RU2180033C2 - Earthquakeproof monolithic concrete storehouse - Google Patents

Abstract

FIELD: civil engineering, in particular erection of reservoirs for storage of ecologically dangerous materials such as radioactive and toxic waste, petroleum and petroleum products positioned in seismodangerous regions. SUBSTANCE: the storehouse has a reservoir confined by the bottom and cover and positioned around the edges of its toroidal capacity. The reservoir is formed by the wall of the capacity of the internal side of the tore, the storehouse wall, cover and bottom are made with prestressed internal and external metal casings, and the internal casings of the bottom and cover conjugate to the external metal casings, and the internal casings of the bottom and cover conjugate to the external side of the tore, duct formers are laid in the cover and wall and in the bottom and wall in the diametrical directions, prestressed reinforcement is passed through them and anchored on the casing of the toroidal capacity from the outside of the storehouse, and a built-up concrete pipe support post with a prestressed reinforcement passed through the post, cover, bottom and the foundation plate, and anchored on the cover and foundation plate is mounted in the center of the storehouse. EFFECT: enhanced earthquakeproofness of the structure at an optimum use of the area of the building and reduced specific consumption of materials. 4 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.

 Storage facilities for petroleum products are known 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.

 Storage facilities for environmentally hazardous products in the form of reinforced concrete prestressed toroidal shells are known (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 a cylindrical tank (3).

 The disadvantages of the known storage design is low seismic resistance due to the presence of right angles in the cylindrical tank.

 The technical problem is to increase the earthquake resistance of the structure 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 in an earthquake-resistant monolithic concrete storage for environmentally hazardous materials, including a base plate, a tank limited by a bottom and a lid, and a toroidal container located around the perimeter of the tank, according to the invention, the tank is formed by a wall of a toroidal capacity of the inner side of the torus, wall, cover and the bottom of the storage are pre-stressed with internal and external metal cladding, while the inner cladding of the bottom and lid is paired s with the outer sheathing of the toroidal container on the inner side of the torus, and the outer sheathing of the bottom and the lid are paired with the outer sheathing of the toroidal capacity on the outer side of the torus, moreover, channel generators are laid in the lid and wall and in the bottom and wall of the torus 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 support post with prestressed reinforcement, missing, is pivotally mounted Erez, a cover, a rack, the bottom and the floor slab and anchored on the cover and base plate. At the same time, channel generators with prestressed reinforcement are filled with grease. 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, and the store cover on the inside of the tank has diametrically located stiffeners.

 The difference of the proposed design lies in the fact that the reservoir is formed by the wall of the toroidal capacity of the inner side of the torus, the wall, lid and bottom of the storage are pre-stressed with internal and external metal casing, while the inner casing of the bottom and lid are associated with the outer casing of the toroidal capacity on the inner side of the torus and the outer casing of the bottom and lid are associated with the outer casing of the toroidal container on the outer side of the torus, and in diameter in the lid and wall and in the bottom and wall In these directions, channel formers were laid, through which prestressed reinforcement was passed and anchored to the sheathing of the toroidal container outside the store, and in the center of the store, a prefabricated reinforced concrete support column with prestressed reinforcement passed through the lid, rack, bottom and base plate and anchored on the lid was pivotally mounted and foundation plate. At the same time, channel generators with prestressed reinforcement are filled with grease, and prestressed reinforcement is anchored on the foundation plate and the sheathing of the toroidal tank on one side of the storage using a spring damper. At the same time, channel generators with prestressed reinforcement are filled with grease.

 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 cover, and a pivotally mounted support post, and the possibility of a monolithic construction of a structure while reducing material consumption and connecting its parts using location It prestressing in the wall and the cover wall and in the bottom and fastened to the outer surface of storage, as well as compounds skins of the bottom and lid to the outer skin of the toroidal vessel. At the same time, 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.

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

 The storage consists of a foundation plate 1, a toroidal tank 2 and a tank formed by a wall 3 of a toroidal tank 2, a bottom 4 and a cover 5. The toroidal tank 2 is made of metal outer and inner casing 6, 7, the space between which is filled with concrete 8. The bottom 4 of the tank made of the outer skin 9 connected to the outer skin 6 of the toroidal tank 2 by means of the outlet 10, the inner skin 11 connected to the outer skin 6 of the toroidal tank 2 by the release of 12 and concrete 8. The cover 5 of the reservoir flax similarly to the bottom 4 and has an outer casing 13 with an outlet 14, an inner casing 15 with an outlet 16 and concrete filling 8. In the center of the storage, a precast concrete column 17 is pivotally mounted with the possibility of its rotation in any direction relative to the hinge axes 18. In concrete along the casing of the bottom and lids in diagonal directions through the wall 3 of the toroidal tank 2 are passed channel generators 19 with prestressed reinforcement 20, which is anchored on the outer skin 6 of the toroidal tank 2 outside the storage with anchors 21 and 22. Anke Rails 21 (active) are made wedge-shaped, and anchors 22 (passive) in the form of spring dampers. In the concrete of the concrete stand 17 through the cover 5, the bottom 4 and the base plate 1, prestressed reinforcement 20 is passed in the channel formers 19 and anchored on the outer casing 13 of the cover 5 with an anchor 21 and the bottom side of the foundation plate 1 using spring dampers 22. The channel former cavity 19 with pre tensioned reinforcement 22 is filled with grease 23 for the possibility of moving reinforcement during deformation of parts of the structure without breaks and preserving the frame of the structure. To swivel the support post 17 with the cover 5 on the last from the inside of the tank in diagonal directions made stiffeners 24.

 Storage is constructed as follows.

 The reinforced concrete foundation plate 1 is pre-formed. After the concrete has set strength, a metal sheet is laid out on the foundation plate - the lower skin of the bottom, which has outlets on the exterior of the sheet. Then, the formwork of the toroidal capacity is collected on the sheet in the form of ring shells of the external and internal, channel formers are fixed on it and the fittings are laid. Concrete the walls of the toroidal container by injecting a concrete mixture, for example, tensile concrete. Outlets of the bottom sheathing extend beyond the area of the toroidal capacity by 1 / 3-1 / 4 of the outer diameter of the toroidal capacity. The channel formers are fixed on the lower outer skin of the bottom, laying them diagonally and joining with the channel formers placed in the torus wall, and the fittings are passed through them, leaving the ends on the outer surface of the store. Then install the inner lining of the bottom, made in the same way as the outer lining with releases. The outcrops of the casing are bent and mated with the surface of the toroidal container, welding them around the perimeter to the outer casing of the toroidal container, the inner one from the inside of the torus, the outer one from the outside of the storage. Then carry out concreting of the bottom. A through hole is left in the center and foundation plate for the passage of reinforcement. After the concrete has gained strength, a prefabricated pipe-concrete stand is installed with spherical heads at the ends and fittings passed through it, which are anchored on the underside of the foundation slab 22 and fastened with temporary ties at the top.

 After that, the storage cover is mounted similarly to the bottom. After the concrete has set the strength cap, the reinforcement is passed through the hole made in the cap, tightened with a hydraulic jack to a predetermined value of P and fixed to the outer skin of the cap. Then the reinforcement of the cover and the bottom is prestressed, fixing it on the outside of the storage with anchors 21 and 22. After that, a lubricant, for example, solid oil, is pumped into the channel formers.

The toroidal capacity with a diameter of 50 m and a diameter of the actual cavity of the torus of 6 m has a capacity of about 5,000 m ³ , and inside the torus a tank of about 10,000 m ³ . Thus, the storage capacity is increased to 15,000 m ³ .

Sources of information
1. A. B. Rubinstein and others. "Pre-stressed monolithic tanks for petroleum products", the magazine "Building Constructions" 1998, p. 6.

 2. Certificate 3504 for PM. Cl. G 21 F 9/22, BI 1, 1997

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

Claims (4)

 1. An earthquake-resistant monolithic concrete storage for environmentally hazardous materials, including a base plate, a tank limited by a bottom and a lid, and a toroidal tank located around the perimeter of the tank, characterized in that the tank is formed by a toroidal wall of the inner side of the torus, the wall, lid, and bottom of the storage are made prestressed with inner and outer metal claddings, while the inner shells of the bottom and the lid are paired with the outer cladding of the toroidal tank with the inside on the front side of the torus, and the outer casing of the bottom and the lid are connected with the outer casing of the toroidal container on the outer side of the torus, moreover, channel formers are laid in the lid and wall and in the bottom and wall in diametrical directions, through which prestressed reinforcement is passed and anchored on the casing of the toroidal container from the outside storage, and in the center of the storage, a prefabricated pipe-concrete support column with pre-stressed reinforcement passed through the lid, rack, bottom and base plate is pivotally mounted anchored on the cover and base plate.  2. Storage according to claim 1, characterized in that the channel generators with prestressed reinforcement are filled with grease.  3. 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.  4. Storage according to claim 1, characterized in that the storage lid on the inside of the tank has diametrically located stiffeners.

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