Patent Number: 048805963
Section: claims

1. In a reactor control assembly utilizing electromagnetic means for retaining a control element in ready position for insertion into a reactor core containing a plurality of fuel assemblies having coolant flowing therethrough, the improvement comprising: first means responsive to temperature of reactor coolant passing through said fuel assemblies for releasing said control element, said first means including a quantity of thermionic material which changes from a high electrical resistance to a low electrical resistance upon an increase in reactor coolant temperature above a selected temperature;  second means responsive to reactor neutron flux for releasing said control element, said second means including a quantity of material which is heated by neutron flux and a quantity of thermionic material that changes from a high electrical resistance to a low electrical resistance upon an increase in temperature above a selected temperature, said thermionic material being heated by the heating of said first-mentioned material by neutron flux; and  an electrical circuit interconnecting a power source with said electromagnetic means, said first and second means being connected to said electrical circuit so as to be electrically in paralllel with said electromagnetic means;  whereby under normal operating conditions electrical current flows from said power source to said electromagnetic means, and activation of either of said first means or said second means causes electrical current flowing to said electromagnetic means to be short-circuited resulting in release of said control element from said electromagnetic means for insertion of said control element into said reactor core.  said control assembly having a guide tube within which is movably positioned an absorber element and a drive mechanism for positioning and retaining said absorber element exterior of the core region under normal reactor operating conditions,  said drive mechanism including an electromagnetic means for retaining said absorber element,  said absorber element, said guide tube, and said drive mechanism each being constructed so as to allow reactor coolant to pass therethrough,  a first means responsive to reactor neutron flux,  a second means responsive to coolant temperature exiting from said fuel assemblies,  each of said first and second means being operatively connected to an electrical circuit connecting a power source to said electromagnetic means so as to be connected in parallel with said electromagnetic means for causing release of said absorber element upon activation of said first or second means,  each of said first and second means containing a quantity of thermionic material which ionizes at a selected temperature causing said means to change from a high electrical resistance to a low electrical resistance, and  said first means additionally including a quantity of material which is heated by reactor neutron flux causing heating of said thermionic material;  whereby activation of said means, due to heating thereof to said selected temperature by either reactor neutron flux or coolant from the fuel assemblies, causes short-circuiting of said electromagnetic means so as to release said absorber element which falls into the reactor core region for reducing reactivity of the fuel assemblies.  said guide tube and said control element each being constructed to allow reactor coolant to flow upwardly therethrough,  said control element being provided with a magnetic armature at an upper end thereof,  an electromagnet located within said guide tube, secured to a drive mechanism, and positioned so as to cooperate with said magnetic armature to retain or release said armature and said control element, and  means responsive either to an increase in temperature of the coolant passing through at least one of said fuel assemblies, or to an increase in neutron flux for effecting deactivation of said electromagnet and release of said control element,  said means comprising a plurality of switches connected to an electrical circuit connecting an electrical source to said electromagnet so as to be in parallel with said electromagnet and activated by ionization of a quantity of thermionic material contained therein, causing said switches to change from a high resistance to a low resistance thereby short-circuiting current flow through said electrical circuit to said electromagnet, said thermionic material being ionized by an increase in temperature above a selected temperature,  one of said plurality of switches being additionally provided with a quantity of material capable of being heated by neutron flux which heats said thermionic material causing ionization thereof. 2. The improvement of claim 1, wherein said first means is positioned such that reactor coolant exiting from the fuel assemblies flows thereacross. 3. The improvement of claim 1, wherein said second means is positioned such that it is shielded from reactor coolant exiting from the fuel assemblies. 4. The improvement of claim 1, wherein each of said first and second means consists of at least one thermionic diode. 5. The improvement of claim 4, wherein at least one of said thermionic diodes constituting said first means is provided with a quantity of uranium comprising said first-mentioned quantity of material which is heated by neutron flux causing heating of said thermionic material and activation of the diode to short circuit electrical current flowing to said electromagnetic means. 6. The improvement of claim 4, wherein each of said thermionic diodes includes an emitter, a collector positioned with respect to said emitter to define a gap therebetween, said emitter and collector being mounted within a sealed container and provided with electrical leads extending therefrom through said sealed container for operative connection to said electrical circuit of said electromagnetic means, and said quantity of thermionic material being located within said sealed container, whereby heating of said thermionic material causes the diode to change from high electrical resistance to low electrical resistance whereupon the diode conducts electrical current causing short circuiting of the electromagnetic means and release of said control element. 7. A self-actuating shutdown system for a nuclear reactor having at least one fuel bundle positioned in a core region and provided with a control assembly and a plurality of fuel assemblies, 8. The system of claim 7, additionally including kinetic energy absorbing means positioned in said guide tube for stopping movement of said absorber element after it has entered the core region. 9. The system of claim 7, wherein said first and second means comprises a plurality of thermionic switches, at least one of said plurality of thermionic switches being responsive to coolant temperature of the fuel assemblies, and at least one of said plurality of thermionic switches being responsive to reactor neutron flux. 10. The system of claim 9, wherein at least one of said plurality of thermionic switches responsive to reactor neutron flux includes a quantity of uranium constituting said quantity of material for heating said thermionic material and activating said switch. 11. The system of claim 9, wherein said temperature responsive thermionic switch is positioned so as to be in direct contact with coolant exiting from said fuel assemblies. 12. The system of claim 9, wherein said neutron flux responsive switch is positioned so as to be substantially isolated from coolant exiting from said fuel assemblies. 13. The system of claim 12, additionally including neutron shield means positioned adjacent said neutron flux responsive switch. 14. The system of claim 9, wherein each of said thermionic switches are constructed as a thermionic diode having a spaced apart emitter and collector located within a sealed container, said quantity of thermionic material located within said sealed container, and electrical leads operatively connected to said emitter and collector plate and extending through said sealed container for electrical connection to said electrical circuit of said electromagnetic means. 15. The system of claim 14, wherein at least one of said thermionic diodes is additionally provided with a quantity of uranium attached to said emitter. 16. The system of claim 15, wherein said quantity of uranium consists of a uranium blanket positioned around said emitter. 17. The system of claim 9, wherein said temperature responsive thermionic switch is located on an exterior surface of said drive mechanism adjacent the exit of coolant from said fuel assemblies. 18. In a self-actuating reactor shutdown system including at least one control element located within a guide tube, a plurality of reactor fuel assemblies having coolant passing therethrough and positioned around the guide tube and the control element, and electromagnetic means for retaining the control element external to a reactor core region and for releasing said control element so as to enable same to enter into the reactor core region, the improvement comprising: 19. The improvement of claim 18, wherein said plurality of switches include one switch responsive to neutron flux and a plurality of switches response to temperature of the coolant passing through a plurality of said fuel assemblies. 20. The improvement of claim 18, additionally including neutron shield means positioned adjacent said neutron flux responsive switch. 21. The improvement of claim 18, wherein each of said switches is constructed to include a spaced apart emitter and collector located within a sealed container, said quantity of thermionic material being located within said sealed container, and electrical leads extending through said sealed container and operatively connecting each of said emitter and collector to said electrical circuit. 22. The improvement of claim 21, wherein one of said switches additionally includes a quantity of uranium within said sealed container said uranium constituting said material capable of being heated by neutron flux.