RU2692396C1 - Method of erection of slab reinforced concrete foundation - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to construction, namely, to foundations of buildings and structures erected on gravel-sand soils. Method of erection of slab-type reinforced concrete foundation includes excavation of excavation, laying of reinforcement on base, concreting of foundation plate with subsequent hardening and erection of foundation over-foundation parts. Excavation of excavation is carried out to mark at (0.4–0.6)h above design foundation marking mark, where h is projected thickness of foundation. Laying of reinforcement and concreting foundation plate with through holes, after curing of which the above-foundation parts of the building are erected, and through the through holes of the slab the polymer solution is supplied into the gravel-sand soil till formation of the lower polymer-concrete layer with thickness of (0.5–0.8)h, after hardening of which the carrying capacity of the foundation is achieved.EFFECT: technical result consists in reduction of material consumption, minimum labor input, reduction of construction period of building and structure.3 cl, 6 dwg

Description

The invention relates to the construction, namely, the device of the foundation of buildings and structures on gravel-sand soils.

There is a method of strengthening the soil base of the existing slab foundation by cementation or chemical fixing / 1 /. Hardening the soil base reduces the precipitation of the foundation of a building under construction.

The disadvantages of this method are that the improvement of the properties of the soil has little effect on the required parameters for the calculation of the foundation (slab thickness, concrete grade and number of reinforcement).

There is a method of strengthening reinforced concrete base plates by increasing the thickness of the plates / 1 /. The reinforcement is produced by tamping over a layer of concrete.

The disadvantage of this method is the reduction of the height of the floor or the complete loss of its volume occupied by the reinforcing foundation structures.

Known box base plates / 2 /. Compared with solid box foundations have increased characteristics on a scale of "bending stiffness-material consumption."

The disadvantages of the method of device foundation is the increased complexity of manufacturing, the complexity of the use of cavities in the body of the plate.

A known method of separate concreting structures / 3 /, which consists in the injection of cement mortar in the form of the formwork, pre-filled with inert materials (gravel, sand). / 3 /

The disadvantages of this method is the need for careful selection of the composition of inert materials, caused by the low permeability of cement; the need for additional reinforcement of bent elements, due to the low tensile strength of concrete.

There is a method of erection of buildings using the "top-down" method, i.e. up-down / 4 /. According to a known method, pile supports are erected for the columns serving as an intermediate foundation, then the construction of the above-ground part of the building is carried out on the intermediate foundation, and the development of the soil in the underground part is performed in parallel, then the foundation slab is used that serves as the final part of the permanent pile foundation foundation.

The disadvantages of this method, adopted for the prototype are: excessive consumption of materials and labor costs for the construction of the underground part, as in many cases there is a "double foundation", ie temporary (pile) and permanent (base plate) construction.

The technical challenge is to create a method of constructing the foundation with minimal complexity and reducing the period of construction of buildings.

The technical problem is solved in such a way that in the method of erection of a slab reinforced concrete foundation, which includes digging the pit to the design depth, laying the reinforcement on the base, concreting the foundation plate, followed by curing and erection of the basement parts of the building, according to the invention, digging out the excavation to a depth less than designed the value (0.4-0.6) h, where h is the calculated thickness of the foundation, the reinforcement is laid and the upper layer of the foundation is concrete-cast with vertical and inclined through holes, and After curing, erected foundation parts of the building are erected and at the same time through the through holes in the upper part of the foundation a polymer solution is fed to impregnate a layer of gravel-sandy soil at the base of the upper part and convert it to the lower polymer concrete foundation layer with a thickness of (0.5-0.8) h, after curing of which Achieved design strength and bearing capacity of the foundation. At the same time, due to the uneven surface and the lack of a waterproofing layer, the upper and lower parts of the foundation are firmly interconnected and work as a single structural element of the building. At the same time, due to the complete impermeability of polymer concrete, there is no need for a special waterproofing layer.

At the same time, when gravel-sandy soil is located below the top of the upper part, the lower foundation layer can be constructed by impregnating a layer of large-pore soil up to 2-4 thicknesses of the foundation, and connected to the upper supporting elements constructed in wells drilled through through holes of the upper reinforced concrete layer .

The proposed method for the construction of the foundation is characterized in that the excavation of the excavation is carried out at a depth of less than the design depth of the foundation at (0.4-0.6) h (where h is the thickness of the foundation), reinforcement is laid and the upper foundation layer is laid with vertical and inclined through holes, and after curing erect the basement parts of the building and at the same time through the through holes in the upper part of the foundation produce a polymer solution to impregnate a layer of gravel-sandy soil and convert it to the bottom The olimerbeton layer of the foundation, after curing of which the bearing design capacity of the foundation is achieved.

The technical result of the invention is the creation of a new construction method for a two-layer foundation consisting of the upper reinforced concrete part and the lower part of the polymer concrete, with the lower part being erected after the upper one, in parallel with the work on the construction of the foundation foundation parts.

The method is illustrated in the drawing, which shows the sequence of works on the construction of the method "up and down".

FIG. 1 - excavated pit; FIG. 2 - concreted upper part of the foundation; FIG. 3 - erection of the supra-foundation parts of the building; FIG. 4 - the device of the lower part of the basement and the erection of the foundation foundation of the building; FIG. 5 — node A of FIG. 2; FIG. 6 is the same as in FIG. 5 variant of gravel-sandy bedding at a distance from the bottom of the upper part.

When designing the submerged parts of buildings and structures, the depth of the pit is sought to be minimized in order to reduce excavation, reduce the amount of mounting of the sides, and avoid pumping out groundwater to protect the surrounding building from additional sediment from dewatering.

Example №1

As an example, let us give the construction of a high-rise building with three underground floors. The foundation pit for the construction of the underground part is enclosed by a “wall in the ground”. At the base of the projected base plate with a thickness of 2.5 m there are sands of medium size and large, medium density. The groundwater level of the OLA is 1.25 m above the base of the basement.

The standard (traditional, well-known) technology provides for digging up the soil to the level of the bottom of the foundation structure (slab, preparation, waterproofing, etc.), in this case approximately 1.5 m below the OLA. It is required to lower the OLA and maintain it for the entire construction period. Required to perform reliable waterproofing. These works are performed consistently and require a long time.

The proposed method is implemented in the following technological sequence. The excavation pit 1 is excavated to the level of the bottom of the upper part 2 of the foundation 3. Then, all the work is carried out on the construction of the upper reinforced concrete part 2 of the foundation plate 3, including the installation of vertical and inclined injection tubes 4 in the concrete body with a design step taken equal to 0.9-1.2 the thickness of the lower part 6 of the foundation 3. After hardening and curing of concrete begins the construction of superfacial supporting structures of the building 5, and in parallel, work is underway on the construction of the lower part 6 of the foundation 3. For this, through injection pipes KI 4 inject polymeric binder, for example, Etalak732 epoxy composition to form polymer concrete mixture by the method of separate concreting in a limited volume of the soil mass under the bottom of the upper part of the foundation. After polymerization of the epoxy composition, a mixture of soil and resin turns into polymer concrete. As a result, under the sole of the upper reinforced concrete part 2, a polymer-concrete lower part 6 of the foundation 3 is formed.

Polymer concrete with sand and gravel aggregate has high strength and deformation characteristics. So, tensile strength is 3-4 times higher than that of Portland cement of equal compressive strength. Polymer concrete is almost waterproof, eliminating the need for horizontal waterproofing of the foundation.

The proposed method provides:

1. Reducing the volume of earthworks and dewatering during construction by reducing the depth of digging of the pit

2. Reducing the volume of "wall in the ground" and the system of fastening the sides of the pit (anchor or struts)

3. No need for waterproofing devices.

4. The duration of the work is reduced due to the possibility of parallel execution of part of the foundation and above-foundation structures by the “top-down” method.

Example 2

In the case when directly at the bottom level of the upper part of the basement, clay soils 9 are deposited, unsuitable for the formation of a strong polymer concrete material. In such conditions, the lower part of the foundation 6 is erected separately from the upper 2, in favorable soil conditions, combining both parts of the foundation 3 with intermediate support elements 8, reinforced with rods 7. According to calculation, the lower part of the foundation can be at a distance of (2-4) h, where h is the thickness of the foundation. The supporting elements 8 are erected in wells drilled through the holes in the upper part 2. In this case, to protect the foundation slab and the floor, a waterproofing layer is required under the bottom of the upper part 2.

Information sources

1. P.A. Konovalov. “Foundations and foundations of reconstructed buildings”. M. 2000.

2. Soil mechanics, bases and foundations. M., "High School", 2004, p. 277.

3. Yu.M. Bazhenov, L.A. Alimov and others. "Technology of concrete, building products and structures." Ed. DIA, M., 2008.

4. Sopegin TV, Sursanov G.V. "Prospects for the use of construction technology" top down ". Permian.

Claims (3)

1. The method of erection of slab reinforced concrete foundation, which includes digging the pit, laying reinforcement on the foundation, concreting the foundation slab with subsequent curing and erection of the foundation foundation parts of the building, characterized in that the excavation of the excavation is carried out up to the mark of foundation foundation where h is the design thickness of the foundation, after which the reinforcement is laid and the foundation slab is cast with through holes, after which it is cured, the basement parts of the building are erected and through the well znye plate holes produce feeding of the polymer solution in the gravel-sand bed to form the lower layer of polymer concrete thickness (0.5-0.8) h, which is reached after curing the calculated bearing capacity of the foundation. 2. The method according to p. 1, characterized in that when the gravel-sandy soil is located at a depth of (2-4) h from the base level, the reinforced concrete slab and the lower polymer concrete foundation layers are connected through the through holes and the soil by supporting elements. 3. The method according to p. 2, characterized in that the upper layer of the foundation is joined by supporting elements with the lower layer through the through holes of the upper reinforced concrete layer, soil layer and polymer concrete layer.

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