Method of operation of twin roll strip caster to reduce chatter

What is claimed is: 1. A method of casting thin strip comprising the steps of: assembling a pair of counter-rotating casting rolls laterally forming a gap between circumferential casting surfaces of the casting rolls at a nip between the casting rolls through which metal strip is cast; assembling side dams adjacent end portions of the casting rolls to permit a casting pool of molten metal to be formed and supported by the casting surfaces of the casting rolls; assembling a metal delivery system above the casting rolls adapted to deliver molten metal to form the casting pool supported on the casting surfaces of the casting rolls above the gap and confined by the side dams; counter-rotating the casting rolls such that the casting surfaces of the casting rolls each travel inwardly toward the nip to form metal shells on the surfaces of the casting rolls and deliver a cast strip downwardly from the gap between the casting rolls with a mushy internal portion; and providing a drive mechanism to directly move one or more casting rolls of the pair of casting rolls to oscillate the gap between the casting rolls at an amplitude between ±5 and ±50 μm at a frequency between 1 and 7 hertz to vary thickness of the mushy internal portion in the cast strip and reduce chatter during casting. 2. The method of casting thin strip as claimed in claim 1 where the oscillating of the gap between the casting rolls at the nip is performed by sinusoid oscillation. 3. The method of casting thin strip as claimed in claim 1 where the oscillating of the gap between the casting rolls at the nip is provided by a periodic function to change the gap between the casting rolls. 4. The method of casting thin strip as claimed in claim 1 where the oscillating of the gap between the casting rolls at the nip is at an amplitude between +10 and +40 μm. 5. The method of casting thin strip as claimed in claim 1 where the oscillating of the gap between the casting rolls at the nip is at an amplitude between +20 and +30 μm. 6. The method of casting thin strip as claimed in claim 1 where the oscillating of the gap between the casting rolls at the nip is oscillated at a frequency between 2 and 5 hertz. 7. The method of casting thin strip as claimed in claim 1 where the amplitude is constant. 8. The method of casting thin strip as claimed in claim 1 where the frequency is constant. 9. The method of casting thin strip as claimed in claim 1 where the amplitude and the frequency are constant. 10. The method of casting thin strip as claimed in claim 1 where the drive mechanism moves one casting roll of the pair of casting rolls. 11. The method of casting thin strip as claimed in claim 1 where the drive mechanism moves the pair of casting rolls. 12. The method of casting thin strip as claimed in claim 11 where the pair of casting rolls move in unison. 13. The method of casting thin strip as claimed in claim 11 where the pair of casting rolls move in opposition. 14. The method of casting thin strip as claimed in claim 11 where the pair of casting rolls move in disharmony. 15. The method of casting thin strip as claimed in claim 1 where the drive mechanism comprises a roll support and an actuator where the actuator enables movement of the one or more casting rolls on the roll support. 16. The method of casting thin strip as claimed in claim 15 where the roll support comprises a cassette frame and one or more roll chocks for supporting the one or more casting rolls and where the one or more casting rolls move on the cassette frame. 17. An apparatus for casting thin strip comprising: at least a pair of counter-rotating casting rolls, each casting roll having a circumferential casting surface and a pair of end portions, where a lateral gap is formed between the circumferential casting surfaces of each casting roll at a nip between the casting rolls through which a metal strip is cast; at least a pair of side dams adjacent the end portions of the casting rolls to permit a casting pool of molten metal to be formed and supported by the casting surfaces of the casting rolls; a metal delivery system above the casting rolls for delivering molten metal to form the casting pool supported by the casting surfaces of the casting rolls above the lateral gap and confined by the side dams; and a drive mechanism configured to directly move one or more casting rolls of the pair of casting rolls to oscillate the gap between the casting rolls at an amplitude between ±5 and ±50 μm at a frequency between 1 and 7 hertz to vary a thickness of a mushy material in the cast strip and reduce chatter during casting. 18. The apparatus for casting thin strip as claimed in claim 17 where the drive mechanism comprises a roll support and an actuator where the actuator is for enabling movement of the one or more casting rolls on the roll support. 19. The apparatus for casting thin strip as claimed in claim 18 where the roll support comprises a cassette frame and one or more roll chocks for supporting the one or more casting rolls and where the one or more casting rolls move on the cassette frame.