Patent Number: 044735286
Section: claims

1. A safeguard system for a nuclear reactor power plant having a reactor assembly with a reactor core including fuel therein, at least one steam generator, said steam generator having a first operative connection to said reactor assembly for the flow of a high-temperature high-pressure reactor coolant therethrough, said reactor coolant having a first pressure the magnitude of which is substantially constant during conditions of normal operation, and a closed primary containment structure sealingly enclosing said reactor and said steam generator, said safeguard system comprising, in combination, a refill reservoir of cooling liquid disposed generally internally of said containment structure, said cooling liquid being pressurized to a second predetermined pressure the magnitude of which during conditions of normal operation is less than the magnitude of said first pressure thereby defining a fist predetermined pressure differential, first conduit means for communicating between said cooling liquid and said reactor assembly, second conduit means for communicating between said steam generator and said cooling liquid, said first conduit means being effective to supply a flow of said cooling liquid to said reactor assembly whenever there is an accidental loss of said reactor coolant causing a reduction in the magnitude of said first pressure sufficient to attain a second predetermined pressure differential as between said cooling liquid and said reactor coolant within said reactor assembly, said second predetermined pressure differential causing flow of said cooling liquid to be directed to said reactor core, said flow of said cooling liquid being directed to said reactor core to thereby replenish said accidental loss of said reactor coolant, said second conduit means being effective when a third predetermined pressure differential is attained between said cooling liquid and the steam within said steam generator for supplying comparatively high-pressure steam to said cooling liquid to thereby provide a pumping force to said cooling liquid to completely fill that portion of the reactor assembly containing the fuel of said reactor core, a deluge reservoir of cooling liquid disposed entirely internally of said containment structure located at a vertical relationship above said reactor assembly creating a static pressure, said deluge reservoir having an upper region and a lower region first permanently open steam venting means within said deluge reservoir in communication with said containment structure at said upper region for directly receiving steam within said containment structure, first steam absorbing means within said deluge reservoir extending substantially throughout the depth of said reservoir and communicating with said venting means for absorbing steam from said venting means throughout said reservoir, a third conduit communicating with said deluge reservoir lower region and connected through valve means to said first conduit wherein the cooling liquid within said deluge reservoir may be selectively introduced into the reactor assembly for reactor core cooling purposes, a quench reservoir of cooling liquid disposed entirely internally of said containment structure, second steam venting means defined within said quench reservoir communicating with said containment structure wherein said quench reservoir is capable of receiving steam from within said containment structure, conduit means selectively connecting said quench reservoir to said steam generator for supplying emergency feed water thereto, second steam absorbing means within said quench reservoir extending substantially throughout the depth of said quench reservoir and communicating with said second venting means for absorbing steam from said second venting means throughout said quench reservoir a pressurizer in communication with said reactor coolant maintaining said reactor coolant first pressure, at least one relief valve communicating with a pressurizer opening when the pressure within said pressurizer exceeds a predetermined maximum pressure, said relief valve having a discharge communicating with said deluge reservoir wherein steam discharged through said relief valve passes into said deluge reservoir and it absorbed thereby, said steam absorbing means of said deluge and quench reservoirs comprising a plurality of conduits extending into said reservoirs each having a perforated axial portion through which vented steam is ejected, and a substantially vertically oriented shroud encompassing each of said perforated portions and in such radial spaced relationship thereto whereby said discharge through the perforated venting conduits is scrubbed externally due to thermal movement of the deluge and quench coolant within said reservoirs within said shrouds, said deluge and quench reservoirs being effective upon said containment structure being pressurized with steam due to accidental loss of reactor coolant to absorb the heat within said steam during and after accidental loss of reactor coolant for depressurizing said containment structure, said deluge reservoir steam absorbing means being constructed to effect immediate direct cooling of said reactor core, and said quench reservoir steam absorbing means being constructed to effect absorption of energy for the term of the accident and at a rate less than that of said deluge reservoir. 2. The method of effecting containment of a nuclear reactor power plant during accidental loss of reactor coolant wherein the reactor power plant includes a reactor assembly with a reactor core including fuel therein, at least one steam generator, said steam generator having a first operative connection to said reactor assembly for the flow of a high-temperature high-pressure reactor coolant therethrough, said reactor coolant having a first pressure magnitude of which is substantially constant during conditions of normal operation, and a closed primary containment structure sealingly enclosing said reactor and said steam generator, said safeguard system comprising, in combination, a refill reservoir of cooling liquid disposed generally internally of said containment structure, said cooling liquid being pressurized to a second predetermined pressure the magnitude of which during conditions of normal operation is less than the magnitude of said first pressure thereby defining a first predetermined pressure differential, first conduit means for communicating between said cooling liquid, and said reactor assembly, second conduit means for communicating between said steam generator and said cooling liquid, said first conduit means being effective to supply a flow of said cooling liquid to said reactor assembly whenever there is an accidental loss of said reactor coolant causing a reduction in the magnitude of said first pressure sufficient to attain a second predetermined pressure differential as between said cooling liquid and said reactor coolant within said reactor assembly, said second predetermined pressure differential causing flow of said cooling liquid to be directed to said reactor core, said flow of cooling liquid being directed to said reactor core to thereby replenish said accidental loss of said reactor coolant, said second conduit means being effective when a third predetermined pressure differential is attained between said cooling liquid and the steam within said steam generator for supplying comparatively high-pressure steam to said cooling liquid to thereby provide a pumping force to said cooling liquid to completely fill that portion of the reactor assembly containing the fuel of said reactor core, a deluge reservoir of cooling liquid disposed entirely internally of said containment structure located at a vertical relationship above said reactor assembly creating a static pressure, said deluge reservoir having an upper region and a lower region, first permanently open steam venting means within said deluge reservoir in communication with said containment structure at said upper region for directly receiving steam within said containment structure, first steam absorbing means within said deluge reservoir extending substantially throughout the depth of said reservoir and communicating with said venting means for absorbing steam from said venting means throughout said reservoir, a third conduit communicating with said deluge reservoir lower region and connected through valve means to said first conduit wherein the cooling liquid within said deluge reservoir may be selectively introduced into the reactor assembly for reactor core cooling purposes, a quench reservoir of cooling liquid disposed entirely internally of said containment structure, second steam venting means defined within said quench reservoir communicating with said containment structure wherein said quench reservoir is capable of receiving steam from within said containment structure, conduit means selectively connecting said quench reservoir to said steam generator for supplying emergency feed water thereto, second steam absorbing means within said quench reservoir extending substantially throughout the depth of said quench reservoir and communicating with said second venting means for absorbing steam from said second venting means throughout said quench reservoir, a pressurizer in communication with said reactor coolant maintaining said reactor coolant first pressure, at least one relief valve communicating with a pressurizer opening when the pressure within said pressurizer exceeds a predetermined maximum pressure, said relief valve having a discharge communicating with said deluge reservoir wherein steam discharged through said relief valve passes into said deluge reservoir and is absorbed thereby, said steam absorbing means of said deluge and quench reservoirs comprising a plurality of conduits extending into said reservoirs each having a perforated axial portion through which vented steam is ejected, and a substantially vertically oriented shroud encompassing each of said perforated portions in such radial spaced relationship thereto whereby said discharge through the perforated venting conduits is scrubbed externally due to thermal movement of the deluge and quench coolant within said reservoirs within said shrouds, said deluge and quench reservoirs being effective upon said containment structure being pressurized with steam due to accidental loss of reactor coolant to absorb the heat within said steam during and after accidental loss of reactor coolant for depressurizing said containment structure, said deluge reservoir steam absorbing means being constructed to effect immediate direct cooling of said reactor core, and said quench reservoir steam absorbing means being constructed to effect absorption of energy for the term of the accident and at a rate of less than that of said deluge reservoir, comprising the steps of venting the steam within the containment structure into cooling liquid within said deluge and quench reservoirs at said different heat absorption rates, and simultaneously absorbing energy from the containment structure in said reservoirs during the accidental loss of said reactor coolant over a duration related to the rate of heat absorption.