Title of Invention	A PROCESS FOR THE PRODUCTION OF FERROCHROME ENRICHED WITH NICKEL
Abstract	A process for the production of ferrochrome enriched with nickel comprising: subjecting the chromite nickeliferrous ore to oxidation followed by the step of reduction using coal as reductant and flux at a low temperature of 1400-1500°C; separating the metal and slag phase after quenching into water.

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FIELD OF INVENTION: This invention relates to a process for the production of ferrochrome enriched with nickel. BACKGROUND OF THE INVENTION: Chromite nickeliferrous overburden dump material is generated in huge amounts along with the production of chromite. 50 Million tonnes of such chromite overburden is generated in India each year in addition to the 140 Million tonnes that has already been accumulated over several years of mining. Dumping of the overburden material is a major problem at mines due to unavailability of space and environmental concerns. Therefore this huge low grade material should be utilized in cost-effective way. Overburden is known to contain valuable nickel in lateritic form. The various approaches tried out for extracting nickel from chromite overburden includes leaching (chemical & biological), bioacids, electrochemical, reduction roasting followed by leaching, microwave heating, etc. The leaching especially chemical leaching approach suffers from high consumption of leachant and its disposal after treatment. Nickel concentration by beneficiation is not amenable option since nickel is present only as minor constituent. Therefore, high carbon ferrochrome enriched with nickel is produced from chromite nickeliferrous ore dump material which is a low chromium containing ore material. A novel process route is designed by preoxidation followed by reduction of this material using coal as reductant for production of metallized ferrochrome which is enriched with nickel. The metal product is produced by low temperature reduction of pre-oxidized nickeliferrous chromite ore material in lab. OBJECTS OF THE INVENTION: An object of this invention is to propose a process for the production of ferrochrome enriched with nickel; Another object of this invention is to propose a process for production of ferrochrome enriched with nickel by low temperature reduction of pre-oxidized chromite nickeliferrous ore; Still another object of this invention is to propose a process for the production of ferrochrome enriched with nickel wherein a clear separation of slag and metal phase takes place at a lower temperature; Further, object of this invention is to propose a process, which is cost effective; Still further object of this invention is to propose a process which is 20% energy saving. DESCRIPTION OF THE INVENTION: According to this invention there is provided a process for the production of ferrochrome enriched with nickel comprising: subjecting the chromite nickeliferrous ore to oxidation at 800 0C. The microstructure of the oxidized nickeliferrous ore is shown in Fig. 1. The nickeliferrous chromite ore has different mineral phases present which consist of Iron oxides, Aluminium iron silicates, chromite, hercynite, corundum and quartz. This ore having very low Cr: Fe ratio ranging from 0.28 to 0.32 were oxidized at low temperatures (900°C). The oxidized sample shows oxidation of FeO phase to Fe2O3 in the chromite particles. After oxidation, the chromite nickeliferrous ore is subjected to the step of reduction using coal as reductant and flux at a low temperature of 1400-1500°C; And separating the metal and slag phase after quenching into water. Reduction of the oxidized chromite nickeliferrous ore was carried out using coal as reductant. Flux used consists of silica source (quartz) and lime. The reduction experiments carried out using the controlled atmosphere high temperature furnace. The raw materials used alongwith there composition is given in the following table. Table 1: Raw materials and their composition The experimental studies for reduction were carried out at low temperatures of 1400-1500°C. The coal reductant is used in 10-50% excess of the stichiometric carbon requirement for reduction of Iron oxides (Fe2O3) and chrome oxides (Cr2O3) in the ore. Based on the special slag designed, the flux addition was carried out as quartz addition in the range of 0-10% excess of required for aluminium oxides and magnesium oxide dissolution to slag. The lime addition was done in the range of 3-5% of the ore. Reduction was carried out in the temperature range of 1400-1500°C for 1.5-3.0 hours. It can be seen that the metal shows total five phases which consists of four phases containing chromium and iron as major constituent. The fifth phase (features 12, 1) in metal is rich in Ni. Hence the product ferrochrome enriched wrth nickel. The metal nuggets produced were having diameter in the range of 0.5-2.0 cms. The metal and slag phase separation is clear which after quenching in water can be separated by physical separation methods. The slag and metal obtained after separation are shown in Fig. 2. The chemical composition of the metal and slag produced is given in Table 2. Table 2: Chemical analysis of the ferrochrome enriched with nickel and slag The microstructure of the ferrochrome enriched with nickel metal is shown in Fig. 3. The point analysis of the respective spots is given in Table 3. It can be seen from Fig.3 and Table 3, that the nickel is present in the iron rich phases. Reaction mechanisms: The oxidation of FeO the chromite ore opens the spinel structure which increases the reactivity of chromite spinel due to formation of vacancies. The oxidation of the chromite ores also helps in reducing the reduction time. The reduction mechanism of chromite ores in absence of lime as flux, generally proceeds as per the following steps. Chromium oxide reacts at 1200 to 1600°C with carbon to form one of the carbides Cr3C2, Cr7C3. 3Cr2O3 +13C→2Cr3C2 + 9CO (1150-1200°C) 27Cr3C2 + 5Cr2O3 →13Cr7C3 + 15CO (1200-1600°C) At still higher temperatures Cr7C3 reacts with Cr2O3 to yield Cr23C6 and finally above 1820°C the Cr metal is favored product. However due to use of lime as fluxing component the slag formation reactions plays an important role in carrying out the reduction of chrome oxides at lower temperatures. In presence of lime as fluxing component the slag formation reactions take place at lower temperatures which promotes the chromium reduction by dissolution in slag. WE CLAIM: 1. A process for the production of ferrochrome enriched with nickel comprising: subjecting the chromite nickeliferrous ore to oxidation followed by the step of reduction using coal as reductant and flux at a low temperature of 1400-1500°C; separating the metal and slag phase after quenching into water. 2. The process as claimed in claim 1, wherein the said step of reduction carried out for 1.5 to 3.0 hrs. 3. The process as claimed in claim 1, wherein said flux comprises silica source (quartz) and lime. 4. The process as claimed in claim 1, wherein the coal reductant is used in 30-50% excess of the stichiometric carbon requirement for reduction of Iron oxides, chrome oxides in the Ore. 5. The process as claimed in claim 1, wherein the flux addition was carried out as quartz addition in the range of 0-10% excess of required for aluminium oxides and magnesium oxide dissolution to slag, the lime addition done in a range of 3 to 5% of the ore. A process for the production of ferrochrome enriched with nickel comprising: subjecting the chromite nickeliferrous ore to oxidation followed by the step of reduction using coal as reductant and flux at a low temperature of 1400-1500°C; separating the metal and slag phase after quenching into water.

Documents:

164-KOL-2009-(04-02-2013)-ABSTRACT.pdf

164-KOL-2009-(04-02-2013)-AMANDED PAGES OF SPECIFICATION.pdf

164-KOL-2009-(04-02-2013)-CLAIMS.pdf

164-KOL-2009-(04-02-2013)-CORRESPONDENCE.pdf

164-KOL-2009-(04-02-2013)-DESCRIPTION(COMPLETE).pdf

164-KOL-2009-(04-02-2013)-DRAWING.pdf

164-KOL-2009-(04-02-2013)-FORM 1.pdf

164-KOL-2009-(04-02-2013)-FORM 2.pdf

164-KOL-2009-(04-02-2013)-FORM 3.pdf

164-KOL-2009-(04-02-2013)-FORM 5.pdf

164-KOL-2009-(04-02-2013)-OTHERS.pdf

164-kol-2009-abstract.pdf

164-kol-2009-claims.pdf

164-KOL-2009-CORRESPONDENCE-1.1.pdf

164-kol-2009-correspondence.pdf

164-kol-2009-description (complete).pdf

164-kol-2009-drawings.pdf

164-KOL-2009-FORM 1-1.1.pdf

164-kol-2009-form 1.pdf

164-kol-2009-form 2.pdf

164-kol-2009-form 3.pdf

164-kol-2009-gpa.pdf

164-kol-2009-specification.pdf

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