This invention relates to making thin strip and more particularly casting of thin strip by a twin roll caster.
It is known to cast metal strip by continuous casting in a twin roll caster. Molten metal is introduced between a pair of counter-rotating horizontal casting rolls which are cooled so that metal shells solidify on the moving roll surfaces. The solidified metal shells are brought together at the nip between the casting rolls to produce a solidified strip product delivered downwardly from the nip between the rolls. The term “nip” is used herein to refer to the general region at which the casting rolls are closest together. The molten metal may be poured from a ladle into a smaller vessel, such as a tundish or distributor, from which it flows through to a metal delivery nozzle located above the nip, which directs the molten metal outwardly below the surface of a casting pool supported on the casting surfaces of the rolls above the nip. This casting pool is typically confined at the ends of the casting rolls by side plates or dams held in sliding engagement adjacent the ends of the casting rolls.
In casting thin strip by twin roll casting, the metal delivery nozzles typically receive molten metal from a movable tundish and deposit the molten metal in the casting pool in a desired flow pattern. Previously, various designs have been proposed for delivery nozzles involving a lower portion submerged in the casting pool during a casting campaign, and having side openings through which the molten metal is capable of flowing laterally into the casting pool outwardly toward the casting surfaces of the rolls. Examples of such metal delivery nozzles are disclosed in Japanese Patent No. 09-103855 and U.S. Pat. No. 6,012,508.
In the past, the formation of pieces of solid metal known as “skulls” in the casting pool in the vicinity of the confining side plates or dams have been observed. The rate of heat loss from the casting pool is higher near the side dams (called the “triple point region”) due to conductive heat transfer through the side dams to the casting roll ends. This localized heat loss near the side dams has a tendency to form “skulls” of solid metal in that region, which can grow to a considerable size and fall between the casting rolls and causing defects in the cast strip. An increased flow of molten metal to these “triple point” regions, the regions near the side dams, have been provided by separate direct flows of molten metal to these triple point regions. Examples of such proposals may be seen in U.S. Pat. No. 4,694,887 and in U.S. Pat. No. 5,221,511. Increased heat input to these triple point regions has inhibited formation of skulls.
Moreover, Australian Patent Application 60773/96 discloses a method and apparatus in which molten metal is delivered to the delivery nozzle in a trough closed at the bottom. Side openings are provided through which the molten metal flows laterally from the delivery nozzle into a casting pool in the vicinity of the casting pool surface. However, in such metal delivery nozzles, there has been a tendency to produce thin cast strip that contains defects known as ridges. Further, there has been concern for extending the useful life of the delivery nozzles and in turn reducing the cost of producing thin cast strip. Specifically, there remained concern for wear on the delivery nozzle caused by the impact of the molten metal due to ferrostatic pressure, and turbulence caused as the molten metal moved through the delivery nozzle to discharge laterally into the casting pool below the meniscus of the casting pool.
The present invention provides an apparatus and method for continuous thin strip casting that is capable of substantially reducing and inhibiting such defects such as ridges in the cast strip, and at the same time reducing wear in the delivery nozzles and costs in thin strip casting. By testing, we have found that a major cause of such strip defects is thinning of the shells during casting caused by localized washing of solidified shells during formation from over flow of the molten metal into the casting pool. We have found by changing the delivery nozzle that the flow of molten metal to an upward flow into the casting pool that there is less potential to cause thinning of the solidified metal shell during formation. This improved flow from the delivery nozzle into the casting pool is particularly notable in the region where the casting pool meets the casting surfaces of the rolls, generally known as the “meniscus” or “meniscus regions” of the casting pool.
Disclosed is a method of casting metal strip comprising:
Also disclosed is a metal delivery apparatus for casting metal strip comprising at least one elongated segment having a main portion and an inner trough extending longitudinally through the main portion with end walls at opposite ends thereof, the inner trough communicating with outlets along opposite sides of each segment adapted to upwardly discharge a flow of molten metal into a casting pool.
The outlets in the method of casting metal strip and of the metal delivery apparatus may have an upward directional discharge angle between 15 degrees and 45 degrees or between 20 degrees and 30 degrees from horizontal. Also, the outlets in the method of casting metal strip and of the metal delivery apparatus may have a discharge with a lateral spread angle between 0 degrees and 30 degrees or between 5 degrees and 15 degrees.
The outlets of the metal delivery apparatus may be offset along opposite sides of the segment and may overlap in longitudinal position. This offset and overlap of the outlets on opposite sides of the segment of the metal delivery nozzle provided further potential for lessening of thinning of the metal shells during formation on the casting rolls and produce less defects in the cast strip.
The at least one segment may have an inner trough extending longitudinally through the main portion with end walls at opposite ends thereof, the inner trough communicating with outlets along opposite sides of each segment.
The outlets may extend to adjacent the end of each segment and may have an end portion with the inner trough extending into the end portion, the end portion having a reservoir portion having passages adapted to deliver molten metal to a casting pool near side dams. This increased flow of molten metal to these “triple point” regions, the regions near the side dams, have been provided by separate direct flows of molten metal to these triple point regions and inhibits formation of “skulls” in the casting pool.
Various aspects of the invention will be apparent from the following detailed description, drawings, and claims.
The invention is described in more detail in reference to the accompanying drawings in which:
a illustrates a cross-sectional end view of a portion of twin roll strip caster with an assembled metal delivery nozzle;
b is an enlarged view of a portion of twin roll strip caster similar to
Referring to
The delivery nozzle 10 includes segments 13, each supported to receive molten metal from the tundish 4. Each segment 13 has an upward opening inner trough 14 to assist in breaking and redirecting the impact of incoming molten metal to the delivery nozzle. As shown, the inner trough 14 of each segment 13 is formed with the bottom portion 21 having a convex upper surface to keep molten metal from pooling in the inner trough during breaks in the flow of molten metal. The flow of molten metal from the inner trough 14 of each segment, communicates with outlets 20 to the casting pool 8, through passages 16.
There is shown in
Referring to
In operation, molten metal is poured from the metal distributor 4 through shroud 5 into the inner trough 14 of the segments 13 of the delivery nozzle 10. Several shrouds 5 may be provided along the length of the segments 13 of the delivery nozzle 10. The molten metal flows from the inner trough 14 into the outlets 20 in this embodiment through passages 16. In some alternative embodiments, passage 16 may be shortened, changed, or be unnecessary, as desired, to provide flow of molten metal from the inner trough 14 to the outlets 20. In any case, the outlets 20 direct the flow of molten metal to discharge the molten metal upwardly laterally into the casting pool 8 in the direction of the meniscus between the surface 8A of the casting pool 8 and the casting surfaces 7 of the casting rolls 6 as explained in more detail below.
As shown in
Referring to
Referring to
Referring to
In each of the embodiments described above, the pair of segments 13 may be assembled lengthwise with the segment end walls 19 in abutting relation and the end portions 18 forming the outer ends of the segment 13 and delivery nozzle 10. Alternatively, delivery nozzle 10 may comprise a single segment 13, or more than two segments 13, that include all the features of, and effectively functions as, the pair of segments 13 as described herein. Further, segment 13 may include partitions 28, extending between segment side walls 15 to strengthen segment 13 under load of molten metal during a casting campaign. As shown in
Referring to
In the embodiment shown in
In the embodiment shown in
Referring now to
This embodiment of the delivery nozzle 10, including the nozzle insert 34 supported on the segment 13, directs a substantial portion of the incoming flow of molten metal from the metal distributor 4 to a substantially planar bottom inner trough 14 of the delivery nozzle 10, thereby increasing the useful life of the delivery nozzle 10 from the impact of incoming molten metal and reducing the amount of turbulence and disturbances in flow of molten metal adjacent the inlets to passages 16. Further, in this embodiment, the nozzle insert 34 provides for a greater reception area in the segment for the flow of molten metal, and thus further reduces the impact of the flow upon the segment 13 and reduces the risk for misaligned streams from the flow to cause unintended disturbances in the casting pool 8.
The nozzle insert 34 may include opposing side walls 36 that extend beyond the segment side walls 15 when the nozzle insert 34 is disposed within the segment 13. Additionally, the sidewalls flare beyond the top edges of the segment side walls 15 such that the upper surfaces may extend over at least a portion of the top of the segment side walls 15. As shown, the upper surfaces fully extend beyond the segment side walls 15.
The nozzle insert 34 has opposing side walls, which extend lengthwise along the nozzle insert 34 in the longitudinal direction of nozzle insert 34 and define a channel for the flow of molten metal from the metal distributor 4 to the inner trough 14 of the segment 13. The nozzle insert 34 includes end walls and is dimensioned to fit with upper parts of segment side walls 15 forming inner trough 14 through the main portion 17 and into the end portion 18 for support as described below. The nozzle insert 34 may be made of any refractory material, such as alumina graphite, the material of the segment 13 or any other material suitable for guiding the flow of incoming molten metal.
A pair of support members 35 may be placed in the bottom of the inner trough 14. The nozzle insert 34 is then placed above and generally within the inner trough 14 supported by the support members 35 and the segment side walls 15. During the casting process molten metal is then discharged by the metal distributor 4 through the nozzle insert 34 into inner trough 14 of the segments 13 of the delivery nozzle 10. The molten metal flows from the inner trough 14 into the passages 16, or the holes 31, and upwardly and outwardly through the side outlets 20 adjacent bottom portions 21 of the segment 13 into the casting pool 8 below the meniscus.
The nozzle insert 34 is disposed above and may be within the inner trough 14. The nozzle insert 34 is supported relative to the segment 13 by the segment side walls 15 and a pair of support members 35. The pair of support members 35 space the nozzle insert 34 apart from the bottom of the inner trough 14 to provide space for the flow of molten metal into the passages 16, while dampening the flow of molten metal in the inner trough 14 of the segments 13 of the delivery nozzle. It must be understood, however, that the nozzle insert 34 may be supported relative to the segment 13 in any suitable manner. The nozzle insert 34 may be supported by portions of the segment 13, supported by any number of support members 35 engaging the segment 13, a combination thereof, or by a separate support from or engaging the segment 13, capable of supporting the nozzle insert 34 relative to the segment 13.
The end wall or side walls of each nozzle insert 34 may act as a weir to separate the flow of molten metal into the reservoir 24. Thus, it is contemplated that such an arrangement may not include the weir(s) 25, as shown in
There is shown in
There is shown in
To explain, with the previous metal delivery nozzle, the liquid metal exiting the nozzle outlets is directed to flow laterally in a direction toward the casting surface 7 of the casting rolls 6. In this circumstance, the liquid metal flowing from the nozzle impacting the casting surface 7 of the casting roll 6 may retard the shell growth rate, relative to cooler residual liquid metal of the casting pool 8, and may even reduce shell thickness in localized areas. Thinner shells in these localized areas may allow bulging of the cast strip below the nip and create a ridge profile on the cast strip.
The metal delivery nozzle shown in and described relative to
The casting roll surface 7 described relative to
While the principle and mode of operation of this invention have been explained and illustrated with regard to particular embodiments, it must be understood, however, that this invention may be practiced otherwise than as specifically explained and illustrated without departing from its spirit or scope.
This application is a divisional application of and claims priority to and the benefit of U.S. Pat. No. 8,225,845, filed Dec. 4, 2009, the disclosure of which is incorporated herein by reference.
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Number | Date | Country |
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2003266155 | Sep 2003 | JP |
100308831 | Jan 2002 | KR |
02085558 | Oct 2002 | WO |
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Entry |
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Abstract of Japanese Publication No. 2003-266155 (Machine Translated to English), Sep. 24, 2003. |
Abstract of Korean Publication No. 10-0308831 (Machine Translated to English), Sep. 3, 2001. |
Number | Date | Country | |
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20120305211 A1 | Dec 2012 | US |
Number | Date | Country | |
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Parent | 12631280 | Dec 2009 | US |
Child | 13533423 | US |