CA2935484A1 - Electrolysis tank casing - Google Patents

Abstract

The present invention relates to an electrolytic cell comprising a box (1) covered with an inner lining and including a bottom (10) and side walls (11,12), the box (1) being intended to receive a cryolite bath , and a containment enclosure on the box, the enclosure comprising side walls, at least one of the side walls of the enclosure being shifted outwardly of the box with respect to a side wall of the box, the tank comprising at least one peripheral shoulder (16, 17) extending between the offset sidewalls of the box and the enclosure, each shoulder comprising at least one window (18a) through which a respective vessel member moving in translation passes. along a translation axis T-T '.

Description

ELECTROLYTIC TANK HOUSING
Technical area The present invention relates to the general technical field of production of electrolytic aluminum in an electrolysis cell containing a bath base of cryolite (hereinafter cryolithal bath).
It relates more specifically to an electrolytic cell box intended for contain such cryolite bath. The anodes are more particularly carbon type precooked.
Presentation of the prior art Aluminum is essentially produced by electrolysis of dissolved alumina in a bath cryolithaire.
Currently, aluminum production on an industrial scale is being work in an electrolytic cell composed in particular:
- a parallelepipedic steel box including a bottom and side walls, the box being open in its upper part, - a refractory lining covering the bottom and the walls lateral box, a cathode based on cathode blocks made of carbonaceous material arranged in the box and connected to electrical conductors used to carry the current electrolysis.
The electrolysis cell also comprises a cryolite bath contained in the caisson and consisting in particular of cryolite and dissolved alumina.
A precooked carbon block constituting the anode of an anode assembly is immersed in the cryolite bath and consumed as the electrolysis reaction progresses producing aluminum.
A through superstructure is mounted on the chamber of the tank electrolysis. This superstructure is for example placed on the caisson and extends to the right top of the opening of the box. The superstructure allows to support different elements of the electrolysis tank arranged at right above the opening of the box such than:
lifting means provided for lowering the anode in the tank Electrolysis as and when consumed, means for supplying reagents intended to enable the introduction into the cryolite bath of reagents consumed during the electrolysis reaction,

2 - a device for collecting pollutant gases intended to prevent the show in the atmosphere of the polluting gases generated during the electrolysis reaction ¨
such as carbon dioxide, carbon monoxide, sulfur dioxide and fluoride of gaseous hydrogen.
Finally, the tank generally comprises a cowling consisting of a series of covers placed between the upper edges of the box and the superstructure. The rollover is planned to cap the open top between the box and the superstructure in order to contain the polluting gases inside the tank.
At the bottom of the electrolysis cell is formed a layer of liquid aluminum evacuated periodically by suction or siphoning.
A disadvantage of this type of electrolytic cell concerns the risks exhaust polluting gases to the outside. These risks of gas escape may have different origins.
Notably, different products used during the electrolysis reaction ¨
such as cover product ¨ can accumulate on the edges of the cabinet against which hoods are supported. This accumulation of products may prevent the positioning correct hoods. This induces the appearance of leaks of polluting gases at edge level top of the box and between the covers on each side of the tank.
Also, anode rods of the anode assemblies pass through the cowling.
These anodic rods are associated with dynamic sealing means provided for avoid the escape of gas through the junctions between the cowling and the rods anodic. However, the dynamic sealing means can be damaged, especially when handling anodic rods to change an anode worn by a new anode. Damage to the dynamic sealing means induced the appearance of leaks of pollutant gases at the junctions between the rollover and the anodic rods.
Another disadvantage of this type of electrolytic cell concerns the kinematics of displacement of the anode assemblies when replacing an anode used by a new anode. Indeed, the presence of the superstructure above the opening of caisson generates an obstacle to the vertical displacement of the anode assemblies. he is therefore necessary to implement a kinematics of complex displacement of anode assemblies around this superstructure to allow their extraction of the electrolysis tank.
An object of the present invention is to provide an electrolysis cell allowing to to overcome at least one of the aforementioned drawbacks. In particular, a goal of the present

3 invention is to provide an electrolytic cell having a seal improved to polluting gases and in which the extraction of anode assemblies is facilitated.
Summary of the invention For this purpose, the invention proposes an electrolytic cell that can be used for production of aluminum, having a box covered with an inner lining and including a bottom and side walls, the box being adapted to receive a bath cryolithaire, characterized in that the vessel further comprises a confinement enclosure including side walls extending above the side walls of the box, least one lateral walls of the enclosure being shifted towards the outside of the box compared a lateral walls of the box, and in that the lateral walls offset from the caisson and of the enclosure are mechanically connected by a shoulder including at least a window through which passes a respective cell element moving in translation along an axis TT 'crossing the window.
In the context of the present invention, a side wall of the enclosure is considered as offset from a side wall of the box when the edge lower of the side wall of the enclosure is offset horizontally from the edge superior of the side wall of the box. To the outside of the box means the opposite side inside of the box relative to the side wall.
The shoulder advantageously extends between the lower edge of the wall offset side of the containment and the upper edge of the side wall of the caisson.
The shoulder is more particularly a physical wall ensuring the watertightness between side walls offset from the containment and the caisson connects mechanically. The shoulder can further advantageously support and ensure the mechanical strength of the containment.
The tank comprises one (or more) shoulder (s) between the casing and the enclosure. Each shoulder includes one (or more) window (s) through which (Which) pass (nt) an element (elements) movable (s) in translation along an axis of translation TT 'crossing the window (s), in particular perpendicularly on the plan wherein extends (ent) said (said) window (s).
This particular arrangement (ie shoulder / window assembly for the passage a respective element of vessel moving in translation along an axis TT ' crossing the window) limits the dimensions of the window (s) so that avoid exhausts of pollutant gases to the outside of the electrolysis cell at through one (s) -ci.

4 This particular arrangement also makes it possible to arrange the moving parts of a tank electrolysis ¨ such as lifting or drilling devices ¨ at the periphery of caisson, unlike the electrolysis cells of the prior art where the devices lifting and / or moving drilling devices are generally positioned to the right an opening defined by the walls of the box. Positioning devices lifting and / or piercing devices at the periphery of the housing allows the absence obstacle to a vertical stroke of anode assemblies. This allows facilitate construction of a watertight containment and replacement of sets anodic from the top of the electrolysis cell without the need for of a kinematics of complex displacement of anodic sets.
The containment chamber is used to confine the tank gases to facilitate their capture and treatment. The containment chamber advantageously comprises a system of removable cowling closing an opening formed by the upper portions walls sides of the containment so as to uncomplicatedly change anodic assembly from the top of the electrolysis cell. An opening is performed in the removable rollover system for extracting or inserting a set anodic in the containment.
Preferred but non-limiting aspects of the electrolytic cell according to the invention are the following.
Preferably, the box includes first and second side walls transverse and first and second longitudinal side walls, the enclosure of containment includes first and second transverse side walls extending above first and second transverse lateral walls of the box, and first and second longitudinal side walls extending above the first and second longitudinal side walls of the box, the first side wall longitudinal the enclosure being shifted towards the outside of the box relative to the first side wall longitudinal section of the box and the first longitudinal side walls of the caisson and the enclosure being mechanically connected by a shoulder including at least one window through which passes a respective element of tank moving in translation along an axis TT 'crossing the window.
The shoulder is advantageously made on at least one longitudinal side of tank electrolysis along which can be distributed devices of lifting and / or piercing devices.
In addition, more particularly, the first and second side walls longitudinal of the enclosure are shifted towards the outside of the box with respect to first and WO 2015/11090

5 PCT / 1B2015 / 000073 second respective longitudinal side walls of the box, the first and second respective longitudinal sidewalls of the casing and of the enclosure being mechanically connected by shoulders, each shoulder including at least a window through which passes a respective moving vessel element in Translation along an axis TT 'passing through the window.
The first and second longitudinal side walls of the casing extend between and below the first and second longitudinal sidewalls of the enclosure.
A shoulder is then advantageously made on both sides longitudinal opposed to the electrolytic cell so as to make symmetrical devices lifting and / or piercing devices, conventionally each associated with a device supply of alumina.
The tank may further comprise four peripheral shoulders extending between the upper edges of the side walls of the box and the lower edges of the walls side of the enclosure. This allows in particular to have the elements mobile translation between the four side walls of the box and the four walls lateral of the enclosure.
Each shoulder may be part of the box and / or enclosure. By example:
the box may comprise two peripheral shoulders extending towards the outside of the volume defined by the box, along the upper edges of the first and second longitudinal side walls of the box, the enclosure being free shoulder and being placed on the shoulders of the box, the enclosure may comprise two peripheral shoulders extending towards inside the volume defined by the enclosure, along the lower edges of the first and second longitudinal side walls of the enclosure, the housing being devoid shoulder, and the enclosure being placed on the upper edges of the walls lateral the box, - the box and the enclosure may respectively include two shoulders peripherals, the shoulders of the casing extending outward from the volume defined by the box along the upper edges of the first and second walls longitudinal sides of the box, and the shoulders of the enclosure extending to inside the volume defined by the speaker along the lower edges of the first and second longitudinal side walls of the enclosure; the fact that the caisson and the enclosure each include shoulders facilitates the implementation support the enclosure on the box and improves the stability of the stack composed of the caisson and the enclosure,

6 - the box and the speaker can still be one and the same element monoblock also including the shoulder (s).
The box and the containment are each preferably of shape cuboid. The tank then advantageously has a shape of two parallelepipeds placed on top of each other, the upper parallelepiped (confinement enclosure) being slightly wider than the lower parallelepiped (box).
Preferably, each window extends in a plane perpendicular to the axis of translation T-T '. The translation axis TT 'may be vertical (or substantially vertical).
In that case, each window extends in a horizontal plane. Similarly, each shoulder may be substantially horizontal. The seal between the window of the shoulder and the element of vessel in translation is then facilitated.
In an alternative embodiment, each window is of complementary shape to the form in section of the respective vessel element passing through said window, more particularly of homothetic form. This minimizes dimensions of the gap between the window and the displaceable element so as to limit the risks exhausting polluting gases through said gap. In certain variants of realization, each element passes through a respective window through a joint dynamic sealing, especially annular. Each seal is for example mounted to the periphery of a window, around the element in translation. this allows improve still the tightness of the tank. Preferably, each window is isolated electrically of the element passing through it.
According to an alternative embodiment, the shoulder comprises at least one slot projecting in a direction opposite to the bottom of the box, a window being formed in the water less a niche.
The window made in the upper part of the slot is therefore raised compared to the height of the cryolite bath so as to limit the exposure of the elements moving in translation through the window to the heat released by the bath cryolite, gas and cover product.
Different types of translational element can be associated with a window.
For example, when the tank comprises at least one supported anode assembly by anodic receivers movable in translation along the axis TT 'for to dive or extract the anode assembly from the cryolite bath, the windows of the shoulder can associated with said anode receivers, each window allowing the passage of a respective anode receiver.
According to a preferred embodiment, the anode assembly passes through the tank a wall

7 longitudinal side to side of the containment and is based on two receivers anodic through windows of two shoulders arranged on sides opposite longitudinal axes of the electrolytic cell. The anode set is based then on support and translation means perfectly stable and without impact on the tightness of the containment.
Of course windows (or other windows) can be associated with others Types of element moving in translation such as a conduction device electric of current to supply the anode with electric current, or a device piercing.
In particular, in one embodiment, the vessel comprises a device for drilling designed to create a hole in a crust forming on the surface of the bath cryolithaire for allow a supply, especially of alumina cryolithaire bath, shoulder comprising at least one window through which the drilling, more particularly a piece (a bar) of the drilling device is moving in translation.
The windows associated with the piercing devices are thus raised by report to the height of the cryolite bath so as to limit the exposure of the devices piercing at the heat released by the cryolite bath, gas and roofing product.
Preferably, each shoulder comprises at least one attachment device sure a face of the shoulder opposite the bottom, for example a plate comprising a orifice crossing and forming a point of attachment, for the handling of the box.
this allows to facilitate the movement of the tank using a handling unit comprising typically a traveling crane, a truck that can be moved on the bridge rolling connectable removably to the box using for example rudder pedals.
Each shoulder can extend the entire length of the sidewall longitudinal (respectively transverse) of the box and / or the enclosure. This allows arrange them elements movable in translation along the axis TT 'over the entire length (respectively the width) of the tank.
Advantageously, the side walls of the containment enclosure and the box may serve as a point of attachment to the periphery of the electrolytic cell for some equipment usually attached above the opening of the box in the art prior.
Thus, the tank may comprise means for lifting anode assemblies, piercing device, a gas collection system and a device feeding alumina which are attached to side walls of the containment and / or on side walls of the box.

8 Preferably, the box, the shoulder (s) and the enclosure are in one piece.
This to limit the risk of leakage at the junction between the box, the the shoulders and enclosure that could be related to dilation problems thermal. In a variant, the casing, the shoulder (s) and the enclosure may be in two (or more of two) parts.
Brief description of the figures Other advantages and characteristics of the electrolysis cell will emerge again from description which will follow of several variants of execution, given as examples non-limiting, from the attached drawings in which:
FIG. 1 is a longitudinal sectional view of an electrolytic cell, - Figure 2 is a cross-sectional view of two tanks electrolysis, FIG. 3 is a partial view of an electrolysis cell comprising a device drilling, FIG. 4 is a schematic representation in perspective of a caisson of a electrolytic cell, - Figure 5 is a perspective view of an electrolysis tank.
detailed description An example of an electrolytic cell according to the invention will now be described.
In these different figures, the equivalent elements bear the same references digital.
We will use in the rest of the text the expressions side wall, bottom , opening superior, with reference to a rectangular parallelepiped.
The reader will appreciate that, in the context of the present invention, by:
- bottom, a horizontal wall of a rectangular parallelepiped located near the ground, - upper opening an opening in a horizontal wall a parallelepiped rectangle opposite to the bottom, - face / side wall, a face / vertical wall of a rectangular parallelepiped extending in a plane perpendicular to the bottom, - longitudinal faces / walls, vertical faces / walls of a parallelepiped rectangle of which at least one dimension is greater than the dimensions of the others sides / side walls, - faces / transverse walls, faces / walls verticals extending perpendicular to the longitudinal faces / walls.

9 With reference to FIGS. 1 to 3, an example of an electrolysis cell is illustrated.
according to the invention.
The electrolysis cell of substantially rectangular parallelepiped shape includes a caisson 1, a confinement chamber 2, a plurality of anode assemblies 3, one cathode 4, a gas collection device 5, one (or more) device (s) drilling 6, and several lifting devices 7.
This tank is used for the production of aluminum. She may be associated with a plurality of other electrolysis cells, possibly identical, the different tanks being arranged one after the other, two electrolysis cells clear being adjacent at one of their longitudinal sidewalls.
With reference to FIG. 4, the casing 1 is generally shaped cuboid. he comprises a bottom 10, first and second transverse side walls 11, and first and second longitudinal side walls 12. The box 1 comprises cradles 13 extending on the outer faces of the bottom 10 and walls 11, 12. These cradles 13 can mechanically strengthen the box 1.
The casing 1 may be metallic, for example steel. The internal faces of the background 10 and sidewalls 11, 12 of the box 1 are covered with blocks refractories 14 to insulate the casing 1. The blocks 14 may comprise by example of refractory bricks and / or carbon blocks.
The chamber 2 defines a closed volume of confinement of the gases above the bath cryolithane 19 in which the anode assemblies 3 are moved.
The enclosure 2 is supported on the upper edges of the casing 1. It comprises of the first and second transverse side walls 21 and first and second longitudinal side walls 22 fixed to the casing 1.
Preferably, the side walls 21, 22 of the enclosure 2 are shifted towards outdoors relative to the side walls 11, 12 of the casing 1 so that said side walls 21, 22 of the enclosure 2 extend around and above the side walls 11, 12 of box 1, the side walls 11, 12, 21, 22 of the box 1 and the chamber 2 being connected mechanically by shoulders 16, 17 which will be described in more detail in the after.
The enclosure 2 also includes a removable hood 23 to cap the opening defined by the four side walls 21, 22 of the enclosure 2. The hood 23 can be composed of an assembly of panels extending generally in a plane, and resting on the upper edges of the side walls 21, 22 of the enclosure 2, and more particularly on gas collection ducts extending at the level of edges upper speakers 2.
The casing 1 is open in its upper part 15. The tank comprises one (or many) shoulder (s) peripheral (s) 16, 17 between the upper edges of the walls lateral 5 box and the lower edges of the side walls of the enclosure.
Each peripheral shoulder 16, 17 protrudes outwardly from the box 1 (respectively towards the inside of the enclosure), parallel to the bottom 10 of the caisson 1. The shoulders may be part of the chamber 1 and / or the chamber 2.
Each shoulder 16, 17 is associated with a side wall 11, 12 (respectively 21,

22) of the casing 1 (respectively of the enclosure).
More precisely in the embodiment illustrated in FIG.
box includes four peripheral shoulders 16, 17 extending along one of the edges higher side walls 11, 12 of the box 1:
two longitudinal peripheral shoulders 16, each shoulder peripheral longitudinal 16 extending along an upper edge of a side wall longitudinal 12 of the chamber 1, two transverse peripheral shoulders 17, each shoulder peripheral transverse 17 extending along an upper edge of a side wall transversal

11 of the casing 1.
Alternatively, the caisson 1 (and / or the enclosure) can (can each) understand :
a single longitudinal peripheral shoulder 16, or two longitudinal peripheral shoulders 16, or - one (two) shoulder (s) peripheral (s) longitudinal (longitudinal) 16 and a transverse peripheral shoulder 17.
Each shoulder 16, 17 may comprise one (or more) window (s) 18a to through from which passes an element of the tank moving in translation according to a axis of translation TT 'during the operation of the tank. This element of the tank may be a part of a lifting device 7 moving in translation along the axis of translation TT 'such as an anode receiver 72 of a hoist 7 which will be described more in detail in the following.
Thus, each window 18a is associated with a respective tank element crossing, said bowl member being movable in translation along the translation axis T-T 'between two extreme positions.
Advantageously, each window 18a extends in a plane perpendicular to the axis of translation T-T '. This makes it possible to reduce the dimensions of the windows 18a by making them independent of the movement of elements moving in translation according to the axis of translation T-T '.
In the embodiment illustrated in FIG. 2, each window 18a is associated with a anodic receiver 72 moving in vertical translation according to the axis of translation T-T '. In this case, the windows 18a extend in a plane horizontal. He is leaving the same for each shoulder 16, 17.
The shape of each window 18a may be complementary to the shape in section (according a plane perpendicular to the translation axis T-T ') of the element passing through through said window. This makes it possible to minimize the dimensions of the window so that limit risks of exhausting polluting gases to the outside of the tank electrolysis. In reference to FIG. 4, each window 18a is of rectangular shape complementary to the rectangular sectional shape of their associated anode receptors 72.
Advantageously, each window 18a of the box 1 may comprise a seal sealant extending over its edges, so that the seal surround the element translatable in translation associated with the window. This improves the tightness of the tank so as to limit the risks of exhausting polluting gases through the Windows.
The seal may be adapted to cooperate with a portion arranged sealing on the sliding element. In this case, the sealing portion extends along of the zone of the sliding element through the seal when moving in translation of the element between its extreme positions. Thus, the tightness of the tank is assured despite of the movement in translation of the element.
The dynamic seal, typically annular around the portion sealing, can also be used as an electrical insulator if the sliding element is not the same electric potential as the edges of the window crossed.
Each (or some) shoulder (s) 16, 17 may also include a (or more) window (s) 18b through which passes a piece of a device piercing 6 which will be described in more detail later.
The shape of each window 18b can be complementary to the shape in section (according a plane perpendicular to the translation axis T-T ') of the piece passing through through said window18b to limit the risks of exhausting gaseous pollutants to outside the electrolysis tank. With reference to FIG. 5, each window 18b is circular shape complementary to the cylindrical shape of the piercing device part 6 who is associated.

12 A seal may be provided on the edges of each window 18b, so that the sealing ring surrounds the translatable part in translation of the drilling 6.
The seal may be adapted to cooperate with a portion arranged sealing on the part of the piercing device 6, this portion extending over the entire area of the sliding piece through the seal when moving in translation of the room between its extreme positions.
The windows 18a and 18b can extend in the combined planes.
Alternatively and as illustrated in FIG. 5, the windows 18a and 18b can to expand separate plans.
In particular, in the embodiment illustrated in FIG.
shoulder 16, 17 includes slots projecting in a direction opposite to the bottom 10 of the box 1.
Each slot comprises a horizontal plateau in which is arranged a window Respective 18b so that the windows 18b extend to a height superior to the height of windows 18a.
Advantageously, the side walls 21, 22 of the enclosure 2 may be in support with the upper edges of the box 1 at the free ends of the shoulders 16, 17. As a result, the area of the opening defined by the edges lower walls 21, 22 of the chamber 2 is substantially equal to the sum of:
the surface of the shoulders 16, 17 and - the surface of the upper opening defined by the upper edges of the walls 11, 12 side of the box 1.
Preferably, the casing 1 or the shoulders 16, 17 and the enclosure 2 are piece.
This makes it possible to limit the risks of leakage at the junction between the box and the enclosure. These The risks are otherwise significant because the enclosure 1 and the enclosure will have a different behavior compared to the dilation caused by the high temperatures operating an electrolytic cell.
In a variant, the casing or the shoulders 16, 17 and the enclosure may to be in two (or more than two) parties. In one embodiment, the box 1 and the enclosure 2 each comprise shoulders extending:
- for the shoulders of the casing 1, on one or more upper edge (s) of (a) lateral wall (s) longitudinal (s) (and transverse) of the box, - for the shoulders of the enclosure 2, on one (or more) edge (s) lower (s) of lateral wall (s) longitudinal (s) (and transverse) of the enclosure.
The shoulder (s) extend (s) preferably perpendicular to the walls

13 side of the chamber 1 and the chamber 2, each shoulder of the chamber 2 can come in contact with a respective peripheral shoulder of the casing 1.
The presence of shoulders at the same time on the side walls of the caisson 1 and of the enclosure 2 makes it easier to press the enclosure 2 onto the casing 1 and allows to improve the stability of the composite stack of the box 1 and the enclosure 2.
As indicated above, each shoulder can extend over the entire length of the side wall of the enclosure 2 (respectively of the caisson 1), the shoulders of the enclosure 2 and the box 1 each comprising one (or more) window (s) to of the positions coinciding when the chamber 2 is placed on the casing 1.
Each anode assembly 3 comprises an anode 31 and an anode structure 32.
The anodic structure 32 allows on the one hand to manipulate the anode 31, and on the other hand part of to supply it with electric current. During the electrolysis reaction, the anode 31 diving in the cryolite bath is consumed. Anode assemblies 3 must therefore be replaced periodically.
The anode 31 is preferably a block of precooked carbonaceous material.
Anodic assemblies 3, and more particularly anodic structure 32 of each anodic assembly 3, extending transversely in the tank between the edges lateral longitudinal lines 22 of the enclosure 2. The anode structure comprises in particular a beam cross. The vessel comprises a plurality of anode assemblies 3 distributed according to one longitudinal axis of the tank.
The anode structure may comprise an armature made of a metal having a good mechanical strength, such as steel. This allows the structure anodic to ensure the maintenance in suspension of the anode assemblies. She can also include sections made of a metal having a good electrical conductivity such as copper or aluminum. This allows the structure anodic to ensure the routing of electric current for power electric anode assemblies.
The cathode 4 may comprise a plurality of cathode blocks of material carbon.
The cathode 4 is connected in its lower part to conduction means electric electrolysis current 41 formed in particular of one or more conductors.
More particularly, each cathode block has at least one recess in its part lower inside which is disposed an electrical conduction means 41.
A good physical and electrical connection is made in the recess between the block cathode 4 and the electrical conduction means 41 using cast iron.
The

14 driver passes through the box 1 at the openings in the box 1, plus particularly the bottom 10 or the longitudinal side walls 12.
The driver collects the electrical current at the cathode to allow his routing from one electrolysis cell to another.
The gas collection device 5 makes it possible to recover for treatment the gases pollutants generated during the electrolysis reaction.
The gas collection device 5 comprises one (or more) sheath (s) of capture on which (which) openings for the suction of gases are distributed.
The capture sheath (s) is (are) associated with one or more device (s) suction (not shown). It (s) extends (ent) on the walls longitudinal side 22 of the enclosure 2, and possibly on the lateral transverse walls 21 from the enclosure 2. The presence of openings along the longitudinal walls 22 of the enclosure 2 improves the efficiency of the collection of gaseous pollutants.
Advantageously, the number of openings of the collection device 5 can be equal to one number of piercing devices 6 attached to the electrolytic cell. In that case, each opening may be associated with a respective piercing device 6 and be positioned at near this one.
Advantageously, each capture sheath may be of square section or rectangular, and be made of a material with a strong robustness mechanical, such as steel. This makes it possible to increase the rigidity and the strength of the sheath suction. This forms a capture sheath which, in addition to its function first of gas routing, may be used in particular as a safety belt.
strapping for the set composed of the caisson 1 and the enclosure 2, and as support of fixing for different elements of the electrolysis cell such as devices drilling 6 or lifting devices 7.
The fact of associating several functions with the capture sheath thus makes it possible to limit the size of the tank and facilitate its manufacture.
The piercing devices 6 make it possible to form holes in a crust of alumina and solidified bath forming on the surface of the cryolite bath 19 during the reaction electrolysis.
These holes are formed regularly to allow the addition of various compounds such as alumina, cryolite (Na3AIF6) or aluminum fluoride (AIF3) ¨
in order to stabilize the operating parameters of the electrolytic cell.
The piercing device comprises a jack 61 and a piercing member 62.

The piercing member 62 is intended to be positioned above the crust at drill. The cylinder 61 allows to animate the piercing member 62 of a vertical movement of va-and forth for piercing the crust via a U-shaped structure 63 composed of first and second wings connected to a transverse soul.
5 The first wing is secured to a rod of the jack 61 and extends into the extension of this along an axis TT 'of translation of the rod. The second wing is in solidarity with the piercing member 62.
A thermally insulating part can be fixed between the first wing and the rod for limit the risk of heat propagation to cylinder 61, a increase too much 10 significant temperature of the cylinder 61 can degrade.
Sliding guide means of the cylinder rod 61 can be planned for the (or) window (s) associated with (s) device (s) drilling 6. These means guiding guide the translational movement of the compound composed of the rod of cylinder 61, the piercing member 62, and the U-shaped structure 63.

15 For example, each window 18b associated with a piercing device 6 can understand a channel 64 surrounding the first wing and forming the guide means for sliding. This channel 64 extends on the edges of the window 18b, and protruding preferably perpendicular to an outer face of the shoulder 16a, 17a view of the bottom 10 of the box 1 (ie face of the shoulder opposite to the volume closed defined enclosure 2), so as to minimize the height of the transverse web top of the shoulder 16a, 17a.
Lifting devices 7 allow manipulation of structures anodic 32, and by consequently, anode assemblies 3. More specifically, lifting 7 allow to move vertically in translation the anode sets 3.
Each anode assembly 3 is associated with two lifting devices 7 respective on each of which rest one end. So the displacement of each anodic assembly 3 is independent of the displacement of the other sets anodic 3 contained in the tank.
Each lifting device 7 comprises a jack 71 and an anode receiver 72.
The cylinder 71 makes it possible to move the receiver vertically in translation anodic 72 along a translation axis T-T '.
The anode receiver 72 comprises a bar of rectangular section extending according to a longitudinal axis coincides with the translation axis T-T '. A portion (by example the end closest to the bottom of the box) of the bar is connected electrically to

16 flexible electrical conduction means to allow feeding electric anode assemblies. The upper end of the bar includes a dwelling destined to receive the end of the anode structure 32 and whose shape is complementary to it.
Guiding means for ensuring a vertical displacement along the axis of translation TT 'of the anode receiver 72 may be provided at the level of windows 18a associated with anode receptors.
These guide means may comprise one (or more) ring (s) surrounding partially the bar to allow vertical sliding between:
- a retracted position where the housing is close to the surface of the bath cryolithaire, and - an extended position where the dwelling is away from the surface of the cryolite bath.
The lifting device is advantageously electrically isolated from the box 1 and of the enclosure 2.
The reader will understand that many changes can be made at the invention described above without materially emerging new teachings described here.
For example in the embodiments described above, the windows 18a were associated with lifting devices 7, and windows 18b were associated with 6. It is obvious to those skilled in the art that the Windows 18a and 18b can be associated with any other vessel element moving in translation along a translation axis T-T '. Also and unlike this who is presented above, windows 18a may be associated with devices piercing 6 and windows 18b to lifting devices 7.
Moreover, in the foregoing description, the window (s) corresponded to two-dimensional openings. In the case of three-dimensional openings, the (where the) window (s) correspond to the projection in a plane of said openings = three-dimensional, this projection defining a region of passage for the element of vat associated with it.

Claims (16)

1. Electrolytic cell for use in the production of aluminum, comprising:
a box (1) covered with an inner lining (14) and including a bottom (10) and side walls (11,12), the box (1) being intended to receive a bath cryolithane (19), characterized in that the tank further comprises a containment chamber (2) including walls lateral (21,22) extending above the side walls (11,12) of the box (1), at least one of the side walls (21,22) of the containment (2) being shifted towards the outside of the box (1) with respect to one of the side walls (11, 12) of the box (1), and in that the offset side walls (11, 12, 21, 22) of the box (1) and of the enclosure of confinement (2) are mechanically connected by a shoulder (16, 17) including at least one window (18a, 18b) through which a respective element passes of tank moving in translation along an axis TT 'passing through the window (18a, 18b). 2. Electrolytic cell according to claim 1, wherein the shoulder (16,17) extends between a lower edge of the side wall offset from the enclosure of containment (2) and an upper edge of the side wall of the box (1). 3. Electrolytic cell according to any one of claims 1 or 2, in which the box (1) includes first and second transverse side walls (11) and first and second longitudinal side walls (12), the enclosure of containment (2) includes:
first and second transverse lateral walls (21) extending above first and second transverse side walls (11) of the box (1), and - first and second longitudinal side walls (22) extending above first and second longitudinal side walls (12) of the box (1), the first longitudinal sidewall (22) of the containment (2) being shifted towards the outside of the box (1) relative to the first side wall longitudinal (12) box (1) and the first longitudinal side walls (12, 22) of the caisson (1) and the confinement enclosure (2) being mechanically connected by a shoulder (16, 17) including at least one window (18a, 18b) through which passes a element respective vessel moving in translation along a TT 'axis crossing the window (18a, 18b). 4. Electrolysis cell according to claim 3, wherein the first and second longitudinal side walls (22) of the enclosure (2) are shifted towards outside the box (1) relative to the first and second side walls longitudinal (12) respective of the box (1), the first and second side walls longitudinal (12, 22) of the housing (1) and the enclosure (2) being connected mechanically by shoulders (16, 17), each shoulder (16, 17) including at least one window (18a, 18b) through which passes a respective vessel member moving in translation along an axis TT 'passing through the window (18a, 18b). 5. Electrolytic cell according to any one of claims 1 to 4, in which the containment enclosure (2) has a removable removable cowling system a opening formed by the upper portions of the side walls of the enclosure (2) of containment. 6. Electrolytic cell according to any one of claims 1 to 5, in which each window extends in a plane perpendicular to the translation axis T-T ' 7. Electrolytic cell according to any one of claims 1 to 6, in which the translation axis TT 'is vertical, each shoulder extending substantially in a horizontal plane. Electrolytic cell according to one of claims 1 to 7, in which which the box (1) and the containment chamber (2) are substantially shaped cuboid. 9. Electrolytic cell according to any one of claims 1 to 8, in which each window is complementary in shape to the sectional shape of the element respective tank passing through said window. 10. Electrolytic cell according to any one of claims 1 to 9, which further comprises a dynamic seal associated with each window. 11. Electrolytic cell according to any one of claims 1 to 10, in which the shoulder comprises at least one slot projecting in one direction opposed to bottom of the box, a window (18b) being formed in the at least one slot. 12. Electrolytic cell according to any one of claims 1 to 11, in which the vessel comprises at least one anode assembly (3) supported by receivers anodes (72) movable in translation along the axis TT 'to dive or extract the anode assembly of the cryolite bath, the shoulder comprising at least one window (18a) through which passes a respective anode receiver. 13. Electrolytic cell according to claim 12, wherein the assembly anodic (3) crosses the vessel from one longitudinal side wall (22) to the other of the enclosure of confinement (2) and relies on two anodic receivers (72) passing through Windows (18a) of two shoulders (16,17) disposed on opposite longitudinal sides of the electrolysis tank. 14. Electrolytic cell according to any one of claims 1 to 13, in which the vessel comprises at least one piercing device for creating a hole in a crust formed on the surface of the cryolite bath, the shoulder comprising at least a window through which the piercing device passes. 15. Electrolytic cell according to any one of claims 1 to 14, in which the box, the shoulder or shoulders and the containment are monobloc. 16. Electrolysis cell according to any one of claims 1 to 15, comprising means for lifting anode assemblies, piercing devices, a system of gas collection and an alumina feeder that are attached to walls sides (21,22) of the containment (2) and / or on walls lateral (11,12) caisson (1).