The present disclosure generally relates to metal making. In particular, it relates to an electromagnetic brake system for a metal-making process and to a method of controlling molten metal flow in a metal-making process.
In metal-making, for example steelmaking, metal can be produced from iron ore in a blast-furnace and converter or as scrap metal and/or direct reduced iron, melted in an electric arc furnace (EAF). The molten metal may be tapped from the EAF to one or more metallurgical vessels, for example to a ladle and further to a tundish. The molten metal may in this manner undergo suitable treatment, both in respect of obtaining the correct temperature for molding, and for alloying and/or degassing, prior to the molding process.
When the molten metal has been treated in the above-described manner, it may be discharged through a submerged entry nozzle (SEN) into a mold, typically an open-base mold. The molten metal partially solidifies in the mold. The solidified metal that exits the base of the mold is further cooled as it passed between a plurality of rollers in a spray-chamber.
As the molten metal is discharged into the mold, undesired turbulent molten metal flow around the meniscus may occur. This flow may lead to slag entrainment due to excessive surface velocity or to surface defects due to surface stagnation or level fluctuations. Further defects may be caused by non-metallic inclusions from previous process steps that are not able to surface and be secluded by the slag layer on top of the meniscus.
In order to control the fluid flow and affect the conditions for stable and clean solidification of the metal, the mold may be provided with an electromagnetic brake (EMBr). The EMBr comprises a magnetic core arrangement which has a number or teeth, and which magnetic core arrangement extends along the long sides of the mold. The EMBr is beneficially arranged in level with the SEN, i.e. at the upper portion of the mold. A respective coil, sometimes referred to as a partial coil, is wound around each tooth. These coils may be connected to a drive that is arranged to feed the coils with a direct (DC) current. A static magnetic field is thereby created in the molten metal. The static magnetic field acts as a brake and a stabilizer for the molten metal. The flow at the upper regions, close to the meniscus of the molten metal, may thereby be controlled. As a result, better surface conditions may be obtained.
WO2016078718 discloses an electromagnetic brake system for a metal-making process. The electromagnetic brake system comprises a first magnetic core arrangement having a first long side and a second long side, which first long side has Nc teeth and which second long side has Nc teeth, wherein the first long side and the second long side are arranged to be mounted to opposite longitudinal sides of an upper portion of a mold, a first set of coils, wherein the first set of coils comprises 2Nc coils, each coil being wound around a respective tooth of the first magnetic core arrangement, and Np power converters, with Np being an integer that is at least two and Nc is an integer that is at least four and evenly divisible with Np, wherein each power converter is connected to a respective group of 2Nc/Np series-connected coils of the first set of coils, and wherein each of the Np power converters is configured to feed a DC current to its respective group of 2Nc/Np series-connected coils. This disclosure further relates to a method of controlling molten metal flow in a metal-making process.
The utilization of the electromagnetic brake system in itself does however not provide optimal fluid flow control of the molten metal near the meniscus, along the entire width of the mold.
Thorough quality investigations of steel quality in slabs promote the usage of double roll flow in slab casting for optimal inclusion removal. This flow pattern guides the jet from the SEN nozzle to the narrow face of the mold, then upward toward the meniscus surface after which the upper recirculation loop follows the meniscus from the narrow face toward the SEN. Depending on casting conditions, this flow pattern is more or less difficult to achieve.
In view of the above, an object of the present disclosure is to provide an electromagnetic brake system and a method of controlling molten metal flow in a metal-making process which solves or at least mitigates the problems of the prior art.
There is hence according to a first aspect of the present disclosure provided an electromagnetic brake system for a metal-making process, wherein the electromagnetic brake system comprises: an upper magnetic core structure having a first long side and a second long side, wherein the first long side and the second long side are configured to be mounted to opposite longitudinal sides of an upper portion of a mold, each of the first long side and the second long side being provided with a plurality of first teeth, a lower magnetic core structure having a third long side and a fourth long side, wherein the third long side and the fourth long side are configured to be mounted to opposite longitudinal sides of a lower portion of a mold, each of the third long side and the fourth long side being provided with a plurality of second teeth, wherein the upper magnetic core structure and the lower magnetic core structure are magnetically decoupled, lateral coils wound around respective lateral first teeth of the first long side and the second long side, wherein the lateral coils wound around oppositely arranged lateral first teeth of a first end of the first long side and the second long side form a first lateral coil set and the lateral coils wound around oppositely arranged lateral first teeth of a second end of the first long side and second long side form a second lateral coil set, inner coils wound around respective first teeth located between the lateral first teeth of the first long side and the second long side, wherein a first inner coil set is formed by inner coils wound around oppositely arranged inner teeth adjacent to the first lateral coil set and a second inner coil set is formed by inner coils wound around oppositely arranged inner teeth adjacent to the second lateral coil set, lower coils wound around a respective second tooth, wherein lower coils wound around oppositely arranged lateral second teeth of a first end of the third long side and the fourth long side form a first lower coil set and lower coils wound around oppositely arranged lateral second teeth of a second end of the third long side and the fourth long side form a second lower coil set, a first power converter system configured to energize the first lateral coil set, the second lateral coil set, the first inner coil set and the second inner coil set, a second power converter system configured to energize the first lower coil set and the second lower coil set, and a control system configured to control the first power converter system to energize the first lateral coil set and the second lateral coil set to generate a first magnetic field having a first field direction, and to simultaneously control the first power converter system to energize the first inner coil set and the second inner coil set to generate a second magnetic field having a second field direction opposite to the first direction, and the control system being configured to, simultaneously as controlling the first power converter system to energize the first lateral coil set, the second lateral coil set, the first inner coil set and the second inner coil set, control the second power converter system to energize the first lower coil set and the second lower coil set to generate a third magnetic field having the first field direction.
An effect obtainable by this control of all the coil sets in combination with the magnetic decoupling of the upper magnetic core structure and the lower magnetic core structure is that a magnetic field distribution/flux density in molten metal in a mold is created where the double roll flow is pronounced for optimal final metal product quality.
According to one embodiment the number of lateral coils is at least four, the number of inner coils is at least four, and the number of lower coils is at least four.
According to one embodiment the upper magnetic core structure is mechanically separated from the lower magnetic core structure.
According to one embodiment the first power converter system is configured to energize the first lateral coil set, the second lateral coil set, the first inner coil set and the second inner coil set with DC current, and the second power converter system is configured to power the first lower coil set and the second lower coil set with a DC current.
According to one embodiment the first power converter system is configured to energize the first lateral coil set, the second lateral coil set, the first inner coil set, and the second inner coil set with AC current.
According to one embodiment the first power converter system comprises Np first power converters, where Np is an integer divisible by 4, and Nc is a total number of lateral coils and inner coils of each of the first long side and the second long side, wherein a first power converter k, with k being an integer less than or equal to Np/2 is connected to lateral coils and inner coils of the first long side according to k+Nc/Np*(i1−1) and i1=1, 2, . . . , Nc/Np and to lateral coils and inner coils of the second long side according to Nc/2+k+Nc/Np*(i2−1), where i1=1, 2, . . . , Nc/Np.
According to one embodiment a first power converter k, with k being an integer greater than Np/2 is connected to lateral coils and inner coils of the first long side according to Nc/2+k−Nc/Np+Nc/Np*(i1−1) and to lateral coils and inner coils of the second long side according to k−Nc/Np+Nc/Np*(i2−1).
According to one embodiment the second power converter system comprises two second power converters, wherein a second power converters m, where m is an integer equal to 1 or 2, is connected to a lower coil m, on the third long side and to a lower coil and to a lower coil m+(−1){circumflex over ( )}(m−1) on the fourth long side. Furthermore, a first power converter of the second power converter system (17) is configured to power the first lower coil set (18a) with a first DC current and a second power converter (17-2) of the second power converter system (17) is configured to power a second the second lower coil set (18b) with a second/different DC current.
According to one embodiment, a first set of the power converters of the first power converter system is configured to energize the first lateral coil set and the first inner coil set with a first DC current and a second set of the power converters of the first converter system is configured to energize the second lateral coil set and the second inner coil set with a second/different current.
Alternatively, when AC is connected to the first power system, a first set of the power converters of the first power converter system is configured to energize the first lateral coil set and the first inner coil set with a first AC current amplitude and a second set of the power converters of the first converter system is configured to energize the second lateral coil set and the second inner coil set with a second AC current amplitude, wherein the second AC current amplitude is different than the first amplitude.
Particularly casting in the slab format is subject to flow asymmetries in the mold due to asymmetric slide-gate positioning or inhomogeneous clogging in the SEN. Asymmetric flow conditions may lead to large variations of the metal end product quality over the solidified slab surface, e.g. the left side of the slab may contain large clusters of non-metallic inclusions due to violent meniscus behavior on this side in the mold whereas a much lower number of defects on the right side indicate a much more stable casting situation here. Due to the individual control provided by the first power converter/second power converter combination and/or third power converter/fourth power converter combination, local counter-action of asymmetric flow conditions on left and right sides of a slabs mold is enabled.
The flow situations may be different in the upper and lower regions of a mold. Hence, the required electromagnetic fields in the upper and lower regions, as well as in left and right sides, may differ. For optimal flexibility in treating this situation and counter-acting undesired flows, maximum magnetic independence of upper and lower region magnetic fields is provided by means of the individual pole pair control provided by the first power converter/second power converter for the upper mold region and the third power converter and fourth power converter for the lower mold region.
There is according to a second aspect of the present disclosure provided a method of controlling an electromagnetic brake system for a metal-making process, wherein the electromagnetic brake system comprises: an upper magnetic core structure having a first long side and a second long side, wherein the first long side and the second long side are mounted to opposite longitudinal sides of an upper portion of a mold, each of the first long side and the second long side being provided with a plurality of first teeth, a lower magnetic core structure having a third long side and a fourth long side, wherein the third long side and the fourth long side are mounted to opposite longitudinal sides of a lower portion of a mold, each of the third long side and the fourth long side being provided with a plurality of second teeth, wherein the upper magnetic core structure and the lower magnetic core structure are magnetically decoupled, lateral coils wound around respective lateral first teeth of the first long side and the second long side, wherein the lateral coils wound around oppositely arranged lateral first teeth of a first end of the first long side and the second long side form a first lateral coil set and the lateral coils wound around oppositely arranged lateral first teeth of a second end of the first long side and second long side form a second lateral coil set, inner coils wound around respective first teeth located between the lateral first teeth of the first long side and the second long side, wherein a first inner coil set is formed by inner coils wound around oppositely arranged inner teeth adjacent to the first lateral coil set and a second inner coil set is formed by inner coils wound around oppositely arranged inner teeth adjacent to the second lateral coil set, lower coils wound around a respective second tooth, wherein lower coils wound around oppositely arranged lateral second teeth of a first end of the third long side and the fourth long side form a first lower coil set and lower coils wound around oppositely arranged lateral second teeth of a second end of the third long side and the fourth long side form a second lower coil set, a first power converter system configured to energize the first lateral coil set, the second lateral coil set, the first inner coil set and the second inner coil set, a second power converter system configured to energize the first lower coil set and the second lower coil set, wherein the method comprises: a) controlling by means of a control system the first power converter system to energize the first lateral coil set and the second lateral coil set to generate a first magnetic field having a first field direction, and simultaneously controlling the first power converter system to energize the first inner coil set and the second inner coil set to generate a second magnetic field having a second field direction opposite to the first direction, and b) controlling by means of the control system, simultaneously as step a), the second power converter system to energize the first lower coil set and the second lower coil set to generate a third magnetic field having the first field direction.
According to one embodiment the upper magnetic core structure is mechanically separated from the lower magnetic core structure.
According to one embodiment in the steps a) and b) of controlling, the first power converter system is configured to energize the first lateral coil set, the second lateral coil set, the first inner coil set and the second inner coil set with DC current, and the second power converter system is configured to power the first lower coil set and the second lower coil set with a DC current.
According to one embodiment in steps a) and b) the first power converter system is configured to energize the first lateral coil set, the second lateral coil set, the first inner coil set, and the second inner coil set with AC current.
According to one embodiment the first power converter system comprises Np first power converters, where Np is an integer divisible by 4, and Nc is a total number of lateral coils and inner coils of each of the first long side and the second long side, wherein a first power converter k, with k being an integer less than or equal to Np/2 is connected to lateral coils and inner coils of the first long side according to k+Nc/Np*(i1−1) and i1=1, 2, . . . , Nc/Np and to lateral coils and inner coils of the second long side according to Nc/2+k+Nc/Np*(i2−1), where i2=1, 2, . . . , Nc/Np.
According to one embodiment a first power converter k, with k being an integer greater than Np/2 is connected to lateral coils and inner coils of the first long side according to Nc/2+k−Nc/Np+Nc/Np*(i1−1) and to lateral coils and inner coils of the second long side according to k−Nc/Np+Nc/Np*(i2−1).
According to one embodiment the second power converter system comprises two second power converters, wherein a second power converters m, where m is an integer equal to 1 or 2, is connected to a lower coil m, on the third long side and to a lower coil and to a lower coil m+(−1){circumflex over ( )}(m−1) on the fourth long side.
According to one embodiment, wherein in the steps a) and b) of controlling, the method further comprises steps of energizing the first lateral coil set and the first inner coil set with a first DC current and energizing the second lateral coil set and the second inner coil set with a second/different DC current.
According to one embodiment, wherein in the steps a) and b) of controlling, the method further comprises steps of energizing the first lower coil set with a first DC current and energizing the second lower coil set with a second/different DC current.
According to one embodiment, wherein in the steps a) and b) of controlling, the method further comprises steps of energizing the first lateral coil set and the first inner coil set with a first AC current amplitude and energizing the second lateral coil set, and the second inner coil set with a second AC current amplitude, wherein the second amplitude is different than the first amplitude.
Generally, all terms used in the claims are to be interpreted according to their ordinary meaning in the technical field, unless explicitly defined otherwise herein. All references to “a/an/the element, apparatus, component, means, etc.,” are to be interpreted openly as referring to at least one instance of the element, apparatus, component, means, etc., unless explicitly stated otherwise. Moreover, the steps of the method need not necessarily have to be carried out in the indicated order unless explicitly stated.
The specific embodiments of the inventive concept will now be described, by way of example, with reference to the accompanying drawings, in which:
The inventive concept will now be described more fully hereinafter with reference to the accompanying drawings, in which exemplifying embodiments are shown. The inventive concept may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided by way of example so that this disclosure will be thorough and complete, and will fully convey the scope of the inventive concept to those skilled in the art. Like numbers refer to like elements throughout the description.
The electromagnetic brake systems presented herein may be utilized in metal-making, more specifically in casting. Examples of metal-making processes are steelmaking and aluminum-making. The electromagnetic brake system may beneficially be utilized in for example a continuous casting process.
The electromagnetic brake system 7 includes an upper magnetic core 8 provided with coils, such as lateral coils 9-1, 9-8. The electromagnetic brake system 7 also includes a first power converter system 11 configured to power or energize the coils of the upper magnetic core 8. The first power converter system 11 may comprise one or more first power converters. The first power converter system 11 is configured to provide DC current and/or AC current to the coils of the upper magnetic core 8.
The electromagnetic brake system 7 also includes a lower magnetic core structure 13 provided with coils, such as lower coils 15-1, 15-4. The upper magnetic core 8 and the lower magnetic core structure 13 are magnetically decoupled. In particular, the upper magnetic core 8 and the lower magnetic core structure 13 are physically separate entities.
The electromagnetic brake system 7 also includes a second power converter system 17 configured to power or energize the coils of the lower magnetic core structure 13. The second power converter system 17 may comprise one or more second power converters. The second power converter system 17 is configured to provide DC current to the coils of the lower magnetic core structure 13.
The electromagnetic brake system 7 also includes a control system 19 configured to control each of the first power converter system 11 and the second power converter system 17 individually. Additionally, if the first power converter system 11 includes more than a single first power converter, the control system 19 is configured to control each one of these first power converters individually. Moreover, if the second power converter system 17 includes more than a single second power converter, the control system 19 is configured to control each one of these second power converters individually.
Each power converter of the first power converter system and the second power converter system is a current source, for example a drive, such as the ABB® DCS 800 MultiDrive.
The upper magnetic structure 8 has a first long side 8a and a second long side 8b opposite to the first long side 8a. The first long side 8a and the second long side 8b are configured to be mounted to upper portions of opposite longitudinal sides/broad faces of a mold. Each of the first long side 8a and the second long side 8b comprises a plurality of first teeth 10a-10h. In the example, first teeth 10a, 10d, 10e and 10h are lateral first teeth and first teeth 10b-c and 10f-g are inner first teeth. Lateral first teeth 10a and 10h are located at a first end of the first long side 8a and second long side 8b. Lateral first teeth 10d and 10e are located at a second end, opposite to the first end, of the first long side 8a and the second long side 8b.
As noted above, the electromagnetic brake system 7 comprises a plurality of coils, in this example for example coils 9-1 to 9-8. Lateral coils 9-1, 9-4, 9-5 and 9-8 are wound around a respective first lateral tooth 10a, 10d, 10e, and 10h. Inner coils 9-2, 9-3 and 9-6, 9-7 are wound around a respective inner tooth 10b, 10c, 10f and 10g.
In this example lateral coils 9-1 and 9-8 of the first end form a first lateral coil set 14a. Lateral coils 9-4 and 9-5 of the second end form a second coil set 14b. Inner coils 9-2, 9-7 adjacent to the first lateral coil set 14a form a first inner coil set 14c and inner coils and 9-3, 9-6 adjacent to the second lateral coil set 14b form a second inner coil set 14d.
The control system 19 is configured to control the first power converter system 11 to energize the first lateral coil set 14a and the second lateral coil set 14b to create a first magnetic field having a first field direction. The control system 19 is furthermore configured to control the first power converter system 11 to simultaneously energize the first inner coil set 14c and the second inner coil set 14d to create a second magnetic field having a second field direction opposite to the first field direction.
When in use, this provides two horizontal magnetic fields in molten metal in a mold, having opposite directions.
The electromagnetic brake system 7 also comprises a plurality of lower coils 15-1, 15-2, 15-3, 15-4 wound around a respective second tooth 16a-16d. Lower coils 15-1 and 15-4 are lateral lower coils, and are provided on oppositely arranged teeth 16a and 16d of the third long side 13a and the fourth long side 13b, respectively. They form a first lower coil set 18a. Likewise, lower coils 15-2 and 15-3 are lateral lower coils, and are provided on oppositely arranged teeth 16b and 16c of the third long side 13a and the fourth long side 13b, respectively. Lower coils 15-2 and 15-c form a second lower coil set 18b.
The control system 19 is configured to control the second power converter system 17 simultaneously as the above-described control of the first lateral coil set 14a, the second lateral coil set 14b, the first inner coil set 14c and the second inner coil set 14d, to energize the first lower coil set 18a and the second lower coil set 18b to create a third magnetic field having the first field direction. The third magnetic field hence has the same field direction as the first magnetic field provided by the upper magnetic core structure 8. In this manner, a pronounced double roll flow may be created.
All of the lateral and inner coils 9-1 to 9-8 are series-connected with each other and with the first power converter 11-1. All of the lower coils 15-1 to 15-4 are series-connected with each other and with the second power converter 17-1. By means of these connections, the above-described magnetic field distribution may be obtained using a single first power converter 11-1 to power the coils wound around the first teeth of the upper magnetic core structure 8 and a single second power converter 17-1 to power the coils wound around the second teeth of the lower magnetic core structure 13.
A general connection scheme valid when the first power converter system 11 comprises Np first power converters, where Np is an integer evenly divisible by 4 will now be described.
Nc denoted the total number of coils of each of the first long side and the second long side of the upper magnetic core structure 8. As an example, Nc is four in the set-up of
When k is an integer greater than Np/2, a first power converter k, is connected to coils of the first long side according to Nc/2+k−Nc/Np+Nc/Np*(i1−1) and to coils of the second long side according to k−Nc/Np+Nc/Np*(i2−1).
A general connection scheme for the lower coils, valid when the second power converter system 17 comprises two second power converters will now be described. According to this connection scheme, a second power converters m, where m is an integer equal to 1 or 2, is connected to a lower coil m, on the third long side and to a lower coil and to a lower coil m+(−1){circumflex over ( )}(m−1) on the fourth long side. The numbering of the coils is from the left to right along the third long side 13a and from right to left along the fourth long side 13b.
By means of these general connection schemes, a pronounced double roll flow pattern may be obtained using the previously described control of the first power converter system and the second power converter system.
Additionally, asymmetric flow control may also be provided. In particular, individual magnetic fields can be provided on the left/right side in the upper level of the mold, and independently also in the lower level of the mold, thus enabling a reactive flow control depending on the left/right and upper/lower level asymmetry of the flow pattern in the mold.
The symmetry of the magnetic fields and flow control in the upper level of the mold is independent from the type of flow control in the lower level of the mold. For example, under certain circumstances, asymmetric flow control on the left/right side in the upper level of the mold may be combined with symmetric flow control on the left/right side in the lower level of the mold or symmetric flow control in the upper level of the mold, may be combined with asymmetric flow control in the lower level of the mold. It is also possible to provide symmetric flow control on both upper and lower levels of the mold or provide independent asymmetric flow control on both upper and lower levels of the mold.
During the casting process, the flow pattern of the molten metal in the mold may display asymmetric features due to deviations from ideal conditions in the mold or upstream in the SEN, which results in inhomogeneous SEN clogging, asymmetric stopper or slide-gate positioning, or asymmetric argon injection. Even with a perfectly aligned and symmetric geometry, the turbulence of the fluid flow in the SEN and mold induces flow variations that cause asymmetric flow patterns to various extent. These asymmetric flow conditions may lead to large local variations of the metal end-product quality, e.g. the left side of a solidified slab may contain large clusters of non-metallic inclusions close to the surface due to violent meniscus behavior and mold powder entrainment on the left side.
By applying asymmetric flow control, the asymmetry in the mold flow pattern can be mitigated, thus maintaining a more stable and symmetric casting process. E.g., excessive meniscus fluctuations and flow speeds on one side of the mold can be mitigated by extra stabilization and braking in this area, or an uneven speed relationship between the SEN jets due to SEN clogging can be homogenized by applying more braking on one side of the lower portion of the mold. A homogeneous solidified end-product, and flexible and localized casting process control are among the advantages of asymmetric flow control.
In a step a) the first power converter system 11 is controlled to energize the first lateral coil set 14a and the second lateral coil set 14b to generate a first magnetic field having a first field direction, and simultaneously to control the first power converter system 11 to energize the first inner coil set 14c and the second inner coil set 14d to generate a second magnetic field having a second field direction opposite to the first direction.
Simultaneously as step a) the second power converter system 17 is controlled to energize the first lower coil set and the second lower coil set to generate a third magnetic field having the first field direction.
Asymmetric flow control is enabled by the method of controlling the electromagnetic brake system by the application of uneven currents within the power converter systems. The individual power converters in a given power converter system, may feed the coils with different DC currents and/or AC current amplitudes, thus distributing different currents to individual coils, consequently applying an uneven magnetic field distribution along a long side.
Thus, for the example shown in
Similarly,
The inventive concept has mainly been described above with reference to a few examples. However, as is readily appreciated by a person skilled in the art, other embodiments than the ones disclosed above are equally possible within the scope of the inventive concept, as defined by the appended claims.
Number | Date | Country | Kind |
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17176292 | Jun 2017 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/063987 | 5/29/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/228812 | 12/20/2018 | WO | A |
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Number | Date | Country | |
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20200156146 A1 | May 2020 | US |