| 摘要 |
A process to recover molybdenum contained in spent petrochemical catalysts has been invented. The proposed process permits the recovery of molybdenum in the form of an alloy, which can also contain other elements, such as nickel, cobalt, tungsten, iron and others. The process starts with a calcining operation for removal of hydrocarbons initially present in the spent catalysts, as well as to oxidize molybdenum and eventual other metal elements, such as nickel, cobalt, tungsten, iron; the calcined material is then fed into a plasma reactor, where molybdenum is recovered in an alloy formed with the other possible elements; the metal alloy can be readily commercialized. Besides recovering molybdenum, the plasma process also generates inert ceramic byproducts, containing alumina, silica and fluxing agents, such as lime. The process is clean and can be used for continuous operation, treating several types of materials, particularly spent catalysts, containing molybdenum or similar elements. |
| 主权项 |
1. A process for recovering molybdenum initially present in spent petrochemical catalysts; the molybdenum is recovered in an alloy, having possibly one or several other elements, such as nickel, cobalt, tungsten, iron or others; a ceramic compound, made mainly of the alumina substrate of the catalysts, containing fluxing agents, such as lime, is also generated in the process as a byproduct. Both molybdenum alloy and ceramic compound can be readily commercialized or be further processed in order to generate purer or different products. The process comprises:
continuous feeding of molybdenum spent catalysts in a rotary kiln; operating temperature of the kiln between 300 and 1,200° C.; oxidizing conditions inside the kiln are maintained; removal of the initially contained hydrocarbon compounds and transformation of the molybdenum disulfide into molybdenum oxide; oxidation of possibly other elements initially present in the spent catalysts, such as nickel, cobalt, tungsten, iron; continuous removal from the kiln of the calcined material; continuous feeding of the calcined material into a plasma reactor; operating temperatures of the plasma reactor between 1,500 and 2,500° C., using a transferred plasma torch to provide the energy for the process; non oxidizing conditions inside the plasma reactor; addition of reducing agents, such as carbon, for the transformation of the molybdenum oxide into molybdenum metal, as well as the transformation of other possible oxides, including nickel, cobalt, tungsten, iron, into their respective metal forms; addition of a fluxing agent, such as lime, to decrease the viscosity of the ceramic compound, made initially of alumina and possibly silica; generation of a metal alloy made of molybdenum and possibly nickel, cobalt, tungsten, iron, all melted inside the plasma reactor; periodically tapping of the metal alloy; periodically tapping of the ceramic compound; production of a metal alloy and of a ceramic compound, both suitable for commercialization; possibly further purification of the metal alloy for generating other products; cleaning the off gases coming from the kiln and the plasma reactor before they are released to the atmosphere. |
