RU2182952C2 - Earthquake-proof monolithic reinforced-concrete storage building - Google Patents

Abstract

FIELD: construction engineering; applicable in construction of tanks for storage of ecologically hazardous materials such as radioactive and toxic wastes and oil products located in seismic regions. SUBSTANCE: storage building consists of concentrically arranged toroidal vessels located inside tores of tanks confined by walls of toroidal vessels, cover and bottom. Walls, bottom and cover of storage building are made of prestressed reinforced concrete with internal and external metal casings. Internal casings of bottom and cover are conjugated with external casings of toroidal vessels, and external casings of bottom and cover are conjugated with external casing of toroidal vessel from outside of storage building. Laid in diametrical direction of storage building in cover, bottom and wall of external toroidal vessel are channel-forming devices through which prestressed reinforcement is passed and anchored to toroidal vessel casing from outside of storage building. Mounted with the help of hinges in center of storage building is prefabricated pipe-concrete supporting post with prestressed reinforcement passed through cover, post, bottom and foundation plate, and anchored to cover and foundation plate. EFFECT: increased seismic stability of storage building with optimal use of site area and reduced specific consumption of materials in storage building. 7 cl, 5 dwg

Description

 The invention relates to the construction, in particular, to the construction of tanks for storing environmentally hazardous materials, such as radioactive and toxic waste, oil and oil products located in earthquake-prone regions.

 Known storage for petroleum products in the form of prestressed monolithic cylindrical tanks, including a concrete base, a cylindrical shell, a bottom and a cover / 1 /.

 A disadvantage of the known storage design is the low seismic resistance due to the presence of the mating of the walls with the bottom and the cover at right angles.

 Known storage for environmentally hazardous products in the form of reinforced concrete prestressed toroidal shells / 2 /.

 The disadvantage of this design is the inability to use the entire space occupied by the shell to form a reservoir.

 Closest to the proposed storage design is an earthquake-resistant monolithic concrete storage for environmentally hazardous materials, including a base plate, a cylindrical prestressed tank with a bottom and a lid, and a toroidal container located along its perimeter with a height equal to the height of the cylindrical tank / 3 /.

 The technical problem is to increase the seismic resistance of large-capacity structures with optimal use of the built-up area and reduce the material consumption of the storage.

 The problem is solved in such a way that an earthquake-resistant monolithic reinforced concrete storage for environmentally hazardous materials, including a base plate, a tank located around the perimeter of the tank, a toroidal tank, a bottom and a lid, according to the invention consists of concentrically placed toroidal containers and located inside the torus tanks, limited by the walls of the toroidal containers, the lid and the bottom, and the walls, bottom and lid of the store are pre-stressed with internal and external metal sheaths, while the inner sheathing of the bottom and the lid are paired with the outer sheathing of the toroidal containers, and the outer sheathing of the bottom and the lid are paired with the outer sheathing of the toroidal container on the outside of the storage, and in the diametrical directions of the storage in the lid and in the bottom and wall of the outer toroidal container ducting channels are laid through which prestressed reinforcement is passed and anchored on the sheathing of the toroidal container outside the storage, and pivotally mounted in the center of the storage a team pipe-concrete support column with prestressed reinforcement, passed through the cover, a rack, the bottom and the floor slab and anchored on the cover and base plate. The storage may consist of two concentrically arranged toroidal containers, while the diameter of the toroidal tank located outside is smaller than the diameter of the toroidal tank located inside. In addition, in the storage, channel generators with prestressed reinforcement are filled with grease. The storage is additionally equipped with pivotally mounted prefabricated pipe-concrete support racks concentrically located in the diametrical directions of the storage in each tank, with prestressed reinforcement passed through the lid, racks, bottom and foundation plate and anchored on the lid and foundation plate. Next, the prestressed reinforcement is anchored on the foundation plate and the sheathing of the toroidal tank on one side of the store using a spring damper. Further, the storage lid on the inside of the tank has diametrically located stiffeners. Further, in the walls of the tanks in the channel formers, vertical coupling elements are placed, anchored on the lid and the base plate.

 The proposed storage design differs from the known one in that it consists of concentrically placed toroidal containers and reservoirs located inside the tori, bounded by the walls of the toroidal containers, the lid and the bottom, and the walls, bottom and lid of the storage are pre-stressed with internal and external metal casings, while the internal the casing of the bottom and cover are paired with the outer casing of the toroidal containers, and the outer casing of the bottom and cover are paired with the outer casing of the toroidal tank from the outside of the store, and in the diametrical directions of the store in the lid and in the bottom and in the wall of the external toroidal tank, channel formers are laid through which prestressed reinforcement is passed and anchored to the sheathing of the toroidal tank outside the store, and in the center of the store a prefabricated pipe-concrete support stand is hingedly mounted prestressed reinforcement, passed through the cover, stand, bottom and base plate and anchored on the cover and base plate. The storage may consist of two concentrically arranged toroidal containers, while the diameter of the toroidal tank located outside is smaller than the diameter of the toroidal tank located inside. In addition, in the storage, channel generators with prestressed reinforcement are filled with grease. The storage is additionally equipped with pivotally mounted prefabricated pipe-concrete support racks concentrically located in the diametrical directions of the storage in each tank, with prestressed reinforcement passed through the lid, racks, bottom and foundation plate and anchored on the lid and foundation plate. Next, the prestressed reinforcement is anchored on the foundation plate and the sheathing of the toroidal tank on one side of the store using a spring damper. Further, the lid and the bottom of the storehouse on the inside of the tank have diametrically located stiffeners. Further, in the walls of the tanks in the channel formers, vertical coupling elements are placed, anchored on the lid and the base plate.

 The proposed design of the storage provides an increase in storage capacity while maintaining the area occupied by the structure, increasing the seismic resistance of the structure by eliminating the angular mating of the walls and the presence of seismic absorbing connections - prestressed reinforcement with anchors in the form of spring dampers, freely placed in the ducts of the bottom and lid and a pivotally mounted support rack and the ability monolithic construction of a structure while reducing material consumption and connecting its parts using location prestressed reinforcement in the wall and the lid, in the wall and the bottom and fixing on the outer surface of the store, as well as the connection of the bottom and lid shells with the outer lining of the toroidal tank. When erecting large-capacity structures, the arrangement of concentrically toroidal containers is one in the other, along with the placement of pipe-concrete racks concentrically in the diametrical directions of the storage on stiffeners and couplers of elements in storages on stiffeners and coupling elements in channel formers, in the wall of toroidal containers on the inside of the torus, anchored on the cover and foundation plate, decides the possibility of providing additional structural stability with the optimal version of the occupied storage I eat the area. In addition, filling the channel formers with lubricant provides the possibility of free movement of the prestressed reinforcement located in them during the earthquake and deformation of the structure without destroying its individual parts.

 Figure 1 presents the storage (longitudinal section); figure 2 - 1-1 figure 1; figure 3 - node a of figure 1; figure 4 - node In figure 1; figure 5 - node C of figure 1.

 The storage consists of a foundation plate 1, toroidal tanks of the outer 2 and inner 3 tanks 4 and 5, formed by the walls of the toroidal tanks 2 and 3, the bottom 6 and the cover 7. Toroidal tanks 2 and 3 are made of metal outer and inner shells 8 and 9, space between which it is filled with concrete 10. The bottom 6 of the storage is made of the outer casing 11 connected to the outer casing 8 of the toroidal tank 2 by means of the outlet 12, the inner casing 13 and 13a connected to the outer casing 8 of the toroidal tanks 2 and 3 by starts 14 and 14a and concrete 10. The lid 7 of the tank is made similar to the bottom 6 and has an outer skin 15 with an outlet 16, inner skin 17 and 17a with outlets 18 and 18a and concrete fill 10. In the center of the storage and concentrically in diametrical directions in the tank 4 prefabricated pipe-concrete racks 19 are pivotally mounted with the possibility of their rotation in any direction relative to the axis of the hinge 20. In concrete along ducts of the bottom 6 and cover 7 in diametrical directions through the wall of the toroidal container 2 are passed channel generators 21 with prestress ennoy armature 22, which anchored in the outer skin 8 of the container 2 outside the toroidal store anchors 23 and 24. Anchors 23 (active) are tapered, and anchors 24 (passive) - in the form of spring damper. In the concrete of the concrete stand 19 through the cover 7, the bottom 6 and the base plate 1, prestressed reinforcement 22 is passed in the channel formers 21 and anchored on the outer skin of the cover 15 of the cover 7 with an anchor 23 and the bottom side of the foundation plate 1 using spring dampers 24. The channel former cavity 21 with pre tensioned reinforcement 22 is filled with lubricant 25 for the possibility of moving reinforcement during deformation of parts of the structure without breaks and maintaining the frame of the structure. To swivel the support stand 19 with the lid 7 on the last from the inside of the tank in diametrical directions, stiffeners 26 are made. In the concrete of the walls of the tanks 4 and 5 there are channel formers 27 in which the coupling elements 28 are passed through the cover 7, the bottom 6 and anchored on the outer lining 15 of the cover 7 with a wedge anchor 23 and the base plate 1 - damper anchor 24.

The storage is built as follows
The reinforced concrete foundation plate 1 is preformed. After the concrete has set strength, a metal sheet is laid out on the foundation plate - the outer skin 11 of the bottom 6, which has outlets around the circumference of the sheet. Then, formwork of toroidal containers 2 and 3 in the form of annular casing - outer 8 and inner 9 is collected on the sheet, channel formers 21 are fixed on it and reinforcement 22 is laid. Concrete walls of toroidal container 2 and 3 are concreted by injection of concrete mixture, for example, tensile concrete. Issues 12 of the casing 11 of the bottom 6 extend beyond the area of the toroidal capacity 2 to 1 / 3-1 / 4 of its outer diameter. On the lower outer sheathing 11 of the bottom 6, the channel formers 21 are fixed, laying them diagonally and connecting with the channel formers placed in the wall of the toroidal container 2, and the reinforcement 22 is passed through them, leaving the ends on the outer surface of the storage. Then, the inner casing 13 of the bottom 6 is installed, made in the form of a sheet with a size equal to the diameter of the tank 4 with the outlet 14 around the sheet circumference, and an annular sheathing sheet 13a of the bottom 6 with a width equal to the width of the tank 5 with the outlets 14a in inner and outer diameters. The outlets 14 and 14a of the casing 13 and 13a are bent and mated with the surface of the toroidal containers 2 and 3, welding them around the perimeter to the outer casing 8. Then concreting the bottom 6. In the center of the bottom 6 in the tank 5, in the diametrical directions of the storage in the tank 4 , in the locations of the channel formers 27 for the clamping elements 28 and the base plate 1, through holes for the passage of reinforcement are left. After the concrete has gained strength 6, prefabricated pipe-concrete racks 19 are installed with ball heads at the ends with reinforcement 22 passed through them, which is anchored on the bottom side of the foundation plate 1 and fastened with temporary ties at the top.

 After that, the lid 7 of the storehouse is mounted similarly to the bottom 6, concreting the stiffeners 26 at the locations of the support posts 19. After the lid 7 has been set with concrete, the rope fittings 22 are passed through the holes made in it, including the tie elements 28 and are pulled with a hydraulic jack to the specified value P and fix on the outer casing 15 of the cover 7. Then reinforce the fittings 22 of the cover 7 and the bottom 6, fixing it on the outside of the storage with anchors 23 and 24. After that, a lubricant, for example, solid oil, is pumped into the channel formers 21. The storage along the outer perimeter is deboned with soil 29.

With a total diameter of the storehouse of 100 m and diameters of the cavities of the tori of the inner 6 m and the outer 5 m, the storage capacity will be about 80,000 m ³ .

Sources of information
1. A. B. Rubinstein et al. "Pre-stressed monolithic reservoirs for petroleum products", magazine "Concrete and reinforced concrete" 1996, 6.

 2. Certificate 3504 for PM. Cl. G 21 F 9/22, BI 1, 1997; RF patent 2140512, class. E 04 H 7/00, BI 30, 10.27.99 (prototype).

 3. RF patent 2140512, cl. E 04 H 7/00, BI 30, 10.27.99 (prototype).

Claims (7)

 1. An earthquake-resistant monolithic reinforced concrete storage for environmentally hazardous materials, including a base plate, a tank located around the perimeter of the tank, a toroidal tank, a bottom and a cover, characterized in that the storage consists of concentrically placed toroidal tanks and tanks located inside the torus, bounded by the walls of the toroidal containers, lid and bottom, and the walls, bottom and lid of the store are pre-stressed with internal and external metal plating, while the inner lining of the bottom and the lid are paired with the outer lining of the toroidal containers, and the outer lining of the bottom and the lid are paired with the outer lining of the toroidal tank on the outside of the storage, channeling channels are placed in the lid and in the bottom and in the wall of the outer toroidal container, through which prestressed reinforcement is passed and anchored on the sheathing of the toroidal tank outside the store, and in the center of the store a prefabricated pipe-concrete supporting steel is pivotally mounted a pole with prestressed reinforcement passed through the cover, stand, bottom and base plate, and anchored on the cover and base plate.  2. Storage according to claim 1, characterized in that the storage consists of two concentrically arranged toroidal containers, while the diameter of the toroidal tank located outside is smaller than the diameter of the toroidal tank located inside.  3. Storage according to claim 1, characterized in that the storage is additionally equipped with pivotally mounted prefabricated pipe-concrete support racks concentrically located in the diametrical directions of the storage in each tank, with prestressed reinforcement passed through the lid, racks, bottom and base plate, and anchored on the lid and foundation plate.  4. Storage according to claim 1, characterized in that the prestressed reinforcement is anchored on the foundation plate and the sheathing of the toroidal capacity on one side of the storage using a spring damper.  5. Storage according to claim 1, characterized in that the storage lid on the inside of the tank has diametrically located stiffeners.  6. Storage according to claim 1, characterized in that vertical coupling elements are placed in the walls of the reservoirs in the channel formers, anchored on the lid and the base plate.  7. The storage facility according to claim 1, characterized in that the duct formers with prestressed reinforcement are filled with grease.

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