RU2067910C1 - Apparatus for flow-type evacuating the metal upon continuous casting - Google Patents

Abstract

FIELD: metallurgy, namely, metal continuous casting. SUBSTANCE: apparatus includes casting ladle, vacuum chamber with branch pipe mounted in bottom of vacuum chamber and entering working chamber of intermediate ladle, vacuum duct and casting nozzles arranged in bottom of intermediate ladle. Inner cavity of intermediate ladle is separated by three zones with the aid of partitions placed symmetrically relative to branch pipe and having trapezoidal cross section with inclination angle of faces near base in range of 5-30 deg. Distance between axes of partitions is 0.4-0.6 of distance between axes of casting nozzles. EFFECT: improved design. 1 cl, 1 dwg

Description

 The invention relates to metallurgy, and more particularly to continuous casting of metals.

 The closest in technical essence is a device for in-line evacuation of metal during continuous casting, including a casting ladle, a vacuum chamber with a nozzle installed in the bottom of the vacuum chamber and included in the working cavity of the intermediate ladle, a vacuum wire and pouring glasses installed in the bottom of the intermediate ladle (see ed. certificate N 295607, class B 22 D 11/10, 1971).

 A disadvantage of the known device is the unsatisfactory quality of continuously cast ingots. This is due to the fact that when metal is supplied from the vacuum chamber through the nozzle, intense inorganic metal flows arise in the working cavity of the intermediate ladle. Under these conditions, intensive destruction of the lining of the intermediate ladle occurs, which leads to an increase in the content of non-metallic inclusions in continuously cast ingots in excess of the permissible values. In addition, due to inorganic flows in the metal, the metal fed to the crystallizers does not average over the temperature and the number of non-metallic inclusions, which leads to a violation of the stability of the formation and crystallization of continuously cast ingots and to their marriage along internal and external cracks. An increase in the content of non-metallic inclusions in the metal leads to their deposition in the pouring glasses, which leads to a decrease in their passage channel and termination of the continuous casting process.

 The technical effect when using the invention is to improve the quality of continuously cast ingots and increase the productivity of the continuous casting process.

 The specified technical effect is achieved by the fact that the device for continuous metal evacuation during continuous casting includes a casting ladle, a vacuum chamber with a nozzle installed in the bottom of the vacuum chamber and entering the working cavity of the intermediate ladle, a vacuum wire and pouring glasses installed in the bottom of the intermediate ladle .

 The inner cavity of the intermediate bucket is divided into three zones using two partitions located symmetrically relative to the nozzle, made of trapezoidal shape in cross section with an angle of inclination of the faces at the base within 5-30 degrees, while the distance between the axes of the partitions is 0.4-0, 6 distances between the axes of the nozzles.

 Improving the quality of continuously cast ingots will occur due to the ordering and the necessary direction of metal flows arising from the nozzle of the vacuum chamber. In addition, the presence of partitions prevents the penetration of non-metallic inclusions through casting glasses into the molds. Under these conditions, the process of floating non-metallic inclusions in the intermediate ladle and their assimilation by the slag mixture is intensified, the destruction of its lining is reduced, and the metal entering the molds is averaged over temperature and non-metallic inclusions.

 The implementation of the trapezoidal partitions in cross section is explained by the need for ordering and the corresponding direction of metal flows, flowing from the nozzle of the vacuum chamber and overflowing through the partitions.

 The range of the angle of inclination of the faces of the walls of the trapezoidal section within 5-30 degrees is explained by the laws of distribution and direction of metal flows in the zones of the intermediate ladle between the partitions and behind them. At lower values, the direction of flow of the metal will lead to its turbulization. At high values, intensive wear of the partitions will occur.

 The specified range is set in direct proportion to the height of the partitions.

 The range of distances between the axes of the partitions within 0.4-0.6 of the distance between the axes of the casting nozzles is explained by the patterns of distribution of metal flows from the nozzle of the vacuum chamber in the working cavity of the intermediate ladle. At lower values, the residence time of the metal in the middle zone of the intermediate ladle will not be sufficient for the floating of non-metallic inclusions and their assimilation. At large values, the necessary direction of metal flows during its overflow through the partitions will not be provided.

 Analysis of scientific, technical and patent literature shows the lack of coincidence of the distinctive features of the claimed device with the signs of known technical solutions. Based on this, it is concluded that the claimed technical solution meets the criterion of "inventive step".

 The following is an embodiment of the invention, not excluding other options within the claims, with reference to the drawing, which shows a diagram of a device for continuous metal evacuation of metal during continuous casting.

 A device for continuous metal evacuation during continuous casting consists of a casting ladle 1, a vacuum chamber 2, a nozzle 3, an intermediate ladle 4, casting nozzles 5, partitions 6, molds 7, vacuum wires 8. Position 9 denotes liquid metal, 10 metal level 11 continuously cast ingot.

 A device for continuous metal evacuation during continuous casting works as follows.

 Example. At the beginning of the continuous casting process, liquid unrefined steel 9 of grade st3 is supplied from a casting ladle 1 with a capacity of 350 tons to the vacuum chamber 2, and a vacuum is created in it to the residual pressure required by the technology within 0.3-0.6 kPa, depending on the deoxidation steel after sealing the vacuum chamber 2 with the level of liquid metal 10 in the intermediate ladle 4. The vacuum is created by means of a vacuum wire 8 connected to a vacuum pump. The metal 9 is fed from the vacuum chamber 2 into the intermediate ladle 4 through the refractory pipe 3 under the metal level 10. Next, the metal 9 from the intermediate ladle 4 serves the elongated refractory glasses 5 in the mold 7 under the metal level. Continuous cast ingots 11 are drawn from the crystallizers 7. The metal flow rate from the intermediate ladle 4 is controlled by stopping mechanisms (not shown in the drawing).

The inner cavity of the intermediate bucket 4 is divided into three zones using two partitions 6 located symmetrically relative to the nozzle 3, made of trapezoidal shape in cross section with an angle of inclination of the faces at the base within 5-30 degrees. The distance between the axes of the partitions 6 is 0.4-0.6 the distance between the axes of the casting nozzles 5. The level of metal 10 is covered with a layer of slag mixture based on CaO SiO ₂ - Al ₂ O ₃ .

 In the presence of trapezoidal partitions 6, directional flows of metal 9 are formed, flowing out of pipe 3, which allow non-metallic inclusions to float and assimilate with a slag mixture with the necessary intensity. At the same time, the destruction of the lining of the intermediate ladle is reduced, the temperature of the metal is averaged and the non-metallic inclusions are evenly distributed over the volume of metal passing through the pouring glasses 5 into the molds 7. In addition, non-metallic inclusions are not deposited in the pouring glasses.

 The table shows examples of the operation of the device for continuous metal evacuation during continuous casting with various technological and structural parameters.

 In the first example, due to the small distance between the axes of the partitions and the angle of inclination of their faces, the necessary direction of metal flows is not provided. Under these conditions, the intensity of floating and assimilation of non-metallic inclusions does not increase, and the required averaging of metal over temperature and distribution of non-metallic inclusions by volume is not provided, the lining of the intermediate ladle is destroyed by metal flows, non-metallic inclusions are deposited in casting glasses, which leads to the cessation of the process of continuous casting.

 In the fifth example, due to the large distance between the axes of the partitions and the large angle of inclination of the faces of the partitions, the metal is supercooled in the zone between the partitions, and the intensive wear of the partitions occurs under the influence of metal flows. At the same time, the necessary direction of metal flows in the intermediate ladle is not provided, intensive destruction of the lining of the intermediate ladle occurs.

 In the sixth example, the prototype, due to the lack of partitions and the separation of the working cavity of the intermediate bucket into separate zones, disorganized turbulent flows of metal flowing from the nozzle of the vacuum chamber are formed. Under these conditions, intensive destruction of the lining of the intermediate ladle occurs, and the rate of assimilation of non-metallic inclusions in the slag layer decreases. The foregoing leads to an increase in the content of non-metallic inclusions in ingots in excess of the permissible values; there is an intensive deposition of non-metallic inclusions in pouring glasses, which causes the marriage of continuously cast ingots in terms of macrostructure quality and termination of the continuous casting process.

 In examples 2-4, due to the presence in the intermediate bucket of partitions of optimal sizes, the necessary organization and direction of metal flows arising from the nozzle of the vacuum chamber are provided. Under these conditions, the intensity of destruction of the lining of the intermediate ladle decreases, the intensity of the assimilation of non-metallic inclusions in the slag layer increases, the failure of casting glasses is eliminated. In this case, the metal is averaged over temperature and non-metallic inclusions.

 The application of the proposed device allows to increase the yield of continuously cast ingots by macrostructure quality by 9% and also to increase the productivity of the continuous casting process of evacuated metal by 5%. The economic effect is calculated in comparison with the base object, which is a device for continuous vacuum casting metal used for continuous casting, used on Novolipetsk Metallurgical Plant. TTT1

Claims (1)

A device for continuous metal evacuation during continuous casting, comprising a casting ladle, an intermediate ladle, a vacuum chamber with a nozzle in the bottom of the vacuum chamber included in the working cavity of the intermediate ladle, a vacuum pipe and pouring glasses in the bottom of the intermediate ladle, characterized in that the inner cavity of the intermediate ladle is equipped with two partitions dividing it into three zones, and the partitions are located symmetrically with respect to the pipe and are made trapezoidal in cross section with an angle the inclination of the faces at the base within 5 30 ^o , while the distance between the axes of the partitions is 0.4 0.6 the distance between the axes of the casting glasses.

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