Patent Number: 045267421
Section: claims

1. In a nuclear reactor plant of the type including a pool filled with a neutron-absorbing pool liquid; a reactor vessel within the pool and enclosing a water filled reactor core provided with cooling channels, the reactor vessel including an inlet chamber communicating with the pool liquid via a lower shutdown opening and an outlet chamber communicating with the pool liquid via an upper shutdown opening, a vertical distance being measured between the lower and upper shutdown openings; heat exchange means; outlet means connecting said heat exchange means and said outlet chamber; inlet means connecting said inlet chamber to said heat exchange means; a circulating pump in the primary circuit of the reactor for providing, during normal operation of the reactor, a substantially constant flow of reactor cooling water through the core; a heat insulating layer covering most of the total pool liquid-facing surface of reactor components belonging to said primary circuit and disposed in said pool; the reactor core, in addition to being included in the primary circuit of the reactor plant, being included in a shutdown circuit which comprises the inlet chamber, the lower shutdown opening, the pool, the upper shutdown opening and the outlet chamber, the shutdown circuit having an inherent flow-driving tendency which, when cooling water flows through the reactor core, causes an inherent pressure difference to prevail in the shutdown circuit, the inherent pressure difference being counteracted and balanced by the pressure drop prevailing across the reactor core due to the flow therethrough of reactor cooling water, so that no significant supply of pool liquid to the primary circuit takes place, the improvement comprising: said reactor vessel being filled during normal operation with cooling water which extends along a portion greater than one half the length of said vertical distance;  pool cooler means disposed in said pool for cooling said pool liquid to a temperature at least 50 degrees Celsius lower than the temperature of said cooling water flowing from said outlet chamber and  said pool liquid and said cooling water extending respectively, within said pool and said reactor vessel to levels sufficiently above said reactor core so that a first static pressure exerted by a theoretical column of cooling water extending inside said reactor vessel and having a height which is equal to said vertical distance is lower than a second static pressure exerted by a theoretical column of pool liquid of the same height as said theoretical column of cooling water, the difference between said second static pressure and said first static pressure being more than 60% of said pressure drop prevailing across said reactor core.  a first control pipe for adding cooling water to said primary system;  a valve device for said first control pipe;  a second control pipe having an inlet opening in the vicinity of said lower shutdown opening;  a third control pipe having an inlet opening for said pool liquid in the upper part of said pool;  a first remotely controllable outflow valve in said second control pipe;  a second remotely controllable outflow valve in said third control pipe; and  relay means for interlocking said first outflow valve with said valve device at a first relay position and interlocking said second outflow valve with said valve device at a second relay position, in such a manner that the ingoing flow of cooling water through said first control pipe is equal to the outgoing flow of pool liquid through said second or third control pipe, said relay means being arranged to assume said second relay position in response to said signal.  pool cooler means disposed in said pool for cooling said pool liquid to a temperature at least 50 degrees Celsius lower than the temperature of said cooling water flowing from said outlet chamber; and  in addition to said circulating pump, a liquid jet pump which during normal reactor operation is arranged to operate in said shutdown circuit and to provide part of said pressure difference prevailing in said shutdown circuit whereby during abnormal reactor operation said jet pump draws pool liquid into said reactor vessel. 2. The improvement according to claim 1, wherein said pool cooler means comprises an inlet pipe and a return pipe for a cooling fluid, a greater part of the total cooling surface of said pool cooler means being arranged in contact with said pool liquid, said inlet pipe and said return pipe being connected to a heat-receiving system arranged outside said pool. 3. The improvement according to claim 1, wherein said vertical distance is at least seven times the vertical dimension of said core. 4. The improvement according to claim 1, wherein all the portions of said inlet means and said outlet means located in said pool are arranged above the upper edge of said reactor core and at a distance therefrom which constitutes at least 20% of the maximum liquid depth of said pool. 5. The improvement according to claim 1, wherein said lower shutdown opening is provided with a gradient lock comprising a plurality of vertical channels, and with a gas lock device with a supply pipe for gas from outside said pool. 6. The improvement according to claim 1, wherein said circulating pump is arranged to be driven by a driving system having a control circuit for controlling its speed, said control circuit of said driving system being connected, via signal transmission means to a level indicator arranged at said lower shutdown opening for indicating the position of a boundary layer between said cooling water and said pool liquid, said level indicator being arranged to give a first signal at a high position of said boundary layer and to give a second signal at a relatively lower position of said boundary layer, whereby said first signal gives an increase of the speed of rotation of the circulating pump, whereas said second signal gives a reduction of this speed. 7. The improvement according to claim 1, wherein a level indicator is arranged at said upper shutdown opening for indicating the position of a boundary layer between said reactor cooling water and said pool liquid, said level indicator being arranged to give a signal at a high position of said boundary layer, said reactor plant further comprising: 8. A reactor plant according to claim 2, wherein at least one of said shutdown openings is provided with a gradient lock comprising a plurality of vertical channels arranged adjacent each other, the pool liquid present in the pool and the cooling water present in the reactor vessel during normal reactor operation exhibiting a measurable mutual difference as regards a certain physical property; and an upper transducer and a lower transducer for said property are arranged at a mutual vertical distance from each other in said gradient lock. 9. A nuclear reactor plant of the type including a pool filled with a neutron-absorbing pool liquid; a reactor vessel within the pool and enclosing a water-filled reactor core provided with cooling channels, the reactor vessel including an inlet chamber communicating with the pool liquid via a lower shutdown opening and an outlet chamber communicating with the pool liquid via an upper shutdown opening, a vertical distance being measured between the lower and upper shutdown openings; heat exchange means; outlet means connecting the heat exchange means and the outlet chamber; inlet means connecting the inlet chamber and the heat exchange means; a circulating pump in the primary circuit of the reactor for providing, during normal operation of the reactor, a substantially constant flow of reactor cooling water through the core; a heat insulating layer covering most of the total pool liquid-facing surface of reactor components belonging to the primary circuit and disposed in the pool; the reactor core, in addition to being included in the primary circuit of the reactor plant, being included in a shutdown circuit which comprises the inlet chamber, the lower shutdown opening, the pool, the upper shutdown opening and the outlet chamber, the shutdown circuit having an inherent flow-driving tendency which, when cooling water flows through the reactor core, causes a pressure difference to prevail in the shutdown circuit, the pressure difference being counteracted and balanced by the pressure drop prevailing across the reactor core due to the flow therethrough of reactor cooling water, so that no significant supply of pool liquid to the primary circuit takes place, the improvement comprising: 10. A reactor plant according to claim 9, further comprising means for interlocking said liquid pump with said circulating pump so that an increase or reduction of the pressure difference generated by said circulating pump results in a corresponding increase or reduction of the pressure difference generated by said liquid pump. 11. A reactor plant according to claim 9, wherein said liquid pump is a water jet pump, in which the water jet receives cooling water flow driven by said circulating pump without delivering any flow of liquid from said pool. 12. The improvement according to claim 9, wherein said pool cooler means comprises an inlet pipe and a return pipe for a cooling fluid, a greater part of the total cooling surface of said pool cooler means being arranged in contact with said pool liquid, said inlet pipe and said return pipe being connected to a heat-receiving system arranged outside said pool.