EP1581671A1 - Cathode systems for electrolytically obtaining aluminium - Google Patents

Abstract

The invention relates to cathode systems for electrolytically obtaining aluminium, said cathode systems being divided into at least two parts with different electrical resistances, in the direction of the longitudinal axes thereof on the side of the current supply from the cathode, in such a way that the electrical resistance from the ends of the collector (2) to the part of the edge region of the cathode which faces the collector is equal to at least 1.2 times the electrical resistance from the ends of the collector to the part of the centre of the cathode which faces the collector, either the contact material or the collector being divided into regions (13, 14) with different resistances. The invention also relates to methods for producing said cathode systems and to the use of the same for electrolytically obtaining aluminium.

Description

Cathode systems for electrolytic aluminum extraction

The invention relates to cathode systems for electrolytic Almnim extraction, in particular those with improved service life.

In the electrolytic extraction of metallic aluminum in the Hall-Heroult process, Al ταiniumoxid, dissolved in about 20 times the amount of melted cryolite (Na ₃ [AlF _fi ]) as a flux, at a temperature of about 960 ° C in Electrolysis cells disassembled by direct current (at a voltage of 4 to 5 V and a current of 80,000 to 500,000 A). The liquid aluminum collects on the bottom of the carbon-lined, as

Tub serving the cathode under the melt, which largely protects against reoxidation. The carbon electrodes acting as an anode (block or Söderberg anodes) are gradually used up by the released oxygen.

Suitable electrolytic cells usually consist of a steel tub, which is covered on the inside with a heat-insulating material. The bottom of the electrolytic cells consists of several cathode blocks arranged in parallel on the insulating material, the joints of which are sealed to one another and to the edge with ramming compounds made from mixtures of carbon granules and coal tar or coal tar pitch. The material for the cathode blocks mostly consists of anthracite (recently also graphite or coke or their mixtures with anthracite), which is calcined at 1200 ° C or higher, then ground and classified according to the particle size. A suitable particle size fraction is mixed with pitch and formed into blocks. The binding pitch is then converted at elevated temperature to a material consisting essentially of carbon. Thereby, graphitized (treatment at approx. 3000 ° C), so-called "semi-graphitized" (treatment at approx. 2300 ° C), so-called "semi-graphitic" (graphitic particles, but treatment of the block at approx. 1200 ° C), and Amorphous blocks (particles are not or only partially graphitized, treatment of the block at approx. 1200 ° C) is differentiated.

The atomic discharge from the liquid electrolyte and the one covering the floor

Aluminum melt takes place through steel bars or collectors, which are connected to the cathode blocks in an electrically conductive manner. In the case of the cathode blocks, too, a consumption of the material by removal is observed, which determines the service life of the electrolysis cell; this is usually 1500 to 3000 days. The removal is not uniform over the length of the cathode blocks, but one observes, particularly with graphitized cathode blocks, two maxima of the removal near the side stones, and a minimum in the middle of the length of the cathode blocks (W-shaped profile). Due to the uneven removal, the useful life is determined by the places of the largest removal.

The useful life of the cathode blocks has been the subject of numerous studies.

M. Serlie and H.A. 0ye have in J. Appl. Electrochemistry 19 (1989), pp. 580 to 588, systematically reports on the various effects on the cathode materials, seals and side stones and their effects on the service life.

EP-A 0 284 298 describes improved sealing materials for connecting the

Cathode blocks described. They are less prone to cracking than known sealing materials and thus reduce the risk of failure. However, this measure does not change the non-uniform abrasion over the length of the block.

In WO-A 97/48838 and in Aluιxιiniuιτι 72, 1996, Issue 11, pages 822 to 826, the

Improvement of the current transfer between the (here plate-shaped) steel collectors and the cathode described by using contact pins in the interface. Attaching these contact pins and working out the recesses on the opposite side are, however, associated with considerable effort.

WO-A 00/46426 describes a one-piece graphite cathode block which has different specific electrical resistances parallel to the longitudinal axis, the resistance near the ends of the block being higher than in the middle. This differentiation is achieved by different heat treatment in the graphitization, namely the use of temperatures from 2200 to 2500 ° C in the area of the ends, and 2700 to 3000 ° C in the area of the center of the cathode blocks. Such different temperatures can be achieved through poor insulation of the graphitization furnaces. Another possibility is to choose the current density differently during the graphitization, and thus the to distribute the Joule heat generated unevenly over the cathode block to be graphitized. While the former possibility has to be discarded for economic reasons, the second possibility requires an additional effort in the production in the graphitization step, which has to be optimized for the special cathode shape.

Another embodiment of a cathode with an improved service life is described in WO-A 00/46427. Here, a graphite cathode is impregnated with a carbonizable substance under reduced pressure at elevated temperature, the temperature and time having to be chosen so that the substance is sufficiently fluid to fill the pores of the cathode, and then the impregnated cathode is at a Temperature below

Carbonized at 1600 ° C. Additional work steps are therefore required in the production of the carotid artery.

Finally, WO-A 00/46428 describes a graphite cathode whose specific electrical resistance in the direction perpendicular to its longitudinal axis is higher than that in FIG

Direction of the longitudinal axis. This difference in resistance is achieved by using different materials to make the cathode, at least some of which are anisotropic, and by making them under conditions that favor the orientation of particles, such as extrusion or vibratory compaction. This procedure requires special (additional) materials as well as adapted manufacturing processes.

All of the measures mentioned thus imply special additional effort in the production of the cathodes.

There is therefore the task of making the removal of the cathode blocks as uniform as possible over the length of the blocks by simple measures. In particular, it is desirable to keep the manufacturing process for the cathodes uniform in order not to unnecessarily increase the diversity in production.

The task is solved by dividing the power dissipation from the

Carbon cathode in multiple zones. This can be achieved by dividing the contact mass or tamping mass effecting the electrical connection between the cathode and the collectors into several zones in which material with different conductivity or different electrical resistance is used, or by multi-part design of the steel bars or collectors.

The invention therefore relates to cathode systems for electrolytic aluminum production, characterized in that they are arranged in the direction of their long axis on the

Side of the current leads from the cathode to the collector are divided into at least two parts with different electrical resistance, so that the electrical resistance from the free ends of the collector to the part of the edge zone of the cathode facing the collector is at least 1.2 times the electrical resistance from the free ends of the collector to the part of the center of the cathode facing the collector. Either the contact mass or the collector are divided into zones of different resistance.

Cathode system is understood here to mean the combination of the cathode block, the collector and the contact or ramming mass, which brings about the electrical contact between the cathode block and the collector.

One way of realizing the solution according to the invention is to use different materials with different contact resistance between the collector and the carbon material of the cathode along the length of the cathode systems. Another way of realizing this is to use multi-part collectors, the material and line cross section of the collector parts being chosen according to the desired resistance between a given (melt-facing) point of the cathode block and the free end of the collectors.

Further objects of the invention are methods for contacting cathodes and collectors by at least two different contact or ramming masses in terms of their electrical conductivity, methods for producing suitable collectors with the multi-part structure described, and the use of different contact or ramming masses or multi-part collector filling forms in cathode systems for the electrolytic extraction of metallic aluminum. The contact or ramming mass serves both the mechanical strength of the combination of collector and cathode and the electrical contact between these parts of the cathode system. It is customary, for example, to pour the gap between the collector and the cathode with cast iron. On the other hand, ramming compounds filled with particulate carbon (anthracite and / or graphite) and / or with metal particles (powder, shot, fibers, whiskers or platelets; in particular made of iron or iron alloys such as steel) are used, their binders tars (especially coal tar) or pitches (especially coal tar pitches). The conductivity or the electrical resistance can be varied by selecting the type (composition, particle size and its distribution) and amount of the filler causing the conductivity. It is also possible to use adhesives, in particular two- or multi-component adhesives, such as those based on epoxy resins or phenolic resins, which are also adequate by adding particulate metal and / or carbon in the form of anthracite and / or graphite powders Maintain conductivity in the desired degree.

At least two different contact masses are preferably used for contacting cathodes and collectors, the boundary between zones of different materials running perpendicular to the long axis of the collectors. The contact resistance between the collector and the cathode is in the middle of the length of the cathode. Mine is the contact resistance in the region of the ends of the cathode.

It is further preferred that the contact mass is cast iron in the region of the center of the cathode length. In the region of the ends of the cathode length, a contact mass is preferably used, which is selected from tars filled with electrically conductive particles, tar pitches, synthetic resins based on epoxy resins and / or phenolic resins, and

Adhesives based on epoxy resins and / or phenolic resins.

Particles of particulate carbon and metal particles in the form of powders, shot, fibers, whiskers and / or platelets are particularly preferred as electrically conductive particles.

Toda et. al., in "Light Metals 1999", ed. by CE Eckert, Warrendale, PA, USA, describes studies on the contact resistance between collector rods and cathode material with two different contact masses of different conductivity. Both investigated masses resulted in a very low contact resistance of less than 0.1 Ω / mm ² . However, there is no indication that contact masses of different conductivity can be used next to each other and that the contact resistance in one zone can be set to be lower than in an adjacent zone.

The division of the contact mass or the collector into zones of different conductivity or different electrical resistance is preferably carried out in such a way that the current density at the point of transition from the cathode to the aluminum melt covering its base is as uniform as possible over the length of the cathode. In the context of the present invention, an embodiment is referred to as “as uniform as possible” in which the current density does not change by more than a factor of 2 over the cathode length. A change by a factor of at most 1.5 is preferred, particularly preferably by a factor of at most 1.3.

Are different contact masses based on adhesives or contact masses

If tars or pitches are used as binders, the recess on the underside of the cathode blocks is preferably filled with the contact masses of different resistance to such an extent that only small amounts emerge when the collector rods are mounted. According to the invention, it is also possible to contact zones by pouring out molten metals, preferably cast iron. The different contact possibilities can also be implemented in succession on the same cathode blocks.

The specific resistance of the selected contact masses can be set in a simple manner by different compositions. The same binders or binder mixtures can be used as a matrix with (depending on type and / or quantity) different ones

Conducting additives are filled; However, it is also possible to vary the binders or cement mixtures depending on the type and amount of the conductive filler in order to achieve a similar processing viscosity and thereby to compensate for the forces acting on the cathode block during assembly. The division of the collectors into zones with different resistance can be carried out in such a way that the collector is divided into pieces of different cross-section, the metals used being the same or different, or into pieces of metals with different conductivity, such as copper and steel. Of course it is it is also possible to vary the cross-section and material of the collector parts at the same time. Because of the mostly different thermal expansion of different metals, it is preferred to realize the desired different resistance by using the same metal and different cross sections. According to the invention, however, it is also possible to use different metals, in which case metal parts with different specific resistance in the direction of the side of the carbon cathode facing the melt are then preferably arranged on a common carrier made of a highly conductive metal (for example copper).

The zones of the collector with different resistance are separated from each other by a flat insulator. Gliminer film is preferred (because of its high thermal stability). The cohesion of collectors assembled in this way is ensured by suitable fastening means, in particular sleeves made of sheet metal.

It is also possible to do without such fasteners if a structure is selected in which a metal bar made of a good electrically conductive material is covered with an insulating film and a sleeve made of poorly conductive material. This covering is carried out so far that the bar in the middle of the length of the cathode system is directly connected to the carbon cathode. In the outer area, i.e. towards the ends of the cathode system, the electrical connection is made exclusively via the sleeve.

In all cases, it is possible to use two collector half-bars or one continuous collector, the continuous collector and the half-bars being suitably divided into zones of different resistance.

The preferred embodiments of the invention are illustrated by the drawings. Show

1 shows a longitudinal section through a cathode system with two contact masses of different resistance; and

2 shows a cross section along the line II-II 'through a cathode system with a

Collector connected to the cathode by a contact ground; and a cross section along the line III-III 'through a cathode system with a

Collector connected to the cathode at this point by casting with cast iron; and

a longitudinal section through a cathode end, in which the collector (steel support) can be seen in two parts; and

a longitudinal section through a cathode end in which the collector is made of different metals of different conductivity; and

a longitudinal section through a cathode end, in which the collector (steel support) can be seen in two parts, and in which the execution of the insulation with rectangular fitting is shown enlarged; and

an alternative embodiment to that shown in FIG. 6, here with a sloping angle fit; and

a longitudinal section through a cathode with a three-part collector; and

the cross section through a collector divided into two zones, the parts of which are mechanically and electrically insulated connected by a sleeve; and

a cross section of the embodiment shown in Figure 4 along the line X-X '; and

a cross section of the embodiment shown in Figure 4 along the line XI-XT. and

a cross section through a collector divided into two zones, the

Zone with higher resistance is designed in the form of a sleeve. 1 shows a longitudinal section through a cathode system with conventional collector rod 2, which is connected to the cathode 1 via two contact masses 13 and 14 with differing electrical resistance. The contact resistance is from the collector

2 by the contact mass 13 greater than that via the contact mass 14, according to the invention by at least a factor of 1.2, preferably at least 1.5, and in particular at least one

Factor 2. In a preferred embodiment, the material of the contact mass 14 is cast iron, while the material of the contact mass 13 is a tar pitch, synthetic resin or synthetic resin adhesive filled with carbon and / or metal particles.

2 and 3 show cross sections along the lines II-II 'and III-III' from FIG. 1. Also in these cases, the contact masses 13 and 14 are chosen so that there is for the contact resistance between the collector 2 and the cathode 1 at the points of the cuts II-II '(R ^π ) and at the point III-III' (R ^πI ) give the following relationships: _R πι. _R π _ _{1: lj2} to L100; preferably 1: 2 to 1:80, and in particular 1: 5 to 1:60.

4 shows a longitudinal section through a cathode 1 with collector 2, the material

3 of the cathode is selected from graphite, semi-graphitic, semi-graphite and amorphous carbon, with graphite cathodes being preferred because of their better conductivity. In this embodiment, the collector consists of two zones 4 and 5, which have different electrical resistances due to their different cross-sections. The materials 4 and 5 can be the same or different. The two zones 4 and 5 are electrically separated from one another by an intermediate layer 6 of an insulating material which must survive the operating temperature of the cathode of approximately 960 ° C. without damage. Mineral insulating materials such as Glimn discs are preferred. The required mechanical strength is achieved in this embodiment in that the zone 4 with the higher conductivity also has the larger cross section. In a further preferred embodiment, it is possible to mechanically connect parts 5 and 4 of the collector to one another without electrically connecting them.

For this purpose, for example, as shown in FIG. 9, a sleeve 15 made of a metal band, for example a steel band, can be attached around the collector made of parts 4 and 5, the sleeve 15 being insulated from collector parts 4 and 5 by an insulator 6 ', for example a mica liner is insulated. Parts 4 and 5 of the collector are electrically separated from one another by an insulating intermediate layer 6. The tensioning device for the cuff is not shown in this drawing.

Another embodiment of the invention with a multi-part collector 2 is shown in FIG. 5, the collector being composed of a thin plate 11 of a metal with a low resistance, such as copper, and two thicker plates 9 and 10 of a metal with a higher resistance, however also higher strength and rigidity, such as steel. The plate 11 is electrically insulated from the plate 9, but is conductively connected to the plate 10. As a result, the resistance on the way from the contact at the end 12 of the collector to the contact zone between the plate 10 and the cathode is lower than that

Resistance on the way from the contact at the end of the collector 12 to the lead-in zone of the plate 9 and the cathode 1. The specific electrical resistance of the materials of the plates 9, 10 and 11 and their geometry (cross-sectional area) is chosen in accordance with the above statements that the resistance from the end 12 of the collector to the contact zone of the cathode 1 and the plates 10 and 9 has a ratio of at least 1: 1.2, in particular this is

Ratio of the resistors chosen so that the current density in the transition from cathode 1 to almrinium melt in the bottom of the cell is as uniform as possible. In this embodiment too, the plates 9, 10 and 11 are mechanically connected to one another, as is shown in principle in FIG. 9.

As even as possible is understood to mean that the ratio of the current density in the peripheral zone to the current density in the central zone of the cathode 1 is not more than 2: 1, preferably not more than 1.5: 1, and particularly preferably not more than 1.2: 1.

6 and 7 are alternative embodiments of the insulation in the case of a two-part

Collector 2 shown: in Fig. 6, the collector part 4 has a right-angled recess, while in Fig. 7 the recess in part 4 has an obtuse angle. This embodiment according to FIG. 7 has proven to be advantageous for the introduction of the insulating intermediate layer 6. In a further preferred embodiment, which is not shown, it is also possible to round the angle in such a way that a platelet-shaped mineral insulator such as

Mica does not break. 8 shows a structure of a cathode system with a cathode 1, the current being dissipated via a collector 2. In this embodiment, the collectors 2 are each composed of three parts or zones 5, 7 and 8, the sleeves again not being shown for reasons of clarity.

The resistors in the embodiment with collectors with three zones of different electrical resistance according to FIG. 8 from the end 12 to zone 5 (= R _12/5 ), from the end 12 to zone 7 (= R _12/7 ) and from that End 12 to zone 8 (= R _12/8 ) preferably behave as shown in the following table:

When assembling the collector and cathode block, care must be taken that the StiOm discharge in the area with several collector zones according to that in FIG. 4

(Longitudinal section) and FIG. 9 (cross section) shown embodiment takes place only over the collector zone facing the cathode.

For this purpose, a flat insulator, for example a mica foil, is inserted on both sides of the collector according to the length of the divided zones, so that no electrical

Connection of the cathode to the zone of lower resistance of the collector in this area is present. FIG. 10 shows a corresponding structure (section XX 'in FIG. 4), in which isoher foils 6 "and 6"' are inserted on both sides of the collector in the region of the divided zones, and which is in position by the ramming sleeve 13 can be fixed. Otherwise, the ramming mass effects the electrical contacting (here between zone 5 and the cathode) and the fixing of collector 2 and cathode 1 in a known manner. In the area of the section XI-XI 'in FIG. 4, which is shown in FIG. 11, such insulation on the side is naturally no longer necessary. Therefore, the contact resistance between the cathode 1 and the collector 2 via the ramming mass 13 is also considerably lower in this area because of the larger contact area, which also serves to increase the current density in this area.

If the collectors are divided into more than two zones, insulation must also be carried out on the sides. The need for insulation on the sides can be avoided if the zone of higher resistance in the collector is not designed as a plate facing the cathode, but in the form of a sleeve which encloses the collector at least as far as the

There is contact via the ramming mass. An embodiment of this type is shown in cross section in FIG. 12, the inner part 4 of the collector 2 being surrounded on three sides by a sleeve 5 of higher resistance. Here insulation 6 is only required inside the collector; the lower effort in the assembly of the collector contrasts with the increased construction effort of this form, depending on the circumstances of the

ZelUconstruction one or the other form of execution is preferable.

Examples:

example 1

Graphite cathodes of conventional design with a length of 3300 mm were equipped with conventional steel supports as collectors and were connected with different resistance by introducing rammers. The specific resistances of the ramming masses in the area near the edge compared to those in the center area were 5: 1. An electrolysis cell equipped in this way with 20 cathode blocks was operated for 1000 days with a current of 220 kA and 4.4 V. As a comparison, cells were operated with the same cathode system, using a uniform ramming mass.

After the indicated running time, the cells were emptied and disassembled, and the cathodes were examined for wear. While in the cathodes of the comparison set-up, the removal was approximately 7.5 cm in both edge zones, and the removal in the middle of the cathode single 2.5 cm, only a removal of approx. 4 cm could be measured in the embodiment according to the invention in the edge zones, whereas a removal of approx. 3.5 cm was measured in the middle.

Example 2

Graplήt cathodes of conventional design with a length of 3300 mm were equipped with conventional steel supports as collectors and connected in the usual way by introducing a ramming compound. An electrolysis cell with 20 cathode blocks was operated for 1000 days with a current of 220 kA and 4.4 V (comparison). According to the invention, the same cathodes were connected to steel supports according to 2 in FIG. 4, the ends of which were milled to a distance from the end of the cathode of approximately 700 mm to 5/6 of their original thickness. The transition to the unprocessed central zone was carried out according to FIG. 7 at an angle of approximately 160 °. The milled surface was covered with a GlimrnerfoHe 6 with a thickness of approx. 0.3 mm

A steel plate 5 of suitable dimensions is fastened to the carrier with the aid of cuffs which are insulated with geothermal elements according to FIG. 9.

The steel beams or connectors were insulated according to the structure shown in FIG. 4 by inserting mica foils on both sides as far as the multi-part zone of the

Collector was enough, and mounted with a conventional ramming compound with the cathode.

After the specified running time, the toes were emptied and dismantled, and the cathodes were examined for wear. While in the cathodes of the comparison set-up, the removal in both edge zones was approx. 8 cm, and in the middle of the cathode the removal was only high

2 cm, in the embodiment according to the invention, only a removal of 3.5 cm could be measured in the edge zones, whereas a removal of approx. 3 cm was measured in the middle.

It was found that such cathode systems according to the invention result in a considerably more uniform removal of the cathodes with a significant reduction in the removal in the

Border zone could be reached. Since the useful life of the cathode is limited by the location of the greatest removal, the use of cathode systems results in the invention significantly extends the life of the cathodes in a simple and inexpensive manner.

-oOo-

LIST OF REFERENCE NUMBERS

1 cathode

2 collectors

3 Material of the cathode (graphite, semi-graphitic, semi-graphitized or amorphous carbon

4 collector zone with higher electrical conductivity than zone 5

5 collector zone

6, 6 ', 6 ", 6'" insulating intermediate layer

, 8 KoHektorzonen

, 10 metal plates with high electrical resistance

1 metal plate with low electrical resistance

2 end of the collector

3 ramming mass

4 cast iron

5 cuffs made from a metal band

-o-o-o-

Claims

claims

1. Cathode systems for the electrolytic Al niniumgewein comprising carbon cathodes and KoUectors, characterized in that the cathode systems in the direction of their long axis on the side of the Sttomabzüge from the cathode to

CoUector are divided into at least two parts with different electrical resistance, such that the electrical resistance from the ends of the CoUector to the part of the cathode facing the CoUector at the ends of the cathode is at least 1.2 times the electrical resistance from the ends of the CoUector to the part facing the coUector is in the middle of the length of the cathode, the thinning of the cathode system differing in at least two parts by electrical resistance by using different contact masses between the coUector and cathode and / or by dividing the coUector in the direction of its long axis on the side of the stiOm exhausts is reacted in the cathode in at least two parts of different electrical resistance.

2. Cathode systems according to claim 1, characterized in that at least two different contact masses are used for contacting cathodes and cojectors, the boundary between zones of different contact masses running perpendicular to the long axis of the cojectors, and that the contact resistance between the coUector and cathode is in the middle the length of the cathode is smaller than the contact resistance in the region of the ends of the cathode.

3. Cathode systems according to claim 2, characterized in that i the area of the center of the cathode length is the contact mass cast iron.

4. Cathode systems according to claim 2, characterized in that in the region of the ends of the cathode length, a contact mass is used, which is selected from with electrically conductive particles, tars, tar pitches, synthetic resins based on epoxy resins and / or phenolic resins, and adhesives based of epoxy resins and / or phenolic resins.

5. Cathode systems according to claim 4, characterized in that the electrically conductive particles are selected from particulate carbon and MetaUteUchen in the form of powders, shot, fibers, whiskers and / or platelets.

6. Cathode systems according to claim 1, characterized in that the KoUectors in the direction of their long axis on the side of the StioiTiabführung in the cathode in at least two parts with different electrical resistance, so that the electrical resistance from the ends of the CoUektor to the at the end of the cathode adjacent zone of the KoUektor at least 1.2 times the electrical resistance of the ends of the

CoUectors up to the zone of the KoUector adjacent to the center of the cathode.

7. Cathode systems according to claim 6, characterized in that the metallic material of the coUector is uniform, and the coUector is divided into mutually isoHert zones with different cross sections.

8. Cathode systems according to claim 6, characterized in that at least two different MetaUe are used to build the KoUektor.

9. Cathode systems according to claim 6, characterized in that a zone of

KoUectors with higher resistance is designed in the form of a plate which faces the cathode side.

10. Cathode systems according to claim 6, characterized in that a zone of the KoUektor is designed with higher resistance in the form of a sleeve which completely covers the side facing the cathode and the surfaces of the KoUektor touched by the cathode.

11. Cathode systems according to claim 6, characterized in that the KoUektor on the surfaces facing the cathode and from zones of different resistance to

Contacting the KoUektor exist, is covered by a flat insulator.

12. A method for the manufacture of cathode systems according to claim 2, characterized in that at least two contact masses of different electrical resistance are introduced into the recess on the underside of the cathode, the electrical resistance of the contact mass in the zone facing the center of the cathode length being lower than that the contact mass of the zone facing the cathode end.

13. A method for the manufacture of cathode systems according to claim 3, characterized in that in the region of the ends of the cathode a contact mass of tars filled with electrically conductive TeUchen, Teerchechen, Kunstiiarzen based on epoxy resins and / or phenolic resins, or adhesives based on epoxy resins and / or phenolic resins is used, and in the area of the center of the cathodes the contact by pouring out

Cast iron is manufactured.

14. A method for the production of cathode systems according to claim 6, characterized in that an angular metal rod is machined on at least one surface facing the cathode, and the resulting depression with a

Metal plate or metal sleeve is electrically insulating and is covered flush with the original size.

15. Use of cathode systems according to claim 1 in the electrolytic extraction of Al ninium-MetaU.

-o-o-o-