JPS62170898A - Nuclear reactor fuel decontaminator by ultrasonic wave - 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 the Invention] The present invention relates to a nuclear reactor fuel that uses ultrasonic waves to remove crud and scale attached to the outer surface of a fuel bottle of a fuel assembly constituting the core of a boiling water reactor. Regarding decontamination equipment.

[Technical background of the invention]

In a boiling water reactor, a large number of fuel assemblies are loaded inside a reactor pressure vessel to form a reactor core, and pure water passing through the core is brought into contact with the outer surface of the fuel bottle of each fuel assembly, and the fuel is heated by nuclear reaction heat to generate high-temperature, high-pressure steam,
The high-temperature, high-pressure steam is sent to a turbine, which rotates it.
A turbine drives a generator. Further, the steam after driving the turbine is guided to a condenser, liquefied, and then supplied to the inside of the reactor pressure vessel again.

Figures 2 and 3 show a fuel assembly 1. Inside a rectangular cylindrical channel hook 2 with an approximately square cross section, there are two water rods 3 marked with . Show
? 1-62 fuel pins 4 are arranged and accommodated in a matrix of 8 rows and 8 columns. Note that a lower nozzle 5 is provided at the lower end of the channel box 2, and a handle 6 is provided at the upper end.

In the fuel assembly 1 as described above, pure water flows into the channel box 2 from the lower nozzle 5, and high-temperature, high-pressure steam generated by contact with the fuel pin 4 flows out from the upper end of the channel box 2. It has become.

By the way, if the fuel pin 4 is used for a long time, crud and scale will adhere to the outer surface of the fuel pin 4, and the heat transfer characteristics of the outer surface will deteriorate. Moreover, the outer surface of the fuel pin 4 is also rendered radioactive.

Therefore, it is necessary to perform decontamination to remove crud and scale attached to the outer surface of the fuel pin 4.

Conventionally, decontamination of reactor fuel has been carried out by removing the channel box 2 of the fuel assembly 1 and spraying a strong water stream onto the fuel pins 4 in the fuel pool. The disadvantage is that it takes a long time to process the fuel and requires long hours of dangerous fuel handling work. In addition, although the decontamination effect can be obtained on the outward facing part of the fuel pin 4 located at the outermost periphery of the fuel assembly 1, the decontamination effect is not sufficient in other parts and other fuel bottles. There was also the drawback that the overall decontamination efficiency was extremely poor.

Therefore, recently, channel box 2 of fuel assembly 1
Decontamination using ultrasonic radiation is being investigated as a method of decontaminating the area without causing any damage.

[Problems with background technology]

Reactor fuel decontamination equipment using ultrasonic waves has the advantage of reducing work time because it is not necessary to remove the channel box 2, but since the ultrasonic waves are attenuated within the channel box, the decontamination effect is reduced. , was not necessarily sufficient. In addition, decontamination using ultrasonic waves, in principle, actively generates cavitation, so there are problems such as erosion of the channel box.

[Purpose of the invention]

An object of the present invention is to provide a nuclear reactor fuel decontamination device using ultrasonic waves that can effectively remove crud and scale attached to the outer surface of a fuel pin in a short time, and can also prevent channel box erosion. There is a particular thing.

[Summary of the invention]

The nuclear reactor fuel decontamination device using ultrasonic waves according to the present invention uses an ultrasonic oscillator in which the amplitude of the vibration plane of the ultrasonic oscillator is constant, and the distance between the ultrasonic oscillator and the channel box is adjusted. It is possible.

(Embodiment of the invention) FIG. 1 shows an embodiment of the invention, in which a fuel pool 1
A cleaning tower 11 is installed at the bottom 10a of the container 0, facing vertically. The cleaning tower 11 has an elongated cylindrical shape with a length sufficient to accommodate the fuel assembly 1, and has a large number of guide rollers 12 provided on its inner surface to guide the fuel assembly 1 in the vertical direction. There is.

An ultrasonic oscillator 13 is installed at the end of the cleaning tower 11.
It is installed horizontally movably so that the distance from the center line can be changed. An oscillator position adjustment mechanism 14 is connected to this ultrasonic oscillator 13, and the fuel pool 1
By rotating the operation handle 14a of the adjustment mechanism 14 provided at a position above 0, the ultrasonic oscillator 1
3 can be moved and adjusted in the horizontal direction. Further, an ultrasonic oscillator 15 is installed outside the fuel pool 10, and the ultrasonic waves generated by the ultrasonic oscillator 15 are radiated horizontally from the ultrasonic oscillator 13 toward the center line of the cleaning tower 11. I have to. The ultrasonic oscillator 15 is configured to operate the ultrasonic oscillator 13 regardless of the load even if the load fluctuates.
The ultrasonic oscillator 13 is driven so that the amplitude of the vibrating surface is constant.

A slurry reservoir 16 is provided at the bottom of the cleaning tower 11. Further, a slurry pump 17 is installed at the bottom of the fuel pool 10 adjacent to the cleaning tower 11,
The suction port of this pump 17 is connected to the slurry reservoir 16 via a slurry discharge pipe 18. Furthermore, a filter device 19 is attached to the upper part of the inner wall surface of the fuel boule 10, and this filter device 19 is connected to the discharge port of the slurry pump 17 via the flexible slurry transfer pipe 2°. There is.

In addition, in the figure, 21 indicates a part of the conveyance device that conveys the fuel assembly 1.

Next, the action will be explained.

When decontaminating the fuel bin 4 (see FIG. 4) in the fuel assembly 1, the fuel assembly 1 to be decontaminated is first lifted from the core by the transport device 21 and transferred into the fuel pool 10. do.

Then, J shown in FIG. descend to. Thereafter, the power of the ultrasonic oscillator 15 is turned on, and the operation handle 1/Ia of the oscillator position adjustment mechanism 14 is rotated to move the ultrasonic oscillator 13 in the horizontal direction. The distance between the ultrasonic oscillator 13 and the ultrasonic oscillator 13 is set to the shortest resonance distance of the ultrasonic waves emitted from the ultrasonic oscillator 13. Therefore, the oscillation state of the ultrasonic waves emitted from the ultrasonic oscillator 13 is a stable low-load state when the distance between the ultrasonic oscillator 13 and the fuel assembly 1 is set to the shortest distance.

In this state, the fuel assembly 1 is inserted into the cleaning tower 11 along the guide roller 12 at a speed such that ultrasonic waves are radiated onto the same surface for 2 to 3 minutes each time, and the fuel bottle 4 is continuously inserted into the cleaning tower 11. will be decontaminated. Note that the sound pressure of the ultrasonic waves emitted at this time must be 1 atm or more, and the frequency used is 26
Preferably around Kl-1z.

In this way, the contaminants such as crud and scale separated from the outer peripheral surface of the fuel assembly 1 flow out together with the pool water from the lower nozzle 5 (see Fig. 2) of the fuel assembly 1. The slurry is collected in a slurry reservoir 16 provided at the bottom of the cleaning tower 11. Further, the slurry is pumped out of the cleaning tower 11 by the slurry pump 17 and sent to the filter device 19 through the slurry transfer pipe 20 along with the pool water. In addition, the water from which pollutants have been removed by the filter device 19 is returned to the fuel pool 10.

Further, the fuel assembly 1 that has been decontaminated is taken out from the cleaning tower 11 and reloaded into the core of the nuclear reactor.

This embodiment provides the following effects.

Since the vibration surface of the ultrasonic oscillator 13 always has a constant amplitude,
By setting the distance between the ultrasonic oscillator 13 and the fuel assembly 1 to be a resonance point, a standing wave is generated and the ultrasonic oscillator 15 can be operated in a stable low-load state.

Furthermore, due to the emission of ultrasonic waves, cavitation occurs in the channel box 2 of the fuel assembly 1 and a bubble cloud is generated in the water, making the underwater environment unstable. Even if the load on the ultrasonic oscillator 15 changes due to a slight change in the distance between the two, the sound pressure of the ultrasonic waves commensurate with the load can be obtained, and stable decontamination ability can be maintained.

Furthermore, by installing the ultrasonic oscillator 13 at the upper end of the cleaning tower 11, the ultrasonic oscillator 1 is generated by the water pressure of the pool water.
3 and the ultrasonic oscillator 15 can be kept low.

Further, by providing the guide roller 12 inside the cleaning tower 11, the fuel assembly 1 can be inserted into the interior of the cleaning tower 11, and the ultrasonic oscillator 13 and the fuel assembly 1 can be inserted into the cleaning tower 11.
Fluctuations in the distance between the two can be suppressed to a small level.

In addition, contaminants such as crud and scale separated from the outer surface of the fuel bottle 4 are removed from the cleaning tower by a pump 17.
1, the emission of ultrasonic waves is not hindered by the accumulation of detached contaminants.
Efficient decontamination can be performed by suppressing the attenuation of ultrasonic waves.

Note that peeling of cladding, etc. by ultrasonic waves reaches a saturated state within a few minutes after ultrasonic waves are irradiated, so it is sufficient to emit radiation for about 3 to 5 minutes on the same object as shown in the =10- of this device. has been confirmed by experiment, and therefore, fuel pin 4
Erosion due to ultrasonic radiation does not occur in the channel box 2 covering the fuel assembly 1, making it possible to reload the fuel assembly 1 into the reactor core.

The position of the ultrasonic oscillator 13 that can be operated in a stable low load state is at a distance of 10 wavelengths when the distance between the vibration surface of the ultrasonic oscillator 13 and the fuel assembly 1 becomes the resonant distance at the oscillation frequency. However, by setting the resonance distance to the shortest, the efficiency of decontamination can be increased.

In addition, the point where the maximum sound pressure occurs at this time, that is, the point where the decontamination ability is maximum, is theoretically at a wavelength shifted from the resonance point, and there are points where the sound pressure increases at i wavelength intervals from this point. However, in reality, the fuel assembly 1 is composed of a water rod 3 and a fuel pin 4, so
Reflection, diffraction, attenuation, etc. of ultrasonic waves occur inside the channel box 2, and the sound pressure distribution does not match the theoretical one. It can be advanced to the center of the cross section.

In the above embodiment, one ultrasonic oscillator 13 is attached to one cleaning tower 11 for decontamination. Good too. In addition, although the description has been made assuming that decontamination is performed while the fuel assembly 1 is inserted into the cleaning tower 11, it is also possible to first accommodate the fuel assembly 1 in the cleaning tower 11 and then perform decontamination while taking it out. or cleaning tower 1
It is also possible to perform decontamination both at the time of insertion into 1 and at the time of withdrawal.

〔Effect of the invention〕

As detailed above, according to the present invention, it is possible to remove crud, etc. attached to the fuel pins without removing the channel box of the fuel assembly, thereby significantly reducing the time required for fuel handling work. Thus, it is possible to reduce the exposure line ω. Further, the configuration can be made relatively simple, the operation is easy, and the reliability is high, so that excellent effects can be obtained.

[Brief explanation of drawings]

FIG. 1 is a schematic configuration diagram showing an embodiment of the present invention, FIG. 2 is a side view of a fuel assembly, and FIG. 3 is a sectional view taken along the line 1--2 in FIG. 1...burn 1 aggregate, 2...channel box,
4... Fuel bottle, 11... Cleaning tower, 13... Ultrasonic oscillator, 14... Oscillator position adjustment mechanism, 15...
Ultrasonic oscillator.

Claims (2)

[Claims] (1) A cleaning tower that is installed in the fuel pool with its center line oriented almost vertically, into which the fuel assembly taken out from the core is inserted through the upper opening; An ultrasonic oscillator that is installed so that it can be moved horizontally so as to change the distance between the cleaning tower and oscillates ultrasonic waves in a substantially horizontal direction toward the center line of the cleaning tower, and an ultrasonic oscillator that can be adjusted by moving horizontally. and an ultrasonic oscillator that drives the ultrasonic oscillator so that the amplitude of the vibration plane of the ultrasonic oscillator is always constant regardless of the load. Reactor fuel decontamination equipment using ultrasonic waves. (2) The oscillator position adjustment mechanism has a rotary operation handle located above the fuel pool, and the distance between the fuel assembly and the ultrasonic oscillator is adjusted by rotating the handle. A nuclear reactor fuel decontamination device using ultrasonic waves according to claim 1.