Submerged nozzle with rotatable insert

The invention claimed is: 1. Submerged nozzle ( 1 ) through which molten steel can be poured from a tundish into a mould, said nozzle comprising: 1.1 a substantially tubular body ( 2 ), extending from a first end ( 3 ) to a second end ( 4 ); 1.2 a passageway ( 5 ), extending through the tubular body ( 2 ) along a longitudinal axis (A) from the first end ( 3 ) towards the second end ( 4 ); 1.3 at least one inlet port ( 6 ), opening into the passageway ( 5 ) at said the first end ( 3 ); 1.4 a plurality of outlet ports ( 8 ), opening into the passageway ( 5 ) in a region ( 7 ) adjacent to the second end ( 4 ); and 1.5 at least one rotatable insert ( 10 ); 1.6 wherein the submerged nozzle ( 1 ) with the at least one rotatable insert ( 10 ) is configured such that a molten metal entering the submerged nozzle ( 1 ) at the at least one inlet port ( 6 ) flows through the passageway ( 5 ) and around the rotatable insert ( 10 ) and exits the submerged entry nozzle ( 1 ) via the plurality of outlet ports ( 8 ), such that a rotation of the rotatable insert ( 10 ) is driven by the molten metal. 2. Submerged nozzle ( 1 ) according to claim 1 , wherein the at least one rotatable insert ( 10 ) is positioned inside the passageway ( 5 ). 3. Submerged nozzle ( 1 ) according to claim 2 , wherein the at least one rotatable insert ( 10 ) is positioned inside the passageway in a region ( 7 ) adjacent to the second end. 4. Submerged nozzle ( 1 ) according to claim 1 , wherein the at least one rotatable insert ( 10 ) rotates with respect to the substantial tubular body ( 2 ) when a fluid flows through the passageway ( 5 ). 5. Submerged nozzle ( 1 ) according to claim 1 , wherein the submerged nozzle ( 1 ) is a submerged entry nozzle (SEN) ( 1 a ) or a monotube ( 1 b ) or a submerged entry shroud (SES) ( 1 c ). 6. Submerged nozzle ( 1 ) according to claim 1 , wherein the rotatable insert ( 10 ) defines an axis of rotation ( 13 ) and comprises blades ( 11 ) with an angle between at least one surface normal ( 14 ) of the blades ( 11 ) and the axis of rotation ( 13 ) in the range of 10° to 85°. 7. Submerged nozzle ( 1 ) according to claim 6 , wherein the angle between the at least one surface normal ( 14 ) of the blades ( 11 ) and the axis of rotation ( 13 ) is in the range of 20° to 80°. 8. Submerged nozzle ( 1 ) according to claim 1 , wherein the rotatable insert ( 10 ) is in the form of a propeller with a minimum of 2 blades. 9. Submerged nozzle ( 1 ) according to claim 1 , wherein the rotatable insert ( 10 ) is in the form of a propeller with a maximum of 15 blades. 10. Submerged nozzle ( 1 ) according to claim 1 , wherein the rotatable insert ( 10 ) is in the form of a propeller having a propeller pitch of at least 50 mm. 11. Submerged nozzle ( 1 ) according to claim 10 , wherein the propeller pitch is at least 200 mm. 12. Submerged nozzle ( 1 ) according to claim 1 , wherein the rotatable insert ( 10 ) is in the form of a propeller having a propeller pitch of less than 2000 mm. 13. Submerged nozzle ( 1 ) according to claim 1 , wherein the rotatable insert ( 10 ) is made from a refractory material. 14. Submerged nozzle ( 1 ) according to claim 13 , where in refractory material is boron nitride. 15. Submerged nozzle ( 1 ) according to claim 1 , wherein the rotatable insert ( 10 ) is made from a refractory material with a maximum grain size of less than 2 mm. 16. Submerged nozzle ( 1 ) according to claim 15 , wherein the the maximum grain size is less than 0.7 mm. 17. Submerged nozzle ( 1 ) according to claim 1 , wherein the substantially tubular body ( 2 ) comprises a wear liner section ( 15 ) inside of the passageway ( 5 ), and wherein the rotatable insert ( 10 ) is positioned inside the passageway ( 5 ) in the region ( 7 ) of the wear liner section ( 15 ). 18. Submerged nozzle ( 1 ) according to claim 1 , wherein the submerged nozzle ( 1 ) is produced by isostatic pressing. 19. A method comprising: obtaining a submerged nozzle through which molten steel can be poured from a tundish to a mould, the submerged nozzle comprising: a substantially tubular body extending from a first end to a second end; a passageway extending through the tubular body along a longitudinal axis from the first end towards the second end; at least one inlet port opening into the passageway in a region adjacent to the second end; a plurality of outlet ports opening into the passageway in a region adjacent to the second end; and at least one rotatable insert, wherein the submerged nozzle with the at least one rotatable insert is configured such that a molten metal entering the submerged nozzle at the at least one inlet port flows through the passageway and around the rotatable insert and exits the submerged nozzle via the plurality of outlet ports, such that a rotation of the rotatable insert is driven by the molten metal; and continuously casting the molten metal using the submerged nozzle. 20. A method comprising: positioning a submerged nozzle in a tundish; and pouring molten steel through the submerged nozzle into a mould, the submerged nozzle comprising: a substantially tubular body extending from a first end to a second end; a passageway extending through the tubular body along a longitudinal axis from the first end towards the second end; at least one inlet port opening into the passageway in a region adjacent to the second end; a plurality of outlet ports opening into the passageway in a region adjacent to the second end; and at least one rotatable insert, wherein the submerged nozzle with the at least one rotatable insert is configured such that the molten metal entering the submerged nozzle at the at least one inlet port flows through the passageway and around the rotatable insert and exits the submerged nozzle via the plurality of outlet ports, such that a rotation of the rotatable insert is driven by the molten metal.