The present invention relates to a plant for producing aluminum by the electrolysis of alumina, also referred to as an aluminum smelter.
The practice is known of producing aluminum industrially by the electrolysis of alumina using the Hall-Heroult process. To this end, an electrolytic cell is used, notably made up of a steel pot shell, an interior refractory coating, and a cathode made of carbonaceous material, connected to conductors which deliver the electrolysis current. The electrolytic cell also contains an electrolytic bath notably made up of cryolite in which the alumina is dissolved. The Hall-Heroult process consists of partially immersing a carbon block, forming the anode, into the electrolytic bath, the anode being consumed as the reaction proceeds. The liquid aluminum, produced by the electrolysis reaction, is deposited in the bottom of the cell by gravity, forming a pad of liquid aluminum that completely covers the cathode.
Generally speaking, aluminum production plants have several hundreds of electrolytic cells connected in series in production halls. An electrolysis current, in the order of several hundreds of amperes, passes through these electrolytic cells creating significant magnetic fields. Depending on the distribution of the various components of the magnetic field in the cell, the pad of aluminum may be unstable, which significantly downgrades the productivity of the cell. It is notably known that the vertical composite of the magnetic field is a determining factor in the stability of an electrolytic cell.
It is known that the stability of electrolytic cells can be improved by minimizing the vertical component of the magnetic field in the cell. To do this, the vertical component of the magnetic field relative to an electrolytic cell is compensated owing to a special arrangement of the conductors conveying the electrolysis current from a cell N to a cell N+1. Part of these conductors, generally aluminum bars, circumvent the ends of the cell N.
However, the self-compensation method of an electrolytic cell creates a significant amount of design constraints owing to its large size due to the specific arrangement of the conductors. In addition, the significant length of the conductors needed to implement this solution generates power loss online and requires a lot of material (aluminum conductors), hence high costs in terms of energy consumption and manufacturing.
Another cause of instability of the electrolytic cells, in addition to the vertical component of the magnetic field, is the presence of horizontal electric currents in the pad of aluminum.
The present invention therefore aims to remedy all or part of these drawbacks, by providing an aluminum smelter in which the stability of the liquids contained in the electrolytic cells is improved, and having lower design, construction and operating costs.
In relation thereto, the subject of the present invention is an aluminum smelter comprising:
(i) a series of electrolytic cells, designed for the production of aluminum according to the Hall-Heroult process,
each electrolytic cell comprising at least one anode, a cathode and a pot shell provided with a side wall and a bottom, each cathode comprising at least one cathode output,
(ii) a main electric circuit through which electrolysis current passes, electrically connecting the electrolytic cells together,
the electrolysis current initially passing through an electrolytic cell N, placed upstream, and secondly through an electrolytic cell N+1, placed downstream,
said main electric circuit comprising an electrical conductor connected to each cathode output of the electrolytic cell N,
the electrical conductor also being connected to at least one anode of the electrolytic cell N+1, in order to conduct the electrolysis current from electrolytic cell N to electrolytic cell N+1,
characterized in that the aluminum smelter further comprises
(iii) at least a means to stabilize the electrolytic cells among at least one secondary electric circuit through which an electric current passes, so as to compensate the magnetic field created by the electrolysis current, or the use of a cathode with a grooved surface,
and such that
at least one of the cathode outputs of the cathode of the electrolytic cell N passes through the bottom of the pot shell,
during the operation of the electrolytic cells N, N+1 (2), the electrolysis current (I1) passes, in an upstream-downstream direction only, through each electrical conductor extending from each cathode output of the electrolytic cell N in the direction of the electrolytic cell N+1.
The invention therefore makes it possible to improve the stability of the electrolytic cells in the aluminum smelter, by acting on the horizontal currents passing though the cells and on the magnetic field generated by the electrolysis current and/or the kinetic stability of the pad of aluminum contained in the cells. It simultaneously allows the conductors conveying the electrolysis current from one cell to another to be reduced in size and weight, and consequently reduces the costs associated with the design and manufacture of the aluminum smelter according to the invention. Energy loss is further reduced.
According to another characteristic of the aluminum smelter according to the invention, the electrolytic cells are aligned along an axis, and such that the electrical conductor extends in a substantially rectilinear manner and in a manner substantially parallel to the axis of alignment of the electrolytic cells.
According to another characteristic of the aluminum smelter according to the invention, each cathode further comprises at least one cathode output passing through the downstream side wall of the pot shell.
This characteristic has the advantage of further reducing the size and weight of the electrical conductors conveying the electrolysis current from one cell to another. This cathode output passes through the side wall of the pot shell of the cell N on its downstream side, in order to respect the characteristic according to which each electrical conductor extends in the direction of the cell N+1, in the upstream-downstream direction only. Owing to the proximity of the downstream side of the cell N and cell N+1, the length of the electrical conductor connecting this cathode output to the anode of the cell N+1 is less than that of an electrical conductor connecting a cathode output by the bottom of the cell N to the anode of the cell N+1. This embodiment therefore has the advantage of reducing the size and length of the electrical conductors in relation to an embodiment of the aluminum smelter according to the invention in which the cells comprise cathode outputs located only on the bottom.
Preferably, each downstream cathode output passing though the side wall of the pot shell of the electrolytic cell N comprises a metal bar, more particularly made of steel, with a copper insert or plate.
This allows the voltage at the cathode output passing through the bottom of the pot shell to be balanced in relation to that at the level of the cathode output passing through the side wall of the pot shell.
Advantageously, the pot shell of the electrolytic cell N comprises several arches secured to the side wall and to the bottom of the pot shell, the electrical conductors connected to each cathode output passing through the bottom of the pot shell of the electrolytic cell N extending between the arches.
This characteristic has the advantage of reducing the size of the electrical conductors conveying the electrolysis current from one cell to another.
Advantageously, the electrolytic cells include short-circuiting means.
The short-circuiting means allow an electrolytic cell to be short circuited so that it can be removed for maintenance, while the other cells in the series continue to operate.
Advantageously, the short-circuiting means of the electrolytic cell N+1 comprise at least a short-circuiting electrical conductor placed permanently between electrolytic cell N and electrolytic cell N+1, each short-circuiting electrical conductor being electrically connected to one of the electrical conductors connected to a cathode output of the cell passing through the bottom of the shell of the electrolytic cell N+1, and each short-circuiting electrical conductor being located a short distance from one of the electrical conductors connected to one of the cathode outputs of the electrolytic cell N.
According to another characteristic of the aluminum smelter according to the invention, the short-circuiting means of the electrolytic cell N+1 comprise at least a short-circuiting electrical conductor placed permanently between electrolytic cell N and electrolytic cell N+1, each short-circuiting electrical conductor being electrically connected to one of the electrical conductors connected to a cathode output of the cell passing through the bottom of the shell of the electrolytic cell N, and each short-circuiting electrical conductor being located a short distance from one of the electrical conductors connected to one of the cathode outputs of the electrolytic cell N+1.
The short distance between the short-circuiting conductor and the other conductor form locations for the introduction of short-circuiting blocks. These short-circuiting blocks can be introduced from above or from below in the second case.
Preferably, at least a secondary electric circuit includes electrical conductors running along the right side and/or the left side of the electrolytic cells along at least one line of electrolytic cells.
Advantageously, the at least one secondary electric circuit includes electrical conductors extending along at least one line of electrolytic cells, under said electrolytic cells.
Advantageously, the electrical conductors of the at least one secondary electric circuit are made of a superconducting material. This allows a decrease in the voltage drop to which each secondary circuit is subjected, thereby saving energy and enabling a less powerful and less expensive power substation to be used for each secondary electric circuit. This characteristic also allows material costs to be reduced in relation to aluminum or copper conductors. It allows the size of the electrical conductors to be reduced, which saves space in the aluminum smelter.
According to another characteristic of the aluminum smelter according to the invention, the electrical conductor of the at least one secondary electric circuit runs along the electrolytic cells of the line(s) at least two times.
This characteristic offers the possibility to reduce the strength of the current passing through this secondary circuit in order to save energy.
The invention will be better understood from the detailed description given below with reference to the accompanying drawings in which:
The short sides 2b of each cell 2 can be divided into a right side and a left side. The left side and the right side are defined in relation to an observer located at the main electric circuit 4 and looking in the overall direction of the direction of the electrolysis current I1.
The long sides 2a of each cell 2 can be divided into an upstream side and a downstream side. The upstream side corresponds to the long side 2a of a cell 2 adjacent to the preceding cell 2, i.e. that through which the electrolysis current I1 passes first. The downstream side corresponds to the long side 2a of a cell 2 adjacent to the next cell 2, i.e. that through which the electrolysis current I1 passes next. More generally speaking, upstream and downstream are defined in relation to the overall direction of the electrolysis current I1.
In the example shown in
In the embodiment of
As can be seen in
Electrical currents I2 and I3 pass through the secondary electric circuits 5 and 6. The strength of the electric currents I2 and I3 is between 20% and 100% of that of the strength of the electrolysis current I1 and preferably between 40% and 70%, and more particularly in the order of half. The direction of flow of electrical current I2 and I3 is advantageously the same as the direction of the flow of the electrolysis current I1. The secondary electric circuits 5 and 6 can both be connected to a power substation 20 and 21 respectively, separate from the power substation 3, as can be seen for example in
The secondary electric circuits 5 and 6 are formed by electrical conductors arranged parallel to the axes of alignment of the cells 2. They run along the right and left sides of the electrolytic cells 2 of each line F, F′ of the series. The secondary electric circuits 5 and 6 can also pass, in whole or in part, under the electrolytic cells 2.
In order to stabilize the liquids contained in the electrolytic cells 2, it is possible to use, in an alternative or complementary manner, secondary electric circuits 5 and 6, one or more cathode blocks 8 having a grooved upper face, as can be seen in
Each electrolytic cell 2 can contain a plurality of cathode blocks 8 placed next to each another. Instead of channels 8a on the upper face of one or more of these cathode blocks 8, it is possible to allow for an inclined upper face, such that the cathode blocks 8 placed next to one another form channels 8b, as is represented schematically in
Such cathode blocks with a grooved upper face are notably known from patent document U.S. Pat. No. 5,683,559.
The upper face of these cathode blocks 8 having longitudinal channels 8a may also comprise a transversal central channel 8c, extending at least partially over the width of the cathode blocks 8. The central channel 8c thus crosses the channel(s) 8a extending at least partially over the length of the cathode blocks 8. In the example of
Typically, as is represented on
The electrolysis current I1 first passes through the anode 9 of cell N, then the electrolytic bath 13, the pad of liquid aluminum 11, the cathode, the cathode outputs 12 and the electrical conductors 14 that convey it toward the anode 9 of the next cell N+1.
As is represented in
Another remarkable point is that the electrical conductors 14 extend in a rectilinear manner and parallel to the alignment axis of the electrolytic cells 2 from the cathode outputs 12 of the cell N in the direction of the cell N+1 so that the electrolysis current passes through them only in the upstream-downstream direction when the electrolytic cells 2 N, N+1 are in operation. The upstream-downstream direction corresponds to the overall direction of flow of the electrolysis current I1. Thus, an observer located at an electrolytic cell 2 and moving in the upstream-downstream direction can only move toward cell N+1. In particular, to reach cell N+1, this observer cannot backtrack, even partially, in the direction of the cell N−1.
In addition, the electrical conductors 14 connected to the cathode outputs 12 passing through the bottom 7b of the pot shell 7 do not extend under the full width of the pot shell 7 of the cell N; an electrical conductor 14 does not pass completely through an electrolytic cell 2 under its pot shell 7 or on the sides. In particular, they do not pass through the plane containing the upstream side wall of the pot shell 7 of the cell N.
The rectilinear extension, in the downstream direction only, parallel to the alignment axis of the electrolytic cells 2, forms the shortest electrical path connecting a cathode output of the cell N, passing through the bottom 7b of the pot shell 7 of this cell N, up to the anode 9 of the next cell N+1. Furthermore, as stated above, the electrolysis current I1 passing through the cell N passes through the cathode outputs 12 then the electrical conductors 14 connected to the cathode outputs 12. The electrolysis current I1, while passing through the electrical conductors 14 is conveyed in a straight line parallel to the alignment axis of the cells 2 in the direction of the next cell N+1. This notably saves energy.
In addition, this arrangement limits the overall dimensions near the electrolytic cells 2. It thus becomes possible to reduce the center-to-center distance separating two adjacent cells 2 in order to increase the available space in the aluminum smelter 1, for example to add two additional electrolytic cells 2 or to decrease the size of the buildings.
Also, making use of electrical conductors 14, extending in a rectilinear manner from one cell to another parallel to the alignment axis of the cells 2, simplifies the structure of these electrical conductors 14. Their modularity makes their fabrication more economical.
It should be noted that this specific arrangement is made possible notably by the existence of the first secondary electric circuit 5 and the second secondary electric circuit 6 which compensate the effects of the magnetic field created by the electrolysis current I1, or that of the cathode with the grooved upper surface that stabilizes the movements of the pad of liquid aluminum 11. It is not necessary to configure the electric conducts 14 so as to obtain self-compensation of the effects of this magnetic field relative to each electrolytic cell 2.
This arrangement allows further savings to be made in terms of material, owing to the decreased length, and thus the weight, of the electrical conductors 14.
Advantageously, the second cathode outputs 12 passing through the side wall 7a can include an element made of a material that conducts electricity better, such as steel, notably copper, in the form of a plate 16 or an insert, for example. The copper plate 16 placed on a steel bar allows, by its high electrical conductivity, to rebalance the voltages on the first cathode outputs 12, passing through the bottom 7b, and the second cathode outputs 12, passing through the side wall 7a, and thus to limit the horizontal electrical currents in the aluminum pad.
As in the embodiment presented in
The aluminum smelter 1 can also advantageously include means to short circuit each cell 2. These short-circuiting means can include electrical short-circuiting conductors 17, shown in
The electrical short-circuiting conductors 17 are designed to short circuit a cell N+1, for example in order to remove the latter for maintenance. The distance between the electrical short-circuiting conductors 17 and the electrical conductors 14 connected to the cathode outputs 12 of the cell N is thus filled by a block made of a conducting element (not represented) so as to conduct the electrolysis current I1 from the cell N to the cell N+2 via this block, the electrical short-circuiting conductors 17 and the electrical conductors 14 normally placed under the cell N+1 (i.e. the electrical conductors 14 connected to the cathode outputs 12 passing through the bottom 7b of the shell 7 of the cell N+1 when it is in place).
It is also possible to allow for electrical short-circuiting conductors 17 placed in contact with electrical conductors 14 connected to the cathode outputs 12 of the cell N and at a distance from electrical conductors 14 connected to the cathode outputs 12 of the cell N+1 passing through the bottom 7a of the pot shell 7.
The electrical short-circuiting conductors 17 may be made of aluminum. Given that the electrolysis current I1 passes through them only occasionally during short-circuiting (for maintenance of a cell 2, or at intervals of several years), they can be designed to work at the highest allowable current density, which allows their mass to be limited.
Finally, it should be noted that, advantageously, the electrical conductors forming the secondary electric circuits 5 and/or 6 can be made of a superconducting material.
These superconducting materials can, for example, contain BiSrCaCuO, YaBaCuO, known from patent applications WO2008011184, US20090247412 or even other materials known for their superconducting properties.
The superconducting materials are used to convey current with little or no loss through the generation of heat by the Joule effect, as their resistivity is zero when maintained below their critical temperature.
For example, a superconducting cable comprises a central copper or aluminum core, ribbons or fibers made of a superconducting material, and a cryogenic envelope. The cryogenic envelope can consist of a sleeve containing a cooling fluid, such as liquid nitrogen for example. The cooling fluid maintains the superconducting materials at a temperature below their critical temperature, for example below 100 K (Kelvin), or between 4 K and 80 K.
The use of electrical conductors made of a superconducting material to form the secondary electric circuits 5 and 6 is of particular interest owing to their length, in the order of a few kilometers. The use of electrical conductors made of superconducting materials requires less voltage in relation to that required by electrical conductors made of aluminum or copper. It is thus possible to decrease the voltage from 30 V to 1 V. This represents a 75% to 99% decrease in energy consumption in relation to electrical conductors made of aluminum. In addition, the cost of power substations 20 and 21, of the secondary electric circuit 5 and the secondary electric circuit 6 respectively, is reduced accordingly.
The electrical conductors of the secondary electric circuits 5 and 6 can be advantageously run along a line F of electrolytic cells 2 at least two times.
The small overall dimensions of the electrical conductors made of a superconducting material in relation to electrical conductors made of aluminum or copper (cross section up to 150 smaller than the cross section of a copper conductor at equal intensity, and still further in relation to an aluminum conductor) facilitates the formation of several turns in series in the loops formed by the secondary electric circuits 5 and 6.
In addition, it is possible to place the electrical conductor of a circuit inside a single cooling sleeve regardless of the number of turns made by this same conductor. In a given location, the sleeve can contain several passages of the same electrical conductor made of superconducting material.
The fact that the loop formed by the secondary electric circuits 5 and 6 contains several turns in series allows the strength of the electrical current I2, I3 passing through the secondary electric circuit 5 and the secondary electric circuit 6, respectively, to be divided (as many times as the number of turns made). The decrease in the value of this current strength allows energy losses due to the Joule effect to be lowered at the junctions between the electrical conductors made of superconducting material and the poles of the power substations. The decrease of the overall current strength with the electrical conductors made of superconducting material allows the power substations 20 and 21 to be reduced in size. For example, the power substation 20 or 21 of the secondary electric circuit 5 or the secondary electric circuit 6 comprising an electrical conductor made of superconducting material can deliver current in the order of 5 kA to 40 kA. This also allows conventional off-the-shelf and thus inexpensive equipment to be used.
It should be noted that the electrical conductors made of superconducting material can be placed under the electrolytic cells 2.
Thus, the aluminum smelter 1 according to the invention has a set of characteristics, the combination of which contributes, by a synergy effect, to reducing the design, construction and operating costs of this aluminum smelter 1, and to increasing its productivity.
Naturally, the invention is in no way limited to the embodiments described above, as these embodiments are provided only as examples. Modifications remain possible, notably from the point of view of forming various elements or by the substitution of equivalent techniques, without deviating from the protective scope of the invention.
Number | Date | Country | Kind |
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11/02199 | Jul 2011 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR2012/000281 | 7/10/2012 | WO | 00 | 1/10/2014 |