RU2236051C2 - Method for inspecting and grading fuel elements - Google Patents

Abstract

FIELD: nuclear power engineering.

SUBSTANCE: proposed method includes pre-check of

-scanner specifications, its adjustment and calibration by

-scanning of certified standard specimens taken from fuel element manufacturer whose parameters are known already.

EFFECT: enhanced precision of fuel element inspection and grading.

1 cl, 2 dwg

Description

The invention relates to nuclear energy and can find application in enterprises manufacturing fuel elements (fuel elements) and assembling them into fuel assemblies (fuel assemblies) for a nuclear reactor.

It is known that for the normal operation of a nuclear reactor, elimination of distortions of the neutron and temperature fields in each fuel element, there must be a strictly specified amount of nuclear fuel (fissile isotope) and its uniform distribution along the length of the fuel element. This should be provided and, as a rule, provided by technology.

Uranium dioxide pellets with strictly specified uranium enrichment 235 are supplied to the fuel elements of fuel rods. A fuel column of a fixed length is collected for each fuel rod, which at a given density determines the mass of fuel in the fuel rod.

In addition, in some cases, all fuel is additionally determined by direct weighing. However, it does not exclude cases when fuel pellets with different enrichment in uranium 235 enters fuel elements when it is equipped with fuel elements, since fuel pellets with different enrichments in uranium 235 may be present in the fuel rod manufacturing process, which do not differ externally from each other. Given the importance of this characteristic of a fuel rod, it became necessary to control the fuel rod and to sort it out before assembling it in a fuel assembly.

A known method of control and sorting of fuel rods, including the operation of loading and unloading fuel rods and wiring them through the channel of a gamma-ray scanner with a neutron source in biological protection with data feed into an electronic computer (see book 2 “Development, production and operation of fuel rods of energy reactors” Edited by F.G. Reshetnikov M .: Energoatomizdat, 1995, pp. 284-285, Fig. 21, 14).

The controlled fuel rod moves along the axis of the irradiator with a strictly constant speed. Control is carried out by delayed γ-radiation. The percentage of 235U is calculated by the formula 235U = e (N + a) / b, where N is the counting rate, and b are the calibration constants.

The error in determining the content of 235U is estimated at ± 0.6%. The relative error in measuring the enrichment of UO ₂ tablets in the range of 3-7% does not exceed 5%. The control results are processed on a computer and presented in the form of a protocol. TVELs with a length of 4 m and a diameter of γ-13.5 mm are subjected to control. The fuel rod is sent to and from the control unit on rollers, causing abrasion of the surface of the zirconium shell of the fuel rod, which can lead to corrosive corrosion resulting from the abrasion of zirconium between contacting surfaces even in the absence of a corrosive medium (see “Zirconium metallurgy.” Translation from English under Edited by G.A. Meerson and Yu.V. Gagarinsky M .: Publishing house of foreign literature, 1959, p. 298).

Corrosion can lead to depressurization of a fuel rod in the core of a nuclear reactor.

The closest in technical essence and the achieved effect is a method of monitoring and sorting out fuel elements for a nuclear reactor, including loading them, piece feeding on an inclined table to a conveyor zirconium belt for conducting a fuel element through the channel of a γ-scanner with a neutron source in biological protection with the supply of control data into an electronic computer, sorting and unloading fuel elements on an inclined table. (see Patent RU 2155394, IPC 7 G 21 С 17/06 of 02/17/1999, publ. 08/27/2000, "Installation of control and sorting of fuel elements").

In the technical solution prototype, Cf-252 with a nominal value of 1.2 mg is used as a neutron source, a beryllium moderator as a neutron moderator, and lead is used as a biological defense.

A densitometer is used to measure the gaps between uranium dioxide tablets and the tablet lengths in the fuel element, a detector is used to determine the presence of clamps in the fuel element, and a detector consisting of eight BGO scintillators, eight photomultiplier tubes with voltage dividers and eight is used to control the delayed γ-radiation fast preamplifiers (“NNC”) and delayed neutron detector.

The method provides control of the fuel rod and the weight of the fuel column is determined; 235U enrichment; fuel tablets with non-standard enrichment; fuel column length; length of the compensation volume; clearances in the fuel column and the presence of clamps.

However, the method cannot guarantee the accuracy of the control of a fuel rod without a corresponding check of the technical characteristics of the γ-scanner, its settings and calibration.

An object of the invention is to improve the accuracy of control and sorting of the fuel element.

This technical problem is solved by the fact that in the method of monitoring and sorting out fuel elements for a nuclear reactor, including loading them, a piece feed on an inclined table to a conveyor zirconium belt of a fuel element through a channel of a γ-scanner with a neutron source in biological protection with the supply of control data to electronic computer, sorting and unloading of fuel elements on inclined tables.

According to the invention, a preliminary check of the technical characteristics of the γ-scanner is carried out, its adjustment and calibration by gamma scanning of certified standard samples of the enterprise-fuel elements with previously known parameters: according to class I:

- average enrichment of 235U fuel load;

- the length of the fuel column;

- the length of the fuel element;

- the length of the compensation volume;

- the presence and length of the clamps,

in class II:

- average enrichment of 235U profiled zones;

- the presence of end caps;

- the length of the profiled zones;

- average enrichment over the 235U zone,

in class III:

- the presence of an abnormal enrichment tablet of 235U in the central part of the fuel column;

- the presence of an abnormal enrichment tablet of 235U in the lower portion of the fuel column;

- the presence of an abnormal enrichment tablet of 235U in the upper part of the fuel column;

- the location of individual abnormal tablets,

in class IV:

- the size of the gaps in the fuel column;

- the location of the gaps;

- the location and length of the retainers,

after γ-scanning of certified standard samples of the enterprise - fuel elements with previously known parameters and comparing them with the data issued by the electronic computer after γ-scanning, they make the decision of γ-scanning of standard batches of fuel elements with data matching, and if the data do not match, they are tuned γ-scanner in accordance with the known parameters of certified standard samples of fuel elements according to classes I-IV.

The proposed method allows to solve the technical problem to improve the accuracy of control and sorting of the fuel element.

To explain the implementation of the method in the drawings presents:

figure 1 - a standard sample of the enterprise (SOP) I class;

- a standard enterprise sample (SOP) class II;

- a standard enterprise sample (SOP) of class III;

- a standard enterprise sample (SOP) IV class;

figure 2 - installation of γ-scanning.

A method of monitoring and sorting fuel elements 1 for a nuclear reactor includes loading, piece feeding on an inclined table 2 to a conveyor zirconium belt 3, wiring the fuel element 1 through a channel 4 of a γ-scanner 5 with a source of 6 neutrons in biological protection 7 with supplying the control data electronically - a computer 8, the unloading of the fuel elements 1 on an inclined table 9 and sorting on an inclined table 10.

Before γ-scanning of standard batches of fuel elements 1, the method involves a preliminary check of the technical characteristics of the γ-scanner 5, its adjustment and calibration by γ-scanning of certified standard samples of the enterprise - fuel elements 11 with previously known parameters

class I:

- average enrichment of 235U fuel load;

- the length L of the fuel element 11;

- the length L _{1 of the} fuel column of tablets 12;

- the length L _{2 of the} compensation volume;

- the presence and length L _{3 of the} retainers 13,

in class II:

- average enrichment for 235U of the profiled zones A, B, C, D, E of different enrichment for 235U;

- the presence of end caps 14, 15;

- the length of the profiled zones A, B, C, D, E;

- average enrichment of the zone at 235U,

in class III:

- the presence of a non-standard tablet 12 “a” for enrichment of 235U in the central part of the fuel column;

- the presence of a non-standard tablet 12 “c” for enrichment of 235U in the lower section of the fuel column;

the presence of an abnormal tablet 12 “s” enrichment of 235U in the upper part of the fuel column;

- the location of the individual abnormal tablets 12,

in class IV:

- the size of the gaps in the fuel column;

- the location of the gaps;

- the location and length L _{4 of the} retainers,

comparing the γ-scan data with the previously known data of certified reference materials of the enterprise of the fuel elements 11 according to classes I-IV and if the data issued by the electronic computer 8 after the γ-scanning coincides with the data of the certified reference materials - the fuel elements 11 of fuel elements 1 of standard batches, and if the data do not match, the γ-scanner 5 is set up in accordance with the known parameters of certified standard samples - heat output fissile elements 11 of class I-IV.

The method is as follows.

Standard samples of the enterprise (SOP) are pre-fabricated - fuel elements 11 of four classes, each of which serves to verify the technical characteristics of the γ-scanner 5.

For class I, two sets of “SOPs” are made, each of which consists of four subclasses with enrichment of fuel pellets of 235U,%: 1.6, 2.4, 3.0, 3.6, 4.4, including as working “SOPs” used to verify the technical characteristics of γ- scanner 5 during operation, as well as control “SOP” used when there is a suspicion of a malfunction of the working “SOP”. In the process of manufacturing the “SOP” all its parameters are certified and entered in the passport.

According to class II, four “SOPs” are made, of which three workers and one control.

Profiled zones A, B, C, D, E, i.e. zones with different enrichment of 235U are certified and all parameters are entered in the passport.

In class III, two sets of three “SOPs” are made with control and working “SOPs” with the exact location of the emergency tablets 12 “a”, 12 “c”, 12 “c”.

All parameters are entered in the passport.

Four “SOPs” are made according to class IV, of which one is a control one using a spring clip. All parameters are entered in the passport.

Average enrichment of 235U fuel load, length of fuel column, length of fuel element, length of compensation volume, presence and length of locks, average enrichment of 235U profiled zones, presence of end caps, length of profiled zones, average enrichment of 235U profiled zone, gap size in the fuel column , the location of the gaps, the location and length of the clamps in the “SOPs” are determined by means of control and manufacturing technology of fuel elements and are also recorded in the passport accordingly vuyuschego class "SOPA".

In the process of setting up the γ-scanner 5, the γ-scanning of “SOPs” of the I-IV class is performed, then the data of the passports, “SOPs” of the I-IV class are compared with the data issued by the electronic computer 8.

When the data coincide, a γ-scan of the standard batches of TVEL 1 is performed, and if there is a mismatch, the γ-scanner 5 is continued to be tuned according to “SOPs” of I-IV class.

Claims (1)

A method for controlling and sorting fuel elements for a nuclear reactor, including loading them, piece feeding on an inclined table to a conveyor zirconium belt for conducting a fuel element through a γ-scanner channel with a biological protection neutron source, supplying control data to an electronic computer, sorting and unloading of fuel elements on inclined tables, characterized in that they carry out a preliminary check of the technical characteristics of the γ-scanner, its adjustment and calibration γ-scanning topics of certified enterprise standard samples - fuel elements with previously known parameters: class I: 235U average fuel charge; fuel column length; the length of the fuel element; length of the compensation volume; the presence and length of the clips in class II: average enrichment of 235U profiled zones; the presence of end caps; the length of the profiled zones; average enrichment over 235U zones, in class III: the presence of an emergency enrichment tablet of 235U in the central part of the fuel column; the presence of an abnormal enrichment tablet of 235U in the lower portion of the fuel column; the presence of an abnormal enrichment tablet of 235U in the upper part of the fuel column; the location of individual abnormal tablets, in class IV: the size of the gaps in the fuel column; location of gaps; location and length of clips after γ-scanning of certified standard samples of the enterprise — fuel elements with previously known parameters and comparing them with the data issued by the electronic computer after γ-scanning — they make the decision to γ-scan standard batches of fuel elements when the data matches, and if the data do not match, they are tuned γ-scanner in accordance with the known parameters of certified standard samples - fuel elements according to classes I-IV.

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