RU94043U1 - SUPPORT GRILLE FOR FUEL ASSEMBLY OF THE NUCLEAR REACTOR - Google Patents

Abstract

1. Support grid for the fuel assembly of a nuclear reactor, made in the form of a perforated plate with round holes arranged along a triangular grid, at least part of which is intended for installing fuel rod ends in them, and with holes for the passage of the coolant, characterized in that each hole for the passage of the coolant is formed by three arcs of circles of radius R, concentric, respectively, to three adjacent round holes and conjugate arcs of circles, the radius of which is in the range from S / 2 - R to S / 30.5 - R, where S is the distance between the centers of the circular holes, while the holes for the passage of the coolant are evenly spaced three pieces around the round holes. ! 2. Support grid according to claim 1, characterized in that part of the circular holes is designed to accommodate guide channels or support pipes. ! 3. The support grid of claim 1, wherein the central circular opening is intended to receive the central tube. ! 4. Support grid according to claim 1, characterized in that it is made by casting, or laser cutting, or water-jet cutting, or drilling.

Description

The utility model relates to nuclear energy, namely, elements of fuel assemblies (fuel assemblies) used mainly for VVER-440 and VVER-1000 reactors.

The VVER-440 support lattice is known from the prior art, for example, 445.20.030-04, which has 102 holes in the form of a “dumbbell” for the heat carrier flow, 12 holes with a diameter of 5.9 min and 24 half-holes along the contour of the support lattice for the heat carrier flow. Holes of the “dumbbell" type are formed by two holes with a radius of 2.95 min, connected by a hole with a width of 5 min. 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 support grid 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) [1]. In the support grid of RK-3 VVER-440, part of the holes for the fuel rods are used to install the supporting pipes.

The disadvantage of this lattice is the resulting anisotropy of the design of the support lattice, caused by the shape and location of the holes for the coolant duct relative to the longitudinal axis of the fuel rods (fuel elements), reducing its strength and rigidity; a significant difference in the configuration of the holes for the coolant passage from the unit cell of the fuel rod bundle, their asymmetric arrangement relative to the axis of the fuel rod, causing a disturbance in the coolant flow when it leaves the support grid into the space between the fuel rods; the use of low-performance milling technology to make holes for the coolant duct.

The prior art support grid for a fuel assembly of a nuclear reactor, made in the form of a perforated plate having round holes, at least part of which is designed to install the tips of the fuel rods, and holes designed to pass the coolant, having the shape of a hexagon, each of three sides of which facing the same holes are parallel to the line connecting the centers of adjacent cylindrical holes, and each of the three other sides facing the cylindrical holes pits formed by a circular arc concentric with the adjacent round opening, the coolant passage holes uniformly disposed around the cylindrical openings (see. RU 2308775 C1, publ. 20.10.2007 [2]).

The disadvantages of the analogue are the complex shape of the holes for the coolant duct and the small thickness of the jumpers between these holes, which causes difficulties in its manufacture using high-performance casting, laser and water-jet cutting technologies.

The closest analogue to the proposed utility model is the fuel assembly support grill, in which the openings for the coolant flow are round or triangular with rounded corners, symmetrically relative to round openings for the lower plugs of the fuel rods and tubular channels in the amount of six pieces around each of them, while on the periphery of each face of the hexagonal lower support grid, there are eleven holes for the lower plugs of the fuel elements forming perpendicular to otivopolozhnoy face hexagonal bottom support grid parallel rows of alternating between a lower holes for the plugs of the fuel elements and coupled via jumper base circular holes or openings of triangular with rounded corners for the coolant flow (see. RU 2248050 C2, publ. 10.03.2005 [3]). This support lattice has a more uniform distribution of the stress-strain state (SSS) in comparison with the known one from [1], which has significant anisotropy.

However, the manufacturability of this grate is very low, because due to the even smaller thickness of the jumpers between the holes than in the support grid [2], it can be performed only by milling and does not allow the use of high-performance casting, laser and water-jet cutting technologies for this reason.

The objective of this utility model is to create a high-tech support lattice, which, by changing the shape and location of the holes for the coolant passage, has a sufficiently high strength and stiffness with the possibility of manufacturing it both according to existing technology and using high-performance casting, laser, and water-jet cutting technologies.

The problem is solved in that the support lattice for the fuel assembly of the nuclear reactor is made in the form of a perforated plate with round holes located on a triangular grid, at least some of which are designed to install the tips of the fuel rods, and with holes for the passage of coolant, each of which are formed by three arcs of circles of radius R, concentric to three adjacent circular holes and conjugate arcs of circles whose radius is in the range S / 2 - R to S / 3 ^0.5 - R, where S is the distance I wait for the centers of the round holes, while the holes for the passage of the coolant are evenly arranged in three pieces around the round holes. Part of the round holes is designed to accommodate the guide channels or supporting pipes, and the central round hole is designed to accommodate the central pipe.

In the proposed lattice, due to the shape and arrangement of the holes, the number of jumpers decreases, and the thickness of the jumpers increases and exceeds the thickness of the jumpers of the closest analogue by more than 2 times, which provides it with sufficient strength and rigidity, as well as the possibility of manufacturing it as in the existing technology while maintaining technological tolerances, and using high-performance technologies of casting, laser and water-jet cutting.

The utility model is illustrated by drawings, where figure 1 shows the proposed support lattice, and figure 2 an enlarged fragment of the Central part of the lattice.

The support lattice for the fuel assembly of a nuclear reactor is made, for example, by casting in the form of a hexagonal perforated plate 1, in which there are round holes 2 and 3 located on a triangular grid, and holes 4 for the passage of coolant.

One part of the round holes is designed to install the tips of the fuel rods, and the other part of the round holes is designed to accommodate the guide channels or supporting pipes. The central circular hole 2 is designed to accommodate a central support pipe.

The openings 4 for the coolant passage are uniformly arranged in three pieces around round holes 2, 3, and each of them is formed by three arcs of circles of radius R, concentric three adjacent circular holes 3 and conjugate arcs 5 of circles whose radius is in the range from S / 2 - R to S / 3 ^0.5 - R, where S is the distance between the centers of the round holes.

To analyze the dynamic characteristics of the structure, we used the method of shock excitation, which allows us to simultaneously obtain the frequency spectra of the external influence (force) and response (acceleration) of the product points from the applied force. The oscillations created upon impact are a short-term process of energy transfer. The spectrum of the impact force is continuous, with a maximum amplitude at 0 Hz and its subsequent decrease with increasing frequency. This allows for simultaneous excitation of the structure in the entire frequency range (depending on the characteristics of the hammer hammer).

The results of tests and calculations of natural frequencies of oscillations and stiffness ratios are given in the table.

The table shows that the proposed support lattice in terms of stiffness is inferior to the lattice [2], and therefore to a close analogue [3], but it has sufficient rigidity and strength compared to the lattice [1], which has long been used in serial production.

Table Dynamic test Payment Natural frequency, Hz Stiffness ratio Natural frequency, Hz Stiffness ratio Known Lattice [1] 1932.0 one 1968.0 one Known Lattice [2] 2475.0 1.84 2518.9 1.84 Suggested grid - - 2,503.3 1.82

Claims (4)

1. The support grid for the fuel assembly of a nuclear reactor, made in the form of a perforated plate with round holes located on a triangular grid, at least some of which is designed to install the tips of the fuel rods, and with holes for the passage of coolant, characterized in that each hole for the coolant passage is formed by three arcs of circles of radius R, concentric respectively to three adjacent circular holes and conjugate arcs of circles whose radius is in Range of S / 2 - R to S / 3 ^0,5 - R, where S - the distance between the centers of circular holes, with openings for the passage of coolant are arranged uniformly around the three pieces of round holes. 2. The support grid according to claim 1, characterized in that the part of the round holes is designed to accommodate guide channels or supporting pipes. 3. The support grid according to claim 1, characterized in that the central circular hole is designed to accommodate the central pipe. 4. The support grid according to claim 1, characterized in that it is made by casting, or laser cutting, or water-jet cutting, or drilling.