Patent Number: 
Section: claims

1. A method of operating a Boiling Water Reactor comprising:a step of analyzing Local Power Range Monitor signals in the Boiling Water Reactor for oscillatory behavior indicative of neutron-flux-coupled density wave oscillations;determining if oscillatory behavior is present in the signals; andinitiating a first reactor protective corrective action if the oscillatory behavior is determined to be present; andif the Local Power Range Monitor signals analyzed in the step of analyzing Local Power Range Monitor signals are not oscillatory beyond noise levels,a step of anticipating and suppressing instability in the Boiling Water Reactor caused by single channel thermal-hydraulic density waves in at least one fuel channel of the Boiling Water Reactor, wherein the single channel thermal-hydraulic density waves are uncoupled from neutron flux variations;the step of anticipating and suppressing the instability comprising performing analytical simulations of the Boiling Water Reactor, independent of neutron flux;the analytical simulations identifying relationships between output power of the Boiling Water Reactor and coolant flow in the Boiling Water Reactor that result in the single channel thermal-hydraulic density waves in the at least one fuel channel of the Boiling Water Reactor; therebydefining a boundary of an exclusion zone on a power-coolant flow operating map of the Boiling Water Reactor where neutron-flux-uncoupled density wave oscillations are possible in the at least one fuel channel of the Boiling Water Reactor;determining whether operating power and coolant flow in the Boiling Water Reactor are within the exclusion zone of the power-coolant flow operating map of the Boiling Water Reactor while the Local Power Range Monitor signals are not oscillatory beyond noise levels;initiating a second reactor protective corrective action if the operating power of the Boiling Water Reactor and coolant flow in the Boiling Water Reactor are within the exclusion zone of the power-coolant flow operating map; andrepeating at least the step of analyzing Local Power Range Monitor signals if the operating power of the Boiling Water Reactor and coolant flow in the Boiling Water Reactor are outside the exclusion zone of the power-coolant flow operating map. 2. The method according to claim 1, wherein the first and second reactor protective corrective actions are scraming the reactor. 3. The method according to claim 1, wherein at least one of the first step and the second step of initiating reactor protective action is reducing reactor power. 4. The method according to claim 1, wherein the method steps are performed in a sequence of analyzing Local Power Range Monitor signals followed by anticipating and suppressing the instability. 5. The method according to claim 1, wherein the method steps of analyzing Local Power Range Monitor signals and anticipating and suppressing the instability are performed in parallel. 6. A method of establishing a stable region on a power-coolant flow operating map for a Boiling Water Reactor and operating the Boiling Water Reactor in the stable region, the method comprising:providing a power-coolant flow operating map for a Boiling Water Reactor; andperforming analytical simulations of the Boiling Water Reactor, independent of neutron flux, the analytical simulations identifying relationships between output power of the Boiling Water Reactor and coolant flow in the Boiling Water Reactor that result in single channel thermal-hydraulic density waves in at least one fuel channel of the Boiling Water Reactor, wherein the single channel thermal-hydraulic density waves are uncoupled from neutron flux variations, such that neutron flux signals are not oscillatory beyond noise signals, thereby defining an exclusion zone on the power-coolant flow operating map where neutron-flux-uncoupled density wave oscillations are possible in the at least one fuel channel of the Boiling Water Reactor, wherein a stable region on the power-coolant flow operating map of the Boiling Water Reactor is established under the exclusion zone, where signals from Local Power Range Monitors are not oscillatory beyond noise levels, and operating the Boiling Water reactor in the stable region. 7. A method of operating a Boiling Water Reactor with improved operational flexibility, the method comprising:providing a power-coolant flow operating map for a Boiling Water Reactor;performing analytical simulations of the Boiling Water Reactor, independent of neutron flux, the analytical simulations identifying relationships between output power of the Boiling Water Reactor and coolant flow in the Boiling Water Reactor that result in single channel thermal-hydraulic density waves in the at least one fuel channel of the Boiling Water Reactor, wherein the single channel thermal-hydraulic density waves are uncoupled from neutron flux variations, such that neutron flux signals are not oscillatory beyond noise signals, thereby defining an exclusion zone on the power-coolant flow operating map where neutron-flux-uncoupled density wave oscillations are possible in the at least one fuel channel of the Boiling Water Reactor, wherein a stable region on the power-coolant flow operating map is established under the exclusion zone; andoperating the Boiling Water Reactor at a power and a coolant flow which are in the stable region on the power-coolant flow operating map, where signals from Local Power Range Monitors are not oscillatory beyond noise levels.