SU1671701A1 - Method of blast furnace operation - Google Patents

Abstract

This invention relates to ferrous metallurgy, in particular, to a method of blast furnace smelting. The aim of the invention is to increase the productivity of a blast furnace and reduce coke consumption. The portions of iron ore materials and coke are formed, consisting of a coke dose and a dose of iron ore materials on the main conveyor, fed into the intermediate hopper of the infinite charging device, loaded into the furnace using a trough distributor and control the parameters of the blowing and gas composition along the radius of the upper part of the furnace. When forming a portion, the ore dose is placed behind the coke dose layer along the main conveyor. The increase in productivity and reduction in coke consumption is achieved by accelerating the period required to achieve an optimal distribution of charge materials and gas flow in the axial zone of the furnace, as compared with the known methods of such control.

Description

This invention relates to ferrous metallurgy, in particular, to a method of blast furnace smelting.

The aim of the invention is to increase the productivity of a blast furnace and reduce coke consumption by accelerating the process of optimizing the distribution of materials and gas flow across the furnace section.

Form portions of iron ore materials and coke, consisting of a dose of coke and a dose of iron ore materials on the main conveyor, feed them into the intermediate hopper of the infinite charging device, load into the furnace using a trough distributor, regulate the ore load across the furnace section, control the parameters of the blowing and gas composition along the radius of the upper part of the mine.

When forming a portion, the ore dose is placed behind the coke dose layer along the main conveyor. The table shows the optimal distribution of the ratio of gasified oxygen (Osh). and carbon (CC) charge and estimated ore loads along the radius of the upper part of the mine and the approximate COi distribution corresponding to these relations, obtained by statistical processing of the kilns of the furnace operation over a long period.

Maintaining an optimal distribution of materials in the axial zone is an important factor in determining the normal course.

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the furnace and its high performance, however, the use of well-known methods for adjusting it: loading iron ore materials directly into the axial zone at small angular positions of the tray, loading before feeding the ore portion of the coke batch at large angular positions of the tray (rolling effect) often leads to the center overload by ore, liquidation 1, the consequences of which take a long period (up to 3 months) with loss of production and coke overrun.

The proposed method allows you to quickly (within a few days) and precisely adjust the desired mode, since, by changing the mass of the ore fed together with coke from 0 to 100% of the mass of the coke dose, it is possible to achieve any degree of development of the central gas flow.

PRI me R. On a blast furnace with a volume of 5580 m3, which has a infinite charging device with a tray-type charge distributor, the charge loading regime is changed with a regular control of the gas composition along the four radii of the upper part of the mine to contain carbon dioxide, carbon monoxide and hydrogen. Before the change, the charge has the following composition, t: coke 28.0; sinter 68; pellets 32; iron ore 10. Before the change, the cyclic charge loading system consists of seven feeds, including coke (K) and iron ore (P) portions, loaded at different angular positions of the rotating tray: 1- K (8-4), P (8-4 ); 2- K (9-5), P (9-4); 3- K (5-1), P (9-4); 4- К (8-4), р (9-5-; 5- К (8-5), Р (9-5); 6- К (9-5), Р (8-5); 7- K (6-2). P (9-4).

The positions of the tray correspond to the following corners of the working surface of the tray relative to the axis of the furnace, degrees: 1st 8,1; 2nd 16.8; 3rd 24.7; 4th 29.1; 5th 32.0; 6th 34.7; 7th 37.7; 3rd 39.8; 9th 42.2; 10th 43.8; 11th 45.2.

After the change, the charge consists of, t: coke 27.5; sinter 68, pellets 30, iron ore 12.

After the change, the cyclic charge loading system consists of seven innings, which include coke (K), coke with ore (K + D) and iron ore (P) portions: 1- K (8-4), P (8-4); 2- K (9-5), P (9-4); 3- K + D (5-1), P (9-4); 4- K (8-4), P (9-5); 5- K (8-5), P (9-5); 6- K (9-5), P (8-5): 7- K + D (6-2), P (9-4).

After changing in the 3rd and 7th feeds of the cycle, ore weighing 12 tons is fed by a layer of coke along the main conveyor during the formation of a portion of the cake.

Coke and ore are combined in the 3rd and 7th feeds with a multiring (K + D (5-1) and UD (6-2)) mode of operation of the rotating tray so that at the beginning of the batch loading into the coke oven It is located in the intermediate zone of the top furnace, and at the end of the loading the ore is located in the central part of the top furnace.

As a result of the changes made in the charge loading mode, the materials and gas flow are redistributed over the furnace cross section.

The calculated ore load at the furnace axis increases from 1.16 to 2.1, and at a distance of 1.7 m from the furnace axis, the calculated ore load also increases from 2.6 to 2.9.

The use of the invention allows to accelerate the process of optimizing the distribution of materials and gas flow, since when it is reached the loading system does not change or change slightly, and by accelerating the optimization process and more accurately controlling the ore load in the axial zone of the furnace, reduce the specific fuel consumption and increase blast furnace productivity.

The advantages of the proposed method are especially significant when it is used to manage large-volume blast furnaces, where optimal ore loading in the central zone is especially required, since overloading the axial zone with iron ore materials can lead to hardening of the central part of the hearth and the furnace to fail.

Claims (1)

Invention Formula The method of blast furnace smelting, including the formation of portions of iron ore materials and coke, consisting of a dose of coke and a dose of iron ore materials on the main conveyor, feeding them into the intermediate hopper of the coneless loading device and using a chute distributor to the furnace, controlling the ore load across the furnace section, controlling parameters and gas composition along the radius of the upper part of the shaft, characterized in that, in order to increase the furnace productivity and reduce coke consumption by accelerating the optimization process distribution of materials and gas flow over the furnace cross section; when forming a portion of coke, a dose of ore is placed behind the coke dose layer in the course of the main conveyor movement.