Process and apparatus for controlling the flows of liquid metal in a crystallizer for the continuous casting of thin flat slabs

The invention claimed is: 1. A process for controlling the flows of liquid metal in a continuous casting of thin slabs, wherein there are provided: a crystallizer ( 1 ) comprising perimetral walls ( 16 , 16 ′, 17 , 18 ), which define a containment volume for a liquid metal bath ( 4 ); a discharger ( 3 ), having an outlet section ( 27 ), centrally arranged in said bath ( 4 ) to discharge said liquid metal; a first electromagnetic brake ( 11 ′) for generating a first braking zone ( 11 ) in a central portion ( 41 ) of said bath ( 4 ) in a position under said outlet section ( 27 ) of said discharger ( 3 ); a second electromagnetic brake ( 12 ′) for generating a second braking zone ( 12 ) in a first side portion ( 42 ) of said bath ( 4 ) between said central portion ( 41 ) and a first perimetral sidewall ( 17 ) substantially orthogonal to front walls ( 16 , 16 ′); a third electromagnetic brake ( 13 ′) for generating a third braking zone ( 13 ) within second side portion ( 43 ) of said bath ( 4 ), which is symmetric to said first side portion ( 42 ) of said bath ( 4 ) with respect to a symmetry plane (A-A) substantially orthogonal to said front walls ( 16 , 16 ′); a fourth electromagnetic brake ( 14 ′) for generating a braking zone ( 14 ) in said first side portion ( 42 ) of said bath ( 4 ) in a position underneath said second braking zone ( 12 ); a fifth electromagnetic brake ( 15 ′) for generating a fifth braking zone ( 15 ) in said second side portion ( 43 ) of said bath ( 4 ) in a position underneath said third braking zone ( 13 ); wherein each of said electromagnetic brakes comprises a pair of magnetic poles symmetrically arranged with respect to symmetry plane of said crystallizer, which is substantially parallel to opposite front walls of said crystallizer, each magnetic pole comprising a core and a respective coil supplied by direct current, said core of each magnetic pole being physically independent from the cores of the other electromagnetic brakes, said magnetic poles being configured, so as to generate a magnetic field which crosses said bath according to directions substantially orthogonal to said front walls of said crystallizer, said apparatus comprising a pair of reinforcing walls, each externally adjacent to one of said front walls of said crystallizer, said apparatus comprising a pair of ferromagnetic plates each arranged parallel to one of said reinforcing walls so that the magnetic poles, arranged on a same side with respect to said symmetry plane are comprised between one of said reinforcing walls and one of said ferromagnetic plates wherein said process includes activating said braking zones ( 10 , 11 , 12 , 13 , 14 , 15 ) either independently or in groups according to characteristic parameters, of the fluid-dynamic conditions of said liquid metal in said bath ( 4 ). 2. A process according to claim 1 , wherein the activation of the braking zones ( 12 , 14 , 13 , 15 ) located in a first of the side portions ( 43 , 42 ) of said bath ( 4 ) is provided if the flow rate of liquid metal directed towards the first of the side portions ( 43 , 42 ) is higher than the flow rate directed towards a second of the side portions ( 42 , 43 ). 3. A process according to claim 2 wherein the braking zones ( 13 , 15 ) related to the side portion ( 43 ) with the highest flow rate of liquid metal are activated so as to develop a higher braking action with respect to the braking zones ( 12 , 14 ) related to the other side portion ( 42 ) with the lowest flow rate. 4. A process according to claim 1 , wherein the activation of the braking zones ( 12 , 14 , 13 , 15 ) related to the side portions ( 43 , 42 ) of said bath ( 4 ) is provided when the speed and waviness of said liquid metal in proximity of a surface ( 7 ) of said bath ( 4 ) exceed a predetermined reference value, said second braking zone ( 12 ) and said third braking zone ( 13 ) being activated so as to develop a higher braking action with respect to said fourth braking zone ( 14 ) and said fifth braking zone ( 15 ). 5. A process according to claim 4 , wherein the activation of said first braking zone ( 11 ) is provided. 6. A process according to claim 1 , wherein the second braking zone ( 12 ) and the third braking zone ( 13 ) are activated when the speeds (V) at a meniscus of said bath ( 4 ) are higher than a predetermined value. 7. A process according to claim 6 , wherein the activation of said first braking zone ( 11 ) is provided. 8. A process according to claim 1 , wherein said fourth braking zone ( 14 ) and said fifth braking zone ( 15 ) are activated when the flow rate of liquid metal in the central portion ( 41 ) of said bath ( 4 ) exceeds a predetermined value. 9. A process according to claim 8 , wherein also the first braking zone ( 11 ) is activated. 10. A process according to claim 1 , wherein it is provided the activation: of a group of braking zones ( 12 , 14 ) activatable in said first side portion ( 42 ) of said bath ( 4 ); and/or of a group of braking zones ( 13 , 15 ) activatable in said second side portion ( 43 ) of said bath ( 4 ). 11. A continuous casting apparatus for thin slabs comprising: a crystallizer ( 1 ); a discharger ( 3 ), having an outlet section ( 27 ), adapted to discharge liquid metal into said crystallizer ( 1 ), a device for controlling the flows of liquid metal in said crystallizer ( 1 ), said device comprising a plurality of electromagnetic brakes ( 11 ′, 12 ′, 13 ′, 14 ′, 15 ′), each of which is activatable to generate a corresponding braking zone ( 11 , 12 , 13 , 14 , 15 ) in a liquid metal bath delimited by two front walls ( 16 , 16 ′) of said crystallizer ( 1 ) which are opposite to each other, and by two sidewalls ( 17 , 18 ) of said crystallizer ( 1 ), which are opposite to each other and orthogonal to said front walls ( 16 , 16 ′), wherein each of said electromagnetic brakes ( 11 ′, 12 ′, 13 ′, 14 ′, 15 ′) comprises a pair of magnetic poles symmetrically arranged with respect to a symmetry plane (B-B) of said crystallizer ( 1 ), which is substantially parallel to said front walls ( 16 , 16 ′) of said crystallizer, each magnetic pole comprising a core and a respective coil supplied by direct current, said core of each of magnetic pole being physically independent from the cores of the other electromagnetic brakes, said magnetic poles being configured so as to generate a magnetic field which cross said bath ( 4 ) according to directions substantially orthogonal to said front walls ( 16 , 16 ′) of said crystallizer ( 1 ), wherein said apparatus comprises a pair of reinforcing walls ( 20 , 20 ′), each externally adjacent to one of said front walls ( 16 , 16 ′) of said crystallizer, said apparatus comprising a pair of ferromagnetic plates ( 21 , 21 ′) each arranged parallel to one of said reinforcing walls ( 20 , 20 ′) so that the magnetic poles, arranged on a same side with respect to said symmetry plane (B-B) are comprised between one of said reinforcing walls ( 20 , 20 ′) and one of said ferromagnetic plates ( 21 , 21 ′) and wherein: a first electromagnetic brake ( 11 ′), if activated, generates a first braking zone ( 11 ) in said central portion ( 41 ) of said bath ( 4 ) in a position under said outlet section ( 27 ) of said discharger ( 3 ) a second electromagnetic brake ( 12 ′), if activated, generates a second braking zone ( 12 ) in a first side portion ( 42 ) of said bath ( 4 ) between a central portion ( 41 ) and a first perimetral sidewall ( 17 ) substantially comprised between said front walls ( 16 , 16 ′); a third electromagnetic brake ( 13 ′), if activated, generates a third braking zone ( 13 ) within a second side portion ( 43 ) of sa