TH86846B - Electrolytic cells for rare earth metal production - Google Patents

Abstract

DC60 (09/02/58) An electrolytic cell for the production of rare earth metals is opened. The electrolytic cell includes a cell housing having one or more inclined channels arranged in the floor of the cell, through which the rare earth metal molten metal produced in the cell can be drained. One or more cathodes are suspended within the cell housing, substantially vertical to one or more channels. All respective opposing surfaces of the cathodes are tilted downwardly and outwardly inclined at an angle from the vertical. One or more pairs of anodes are suspended within the cell housing; each anode in the one or more pairs has its facing surface tilted from the vertical and spaced parallel to every other inclined surface of the cathode to determine the anode-cathode distance. (anode-cathode distance therebetween) is very constant. The electrolytic cell also has a sump for accommodating the rare earth molten metal from the channels, where the sump is spaced apart and separated from the one or more cathodes and one or more anodes. The separation of the rare earth molten metal from the cathode and anode prevents reaction and/or contamination with fugitive carbon generated by the anode or back reaction with off gases. Edit brief 09/02/2015 An electrolytic cell for production of rare earth metals is opened. The electrolytic cell includes a cell housing having one or more inclined channels arranged in the floor of the cell housing, through which the rare earth molten metal is produced in the cell. The electrolyte can be drained. The one or more cathodes are suspended within the cell housing. Substantially vertical with one or more channels. All of the respective opposing surfaces of the one or more cathodes are inclined downward and outwardly at an angle from the vertical. One or more pairs of anodes are suspended within the cell envelope; each anode in the one or more pairs has its facing surface inclined from the vertical and spaced parallel to every other inclined surface of the one or more cathodes to provide a very constant anode-cathode distance between them. The electrolytic cell also contains sump for accommodating the rare earth molten from the channels, the sump being spaced apart and separated from the one or more cathodes and one or more anodes. This separation of the rare earth molten from the anode and anode prevents reaction and/or contamination with fugitive carbon generated by the anode or reaction. Back reaction with off gases ----------------------------------------------------------------------------------------------------------------- An electrolytic cell for production of rare earth metals is open. The electrolytic cell includes a cell housing having one or more inclined channels arranged in the floor of the cell, through which the rare earth metal molten metal is produced in the cell. The electrolyte can be drained. One or more cathodes are suspended within the cell housing, substantially vertically to one or more channels. All respective opposing surfaces of the cathodes are inclined downward and outwardly at an angle from the vertical. One or more pairs of anodes are suspended within the cell housing; each anode in the one or more pairs has a facling surface inclined from the vertical and spaced parallel to every other inclined surface of the cathode to determine the anode-cathode distance. (anode-cathode distance therebetween) is very constant. The electrolytic cell also has a sump to receive the rare earth molten metal from the channels, where the sump is spaced apart and separated from one or more cathodes and one or more anodes. The separation of the rare earth molten metal from the cathode and anode prevents reaction and/or contamination with fugitive carbon generated from the anode or back reaction with off gases.

Claims (1)

1. A method for processing and analyzing data from electromagnetic-derived (R) measurements performed at sea or inland (4) above the seafloor (1) to shale (3) with relatively low resistivity. (Formula 3) for detecting possible petroleum-containing reservoir shale (2) with relatively high resistivity (formula 2) where the low-frequency electromagnetic transmitter (5) is arranged in the sea. (4) and emits electromagnetic fields (F) scattered in the sea (4), in rocks (3,2) and in the air (0) over the sea, where the electromagnetic receiver (6) is rubbed.