RU1803427C - Method and device for charging blast furnace - Google Patents

Abstract

SUMMARY OF THE INVENTION: a method of loading a charge comprises distributing it in at least six equal sectors of the circumference of the blast furnace, wherein the charge is distributed when it is poured into the receiving funnel by alternately deviating the charge flow towards the skip, opposite to the skip and in the intermediate direction x, the charge stream after deflection is divided into at least two streams. Two plates 4 are mounted in the upper part of the receiving funnel 1 with the possibility of rotation around a horizontal axis. Dividers are mounted on the surface of the plates, with dividers installed in the upper part of the plates along the longitudinal axis and at the bottom at an angle to it, while they intersect on the longitudinal axis of the plate. 2 s.p. f-ly. 3 s.p. f-ly, 3 ill. ate

Description

The invention relates to ferrous metallurgy and is used in loading blast furnaces equipped with a charge distributor.

An object of the invention is to reduce coke consumption and increase furnace productivity.

In FIG. 1 is a perspective view of a device for loading a charge into a blast furnace; in FIG. 2 - plate surface; in FIG. Za-Zg is the arrangement of ridges and slopes at various positions of the slabs and after a complete loading cycle consisting of three feeds.

Successive tapering and expansion of the charge stream are known to result in equalization of the circumferential distribution. The more such constrictions and extensions along the flow path, the more uniform the qualitative and quantitative circumferential distribution. In a typical blast furnace loading method, the formation of the circumferential distribution is carried out on a small cone. Moreover, the charge is distributed unevenly on the small cone. After it is lowered, the flow of materials undergoes only one narrowing-expansion, when moving from a bowl of a small cone, the cross-section of the flow decreases, and then when it is poured onto a large cone and at the top, it increases.

After the charge is distributed due to flow deviation in the receiving funnel, the material undergoes two narrowing-expansion: when pouring from the receiving funnel to a small cone and when pouring from a small cone to a large one. Thus, the proposed method allows for a more uniform circumferential distribution.

A device for loading a charge into a blast furnace consists of a housing with protective plates 1 with an outlet 2. Two plates 4 are installed on the suspension axis 3, facing their surface to the tipping skip 5. The plates can occupy limiting positions with an inclination towards the skips I, to the side opposite to skips II and intermediate positions III. The plates are driven by rack pushers (hydraulic actuators) 6. Dividers are mounted on the surface of the plates. In the upper part of the plate dividers 7 are installed along its longitudinal axis, in the lower part of the divider 8 are installed at an angle to the longitudinal axis.

It is advisable to consider the implementation of the method of loading the charge into the blast furnace using the described device using an example when the charge is distributed over six equally circular sectors. This case corresponds to three positions of the plates in the declared receiving funnel: two extreme and one intermediate. During one loading cycle from three feeds, plates 4 alternately occupy each of the three positions once. If conditionally taken as the beginning of the next

cycle in the continuous process of loading the charge from the right skip 5 when the right plate is tilted towards the skip, and the suspension axis of the plates is considered to coincide with the longitudinal axis of the funnel (other positions are possible), the claimed method is implemented using the declared receiving funnel as follows. The right plate 4, turn towards the skip to the limit position I, the left to the opposite

5 side II. The right skip overturns and the mixture is poured onto the plate 4. As a result, the flow is deflected into the sector corresponding to the station (angle of rotation of the rotary vertical axis) 30 °. In this sector, quantitative

0 and quality comb. When the mixture moves along the surface of the slabs, the flow is divided into two parts due to the divider 7 and 8. This somewhat stretches the forming crest and reduces the circumferential

5 uneven distribution of the charge. After that, the left skip 5 approaches the receiving funnel. Since the left plate is deflected in direction II, opposite the skip, the charge will be poured into the sector corresponding to the station 210 °. Similarly load the mixture from the third and fourth skips of the first feed of the cycle. Since the ridges (qualitative and quantitative, since they coincide) formed during the sintering of the charge from the right skip correspond to slopes of the charge from the left skip, after a single feed, a relatively uniform circumferential distribution of the charge is achieved. After the first filing arrangement

0 plates 4 varies. Both of them occupy an intermediate position III. In the adopted embodiment, this feed position is completely repeated. The ridges and slopes with this arrangement of plates are loaded into sectors,

5 corresponding stations 90 and 270 ° (Fig. 36). After this, the slabs move to the extreme positions: the right tilts from the skip (position II), left to the skip (position I). In this case, the charge flows are deflected so

0 in such a way that the crests of the slope occupy positions of 150 and 330 ° (Fig. Sv). As a result of the entire loading cycle of three feeds, a uniform circumferential distribution is formed (Fig. 3g). The number of stations may be

5 is greater than 6. For example, 8. In this case, the complete feed cycle is 4, and along with the two extremes there are two intermediate positions. The number of feeds in the cycle is generally equal to n / 2, where n is the number of stations (sectors), the number of intermediate positions of the plate is 2 - 2. In the intermediate positions at 8 stations, the plates will also be inclined towards the skip, or in the opposite direction. At eight stations, ridges will be located in sectors 22.5; 67.5; 112.5; 157.5; 203.5; 248.5; 293.5; 338.5 degrees. This mode of operation is ensured if sin a / sin p 2,685, where a and / 3 are the angles of inclination of the plates relative to the vertical in the limiting and intermediate positions. If the maximum angle of rotation of the plate relative to the vertical is 37 °, (53 ° relative to the horizontal), then in the intermediate position this angle will be 13 °. Changing the accepted number of stations and the axis of suspension of the plate leads to a change in the angles of rotation of the plates in the pro; intermediate position.

Claims (5)

SUMMARY OF THE INVENTION 1. A method of loading a charge into a blast furnace, comprising pouring the mixture from the skip into a receiving funnel and distributing it in at least six equally-sized sectors of the circumference of the blast furnace, characterized in that, in order to reduce coke consumption and increase furnace productivity, the flow the charges, when poured into the receiving funnel, are alternately deflected towards the skip, to the opposite side from the skip and to intermediate positions between them. 2. The method according to claim 1, characterized in that the charge stream after deflection is divided by at least two. 3. A device for loading a charge into a blast furnace, including a skip and a receiving funnel with an outlet located below it, characterized in that the device is equipped with two plates mounted in the upper part of the receiving funnel with a possibility of rotation about a horizontal axis. 4. The device according to claim 3, with the exception that it is equipped with dividers mounted on the surface of the plates. 5. The device according to claim 4, the clause is that in the upper part of the plates the dividers are installed along its longitudinal axis, and in the lower part at an angle whose apex lies on the longitudinal axis. g / e $ eme ffeSetocfttsno, by afloooto ctrwa zЈ f {fctf & nfyy & jto schip & L7X0C txe / ncr