Patent Number: 046997490
Section: claims

1. A control system for a nuclear power plant including a reactor with a core having an upper portion and a lower portion and control rods which are inserted into and withdrawn from the core of the reactor vertically to control reactivity in the core, said system comprising: means to measure neutron flux separately in the upper portion and the lower portion of the reactor and to generate from such measurements a signal representative of axial distribution of power between the upper and lower portions of the reactor core;  means to detect a dropped control rod in the reactor and to generate a dropped rod signal in response thereto;  means to generate an axial power distribution limit signal representative of a critical axial power distribution for a dropped rod condition;  means to compare said axial power distribution signal to said axial power distribution limit signal and to generate an axial power distribution out of limits signal when said axial power distribution signal exceeds the axial power distribution limit signal; and  means responsive only to the presence of both said dropped rod signal and the axial power distribution out of limits signal to generate a signal for shutting the reactor down.  measuring separately on an on-line basis the neutron flux in the upper portion and the lower portion of the reactor core;  generating from said measurements of the neutron flux in the upper and lower portions of the reactor core a signal representative of the axial distribution of power between the upper and lower portions of the reactor core;  monitoring the operation of the reactor and generating a dropped rod signal in response to the detection of an uncommanded insertion of a control rod into the reactor core;  generating an axial power distribution limit signal representative of a selected critical value of the axial power distribution signal for a dropped rod condition;  comparing, in response to the generation of a dropped rod signal, the axial power distribution signal to the axial power distribution limit signal; and  shutting down the reactor when the axial power distribution signal exceeds the axial power distribution limit signal only in the presence of a dropped rod signal.  a nuclear reactor with a core having an upper and lower portion;  control rods insertable vertically into said reactor core;  means to insert said control rods in and to withdraw them from said core to control the reactivity of the core;  means to measure the neutron flux separately in the upper and lower portions of the reactor core and to generate from such measurements a signal representative of the axial distribution of power between the upper and lower portions of the reactor core and a signal representative of the total neutron flux in both the upper and lower portions of the reactor core;  means responsive to the total neutron flux signal to generate a dropped control rod signal when the rate of change of the total neutron flux signal is more negative than a preset negative limit;  means to generate an axial power distribution limit signal representative of a critical axial power distribution for a dropped rod condition;  means to compare said axial power distribution signal to said axial power distribution limit signal and to generate an axial power distribution out of limits signal when said axial power distribution signal exceeds the axial power distribution limit signal; and  means responsive only to the presence of both said dropped rod signal and the axial power distribution out of limits signal to generate a reactor trip signal, said means for inserting and withdrawing said control rods being responsive to said reactor trip signal to fully insert said control rods into the reactor core. 2. The control system of claim 1 for use in a reactor in which the control rods include part length control rods and full length control rods which may be inserted into and withdrawn from the reactor core, said system including means to indicate the position of said part length control rods and wherein said means to generate an axial power distribution limit signal generates an axial power distribution limit signal of a first selected value in response to an indication by said indicating means that said part length control rods are inserted in said reactor core and to generate an axial power distribution limit signal of a second value in response to an indication that said part length rods are withdrawn from the reactor core such that said reactor is shutdown in the presence of a dropped rod condition for a first value of axial power distribution when the part length control rods are inserted and for a second value of axial power distribution when the part length control rods are withdrawn from the reactor core. 3. The control system of claim 1 wherein said means to detect a dropped control rod in the reactor includes means for monitoring reactor neutron flux and means for generating said dropped rod signal when a negative rate of change in reactor flux more negative than a first preset flux rate limit is detected. 4. The control system of claim 3 wherein said means to detect a dropped control rod in the reactor also includes means for generating a reactor trip signal when a negative rate of change in reactor flux more negative than a second preset flux rate limit, which in turn, is more negative than said first preset flux rate limit, is exceeded. 5. A method of controlling a nuclear power plant including a reactor with a core having an upper portion and a lower portion and control rods which are inserted into and withdrawn from the core vertically to control reactivity, said method comprising the steps of: 6. The method of claim 5 wherein said step of monitoring the operation of said reactor and generating a dropped rod signal comprises the steps of monitoring said neutron flux measurements and generating the dropped rod signal when the rate of change of the neutron flux is more negative than a first preselected negative value. 7. The method of claim 5 wherein said control rods include part length control rods and full length control rods, wherein said method includes the step of monitoring the position of said part length control rods and wherein said step of generating an axial power distribution limit signal includes generating an axial power distribution limit signal of a first value when said part length rods are inserted into the reactor core and generating an axial power distribution limit signal having a second value when the part length control rods are withdrawn. 8. The method of claim 6 including the step of shutting down the reactor when the rate of change of the neutron flux is more negative than a second preselected negative value which is more negative than the first preselected negative value. 9. In combination: