RU2682729C2 - Electrolysis tank casing - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to production of aluminum. Electrolysis tank comprises a lined casing designed to hold the cryolite bath and includes a bottom and side walls, a cover configured to form a closed volume for holding gases over the cryolite bath and including side walls extending above the side walls of the casing. At least one of the side walls of the cover is offset outward from the casing with respect to one of the side walls of the casing. Offset side walls of the casing and the cover are mechanically connected by at least one flange that includes at least one window through which the cell of the electrolysis tank passes progressively while moving along the translation axis T-T'.EFFECT: improved air-tightness of the electrolysis cell with respect to gaseous pollutants.16 cl, 5 dwg

Description

Technical field

The present invention relates generally to the technical field of aluminum production by electrolysis in an electrolyzer containing a cryolite-based bath (hereinafter referred to as a “cryolite bath”).

More precisely, it relates to a casing of an electrolyzer intended to contain such a cryolite bath. Anodes are, in particular, carbon prebaked type.

Presentation of the prior art

Aluminum is mainly produced by electrolysis of alumina dissolved in a cryolite bath.

Currently, the production of aluminum on an industrial scale is carried out in an electrolyzer containing, in particular:

- a steel casing in the shape of a parallelepiped, including a bottom and side walls, the casing being open in its upper part,

- refractory lining covering the bottom and side walls of the casing,

- a cathode based on cathode blocks of carbon material installed in the casing and connected to electrical conductors that serve to conduct the electrolysis current.

The electrolyzer also includes a cryolite bath contained in the casing and consisting mainly of cryolite and dissolved alumina.

The pre-calcined carbon block constituting the anode of the anode assembly is immersed in a cryolite bath and is consumed as the electrolysis reaction proceeds to produce aluminum.

An intersecting superstructure is installed on the casing of the electrolyzer. This superstructure, for example, is located on the casing and extends over the opening of the casing. The superstructure allows you to maintain various elements of the electrolyzer located at a level above the opening of the casing, such as:

- lifting means provided for lowering the anode into the cell as it is spent,

- means for supplying reagents provided to enable the introduction into the cryolite bath of reagents consumed during the electrolysis reaction,

- an exhaust gas collection device for preventing the emission of polluting gases generated during the electrolysis reaction, such as carbon dioxide, carbon monoxide, sulfur dioxide and hydrogen fluoride, into the atmosphere.

Finally, the electrolyzer typically has a bell containing a series of covers placed between the upper edges of the casing and the superstructure. The bell is provided in order to close the open upper part between the casing and the superstructure to hold the exhaust gases inside the cell.

A layer of liquid aluminum is formed in the bottom of the cell, periodically removed by pumping or draining.

The disadvantage of this type of cell is the risk of gaseous pollutants coming out. These gas release risks can have various causes.

In particular, various products used in the electrolysis reaction, such as backfill products, can accumulate on the sides of the casing on which the covers rest. This accumulation of products may interfere with proper placement of covers. This causes leakage of polluting gases at the level of the upper edge of the casing and between the covers located on each side of the cell.

Also through the bell pass the anode rods of the anode nodes. These anode rods are associated with dynamic compaction means provided to prevent gas from escaping through the joints between the bell and the anode rods. However, dynamic compaction tools can be damaged, especially when handling anode rods to replace a spent anode with a new anode. Damage to dynamic compaction means leads to leakage of polluting gas at the joints between the bell and the anode rods.

Another disadvantage of this type of electrolytic cells relates to the kinematics of the movement of the anode nodes when replacing the spent anode with a new anode. The presence of the superstructure above the opening in the casing prevents the vertical movement of the anode nodes. Therefore, it is necessary to use the complex kinematics of the movement of the anode nodes around this superstructure so that they can be removed from the cell.

An object of the present invention is to provide an electrolytic cell that overcomes at least one of the aforementioned disadvantages. In particular, it is an object of the present invention to provide an electrolytic cell that has improved leak tightness against gaseous pollutants and in which the extraction of the anode assemblies is facilitated.

SUMMARY OF THE INVENTION

For this purpose, the invention proposed an electrolytic cell used to produce aluminum, comprising a casing coated with a lining and including a bottom and side walls, the casing being designed to hold a cryolite bath, characterized in that the electrolyzer further comprises a shelter including side walls, extending above the side walls of the casing, and at least one of the side walls of the shelter is biased outward of the casing with respect to the side walls of the casing, and the fact that the offset side walls of the casing and the roofs are mechanically connected by a flange comprising at least one window through which a corresponding cell of the electrolyzer passes, progressively moving along the axis T-T 'through the window.

In the context of the present invention, the side wall of the shelter is considered offset with respect to the side wall of the casing when the lower edge of the side wall of the shelter is horizontally offset with respect to the upper edge of the side wall of the casing. The outer casing means in the direction opposite to the inner space of the casing with respect to the side wall.

The flange extends mainly between the lower edge of the offset side wall of the shelter and the upper edge of the side wall of the casing. More precisely, the flange is a physical wall that provides tightness between the offset walls of the shelter and the casing with which it is connected mechanically. The flange can also advantageously maintain and provide mechanical integrity to the shelter.

The cell contains one (or more) flange (s) between the casing and the shelter. Each flange includes one (or more) window (s) through which element (s) pass (s), translationally moving (s) along the translation axis TT 'through window (s), in particular perpendicular the plane in which the aforementioned window (s) extends.

This particular arrangement (i.e., a flange / window assembly for passing the corresponding cell element progressively moving along the T-T 'axis through the window) allows the window (s) to be limited in size to prevent pollutant gases from escaping from the cell through them.

This particular arrangement also allows the installation of movable electrolyser elements, such as lifting devices or punching devices, on the periphery of the casing, in contrast to prior art electrolyzers in which mobile lifting devices and / or punching devices are generally in line with the opening, given walls of the casing. The fact of placing lifting devices and / or punching devices on the periphery of the casing means that there is no obstacle to the vertical movement of the anode assemblies. This makes it easier to make a sealed shelter and replace the anode nodes through the top of the cell, without the need for complex kinematics of the movement of the anode nodes.

Shelter allows you to hold the exhaust gases from the cell, which facilitates their capture and processing. The shelter mainly contains a system of removable covers that close the opening formed by the upper parts of the side walls of the shelter in order to carry out without any interference the replacement of the anode assembly through the top of the cell. In the system of removable covers create an opening for removing or introducing the anode assembly from / to the shelter.

Preferred, but not limiting features of the electrolyzer according to the invention are as follows.

Preferably, the casing includes first and second transverse side walls and the first and second longitudinal side walls, the shelter includes first and second transverse side walls extending above the first and second transverse side walls of the casing, and the first and second longitudinal side walls extending above the first and second longitudinal side walls of the casing, the first longitudinal side wall of the shelter is offset outward of the casing relative to the first longitudinal side wall of the casing, and the first longitudinal side walls of the skin the ear and the shelter are mechanically connected by a flange that includes at least one window through which a corresponding cell of the electrolyzer passes, moving progressively along the axis T-T 'through the window.

The flange is advantageously formed on at least one longitudinal side of the cell, along which lifting devices and / or punching devices can be distributed.

In addition, in particular, the first and second longitudinal side walls of the shelter are offset outside the casing with respect to the corresponding first and second longitudinal side walls of the casing, the respective first and second longitudinal side walls of the casing and the shelter being mechanically connected by flanges, each flange including at least one window through which a corresponding cell of the electrolyzer passes, progressively moving along the axis TT 'through the window.

The first and second longitudinal side walls of the casing extend between and above the first and second longitudinal side walls of the shelter.

The flange is thus advantageously formed on two opposite longitudinal sides of the electrolyzer in such a way as to make the lifting devices and / or punching devices symmetrical, each of which is usually associated with an alumina feed device.

The cell may further comprise four peripheral flanges extending between the upper edges of the side walls of the casing and the lower edges of the side walls of the shelter. This, in particular, allows you to place the translationally moving elements between the four side walls of the casing and the four side walls of the shelter.

Each flange may form part of a casing and / or cover. For example:

- the casing may contain two peripheral flanges, extending outward from the volume specified by the casing, along the upper edges of the first and second longitudinal side walls of the casing, and the shelter has no flange and is placed on the flanges of the casing,

- the shelter may contain two peripheral flanges extending inwardly specified by the shelter volume along the lower edges of the first and second longitudinal side walls of the shelter, the casing having no flange, and the shelter is placed on the upper edges of the side walls of the casing,

- the casing and the shelter can have two peripheral flanges - casing flanges extending outward from the volume specified by the casing along the upper edges of the first and second longitudinal side walls of the casing, and shelter flanges extending inwardly of the volume specified by the shelter along the lower edges of the first and second longitudinal side walls of the shelter ; the fact that both the casing and the shelter have flanges facilitates the possibility of supporting the shelter on the casing and improves the stability of the composite structure composed of the casing and the shelter,

- the casing and the shelter can also be the same monoblock element, also containing a flange or flanges.

Both the casing and the shelter are preferably parallelepipedal. Then the electrolyzer will be advantageously in the form of two parallelepipeds, placed on top of each other, and the upper parallelepiped (shelter) will be slightly wider than the lower parallelepiped (casing).

Preferably, each window extends in a plane perpendicular to the translation axis T-T '. The axis of translation of T-T 'may be vertical (or almost vertical). In this case, each window extends horizontally. Similarly, each flange can be nearly horizontal. Then it is facilitated to ensure tightness between the flange window and the translationally moving cell element.

In an alternative embodiment, each window has a shape complementary to the cross-sectional shape of the corresponding cell element passing through said window, in particular of a homothetic shape. This allows you to minimize the size of the gap between the window and the moving element in order to limit the risk of the release of polluting gases through the gap. In some embodiments, each element passes through a corresponding window through a dynamic seal, in particular an annular one. Each seal is installed, for example, around the perimeter of the window, around the translationally moving element. This allows you to further increase the tightness of the cell. Preferably, each window is electrically isolated from an element passing through it.

According to an alternative embodiment, the flange comprises at least one protrusion protruding in a direction opposite to the bottom of the casing, a window being formed in this at least one protrusion.

Therefore, the window made in the upper part of the protrusion is raised relative to the height of the cryolite bath in order to limit the effect on the elements moving through the window of the heat generated by the cryolite bath, gases, and the backfill product.

Different types of translational elements can be associated with a window. For example, when the electrolyzer includes at least one anode assembly supported by anode receivers, translationally moving along the translation axis TT 'to immerse the anode assembly in or to remove it from the cryolite bath, the flange windows can be connected to the anode receivers, and each window allows the corresponding anode receiver to pass through it.

According to a preferred embodiment, the anode assembly crosses the cell from one longitudinal side wall of the shelter to another and rests on two anode receivers passing through the windows of two flanges located on opposite longitudinal sides of the cell. The anode assembly then rests on the means of support and translational movement, is ideally stable and does not affect the tightness of the shelter.

Of course, these windows (or other windows) can be connected with other types of translationally moving element, such as a device for transmitting electric current for feeding the anode to electric currents, or a punching device.

In particular, in one embodiment, the electrolyzer contains a punching device designed to create an opening in the crust formed on the surface of the cryolite bath, in order to be able to supply, in particular alumina, the cryolite bath, and the flange has at least one window through which the device passes punching, in particular, a part (core) of a punching device moving progressively.

Therefore, the windows associated with the punching devices are raised relative to the height of the cryolite bath, in order to limit the impact on the punching devices of the heat, gases and backfill product generated by the cryolite bath.

Preferably, each flange comprises at least one fastening device on the opposite side of the flange side, for example, a plate having a through hole and forming a fastening point for transporting the casing. This makes it possible to facilitate the movement of the electrolyzer using a loading and unloading unit, usually containing an overhead crane, a trolley that can move along an overhead crane, which is detachably connected to the casing using, for example, lifting beams.

Each flange can extend along the entire length of the longitudinal (or, respectively, transverse) side wall of the casing and / or shelter. This allows you to set the elements translationally moving along the axis T-T 'along the entire length (or, accordingly, the width) of the cell.

Advantageously, the side walls of the shelter and the casing could serve as a fastening point on the periphery of the electrolyser for equipment usually mounted in the prior art above the opening of the casing. Thus, the electrolyzer may contain means for lifting the anode assemblies, punching devices, a gas collection system and an alumina feed device that are attached to the side walls of the shelter and / or to the side walls of the casing.

Preferably, the casing, flange (s) and shelter are monoblock. This allows you to limit the risks of leakage at the joints between the casing, flange (s) and the cover, which may be associated with problems of thermal expansion. Alternatively, the cover, flange (s) and cover may be made of two (or more than two) parts.

Brief Description of the Figures

Other advantages and characteristics of the electrolyzer will become apparent from the following description of several alternative embodiments, given as non-limiting examples, and from the accompanying drawings, in which:

- Figure 1 shows a view in longitudinal section of an electrolyzer,

- Figure 2 shows a cross-sectional view of two adjacent cells,

- Figure 3 is a partial view of a cell with a punching device.

- Figure 4 is a schematic perspective view of a casing of an electrolyzer,

Figure 5 shows a perspective view of the electrolyzer.

Detailed description

Now we describe an example of an electrolytic cell according to the invention. In these various figures, equivalent elements bear the same reference numbers.

The expressions “ side wall ”, “ bottom ” and “ upper opening ” will be used later in the text with reference to a rectangular parallelepiped.

The reader should take into account that in the context of the present invention:

- " bottom " means the horizontal wall of the rectangular box, located near the ground,

- " upper opening " means a hole made in the horizontal wall of a rectangular parallelepiped, opposite the bottom,

- “ side / wall ” means a vertical face / wall of a rectangular parallelepiped extending in a plane perpendicular to the bottom,

- " longitudinal sides / walls " means the vertical faces / walls of a rectangular parallelepiped, at least one size of which is larger than the dimensions of the other side faces / walls,

- “ transverse sides / walls " means vertical faces / walls extending perpendicular to the longitudinal faces / walls.

Turning to figures 1-3, there is illustrated an example of an electrolytic cell according to the invention.

The cell in the form of an almost rectangular parallelepiped contains a casing 1, a shelter 2, a plurality of anode nodes 3, a cathode 4, a gas collection device 5, one (or more) punching device (a) 6 and several lifting devices 7.

This electrolyzer is applicable for the production of aluminum. It can be associated with many other electrolytic cells, possibly identical, moreover, the various electrolytic cells are arranged sequentially one after another, and two consecutive electrolytic cells are adjacent along one of their longitudinal side walls.

Turning to figure 4, the casing 1 of the electrolyzer has a generally parallelepipedal shape. It contains a bottom 10, a first and second transverse side wall 11 and a first and second longitudinal side wall 12. The casing 1 also has buttresses 13 extending on the outer sides of the bottom 10 and side walls 11, 12. These buttresses 13 provide mechanical reinforcement of the housing 1.

The casing 1 may be metal, for example, steel. The inner sides of the bottom 10 and side walls 11, 12 of the casing 1 are covered with refractory blocks 14, providing thermal insulation of the casing 1. The blocks 14 may include, for example, refractory bricks and / or carbon blocks.

Shelter 2 forms a closed volume of gas retention above the cryolite bath 19, in which the anode nodes 3 move.

Shelter 2 rests on the upper edges of the casing 1. It contains the first and second transverse side walls 21 and the first and second longitudinal side walls 22 attached to the casing 1.

Preferably, the side walls 21, 22 of the shelter 2 are offset outward relative to the side walls 11, 12 of the casing 1 so that said side walls 21, 22 of the shelter 2 extend around and above the side walls 11, 12 of the casing 1, the side walls 11, 12, 21 22 of the casing 1 and the shelter 2 are mechanically connected by flanges 16, 17, which will be described in more detail below.

Shelter 2 also includes a removable cover 23 for closing the upper opening defined by the four side walls 21, 22 of the shelter 2. The cover 23 may consist of a set of panels extending generally in one plane and lean on the upper edges of the side walls 21, 22 of the shelter 2, and more precisely, on gas-collecting boxes extending at the level of the upper edges of the shelter 2.

The casing 1 is open in its upper part 15. The cell has one (or more) peripheral flange (s) 16, 17 between the upper edges of the side walls of the casing and the lower edges of the side walls of the shelter.

Each peripheral flange 16, 17 extends outwardly outside the casing 1 (or, respectively, inside the shelter), parallel to the bottom 10 of the casing 1. Flanges can form part of the casing 1 and / or the shelter 2.

Each flange 16, 17 is connected with the side wall 11, 12 (or, respectively, 21, 22) of the casing 1 (or, respectively, of the shelter).

In particular, in the embodiment shown in FIG. 4, the casing comprises four peripheral flanges 16, 17 extending along one of the upper edges of the side walls 11, 12 of the casing 1:

- two longitudinal peripheral flanges 16, with each longitudinal peripheral flange 16 extending along the upper edge of the corresponding longitudinal side wall 12 of the casing 1,

two transverse peripheral flanges 17, each transverse peripheral flange 17 extending along the upper edge of the corresponding transverse side wall 11 of the casing 1,

Alternatively, the casing 1 (and / or shelter) may (may each) include:

- one longitudinal peripheral flange 16, or

- two longitudinal peripheral flanges 16, or

- one (two) longitudinal (x) peripheral (x) flange (CA) 16 and one transverse peripheral flange 17.

Each flange 16, 17 may contain one (or more) window (s) 18a, through which (s) passes the cell element, translationally moving along the axis T-T 'during operation of the cell. This cell element may be a part of a lifting device 7 moving progressively along the translation axis T-T ', such as the anode receiver 72 of the lifting device 7, which will be described in more detail below.

Thus, each window 18a is associated with a corresponding electrolyser cell passing through it, said electrolyser cell being moved progressively along the translation axis T-T 'between the two extreme positions.

Advantageously, each window 18a extends in a plane perpendicular to the translation axis T-T '. This allows you to reduce the size of the windows 18a, making them independent of the progress of the elements moving translationally along the translation axis T-T '.

In the embodiment illustrated in FIG. 2, each window 18a is connected to a corresponding anode receiver 72, translationally moving vertically along the translation axis T-T '. In this case, the window 18a extends in a horizontal plane. The same is true for each flange 16, 17.

The shape of each window 18a may be complementary to the cross-sectional shape (along a plane perpendicular to the translation axis T-T ') of the element passing through said window. This minimizes the window size to limit the risk of pollutant gases escaping from the cell. Referring to FIG. 4, each window 18a has a rectangular shape complementary to a rectangular cross-sectional shape of associated anode receivers 72.

Advantageously, each window 18a of the housing 1 may comprise a seal extending along its edges, so that the seal surrounds the translationally moving member associated with the window. This makes it possible to increase the tightness of the electrolyzer to limit the risk of polluting gas escaping through windows.

The seal may be designed to interact with the seal portion located on the sliding member. In this case, the sealing part extends along the zone of the element sliding through the seal during the translational movement of the element between its extreme positions. Thus, the tightness of the cell is ensured, despite the translational movement of the cell.

A dynamic seal, usually annular, around the sealing part can also serve as electrical insulation if the sliding element is not under the same electric potential as the edges of the window it intersects.

Each (or some) of the flange (s) 16, 17 may also (may) contain one (or more) window (s) 18b through which the part of the punching device 6 passes, which will be described in more detail below.

The shape of each window 18b may be complementary to the cross-sectional shape (along a plane perpendicular to the translation axis T-T ') of the part passing through said window 18b in order to limit the risk of polluting gases escaping from the cell. Referring to FIG. 5, each window 18b has a circular shape complementary to the cylindrical shape of the associated part of the punching device 6.

A seal may be provided at the edges of each window 18b, whereby a seal surrounds the translationally moving part of the punching device 6.

The seal may be designed to interact with the sealing part located on the part of the punching device 6, this part extending over the entire area of the part sliding through the seal while translating the part between its extreme positions.

Windows 18a and 18b may extend in coincident planes.

Alternatively, and as shown in FIG. 5, windows 18a and 18b may extend in different planes.

In particular, in the embodiment shown in FIG. 5, each flange 16, 17 has protrusions protruding in a direction opposite to the bottom 10 of the housing 1.

Each protrusion has a horizontal platform in which a corresponding window 18b is formed, as a result of which the windows 18b extend at a higher height than the height of the windows 18a.

Advantageously, the side walls 21, 22 of the shelter 2 can abut against the upper edges of the casing 1 at the free ends of the flanges 16, 17. It follows that the area of the opening defined by the lower edges of the side walls 21, 22 of the shelter 2 is practically equal to the sum:

- the area of the flanges 16, 17 and

- the area of the upper opening defined by the upper edges of the side walls 11, 12 of the casing 1.

Preferably, the casing 1, the flange (s) 16, 17 and the cover 2 are monoblock (i.e., a single unit). This limits the risk of leakage at the interface between the casing and the shelter. These risks otherwise increase greatly due to the fact that the casing 1 and the shelter will behave differently with respect to expansion caused by the high operating temperatures of the cell.

Alternatively, the casing, flange (s) 16, 17 and the cover may be made of two (or more than two) parts. In one embodiment, both the casing 1 and the shelter 2 have flanges extending:

- for the flanges of the casing 1, along (one of) the upper edge (s) (one of) the longitudinal (and transverse) wall (s) of the casing,

- for shelter flanges 2, along (one of) the lower edge (s) (one of) of the longitudinal (and transverse) wall (walls) of the shelter,

The flange (s) preferably extends (perpendicularly) to the side walls of the casing 1 and the cover 2, with each flange of the cover 2 may come into contact with the corresponding peripheral flange of the casing 1.

The presence of flanges on the side walls of both the casing 1 and the shelter 2 makes it easier to support the shelter 2 on the casing 1 and improves the stability of the composite structure consisting of the casing 1 and the shelter 2.

As mentioned above, each flange can extend along the entire length of the side wall of the shelter 2 (or, respectively, the casing 1), and each of the flanges of the shelter 2 and the casing 1 contains one (or more) window (s) in the same positions when the shelter 2 is located on the casing 1.

Each anode assembly 3 comprises an anode 31 and an anode structure 32. The anode structure 32 allows, firstly, to manipulate the anode 31, and, secondly, to supply electric current to it. During the electrolysis reaction, the anode 31, immersed in a cryolite bath, is consumed. Anode nodes 3 must be periodically replaced.

The anode 31 is preferably a block of prebaked carbon material.

The anode nodes 3, and more precisely, the anode structure 32 of each anode node 3, extends transversely in the cell between the longitudinal lateral sides 22 of the shelter 2. The anode structure contains, in particular, a cross member. The cell contains many anode nodes 3 distributed along the longitudinal axis of the cell.

The anode structure may comprise reinforcement made of metal having good mechanical strength, such as steel. This allows the anode structure to maintain the anode assemblies in suspension. It may also contain sections made of metal having good electrical conductivity, such as copper or aluminum. This allows the anode structure to provide an electric current supply for powering the anode assemblies.

The cathode 4 may include a plurality of cathode blocks of carbon material.

The cathode 4 is connected in its lower part with electrically conductive means for removing the electrolysis current 41, formed, in particular, from one or more conductors. More specifically, each cathode block has at least one groove in its lower part, within which an electrically conductive means 41 is located.

A good physical and electrical connection between the cathode block 4 and the electrically conductive means 41 is realized in the groove using cast iron. The conductor passes through the casing 1 at the level of the holes made in the casing 1, in particular, in the bottom 10 or the longitudinal side walls 12.

The conductor diverts electric current from the cathode to supply it from one cell to another.

The gas gathering device 5 allows to capture for processing polluting gases generated during the electrolysis reaction.

The gas collecting device 5 comprises one (or more) gas collecting (x) boxes (s) on which the suction openings for gas suction are distributed.

The getter box (s) (s) are connected (s) to one (or more) suction device (s) (s) (not shown). It (s) extends (s) along the longitudinal side walls 22 of the shelter 2 and, possibly, along the transverse side walls 21 of the shelter 2. The presence of holes along the longitudinal walls 22 of the shelter 2 improves the efficiency of collecting gaseous pollutants.

Advantageously, the number of openings of the gas collection device 5 may be equal to the number of punching devices 6 attached to the cell. In this case, each hole can be connected with the corresponding device 6 punching and located close to it.

Advantageously, each gas collecting box may have a square or rectangular cross section and be made of a material having high mechanical strength, such as steel. This makes it possible to increase the rigidity and strength of the gas collecting box. Thus, a gas collecting box is obtained, which, in addition to its primary gas removal function, can be used, in particular, as a tightening belt of a unit consisting of a casing 1 and a shelter 2, and as a mounting support for various elements of the electrolyzer, such as devices 6 piercing or lifting devices 7.

Giving several functions to the gas collecting box allows you to limit the overall size of the cell and facilitate its manufacture.

Punching device 6 allows you to create holes in the crust of alumina and nastilya formed on the surface of the cryolite bath 19 during the electrolysis reaction.

These holes are created regularly to allow the addition of various compounds, such as alumina, cryolite (Na ₃ AlF ₆ ) or aluminum fluoride (AlF ₃ ), to stabilize the parameters of the cell.

The punching device comprises a power cylinder 61 and a punch 62.

Punch 62 is intended to be located above the punctured crust. The slave cylinder 61 allows the punch 62 to be driven forward and backward to pierce the crust by means of a U-shaped structure 63 consisting of a first and a second sidewall connected to a transverse rod.

The first sidewall is interconnected with the piston rod 61 and extends as its extension along the translation axis T-T 'of the rod. The second sidewall is interconnected with the punch 62.

An insulating part can be fixed between the first sidewall and the stem to limit the risk of heat spreading to the ram 61, since an excessive temperature rise of the ram 61 can cause damage.

For the window (s) associated with the punching device (s) 6, means for guiding the slide of the ram cylinder 61 may be provided. These guiding means allow you to direct the translational movement of the assembly consisting of the rod of the ram cylinder 61, the punch 62 and the U-shaped structure 63 .

For example, each window 18b associated with the punching device 6 may include a channel 64 surrounding the first sidewall and forming guiding means for sliding. This channel 64 extends along the edges of the window 18b and preferably extends perpendicular to the outer edge of the flange 16a, 17a towards the bottom 10 of the casing 1 (i.e., the edge of the flange opposite the closed volume defined by the cover 2) to minimize the height of the transverse rod above the flange 16a , 17a.

Lifting devices 7 allow you to manipulate the anode structures 32, and therefore the anode nodes 3. In particular, the lifting devices 7 provide the possibility of vertical translational movement of the anode nodes 3.

Each anode assembly 3 is connected with two corresponding lifting devices 7, on each of which one of its ends rests. Thus, the movement of each anode assembly 3 is independent of the movement of the other anode assemblies 3 contained in the cell.

Each lifting device 7 comprises a power cylinder 71 and an anode receiver 72.

The master cylinder 71 allows the anode receiver 72 to be moved forward vertically along the translation axis T-T '.

The anode receiver 72 includes a beam with a rectangular section, extending along a longitudinal axis coinciding with the translation axis T-T '. A part (for example, the end closest to the bottom of the casing) of the beam is electrically connected to flexible electrically conductive means to provide power to the anode assemblies. The upper end of the beam has a socket for receiving the end of the anode structure 32, the shape of which is complementary to the shape of the latter.

Guide means allowing vertical movement along the translation axis T-T 'of the anode receiver 72 may be provided at the level of the windows 18a associated with the anode receivers.

These guiding means may contain one (or more) ring (s) partially surrounding the beam, to enable it to slide vertically between:

- retracted position, where the nest is close to the surface of the cryolite bath, and

- elongated position, where the nest is far from the surface of the cryolite bath.

The lifting device is preferably electrically isolated from the casing 1 and the shelter 2.

It should be understood by the reader that numerous modifications may be made to the invention described above without substantially departing from the new information disclosed herein.

For example, in the embodiments described above, windows 18a were associated with lifting devices 7, and windows 18b were associated with punching devices 6. It will be apparent to those skilled in the art that windows 18a and 18b can be connected to any other cell of the cell moving progressively along the translation axis T-T '. Also, and in contrast to what is presented above, windows 18a can be connected with punching devices 6, and windows 18b can be connected with lifting devices 7.

In addition, in the above description, the window (s) corresponded to two-dimensional openings. In the case of three-dimensional openings, the window (s) corresponds to the projection onto the plane of said three-dimensional openings, and this projection defines the area of the passage opening for the cell element that is associated with it.

Claims (23)

1. Electrolyzer for the production of aluminum, containing: a casing (1) coated with a lining (14) and including a bottom (10) and side walls (11,12), and the casing (1) is designed to hold the cryolite bath (19), characterized in that the electrolyzer further comprises a shelter (2), made with the formation of a closed volume for holding gases above the cryolite bath and including side walls (21,22), extending above the side walls (11,12) of the casing (1), at least one of the side walls (21,22) of the shelter (2) is displaced outside the casing (1) with respect to one of the side walls (11,12) of the casing (1), while the displaced side walls (11,12; 21 , 22) the casing (1) and the shelter (2) are mechanically connected by at least one flange (16, 17), which includes at least one window (18a, 18b) through which an electrolytic cell moves along the translation axis TT 'through the window (18a, 18b). 2. The cell according to claim 1, in which the flange (16.17) extends between the lower edge of the offset side wall of the shelter (2) and the upper edge of the side wall of the casing (1). 3. The cell according to claim 1 or 2, in which the casing (1) includes a first and second transverse side wall (11) and a first and second longitudinal side wall (12), and the shelter (2) includes: - the first and second transverse side walls (21) extending over the first and second transverse side walls (11) of the casing (1), and - the first and second longitudinal side walls (22), extending over the first and second longitudinal side walls (12) of the casing (1), moreover, the first longitudinal side wall (22) of the shelter (2) is shifted outward of the casing (1) relative to the first longitudinal side wall (12) of the casing (1), and the first longitudinal side walls (12, 22) of the casing (1) and the shelter ( 2) are mechanically connected by the said at least one flange (16, 17). 4. The cell according to claim 3, in which the first and second longitudinal side walls (22) of the shelter (2) are shifted outward of the casing (1) relative to the first and second corresponding longitudinal side walls (12) of the casing (1), the first and second corresponding the longitudinal side walls (12, 22) of the casing (1) and the shelter (2) are mechanically connected by flanges (16, 17). 5. The electrolyzer according to claim 1 or 2, in which the shelter (2) contains a system of removable covers that covers the opening formed by the upper parts of the side walls of the shelter (2). 6. The cell according to claim 1 or 2, in which each window extends in a plane perpendicular to the axis of translation T-T '. 7. The electrolyzer according to claim 1 or 2, in which the axis of translation T-T 'is vertical, with each flange extending practically in a horizontal plane. 8. The electrolyzer according to claim 1 or 2, in which the casing (1) and the shelter (2) are almost parallelepiped in shape. 9. The electrolyzer according to claim 1 or 2, in which each window has a shape complementary to the shape of the cell of the cell progressively moving through it. 10. The cell according to claim 1 or 2, which further comprises a dynamic seal associated with each window. 11. The electrolyzer according to claim 1 or 2, in which said at least one flange is made with at least one protrusion formed with a window and protruding in the direction opposite to the bottom of the casing. 12. The electrolyzer according to claim 1 or 2, which contains at least one anode assembly (3), supported by anode receivers (72), translationally moving along the translation axis TT 'to immerse the anode assembly in or to remove it from the cryolite bath, said at least one flange has at least one window (18a) through which the anode receiver passes. 13. The cell according to claim 12, wherein said at least one anode assembly (3) crosses the cell from one longitudinal side wall (22) of the shelter (2) to another and rests on two anode receivers (72) configured to pass through windows (18a) of two flanges (16.17) located on opposite longitudinal sides of the cell. 14. The electrolyzer according to claim 1 or 2, which contains at least one punching device for creating a hole in the crust formed on the surface of the cryolite bath, said at least one flange having at least one window through which the punching device passes. 15. The cell according to claim 1 or 2, in which the casing, said at least one flange and the shelter are monoblock. 16. The electrolyzer according to claim 1 or 2, which contains means for lifting the anode assemblies, punching devices, a gas collection system and an alumina feed device that are attached to the side walls (21.22) of the shelter (2) and / or to the side walls (11, 12) the casing (1).

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