EP2673400A2 - Cathode assembly and cathode block having a groove with a guide recess - Google Patents

Abstract

A cathode configuration for an aluminum electrolysis cell has at least one cathode block based on carbon and/or graphite. At least one groove is formed in the cathode block and the groove is lined with a graphite foil, at least in certain regions. At least one busbar is disposed in the groove and has an encasement of cast iron at least in certain regions. At least one recess is formed in the wall of the cathode block that delimits the at least one groove, and the encasement of cast iron engages into the at least one recess, at least in certain portions. A cathode block for such a cathode configuration is provided and also a process for producing a cathode configuration for an aluminum electrolysis cell.

Description

 Cathode arrangement and cathode block with a

 Guide groove having groove

The present invention relates to a cathode assembly for an aluminum electrolysis cell, a cathode block for such a cathode assembly, and a method of manufacturing such a cathode assembly.

Such electrolysis cells are used for the electrolytic production of aluminum, which is usually carried out industrially by the Hall-Heroult process. In the Hall-Heroult process, a melt composed of alumina and cryolite is electrolyzed. The cryolite, Na ₃ [AIF ₆ ], serves to lower the melting point from 2,045 ° C. for pure aluminum oxide to approximately 950 ° C. for a mixture containing cryolite, aluminum oxide and additives such as aluminum fluoride and calcium fluoride.

The electrolysis cell used in this method has a bottom composed of a plurality of adjacent cathode blocks forming the cathode. In order to withstand the thermal and chemical conditions prevailing in the operation of the cell, the cathode blocks are usually composed of a carbonaceous material. In each case, grooves are provided on the lower sides of the cathode blocks, in each of which at least one bus bar is arranged, through which the current supplied via the anodes is removed. The gaps between the individual walls delimiting the grooves of the cathode blocks and the busbars are often poured with cast iron in order to electrically and mechanically connect the busbars to the cathode blocks through the cast iron busbars produced thereby. About 3 to 5 cm above the top of the cathode located on the molten aluminum layer is formed of individual anode blocks anode, between the and the surface of the aluminum, the electrolyte, So the melt containing alumina and cryolite is located. During the electrolysis carried out at about 1000 ° C., the aluminum formed is deposited below the electrolyte layer due to its greater density compared to that of the electrolyte, ie as an intermediate layer between the upper side of the cathode blocks and the electrolyte layer. During electrolysis, the aluminum oxide dissolved in the cryolite melt is split by the flow of electrical current into aluminum and oxygen. Electrochemically, the layer of molten aluminum is the actual cathode because aluminum ions are reduced to elemental aluminum on its surface. Nevertheless, the term cathode will not be understood below to mean the cathode from an electrochemical point of view, ie the layer of molten aluminum, but rather the component forming the electrolytic cell bottom and composed of one or more cathode blocks.

A major disadvantage of the cathode assemblies used in the Hall-Heroult method is their relatively low wear resistance, which manifests itself by a removal of the cathode block surfaces during the electrolysis. In this case, the removal of the cathode block surfaces due to an inhomogeneous current distribution within the cathode blocks is not uniform over the length of the cathode blocks, but to an increased extent at the cathode block ends, so that the surfaces of the cathode blocks change after a certain electrolysis time to a W-shaped profile. Due to the uneven removal of the cathode block surfaces, the service life of the cathode blocks is limited by the places with the largest removal.

In order to counteract this problem, WO 2007/1 18510 A2 proposes a cathode block whose groove, which is intended to receive a conductor rail, has a greater depth in the middle, relative to the cathode block length, than at the cathode block ends. As a result, in the operation of the electrolysis cell over the cathode block length is a substantially homogeneous vertical Power distribution is achieved, whereby the increased wear on the cathode block ends is reduced and so the life of the cathode is increased.

Another disadvantage of the cathode arrangement used in the Hall-Heroult process is its comparatively high electrical resistance. One of several reasons for the comparatively high electrical resistance is that the contact resistance between the bus bars and the cathode blocks of the cathode is comparatively high, and this contact resistance also increases with increasing service life of the cathode. The reason for this is, on the one hand, that undesired melt constituents diffuse into the cathode blocks during the electrolysis, which leads to the formation of insulating layers of, for example, β-aluminum oxide, and, on the other hand, that the steel of the busbars, the cast iron and the carbon of the cathode blocks become longer Stress begin to crawl, ie The steel of the busbars, the cast iron and the carbon of the cathode blocks irreversibly deform after prolonged use.

In order to reduce the electrical contact resistance between the busbars and the cathode blocks and thus to increase the energy efficiency of the electrolysis process, it has been proposed in WO 2007/071392 A2 to line the groove of a carbon or graphite-based cathode block at least in regions with a graphite foil. Apart from the fact that the graphite foil reduces the electrical contact resistance between the busbar or the surrounding layer of solidified cast iron and the cathode block due to their good two-sided positive locking, the graphite foil due to their elasticity in particular reduces the increase of this contact resistance with increasing operating time of the cathode, because the graphite foil filling gaps formed between the walls of the cathode block and the bus bar during the creeping of the steel of the bus bar and the carbon of the cathode block. However, graphite foils have a smooth and very lubricious surface. Therefore, in a cathode block whose groove is lined with a graphite foil, there is a fear that the busbar accommodated therein, which is usually several meters long and several hundred kilograms heavy, subsequently shifts uncontrollably in the groove in the groove direction or even out the groove falls out when, for example, the cathode block is raised during its mounting or moved for some other reason. This danger exists in particular with a rectangular cross-section groove, which is practically the only applicable form for the groove of a cathode block with variable groove depth over its length. In addition, by slipping the busbar in the groove of the exact fit between the groove and the cast iron is lost, resulting in a poorer current transition from the busbar to the cathode block and thus to a decrease in energy efficiency. Finally, graphite foil is not or only to a very limited extent connectable with cast iron, so that a pouring of the gap between busbar and graphite foil with liquid cast iron and a subsequent hardening or solidification of the cast iron not to a compound of graphite foil with the cast iron, but only a cladding of the busbar with cast iron leads.

It is therefore an object of the present invention to provide a cathode assembly for an aluminum electrolytic cell of the type mentioned, which has a low and especially over a prolonged electrolysis period permanently low electrical resistance and in particular low contact resistance between the busbar and cathode block, and at the unwanted subsequent displacement of the busbar in the groove of the cathode block perpendicular to the longitudinal direction of the cathode block, ie in the depth direction of the groove, and in particular falling out of the busbar from the groove is reliably prevented, in particular even with a groove having a rectangular cross-section, as is commonly used in cathode blocks with over the cathode block length varying groove depth.

According to the invention, this object is achieved by a cathode arrangement for an aluminum electrolysis cell having at least one cathode block based on carbon and / or graphite, which has at least one groove lined at least in regions with a graphite foil, wherein at least one bus bar is provided in the at least one groove, which at least partially has a casing made of cast iron, wherein in the at least one groove bounding wall of the cathode block at least one recess is provided and engages the casing of cast iron at least partially into the at least one recess.

This solution is based on the recognition that a precisely fitting and in the direction perpendicular to the longitudinal direction of the cathode block displacement positive connection of a busbar with a graphite foil lined groove having cathode block is achieved if provided in at least one groove defining wall of the cathode block at least one recess is introduced and at least partially covered with cast iron busbar so in the groove that the casing of cast iron engages at least partially into the recess. According to the invention, it has been recognized that in this way, regardless of the high lubricity of the graphite foil used, a firm mechanical connection between the busbar covered busbar and the cathode block perpendicular to the longitudinal direction of the cathode block is achieved, the unwanted displacement of the busbar in this direction and in particular a Falling out of the busbar from the lined with graphite foil groove counteracts, especially in a groove with a rectangular cross-sectional shape, as this for cathode blocks with a varying over the cathode block length Groove depth is preferred. Thus, the cathode assembly according to the invention has the advantage of improved current transfer between the bus bar and the cathode block and thus improved energy efficiency due to the electrical and mechanical properties of graphite foil with the lining of the groove with graphite foil, while avoiding the associated with the high lubricity of graphite Disadvantage of an uncontrolled mobility of the busbar in the groove in the direction perpendicular to the longitudinal direction of the cathode block and a concomitant possible impairment of the electrical connection between the busbar and the cathode block during prolonged operation of the electrolysis cell.

In addition, the present invention makes it possible to use the lubricious properties of the graphite foil specifically to selectively ensure a longitudinal displacement of the busbar in the groove, especially in movements caused by temperature changes during startup.

Moreover, the cathode arrangement according to the invention with the advantages described above can be produced with extremely little effort and without expensive additional process steps. Thus, the proposed mechanical connection between the busbar and the cathode block can be achieved simply by filling a depression of the cathode block at least partially with the cast iron in the course of the already required potting of the busbar with the cast iron. As a result, a very intimate contact between the busbar, the casing of cast iron, the graphite foil and the cathode block is achieved, which contributes to a particularly low electrical contact resistance between the busbar and the cathode block. In addition, the graphite foil absorbs the mechanical pressure occurring during the operation of the cathode arrangement perpendicular to the film plane. In the context of the present invention, a recess is defined as a recess, in contrast to a mere surface roughness, which has a depth of at least 0.05 mm, and preferably 0.5 mm, relative to the surface of the wall delimiting the groove.

In addition, a graphite foil in the sense of the present invention does not only mean thin graphite sheet, but in particular also a partially compressed preform or a flexible sheet of expanded graphite.

In the context of the present invention, a cathode arrangement is understood to mean a cathode block having at least one groove, wherein in each of the at least one groove at least one conductor rail possibly having a cast iron envelope is accommodated. Likewise, this term refers to an arrangement of several, each having at least one groove having cathode blocks, wherein in each of the at least one groove at least one possibly a cast iron casing having bus bar is added.

In principle, the casing of cast iron can be in direct contact, at least in the region of the depression, with the graphite foil or with the cathode block itself. Although this is preferred according to the present invention, this is not mandatory. To produce the desired mechanical connection between the conductor rail and the cathode block, it is primarily important that the casing of cast iron at least partially engages in the at least one recess, so at least partially fills the cavity formed by the at least one recess.

According to a preferred embodiment of the present invention, the portion of the cast-iron casing, which engages in the at least one depression, is designed to be complementary to the depression. In this way, a particularly good form-locking engagement of the cast iron casing in the depression and thus a particularly effective mechanical attachment of the cast iron casing and the associated busbar to the cathode block can be achieved.

In order to achieve a particularly good fit between the cast iron envelope and the cathode block, it is proposed in development of the invention that the at least one recess engaging portion of the envelope and possibly the sheathed busbar at least 70%, preferably at least 80%, especially preferably at least 90%, most preferably at least 95% and most preferably 100% of the well fills. Thereby, an unwanted displacement of the busbar in the direction perpendicular to the longitudinal direction of the cathode block and in particular falling out of the busbar from the groove can be particularly reliably avoided.

Advantageously, each of the at least one recess extends continuously over at least 20%, preferably over at least 40%, more preferably over at least 60%, most preferably over at least 80% and most preferably at least approximately over the entire length of the groove. In this way, a possible slipping out of the busbar can be prevented from the groove during assembly. In addition, when the recess extends over a considerable part of the groove length as described above, good slidability of the bus bar in the longitudinal direction of the groove can be ensured while still reliably preventing unwanted displacement of the bus bar parallel to the depth direction of the groove.

In principle, the cathode block can also have a multiplicity of depressions which follow one another in the longitudinal direction of the groove and which are separated from one another by depression-free sections of the groove. This embodiment is particularly especially advantageous if a longitudinal displacement of the busbar in the cathode block is not desired.

In order to ensure a reliable anchoring of the cast iron casing and the bus bar in the cathode block, the at least one depression preferably has a depth of 2 mm to 40 mm, more preferably 5 mm to 30 mm and most preferably 10 mm to 20 mm.

For the same reason, the at least one recess preferably has an opening width of 2 mm to 40 mm, particularly preferably 5 mm to 30 mm and very particularly preferably 10 mm to 20 mm, based on the height of the cathode block.

It follows that the at least one depression in cross-section preferably has an area of 1.5 mm ² to 1.600 mm ² , particularly preferably 10 mm ² to 900 mm ² and very particularly preferably 40 mm ² to 400 mm ² , These values are particularly preferred for wells with a polygonal and especially with a rectangular cross-section. If the at least one depression has a curved cross section, such as a substantially semicircular cross section, the at least one depression in cross section preferably has an area of 1.5 mm ² to 630 mm ² , particularly preferably 10 mm ² to 350 mm ² and most preferably from 40 mm ² to 160 mm ² .

In principle, the at least one recess can have any polygonal or curved cross section. Good results in terms of a good positive engagement of the cast iron casing in the at least one depression and at the same time with regard to a reliable and unproblematic Füllbarkeit- the recess with cast iron during the casting are achieved in particular if the at least one depression has an at least substantially semicircular, triangular, rectangular or trapezoidal cross-section.

In a development of the concept of the invention, it is proposed that the at least one recess extends substantially perpendicularly into the wall of the cathode block delimiting the groove. In this way, a particularly reliable fixing effect in the depth direction of the groove is effected.

According to the present invention, the at least one depression, viewed in the depth direction of the groove, is delimited at each of its ends by a transitional area between the depression and an adjoining portion of the groove wall. When this transition region is angled, the angle between the adjacent portion of the groove wall and the wall of the depression, viewed from the cathode block inner side, is preferably 90 degrees to 160 degrees, more preferably 90 degrees to 135 degrees, and most preferably 100 degrees to 120 Degree. In the event that this transition region is curved, possibly but not necessarily ideally circularly curved, the radius of curvature of the transition region is preferably at most 50 mm, more preferably at most 20 mm and most preferably at most 5 mm.

According to another preferred embodiment of the present invention, the groove bounding wall comprises a bottom wall and two side walls, each side wall each having at least one, preferably a recess extending perpendicularly to the surface of the respective side wall. In this way, a two-sided mounting of the busbar is achieved in the groove, whereby the busbar is particularly effective in the desired position can be fixed. In principle, in one or in both of the side walls, a plurality of, for example per side wall at least 1, at least 2, at least 3 or at least 4 recesses may be provided, in each of which the enclosure the busbar made of cast iron engages at least in sections. As a result, a particularly strong connection between the busbar and the cathode block is achieved. Preferably, the depth and / or the volume of the individual depressions is lower, the more depressions are provided in the groove.

Preferably, the at least one recess has over its length an at least substantially constant distance to the bottom wall of the groove and extends parallel to this. In such an embodiment, a displaceability of the busbar is ensured parallel to the groove bottom.

According to a further preferred embodiment of the present invention, each of the at least one recess is at least partially and preferably fully lined with the graphite foil, wherein of course preferably also the remaining areas of the groove are fully lined with the graphite foil. This results in the region of the wells, a particularly low electrical contact resistance between the cast iron and the cathode block. In addition, owing to the lubricious properties of the graphite foil, a displaceability of the busbar in the longitudinal direction of the at least one depression and thus in the longitudinal direction of the cathode block as described above can be ensured if a majority of the surface and preferably at least approximately the entire surface of the wall delimiting the groove Graphite foil is lined. The graphite foil can be pressed by the sheathing of the busbar made of cast iron against the boundary of the recess to cause both a particularly good electrical contact and a particularly effective positive locking. This effect is particularly useful when heating the electrolysis cell for commissioning, since the specific thermal expansion of steel or iron is about three times the specific thermal expansion of conventional cathode materials. The lining of the at least one recess of the groove with the graphite foil can be achieved in the manufacture of the cathode assembly in a simple manner that the graphite foil is inserted into the groove so that it fills the depression, and then the cast iron is poured into the groove in that the graphite foil is pressed into the depression and in particular pressed directly there against the cathode block material delimiting the depression.

In order to achieve a vertical current density distribution which is uniform over the cathode block length, it is proposed in a development of the invention that the at least one groove has a varying depth along its length or the length of the cathode block, it being particularly preferred that these be based on the Longitudinal direction, in its center has a greater depth than at its two longitudinal ends. In this way, an even distribution of the electric current supplied via the cathode arrangement is achieved over the entire length of the cathode block, whereby an excessive electrical current density at the longitudinal ends of the cathode block and thus premature wear at the ends of the cathode block is avoided. In this embodiment, the practically unique cross-sectional shape for the groove is rectangular, and therefore the effect of the present invention, namely reliable avoidance of the bus bar falling out of the slot opening, is particularly pronounced here.

Such a uniform current density distribution over the length of the cathode block avoids movements in the aluminum melt caused by the interaction of electromagnetic fields, making it possible to arrange the anode at a lesser height above the surface of the aluminum melt. This reduces the electrical resistance between anode and molten aluminum and increases the energy efficiency of the melt electrolysis carried out. Also, in the above-described embodiment, in which the cathode block has a groove of varying depth, the at least one recess of the cathode block is preferably formed to have a substantially constant distance from the bottom of the groove over the length of the groove so as to have If necessary, to move the busbar along the longitudinal direction of the cathode block.

The cathode arrangement according to the invention is also particularly suitable for the use of conventional groove and / or busbar geometries. For example, the groove and / or the busbar may have a substantially rectangular cross-section in a conventional manner. This is particularly preferred when the groove has a depth varying in the longitudinal direction. The busbar may in particular also consist of steel in a conventional manner.

In a further development of the inventive concept, it is proposed that the graphite foil lining the groove at least in regions contains expanded graphite and in particular preferably compressed expanded graphite, which is particularly preferably binder-free. Most preferably, the graphite foil lining the groove at least regionally consists of expanded graphite and particularly preferably compressed binder-free expanded graphite. As stated above, the film may in principle also be formed by a substantially plate-shaped preform which contains expanded graphite and thereby has sufficient elasticity to be elastically deformed so as to permit the above-described filling of the recess by the cast iron envelope and thereby into the recess between the cast iron and the wall bounding the groove. Preferably, the graphite content of the graphite foil is at least 60%, more preferably at least 70%, particularly preferably at least 80%, particularly preferably at least 90% and very particularly preferably at least approximately 100%.

Good results with regard to optimum utilization of the mechanical and electrical properties of the graphite are achieved, in particular, if the graphite foil has a thickness between 0.2 mm and 3 mm, preferably between 0.2 mm and 1 mm and particularly preferably between 0.3 mm and 0.5 mm.

Depending on the desired properties, the graphite foil can be inserted or glued into the groove. An adhesion of the graphite foil into the groove is particularly preferred if the graphite foil is pressed against the surface of the depression only comparatively little or if even the slightest displacement of the graphite foil in the longitudinal direction of the cathode block is to be avoided.

According to a further preferred embodiment of the present invention, the cathode block has one or two grooves for receiving in each case at least one bus bar. In principle, within the scope of the invention, a groove of the cathode block can accommodate exactly one busbar, but in particular also two busbars which are inserted into different longitudinal sections of the slot. The busbars can be arranged opposite one another on the front side.

Another object of the present invention is a cathode block for a cathode assembly of an aluminum electrolytic cell based on carbon and / or graphite, which has at least one groove for receiving a bus bar, wherein provided in the at least one groove defining wall of the cathode block at least one recess is. Such a cathode block can be used with advantage as part of the previously described cathode arrangement. In this case, the cathode block may be based on amorphous carbon, graphitic carbon, graphitized carbon or any mixture of the above carbons.

Furthermore, the present invention relates to a method for producing a cathode arrangement for an aluminum electrolysis cell, which comprises the following steps:

Providing a cathode block based on carbon and / or graphite, which has at least one groove for receiving a bus bar, wherein at least one depression is provided in the wall of the cathode block bounding the at least one groove,

 Lining at least a portion of the at least one groove with a graphite foil,

 Inserting a bus bar into the at least one groove,

 Filling liquid cast iron into at least a portion of the at least one depression between the graphite foil and the busbar and

 Solidifying the cast iron.

Due to the static pressure of the cast iron column, the graphite foil located in the groove is forced into the at least one depression, where it is pressed against the cathode block defining the at least one depression, in particular. In this way, it is particularly easy to produce a cathode arrangement with a recess which is partially or completely lined by the graphite foil and has a particularly low electrical contact resistance between the conductor rail and the cathode block. When heating the electrolysis cell for commissioning, the different thermal expansion tions of steel or iron and cathode material reaches a particularly intimate contact.

The graphite foil can be inserted and / or glued into place prior to insertion of the busbar. A loose insertion of the graphite foil in the groove may be sufficient as a prefixing, since the graphite foil is preferably pressed by the cast iron during casting onto the at least one wall of the cathode block delimiting the groove.

To produce the cathode block, a carbonaceous or graphite-containing starting material or a mixture of several such materials can be brought into a mold and then compacted to form a green body. The starting materials are preferably present in particulate or granular form. Subsequently, the green body can be heated while carbonized and optionally graphitized. In the context of the present invention, it is possible to use both carbonized cathode blocks, which are understood to mean those cathode blocks which have been subjected to a temperature treatment of up to a maximum of 1, 500 ° C. and preferably between 800 and 1 200 ° C. and a high proportion of amorphous carbon, as well as graphitized cathode blocks, which are understood as those cathode blocks, which have been subjected to a temperature treatment of more than 2,000 ° C and preferably between 2,300 and 2,700 ° C in their preparation and have a high proportion of graphitic carbon. Finally, cathode blocks based on graphitic carbon can be used, that is, those which have not been graphitized, but have been added with graphite as the starting material.

As starting materials for carbonized cathode blocks, for example, a mixture of calcined anthracite, graphite and hard coal and / or Petroleumpech is used, whereas graphitic cathode blocks, for example from a mixture containing graphite and coal and / or petroleum pitch. Graphite refers here to both natural and synthetic graphite.

According to an advantageous development of the method, in the production of the cathode block, the starting material containing carbon and / or graphite is introduced into a mold which has a projection which is complementary to the at least one recess.

Likewise, the at least one recess can be produced by subsequently removing and / or displacing cathode block material of the at least one wall of the cathode block delimiting the groove. In particular, the recess can be subsequently introduced by a milling process, wherein a milling head used for introducing the depression preferably has a cross section corresponding to the recess.

Another object of the present invention is a cathode assembly, which is obtainable by a method as described above.

Hereinafter, the present invention will be described purely by way of example with reference to advantageous embodiments and with reference to the accompanying drawings.

Showing:

1 is a cross-sectional view of a portion of an aluminum electrolytic cell having a cathode assembly according to an embodiment of the present invention; Fig. 2 is a longitudinal section of the cathode assembly shown in Fig. 1

Aluminum electrolytic cell and

3a-d are exemplary cross-sections of depressions, which are provided in a groove of a cathode block according to the invention.

FIG. 1 shows in cross-section a section of an aluminum electrolysis cell 10 with a cathode arrangement 12 which at the same time forms the bottom of a trough for an aluminum melt 14 produced during operation of the electrolysis cell 10 and for a cryolite present above the aluminum melt 14. Alumina melt 16 forms. With the cryolite-alumina melt 16 is an anode 18 in contact. Laterally, the trough formed by the lower part of the aluminum electrolytic cell 10 is limited by a lining of carbon and / or graphite, not shown in FIG. 1.

The cathode arrangement 12 comprises a plurality of cathode blocks 20, which are each connected to one another via a ramming mass 24 inserted into a ramming mass gap 22 arranged between the cathode blocks 20. A cathode block 20 in this case comprises two grooves 26 arranged on its underside and having a rectangular, namely substantially rectangular cross section, wherein in each groove 26 in each case a bus bar 28 made of steel with likewise rectangular cross section is accommodated. Each of the groove 26 delimiting wall 32, 34 is lined by a dashed lines in Fig. 1 graphite foil 30 shown.

The grooves 26 are each bounded by two side walls 32 and a bottom wall 34 of the cathode block 20, wherein in each of the side walls 32 is provided a substantially perpendicular in the side wall 32 extending recess 36 having an approximately semicircular cross-section. Each recess 36 is bounded by an upper and a lower transition region 37 of the cathode block 20, respectively. The transition regions 37 are in the present Embodiment angularly formed at an angle α between the adjacent portion of the groove wall and the wall of the recess of 90 degrees. The gap between the busbar 28 and the lined with the graphite foil 30 groove 26 is in each case cast with cast iron 38, so that the graphite foil 30 is fixed between the cast iron 38 and the cathode block 20. In this case, the graphite foil 30 is pressed by the cast iron 38 against the respective groove 26 bounding walls 32, 34. In the present embodiment, the recesses 36 are each lined by the graphite foil 30, wherein the cast iron 38 form-fittingly fills the lined depressions 36 and presses the graphite foil 30 against the cathode block 20 delimiting the depression 36. In this way, over the entire cross section of the groove 26, a low electrical contact resistance between the bus bar 28 and the cathode block 20 is ensured. The cast iron 38 forms a sheath 39 for the busbar 28 and communicates with the busbar 28 in material connection.

In addition, the received in the wells 36 cast iron 38 forms with the recess 36 delimiting material of the cathode block 20 each have a positive connection, which prevents movement of the connected to the cast iron 38 busbar 28 in the direction of the arrow 40. An unwanted movement of the bus bar 28 in the depth direction of the groove 26 or even falling out of the bus bar 28 from the groove 26 are prevented.

In FIG. 1, the cross section of the cathode assembly 10 is shown concretely at a longitudinal end of the cathode block 20. The depth of the grooves 26 of the cathode block 20 varies over the length of the grooves 26. The groove cross section in the region of the center of the groove 26 is indicated in Fig. 1 by a dashed line 42. The difference between the groove depth at the longitudinal ends of the groove 26 and in the middle of the groove 26 in the present embodiment is about 10 cm. The width 44 of each groove 26 is over the entire groove length in Essentially constant and is about 15 cm, whereas the width 46 of the cathode blocks 20 is about 65 cm each.

In the present embodiment, a plurality of anodes 18 and a plurality of cathode blocks 20 are arranged one above the other so that each anode 18 covers two juxtaposed cathode blocks 20 and covers in length half of a cathode block 20, wherein each two juxtaposed anodes 18 the length of a Cover cathode block 20.

FIG. 2 shows the cathode block 20 shown in FIG. 1 in longitudinal section. As can be seen in FIG. 2, the groove 26 viewed in its longitudinal section extends towards the center of the cathode block 20 in the shape of a triangle, thereby ensuring a substantially uniform electrical vertical current density over the entire cathode length. The recesses 36 extend as indicated in FIG. 2 by a dashed line parallel to the groove bottom 34 and have over the length of the groove 26 at a constant distance from the groove bottom 34. The bus bar 28, which is not shown in FIG. 2 for better clarity, is bar-shaped in the present exemplary embodiment and has a rectangular longitudinal section, so that between the bus bar and the groove bottom 34 there is an intermediate space becoming larger towards the center of the groove 26 which may be filled either by cast iron 38 or by additional metal plates connected to the bus bar 28. Likewise, a bus bar 28 could be used, which is adapted in its longitudinal section to the triangular course of the groove 26.

Finally, FIGS. 3a to d show exemplary depressions 36, which are provided in a groove of a cathode block 20 according to the invention, in cross-section. In this case, the depressions 36 each have a substantially semicircular cross section (FIG. 3 a), a substantially trapezoidal cross section (FIG. 3b) or a substantially triangular cross section (Fig. 3c). The angle α of the transition regions 37 between the wall of the recess 36 and the adjacent portion of the groove wall 32, viewed from the inside of the cathode block 20, is approximately 90 degrees in FIG. 3a, approximately 120 degrees in FIG Fig. 3c about 125 degrees. FIG. 3 d shows an embodiment in which a plurality of recesses 36 with a triangular cross-section as shown in FIG. 3 c are arranged consecutively in the depth direction of the groove 26 in order to effect a particularly reliable support of an inserted bus bar 28. The transition regions 48 between two adjoining recesses 36 have between the walls of two adjacent recesses 36, seen from the inside of the cathode block 20, an angle ß of about 70 degrees. The depressions 36 shown in FIGS. 3 a to d each extend perpendicularly into the side wall 32 of the cathode block 20 delimiting the groove 26 so that they form a fixation with cast iron received in the depressions 36 which is effective in the depth direction of the groove 26 and prevents unwanted movement of the bus bar 28 parallel to the depth direction of the groove 26 after casting the bus bar 28 with cast iron 38.

LIST OF REFERENCE NUMBERS

10 aluminum electrolysis cell

 12 cathode arrangement

 14 aluminum melt

 16 cryolite-alumina melt

 18 anodes

 20 cathode block

 22 ramming joint

 24 ramming mass

 26 groove

28 busbar 30 graphite foil

32 side wall

34 bottom wall

 36 deepening

 37 transition region between the wall of the recess and the adjacent portion of the groove wall

 38 cast iron

 39 serving

 40 arrow

 42 dashed line

 44 width of the groove 26

 46 width of the cathode block 20

 48 transition area between two adjoining depressions

α angle between the wall of the depression and the adjacent one

 Section of the groove wall

ß angle between the walls of two adjacent

 wells

Claims

claims

1. Cathode arrangement for an aluminum electrolytic cell (10) having at least one cathode block (20) based on carbon and / or graphite, which has at least one at least partially lined with a graphite foil (30) groove (26), wherein in the at least one Groove (26) at least one bus bar (28) is provided, which at least partially has a sheath (39) made of cast iron (38),

 characterized in that

 in which the at least one groove (26) bounding wall (32, 34) of the cathode block (20) at least one recess (36) is provided and the sheath (39) made of cast iron (38) at least partially into the at least one recess (36) intervenes.

2. Cathode arrangement according to claim 1,

 characterized in that

 the portion of the sheath (39) of cast iron (38) engaging in the at least one recess (36) is designed to be complementary to the recess (36).

3. Cathode arrangement according to claim 1 or 2,

 characterized in that

 at least 70%, preferably at least 80%, more preferably at least 90%, most preferably at least 95%, and most preferably the portion of the sheath (39) engaging in the at least one depression (36) and optionally the conductor rail (28) covered by it at least 100% of the depression (36) fills.

4. Cathode arrangement according to at least one of the preceding claims, characterized in that

each of the at least one recess (36) extends continuously over at least 20%, preferably over at least 40%, more preferably over at least 60%, most preferably over at least 80% and most preferably at least approximately over the entire length of the groove (26) ,

Cathode arrangement according to at least one of the preceding claims, characterized in that

each of the at least one recess (36) has a depth of 2 mm to 40 mm, preferably of 5 mm to 30 mm and particularly preferably of 10 mm to 20 mm.

Cathode arrangement according to at least one of the preceding claims, characterized in that

each of the at least one recess (36) has an opening width, based on the height of the cathode block, of 2 mm to 40 mm, preferably 5 mm to 30 mm and particularly preferably 10 mm to 20 mm.

Cathode arrangement according to at least one of the preceding claims, characterized in that

each of the at least one recess (36) in cross-section preferably has an area of 1, 5 mm ² to 1,600 mm ² , preferably from 10 mm ² to 900 mm ² and particularly preferably from 40 mm ² to 400 mm ² .

Cathode arrangement according to at least one of the preceding claims, characterized in that

the at least one depression (36) has an at least substantially semicircular, triangular, rectangular or trapezoidal cross-section.

9. Cathode arrangement according to at least one of the preceding claims, characterized in that

 the recess (36) extends substantially perpendicularly into the wall (32, 34) of the cathode block (20) delimiting the groove (26).

10. Cathode arrangement according to at least one of the preceding claims, characterized in that

 the at least one depression (36), viewed in the depth direction of the groove (26), is delimited at each of its ends by a transition region (37) between the depression (36) and an adjoining portion of the groove wall (32, 34) each of the transition areas (37) is angled, wherein the angle (a) between the wall of the recess (36) and the adjacent portion of the groove wall (32, 34), viewed from the cathode block inner side, 90 degrees to 160 degrees, preferably 90 Degree to 135 degrees, and more preferably 100 degrees to 120 degrees.

11. Cathode arrangement according to at least one of claims 1 to 9,

 characterized in that

 the at least one depression (36), viewed in the depth direction of the groove (26), is delimited at each of its ends by a transition region (37) between the depression (36) and an adjoining portion of the groove wall (32, 34) each of the transition regions (37) is curved, wherein the radius of curvature of the transition region is a maximum of 50 mm, preferably a maximum of 20 mm and more preferably a maximum of 5 mm.

12. Cathode arrangement according to at least one of the preceding claims, characterized in that the groove (26) bounding wall (32, 34) comprises a bottom wall (34) and two side walls (32), each side wall (32) each having at least one recess (36).

13. Cathode arrangement according to at least one of the preceding claims, characterized in that

 the at least one depression (36) has a substantially constant distance from the bottom wall (34) of the groove (26) over its length.

14. Cathode arrangement according to at least one of the preceding claims, characterized in that

 each of the at least one recess (36) is at least partially and preferably fully lined with the graphite foil (30) and preferably each of the at least one groove (26) is fully lined with the graphite foil (30).

15. Cathode arrangement according to claim 14,

 characterized in that

 the graphite foil (30) is pressed against the boundary of the depression (36) by the sheathing (39) of the busbar (28) made of cast iron (38).

16. Cathode arrangement according to at least one of the preceding claims, characterized in that

 the groove (26) has a depth varying over its length.

17. Cathode arrangement according to claim 16,

 characterized in that

the groove (26) has a smaller depth at its longitudinal ends than at its center.

18. Cathode arrangement according to at least one of the preceding claims, characterized in that

 each of the at least one groove (26) has an at least substantially rectangular cross-section.

19. Cathode arrangement according to at least one of the preceding claims, characterized in that

 each of the at least one bus bar (28) has a substantially rectangular cross-section.

20. Cathode arrangement according to at least one of the preceding claims, characterized in that

 the graphite foil (30) comprises expanded graphite, preferably contains or consists of at least partially compressed expanded graphite.

21. Cathode arrangement according to at least one of the preceding claims, characterized in that

 the graphite foil (30) has a thickness between 0.2 mm and 3 mm, preferably between 0.2 mm and 1 mm and particularly preferably between 0.3 mm and 0.5 mm.

22. Cathode arrangement according to at least one of the preceding claims, characterized in that

 the graphite foil (30) is inserted and / or glued into the groove (26).

23. Cathode arrangement according to at least one of the preceding claims, characterized in that

the cathode block (20) has one or two grooves (26) for receiving in each case at least one bus bar (28).

24. Cathode block for a cathode arrangement (12) of an aluminum electrolysis cell (10) based on carbon and / or graphite with at least one groove (26) for receiving a bus bar (28),

 characterized in that

 in which the at least one groove (26) defining wall (32, 34) of the cathode block (20) at least one recess (36) is provided.

25. A method for producing a cathode arrangement (12) for an aluminum electrolysis cell (10), which comprises the following steps:

Providing a cathode block (20) based on carbon and / or graphite, which has at least one groove (26) for receiving a bus bar (28), in which the at least one groove (26) defining wall (32, 34) of the cathode block (20) at least one depression (36) is provided,

 Lining at least a portion of the at least one groove (26) with a graphite foil (30),

 Inserting a bus bar (28) into the at least one groove (26), filling liquid cast iron into at least a portion of the at least one recess (36) between the graphite foil (36) and the bus bar (28) and

 Solidifying the cast iron (38).

26. The method according to claim 25,

 characterized in that

 the graphite foil (30) is inserted into the groove (26) and / or glued.

27. The method according to claims 25 or 26,

characterized in that in the manufacture of the cathode block (20), carbon and / or graphite-containing material is introduced into a mold having a projection complementary to the at least one recess (36).

28. The method according to at least one of claims 25 to 27,

 characterized in that

 the at least one depression (36) is produced by removing and / or displacing material of the wall (32, 34) delimiting the groove (26) of the cathode block (20).

29. Cathode arrangement obtainable by a method according to at least one of claims 25 to 28.