OA17792A - Electrolysis cell intended for the production of aluminum and an electrolysis plant comprising this cell - Google Patents

Abstract

This cell (1) comprises a box (2) having two longitudinal sides (18) symmetrical with respect to a longitudinal median plane (P) of the electrolysis cell (1), an anode assembly movable only in vertical translation relative to the casing (2), the anode assembly comprising an anode block (100) and a transverse anode support (200) extending orthogonally to the longitudinal sides (18) of the casing (2) and from which the block (100) is suspended anodic. The anode support (200) comprises two connection portions (202) from which the anode support (200) is supplied with electrolysis current, and the tank (1) comprises connection electrical conductors (20) electrically connected to the two. connection portions (202) of the anode support (200), the two connection portions (202) being arranged on either side of the plane (P).

Description

The present invention relates to an electrolysis cell, intended for the production of aluminum, and an electrolysis plant, in particular an aluminum smelter, comprising this electrolysis cell.

It is known to produce aluminum industrially from alumina by electrolysis according to the Hall-Héroult process. For this purpose, an electrolysis cell is provided conventionally comprising a steel box inside which is arranged a coating of refractory materials, a cathode of carbonaceous material, through which cathode conductors intended to collect the electrolysis current to be the cathode to lead it to cathode outlets passing through the bottom or sides of the box, routing conductors extending substantially horizontally to the next tank from the cathode outlets, an electrolytic bath in which is dissolved the alumina, at least one anode assembly comprising a substantially vertical anode rod and at least one anode block suspended from the anode rod and immersed in this electrolytic bath, an anode frame from which the anode assembly is suspended via the substantially anode rod vertical, the latter being movable with the anode frame relative to the box and to the cathode, and the run-up conductors nt, extending from bottom to top, connected to the routing conductors of the previous electrolysis cell to carry the electrolysis current from the cathode outputs to the anode frame and to the anode assembly and the the anode of the next tank. The anodes are more particularly of the prebaked anode type with prebaked carbonaceous blocks, that is to say baked before introduction into the electrolytic cell.

Since the anode blocks are consumed during the electrolysis reaction, it is necessary to periodically replace the anode assemblies. Conventionally, the replacement of an anode assembly is carried out on one side of the electrolytic cell.

However, the replacement of anode assemblies on the sides of the cells requires having a relatively large inter-cell space.

Document US3575827 discloses the replacement of an anode assembly from the top of the vessel. According to this document, the electrolytic cells are arranged transversely to the length of the line they form. The electrolytic cells include an anode assembly with an anode conductor in the form of an electrically conductive plate, not vertical, but horizontal, from which an anode is suspended, the conductive plate being supplied with electrolysis current by

J flexible electrical conductors connected to only one side, upstream, of the anode assembly. Thus, the anode assembly can be extracted from the top of the tank.

However, due to this horizontal and plate arrangement, the anode conductor is more exposed to high temperatures. This results in an increase in electrical resistivity, involving energy losses, and a reduction in the mechanical strength of the anode assembly.

In addition, the use of a plate connected and supplied with current only on the upstream side, to distribute the current on the anodes of the tank implies an important electrical balancing between the upstream side and the downstream side of the tank taking into account the current tank width. Thus, to ensure correct electrical balancing, it is necessary to use a plate with a very large section or to separate this plate into a plurality of separate parallel plates forming a plurality of separate electrical circuits of equivalent resistance. In both cases, this would lead to anode assemblies equipped with anode electrical conductors of very large size and expensive in terms of raw material.

Furthermore, the heat flow extracted by the anode conductors on the upstream side of the vessel would introduce a significant thermal imbalance between the two sides of the vessel, making it difficult to control the electrolysis process and greatly reducing the life of the vessel.

Also, the present invention aims to remedy all or part of these drawbacks by providing an electrolysis cell allowing replacement of the anode assembly from above while maintaining high efficiency.

To this end, the present invention relates to an electrolysis cell, intended for the production of aluminum by electrolysis, in which the electrolysis cell comprises a box having two opposite longitudinal sides, an anode assembly, movable only in translation. vertical with respect to the box, the anode assembly comprising at least one anode block and a transverse anode support extending substantially transversely to the longitudinal sides of the housing and from which is suspended said at least one anode block, the transverse anode support comprising two connection portions from which the transverse anode support is intended to be supplied with electrolysis current, the electrolysis cell further comprising electrical connection conductors electrically connected to the two connection portions of the transverse anode support, characterized in that the two connection portions are distant in a substantially trans direction versal of the electrolytic cell.

Due to this double connection on either side of the anode support, it is possible to reduce the quantity of raw material constituting the latter, to reduce its dimensions, in particular its average section, while maintaining an electrical conductivity balanced over the width. of the tank. The thermal balance of the tank is also not disturbed by significant differences in thermal losses between the upstream side and the downstream side, due to this double connection on either side of the anode support and more particularly of on either side of the tank.

Thus, the electrolysis cell according to the invention advantageously allows a lightening of the anode assembly and a minimization of its size, which provides a saving in raw material on the anode assembly but also on the peripheral structural equipment. The lightness and compactness of the anode assembly makes it possible to consider the use of means for moving the anode assemblies of reduced dimensions, and therefore less expensive.

The lightening of the anode assembly also makes it possible in practice to more easily envisage a replacement of an anode assembly from the top, that is to say by upward vertical traction of the anode assembly. Replacing the anode assembly from the top advantageously makes it possible to free up the space between the tanks, either to facilitate operations, or to bring the tanks closer to each other in order to align more tanks in the same space or the same number. of tanks in less space.

Advantageously, the two opposite longitudinal sides are substantially symmetrical with respect to a longitudinal median plane of the electrolytic cell, and the two connection portions are arranged on either side of said plane. More particularly, the transverse anode support has two end portions, and the connection portions are arranged on these end portions.

According to a preferred embodiment, the anode support comprises a first structure, in a first electrically conductive material, and a second structure, in a second electrically conductive material, the second material having an electrical conductivity substantially greater than that of the first material.

Thus, the anode support offers a combination of a material having high electrical conductivity, to ensure electrical conductivity and reduce energy losses, and of a material having an admittedly lower electrical conductivity, but serving as a strong and rigid supporting structure. making it possible to mechanically support a plurality of anode blocks, despite the exposure of this supporting structure to high temperatures which can reach approximately 1000 ° C.

The use of such a composite anode support makes it possible to reduce the quantity and cost of the raw materials necessary for the anode support to perform the two functions of transporting electric current and of supporting the anode blocks.

The first material is more particularly steel for its low cost and its high mechanical strength, also at high temperature. The second material is more particularly copper for its very high electrical conductivity, but also its capacity to deform and its advantageous properties as a contact surface for an electrical connection.

A copper anode support alone would deform under the weight of the anode blocks, more particularly due to the high temperatures in the vessel. Also, a steel anode support alone would have a very large footprint to ensure correct conduction of the electrolysis current to the anode blocks, despite the improvements mentioned above made by the present invention.

Preferably, the second structure is fixed to the first structure so that the first structure mechanically supports the second structure. This attachment can be achieved, for example, by bolting, welding or molding one of the materials in a skeleton formed by the other material, in particular a copper casting in a steel skeleton.

According to a particular embodiment, the first structure comprises a transverse bar extending substantially transversely from one connection portion to the other connection portion.

Such a bar is less sensitive to the thermal radiation given off by the electrolytic bath than a plate of equivalent section arranged horizontally, and the surrounding air also circulates better around it. A bar is also mechanically more suitable for supporting heavy loads.

Advantageously, the bar extends integrally between the connection portions.

By extending in one piece is meant to extend continuously from one portion of the connection to the other. In other words, each longitudinal bar is in one piece and corresponds to one and the same mechanical part extending from one connection portion to the other.

Thus, the mechanical strength of the bar is improved and this also possibly limits the energy losses compared with an electrolysis cell in which the bars forming the anode support would be discontinuous, formed of a plurality of sections joined to each other.

Advantageously, the connection portions are arranged on the ends of the longitudinal bar and are more particularly located near the longitudinal sides of the box.

Advantageously, the second structure at least partially forms the connection portions of the anode support.

Thus, the electrical connection of the anode assembly with the electrical connection conductors of the tank is achieved by means of the second structure formed with a material having good electrical conductivity. Voltage drops are then minimized for transporting the electrolysis current to the anode blocks.

According to an advantageous embodiment, the second structure comprises two distinct parts each forming at least partially one of the two connection portions.

It is not necessary for the second structure of better electrical conductivity to be continuous from one connection portion to the other of the anode support, because this second structure is used for the electrical supply of the anode blocks and would therefore hardly be traversed by an electric current over its entire length due to the fact that it is supplied with electrolysis current at two distinct points distant in a direction substantially transverse to the vessel, in particular at two opposite ends of the anode support, on each side of the vessel . This discontinuity, or separation of the second structure into two distinct parts, makes it possible to minimize the quantity of second material used, this second material conventionally having a high cost.

These two distinct parts are more particularly distant along the transverse direction of the tank.

Advantageously, the two opposite longitudinal sides of the cell are substantially symmetrical with respect to a longitudinal median plane of the electrolytic cell, and the two separate parts are arranged on either side of the plane (P). The electrolysis current flowing through each of the two separate parts is then of substantially identical intensity but in the opposite direction in the anode support so that the electrical balancing in the support is achieved at the center of the anode support. Also, the two distinct parts are advantageously substantially symmetrical with respect to said plane. The anode assemblies can therefore have a symmetry with respect to a median plane so that the anode assemblies can be inserted into the tank without there being any predetermined direction to be observed.

According to a preferred embodiment, the transverse anode support comprises a plurality of logs fixed to the first structure and intended to be sealed in recesses formed in a surface of said at least one anode block, and the distance in the transverse direction between the two distinct parts is roughly equivalent to the distance between two adjacent logs.

When the power supply of the anode blocks is carried out by means of logs electrically connected to the anode support, a zone in which the current does not flow in the anode support can be made between two logs so that this configuration allows a significant saving of second material for form the second structure. According to a preferred embodiment, the transverse anode support comprises a plurality of logs attached to the first structure and each part is attached to the first structure only at the level of the attachment of the logs and a connection portion. This fixing of the second structure to the first structure can for example be carried out by welding or bolting.

Each log can therefore be perfectly electrically powered by the part of the second structure which extends from the corresponding connection portion to the end of attachment of the log to the first structure which is the supporting structure. Also, this way of fixing the second structure on the first structure allows the first structure to be able to expand independently of the second structure so that the temperature changes undergone by the anode support during its life do not degrade it. More specifically, taking the case of steel as the first material and copper as the second material, the first material will expand less than the second material when exposed to heat, and the second material, more flexible than the first. material, which must be rigid to form the supporting structure, may deform slightly along the first structure between two fixing points.

According to a particular embodiment, the anode assembly comprises two adjacent anode blocks in a transverse direction of the electrolysis cell, the two anode blocks being supported by the same first structure and arranged under two separate parts of the second structure.

Current electrolysis cells are of large width so that it is advantageous to use two anode blocks over the width of the cell, therefore attached to the same anode assembly to facilitate the evacuation of gas accumulating under the blocks. anode blocks, the manufacture and handling of anode blocks.

According to a preferred embodiment, the anode support forms a ring delimited by two transverse bars connected to one another at their ends, the bars extending substantially parallel to each other and perpendicular to the longitudinal sides of the box.

The annular shape of the anode support allows savings in raw material and weight reduction compared to an anode support formed of a single bar or of a plate which would cover overall the same area in a horizontal plane as the ring thus formed. , for equivalent mechanical strength and electrical conductivity.

This annular shape makes it possible in particular to minimize the total lengths of electrical conductors from the connection portions to the anode blocks.

The annular shape makes it possible to minimize the warping or deformation of the spiral anode supports due to the successive expansions undergone by the anode supports.

The annular or parallel multi-bar shape also offers the possibility of enlarging the anode assemblies while minimizing the material cost. The fact of having large anode assemblies, in particular with two adjacent anode blocks in the direction of the length of the electrolytic cell, makes it possible to reduce the number of displacement means or lifting structure in the vertical direction of the anode assemblies, in particular to reduce the number of jacks, and the number of electrical connections with electrical connection conductors.

Thus, the anode assembly advantageously comprises two adjacent anode blocks in a longitudinal direction of the electrolytic cell, each anode block being supported by a separate cross bar. No bar extends above the space between the two adjacent anode blocks in the longitudinal direction of the tank so that the heat radiated by the bath between these anode blocks does not impact the resistance and conductivity of the supports anodic. Also, the bars do not obstruct the overflow of roofing material between these adjacent anode blocks.

The logs connecting the anode support to the anode blocks advantageously extend substantially vertically under each bar.

Thus, this allows a saving in material, in comparison with logs having multidirectional cross members and side members supporting a plurality of feet sealed in an anode block.

According to a preferred embodiment, the first structure forms a ring and the second structure is arranged inside the ring formed by the first structure.

This advantageously makes it possible to save material because the length and quantity of material of the second structure is thus minimized to fulfill the function of electrical conduction, more particularly from the connection portions to the upper ends of fixing the logs on the first structure. The logs must above all be held mechanically, that is why they must be fixed, more particularly welded, in line with the first structure. The electrical connection to the second structure can then be connected by the blank of the log or the current can pass through the first structure but over a short distance so as not to degrade energy consumption. Thus, when the logs connecting the anode support to the anode blocks advantageously extend substantially vertically under each bar, the first structure is located directly above the logs while the second structure is offset on the inside of the ring with respect to on the axis along which the logs extend; the second structure is not in the continuity of this axis but its length is minimized because it is positioned on the inside of the ring.

Also, the second material forming the second structure is protected by the first structure surrounding it, against degradation due to strong thermal radiation generated by a withdrawal of an adjacent anode assembly from the electrolytic bath, against projections of corrosive materials, and against possible impacts when handling the anode support alone or anode assemblies comprising such an anode support.

Advantageously, the ring has U-shaped ends, the second structure comprises two parts each having a corresponding U-shape complementary to that of the ends of the ring, and, at room temperature, the length of the outer peripheral wall of the rings. curvilinear portions of the U formed by each part of the second structure (220) is less than the length of the inner peripheral wall of the curvilinear portions of the U formed by the corresponding end of the ring

Thus, this prevents premature wear of the anode support caused by expansion of the second structure under the effect of the temperature in the electrolytic cell in operation. Without such an arrangement, the second material would force against the first structure. As the second material has a tendency to expand more than the first material, the embodiment defined above allows the second material to expand without coming forcing against the first material and risking degrading the second material or the fasteners of the second structure on the first structure. A free expansion zone is preserved for the expansion of the second structure, via a shorter radius of curvature of the second structure, in order to avoid rupture of the fasteners (welds-bolting) and of the electrical connections between the first structure and the second structure.

Advantageously, the anode assembly comprises a plurality of logs extending between the anode support and said at least one anode block and in that the anode support comprises a portion bent in a vertical plane at each of its ends so that the portions of the anode support are disposed above the upper surface of the logs.

Thus, this makes it possible to reduce the distance between the anode support and the anode block, and therefore to reduce the height of the logs. Logs of excessive height would lead to an increase in the potential drop, detrimental to the efficiency of the electrolysis cell, as well as to an increase in the length and mass of conductive material forming the anode support.

Advantageously, the anode assembly comprises a plurality of logs extending substantially vertically between the anode support and said at least one anode block, and in that the log has a substantially horizontal sealing end sealed within the anode block.

The use of such logs reduces the total number of logs and improves the thermal and electrical balance of the anode assemblies.

According to an advantageous possibility, the anode support comprises at least one reinforcing spar extending in a substantially transverse direction of the electrolytic cell and connecting the two ends of the anode support.

This characteristic makes it possible to mechanically reinforce the anode support and to limit the bending or deformation of the latter.

According to an advantageous embodiment, the anode support comprises a cross member extending in a longitudinal direction of the electrolytic cell and connecting the two longitudinal bars to each other and, where appropriate, to said at least one reinforcing beam.

This further strengthens the anode support to limit flexion.

Side rails and cross members can be used as means of gripping the anode assemblies for their handling.

According to one embodiment, the anode assembly comprises two adjacent anode blocks in a longitudinal direction of the electrolytic cell, each anode block being supported by a separate longitudinal bar.

According to another aspect, the invention relates to an electrolysis plant, in particular an aluminum smelter, comprising an electrolysis cell having the aforementioned characteristics, in which the electrolysis cells are arranged transversely with respect to the length of the line.

Other characteristics and advantages of the present invention will emerge clearly from the detailed description below of an embodiment, given by way of non-limiting example, with reference to the accompanying drawings in which:

Figure 1 is a schematic sectional side view of an electrolysis cell according to one embodiment of the invention,

Figure 2 is a schematic sectional side view of an electrolysis cell according to one embodiment of the invention,

Figure 3 is a schematic side view of an anode assembly of an electrolysis cell according to one embodiment of the invention,

Figure 4 is a top view of the anode assembly of Figure 3,

Figure 5 is a sectional view along the line l-I of Figure 3, respectively from the side on which is shown an anode assembly,

Figure 6 is a schematic side view of an anode assembly of an electrolysis cell according to one embodiment of the invention,

Figure 7 is a top view of the anode assembly of Figure 6,

Figure 8 is a sectional view along the line II-II of Figure 6,

Figure 9 is a schematic sectional side view of an anode assembly of an electrolysis cell according to one embodiment of the invention,

Figure 10 is a schematic top view of an anode assembly of an electrolysis cell according to one embodiment of the invention,

Figure 11 is a schematic side sectional view along the line III-III of Figure 10,

Figure 12 is a schematic top view of an anode assembly of an electrolysis cell according to one embodiment of the invention,

Figure 13 is a schematic side sectional view along the line IV-IV of Figure 12,

Figure 14 is a schematic perspective view of an anode assembly of Figures 12 and 13;

- Figure 15 is a schematic top view of an anode assembly of an electrolysis cell according to one embodiment of the invention.

Figure 1 shows electrolysis tanks 1 according to one embodiment of the invention, intended for the production of aluminum by electrolysis.

The electrolysis cells 1 comprise a box 2, in particular made of steel, inside which is arranged a coating 4 of refractory materials, a cathode 6 of carbonaceous material, traversed by cathode conductors 8 intended to collect the electrolysis current. at the cathode 6 in order to conduct it to cathode outlets 10 passing through the bottom or the sides of the box 2, routing conductors 12 extending substantially horizontally to the next electrolysis cell 1 from the cathode outlets 10 , an electrolytic bath 14 in which the alumina is dissolved, and a sheet 16 of liquid metal, in particular liquid aluminum, forming during the electrolysis reaction.

The box 2 may have a substantially parallelepipedal shape. It comprises two opposite longitudinal sides 18, substantially symmetrical with respect to a longitudinal median plane P of the electrolysis cell 1. The box 2 may have two transverse sides connecting the longitudinal sides, substantially delimiting a rectangle.

The term “longitudinal median plane” is understood to mean a plane substantially perpendicular to a transverse direction X of the electrolysis cell 1 and separating the electrolysis cell 1 into two substantially equal parts.

Note that the electrolysis cell 1 is arranged transversely to the length of a line of electrolysis cells. In other words, the electrolysis cell 1 extends lengthwise in a longitudinal direction Y which is substantially perpendicular to the direction X in which the line of electrolysis cells extends which the electrolysis cell 1 forms. part.

The electrolysis cell 1 according to the invention further comprises an anode assembly. The anode assembly comprises one or more anode blocks 100 and a transverse anode support 200, elongated transversely with respect to the length of the electrolysis cell 1, from which the anode block (s) 100 is suspended.

The anode blocks 100 are more particularly made of a carbonaceous material of the prebaked type, that is to say baked before introduction into the electrolysis tank 1.

The anode assembly is movable only in translation, in particular in vertical translation, relative to the box 2. Also, the electrolysis cell 1 is configured to allow a change of the anode assembly from above, as shown in the figure. 1 for tank 1 located to the right of figure 1.

As can be seen in FIG. 1 or 2, the transverse anode support 200 extends substantially orthogonally to the longitudinal sides 18 of the box 2. In other words, the transverse anode support 200 extends in a substantially transverse direction X of the electrolysis tank 1.

The transverse anode support 200 comprises two connection portions 202. It is from these connection portions 202 that the anode support 200 is supplied with electrolysis current.

The electrolysis cell 1 further comprises electrical connection conductors 20, electrically connected to the two connection portions 202 to conduct the electrolysis current to the anode support 200.

The electrical connection conductors 20 extend substantially vertically along each longitudinal side 18 of the box 2.

Note that the two connection portions 202 are arranged on either side of the plane P, so that the anode support 200 benefits from a bilateral connection.

The two connection portions 202 are separate and distant in a substantially transverse direction X from the electrolysis cell 1.

The two connection portions 202 can be arranged substantially symmetrically with respect to the plane P.

They can be arranged at each of the two ends of the transverse anode support 200.

In particular, the connection portions 202 can be arranged near the longitudinal sides 18 of the box 2.

More precisely, they can be arranged substantially vertically above the longitudinal sides 18 of the box 2, or, more advantageously, they may not extend to the right of the box 2, that is to say they can be arranged outside a volume obtained by vertical translation of a surface projected into a horizontal plane of the box 2.

The connection portions 202 are thus less exposed to the heat given off by the electrolytic bath 14 in operation.

As can be seen in Figures 10 and 12, the anode support 200 has a ring shape. In particular, it comprises two longitudinal bars 204, substantially parallel to each other, extending substantially orthogonal to the longitudinal sides 18 of the box 2, that is to say in a substantially transverse direction X of the electrolytic cell. Bars 204 are connected to each other at their ends.

Each longitudinal bar 204 extends integrally between its two ends. In other words, each longitudinal bar 204 corresponds to one and the same mechanical part extending from one of its ends to the other end.

The connection portions 202 are advantageously arranged at the level of the ends of each of the longitudinal bars 204, therefore at the ends of the ring formed by the anode support 200, so as to offset them as far as possible from the center of the tank 1 of electrolysis.

As can be seen in the figures, the anode support 200 may comprise a first structure 210, intended to ensure the mechanical strength of the anode support 200, and a second structure 220, intended to transport the electrolysis current from the portions. 202 for connection to the anode block (s) 100.

The first structure 210 is made of a first electrically conductive material. The second structure 220 is made of a second electrically conductive material. The second material has an electrical conductivity which is substantially greater than that of the first material.

For example, the first structure 210 is made of steel, the second structure 220 is made of copper. Thus, the first material can correspond to steel, the second material can correspond to copper, the anode support 200 therefore corresponding to a steel / copper composite.

The first structure 210 is formed by the longitudinal bars 204. The second structure 220 can be formed by additional copper bars, distinct from the longitudinal bars 204. The copper bars can take the shape of the longitudinal bars 204.

The second structure 220 is fixed to the first structure 210. Thus, the first structure 210 supports the second structure 220.

The first structure 210 has an annular shape. To this end, the longitudinal bars 204 may be the same bar folded at their ends or separate bars fixed together at their ends. The copper conduction bars 222 forming the second structure 220 can also be bent to conform to the shape of the first structure 210.

The electrical connection conductors 20 can be connected to the second structure 220. As can be seen in FIG. 14, the second structure 220 more particularly forms a sole 32 in each connection portion 202, the sole being intended to rest against a connection surface. of the associated electrical connection conductor. A connector 30 can be used to ensure a good electrical connection of the anode support 200 by compressing the connection portion 202 (the sole) against the associated electrical connection conductor (the connection surface).

The second structure 220 is advantageously dissociated into two distinct parts 220a, 220b corresponding to two separate and distant conduction bars 222. A part of each of the conduction bars 222 forms at least in part one of the two connection portions 202.

According to the example of Figures 1 to 9, the second structure 220 is arranged on one side of the bar 204 forming the first structure 210.

According to the example of Figures 10 to 13, the second structure 220 is arranged inside the ring formed by the first structure 210. The second structure is then shorter than if placed on the outside of the ring and further protected by the first part surrounding it.

More particularly, according to the example of Figures 10 and 11, the ring formed by the first structure 210 has U-shaped ends and the two conduction bars 222 or parts 220a, 220b of the second structure 220 also have a shape U-shaped, complementary to that of the ends of the ring formed by the first structure 210. In addition, at room temperature, that is to say at a temperature between 15 ° C and 25 ° C, the length of the outer peripheral wall of the curvilinear portions of the U formed by each conduction bar 222 is less than the length of the inner peripheral wall of the curvilinear portions of the U formed by the corresponding end of the ring.

There is thus a clearance, when cold, between the conduction bars 222 and the longitudinal bars 204, in particular at the level of the curvilinear portions of these bars.

As can be seen from the figures, the anode assembly comprises a plurality of logs 230 between the anode support 200 and the anode block (s) 100.

Each log 230 includes a proximal end attached to an upper face of the or one of the anode blocks 100 and a distal end attached to the first structure

210 only The proximal end can for example be welded to the first structure 210. An electrical connection can also be made by welding between the logs 230 and the second structure 220.

Each log 230 may extend substantially rectilinearly between its proximal end and its distal end, as shown in Figure 5.

The second structure 220 is advantageously fixed to the first structure 210 only at the level of the connection portions 202 and / or at the level of the distal ends of the logs 230, as illustrated in FIGS. 10 and 12.

The second structure 220 is for example riveted, bolted or welded to the first structure. According to the example of Figures 10 and 12, a plurality of fasteners 240 hold the second structure 220 fixed against the first structure 210.

Each part 220a, 220b supplies electric current to separate logs 230 and the parts are distant in the substantially transverse direction of the electrolytic cell.

Due to this double connection on either side of the anode support, it is possible to use a second discontinuous structure, in two parts 220a, 220b and to minimize the raw material costs. The two parts 220a, 220b are more particularly distant by a distance corresponding to the distance between the two most centrally located logs 230 of the anode assembly and symmetrical with respect to the plane P.

Each log 230 may include a single proximal end and a single distal end. In other words, the logs 230 may be devoid of cross members or spars extending in a substantially horizontal plane.

As seen in Figure 9, the proximal end may be integral with a substantially horizontal bar 240 or sealing plate extending transversely of the vessel and sealed within the anode block 100.

Figure 15 shows another anode assembly in which such a bar 240 or sealing plate extends longitudinally of the vessel.

As shown in Figures 2 to 8 and 10 to 13, the anode support 200 advantageously comprises a portion 250 bent at each of its ends.

More precisely, the longitudinal bars 204 and, where appropriate, the conduction bars 222 can be bent to present a portion 250 bent in a vertical plane at each of their ends, so that the connection portions of the anode support are arranged above. from the top surface of the logs.

Thus, the distance between the anode support and the anode block can be reduced, and consequently the height of the logs. Logs of excessive height would lead to an increase in the potential drop, detrimental to the efficiency of the electrolysis cell, as well as to an increase in the length and mass of conductive material forming the anode support.

As can be seen in Figures 2 and 11, the anode support 200 may comprise at least one reinforcing spar 260 extending in a substantially transverse direction X of the electrolytic cell 1 and connecting the two ends of the anode support 200. .

As can be seen in FIG. 12, the anode support 200 may furthermore comprise one or more cross members 270 extending in a substantially longitudinal direction Y of the electrolysis cell 1. The crosspiece (s) 270 connect the two longitudinal bars 204 to one another

These side members 260 and cross members 270 can also be used as hooking means for handling the anode assembly or the anode support.

According to the example of Figures 10 to 14, the anode assembly comprises two adjacent anode blocks 100a, 100b in a longitudinal direction Y of the electrolysis cell 1. Each anode block 100a, 100b is advantageously supported by a separate longitudinal bar 204.

As can be seen in the figures, the proximal end of each log 230 may be arranged on a center line of the upper face of the corresponding anode block 100.

Each log 230 may for example extend in a substantially vertical direction only.

According to the example of Figures 6 to 8, the anode assembly comprises two adjacent anode blocks 100a, 100a 'or 100b, 100b' in a longitudinal direction Y of the electrolytic cell 1, and these two blocks 100a, 100a 'or 100b, 100b 'anode are supported by the same longitudinal bar 204.

As can be seen in Figure 8, the logs 230 can then extend obliquely, or at least have a horizontal component.

Still according to the example of Figures 6 to 8, the logs 230 connecting the same longitudinal bar 204 to two blocks 100a, 100b or 100a ’, 100b’ anode can be arranged in pairs. The two logs 230 of the same pair are aligned in a substantially longitudinal direction Y of the electrolysis cell 1. In other words, the two logs

G

230 of the same pair may extend in a plane substantially perpendicular to a substantially transverse direction X of the electrolysis cell 1.

According to another aspect, the invention relates to an electrolysis plant, in particular an aluminum smelter, comprising an electrolysis cell 1 as described above.

Of course, the invention is in no way limited to the embodiment described above, this embodiment having been given only by way of example. Modifications are possible, in particular from the point of view of the constitution of the various elements or by the substitution of technical equivalents, without departing from the scope of protection of the invention.

Claims (22)

1. Electrolysis cell (1), intended for the production of aluminum by electrolysis, in which the electrolysis cell (1) comprises a box ( 2) having two opposite longitudinal sides (18), an anode assembly, movable only in vertical translation 5 relative to the box (2), the anode assembly comprising at least one anode block (100) and a transverse anode support (200) extending substantially transversely to the longitudinal sides (18) of the box (2) and from which is suspended said at least one anode block (100), the transverse anode support (200) comprising two connection portions (202) from which is intended to be supplied to the transverse anode support 10 (200) with electrolysis current, the electrolysis vessel (1) further comprising electrical connection conductors (20) electrically connected to the two connection portions (202) of the support (200) transverse anode, characterized in that the two connection portions (202) are distant in a substantially transverse direction of the electrolysis cell (1). 2. Electrolysis cell (1) according to claim 1, characterized in that the two opposite longitudinal sides (18) are substantially symmetrical with respect to a longitudinal median plane (P) of the electrolysis cell (1), and in that the two connection portions (202) are arranged on either side of the plane (P). 3. Electrolysis cell (1) according to claim 2, characterized in that the support 20 (200) transverse anode has two end portions, and in that the connection portions (202) are arranged on these end portions. 4. Electrolysis cell (1) according to one of claims 1 to 3, characterized in that the anode support (200) comprises a first structure (210), in a first electrically conductive material, and a second structure (220 ), in a second material 25 electrically conductive, the second material exhibiting an electrical conductivity substantially greater than that of the first material. 5. Electrolysis cell (1) according to claim 4, characterized in that the first structure (210) comprises a transverse bar (204) extending substantially transversely from one portion (202) for connection to the other portion. (202) connection. 30 6. Electrolysis cell (1) according to claim 5, characterized in that the bar (204) extends integrally between the end portions. 7. Electrolysis cell (1) according to one of claims 4 to 6, characterized in that the second structure (220) is fixed to the first structure (210) so that the first structure (210) mechanically supports the second structure (220). t 8. Electrolysis cell (1) according to one of claims 4 to 7, characterized in that the second structure (220) at least partially forms the connection portions (202) of the anode support (200). 9. Electrolysis cell (1) according to one of claims 4 to 8, characterized in that the second structure (220) comprises two distinct parts (220a, 220b) each forming at least partially one of the two portions ( 202) connection. 10. Electrolysis cell according to claim 9, characterized in that the two separate parts (220a, 220b) are distant in the transverse direction of the cell. 11. Electrolysis cell (1) according to claim 10, characterized in that the two opposite longitudinal sides (18) are substantially symmetrical with respect to a longitudinal median plane (P) of the electrolysis cell (1), and in that the two distinct parts (220a, 220b) are arranged on either side of the plane (P). 12. Electrolysis cell (1) according to claim 11, characterized in that the two separate parts (220a, 220b) are substantially symmetrical with respect to the plane (P). 13. Electrolysis cell (1) according to one of claims 10 to 12, characterized in that the transverse anode support comprises a plurality of logs (230) fixed on the first structure (210) and intended to be sealed in recesses formed in a surface of said at least one anode block (100), and in that the distance in the transverse direction between the two separate parts is substantially equivalent to the distance between two adjacent logs (230). 14. Electrolysis cell (1) according to one of claims 10 to 13, characterized in that the transverse anode support comprises a plurality of logs (230) fixed to the first structure (210) and in that each part is fixed to the first structure only at the level of the fixing of the logs and of a connection portion. 15. Electrolysis cell (1) according to one of claims 9 to 14, characterized in that the anode assembly comprises two adjacent anode blocks (100a, 100a ') in a transverse direction of the cell (1) of electrolysis, the two anode blocks (100a, 100a '; 100b, 100b') being supported by the same first structure (210) and arranged under two distinct parts of the second structure (220). 16. Electrolysis cell (1) according to one of claims 1 to 15, characterized in that the anode support (200) forms a ring delimited by two transverse bars (204) connected to each other at their ends, the bars (204) extending substantially parallel to each other and perpendicular to the longitudinal sides (18) of the box (2). 17. Electrolysis cell (1) according to claim 16, characterized in that the anode assembly comprises two adjacent anode blocks (100a, 100b) in a direction 5 longitudinal electrolysis cell (1), each anode block (100a, 100b) being supported by a separate transverse bar (204). 18. Electrolysis cell (1) according to one of claims 4 to 15, wherein, characterized in that the first structure (210) forms a ring and in that the second structure (220) is arranged at the inside the ring formed by the first 10 structure (210). 19. Electrolysis cell (1) according to claim 18, characterized in that the ring has U-shaped ends, the second structure (220) comprises two parts each having a corresponding U-shape complementary to that of the ends. of the ring, and in that, at room temperature, the length of the wall 15 outer peripheral of the curvilinear portions of the U formed by each part of the second structure (220) is less than the length of the inner peripheral wall of the curvilinear portions of the U formed by the corresponding end of the ring. 20. Electrolysis cell (1) according to one of claims 1 to 19, characterized in that the anode assembly comprises a plurality of logs (230) extending between the support 20 (200) and said at least one anode block (100) and in that the anode support (200) comprises a portion (250) bent in a vertical plane at each of its ends so that the portions (202) of connection of the anode support (200) are disposed above the upper surface of the logs (230). 21. Electrolysis cell (1) according to one of claims 1 to 20, characterized in that the anode assembly comprises a plurality of logs (230) extending substantially vertically between the anode support (200) and said anode. at least one anode block (100), and in that the log has a substantially horizontal sealing end sealed within the anode block (100). 22. An electrolysis plant, in particular an aluminum smelter, comprising a row of electrolysis cells (1) according to one of claims 1 to 21 electrically arranged in series, characterized in that the electrolysis cells are arranged transversely with respect to the length of the queue.