RU2771463C1 - Support system for the housing of the melt localizer - Google Patents

Abstract

FIELD: mechanical engineering.SUBSTANCE: invention relates to the field of mechanical engineering, in particular to the support systems of the housing of the melt localization device. The support system includes a lower support, an upper support. The lower support consists of radial supports located in the lower part of the housing. The upper support contains lanyards, each of which contains an adjusting nut connecting the rods. At the ends of the rods, holes are made in the form of hyperbolic surfaces for connecting the housing with the embedded plates by means of fasteners. Said lanyards are installed tangentially to the body in pairs in such a way that the longitudinal axis of each radial support passes in the projection at an equidistant distance from the attachment points of the paired lanyards. In the eyes of the rods of each turnbuckle, flange stops are additionally installed, connected to each other by means of straight studs, fixed by means of fasteners, and installed parallel to each other with pretension.EFFECT: increased reliability of the melt localization device.1 cl, 6 dwg

Description

The invention relates to devices for melt localization (hereinafter referred to as CLR) equipped with a vessel for receiving and distributing the melt, in particular, to mechanisms for securing and stabilizing the vessel for receiving and distributing the melt in severe accidents.

The greatest radiation hazard is posed by accidents with a core meltdown, which can occur with various combinations of failures (destruction of equipment elements) of active and passive safety systems and normal operation systems, or in conditions of a complete blackout of the NPP, and the impossibility of supplying power within the time period established by the NPP project for providing emergency core cooling.

In such accidents, the core melt - corium, melting the in-reactor structures and the reactor vessel, flows out of it and, due to residual heat remaining in it, can violate the integrity of the NPP hermetic shell - the last barrier to the release of radioactive products into the environment.

To avoid this, it is necessary to localize the corium leaking from the reactor vessel and ensure its continuous cooling, up to the complete crystallization of all components of the corium. This function is performed by the melt localization device, which prevents damage to the hermetic shell of the nuclear power plant and, thereby, protects the population and the environment from radiation exposure during severe accidents of nuclear reactors.

In particular, one of the main tasks for the localization of the melt is performed by the housing of the CLR with a filler designed to receive and distribute the melt, which is installed in the reactor shaft and fixed in it by means of support mechanisms and fasteners.

Due to the fact that under BDBA conditions under various scenarios of the melt exit from the reactor pressure vessel there is an impact on the casing of the CLR, which is transmitted to the support mechanisms and fasteners, it is necessary to provide conditions that exclude the possibility of destruction of these elements, which can lead to separation of the casing of the CLR and its overturning, followed by the release of the melt outside the body of the ULR and the sealed shell.

Known support system [1] ULR containing lower and upper supports, while the lower support consists of a horizontal embedded plate with radial supports, which are connected to the radial supports placed in the lower part of the housing ULR, and the upper support consists of a set of lanyards, each of which contains an adjusting nut and rods, while these lanyards are installed in pairs in the upper part of the CLR housing from the outer side of the flange, tangent to the CLR housing, and connect the CLR housing with embedded plates installed in the vertical wall of the reactor shaft.

The disadvantage of the support system is low reliability, due to the fact that under design basis seismic impact or shock volley non-axisymmetric melt flow into the body with filler, the body of the ULR can be displaced under the action of shock loads and destroy the upper support, which is due to the design features of turnbuckles when exposed to shock loads from the side of the body of the ULR, in which the destruction of the turnbuckle rods and the adjusting nut occurs, since the shock load is concentrated precisely in this place.

The technical result of the claimed invention is to increase the reliability of the melt localization device.

The task to be solved by the claimed invention is to eliminate the destruction of the upper support during beyond-design seismic impact or shock salvo non-axisymmetric flow of the melt, and, as a result, overturning of the casing of the ULR and the release of the melt beyond its limits.

The problem is solved due to the fact that in the support system of the body of the melt localization device, including the lower support, consisting of radial supports located in the lower part of the body, the upper support containing lanyards, each of which contains an adjusting nut connecting the rods, at the ends of which holes are made in the form of hyperbolic surfaces for connecting the body with the embedded plates by means of fasteners, while these lanyards are installed tangentially to the body in pairs in such a way that the longitudinal axis of each radial support passes in the projection at an equidistant distance from the attachment points of paired lanyards, according to the invention, in the eyes of the rods of each lanyard are additionally equipped with flange stops connected to each other by means of straight studs, fixed by means of fasteners, and installed parallel to each other with a pretension.

A distinctive feature of the claimed invention is that in the eyes of the rods of each turnbuckle, flange stops are installed, connected to each other by means of straight studs, fixed with pretension by means of fasteners, and installed parallel to each other, which ensures compression of the main adjusting nut, and therefore, during elastic stretching of straight studs, the main adjusting nut is unloaded, and during plastic deformation of straight studs, the main adjusting nut experiences elastic tension.

This design of lanyards provides:

- free thermal radial expansions of the body of the ULR in the plane of the turnbuckles location (in the horizontal plane) due to the tangential release of the turnbuckles in the eyes of the body of the ULR, in which any radial expansion of the body of the ULR only leads to a change in the flat angle of the tangent position of the lanyard relative to the generatrix of the body of the ULR. This eliminates the risk of lanyard shape change with the loss of their performance and the formation of cracks or destruction of the casing of the ULR;

- non-exceeding of the action of radial pull-out forces on embedded parts in the concrete shaft of the reactor (controlled loading) due to the distribution of the shock radial load between all turnbuckles. In this case, part of the lanyards will work in compression, and some will work in tension in the plane of the lanyards. At the same time, the horizontal shock load leads to the occurrence of plane vibrations of the casing flange of the ULR, in which, firstly, all straight studs of turnbuckles work alternately in tension and compression in the area of elastic-plastic deformations in straight studs, and secondly, all main adjusting nuts work alternately for tension and compression in the zone of action of elastic deformations, up to the damping of plane vibrations;

- reduction of the non-axisymmetric impact on the lower support of the ULR body with non-axisymmetric axial (vertical) shock loading of the ULR body in the flange area due to the distribution of the shock axial load between all turnbuckles. In this case, those lanyards, in the zone of which the action of a non-axisymmetric axial impact load has manifested itself, do not provide mechanical resistance to the shape change of the ULR housing flange. At the same time, the flange of the hull of the ULR, in the location zone of which the axial impact action has manifested itself, redistributes the shock load along its perimeter, splitting the axial impact into two additional components with the formation of both azimuthal (along the perimeter of the hull of the ULR) and radial (planar) vibrations. Part of the impact in the form of axial elastic vibrations of the body of the ULR does not affect the lanyards. Part of the impact in the form of azimuthal oscillations is damped by turnbuckles as follows: straight studs work in tension and compression in the area of elastic deformations, and the main adjusting nuts either unload when the straight studs are elastically stretched, or experience elastic deformations when the straight studs are compressed. Part of the impact in the form of radial vibrations propagating in the plane of the lanyards are alternately damped by them, as in the damping of a radial shock load;

- non-exceeding of the effect of azimuthal pull-out forces on embedded parts located in the vertical wall of the reactor shaft during beyond design seismic impacts on the casing of the catcher (suppression of torsional vibrations of the flange of the casing of the catcher) due to the alternating operation of turnbuckles in tension and compression when exposed to plane torsional vibrations from the flange of the casing of the catcher . Vibration damping is provided by the absorption of the energy of elastic-plastic deformations of straight pins and elastic deformations of the main adjusting nuts of turnbuckles, up to the damping of torsional vibrations;

- preservation of the integrity of the hull flange of the ULR, embedded parts of the reactor shaft and the upper support with axial thermal expansion of the hull of the ULR due to the rotation of the turnbuckle rods with eyes in the axial (vertical) plane, which is ensured by the execution of the hyperbolic surface of the holes for attaching the lanyards in the forks of the ULR housing and in the forks vertical embedded plates installed in the reactor shaft. The execution of the hyperbolic surface of the holes in the fasteners can be performed both on the body of the ULR and on embedded plates.

In FIG. 1 shows a melt localization device made in accordance with the claimed invention.

In FIG. 2 shows the location of paired lanyards around the body of the ULR.

In FIG. 3 shows a fragment of the ULR body with paired lanyards.

In FIG. 4 shows a lanyard with flange stops and straight studs.

In FIG. 5 shows a fragment of the fastening of the lanyard rod with a hole made in the form of a hyperbolic surface.

In FIG. 6 shows a fragment of the ULR body with a radial support having oval holes.

In FIG. 1 shows a melt localization device (1) comprising a housing (2) for receiving and distributing the melt (3). The body (2) is installed under the bottom of the body (18) of the reactor. A filler (4) is installed in the housing (2) of the CLR, designed to receive, distribute and dilute the melt (3). In the lower part of the body (2) of the ULR there is a lower support (5), and in the upper part - an upper support (11).

The lower support (5) consists of a horizontal sectional, solid or divided embedded plate (9) having radial supports (8), which are connected to the radial supports (6) made in the lower part (7) of the body (2) of the ULR from the outside . Radial bearings (6) and radial bearings (8) are connected by clamps (10), while each of the radial bearings (6) and (8) has oval-shaped holes (21).

As shown in FIG. 2-5, the upper support (I) contains lanyards (12a) and (12b) installed in pairs (as shown in Fig. 3) in the upper part of the body (2) of the ULR in such a way that the longitudinal axis of each radial support (6) and (8) passes in the projection at an equidistant distance from the places (13) for fastening turnbuckles (12a) and (12b) installed tangentially to the body (2) of the ULR. Turnbuckles (12a) and (12b) connect the housing (2) of the CLR with embedded plates (22) installed in the vertical wall (14) of the reactor shaft, using fasteners (19), (20). Rods (15) of turnbuckles (12a) and (12b) have holes (16) made in the form of hyperbolic surfaces. Flange stops (23) are installed on paired rods (15) with lugs, and the rods (15) are connected in pairs by main adjusting nuts (26). Flange stops (23) are connected in pairs with straight pins (24), which are fixed on both sides in each flange stop (23) using fasteners (25). The straight studs (24) are pretensioned.

As shown in FIG. 4-5, the rods (15) of the lanyards (12a), (12b) have holes (16) made in the form of hyperbolic surfaces, in which the axes (19) of the fasteners (20) are installed. When changing the position of the rods (15) of turnbuckles (12a), (12b) connecting the body (2) of the ULR with the places (13) of fastenings of these turnbuckles, the rods (15) rotate in the axial plane passing through the axis of each turnbuckle (12a), ( 12b).

The claimed invention works as follows.

At the moment of destruction of the reactor vessel, the melt (3) of the core, under the action of hydrostatic and excess pressure, begins to flow into the vessel (2) of the CLR, in which it thermochemically and thermomechanically interacts with the filler (4).

In case of a non-axisymmetric volley of melt (3) (for example, when 60 tons of superheated steel enters for 30 s), the main shock load falls on the side wall of the housing (2) of the CLR.

As shown in FIG. 3, in this case, those lanyards (12a), in the zone of which the action of a non-axisymmetric axial impact load has manifested itself, do not provide mechanical resistance to the shape change of the flange (17) of the body (2) of the ULR. At the same time, the part of the flange (17) of the casing (2) of the CLR, in which the axial impact action has manifested itself, redistributes the shock load along its perimeter, splitting the axial shock effect into two additional components with the formation of both azimuthal oscillations propagating along the perimeter of the casing (2) of the CLR, and radial (planar) oscillations. Part of the impact in the form of axial elastic vibrations of the body (2) of the ULR does not affect turnbuckles (12a), (12b). Part of the impact in the form of azimuthal oscillations is damped by lanyards (12a), (12b) as follows: straight studs (24) work in tension and compression in the area of elastic deformations, and the main adjusting nuts (26) are either unloaded during elastic tension of straight studs ( 24), or experience elastic deformations during compression of straight pins (24).

The shock radial load is extinguished as follows. One part of the turnbuckles (12a), (12b) will work in compression, the other part will work in tension in the plane of the turnbuckles (12a), (12b). In this case, the horizontal shock load leads to the occurrence of plane oscillations of the flange (17) of the body (2) of the ULR, in which, firstly, all straight pins (24) of turnbuckles (12a), (12b) alternately work in tension and compression in the area of action elastic-plastic deformations in straight studs (24), and secondly, all main adjusting nuts (26) work alternately in tension and compression in the zone of elastic deformations, up to the damping of plane vibrations.

The use of an upper support in the melt localization device, consisting of lanyards, each of which contains flat studs, flange stops and main adjusting nuts, made it possible to completely eliminate the likelihood of the melt exiting the CLR body by eliminating its tipping over and destruction of the upper support, even with beyond design seismic impact or shock salvo non-axisymmetric flow of the melt.

Information sources:

1. RF patent No. 2696619, IPC G21C 9/016, priority dated September 25, 2018.

Claims (1)

Support system of the body of the melt localization device, including a lower support consisting of radial supports located in the lower part of the body, an upper support containing lanyards, each of which contains an adjusting nut connecting rods, at the ends of which holes are made in the form of hyperbolic surfaces for connecting the body with embedded plates by means of fasteners, while these lanyards are installed tangentially to the body in pairs in such a way that the longitudinal axis of each radial support passes in the projection at an equidistant distance from the attachment points of paired lanyards, characterized in that flange stops are additionally installed in the eyes of the rods of each lanyard , connected to each other by means of straight studs, fixed by fasteners, and installed parallel to each other with pretension.

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