Aluminum smelter comprising electrical conductors made from a superconducting material

The invention claimed is: 1. An aluminum smelter comprising: (i) a series of electrolytic cells, designed for production of aluminum, forming one or more rows, (ii) a supply station designed to supply the series of electrolytic cells with an electrolysis current, the supply station comprising two poles, (iii) a main electrical circuit through which the electrolysis current flows, having two extremities each connected to one of the poles of the supply station, and (iv) at least one secondary electrical circuit comprising an electrical conductor made of superconducting material through which a current flows, running along the one or more rows of electrolytic cells, characterized in that the electrical conductor made of superconducting material in the secondary electrical circuit runs along the row or rows of electrolytic cells at least twice in such a way as to make several complete turns in series. 2. An aluminum smelter according to claim 1 , characterized in that the electrical conductor made of superconducting material in the secondary electrical circuit comprises a single cryogenic casing within which run side by side the turns made by said electrical conductor made of superconducting material. 3. An aluminum smelter according to claim 1 , characterized in that the electrical conductor made of superconducting material in the secondary electrical circuit is flexible and has at least one curved part. 4. An aluminum smelter according to claim 1 , characterized in that the secondary electrical circuit comprises two extremities, each extremity of said secondary electrical circuit being connected to one electrical pole of a supply station which is separate from the supply station for the main electrical circuit. 5. A method comprising: providing an aluminum smelter, comprising: (i) a series of electrolytic cells, designed for the production of aluminum, forming one or more rows, (ii) a supply station designed to supply the series of electrolytic cells with an electrolysis current, the supply station comprising two poles, (iii) a main electrical circuit through which the electrolysis current flows, having two extremities each connected to one of the poles of the supply station, and (iv) at least one secondary electrical circuit comprising an electrical conductor made of superconducting material through which a current flows, running along the one or more rows of electrolytic cells, characterized in that the electrical conductor made of superconducting material in the secondary electrical circuit runs along the row or rows of electrolytic cells at least twice in such a way as to make several complete turns in series, and characterized in that the secondary electrical circuit comprises two extremities, each extremity of said secondary electrical circuit being connected to one electrical pole of a supply station which is separate from the supply station for the main electrical circuit; and delivering the current of intensity between 5 kA and 40 kA from the supply station through the secondary electrical circuit, characterized in that the electrical conductor made of superconducting material in the secondary electrical circuit runs along the one or more rows of electrolytic cells a predetermined number of times so as to allow use of the supply station for the secondary electrical circuit delivering the current of intensity between 5 kA and 40 kA. 6. An aluminum smelter according to claim 1 , characterized in that at least one part of the electrical conductor made of superconducting material in the secondary electrical circuit is located beneath at least one electrolytic cell in the one or more rows. 7. An aluminum smelter according to claim 1 , characterized in that at least part of the electrical conductor made of superconducting material in the secondary electrical circuit runs along a right-hand side and/or a left-hand side of the electrolytic cells in the one or more rows. 8. An aluminum smelter according to claim 1 , characterized in that the electrical conductor made of superconducting material is formed of a cable comprising a central core of copper or aluminum, at least one fiber of superconducting material and a cryogenic casing. 9. An aluminum smelter according to claim 8 , characterized in that a cooling fluid flows through the cryogenic casing. 10. An aluminum smelter according to claim 9 , characterized in that the cooling fluid is liquid nitrogen and/or helium. 11. An aluminum smelter according to claim 1 , characterized in that the electrical conductor made of superconducting material is placed partly within an enclosure forming a magnetic shield. 12. An aluminum smelter according to claim 11 , characterized in that the enclosure forming the magnetic shield is located at least one of the extremities of the one or more rows of electrolytic cells. 13. An aluminum smelter according to claim 1 , characterized in that the secondary electrical circuit runs along the row or rows of electrolytic cells at least twice in such a way that the current flowing through the secondary electrical circuit runs along the row or rows of electrolytic cells at least twice in a same direction. 14. A method according to claim 5 , characterized in that the secondary electrical circuit runs along the row or rows of electrolytic cells at least twice in such a way that the current flowing through the secondary electrical circuit runs along the row or rows of electrolytic cells at least twice in a same direction.