JPH0423758B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a core monitoring device for periodic inspections that monitors the state inside a reactor core during periodic inspections.

[Technical background of the invention and its problems] Generally, in boiling water nuclear power plants, periodic inspections are carried out approximately every year.

This periodic inspection mainly inspects various system equipment, but inspection work that affects the reactivity of the reactor includes fuel assembly replacement or shuffling, overhaul of the control rod drive mechanism, control rod replacement, etc. It is done. The number of these inspections and replacements varies depending on the operating cycle, but normally 1/4 of the control rod drive mechanism is overhauled.

In the periodic inspection process, work related to reactor internals, such as fuel assembly replacement work and overhaul inspection of the control rod drive mechanism, is a critical path in the process, and from the perspective of shortening the periodic inspection period, each work is Plan so that work is carried out continuously within a certain range,
It has been implemented.

During such periodic inspections, fuel assemblies surrounding the control rods of the control rod drive mechanism that are subject to overhaul are removed from the core in advance, and the control rods are placed in the fully withdrawn position.

On the other hand, in the fuel exchange mode of the reactor monitoring system and reactor control system of the current boiling water nuclear power plant, the function in the fuel exchange mode is that only one control rod can be inserted, provided that all control rods are fully inserted. If the control rods are withdrawn and all control rods are not fully inserted, the refueling machine is interlocked to prevent it from moving onto the core.

As described above, the equipment functions of boiling water nuclear power plants do not match the current periodic inspection method, and currently, during periodic inspections, the interlock function of the fuel exchange mode is blocked and periodic inspections are performed.

In addition, the various replacement and inspection work mentioned above is only carried out by operators or workers according to procedure manuals, with the principle that internal structures within one cell in the reactor core are not changed at the same time. The reality is that there are no functions in place to prevent erroneous operations and work.

[Purpose of the Invention] The present invention has been made in response to the above-mentioned conventional circumstances, and is capable of automatically updating information on changes in reactor internal structures and various system equipment that affect the reactivity of a nuclear reactor during periodic inspections. The purpose of this invention is to provide a core monitoring device for periodic inspections that can accurately grasp the internal state of the reactor core and safely perform periodic inspections.

[Summary of the Invention] That is, the present invention inputs signals regarding the control rod position and fuel body removal position during periodic inspections, and operates the blade guide in the reactor core based on this input signal to prevent the blade guide from being inserted. Alternatively, a blade guide operation monitoring means for generating an alarm in an alarm via a fuel exchanger computer when it is determined that the loaded fuel body will fall;
Input signals regarding the fuel assembly removal position and blade guide insertion position during periodic inspections,
A control rod monitoring means outputs a control rod drive prevention signal to the reactor manual control system when it is determined that driving the control rod or the loaded fuel rod will collapse if the control rod is driven based on this input signal, and a control rod monitoring means that outputs a control rod drive prevention signal to the reactor manual control system. A signal regarding the position of the control rod and the insertion position of the blade guide is input into the input signal, and when it is determined that the loaded fuel assembly will collapse if the fuel is exchanged based on this input signal, a fuel exchanger function stop signal is sent to the refueling machine computer. This is a core monitoring device for periodic inspections, characterized in that it is equipped with a refueling machine monitoring means that outputs.

[Embodiment of the Invention] The details of the present invention will be described below with reference to an embodiment shown in the drawings.

FIG. 1 shows a core monitoring device for periodic inspection according to an embodiment of the present invention. In the figure, reference numeral 1 indicates a reactor pressure vessel, and a reactor core 2 is housed in this reactor pressure vessel 1. There is. A fuel exchanger 3 is arranged in the upper part of the reactor pressure vessel 1, and the reactor core 2
A control rod drive mechanism 5 for inserting the control rods 4 into the reactor core 2 is arranged below the reactor core 2 . Furthermore, a high-sensitivity neutron detector 6 is arranged within the reactor core 2 .

That is, the fuel exchanger 3 is disposed on the operating floor 7 formed on the top floor of the reactor building, moves between the reactor core 2 and the fuel pool, and mainly grabs and moves fuel assemblies and blade guides. This fuel exchange machine 3 is controlled by a fuel exchange machine computer 8.

That is, all fuel assembly movement steps are stored in advance in the refueling machine computer 8.
The fuel exchanger 3 is controlled according to this program step. It should be noted that since the control rod 4 is operated as each step progresses, the operator must confirm each step.

This fuel exchanger computer 8 grasps the positions of all fuel assemblies and blade guides while the fuel assemblies are being moved, and outputs the data to the core monitoring device 9 for periodic inspection.

In the figure, reference numeral 10 indicates a control rod hydraulic drive unit, and this control rod hydraulic drive unit 10
drives the drive piston of the control rod drive mechanism 5.
The control rod hydraulic drive unit 10 is composed of pipes, valves, electromagnetic valves, instruments, etc., and is formed into a unit, and is provided in the same number as the control rods 4.

That is, when driving the control rods 4, the solenoid valve is energized while the manual isolation valve of the control rod hydraulic drive unit 10 is open, and water pressure is supplied from the control rod hydraulic drive unit 10 to the control rod drive mechanism 5.
This control rod hydraulic drive unit 10 corresponds to the control rod 4.
When the surrounding fuel assembly is being taken out, the isolation valve is closed to prevent the control rod 4 from falling due to incorrect insertion, and the control rod drive mechanism 5 is isolated from being driven.

It is also isolated when disassembling and inspecting the control rod drive mechanism 5 and inspecting the control rod hydraulic drive unit 10. The open/closed state of the isolation valve of the control rod hydraulic drive unit 10 is detected by a limit switch.
It is output to the input circuit of the core monitoring device 9 for periodic inspection. The solenoid valve of the control rod hydraulic drive unit 10 is controlled by a reactor manual control system indicated by the reference numeral 11.

That is, the control rods 4 are operated by a manual switch of the reactor manual control system 11, but the reactor manual control system 11 has a built-in control rod withdrawal prevention circuit, which prevents the control rods 4 from being operated. It has a function of electrically blocking the operator's operation of the control rods 4 when the control rods 4 are out of regular operation or when the core reactivity is not appropriate.

In the figure, reference numeral 12 indicates a control rod position indicating system board, and this control rod position indicating system board 12 digitally converts the control rod drive mechanism position signal S1 detected by the reed switch of one probe in the control rod drive mechanism 5. processing and monitoring all control rod drive mechanism positions. This control rod position indication system panel 12 displays the position of the control rod drive mechanism 5 to the operator and also outputs various information to the process computer. A signal S2 indicating the position of is output.

In the figure, reference numeral 13 indicates a control rod drive mechanism automatic exchange machine, which is composed of a bolt detacher, a platform, a cart, etc. It is automatically installed from the bottom of the furnace pressure vessel 1.

In the figure, reference numeral 14 indicates a control rod drive mechanism automatic exchange machine control panel, and this control rod drive mechanism automatic exchange machine control panel 14 is a control rod drive mechanism automatic exchange machine 1.
3 remotely controlled. The control rod drive mechanism automatic exchange control panel 14 outputs control rod drive mechanism number data while the control rod drive mechanism is being attached or detached to the core monitoring device 9 for periodic inspection.

In the figure, reference numeral 15 indicates a neutron flux monitor, and this neutron flux monitor 15 monitors the neutron flux during reactor shutdown using a high-sensitivity neutron detector 6 disposed within the reactor core 2. Further, the signal S3 from the neutron flux monitor 15 is output to the core monitoring device 9 for periodic inspection.

In the figure, reference numeral 9 indicates a core monitoring device for periodic inspection according to an embodiment of the present invention. Control.

That is, this periodic inspection core monitoring device 9 inputs the signal S4 from the refueling machine computer 8, and detects when the control rod position of the target cell is not fully inserted during fuel transfer, or when the reactivity in the core 2 is detected. When the value increases, a fuel exchanger function stop signal S5 is output to the fuel exchanger computer 8.

Figure 2 shows the arrangement of fuel assemblies 20 and control rods 4, which are part of the core 2. The control rods 4 arranged around the control rods 4 and the four fuel assemblies around them are called cells. .

The upper row in the figure shows the fuel assemblies 20 in a loaded state, but the steps from left to right in the center row to right in the lower row sequentially show the steps for removing the fuel assemblies 20 from the reactor. The control rod 4 is structured so that it cannot stand on its own within the core 2 unless two fuel assemblies 20 or a double blade guide 21 are present in the cell in a symmetrical direction. Moreover, since only a few blade guides 21 are used in the plant, after all the fuel assemblies 20 in the cells are taken out and the control rods 4 are moved, they are moved to other cells.

The periodic inspection core monitoring device 9 monitors the insertion operation of the double blade guide 21 using a flowchart as shown in FIG. 3, and outputs a blade guide insertion permission signal to the fuel exchanger computer 8 if the operation is correct. ,On the other hand, when the operation is incorrect,
A warning is issued to the operator using the CRT 22 or the alarm 23.

In addition, this periodic inspection core monitoring device 9 monitors the withdrawal operation of the double blade guide using a flow chart as shown in FIG. 4, and when the withdrawal operation is correct, sends a blade guide withdrawal permission signal to the fuel exchanger computer 8, and if there is an error, the CRT 22 or alarm 23 issues a warning to the operator. In addition, the neutron flux from the neutron flux monitor 15 is input, and if the reactivity in the reactor core 2 abnormally increases, the fuel exchanger calculator 8
outputs a fuel exchanger function stop signal.

Furthermore, this periodic inspection core monitoring device 9 inputs signals from the control rod hydraulic drive unit 10,
5 based on the signal from the fuel exchanger computer 8.
The withdrawal operation of the control rod 4 is monitored using a flowchart as shown in the figure, and if the operation is correct, a control rod withdrawal permission signal is output to the reactor manual control system 11. If the operation is incorrect, an alarm signal is output to the CRT 22 or the alarm 23.

In addition, this periodic inspection core monitoring device 9
The insertion operation of the control rod 4 is monitored using a flowchart as shown in the figure, and if the operation is correct, a control rod insertion permission signal is output to the reactor manual control system 11. On the other hand, if it is incorrect, an alarm signal is output to the CRT 22 or the alarm 23.

In addition, this periodic inspection core monitoring device 9 inputs the control rod drive mechanism number data of the control rod drive mechanism being attached or detached from the control rod drive mechanism automatic exchange control panel 14, and sends control rod hydraulic drive unit 10, control rod position instructions. Based on the signals input from the system panel 12 and the fuel exchanger computer 8, the isolation operation of the control rod hydraulic drive unit 10 and the attachment/detachment operation of the control rod drive mechanism 5 are monitored according to a flowchart as shown in FIG. If this operation is normal, a control rod drive mechanism attachment/detachment permission signal is output to the fuel exchanger computer 8, and if there is an error, an alarm signal is output to the CRT 22 or alarm 23.

Furthermore, this periodic inspection core monitoring device 9 receives signals from the refueling machine computer and monitors the fuel assembly removal operation according to a flowchart as shown in FIG. If the retrieval operation is correct, a fuel assembly retrieval permission signal is output to the fuel exchanger computer 8, and if the retrieval operation is incorrect, the CRT 2 is output.
2 or output an alarm signal to the alarm device 23.

In addition, the loading operation of the fuel assembly is monitored using a flowchart as shown in FIG. 9, and when it is correct, a loading permission signal is output to the fuel exchanger computer 8.
If there is a mistake, CRT 22 or alarm 23
Outputs an alarm signal.

Furthermore, this periodic inspection core monitoring device 9 inputs the neutron flux signal S3 from the neutron flux monitor 15, and if the reactivity in the core 2 abnormally increases, all reactor internal structure modification work is stopped. let

[Effects of the Invention] As described above, the core monitoring device for periodic inspections of the present invention constantly monitors the states of control rods, fuel assemblies, and blade guides during periodic inspections,
Since a warning signal is output when there is a defective or erroneous operation procedure, operators can quickly learn about this and prevent incorrect insertion and removal of blade guides, control rods, and fuel bodies during periodic inspections. Various accidents such as falls can be prevented.

This can reduce the burden on workers and improve the operating rate of periodic inspections.

[Brief explanation of drawings]

Fig. 1 is a block diagram showing the core monitoring device for periodic inspection of the present invention, Fig. 2 is an explanatory diagram showing the fuel exchange method, Fig. 3 is a flowchart for monitoring the insertion operation of the blade guide, and Fig. 4 is a flowchart for monitoring the extraction operation of the blade guide, FIG. 5 is a flowchart for monitoring the extraction operation of the control rod, FIG. 6 is a flowchart for monitoring the insertion operation of the control rod, and FIG. 7 is a flowchart for monitoring the extraction operation of the control rod. The figure is a flowchart for monitoring the isolation operation of the control rod hydraulic drive unit and the attachment and detachment work of the control rod drive mechanism.
FIG. 8 is a flowchart for monitoring the fuel assembly removal operation, and FIG. 9 is a flowchart for monitoring the fuel assembly loading operation. 3... Fuel exchanger, 4... Control rod, 5... Control rod drive mechanism, 8... Fuel exchanger computer, 10...
...Control rod hydraulic drive unit, 11...Reactor manual control system, 12...Control rod position indication system panel, 20...
fuel assembly.

Claims (1)

[Claims] 1 Inputting signals regarding control rod positions and fuel assembly removal positions during periodic inspections, and operating the blade guide in the core based on these input signals will result in the blade guide not being able to be inserted or the loaded fuel assembly collapsing. A blade guide operation monitoring means that generates an alarm on an alarm via a fuel exchanger computer when it is determined that this is the case, and a signal regarding the fuel assembly removal position and blade guide insertion position at the time of periodic inspection are input, and the input signal is Control rod monitoring means outputs a control rod drive prevention signal to the reactor manual control system when it is determined that the control rod or the loaded fuel rod will collapse if the control rod is driven based on the control rod control system during periodic inspections. A fuel module that inputs signals regarding the position and insertion position of the blade guide, and outputs a fuel exchanger function stop signal to the fuel exchanger computer when it is determined that the loaded fuel assembly will fall if the fuel is exchanged based on this input signal. 1. A core monitoring device for periodic inspection, characterized in that it is equipped with exchanger monitoring means.