RU98158U1 - INTERMEDIATE BUCKET FOR CONTINUOUS METAL CASTING - Google Patents

Abstract

 1. An intermediate ladle for continuous casting of metal, including a lined casing with a receiving and casting chambers separated by partitions, each of which has upper and lower channels, characterized in that the distance between the opposite surfaces of the walls of the receiving chamber is 1.3-1.8 nominal level of liquid metal. ! 2. The intermediate bucket according to claim 1, characterized in that the ratio of the areas of the upper to the lower channel of each dividing wall is 1: 0.94-0.98. ! 3. The intermediate bucket according to claim 1, characterized in that the lower channels are made with a slope of 25-45 ° in the direction of the receiving chamber.

Description

The proposed utility model relates to ferrous metallurgy, namely, to steelmaking, in particular, to the construction of intermediate ladles and can be used for continuous casting of steel at UNRS.

Known intermediate ladle for continuous casting of metal according to US patent No. 5169591, class. B22D 41/02, 1992, including a receiving and casting chamber, separated by a partition, in which the upper, middle and lower rows of overflow channels are made.

A disadvantage of the known technical solution is the low degree of mixing of the metal volume in the casting chamber, which is clogged with non-metallic inclusions penetrating through overflow channels from the receiving chamber, which reduces the casting efficiency.

The closest to the proposed technical solution for the technical nature and the achieved result (prototype), according to the authors, is an intermediate bucket of a two-strand continuous casting machine according to RF patent No. 1790468, class. B22D 11/10, including a lined casing, a receiving and casting sections with outlet glasses, the sections being separated by partitions with upper and lower through channels made therein.

A disadvantage of the known technical solution is the low quality of the metal and the low stability of the metal casting process, due to the fact that the channels made in the partitions serve only for supplying the metal to the casting sections and do not contribute to the organization of directional mixing of the metal to ensure accelerated ascent of non-metallic inclusions and gases contained in the melt (liquid metal) and subsequent assimilation by their protective slag, and, therefore, the required uniformity of the metal in chemical composition and mi microstructure of slabs.

The problem the technical solution is aimed at improving the quality of cast metal by reducing the number of non-metallic inclusions and the heterogeneity of the metal. In this case, obtaining such a technical result is achieved, such as reducing the rejection of slabs by non-metallic inclusions, increasing the service life of the intermediate ladle, reducing the defect of hot-rolled pickled and cold-rolled products due to the “captivity” defect and, as a result, obtaining additional profit.

The above disadvantages are eliminated by the fact that in the intermediate ladle for continuous casting of metal, including a lined casing with a receiving chamber and casting chambers, separated by partitions, each of which has upper and lower channels, the distance between the opposite surfaces of the walls of the receiving chamber is 1.3-1, 8 nominal level of liquid metal, and the ratio of the areas of the upper to the lower channel of each dividing wall is 1: 0.94-0.98; the lower channels are made with a slope of 25-45 ° in the direction of the receiving chamber.

A comparative analysis of the proposed technical solution with the prototype shows that the claimed technical solution differs from the known one for its structural design, namely, the ratio of the distance between the opposite surfaces of the walls of the receiving chamber and the nominal level of liquid metal. Thus, the claimed technical solution meets the criterion of the utility model "Novelty."

Since the proposed utility model can be used in industry, and testing the prototype has already shown positive results, therefore, this technical solution meets the criterion of the utility model "Industrial applicability".

A comparative analysis of the proposed technical solution not only with the prototype, but also with other technical solutions did not allow us to identify the essential features inherent in the claimed solution. It follows that the claimed combination of significant differences allows to obtain the above technical result.

The proposed technical solution will be clear from the following description and the drawings attached to it:

Figure 1 - schematically shows the proposed intermediate bucket;

Figure 2 - shows a section aa of figure 1.

An intermediate ladle for continuous casting of metal includes a lined casing 1, with a receiving 2 and casting 3, 4 chambers, which are separated by partitions 5 and 6, in which the upper 7 and lower 8 through channels are made. The distance -L- between the opposite surfaces of -P- and -O- of the partitions 5, 6 of the receiving chamber 2 is 1.3-1.8 of the nominal level of -H- liquid metal. And the ratio of the areas of the upper 7 to the lower 8 channel of each dividing partition 5, 6 is 1: 0.94-0.98. The lower channels 8 are made with a slope of -α- equal to 25-45 ° in the direction of the receiving chamber 2. In the receiving chamber on the bottom of the bucket there is a jet receiver-damper 9 (turbostop) made of highly resistant refractory material.

An intermediate ladle for continuous casting of metal works as follows.

The metal stream from the steel pouring ladle (not shown in the figures) enters the jet receiver-damper 9 (turbostop), this ensures the quenching of the kinetic energy of the jet, which eliminates the "erosion" of the lining of the bottom, walls and partitions in the receiving chamber 2 of the intermediate ladle during casting metal. Then, the liquid metal through the through upper 7 and lower 8 channels of the partitions 5, 6 enters the casting chambers 3 and 4 of the intermediate ladle. Next, the liquid metal through the exhaust glasses 10, 11 of the casting chambers is fed into the molds (under the metal level). Continuous cast ingots are drawn from crystallizers. The consumption of metal from the tundish is regulated using stoppers 12 or slide gates (not shown in the figures).

The implementation of the distance -L- between the opposite surfaces of -P- and -O- partitions 5, 6 of the receiving chamber 2 is less than 1, 3 of the nominal level of -H- liquid metal leads to erosion and destruction of the partitions due to the effect of intense hot melt flows in the latter receiving chamber 2. When casting the melt, the flow of liquid metal in the bottom region acquires a higher speed and without interacting with anything, passing through channels 7, 8, is sent to the dispenser glass, taking with it the products of deoxidation of the liquid metal, which is negative but affects the quality of the finished product.

The implementation of the distance -L- between the opposite surfaces of -P- and -O- of the partitions 5, 6 of the receiving chamber 2 is more than 1.8 of the nominal level of -H-liquid metal leads to a decrease in the size of the casting chambers, which leads to an increase in the ascent path of non-metallic inclusions and a decrease the time required for their allocation (flotation), which is also undesirable.

The ratio of the areas of the upper 7 to the lower 8 channel of each dividing partition 5, 6 as 1: 0.94-0.98, and the implementation of the lower channels 8 with a slope of -α- equal to 25-45 ° in the direction of the receiving chamber 2 of the intermediate bucket was determined by an experienced by as a result of research work.

It follows that when using the proposed technical solution during the casting of liquid metal, the melt flow passing from the receiving chamber through the upper and lower channels of the separation walls into the casting chambers acquires a laminar character, as a result of which the inclusions contained in the liquid steel coagulate and their sizes increase, which creates favorable conditions for their selection. At the same time, these particles move to the steel-slag interface and are absorbed by the slag layer, resulting in an increase in the quality of the cast steel. Industrial tests carried out at one of the casting sites for liquid metal showed that the service life of the tundish increased by an average of 12.5%, and in the production of cold-rolled rolled trial alloys, the yield of non-conforming products due to a “defect” defect decreased by 2%.

From this we can conclude that the task whose solution the technical solution is aimed at is fulfilled, while achieving the above technical result is achieved.

Claims (3)

1. An intermediate ladle for continuous casting of metal, including a lined casing with a receiving and casting chambers separated by partitions, each of which has upper and lower channels, characterized in that the distance between the opposite surfaces of the walls of the receiving chamber is 1.3-1.8 nominal level of liquid metal. 2. The intermediate bucket according to claim 1, characterized in that the ratio of the areas of the upper to the lower channel of each dividing wall is 1: 0.94-0.98. 3. The intermediate bucket according to claim 1, characterized in that the lower channels are made with a slope of 25-45 ° in the direction of the receiving chamber.