JPS6018038B2 - Detector guide tube for mobile in-reactor neutron instrumentation equipment - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to a detector guide tube for a mobile in-core neutron instrumentation device that calibrates a detector assembly inserted into a boiling water reactor. Regarding.

[Technical background of the invention]

In a boiling water reactor, a plurality of detector assemblies are inserted into the reactor core, and the plurality of neutron detectors installed in the detector assemblies are configured to detect neutrons in the reactor core. There is.

Furthermore, a mobile in-core neutron meter bag device is provided which moves a calibration detector along the detector assembly and calibrates the neutron detector. This mobile in-core neutron instrumentation device is constructed as shown in Figures 1 and 2. In other words, ``The military in the diagram is a nuclear reactor pressure vessel,
A reactor core 2 is housed within this reactor pressure vessel 1 .

The detector assembly 3 is inserted into the reactor core 2 by penetrating the lower mirror portion of the reactor pressure vessel 2. Although a plurality of detectors are inserted into this detector assembly 3,
[Tradition] Only one is shown in the figure. This detector assembly 3 includes a plurality of neutron detectors, for example, four neutron detectors (not shown).
There are. In addition, a calibration tube 4 is provided in the detector assembly 3 along the direction of the arrow, and the calibration detector of the mobile in-reactor neutron meter is moved inside this calibration tube 4 to The detector is configured to calibrate a neutron detector. This mobile in-core neutron instrumentation device is configured as follows.

That is, 5 is a detector guide tube, and one end of this detector guide tube 5 is connected to the lower end of the calibration tube 4. The detector guide tube 5 penetrates the reactor bed building 6, the reactor containment vessel wall 7, the reactor building wall 8, etc., and is led out to the outside. The other end is connected to a detector drive mechanism 9.The detector drive mechanism 9 is connected to a drive cable 10 having specularity.
A calibration detector 11 is attached to the tip of the drive cable IQ. When the drive cable 10 is operated, the calibration detector 11 is inserted into the calibration tube 4 through the detector guide tube 5, and when the drive cable 10 is pulled out, the calibration detector 11 is inserted into the calibration tube 4 through the detector guide tube 5. It is configured to be taken out through the guide tube 5 to the position of the detector drive mechanism 9. In the middle of the detector guide tube 5, there are provided an indexing machine 12 for indexing the drive cable 10, a valve assembly 13, a shielding container 14, and the like. "Conventionally, the detector guide tube 6' is made of stainless steel, and its inner surface is coated with a solid lubricant 6 to reduce the frictional resistance of the calibration detector guide tube and drive cable guide Q. is configured to do so.

[Problems with background technology]

The lifespan of the detector guide tube is approximately 3 due to wear and corrosion.
The detector guide tube is replaced with a new detector guide tube approximately every three years.

By the way, since this detector guide tube is long and complicatedly bent, when installing a new detector guide tube, bending work or the like must be carried out at the construction site, and the installation must be done by what is called a current fitting method. However, in the conventional detector guide tube, the detector guide tube is made of stainless steel, which is hard and easily work-hardened, making it difficult to bend, etc., which increases the working time and reduces the radiation exposure of workers. There was a problem that was getting bigger. In addition, as mentioned above, this stainless steel detector guide tube is difficult to bend, so the cross-sectional shape is likely to change during bending, which may cause problems with the passage of the calibration detector and disturbance cable. In order to solve this problem, it is possible to use the same material as the detector guide tube. However, if this method is used, the wear of the detector guide tube will increase, which will significantly shorten the life of the detector guide tube. In the conventional method, the solid lubricant gradually peels off due to friction with the calibration detector and the drive cable, and particles of the peeled solid lubricant accumulate in the detector guide tube.

And ~ If this particle adheres to the calibration detector or drive cable and is inserted into the reactor core, this particle will become radioactive, but when this calibration detector or drive cable is pulled out, this activated particle will be detected. There were cases where the particles were brought into the detector drive mechanism and contaminated the inside of this detector drive mechanism. Furthermore, there was also a problem in that such particles hardened with moisture and prevented smooth movement of the calibration detector. To solve this problem, it is conceivable to form the detector guide tube itself from a synthetic resin material with a small coefficient of friction, or to coat the inner surface of the detector guide tube with such a synthetic resin material. but,
The temperature inside the reactor containment vessel is between 60℃ and 7℃ during reactor operation.
As the temperature reaches 0°C and the radiation level increases, synthetic resin materials undergo severe deterioration, resulting in problems such as a significantly shortened lifespan. [Purpose of the Invention] The present invention is easy to bend, etc., requires only a short time on site, and can significantly reduce the radiation dose of workers.
In addition to its high durability and long service life, the generation of lubricant particles is extremely low, which prevents contamination from radioactive particles, and when these particles solidify with moisture, they can help calibrate the detector smoothly. The object of the present invention is to obtain a detection guide for a mobile in-reactor neutron meter Ryosotaka that does not hinder its movement.

[Summary of the Invention] The present invention comprises a guide tube body made of an aluminum material, a porous aluminum oxide coating formed by oxidizing the inner surface of the guide tube body,
The solid lubricant is filled into the pores of this aluminum oxide coating.

Therefore, ``Aluminum material is flexible and ductile, so it is easy to bend, etc., and installation work on site is short, greatly reducing radiation exposure for workers. An aluminum oxide coating is formed on the guide tube body.Although this aluminum oxide coating is grooved, it has high wear resistance and has a long life.Also, this aluminum oxide coating oxidizes the inner surface of the guide tube body and Because it is formed integrally with the material of Since the detector is held in place, it does not peel off.Therefore, no particles are generated, and contamination due to particle activation can be reliably prevented.Furthermore, the solidification of such particles prevents smooth movement of the calibration detector. Embodiments of the Invention An embodiment of the invention will be described below with reference to FIGS. 3 and 4.

In the figure, 101 is a reactor pressure vessel, and a reactor core 102 is accommodated within this reactor pressure vessel 101. The detector assembly IQ3 is inserted into the reactor core 102 by penetrating the lower mirror portion of the reactor pressure vessel IQI. Although a plurality of detector assembly wings 03 are inserted, only one is shown in FIG. A plurality of, for example, four neutron detectors (not shown) are provided within this detector assembly 103. In addition, a calibration tube 104 is provided in this detector assembly 103 along its axis in all directions, and the calibration detector of the mobile in-reactor neutron meter Kesadaka moves within this calibration tube turtle 04. The neutron detector is configured to calibrate the neutron detector. This mobile in-core neutron meter bag device is constructed as follows.

That is, 105 is a detector guide tube, and one end of this detector guide tube 05 is connected to the lower end of the calibration tube Q6. , passes through the reactor containment vessel armpit OT, the reactor building 108, etc., and is led out to the outside.The other end of this detector guide pipe shaft 05 is connected to the detector drive mechanism mechanism 0.
9 is connected. This detector drive mechanism 18
Reference numeral 9 denotes a flexible drive cable 10 which is configured to be fed into and pulled out of the detector guide tube 06, and a calibration detector 11 is attached to the tip of the sardine scale cable 06. is installed. Then, when the above-mentioned drive cable holder 0 is pulled out, the 11 calibration detectors are inserted into the calibration tube holder Q4 through the detector guide tube 185, and when the drive cable holder IQ is pulled out, the calibrator detector 11 is inserted into the calibration tube holder Q4 through the detector guide tube 185. The instrument is configured to be taken out through the detector guide tube to the position of the detector drive mechanism Q8. Incidentally, in the middle of the detector guide tube Q5, there is also a shielding device for indexing the drive cable 1 through 0 for the indexing device 2 valve assembly 3 as well. Then, the detector guide tube turtle 0
5 is constructed as shown in Fig. 5.

Q58 is a guide tube body, and this guide tube body turtle 8a is made of aluminum material such as aluminum or aluminum alloy. An aluminum oxide coating 1 5 is formed on the inner surface of the guide tube body Q5a by oxidizing the inner surface of the guide tube body 105a.

This aluminum oxide coating 115 is porous with many fine pores. Note that these holes can be formed depending on the conditions of the chemical process when forming the aluminum oxide film l i5. and,
This hole is filled with a solid lubricant 1 and 6, and is configured to reduce the frictional resistance of the calibration detector 1 and the drive cable 110. [Effects of the Invention] As described above, the present invention comprises a guide tube body made of an aluminum material, a porous aluminum oxide coating formed by oxidizing the inner surface of the guide tube body, and a porous aluminum oxide coating formed by oxidizing the inner surface of the guide tube body, and a porous aluminum oxide coating formed by oxidizing the inner surface of the guide tube body. It is equipped with a solid lubricant filled inside.

Therefore, ``aluminum material is flexible and ductile, so it is easy to bend, etc., and the installation work on site is short, significantly reducing the radiation exposure of workers. An aluminum oxide coating is formed on the guide tube body, and this aluminum oxide coating is hard and has high wear resistance, resulting in a long life.Also, this aluminum oxide coating oxidizes the inner surface of the guide tube body, causing damage to the guide tube body. Since it is formed integrally with the material, it will not peel off.Also, since this aluminum oxide coating is porous and the solid lubricant is filled in the pores, there is less frictional resistance, and the solid lubricant in parentheses is in the hole. Because it is retained, it does not fall off.Therefore, particles are not generated and contamination due to particle activation can be reliably prevented, and the solidification of such particles will prevent smooth movement of the calibration detector. The effect is great, such as the fact that the detector guide tube is not exposed to the light. FIG.

FIGS. 3 and 4 show an embodiment of the present invention, with FIG. 3 being a longitudinal sectional view of the whole, and FIG. 4 being a longitudinal sectional view of a part of the detector guide tube. 101... Nuclear reactor pressure vessel, 102...
...Reactor core, 103...Detector assembly, IQ4...
... Calibration tube, i05 ... Detector guide tube, 105a ... Guide tube body, 110 ... Drive cable, stove 11 ...
- Calibration detector, 115...aluminum oxide film, 116...solid lubricant.

Figure 1 Figure 2 Figure 3 Figure 4

Claims (1)

[Claims] 1. A guide tube body made of aluminum material, a porous aluminum oxide coating formed by oxidizing the inner surface of this guide tube body, and a solid lubricant filled in the pores of this aluminum oxide coating. A detector guide tube for a mobile in-core neutron instrumentation device, characterized by comprising: