This application is based upon and claims benefit of priority of Japanese Patent Applications No. 2008-084166 filed on Mar. 27, 2008 and No. 2008-335527 filed on Dec. 27, 2008, the contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a continuous casting immersion nozzle for pouring molten steel from a tundish into a mold.
2. Description of the Related Art
In a continuous casting process for producing casting steel products of a predetermined shape by continuously cooling and solidifying molten steel, molten steel is poured into a mold through a continuous casting immersion nozzle (hereafter, also referred to as the “immersion nozzle”) positioned at the bottom of a tundish.
Generally, the immersion nozzle includes a tubular body with a bottom, and a pair of outlets. The tubular body has an inlet for entry of molten steel disposed at an upper end and a passage extending inside the tubular body downward from the inlet. The pair of outlets are disposed in the sidewall at a lower section of the tubular body so as to communicate with the passage. The immersion nozzle is used with its lower section submerged in molten steel in the mold to prevent flying of poured molten steel into the air and oxidation thereof through contact with the air. Further, the use of the immersion nozzle allows regulation of the molten steel flow in the mold and thereby prevents impurities floating on the molten steel surface such as slags and non-metallic inclusions from being entrapped into the molten steel.
In recent years, there has been a demand for improving the quality and productivity of steel in the continuous casting process. Increasing the productivity of steel with existing production facilities requires rising the pouring rate (throughput). Thus, in order to increase the amount of molten steel that passes through the immersion nozzle, attempts have been made through approaches such as increasing the diameter of the nozzle passage and increasing the dimensions of the outlets within a limited space in the mold.
Increasing the outlet dimensions results in imbalances in flow velocity distribution between the exit-streams discharged out of the lower portions and the exit-streams out of the upper portions of the outlets, and between the exit-stream out of the right outlet and the exit-stream out of the left outlet. The imbalanced flows (drifts) impinge on the narrow sidewalls of the mold and then induce unstable patterns of molten steel flow in the mold. As a result, the level fluctuation at the molten steel surface is caused by excessive reverse flows, and the steel quality is lowered due to entrapment of mold power, and also problems such as breakout occur.
International publication No. 2005/049249, for example, discloses an immersion nozzle including a tubular body, the body having a pair of opposing lateral outlets in the sidewall of a lower section thereof. The lateral outlets each are divided by one or two inward horizontal projections into two or three vertically arranged portions to make a total of four or six outlets (See
The present inventors performed water model tests regarding the immersion nozzle of International publication No. 2005/049249, a conventional type immersion nozzle, and a modification of the conventional type immersion nozzle (See
The difference Δσ between the standard deviations of the velocities of the right- and left-hand reverse flows and the average value Vav of the velocities of the right- and left-hand reverse flows increase with a rise in throughput. From the viewpoint of improving the quality of slabs, it is desirable that Δσ is 2 cm/sec or less, and that Vav is 10 cm/sec to 30 cm/sec. Note that Δσ of all the samples were 2 cm/sec or less, while Vav of all the samples were outside the range of 10 cm/sec to 30 cm/sec.
In the case of the immersion nozzle of International publication No. 2005/049249 (four-outlet type nozzle), as indicated by the results of the fluid analyses in
Further, the immersion nozzle of International publication No. 2005/049249, which has four or more outlets, not only requires a complicated manufacturing process, but is liable to induce imbalance between the right- and left-hand exit-streams when clogging or thermal wear of the outlets occurs.
The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide an immersion nozzle for continuous casting which reduces the drift of molten steel flowing from the outlets of the nozzle and reduces the level fluctuation at the molten steel surface and which is easy to manufacture.
The present invention relates to an immersion nozzle for continuous casting. The immersion nozzle for continuous casting includes a tubular body with a bottom, and a pair of opposing outlets. The tubular body has an inlet for entry of molten steel disposed at an upper end and a passage extending inside the tubular body downward from the inlet. The pair of opposing outlets are disposed in a sidewall at a lower section of the tubular body so as to communicate with the passage. The immersion nozzle for continuous casting further includes a pair of opposing ridges horizontally projecting into the passage from an inner wall between the pair of outlets. The inner wall defines the passage.
The term “ridges horizontally projecting into the passage from an inner wall” as used herein refers to ridges each extending horizontally from one side to the other side in an inner wall, i.e., from one border between one outlet and one side in the inner wall to the other border between the other outlet and the other side in the inner wall.
In the immersion nozzle for continuous casting of the present invention, it is preferable that a/a′ ranges from 0.05 to 0.38 and b/b′ ranges from 0.05 to 0.5, where a′ and b′ are a horizontal width and a vertical length, respectively, of the outlets in a front view; a is a projection height of the ridges at end faces; and b is a vertical width of the ridges. Further, it is preferable that c/b′ ranges from 0.15 to 0.7, where c is a vertical distance between upper edges of the outlets in a front view and vertical widthwise centers of the ridges.
In the immersion nozzle for continuous casting of the present invention, it is also preferable that the ridges each have tilted portions at opposite ends in a lengthwise direction of the ridges. The tilted portions are tilted downward toward an outside of the tubular body. Additionally it is preferable that each outlet has an upper end face and a lower end face that are tilted downward toward the outside of the tubular body at the same tilt angle as the tilted portions.
In the immersion nozzle for continuous casting of the present invention, further, it is preferable that L2/L1 ranges from 0 to 1, where L1 is a width of the passage, along a lengthwise direction of the ridges, immediately above the outlets; and L2 is a length of the ridges except the tilted portions.
The immersion nozzle 10 includes a cylindrical tubular body 11 with a bottom 15, and a pair of opposing outlets 14, 14. The tubular body 11 has an inlet 13 for entry of molten steel at the upper end of a passage 12 extending inside the tubular body 11. The pair of opposing outlets 14, 14 are disposed at a lower section thereof so as to communicate with the passage 12. The tubular body 11 is made of a refractory material such as alumina-graphite since the immersion nozzle 10 is required to have spalling resistance and corrosion resistance.
The outlets 14, 14 have a rectangular configuration with rounded corners, when seen in a front view. The tubular body 11 has opposing ridges 16, 16 that project in the horizontal direction into the passage 12 from an inner wall 18, which defines the passage 12, between the pair of outlets 14, 14. Namely, the opposing ridges 16, 16 are arranged symmetrically about a vertical plane passing through the centers of the respective outlets 14, 14 (shown in the chain double-dashed line in
If each outlet 14 has the upper end face 14a and lower end face 14b tilted downward toward the outside of the tubular body 11 but the ridges 16, 16 are not tilted downward at the opposite ends in the lengthwise direction, the exit-streams to flow through the spaces above the ridges 16, 16 are interrupted by the ridges 16, 16. As a result, the exit-streams are discharged out of the outlets 14, 14 upward. The exit-streams thus discharged collide with the reverse flows at the molten steel surface in the mold, destabilizing the velocities of the reverse flows. For this reason, the tilted portions 16a, 16a at the opposite ends of each ridge 16 in the lengthwise direction are tilted at the same tilt angle as the upper end face 14a and lower end face 14b of each outlet 14.
Each of the ridges 16, 16 extends horizontally from one side to the other side in the inner wall 18, i.e., from one border between one outlet 14 and one side in the inner wall 18 to the other border between the other outlet 14 and the other side in the inner wall 18. Preferably, the end faces of each ridge 16 at the opposite ends in the lengthwise direction, i.e., the end faces of the respective tilted portions 16a, 16a, are vertical faces perpendicular to the lengthwise direction of the ridges 16, 16 as shown in
Preferably, the tubular body 11 has at the bottom 15 a recessed reservoir 17 for molten steel. Although the absence of the recessed reservoir 17 does not adversely influence the effect of the present invention, the recessed reservoir 17 for molten steel permits more uniform and more stable distribution of molten steel between the outlets 14, 14 by temporarily holding molten steel poured into the immersion nozzle 10.
It does not influence the effect of the present invention whether or not a horizontal width a′ of the outlets 14, 14 is the same as the width of the passage 12 (in the case where the passage 12 is cylindrical, the diameter thereof).
Conventional immersion nozzles suffer from discharge of larger amounts of the exit-streams from the lower portions of the outlets, which causes imbalance in flow velocity distribution between the exit-streams that issue from the lower portions and the exit-streams that issue from the upper portions of the outlets. The immersion nozzle 10 according to the embodiment of the present invention, on the other hand, allows sufficient amounts of the exist-streams to issue also from the upper portions due to the effect of the opposing ridges 16, 16 to hold back the molten steel flowing through the immersion nozzle 10. Additionally, due to the effect of the clearance between the ridges 16, 16 to regulate the flow, the molten steel flowing downward through the clearance becomes bilaterally symmetric about the axis of the immersion nozzle 10 when seen in the vertical plane passing through the centers of the respective outlets 14, 14. Further, the immersion nozzle 10 by allowing the exit-streams to uniformly flow out of the entire areas of the outlets 14, 14, reduces the maximum velocities of the exit-streams that impinge on the mold's narrow sidewalls, and in turn, decreases the velocities of the reverse flows. This solves the problems of the level fluctuation at the molten steel surface and the entrapment of mold powder, and thereby prevents lowering of the steel quality.
In addition, the immersion nozzle 10 can be easily manufactured by a method of forming a traditional immersion nozzle because the immersion nozzle 10 is obtained by forming the opposing ridges that protrude into the passage from the inner wall thereof between the pair of outlets.
Examples of methods of forming outlets in a traditional immersion nozzle include: a method comprising forming outlets, of a size smaller than finally intended, in a tubular body, and then boring the outlets perpendicularly to the tubular body to enlarge the outlets and to form ridges of an intended cross sectional dimension; and a method comprising forming recesses, which are parts to be ridges, in a cored bar by CIP (Cold Isostatic Pressing), then charging the recesses with clay, a material used for producing the tubular body, and pressing the clay, thereby forming ridges of an intended cross sectional dimension.
[Water Model Tests]
In order to determine the optimum configuration of the outlets 14, 14 with the ridges 16, 16 therebetween, water model tests were performed using models of the immersion nozzle 10. The water model tests performed will be described in the below.
Parameters used to determine the optimum configuration of the outlets 14, 14 with the ridges 16, 16 therebetween are denoted as follows. The horizontal width and vertical length of the outlets 14, 14 as seen in a front view are denoted as a′ and b′, respectively; the projection height of the ridges 16, 16 at the end faces is denoted as a, the ridges 16, 16 having a substantially rectangular cross section, and the vertical width of the ridges 16, 16 is denoted as b; and the vertical distance between the upper edges of the outlets 14, 14 to the vertical widthwise centers of the ridges 16, 16 is denoted as c (See
A 1/1 scale mold 21 was made of an acrylic resin. The mold 21 was dimensioned such that the length of the long sides (in
The immersion nozzle 10 was placed in the center of the mold 21 such that the outlets 14, 14 faced the narrow sidewalls 23, 23 of the mold 21. Propeller-type flow speed detectors 22, 22 were installed 325 mm (¼ of the length of the long sides of the mold 21) off narrow sidewalls 23, 23, respectively, of the mold 21 and 30 mm deep from the water surface. Then, the velocities of the reverse flows Fr, Fr were measured for three minutes. After that, the difference Δσ between standard deviations of the velocities of the right- and left-hand reverse flows Fr, Fr and the average value Vav thereof were calculated and the results were evaluated.
Here, a description will be made regarding the correlation between the reverse flows and the throughput.
The water model tests were performed to clarify both the correlation between the difference Δσ between standard deviations of the reverse flows on the right- and left-hand sides of the immersion nozzle and the throughput and the correlation between the average value Vav of the velocities of the right- and left-hand reverse flows and the throughput. The results of the water model tests indicated that the values Δσ and Vav increased proportionally to the rise in the throughput. The envisaged mold and immersion nozzle for the tests were dimensioned such that the mold had the length of 700 mm to 2000 mm and the width of 150 mm to 350 mm and the passage of the immersion nozzle had the cross sectional area of 15 cm to 120 cm2 (diameter of 50 mm to 120 mm), which dimensions are normally applied in continuous casting of slabs. When the throughput was below 1.4 ton/min, the velocities of the reverse flows at the surface of molten steel were too slow. However, when the throughput was above 7 ton/min, the velocities of the reverse flows were too fast, causing the risk of a reduction in steel quality due to the increased level fluctuation at the surface of the molten steel and due to entrapment of mold powder. Accordingly, it was desirable that the throughput was 1.4 ton/min to 7 ton/min. The test showed that the throughput was within the above-mentioned optimum range when the difference Δσ between the standard deviations of the velocities of the right- and left-hand reverse flows was 2.0 cm/sec or below and when the average value Vav of the velocities of the right- and left-hand reverse flows was 10 cm/sec to 30 cm/sec. Accordingly, Δσ of 2.0 cm/sec and below and Vav of 10 cm/sec to 30 cm/sec were taken as critical ranges in evaluation of the below-mentioned results of the water model tests performed to determine the optimum configuration of the outlets with the ridges therebetween.
The throughputs in the water model tests were converted using the equation: specific gravity of molten steel/specific gravity of water=7.0. So, the above throughputs are equivalent to the throughputs of molten steel.
When a/a′ was below 0.05, the ridges did not sufficiently exhibit the effects of interrupting and regulating the flow, causing asymmetric streams on the right- and left-hand sides of immersion nozzle in the mold and reverse flows having velocities of beyond 30 cm/sec. This would result in a wide fluctuation in the surface level of the molten steel, and adverse effects such as entrapment of mold powder. On the other hand, when a/a′ was beyond 0.38, the exit-streams in the lower portions of the outlets had slightly too low velocities, namely, the exit-streams in the upper portions of the outlets had excessive velocities, and the reverse flows had velocities of beyond 30 cm/sec. This would result in a wide fluctuation in the surface level of the molten steel, and adverse effects such as entrapment of mold powder.
The other parameters used in the present test were set to the following values.
b/b′=0.25, c/b′=0.57, L2/L1=0.83, θ=15°, R/a′=0.14
When b/b′ was outside the range of 0.05 to 0.5, the same phenomena would occur as observed when a/a′ was outside the range of 0.05 to 0.38: a wide fluctuation in the surface level of the molten steel; and adverse effects such as entrapment of mold powder.
The other parameters used in the present test were set to the following values.
a/a′=0.21, c/b′=0.48, L2/L1=0.77, θ=15°, R/a′=0.14
When c/b′ was outside the range of 0.15 to 0.7, the same phenomena would occur as observed when a/a′ was outside the range of 0.05 to 0.38: a wide fluctuation in the surface level of the molten steel; and adverse effects such as entrapment of mold powder.
The other parameters used in the present test were set to the following values.
a/a′=0.24, b/b′=0.25, L2/L1=0.77, θ=15°, R/a′=0.14
L2/L1=0 means L2=0, namely, that the ridges 16, 16 are inverted V-shaped with no horizontal portions 16b, 16b. On the other hand, when L2/L1 was above 1, manufacture of the immersion nozzle would be difficult.
In
The other parameters used in the present test were set to the following values.
a/a′=0.29, b/b′=0.25, c/b′=0.5, θ=15°, R/a′=0.14
The mold used in the present test had dimensions of 1500 mm×235 mm and the throughput was 3.0 ton/min.
The other parameters used in the present test were set to the following values.
a/a′=0.13, b/b′=0.25, c/b′=0.4, L2/L1=1, θ=0°
Table 1 shows the results of water model tests performed using the immersion nozzles for continuous casting according to the embodiment of the present invention, one nozzle having the reservoir for molten steel in the bottom of the tubular body, the other having no reservoir. Table 1 indicates that Δσ and Vav did not vary greatly depending on the presence or absence of the reservoir and were in the optimum ranges.
The other parameters used in the present test were set to the following values. The mold had dimensions of 1200 mm×235 mm and the throughput was 2.4 ton/min.
a/a′=0.14, b/b′=0.33, c/b′=0.5, L2/L1=1, θ=0°, R/a′=0.14
[Fluid Analysis]
A description will be made regarding the fluid analyses on the exit-streams from the immersion nozzle for continuous casting according to the embodiment of the present invention and those from an immersion nozzle according to prior art.
The fluid analyses were performed by using FLUENT (fluid analysis software) manufactured by Fluent Asia Pacific Co., Ltd. (i.e., ANSYS Japan K.K. at present).
The analyses were performed on the assumption that the mold was 1540 mm long and 235 mm wide and that the throughput was 2.7 ton/min.
Regarding the immersion nozzle for continuous casting according to the embodiment of the present invention, further study was made by fluid analyses on changes in the exit-streams caused by varying the tilt angle of the tilted portions of the ridges and that of the upper end faces and lower end faces of the outlets on condition that the tilted portions and the upper end faces and lower end faces had the same tilt angle. The results of the fluid analyses are shown in
The results of the fluid analyses shown in
While preferred embodiments of the invention have been described and illustrated above, it should be understood that these are exemplary of the invention and are not to be considered as limiting. Additions, omissions, substitutions, and other modifications can be made without departing from the spirit or scope of the present invention. Accordingly, the invention is not to be considered as being limited by the foregoing description, and is only limited by the scope of the appended claims.
Number | Date | Country | Kind |
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2008-084166 | Mar 2008 | JP | national |
2008-335527 | Dec 2008 | JP | national |
Number | Name | Date | Kind |
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4949778 | Saito et al. | Aug 1990 | A |
20070102852 | Richaud et al. | May 2007 | A1 |
20070158884 | Tsukaguchi | Jul 2007 | A1 |
Number | Date | Country |
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43 19 194 | Dec 1994 | DE |
57-106456 | Jul 1982 | JP |
4-238658 | Aug 1992 | JP |
7-232247 | Sep 1995 | JP |
8-294757 | Nov 1996 | JP |
2001-347348 | Dec 2001 | JP |
WO 2005049249 | Jun 2005 | WO |
Number | Date | Country | |
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20090242163 A1 | Oct 2009 | US |