RU2753764C1 - Reactor section of npp with increased seismic resistance - Google Patents

Abstract

FIELD: NPP seismic resistance.

SUBSTANCE: invention relates to ensuring increased seismic resistance of nuclear power plants. The reactor compartment includes a reinforced concrete foundation slab 1, on which a base plate 4 is installed through the seismic elements 2 with a gap 3, a multilayer containment shell 5, fixed on the support plate 4 by means of radial support ribs 6. Inside the containment shell 5 there is a reactor installation 7, rooms with technological equipment 8, crane 9, mounted on a cargo platform 10, installed with a gap 11 on a base plate 12 through seismic damping elements 13, and a central transport shaft 14. Outside the containment shell 5, there are enclosures 15 and a transport tunnel 16 with a gate 17, connected to the central transport shaft 14 through a sealed lock 18 and passages 19. Seismic suppressing elements 2 and 13 are made in the form of supporting metal balls inside individual coaxial metal bowls 20. The floor slab 25 of the transport tunnel 16 is installed above the reinforced concrete foundation slab 1 with a gap 26, in which the seismic damping elements 2 are located inside the individual coaxial metal bowls 20. The soil 21 adjacent to the structure is fixed by the vertical slab 27, and the soil adjacent to the structure 15 above the transport tunnel 16, is fixed by vertical 27 and horizontal 28 plates with the formation of a gap between the horizontal plate 28 and the ceiling plate 29 of the transport tunnel 16.

EFFECT: increasing the operational reliability of the structure with significant horizontal seismic impacts.

1 cl, 3 dwg

Description

The invention relates to nuclear energy and can be used for the construction of nuclear power plants (NPP) in earthquake-prone areas.

Known construction of nuclear power plant Koberg ("Koeberg") with seismic isolation, made in the form of a sliding support (see "Modern methods of seismic protection of buildings", Polyakov VS et al., M .: Stroyizdat, 1989). The foundation of the structure consists of a double reinforced concrete monolithic slab with dimensions in the plan 150x90m, each foundation slab has 600 columnar supports, on each support there are four elastic neoprene cushions that serve as horizontal shock absorbers. Above the pillows is another part of the support, which includes two friction plates that can move relative to one another with a friction coefficient of 0.2. The upper plate, made of stainless steel, is connected to the overlying structure, and the lower one, made of bronze with the addition of lead, is connected to a resilient cushion. With a weak seismic impact (acceleration 0.15-0.2g), the elastic cushion twists without displacement of the friction plates. With an increase in acceleration, the twisting of the pad is accompanied by a mutual displacement of the plates.

The disadvantage of this analogue is its low reliability in case of seismic vibrations. This is due to the fact that with a large mass of the structure and significant horizontal seismic vibrations, the friction forces between the plates restrict the freedom of movement of the lower plate relative to the upper one, as a result of which the oscillatory displacements of the structure are inevitable and deformations or destruction of the structure are possible with the occurrence of inertial forces. With the collapse and deformation of the reinforced neoprene cushion and metal plates, such seismic isolation for subsequent seismic events becomes unworkable, due to the fact that the integrity and durability of seismic isolation is not ensured for conditions with significant vertical loads, significant seismic effects and long-term operation of the structure.

The closest to the claimed technical solution is the reactor compartment of a nuclear power plant, which includes a reinforced concrete foundation slab, on which a base plate is installed through seismic elements, a multilayer protective shell secured to the base plate by means of radial support ribs, inside which the reactor plant is located, rooms with technological equipment, a crane mounted on a cargo platform mounted on a base plate through seismic damping elements and a central transport shaft, and outside the containment shell there are an outbuilding and a transport tunnel with a gate connected to the central transport shaft through a sealed lock and passages (see patent RU 2031456, IPC G21C 13/00 (1995.01), publ. 03/20/1995). In this reactor compartment, the seismic damping elements installed between the reinforced concrete foundation slab and the base plate are made in the form of rollers, and the seismic damping elements installed between the cargo platform and the base plate are in the form of swinging struts. The seismic isolation system is supplemented with dampers installed between the inner surface of the containment shell and the room with technological equipment.

The disadvantage of the prototype is low reliability when exposed to significant seismic vibrations. This is due, firstly, to the use for seismic isolation of rooms with technological equipment and a reactor plant as kinematic seismic suppressing supports of swinging struts, which fail in operation with significant seismic vibrations and displacements, since with significant vibrations, especially low-frequency ones, the reactor plant with With such kinematic supports, significant displacements can occur, at which the loss of stability of the entire structural system located inside the containment shell, including the reactor plant and rooms with technological equipment, and their complete collapse with catastrophic consequences can occur. Secondly, dampers, adopted as additional seismic isolation of the internal structures of the containment shell, are operable within certain limits and only partially damp vibrations, in this case horizontal ones, and fail in operation with significant seismic influences. In conditions of high seismic activity, significant displacements and accelerations, that is, outside the range of action of any damper, it is natural that the dampers do not provide seismic isolation, vibrations are transmitted to the structure and as a result of its oscillatory movements with the emergence of horizontal inertial forces, deformation and destruction of the structure occurs. Thirdly, rollers installed with longitudinal axes perpendicular to each radial support rib of the containment shell act as compensators for temperature deformations of the containment shell, but not seismic isolation, since other rollers located in a mutually perpendicular direction prevent the free rolling of the rollers in any direction. The containment is therefore not earthquake resistant. Fourthly, the seismic resistance of the entire complex is not ensured, since the section of the entrance of the transport tunnel into the structure and the outbuilding with premises do not have seismic isolation. In the event of a collapse of the structure adjacent to the containment shell, deformations of the containment shell and its contents are possible.

The technical result of the invention is to increase the operational reliability of the structure with significant horizontal seismic impacts.

The technical result is achieved by the fact that the reactor compartment of the NPP with increased seismic resistance, including a reinforced concrete foundation plate, on which a base plate is installed with a gap by means of seismic damping elements, a multilayer protective shell, fixed on the base plate using radial support ribs, inside which the reactor plant is located, premises with technological equipment, a crane mounted on a cargo platform installed on a base plate through seismic damping elements and a central transport shaft, and outside the containment shell there are an outbuilding and a transport tunnel with a gate, connected to the central transport shaft through a sealed lock and passages, according to the invention, seismic damping elements are additionally installed between the reinforced concrete foundation slab and the floor slab of the transport tunnel, while all the seismic damping elements of the reactor plant are made in the form of supporting metal balls located so that they can freely move in any direction of the horizontal plane inside individual coaxial metal bowls, and between rooms with technological equipment and the inner surface of the containment, as well as between the building and the adjacent soil, fixed by the vertical slab, vertical structural gaps are formed, the minimum width of which is equal to the radius of the metal bowl, while the cavity of the gap between the building and the adjacent soil is protected from external influences by a sliding blind area, and on In the section of the transport tunnel adjacent to the building, the soil is fixed with vertical and horizontal plates with the formation of a gap between the horizontal plate and the ceiling plate of the transport tunnel.

This structure will increase its operational reliability due to the complete isolation of the reactor compartment of the NPP from the impact of destructive horizontal inertial forces by eliminating horizontal displacements of its above-foundation structural elements and ensuring the state of rest of the structure in case of any significant horizontal earth vibrations caused by natural or artificial means, and will also provide performance of seismic isolation during long-term continuous and multiple repeated seismic vibrations.

The essence of the invention is illustrated by drawings, where Fig. 1 shows a vertical section of the reactor compartment of a nuclear power plant, Fig. 2 - node A, in Fig. 3 - node B.

The reactor compartment of a nuclear power plant of increased seismic resistance includes a reinforced concrete foundation slab 1, on which a support plate 4 is installed through the seismic elements 2 with a gap 3, a multilayer containment shell 5, fixed on the support plate 4 with the help of radial support ribs 6. Inside the containment shell 5 there is a reactor unit 7 , rooms with technological equipment 8, crane 9, mounted on a cargo platform 10, installed with a gap 11 on a base plate 12 through seismic damping elements 13 and a central transport shaft 14. Outside of the containment shell 5, there are enclosures 15 and a transport tunnel 16 with a gate 17 connected with the central transport shaft 14 through the sealed lock 18 and passages 19. The seismic suppressing elements 2 and 13 are made in the form of supporting metal balls located so that they can freely move in any direction of the horizontal plane inside the individual coaxial metal bowls 20. In this case, between the rooms with technological equipment 8 and the inner surface of the containment shell 5, as well as between the building 15 and the adjacent soil 21, vertical structural gaps 22 and 23 are formed. Moreover, the minimum width of the gaps 22 and 23 is equal to the radius of the metal bowls 20, and the cavity of the gap 23 between the building 15 and the adjacent soil 21 is protected from external influences by a sliding blind area 24. The floor slab 25 of the transport tunnel 16 is installed above the reinforced concrete foundation slab 1 with a gap 26, in which the earthquake elements 2 are located inside the individual coaxial metal bowls 20. The soil 21 adjacent to the structure is fixed by a vertical slab 27, and the soil adjacent to the structure 15 above the transport tunnel 16 is fixed by vertical 27 and horizontal 28 plates with the formation of a gap between the horizontal plate 28 and the ceiling plate 29 of the transport tunnel 16.

The reactor compartment of a nuclear power plant with increased seismic resistance operates as follows. Due to the fact that the entire complex of structures is structurally separated from the ground by means of horizontal gaps 3 and 26, a vertical gap 23 and has only movable point contacts with the ground in the form of supporting metal balls 2, placed in horizontal structural gaps 3 and 26 in recesses in the form of individual coaxial metal bowls 20, then any horizontal vibrations of the earth, seismic or otherwise, affect only the foundation slab 1 installed on the ground. During oscillatory movements of the base plate 1, the supporting metal balls 2, following the movements of the foundation plate 1, freely roll in their individual coaxial metal bowls 20 in any direction of the horizontal plane. Obviously, it is impossible to move the structure resting on them with freely rolling balls, as a result of which the structure maintains a state of rest, and the annular cavity of the vertical structural gap 23 does not prevent the preservation of this state during seismic movements of the soil. The considered effect of complete isolation of the structure from the most destructive horizontal vibrations remains at any significant seismic manifestations (9-10 or more points) with their extreme parameters (movement, speed, acceleration). The structural autonomy of the containment 5 and the reactor facility 6 with rooms 8 is solved by the type of general seismic isolation by means of a horizontal gap 11, support metal balls 13, individual coaxial metal bowls 20 and a vertical gap 22 and is the second duplicate level of seismic isolation of a room with technological equipment 8 and a reactor installation 7, from possible external influences on the containment 5. Compared to the prototype, the transport tunnel 16 is also isolated from the ground due to the gap 25 and the supporting metal balls 2, which allows you to maintain the integrity of the structure during seismic vibrations.

The use of the proposed reactor compartment of a nuclear power plant with increased seismic resistance in comparison with the prototype will increase the operational reliability due to the complete isolation of the reactor compartment of the nuclear power plant from the impact of destructive horizontal inertial forces caused by natural or artificial intensity.

Claims (1)

The reactor compartment of a nuclear power plant with increased seismic resistance, including a reinforced concrete foundation slab, on which a base plate is installed with a gap by means of seismic damping elements, a multilayer protective shell secured to the base plate using radial support ribs, inside which the reactor plant, rooms with technological equipment, a crane, are located, mounted on a cargo platform installed on a base plate through seismic damping elements, and a central transport shaft, and outside the containment shell there is an outbuilding and a transport tunnel with a gate, connected to the central transport shaft through a sealed lock and passages, characterized by that the seismic suppressing elements are additionally installed between the reinforced concrete foundation slab and the floor slab of the transport tunnel, while all the seismic suppressing elements of the reactor plant are made in the form of supporting metal balls located with the possibility of their free movement in any direction of the horizontal plane inside individual coaxial metal bowls, and between rooms with technological equipment and the inner surface of the containment, as well as between the building and the adjacent soil, fixed by a vertical slab, vertical structural gaps are formed, the minimum width of which is equal to the radius of the metal bowl, while the cavity of the gap between the building and the adjacent soil is protected from external influences by a sliding blind area, and in the section of the transport tunnel adjacent to the building, the soil is fixed by vertical and horizontal plates with the formation of a gap between the horizontal plate and the ceiling plate of the transport tunnel I am.

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