Patent Number: 043022880
Section: claims

1. In a system having a fluid-filled vessel with fluid outflow means including an outflow line for removing fluid from said vessel and fluid inflow means, including an inflow line and inflow rate control means therein, for injecting fluid into said vessel, a fluid inflow control system for maintaining the fluid level in said vessel between predetermined upper and lower limits comprising: first and second fluid level control channels each including means for sensing the fluid level in said vessel and for developing a control signal indicative of the position of said fluid level; means normally operative to apply the control signal of the first control channel to said inflow rate control means whereby the fluid inflow rate is varied to maintain said fluid level within said upper and lower limits; a plurality of fluid level monitoring means each normally producing indications in the event that said fluid level reaches said upper or lower limits; and means operative in response to said indications from a majority of said fluid level monitoring means for disconnecting the control signal of said first control channel from said inflow rate control means and for applying the control signal of said second control channel thereto whereby control of fluid level in said vessel is transferred automatically to said second channel upon failure of said first channel to maintain said fluid level within said upper and lower limits. 2. The system of claim 1 further including means providing a difference signal indicative of the difference between fluid outflow and inflow flow rates, and means for modifying the control signals of each of said channels in response to said difference signal to thereby provide rapid and fine control of the fluid level in said vessel. 3. The system of claim 2 further including means for monitoring the rate of change of said difference signal and responsive to a predetermined rate of change of said difference signal for automatically disconnecting said difference signal from said control channels. 4. The system of claim 1 further including means for monitoring the rate of change of the control signal of said first channel and responsive to a predetermined rate of change of said control signal of said first channel for automatically transferring vessel fluid level control to said second channel. 5. In a water-cooled nuclear reactor with a nuclear fuel core submerged in water within a pressure vessel and having an output line for taking heated water from said vessel and a feedwater line, including feedwater flow rate control means, for injecting water into said vessel, a feedwater flow control system for maintaining the water level in said vessel between predetermined upper and lower limits comprising: first and second water level control channels each including means connected to said vessel for sensing the water level therein and for developing a level correction signal proportional to the difference between the sensed water level and a predetermined water level; means normally operative to apply the level correction signal of said first channel to said feedwater flow rate control means whereby said feedwater flow rate is adjusted to change the water level toward said predetermined level; a plurality of water level monitoring means connected to receive indication of the water level in said vessel for producing separate upper and lower limit signals in the event said water level reaches said upper limit or drops to said lower limit; logic means connected to receive said limit signals and operative to produce a channel transfer signal upon receipt of upper or lower limit signals from a majority of said water level monitoring means; and a channel transfer switch responsive to said channel transfer signal for disconnecting said first channel from said feedwater flow rate control means and for applying the level correction signal of said second channel to said feedwater flow rate control means. 6. The system of claim 5 further including means providing a difference signal proportional to the difference between the water flow rates through said output and feedwater lines and means for modifying the level correction signals in each of said channels in response to said difference signal. 7. The system of claim 6 further including means for monitoring the rate of change of said difference signal and responsive to a predetermined rapid rate of change of said difference signal for automatically disconnecting said difference signal from said control channels. 8. The system of claim 5 including means responsive to a predetermined rate of change of the level correction signal of said first channel for disconnecting said first channel from said feedwater flow rate control means and for applying the level correction signal of said second channel thereto. 9. In a boiling water nuclear reactor with a nuclear full core submerged in water within a pressure vessel and having a steam outflow line for applying steam to a utilization device and a feedwater inflow line, including feedwater inflow rate control means therein, for injecting water into said vessel, a feedwater flow control system for maintaining the water level in said vessel between predetermined upper and lower limits comprising: first flow rate sensing means connected to said steam line providing a steam flow rate signal proportional to the steam flow rate in said steam line; second flow rate sensing means connected to said feedwater line providing a feedwater flow rate signal proportional to the feedwater flow rate in said feedwater line; a flow rate summer circuit connected to receive said steam flow rate and feedwater flow rate signals and responsive thereto to produce a flow rate difference signal proportional to the difference between the water-equivalent steam outflow rate and the feedwater inflow rate; first and second water level control channels each including: water level sensing means including upper and lower sensors connected to said vessel providing a water level position signal indicative of the position of the water level in said vessel, a level signal summer circuit connected to receive said water level position signal at a first input thereof, means for applying said flow rate difference signal to a second input of the level signal summer circuit of each channel whereby said level signal summer circuit produces a modified level position signal proportional to the difference between said level position signal and said flow rate difference signal, a level control circuit for normally receiving said modified level position signal for comparing it to a predetermined level set point and for producing a level correction output signal, a level signal switching circuit operative in a normal first position to connect the output of said level signal summer circuit to the input of said level control circuit for normally applying said modified level position signal to said level control circuit, said switching circuit being operative in a second position to disconnect said level signal summer circuit and to connect the output of said water level sensing means to the input of said level control circuit whereby said level position signal is applied directly thereto; rate of change detection means connected to receive said flow rate difference signal and responsive to a predetermined rapid rate of change thereof to apply a switch actuating output signal to said level signal switching circuit whereby said level signal switching circuit is placed in said second position thereof; a controller for said feedwater inflow rate control means for adjusting said control means in response to said level correction signal; a level correction signal switching circuit operative in a normal first position to transmit the level correction signal from the level control circuit of said first channel to said controller and operative in a second position alternatively to transmit the level correction signal from the level control circuit of said second channel to said controller; at least three water level monitoring means each normally producing separate upper and lower limit signals in the event that the water level in said vessel rises to said upper limit or drops to said lower limit; a logic circuit connected to receive said limit signals and responsive to the occurrence of at least two upper or at least two lower limit signals from said level monitoring means for applying a switch actuating signal to said level correction signal switching circuit whereby said level correction signal switching circuit is placed in said second position thereof to thereby transmit the level correction signal from the level control circuit of said second channel to said controller. 10. In a system having a fluid-filled vessel with fluid outflow means, including an outflow line, for removing fluid from said vessel and fluid inflow means, including an inflow line and inflow rate control means therein, for injecting fluid into said vessel, a method for maintaining the fluid level in said vessel between predetermined upper and lower limits comprising the steps of: (1) providing first and second fluid level control channels each including means for sensing the fluid level in said vessel and for developing a fluid level control signal indicative of the position of said fluid level in said vessel;  (2) normally applying the fluid level control signal of the first control channel to said inflow rate control means whereby the fluid inflow rate is varied to maintain said fluid level within said upper and lower limits;  (3) providing a plurality of fluid level monitoring means each normally producing separate indications in the event that said fluid level reaches said upper or lower limits;  (4) applying said indications to a majority sensing logic means which is responsive to said indications from a majority of said fluid level monitoring means for disconnecting the control signal of said first control channel from said inflow rate control means and for applying the control signal of said second channel thereto whereby control of the fluid level in said vessel is transferred automatically to said second channel upon failure of said first channel to maintain said fluid level within said upper and lower limits. 11. The method of claim 10 including the further steps of providing means for producing a difference signal indicative of the difference between fluid outflow and fluid inflow rates and modifying the control signals of each of said channels in response to said difference signal to thereby provide rapid control of the fluid level in said vessel. 12. The method of claim 11 including the further steps of monitoring the rate of change of said difference signal and automatically disconnecting said difference signal from said control channels in response to a predetermined rate of change of said difference signal. 13. The method of claim 10 including the step of monitoring the rate of change of the fluid level control signal of said first control channel and automatically transferring control of the fluid level in said vessel to said second channel upon detection of a rate of change of the fluid level control signal of said first channel greater than a predetermined rate. 14. In a system having a fluid-filled vessel with fluid outflow means including an outflow line, for removing fluid from said vessel and fluid inflow means including an inflow line and inflow rate control means therein, for injecting fluid into said vessel, a fluid inflow control system for maintaining the fluid level in said vessel between predetermined upper and lower limits comprising: first and second fluid level control channels each including means for sensing the fluid level in said vessel and for developing a control signal indicative of the position of said fluid level; channel transfer means normally operative to apply the control signal of the first control channel to said inflow rate control means whereby the fluid inflow rate is varied to maintain said fluid level within said upper and lower limits, said channel transfer means being operative when actuated to disconnect said first control channel from said inflow rate control means and to apply the control signal of said second control channel to said inflow rate control means; a rate of change sensing device connected to monitor said control signal of said first channel and responsive to a rate of change thereof greater than a predetermined rate for producing a channel transfer signal; and means for applying said channel transfer signal to said channel transfer means for actuation thereof.