EP2609230A1 - Cathode, device for aluminum production, and use of the cathode in aluminum production - Google Patents

Abstract

The invention relates to a cathode (10) and to a device (100) for melt flow-based metal production and provides uses for the cathode (10) and the device (100). A core aspect of the present invention consists in designing the cathode (10) to have at least two layers, that is, a process-side process layer (12) made of or with an abrasion-resistant process material (12'), and a current transfer layer (11) made with or of an electrically conductive, and in particular low-impedance, current transfer material (11'). Furthermore, the process side (10o) is designed in a profiled manner with a recess (10a, 12a) and/or an elevation (10e, 12e), or with a plurality of recesses (10a, 12a) and/or elevations (10e, 12e).

Description

 CATHODE, DEVICE FOR ALUMINUM MANUFACTURE AND USE OF CATHODE IN ALUMINUM MANUFACTURE

GEB IET OF THE INVENTION

The present invention relates to a cathode for metal and in particular for aluminum iniumgewinnung, a device for metal and in particular for aluminum extraction and a use of the cathode and the apparatus for metal and in particular for aluminum extraction.

INTERGRUN D OF THE INVENTORY

In the extraction of metals, and in particular in the extraction of alumium inium, processes based on so-called melt electrolysis are frequently used.

In aluminum mining traditionally the so-called Hall-Heroult process is often used. In this process, aluminum oxide AI2O3 is treated and dissolved in a melt with cryolite Na ₃ [AIF ₆ ] in the course of fused-salt electrolysis, in which case the pure aluminum is deposited in a reduction process. The core idea of this procedure is that, before the actual electrolysis step, the mixture of aluminum oxide with the cryolite takes place as a solvent, in order to prevent the

Lower melting temperature, namely of about 2045 ° C for the pure

Alum inium oxide in a range of about 950 ° C for the mixture.

The reduction of Alum iniumoxid to pure Alum inium then takes place approximately in accordance with the process

2A1 ₂ 0 ₃ - ^ 4Al + 30 ₂ .

The resulting reduced liquid aluminum has a greater density than the melt of alumium inium oxide and cryolite and can therefore be used as soil be removed in a corresponding facility, z. B. via a suction pipe or the like.

The resulting oxygen reacts with the carbon of the anodes.

The problem with such a procedure and the construction and use of appropriate systems on the one hand, the susceptibility to wear of the cathodes used, as well as the large specific energy requirement to enable the redox reaction, in addition, the energy efficiency z. B. reduced by resistive losses.

SUMMARY OF THE INVENTORY

The invention is based on the object to provide a cathode and a device for alum iniumgewinnung m ittels melt electrolysis and their uses in which m particularly simple means the cathode surfaces protected against wear and thus the wear processes are slowed down and on the other hand, the actual aluminum iniumgewinnung m It can be done with higher energy efficiency.

The problems underlying the invention are in a cathode for melt flow-based Alum iniumgewinnung according to the invention m solved with the features of independent claim 1. The objects on which the invention is based are furthermore achieved according to the invention in a device for melt flow-based aluminum production with the features of independent patent claim 14. The objects are further achieved by using the cathode according to the invention and the device according to the invention in the melt flow-based aluminum production according to the independent patent claims 16 and 17. Advantageous developments are the subject matter of the dependent claims. The invention provides a cathode for an electrolytic cell for

Obtaining aluminum from its oxide in an electrolysis bath, the cathode having a process side which in operation faces the electrolysis bath, the cathode being constructed in a layered manner, with a process layer containing a process material which partially or completely forms the process side of the cathode, and a power transmission layer containing a power transmission material, wherein the process material is more abrasion resistant than the power transmission material, wherein the power transmission material is more electrically conductive than the power transmission material

Process material is and wherein the process side is formed profiled by one or more recesses and / or elevations. The relative difference of the abrasion resistance and the specific electrical conductivity is present under real electrolysis conditions. Preferred measurement temperatures, in which abrasion resistance and specific electrical conductivity are each compared, are real process temperatures, such as 950 ° C.

Core aspects of the cathode according to the invention are thus on the one hand, the multi-layered structure of the cathode, namely L m at least one of the Schmelzflussbad associated and operating facing process layer m it or made of an abrasion resistant process material and the Schmelzflussbad in operation remote power transmission layer or with an electrically highly conductive power transmission material and on the other hand the profiling of the process side of the cathode with a recess and / or elevation or a plurality of recesses and / or elevations.

By providing an abrasion-resistant process material at the cathode, the exposure of the components of the melt flow bath to the cathode surface on the process side and the associated abrasion are reduced or prevented. The formation of the profiling on the basis of one or more recesses and / or elevations verm indert the abrasion on, because quasi by a cavern or channel formation, the movement of the constituents of the melt bath is reduced, in particular of the liquid aluminum by electromagnetic interactions.

According to the invention, an increased energy efficiency is achieved, namely on the one hand the fact that due to the reduced movement of the constituents of the melt bath, the distance D of the cathode arrangement to an anode arrangement provided in operation, more precisely the distance δ of the anode bottom from the surface or interface of the molten liquid Alum iniums , can be reduced, which is equivalent to a reduction of ohmic losses, and on the other hand, that as the lowest layer d a low-ohmic material can be used, in which case only aspects of energy efficiency must be taken into account, because a direct contact between components of the melt bath not to take into account.

For the purposes of the invention, the term cathode is generally understood. It may be z. B. - but not exclusively - to act as a so-called cathode bottom, which is composed of a plurality of cathode blocks, so that the core aspects of the invention - namely the above-described layered structure on the one hand and the profiling on the other - are realized by this cathode bottom as a whole.

With the term cathode but also such a cathode bottom forming substructures should be addressed in the sense of cathode blocks, so that the core aspects of the invention - namely the above-described layered structure on the one hand and the profiling on the other hand - also of cathode blocks - or of their entirety - realized could be.

The process layer and in particular the process material may be formed amorphous, in particular with, from or based on a carbon matrix. Substance material and / or based on calcined anthracite, preferably m with a vertical electrical resistivity at room temperature in the range of about 23 Ω · μΓΠ to about 40 Ω- μΓΠ, preferably in the range of about 25 Ω- μηι to about 35 Ω · μηη , In this case, a vertical specific electrical resistance means the electrical resistance perpendicular to a cathode in a mounting situation of an electrolysis cell, that is to say, for example, measured perpendicular to the longitudinal axis of a cathode block. At typical process temperatures of 950 ° C, the vertical electrical resistance in the range of about 20 Ω- μηι to about 32 Ω- μηι, preferably in the range of about 22 Ω · μΓΠ to about 28 Ω · μηη.

The current transfer layer, and in particular the current transfer material, may be formed with, or formed of, a carbon material, in particular in graphitic form with or of graphite and / or graphite material, preferably with a vertical room temperature electrical resistivity in the range of about 14 Ω- μηι to about 20 Ω- μΓΠ, preferably in the range of about 16 Ω · μΓΠ to about 1 8 Ω · μΓη. At typical process temperatures of 950 ° C, the vertical electrical resistance in the range of about 1 3 Ω · μΓΠ to about 1 8 Ω- μΓΠ, preferably in the range of about 14 Ω · μΓΠ to about 16 Ω · μηη.

Although a carbon material is mentioned here as a basis in each case, but can also be provided in the case of ischungen from other material classes, for. Refractory metal compounds or the like.

Provided recesses in or on the process side can be formed by recesses in the process layer and / or the current transfer layer and in particular in the process material.

Provided surveys in or on the process side can be formed by surveys in the process layer and in particular in the process TERIAL. The surveys can also be understood as ridges, ridges or fins.

The process side can be formed planar in sections. In particular, the recesses and / or elevations may be formed substantially square in cross-section.

However, the recesses and / or the elevations may have any desired shape in cross-section and in their longitudinal direction. You can z. B. be formed of arbitrarily structured convex or concave areas or sections. A fixation on rectangular or square shapes is not necessary, even if they are geometrically very simple. In principle, aspects of the particularly simple production of such recesses and elevations can also be taken into account here. Also conceivable, for example, arcuate, kreisabschnitt- shaped, trapezoidal or triangular shapes.

The process layer can be arranged directly on the current transfer layer. In particular, the boundary surface between the process layer and the current transfer layer, that is to say a lower side of the process layer and an upper side of the current transfer layer, can be made planar. Although a two-layer structure of the electrode body is sufficient for the realization of the present invention, but also a plurality of layers may be provided to z. B. to reduce thermo-mechanical stresses by building a gradient system.

The depth ta of a recess and the width ba of a recess may have or assume values in the range of about 1: 3 to about 1: 1, and preferably in the range of about 1: 2 to about 1: 1 so that roughly the relationship (1)

1: 3 <ta: ba <1: 1 (1) and especially the relationship (V)

\: 2 <ta: ba <\: \ (1 ') is fulfilled.

The height of a bump and the width of a bump may or may have values with a ratio ranging from about 1: 2 to about 2: 1, and preferably at a ratio in the range of about 1: 1, so that approx (2)

\: 2 <he: be <2: \ (2) and in particular the relation (2 ') he be * \ \ (2') is fulfilled.

The width ba of a recess and the width of a projection may have or assume values with a ratio in the range from about 1: 1 to about 4: 1, so that approximately the relationship (3)

1: 1 <ba: be <4: 1 (3) is met.

The depth ta of a recess may in particular have or assume values in the range of about 100 mm to about 250 mm, preferably in the range of about 100 mm.

The width ba of a recess may in particular have or assume values in the range from approximately 140 mm to approximately 200 mm. The height of an elevation can in particular have or assume values in the range from approximately 1 00 mm to approximately 250 mm, preferably in the range of approximately 1 00 mm.

The width of a survey may in particular be values in the range of about 100 mm to about 200 mm, preferably in the range of about

1 00 mm or assume.

An essential aspect in forming the geometry of the electrode assemblies is that due to the properties of the aluminum oxide, aluminum and cryolite melt flow bath certain boundary conditions, eg. B. with respect to the distance D between the cathode and the anode assembly, more precisely the distance δ of the anode assembly from the surface of the molten liquid Alum iniums arise so that the electrolytic cell can be operated energetically efficient. Thus, it has been found that the distance δ between the aluminum and the anode assembly in operation should not exceed a value of 50 mm to 80 mm, otherwise the ohmic losses would make the manufacturing process inefficient.

The cathode can preferably be constructed from a plurality of cathode blocks, in particular in the manner of a cathode bottom, wherein the cathode blocks are constructed in particular geometrically and / or structurally the same or the same acting and / or laterally adjacent to each other with respect to the process side and / or the current collection side are and / or wherein one, several or all cathode blocks are individually layered and profiled constructed.

This means in particular that in this case by one, several or all cathode blocks, the core aspects according to the invention, namely, on the one hand, the layered structure of the cathode with an abrasion-resistant upper process layer and a more electrically conductive lower current flow. tragungsschicht and on the other hand, the profiled design of the process side m with one or more surveys and / or recesses - are already realized individually.

In this case, directly adjacent cathode blocks may have a contact and compensation area between them, which is designed and provided for mechanical separation, in particular for receiving thermo-mechanical stresses, in particular in the manner of a tamping or ramming joint.

The construction of the cathode of a plurality of cathode blocks reduces thermo-mechanical loads, especially when using so-called tamping joints as compensating elements.

Provided elevations on the process side and in particular in the process layer and the process material may be formed as fins, ridges or webs, in particular in cross-section substantially rectangular manner, as convex areas, as Undulationsbereiche, as areas with prismatic shape, in particular with triangular or trapezoidal iger

Base area and / or as their combinations.

Provided elevations and / or recesses may have along their longitudinal direction a varying cross-section, in particular a varying height he or depth ta.

As already mentioned above, the square or rectangular basic structure is not obligatory in the design of the elevations or recesses and therefore in particular of the fins.

It is also not necessary for the recesses or elevations, that is to say in particular the fins, to be constant in cross-section in the longitudinal direction. Rather, they can vary in their height or depth but also in their width, whereby the geometry can be selected in such a way that particularly efficient However, in a simple manner, the movement of the constituents of the melt-flow bath can be further restricted.

According to another aspect of the present invention, there is provided an apparatus for melt flow based aluminum recovery having an anode assembly, a cathode according to the invention, and a melting and reaction space between the anode assembly and the cathode.

In this case, the distance D between the cathode and the anode arrangement may have or assume a value in the range from about 20 mm to about 200 mm, preferably in the range from about 40 mm to about 70 mm, so that approximately the relationship (4)

20mm <D <200mm (4) and in particular the relationship (4 ')

40 mm <D <10 mm (4 '), such that, in operation of the device, the distance δ between the anode assembly of the surface or interface of the molten and liquid aluminum is in the range of about 15 mm to about 45 mm, preferably can be set in the range of about 30 mm, so that approximately the relationship (5)

15 mm <δ <45 mm (5) and in particular approximately the relationship (5 ') δ 30 mm (5') is satisfied.

The cathode according to the invention can be used in a process for melt flow-based metal and in particular aluminum iniumgewinnung, preferably in the context of a fused-salt electrolysis of a cryolite bath after a Hall-Heroult process and an apparatus therefor.

The device according to the invention can be used in a process for melt-flow-based metal and in particular aluminum ingeneration, preferably in the context of a fused-salt electrolysis of a cryolite bath after a Hall-Heroult process.

These and other aspects will be explained by way of example on the basis of the accompanying schematic drawings.

KU DESCRIPTION OF THE FIGURES

FIGS. 1A-D show, in schematic and partly sectional views, a first embodiment of the inventive device for molten-salt electrolysis-based aluminum mining using a first embodiment of the cathode according to the invention.

2A-D show, in schematic and partly sectional views, a second embodiment of the inventive device for molten salt electrolysis-based aluminum mining using a second embodiment of the cathode according to the invention.

FIGS. 3A-E show a schematic and sectional side view

Various embodiments of profiles for the process side of embodiments of the cathode according to the invention. 4 shows a schematic plan view of the geometric assignment of a plurality of blocks of existing cathodes and anode arrangements.

Fig. 5 shows a schematic and partially sectioned side view of a further embodiment of the device according to the invention for electrolysis-based Alum iniumgewinnung using another embodiment of the cathode according to the invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Hereinafter, embodiments of the present invention will be described. All embodiments of the invention and also their technical features and properties can be isolated individually or randomly combined, so that they can be combined with each other arbitrarily and without restriction.

Structurally and / or functionally identical, similar or identically acting features or elements are referred to below in connection with the figures with the same reference numerals. Not always will a detailed description of these features or elements be repeated.

The figures describe the invention by way of example by means of exemplary embodiments and in a schematic manner and are not true to scale unless otherwise stated.

At first reference is made to the drawings in general.

In particular, the present invention also relates to a composite cathode 10 having a profiled surface 10o, in particular for use with a pre-fabricated surface. Direction 1 00 and a method for melt flow-based Alum iniumgewinnung.

On an industrial scale, alumium inium is obtained, inter alia, by a process of electrolysis of alumina in a cryolitic melt 21 m by means of a Hall-Heroult process. Specific embodiments of such a procedure use coated cathode blocks 1 0 ', z. Example, with an electrically conductive lower layer 1 1 and an abrasion-resistant upper layer 12. In this case, different embodiments of the surface of the upper layer can be used.

The process of producing primary aluminum via electrolysis in a Hall-Heroult process is very energy intensive. In addition to the applied electrochemical energy for reducing the Alum iniumoxids to aluminum, a large proportion of the introduced electrical energy in the layer of the cryolite bath 21 is converted into heat.

Due to the movement of the liquid Alum iniums, which is caused inter alia by the interaction with the electric current induced by strong magnetic fields, a m inimaler distance of 30 to 50 mm between the Alum iniumoberfläche and the anode surface must be adhered to a short circuit and an undesired reverse reaction -. As a re-oxidation of the already formed Alum iniums - to avoid.

Profiled surfaces 1 0o, d. H. Surfaces with recesses 10a, 12a and / or elevations 10e, 12e provided can reduce or even avoid these effects and in particular the movement of the aluminum. However, present current density inhomogeneities, which can lead to abrasion forces, can not be avoided.

Therefore, the inventive provision of an abrasion-resistant material 12 'for the cathode surface 1 0o, 12o, z. B. in anthracitic form, from particular advantage to reduce or avoid such abrasion.

However, this alone would lead to an increase in the electrical resistance and thus contradict the goal of increasing energy efficiency.

On the other hand, layered flat cathode blocks 10 'made of an electrically conductive graphite layer 11 as a lower layer and an abrasion-resistant amorphous upper layer 12 can enable such increases in energy efficiency by minimizing the cathode resistance.

However, this alone would not avoid the movement of the metal and thus the Abrasionsproblematik.

The core idea of the present invention, on the basis of these preliminary considerations and investigations by the applicant and the inventors according to the invention, is to present a combination in which a layered cathode configuration is combined with a profiled surface of the cathode block. As a result, on the one hand a resistance to abrasion forces is possible, on the other hand, however, an increase in energy efficiency on the basis of the lowering of the cathode resistance possible.

It is therefore proposed a design in which a conductive lower layer 1 1 as a base layer and an abrasion-resistant upper layer 12, z. B. in the form of an amorphous and / or anthracitic layer to näm Lich thereby cause a comparatively high energy efficiency m with a corresponding abrasion resistance with respect to the moving molten bath components.

For profiling the surface 10o, 12 recesses 10a, 12a and / or elevations 10e, 12e are provided in the uppermost layer, the metal movement and the movement of the portions of the melt flow bath 20 'in Generally reduce, thereby reducing the abrasive forces and to create the possibility of lowering the distance between the anode 30 and the cathode 1 0, so the distance D between the anode 30 and the metal 20 'm with the objective of a further increase in energy efficiency.

In order to avoid the instability of such an electrolytic cell, namely because of possibly occurring stray currents, a certain layer thickness of molten aluminum 22 above the elevations 1 0e, 12e or fins 12f may not be exceeded or fallen below within certain limits.

Layered cathodes 10 constructed according to the invention can be formed by a vibration molding process.

The amorphous or anthracitic material on the process side may, for. B. based on a material m with a share of about 70% of electrically calcined anthracite and 30% graphite in the solid. The underlying graphitic material with a low electrical resistivity for the power transmission side may e.g. B. be a material with a share of 100% synthetic graphite in the solid.

The layer thicknesses for the lower and the upper layer, d. H. that is, for the current transfer layer and the process layer may have a layer thickness ratio of 50:50.

Trained recesses 10a, 12a on the process side 10o can, for. B. be configured so that an approximately central recess 1 0az, 12az is completely associated with a cathode block 1 0 'and two peripheral recesses 1 0ap, 12ap are shared at the edge with adjacent cathode blocks 1 0' right and left of it.

The central or central recess 10a, 12az may have a width in the range of 200 mm and a depth in the range of 1 00 mm. The corners or edges do not have to be strictly rectangular, but could form rounded edges with a radius of curvature of, for example, r = 20 mm. The divided peripheral recesses 10a, 12ap could have a width of 50 mm at the edge and also a depth of 1 00 mm. Again, the edge courses are not strictly limited to rectangular geometries, but may have rounded corners or edges with a radius of curvature of, for example, r = 20 mm.

In operation, the height of the entire aluminum layer may be about 1 50 mm, e.g. B. 30 mm above the elevations 1 0e, 12e and som it can also be a value of about 30 mm for the distance δ from the surface or interface of the molten and liquid Alum inium 22 to the anode assembly 30 can be achieved, which is advantageous in operation is to be provided.

Now, reference will be made in detail to the drawings.

1 A to 1 D show various schematic and partially sectioned views of a first embodiment of the device 100 according to the invention for melt flow-based Alum iniumgewinnung using an embodiment of the cathode 10 according to the invention.

In FIGS. 1 A to 1 D, respective sectional and plan views AA or BB, CC and DD are shown, which mark the respective other views and relate to the respective FIGS Refer to 1 D.

The proposed in these figures 1 A to 1 D device 1 00 for melt flow based Alum iniumgewinnung based on a cathode assembly 1 0 m with a cathode block 1 0 'with a lowermost arranged Stromübertragungsschicht 1 1 and one above and the process chamber 20 - with the Schmelzflusselektrolysebad 20 'from the molten and liquid Alum inium 22 and the area above it 21 with the mixture of cryolite and aluminum oxide-exposed process layer 12.

The current transfer layer 1 1 is formed with an upper side 1 1 o and a lower side 1 1 u, which simultaneously forms the current transfer side 10u of the cathode 1 0. The current transmission layer 11 is formed with or from a current transmission material 11 ', which-in comparison to the process layer 12 provided above-has a lower or particularly low electrical resistance and can therefore be termed low-resistance. This power transmission material 1 1 'z. B. based on or formed of a natural or synthetic graphite and in particular have a specific electrical resistance at room temperature in the range of about 14 Ω pm to about 20 Ω pm and preferably in the range of about 16 Ω pm to about 1 8 Ω pm ,

The process layer 12 m directly adjoins the current transfer layer 1 1 as the lowermost layer with the process material 12 'in abrasion-resistant form, whereby its lower side 12u and upper side 12o are formed, the latter simultaneously forming the process side 10o of the cathode 10.

The interface between the current transfer layer 1 1 and the process layer 12 is formed by the top 1 1 o of the current transfer layer 1 1 and the bottom 12u of the process layer 12 and is planar in this case. However, this is not mandatory. Rather, the interface 1 1 o, 12u can be selected and formed according to the geometric requirements of the overall arrangement of the device 1 00.

Embedded in the current transfer material 1 1 'of the current transfer layer 1 1 is still a current decrease or a current collecting element 1 3, z. B. provided in the form of a steel bar, which is m it with a cast iron casing 14 to the current transfer material 1 1 'down. At the top 1 0o or process side 1 0o of the cathode 1 0, ie in the region of the top 12o of the process layer 12 or the process material 12 'is a corresponding profiling of recesses 10a, 12a and elevations 1 0e, 12e, here in the form of so-called Fins 1 0f, 12f, formed.

In the arrangement according to FIGS. 1 A to 1 D, the cathode 1 0 is in the form of a plurality of cathode blocks 1 0 ', so that each of the blocks 1 0' on the process side 1 0o a central recess 12az and two peripheral recesses 12 ap and thus has two elevations 12e or fins 12f bounding these central and peripheral recesses 12az and 12ap.

Lateral adjacent and below the peripheral recesses 12 ap, the so-called stamping joints 40 are arranged, which realize the vicinity of adjacent cathode blocks 1 0 'of the cathode 1 0 and thereby absorb and compensate thermo-mechanical stresses due to their mechanical properties, if nem Lich the device. 1 00 and in particular the cathode 1 0 is heated from room temperature to the operating temperature in the range of usually up to 1 000 ° C.

The dimensions given in FIGS. 1A to 1D are for illustration purposes only and are not mandatory. Rather, the dimensions given in the description for the design of the layer thicknesses, distances and the like can be used.

Figs. 2A to 2D show in an analogous manner to Figs. 1 A to 1 D, another embodiment of the device according to the invention 1 00 and the inventive cathode 1 0th

Namely, while in the embodiment of Figs. 1 A and 1 D, the fins 12f or elevations 10e, 12e in the entire length or the y-direction, which is indicated in the drawings, extend and there have a constant height he, they are Finns 12f or surveys 1 0e, 12e at the Embodiment of Figs. 2A to 2D in the longitudinal or y-direction not m he formed with a constant height he, but in a stepped manner m with a first and m with a second height, which are different from each other. In this case, each elevation 1 0e, 12e has a first height along the first half of the total length in the y direction and a second height along the second half. In this case, in the sequence of blocks 1 0 'in the cathode 1 0, ie along the x-direction in Figs. 2A to 2D beyond an alternation provided so that alternately or checkerboard different height gradients for the individual surveys 1 0e, 12e are formed so as to reduce the movement of the material of the melt flow bath.

In principle, other height profiles are also conceivable, namely with a plurality of further heights for the fins 12f or else with continuous height profiles, ie in beveled form or the like.

3A to 3B show different embodiments for the profiling of the process side 1 0o, ie ultimately for the geometric design or cross-sectional shape of the recesses 10a, 12a and the elevations 1 0e, 12e or fins 12f.

In the embodiment of FIG. 3A, the cross-sectional profile is again, which is also shown in Figs. 1 A to 1 D and 2A to 2D reproduced, ie an arrangement in which the recesses 1 0a, 12a and the elevations 1 0e, 12e are formed in cross-section substantially rectangular.

In the embodiment of FIG. 3B, the recesses 10a, 12a and the projections 10e, 12e have rounded, ie not rectangular edge profiles.

In the embodiment of Fig. 3C are provided for the recesses 10a, 12a and the elevations 1 0e, 12e triangular cross-sectional profiles, so a total of prism-shaped ig. In the arrangement according to FIG. 3D, elevations 1 0e, 12e are convex areas, quasi in the form of cylinder sections.

In the arrangement of FIG. 3E, the sequence of recesses 10a, 12a and elevations 10e, 12e shows a wave-like course, optionally in sinusoidal form.

4 shows a schematic top view of the geometric assignment of a plurality of blocks 10 'of existing cathodes 110 and anode arrangements 30. Laterally in the x direction, one block of the anode arrangement 30 covers two blocks 101' of the cathode 110, but in y Direction only up to half of the extension of the blocks 10 'of the cathode 1 0, so that in the y direction two rows of blocks of the anode assembly 30 for complete coverage of the cathode block 1 0' are necessary.

Fig. 5 shows a schematic and partially sectioned side view of a further embodiment of the inventive device 1 00 for the electrolysis-based Alum iniumgewinnung melt-electrolysis using another embodiment of the inventive cathode 1 0th

In an otherwise analogous structure in comparison to the device 100 according to FIGS. 1 A to 1 D, here the stamping joints 40, 40 'are not in the region of a recess 10 a, 12 a or recess 10 a, 12 a, but in each case in the region of an elevation 1 0e, 12e provided. REFERENCE LIST

1 0 cathode according to the invention

 1 0 'cathode block

 1 0a recess

 10th elevation, footbridge, ridge

 1 0o process side, top side

 1 0u power transmission side, bottom

 1 1 power transfer layer

 1 1 'power transmission material

 1 1 o top of the current transfer layer 1 1, interface

1 1 u underside of the current transfer layer 1 1

 12 process layer

 12 'process material

 12a recess

 12az central recess

 12ap peripheral recess

 12th elevation, jetty, ridge

 2f fin, burr

 12o top of the process layer 12

 12u underside of the process layer 12, interface

 1 3 Power take-off, steel girder, current collecting element

14 iron coat

 20 process space

 20 'melt, melt

 21 melt of cryolite and alum inium oxide

 22 melt of aluminum inium

 30 anode assembly, anode

 40 contact and compensation element

 40 'Stampffuge, ramming joint

1 00 inventive device ba width of a recess be width of a survey

he height of a survey

 D minimum distance cathode 1 0 to the anode assembly 30th

D 'distance cathode 1 0 to the anode assembly 30 in the range of

 Elevation of lower altitude

δ distance anode assembly 30 to the melt 22 of aluminum ta depth of a recess

Claims

A cathode (10) for an electrolytic cell for recovering aluminum from its oxide in an electrolytic bath, comprising a process side (10o) which in use faces the electrolytic bath (20 '), the cathode (10) being stacked a process layer (12) containing a process material (12 ') which partially or completely forms the process side (10o) of the cathode (10) and a current transfer layer (11) containing a current transfer material (11'), the process material (12 '; ) is more abrasion-resistant than the current transfer material (11 '), wherein the current transfer material (11') is more electrically conductive than the process material (12 ') and wherein the process side (10o) is defined by one or more recesses (10a) and / or protrusions (10e) profiled is formed.

2. Cathode (10) according to claim 1, wherein the process layer (12) and in particular the process material (12 ') is formed amorphous, in particular with or from or based on a carbon material and / or on the basis of calcined anthracite, preferably with a vertical resistivity at room temperature in the range of about 23 Ω · μΓη to about 40 Ω-μΓΠ, more preferably in the range of about 25 Ω · μΓΠ to about 35 Ω · μηη.

3. Cathode (10) according to one of the preceding claims, wherein the current transfer layer (11) and in particular the current transfer material (11 ') is formed with, from or on the basis of a carbon material, in particular in graphitic form with or from a graphite and / or Graphite material, preferably with a vertical electrical resistivity at room temperature, in the range of about 14 Ω-μηι to about 20 Ω · μΓη, more preferably in the range of about 16 Ω · μΓΠ to about 18 Ω · μΓη.

4. Cathode (10) according to one of the preceding claims, wherein

Recesses (10a) are formed in or on the process side (10o) of Recesses (12a) in the process layer (12) and in particular in the process material (12 ') and / or elevations (10e) are formed in or on the process side (10o) of elevations (12e) in the process layer (12) and in particular in Process material (12 ').

5. Cathode (10) according to one of the preceding claims, wherein the

Process side (10o) planar in sections planar and in particular the recesses (10a) and / or elevations (10e) in cross section are substantially rectangular, square, arcuate, circular section, trapezoidal or triangular.

6. Cathode (10) according to one of the preceding claims, wherein the

Process layer (12) is arranged directly on the current transfer layer (11) and in particular the interface between the process layer (12) and the current transfer layer (11), ie a bottom side (12u) of the process layer (12) and an upper side (11o) of the current transfer layer (11). 11) are planar.

A cathode (10) according to any one of the preceding claims, wherein the depth ta of a recess (10a, 12a) and the width ba of a recess (10a, 12a) are values having a ratio in the range of about 1: 3 to about 1: 1 and preferably with a ratio in the range of about 1: 2 to about 1: 1, so that approximately the relationship (1)

\: 3 <ta: ba <\: \ (1) and especially the relationship (1 ')

\: 2 <ta: ba <\: \ (1 '), where the height of a bump (10e, 12e) and the width of a bump (10e, 12e) are values with a ratio in the range of about 1: 2 to about 2: 1 and preferably with a ratio in the range of about 1: 1, or assume, so that approximately the relationship (2)

1: 2 <he: be <2: 1 (2) and in particular the relation (2 ') he: be' 1: 1 (2 ') is satisfied, and / or wherein the width ba of a recess (10a, 1 2a) and the width of an elevation (10e, 12e) assume values with a ratio in the range from about 1: 1 to about 4: 1, so that approximately the relationship (3)

1: 1 <ba: be <4: 1 (3) is met.

8. Cathode (10) according to one of the preceding claims, wherein the depth (ta) of a recess (10a, 12a) values in the range of about 1 00 mm to about 250 mm, preferably in the range of about 1 00 mm, the width (Ba) a recess (10a, 12a) values in the range of about 140 mm to about 200 mm, the height (he) of a survey (1 0e, 12e) values in the range of about 1 00 mm to about 250 mm, preferably in the range of about 1 00 mm, and / or the width (be) of a bump (10e, 12e) have values in the range of about 1 00 mm to about 200 mm, preferably in the range of about 1 00 mm.

9. Cathode (1 0) according to any one of the preceding claims, wherein the cathode comprises a plurality of cathode blocks (1 0 '), in particular of a plurality of cathode blocks (1 0') is constructed, wherein the cathode blocks (1 0 ') in particular are constructed geometrically and / or structurally the same or the same effect and / or with respect to the process side (1 0o) and / or the current decrease side (1 0u) are arranged laterally adjacent to each other.

1 0. The cathode (1 0) according to claim 9, wherein the process side (1 0o) to at least one cathode block (1 0 ^' ), in particular all cathode blocks (1 0'), by one or more recesses (1 0a) and / or Elevations (1 0e) profiled is formed.

1 1. Cathode (1 0) according to claim 9 or 1 0, wherein each directly adjacent cathode blocks (1 0 ') have a contact and compensation area (40) between them, which is designed and provided for mechanical separation, in particular for receiving thermo-mechanical stresses , in particular in each case in the manner of a stamping seam (40 ').

12. Cathode (1 0) according to any one of the preceding claims, wherein elevations (1 0e, 12e) on the process side (10o) and in particular in the process layer (12) and the process material (12 ') as fins, ridges or webs (12f ) are formed, in particular in cross-section substantially rectangular manner, as convex areas, as Undulationsbereiche, as areas with prismatic shape, in particular with triangular or trapezoidal

Base area and / or as their combinations.

1 3. Cathode (1 0) according to any one of the preceding claims, wherein provided elevations (1 0e, 12e) and / or recesses (1 0a, 12a) along its longitudinal direction have a varying cross-section, in particular a varying height (he) or Depth (ta).

14. An apparatus (100) for melt flow electrolysis-based aluminum recovery, comprising an anode assembly (30), a cathode (1 0) according to any one of claims 1 to 1 3 and with a melting and reaction space (20) between the anode assembly (30) and the cathode (1 0).

The device (100) of claim 14, wherein the distance (D) between the cathode (10) and the anode assembly (30) has a value in the range of about 20 mm to about 200 mm, preferably in the range of about 40 mm to about 70 mm, or assumes, so that approximately the relationship (4)

20 mm <£> <100 mm (4) and in particular approximately the relationship (4 ')

40 mm <D <70 mm (4 ') is satisfied.

16. The use of a cathode (10) according to any one of claims 1 to 13 in a process for melt flow-based metal and in particular aluminum extraction, preferably in the context of a fused-salt electrolysis of a cryolite bath after a Hall-Heroult process and an apparatus therefor.

17. Use of a device (100) according to any one of claims 14 or 15 in a method for melt flow-based metal and in particular aluminum extraction, preferably in the context of a fused-salt electrolysis of a cryolite bath after a Hall-Heroult process.