Electrochemical metallurgical process for extracting metals and sulfur from metallic sulfides

What is claimed is: 1 . An electrochemical metallurgical process for extracting metals and sulfur from metal sulfides, characterized by the following steps: (1) Metal sulfide is transformed into an electrode, known as a metal sulfide electrode; (2) The metal sulfide electrode serves as the anode, alongside the insertion of both anode and cathode into the electrolyte at intervals to establish an electrode array for electrolysis, during this process, the sulfur element within the metal sulfide undergoes oxidation and is absorbed in the form of sulfur onto the anode, simultaneously, metal ions migrate into the electrolyte, initiating reduction reactions on the cathode surface, resulting in the formation of metal elements, cathode materials may include titanium, copper, stainless steel, lead, zinc, aluminum, or graphite. 2 . According to the electrochemical metallurgical method for extracting metal and sulfur from metal sulfide as described in claim 1 , it is distinguished by the adjustment of metal sulfide composition through the addition of elements during the preparation phase, as well as the modification of mechanical properties by incorporating enhancers, these additional elements may include one or more of copper, manganese, cobalt, sulfur, molybdenum, tin, bismuth, lead, zinc, selenium, antimony, tellurium, cadmium, and the reinforcing agent is carbon fiber, stainless steel fiber, copper fiber or lead fiber; Metal sulfide can exist as a pure substance or a mixture, pure substances encompass various compounds, including but not limited to lithium sulfide, sodium sulfide, magnesium sulfide, aluminum sulfide, potassium sulfide, calcium sulfide, manganese sulfide, iron sulfide, ferrous sulfide, cobalt sulfide, copper sulfide, cuprous sulfide, zinc sulfide, molybdenum sulfide, silver sulfide, cadmium sulfide, tin sulfide, antimony sulfide, lead sulfide, and bismuth sulfide; Mixtures of metal sulfides include natural sulfide concentrates, metallurgical intermediates, or by-products, examples of natural sulfide concentrates consist of, but are not limited to, pyrite, green vanadite, chalcopyrite, bornite, chalcocite, cuprite, fahlerite, arsenophenite, cobaltite, quartzite, wolframite, sulfotin, tetrahedrite, columnite, sulfotinite, antiantimonite, disulfide tin, trapezite, manganese sulfite, and pyroxene. Additionally, mixtures may comprise metallurgical intermediates or by-products such as copper matte, cobalt matte, lead matte, antimony matte, iron matte, copper matte, and bismuth matte. 3 . Claim 2 's electrochemical metallurgical method for extracting metals and sulfur from metal sulfides is characterized by employing various preparation methods for metal sulfide electrodes, these methods include thermal spraying, hot plating, physical vapor deposition (such as vacuum evaporation and magnetron sputtering), chemical vapor deposition, casting (such as sand casting and solid casting), and powder metallurgy (such as pressing and centrifugal forming). 4 . Electrochemical metallurgical method for extracting metals and sulfur from metal sulfides in accordance with claim 3 , characterized by: Thermal spraying method: the use of heat sources to melt the metal sulfide powder, by controlling the pressure of the protective gas is sprayed to the surface of the substrate to form a metal sulfide electrode, where the pressure is 1˜20 MPa; Vacuum evaporation method: the metal sulfide powder is added to the evaporation container, adjust the vacuum degree, heating the powder deposited on the substrate to obtain the metal sulfide electrode, where the vacuum degree is 10 −6 ˜10 2 Pa; In the magnetron sputtering method, the substrate is linked to the anode while the metal sulfide target is connected to the cathode, the vacuum is reduced to below 10 −3 Pa, followed by filling with argon to maintain the vacuum within the range of 10 −2 to 10 Pa, power is then activated, leading to the deposition of the metal sulfide electrode through magnetron sputtering; The material composition of the sulfide target encompasses, but is not restricted to, magnesium sulfide, zinc sulfide, calcium sulfide, aluminum sulfide, and cadmium sulfide; In the chemical vapor deposition method, the metal powder and sulfur powder are placed in an evaporator within a chemical vapor deposition chamber filled with protective gas, upon heating, the metal and sulfur powders evaporate and react in the chamber, depositing onto the substrate and forming the metal sulfide electrode; In the hot plating method, the metal sulfide is melted within a melting furnace, and the substrate is immersed into the molten metal sulfide for hot plating, resulting in the formation of the metal sulfide electrode; The sand casting method involves preparing a cavity using mold sand and core sand, the metal sulfide is melted in a furnace, poured into the prepared cavity, and left to cool and solidify, the metal sulfide electrode is obtained through sand removal and cleaning; For the solid casting method, foam is buried in sand, and the metal sulfide is melted in a furnace, the molten metal sulfide replaces the foam, and upon cooling and solidification, the metal sulfide electrode is obtained through sand removal and cleaning; In the press method, metal sulfide powder and forming agent are mixed and pressed into a mold to obtain a green form, the green form is then sintered to obtain the metal sulfide electrode, pressing parameters include a molding pressure of 10 to 30 MPa, pressing speed of 1 to 15 mm/s, and pressure holding time of 0.1 to 10 hours; Similarly, in the centrifugal forming method, metal sulfide powder and forming agent are mixed and centrifugally formed in a mold to obtain a green form, the green form is then sintered to obtain the metal sulfide electrode, centrifugal forming speed typically ranges from 500 to 4500 r/min; Sintering is typically conducted in a protective gas atmosphere, with temperatures ranging from 400 to 1200° C. and sintering times from 0.1 to 10 hours, protective gases used include but are not limited to argon, nitrogen, and carbon dioxide. 5 . Claim 4 's electrochemical metallurgical method for extracting metals and sulfur from metal sulfides is distinguished by the average particle size of the metal sulfide powder, which ranges from 1 nm to 1 mm. 6 . In accordance with claim 4 , the electrochemical metallurgical method for extracting metals and sulfur from metal sulfides is characterized by the substrate material, which can be metal, graphite, or composite material: Metal substrate materials include, but are not limited to, copper, zinc, lead, tin, aluminum, titanium, stainless steel, aluminum alloy, lead alloy, titanium alloy, manganese alloy, copper alloy, zinc alloy, tin alloy, tungsten alloy, and molybdenum alloy, composite substrate materials include, but are not limited to, conductive silicone rubber, conductive plastic, and conductive fiber. 7 . As per claim 4 , the electrochemical metallurgical method for extracting metals and sulfur from metal sulfides is distinguished by the dimensions of the substrate: The longitudinal cross-section area ranges from 1 cm 2 to 10 m 2 , while the thickness or radius ranges from 1 to 2000 mm, additionally, the adhesion thickness of metal sulfide on the substrate ranges from 1 to 30 mm. 8 . According to claim 4 , the electrochemical metallurgical method for extracting metals and sulfur from metal sulfides is characterized by the forming agent, which includes but is not limited to starch, sulfur, molybdenum disulfide, graphite powder, paraffin wax, and rosin. 9 . The electrochemical metallurgical method for extracting metals and sulfur from metal sulfides described in claim 1 is characterized by the composition of the ele