one of claims 1 to 15, characterized in that the guide element ( 5 ) of at least two parts, the guide element ( 5 ) within the vacuum separation - cooled guide element - and a further guiding element ( 6 ) within the housing separation - uncooled guide element -, both within the secondary housing ( 7 ) releasably firmly connected to each other. Feedthrough according to one of Claims 1 to 16, characterized in that the uncooled guide element ( 6 ) consists of a high temperature resistant material and at least indirectly with at least one heating element ( 16 ) connected is. Feedthrough according to claim 17, 16 or one of the preceding claims, characterized in that as materials for the cooled guide element ( 5 ) Stainless steel, for the uncooled guide element ( 6 ) Molybdenum and for the heating element ( 16 ) CFC are used. Carrying out according to one of claims 16 to 18, characterized in that between uncooled guide element ( 6 ) and cooled guide element ( 5 ) A reducer is arranged. Bushing according to one of claims 16 to 19, characterized in that at least one within the secondary housing ( 7 ) located contact surface between cooled guide element ( 5 ) and uncooled guide element ( 6 ) as an adjustment surface ( 14 ), slightly beveled on both sides for axial correction by rotation, is formed.

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