Utilización de pellets autorreductores en la producción de aleaciones (hierro-cromo alto carbono)

The self-reducing agglomerates were effective in reducing chromites for producing high carbon iron-chromium , improving the speed is reduced , or by increasing the efficiency of chrome recovery and electric power is economizing . The self-reducing pellets of Brazilian chromite containing petroleum coke and 2% Fe -75 % Si, bonded with Portland cement with and without addition of fluxantes (SiO2 and CaO) , were tested at 1773K until there was , evolution of gas reduction . The resulting product was analyzed by electron microscopy and the composition of the phases present by EDS . This work demonstrates that the addition of the composition fluxantes the self-reducing chromite pellets before being reduced causes formation of a slag phase , hindering reduction speed . The results showed that in the self-reducing agglomerates without adding fluxantes , the reduction rate was 2 times faster compared with fluxantes containing at 1773K . This confirms the importance of the mechanism of gas - solid reaction in the carbothermal reduction of the chromite .Los aglomerados autorreductores se mostraron eficientes en la reducción de cromitas para la producción de hierro-cromo alto carbono, sea mejorando la velocidad de reducción, sea aumentando el rendimiento de recuperación de cromo y sea economizando energía eléctrica. Los pellets autorreductores de cromita brasileña conteniendo coque de petróleo y 2% de Fe-75%Si, aglomeradas con cemento Portland con y sin adición de fluxantes (SiO2 y CaO), fueron ensayados a 1773K hasta que no hubiese, evolución de los gases de reducción. El producto resultante fue analizado por microscopia electrónica y la composición de las fases presentes por EDS. En este trabajo se demuestra que la adición de fluxantes en la composición de los pellets autorreductores de cromita antes de ser reducidos origina formación de una fase escoria, dificultando la velocidad de reducción. Los resultados mostraron que en los aglomerados autorreductores sin adición de fluxantes, la velocidad de reducción fue 2 veces más rápida, comparados con los que contenían fluxantes, a 1773K. Esto confirma la importancia del mecanismo de reacción gas-sólido en la reducción carbotérmica de la cromita

Use of calcium carbide for gold recovery from arsenic refractory minerals

La arsenopirita, FeAsS, es un mineral que se encuentra frecuentemente en asociación con oro. En este tipo de mineral, el oro se suele encontrar en forma sub-microscópica, encapsulado en la matriz del mismo mineral, o bien constituyendo una solución sólida, lo cual dificulta o impide la recuperación del oro mediante las técnicas disponibles de lixiviación. Inclusive, una molienda muy fina no logra romper la matriz en la que se encuentra el oro, inhabilitando el acceso a las soluciones de lixiviación. Algunas alternativas conducentes a la recuperación de oro a partir de aquellos minerales, consisten en oxidación química, oxidación a presión, oxidación bacteriana y tostación oxidante (muy contaminante por generación de gases de As2O3 y SO2). El presente estudio pretende identificar las condiciones para ruptura de la matriz de la arsenopirita para con ello continuar con el proceso tradicional de la cianuración. Para ello se experimentó con minerales concentrados, conteniendo arsenopirita aurífera.The arsenopyrite, FeAsS, it is a mineral that is commonly found associated with gold. In this kind of mineral, Gold is presented in sub-microscopic size particles, encapsulated in a matrix of the same mineral or forming a solid solution, this does not allow the recovery of gold with the available lixiviation techniques. Moreover, a fine grinding does not a chive to break the matrix in which the gold is located, not allowing the lixiviation solutions to come in. Some alternatives that lead to the recovery of gold from those minerals include chemical oxidation, oxidation under pressure, bacterial oxidation and roasting oxidation (which is very polluting due to the emission of As2O3 y SO2 gases. The aim of the following study is to identify the conditions to break the arsenopyrite matrix for continuing the usual process of cianuration. For doing so, experiments were carried out containing arsenopyrite with gold contents

Study of reduction in self-reducing pellet of chromites.

Neste trabalho estuda-se o comportamento de redução para a obtenção da liga FeCrAC a partir da pelota auto-redutora feita de minério de cromita, coque de petróleo, ferro-silicio, cal hidratada, sílica e cimento portland ARI. As principais variáveis consideradas são: teor de redutor na composição da pelota, quantidade do redutor, temperatura e tempo. Inicialmente os materiais (cromita, ferro-silício, coque de petróleo, cal hidratada, sílica e cimento Portland ARI), foram caracterizados por: análise química e análise granulométrica. Após a caracterização os materiais (cromita, ferro-silício, coque de petróleo e cimento Portland ARI) foram aglomerados na forma de pelotas juntamente com cal hidratada e sílica para ajuste da basicidade quaternária da escória. A redução das pelotas foi feita num forno de indução que pode atingir temperaturas de até 1973K (1700oC). Todos os experimentos de redução foram realizados no aparato experimental utilizando-se cadinhos de grafite nas temperaturas de 1773K (1500oC), 1823K (1550oC) e 1873K (1600oC). Após os ensaios de redução os produtos obtidos (escória e metal) foram analisados por microscopia ótica, por microscopia eletrônica de varredura (MEV) e análise por EDS. O efeito do aumento da temperatura na redução da cromita é significativo. Houve aumento na velocidade de redução de 4 a 6 vezes com o aumento de 1773K (1500oC) para 1873K (1600oC). Os resultados indicam um efeito marcante de pequenas adições de Fe-Si na velocidade de redução da cromita. Na temperatura de 1773K (1500oC) as adições até ~2% de Fe-Si são benéficas e para adições maiores praticamente não há vantagens técnicas e econômicas. Os tempos necessários para atingir a fração unitária de redução foram 12, 7,5 e 5 minutos para adições de Fe-Si de 0, ~1%, e ~2%, respectivamente; a temperatura de 1823K (1550oC). À temperatura de 1873K (1600oC) as adições de Fe-Si na pelota apresentam também efeitos significativos na velocidade de redução, porém adições de ~1%, e ~2% mostraram os mesmos resultados, indicando que o teor ótimo de adição de Fe- Si na pelota deve estar em torno de 1%. Verificou-se que a utilização de pelotas auto-redutoras contendo 26% em excesso, sobre o estequiométrico, de coque de petróleo aumentou o rendimento de recuperação de Cr de 96% para 98%. O rendimento e a eficiência do processo de auto-redução supera aos processos convencionais de produção de FeCrAC, obtendo-se altas recuperações de cromo na faixa de 96% até 98% para Cr.The reduction behaviors, at high temperature, of the self-reducing pellets of chromites for production of high carbon ferro-chromium are studied in this work. The influences of the temperature, of the excess of reductant and the small addition of the Fe-Si were analyzed. The materials used (chromites, petroleum coke, Portland cement, hydrated lime and silica) were characterized chemically and by size distribution. The composite pellets (self-reducing) were produced aiming a quaternary basicity of 0.91. The reductant was calculated considering a stoichiometry of reduction and dissolution of 4wt%C in the final metallic phase. The reduction experiments were made in a special system, in argon atmosphere, heated by induction and at temperatures of 1773, 1823 and 1873K. The dried pellets were placed into a pre-heated graphite crucible and left there along up to no gas evolution was observed. The results of the reacted fraction with time were plotted and the obtained product (metallic and slag phases) after experiments were analyzed by optical and by electron micrograph. The chemical estimations were made by micro-analysis (EDS) The effect of increasing the temperature of reduction was sensitive, such that, the reduction rate increased 4 to 6 times with increase of temperature from 1773 to 1873. The small additions, up to 2% of Fe-Si, for substituting the equivalent fixed carbon of the petroleum coke showed to improve substantially the reduction rate, almost doubling it in comparison with pellets without any addition. The use of excess of 26%, over the stoichiometry, of the petroleum coke decreased around 50% of the chromium content in the slag, with relation to pellet without excess. The chromium recovery yield reached 98%. This result coupled with very high reduction rate of self-reducing pellets show the potential for self-reducing processes for ferro-chromium production

Self-reduction and fusion reduction of chromite self-reducing pellets

Neste trabalho estudou-se a evolução da redução da pelota auto-redutora de cromita contendo coque de petróleo, ferro-silício, cal hidratada, sílica e cimento Portland ARI (alta Resistência Inicial), para a obtenção da liga ferro-cromo alto carbono (FeCrAC). As principais variáveis estudadas foram: influência das adições de Fe-75%Si em sinergismo com coque de petróleo, adição de fluxantes, temperatura e tempo de redução. Além disso, foram realizadas experiências para confirmação dos resultados de auto-redução num forno rotativo de laboratório. Inicialmente os materiais (cromita, ferro-silício, coque de petróleo, cal dolomitica, sílica e cimento Portland ARI), foram caracterizados por análise química e análise granulométrica. Após a caracterização, os materiais, foram aglomerados na forma de pelotas (P1, P2, P3, P4 e P5), com adições de 0, 1, 2 e 4% Fe-75%Si, e adições de 2% Fe-75%Si e de fluxantes (3,83% cal dolomitica e 2,88% sílica), respectivamente. A redução das pelotas foi feita num forno de indução podendo atingir temperaturas de até 1973K (1700oC). Os ensaios experimentais foram realizados nas temperaturas de 1773K (1500°C), 1823K (1550oC) e 1873K (1600oC), utilizando-se cadinhos de grafite. Após os ensaios de redução os produtos obtidos (escória e metal) foram analisados por microscopia ótica, por microscopia eletrônica de varredura (MEV) e por análise de espectro de dispersão de energia (EDS). O processo de redução nas pelotas 1, 2, 3 e 4 segue os seguintes fenômenos i) via intermediários gasosos (CO/cromita) formam-se glóbulos metálicos nucleados na superfície das partículas de cromita, inicialmente rico em ferro; ii) estes crescem, pela redução na superfície da cromita deixando óxidos refratários na periferia da partícula de cromita original; iii) uma escoria incipiente se forma com os componentes da pelota (aglomerantes inorgânicos, cinza do redutor e fluxantes) e com a dissolução da ganga das partículas pequenas reduzidas da cromita; iv) a escória incipiente dissolve parte refratária da superfície da cromita, liberando a fase metálica e a escória vai se tornando cada vez mais refratária; v) o nódulo metálico segue crescendo e enriquecendo-se de cromo, reduzindo os óxidos de cromo e eventualmente de ferro dissolvido na escória incipiente; vi) o coalescimento da fase metálica é favorecido pela formação de escória e dissolução da ganga refrataria da cromita. O processo de redução da pelota 5 pela presença de fluxantes forma uma quantidade maior de escória inicial e apresenta os seguintes fenômenos: i) as reações indireta e direta reduzem as partículas finas de cromita, com formação de nódulos metálicos e fase escória nos primeiros instantes de redução; ii) os nódulos metálicos são formados pela redução das partículas finas de cromita. As partículas grandes sofrem pequena redução superficial e são encobertas pela escória, permanecendo dispersas na mesma; iii) a formação de escória encobrindo a cromita prejudica a redução gasosa aumentando o tempo de redução da mesma, porem facilita o coalescimento da fase metálica; iv) o nódulo metálico segue crescendo e enriquecendo-se de cromo, reduzindo aos poucos as partículas grandes de cromita. Existe regeneração do gás redutor (Boudouard) que pode ser diretamente com C do redutor ou com C dissolvido na fase metálica. A auto-redução carbotérmica das pelotas de cromita, na faixa de temperatura 1773K (1500oC) a 1873K (1600°C), sofre grande influência da temperatura, seja com ou sem adição de Fe-75%Si. O aumento da temperatura de 1773K (1500°C) para 1873K (1600°C) diminui o tempo para atingir redução completa conforme segue: i) 8 vezes para pelota sem Fe-75%Si; ii) 4 vezes para pelota com 1% de Fe-75%Si; e iii) 3 vezes para pelota com 2% de Fe-75%Si. Há um efeito significativo de adições de Fe-75%Si em pelotas auto-redutoras de cromita no tempo para atingir redução completa. O teor benéfico destas adições foi de 2%, contribuindo com aproximadamente 9% de calor necessário para redução completa, para as temperaturas ensaiadas de 1873K (1600ºC), 1823K (1550ºC) e 1773K (1500ºC). A evolução da redução é altamente sensível (diminui) com adição de fluxantes formadores de escória com temperatura líquidus abaixo de 1773K (1500ºC). A evolução da redução pela reação indireta (CO/cromita) é notavelmente mais rápida que a redução pela reação direta (C/cromita e C dissolvido na fase metálica/óxido de cromo na escória). A redução gasosa atuante nos primeiros estágios de redução, vai sendo prejudicada à medida que aumenta a quantidade de escória. As pelotas (1, 2, 3 e 4) sem adição de fluxantes (sílica e cal dolomítica), após reduzidas, são altamente porosas e têm pequena formação de fase escória se comparar com aquelas com adição de fluxantes com formação maior de fase escória (pelota 5). A pelota 3 com 2% de Fe-75%Si apresentou melhores resultados em relação ao tempo de redução. A pelota com adição de 4% Fe-75%Si (pelota 4), não apresentou diminuição do tempo de redução, devido a uma maior formação de escória que prejudica a reação indireta (mais rápida). As evidências micrográficas, auxiliadas por análises por EDS, mostraram que as reduções das partículas de cromita, foram praticamente completas quando as frações de reação se aproximam da unidade, confirmando a confiabilidade da metodologia utilizada. A redução da pelota auto-redutora, independente da sua composição, acontece de forma não isotérmica apesar de ser ensaiada numa temperatura isotérmica, apresentando-se um gradiente de temperatura entre a superfície e o centro da pelota, ao longo do tempo, mas esta desaparece conforme a reação progride tornando-se uniforme ao final da reação; evidenciando que a transferência de calor é a etapa lenta do processo devido: às reações de redução serem bastante endotérmicas; ao tamanho das pelotas; às altas temperaturas; e por ser um material poroso e refratário. A resistência a compressão das pelotas (1, 2, 3, 4 e 5) após 28 dias de cura e antes de serem reduzidas foi de ~4 kgf/pelota, porém tornou-se bastante alta após reduzidas (150 a 400 kgf/pelota); tornando-as aptas para carga em reatores de fusão. Estes resultados foram confirmados com ensaios no forno rotativo de laboratório, utilizando-se a pelota 2 (2% de Fe-75%Si), evidenciando: i) que as reduções de Cr e Fe foram praticamente completas (fração média de reação de 0,99) em 30 minutos de ensaio a 1500ºC; ii) a coalescência das partículas metálicas, obtidas por redução depende da capacidade da escória de dissolver os óxidos remanescentes na partícula de cromita reduzida; iii) há formação de fase incipiente de escória não-continua, aos 5 minutos de ensaio, pela parte da ganga do minério de cromita com os componentes de aglomerantes e/ou fluxantes; iv) a recuperação do teor metálico é alto (99%), em 30 minutos de ensaio, a 1500º C. Os resultados mostram um grande potencial do processo de auto-redução na produção de ferro-cromo alto carbono (FeCrAC).The evolution of reduction of the self-reducing pellets of chromite for obtaining ferro-chromium high carbon (FeCrHC) was analyzed. The influences of Fe-75%Si additions, addition of fluxing agents, temperature and time of reduction were studied. The materials (chromite, ferro-silicon, petroleum coke, dolomite lime, silica and cement Portland), were characterized by chemical and particle size analysis. After characterization, the materials were agglomerated in the form of pellets (P1, P2, P3 and P4), with additions of 0, 1, 2 and 4% Fe-75%Si, respectively, and P5 with additions of 2% Fe-75%Si and fluxing agents (3.83% dolomite lime and 2.88% silica). The reduction of pellets was made using induction furnace with capability to reach temperatures up to 1973K (1700ºC). The experiments were performed at temperatures of 1773K (1500ºC), 1823K (1550ºC) and 1873K (1600ºC), using graphite crucibles. After the reduction the products (slag and metal) were analyzed by optical microscopy, scanning electronic microscopy (MEV) and energy dispersion spectrum analysis (EDS). The reduction process in pellets 1, 2, 3 and 4 followed phenomena as: i) gaseous reduction (CO/chromite) produces metallic globules on the surface of chromite particles, initially rich in iron; ii) these globules grow continuing the reduction at the periphery of chromite particles, leaving refractory oxides at this area of the original chromite particle; iii) an incipient slag is formed with the components of the pellet (inorganic binders, ash of reducer and fluxing agents) and with the dissolution of gangue from small particles of the reduced chromite; iv) the incipient slag dissolves refractory oxides remaining at the periphery of the chromite particles, liberating the metallic phase and the slag becomes more refractory; v) the metallic phase grows and becomes richer in chromium by reducing chromium oxides and eventually of iron dissolved in the incipient slag; vi) the coalescence of the metallic phase is favored by the slag formation and dissolution of refractory gangue of the chromite. The reduction process of pellet 5 follows as: i) indirect and direct reactions reduce fine particles of chromite, with formation of metallic nodules and slag phase at the beginning of reduction; ii) the metallic nodules are formed by the reduction of fine particles of chromite. Large chromite particles are reduced at the peripherical surfaces and are embebeded by the slag and remain dispersed in it; iii) the slag formed is harmful for the gaseous reduction and the time for completing the reduction is increased, but facilitates the coalescence of the metallic phase; iv) the metallic nodule follows growing and becomes richer in chromium. The carbothermic self-reduction pellets of the chromite at the temperature range of 1773K (1500ºC)-1873K (1600ºC), presents great influence of the temperature, either, with or without addition of Fe-75%Si. The increase of the temperature from 1773K (1500ºC) to 1873K (1600ºC) decreases the time for completing the reduction as: i) 8 times for pellet without Fe-75%Si; ii) 4 times for pellet with 1% of Fe-75%Si; and iii) 3 times for pellet with 2% of Fe-75%Si. A significant effect of additions of Fe-75%Si in self-reducing pellets of chromite in the reduction time was observed. The best addition was with 2% and its contribution was approximately 9% of necessary heat for complete the reduction, for the temperatures of 1873K (1600ºC), 1823K (1550ºC) and 1773K (1500ºC). The evolution of reduction is highly sensitive (it decreases) with addition of fluxing agents which form the slag with liquidus temperature below 1500ºC. The evolution of reduction for the indirect reaction (CO/chromites) is remarkably faster than that of the reduction by the direct reaction (C/chromite and C dissolved in the metallic phase/chromium oxide in the slag). At the beginning the gaseous reduction is predominant but it becomes less important with formation of larger amount of slag. The pellets (1, 2, 3 and 4) without addition of fluxing agents (silica and dolomite lime), after reduced, are highly porous and have small formation of slag phase than pellet 5 with addition of fluxing agents. Pellet 3 with 2% of Fe-75%Si presented the best results with relation to time for completing the reduction of chromite. The pellet with addition of 4% Fe-75%Si (pellet 4) did not present advantage with relation to that of 2% addition due to larger volume of slag formation. The micrograph analysis showed that the reductions of chromite particles practically were complete when the reaction fractions approach to the unit, confirming the confidence of the methodology used for determining the reaction fraction. The reduction of the self-reducing pellet, regardless its composition, happens by not isothermal way although it is submitted at isothermal temperature. The temperature gradient between surface and the core of the pellet is larger at the beginning but it disappears as the reaction progresses, becoming uniform with time. The heat transfer showed to be the slowest step of the process due to, the endothermic reactions of reduction, the size of the pellets, the high temperatures and porous nature and refractory material. The compression strength of the pellets (1, 2, 3, 4 and 5), after 28 days of curing, before of the reduction was ~4kgf/pellet but it increased up to 150 - 400 kgf/pellet; which are acceptable for charging the melting furnace for metal/slag separation. These results were confirmed by using laboratory rotating furnace, with pellet 2 (2% of Fe-75%Si), as: i) the reductions of Cr and Fe were practically complete (fraction of reaction 0,99) after 30 minutes of experiment at 1500ºC; ii) the coalescence of metallic particles, depends the capability of the slag to dissolve remaining oxides in the reduced chromite particle; iii) incipient not-continuous slag phase forms, at 5 minutes of experiment, from the gangue of the chromite and from the components of binders and/or fluxing agents; iv) the yield of metallic recovery is high (99%), after 30 minutes of experiment at1500º C. The results show that the self-reduction process presents a great potential for the ferro-chromium high carbon production (FeCrHC)

High Carbon Ferro-Chromium by Self-Reducing Process

This paper discusses the effects of temperature, addition of ferro-silicon and fluxing agents for the production of high carbon ferro-chromium by self-reducing process. The use of self-reducing agglomerates for ferro-alloys production is becoming an emerging processing technology due to lowering the electric energy consumption and improving the metal recovery in comparison with traditional ones. The self-reducing pellets were composed by chromite, petroleum coke, cement and small (0.1% - 2%) addition of ferro-silicon. The slag composition was adjusted by addition of fluxing agents. The reduction of pellets was carried out at 1773K (1500 degrees C), 1823K (1550 degrees C) and 1873K (1600 degrees C) by using induction furnace. The products obtained, containing slag and metallic phases, were analyzed by scanning electron microscopy and chemical analyses (XEDS). By increasing temperature from 1773K to 1823K large effect on the reduction time was observed. It decreased from 30 minutes to 10 minutes, for reaching around 0.98 reduction fraction. No significant effect on reduction time was observed when the reduction temperature was increased from 1823K to 1873K. At 1773K, the addition of 2% of ferro-silicon in the pellet resulted in an increasing reaction rate of around 6 times, in comparison with agglomerate without this addition. The addition of fluxing agents (silica and hydrated lime) has effect on reduction time (inverse relationship) and the pellets become less porous after reduction

High carbon ferro-chromium by self-reducing process: Fundamentals

Fe-Cr-C production is a very high electrical energy consuming process. When self-reducing agglomerates are used,it is expected to reduce up to 10% of this electrical energy. This paper presents the fundamental aspects of the reactions involved for reduction of chromites from self-reducing agglomerates. Brazilian chromite containing 41.2%Cr2O3 was mixed with petroleum coke and agglomerated with cement as the binder. The concept of “initial slag” was introduced and it was assumed that this “initial slag” is formed by fluxing agents, coke ash, silica, binder and only dissolution of 5% of the gangue from the chromite. This concept is important since the gangue of chromite is composed mainly of refractory oxides (MgO+Al2O3), which are difficult to dissolve into slag. The effects of “initial slag” composition, one with low liquidus temperature(~1700K) and other with high liquidus temperature (~1750K) were investigated. The mixture was pelletized, dried and submitted to a temperature of 1773K until completion of the reaction. The reaction fraction as a function of time was determined. The results show that pellets containing components with liquid slag phase formed at higher temperature presented significant better reduction behavior than pellet with the liquid slag phase formed at lower temperature. The scanning electron microscopy analysis showed that a liquid phase was formed but the pellet did not collapse and indicated that thecoalescence of the metallic phase depends on the dissolution of the pre-reduced particles of the chromite into slag

The self-reducing pellet production from organic household waste

The organic household waste has a growing disposal problem, requiring costly disposal systems. It is necessary to find new applications for these materials; one could be the steelmaking raw material production. In this paper is studied the development of self-reducing pellets from the organic waste pyrolysis, where is generated carbon and condensable and non-condensable volatiles. Non-condensable volatiles were burned and condensable volatiles were recovered. The resulting tar was mixed with iron ore, coal powder and flux (CaO), to then be pelletized together. Compression, falls and tumbler tests were conducted to characterize the pellets before and after heat treatment and reduction processes. The reduction curve and their physical and morphological characterization were measured. The results were as was expected, the fluidized coal create sufficient adhesion that pellets earned resistance with an equivalent resistance of common pellets, showing a good feasibility of this process

Effect of SiO2 on the compressive strength and hot resistance abrasion of self reducing pellets bonded with Portland cement

A pelotização é o método de aglomeração de minério que oferece o melhor custo benefício. No processo, é necessária a adição de um aglomerante para conseguir as propriedades desejadas. Entre estes, ocimento é um dos destaques pela facilidade e custo. A adição de pozolânicos no concreto na construção civil para o aumento da resistência é de longa data. Neste trabalho, se estuda o efeito da adição de 1% de SiO2 ou bentonita na mistura das pelotas autorredutoras. Realizam-se ensaios de compressão a frio, compressão após tratamento térmico 950°C, teste e abrasão a quente, teste de quedas, além de difração de raios-X. Como resultados obteve-se um incremento da resistência a compressão a frio e a abrasão a quente com a resistência a compressão após tratamento térmico a 950°C.FAPESPVAL

High Carbon Ferro-chromium Production by Self-reducing Process: Effects of Fe-Si and Fluxing Agent Additions

The technology of self-reducing pellets for ferro-alloys production is becoming an emerging process due to the lower electric energy consumption and the improvement of metal recovery in comparison with the traditional process. This paper presents the effects of reduction temperature, addition of ferro-silicon and addition of slag forming agents for the production of high carbon ferro-chromium by utilization of self-reducing pellets. These pellets were composed of Brazilian chromium ore (chromite) concentrate, petroleum coke, Portland cement, ferro-silicon and slag forming components (silica and hydrated lime). The pellets were processed at 1 773 K, 1 823 K and 1 873 K using an induction furnace. The products obtained, containing slag and metallic phases, were analyzed by scanning electron microscopy and chemical analyses (XEDS). A large effect on the reduction time was observed by increasing the temperature from 1 773 K to 1 823 K for pellets without Fe-Si addition: around 4 times faster at 1 823 K than at 1 773 K for reaction fraction close to one. However, when the temperature was further increased from 1 823 K to 1 873 K the kinetics improved by double. At 1 773 K, the addition of 2% of ferro-silicon in the pellet resulted in an increasing reaction rate of around 6 times, in comparison with agglomerate without it. The addition of fluxing agents (silica and lime), which form initial slag before the reduction is completed, impaired the full reduction. These pellets became less porous after the reduction process.FAPESP (Sao Paulo State Foundation for Research Support)CNPq (Brazilian Council for Research and Technological Development