RU29381U1 - Neutron Measuring Channel - Google Patents

Description

A useful model is the neutron measuring channel (hereinafter referred to as the “SOI”) refers to the technique of measuring ionizing radiation and controlling energy release in nuclear reactors. SOI are used to monitor the state of the active zone of nuclear reactors and relate to the equipment of the in-reactor monitoring system.

KNI is, as I liked, an assembly of direct charging detectors (DNZ) located on the same vertical and structurally interconnected. The SOIs operate in severe operating conditions: high temperature, pressure, intense y- and neutron. In this case, the SOI should have a sufficiently high metrological and reliability characteristics, be small in size and constructively mate with the internal units.

Known SOI, containing a housing with a flange and a sealed penetration, in which there is a protective shield and an assembly of direct charging detectors located on the same vertical and equipped with cables passed through the penetration (V.A. Bragin, I.V. Batenin, M. N. Golovanov et al .; Under the editorship of GL Levin. - Systems for the on-line monitoring of nuclear power plants with VVER reactors. M: Energoatomizdat, 1987, p. 19-22).

A significant drawback of this design is its low metrological and reliability characteristics due to the impossibility of accurately linking the RP to specific coordinates of the reactor core.

The closest technical solution to the claimed utility model is the SOI, comprising a housing with a flange and a sealed penetration, in which there is a beam with fixed on it

direct charging detectors equipped with cables permeated through the penetration (RF Patent No. 2 140 105, on 20.10.1999, IPC G 21 С 17/00, G 01 Т 3/00, Н 01 J 49/00. Assembly of detectors of the in-reactor system control). The traverse is made in the form of a plate, for example, a trough-shaped profile with slots. In the traverse installed DPZ, the cables of which through the slots are led out on the opposite side of the traverse, while the DPZ is fixed to the traverse either by means of a latch attached to the plate with solder, or using clamps. Traverse at the same time combines the functions of a protective shield to protect cables from p-learning.

In this design, the traverse with slots has insufficient rigidity to ensure it is sent to the channel body and to accurately bind the dipole to certain coordinates of the reactor core, which negatively affects the metrological characteristics of the SOI. A significant drawback of the described design is its lack of manufacturability due to the large number of parts and operations used in the manufacture and assembly of structural elements and the South Ossetia as a whole.

The authors of the claimed utility model had the task of increasing the manufacturability of the KPI and its metrological and reliability characteristics.

The task is achieved by the fact that in the neutron measuring channel (KPI), containing a housing with a flange and a tight penetration, in which there is a traverse with direct-charge detectors mounted on it, equipped with cables passed through the penetration, the traverse is made in the form of a pipe with slots and slots located along its generatrix and equipped with a tip made of ferromagnetic material, while direct charging detectors are installed in the traverse opposite these slots, fixed on it and E1 foil cable by means of a zirconium alloy having projections which pass through slots in the crosspiece and is hermetic penetrant

a flange with detector cables hermetically fixed in it with the help of bushes.

The execution of the traverse in the form of a pipe with slots and slots located along its generatrix allows the installation of DPZ, cables, their elements and assembly of the SOI as a whole with fewer cable bends, excluding cable fastening between the DPZ, and fewer fasteners. The traverse of this design has greater rigidity and protects the cables and DPZ from damage when they are installed in the channel body, providing a more accurate coordinate reference to the location of the DPZ in the KPI body, and subsequently in the reactor core.

The installation of a tip made of ferromagnetic material on the crosshead allows you to carry out technological control of the accuracy of the location of the crosshead with DPZ in the SOI housing during the manufacturing process, for example, by the eddy current method. At the same time, the gap between the tip of the crosshead and the inner end surface of the KPI housing is precisely fixed, thereby, if necessary, it is possible to reinstall the crosshead in the housing until an acceptable clearance is obtained.

DPS fastening in the slots of the crosshead is carried out using a zirconium alloy foil, which simultaneously serves as a protective E1fan of cables from p-radiation of the DPS. At the same time, the number of fasteners is protected and technological soldering operations are excluded. The use of zirconium foil as a protective shield material allows decreasing the thickness of the shield, preserving its protective properties, and to ensure the total cross-sectional dimensions of the overcurrent protection shield, protective shield, and cables in the crosshead volume. Thereby, the manufacturability of the SOI assembly as a whole and its reliability are increased.

to improve the reliability characteristics of the SOI by increasing the radiation and thermal resistance of the hermetic connection of the elements of penetration and cables. In addition, this design of penetration allows for individual control of the tightness of all joints of the penetration during the manufacturing process, allowing the elimination of possible technological defects of individual elements of penetration. Improving the manufacturability and reliability of hermetic penetration ensures the maintenance of the required level of sealing of the SOI during operation, while maintaining the mass of gas filler, for example, helium, in the internal volume of the SOI, necessary for heat exchange processes between structural elements. At the same time, the metrological characteristics of the SOI are kept within specified limits throughout the entire life of the device. The proposed design of hermetic penetration is characterized by greater reliability as a second barrier to the coolant of the primary circuit of the reactor installation.

In FIG. 1 is a schematic representation of the SOI. In FIG. 2 shows the shape of a zirconium foil. In FIG. Figure 3 shows the cross section of the SOI in the area of attachment of the DPZ to the traverse. In FIG. 4 shows an enlarged cross section of an airtight penetration.

The neutron measuring channel contains a housing consisting of three parts 1, 2, and 3 (see Fig. 1), in which a crosshead 4 with direct charge detectors (DPS) mounted on it is placed 5. DPS 5 are equipped with cables 6 passed through the penetration 7. Slots 8 and slots 9 are made along the generatrix of the traverse 4 in the places where the DPZ 5 is installed. The traverse 4 is equipped with a ferromagnetic tip 10. The DPZ 5 is secured to the crosshead 4 and shielded from the cables 6 by means of a zirconium alloy foil 11 with protrusions 12 (see Fig. 2). By choosing the material of the zirconium alloy foil, the thickness of the protective shield is reduced. In this case, the protrusions 12 of the foil 11 are passed through the slots 9. The protrusions 12 make it possible to tighten the installation of the DPZ 5 to the traverse 4, fixing the DPZ 5 and freeing up space

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inside the crosshead 4 for cables 6 (see Fig. 3). The tight groove 7 (see Fig. 4) is made in the form of a flange 13, in which cables 6 of the DPZ 5 are sealed with the help of the bushings 14. The leads of the cables 6 of the DPZ 5 are connected to an electrical connector 15 located in part 3 of the SOI housing.

SOI is made as follows.

The housing of the SOI consists of three parts 1, 2 and 3 (see Fig. 1). Part 1 of the housing with a flange is designed to accommodate the beam 4 with direct charging detectors (DPZ) 5. Part 2 of the housing is designed to connect the beam 4 with the housing. Part 3 of the housing contains an electrical connector 15 for outputting cables 6 to the measuring unit (not shown in FIG.). All parts 1, 2 and 3 of the housing are connected to each other by welding and are made of corrosion-resistant and radiation-resistant material, for example, stainless steel grade 08X18H10T. The length of the SOI casing is usually 84-12 m, and the outer diameter of the in-reactor part of the casing is about 10 mm with a wall thickness of 0.84-1 mm.

Traverse 4, on which DNZ 5 is placed, is a pipe with a length exceeding the total length of the detectors and a thickness of 0.2-f 0.5 mm and is made of stainless steel. Slots 8 were made in the pipe for mounting detectors 5 by their number, as well as slots 9 for mounting detectors with zirconium foil 11, four slots for each detector.

DPZ 5 with cables 6 are placed opposite the slots 8 in the traverse 4 with an accuracy of 1 mm along its length. Cables extend along the length of the beam. Zirconium foil 11 with a thickness of 0.24-0.3 mm has a length exceeding the length of the detector and pffina overlapping the detector after it is fixed, for example, 120 mm and 6 mm, respectively. The foil 11 separates the detectors 5 from the cables 6 (with the exception of the traverse 4 closest to the ferromagnetic tip 10). Foil 11 has

a rectangular shape and a quadruple protrusion 12, two with each length of the side (see Fig. 2). In traverse 4, in the area of the slots 8, a gap 9 is made even for protrusions 12 of foil 11. When the detectors 5 are fastened with foil 11 to the traverse 4, its protrusions 12 are passed into the gap 9 flush with the surface of the traverse on its outer side and attached to it, for example, by welding. Cables 6 from neighboring DPZ 5 extending over zirconium foil 11 are fixed on it by pressing the edges of the rectangular slot 8 of the crosshead 4 (as shown in Fig. 3). Then, a tip 10 of ferromagnetic material, for example, of steel 20X13, is attached to the cable-free end of the beam 4 by welding.

To secure the cables 6 of the DPZ 5 in the sealed penetration 7 to the cables 6, stainless steel sleeves 14 (see Fig. 4) are tightly connected to the cables 6 by laser welding at the passage of a particular cable. Through the penetration 7. Then, the laser welded sleeves 14 are tightly connected to flange 13. Flange 13 is a washer made of steel 08X18P10T with a diameter of 20 mm and a thickness of 5 mm with holes for fixing the bushings 14 with cables 6.

The assembly thus obtained, consisting of a traverse 4 with a tip 10 and with a DPZ 5 fixed on it with cables 6 and from a sealed penetration 7, is subjected to a leak test. If necessary, defects are corrected for welded joints. After this, the specified node and part 2 of the housing are pushed into part 1 of the housing until the tip 10 is in contact with the inner end of part 1 of the housing, the position of the ferromagnetic tip 10 of the beam 4 in part 1 of the housing is edged by current, and these elements are connected to each other and to part 1 of the housing followed by a leak test. Then the internal cavity of the structure is filled with helium at a pressure of 12 atm.

After that, the soldering of the leads of the cables 6 DPZ 5, emerging from the hermetic penetration 7, to the electrical connector 15 mounted on part 3 of the housing, which is then connected to part 2,

forming a single design of the SOI. After that, a full range of acceptance tests is carried out.

After the SOI is placed in the reactor vessel, the SOI landing surfaces are compacted in the reactor vessel and the electrical connectors are connected to the cable loops, which in turn are connected to the measuring equipment. When the reactor reaches its power under the influence of the neutron flux, the DGO produces a current electric signal proportional to the neutron flux density.

Compared with the well-known SOIs, the declared 1SNI is characterized by increased manufacturability and higher metrological and reliability characteristics due to a decrease in the number of elements and operations used in the assembly and installation of SOIs, due to the greater rigidity of the crosshead, which ensures its passage into the channel body, accurate binding of DNZ to certain coordinates of the reactor core, as well as due to the possibility of providing step-by-step technological control at all stages of production of SOI.

Due to the improved manufacturability of the claimed detector in comparison with the prototype has a lower manufacturing cost by more than 20%. The rejection of the claimed detectors after manufacture before the stage of placement in the measuring channel of the reactor installation decreased by more than 10% in comparison with the prototype.

FSUE NII NPO Luch experimental batches of declared DPZ were developed, designed and manufactured in accordance with GOST R 15.201-2000 SR1Sh Production for industrial purposes. The procedure for the development and putting products into production and OST 95 332-93 “Products of nuclear instrumentation and radiation technology. Acceptance rules.

1. Acceptance tests of manufactured neutron measuring channels and their components (DPZ, cable) in the amount of:

1.1.

1.1.1. Control of overall, installation and connecting dimensions, appearance and marking.

1.1.2. Control of the electrical insulation resistance (Keys) at a temperature of (25 ± 10) ° C between the terminals of the DCS and between the terminals of the DCS and the housing, Keys not less.

1.1.3. Control of electrical insulation resistance (Ksh) at a temperature of (350-30) ° C between the terminals of the DPZ and between the terminals of the DPZ and the housing, Keys not less.

1.1.4. Monitoring of the electric capacitance (C) at a temperature of (25 ± 10) ° C between the terminals of the remote sensing device and between the terminals of the remote sensing device and the housing, actual values.

1.1.5. Control of tightness, leakage on helium no more than 6.65-10.

1.2 Cable

1.2.1. Control of overall, installation and connecting dimensions, appearance and marking.

1.2.2. Control of electrical installation and the integrity of electrical circuits.

1.2.3. Monitoring of electrical insulation resistance (Keys) at a temperature of (25 ± 10) C between the contacts of the electrical connectors and between the contacts of the electrical connectors and screens, Keys not less.

1.2.4. Monitoring of electrical capacitance (C) between the contacts of electrical connectors and screens, actual values.

1.2.5. Control of tightness of the cable sheath, leakage on helium not more than 6.65-10 m1Pa / s.

2L. DPZ.

2.1.1. Control of electrical insulation resistance and capacitance in accordance with paragraphs. 1.1.2, 1.1.3,1.1.4.

2.1.2. Resistance to bending of a part of DPZ with a diameter of 7.5 mm (bending radius 1000 mm, bending angle - 30), the number of bends - at least 15, with subsequent control of electrical parameters according to paragraph 2.1.1.

2.1.3. Control of tightness

At a temperature of (25 ± 10) ° С, insulation resistance Кш is not less than, leakage through helium is not more than 6.65-10 m.Pa / s.

2.1.4. The control of the leak tightness at the temperature (350-30) ° С, leakage on helium no more than 6.65-10 m.Pa / s.

2.1.5. Control of the leak tightness at the temperature of (150 ± 10) C, leakage through helium no more than 6.65-10 m.Pa / s.

2.1.6. Tests on the stability of the injection chamber to an external pressure of 24 MPa at (25 ± 10) C, insulation resistance after exposure to pressure not less.

2.1.7. Tests for sensitivity to thermal neutron flux (conversion coefficient 3.0-10 ± 2% Cl.m neutron), spread of sensitivity to thermal neutron flux (no more than ± 1%), error in determining the absolute sensitivity of the remotely sensed to linear energy release (not more than 5% with a confidence level of 0.95) and the effectiveness of zirconium screens.

2.1.8. Tests on the resistance of the overpressure to the effects of temperature (350-30) ° С, insulation resistance at the test temperature Кш not less.

2.1.9. Functioning of the tightness control sensor, insulation resistance when installed in the neutron-measuring channel at least, when immersed in water.

2.2.1. Tests for resistance to bending of the cable (bending radius 150 mm 10 bends). Checking the integrity of electrical circuits and resistance pop. 1.2.3.

2.1.2. Tests for noise immunity according to the methodology and equipment of the RRC “Kurchatov Institute.

2.3. Neutron measuring channel.

2.3.1. Tests for resistance to mechanical (vibration) influences and seismic resistance, vibration resistance according to GOST 30630.1.2-99 method 103-1.1, seismic resistance according to GOST 17516.1-90 - fixed frequency method. During testing, control of electrical parameters according to paragraph 1.1.2. and 1.1.4., at the end of the tests in paragraphs. 1.1.2,1.1.3,1.1.4.

2.3.2 Control of the appearance and overall dimensions of the total dimensions of the neutron measuring channel and its components.

The test results are positive. It has been established that the claimed neutron-measuring channel corresponds to its functional purpose: measuring ionizing radiation and controlling energy release in nuclear reactors. The claimed neutron measuring channel exceeds the known analogues and prototype in terms of manufacturability and higher metrological and reliability characteristics.

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Claims (1)

A neutron measuring channel, comprising a housing with a flange and a tight penetration, in which a crosshead is located with direct charge detectors attached to it, equipped with cables passed through the penetration, characterized in that the crosshead is made in the form of a pipe with slots and slots located along its generatrix , and is equipped with a tip made of ferromagnetic material, while the direct charging detectors are installed in the traverse opposite to the specified slots, are mounted on it and shielded from the cables using foil made of zirconium alloy having protrusions that are passed through slots in the traverse, and the hermetic penetration is a flange with the detector cables hermetically fixed in it with the help of bushes.