Electrolytic device and anode assembly intended for the production of aluminium, electrolytic cell and apparatus comprising such a device

The invention claimed is: 1. Electrolysis device for production of aluminum comprising a pot shell having an inner lining defining an opening through which at least one anode block is designed to be moved, the at least one anode block being suspended from an anode support forming with the at least one anode block an anode assembly movable relative to the pot shell, the device further comprising moving means comprising at least one anode receiver designed to work in conjunction with the anode support to move the anode assembly in a substantially vertical direction, the anode support being designed to be connected to anode conductors to route an electrolysis current to the at least one anode block, characterized in that the at least one anode receiver is placed outside a space defined by any vertical projection of a translation path of the at least one anode block during movement of the at least one anode block through the opening, the at least one anode receiver having a contact surface working in conjunction with a corresponding anode contact surface of the anode support to establish with the anode support an electrical contact to route the electrolysis current between the at least one anode receiver and the anode assembly and a mechanical contact to move the anode assembly in a substantially vertical direction. 2. Device according to claim 1 , characterized in that the device is designed to receive a plurality of anode assemblies distributed along a longitudinal direction of the pot shell, the anode support of the anode assemblies extending along a transverse direction of the pot shell, the device further comprising compensating means working in conjunction with the moving means to absorb expansion of the anode support along the transverse and/or longitudinal direction. 3. Device according to claim 2 , characterized in that the contact surface of the at least one anode receiver is arranged above the at least one anode receiver to bear the anode assembly. 4. Device according to claim 2 , characterized in that the at least one anode receiver comprises a drive portion guided translationally in the substantially vertical direction and an electrically conductive portion. 5. Device according to claim 4 , characterized in that the contact surface of the at least one anode receiver is arranged on the conductive portion of the at least one anode receiver. 6. Electrolysis device for production of aluminum comprising a pot shell having an inner lining defining an opening through which at least one anode block is designed to be moved, the at least one anode block being suspended from an anode support forming with the at least one anode block an anode assembly movable relative to the pot shell, the device further comprising moving means comprising at least one anode receiver designed to work in conjunction with the anode support to move the anode assembly in a substantially vertical direction, the anode support being designed to be connected to anode conductors to route an electrolysis current to the at least one anode block, characterized in that the at least one anode receiver is placed outside a space defined by any vertical projection of a translation path of the at least one anode block during movement of the at least one anode block through the opening, the at least one anode receiver having a contact surface working in conjunction with a corresponding anode contact surface of the anode support to establish with the anode support an electrical contact to route the electrolysis current between the at least one anode receiver and the anode assembly and a mechanical contact to move the anode assembly in a substantially vertical direction, characterized in that the device is designed to receive a plurality of anode assemblies distributed along a longitudinal direction of the pot shell, the anode support of the anode assemblies extending along a transverse direction of the pot shell, the device further comprising compensating means working in conjunction with the moving means to absorb expansion of the anode support along the transverse and/or longitudinal direction, characterized in that the at least one anode receiver comprises a drive portion guided translationally in the substantially vertical direction and an electrically conductive portion, characterized in that the contact surface of the at least one anode receiver is arranged on the conductive portion of the at least one anode receiver, and characterized in that the contact surface is substantially horizontal, the compensating means being essentially formed by the contact surface and the anode contact surface of the anode support working in conjunction with the contact surface, the expansion of the anode support in the transverse direction being absorbed by sliding of the anode contact surface on the contact surface in the transverse and/or longitudinal direction of the pot shell. 7. Device according to claim 6 , characterized in that the sliding of the anode contact surface of the anode support on the contact surface is facilitated by the use of an electrically conductive grease applied on one of the anode contact surface and the contact surface. 8. Electrolysis device for production of aluminum comprising a pot shell having an inner lining defining an opening through which at least one anode block is designed to be moved, the at least one anode block being suspended from an anode support forming with the at least one anode block an anode assembly movable relative to the pot shell, the device further comprising moving means comprising at least one anode receiver designed to work in conjunction with the anode support to move the anode assembly in a substantially vertical direction, the anode support being designed to be connected to anode conductors to route an electrolysis current to the at least one anode block, characterized in that the at least one anode receiver is placed outside a space defined by any vertical projection of a translation path of the at least one anode block during movement of the at least one anode block through the opening, the at least one anode receiver having a contact surface working in conjunction with a corresponding anode contact surface of the anode support to establish with the anode support an electrical contact to route the electrolysis current between the at least one anode receiver and the anode assembly and a mechanical contact to move the anode assembly in a substantially vertical direction, characterized in that the device is designed to receive a plurality of anode assemblies distributed along a longitudinal direction of the pot shell, the anode support of the anode assemblies extending along a transverse direction of the pot shell, the device further comprising compensating means working in conjunction with the moving means to absorb expansion of the anode support along the transverse and/or longitudinal direction, characterized in that the at least one anode receiver comprises a drive portion guided translationally in the substantially vertical direction and an electrically conductive portion, characterized in that the contact surface of the at least one anode receiver is arranged on the conductive portion of the at least one anode receiver, and characterized in that the compensating means are arranged in the at least one anode receiver. 9. Device according to claim 8 , characterized in that the compensating means are arranged between an upper portion of the at least one anode receiver bearing the contact surface and the drive portion. 10. Device according to claim 9 , characterized in that the compensating means comprise at least one connecting member between the upper portion and the drive portion making it possible to absorb the expan