Patent Number: 041586026
Section: claims

1. Apparatus for scramming a nuclear reactor having fuel elements and cooled by a flow of primary coolant, comprising: (a) reactor scramming means having a large neutron absorption and insertable into the high neutron flux region of the reactor;  (b) means in the nuclear reactor for retaining the scram means away from the high neutron flux region of the reactor and in contact with a separator plate by restricting a portion of the flow of coolant through the reactor and developing a differential pressure across said separator plate, said separator plate being concurrently exposeable to the pressure of primary coolant flowing past the reactor fuel elements, said restricted flow and resulting differential pressure generating a force which maintains the scramming means away from the high neutron flux region when there is a flow in the reactor, said retaining means being adapted for releasing the scramming means from the separator plate independently from external actuation and in response to and substantially simultaneously with a reduction in the flow of coolant past the reactor fuel elements, thereby causing the scramming means to enter the high neutron flux region of the reactor; and  (c) a supporting drive shaft and connector means connected between said drive shaft and the scramming means for manuvering the scramming means with respect to the high flux region of the core irrespective of coolant flow.  (a) a control rod in a control rod housing in a nuclear reactor, said control rod having a sealing surface and insertable into the high neutron flux region of the reactor independently from external actuation;  (b) a supporting drive shaft connected to the control rod for moving the control rod with respect to the fuel elements; and  (c) a stationary separator plate forming a top wall of the control rod housing and directly and concurrently exposed to the pressure of coolant flowing past the fuel elements in the nuclear reactor and having an orifice across which a differential pressure is developed by the flow of coolant through the reactor, said separator plate also having a sealing surface around said orifice which complements the sealing surface of the control rod, the sealing surfaces on the control rod nd separator plate can be retained together by the differential pressure developed by the coolant flow, said separator plate being positioned within the reactor so that a reduction in the flow of coolant past the fuel elements causes, in direct response thereto, a corresponding reduction of the differential pressure across the separator plate, release of the sealing surfaces on the control rod and the separator plate, and the entry of the control rod into the high neutron flux region of the reactor substantially simultaneously with the reduction in flow.  (a) a control rod in a control rod housing in a nuclear reactor, said control rod having a sealing surface and being adapted for self-initiating a scram; and  (b) a separator plate forming a top wall of the control rod housing and directly and concurrently exposed to the pressure of coolant flowing past the fuel elements in the nuclear reactor and having an orifice across which a differential pressure is developed by the flow of coolant through the reactor, said separator plate also having a sealing surface around said orifice which complements the sealing surface of the control rod, the sealing surfaces on the control rod and separator plate can be retained together by the differential pressure developed by the coolant flow, said separator plate being positioned within the reactor so that a reduction in the flow of coolant past the fuel elements causes, in direct response thereto, a corresponding reduction of the differential pressure across the separator plate, release of the sealing surfaces on the control rod and the separator plate, and the entry of the control rod into the high neutron flux region of the reactor substantially simultaneously with the reduction in flow;  (c) a rod drive shaft operatively connected to the control rod for maneuvering the control rod sealing surface into sealing engagement with the sealing surface of the separator plate, said control rod being insertable into the high neutron flux region of the reactor independently from actuation by the rod drive shaft; and  connecting means between the control rod and supporting rod drive shaft for manuvering said control rod with respect to the high neutron flux region of the reactor irrespective of the flow of coolant.  (a) restricting a portion of the flow of coolant through the reactor;  (b) developing a differential pressure across a separator plate within the reactor by the restricted flow;  (c) exposing concurrently the separator plate to the pressure of primary coolant flowing past the fuel elements;  (d) manuvering a control rod with a suporting drive shaft with respect to the fuel elements irrespective of coolant flow  (e) retaining the control rod remote from the high neutron flux region of the reactor and in sealing contact with the separator plate by using the differential pressure developed by the restricted flow; and  (f) reducing with differential pressure in order to free the control rod for movement with respect to the high flux region.  manuvering a control rod with a supporting drive shaft with respect to the fuel elements irrespective of coolant flow;  (b) developing a differential pressure across a top wall of a control rod housing by exposing said top wall to the flow of primary coolant;  (c) exposing concurrently said top wall to the pressure of primary coolant flowing past the fuel elements;  (d) sealing the control rod against said top wall of the housing at a position remote from the high neutron flux region of the reactor by using said differential pressure caused by the flow of coolant through the reactor;  (e) unsealing the control rod from said top wall and thereby reducing the differential pressure; and  (f) inserting the control rod after unsealing into the high neutron flux region of the reactor. 2. The apparatus of claim 1 wherein the supporting drive shaft can quickly insert on command the scramming means into the high flux region of the reactor so that the reactor is scrammed, said drive shaft means being actuatable independently from a reduction in the flow of coolant. 3. The apparatus of claim 1 wherein the supporting drive shaft can maneuver the scamming means with respect to the high flux region of the reactor so that the level of neutron flux is controllable during operation of the reactor. 4. In a nuclear reactor of the type cooled by a flow of coolant and having controls rods that are mounted for movement with respect to the fuel elements in the core, the improvement comprising: 5. The apparatus of claim 4 wherein the supporting drive shaft can reduce the differential pressure across the separator plate on command, thereby causing the control rod to enter the high neutron flux region of the reactor. 6. The apparatus of claim 4 wherein the control rod is laterally displaceable with respect to the separator plate and the housing so that the sealing surfaces are separated and the differential pressure is reduced, thereby causing the control rod to enter the high neutron flux region of the reactor. 7. The apparatus of claim 4 wherein the supporting drive shaft can maneuver the control rod with respect to the high neutron flux region of the reactor so that the level of neutron flux is controllable during operation of the reactor. 8. The apparatus of claim 4 including means forming part of the sealing surfaces for centering the control rod with respect to the orifice in the separator plate. 9. In a nuclear reactor of the type cooled by a flow of coolant and having control rods that are mounted for movement with respect to the fuel elements in the core, the improvement comprising: 10. The apparatus of claim 9 wherein the rod drive shaft maneuvers the control rod with respect to the high neutron flux region of the reactor during operation. 11. The apparatus of claim 9 including means for connecting the rod drive shaft to the control rod so that the rod drive shaft can cause the control rod to be rapidly inserted into the high neutron flux region of the reactor independently from a reduction in the flow of coolant, thereby scramming the reactor. 12. The apparatus of claim 9 including means having lost motion for connecting the control rod to the rod drive shaft, said connecting means permitting the control rod to scram the reactor by entering the high neutron flux region of the reactor either independently of or directly actuated by the rod drive shaft. 13. The apparatus of claim 9 including means for connecting the rod drive shaft to the control rod so that the control rod is laterally displaceable with respect to the separator plate and the control rod housing and a reduction in the differential pressure is obtained, thereby causing the control rod to enter the high neutron flux region of the reactor. 14. A method for controlling the neutron flux in a nuclear reactor having fuel elements, comprising the steps of: 15. The method of claim 14 wherein the step of reducing the differential pressure occurs as a direct consequence of and substantially simultaneously with a reduction in the flow of coolant past the fuel elements in the reactor, thereby directly causing the insertion of the control rod into the high neutron flux region independent of external actuation. 16. The method of claim 14 wherein the step of reducing the differential pressure includes the step of actuating the reduction of differential pressure on command independently of a reduction in the flow of coolant so that the control rod is quickly inserted into the high neutron flux region of the reactor. 17. The method of claim 16 further including the step of maneuvering the control rod with respect to the high neutron flux region of the reactor in order to regulate the level of neutron flux during operation. 18. A method for controlling the neutron flux in a nuclear reactor having fuel elements, comprising the steps of: 19. The method of claim 18 wherein the step of unsealing the control rod is performable independently from a reduction in coolant flow. 20. The method of claim 18 wherein the step of unsealing the control rod is accomplished by a lateral acceleration of the reactor. 21. The method of claim 20 wherein the step of unsealing by lateral acceleration is performed by an earthquake. 22. The method of claim 18 wherein the step of unsealing occurs without external actuation and substantially simultaneously with a reduction in the flow of coolant past the fuel elements in the reactor.