A partial SEN capable of having flow diverter parts installed therein, and a method of using the SEN in a continuous casting system are disclosed. The partial SEN includes a hollow distribution zone at a bottom portion of the SEN which is designed to allow the installation of at least two different types of flow diverter parts, one type of flow diverter parts for a first type of caster mold, and a second type of flow diverter parts for a second type of caster mold. The design of the flow diverter parts and the resulting angles achieved when the flow diverter parts are installed in the partial SEN are matched to a caster mold such that the flow characteristics of molten steel exiting the SEN into the caster mold during continuous casting operation are of a desired and optimal nature to prevent various types of casting defects.
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1. A method of preparing a continuous casting system for continuous casting of liquid metal to form a metal strand having a desired width, said method comprising:
selecting one type of flow diverter parts from at least two different types of flow diverter parts, each type of flow diverter parts corresponding to a different type of caster mold having a different width dimension;
providing a partial submerged entry nozzle (SEN) for a continuous casting system comprising an inlet capable of receiving an incoming flow of molten steel from a tundish, a distribution zone, and a body having a bore, the SEN transitioning along the length of the body from a substantially circular geometry to a substantially rectangular geometry having opposing side walls and opposing front and back walls at said distribution zone;
installing said selected type of flow diverter parts into the distribution zone of the partial SEN to assemble the SEN to provide in the distribution zone of the assembled SEN passageways for secondary flows formed at least partially by said flow diverter parts, wherein said flow diverter parts comprise at least a flow divider, a first diffuser, and a second diffuser, wherein said flow divider is installed upstream of said first diffuser and said second diffuser, and said flow diverter is configured to divide said liquid metal into a first stream and a second stream of liquid metal in said distribution zone, and wherein said first diffuser and said second diffuser are installed downstream of said flow diverter, said first diffuser is configured to further divide said first stream near a first exit port, and said second diffuser is configured to further divide said second stream near a second exit port; and
installing said SEN between a tundish and a caster mold of a liquid metal continuous casting system such that said selected type of flow diverter parts provide desired flow characteristics for molten metal.
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U.S. Provisional Patent Application Ser. No. 60/594,665, which was filed on Apr. 27, 2005, is incorporated herein by reference in its entirety. U.S. Pat. No. 5,944,261, which issued on Aug. 31, 1999, is incorporated herein by reference in its entirety. U.S. Pat. No. 6,027,051, which issued on Feb. 22, 2000, is incorporated herein by reference in its entirety.
In the continuous casting method of manufacturing steel, molten (liquid) steel from the steel-making operation or ladle metallurgy step is cast directly by a casting machine into semi-finished shapes (slabs, blooms, and billets). The terms “molten” and “liquid” are used interchangeably herein. The semi-finished shape is determined by the casting machine mold which receives the molten steel from a tundish and casts the steel into a steel strand with a molten inner core and an outer surface solidified by primary (water jacket) cooling within the mold. The strand is further subjected to secondary cooling upon exit from the mold until the entire strand is solidified at the time it is cut into slabs, blooms, or billets at the exit of the casting machine.
In the continuous casting process, the molten steel from the tundish flows into the mold through a submerged entry nozzle (SEN), which is connected to the outlet of the tundish, and the tundish is positioned so as to place the SEN into the mold to a selected depth. The flow of the molten steel from the tundish is gravity driven by the pressure difference between the liquid levels of the tundish and that at the top free surface of the mold. The flow is controlled by a stopper rod which partially blocks the tundish exit port, or a slide gate that moves across the inlet port of the SEN. As the steel enters the mold, the steel freezes against the water cooled walls and begins to form a shell, which is continuously withdrawn at the casting speed to produce the steel strand.
In such a process, the flow dynamics of the molten steel moving from the tundish to the mold can affect the quality of the continuous cast steel. The outlet ports of the SEN are below the liquid level in the mold. Turbulence and other transient phenomena in the molten steel exiting from the SEN into the mold may produce oxide inclusions and argon bubbles which other type inclusions may attach to, or high flow velocities may shear off droplets of mold slag into the steel flow where they become entrained in the liquid steel. Similarly, foreign particles trapped at the mold meniscus can similarly be entrained in the steel and generate surface defects and surface cracks. All of these produce inclusions that are product defects and result in product rejection and loss of manufacturing efficiency.
Such problems have a greater effect in thin slab casting, where inclusion entrapment due to the SEN-to-mold flow patterns occurs with a higher event frequency than in thick slab casting. This is due primarily to the thinner dimensions of the thin slab mold which require a higher flow velocity from a smaller geometry inlet nozzle to cast thin slab at the same throughput rate as thick slab. With thin slab casting, which is also known as Compact Strip Production, or CSP, the caster mold is too thin to permit a satisfactory submerged positioning of the nozzle inside the mold cavity. It is typically physically impossible for a CSP caster mold to accept a round SEN due to the narrow rectangular dimensions of the mold. Therefore, it is generally accepted by those skilled in the art of casting in a thin slab caster that the nozzle of the SEN has to be rectangular in shape to fit inside the mold.
An SEN may be manufactured having flow diverter parts such as flow dividers and baffles or flow diffusers in order to control the flow characteristics of the molten steel from the SEN into the mold. However, desired flow characteristics may be different for different types of molds.
Further limitations and disadvantages of conventional, traditional, and proposed approaches will become apparent to one of skill in the art, through comparison of such systems and methods with the present invention as set forth in the remainder of the present application with reference to the drawings.
A first embodiment of the present invention provides a submerged entry nozzle (SEN) for flowing liquid metal therethrough. The SEN comprises an elongated bore having an inner surface defining at least one entry port at a top portion of the SEN and a hollow distribution zone at a bottom portion of the SEN. The hollow distribution zone is adapted to allow installation of any type of at least two different types of flow diverter parts corresponding to at least two different types of caster mold types having different width dimensions and which may be used for continuous casting of the liquid metal.
Another embodiment of the present invention comprises a method of preparing a continuous casting system for continuous casting of liquid metal to form a metal strand having a desired width. The method comprises selecting one type of flow diverter parts from at least two different types of flow diverter parts, where each type of flow diverter parts corresponds to a different type of caster mold having a different width dimension. The method further comprises installing the selected type of flow diverter parts into a hollow distribution zone of a bottom portion of a partial SEN to form a fully-assembled SEN. The method also comprises installing the fully-assembled SEN between a tundish and a caster mold of a liquid metal continuous casting system such that a width dimension of the caster mold matches an angle characteristic of the selected type of flow diverter parts.
A further embodiment of the present invention comprises a method of performing continuous casting of liquid metal. The method comprises directing a flow of the liquid metal from a ladle into a tundish. The method further comprises directing the flow of the liquid metal from the tundish into at least one entry port at a top portion of a submerged entry nozzle (SEN). The SEN includes at least one installable flow diverter part installed in a hollow distribution zone at a bottom portion of the SEN forming at least two exit ports that allow the liquid metal to flow out of the exit ports at angles determined by the at least one installable flow diverter part. The method also comprises directing the flow of the liquid metal out of the at least two exit ports and into a caster mold. The caster mold has a width dimension that is matched to the angles determined by the at least one installable flow diverter part.
These and other advantages and novel features of the present invention, as well as details of an illustrated embodiment thereof, will be more fully understood from the following description and drawings.
The SEN 100 is manufactured without any flow diverter parts or with only a partial set of permanently installed flow diverter parts (referred to as a partial SEN) but with the capability of having different types of flow diverter parts installed before use in a continuous casting system. When flow diverter parts are installed in the partial SEN, the partial SEN becomes a fully-assembled SEN. The different types of flow diverter parts are designed to be matched to different types of caster molds that may be used in the continuous casting system for manufacturing different dimensions of steel slab, etc. In particular, any given type of flow diverter parts are designed such that the flow characteristics of the liquid metal (e.g., molten steel) out of the SEN and into a corresponding caster mold are such that the problems described in the background section herein are minimized. As a result, a common or universal partial SEN may be manufactured which is adaptable to different types of molds by installing the corresponding matched flow diverter parts after a decision is made as to which type of metal slabs to manufacture (e.g., deciding the width dimension of the steel slabs to manufacture today).
Dividing the stream into passageways for secondary lateral streams enables greater control of the steel exiting the ports 320 and 330, formed by the bottom portion of the SEN 100 and the flow diverter 150, when combined by the stream concentration, which has occurred upstream in the SEN 100. Each stream 311 and 312 has a uniform and laminar flow characteristic to aid in effectively producing a consistent stream at both lateral streams inside the caster mold.
To ensure that the correct stream orientations are effected downstream of the first lateral division of the concentrated flow 310 and the point 151 of the flow divider 150, one or more diffusers or baffles 160 and 170 are located upstream of the exit ports 320 and 330 to further divide the streams into upper lateral and lower lateral portions at each exit port. The diffusers 160 and 170 act to ensure that the steel stream has intimate contact with the exit port surfaces when exiting the SEN 100 to further separate and guide the streams through the distribution zone 145 to the exit ports 320 and 330.
The orientation (angle, location, and shape) of the flow diverter parts 150, 160, and 170 are specifically designed to ensure that each caster mold requirement may be optimized and, therefore, is designed differently for each application. In accordance with various embodiments of the present invention, the flow diffusers 160 and 170 may be downstream of the point 151 or may be upstream of the point 151. Various other flow diverter configurations are possible, as well, in accordance with various embodiments of the present invention (e.g., see U.S. Pat. No. 5,944,261 and U.S. Pat. No. 6,027,051). Again, the decision as to which type of flow diverter parts to install may be made after the partial SEN 100 is made and just before continuous casting of a steel strip commences.
In accordance with various alternative embodiments of the present invention, the flow diffusers (e.g., 160 and 170) may not be installable but the flow divider (e.g., 150) is installable. That is, the flow diffusers may be a permanent part of the partial SEN and only the flow divider is selected to be installed. Also, the SEN may not require any flow diffusers and may only use an installable flow divider. As a result, there may not be any permanent or installable flow diffusers for a particular SEN design. Such a design may be acceptable when a corresponding flow divider accomplishes the vast majority of the desired flow characteristics.
A method of preparing the continuous casting system 700 of
For example, the partial SEN 100 is capable of having flow diverter parts 150, 160, and 170 installed as well as flow diverter parts 610, 620, and 630, but not at the same time. In order for the system 700 to be used with the caster mold 730, the partial SEN 100 is used and the flow diverter parts 150, 160, and 170 are selected because they are matched to the caster mold 730. That is, the flow diverter parts 150, 160, and 170, when installed in the partial SEN 100, will provide the proper flow characteristics of molten steel to the caster mold 730 based on the width dimension 731 of the caster mold 730. As a result, problems such as inclusion entrapment as described in the background section herein, as well as other problems, may be avoided. If a second caster mold having a different width dimension is used, the flow diverter parts 610, 620, and 630 may be installed in a partial SEN 100 and used in the system 700 to make steel strand of a different width dimension. Again, the flow diverter parts are matched to the second caster mold.
In accordance with the various embodiments of the present invention, the flow diverter parts may be installed in the SEN either before or after installing the SEN in the tundish to provide maximum flexibility of installation during use.
A method of performing continuous casting of liquid metal using the system 700 of
In summary, certain embodiments of the present invention provide a partial SEN having a hollow distribution zone into which flow diverter parts such as flow dividers and flow diffusers or baffles may be installed. Installed flow diverter parts are selected to match to a caster mold to be used in a continuous casting process of liquid metal. The partial SEN may be capable of having any of a number of different types of flow diverter parts installed, each type of flow diverter parts matching to a different type of caster mold having a different width dimension. Matching a type of flow diverter parts to a type of caster mold results in achieving desired flow characteristics of the liquid metal as the liquid metal transitions from the SEN into the caster mold.
While the invention has been described with reference to certain embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its scope. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
Hanna, Robert C., Teeter, Kirby Joe
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