RU64650U1 - SPATIAL FUNDAMENTAL PLATFORM FOR BUILDINGS AND CONSTRUCTIONS FOR CONSTRUCTION ON WEAK, LOWING, EMBEDDED SOILS AND IN SEISMIC ZONES - Google Patents

Abstract

The utility model "Spatial foundation platform for buildings and structures for construction on weak, subsidence, heaving soils and in seismic zones" refers to the construction of buildings and structures on weak, subsidence soils, as well as in seismic zones.

The problem solved by the proposed utility model is to increase the reliability of a building or structure by creating favorable conditions for the operation of soft soils and increased seismic stability in seismic zones.

The task is achieved due to the fact that the spatial foundation platform for buildings and structures for construction on weak, subsidence, heaving soils and in seismic zones, containing thin reinforced concrete foundation slabs of continuous cross section, located one above the other, fastened together by cross reinforced concrete beams, the space between with which it is filled with a heater, for example, expanded clay, with the upper structure the spatial foundation platform is rigidly connected and forms a closed building, with the third perimeter foundation platform is rigidly connected to the “wall in soil” reinforced concrete panels buried in the ground, while an air gap is made around the buried reinforced concrete panels in the form of a “wall in the ground” or backfill is made from soft soil instead of the gap, and between its opposite walls in the ground there is a tension device.

Description

The utility model relates to the construction of buildings and structures on weak subsidence soils, as well as in seismic zones.

It is known that weak soils adversely affect strength and deformability, especially the seismic stability of buildings and structures. The reason here is that under static and especially under seismic influences (including vibrations), weak soils are squeezed out from under the foundation, settle, crack, etc., i.e. have an additional negative effect on the foundation and the upper structure of the building. The standards recommend strengthening the soil in different ways, using piles, etc., and in seismic areas, at the same time, increase the magnitude of seismic impacts compared to building on “good soils”. Behind this, obviously, lies the desire to overcome the uncertainties of the seismic effect on soft soils and on their impact on the building (structure). This uncertainty is a kind of "black box", revealing the hidden patterns of which are not yet possible. But if such a direct path is not feasible, then there is another workaround that helps at least reduce (smooth out) the negatives. The idea of this option is that the foundation design for the building and the base-foundation-top structure system not only strengthen the structure being built, but at the same time strengthen the soil itself or create more favorable conditions for the soil and help reduce seismic effects on foundation and top structure.

For construction on soft soils, the foundations constructed by the “wall in soil” method are known. The arrangement of underground structures using the “wall in soil” method consists in the development of trenches in the soil with vertical slopes using clay mortar for their fastening and the subsequent filling of trenches with monolithic concrete or prefabricated reinforced concrete elements. Designs of a closed form and an open form can be used as foundations for supports of any shape and size in plan. The minimum dimensions in terms of such foundations along the outer contours are determined by the dimensions of the sections of the supports. At the top, the foundations are overlapped by distribution plates (as in massive lowering wells, over which the supports are erected (see E.V. Kosterin. Foundations and foundations. M: Higher. School. 1990, p. 363-362).

The disadvantages of this design is that it does not constitute a closed building with the foundation and supra-foundation parts. In addition, the construction "wall in the ground" is not used in the structural composition with slab foundations and does not create favorable conditions for the work of soil under the slab and is only in cramped conditions of transverse deformations. In the proposed utility model, the soil is compressed by the foundation plate and is in cramped conditions for lateral deformation of the soil mass, which allows you to create an effective design. Around the “wall in the ground” it is not practical to leave an air gap or to make a “soft backfill” of the gap, which reduces the effect of soil compaction. In the proposed utility model, due to the rigid connection to the spatial foundation platform along the contour, such an opportunity is created and the design becomes effective under seismic influences.

Known prefabricated spatial reinforced concrete foundation platform for the construction of buildings in special soil conditions and seismicity (patent No. 38789, 7 E02D 27/32, 27/34, 27/35 publ. July 10, 2004 Bull. No. 19), including interconnected upper and lower plates, the lower plate is installed without recesses on the outer surface of the soil with the device

a sliding layer, between the upper and lower plates a ventilated underground ventilated in all directions is formed, the plates of the upper and lower zones are interconnected by reinforced concrete trusses diagonal or dividing or beams that have key protrusions that enter the recesses of the upper and lower plates, the seams between the plates or trusses and all keyed connections are monolithic, and embedded parts and valve outlets are welded, cross connections are established between trusses or beams in the transverse direction, location trusses or beams is consistent with the topology of the load from the upper structure and can be oriented parallel to the long or short side in terms of a rectangular building, and with a complex structure of the building combinations of trusses or beams are possible, with a round outline of the truss building can be arranged radially, and the plates can be segmented or trapezoidal shape, the step of the trusses is taken equal to or greater than the height of the platform, in the case of installing frame buildings in the slots, holes are provided for glasses in which to install are columns, which are then zamonolichivayutsya with upper and lower boards in which the pinched column.

Known spatial foundation platform for units with dynamic load for construction on soft and permafrost soils (patent No. 50553, 7 E02D 27/34, 27/35, publ. 20.01.2006, BI No. 2), including slab elements of a continuous arrangement, the design of the spatial foundation platform is shaped from the combined upper and lower reinforced concrete thin ribbed plates interconnected by a system of cross reinforced concrete beams of I-profiles, for example, trusses or metal spatial sprats gels that form a ventilated underground with the possibility of filling it with compacted soil to increase the attached mass to the foundation, and the foundation platform is installed on a leveled base without being buried in the ground.

The disadvantages of the design data is that the spatial foundation platform, using the weak properties of soils, exerts little pressure on them, but does not strengthen the weak soil, does not improve the working conditions. In the marginal zones of support of the spatial foundation platform, weak soil can protrude from under the spatial foundation platform and uneven base sediments can be created, and under seismic influences, unreliable conditions can be created due to this.

The closest technical solution, taken as a prototype, is a monolithic spatial foundation platform (see patent No. 45410 7 E02D 27/32, 27/34, 27/35, publ. 10.05.2005, Bull. No. 13). The monolithic spatial foundation platform is made of two thin reinforced concrete foundation plates of a continuous section, located one above the other. Thin slabs are seamlessly fastened together by cross-reinforced concrete beams, the space between which is filled with a heater, for example, expanded clay. A sliding layer of materials with a low coefficient of friction is installed between the monolithic spatial foundation platform and the base.

The disadvantages of this design are similar to those described above, i.e. the spatial foundation platform, using the weak properties of soils, exerts little pressure on them, but does not strengthen the weak soil, does not improve the conditions for its work. In the marginal zones of support of the spatial foundation platform, weak soil can protrude from under the spatial foundation platform and uneven base sediments can be created, and under seismic influences, unreliable conditions can be created due to this. The proposed utility model is devoid of these disadvantages.

The problem solved by the proposed utility model is to increase the reliability of a building or structure by creating favorable conditions for the operation of soft soils and increased seismic stability in seismic zones.

The problem is solved as follows.

A spatial foundation platform for buildings and structures for construction on weak, subsidence, heaving soils and in seismic zones, containing thin reinforced concrete foundation slabs of continuous cross section, located one above the other, fastened together by cross reinforced concrete beams, the space between which is filled with insulation, for example, expanded clay , with the upper structure, the spatial foundation platform is rigidly connected and forms a closed building, which is rigidly connected around the perimeter and with “wall in soil” reinforced concrete panels buried into the ground, while on the outside, an air gap is made around the buried reinforced concrete panels in the form of “wall in the ground” or “wall in soil” instead of the air gap around the buried reinforced concrete panels backfill made of soft soil. And between its opposite walls in the ground there is a tension device.

In the proposed utility model, the reliability of earthquake resistance is increased not only by reducing the pressure on the soil, but also by hardening the soil under the spatial foundation platform, taken in a "clip". The air gap device or “soft” backfill reduces horizontal seismic effects on the foundation and, therefore, on the entire structure. The created spatial foundation platform, together with the over-basement structure, forms a closed building or structure that has increased reliability and seismic resistance under various, including seismic, influences.

The proposed utility model is illustrated by the figure:

Figure 1 - General view of the spatial foundation platform for buildings and structures for construction on weak, subsidence, heaving soils and in seismic zones.

The upper structure in the form of a building or structure 1 is combined with a spatial foundation platform 2 and forms a closed building.

Spatial foundation reinforced concrete platform 2 is not buried in the ground. Reinforced concrete panels are firmly fixed along the contour of the spatial foundation platform 2, buried in the ground in the form of a “wall in the ground” 3, around which an air gap 4 is made on the outside or filled with soft soil. Soil 5 between recessed reinforced concrete panels and beyond, soil 6 in its natural state. Between the opposite "walls in the ground" there is a tension device 7.

The assembly of a building or structure is as follows.

Around the closed-type building on a leveled surface of weak soil around the perimeter of the spatial foundation platform 2, a trench is opened in which reinforced concrete panels of the 3 “wall in soil” type are installed, which are then rigidly fixed to the spatial foundation platform 2. A tensioner is installed between the opposite “walls in the ground” device 7. Soft soil 4 is filled in the trenches or an air gap 4 is left, which is closed by a lid.

In the middle zone under the spatial foundation platform 2, the soil is in favorable constrained conditions even without reinforced concrete “wall in soil” panels due to lateral resistance (resistance) of the extreme soil zones surrounding it. In the presence of a "wall in the ground" this effect is enhanced and is also created for the extreme zones (due to the resistance of the panels), thereby increasing the reliability of the entire structure in seismic zones. Thus, the soil under the spatial foundation platform is strengthened, its bearing capacity is increased and thereby the reliability of the entire structure is increased, it does not creep and does not sag during fluctuations.

Claims (3)

1. A spatial foundation platform for buildings and structures for construction on weak, subsidence, heaving soils and in seismic zones, containing thin reinforced concrete foundation slabs of continuous cross section, located one above the other, fastened together by cross reinforced concrete beams, the space between which is filled with insulation, for example expanded clay, with the upper structure the spatial foundation platform is rigidly connected and forms a closed building, characterized in that the spatial the foundation platform along the perimeter is rigidly connected to the “wall in the ground” reinforced concrete panels, buried in the ground, while an air gap is made around the buried reinforced concrete panels in the form of a “wall in the ground” on the outside. 2. The spatial foundation platform for buildings and structures for construction on weak, subsidence, heaving soils and in seismic zones according to claim 1, characterized in that, on the outside, around the buried reinforced concrete panels in the form of a “wall in the ground” instead of an air gap, backfilling is performed from soft ground. 3. The spatial foundation platform for buildings and structures for construction on weak, subsidence, heaving soils and in seismic zones according to claim 1, characterized in that there is a tension device between its opposite walls in the ground.