Aluminium Smelter and Method to Compensate for a Magnetic Field Created by the Circulation of the Electrolysis Current of Said Aluminium Smelter

1 . Aluminum smelter comprising at least one row of electrolytic cells arranged transversely in relation to length of said at least one row, a first electrolytic cell of the row of electrolytic cells comprising anode assemblies and rising and connecting electrical conductors to the anode assemblies, characterized in that the rising and connecting electrical conductors extend upwardly along two opposite upstream and downstream longitudinal edges of the first electrolytic cell for conducting electrolysis current to the anode assemblies, and in that the aluminum smelter includes: at least one first electrical compensation circuit extending beneath the electrolytic cells, said at least one first electrical compensation circuit being configured to be traversed by a first compensation current designed to flow under the electrolytic cells in an opposite direction to a global direction of flow of the electrolysis current, at least one second electric compensation circuit extending over at least one side of said at least one row of electrolytic cells, said at least one second electric compensation circuit being configured to be traversed by a second compensation current designed to flow in a same direction as the global direction of flow of the electrolysis current. 2 . Aluminum smelter according to claim 1 in which the rising and connecting electrical conductors comprise upstream rising and connecting electrical conductors, adjacent to the upstream longitudinal edge of the first electrolytic cell and downstream rising and connecting electrical conductors, adjacent to the downstream longitudinal edge of the electrolytic cell, and the aluminum smelter is laid out so that a distribution of the electrolysis current is asymmetrical between the upstream and downstream rising and connecting electrical conductors, an intensity of an upstream electrolysis current designed to run through all of the rising and connecting electrical conductors upstream of the first electrolytic cell being equal to 50-100% of an overall intensity of the electrolysis current, and an intensity of a downstream electrolysis current designed to run through all of the rising and connecting electrical conductors downstream of the first electrolytic cell is equal to 0-50% of the overall intensity of the electrolysis current, a total intensity of the upstream and downstream electrolysis currents being equal to the overall intensity of the electrolysis current. 3 . Aluminum smelter according to claim 2 in which the aluminum smelter comprises a power station configured to cause to flow through said at least one first compensation electrical circuit a first compensating current of intensity equal to twice the intensity of the downstream electrolysis current (IEB) to the nearest 20%. 4 . Aluminum smelter according to claim 2 in which the aluminum smelter includes a power station configured to cause to flow through said at least one second electrical compensation circuit the second compensation current of an intensity between 50% and 100% of a difference in intensity between the upstream and downstream electrolysis currents. 5 . Aluminum smelter according to claim 1 in which the rising and connecting electrical conductors are distributed at regular intervals along the upstream and downstream longitudinal edges of the first electrolytic cell to which the rising and connecting electrical conductors are adjacent. 6 . Aluminum smelter according to claim 1 in which the upstream rising and connecting electrical conductors and the downstream rising and connecting electrical conductors are equidistant from a longitudinal central plane of the first electrolytic cell. 7 . Aluminum smelter according to claim 6 in which the upstream rising and connecting electrical conductors and the downstream rising and connecting electrical conductors are arranged substantially symmetrically relative to said longitudinal median plane the first electrolytic cell. 8 . Aluminum smelter according to claim 1 in which said at least one first electrical compensating circuit includes electrical conductors extending under the electrolytic cells together forming a layer made up of a plurality of parallel electrical conductors. 9 . Aluminum smelter according to claim 8 in which the electrical conductors of said layer are arranged at regular intervals from each other along a longitudinal direction of the electrolytic cells. 10 . Aluminum smelter according to claim 8 in which the electrical conductors of said layer are arranged substantially symmetrically with respect to a transverse median plane the electrolytic cells. 11 . Aluminum smelter according to claim 8 in which the electrical conductors of said layer are arranged in a same horizontal plane. 12 . Aluminum smelter according to claim 8 in which said at least one second electric compensating circuit includes electrical conductors extending from each side of said at least one row of electrolytic cells, and the second compensating current flows in the same direction as the global direction of flow of the electrolysis current each side of the electrolytic cells. 13 . Aluminum smelter according to claim 12 in which an intensity of an inner second compensating current flowing in an inner loop of said at least one second compensating circuit differs from an intensity of an outer second compensating current flowing in an outer loop of said at least one second compensating circuit. 14 . Aluminum smelter according to claim 13 in which the intensity of the inner second compensating current flowing in the inner loop is greater than the intensity of the outer second compensating current flowing in the outer loop. 15 . Aluminum smelter according to claim 12 in which the electrical conductors forming the at least one second compensating electrical circuit are substantially symmetrical with respect to a median transverse plane of the electrolytic cells. 16 . Aluminum smelter according to claim 12 in which the electrical conductors of the second compensating electrical circuit extend in a same horizontal plane, at a height of a layer of liquid aluminum formed inside the electrolytic cells during the electrolysis reaction. 17 . Aluminum smelter according to claim 1 in which said at least one first electric compensating circuit is independent of a main electrical circuit through which the electrolysis current flows. 18 . Aluminum smelter according to claim 1 in which said at least one second electric compensating circuit is independent of a main electrical circuit through which the electrolysis current flows. 19 . Aluminum smelter according to claim 1 in which the first electrolytic cell is of modular electrical construction in N modules repeated in a direction of length of the first electrolytic cell, each module comprising electrical conductors configured to generate a same predetermined magnetic configuration. 20 . Method of compensating for a magnetic field created by the flow of an electrolysis current in the electrolytic cells of the aluminum smelter according to claim 1 , the method comprising: causing a flow, in the opposite direction to the global direction of flow of the electrolysis current, of the first compensation current through said at least one first electrical compensation circuit, causing a flow, in the same direction as the global direction of flow of the electrolysis current, of a second compensation current through said at least one second electrical compensation circuit. 21 . Method according to cl