Patent Number: 
Section: claims

1. Apparatus for translation along an axis of fluid flow, the apparatus comprising:a duct configured to conduct a fluid in a first direction;a plug fixed to the duct;a loading assembly disposed within the duct and configured to move a member in the first direction into a loaded position when pressure of the fluid in the duct satisfies a loading condition;a first piston coupled to the member, the first piston within and slidably coupled to the duct, wherein the plug and the first piston define a pair of cooperating apertures that forms at least a portion of a converging-diverging passage; anda firing assembly operably coupled to the loading assembly and disposed within the duct, the firing assembly and the loading assembly being configured to store energy when the member is in the loaded position and to release stored energy and move the member out of the loaded position in a second direction opposite the first direction when the pressure of the fluid in the duct satisfies a firing condition. 2. The apparatus of claim 1, wherein the member is disposed within the duct and having an end that is configured to engage a neutron modifying material. 3. The apparatus of claim 1, wherein the converging-diverging passage is disposed along a fluid flow path such that pressure variations within the converging-diverging passage secure the first piston and the member when the pressure of the fluid in the duct satisfies the loading condition. 4. The apparatus of claim 3, wherein the pair of cooperating apertures includes a first aperture defined at least partially by the first piston and a second aperture defined at least partially by the plug, the first aperture and the second aperture defining at least a portion of a converging opening and at least a portion of a diverging opening. 5. The apparatus of claim 4, further comprising:wherein the converging opening extends between an inlet end and an inlet throat;wherein the diverging opening extends between an outlet throat and an outlet end; andwherein the inlet throat of the converging opening has an inlet throat cross-sectional area that is equalized with an outlet throat cross-sectional area of the outlet throat of the diverging opening. 6. The apparatus of claim 4, wherein the first piston includes a first body that defines the first aperture and the plug includes a second body that defines the second aperture such that the pair of cooperating apertures is spaced from peripheries of the plug and the first piston. 7. The apparatus of claim 4, further comprising:wherein the firing assembly includes a cup and a second piston, wherein the cup has a sidewall that defines an interior space; andwherein the second piston is disposed within the interior space of the cup. 8. The apparatus of claim 7, further comprising:wherein the member has an opposing second end, wherein the second piston is coupled to the opposing second end of the member, wherein the second piston includes a piston body that separates the interior space of the cup into a first region and a second region;wherein the member is positioned along the fluid flow path; andwherein the cup has an open end such that the first region is exposed to the fluid flow path. 9. The apparatus of claim 8, further comprising:wherein the cup is configured to contain a compressible fluid within the second region;wherein the cup defines an opening configured to fluidly couple the first region and a liquid coolant associated with the fluid flow path; andwherein a pressure of the compressible fluid varies with the pressure of the liquid coolant. 10. The apparatus of claim 8, further comprising:wherein the second piston is slidably coupled to the sidewall of the cup;wherein the second piston defines an orifice that places the first region in fluid communication with the second region, and wherein the orifice is configured to restrict a flow of the fluid therethrough such that release of stored energy applied by the firing assembly overcomes a suction force associated with the pressure variations within the converging-diverging passage when the pressure of the fluid in the duct satisfies a firing condition. 11. The apparatus of claim 1 further comprising a hysteresis device positioned to apply a driving force independent of release of stored energy by the firing assembly. 12. The apparatus of claim 11, further comprising:wherein the hysteresis device is configured to receive a hysteresis control signal; andwherein the hysteresis device initiates the driving force in response to receiving the hysteresis control signal. 13. The apparatus of claim 11, wherein the hysteresis device is a spring mechanism. 14. The apparatus of claim 1 further comprising an expansion device, the expansion device having a contracted state and an expanded state, and positioned to provide a resisting force in the expanded state. 15. The apparatus of claim 14, wherein the expansion device further comprises an engaging member, the engaging member maintaining the expansion device in the expanded state. 16. The apparatus of claim 15, wherein the expansion device is configured to receive an engagement control signal, wherein the engaging member maintains the expansion device in the expanded state in response to receiving the engagement control signal. 17. The apparatus of claim 15, wherein the expansion device is configured to receive a disengagement control signal, wherein the engaging member disengages and allows the expansion device to return to the contracted state in response to the disengagement control signal. 18. The apparatus of claim 14, wherein the expansion device comprises a thermal expansive material. 19. The apparatus of claim 14, wherein the expansion device further comprises a bellows. 20. The apparatus of claim 1, further comprising a locking mechanism, wherein the locking mechanism has a locked state and an unlocked state, wherein the locking mechanism in the locked state engages the loading assembly. 21. The apparatus of claim 20, wherein the locking mechanism in the locked state engaging the member inhibits movement of the member relative to the duct. 22. The apparatus of claim 20, wherein the locking mechanism is configured to receive a locking control signal, wherein the locking mechanism enters and maintains the locked state in response to receiving the locking control signal. 23. The apparatus of claim 20, wherein the locking mechanism is configured to receive an unlocking control signal, wherein the locking mechanism enters and maintains the unlocked state in response to the unlocking control signal. 24. The apparatus of claim 20, wherein the locking mechanism comprises a ferromagnetic material. 25. The apparatus of claim 1, further comprising a flow restricting device, wherein the firing assembly releases the stored energy in response to movement of the flow restricting device. 26. The apparatus of claim 25, wherein the flow restricting device moves in response to a change in temperature. 27. A nuclear reactor, comprising:a fuel assembly including a fuel assembly duct containing nuclear fuel;a pump in fluid communication with the fuel assembly duct of the fuel assembly, wherein the pump is configured to provide a coolant flow along a coolant flow path; anda control assembly including:a control assembly duct configured to conduct coolant along at least a portion of the coolant flow path;a plug fixed to the control assembly duct;a neutron modifying material coupled to a member;a first piston disposed within and slidably coupled to the control assembly duct, and coupled to the member; anda firing assembly disposed within the control assembly duct and coupled to the first piston and the member, and configured to release stored energy when the pressure of the coolant in the coolant flow path satisfies a firing condition; andwherein the release of the stored energy inserts the neutron modifying material into the nuclear fuel when the pressure of the coolant in the coolant flow path satisfiesthe firing condition; wherein the plug and the first piston define a pair of cooperating apertures that forms at least a portion of a converging-diverging passage. 28. The nuclear reactor of claim 27, wherein the converging-diverging passage is disposed along the coolant flow path such that pressure variations within the converging-diverging passage secure the neutron modifying material in a withdrawn position until the pressure of the coolant in the coolant flow path satisfies the firing condition. 29. The nuclear reactor of claim 28, wherein the pair of cooperating apertures includes a first aperture defined at least partially by the first piston and a second aperture defined at least partially by the plug, the first aperture and the second aperture defining at least a portion of a converging opening and at least a portion of a diverging opening. 30. The nuclear reactor of claim 29, wherein the converging opening extends between an inlet end and an inlet throat, wherein the diverging opening extends between an outlet throat and an outlet end, and wherein the inlet throat of the converging opening has an inlet throat cross-sectional area that is equalized with an outlet throat cross-sectional area of the outlet throat of the diverging opening. 31. The nuclear reactor of claim 29, wherein the first piston includes a first body that defines the first aperture and the plug includes a second body that defines the second aperture such that the pair of cooperating apertures is spaced from peripheries of the plug and the first piston. 32. The nuclear reactor of claim 28, wherein the firing assembly includes a cup and a second piston, wherein the cup has a sidewall that defines an interior space, and wherein the second piston is disposed within the interior space of the cup. 33. The nuclear reactor of claim 32, wherein the member has a first end and an opposing second end, wherein the neutron modifying material is coupled to the first end of the member, and wherein the second piston is coupled to the opposing second end of the member, wherein the second piston includes a piston body that separates the interior space of the cup into a first region and a second region, and wherein the cup has an open end such that the first region is exposed to the coolant flow path. 34. The nuclear reactor of claim 33, wherein the coolant is configured to store the stored energy that inserts the neutron modifying material into the nuclear fuel of the fuel assembly when the pressure of the coolant in the coolant flow path satisfies the firing condition. 35. The nuclear reactor of claim 34, wherein the second piston is slidably coupled to the sidewall of the cup, wherein the second piston defines an orifice that places the first region in fluid communication with the second region, and wherein the orifice is configured to restrict a flow of the coolant therethrough such that release of stored energy applied by the coolant overcomes a suction force associated with the pressure variations within the converging-diverging passage when the pressure of the coolant in the coolant flow path satisfies the firing condition. 36. The nuclear reactor of claim 27, wherein the control assembly further comprises a hysteresis device positioned to apply a driving force. 37. The nuclear reactor of claim 36, wherein the hysteresis device is configured to receive a hysteresis control signal, wherein the hysteresis device initiates the driving force in response to receiving the hysteresis control signal. 38. The nuclear reactor of claim 36, wherein the hysteresis device is a spring mechanism. 39. The nuclear reactor of claim 27, wherein the control assembly further comprises an expansion device, the expansion device having a contracted state and an expanded state, wherein the expansion device is positioned to provide a resisting force in the expanded state. 40. The nuclear reactor of claim 39, wherein the expansion device further comprises an engaging member, wherein the engaging member maintains the expansion device in the expanded state. 41. The nuclear reactor of claim 40, wherein the expansion device is configured to receive an engagement control signal, wherein the engaging member maintains the expansion device in the expanded state in response to receiving the engagement control signal. 42. The nuclear reactor of claim 40, wherein the expansion device is configured to receive a disengagement control signal, wherein the engaging member disengages and allows the expansion device to return to the contracted state in response to the disengagement control signal. 43. The nuclear reactor of claim 39, wherein the expansion device comprises a thermal expansive material. 44. The nuclear reactor of claim 39, wherein the expansion device further comprises a bellows. 45. The nuclear reactor of claim 27, further comprising a locking mechanism, wherein the locking mechanism has a locked state and an unlocked state, wherein the locking mechanism in the locked state engages the control assembly. 46. The nuclear reactor of claim 45, wherein the locking mechanism in the locked state engaging the control assembly inhibits movement of the firing assembly relative to the control assembly duct. 47. The nuclear reactor of claim 45, wherein the locking mechanism is configured to receive a locking control signal, wherein the locking mechanism enters and maintains the locked state in response to receiving the locking control signal. 48. The nuclear reactor of claim 45, the locking mechanism is configured to receive an unlocking control signal, wherein the locking mechanism enters and maintains the unlocked state in response to the unlocking control signal. 49. The nuclear reactor of claim 45, wherein the locking mechanism comprises a ferromagnetic material. 50. The nuclear reactor of claim 27, wherein the control assembly further comprises a flow restricting device, wherein the firing assembly releases stored energy in response to movement of the flow restricting device. 51. The nuclear reactor of claim 50, wherein the flow restricting device moves in response to a change in temperature. 52. A method of manufacturing a control assembly for a nuclear reactor, the method comprising:defining a coolant flow path within an inner volume of a duct;fixing a plug to the duct;disposing a loading assembly within the duct;slidably coupling a first piston to the duct, wherein the plug and the first piston define a pair of cooperating apertures that forms at least a portion of a converging-diverging passage;coupling a neutron modifying material to the first piston with a member;positioning the converging-diverging passage along the coolant flow path such that pressure variations within the converging-diverging passage secure the first piston, the member, and the neutron modifying material during normal operation of the nuclear reactor; andpositioning a biasing member to apply a biasing force to the member and the first piston, the biasing force releasing the first piston, the member, and the neutron modifying material when the pressure of the coolant in the duct satisfies a firing condition. 53. The method of claim 52, further comprising associating a first aperture of the pair of cooperating apertures with the first piston and a second aperture of the pair of cooperating apertures with the plug, the first aperture and the second aperture defining at least a portion of a converging opening and at least a portion of a diverging opening.