RU2273697C2 - Three-dimensional foundation platform connected to tank to form closed system to be built on weak, permafrost, heaving soil and in seismic zones (variants) - Google Patents

Abstract

FIELD: foundations for special purposes, particularly foundation platforms connected to tanks.

SUBSTANCE: reinforced concrete beams or trusses are installed between reinforced concrete panels of upper and lower belts of three-dimensional platform. Reinforced concrete beams or trusses have inclined upper face and are connected one to another in center by monolithic rigid core. The reinforced concrete panels have trapezoid or segmented shape in plane. Reinforced concrete beams or trusses with key connections are located in parallel between reinforced concrete panels of upper and lower belts. Tank walls and coverings have arched structure shaped as prismatic polyhedron inscribed in cylindrical surface defined by square parabola or another curve with generatrices parallel to beams or trusses of three-dimensional foundation platform.

EFFECT: increased structural efficiency due to increased reliability of three-dimensional foundation platform, reduced metal consumption and labor inputs.

2 cl, 9 dwg

Description

The invention relates to the construction of a spatial foundation platform, combined with a reservoir in a closed system, on weak, subsidence, heaving soils in seismic areas.

A well-known spatial foundation platform (see patent No. 2206665, M. class. 7 E 02 B 27/32, 27/34, 27/35, publ. BI No. 17, 2003), which includes interconnected by metal elements the upper and lower plates, the upper plate with the ribs down and the lower plate with the ribs up, are interconnected by a metal spatial truss with racks and braces with the formation of a single spatial structure for installation on the upper plate as on a common foundation platform of one or more tanks together with the pipes serving them plumbing and equipment. The dimensions of the bearing area of the spatial foundation platform are chosen larger than the dimensions of the bearing area of the foundation, the upper and lower plates together with the metal spatial sprengel form a blown underground ventilated in all directions, preventing heat exchange between the heated reservoir filler and permafrost soil.

In this spatial foundation platform, the presence of connections between the tank and the platform is not indicated, there is no closed structure. The use of metal elements in the platform for connecting the upper and lower plates requires special anti-corrosion measures. The use of reinforced concrete for these purposes will increase the reliability of the structure.

Known as a prefabricated building or a closed-type structure, including a foundation, for construction on permafrost, weak, heaving soils and in seismic areas (see RF patent No. 2215852, publ. BI No. 31, 10.11.2003). A building or structure includes walls, a coating and a foundation made of the same steel-reinforced concrete elements, each of which consists of reinforced concrete slabs and a metal reinforcing spatial truss, having a belt and braces, which are attached to embedded parts located in the corners or intermediate nodes of the reinforced concrete slabs. The foundation slabs are installed on the base and combined into a continuous slab over the area of the entire building. Floor slabs are laid on the truss knots with the formation of a room for the placement of technological equipment

This effective enclosed structure is not extended to reservoirs and its association (connection) with the platform, in addition, the use of only metal connections in the foundation requires certain anti-corrosion measures to increase durability. Replacing these bonds in whole or in part with reinforced concrete elements increases the durability of the proposed design.

Known prefabricated round silos with panels-shells of the flute type, the panels are equipped with end ribs, in the external grooves of which are placed prestressed annular reinforcement of the silo. The tension of this reinforcement is produced during the enlargement assembly of individual tier sections on a special stand, in which the internal strut of the section is created by compressed air. After tensioning, the reinforcement is protected with cement mortar applied by gunning (see the book Baykov V.N., Sigalov E.E. Reinforced concrete structures, general course, edition 4, revised., M., Stroyizdat, 1985, pp. 601-602 Fig. XYI.32).

However, the use of such structures for reservoirs was not found, including those combined with a spatial foundation platform. Reinforcing truss elements are not used.

Known prefabricated reinforced concrete tanks made of vertical reinforced concrete slabs, tightened by entrapment with a prestressed high-strength wire, protected by shotcrete.

Known rectangular reinforced concrete tanks, in which the walls are made in the form of plates, which can be the same in thickness, the coating of rectangular tanks is arranged ribbed or bezbalkochny. In round tanks, walls made of reinforced concrete with reinforcement have a trapezoidal section, broadening downward. The coating of round reinforced concrete tanks may be flat, ribbed or domed. The bottom of the tank, standing on the ground or dug into the ground, in most cases is flat (see the book by K.V. Sakhnovsky, Reinforced Concrete Structures, Gosstroyizdat, L.-M., 1939, p. 679 fig. 808 and p. 677 Fig. 802 and 803).

A significant drawback of these known reservoir designs is the separate (non-systemic) functioning of the reservoir itself and the foundation structure for it. Both of these parts (foundation and upper structure) work independently, which creates the unreliability of the structure in special soil conditions.

An equally significant drawback of the known construction of foundations for the construction of tanks in special soil conditions (weak, subsidence, heaving soils), especially in seismic zones, is their unreliability of work due to sensitivity to uneven precipitation that creates emergency situations. When building on permafrost soils, there are difficulties in maintaining their properties due to heat fluxes, especially for heated tanks. In seismic zones, the reliability and integrity of the reservoirs is not ensured, since seismic impacts on the buried part of the foundation create emergency situations: violent disturbances in the reservoir and uneven displacement of the base (including embankments).

The difference between the proposed invention and these reservoir designs is that a new feature is not created - a connection with the spatial platform with the formation of a closed structure that would work well on various types of soft soils; do not create conical bottoms (as in the first embodiment of the claims) and the arch-vaulted type tank according to the second embodiment of the claims proposed by the authors.

The closest technical solution, taken as a prototype, is a spatial foundation platform (see patent No. 2206665, M. class. 7 E 02 In 27/32, 27/34, 27/35, publ. BI No. 17, 2003) , which includes the upper and lower plates joined together by means of metal elements, the upper plate with the ribs down and the lower plate with the ribs up interconnected by a metal spatial truss with racks and braces to form a single spatial structure for installation on the upper plate as on a common foundation platform, one about or several tanks together with the pipelines and equipment serving them. The dimensions of the bearing area of the spatial foundation platform are chosen larger than the dimensions of the bearing area of the foundation, the upper and lower plates together with the metal spatial sprengel form a blown underground ventilated in all directions, preventing heat exchange between the heated reservoir filler and permafrost soil.

The disadvantages of this platform for reservoirs are some constructive mismatch between the use of rectangular plates in the foundation platform with the axisymmetric shape of the tank in plan, i.e. the load from the tank is transmitted as axisymmetric, and the design and structure of the platform are not. This violates the harmony of work (the correspondence between the load and the structure of the structure) and its unreliability. The proposed radial structure of the platform with a radial arrangement of bonds (beams or trusses) and segment (trapezoidal) plates eliminates this drawback, is more reliable and is an improvement of the prototype.

Another disadvantage of the prototype is the use of all ties sprengels made of metal, which requires certain anti-corrosion measures to increase durability. Replacing these metal bonds in whole or in part with reinforced concrete elements increases the durability of the structure. The prototype does not stipulate the possibility and expediency of combining the tank into a closed system, the possibility of creating a conical bottom. The proposed design is an improvement of the prototype, improves the reliability, reduce the metal structure. There are no effective solutions for construction in areas where special soil conditions and seismicity are combined.

The objective of the invention is to create an effective structure due to a more reliable spatial foundation platform made of reinforced concrete, combined with the tank in a closed structure suitable for construction on weak, permafrost, heaving soils, as well as in seismic zones with low labor costs and low metal consumption.

In order to improve the spatial foundation platform, in addition to replacing metal with reinforced concrete, there are two ways: either replace the bond structure with radial, as the authors propose in claim 1, or change the shape of the tank, adapt it to the parallel connection (arch-vaulted design proposed by the authors in the second claim).

The present invention consists of a spatial foundation platform, combined with the tank in a closed structure, for construction on weak, permafrost, heaving soils and in seismic zones, including combined upper and lower reinforced concrete slabs, reinforced concrete slabs can be ribbed and reinforced concrete slabs of the lower zone are installed ribs up on a flattened sealed base after removing the plant layer, and reinforced concrete slabs of the upper belt with ribs down,

moreover, the lower plate is installed without burial on the outer surface of the soil, the tank is installed on the upper plate together with the pipelines and equipment that serve them, the dimensions of the area of support of the spatial foundation platform are chosen larger than the dimensions of the area of support of the foundation structure, ventilated in all directions between the upper and lower plates a blown underground that prevents heat transfer between the heated reservoir filler and permafrost, thereby ensuring by direct its strength properties,

between the bottom plate and the base of the soil in seismic zones there is a sliding layer of materials with a low coefficient of sliding friction on the base, which reduces friction between the foundation platform and the base, shields are installed along the contour of the spatial foundation platform that are hermetically joined to the upper and lower plates and form a reserve tank for draining liquid from the tank in emergency situations, in the top plate holes are made to the lid for inspection and emergency filling containers formed by the bottom plate and shields, and in the shields installed supply and exhaust pipes for natural or forced ventilation, and

between the reinforced concrete slabs of the upper and lower zones of the spatial foundation platform, reinforced concrete beams or trusses are installed, located radially, which have an inclined upper face and are fastened in the center with a monolithic rigid core, and reinforced concrete slabs have a trapezoidal (or segment) shape in plan;

the reinforced concrete slabs of the upper belt of the spatial foundation platform laid along the inclined faces of reinforced concrete beams or trusses with a slope towards the center form a conical bottom of the reservoir structure,

reinforced concrete beams or trusses have key protrusions with inclined wedge-shaped faces, and reinforced concrete slabs of the upper and lower chords have recesses that include key protrusions of reinforced concrete beams or trusses, key protrusions and recesses can be reinforced with outlets of reinforcement, keys and joints between reinforced concrete beams and slabs monetized

cross connections between reinforced concrete beams or trusses are established,

the reservoir is made of steel-reinforced concrete elements, consisting of reinforced concrete slabs of a flat or curvilinear shape, with a curvilinear outline, the bulge is oriented inside the tank, supported by a spatial metal spreel; the tank is installed and attached to the spatial foundation platform; reinforced concrete slabs are connected to each other in nodes with the help of embedded parts, and sprengels - with longitudinal rods, sprengel belts can be prestressed,

in the circumferential direction, the spatial trusses of the steel-reinforced concrete slabs of the tank structure are connected by rods that can be prestressed, and in the vertical direction, the trusses with the help of additional rods form buttresses attached to the foundation platform, which can also be prestressed;

the spatial coating of the tank is formed from steel-reinforced concrete elements, rests on the walls of the tank and joins buttresses in a frame way,

Thus, the upper structure of the tank, coating, walls, conical bottom are attached to the foundation platform and forms a closed system.

And in the second embodiment, reinforced concrete beams or trusses are located between the reinforced concrete slabs of the upper and lower zones of the spatial foundation platform in parallel,

and the tank is made of an arch-vaulted shape in the form of a prismatic polyhedron inscribed in a cylindrical surface outlined by a square parabola or other curve, the generators of which are parallel to the beams or trusses of the spatial foundation platform, the walls and coatings are combined in an arched-vaulted structure, which is closed by the end walls of the flat or curved shape from steel-reinforced concrete elements

The proposed invention has reliable operation on weak, permafrost, heaving soils, as well as in seismic zones with low labor costs due to:

creating a closed coupled structure consisting of a foundation platform and a reservoir structure,

connection of spatial trusses of steel-reinforced concrete slabs of a tank structure in the circumferential direction and in the vertical direction, supported by buttresses;

reduction of metal consumption and increase of anticorrosiveness of the foundation structure by using instead of metal structures of trusses special reinforced concrete beams or trusses with the proposed reinforced concrete keyed joints with plates of the upper and lower zones in the integral spatial structure of the platform;

wedges of the keyway of reinforced concrete beams or trusses, which automatically ensures the reliability of compaction, and the inclined wedge-shaped faces of the protrusions during monolithic also provide reliable compaction;

connections of the spatial coating of the tank, which are based on the walls of the tank and connected in a frame way with buttresses. Both parts (the foundation and the upper structure, the coating of the tank) should be considered as an integral interconnected system in which the functions of the individual parts are combined and combined: for example, the foundation in the form of a continuous plate acts as the bottom of the tank and takes up spacer efforts, helping the upper structure - the tank, including frame cover design;

connection of key protrusions with inclined wedge-shaped faces of reinforced concrete beams with recesses in the upper and lower reinforced concrete slabs with reinforcement, connection of reinforced concrete beams with the core and monolithic not only the keys, but also the joints between the beams and the truss;

the execution of the conical bottom of the tank with a slope towards the center creates a more efficient design.

According to paragraph two of the claims, the design includes a modified structure of the spatial foundation platform due to the location of reinforced concrete beams or trusses in parallel forming the arch-vaulted shape of the tank, in which the coatings and walls of the tank are combined, which creates favorable working conditions for the entire closed structure. The proposed design, as in claim 1, is designed to work on soft, heaving, permafrost soils and in seismic zones.

The spatial foundation platform, combined with the tank in a closed structure, for construction on weak, permafrost, heaving soils and in seismic zones is presented in the drawings, where:

figure 1 is a General view of the spatial foundation platform, combined with the tank;

figure 2 is a General view of the spatial foundation platform during installation, the upper plates are partially conditionally removed;

figure 3 is a General view of the steel-reinforced concrete element of a rectilinear outline;

figure 4 is a General view of the steel-reinforced concrete element of a cylindrical shape, from which the walls of the channel-type reservoir are formed with the location of the reinforced concrete slabs convex inward and the outer arrangement of spatial metal trusses;

figure 5 is a General view of a steel-reinforced concrete beam with key projections;

figure 6 is a General view of the key node connecting the beam or truss with reinforced concrete slabs of the upper and lower zones of the foundation platform;

Fig.7 is a General view of the design of the spatial foundation platform, combined with a tank arch-vaulted type (without end parts);

on Fig is a fragment of the plan of the upper plates of the spatial platform with rectangular plates under the tank. The location of the keyed connections is indicated;

figure 9 is a variant of the shape of the arch-vaulted tank.

The spatial foundation platform 1 (see Fig. 1) is arranged solid for the entire structure or a larger area and consists of reinforced concrete slabs of the upper 2 and lower 3 belts with reinforced concrete beams 4 or trusses between them located radially (see Fig. 2) and fastened in the center a monolithic rigid core 5. Reinforced concrete slabs 2 and 3 can be ribbed; reinforced concrete slabs of the lower belt 3 are installed - with the ribs up on the aligned base, and reinforced concrete slabs of the upper belt 2 - with the ribs down. Reinforced concrete slabs of the upper belt 2 of the spatial foundation platform 1 are laid on the inclined faces of the reinforced concrete beams 4 or trusses, made inclined with a slope to the center and form a conical bottom of the tank 6 (see figure 2). Reinforced concrete beams 4 or trusses have key projections 7 (see Fig. 2.8) with inclined wedge-shaped faces, and reinforced concrete slabs of the upper belt 2 and lower belt 3 have recesses 8 (see Fig. 6), which include key projections 7 reinforced concrete beams 4 or trusses, key protrusions 7 and recesses 8 can be reinforced with the outlets of reinforcement 9 (see Fig. 5,6), the beams in the center are connected to a rigid core 5. Seams between reinforced concrete beams 4, reinforced concrete slabs 2 and 3 and rigid core 5 monolithic. Between the reinforced concrete beams 4 or trusses in the transverse direction, cross connections 10 are established (see figure 2).

Thus, a spatial slab-beam system is formed, providing spatial rigidity, and low sensitivity to uneven subsidence of the base due to rigidity and spatial redistribution of forces. The pressure on the foundation soil is small due to the large area of the spatial foundation platform 1.

The reservoir 6 is made of steel-reinforced concrete elements 11 (see Figs. 3 and 4), consisting of reinforced concrete slabs 12 of a flat or curved shape, with a curved shape, the bulge is oriented inward (see Fig. 5 a and b), and spatial metal trusses 13. The connection of spatial metal truss 13 with reinforced concrete slabs 12 is carried out using embedded parts 14 of reinforced concrete slabs 12. The tank 6 can be made together with pipelines and equipment serving them (not shown).

Steel-reinforced concrete elements 11 of a curved shape (see Fig. 5 b) consist of a reinforced concrete slab 12 with a bulge inward and a spatial metal truss 13 located outward.

In the circumferential direction, the spatial metal trusses 13 of the steel-reinforced concrete elements 11 of the tank 6 are connected by rods 15, which can be prestressed, and in the vertical direction, the spatial metal trusses 13 with the help of additional rods 16 form buttresses attached to the foundation platform 1.

The spatial coating 17 of the reservoir 6 is formed from steel-reinforced concrete elements 11, the coating 17 is supported on the walls of the reservoir structure 6 by a frame method and is attached to the buttresses 16.

The spatial foundation platform 1, combined with the reservoir structure 6, is installed on a level base with a sliding layer 18.

The outer truss 13 of the plates of the tank 6 together with the additional rods 16 form a continuous rod buttress system connected to the spatial foundation platform 1. In the upper part, the truss system is connected to the steel-reinforced concrete coating 17, forming a frame closed system of the coating, the walls of the tank and the spatial foundation platform 1 together with the bottom.

Outside, the spatial foundation platform 1 is closed by shields 19, forming a reserve capacity.

To ensure the impermeability of precast concrete tanks 6, the following technical solutions are used: lining from the inside with steel sheets 3-4 mm thick; inner lining with sheets of aluminum alloys or stainless steel; application of polymer coating tanks from the inside; shotcrete; the use of a tank integral "bag" of polymer films. Films can be made of a large number of grades used for tent and pneumatic structures (see the Handbook "Modern spatial structures (reinforced concrete, metal, wood, plastics), Moscow, Higher School, section 15" Soft shells ", 1991, p. 158-166) .The authors prefer the use of a one-piece tank bag.

The second version of the base platform with a tank arch-vaulted type (see Fig.7, 9).

Reinforced concrete beams 4 or trusses are located between the reinforced concrete slabs of the upper 2 and lower 3 zones of the spatial foundation platform parallel to the arch-vaulted shape of the reservoir 6. The reservoir 6 is made of steel-reinforced concrete elements 11 of the arch-vaulted shape in the form of a prismatic polyhedron inscribed in a cylindrical surface outlined in square a parabola or other curve, the generators of which are parallel to the beams 4 or trusses of the spatial foundation platform 1.

Between themselves, reinforced concrete slabs 12 are connected using embedded parts 14, and metal trusses 13 are connected in the circumferential direction by rods 15, truss belts can be prestressed.

Steel-reinforced concrete elements 11 are based on the walls of the tank 6 and are attached to the rods 16, which form buttresses.

The side walls of the spatial foundation platform are closed with shields 19, which create the possibility of placing various equipment in the foundation, placing pipelines.

In the second embodiment (Fig. 7, 9) reinforced concrete beams or trusses 4 with key connections 7 are located between the reinforced concrete slabs of the upper 2 and lower zones 3 of the spatial foundation platform 1 in parallel. The tank 6 is made arch-vaulted in the form of a prismatic polyhedron inscribed in a cylindrical surface, outlined by a square parabola or other curve, the generators of which are parallel to the beams 4 or trusses of the spatial foundation platform 1.

The walls and coatings of the tank 6 are combined in an arched-vaulted structure, which is closed by the end walls of a flat or curved shape from steel-reinforced concrete elements (not shown), and is generally attached to the spatial foundation platform 1 and together with it forms an integral rigid structure.

The spatial coverings 17 and the walls with the bottom, which is a common part of the reservoir 6 and the spatial foundation platform 1, are combined.

The end elements of the tank 6 can be assembled in the form of flat or curved walls from steel-reinforced concrete elements 11 (see Fig. 4), in the case of curved walls, a curved segment insert with an atypical steel and reinforced concrete element will be required. In the plates of steel-reinforced concrete elements 11 there can be small and large holes for technological needs.

The dimensions of the bearing area of the spatial foundation platform 1 are selected larger than the dimensions of the bearing area of the supra-basement structure. A ventilated underground ventilated in all directions is formed between the upper and lower plates, preventing heat exchange between the heated reservoir filler and permafrost, thereby ensuring its strength properties, a sliding layer of materials with a low coefficient of sliding friction is installed in the seismic zones between the bottom plate and the soil base on the base, reducing friction between the foundation platform and the base, along the contour of the spatial foundation platform Shields that are tightly docked with the upper and lower plates and form a reserve tank for draining liquid from the tank in emergency situations, openings can be made in the upper plate with a lid for inspection and emergency filling of the reserve tank formed by the lower plate and shields, and in shields Supply and exhaust pipes for natural or forced ventilation are installed.

The spatial foundation platform 1 is mounted with the reservoir 6 according to the first embodiment as follows.

Reinforced concrete slabs of the lower belt 3 are installed on a leveled base with a sliding layer. The keyways 7 of the reinforced concrete beams 4 or trusses are located in the recesses 8 between the reinforced concrete slabs of the lower belt 3, which are arranged radially to the center and fastened in the center with a monolithic rigid core 5.

Reinforced concrete slabs of the upper belt 2 of the spatial foundation platform 1 form a conical bottom of the reservoir structure 6 and are laid on the inclined faces of the reinforced concrete beams 4 or trusses with a slope towards the center.

The connection of reinforced concrete beams or trusses 4 with reinforced concrete slabs of the lower zone 2 is carried out using the releases of reinforcement 9.

Reinforced concrete slabs of the upper belt 2 are laid on reinforced concrete beams 4 or trusses, in the recesses 8 between which are key protrusions 7 of reinforced concrete beams 4 or trusses, additional connection is carried out using reinforcement 9.

Between reinforced concrete beams 4 or trusses in the transverse direction, cross connections 10 are established.

The reservoir 6 is made of steel-reinforced concrete elements 11, consisting of reinforced concrete slabs 12 of a flat or curved shape, with a curved shape, the bulge is oriented inward, and spatial metal trusses 13. The connection of spatial metal truss 13 with reinforced concrete slabs 12 is carried out using embedded parts 14 of reinforced concrete slabs 12.

The spatial metal trusses 13 of the steel-reinforced concrete elements 11 of the tank 6 are connected in the circumferential direction by rods 15, which can be prestressed, and in the vertical direction, the spatial metal trusses 13 with the help of additional rods 16 form buttresses and are attached to the foundation platform 1.

The spatial coating 17 of the reservoir structure 6 is formed from steel-reinforced concrete elements 11, which are supported on the walls of the reservoir structure 6 by a frame method and are attached to buttresses 16.

Thus, the upper structure of the tank (walls and coatings) are attached to the spatial foundation platform 1, forming a closed system.

The installation of the spatial foundation platform 1 according to the second claim is carried out in much the same way as the first claim, and the tank 6 is made in the form of an arched-vaulted structure and can be mounted in sections or by a hinged method.

A tank 6 of steel-reinforced concrete elements 11 is mounted with reinforced concrete plates 12 inward and outward with a metal spatial truss 13, forming an arch-vaulted coating (see Figs. 7, 8). Each section of the arch-vaulted structure is assembled by the method of building-up or as a whole. The sections are interconnected as follows: reinforced concrete slabs 12 in knots using embedded parts 14 (bolted or welded), and metal spatial trusses 13 longitudinal along the generatrix rods 15, trusses belts can be prestressed. End elements (not shown) of the tank 6 can be assembled in the form of flat or curved walls of steel-reinforced concrete elements. In the case of curved walls, a segment insert with atypical steel-reinforced concrete elements will be required. Slabs of steel-reinforced concrete elements can have small and large openings for technological needs.

When the design is working, the strut from the internal pressure of the tank 6 is perceived by its walls surrounded by strained metal belts and buttresses, partially transmitting the strut to the foundation platform. The pressure on the conical bottom is perceived by the entire spatial platform 1 and transmitted to the base in the form of a small pressure due to the large area of the platform 1. Possible uneven precipitation of the weak base is insensitive due to the multiply connected platform and its spatial rigidity. All this increases the reliability of the design. The sliding layer increases the seismic resistance of the entire structure.

The closedness of the entire system favorably contributes to the work of the entire structure: the spacer from the frame coating together with the fluid pressure in the tank is perceived by buttresses and the foundation platform as a spatial tightening, contributing to the work of the entire upper structure, facilitates its work and reduces metal consumption.

The horizontal rod elements of the trusses encircle the tank and, thanks to prestressing using shrink couplings (not shown) on the reinforced concrete slab elements, compress them and improve their work (reduce the tension caused by internal pressure). Thus, the whole structure as a whole is an effective spatial closed-loop system with multiplicity, increased rigidity and reliability, which allows it to be used in special soil conditions and seismicity.

Note that the parameters of the spatial foundation platform: plate thickness, beam height, their reinforcement, etc. are determined by calculations depending on the size of the tank. Experimental calculations and design solutions have shown the effectiveness of this design.

In KrasGASA, at the department "Structural Mechanics and Structural Management", a model of a spatial foundation platform with a reservoir of various structures was made.

Feasibility study:

- the proposed design of the spatial foundation platform, combined with the reservoir in a closed system, is designed to work on weak, permafrost, heaving soils and in seismic zones due to the large area of the spatial foundation platform, creating a closed system;

- insensitive to uneven precipitation in seismic regions and due to the device of the sliding layer;

- has increased reliability due to the creation of a closed system, the connection of spatial trusses of steel-reinforced concrete slabs of the tank structure in the circumferential direction and in the vertical direction, the execution of the conical bottom of the tank with a slope towards the center allows more reliable and efficient operation of the tank tank; the connection of the key ledges with the inclined wedge-shaped faces of the reinforced concrete beams with recesses in the upper and lower reinforced concrete slabs with reinforcement, providing a holistic spatial work of the foundation structure and the entire system;

- low metal consumption due to the introduction of reinforced concrete beams.

Both parts (foundation and upper structure) should be considered as an integral interconnected system in which the functions of the individual parts are combined and combined: for example, a foundation in the form of a continuous plate performs the functions of the bottom of the tank and takes up spacer efforts, helping the upper structure - the tank, including the frame structure coverings.

The connection of the plates of the upper and lower zones of the spatial foundation platform by means of deepening them and the key protrusions of reinforced concrete beams or trusses with the formation of the spatial one provides rigidity in two directions and low sensitivity to uneven settlement of the base due to rigidity and spatial redistribution of forces.

Advantages of the construction according to claim 2 of the formula are basically similar to paragraph 1 and, in addition, the formed closed structure according to paragraph 2 of the claims of the arch-vaulted form of the reservoir structure together with the foundation platform is very structurally efficient in terms of material consumption and labor costs for erection and operation and can be used in difficult ground conditions insensitive to uneven precipitation in seismic regions, for which the device provides a sliding layer as in the prototype.

This type of tank can also be used to store not only liquid, but also bulk materials (while the transport equipment is located in the inter-foundation space). Note that the explosion and fire resistance of both types of steel-reinforced concrete tanks is higher than similar metal ones.

Literature

1. Spatial foundation platform, patent No. 2206665, M.cl. 7 E 02 B 27/32, 27/34, 27/35, publ. BI No. 17, 2003 (prototype).

2. A prefabricated building or a closed structure, including a foundation, for construction on permafrost, weak heaving soils and in seismic areas, RF patent No. 2215852, publ. BI No. 31, November 10, 2003).

3. Reference book “Modern spatial structures (reinforced concrete, metal, wood, plastics), M.,“ Higher School ”, Section 15“ Soft shells ”1991, p.158-166).

4. K.V. Sakhnovsky, Reinforced Concrete Structures, Gosstroyizdat, L.-M., 1939, p. 679 fig. 808 and p. 677 fig. 802 and 803).

5. Baykov V.N., Sigalov Z.E., Reinforced concrete structures. General course, textbook for universities, 5th edition, M., Stroyizdat, 1991. p. 604-605).

6. Reference book “Modern spatial structures (reinforced concrete, metal, wood, plastics), M., Higher School, section 15“ Soft shells ”, 1991, p. 158-166.

Claims (2)

1. The spatial foundation platform, combined with the tank in a closed structure, for construction on weak, permafrost, heaving soils and in seismic zones consists of combined upper and lower reinforced concrete slabs, reinforced concrete slabs are installed upside down on a leveled compacted base after removing the plant layer and reinforced concrete slabs of the upper zone - with the ribs down, the lower plate being installed without deepening on the outer surface of the soil, a cut is installed on the upper plate together with the pipelines and equipment serving them, the dimensions of the bearing area of the spatial foundation platform are chosen larger than the dimensions of the bearing area of the foundation, between the upper and lower plates a ventilated underground is ventilated in all directions, preventing heat exchange between the heated filler of the tank and the permafrost, which prevents thawing of permafrost soil and ensures its strength properties in seismic zones between the lower pl A sliding layer of materials with a low coefficient of sliding friction, which reduces friction between the foundation platform and the base, is installed on the base and the base; shields are installed along the contour of the spatial foundation platform, which are hermetically joined to the upper and lower plates and form a reserve tank for draining liquid from the tank emergency situations, in the top plate holes with a cover are made for inspection and emergency filling of the reserve capacity, supply and exhaust are installed in the shiites pipes for natural or forced ventilation, characterized in that between the reinforced concrete slabs of the upper and lower zones of the spatial foundation platform, reinforced concrete beams or trusses are radially installed, which have an inclined upper face and are fastened in the center with a monolithic rigid core, and reinforced concrete slabs have a trapezoidal or segmented plan shape, along the inclined faces of reinforced concrete beams or trusses with a slope to the center, reinforced concrete slabs of the upper belt of the spatial base plate are laid we, which form the conical bottom of the tank structure, reinforced concrete beams or trusses have key protrusions with inclined wedge-shaped faces, and reinforced concrete slabs of the upper and lower chords have recesses that include key protrusions of reinforced concrete beams or trusses, key protrusions and recesses are reinforced with valve outlets, keys and the joints between reinforced concrete beams and slabs are monolithic, cross connections are established between reinforced concrete beams or trusses in the transverse direction, the tank is made of steel reinforced concrete elements consisting of reinforced concrete slabs of a flat or curved shape, supported by a spatial metal spreel, with a curved outline of the slabs, their convexity is oriented inside the tank, in the circumferential direction, the spatial trusses of the steel-reinforced concrete slabs of the reservoir structure are connected by rods that are prestressed, and in the vertical direction by the spindles the rods form the buttresses attached to the foundation platform, which also are strained, the spatial coating of the tank is formed of steel-reinforced concrete elements, rests on the walls of the tank and is attached to the buttresses in a frame way, the tank is mounted and attached to the spatial foundation platform, thus the tank’s upper structure, coating, walls, conical bottom are attached to the foundation platform and form a closed system . 2. The spatial foundation platform, combined with the tank in a closed structure, for construction on weak, permafrost, heaving soils and in seismic zones consists of combined upper and lower reinforced concrete slabs, reinforced concrete slabs are installed upside down on a leveled compacted base after removing the plant layer and reinforced concrete slabs of the upper zone - with the ribs down, the lower plate being installed without deepening on the outer surface of the soil, a cut is installed on the upper plate together with the pipelines and equipment serving them, the dimensions of the bearing area of the spatial foundation platform are chosen larger than the dimensions of the bearing area of the foundation structure, a ventilated underground ventilated in all directions is formed between the upper and lower plates, preventing heat exchange between the heated filler of the tank and the permafrost, which prevents thawing of permafrost soil and ensures its strength properties in seismic zones between the lower pl A sliding layer of materials with a low coefficient of sliding friction, which reduces friction between the foundation platform and the base, is installed on the base and the base; shields are installed along the contour of the spatial foundation platform, which are hermetically joined to the upper and lower plates and form a reserve tank for draining liquid from the tank when emergency situations, in the top plate holes with a cover are made for inspection and emergency filling of the reserve capacity, supply and exhaust are installed in the shiites pipes for natural or forced ventilation, characterized in that reinforced concrete beams or trusses with key connections are located parallel between the reinforced concrete plates of the upper and lower zones of the spatial foundation platform, the walls and coatings of the tank form an arch-vaulted shape in the form of a prismatic polyhedron inscribed in a cylindrical surface, delineated by a square parabola or other curve, the generators of which are parallel to the beams or trusses of the spatial base plate the end walls, flat or curved, made of steel-reinforced concrete elements, close the end walls, the arch-vaulted design of the tank, the tank structure is attached to the spatial foundation platform and together with it forms an integral closed structure.

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