DE19746316A1 - Axial magnetic field contact piece for a vacuum chamber - Google Patents

Abstract

The contact piece is made in a pot (11) and has a section forming a contact surface (28). A first section of a material of high conductance is formed on the base of the pot contg. an insulating separating wall (20) forming a coil former perpendicular to the base. An insulating plate is placed on the first section parallel to the base with two diametrically opposed openings (22,23). A second section with the contact surface is arranged above the plate and electrically connected to the first section via the openings An Independent claim is included for a method of manufacturing a contact piece.

Description

The invention relates to an axial magnetic field contact piece produced in a mold according to the preamble of claim 1 and a method according to the preamble of claim 7.

A method for producing a contact piece for a vacuum chamber is became known, see DE 195 37 657 A1, in which a base body made of electrically good conductive material and a sintered structure made of an electrically less conductive but for this purpose, erosion-resistant material is brought into a bowl-like shape and up to about the melting temperature of the electrically highly conductive material, but still below that Melting temperature of the less electrically conductive material are heated, so that the electrically highly conductive material melts well and into the sintered structure penetrates. The contact piece produced with this is still to be edited, at for example, turn off and continue to be to form a spiral contact piece work.

So that the contact piece can be used as an axial magnetic field contact piece provide a current loop behind the contact piece, the magnetic field of which serves to to apply an axial magnetic field to the plasma in the event of a power cut. The production Axial magnetic field contact pieces usually require a large number of parts.

The object of the invention is to provide an Axialmagentfeldkontaktstück that with few parts is needed and is therefore easy to manufacture, as well as a process for producing them position of this contact piece.

This object is achieved by the characterizing features of the Claims 1 and 7.

According to the invention, in the form or the crucible, the or the cup-shaped is, on the bottom of a first section of electrically highly conductive material see, which forms a coil form and the material is accordingly suitable dividing walls with insulating material. On this first section is a partition plate also placed with insulating material, the two diametrically ge has opposite openings. The die is located above the partition plate Contact area forming second section, the first with the second section is electrically connected through the openings because during the manufacturing process the electrically conductive material of the two sections flows into one another.

The partitions are arranged according to the invention so that they have a circular arc shape have the, between diametrically opposed, radial openings between let yourself be free; close at one end in the opposite direction radially outwardly extending wall sections that extend to the inner wall of the mold pass.

The connections of the two sections are located through the openings of the partition plate in the area of the radial wall sections with which these on the inner wall connect, on the side of the respective wall section that the be adjacent end of the circular arc shape is opposite to the breakthrough.

The partitions and the partition plate can be made of insulating material, e.g. B. from Ke ramic exist; there is also the possibility that the partitions and the partition plate made of sheet steel coated at least on one side with insulating material stand.  

The openings in the partition plate are semicircular and open radially.

To produce such a contact piece, the electrically non-conductive Partitions used in the bowl shape, the partitions perpendicular to the Stand up the crucible or bowl. Electrically conductive between the partitions Material, preferably copper, is inserted on top of this, an electrical separating plate insulating material with two diametrically opposite openings then electrically good conductive material with less electrically conductive, tear-off stem material attached. The unit is then heated to a temperature that above the melting point of the electrically highly conductive material and below the less electrically conductive, tear-resistant material and below the enamel point of the partition walls, so that the electrically highly conductive material above and melts below the partition plate and flows into one another through the openings. The electrically good conductive material forms with the less electrically conductive Material is a sintered structure that forms the contact surface.

Copper is preferably used as the material with good electrical conductivity and less electrically as the material ger highly conductive material preferably chromium used, the contact surface is formed by a chrome-copper sintered layer.

With the method according to the invention, an axial magnet is formed in one piece Field contact piece generated in a single operation.

The electrically highly conductive material can be inserted in its entirety as a powder become; there is of course also the possibility of the electrical material the lower Preform the section and the upper section and then in the intermediate space between the partition walls and the crucible wall and above the partition plate to insert.

Using the drawing, in which an embodiment of the invention is shown, the invention and further advantageous embodiments of the invention and further advantages are explained and described in more detail.  

Show it:

Fig. 1 is a sectional view according to section line II of Fig. 2, and

FIG. 2 is a sectional view along the section line II-II of FIG. 1.

The axial field magnetic contact piece, which is designated in its entirety with the reference numeral 10 in FIGS . 1 and 2, comprises a cup-like shape 11 with a bottom 12 and side walls 13 , the inner surfaces of which are provided with a coating 14 of non-wettable material.

On the floor 12 perpendicular to it partitions 15 and 16 are set up, the shape of which is explained below with reference to FIG. 2, which are coated on both sides with a coating 17 and 18 Be made of electrically insulating material. The partitions are made of sheet steel.

In the area between the partitions 15 , 16 and the inner walls of the Be tenwand 13 , a molding 19 is used made of electrically highly conductive material. On the partitions 16 , 17 and the molding 19 , a plate 20 is placed, which consists of the same material as the partitions 15 , 16 and which is also coated on both sides with a coating 21 of insulating material. The partition plate 20 with the coating 21 has diametrically opposite openings 22 and 23 , which are shown in dashed lines in FIG. 2 and have a semicircular shape, which are open to the inner wall 13 . A plate-shaped molded body 24 made of electrically highly conductive material is placed on the partition plate 20 and has an axially projecting strip 25 on its peripheral edge, so that a recess 26 is formed into which a powder material 27 made of less electrically conductive material is sprinkled.

By means of the separating plate 20 , two levels 1 and 2 are formed, of which a coil shape is arranged in level 1 , whereas the free end surface of level 2 forms the contact surface 28 of the contact piece.

Fig. 2 shows the shape of the partition walls 15, 16. Each partition has an approximately semicircular section 16 a, at one end of a straight section from 16 b connects, which ends on the inner surface of the wall 13 or the coating. The straight section 16 b does not run purely radially, but forms an obtuse angle α with the outer surface of the circular section 16 a.

In the same way, the partition 15 has an arcuate section 15 a, which is followed by a rectilinear section 15 b. The shape is the same as that of the partition 16 . Between the free ends of the arcuate sections 15 a and 16 a, radial openings 29 and 30 are left free, so that the part 31 of the electrically well-conductive material located between the arc sections 16 a and 15 a with the parts 32 and 33 outside the partition walls 16 and 15 material located in connection.

The electrically highly conductive material in level 1 can be formed by a preformed shaped piece that has slots that accommodate the partitions 15 and 16 ; there is also the possibility of filling the space between the partition walls 15 and 16 and the inner surface of the wall 13 or the coating 14 with powder made of electrically highly conductive material.

After the raw part has been produced, the raw part is introduced into a vacuum oven and heated therein to a temperature which is above the melting temperature of the electrically highly conductive material, but below that of the less electrically conductive material than in the layer 27 , and of course the partition walls 15 and 16 and the corresponding coatings 17 , 18 and 14 do not melt.

The electrically highly conductive material in level 1 is in mechanical connection via the openings 22 , 23 with the electrically highly conductive material in level 2 , since this penetrates through these openings 22 , 23 by melting.

After cooling, the contact piece is drilled with a 10 bore 34 from the bottom side, in which a contact piece carrier can be inserted 35th

It is still to be added that the openings 22 and 23 are in the areas that are outside the partition 16 and 15, respectively, in the vicinity of the linear sections from 16 b and 15 b. This gives an electrical current flow I ₁ from the contact piece carrier 35 on the one hand through the opening 30 to the opening 22 and from there into the level 2 and on the other hand a current flow 12 through the opening 29 to the opening 23 and from there also into the second level , so that a double coil is formed by the two current flows I ₁ and I ₂ , which generates an axial magnetic field.

This axial magnetic field causes that between two opposing Contact arcs generated is a diffuse arc.

Copper is preferably used as the electrically highly conductive material and chromium is preferably used as the less electrically conductive material. There is a Cu / Cr sintered layer in the layer 27 , which has good tear resistance.

The contact piece according to Figures 1 and 2 can be produced in a simple manner in a unitary Chen operation; Subsequent processing is only the production of the bore 34 and a possibly flat turning of the contact surface 28 .

The bowl shape or the crucible 11 can be made of sheet steel, the loading coating 14 made of insulating material could allow removal of the finished contact piece from the bowl shape 13 .

The partitions 15 , 16 , which are axially aligned, are made of sheet steel and have a coating on both sides, as is the partition plate 20 ; there is of course also the possibility that the partitions and the partition plate are made of thin-walled ceramic.

The method for producing the contact piece 10 proceeds as follows:
The dividing walls 15 , 16 are inserted into the crucible 11 provided with the coating 14 , the area between the dividing walls and between the dividing walls and the inner surface of the wall 13 is filled with copper powder or one or more pre-punched or preprocessed shaped pieces are used. Then the partition plate 20 is placed on and the area above the partition plate is filled with copper-chromium powder in a suitable manner; it can also be a prefabricated molded part 24 with the recess 26 ; A prefabricated sintered body made of chromium or chromium-copper can also be inserted into the recess or the recess can be filled with chromium powder or chromium-copper powder.

The materials are only given as examples. Of course there is the possibility ability to use all types of suitable materials.

Claims (7)

1. In a crucible produced axial magnetic field contact piece for a vacuum chamber, with a contact surface ( 28 ) forming section, characterized in that in the crucible ( 11 ) on the bottom ( 12 ) a first section ( 19 ) made of electrically good conductive material is provided which contains a coil-shaped partition walls with insulating material oriented perpendicular to the floor, that a partition plate ( 20 ) with insulating material which runs parallel to the floor and has two diametrically opposite openings ( 22 , 23 ) is placed on the first section, and that is located above the separating plate ( 20 ) of the second section having the contact surface ( 28 ), the first being electrically conductively connected to the second section via the openings ( 22 , 23 ). 2. Contact piece according to claim 1, characterized in that the partitions ( 15 , 16 ) have a diametrically opposite radial openings ( 29 , 30 ) leaving circular arc shape ( 15 a, 16 a) and that at each end of the circular arc men ( 15 a , 16 a) connect oppositely directed, approximately radial wall sections ( 15 b, 16 b) which extend to the inner wall of the wall ( 13 ) of the crucible ( 11 ). 3. Contact piece according to claim 1 or 2, characterized in that the United connection of the two sections through the openings ( 22 , 23 ) of the partition plate ( 20 ) in the connection region of the wall sections ( 15 b, 16 b) are on the side of Wall sections ( 15 b, 16 b), the opposite end of the circular arc shape ( 16 a, 15 a) of the other partition with the opening ( 29 , 30 ) opposite. 4. Contact piece according to one of the preceding claims, characterized in that the partition walls ( 15 , 16 ) and the partition plate ( 20 ) made of insulating material, for. B. made of ceramic. 5. Contact piece according to one of claims 1 to 3, characterized in that the partition walls ( 15 , 16 ) and the partition plate ( 20 ) consist of sheet steel coated at least on one side with insulating material. 6. Contact piece according to one of the preceding claims, characterized in that the openings ( 22 , 23 ) are semicircular and open towards the edge. 7. The method for producing a contact piece according to one of claims 1 to 6, characterized by the steps

• - inserting electrically non-conductive partitions into a cup-shaped crucible, to form a coil shape,
• - inserting electrically highly conductive material into the spaces between the partitions and the partitions and the cylinder wall of the crucible,
• - placing a partition plate made of electrically insulating material with two diametrically opposite openings,
• - placing electrically conductive material on the partition plate,
• - placing less electrically conductive material on the free surface,
• - Heating to a temperature which is above the melting point of the electrically highly conductive material and below the melting point of the less electrically conductive material and the partition walls and the partition plate.