Patent Number: 051261014
Section: description

DESCRIPTION OF THE PREFERRED EMBODIMENTS As shown in FIG. 1, an apparatus for cleaning up reactor coolant in accordance with a first embodiment of the present invention includes a piping 11 having its open end at the bottom of a reactor pressure vessel 1, a piping 4 branching off a primary loop recirculation piping 3 and being connected to the piping 11, a regenerative heat exchanger 5, a non-regenerative heat exchanger 6, a pump 7, a cleanup device 8, a piping 15 extending from the cleanup device 8 to a reactor feedwater piping 9, and a siphon brake valve 13 provided at the highest position C in the piping 11. The piping 11 for taking out the reactor coolant in the reactor pressure vessel 1 is arranged to extend through the side wall of the reactor pressure vessel 1 at a position E which is higher than the position of a reactor core 12 within the reactor pressure vessel 1. In operation, during normal running of the reactor and during the hot stand-by period of the same, the siphon brake valve 13 is closed to cut off communication with the atmosphere. The crud component accumulated in the bottom portion of the reactor pressure vessel 1 flows through the piping 11 together with the reactor coolant and then intermingles with the reactor coolant flowing through the branch piping 4. The crud component which has intermingled with the reactor component from the branch piping 4 passes through the regenerative heat exchanger 5 and the non-regenerative heat exchanger 6 and is then fed into the cleanup device 8 by means of the pump 7. After the crud component has been eliminated by the cleanup device 8, the reactor coolant flows through the piping 15 into the reactor feedwater piping 9 and is returned to the reactor pressure vessel 1. During inspection or modification of the reactor, the siphon brake valve 13 is closed to cut off communication with the atmosphere. The reactor coolant in the reactor pressure vessel 1 flows out of it together with the crud component accumulated in the bottom portion of the reactor pressure vessel 1. Thereafter, the reactor coolant is discharged into another portion through a piping (not shown) without being returned to the reactor pressure vessel 1 through the feedwater piping 9. Should the reactor coolant be partially lost due to, for example, breakage of the piping 11 outside the reactor pressure vessel 1, the reactor pressure vessel 1 is replenished with the required amount of reactor coolant from an emergency core cooling system (not shown), whereby the reactor core 12 is again flooded with the reactor coolant. When the pressure in the reactor 12 falls to atmospheric pressure, the remote operable valve 13 for the siphon brake opens to the atmosphere to cancel out the siphon effect. Accordingly, if the supply of water into the reactor core 12 is stopped, the water level in the reactor core 12 does not fall below the height of the position c at which the siphon brake valve 13 and the piping 11 are connected to each other. Subsequently, the reactor coolant may be replenished by an amount corresponding to any fall in the water level due to evaporation, and it is therefore possible to cool the reactor core 12 by means of a residual-heat eliminating system (not shown). Since, in this embodiment, the position E at which the piping 11 extends from the reactor pressure vessel 1 to the exterior is selected to be higher than the position of the reactor core 12, it is possible to ensure that the piping has a sufficiently large gradient as compared with the conventional arrangement where a corresponding piping is connected to the lowest portion of a reactor pressure vessel. Accordingly, the amount of crud component in the reactor coolant sticking to the inner surface of the piping 11 can be reduced by virtue of the effect of gravitation. Since the piping 11 extends upward within the reactor pressure vessel 1, the radiation source leaking from the portion of the piping 11 which is accommodated in the reactor pressure vessel 1 is shielded by the steel plate thereof. As can be seen from FIG. 4 which shows the relationship between the thickness of the steel plate and the attenuation factor of the radiation source, the level of the radiation source (1.5 MeV) of the reactor coolant can be reduced to approximately 1/100 by virtue of the steel plate (approximately 16 cm thick) of the reactor pressure vessel 1. As described above, it is possible to decrease the radiation dose in the atmosphere in a primary containment vessel 10 during scheduled inspections and it is also possible to provide the effect of mitigating the radiation exposure of workers who must work within the primary containment vessel 10 during scheduled inspections. If breakage should take place in the piping for taking out the reactor coolant through the lowest portion of the reactor pressure vessel, it is possible to easily cope with the accident. FIG. 2 shows an apparatus for cleaning up reactor coolant in accordance with a second embodiment of the present invention. In the figure, the same reference numerals are used to denote elements which are the same as those shown in FIG. 1. The reactor-coolant cleanup apparatus of FIG. 2 differs from that of FIG. 1 in that the piping 4 branching off the primary loop recirculation piping 3 and being connected to the piping 11 is eliminated. In the operation of the apparatus shown in FIG. 2, the reactor coolant in the reactor pressure vessel 1 is taken out of it through the piping 11 alone. Accordingly, it is possible to increase the rate of reactor coolant taken out at the lowest portion of the reactor pressure vessel 1 through the piping 11 and, therefore, to increase the velocity of reactor-coolant flow in the piping 11. Accordingly, the amount of crud in the reactor coolant sticking to the inner surface of the piping 11 can be reduced and it is also possible to reduce the dose rate of the piping 11 by the synergistic effect of an increase in the velocity of reactor-coolant flow and a reduction in the amount of crud sticking to the inner surface of the piping 11 owing to the large gradient of the piping. Since no piping branches off the primary loop recirculation piping 3, the welded portion which joints the primary loop recirculation piping 3 and the reactor coolant taking-out piping 4 can be eliminated. Accordingly, the number of portions to be inspected during an in-service inspection (ISI) while the reactor is in service can be decreased so that radiation exposure can be mitigated. FIG. 3 shows an apparatus for cleaning up reactor coolant in accordance with a third embodiment of the present invention. In the figure, the same reference numerals are used to denote elements which are the same as those shown in FIG. 1. The reactor-coolant cleanup apparatus of FIG. 3 differs from the apparatus shown in FIG. 1 in that the former apparatus is provided with an automatic control device 14 for controlling the opening and closing of the siphon brake valve 13. In the operation of the reactor-coolant cleanup apparatus of FIG. 3, if the piping 11 for taking out the reactor coolant at the lowest portion of the reactor pressure vessel 1 should be broken outside the reactor pressure vessel 1 and a loss-of-reactor-coolant accident should thereby be caused, a pressure gauge P is employed to monitor the pressure and water level in the reactor as well as the pressure in the piping. If it is determined (a) that the pressure in the aforesaid reactor pressure vessel 1 has fallen to a level equal to the atmospheric pressure and (b) that the water level in the reactor pressure vessel 1 has fallen to the position E at which the piping 11 is arranged to extend through the side wall of the reactor pressure vessel 1, the automatic control device 14 operates to open the siphon brake valve 13, enabling the accident to be handled rapidly and correctly. FIG. 5 shows the system construction of a conventional reactor-coolant cleanup system for use in a boiling water reactor power plant. The reactor coolant in the reactor pressure vessel 1 is taken out of the primary containment vessel 10 by way of a piping 2 which is connected to the bottom of the reactor pressure vessel 1 and the branch piping 4 branching off the primary loop recirculation piping 3. The reactor coolant is then passed through the regenerative heat exchanger 5, the non-regenerative heat exchanger 6, a cleanup pump 7 for reactor coolant, and an apparatus 8 for cleaning up radioactive materials in that order. Thereafter, the reactor coolant is returned to the reactor pressure vessel 1 by way of the reactor feedwater piping 9. In this conventional example, no account is taken of counter-measures for reducing the dose rate of the reactor-coolant taking-out piping 2 connected to the bottom of the reactor pressure vessel 1. In accordance with the present invention, the following advantages can be achieved. (1) Since the piping for taking out reactor coolant extends out of the reactor pressure vessel at a position which is higher than the lowest portion thereof, the length of the horizontally extending portion of the piping can be decreased so that the amount of crud sticking to the inner surface of the piping within the reactor decreases. Accordingly, the intensity of the radiation source is reduced and the resultant radiation exposure can be mitigated to a further extent. (2) Since the piping for taking out reactor coolant extends, within the reactor pressure vessel, to a position higher than the lowest portion of the reactor pressure vessel, the side wall of the reactor pressure vessel serves as shielding. Accordingly, it is possible to exclude a portion of the piping from the radiation source which contributes to radiation exposure. (3) Since the piping for taking out reactor coolant extends, within the reactor pressure vessel, to a position higher than the lowest portion of the reactor pressure vessel, it is possible to reduce the amount of reactor coolant flowing out of the reactor pressure vessel due to accidents. (4) If the piping which branches off the primary loop recirculation piping so as to extract a portion of the reactor coolant in the reactor is eliminated, it is possible to increase the velocity of flow in the piping for taking out water in the reactor core so that the amount of crud sticking to the inner surface of this piping can be reduced. (5) Even if an accident should take place, after the pressure in the reactor pressure vessel has fallen to a level equal to atmospheric pressure, a siphon brake is applied to both the interior and the exterior of the reactor pressure vessel in a state wherein the water level in the reactor pressure vessel has reached the position at which the piping for taking out water in the reactor core extends through the side wall of the reactor pressure vessel, whereby the reactor core is maintained in a flooded state. It is, therefore, possible to easily cope with the accident. (6) The inlet port of the piping for taking out water in the reactor core is located at the lowest portion of the reactor pressure vessel. Accordingly, in the case of a drain-off operation of the reactor pressure vessel, it is possible to drain all reactor coolant from the reactor pressure vessel by virtue of the siphon effect.