JPS58106498A - Control rod withdrawal monitoring device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] Technical field of invention This invention relates to a control rod withdrawal monitoring device in a boiling water reactor.

Technical background of the invention A conventional example will be explained with reference to FIGS. 1 to 5.

As shown in Fig. 1, in a boiling water reactor, four fuel assemblies 2 are arranged around a control rod 1 having a cross-shaped cross section to form a unit cell 3. Unit cell 3...
A large number of these are arranged in a lattice pattern to form a reactor core 4 having a substantially circular planar shape as shown in FIG. This reactor core 4 is housed within a reactor pressure vessel 9. Then, the coolant passes upward through the core 4 and is circulated by the recirculation bomb f10 and the jet pump 12. Further, a control rod assembly mechanism 8... is provided at the bottom of the reactor pressure vessel 9, and the control rod assembly mechanism 8... is connected to the control rod assembly mechanism 8...
・It is inserted into or withdrawn from the core 4 by
is configured to control the output of the In addition, the output control of this core 4 controls the operation of the recirculation phase sensor f10,
By controlling the flow rate of the coolant passing through the core 4, that is, the core flow rate, the void ratio of the coolant in the core 4 can be changed and controlled.

In addition, a large number of power range neutron detectors 5 are located within the core 4.
...is provided. These output region neutron detectors 5 are arranged between the unit cells 3, and are arranged in four stages in the vertical direction. In addition, one square in Fig. 2 indicates the fuel assembly 2..., the large white circle indicates the control rod 1..., and the smaller white circle or black circle indicates the power range neutron detector 5... show.

Such a nuclear reactor is equipped with a control rod withdrawal monitoring device. 6 is the control rod withdrawal monitoring circuit,
The output signals from each output region neutron detector 5... are configured to be input to this control rod withdrawal monitoring circuit 6□. Then, the control rod 1 to be pulled out...For example, if the shaded control rod 1' in Fig. 2 is designated, there will be 4 rods surrounding this control rod 1', a total of 16 in 4 stages, as shown in Fig. 4. A group of power range neutron detectors 5... are selected for monitoring the withdrawal of this control rod 1'. Moreover, this group of output region neutron detectors 5... are connected to a plurality of systems, such as A system, B system, etc., as shown in FIG.
The system is divided into two systems. In addition, the white circle in the figure indicates the output region neutron detector 5 belonging to the A system,
Moreover, the black circles indicate the neutron detectors 5 belonging to the B system. Then, the control rod withdrawal monitoring circuit 6 averages the outputs of these output range neutron detectors 5 for each system A and B, and if these average values exceed a predetermined control rod withdrawal prevention signal setting value, In this case, a control rod withdrawal prevention signal is sent from the control rod withdrawal monitoring circuit 6 to the control rod control device 7, and the control rod withdrawal monitoring circuit 6 sends a control rod withdrawal prevention signal to the control rod control device 7.
is configured to prevent further withdrawal of the. Therefore, if the control rod 1' is improperly withdrawn and the surrounding output increases excessively, the control rod withdrawal monitoring circuit 6
A control rod withdrawal prevention signal is output from the control rod 1' to prevent further withdrawal of the control rod 1' and maintain the health of the surrounding fuel.

Problems with the Background Art When the output of a fuel increases excessively, whether or not the fuel is damaged is determined not only by the amount of increase in output, but also by the amount of time after the increase in output, as shown in Figure 5. Related, its after the output increase! ! However, if it is left unused for a long time, fuel damage may occur even if the amount of increase in output is small.

Therefore, in the conventional system, the output increases up to point A in Figure 5, and even if the control rod is prevented from being withdrawn at point A and further increase in output is prevented, if left in this state for a long time, Fuel damage could have occurred.

OBJECTS OF THE INVENTION An object of the present invention is to provide a control rod withdrawal monitoring device that does not cause fuel damage even if the control rod is left as it is for a long time after being prevented from being withdrawn.

Summary of the Invention The present invention provides a control rod withdrawal monitoring circuit that outputs a control rod withdrawal prevention signal and a signal to reduce the core flow rate when the power around the control rod being withdrawn increases excessively. It is prepared. Therefore, as control rod withdrawal is prevented, the core flow rate decreases and the output of the entire core decreases, so even if the control rods are left in this state for a long time after their withdrawal is prevented, the fuel around the control rods that have been prevented from being withdrawn will This is to reliably prevent damage.

Embodiment of the Invention An embodiment of the present invention will be described with reference to FIGS. 6 to 11.

First, the configuration of a boiling water reactor will be explained. 101 in the figure
...A control rod with a cross-shaped cross section, and this control rod 1
Four fuel assemblies 102... are arranged around 01..., forming a unit grid 10.9.... A large number of unit lattices Lμ are arranged in a lattice form, forming a core 104 having a substantially circular planar shape as shown in FIG.

This reactor core 104 is housed within a reactor pressure vessel 1056. And this reactor pressure vessel 10
The coolant in the reactor core 104 is configured to be circulated through the core 104 from the bottom to the top by the recirculation Inf 114 and the jet pumps 117 . This recirculation pump 7° 114 is controlled by a recirculation pump control device 116 and is configured to control the flow rate of coolant passing through the reactor core 104, that is, the core flow rate, and to control the output of the entire reactor core 104. . In addition, this reactor pressure vessel 1
Control rod drive mechanisms 107... are provided at the bottom of the 05, and these control rod drive mechanisms 107...
01... are inserted into or withdrawn from the reactor core 104. These control rod drive mechanisms 102 are configured to be controlled by a control rod control device 108.

Next, a control rod withdrawal monitoring device provided in this reactor will be explained. . A large number of power range neutron detectors 1θ6... are provided within the reactor core 104. These output region neutron detectors 106... are unit cells 103...
...They are provided in four stages in the vertical direction, every second. The outputs s1 of these output range neutron detectors 106 are sent to a control rod withdrawal monitoring circuit 109. This control rod withdrawal monitoring circuit 1
09 is constructed as shown in FIG.

110 is a selection circuit, and the output region neutron detector 10
The signal S from 6... is first sent to this selection circuit 11.
It is input to 0. Further, this selection circuit 110 receives a signal S from the control rod control device 10B that designates a control rod to be pulled out.
! is configured to be input. Then, this selection circuit 110 selects the designated control rod 101' as shown in FIG. 9 based on the signal s2 designating the control rod.
A total of 16 output area neutron detectors 10 in 4 stages surrounding the
6... is selected, and the selected output region neutron detector 106... is selected as the A system.

Divided into B system, output range neutron detector 106 of A system...
・The signal Sl... is sent to the A unaverage circuit 111a,
System output region neutron detector 106...signal S1
... are configured to be sent to the B asymmetric circuit 111b, respectively. Then, the A unaverage circuit 111a and the B unaverage circuit 111b calculate the average value of the sent signals Sl... from the output range neutron detectors 106, and convert the average value signal into 'In adjustment circuit 112h
The signal is configured to be sent to an A-system determination circuit 113a and a B-system determination circuit 113b, respectively, via an XB-system gain adjustment circuit 112b. In addition, the A-system gain adjustment circuit 11
2a, B system gain adjustment circuit 112b XA system judgment circuit 11
Each of the EaXB system determination circuits 113b is configured to receive a control rod withdrawal prevention set value signal S3.

Then, the A system determination circuit 113a and the B system determination circuit 11
3b, this control rod withdrawal prevention set value signal S is compared with the average value of the signals of the output region neutron detector 106...
If this average value exceeds the control rod withdrawal prevention setting value, a control rod withdrawal prevention signal S4 is sent to the control rod control device 108,
A signal is sent to the recirculation pump controller 116 to prevent further withdrawal of the control rods and to reduce the core flow rate, such as a recirculation chimp trip signal S5.
is configured to trip. In addition, 115
is a pinox number determination circuit that determines the number of pinoxed neutron detectors 106 in the selected output range that are faulty and has been pinned, and calculates the number of pinoxed neutron detectors corresponding to the number of pinoxed A unaverage circuit 111aXB average circuit 11
lb.

It is configured to send correction signals to the A-system determination circuit 11Sh, the XB-system determination circuit 113b, respectively.

Next, the operation of the above embodiment will be explained. When the control rod to be extracted, for example, the control rod 101' marked with diagonal lines in FIG. A total of 16 power range neutron detectors 106 . . . in four stages are selected surrounding the control rod 101'. Then, the signal Sl... from the selected output region neutron detector 106... is sent to the A unaverage circuit I J 1 for each A system and B system.
a.

The average value 10- is averaged by the B-unaveraged circuit 111b, and the average value 10- is compared with the control rod withdrawal prevention setting value by the A-system determination circuit 113th and the B-system determination circuit 113b, respectively.

Then, the control rod 101' was improperly withdrawn,
If the fuel output around this control rod 101' locally increases excessively and the average value of the A system or B system exceeds the control rod withdrawal prevention setting value, the A system determination circuit 113a or the B system determination circuit 113b A control rod withdrawal prevention signal S4 is output to prevent the control rod 101' from being withdrawn. At the same time, a recirculation positive trip signal S5 is output from the A-system determination circuit 113a or the B-system determination circuit 113b, and the recirculation pump f114 trips. Therefore, the core flow rate decreases, and the output of the core 104 decreases. Therefore, this control rod 1
The output of the fuel around point 01' increases to point A as shown by the broken line in FIG.
Descending. Therefore, even if the control rod 101' is left in this state for a long time, the fuel around the control rod 101' will not be damaged.

Note that the present invention is not necessarily limited to the above-mentioned embodiment, and for example, it is not necessary to output a trip signal for the recirculation pump from the control rod withdrawal monitoring circuit, and in short, it is not necessary to output a trip signal for the recirculation pump from the control rod withdrawal monitoring circuit. It is only necessary to output a signal that reduces the core flow rate sufficiently to prevent damage to the fuel around the control rods where the control rods are exposed.

Effects of the Invention In the present invention, a control rod withdrawal prevention signal is outputted from the control rod withdrawal monitoring circuit, and a core flow rate reduction signal is outputted to reduce the core flow rate. Fuel output decreases due to a decrease in core flow rate.

Therefore, even if the control rod is left in this state for a long time, damage to the fuel around the control rod that has been prevented from being pulled out can be reliably prevented, which is highly effective.

[Brief explanation of drawings]

Figures 1 to 4 show conventional examples, where Figure 1 is a plan view of a unit cell, Figure 2 is a schematic plan view of the core, Figure 3 is a schematic configuration diagram, and Figure 4 is a diagram showing the control rods. It is a figure which shows the relationship with the surrounding output area neutron detector. Further, FIG. 5 is a diagram showing the relationship between the amount of increase in output, the time after the increase in output, and fuel damage. 6 to 10 show an embodiment of the present invention, FIG. 6 is a plan view of a unit cell, FIG. 7 is a plan view of a core,
FIG. 8 is a schematic configuration diagram, FIG. 9 is a diagram showing the relationship between the control rod and the surrounding output area neutron detector, and FIG. 10 is a schematic configuration diagram of the control rod withdrawal monitoring circuit. Further, FIG. 11 is a diagram showing the relationship between the amount of increase in output, the time after the increase in output, and fuel damage. 101... Control rod, 102... Fuel assembly, 104
...Reactor core, 106...Power range/neutron, 107.
...Control rod drive mechanism, 108...Control rod control device, 1
0 No. Control rod withdrawal monitoring circuit, 114 Recirculation pump, 116 Recirculation pump control circuit. Applicant's agent Patent attorney Takehiko Suzue 13-

Claims (2)

[Claims] (1) Select the power range neutron detectors installed in the reactor core and a group of power range neutron detectors surrounding the control rod designated for withdrawal operation, and select the selected group of power range neutron detectors. Divide into multiple systems and calculate the average value of the output of the neutron detector in the output range for each non-volatile system. If any of the average values of these systems exceeds the control rod withdrawal prevention setting value, a control rod withdrawal prevention signal is generated. A control rod withdrawal monitoring device characterized by comprising a control rod withdrawal monitoring circuit that outputs a core flow rate reduction signal to a recirculation pump control device to reduce the core flow rate. (2) The control rod withdrawal monitoring device according to claim 1, wherein the control rod withdrawal monitoring circuit outputs a recirculation pump trip signal as the core flow rate reduction signal.