SU1424965A1 - Method of starting the pouring of steel from ladle without stopper - Google Patents

Abstract

The invention relates to metallurgy, in particular to the casting of steel from a stopless ladle. The aim of the invention is to increase the productivity of the casting unit, increasing the yield of ingots. The method consists in filling the channels of the dosing cups, before filling the ladle with liquid metal, by spherical granules with a diameter of 0.05-0.1 of the diameter of the canal with a content of 98.5-99.6% carbon. Granules have a bulk bulk density of 0.8-1.0 g / cm and have a hardness of 4-5 units on the Mohs scale. This makes it possible to ensure that the filling of the dispensing channels is completely empty, to stabilize the stream of metal flowing out of the ladle. 1 hp f-ly, 2 tab. i (i

Description

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WITH

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01

FIELD OF THE INVENTION The invention relates to ferrous metallurgy, in particular to the casting of steel from unstoppable ladles.

The aim of the invention is to increase the productivity of the casting aggregate, to increase the yield of annual ingots due to the stabilization of the metal jet and to ensure the complete emptying of the filling from the metering cups.

The method is as follows.

Before casting, the outlet opening of the metering cup of the slide gate in the casting ladle and the outlet ports of the metering cup of the unstoppable tundish are closed.

Next, metering cups are filled with spherical heat-resistant granules with a diameter of 0.05-0.1 of the diameter of the outlet of the metering cups.

Granules contain .98.5-99.6% carbon, have a bulk bulk density of 0.8-1.0 g / cm and have a hardness of 4-5 units on the Mohs scale.

Next, the steel-teeming ladle is filled with liquid metal to a predetermined level and the outlet opening of the metering cup is opened, ensuring the pouring of the backfill and the release of metal into the tundish, which is heated before filling the metal.

After the tundish has been filled to the specified level, the outlet openings of the metering cups are opened and the granules are poured onto the chute and the metal is released into the crystallizer.

As a concrete example, casting of steel grade Art. 3 of the 100-ton steel-teeming ladle, equipped with a slide gate with a 40 mm dosing cup through a non-stop tundish, equipped with 6 15-meter dosing cups, into molds with a section 125x125 mm. Metal spill

The method of "smelting to smelting with a working speed of drawing blanks of 1.9-2.1 m / min.

Before starting the casting, the metering cup of the slide gate in the casting ladle is filled with spherical granules with a diameter of 3-4 mm, containing 99.0% of carbon, having a hardness of 5 units by the scale of Mohs and a bulk bulk density of 1.0 g / cm. Before filling the tundish with metal, the dosing cups are capped with asbestos plugs from the bottom, and they are filled with spherical granules with a diameter of 0.75-1.5 mm, containing 99.0% of carbon, having a hardness of 5 units by the Mohs scale and a bulk bulk mass of 1.0 g /cm. Prior to casting, the tundish is heated by gas burners to a lining surface temperature of 1200 ° C. The intermediate ladle heated to 1200 ° C is filled with liquid metal up to 250 m.m. The duration of the filling out of the dispensing cup is steelworking after opening the spherical closure 9 s, which allows replacing the steelblasting (re-scraping) during the casting of melts by the method “melting to melting”.

After filling the metal with a metal to a predetermined level, remove the plug from the dispenser glass and pour it back into the groove for 13 seconds. After pouring out the filling, the metal is delivered by a well-organized stream into the mold. At the same time 100 ° / oy launch of each stream is provided. In the process of spraying the spherical granules no dust is observed.

In the process of conducting research when casting steel of grade 3 into billets with a section of 125x125 mm, backfilling in the form of olar-shaped granules of different diameters with different physical properties and different chemical composition was tested.

The results of the tests are given in Table. 1 and 2.

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1,50,1099

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1,50,1099

Table 1

0.6 0.7 0.8

60 70 100

The spherical shape of the granules with a diameter of 0.05-0.1 outlet of the metering cup, as shown by the results of the experiment, provides a complete and rapid ejection of the filling. This, in turn, 5 makes it possible to form a well-formed metal jet, to start casting on i all 6 strands and not to interrupt the seriality when casting using the "melting to melt" method. I It was established experimentally that granules Q} of spherical shape with a size of less than 0.05 hours — 1 in diameter of the outlet orifice — do not completely empty, and precipitation occurs.,. relatively slowly. The raining of jgij | l i granules with a size of more than 0.1 of the diameter of the outlet hole does not fully occur. This 15 4 does not allow to form a well-formed metal stream, entering it into a crystal: and to ensure a normal start: on a 6-stream x.

With a carbon content of 98.5-99.6% in 20

: backfilling it does not bake when heated to 1200 ° C (when the tundish is heated) and when it comes into contact with the liquid metal. With a carbon content of less than 98.5%, the probability of sintering the backfill increases dramatically. There are cases when 25 have to resort to burning the dosage glasses with oxygen, which causes the indicated disturbances in the stability of the start of casting. With a carbon content of more than 99.6% of the granules, no positive effect is observed, and sushi, the cost of backfilling significantly increases.

Experimentally established; that spherical granules with a bulk density of 0.8-1.0 g / cm possess the necessary flowability and ejection rate from the dosing cup, which allows immediately after spontaneous ejection of the filling to form a full metal stream. Application of granules with bulk bulk

a mass of less than 0.8 g / cm is accompanied by an unacceptable increase in the duration of the filling out of the filling, which leads to the sinking of the metal in the glass and the violation of the stability of the outflow of the metal entering the crystallizer. Granules with bulk

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bulk density of more than 1.0 g / cm, without improving the achieved positive effect, significantly increase the cost of their manufacture.

Spherical granules with a hardness of 4-5 units on the Mohs scale are not destroyed during transportation, mechanical agitation and calcination, therefore, do not pollute the atmosphere of the workplace of the casting workers. With a lower hardness, the granules are destroyed, their precipitation is accompanied by the release of dust, and in some cases, by clogging of the dosing cups. At higher hardness, a positive effect does not increase, but the cost of the granules increases dramatically.

The proposed method makes it possible to ensure the complete precipitation of the filling from dosing glasses, to continue the mass production of melts during casting using the melting to melt method, to stabilize the metal stream flowing from the ladle, to increase the yield of blanks and to increase the productivity of the unit.

Claims (2)

1. A method for starting steel casting from a stopless ladle, including closing off the outlet openings of the metering cups, filling them with carbon-containing heat-resistant material, filling the ladle with liquid metal and then opening the outlet openings, ensuring the pouring out of the backfill and releasing the metal, characterized in that, in order to improve the performance of the casting the aggregate, increasing the yield of ingots, filling up the dosing cups, is produced by spherical granules with a diameter of 0.05-0.1 of the diameter of the outlet opening of the dosing glasses with a content of 98.5-99.6% carbon, while the granules have a bulk bulk density of 0.8-1.0 g / cm. 2. A method according to claim 1, characterized in that, in order to reduce dust emission, the hardness of the granules is 4-5 units on the Mohs scale.