RU2184996C1 - Method for metering overlap of telescopic joint in upper loop with graphite column flange of pressure-tube reactor - Google Patents

Abstract

FIELD: fast reactors. SUBSTANCE: telescopic joint is exposed to alternating magnetic field, response signal is picked up and used to determine changes in magnetic reluctance of adjacent sections in telescopic joint; amount of overlap is found by space between these changes; frequency of alternating magnetic field acting on telescopic joint is 50-500 Hz. EFFECT: provision for direct overlap check without extracting and replacing process channel. 2 cl, 2 dwg

Description

 The proposal relates to techniques for operating nuclear power reactors such as RBMK and can be used to monitor the condition of the reactor and graphite masonry.

 The graphite masonry of the RBMK-1000 reactor is under the complex influence of operational factors, the most important of which are elevated temperature and reactor irradiation. As a result of this, graphite blocks undergo irreversible changes in their initial geometric dimensions due to the processes of thermodynamic creep and radiation growth. The nature of the change in the linear dimensions of graphite blocks depending on the neutron irradiation fluence is very complex, although in general terms the radiation-induced shape change of graphite of all grades is the same - this is the shrinkage of the blocks before reaching the critical fluence and their subsequent swelling.

 To assess the performance and confirm the resource of reactors of this type, a series of measurements should be periodically carried out, including the height of the graphite columns. The graphite column of the reactor core with a cylindrical shank of the flange forms a telescopic connection with the upper path of the reactor, which compensates for the linear shape changes of the graphite column during reactor operation. The amount of overlap or engagement of this telescopic connection is strictly regulated and should be 225 mm in the new reactor. With shrinkage of blocks of graphite columns, this value decreases, but should not be less than 80 mm. This is the ultimate state, which indicates the development of a design resource by the reactor. In connection with the above, the amount of overlap of the telescopic connection of the upper path with the graphite column flange should be periodically monitored. However, this control is hampered by the fact that inside the cell of the reactor formed by the upper path and the shank of the graphite column flange there is a process channel, which is the main structural element of the reactor core. To control the amount of overlap of the telescopic connection of the upper duct with the graphite column flange, the process channel is cut out and removed from the reactor by vertical movement. An endoscope or periscope is inserted into the cell from the deck of the central hall and its lens is lowered to the depth of the telescopic connection (see Fig. 1). At the same time, the elevations of the end face of the shank of the graphite column flange and the first inner shoulder on the upper duct pipe are determined and strictly fixed. According to the measurement results determine the size of "B". Since, in accordance with the design documentation for the RBMK-1000 reactor, the distance from the first inner shoulder on the upper path pipe to the lower end of the path is known and is 330 mm (size “B”), the calculated value “B” is subtracted from this value. The difference between these two values: the design size of 330 mm and the calculated value of "B" gives the desired value of "A" overlap of the telescopic connection.

 A known method of controlling the magnitude of the overlap of the telescopic connection of the upper tract with the graphite column flange of a channel nuclear reactor, including determining the elevations of the ends mating in the nodes and the subsequent calculation of the overlap [1].

 The disadvantage of this method is that it is not a direct measurement of the desired value, but indirect.

 In addition, the disadvantage of this method is the need for extraction and subsequent disposal of the technological channel and placing in the cell a new one.

 The purpose of the proposed technical solution is to directly measure the magnitude of the overlap of the telescopic connection without removing the process channel from the reactor cell.

 The goal is achieved due to the fact that in the method of controlling the overlap of the telescopic connection of the upper path with the flange of the graphite column of the RBMK-1000 nuclear reactor, which includes determining the elevations of the ends mating in the connection of the nodes and the subsequent calculation of the overlap, the telescopic connection is exposed to an alternating magnetic field , they pick up the response signal, record the change in the magnitude of the magnetic resistance of the boundary sections of the telescopic connection and the distance th between these changes are judged on the amount of overlap. In this case, it is advisable to influence the telescopic connection with an alternating magnetic field with a frequency of 50-500 Hz.

 A comparative analysis of the claimed technical solution allowed to identify distinctive features, which proves the conformity of the claimed combination of features to the criteria of the invention of "Novelty."

 When searching for analogues and prototype, no technical solutions were found that are similar to the distinguishing features of the proposed solution, which proves the compliance of the claimed combination of features with the criteria of the invention "Inventive step".

 The essence of the proposed method is disclosed in relation to the RBMK-1000 reactor, a fragment of the upper part of the cell of which is shown in Fig. 1 with a previously extracted fuel assembly.

 In FIG. Figure 2 shows the received response signal (D), combined with the schematically shown telescopic connection of the upper path of the reactor with the shank of the graphite column flange (D), the nonius of the immersion depth of the electromagnetic sensor from the mark of the upper end of the path (mark +19.840) (E), and the nonius of measuring overlapping (G).

 The design feature of the RBMK-1000 reactor is that the upper path 1 of the reactor and the shank 2 of the flange 3 of the graphite column 4 are made of pearlitic steel. Technological channel 5 in the area of the telescopic connection is made of austenitic steel grade 08X18H9T, which is not a ferromagnetic material.

 The differential channel 8 of electromagnetic radiation is introduced into the cavity of the technological channel 5 through the steam pipe 6 of the cage 7 of the upper path 1 and lowered by vertical movement to the height of the location of the telescopic connection of the upper path 1 with the flange 3 of the graphite column 4. The telescopic connection is exposed to an alternating magnetic field with a frequency of 50 -500 Hz. In this case, the effect is conducted through the wall of the technological channel 5 without attenuation of the magnetic field. At the same time, the response signal (fragment D of FIG. 2) about the magnitude of the magnetic resistance of the telescopic connection sections is captured and recorded (recorded). Since a structural change in the thickness of the magnetic material takes place at the overlapping boundaries, a sharp change in the magnitude of the magnetic resistance is observed when the magnetic field crosses the boundaries of the telescopic connection, which is recorded by electronic equipment.

 The response of the sensor to a constructive change in the thickness of the magnetic material consists in a change in the amplitude of the pulses, namely, when switching from a thin pipe to a thick one, the amplitude of the pulses decreases, and when the transition goes back, it increases. When an electromagnetic field is applied to sections of pipe structures of a reactor with constant magnetic resistance, i.e. constant thickness, the response signal remains constant and the amplitude of the pulses does not change. In the process of scanning the zone of the telescopic connection, the signal from the sensor is digitized and stored in the computer memory as a file.

 As can be seen from fragments D and E of Fig. 2, the boundaries of the telescopic connection of the upper duct with the graphite column flange are 7525 mm deep from the deck of the reactor hall - this is the depth of the lower end of the duct and 7400 mm is the depth of the upper end of the flange shank. The difference in these values gives an overlap of 125 mm. At the same time, the distance between the peaks of the response signal (fragment D of FIG. 2) on the change in the magnitude of the magnetic resistance of the boundary sections of the telescopic connection along the vernier of fragment F of FIG. 2 is also 125 mm, which indicates a satisfactory amount of overlap and the possibility of further operation of the reactor.

 The above diagram was recorded from a real cell 31-56 of the 2nd power unit of the Kursk NPP and confirms the practical feasibility of the proposed method.

 The magnetic properties of the structures surrounding the sensor change as the sensor passes through the ends, shoulders, ledges, bores of these structures, and sharp changes in the amplitude of the response signal due to changes in the magnetic resistance of these sections are observed at the boundaries of these structural changes in thicknesses.

 It should be noted that the response of the sensor to the presence of a gradient (constructive change in thickness) depends on the distance between the sensor and the magnetic properties that caused the transition to transition, as well as on the presence of materials that shield the electromagnetic field. Therefore, the presence of small steps on the pipes located closer to the sensor can cause a response comparable in amplitude with the response from the boundaries of the telescopic connection. To correctly isolate the signal from such steps, the processing program contains a subroutine for recognizing the waveform, the initial data for which were obtained on bench calibration measurements. Subsequently, a special program for processing the measured data finds the position of the ends of the telescopic connection in the file and, using similar files obtained at the stand for different values of the overlap, calculates the desired overlap of the controlled cell. The sensor for scanning the telescopic connection can be a combined electromagnetic sensor containing two signal, included counter windings and one exciting winding. An alternating sinusoidal voltage with a frequency in the range of 50-500 Hz and an amplitude of 1-10 V is applied to this winding. A signal whose amplitude depends on the gradient of the magnetic properties of the medium near the sensor is induced on the signal windings.

 Thus, the combined implementation of the features of the claimed method of controlling the amount of overlap of the telescopic connection of the upper path to the flange of the graphite column of the RBMK-1000 nuclear reactor allows direct control of the amount of overlap without removing and replacing the process channel.

Sourse of information
1. Regulation of operational control of technological channels, CPS channels and graphite masonry of RBMK-1000 reactors, NIKIET, 1993, inv. E040-2703, p. 7, 8, 10, 18, 19, 23.

Claims (2)

 1. A method of controlling the amount of overlap of the telescopic connection of the upper path with the graphite column flange of a channel nuclear reactor, which includes determining the elevations of the ends of the nodes mating in the connection and then calculating the overlap value, characterized in that the telescopic connection is exposed to an alternating magnetic field, the response signal is captured, and the response signal is fixed according to it, the change in the magnitude of the magnetic resistance of the boundary sections of the telescopic connection and the distance between these changes we judge the amount of overlap.  2. The method according to p. 1, characterized in that the exposure is an alternating magnetic field with a frequency of 50-500 Hz.

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