RU2188099C1 - Refractory nozzle - Google Patents

Abstract

FIELD: apparatuses for supplying melt metal into intermediate ladle of machines for continuous casting of bloom and slab billets. SUBSTANCE: refractory nozzle includes inlet opening with circular cross section and outlet opening - with cross section whose profile is restricted by part of circle with radius R and at least by one chord. Cross section area of outlet opening consists 0.2-1.0 of cross section area of its inlet opening; total length of conduit for passing metal exceeds 15 radius values of circle of above mentioned profile. Profile of cross section of outlet opening may be restricted by part of circle with radius R and by two chords inclined one relative to another by angle no more than 30 degrees and it may be like segment. Flat stream is formed in outlet opening; said stream is divided by two horizontal flows near bottom of intermediate ladle. It provides lowered kinematic energy of metal stream and prevent entrapping of surface slag to melt. EFFECT: enhanced quality and mechanical properties of billets. 4 cl, 7 dwg

Description

 The invention relates to the field of metallurgy, and more particularly to refractory glasses for supplying metal to the tundish of a continuous casting machine.

 A refractory cup is known for supplying metal to an intermediate ladle of a continuous casting machine with a metal-conducting channel, the inlet of which is made with a circular cross-section, in which the outlet of the metal-channel is also made with a circular cross-section, and the cross-sectional area of the outlet is equal to the cross-sectional area the inlet, and the total length of the metal-conducting channel of the glass is 10 radii of the circumference of the outlet (V.A. Efimov, A.S. El Darkhan. Current technology of casting alloys and crystallization. M .: Engineering, 1998, p. 338, Fig. 8.12).

 A disadvantage of the known refractory glass is that it does not allow the use of protective coating slags in the intermediate bucket, which is associated with the short length of the metal-conducting glass channel. In addition, the metal stream from the known refractory glass is characterized by significant kinetic energy, which is associated with a round cross-section of the metal-conducting channel of the glass. These factors determine the high contamination of the workpieces with non-metallic inclusions, both formed during the oxidation of the metal in the intermediate ladle, and also trapped in the intermediate ladle from the cover slag in the casting ladle.

 A refractory cup for supplying metal to an intermediate ladle of a continuous casting machine with a metal-conducting channel, the inlet of which is made with a circular cross-section, in which the outlet of the metal-conducting channel is also made with a circular cross-section, the cross-sectional area of the outlet being equal to the area is also known. the cross section of the inlet, and the total length of the metal-conducting channel of the glass allows the use of integumentary slags in the intermediate bucket (Dos izheniya in the field of continuous casting of steel. between the materials. Congress. M .: Metallurgy, 1987, fig. 8.1).

 A disadvantage of the known refractory cup is the large kinetic energy of the metal jet formed by it and the uniform distribution of metal flows from the axis of the jet, which leads to the formation of funnel-like vortices on the surface of the metal in the tundish and the entrainment of the slag in the bucket by the metal. This is a consequence of the round cross section of the metal channel and determines the high contamination of the workpieces with non-metallic inclusions.

 The closest in technical essence and the achieved result is a refractory cup adopted for the prototype, which can be used to feed metal into the intermediate ladle, with a metal-conducting channel, the inlet of which is made with a round cross section, and the outlet at the lower edge is made with an oval cross section , the small axis of which is equal to the diameter of the inlet, and the large is 1.2-4.0 of this diameter. With these size ratios, the cross-sectional area of the outlet is 1.25-4.80 of the cross-sectional area of the inlet (aut. USSR 614884, B 22 D 41/50, 11/10, 02.07.76).

 Despite the oval profile of the outlet of the fireproof nozzle, the metal jet emerging from it is characterized by significant kinetic energy, which is associated with the preservation of the large size of the small axis of the oval outlet. In addition, the disadvantage of the prototype is that it does not allow the use of protective coating slags in the intermediate bucket, which is associated with the small length of the metal-conducting channel of the glass. In addition, the metal stream from the refractory cup is characterized by significant kinetic energy, which is associated with the preservation of the large size of the small axis of the outlet. These factors determine the high contamination of the workpieces with non-metallic inclusions, both formed during the oxidation of the metal in the intermediate ladle, and also trapped in the intermediate ladle from the cover slag in the casting ladle.

 The technical result of the invention is to create conditions for the use of coating slag in the intermediate ladle, to reduce the kinetic energy generated by the refractory cup of the metal jet, and to control the metal flows in the intermediate ladle to exclude intense flows on the surface, including funnel-like vortices, and thus reduce contamination of workpieces with non-metallic inclusions.

The result is achieved in that in a known refractory cup for supplying metal to an intermediate ladle of a continuous casting machine with a metal-conducting channel, the inlet of which is made with a circular cross section, according to the invention, the outlet of the metal-conducting channel is made with a cross-section, the profile of which is formed by a part of a circle of radius R and at least one of its chords, while the cross-sectional area of the outlet is 0.2-1.0 cross-sectional areas of its input about the hole, and the total length of the metal channel exceeds 15 radii R of the circumference of the profile. The cross-sectional profile of the outlet of the metal channel can be formed by a part of a circle of radius R and two chords located at an angle to each other, not exceeding 30 ^o . The cross section of the outlet of the metal channel can be in the form of a segment.

 The claimed combination of features, namely, the outlet cross-sectional profile and the regulated outlet cross-sectional area and the length of the metal-conducting channel, make it possible to use protective coating slag in the tundish, exclude its capture by metal by reducing the kinetic energy of the metal jet formed by the glass and suppressing intense metal flows in bucket and vortex formation on the metal surface, which ensures high purity of workpieces for non-metallic inclusions.

 When the ratio of the cross-sectional area of the outlet of the metal-conducting channel to the cross-sectional area of its inlet is less than 0.2, the dimensions of the inlet increase significantly to provide the required throughput of the refractory cup, and therefore, the dimensions of the cup increase, with a ratio greater than 1.0 they increase the dimensions of the outlet of the channel, which determines a sharp slowdown in the reduction of the kinetic energy of the metal jet formed by the refractory cup at the same time a change in the dimensions of the glass.

 Variants of the execution of the outlet profile provide a reduction in the contamination of the workpieces with inclusions for intermediate ladles of the most common designs - rectangular, T-shaped and others.

 The invention is illustrated by drawings, where in Fig.1 shows a refractory cup for feeding metal into the intermediate bucket of a rectangular shape; figure 2 is a cross section of the inlet; figure 3 is a cross section of the outlet of this glass; figure 4 is a cross section of the outlet of the channel of the glass for the intermediate bucket T-shaped; figure 5 is a cross section of the outlet of the channel of the glass for the intermediate bucket oval; 6 and 7 show a diagram of metal flows in an intermediate bucket of a rectangular shape, a top view and a longitudinal section, respectively.

 A refractory cup for supplying metal to a rectangular bucket of a rectangular shape (Figs. 1, 2, and 3) has a metal-conducting channel 1, the inlet 2 of which is made with a circular cross-section (Fig. 2), and the outlet 3 is made with a cross-section, the profile of which formed by a part of a circle of radius R and two parallel chords 4 (figure 3). The length of the glass L exceeds 15 radii R of the circumference of the profile.

 The cross section of the outlet of the metal-conducting channel of the cup for supplying metal to the T-shaped intermediate bucket has the form of a segment (Fig. 4), and for supplying metal to the oval bucket, the cross-sectional profile of the outlet channel opening is formed by a part of a circle of radius R and two chords located at an angle α to each other.

 A glass for supplying metal to an intermediate bucket of a rectangular shape works as follows (Figures 4 and 5).

 The outlet 3 installed in the intermediate ladle 5 with thresholds 6 and pouring nozzles 7 of the nozzle 1 forms a flat vertical stream, which at the bottom of the intermediate ladle 5 bifurcates into horizontal flows (shown by arrows), each of which goes to one of two thresholds 6 and then to the corresponding pouring glass 7. Thresholds 6 provide separation of metal flows from the bottom of the bucket 5 and their direction to the coating slag on the metal surface (Fig. 5).

 Due to the plane stream formed by the exit section of the outlet, its approach to the metal level in the bucket and the direction of metal flows mainly along the intermediate ladle 5 on the metal surface near the glass, the flow intensity is limited and conical vortices are not formed, which cause emulsification of the coating slag by the metal, which determines high purity metal on non-metallic inclusions. The direction of the metal to the mirror by the thresholds provides additional purification of the metal from non-metallic inclusions due to their coagulation and subsequent absorption of the integumentary slag.

 When using a refractory cup (Fig. 4), most of the metal after it is reflected from the bottom of the intermediate ladle is sent from the receiving part of the ladle directly to the casting part in a fan-shaped flow, and when using the cup of Fig. 5, by flat jets to the casting cups. In both cases, thresholds set quasistantly to the cross-sectional profiles of the outlet openings of the canal can be used to separate metal flows from the bottom of the intermediate ladle.

The invention can be used for the production of billets with a low content of non-metallic inclusions and gases, which provides an increase in the mechanical and service characteristics of finished rolled products from cast metal. Thus, the total content of nonmetallic inclusions in slab billets when using the invention is up to 100 • 10 ³ vol.%, The elongation and toughness of the rolled sheets are 10-20% higher, the ultrasound rejects are reduced by 2.5 times.

Claims (4)

 1. A refractory cup for supplying metal to an intermediate ladle of a continuous casting machine with a metal-conducting channel, the inlet of which is made with a circular cross-section, characterized in that the outlet of the metal-conducting channel is made with a cross-section, the profile of which is formed by a part of a circle of radius R and, at least one of its chords, while the cross-sectional area of the outlet is 0.2-1.0 of the cross-sectional area of its inlet, and the total length of the metal wire The total channel exceeds 15 radii of the profile circumference.  2. The refractory cup according to claim 1, characterized in that the cross-sectional profile of the outlet of the metal channel is formed by a part of a circle of radius R and two chords. 3. Refractory cup according to one of claims 1 and 2, characterized in that the cross-sectional profile of the outlet of the metal channel is formed by a part of a circle of radius R and two chords located at an angle to each other not exceeding 30 ^o .  4. The refractory cup according to claim 1, characterized in that the cross section of the outlet of the metal channel is in the form of a segment.

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