Patent Number: 046438718
Section: description

The drawing very diagrammatically shows the vessel 10 for a pressurized water nuclear reactor, whose core 12 is located within the vessel 10 and is supported by a ferrule or collar 14. The reactor core is traversed by a cooling fluid 16 which flows in the direction of the arrows. The cooling fluid 16, generally constituted by pressurized water in this type of reactor, extracts the heat given off by the nuclear fission in the reactor core and the transfer thereof to the not shown steam generators by a primary cooling circuit. The primary circuit is constituted by a number of loops, but only a hot branch 18 and a cold branch 20 are partly shown in the drawing. According to the invention, at least one high pressure reservoir 22 filled with boric acid solution 24 is placed in the reactor confinement enclosure 26. In practice, for safety reasons, there are at least two reservoirs like reservoir 22. Each reservoir 22 is placed at a level such that the bottom thereof is positioned above the hot branch 18 and cold branch 20 of the primary circuit. A first pipe 28 permanently connects the top of reservoir 22 to reactor vessel 10 between hot branch 18 and cold branch 20 of the primary circuit and the high level of reactor core 12. A second pipe 30 connects the bottom of the reservoir 22 to vessel 10 which it preferably enters at the same level as pipe 28 in order to prevent the natural flow of water between vessel 10 and reservoir 22. In a not shown variant, pipes 28 and 30 can enter the vessel 10 at two different levels when it is desired for the boric acid solution to flow by natural convection between the vessel and the reservoir. As illustrated in the drawing, pipe 30 is extended downwards within the vessel 10 by an elbow or bend 29, whose end enters a funnel 31 constituting the upper end of a tube 33 issuing in the vicinity of the bottom of the vessel. The end of bend 29 is at a level close to the high level of core 12 in such a way that if the level in vessel 10 drops the steam formed firstly enters the pipe 28 to start the drainage of reservoir 22. The free space left between the end of bend 29 and funnel 31 makes it possible for the injection water from reservoir 22 to partly mix with the hot water of the vessel, the remainder of the injection water passing directly to the bottom of the vessel via tube 33. As illustrated in the drawing, each of the pipes 28 and 30 has a substantially horizontal part forming an obstacle to the natural convection of boric acid solution 24 between the reactor vessel and the reservoir. As neither of the pipes 28 and 30 is equipped with a valve, reservoir 22 is directly and permanently connected by said two pipes with reactor vessel 10. In the represented embodiment, the water 24 in reservoir 22 is cooled by means of a cooling circuit 34 having a coil-shaped heat exchanger 36 located within reservoir 22, a circulating pump 35 and a valve 37. The cooling fluid flowing in circuit 34 comes from a reservoir 42 and is permanently cooled, for example, by means of a second exchanger 38 within reservoir 42. The cooling circuit 34 is connected to the primary circuit via a standby or emergency injection circuit 32 controlled by a valve 39, which opens when it receives an emergency injection signal and by a three-way valve 49 which, as soon as the primary pressure has dropped sufficiently, permits the filling of the primary circuit by blocking the recirculation of the emergency injection water towards reservoir 42. Preferably, the emergency cooling device according to the invention also has pipes 40 and 60 for cooling the reactor on shutdown, which respectively connect the upper part and bottom of reservoir 22 with one or more of the hot and cold branches 18, 20 respectively of the primary circuit. These pipes 40 and 60, by means of a pump 42 and after opening the electrovalves 44 and 64, make it possible to remove the sensible heat of the primary circuit and the residual power of the reactor core during the cold shutdown of the latter, no matter what the temperature and pressure of the primary circuit water. A heating circuit 70 for the water in reservoir 22 is connected with pipe 40 upstream of electrovalve 44. Circuit 70 has an electrovalve 69 and a coil 71, preferably located at the bottom of reservoir 22 and issuing into the nozzle of pipe 60. The ends of coil 71 are thus indirectly connected by pipes 40 and 60 to the hot and cold branches 18, 20 respectively of the primary circuit. Thus, this circuit is arranged in such a way that it causes no movement of the water of reservoir 22 towards the primary circuit, thus making it possible to keep the boron concentration of the reservoir at a constant level. Obviously, the water in reservoir 22 can be heated by any means (e.g. electricity). In the represented embodiment, the boric acid concentration of the water 24 contained in reservoir 22 is controlled and adjusted by means of a circuit 50 comprising two electrovalves 52. Circuit 50 connects reservoir 22 to a conventional chemical and volumetric control circuit outside the confinement enclosure 26 of the reactor. Finally, a purging or draining circuit 54, controlled by an electrovalve 56, issues into the upper part of reservoir 22. The operation of the pressurized water reactor partly described with reference to the drawing is identical to that of known reactors of this type and will not be further described here. During an accidental decompression of the primary circuit resulting from a loss of primary fluid through an opening or crack formed in a pipe, the optionally cold boric acid solution contained in reservoir 22 is automatically discharged by pipe 30 into reactor vessel 10 as soon as the water level in said vessel drops below the entry point of pipe 28. Thus, the putting into operation of the device according to the invention, is automatically controlled by the drop in the water level in the reactor vessel, without it being necessary to use one or more electrovalves. In addition, this is in no way linked with the opening of valves. Thus, the cooling of reactor core 12 is always ensured as soon as the latter is exposed to the risk of being drained, i.e. at the most opportune moment, no matter what the size of the crack or opening formed in the primary circuit. Thus, the device according to the invention is much more efficient than the prior art devices in which the putting into operation is controlled by isolating valves sensitive to a given pressure in the primary circuit. The device described relative to the drawing also makes it possible to ensure the cooling of the reactor on shutdown by opening electrovalves 44 and 64 and by making the primary fluid flow between vessel 10 and reservoir 22 by means of pump 42 located in pipe 60. The primary fluid is then cooled in reservoir 22 by means of cooling circuit 34 and in particular exchanger 36. The present device thus makes it possible to remove the sensible heat from the primary circuit and the residual power from the reactor core 12 during the cold shutdown of the reactor, without it being necessary to wait for the temperature and pressure of the primary circuit water to drop significantly compared with their normal operating value. Obviously, the invention is not limited to the embodiment described hereinbefore. In particular, the pipes 40 and 60 for cooling the reactor on shutdown can optionally be eliminated and in this case the device will only carry out the standby cooling of the reactor core in the case of an accident through loss of primary fluid. Circuit 50 which makes it possible to control and adjust the boric acid concentration in the water 24 contained in reservoir 22 can also be eliminated or replaced by any equivalent device.