RU2391725C1 - Procedure and facility for mixing coolant in fuel assemblies of nuclear reactor - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: to equalise temperature and steam content of coolant in different cells and fuel assemblies in active zone disclosed here facility deflects flows by means of deflectors facilitating flows changed energy release and their mixing with neighbour flows, thus averaging corresponding temperature and steam content. Flow of coolant is deflected along perpendicular to base (8) of sector (7) in hexagonal fuel assemblies (1) in each out of six triangular sector (7) of cross section of each fuel assembly (1); also in adjacent sectors vectors of deflection of flows (9) are opposite directed relative to bases (8) of their own sectors. The facility for coolant mixing in active zone of the nuclear reactor consists of at least one grate (4) equipped with deflecting components (5). Incline of deflecting components (5) is made along perpendicular to base (8) of sector (7) in each out of six triangular sectors (7) of cross section of each fuel assembly (1). Also inclines of deflecting components (5) in each pair of adjacent sectors are made in opposite directions relative to bases (8) of their own sectors (7).

EFFECT: equalising parametres of coolant at zero summary torque.

5 cl, 6 dwg

Description

Technical field

The invention relates to nuclear energy, and more specifically to fuel assemblies of nuclear reactors with water under pressure.

State of the art

The energy release over the cross section of the fuel assembly of a nuclear reactor has significant irregularities. This leads to an uneven distribution of the parameters of the coolant and, accordingly, the reserves before the heat transfer crisis in the cells between the fuel elements. To align the parameters of the coolant along the cross section of the fuel assembly, mixing devices are used in the form of gratings with deflectors (blades).

A device (blades) is known for mixing a coolant over the cross section of a fuel assembly [US Patent No. 3,862,000, patent application 31.08.72, MKI G21C 3/34] of a nuclear reactor, including a grating made of intersecting plates forming cells equipped with deflectors at the intersection ( deflecting elements). The baffles are located concentrically to the place where adjacent angles of adjacent fuel assemblies converge and are oriented in the peripheral direction in order to deflect in the transverse direction inside each assembly a part of the longitudinal coolant flow.

The known device for mixing the coolant has a significant disadvantage, namely, that in the corners of the Assembly are formed equally directed vortex deviations of the coolant flow. Moreover, in each sector of the cross section of the fuel assembly, the deflectors in the left and right halves of the sector have opposite directions. This direction of the deflectors and, accordingly, the direction of flow deviation will create a constant torque on the fuel assembly, which can lead to spatial curvature of the guide channels and the difficulty of moving the absorbing rods in them.

Disclosure of invention

The aim of the invention is to increase the reliability of the fuel Assembly and the safety of a nuclear reactor.

The objective of the invention is the provision of mass transfer between fuel assemblies by deflecting the coolant flow at zero total torque.

The technical result of the invention is to ensure the alignment of the parameters of the coolant in the active zone of a nuclear reactor by mass transfer between the fuel assemblies and the exclusion of torque loads on the fuel assemblies.

The achievement of the objective of the invention is ensured by the fact that a method of mixing the coolant in the fuel assemblies of a nuclear reactor having a cross-section in the shape of a hexagon by deviating the direction of flow of the coolant from the vertical axes of the fuel assemblies is provided. What is new is that in each of the six triangular sectors of the cross section of each fuel assembly, the coolant flow is deflected along the perpendicular to the base of the sector, and in adjacent sectors, the flow deviation vectors are oppositely directed with respect to the bases of their sectors.

The achievement of the objective of the invention is also ensured by the fact that a device for mixing the coolant in the fuel assemblies of a nuclear reactor having a cross-section in the shape of a hexagon containing at least one grating equipped with deflecting elements mounted with an inclination relative to the vertical axis of the fuel assembly is provided. What is new is that in each of the six triangular sectors of the cross section of each fuel assembly, the inclination of the deflecting elements is made perpendicular to the base of the sector, and in each pair of adjacent sectors the inclination of the deflecting elements is made in opposite directions relative to the bases of their sectors.

The achievement of the objective of the invention is also ensured by the fact that in the proposed device for mixing the coolant in the fuel assemblies of the nuclear reactor, the deflecting elements are made in the form of blades mounted on the upper edge of the lattice.

The achievement of the objective of the invention is also ensured by the fact that in the proposed device for mixing the coolant in the fuel assemblies of the nuclear reactor, the deflecting elements are made in the form of channels formed by the walls of the lattice made with an inclination relative to the longitudinal axis of the fuel assembly.

The achievement of the objective of the invention is also ensured by the fact that in the proposed device for mixing the coolant in the fuel assemblies of a nuclear reactor, the lattice is made of cells having the shape of faceted tubes with six vertical sides located on the sides of a regular hexagon along which the cells are interconnected and six located at the corners of said regular hexagon with inclined faces, made in such a way that their normal intersects the cell axis at an indirect angle, and The top edges of the non-adjacent of the inclined faces are closer to the axis of the cell than the lower edges, and for the other three inclined faces, the upper edges are farther from the axis than the lower edges.

With this design of the device and the method of mixing the coolant in the core of a nuclear reactor, the total torque due to the organized mass transfer between the fuel assemblies is zero and, accordingly, the cause of the distortion of the fuel assemblies is eliminated.

Also, the proposed method and device provide effective mixing of the coolant and the alignment of its parameters along the core section by exchanging it between adjacent sectors of the fuel assembly section and between adjacent fuel assemblies.

Brief Description of the Drawings

The invention is illustrated by drawings, on which:

figure 1 - fuel assembly with a device for mixing the coolant;

figure 2 - diagram of the deviation of the flow of coolant;

figure 3 - a device for mixing the coolant in the core of a nuclear reactor with deflectors in the form of blades;

figure 4 - a device for mixing the coolant in the active zone of a nuclear reactor with deflectors in the form of inclined channels;

figure 5 - cell device for mixing the coolant in the active zone of a nuclear reactor with baffles in the form of inclined channels;

6 is a top view of the cell of the device for mixing the coolant in the active zone of a nuclear reactor with deflectors in the form of oblique channels.

Embodiments of the invention

A device for mixing the coolant is installed in hexagonal fuel assemblies (1) of a nuclear reactor containing a bunch of fuel rods (2), spacer grids (3). A device for mixing the coolant is one or more grids (4), equipped with deflecting elements (5). The grilles (4) are fixed on the supporting elements (6) in the upper part of the fuel assemblies (1) between the spacer grids (3). In the cross section, the gratings (4) and the bundle of fuel rods (2) are a regular hexagon and conditionally symmetrical axes can be divided into six triangular sectors (7), the bases (8) of which are the outer sides of the bundle of fuel rods (sides of the hexagon). In each sector (7), the deflecting elements (5) are made with a slope having a vector (9) along the perpendicular to its base (8). In two adjacent sectors, vectors (9) have opposite directions relative to the bases of their sectors.

Alternatively, the deflecting elements (5) are made in the form of blades (10) (or deflectors) mounted on the upper edge of the grating (4), having an inclination relative to the vertical axis of the fuel assembly.

Alternatively, the deflecting elements (5) are made in the form of channels (11) formed by the walls of the grating (4) made with an inclination relative to the longitudinal axis of the fuel assembly.

In the proposed device for mixing the coolant in the fuel assemblies (1) of a nuclear reactor, the lattice (4) can be made of cells (12) having the shape of faceted tubes. Faceted tubes contain six vertical faces located on the sides of the regular hexagon (13), along which the cells (12) are interconnected, as well as six inclined faces located at the corners of the regular hexagon (14). The normal of the inclined faces (14) intersects the axis (15) of the cell (12) at an indirect angle. For three non-adjacent of inclined faces (14), the upper edges (16) are closer to the axis (15) of the cell (12) than the lower edges (17), ay of the other three inclined faces, the upper edges (18) are farther from the axis (15) than lower edges (19).

The operation of the device for mixing the coolant in the active zone of a nuclear reactor is as follows.

The coolant enters the fuel assembly (1) and is heated accordingly to the energy released in the fuel elements. Since the energy release over the cross section and height of the fuel assembly has significant unevenness, heating of the coolant also turns out to be uneven. To equalize the temperatures and vapor contents of the coolant in different cells and fuel assemblies, the claimed device with the help of blades (10) or channels (11) deflects the flows (9), providing them with a change in energy release and mixing with neighboring flows with the corresponding averaging of temperatures and vapor contents. The inclination directions of the blades (10) or channels (11) are selected in such a way that the flow deviations form closed contours around each center from the converging angles of the fuel assemblies (1). Moreover, in two adjacent corners of each fuel assembly (1), the directions of flow swirl in closed circuits are opposite. Since the cross section of the fuel assembly (1) has the shape of a regular hexagon, and the flow deflection contours of the heat carrier fluid (20) are symmetric, the total torque from hydrodynamic forces for each fuel assembly (1) is zero. In total, such a flow deviation leads to a displacement of the coolant mass along closed loops, due to which warmer masses of the coolant fall into regions with less energy release, and vice versa. As a result, the unevenness of the heating medium heating over the core cross section decreases, the temperatures and steam content are aligned.

The direction of the coolant flow to the heat-generating element and its flow around increase the intensity of heat removal from its surface.

Thus, the proposed solution for a device for mixing the coolant has a significant novelty and technical efficiency.

The economic efficiency of the application of the invention is also determined by increasing the safety of a nuclear reactor by reducing the unevenness of the parameters of the coolant in the fuel assembly and the core and the possibility of increasing the power of the reactor by increasing the reserves to critical parameters of the coolant.

Claims (5)

1. The method of mixing the coolant in the fuel assemblies (1) of the nuclear reactor, having a hexagonal cross section, by deviating the flow direction (9) of the coolant from the vertical axes of the fuel assemblies, characterized in that in each of the six triangular sectors (7) of the cross section of each fuel assembly (1), the coolant flow is deflected along the perpendicular to the base (8) of the sector (7), and in adjacent sectors the flow deviation vectors (9) are oppositely directed with respect to Warping (8) of its sectors. 2. A device for mixing the coolant in the fuel assemblies (1) of a nuclear reactor having a hexagonal cross-section, containing at least one grating (4), equipped with deflecting elements (5) installed with an inclination relative to the vertical axis of the fuel assembly, characterized in that in each of the six triangular sectors (7) of the cross section of each fuel assembly (1), the inclination of the deflecting elements (5) is made along the perpendicular to the base (8) of the sector (7), and in each pair of adjacent sectors, the slopes of the deflecting elements (5) are made in opposite directions relative to the bases (8) of their sectors (7). 3. A device for mixing the coolant in the fuel assemblies of a nuclear reactor according to claim 2, characterized in that the deflecting elements (5) are made in the form of blades (10) mounted on the upper edge of the grating (4). 4. A device for mixing the coolant in the fuel assemblies of a nuclear reactor according to claim 2, characterized in that the deflecting elements are made in the form of channels (11) formed by the walls of the grating (4) made with an inclination relative to the longitudinal axis of the fuel assembly. 5. A device for mixing the coolant in the fuel assemblies of a nuclear reactor according to claim 4, characterized in that the lattice (4) is made of cells (12) having the shape of faceted tubes with six vertical sides located on the sides of a regular hexagon (13), along which the cells (12) are interconnected, and six inclined faces (14) located at the corners of the said regular hexagon are made in such a way that their normal intersects the axis (15) of the cell (12) at an indirect angle, and for three non-adjacent faces (14) the upper edge (16) closer to the axis (15) of the cell than the lower edge (17), while the other three faces inclined upper edge (18) farther from the axis (15) than the lower edge (19).

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