FR3028265A1 - PROCESS FOR HANDLING A PLURALITY OF ANODES INTENDED FOR THE PRODUCTION OF ALUMINUM BY IGNEOUS ELECTROLYSIS - Google Patents

Abstract

Each anode (40) comprises a block of carbonaceous material and at least one groove (60) which extends parallel to the longitudinal faces (52) of the block, from one lateral face (53) to the opposite lateral face (53), which opens into the lower face (51) of the block, and whose bottom face is located at a distance from the upper face (50) of the block. At least one reinforcing element (70) located in the groove locally fills the groove in the transverse direction (Y) without extending over the entire length of the block. The handling method comprises an arrangement step of arranging the anodes next to each other in a package (55) so that the reinforcing elements (70) of all the anodes of the package are arranged substantially in the same area. mechanically reinforced (75).

Description

The present invention relates to a method of handling a plurality of anodes for the production of aluminum by igneous electrolysis. The invention also relates to an anode for the production of aluminum by igneous electrolysis and an installation comprising such anode. The invention further relates to a method for producing aluminum by igneous electrolysis. Aluminum metal is produced industrially by igneous electrolysis in electrolysis cells according to the well-known Hall-Héroult process, namely by electrolysis of the alumina in solution in an electrolyte bath, essentially consisting of cryolite. The electrolyte bath is contained in an electrolysis cell comprising a steel box lined internally with refractory and / or insulating materials, and at the bottom of which is located a cathode assembly. Anodes, typically of carbonaceous material, are partially immersed in the electrolyte bath. The electrolysis current, which circulates in the electrolysis bath and possibly a sheet of liquid aluminum through the anodes and cathode elements, operates the alumina reduction reactions. French patent application FR 2 806 742 (corresponding to US Pat. No. 6,409,894) describes the installations of an electrolysis plant intended for the production of aluminum. According to the most widespread technology, the electrolysis cells comprise a plurality of so-called "precooked" anodes of carbon material which are consumed during the electrolytic reduction reactions of aluminum. Gases, and more particularly carbon dioxide, are generated during the electrolysis reactions and naturally accumulate in the form of gas bubbles under the lower, generally substantially flat, horizontal face of the anode, which influences the overall stability of the tank. It results indeed from the accumulation of these gas bubbles: electrical variations and instabilities; high frequency and long duration of anode effects; an increased possibility of reverse reaction and therefore a loss of efficiency due to the small distance between the aluminum layer produced and the CO2 bubbles; increased carbon consumption and the formation of harmful gases due to the conversion of CO2 into CO in contact with carbon. It is known to use pre-formed anodes having one or more grooves in their lower part, so as to facilitate the evacuation of the gas bubbles and to prevent their accumulation. The grooves make it possible to reduce the average free path of the gas bubbles under the anode to leave the space between the electrodes and thus reduce the size of the bubbles that form under the anode. The presence of grooves thus makes it possible to solve the aforementioned problems and to reduce energy consumption.

A well known limit to the use of these grooves results from the fact that the depth of the grooves from the underside of the anodes is limited so as not to disturb the mechanical and physical integrity of the anodes. Indeed, when the grooves are formed during the molding of the raw anodes, they create weaknesses that increase the risk that these raw anodes crack during their transport, storage or cooking. And when the grooves are formed by sawing the cooked anodes, the mechanical stresses and vibrations exerted by the saw blades can cause the crumbling, cracking and bursting of the anodes if the grooves are too deep.

However, the anodes are consumed progressively during the electrolysis reaction, and this over a height greater than the depth of the grooves. It follows that the lifetime of the grooves of anode is less than the lifetime of the anode. Therefore, for a certain period of time during the life of the anodes, the lower part of the anodes no longer has a groove. The problems mentioned above for anodes without grooves are then felt. By way of example, for a 600 mm high anode with a consumable carbon height of 400 mm and a groove of 250 mm deep, the groove produces a beneficial effect for only 62.5% of the service life. the anode. An object of the invention is to overcome the disadvantages mentioned above, that is to say to avoid problems related to the accumulation of gas under the anode, and for a longer time than in the past. prior art, without compromising the integrity of the anodes during their manufacture, storage, transportation or use. For this purpose, and according to a first aspect, the invention relates to a method of handling a plurality of anodes for the production of aluminum by igneous electrolysis.

Each anode comprises a substantially parallelepipedal block of carbonaceous material having an upper face, a lower face, and a peripheral wall formed of two longitudinal faces and two lateral faces. In addition, each anode comprises at least one groove which extends substantially parallel to the longitudinal faces, from one of the lateral faces to the opposite lateral face, and which opens into the lower face of the anode. In addition, the groove has a bottom face located at a distance from the upper face of the anode, so that the anode has a solid upper portion located between the bottom face of the groove and the upper face of the anode. . At least one reinforcing member is located in the groove, said reinforcing member extending from a longitudinal wall of the groove to the opposite longitudinal wall and having a smaller maximum dimension than that of the groove in the direction orthogonal to the side faces of the anode - said longitudinal direction X. The method comprises an arrangement step of arranging the anodes next to each other in a package, a longitudinal face of an anode being opposite and adjacent to each other. to a longitudinal face of an adjacent anode.

According to a general definition of the invention, in the arrangement step, the anodes are arranged relative to each other so that the reinforcing elements of all the anodes of the packet are arranged substantially in one and the same volume of the package. anodes, said volume extending: in a direction (Z) orthogonal to the upper and lower faces, over substantially the entire height of the anodes of the packet; in a direction orthogonal to the longitudinal faces of the anodes, said transverse direction (Y), over substantially the entire dimension of the anode packet; and in the longitudinal direction (X), substantially a distance equal to said maximum dimension of said reinforcing element.

Said volume thus forms in the anode package a mechanically reinforced zone. Thanks to the presence of the reinforcing elements, and to the particular arrangement of the anode package providing for the location of these reinforcing elements in the same volume occupying only a portion of the anode package, the invention makes it possible to create in this package of anodes a mechanically reinforced area.

On the one hand, this mechanically reinforced zone makes it possible to make grooves of greater height than in the prior art, the loss of mechanical strength generated by the size of the groove being compensated by the creation of this zone. It is therefore possible to obtain the beneficial effects of the groove on the evacuation of gases over a greater proportion of the life of the anode.

On the other hand, this mechanically reinforced zone can withstand greater mechanical stresses than the zones of the anode bundle in which the grooves are devoid of reinforcement elements. Indeed, by filling a groove locally, a reinforcing element prevents, under the action of a force exerted on the anode, a mutual approximation of the longitudinal walls of the groove which would cause internal stresses that could lead to damage to the groove. the anode. The aforementioned specific arrangement of the anode reinforcing elements of the package creates a global reinforcement zone preventing damage to the anodes during the overall handling of the anode package.

It is specified that, if all the reinforcing elements of all the anodes of the packet are situated substantially in the same mechanically reinforced zone, on the other hand a reinforcement element of a given anode of the packet does not necessarily occupy the whole of the portion. corresponding to the mechanically reinforced area. By "corresponding portion of the mechanically reinforced zone" is meant the intersection between the mechanically reinforced zone and the groove of said given anode in which said reinforcing element is located. In addition, it is specified that the expression "the upper solid portion of the anode" is used to designate a portion of the anode devoid of groove. However, this portion may include non-solid local areas, in particular recesses for fixing the anode in the electrolysis cell. The invention is advantageously applied when the anodes are arranged next to each other - the transverse direction then being substantially horizontal - and the anode package is intended to be clamped between the legs of a clamp-type tool. The invention is also advantageous when the anodes are stacked on each other - the transverse direction then being substantially vertical - to prevent the weight of the upper anodes from causing pinching of the grooves of the lower anodes. It should be noted that the terms "upper", "lower" and "height" are used with reference to the position occupied by the anode in the electrolysis cell, it being understood that the anode in the package may have an orientation different. Concretely, if the reinforcing element is not taken into account, the groove opens into the two lateral faces of the anode. Taking into account the reinforcing element, the groove can only lead to one of the lateral faces of the anode, depending on whether the reinforcing element extends over the entire height of the groove or not.

The dimension of the reinforcing element in the longitudinal direction may be substantially constant over the entire height of the groove. In addition, this reinforcing element may be located adjacent to a lateral face of the anode, and have at least one portion located at a distance from the bottom face of the groove, so as to optimize the location of the zone mechanically. reinforced - in terms of the distribution of the points of application of the efforts and the limitation of the cantilever.

It can be expected that the anodes of the package are substantially identical. It can also be provided that an anode has a plurality of parallel grooves (for example two), each of the grooves including a reinforcing element, the reinforcing elements being substantially identical and vis-à-vis in the transverse direction.

According to a possible embodiment, in the arrangement step, the anodes are arranged relative to each other so that the lower and upper faces of the anodes of the anode package extend vertically and that said mechanically reinforced zone is located. in the lower part of the package of anodes. This makes it possible in particular to limit the effect of the weight on the deformation of the grooves of the anodes. The positioning of the mechanically reinforced zone at the bottom of the anode package improves the stability of the anode package during its gripping and handling, especially between the legs of a gripper type tool. Moreover, according to a possible embodiment, in the arrangement step, the anodes are arranged relative to each other so that, on one side of the anode package, the upper face of an anode and the lower face of another anode. In this case, the reinforcing elements, if they do not extend over the entire height of the groove, are not all vis-à-vis in the transverse direction Y. On the other hand, a reinforcement element of an anode may advantageously be substantially vis-à-vis the upper solid portion of the adjacent anode. Thus, there are created in the anode packet, and more precisely in the mechanically reinforced zone, two solid zones along the entire Y direction, these solid zones being able to be distinct and spaced apart from one another. Concentrating the forces exerted on the anode package in these two solid areas is very advantageous in terms of mechanical strength. However, the forces can also be exerted nearby but at a distance from these full areas, because these contribute to reinforce locally the package of anodes, including on their periphery. The method may further comprise a subsequent clamping step of clamping the anode package between two members, in the transverse direction, exerting a force in at least a first bearing zone located substantially opposite the mechanically reinforced zone. , substantially facing at least one reinforcing element. By applying most or all of the force in the mechanically reinforced zone of the anode package, the risk of damage to the anodes of the package during handling is considerably reduced. By "substantially opposite" is meant next to or near the mechanically reinforced area. Indeed, as explained above, the anode package is locally reinforced not only in the mechanically reinforced zone, of course, but also at the periphery of said mechanically reinforced zone. Thus, applying a force outside the mechanically reinforced zone, but close to it, does not risk damaging the grooves or the anode.

It can be expected that, in the clamping step, a force is also exerted in at least one second bearing zone situated at a distance from the mechanically reinforced zone, the first force being N times greater than the second force, with N k 1.3, or even N k 1.5, or even N 2. In other words, the second bearing zone is opposite a portion of the grooves of the anodes of the package which is devoid of reinforcing elements. However, this is not necessarily a vacuum zone over the entire dimension of the anode package in the transverse direction Y. Indeed, the second bearing zone may be opposite the upper portion full of less some of the anodes of the package. Thus, when the clamping of the anode package can not be done in a single support zone on each side of the anode package, it is possible to calibrate the respective forces on the support zones to limit the forces in the most fragile areas, in favor of the mechanically reinforced area. For example, in the clamping step, the bundle of anodes can be clamped between two legs of a tool, each of the legs having four support points, two of these support points being in the first zone of support, the other two points of support being in the second support zone. The differentiated calibration of the forces applied in the first and second zones can be obtained by using an eccentrically articulated lifter. The two support points in the first support zone are advantageously located substantially facing at least one reinforcing element of an anode of the package. According to one possible embodiment, the reinforcing element extends from a lateral face of the anode towards the opposite lateral face, over a maximum length (I) such that I <L / 2, where L is the length of the anode between its lateral faces. Preferably, one can have I 113, and / or I k U8, or even I k L / 5, to ensure sufficient strength of the reinforcing element without penalizing the efficiency of the groove during the production of aluminum by electrolysis. The volume forming in the anode package a mechanically reinforced zone therefore extends over the same maximum length I in the longitudinal direction X. This handling method can be implemented: for the transport of a package of raw anodes to an anode baking oven; and / or for transporting a package of cooked anodes from anode baking furnace; and / or for transporting a bundle of raw or cooked anodes from or to a storage area. These are operations in which the risk of damage to the anodes, relatively high in the prior art, is considerably reduced by the invention. According to a second aspect, the invention relates to an anode for the production of aluminum by igneous electrolysis, comprising a substantially parallelepipedic block of carbonaceous material having an upper face, a lower face, and a peripheral wall formed of two longitudinal faces. and two lateral faces, the anode having at least one groove which extends substantially parallel to the longitudinal faces, from one of the lateral faces to the opposite lateral face, and which opens into the lower face of the anode. In addition, the groove has a bottom face located at a distance d1 from the upper face of the anode, the anode further comprising at least one reinforcing element located in the groove, said reinforcing element extending from a longitudinal wall of the groove to the opposite longitudinal wall. This reinforcing element extends from a lateral face of the anode towards the opposite lateral face over a maximum length I such that L / 8E I <1/2, where L is the length of the anode between its lateral faces; has an upper edge which is located at a non-zero distance d2 from the bottom face of the groove. Thanks to these geometric characteristics of the anode and the reinforcing element present in the groove, the invention allows the production of an anode having a groove whose height is close to the height of the anode intended to be consumed. therefore, which can fulfill its function over a large part of the anode life, without jeopardizing the mechanical strength of the anode - typically during demolding, transport, storage, cooking, handling. The aforementioned geometrical characteristics result from an optimization of contradictory parameters, namely: the maximization of the height of the grooves and their effective length during their existence during the production of aluminum by electrolysis and the obtaining of a mechanical resistance sufficient of the anode.

In addition, the dimensions and the location of the reinforcing element allow an embodiment of the anode and its groove by molding, with use of a blade included in the mold and sliding release of the anode formed. The anode according to the invention may be a green anode or a cooked anode.

The dimension of the reinforcing element in the longitudinal direction may be substantially constant over the entire height of the groove, and thus correspond to the "maximum length I". It can further be provided that an anode has a plurality of parallel grooves (for example two), each of the grooves including a reinforcing element. The reinforcing elements may be substantially identical and vis-a-vis in the transverse direction. A groove may also comprise a plurality of reinforcing elements, each of them preferably having the aforementioned geometric characteristics. According to a possible advantageous embodiment, one can have I 5 L / 3, which makes it possible to increase the effectiveness of the groove during the production of aluminum.

According to an advantageous embodiment possible, one can have I L / 5, which gives the anode a good rigidity and a significant resistance to mechanical stresses. It can be provided that the height h of the groove is between 0.5 H and 0.8 H, preferably between 0.6 H and 0.7 H, where H is the height of the anode between its lower faces and higher. For example, the height h of the groove may be greater than 350 mm, or even greater than 400 mm, for an anode having a height H of the order of 650 mm. The reinforcing member may be adjacent to the underside of the anode. Alternatively, it may be located at a distance from the underside of the anode. According to one possible embodiment, the reinforcing element has substantially the shape of a rectangular parallelepiped having a face located substantially in the plane of the lower face of the anode and a face located substantially in the plane of a lateral face of the 'anode. In addition: the length of the reinforcing element - along a direction orthogonal to the lateral faces of the anode, said longitudinal direction - is between 300 and 500 mm, preferably between 310 and 400 mm; and the height of the reinforcing element - along a direction orthogonal to the lower and upper faces of the anode - being between 100 and 300 mm, preferably between 150 and 200 mm.

The reinforcing element may be made of the same material as the anode and molded with the anode. Alternatively, the reinforcing member may be an insert separate from the carbonaceous material block and placed in the groove during molding, or after molding. The reinforcing element can then be made of carbon material or aluminum, and can therefore remain in place in the groove both during the firing of the anode and in the electrolysis cell. It would be possible alternatively to envisage a reinforcement element in the form of an insert made of another material which could disappear by combustion and / or by gasification during the baking of the anodes (and could no longer provide mechanical reinforcement of the anodes after their cooking) or can be removed after cooking the anodes. According to one possible embodiment, the anode comprises a plurality of substantially parallel grooves, and a reinforcing element located in each of the grooves, the reinforcing elements being located facing each other along the transverse direction. For example, it is possible to provide two identical grooves each comprising a reinforcing element, the two reinforcing elements being identical and located identically in the corresponding groove. According to a third aspect, the invention relates to a process for producing aluminum by igneous electrolysis, which comprises the implementation of the handling method as previously described, and / or which comprises the use of at least one anode such as than previously described. The process for producing aluminum by igneous electrolysis can typically comprise the steps of: providing at least one anode as previously described; install the anode in an aluminum electrolysis cell; passing current in the electrolytic cell through the anode; and recovering the aluminum obtained by electrolysis in the bottom of the electrolytic cell. According to a fourth aspect, the invention relates to an installation, such as an anode manufacturing facility for the production of aluminum by igneous electrolysis or an igneous electrolysis aluminum production facility, the installation comprising at least one anode as previously described.

Several possible embodiments of the invention will now be described, by way of non-limiting examples, with reference to the appended figures: FIG. 1 is a diagrammatic sectional view of an electrolytic aluminum production plant comprising anodes according to the invention; Figure 2 is a perspective view of an anode according to the invention; Figure 3 is a longitudinal sectional view of an anode according to a first embodiment of the invention; FIG. 4 is a side view of an anode according to the invention; Figures 5a to 5d are longitudinal sectional views of an anode according to other embodiments of the invention; FIG. 6 illustrates a step of clamping anode pack in the handling method of the invention; Figure 7 is a schematic representation similar to Figure 6, showing the bearing areas on the anodes during tightening; FIG. 8 is a diagrammatic representation in longitudinal section of an anode of the anode packet of FIG. 7, showing the bearing zones during clamping; Figure 9 is a representation similar to Figure 8, showing an anode in strong lines and an adjacent anode in fine lines. FIG. 1 represents an electrolysis cell 3 located in a building 2 of an electrolytic aluminum production installation 1, and more particularly in an electrolysis room of such an installation 1. Each cell 3 extends in a transverse direction Y, and the cells 3 are arranged next to each other in a longitudinal direction X. Each cell 3 comprises a tank 20, a support structure 30 called "superstructure" and a plurality of anodes 40, 40 . The tank 20 comprises a box 21 of steel, an inner lining 22 which is generally formed by blocks of refractory materials, and a cathode assembly which comprises blocks made of carbonaceous material, called "cathode blocks" 23, and metal connecting bars 24 to which are fixed the electrical conductors 45, 46, 47 serving for the routing of the electrolysis current. Each anode 40 is provided with a metal rod 41 which is typically attached to the anode 40 via a multipode 42. The anodes 40 are removably attached to a movable metal frame 25, called "anode frame" by a removable connector 26. The anode frame 25 is carried by the superstructure 30 and fixed to electrical conductors 47, called "positive risers", for the routing of the electrolysis current. Generally, more than a hundred cells 3 are arranged next to each other, in rows or queues, in the direction X. The cells 3 of a row are electrically connected in series using connecting conductors 45. , 46, 47. The cells 3 are arranged so as to clear a circulation aisle along the installation 1 and an access path 49 between the cells 3. Each cell 3 is provided with a rollover system. This includes a series of removable covers 33 which are typically metallic, and more typically aluminum alloy. The rollover system confines the effluents within the interior of the cell 3 and is connected to means (not shown) for discharging the effluents and directing them to a treatment center. The covers 33 are typically inserted into a guide groove 35 arranged along the cell 3 (in the Y direction) and are placed on a flange 31 of the superstructure 30. The rod 41 of the anodes 40 typically emerges from the overturning through openings arranged for this purpose in the rollover system. According to the most widespread technology, the anodes 40 are of precooked carbon material. The anodes 40 are gradually consumed during the electrolytic reduction reactions of the aluminum, and the spent anodes 40 'must be replaced by new anodes 40. A new anode 40 according to the invention is shown in FIG. 40 comprises a substantially parallelepipedal block of carbonaceous material. It has an upper face 50, a lower face 51 and a peripheral wall formed of two longitudinal faces 52 and two lateral faces 53. As illustrated in FIG. 2, the longitudinal direction X is defined as the direction orthogonal to the lateral faces 53 of the anode 40. The term "length" will be used with reference to the X direction; the transverse direction Y as the direction orthogonal to the longitudinal faces 52 of the anode 40. The term width will be used with reference to the direction Y; the direction Z as the direction orthogonal to X and Y. The terms "upper", "lower" and "height" will be used with reference to the direction Z. It should be noted that the directions X, Y, Z of Figure 2 correspond to the directions X, Y, Z of Figure 1. Indeed, for simplicity, the anode 40 will be described with reference to the position it occupies in the cell 3 of electrolysis. However, during its handling, the anode 40 may have a different orientation. In the embodiment shown, the anode 40 has a plane of symmetry P1 longitudinal - parallel to (X, Z). It also presents, with the exception of the reinforcement elements that will be described later, a plane of symmetry P2 transverse - parallel to (Y, Z).

The anode 40 has three recesses 54 formed from its upper face 50. These recesses 54, which are each intended to receive a foot of the multipode 42, have for example the shape of a Z axis cylinder. The recesses 54 are here substantially identical, centered on the plane Pi, aligned in the direction X, and evenly spaced along the direction X. In addition, the anode 40 comprises at least one groove 60 intended to facilitate the evacuation of the gas bubbles generated during electrolysis reactions. In the embodiment shown, the anode 40 has two grooves 60 substantially identical and parallel, disposed substantially symmetrically with respect to the plane Pl. However, the anode 40 could comprise a different number of grooves, for example a single or on the contrary more two. Each groove 60 extends substantially parallel to the longitudinal faces 52, of a lateral face 53 to the opposite lateral face 53, and opens into the lower face 51 of the anode 40. The groove 60 is in the form of a rectangular parallelepiped having two longitudinal walls 61 and a bottom face 62 - or upper face - as seen in Figure 4. The bottom face 62 is located at a distance dl from the upper face 50 of the anode 40. L anode 40 thus has a solid upper portion 56 located between the bottom face 62 of the groove 60 and the upper face 50 of the anode 40. The anode 40 further comprises at least one reinforcing element 70 located in the groove 60. This reinforcing element 70 extends from a longitudinal wall 61 of the groove 60 to the opposite longitudinal wall 61, so that it locally fills the groove 60. It thus forms a mechanical reinforcement preventing a mutual approximation of the walls. longitudinal 61 groove 60 under the effect of one of the efforts to which the anode 40 is subjected during its manufacture, cooking, storage, transportation and / or use. The reinforcing element 70 is located in the groove 60. In particular, it does not extend over the entire length L of the anode 40, so that there always exists a groove 60 opening on the lower face 51 of the anode 40 for the evacuation of the gases that form during the entire period of use of the anode 40.

The reinforcing element 70 may be made of the same material as the anode 40 - that is to say of carbon material - and be molded with the anode. In the embodiments shown, the reinforcing element 70 extends from a lateral face 53 of the anode 40 towards the opposite lateral face 53 over a maximum length I. This length I may be substantially constant over the entire height of the reinforcing element 70 (Figures 3 and 5b to 5d), or not (Figure 5a). Alternatively, it could be provided that the reinforcing member 70 is not adjacent to a side face 53 of the anode 40. In order to meet the requirements such as: maximizing the carbon mass of the anode 40, maximizing of the height of the groove 60 and obtaining sufficient mechanical strength to prevent damage to the anode 40 during its handling, the reinforcing element 70 must be designed and located within the groove 60 so appropriate. Thus, it has been determined that the following characteristics - which need not all be met together on a given anode - have a number of advantages. On the one hand, the length I of the reinforcing element 70 - or the maximum length if the length I is not constant over the entire height of the reinforcing element 70 - may be such that I to L / 8 and I <L / 2, preferably I 5 L / 3 and / or I k to L / 5, L being the length of the anode 40 between its side faces 53.

On the other hand, the reinforcing element 70 may have at least one portion located at a distance from the bottom face 62 of the groove 60, in order to optimize the distribution of the points of application of the forces, by limiting the door-to-door false when handling the anodes 40, and to maintain optimum efficiency of the groove. This can be translated into practice in different ways. Thus, as in FIG. 5a, the reinforcing element 70 can extend over the entire height of the groove 60. On the other hand, the reinforcing element 70 can have an upper edge 72 located at a distance d2. none of the bottom face 62 of the groove 60, as in Figures 3 and 5b to 5d (in other words, the reinforcing element 70 does not extend to the bottom face 62 of the groove 60). Furthermore, the reinforcing member 70 may be located adjacent to the lower face 51 of the anode 40 (as in Figures 3, 5a, 5c and 5d) or not (as in Figure 5b). Furthermore, a given groove 60 may comprise a single reinforcing element (FIGS. 3, 5a, 5d) or several disjoint reinforcing elements 70, in particular two (FIGS. 5b, 5c).

When the anode 40 has a plurality of grooves 60, the reinforcing elements 70 of the different grooves are located opposite one another along the transverse direction Y. In this case, according to one possible embodiment, the grooves 60 are substantially identical and have identical configurations as to the number, the geometric characteristics and the location of the reinforcing elements 70.

Due to the presence of one or more reinforcement elements 70 having particular geometrical characteristics and positioning, as explained above, the invention makes it possible to increase the height h of the groove 60 with respect to the art. prior. Thus, this groove 60 remains present, and therefore produces its beneficial effects, over a greater part of the life of the anode 40 before the latter is too consumed and must be replaced. For example, for an anode 40 having a height H of the order of 650 mm - between its lower 51 and upper 50 - the consumable carbon height is generally of the order of 450 mm, before it it is necessary to replace the anode 40.

Thanks to the invention, it is possible to achieve a height h of the groove 60 greater than 350 mm, or even greater than 400 mm, for example of the order of 420 mm or even 450 mm. By way of comparison, the height h for this type of anode of the prior art is of the order of 250 to 300 mm approximately. The other dimensions of the anode 40 illustrated in the figures can be as follows: length L of the anode 40: approximately 1500 mm; depth p of the recesses 54: approximately 150 mm; diameter of the recesses 54: about 200 mm; - width of the grooves 60 in the direction Y: of the order of 12 to 15 mm. According to a first embodiment, illustrated in FIG. 3, the reinforcing element 70 has substantially the shape of a rectangular parallelepiped having a face 71 situated substantially in the plane of the lower face 51 of the anode 40 and a face 73 located substantially in the plane of a lateral face 53 of the anode 40. The length I of the reinforcing element 70 is between 300 and 500 mm, for example of the order of 350 mm (or about 23% of the). The height d of the reinforcing element 70 is between 100 and 300 mm, for example of the order of 180 mm. As for the distance d2 between the bottom face 62 of the groove 60 and the upper edge 72 of the reinforcing element, it is for example of the order of 250 mm. Other embodiments are illustrated in Figures 5a to 5d. In FIG. 5a, the reinforcing element 70 has substantially the shape of a trapezium whose base forms the upper edge 72, coinciding with the bottom face 62 of the groove 60, and the other base forming the lower edge 71, in the plane of the lower face 51 of the anode 40. Furthermore, a lateral face 73 of the reinforcing element 70 is located substantially in the plane of a lateral face 53 of the anode 40. Finally, the other lateral face 73 of the reinforcing element 70 forms an inclined plane so that the dimension along X of the reinforcing element 70 decreases towards the lower face 51 of the anode 40. The maximum length I is of the order of L / 5. In FIG. 5b, the groove 60 comprises two substantially identical reinforcement elements 70. Each reinforcing element 70 has substantially the shape of an elongate rectangular parallelepiped along X, of length I substantially constant and close to L / 5. In the direction Z, the reinforcing elements 70 are spaced from the bottom face 62 of the groove 60, one from the other, and from the lower face 51 of the anode 40. The embodiment of FIG. 5c is similar to that of FIG. 5b, except that the lower reinforcing member 70 is adjacent to the lower face 51 of the anode 40.

In FIG. 5d, the groove 60 comprises a single reinforcing element 70 having substantially the shape of an elongated rectangular parallelepiped along X, of length I substantially constant and close to L / 3. The reinforcing member 70 is spaced from the bottom face 62 of the groove 60 but adjacent to the lower face 51 of the anode 40. Reference is now made to FIGS. 6-8 to describe the method according to the invention of handling anodes arranged in a package 55. This method can be implemented for transporting a package 55 of anodes 40 raw to anode baking oven, for the transport of a package 55 of anodes 40 fired from anode baking furnace, and / or for transporting a package of anode 40 raw or cooked from or to a storage area.

The anodes 40 involved in the process according to the invention may be as previously described. More generally, the handling method according to the invention can be applied to anodes 40 having at least one reinforcing element 70 in the groove 60, said reinforcing element 70 extending from a longitudinal wall 61 of the groove 60 at the opposite longitudinal wall 61 and having a maximum length I less than the length of the groove 60 - which is generally the length L of the anode 40. The method comprising an arrangement step of arranging the anodes 40 at each other. next to the others in a bundle 55. In such a bundle 55, as illustrated in FIG. 7, a longitudinal face 52 of an anode 40 is opposite and adjacent to a longitudinal face 52 of an adjacent anode . In addition, the reinforcing elements 70 of all the anodes 40 of the packet 55 are arranged substantially in the same volume of the packet 55 of anodes. As can be seen in particular in FIGS. 6 to 8, this volume extends: along the direction Z, over substantially the entire height of the anodes 40 of the pack 55; in the transverse direction Y, over substantially the entire dimension of the anode package 55; and in the longitudinal direction X, substantially a distance equal to said maximum dimension I of said reinforcing element 70.

This volume thus forms a mechanically reinforced zone 75 in the anode package 55. Thus, despite the presence of the grooves 60, a mechanically reinforced zone 75 is created in the anode package 55 on which relatively mechanical stresses can be applied. elevated without causing damage to the anodes 40 (under normal handling conditions). As illustrated in FIG. 7, it is possible to arrange the anodes 40 relative to one another so that the transverse direction Y is substantially horizontal and the reinforcing elements 70 of all the anodes 40 of the pack 55 are located in part. The mechanically reinforced zone 75 can then be in the form of a rectangular parallelepiped forming the base of the package 55 of anodes, on which it rests. In addition, provision can be made to arrange the anodes 40 relative to each other so that, on one side of the anode package 55, the upper face 50 of an anode 40 and the lower face 51 of an other anode 40.

In this case, as illustrated in FIG. 9, a reinforcing element 70a of a given anode 40a of the anode package 55 may be in facing relation - in the Y direction - of the upper solid portion 56b. an adjacent anode 40b of the pack 55, thereby forming a first "full" area 91. In addition, a reinforcing member 70b of the anode 40b may be in facing relation - in the Y direction - of the upper solid portion 56a of the anode 40a, thus forming a second "full" zone 92. In the embodiment shown in Figure 9, these solid areas 91, 92 are distinct and spaced from each other. Thus, the combination of the reinforcement elements 70 and the upper solid portions 56 creates in the packet 55 of anodes 40 two solid areas 91, 92 substantially continuous over the entire direction Y, despite the presence of the grooves 60. These solid areas 91, 92 are included in the mechanically reinforced zone 75. They create within them, but also at their periphery, mechanically stronger zones on which relatively high mechanical stresses may be applied without causing damage to the anodes 40 (under normal conditions Handling).

Although the packet 55 shown in Fig. 7 has five anodes 40, this figure should not be considered limiting. Once the anodes 40 are arranged in such a package 55, the package 55 of anodes can be clamped in the transverse direction Y between two members, for example between the legs 76 of a clamp type tool 77. In order not to damage the anodes 40, the invention takes advantage of the creation of the mechanically reinforced zone 75, providing that the clamping force is exerted in a first bearing zone 81 located substantially opposite this mechanically reinforced zone 75, (see Figures 7 to 9). In the embodiment shown, the tabs 76 of the clamp 77 each comprise four support points. Thus, on each side of the pack 55 of anodes 40, the clamping force is distributed in several localized spot efforts. First two support points exert their efforts in the first bearing zone 81 and are advantageously located each substantially facing at least one reinforcing element of an anode 40 of the anode package 55 or the upper solid portion. 56 of an anode 40 of the anode package. Two second bearing points exert their forces in a second bearing zone 82 situated above the first bearing zone 81, away from the mechanically reinforced zone 75. The first bearing points are generally substantially horizontally aligned. and the second fulcrums are generally substantially horizontally aligned above the first fulcrums. Two of the forces exerted by the four fulcrums are exerted in the first bearing zone 81, on a "full" portion of the packet 55 of anodes or in the vicinity of such a solid portion. And two of the forces exerted by the four fulcrums are exerted in the second bearing zone 82 located at a portion of the packet 55 of anodes which comprises - in the direction Y - a succession of solid portions ( upper solid portion 56 of an anode 40) and empty parts (part of a groove 60 without reinforcing member of an anode 40). Thus, when the clamping of the anode package can not be done in a single support zone on each side of the anode package, it is possible to calibrate the respective forces on the support zones to limit the forces in the most fragile zones, in favor of the mechanically reinforced zone 75. However, since the force exerted in the second bearing zone 82 is only a part of the overall clamping force, the integrity of the anodes 40 is not jeopardized.

In order to improve the method, it can further be provided that the force exerted (or the sum of the point forces exerted) in the second bearing zone 82 has a smaller amplitude than the force exerted (or the sum of the one-off efforts exerted) in the first bearing zone 81, that is to say in "full" portions. For example, the amplitude of the forces exerted in the first bearing zone 81 may be N times greater than the amplitude of the forces exerted in the second bearing zone 82. It may be chosen to have N k 1.3 or, in particular, according to one embodiment of the invention, a ratio of N = 1.5 can be provided, which corresponds to a distribution of 60/40 between the forces on the zone 81 and the efforts on the zone 82. One can even envisage a distribution of 70/30. By way of comparison, in the prior art (that is, in the absence of a mechanically reinforced zone created by reinforcing elements and a specific arrangement of the anodes in the package), the ratio N is generally of 1, which corresponds to a distribution of 50/50 between said forces, and the bearing zones are arranged substantially symmetrically on either side of the plane P2. Thus, compared with the aforementioned prior art, the bearing zones have been lowered, and as illustrated in FIG. 7, this relative calibration of the forces can be obtained by providing the free end of the tabs 76 of the clamp 77 a spreader 78 articulated around an axis 79 not centered between the lower bearing zones 81 and 82. The difference of the lever arm causes the difference in the amplitudes of the clamping forces exerted. Such a handling method can be implemented in an anode manufacturing plant 40, whether on raw anodes intended to be placed in an oven or on baked anodes intended to be placed in a cell 3. electrolysis, during storage or transport of the anodes.

It goes without saying that the invention is not limited to the embodiments described above as examples but that it includes all the technical equivalents and variants of the means described as well as their combinations.

Claims (17)

REVENDICATIONS1. A method of handling a plurality of anodes (40) for the production of aluminum by igneous electrolysis, each anode (40) having a substantially parallelepipedic block of carbonaceous material having an upper face (50), a lower face (51) ), and a peripheral wall formed of two longitudinal faces (52) and two lateral faces (53), each anode (40) having at least one groove (60) extending substantially parallel to the longitudinal faces (52). from one of the lateral faces (53) to the opposite lateral face (53) and which opens into the lower face (51) of the anode (40), the groove (60) having a bottom face (62) remote from the upper face (50) of the anode (40) so that the anode (40) has a solid upper portion (56) between the bottom face (62) of the groove (60) and the upper face (50) of the anode (40), at least one reinforcing member (70) being located in the groove (60), said reinforcing member (70) extending from a longitudinal wall (61) of the groove (60) to the opposite longitudinal wall (61) and having a maximum dimension (I) less than that of the groove (60) in the direction orthogonal to the side faces of the anode (40), said longitudinal direction (X), the method comprising an arranging step of arranging the anodes (40) next to each other in a package (55), a longitudinal face (52) of an anode (40) facing and adjacent a longitudinal face (52) of an adjacent anode (40), characterized in that In the arrangement step, the anodes (40) are arranged relative to each other so that the reinforcing elements (70) of all the anodes (40) of the package (55) are arranged substantially in the same volume of the package. (55) of anodes, said volume extending: in a direction (Z) orthogonal to the upper (50) and lower (51) faces, on substantially the entire height of the anodes (40) of the package (55); in a direction orthogonal to the longitudinal faces (52) of the anodes (40), said transverse direction (Y), over substantially the entire dimension of the packet (55) of anodes; and in the longitudinal direction (X), substantially a distance equal to said maximum dimension (I) of said reinforcing member (70); said volume thus forming a mechanically reinforced area (75) in the anode package (55). 2. Method according to claim 1, characterized in that, in the arranging step, the anodes (40) are arranged relative to one another so that the lower (51) and upper (50) faces of the anodes (40) of the anode package (55) extend vertically and said mechanically reinforced region (75) is located at the bottom of the anode package (55). 3. Method according to claim 1 or 2, characterized in that, in the arranging step, the anodes (40) are arranged relative to one another so that on one side of the pack (55) the anodes (40), alternating the upper face (50) of one anode (40) and the lower face (51) of another anode (40). 4. Method according to one of claims 1 to 3, characterized in that it comprises a subsequent clamping step of clamping the package (55) of anodes (40) between two members (76), in the transverse direction (Y), exerting a force in at least a first bearing zone (81) located substantially opposite the mechanically reinforced zone (75), preferably substantially facing at least one reinforcing element (70). 5. Method according to claim 4, characterized in that, in the clamping step, a force is also exerted in at least a second bearing zone (82) located at a distance from the mechanically reinforced zone (75), the first force being N times greater than the second force, with N k 1.3, or even N k 1.5, or even N k 2. 6. Method according to claim 4 or 5, characterized in that the reinforcing element (70) extends from a side face (53) of the anode (40) towards the opposite side face (53) on a maximum length (1) such that I <L / 2, and preferably such that I 5 1/3, and / or I k L / 8, or even 1 k 1/5, where L is the length of the anode (40) between its lateral faces (53), and in that the first bearing zone (81) is situated substantially facing at least one reinforcing element (70) of an anode (40) of the package (55). 7. Method according to one of claims 1 to 6, characterized in that it is implemented: for transporting a package (55) of anodes (40) raw to anode baking oven ( 40); and / or for transporting a package (55) of anodes (40) fired from anode baking furnace (40); and / or for transporting a bundle (55) of raw or cooked anodes (40) from or to a storage area. 8. Anode for the production of aluminum by igneous electrolysis, comprising a substantially parallelepipedal block of carbonaceous material having an upper face (50), a lower face (51), and a peripheral wall formed of two longitudinal faces (52). ) and two lateral faces (53), the anode (40) having at least one groove (60) extending substantially parallel to the longitudinal faces (52), from one of the side faces (53) to the lateral face (53) opposite, and which opens into the lower face (51) of the anode (40), the groove (60) having a bottom face (62) located at a distance dl from the upper face (50) of the anode (40), the anode (40) further comprising at least one reinforcing member (70) located in the groove (60), said reinforcing member (70) extending from a longitudinal wall (61) from the groove (60) to the opposite longitudinal wall (61), characterized in that the reinforcing element (70) extends from then a side face (53) of the anode (40) towards the opposite side face (53) over a maximum length (I) such that L / 8 5. I <L / 2, where L is the length of the anode (40) between its side faces (53); has an upper edge (72) which is located at a non-zero distance d2 from the bottom face (62) of the groove (60). 9. Anode according to claim 8, characterized in that I 5 L / 3. 10. Anode according to claim 8 or 9, characterized in that I k 115. 11. Anode according to one of claims 8 to 10, characterized in that the height h of the groove (60) is between 0.5 H and 0.8 H, preferably between 0.6 H and 0.7 H, where H is the height of the anode (40) between its lower (51) and upper (50) faces. 12. Anode according to one of claims 8 to 11, characterized in that the reinforcing element (70) is adjacent to the underside (51) of the anode (40). 13. Anode according to one of claims 8 to 12, characterized in that the reinforcing element (70) has substantially the shape of a rectangular parallelepiped having a face (71) located substantially in the plane of the lower face ( 51) of the anode (40) and a face (73) located substantially in the plane of a side face (53) of the anode (40), the length (I) of the reinforcing member (70) - along a direction orthogonal to the lateral faces of the anode (40), said longitudinal direction (X) - being between 300 and 500 mm, and the height (d) of the reinforcing element (70) - along a direction orthogonal to the lower (51) and upper (50) faces of the anode (40) - being between 100 and 300 mm. 14. Anode according to one of claims 8 to 13, characterized in that the reinforcing element (70) is made of the same material as the anode (40) and integrally molded with the anode (40). 15. Anode according to one of claims 8 to 14, characterized in that it comprises a plurality of grooves (60) substantially parallel, and a reinforcing element (70) located in each of the grooves (60), the elements of reinforcement (70) being located vis-a-vis along the direction orthogonal to the longitudinal faces (52) of the anode (40), said transverse direction (Y). 16. Process for producing aluminum by igneous electrolysis, characterized in that it comprises the implementation of the handling method according to one of claims 1 to 7, and / or in that it comprises the use of at least one anode (40) according to one of claims 8 to 15. 17. Installation, such as an anode manufacturing plant (1 ') (40) for the production of aluminum by igneous electrolysis or an installation (1) for the production of aluminum by igneous electrolysis, characterized in that it comprises at least one anode (40) according to one of claims 8 to 15.