In some embodiments, an anode apparatus comprises: (a) an anode body comprising at least one outer sidewall, wherein the outer sidewall is configured to define a shape of the anode body, and to perimetrically surround a hole in the anode body, wherein the hole comprises an upper opening in a top surface of the anode body and wherein the hole axially extends into the anode body; (b) a pin comprising: a first end and a second end opposite the first end, wherein the second end extends downward into the upper end of the anode body and into the hole of the anode body; and (c) a sealing material configured to cover at least a portion of at least one of the following: (1) an inner sidewall of the anode body; (2) the top surface of the anode body; (3) the pin; and (4) the anode support.

An anode clamp configured for clamping an anode rod to an anode bus, the anode clamp comprising a first rotating mechanism and a second rotating mechanism. The first rotating mechanism is configured to be rotated by a user and is in contact with the second rotating mechanism. When the first rotating mechanism is rotated, it causes the second rotating mechanism to rotate. The second rotating mechanism as a pawl which is configured for being rotated downwards to apply pressure on an anode rod located below the pawl.

An anode clamp configured for clamping an anode rod to an anode bus, the anode clamp comprising a first rotating mechanism and a second rotating mechanism. The first rotating mechanism is configured to be rotated by a user and is in contact with the second rotating mechanism. When the first rotating mechanism is rotated, it causes the second rotating mechanism to rotate. The second rotating mechanism as a pawl which is configured for being rotated downwards to apply pressure on an anode rod located below the pawl.

The present invention discloses a system and method for measuring an anode current of an aluminum electrolytic cell. The system includes a plurality of electrolytic cell units, where the electrolytic cell units each include: a column bus, two horizontal buses, m anodes, m anode rods, one or a pair of crossover buses, and a plurality of optical fiber current sensors. When one side of the anode rod is adjacent to another anode rod, the horizontal bus between the two anode rods is provided with one of the optical fiber current sensors; and when any side of the anode rod is adjacent to the column bus or the crossover bus, the horizontal bus between the anode rod and the column bus or the crossover bus is provided with one of the optical fiber current sensors. In the present invention, optical fiber current sensors are mounted between two adjacent anode rods and between the anode rod and the column bus or the crossover bus for current measurement, the current of each anode can be measured accurately, and the measurement precision is accurate to be within 1%.

The present invention discloses a system and method for measuring an anode current of an aluminum electrolytic cell. The system includes a plurality of electrolytic cell units, where the electrolytic cell units each include: a column bus, two horizontal buses, m anodes, m anode rods, one or a pair of crossover buses, and a plurality of optical fiber current sensors. When one side of the anode rod is adjacent to another anode rod, the horizontal bus between the two anode rods is provided with one of the optical fiber current sensors; and when any side of the anode rod is adjacent to the column bus or the crossover bus, the horizontal bus between the anode rod and the column bus or the crossover bus is provided with one of the optical fiber current sensors. In the present invention, optical fiber current sensors are mounted between two adjacent anode rods and between the anode rod and the column bus or the crossover bus for current measurement, the current of each anode can be measured accurately, and the measurement precision is accurate to be within 1%.

In one embodiment, an electrolytic cell for the production of aluminum from alumina includes: at least one anode module having a plurality of anodes; at least one cathode module, opposing the anode module, wherein the at least one cathode module comprises a plurality of cathodes, wherein the plurality of anodes are suspended above the cathode module and extending downwards towards the cathode module, wherein the plurality of cathodes are positioned extending upwards towards the anode module, wherein each of the plurality of anodes and each of the plurality of cathodes are alternatingly positioned, wherein the plurality of anodes is selectively positionable in a horizontal direction relative to adjacent cathodes, wherein the anode module is selectively positionable in a vertical direction relative to the cathode module, and wherein a portion of each of the anode electrodes overlap a portion of adjacent cathodes.

In one embodiment, an electrolytic cell for the production of aluminum from alumina includes: at least one anode module having a plurality of anodes; at least one cathode module, opposing the anode module, wherein the at least one cathode module comprises a plurality of cathodes, wherein the plurality of anodes are suspended above the cathode module and extending downwards towards the cathode module, wherein the plurality of cathodes are positioned extending upwards towards the anode module, wherein each of the plurality of anodes and each of the plurality of cathodes are alternatingly positioned, wherein the plurality of anodes is selectively positionable in a horizontal direction relative to adjacent cathodes, wherein the anode module is selectively positionable in a vertical direction relative to the cathode module, and wherein a portion of each of the anode electrodes overlap a portion of adjacent cathodes.

There is provided a process for manufacturing a carbonaceous anode for an electrolysis cell for the production of aluminium. The process comprises contacting coke particles with a boron-containing solution to obtain boron-impregnated coke particles, mixing the boron-impregnated coke particles with coal tar pitch to form an anode paste, and forming a green anode with the anode paste. A carbonaceous anode for an electrolysis cell for the production of aluminium is also provided, which comprises at least a first fraction of coke particle, a second fraction of coke particles and coal tar pitch, wherein at least the first faction of coke particles comprises boron-impregnated coke particles, the boron-impregnated coke particles being distributed throughout the carbonaceous anode. The carbonaceous anode presents good resistivity towards air and CO.sub.2 oxidation, which translates into less dusting of the anode, thus improving its integrity throughout its lifetime.

A cell includes a pot shell defining an opening through which an anode block is designed to be moved, said anode block being suspended from an anode support forming with said anode block an anode assembly mobile in relation to the pot shell, and a confinement chamber defining a closed volume above said opening for the containment of the gases generated during the production of aluminum, the anode support being connected to an electrical conductor to supply an electrolysis current to the anode block, the anode assembly is fully contained in the confinement chamber, and in that the electrical connection between the mobile electrical conductor and the anode support is made within the confinement chamber.

A cell includes a pot shell defining an opening through which an anode block is designed to be moved, said anode block being suspended from an anode support forming with said anode block an anode assembly mobile in relation to the pot shell, and a confinement chamber defining a closed volume above said opening for the containment of the gases generated during the production of aluminum, the anode support being connected to an electrical conductor to supply an electrolysis current to the anode block, the anode assembly is fully contained in the confinement chamber, and in that the electrical connection between the mobile electrical conductor and the anode support is made within the confinement chamber.