RU2114922C1 - Method of producing pellets - Google Patents

Abstract

FIELD: ferrous metallurgy. SUBSTANCE: invention aims at increasing strength of pellets produced from iron-ore concentrates and fired at 1150-1375 C. Method consists in fabricating crude pellets in tray or drum pelletizing apparatuses from a charge composed of titanium- magnetite concentrate, binding or alloying additives; drying pellets; oxidizing them to 85-90%; firing with partial dissociation of hematite at 1150-1375 C; and cooling. Content of calcium, silicon, magnesium, and titanium oxides in finished product is controlled from CaO/SiO₂ ratio in dependence on content of TiO₂ and MgO using following equation: Cao/SiO₂=(1.2-1.3)-(0.20- 0.25)(MgO+TiO₂-1.0) where (1.2-1.3) is CaO/SiO₂ ratio when summary MgO and TiO₂ content is equal to 1 wt %. EFFECT: improved strength of product.

Description

 The invention relates to mining metallurgy, and more particularly to the production of pellets from iron ore concentrates.

A known method for producing pellets, including the preparation of raw pellets from magnetite iron ores with flux, their calcination in an oxidizing atmosphere at a temperature sufficient to oxidize Fe ₃ O ₄ to Fe ₂ O ₃ , but not exceeding the melting temperature of the charge (1205 ^o C) (patent U.S. N 3235372 NKI 75-5, 1971). The pellets are kept at these temperatures until almost complete oxidation, and then fired at a temperature of 1205-1345 ^o With, sufficient for local formation of the liquid phase, but without the formation of a melt on the surface. The disadvantage of this method is the low strength of the pellets, especially during recovery, due to the fact that when receiving pellets from concentrates containing refractory magnesium and titanium oxides in the waste rock, the amount of liquid phase formed during firing in the range of 1205 - 1345 ^o C is not enough Resist the destructive conditions surrounding the recovery process.

The closest in technological essence is the method of producing oxidized pellets, which consists in the fact that the pellets are fired in two stages: low temperature, where the firing temperature does not exceed the melting temperature of the melt and almost complete (85-90%) oxidation of Fe ₃ O ₄ to Fe ₂ O ₃ ; high temperature, where the firing temperature rises to 1300-1375 ^o C and is equal to or higher than the dissociation temperature of hematite to magnetite in the pellets (ed. certificate N 670626, class C 22 V 1/20, 1979). High-temperature firing lasts until the degree of dissociation of hematite is at least 20%. The reverse transition of hematite during dissociation is not zonal, and the new phase (Fe ₃ O ₄ ) is allocated at the contact with local melt formations uniformly over the entire cross section of the pellet. Magnetite, dissolving in a silicate melt, increases the content of ferrous iron in it, which, in contrast to ferric iron, lowers the melting point and promotes vitrification of slag inclusions when cooling pellets. Ore grains of such pellets are blocked from low-temperature contact with reducing gases in the upper horizons of the blast furnace, where they are actively destroyed (500-600 ^o C).

Vitreous slag inclusions and ore grains surrounded by them are restored in the temperature range of 700-900 ^o C, while softening. The resulting stresses relax and do not cause destruction of the granules.

The disadvantage of this method is the low strength of the pellets in the temperature range 1150-1375 ^o C. This need is justified by the practice of modern conveyor machines for layer-by-layer firing of pellets, since it is known that the upper limit of the firing temperature does not exceed 1375 ^o C and is determined by the fusion of the pellets, and the lower does not exceed 1150 ^o C and is determined by the optimal performance of the units and the resistance of grates.

The objective of the invention is to increase the strength of the pellets fired in the temperature range 1150-1375 ^o C.

The technological task is achieved in that in the known method for the production of pellets, including the production of raw pellets in a disk or drum pelletizer from a charge - from iron ore concentrate, binders or fluxing additives, drying the pellets, their oxidation to 85-90%, roasting with partial dissociation of hematite , cooling, monitoring the content of calcium, silicon, magnesium and titanium oxides in the finished pellets, titanomagnetite concentrate is used as iron ore concentrate. The pellets are fired at a temperature of 1150-1375 ^o C, while the content of calcium, silicon, magnesium and titanium oxides is controlled from the ratio of calcium and silicon oxides (CaO / SiO ₂ ) depending on the content of titanium oxides (TiO ₂ ) and magnesium (MgO ) according to the following relationship:
CaO / SiO ₂ = (1.2-1.3) - (0.20-0.25) • (MgO + TiO ₂ - 1.0), (1)
where CaO, SiO ₂ , MgO and TiO ₂ - oxide content, wt.%.

With small amounts of refractory oxides MgO and TiO ₂ (<1%), the amount of melt formed in the pellets at 1150-1375 ^o C is determined by low-melting calcium selicoferrites and when CaO / SiO ₂ basicity = 1.2 - 1.3, the melt is sufficient for hardening pellets. With the growth in pellets of refractory oxides MgO and TiO ₂ introduced into the concentrate, which are part of calcium ferrites, their melting point rises. As a result, in the temperature range 1150-1375 ^o C, the amount of slag melt is reduced, and non-slag ore grains can directly contact with reducing gases in the upper horizons of blast furnaces. Early solid-phase recovery of hematite (at 500-600 ^o C) leads to dilution and destruction of the pellets. To eliminate this phenomenon, it is necessary to reduce the addition of calcium oxides so that the total basicity of gangue in the ratio (CaO + Mg + TiO ₂ ) / SiO ₂ does not increase.

Acidic melts have a wide range of viscous-plastic state in the range of 1150-1375 ^o С. The resulting slag surrounds ore grains, solidifying in the form of iron-calcium-titanium-silicate glasses. They are restored and at the same time softened at 700-900 ^o C in the upper horizons of the blast furnace. The stresses arising from the swelling of ore grains during the transition of hematite to magnetite relax in the softening structure of the pellet, and its destruction does not occur.

The method is as follows:
In the concentrate for pelletizing is determined by chemical analysis of the content of oxides of Mg, Ti, Ca and Si. Based on the required amount and composition of binders and fluxing (limestone) additives, they calculate the composition of the mixture according to the standard equations of material balance and relation (1).

Pellets of a predetermined composition are obtained in belt or drum granulators and laid in a layer 300 to 500 mm high on a conveyor roasting machine. For each of the composition of the charge is determined in the range of 1150-1375 ^o With the temperature of the upper and lower layers, eliminating the fusion of the upper pellets and ensuring the achievement of the design capacity of the machines. The content of Ca, Mg, Si, and Ti oxides in the calcined pellets is controlled and corrected in accordance with relation (1) by changing the content or elimination of flux (limestone) from the mixture.

 The method was tested in an industrial environment Kachkanarsky GOK. Pellets were obtained from titanomagnetite concentrate with the addition of Kanepereysky bentonite in plate granulators with a diameter of 7.5 m. The firing was carried out on an OK-228 conveyor firing machine in a layer with a height of 420 mm. The processing mode is presented in table. 1, and the test results are in table. 2. The tests showed that maintaining the basicity within the claimed limits when the content of oxides of Mg and Ti at the level of 2.5-2.7% allows to increase the strength of the pellets both in the initial state and during recovery. Pellets with increased (experiments 1, 2) and reduced basicity (experiment 6) that go beyond the claimed limits have low strength, especially during recovery.

Claims (1)

A method for the production of pellets, including pelletizing in a dish or drum pelletizer, a mixture consisting of iron ore concentrate, binders or fluxing additives, drying the pellets, oxidizing them to 85 - 90%, roasting with dissociation of hematite and cooling, characterized in that they are used as iron ore concentrate titanomagnetite concentrate, and in the finished pellets, the content of calcium, silicon, magnesium and titanium oxides is determined and the ratio of the content of calcium and silicon oxides is controlled depending on the content of magnesium and titanium oxides according to the following relationship:
CaO / SiO ₂ = (1.2 - 1.3) - (0.20 - 0.25) (MgO + TiO ₂ - 1.0),
where (1.2 - 1.3) is the value of the ratio CaO / SiO ₂ with the content of MgO + TiO ₂ = 1 wt.%.

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