Patent Number: 
Section: claims

1. A system including at least one control drum for a nuclear reactor, the at least one control drum comprising:an outer shell;an inner shell;a plurality of tubes, the plurality of tubes including at least one neutron absorbing tube and at least one neutron scattering tube,the at least one neutron absorbing tube configured to contain neutron absorbing material, the neutron absorbing material including at least one of boron material, carbide material, hafnium material, gadolinium material, or any combinations thereof, andthe at least one neutron scattering tube configured to contain neutron scattering material, the neutron scattering material including at least one of beryllium material, graphite material, europium material, or any combinations thereof; andthe at least one baffle plate including a plurality of perforations, wherein each perforation of the plurality of perforations is configured to receive and support a corresponding tube of the plurality of tubes. 2. The system of claim 1, whereinthe plurality of perforations are arranged along at least one ring of the at least one baffle plate, the at least one ring including at least a first sector and a second sector, the first sector including a plurality of neutron absorbing tubes and the second sector including a plurality of neutron scattering tubes, the plurality of neutron absorbing tubes including the at least one neutron absorbing tube, and the plurality of neutron scattering tubes including the at least one neutron scattering tube. 3. The system of claim 1, whereinthe at least one baffle plate is a plurality of baffle plates; andthe plurality of baffle plates are sequentially arranged between the outer shell and the inner shell along a first direction of the control drum. 4. The system of claim 1, whereineach perforation of the plurality of perforations includes at least one spring configured to allow for expansion of a corresponding supported tube. 5. The system of claim 1, further comprising:a drive mechanism including a drive shaft, the drive shaft configured to mate with the inner shell via a magnetic coupling; andthe drive mechanism is further configured to rotate the control drum via the drive shaft such that the at least one neutron absorbing tube faces at least one nuclear fuel rod during a first state of the nuclear reactor and the at least one neutron scattering tube faces the at least one nuclear fuel rod during a second state of the nuclear reactor. 6. The system of claim 5, further comprising:at least one torsional spring attached to the inner shell, the at least one torsional spring configured to rotate the control drum via the drive shaft such that the at least one neutron absorbing tube faces the at least one nuclear fuel rod during a third state of the nuclear reactor. 7. The system of claim 6, wherein the third state is a fail-safe state of the nuclear reactor where at least one of the magnetic coupling or the drive mechanism has failed. 8. The system of claim 1, whereinthe neutron absorbing material has a form of a powder, pellets, or a solid; andthe neutron scattering material has a form of a powder, pellets, or a solid. 9. The system of claim 1, wherein the control drum is horizontally mounted in a reflector region surrounding a nuclear fuel assembly of the nuclear reactor, the control drum horizontally mounted with respect to the nuclear reactor. 10. The system of claim 1, wherein the control drum is configured to be installed in the nuclear reactor, the nuclear reactor being a mobile nuclear reactor. 11. A nuclear reactor comprising:a plurality of nuclear fuel rods;a plurality of control drums, each control drum of the plurality of control drums attached to a drive shaft of a plurality of drive shafts, and at least one control drum of the plurality of control drums includes,a plurality of tubes, the plurality of tubes including at least one neutron absorbing tube and at least one neutron scattering tube,the at least one neutron absorbing tube configured to contain neutron absorbing material, the neutron absorbing material including at least one of boron material, carbide material, hafnium material, gadolinium material, or any combinations thereof, andthe at least one neutron scattering tube configured to contain neutron scattering material, the neutron scattering material including at least one of beryllium material, graphite material, europium material, or any combinations thereof, andat least one baffle plate arranged between an outer shell and an inner shell, the at least one baffle plate including a plurality of perforations, wherein each perforation of the plurality of perforations is configured to receive and support a corresponding tube of the plurality of tubes; anda plurality of motors attached to the plurality of drive shafts, at least one motor of the plurality of motors configured to rotate the at least one control drum such that the at least one neutron absorbing tube of the at least one control drum faces the plurality of nuclear fuel rods during a first state, and the at least one neutron scattering tube of the at least one control drum faces the plurality of nuclear fuel rods during a second state. 12. The nuclear reactor of claim 11, whereinthe plurality of perforations are arranged along at least one ring of the at least one baffle plate, the at least one ring including at least a first sector and a second sector, the first sector including a plurality of neutron absorbing tubes and the second sector including a plurality of neutron scattering tubes, the plurality of neutron absorbing tubes including the at least one neutron absorbing tube, and the plurality of neutron scattering tubes including the at least one neutron scattering tube. 13. The nuclear reactor of claim 11, whereinthe at least one baffle plate is a plurality of baffle plates; andthe plurality of baffle plates are sequentially arranged between the outer shell and the inner shell along a first direction of the at least one control drum. 14. The nuclear reactor of claim 11, whereineach perforation of the plurality of perforations includes at least one spring configured to allow for expansion of a corresponding supported tube. 15. The nuclear reactor of claim 11, whereinthe inner shell is configured to mate with the drive shaft via a magnetic coupling. 16. The nuclear reactor of claim 15, further comprising:at least one torsional spring attached to the inner shell, the at least one torsional spring configured to rotate the at least one control drum via the drive shaft such that the at least one neutron absorbing tube faces the plurality of nuclear fuel rods during a third state. 17. The nuclear reactor of claim 16, wherein the third state is a fail-safe state where at least one of the magnetic coupling or the at least one motor has failed. 18. The nuclear reactor of claim 11, whereinthe neutron absorbing material has a form of a powder, pellets, or a solid; andthe neutron scattering material has a form of a powder, pellets, or a solid. 19. The nuclear reactor of claim 18, wherein the plurality of control drums are horizontally mounted in a nuclear reactor core of the nuclear reactor. 20. The nuclear reactor of claim 18, whereinthe neutron absorbing material includes at least one of boron carbide, hafnium, gadolinium, or any combinations thereof; andthe neutron scattering material includes at least one of beryllium, graphite, europium, or any combinations thereof.