RU2610913C1 - Nuclear reactor fuel assembly - Google Patents

Abstract

FIELD: atomic power engineering.

SUBSTANCE: invention relates to atomic power engineering, namely, to fuel assemblies (FA) of VVER type nuclear reactors (VVER-440, VVER-1000, etc.). FA is equipped with an anti debris-filter (ADF) installed in the FA shanks. FA ADF consists of two plate-type filter elements arranged in a shank above each other, containing two groups of intercrossed straight plates forming along the fuel assembly axis a row of curvilinear channels of rectangular cross section for the heat carrier passage. Herewith the channels of the lower filter element are arranged at an angle to the FA longitudinal axis, while the channels of the upper filter element located between the lower filter element and the bearing grate are parallel to the FA axis.

EFFECT: technical result is increased efficiency of trapping debris-objects in the form of straight rods and flat objects of any length and low thickness.

4 cl, 6 dwg

Description

The invention relates to nuclear energy, and in particular to fuel assemblies (FA) of VVER-type nuclear reactors (VVER-440, VVER-1000, etc.)

The prior art design of the fuel assemblies of nuclear reactors VVER-440, VVER-1000 (see Kirillov P.L. et al. Handbook of thermohydraulic calculations (nuclear reactors, heat exchangers, steam generators). M.: Energoatomizdat, 1990, Fig. P. 8.1, A.8.3 and A.8.5, p. 317-319), the fuel assembly of which consists of a bundle of fuel rods 1, mounted in a bearing lower grating (HP) 7 and interconnected by spacer grids (DR) 2, mounted on a central pipe 9 In TVSA VVER-1000 DR are also attached to the corners 3, attached by screws 6 to the shank 4. In TVS-2M DR are attached to the guide rails Alam (TC). In all designs of fuel assemblies, there is a head 5 for providing loading and unloading of fuel assemblies.

The prior art working cassette (RC) of a VVER-440 nuclear reactor, whose HP is hexagonal, has 126 round holes for installing fuel rods, a central hole for installing a central pipe, 102 holes in the form of a "dumbbell" for the coolant duct, 12 holes with a diameter of 5 , 9 mm and half-holes along the contour of the support grid for the flow of coolant. Holes of the "dumbbell" type are formed by two holes with a radius of 2.95 mm, connected by a hole with a width of 5 mm. The holes for the installation of the fuel rods and the central pipe have a diameter of 5 ^+0.1 , and along the contour of each face of the hexagonal HP there are seven holes for the bottom plugs of the fuel rods (see Dementiev B.D. Nuclear Power Reactors. M .: Energoatomizdat, 1990, p. 31 -35). HP RK-3 VVER-440 has an additional round hole for the installation of supporting pipes (NT).

The VVER-1000 TVS support grid has a similar design, which additionally has round openings for mounting the NK.

Functionally, HP is a load-bearing power element that holds a bunch of fuel rods in stationary mode and during transport and technological operations (TTO), and in VVER-1000 fuel assemblies it also provides loading and unloading of fuel assemblies using NK.

A significant drawback of the known HP is the ability to pass large debris objects with a flow of coolant. For example, the large width and length of the core openings of a standard HP allows cylindrical debris objects with a diameter of up to 6.3 mm and flat with a width of up to 13.4 mm and a thickness of up to 5.2 mm to be passed into the bundle of fuel elements. HP with round pouring holes and daisy type HP for TVS-2M also do not have the required anti-debris properties and pass long cylindrical debris objects up to the transverse dimensions of 7.18 mm and 6.63 mm, respectively.

Experimental studies have shown that existing HP designs have a retention efficiency of arbitrary debris objects of 50 ... 60%, which, as practice has shown, is not enough, because depressurization of the cladding of fuel rods for this reason is ~ 56% of the total number of failures.

In this regard, it became necessary to equip the fuel assemblies with anti-debris filters (ADPs) installed in the shanks at the entrance to the fuel assemblies. Currently, all VVER-440 RCs and VVER-1000 fuel assemblies have ADP.

In the TVS-2M project for VVER-1000, an ADP was developed consisting of perforated plates of a triangular shape. The known design of the ADF TVS-2M is assembled from 12 such plates installed at a certain angle to each other, with the help of additional ribs in a complex spatial structure, while the large length of the welds reduces the reliability of the welded joints.

There were also proposals to equip regular HP with additional rods of wire 1.5 ... 2 mm welded to the bottom surface of the HP in the area of the pouring holes, which is practically impossible to realize in mass production.

These ADP designs were investigated at ENITs OJSC and the research results were presented at the 7th ISTC “Safety, Efficiency and Economics of Nuclear Energy”, Moscow, May 26-27, 2010 in the report “Experimental Study of the Efficiency of Anti-Debris Filters of VVER-Cassettes” 1000. "

Comparative studies of various ADP designs carried out by ENITS OJSC showed that the retention efficiency of debris objects for TVS-2M ADP is 77.9%, and for TVSA ADP - 79.1%, i.e. increases to almost 80%.

At the same time, however, the pressure drop of the coolant at the inlet section of the fuel assembly increases by 1.45 ... 1.65 times compared to the pressure drop on HP.

A disadvantage of the known structures is that they cannot be manufactured by machining, since they have narrow slits, 2 mm wide, and rather thin jumpers between them.

The closest analogue of the proposed fuel assembly is the known fuel assembly of a nuclear reactor (fuel assembly VVER-1000), containing a bunch of fuel rods and NK 8, mounted in HP 7 and interconnected DR 2, mounted on the Central pipe 9 and corners 3, with ADP installed in the shank 4, which is a densely perforated flat plate with holes of the form "chevron", a width of 2 mm (RU 2264666, publ. 20.11.2005).

The disadvantages of this ADP are: small, 0.3 ... 0.6 mm, the thickness of the jumpers between the holes with a plate thickness of 6 ... 8 mm and significant hydraulic resistance.

The main disadvantage of all existing ADP designs is the high complexity of manufacturing.

The manufacture of well-known ADPs both by electro-erosion method and by means of waterjet cutting leads to great labor costs.

Moreover, the well-known ADP designs with their rather high efficiency with respect to curved debris objects are practically not effective against debris objects in the form of straight rods and flat objects of large width of any length having a thickness of less than 2 mm.

The technical result of the invention is to increase the reliability and availability of fuel assemblies of the WWER type while reducing the complexity of its manufacture.

This technical result is achieved by the fact that in a fuel assembly of a nuclear reactor containing a bunch of fuel rods fixed in a carrier grid and interconnected by spacer grids mounted on a central pipe or guide channels, and a filter for trapping foreign objects, installed in the fuel assembly shank, characterized in that the filter consists of two plate-type filtering elements located in the shank one above the other, containing two groups of 10-11 intersecting rectilinear plates interconnected by grooves in the groove and forming along the axis of the fuel assembly a series of curved channels for the passage of the coolant, a rectangular cross-section, the channels 14 of the lower filter element 13 are located at an angle to the longitudinal axis of the fuel assembly, and the channels 15 of the upper filter element 12 located between the lower filter element and HP are parallel to the axis of the fuel assembly.

ADP is installed inside the shank in an annular groove and is fixed in the axial direction using a ring connected by welding with the shank in several places.

The cross section of the channels for the passage of the coolant in the form of a rectangle has a height of not more than 2 mm and a width of 7 ... 10 mm.

The channel profile when arranged in rows in the axial direction has the shape of a broken line. In this case, the angle of inclination of the straight lines of the lower filter element is 15 ° ... 25 ° with respect to the axis of the fuel assembly to ensure the minimum hydraulic resistance of the proposed NRF with a filter element thickness of 8 ... 10 mm

The upper filter element has channels parallel to the axis of the fuel assembly, which provides filtering of rectilinear debris-objects that enter into the channels of the lower filter element with rotation.

Moreover, such an arrangement of channels in the upper filter element leads to the direction of coolant flow at the outlet of the ADP parallel to the axis of the fuel assembly, which helps to reduce the CGS, vibration and hydraulic loads in the lower part of the fuel assembly, the bundle of fuel rods and fuel rods.

The thickness of the plates of the ADF elements is 0.5 ... 1.0 mm.

The proposed ADF is made of stainless steel type X18H10T using modern digital high-performance gas laser cutting technology, mastered in serial production.

The pour section of the proposed ADP should preferably be no less than that of the standard HP.

The invention is illustrated by drawings.

In FIG. 1 shows the proposed fuel assembly.

In FIG. 2 shows the upper filter element of the proposed fuel assembly.

In FIG. 3 shows the lower filter element of the proposed fuel assembly.

In FIG. 4 shows an enlarged fragment of the filter of the proposed fuel assembly.

In FIG. 5 shows plates with upper slots of which the filter of the proposed fuel assembly consists.

In FIG. 6 shows plates with lower slots of which the filter of the proposed fuel assembly consists.

The filtering elements consist of two types of plates: plates 10 with lower slots 16 parallel to the axis of the fuel assembly, and plates 11 inclined to a certain angle with upper slots 17, forming channels 14-15 for the coolant duct.

Claims (4)

1. A fuel assembly of a nuclear reactor containing a bunch of fuel rods fixed in a carrier grid and interconnected by spacer grids mounted on a central pipe or guide channels, and a filter for trapping foreign objects installed in the fuel assembly shank, characterized in that the filter consists of two plate-type filtering elements located in the shank one above the other, containing two groups of intersecting rectilinear plates, forming along the axis of the fuel assembly a series of cr of rectangular channel cross-sectional channels for the passage of coolant, while the channels of the lower filter element are located at an angle to the longitudinal axis of the fuel assembly, and the channels of the upper filter element located between the lower filter element and the carrier grill are parallel to the axis of the fuel assembly. 2. The fuel assembly of a nuclear reactor according to claim 1, characterized in that the rectangular channels for the passage of the coolant have a height of not more than 2 mm with a width of 7 ... 10 mm. 3. The fuel assembly of a nuclear reactor according to claim 1, characterized in that in the lower filter element with a thickness of more than 8 mm, the channels are located at an angle of 15 ° ... 25 ° with respect to the longitudinal axis of the fuel assembly. 4. The fuel assembly of a nuclear reactor according to claim 1, characterized in that the filter elements are made of stainless steel type X18H10T using gas laser cutting.

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