RU2163036C2 - Nuclear reactor fuel assembly - Google Patents

Abstract

FIELD: nuclear reactors. SUBSTANCE: each component of spacer grid rim has one of its ends provided with lip of height equal to rim width; other end of rim is placed on this lip and secured by spot welding in overlapping manner; mating joint between rim components is smaller in width than channel between peripheral cells and rim and its lip is arranged in one of them; each edge of rim is provided in top and bottom parts with coolant baffle plates arranged over entire length from periphery to center at angle of 15-30 deg. Baffle plates are made in the form of lugs and placed between fuel elements over peripheral row. Reliable joint is provided between rim components; reactor incorporates provision for equalizing coolant heat transfer. EFFECT: improved reliability of fuel assemblies and operating efficiency of reactor. 2 cl, 5 dwg

Description

 The invention relates to nuclear energy and can be used in enterprises engaged in the manufacture of fuel assemblies (FAs), mainly for nuclear power reactors of the WWER-1000 type.

 Known fuel assemblies of a nuclear reactor, including a bunch of fuel elements (fuel elements) installed vertically in a frame assembled from spacer grids mounted on tubular channels, a shank and a removable head (see US patent N 4687619, CL G 21 C 19/20, 1987 year). A disadvantage of the known fuel assembly is the low level of manufacturability of the design of its head, characterized by increased laboriousness of the operations of assembling and repairing the bundle of fuel elements, mounting and dismounting of the head itself.

 Known fuel assemblies of a nuclear reactor, including a bunch of fuel rods mounted vertically in a frame assembled from spacer grids mounted on tubular channels, a shank and a removable head (see German application N 2845515, class G 21 C 3/04, 1979). A disadvantage of the known fuel assemblies is the low level of manufacturability of the design of the head and the low reliability of the connection, ensuring its removability.

 Known fuel assemblies of a VVER-1000 nuclear reactor, including a bunch of fuel rods installed in a frame of spacer grids mounted on tubular channels, a shank and a removable head, where each spacer grid is assembled from separate shaped cells welded together at points and fastened to the outside by a rim, each the cell is equipped with internal protrusions, firmly tightening to fix the fuel rods passed through the cells and forming channels for passing the coolant between the fuel rods and the cell walls, between the cells and between the periphery cells and rim (see the book by B. A. Dementyev. Nuclear Power Reactors. M., Energoatomizdat, 1990, p. 44, Fig. 2.13 of the fuel assemblies of the VVER-1000 reactor). A disadvantage of the known fuel assemblies are the same disadvantages as for fuel assemblies according to US patent N 4687619 and German application N 2845515.

 The closest in technical essence and the achieved effect is a fuel assembly of a nuclear reactor, including a bunch of fuel rods mounted vertically in a frame of spacer grids mounted on tubular channels, a shank and a removable head, where each spacer grid is assembled from separate figured cells welded together at points and fastened on the outside by a rim, each cell is equipped with internal protrusions firmly with an interference fit fixing the fuel rods passed through the cells and forming channels for the passage of heat of Tell between the fuel rods and the walls of the cells, between cells and between cells and the peripheral rim (See. Patent RU N 2124238 of Russian Federation application 97108408 of 05/20/97 N, at cl. 6 G 21 C 3/30, 3/34).

 FAs of Patent 2124238 of the Russian Federation eliminate the disadvantages of known FAs, but at the same time FAs of Patent 2124238 and known FAs have disadvantages in terms of uneven heat transfer in a nuclear reactor and unreliable design of the rim of spacer grids.

 It is known that at present there is a widespread introduction of spacer grids of zirconium alloys, promising in mechanical properties, radiation growth, and relaxation characteristics to increase energy production (see Nuclear Technology Abroad, 1990, N 4, p. 3-5) during the manufacturing process of which they set and spot weld curly cells from a zirconium alloy with each other to form a field of curly cells, enter the typed field of curly cells into a hexagonal rim from a zirconium alloy and fix it (see Development a, production and operation of fuel elements of power reactors (Book 1, edited by F.G. Reshetnikov, Energoatomizdat, 1995, p. 187).

 The manufacture of a hexagonal rim from a zirconium alloy is carried out according to the known technology from components by means of their argon-arc welding in a controlled argon medium in a chamber that has undergone preliminary evacuation to prevent oxidation of zirconium during welding.

 According to the requirements for the fuel assemblies in terms of geometric dimensions, the spacer grid must be turnkey (see Design, Production, and Operation of Fuel Rods for Power Reactors, Book 1 edited by F. G. Reshetnikov, Energoatomizdat, 1995, p. 154), however because of the welds of argon-arc welding of the components of the rim, the spacing grid after welding does not meet these requirements and it is necessary to clean the welds to the level of the faces of the rim. Mechanical cleaning of the welds of the rim of the spacer grid will lead to abrasion of the zirconium alloy of the rim, the appearance of corrosive corrosion resulting from abrasion even in the absence of a corrosive medium (see Zirconium metallurgy. Translation from English. Edited by G.A. Meerson and Yu.V. Gagarinsky . Publishing house of foreign literature, M., 1959, p. 298), which does not exclude the destruction of the rim, respectively, of the spacer grids of the fuel assembly as a whole in a nuclear reactor. Tests conducted under conditions similar to those of a nuclear reactor showed the presence of traces of corrosive corrosion in the weld area of the spacer rim.

 The channels for the coolant flow in the nuclear reactor, formed by internal protrusions, between the cell wall and the fuel element, between adjacent cells and between the peripheral cells and the rim are parallel to each other and the fuel assembly axis and create a laminar coolant flow both in the zone of intense heat generation and in the zone of lesser heat heat release, which does not contribute to uniform heat removal, since the density of the neutron flux in the reactor is maximum in the center and decreases to the periphery. Since the energy release is due to the fission of the nuclei of the fuel substance in a neutron field, the heat release in the center is higher and decreases to the periphery (see A.S. Zaimovsky, V.V. Kalashnikov, I.S. Golovnin. Heat-generating elements of atomic reactors, Gosatomizdat, M ., 1962, p. 337). Accordingly, we can consider a single fuel assembly, in which intense heat is released in the center and decreases to the periphery. Naturally, the heat removal of fuel assemblies is also uneven.

 The energy release in the center is about three times higher than the average for the core. In the same ratio are specific heat loads. Any alignment of heat removal, even incomplete, gives a significant economic effect of removing more power from the reactor, ceteris paribus, which is especially important for power reactors (see B. A. Dementyev. Nuclear power reactors, M., 1990, Energoatomizdat, p. 147). An object of the invention is to increase the reliability of fuel assemblies by increasing the reliability of fastening to each other the components of the rim of the spacer grid during the manufacturing process and the efficiency of the reactor by aligning the heat transfer with the coolant.

This technical problem is solved in that in the fuel assembly of a nuclear water-water power reactor, including a bunch of fuel elements mounted vertically in a frame of spacer grids mounted on tubular channels, a shank and a removable head, where each spacer grid is assembled from separate figured cells, welded together at points fastened on the outside, made of rim made of component parts, and forming channels for the passage of the coolant between the fuel element ntami and cell walls, between cells and between peripheral cells and the rim;
according to the invention, at each of the rim components, one end is provided with a threshold with a height equal to the rim thickness, the other end of the rim component is lap-welded and spot-welded in it, the joint of the rim components is joined in width less than the width of the channel between the peripheral cells and the rim and its threshold is placed in one of them, and each face of the rim in the upper and lower parts is provided along the entire length of the coolant bumps from the periphery to the center at an angle of 15-30 ^o . Another difference is that the chippers are made in the form of petals and placed between the fuel rods in the peripheral row.

Fixing between each other the components of the rim of the spacer grid by making a threshold on each of the components with a height equal to the thickness of the rim with lapping and fixing by spot welding the other end of the component of the rim, making the joining of the components of the rim in width less than the width of the channel between peripheral cells and the rim and the placement of the docking point with one's threshold in one of them will improve the reliability of fastening the components of the rim to each other, respectively the lattice and the fuel assembly as a whole by eliminating argon arc welding in a controlled argon medium in the chamber with preliminary evacuation of the latter, exclude mechanical cleaning of the argon arc welding seams to the level of the rim faces and accordingly eliminate the occurrence of ulcerative corrosion in the places of argon arc welding of zirconium alloy rim components , get a turnkey rim without any mechanical processing due to the location of the junction with your threshold in the channel formed by peripheral cells by the females and the rim. The execution on each face of the rim in the upper and lower part of the bumpers in the form of petals with placement between the fuel elements in the peripheral row at an angle of 15-30 ^o from the periphery to the center will improve the efficiency of the reactor by aligning the heat transfer with the heat carrier, which will change the laminar flow to turbulent with a direction from the periphery to the center and vice versa with a constant upward flow.

 The implementation of the rims of the distance gratings with bumpers with an inclination from the periphery to the center will eliminate the damage to the fuel assemblies during overloading in the reactor by eliminating the engagement of the rims of the distance grids of the fuel assemblies against each other, while the bumps act as peculiar chamfers on the rims of the distance gratings.

The drawings show:
in FIG. 1 - fuel assemblies of a nuclear reactor;
in FIG. 2 - spacer grid, top view;
in FIG. 3 - spacer grid, side view;
in FIG. 4 - docking of the rim;
in FIG. 5 is a diagram of the direction of flow of the coolant flow in a nuclear reactor.

 The fuel assembly of a nuclear water-water power reactor includes a bunch of fuel elements (TVEL) 1 mounted vertically in a frame of spacer grids 2 mounted on tubular channels 3, a shank 4 and a removable head 5. Each spacer grid 2 is assembled from separate curly cells 6, welded together at points 7 by spot welding, fastened on the outside by a rim made of components 8, 9, 10 and forming channels 11, 12, 13 for the passage of the coolant (arrow) between the fuel rods 1 and the walls of the cells 6, between the cells 6 and between the cells 6 and the rim of the components 8, 9, 10.

At each of the components of the rim 8, 9, 10, one end is provided with a threshold 14 with a height equal to the thickness of the rim, an overlap is placed and fixed by spot welding 15 the other end of the rim component, the joint of the rim components 8, 9, 10 in width made smaller than the width of the channel 13 between the peripheral cells 6 and the rim and its threshold 14 is placed in one of them. Each face of the constituent parts 8, 9, 10 of the rim in the upper and lower parts is provided along the entire length with coolant bumps from the periphery to the center at an angle α = 15-30 ^o . The chippers are made in the form of petals 16 and are placed between the fuel rods 1 along the peripheral row. The angle α is chosen optimal, because when the angle decreases to less than 15 ^{o, the} turbulence of the flow decreases and approaches the laminar flow, and an increase in the angle α> 30 ^o will increase the resistance to the flow of the coolant.

 The spacer grid 2 to the fuel assembly is made as follows. The components 8, 9, 10 of the rim of the spacer grid are made by stamping simultaneously with the petals 16 - chippers.

 Set and spot welding of 7 cells 6 with each other with the formation of a field of curly cells 6 and channels 12 between the cells for the coolant, place the end of component 9 in the threshold 14 of component 8 and the end of component 10 in the threshold 14 of component 9 and the end of the component 8 in the threshold 14 of component 10, spot welding of the components 8, 9, 10 to each other with the formation of the rim is carried out, the field of curly cells 6 is introduced into the rim so that the joints of the components 8, 9, 10 join their thresholds 14 in channels 13 formed peripheral cells 6 and the rim of the components 8, 9, 10, and spot welding is conducted peripheral cells 6 to the rim.

 The fuel assembly is made as follows. A beam of fuel elements 1 is inserted into the shaped cells 6 of the spacer grids 2 mounted on the tubular channels 3 of the frame, which are tightly fixed in the cells 6 with the formation of channels 11 between the fuel elements 1 and the walls of the shaped cells 6 for the coolant duct in a nuclear reactor and fix the head 5 and shank 4.

Due to the fact that the petals 16 chippers have an angle of inclination of 15-30 ^o from the periphery to the center, the coolant flow acquires a turbulent motion in the nuclear reactor, which contributes to better heat removal, and the implementation of the proposed fastening of the rim components eliminates corrosive corrosion of the rim and will increase the duration of the campaign of fuel assemblies in a nuclear reactor.

Claims (2)

1. The fuel assembly of a nuclear water-water power reactor, including a beam of fuel elements mounted vertically in a frame of spacer grids mounted on tubular channels, a shank and a removable head, where each spacer grid is assembled from separate figured cells welded together at points, fastened on the outside by a rim made of component parts and forming channels for the passage of the coolant between the fuel elements and the cell walls, between the cells and I wait for the peripheral cells and the rim, characterized in that each of the rim components has one end with a threshold with a height equal to the rim thickness, the other end of the rim component is lap-welded and spot-welded, the joint of the rim component parts in width is made smaller the width of the channel between the peripheral cells and the rim and its threshold is placed in one of them, and each face of the rim of the upper and lower parts is provided along the entire length of the coolant bumps from the periphery to the center at an angle of 15 - 30 ^o .  2. The fuel assembly according to claim 1, characterized in that the chippers are made in the form of petals and are placed between the fuel elements in a peripheral row.

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