JP5513846B2 - Nuclear power plant and method for operating the same - Google Patents

Description

  The present invention relates to a nuclear power plant including a fuel pool cooling purification system and a pressure suppression pool purification system, and an operation method thereof.

  In a nuclear power plant using a boiling water light water reactor, the decay heat of spent fuel stored in the spent fuel pool is removed, the pool water temperature is kept below a specified value, and the quality of the spent fuel pool is maintained. It has fuel pool cooling and purification equipment. Moreover, the nuclear power plant using the improved boiling water light water reactor has a pressure suppression pool purification facility for maintaining the water quality of the pressure suppression pool (S / P) in addition to the fuel pool cooling purification facility.

  FIG. 10 shows the configuration of the current fuel pool cooling purification system (FPC system) and pressure suppression pool purification system (SPCU system).

  Pool water warmed by decay heat generated from the spent fuel 2 in the spent fuel pool 1 moves to the upper part of the spent fuel pool 1. Pool water in the upper part of the spent fuel pool 1 flows into the skimmer surge tank 3. Pool water flowing into the skimmer surge tank 3 passes through the FPC pump suction pipe 4, is pressurized by the FPC pump 27, and is purified by the FPC filtration desalting tower 28. The purified pool water is cooled by the FPC heat exchanger 29 and returned to the bottom of the spent fuel pool 1 via the FPC return pipe 15 and the spent fuel pool diffuser 16.

  Here, two FPC heat exchangers 29 are divided into two groups (two systems) of reactor auxiliary coolant water systems (RCW systems) (not shown) consisting of three independent sections (three systems). It is cooled one by one.

  The pressure suppression pool water passes through the SPCU pump suction pipe 20 through the S / P strainer 19, is pressurized by the SPCU pump 30, and is purified by the FPC filtration desalting tower 28. The purified pressure suppression pool water is returned to the pressure suppression pool 18 via the S / P return pipe 23.

  As shown in Patent Document 1, from the viewpoint of rationalization of the fuel pool cooling and purification equipment and the pressure suppression pool purification equipment, it is mentioned that the SPCU pump can be used as an FPC pump. In Patent Document 1, the fuel pool cooling purification / pressure suppression pool purification facility is composed of one FPC pump, one SPCU pump, two FPC filtration desalting towers, and two FPC heat exchangers.

JP 2003-149380 A

  In nuclear power plants, it is currently desired to respond to a single failure during online maintenance (maintenance of equipment during reactor operation) in order to improve reliability and to shorten regular inspections to increase the operating rate.

  However, in the conventional FPC system / SPCU system configuration, the FPC system has two sections (two systems). For this reason, if one of the two FPC systems is shut down for online maintenance during reactor operation, and if a single failure of the equipment is assumed as a safety evaluation criterion, Since the fuel pool cooling sometimes becomes impossible, there was a problem that safety could not be secured.

  In addition, when performing regular inspection shortening with the conventional FPC / SPCU system configuration, the amount of decay heat to be removed from the fuel pool increases in order to close the spent fuel pool gate in a situation where the decay heat is large. To do. Therefore, the heat removal amount of the heat exchanger is increased, and there is a problem that the heat load balance of the RCW system 3 section deteriorates in the configuration of the FPC system 2 section.

  The present invention has been made in view of the above problems, and in the FPC system / SPCU system of a nuclear power plant, it is possible to obtain high reliability even when a single failure is assumed at the time of online maintenance, The purpose is to improve the thermal load balance of the RCW 3 divisions.

In order to achieve the above object, a nuclear power plant according to the present invention includes a spent fuel pool for storing spent fuel in water, a pressure suppression pool for suppressing an excessive pressure rise in a reactor containment vessel, A fuel pool cooling and purification system that takes out fuel pool water from the spent fuel pool, cools and purifies the fuel pool water and returns it to the spent fuel pool, and a part of the fuel pool cooling and purification system by switching a valve And a pressure suppression pool purification system that takes out the pressure suppression pool water in the pressure suppression pool and purifies the pressure suppression pool water, wherein the fuel pool cooling and purification system includes a fuel A filtration desalination device for purifying pool water, three heat exchangers in parallel with each other for cooling the fuel pool water, and a first in parallel with each other for circulating the fuel pool water Second and third pump, has, the pressure suppression pool cleaning system is configured to purify the pressure suppression pool water by using at least the third pump and the filtration demineralizer, and The discharge side pipes of the first, second, and third pumps of the fuel pool cooling and purification system can communicate with each other, and branch off from the discharge side pipe of the first pump, and A bypass pipe that is bypassed and connected to the upstream side of the heat exchanger is provided, and when the reactor is shut down, the fuel pool water is circulated by the bypass pipe and the first pump to exchange the three heats. It is comprised so that the said fuel pool water can be cooled with the at least 1 unit | set heat exchanger .

Further, the nuclear power plant operating method according to the present invention is:
A method for operating a nuclear power plant, comprising: a spent fuel pool for storing spent fuel in water; and a pressure suppression pool for suppressing an excessive pressure rise in a reactor containment vessel, comprising: Using the three heat exchangers in parallel with each other and the first, second and third pumps in parallel with each other, the fuel pool water in the spent fuel pool is taken out and the fuel pool water is cooled. And a fuel pool cooling and purification step for purifying and returning to the spent fuel pool, and switching the valve to take out the fuel pool water in the spent fuel pool, bypassing the filtration demineralizer, and a fuel pool cooling step of cooling the fuel pool water by the heat exchanger at least one group of heat exchangers of the 3 groups by circulating the fuel pool water pump, by switching the valve, the pressure Remove the pressure suppression pool water in the control pool, have a, and the suppression pool cleaning system process to purify the pressure suppression pool water by using at least the third pump and the filtration demineralizer, the pressure suppression the pool cleaning system process characterized Rukoto, the performed simultaneously with the fuel pool cooling step.

  According to the present invention, in the FPC system / SPCU system of a nuclear power plant, high reliability can be obtained even when a single failure is assumed at the time of online maintenance, and the thermal load balance of the RCW system 3 sections is improved. be able to.

1 is a system diagram showing a fuel pool cooling and purification system (FPC system) and a pressure suppression pool purification system (SPCU system) according to a first embodiment of a nuclear power plant according to the present invention, and shows the situation during normal operation of a nuclear reactor. FIG. FIG. 2 is a system diagram showing a water filling operation state of a reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. 1. FIG. 2 is a system diagram showing a water draining operation state of a reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. 1. It is a systematic diagram which shows the fuel pool cooling purification system and pressure suppression pool purification system which concerns on 2nd Embodiment of the nuclear power plant which concerns on this invention, Comprising: It is a figure which shows the condition at the time of a nuclear reactor normal operation. 5 is a system diagram showing a water filling operation state of a reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. FIG. 5 is a system diagram showing a water drain operation state of a reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. 4. FIG. 5 is a system diagram showing a fuel pool cooling purification system / pressure suppression pool purification system according to a third embodiment of a nuclear power plant according to the present invention, and is a diagram showing a state of a pressure suppression pool purification operation during normal reactor operation; It is. 8 is a system diagram showing a water filling operation state of a reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. FIG. 8 is a system diagram illustrating a water drain operation state of a reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. 7. It is a systematic diagram which shows the fuel pool cooling purification system and pressure suppression pool purification system of the conventional nuclear power plant, Comprising: It is a figure which shows the condition at the time of a nuclear reactor normal operation.

  Hereinafter, an embodiment of a fuel pool cooling purification / pressure suppression pool purification facility for a nuclear power plant according to the present invention will be described with reference to the drawings. Here, parts that are the same as or similar to those in the prior art shown in FIG.

[First Embodiment]
A first embodiment of a nuclear power plant according to the present invention will be described with reference to FIGS. 1, 2, and 3. FIG. 1 is a system diagram showing a fuel pool cooling purification system / pressure suppression pool purification system according to the first embodiment, and is a diagram showing a situation during normal operation of a reactor. FIG. 2 is a system diagram showing a water filling operation state of the reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. FIG. 3 is a system diagram showing a water draining operation state of the reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. In these drawings, among the valves, those shown in white are in an open state, and those that are black are in a closed state. The same applies to the following drawings.

  This first embodiment is a boiling water nuclear power plant, in which a spent fuel pool 1 is filled with cooling water, and spent fuel 2 is stored therein. Cooling water overflowing from the spent fuel pool 1 flows into the skimmer surge tank 3, and the cooling water in the skimmer surge tank 3 circulates through a fuel pool cooling and purification system (FPC system) 50 to enter the spent fuel pool 1. It is comprised so that it may return to the spent fuel pool diffuser 16 of this.

  That is, the skimmer surge tank 3 passes through a fuel pool cooling purification (FPC) pump suction pipe 4, a fuel pool cooling purification (FPC) pump (first pump) 9, a fuel pool cooling purification (FPC) / pressure suppression pool purification. The (SPCU) pump (second pump) 8 and the FPC / SPCU pump (third pump) 7 are connected to the suction side. A valve 51 is arranged between the clearance surge tank 3 and the suction side piping of the FPC pump 9, and a valve 52 is arranged between the clearance surge tank 3 and the suction side piping of the FPC / SPCU pump 8 in addition to the valve 51. ing. The suction side pipes of the FPC / SPCU pumps 8 and 7 are connected to each other by a connection pipe 5, and a connection valve 6 is disposed in the connection pipe 5. Reference numeral 24 denotes an SPCU pump discharge pipe of the FPC / SPCU pump 7.

  Check valves 53, 54, and 55 for preventing backflow in the pumps are disposed on the discharge side pipes of the FPC pump 9 and the FPC / SPCU pumps 8 and 7, respectively. The downstream sides of the check valves 53 and 54 are connected to each other via the valve 32, and the downstream sides of the check valves 54 and 55 are connected to each other via the valve 33. A first FPC filtration desalting tower (first FPC filtration desalting apparatus) 10 and a second FPC filtration desalting tower (second FPC filtration desalting apparatus) are respectively provided downstream of the check valves 55 and 54. ) 11 is connected. The downstream sides of the first FPC filtration and desalting tower 10 and the second FPC filtration and desalting tower 11 are connected to each other via a valve 34.

  An FPC heat exchanger group 56 is connected to the downstream side of the second FPC filtration desalting tower 11 via an FPC heat exchanger inlet valve 35. The FPC heat exchanger group 56 includes first, second, and third FPC heat exchangers 12, 13, and 14, which are connected in parallel.

  The downstream side of the FPC heat exchanger group 56 is connected to the spent fuel pool diffuser 16 in the spent fuel pool 1 via the FPC return pipe 15.

  On the downstream side of the check valve 53 on the discharge side of the FPC pump 9, the FPC filtration demineralization tower bypass pipe 17 branches and is connected to the upstream side of the FPC heat exchanger group 56 via the FPC filtration demineralization tower bypass valve 36. Has been.

  The pressure suppression pool purification system (SPCU system) 70 purifies pool water in the pressure suppression pool (S / P) 18 by using a part of the fuel pool cooling purification system 50 by switching the valve in a timely manner. The system to do. The S / P strainer 19 in the pressure suppression pool 18 and the suction side of the FPC / SPCU pump (third pump) 7 are connected by an SPCU pump suction pipe 20. Valves 60 and 61 and a check valve 62 are arranged in series in the SPCU pump suction pipe 20.

  An S / P return pipe 23 is connected from the downstream side of the first FPC filtration desalting tower 10 through the valve 37 to the pressure suppression pool 18. Further, a bypass pipe 64 that bypasses the first FPC filtration desalting tower 10 from the upstream side of the first FPC filtration desalting tower 10 and reaches the S / P return pipe 23 via the valve 63 is connected. .

  A reactor well water filling pipe 39 extending from the downstream side of the first FPC filtration desalting tower 10 to the equipment temporary storage pool 21 via the water filling valve 38 is disposed.

  The reactor well 26 can be water-filled together with the equipment temporary storage pool 21 for fuel replacement or the like when the reactor operation is stopped. The reactor well 26 and the equipment temporary storage pool 21 can be communicated with the spent fuel pool 1 in a state where water is filled.

  A drain pipe 22 extends downward from the bottom of the equipment temporary storage pool 21 and is connected to a low-conductivity waste liquid system 43. Further, the reactor well drain pipe 40 branches from the drain pipe 22 and is connected to the connection pipe 5 via the drain valve 41.

  A residual heat removal system (RHR system) 42 for removing decay heat at the time of a nuclear accident is connected to the FPC return pipe 15 and also to the reactor well 26. Further, the residual heat removal system 42 is connected to the FPC pump suction pipe 4 via the valve 65 by the RHR-FPC communication pipe 31.

  Next, the operation of the first embodiment will be described.

  As shown in FIG. 1, during normal operation of the nuclear reactor, the pool water is connected to the FPC pump suction pipe 4 and the connection pipe 5 via the skimmer surge tank 3 for cooling and purification of the spent fuel pool 1. 6 and open to the connection pipe 5, and then pressurized by two of the FPC / SPCU pump 7, FPC / SPCU pump 8, or FPC pump 9, and the first FPC filtration desalting tower 10 and the second FPC It is purified by the filtration desalting tower 11. The purified pool water is cooled by the parallel FPC heat exchangers 12, 13, and 14, and returned to the spent fuel pool 1 through the FPC return pipe 15 and the spent fuel pool diffuser 16.

  At this time, the valves 36, 37, 38, 41, 60, 61, 63, 65 are closed, the SPCU pump suction pipe 20, the S / P return pipe 23, the reactor well water filled pipe 39, and the reactor well drain pipe. 40, water does not flow through the FPC filtration demineralization tower bypass pipe 17 and the RHR-FPC communication pipe 31, and the pressure suppression pool purification system 70 has stopped functioning.

  When water filling of the reactor well 26 is performed for periodic inspections when the reactor is shut down, as shown in FIG. 2, the fuel pool water is used to clean the skimmer surge tank 3 for cooling the spent fuel pool 1. Through the FPC pump suction pipe 4, then pressurized by the FPC pump 9, passed through the FPC filtration demineralization tower bypass pipe 17, cooled by the FPC heat exchangers 12, 13 and 14, and passed through the FPC return pipe 15. And returned to the spent fuel pool 1.

  At the same time, the pool water in the pressure suppression pool 18 passes through the SPCU pump suction pipe 20 via the S / P strainer 19 and is pressurized by the two units of the FPC / SPCU pump 7 and the FPC / SPCU pump 8. The first FPC filtration demineralization tower 10 and the second FPC filtration demineralization tower 11 purify the water, and are led to the equipment temporary pool 21 via the reactor well water filled pipe 39.

  At this time, the valves 32, 35, 37, 41, 52, 63, 65 are closed, and water does not flow through the S / P return pipe 23, the reactor well drain pipe 40, and the RHR-FPC connection pipe 31.

  When the reactor well 26 is filled with water when the reactor operation is stopped and the water in the reactor well 26 is drained after the fuel exchange operation is completed, a flow path for cooling the spent fuel pool 1 as shown in FIG. Is the same as when the reactor well 26 is filled with water shown in FIG. That is, the fuel pool water is transferred to the FPC pump suction pipe 4 via the skimmer surge tank 3, and then pressurized by the FPC pump 9, passes through the FPC filtration demineralization tower bypass pipe 17, and passes through the FPC heat exchangers 12, 13. , 14 and returned to the spent fuel pool 1 through the FPC return pipe 15.

  In addition, when draining the reactor well 26, the water in the reactor well 26 passes from the bottom of the equipment temporary storage pool 21 via the drain pipe 22 and the reactor well drain pipe 40, and the FPC / SPCU pump 7. It is pressurized by two parallel pumps of the FPC / SPCU pump 8 and purified by the first FPC filtration demineralization tower 10 and the second FPC filtration demineralization tower 11. The purified water passes through the S / P return pipe 23 and is returned to the pressure suppression pool 18. At this time, the valves 32, 35, 38, 52, 60, 61, 63, 65 are closed, the reactor well water-filled pipe 39, the RHR-FPC communication pipe 31, upstream of the check valve 62 of the SPCU pump suction pipe 20. There is no water flowing through.

  According to the first embodiment, since the first, second, and third FPC heat exchangers 12, 13, and 14 are connected in parallel, the three FPC heat exchangers are operated during the reactor operation. Even if it is assumed that one of the remaining two FPC heat exchangers has undergone a single failure when one of them is being maintained, one can be operated. Thereby, the spent fuel pool 1 can be cooled, and cooling performance is ensured.

  In addition, since there are three pumps, that is, an FPC pump (first pump) 9, an FPC / SPCU pump (second pump) 8, and an FPC / SPCU pump (third pump) 7, these are provided. One of them can be used during online maintenance even if one of the remaining two has a single failure. Thereby, the spent fuel pool 1 can be cooled, and cooling performance is ensured.

  In addition, after the decay heat generated from the spent fuel in the spent fuel pool is sufficiently reduced, the spent fuel pool is cooled in one FPC system. At this time, online maintenance can be performed for one of the other two FPC systems, and the remaining one system can be operated as a spare machine. According to the first embodiment, even when a single failure occurs during online maintenance of the FPC system, the spent fuel pool can be cooled by the remaining one FPC system.

  In addition, while securing one category of spent fuel pool cooling, it is possible to fill and drain large-capacity reactor wells with two pumps during periodic inspections, thereby shortening the periodic inspection time.

[Second Embodiment]
A second embodiment of a nuclear power plant according to the present invention will be described with reference to FIGS. 4, 5 and 6. In addition, in the same structure as 1st Embodiment, the same code | symbol is attached | subjected and duplication description is abbreviate | omitted.

  FIG. 4 is a system diagram showing a fuel pool cooling purification system / pressure suppression pool purification system according to the second embodiment, and is a diagram showing a situation during normal operation of the reactor. FIG. 5 is a system diagram showing the water filling operation state of the reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. FIG. 6 is a system diagram showing the water draining operation state of the reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG.

  In the second embodiment, the connection pipe 5 in the configuration of the first embodiment is branched from the RHR-FPC communication pipe 31 and connected to the SPCU pump suction pipe 20 to form an FPC system three-section configuration.

  The clearance surge tank 3 is connected to the suction side of two FPC pumps (first and second pumps) 27 connected in parallel with each other via an FPC pump suction pipe 4. A valve 51 is disposed between the clearance surge tank 3 and the suction side piping of the FPC pump 27. Check valves 53 and 54 for preventing a back flow in each pump are arranged in each discharge side pipe of the two FPC pumps 27.

  A second FPC filtration desalting tower 11 is connected to the downstream side of the check valves 53 and 54 via a valve 71. An FPC heat exchanger group 56 is connected to the downstream side of the second FPC filtration desalting tower 11 via an FPC heat exchanger inlet valve 35. The configuration of the FPC heat exchanger group 56 is the same as that of the first embodiment. The first FPC filtration demineralization tower 10 is connected in parallel to the second FPC filtration demineralization tower 11 via a valve 33 and a valve 34 on the upstream side and the downstream side of the second FPC filtration demineralization tower 11, respectively. It is connected.

  The downstream side of the FPC heat exchanger group 56 is connected to the spent fuel pool diffuser 16 in the spent fuel pool 1 via the FPC return pipe 15 as in the first embodiment.

  The FPC filtration demineralization tower bypass pipe 17 branches on the upstream side of the valve 71 and is connected to the upstream side of the FPC heat exchanger group 56 via the FPC filtration demineralization tower bypass valve 36.

  In the pressure suppression pool purification system (SPCU system) 70, the S / P strainer 19 in the pressure suppression pool 18 and the suction side of the SPCU pump (third pump) 30 are connected by an SPCU pump suction pipe 20. Valves 60 and 61 and a check valve 62 are arranged in series in the SPCU pump suction pipe 20.

  The connection pipe 5 extends from the RHR-FPC connection pipe 31 that connects the residual heat removal system (RHR system) 42 and the FPC pump suction pipe 4, and is connected to the SPCU pump suction pipe 20 via the connection valve 6. ing.

  A check valve 55 is connected to the SPCU pump discharge pipe 24 on the discharge side of the SPCU pump 30, and the downstream side of the check valve 55 is branched into three pipes. The first of the branch pipes is connected to the upstream side of the valve 33 and the first FPC filtration demineralization tower 10 via the valve 72, and the second one is the inlet of the FPC heat exchanger group 56 via the valve 73. The third pipe is a bypass pipe 64 that reaches the S / P return pipe 23 via the valve 63.

  Similarly to the first embodiment, the valve 37 is connected to the pressure suppression pool 18 via the S / P return pipe 23. Further, similarly to the first embodiment, the valve 38 and the reactor well water filling pipe 39 extend to the equipment temporary storage pool 21.

  The downstream side of the first FPC filtration desalting tower 10 is connected to a pipe connecting the valve 37 and the valve 38 via a valve 74.

  Similar to the first embodiment, a drain pipe 22 extends downward from the bottom of the equipment temporary storage pool 21 and is connected to the low-conductivity waste liquid system 43. Further, the reactor well drain pipe 40 branches from the drain pipe 22 and is connected to the connection pipe 5 via the drain valve 41.

  Next, the operation of the second embodiment will be described.

  As shown in FIG. 4, during normal operation of the nuclear reactor, with respect to cooling and purification of the spent fuel pool 1, the pool water passes through the clearance surge tank 3, the FPC pump suction pipe 4, and the valve 51. The pressure is increased by one of the two FPC pumps 27 arranged in parallel, and purified by the first FPC filtration demineralization tower 10 or the second FPC filtration demineralization tower 11. The purified pool water is cooled by the three FPC heat exchangers 12, 13, and 14 arranged in parallel, and returned to the spent fuel pool 1 via the FPC return pipe 15 and the spent fuel pool diffuser 16.

  At this time, the valves 6, 36, 37, 38, 41, 60, 61, 63, 65, 72, 73, 74 are closed, the SPCU pump suction pipe 20, the S / P return pipe 23, and the reactor well water-filled pipe 39, water does not flow through the reactor well drain pipe 40, the FPC filtration demineralization tower bypass pipe 17, the RHR-FPC communication pipe 31, and the connection pipe 5, and the pressure suppression pool purification system 70 stops functioning.

  When water filling of the reactor well 26 is performed for periodic inspection when the reactor is shut down, as shown in FIG. 5, for cooling the spent fuel pool 1, the fuel pool water uses the skimmer surge tank 3. Then, after moving to the FPC pump suction pipe 4, it is pressurized by the two FPC pumps 27, passes through the FPC filtration desalting tower bypass pipe 17, is cooled by the FPC heat exchangers 12, 13, and 14, and the FPC return pipe 15 is returned to the spent fuel pool 1.

  At the same time, the pool water in the pressure suppression pool 18 passes through the SPCU pump suction pipe 20 via the S / P strainer 19 and is pressurized by the SPCU pump 30, and the first FPC filtration demineralizer 10 and the second desalting tower 10. It is purified by the FPC filtration desalting tower 11 and led to the equipment temporary pool 21 via the reactor well water-filled pipe 39.

  At this time, the valves 6, 35, 37, 41, 63, 65, 71, 73 are closed, and the connection pipe 5, the S / P return pipe 23, the reactor well drain pipe 40, and the RHR-FPC communication pipe 31 are connected. The water does not flow.

  When the reactor well 26 is filled with water when the reactor operation is stopped and the water in the reactor well 26 is drained after the fuel exchange operation is completed, a flow path for cooling the spent fuel pool 1 as shown in FIG. Is the same as when the reactor well 26 is filled with water shown in FIG. That is, the fuel pool water is transferred to the FPC pump suction pipe 4 via the skimmer surge tank 3, then pressurized by the two FPC pumps 27, passes through the FPC filtration demineralization tower bypass pipe 17, and then the FPC heat exchanger. 12, 13, and 14, and returned to the spent fuel pool 1 through the FPC return pipe 15.

  Further, when draining the reactor well 26, the water in the reactor well 26 flows from the bottom of the equipment temporary storage pool 21 via the drain pipe 22, the reactor well drain pipe 40 and the connection pipe 5, and the SPCU pump 30. And purified by the first FPC filtration demineralization tower 10 and the second FPC filtration demineralization tower 11. The purified water passes through the S / P return pipe 23 and is returned to the pressure suppression pool 18. At this time, the valves 6, 35, 38, 63, 65, 71 and 73 are closed, and water does not flow into the reactor well water-filled pipe 39 and the RHR-FPC communication pipe 31.

  According to the second embodiment, as in the first embodiment, the first, second, and third FPC heat exchangers 12, 13, and 14 are connected in parallel. Even if it is assumed that one of the remaining two FPC heat exchangers has caused a single failure when maintenance is being performed on one of the three FPC heat exchangers, 1 The group is operational. Thereby, the spent fuel pool 1 can be cooled, and cooling performance is ensured.

  Since three pumps, that is, two FPC pumps (first and second pumps) 27 and an SPCU pump (third pump) 30 are provided, one of these pumps is on-line maintenance. One pump can be used even if one of the remaining two units has a single failure. Thereby, the spent fuel pool 1 can be cooled, and cooling performance is ensured.

  Similarly to the first embodiment, after the decay heat generated from the spent fuel in the spent fuel pool is sufficiently reduced, the spent fuel pool is cooled in one FPC system. At this time, online maintenance can be performed for one of the other two FPC systems, and the remaining one system can be operated as a spare machine. Thus, even when a single failure occurs during online maintenance of the FPC system, the spent fuel pool can be cooled by the remaining one FPC system.

  Moreover, in this 2nd Embodiment, there are comparatively few changes with respect to the conventional system | strain shown in FIG. 10, and it is advantageous when performing remodeling construction.

[Third Embodiment]
A third embodiment of the nuclear power plant according to the present invention will be described with reference to FIGS. 7, 8 and 9. In addition, in the same structure as 1st Embodiment, the same code | symbol is attached | subjected and duplication description is abbreviate | omitted.

  FIG. 7 is a system diagram showing the fuel pool cooling purification system / pressure suppression pool purification system according to the third embodiment, and is a diagram showing the state of the pressure suppression pool purification operation during the normal operation of the reactor. FIG. 8 is a system diagram showing a water filling operation state of the reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG. FIG. 9 is a system diagram showing a water drain operation state of the reactor well when the reactor operation is stopped in the fuel pool cooling purification system / pressure suppression pool purification system of FIG.

  In this 3rd Embodiment, it becomes the structure which provides the 3rd filtration demineralization tower 25 in the filtration demineralization tower bypass piping 17 in the structure of 1st Embodiment. Other configurations are the same as those of the first embodiment.

  Next, the operation of the third embodiment will be described.

  First, the situation during the pressure suppression pool purification operation during the normal operation of the nuclear reactor will be described with reference to FIG.

  Concerning the cooling and purification of the spent fuel pool 1, the pool water passes through the FPC pump suction pipe 4 via the skimmer surge tank 3, and the FPC pump (first pump) 9 and the FPC / SPCU pump (second pump). ) 8 is pressurized. Pool water pressurized by the FPC pump 9 and the FPC / SPCU pump 8 is purified by the second FPC filtration and desalting tower 11 and the third FPC filtration and desalting tower 25. The purified pool water is cooled by the parallel FPC heat exchangers 12, 13, and 14 as in the first embodiment, and the spent fuel pool is passed through the FPC return pipe 15 and the spent fuel pool diffuser 16. Returned to 1.

  At the same time, the pool water in the pressure suppression pool 18 passes through the SPCU pump suction pipe 20 via the S / P strainer 19 and is pressurized by the FPC / SPCU pump (third pump) 7 to be subjected to the first FPC filtration. It is purified by the desalting tower 10 and returned to the pressure suppression pool 18 through the S / P return pipe 23.

  At this time, the valves 6, 33, 34, 38, 41, 65 are closed, and water flows into the communication pipe 5, the reactor well water filling pipe 39, the reactor well drain pipe 40, and the RHR-FPC connection pipe 31. Absent.

  When water filling of the reactor well 26 is performed for periodic inspection when the reactor is shut down, as shown in FIG. 8, the fuel pool water is used for cooling the skimmer surge tank 3 for cooling the spent fuel pool 1. Then, after moving to the FPC pump suction pipe 4, it is pressurized by the FPC pump 9. After that, it is cooled by the FPC heat exchangers 12, 13, 14 through the third FPC filtration desalting tower 25, and returned to the spent fuel pool 1 through the FPC return pipe 15.

  Meanwhile, at the same time, the pool water in the pressure suppression pool 18 passes through the SPCU pump suction pipe 20 via the S / P strainer 19 in the same manner as when the reactor well 26 is filled with water in the first embodiment (FIG. 2). Pressurized by two units of the FPC / SPCU pump 7 and the FPC / SPCU pump 8, purified by the first FPC filtration demineralization tower 10 and the second FPC filtration demineralization tower 11, Via, it is led to the equipment temporary pool 21.

  At this time, the valves 32, 35, 37, 41, 52, 63, 65 are closed, and water does not flow through the S / P return pipe 23, the reactor well drain pipe 40, and the RHR-FPC connection pipe 31.

  When water is drained from the reactor well 26 after filling the reactor well 26 when the reactor is stopped, as shown in FIG. 9, the flow path for cooling the spent fuel pool 1 is the atom shown in FIG. This is the same as when the furnace well 26 is filled with water. That is, the fuel pool water is pressurized by the FPC pump 9 after moving to the FPC pump suction pipe 4 via the clearance surge tank 3. After that, it is cooled by the FPC heat exchangers 12, 13, 14 through the third FPC filtration desalting tower 25, and returned to the spent fuel pool 1 through the FPC return pipe 15.

  Further, when draining the reactor well 26, the water in the reactor well 26 flows from the bottom of the equipment temporary storage pool 21 as in the draining of the reactor well 26 in the first embodiment (FIG. 3). Via the drain pipe 22 and the reactor well drain pipe 40, the pressure is increased by two parallel pumps of the FPC / SPCU pump 7 and the FPC / SPCU pump 8. 2 is purified by the FPC filtration desalting tower 11. The purified water passes through the S / P return pipe 23 and is returned to the pressure suppression pool 18. At this time, the valves 32, 35, 38, 52, 60, 61, 63, 65 are closed, and water does not flow through the SPCU pump suction pipe 20, the reactor well water filling pipe 39, and the RHR-FPC communication pipe 31.

  According to the third embodiment, since the three FPC heat exchangers 12, 13, and 14 are connected in parallel as in the first embodiment, three FPC heats are generated during the reactor operation. Even if one of the two FPC heat exchangers is undergoing maintenance on one of the exchangers, assuming that one of the remaining two FPC heat exchangers has caused a single failure, one can operate. . Thereby, the spent fuel pool 1 can be cooled, and cooling performance is ensured.

  In addition, since three pumps, that is, FPC pump 9, FPC / SPCU pump 8 and FPC / SPCU pump 7, are provided, one of these is one of the remaining two during online maintenance. One pump can be used even if there is a single failure in the table. Thereby, the spent fuel pool 1 can be cooled, and cooling performance is ensured.

  In addition, after the decay heat generated from the spent fuel in the spent fuel pool is sufficiently reduced, the spent fuel pool is cooled in one FPC system. At this time, online maintenance can be performed for one of the other two FPC systems, and the remaining one system can be operated as a spare machine. According to the first embodiment, even when a single failure occurs during online maintenance of the FPC system, the spent fuel pool can be cooled by the remaining one FPC system.

  In addition, while securing one category of spent fuel pool cooling, it is possible to fill and drain large-capacity reactor wells with two pumps during periodic inspections, thereby shortening the periodic inspection time.

  Furthermore, according to the third embodiment, the spent fuel pool can be cooled and the spent fuel pool can be purified even when the pressure suppression pool is purified and when the reactor well is drained or filled.

[Other Embodiments]
Each of the embodiments described above is merely excitation, and the present invention is not limited to these. For example, the third FPC filtration demineralization tower 25 of the third embodiment can be applied to the second embodiment.

DESCRIPTION OF SYMBOLS 1 ... Spent fuel pool, 2 ... Spent fuel, 3 ... Clearance surge tank, 4 ... Fuel pool cooling and purification (FPC) pump suction pipe, 5 ... Connection pipe, 6 ... Connection valve, 7 ... FPC / SPCU pump (No. 3), 8 ... FPC / SPCU pump (second pump), 9 ... Fuel pool cooling and purification (FPC) pump (first pump), 10 ... First FPC filtration demineralizer (first FPC) Filtration demineralizer), 11 ... second FPC filtration demineralizer (second FPC filtration demineralizer), 12, 13, 14 ... FPC heat exchanger, 15 ... FPC return pipe, 16 ... spent fuel pool Diffuser, 17 ... FPC filtration demineralization tower bypass pipe, 18 ... Pressure suppression pool (S / P), 19 ... S / P strainer, 20 ... SPCU pump suction pipe, 21 ... Equipment temporary storage pool, 22 ... Drain pipe, 23 ... S / P return Piping, 24 ... SPCU pump discharge piping, 25 ... Third FPC filtration demineralization tower (third FPC filtration demineralizer), 26 ... Reactor well, 27 ... FPC pump, 28 ... FPC filtration demineralization tower, 29 ... FPC heat exchanger, 30 ... SPCU pump, 31 ... RHR-FPC communication pipe, 35 ... FPC heat exchanger inlet valve, 36 ... FPC filtration demineralization tower bypass valve, 38 ... water filling valve, 39 ... reactor well water filling pipe 40 ... Reactor well drain piping, 41 ... Drain valve, 42 ... Residual heat removal system (RHR system), 43 ... Low conductivity waste liquid system, 50 ... Fuel pool cooling and purification system (FPC system), 53, 54 55 ... Check valve, 56 ... FPC heat exchanger group, 62 ... Check valve, 64 ... Bypass piping, 70 ... Pressure suppression pool purification system (SPCU system)

Claims (8)

A spent fuel pool for storing spent fuel in water;
A pressure suppression pool that suppresses excessive pressure rise in the containment vessel,
A fuel pool cooling and purifying system that takes out fuel pool water in the spent fuel pool, cools and purifies the fuel pool water, and returns the fuel pool water to the spent fuel pool;
A pressure suppression pool purification system that takes out the pressure suppression pool water in the pressure suppression pool using a part of the fuel pool cooling purification system by switching a valve and purifies the pressure suppression pool water;
A nuclear power plant having
The fuel pool cooling and purification system includes a filtration desalination device for purifying the fuel pool water, three heat exchangers in parallel with each other for cooling the fuel pool water, and a first in parallel with which the fuel pool water is circulated. , Second and third pumps,
The pressure suppression pool purification system is configured to purify the pressure suppression pool water using at least the third pump and the filtration desalination apparatus ; and
The discharge side pipes of the first, second, and third pumps of the fuel pool cooling and purification system can communicate with each other, and branch off from the discharge side pipe of the first pump, and A bypass pipe that is bypassed and connected to the upstream side of the heat exchanger is provided, and when the reactor is shut down, the fuel pool water is circulated by the bypass pipe and the first pump to exchange the three heats. The fuel pool water is configured to be cooled by at least one heat exchanger of the vessel ,
A nuclear power plant characterized by Operation when stopping of the reactor, before Symbol second and third by driving the pressure suppression pool water by a pump, the clean pressure while purifying the pressure suppression pool water using the filter demineralizer The nuclear power plant according to claim 1, wherein the nuclear power plant is configured to be able to transfer restraint pool water to the fuel pool. During shutdown of the reactor, before SL and drives the fuel pool water in the fuel pool in the second and third pump, its being purified while purifying the fuel pool water using the filter demineralizer The nuclear power plant according to claim 1, wherein the fuel pool water is configured to be transferred to the pressure suppression pool. A residual heat removal system that takes out fuel pool water in the spent fuel pool at the time of a nuclear reactor accident, cools the fuel pool water, and returns the fuel pool water to the spent fuel pool;
A fuel pool cooling and purification pump suction pipe connecting the suction side of the first and second pumps and the spent fuel pool;
A communication pipe connecting the fuel pool cooling and purification pump suction pipe and the residual heat removal system;
A pressure suppression pool purification pump suction pipe connecting the suction side of the third pump and the pressure suppression pool;
A connection pipe connecting the middle of the communication pipe and the middle of the pressure suppression pool purification pump suction pipe;
The nuclear power plant according to any one of claims 1 to 3, wherein The filtration demineralizer comprises first, second and third filtration demineralizers,
The fuel pool cooling and purifying system uses at least the first pump, at least the first filtration desalination apparatus, and the three heat exchangers during operation of the nuclear reactor. Cooling and purifying the water back to the spent fuel pool,
The pressure suppression pool purification system is configured to purify the pressure suppression pool water using at least the third pump and at least the third filtration demineralizer during operation of the nuclear reactor. about,
The nuclear power plant according to claim 1. When the reactor is shut down,
Cooling and purifying the fuel pool water in the spent fuel pool using the first pump, the first filtration desalination apparatus, and the three heat exchangers to return the spent fuel pool to the spent fuel pool,
The pressure suppression pool purification system purifies the pressure suppression pool water purified while purifying the pressure suppression pool water using the second and third pumps and the second and third filtration demineralizers. The nuclear power plant according to claim 5, wherein the nuclear power plant is configured to be transferred to the fuel pool. When the reactor is shut down,
Cooling and purifying the fuel pool water in the spent fuel pool using the first pump, the first filtration desalination apparatus, and the three heat exchangers to return the spent fuel pool to the spent fuel pool,
The pressure suppression pool purification system purifies the fuel pool water while purifying the fuel pool water using the second and third pumps and the second and third filtration and desalination apparatuses. The nuclear power plant according to claim 5, wherein the nuclear power plant is configured to be transferred to a suppression pool. A method for operating a nuclear power plant having a spent fuel pool for storing spent fuel in water and a pressure suppression pool for suppressing an excessive pressure rise in a reactor containment vessel,
Using the filtration desalination apparatus, the three heat exchangers in parallel with each other, and the first, second and third pumps in parallel with each other, the fuel pool water in the spent fuel pool is taken out and A fuel pool cooling and purification step for cooling and purifying the fuel pool water and returning it to the spent fuel pool;
By switching the valve, the fuel pool water in the spent fuel pool is taken out, the filtration desalination device is bypassed, and the fuel pool water is circulated by the first pump, so that the three heat exchangers A fuel pool cooling step of cooling the fuel pool water by at least one of the heat exchangers;
A pressure suppression pool purification system step of switching the valve, taking out the pressure suppression pool water in the pressure suppression pool, and purifying the pressure suppression pool water using at least the third pump and the filtration demineralizer;
Yes, and nuclear power plant operation wherein the pressure suppression pool cleaning system process characterized by Rukoto, performed simultaneously with the fuel pool cooling step the.

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