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A method of and apparatus for localized control of heat flux in continuous casting of thin cast strip comprising removing oxides from the casting surface of each casting roll by contacting the casting surface of each casting roll with the rotating brush in advance of the casting area, and delivering

A method of and apparatus for localized control of heat flux in continuous casting of thin cast strip comprising removing oxides from the casting surface of each casting roll by contacting the casting surface of each casting roll with the rotating brush in advance of the casting area, and delivering gas at the casting surface between the rotating brush and entry to the casting area to form a gas layer on the casting surface of each casting roll where the oxides have been removed. The delivering of gas at the casting surface between the rotating brush and entry to the casting area is preferably done in at least three zones along the casting roll axes to form a gas layer on the casting surface of each casting roll where the oxides have been removed, where the gas projected in the respective zones can be of different composition, mixture, pressure, or combination thereof.

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What is claimed is: 1. A method of localized control of heat flux in continuous casting of thin cast strip comprising the steps of: assembling a pair of counter-rotating casting rolls laterally to form a nip between circumferential casting surfaces of the rolls through which metal strip may be cast

What is claimed is: 1. A method of localized control of heat flux in continuous casting of thin cast strip comprising the steps of: assembling a pair of counter-rotating casting rolls laterally to form a nip between circumferential casting surfaces of the rolls through which metal strip may be cast; forming a casting pool of molten metal supported on the casting surfaces of the casting rolls above the nip to form a casting area; assembling a rotating brush peripherally to contact the casting surface of each casting roll in advance of contact of the casting surfaces with the molten metal in the casting area; removing oxides from the casting surface of each casting roll by contacting the casting surface of each casting roll with the rotating brush; delivering gas at the casting surface adjacent the rotating brush to form a gas layer on the casting surface of each casting roll where the oxides have been removed; and counter-rotating the casting rolls such that the casting surfaces of the casting rolls each travel toward the nip to produce a cast strip downwardly from the nip. 2. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 1 wherein: the delivering of the gas on the casting surface of each casting roll is adjacent the nip formed between the rotating cleaning brush and the casting surface of the casting roll. 3. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 1 wherein: the step of delivering gas at the casting surface of each casting roll to replace the removed oxides comprises flooding the casting surfaces adjacent the rotating brushes with the gas. 4. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 1 wherein: the step of delivering the gas to form a gas layer comprises introducing the gas into a housing provided about the rotating brush. 5. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 1 wherein: the casting surfaces of the casting rolls are textured with a random distribution of discrete projections. 6. The method of localized control of heat flux the localized heat flux in continuous casting of thin cast strip as claimed in claim 1 wherein: the gas comprises at least one gas selected from the group consisting of nitrogen, argon, hydrogen, helium, water vapor, dry air, carbon monoxide, carbon dioxide or a mixture of two or more thereof. 7. A method of localized control of heat flux in continuous casting of thin cast strip comprising the steps of: assembling a pair of counter-rotating casting rolls laterally to form a nip between circumferential casting surfaces of the rolls through which metal strip may be cast; forming a casting pool of molten metal supported on the casting surfaces of the casting rolls above the nip to form a casting area; assembling a rotating brush peripherally to contact the casting surface of each casting roll in advance of contact of the casting surfaces with the molten metal in a casting area; removing oxides from the casting surface of each casting roll by contacting the casting surface of each casting roll with the rotating brush; delivering gas at the casting surface adjacent the rotating brush in at least three zones extending along the casting surfaces of the casting rolls to form a gas layer on the casting surface of each casting roll where the oxides have been removed; and counter-rotating the casting rolls such that the casting surfaces of the casting rolls each travel toward the nip to produce a cast strip downwardly from the nip. 8. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 7 wherein: where the gas projected in the respective said at least three zones is different in composition, mixture, pressure, or at least two thereof. 9. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 7 wherein: at least five zones are provided extending along the casting surfaces of the casting rolls. 10. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 8 wherein: the delivering of the gas on the casting surface of each casting roll is adjacent the nip formed between the rotating cleaning brush and the casting surface of the casting roll. 11. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 8 wherein: the step of delivering gas on the casting surface of each casting roll to replace the removed oxides comprises flooding the casting surfaces adjacent the rotating brushes with a gas. 12. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 8 wherein: the step of delivering the gas to form a gas layer comprises introducing the gas into a housing provided about the rotating brush. 13. The method of localized control of heat flux in continuous casting of thin cast strip as claimed in claim 8 wherein: the casting surfaces of the casting rolls are textured with a random distribution of discrete projections. 14. The method of localized control of heat flux the localized heat flux in continuous casting of thin cast strip as claimed in claim 8 wherein: the gas comprises at least one gas selected from the group consisting of nitrogen, argon, hydrogen, helium, water vapor, dry air, carbon monoxide, carbon dioxide or a mixture of two or more thereof. 15. An apparatus for continuously casting thin cast strip with localized heat flux control comprising: a pair of counter-rotating casting rolls having circumferential casting surfaces laterally spaced to form a nip therebetween through which thin cast strip may be discharged downwardly, and capable of supporting a casting pool of molten metal on the circumferential casting surfaces adjacent the nip to form a casting area; rotating brushes capable of removing oxides from the casting surfaces of each casting roll positioned to remove such oxides from the casting surfaces in an area away from a casting area; and gas nozzles positioned along the casting surfaces of the casting rolls capable of directing gas on the casting surface of each casting roll adjacent the rotating brush to form a gas layer where oxides have been removed from the casting surfaces of the casting rolls. 16. The apparatus for continuously casting thin cast strip with localized heat flux control as claimed in claim 15 wherein: the gas nozzles are capable of delivering the gas on the casting surface of each casting roll adjacent the nip formed between the rotating cleaning brush and the casting surface of the casting roll. 17. The apparatus for continuously casting thin cast strip with localized heat flux control as claimed in claim 15 wherein: the gas nozzles are capable flooding the casting surfaces adjacent the rotating brushes with a gas. 18. The apparatus for continuously casting thin cast strip with localized control of heat flux as claimed in claim 15 comprising in addition: a housing about the rotating brush, and the gas nozzle is capable of delivering the gas to form a gas layer is introduced through the housing. 19. The apparatus for continuously casting thin cast strip with localized control of heat flux as claimed in claim 15 wherein: the casting surfaces of the casting rolls are textured with a random distribution of discrete projections. 20. The apparatus for continuously casting thin cast strip with localized control of heat flux as claimed in claim 15 wherein: the gas comprises at least one gas selected from the group consisting of nitrogen, argon, hydrogen, helium, water vapor, dry air, carbon monoxide, carbon dioxide or a mixture of two or more thereof. 21. The apparatus for continuously casting thin cast strip with localized control of heat flux as claimed in claim 15 comprising in addition a control system comprising: hydraulic motors capable of controlling the contact of the brush with the casting surface of each casting roll in advance of the casting area; and a monitoring device capable of monitoring the torque of the hydraulic motors to control the energy exerted by the rotating brushes against the casting surfaces of the casting rolls using the desired degree of cleaning as a reference to clean the expose a majority of projections of the casting surfaces of the casting rolls and provide wetting contact between the casting surface and the molten metal of the casting area. 22. The apparatus for continuously casting thin cast strip with control of localized heat flux as claimed in claim 21 where the monitoring device is capable of monitoring the torque of the hydraulic motors by measuring the pressure differential between inlet and outlet of hydraulic fluid through the hydraulic motors. 23. The apparatus for continuously casting thin cast strip with control of localized heat flux as claimed in claim 21 where the monitoring device is capable of measuring the torque between the hydraulic motor and a chock or a motor mount. 24. An apparatus for continuously casting thin cast strip with localized heat flux control comprising: counter-rotating casting rolls having circumferential casting surfaces laterally spaced to form a nip therebetween through which thin cast strip may be discharged downwardly, and capable of supporting a casting pool on the circumferential casting surfaces adjacent the nip enclosed to form a casting area; rotating brushes capable of removing oxides from the casting surfaces of each casting roll positioned to remove such oxides from the casting surfaces in an area away from the casting area; and gas nozzles capable of delivering gas at the casting surface adjacent the rotating brush in at least three zones extending along the casting surface of each casting roll to form a gas layer on the casting surface of each casting roll where the oxides have been removed. 25. The apparatus for continuously casting thin cast strip with localized heat flux control as claimed in claim 24 wherein: the gas nozzles are capable of delivering in the respective said at least three zones different composition, mixture, pressure, or at least two thereof. 26. The apparatus for continuously casting thin cast strip with localized heat flux control as claimed in claim 24 wherein: the gas nozzles are capable of delivering the gas on the casting surface in at least five zones along the axes of the casting rolls. 27. The apparatus for continuously casting thin cast strip with localized heat flux control as claimed in claim 24 wherein: the gas nozzles are capable of delivering of the gas on the casting surface of each casting roll adjacent the nip formed between the rotating cleaning brush and the casting surface of the casting roll. 28. The apparatus for continuously casting thin cast strip with localized heat flux control as claimed in claim 24 wherein: the gas nozzles are capable flooding the casting surfaces adjacent the rotating brushes with a gas. 29. The apparatus for continuously casting thin cast strip with localized control of heat flux as claimed in claim 24 comprising in addition: a housing about the rotating brush, and the gas nozzle is capable of delivering the gas to form a gas layer introduced through the housing. 30. The apparatus for continuously casting thin cast strip with localized control of heat flux as claimed in claim 24 wherein: the casting surfaces of the casting rolls are textured with a random distribution of discrete projections. 31. The apparatus for continuously casting thin cast strip with localized control of heat flux as claimed in claim 24 wherein: the gas comprises at least one gas selected for the group consisting of: nitrogen, argon, hydrogen, helium, water vapor, dry air, carbon monoxide, carbon dioxide or a mixture of two or more thereof. 32. The apparatus for continuously casting thin cast strip with control heat flux as claimed in claim 24 comprising in addition a the control system comprising: hydraulic motors capable of controlling the contact the casting surface of each casting roll with a rotating brush in advance of contact of the casting surfaces with the molten metal in the casting area; and a monitoring device capable of monitoring the hydraulic motors to control the energy exerted by the rotating brushes against the casting surfaces of the casting rolls using the desired degree of cleaning as a reference to clean the expose a majority of projections of the casting surfaces of the casting rolls and provide wetting contact between the casting surface and the molten metal of the casting area. 33. The apparatus for continuously casting thin cast strip claimed in claim 32 where the monitoring device is capable of monitoring the torque of the hydraulic motors by measuring the pressure differential between inlet and outlet of hydraulic fluid through the hydraulic motors. 34. The apparatus for continuously casting thin cast strip claimed in claim 32 where the monitoring device is capable of measuring the torque between the hydraulic motor and a chock or a motor mount.