RU59650U1 - SEISMIC RESISTANT SMALL BUILDING, STRUCTURE - Google Patents

Abstract

A useful model of an earthquake-resistant low-rise building, structure refers to the construction, namely, to the construction of low-rise buildings and structures erected in seismic areas under difficult ground conditions.

The problem solved by the utility model is to increase the seismic resistance of the buildings and structures being built, simplify the construction of the foundation, and reduce labor costs in its manufacture.

The problem is achieved by the fact that in the inventive device, including the upper structure of the external and internal longitudinal and transverse load-bearing walls, the coating, foundation and the underground part according to the utility model, the upper structure and the foundation are connected by firmly constructive bonds in a single closed system, while the foundation is made in the form of an unfilled continuous foundation platform, consisting of the upper, combined with the floor of the first floor of the building, structure, and lower reinforced concrete slabs, interconnected systems th cross beams, the space between them is filled with heat insulation material, such as expanded clay, slag, and the space between the platform and the base is aligned with the sliding layer made of several layers of polymer film, e.g., polyethylene prosypkoy inert material such as sand. In the foundation platform there are hatches with covers for lowering into the underground part of the building, structures, and underground passageways and semi-passageways for laying communications that do not have strong ties with the platform are buried under the ground. Flexible joints are introduced into the joints between communication pipes and entrances to the building and structure. The underground part has its own foundations, walls and floors.

1 P.F., 1 ill.

Description

The utility model relates to construction, namely, to structures of low-rise buildings and structures erected in seismic regions under difficult ground conditions.

The known construction of the foundation of an earthquake-resistant building (see patent for invention No. 1774976, E 02 D 27/34, BI 3 41, 1992, p.223), including a plate placed with a gap partially filled with loose material relative to the ground surface, supports with a curved surface, the upper and lower parts of which are respectively located in the recesses of the plate and compacted soil, and elastic gaskets between the plate and the supports, while the foundation is equipped with additional supports with a curved surface placed on the ground surface between the main with oval supports. The slab is made of two layers, the lower of which has less strength than the upper one and is made of concrete of class B 3,5-VY, the recesses in the slab are located within the lower layer, and the depth of placement of the supports in the ground and the degree of compaction of the soil under the supports are equal, respectively the deepening of the supports and the degree of compaction of the soil achieved from the settlement of the building, the structure when placing its supports on uncompacted soil, and the maximum vertical diameter d of the additional supports is determined from the ratio:

d = D- (h ₃ + f _oc ),

where: D is the maximum vertical diameter of the main supports;

h ₃ - the depth of incorporation of the main supports in the base plate;

f _OS - the estimated draft of the building, structure.

This foundation has the following disadvantages:

- the foundation is not fixed with the upper structure - a building with self-supporting brick walls and does not form a closed spatial system, which allows the building to work well with seismic effects;

- natural boulders of various shapes are used as supports, which do not provide foundation displacement and thereby do not reduce the effect of horizontal seismic forces;

- the foundation design does not suppress horizontal seismic forces;

The construction of an earthquake-resistant foundation of a building with brick walls is known (see the article by Yu.A. Shishkov “Earthquake-resistant foundations for Kot-Agach”, magazine “Design and Construction in Siberia” No. 3, 2004).

External walls (from any materials, preferably from wooden beams) resting on a strapping belt around the perimeter of the building using metal. The belt together with metal beams and wooden or prefabricated metal floor slabs form a hard drive at the floor level of the first floor. When using brick walls, the strapping belt is made of monolithic reinforced concrete with reinforced longitudinal reinforcement and transverse reinforcement from clamps working for torsion. The foundation racks are provided from steel pipes 1.2-1.4 m high and about 30 cm in diameter. In turn, the racks are supported by a beam-type foundation along the outer contour and columnar (pipe-concrete) foundations for internal supports. The shoes of the foundations are based on an artificial base - seismic isolating

a pillow about 20-40 cm thick made of gravel sand (or coarse or medium-sized sand) with the inclusion of small rolled boulders approximately 10 (15) to 20 (30) cm in size. Two layers of a polymer film ZASCH “Techpolymer” are laid dry on top of a seismic insulating pillow "1-2 mm thick, which prevents the penetration of cement milk into the sand and provides a decrease in the friction force when slipping shoes in case of seismic effects. This foundation design provides a reduction in seismic impact of approximately 2 points.

The disadvantages of such a foundation include:

- the buried underground part of the building and the upper structure are interconnected only at separate points, using columns for this, which helps to increase horizontal seismic effects on the building, thereby reducing its seismic stability;

- the absence of a rigid, unchanged in the horizontal plane of the foundation contour of the foundation tapes, struts and shoes for the inner columns, thereby reducing the seismic stability of the building;

- the construction of the foundation is difficult to manufacture, labor intensive. The problem solved by the utility model is to increase the seismic resistance of the buildings and structures being built, simplify the construction of the foundation, and reduce labor costs in its manufacture.

This object is achieved in that an earthquake-resistant low-rise building, a structure including a top structure of external and internal longitudinal and transverse load-bearing walls, a coating, foundation and underground part, in which the upper structure and foundation are connected by firmly constructive connections to an integral closed spatial system such as a box or spatial framework, while the foundation is made in the form of a solid foundation, not buried in the ground

spatial platform, consisting of upper and lower slabs, fastened together by cross beams, between which there are voids, while the upper slabs are aligned with the floor of the first floor of the building, and the space between them is filled with insulation, such as expanded clay, in addition, between the spatial platform and the aligned the base is a sliding layer made, for example, of several layers of a polymer film, for example, polyethylene, with inert material sprinkling, under the foundation platform or near its distribution the basement and underground passageways and semi-passageways for laying communications are autonomously laid in the ground, hatches with covers for lowering into the underground part of the building are placed in the foundation platform, and the basement, underground passageways and semi-passageways for laying communications do not have strong ties with the spatial platform, have own foundations, walls and ceilings, joints between pipes in channels and entrances to the house are provided with flexible inserts that do not interfere with possible small mutual displacements, the underground part It has its own foundations, walls and floors.

Distinctive features from prototypes are:

- the upper structure and the foundation are connected by firmly constructive ties in the form of rigidly fixed columns of the inner building of the building at the nodes of intersection of the internal ribs of the platform;

- due to the reduction of horizontal seismic effects by at least 2-3 points, the sections of the metal frame of the upper structure are reduced, thereby saving metal, increasing safety;

- the foundation is made in the form of an unfilled solid foundation platform, consisting of an upper, combined with the floor of the first floor of the building, and lower reinforced concrete slabs fastened together by a system of cross beams;

- the space between the plates and beams is filled with a sealant, for example, expanded clay, slag;

- between the spatial platform and the leveled base there is a sliding layer made of several layers of a polymer film, for example, polyethylene with sprinkling with an inert material, such as sand;

- hatches with covers for lowering into the underground part of the building are placed in the foundation platform;

- the spatial foundation platform preserves natural conditions without creating artificial underground inclusions creating a concentrated screen (obstacle) for the passage of seismic waves;

- a spatial foundation platform under a closed building is acceptable for seismic areas with difficult soil conditions, including on permafrost soils (ventilated underground), which take place, for example, in seismically active areas of Gorny Altai, i.e. seismic combined with permafrost;

- Under the foundation platform, underground passageways and semi-passageways for laying communications that do not have strength ties with the platform are buried in the ground;

- in the junction between the pipes of communications and inputs to the building, structure introduced flexible inserts;

- the underground part has its own foundations, walls and floors.

The spatial multiplicity of the upper structure in the form of a low-rise building with a foundation platform provides strength properties with vertical seismic shocks. The increased bending stiffness of the foundation platform, working in conjunction with the upper structure, prevents emergency situations due to

subsidence, buckling and other uneven displacements of the base in seismic areas under difficult ground conditions.

Filling the interfoundation space with a heater, for example, expanded clay, slag significantly reduces the heat loss of the building through the foundation and protects the base soil from frost heaving. A sliding layer in the form of several layers of a polymer film between the foundation platform and the leveled base reduces friction between them, while the sliding layer reduces the effect of horizontal seismic forces of any direction (longitudinal, transverse, twisting) on the platform and on the entire building, structure.

Devices with the claimed combination of distinctive features in the patent and scientific literature are not found.

The device is illustrated by figures, where figure 1 shows a cross section of a building.

An earthquake-resistant low-rise building, structure 1 includes the upper structure 2 of the outer 3 and inner 4 longitudinal and transverse load-bearing walls, cover 5, foundation 6, made in the form of a spatial foundation platform, and the underground part 7.

The upper structure of the earthquake-resistant low-rise building 1 and the foundation 6 are connected by firmly constructive ties 8 to a solid closed spatial system such as a box or spatial frame. The foundation 6 is made in the form of a solid foundation platform, not buried in the ground, consisting of the upper 9, combined with the floor of the first floor of building 1 and the lower reinforced concrete slabs 10, fastened together by cross beams 11, between which there are voids. The upper plates 9 are combined with the floor of the first floor of the building, and the space between them is filled with insulation, for example, expanded clay.

Between the foundation in the form of a spatial platform 6 and the aligned base 12 is a sliding layer 13.

The sliding layer 13 is made, for example, of several layers of a polymer film, for example, polyethylene, with sprinkling inert material.

In the foundation platform 9, hatches 14 with covers for lowering into the underground part of building 1 are placed.

Under the foundation platform 9 or near it, underground passageways and semi-passageways 15 are located autonomously in the ground for laying communications, which do not have strength ties with the foundation 6, made in the form of a spatial foundation platform, and the basement 16. The passage and semi-passage channels 15 and the basement 16 have own foundations, walls and ceilings, the junction between the pipes in the channels and entrances to the house are provided with flexible inserts that do not interfere with possible small mutual displacements.

The device is constructed as follows:

The underground part 7, made of basement 16 and underground passageways or semi-passageways 15 for laying communications, is pre-buried in the ground. Then a sliding layer 13 is formed, which is made of several layers of a polymer film, for example, polyethylene, with sprinkling with an inert material, for example, sand.

A foundation 6 is installed on the sliding layer 13, made in the form of an unfilled solid foundation platform, consisting of the upper 9, combined with the floor of the first floor of building 1 and the lower reinforced concrete slabs 10, fastened together by a system of cross beams 11, the space between which is filled with insulation.

A low-rise building 1 is installed on the foundation, which is connected by firmly constructive ties 8 into a one-piece closed box.

The base platform is equipped with hatches 14 with covers for the descent into the underground part of building 1.

The proposed utility model has increased seismic resistance, a simplified foundation design and can reduce labor costs in its manufacture.

Claims (1)

An earthquake-resistant low-rise building, a structure comprising a top structure of external and internal longitudinal and transverse load-bearing walls, a coating, a foundation and an underground part, characterized in that the upper structure and the foundation are connected by firmly constructive ties into an integral closed spatial system such as a box or spatial frame, in this case, the foundation is made in the form of a continuous foundation spatial platform not buried in the ground, consisting of an upper and lower plate, cross-linked together beams, the space between them is filled with insulation, for example expanded clay, while the upper plates are aligned with the floor of the first floor of the building, in addition, between the spatial platform and the leveled base there is a sliding layer made, for example, of several layers of a polymer film, for example polyethylene, with inert material sprinkling, a basement and underground passageways and semi-passageways for laying communications, in a foundation platform, are independently located in or near the foundation platform in the ground; hatches with covers for lowering into the underground part of the building are placed, and the basement, underground passageways and semi-passageways for laying communications do not have strong ties with the spatial platform, have their own foundations, walls and ceilings, joints between pipes in the channels and entrances to the house are provided with flexible inserts that do not interfere with possible small mutual displacements.