RU2603786C1 - Solution for preliminary pumping into soils of bases for elimination of deformations of buildings and structures - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to reconstruction of building structures. Solution for preliminary pumping into soils of bases for elimination of deformations of buildings and structures, containing a mixture of water and dry ingredients on a mineral base with following ratio, wt%: microcement (type microdur) 20-50; colloidal silica 5-15, hydrated lime Ca(OH)₂ 10-25; mineral microfiller, for example carbonate flour, 20-50; suspension viscosity regulator, for example superplasticiser C-3, up to 2 % of weight of binder; water-retaining additive, for example, methylcellulose, up to 5 % of weight of binder.

EFFECT: reduction of labour and materials consumption and higher reliability of works on elimination of deformations of buildings and structures.

1 cl, 1 dwg

Description

The invention relates to the field of reconstruction of building structures, namely the elimination of their general deformations.

Known solution for preliminary injection into the soil of the grounds while eliminating deformations of buildings and structures, containing a mixture of water and dry ingredients on a mineral basis. The solution contains: bentonite powder 30%, carbonate flour 68%, plasticizer 2%. [A. Bezuijen. // Compensation grouting in sand: Experiments, field experiences and mechanisms. 2010. Pp. XX].

The disadvantage of the composition of this solution is that when it is used, stable results are not achieved, resulting in cracks of indefinite length and opening. These cracks require an increased flow rate of the mortar, may remain partially unfilled with the mortar, which in the future can lead to suffusion processes and reverse deformations of the structure.

Closest to the proposed is a solution for preliminary injection of soils into the soil while eliminating deformations of buildings and structures, containing a mixture of water and dry ingredients based on minerals, including cement additives, while the solution contains the following composition: bentonite powder 25%, Portland cement - 50%, fly ash - 23%, plasticizer 2% [M.R. Moseley, K. Kirsch, E. Falk. Soil fracturing // Ground Improvement (second Edition). 2004. Pp. 220-251].

The advantage of the composition of the solution for pre-injection is that it is highly permeable, as a result of its use, a matrix layer is created that prevents the expandable layer from cracking.

The disadvantage of the composition of the solution for pre-injection is that the absence of hydraulic fracturing is not guaranteed. Cracking takes place and with it the same dangers as in the previous technical solution: suffusion processes and reverse deformations of the structure.

The aim of the present invention is to reduce the cost of labor and materials and increase the reliability of work to eliminate the deformation of buildings and structures by eliminating cracking and hydraulic fracturing of the soil.

To achieve this goal, the solution for preliminary injection into the soil of the base while eliminating deformations of buildings and structures contains a mixture of water and dry ingredients on a mineral basis and has the following composition:

microcement (such as microduros) 20-50% colloidal silica 5-15% hydrated lime, e.g. Ca (OH) ₂ 10-25% mineral microfiller, for example carbonate flour 20-50% slurry viscosity regulator e.g. superplasticizer C-3 up to 2% by weight of the binder water retention additive, for example cellulose up to 5% by weight of the binder

The essence of the invention is illustrated in the drawing, which shows a diagram of a technological complex to eliminate the deformation of buildings and structures (to explain the purpose and place of use of the solution).

The proposed solution (aqueous suspension) for preliminary injection of soils into the soil while eliminating the deformation of buildings and structures has the following composition:

microcement (such as microduros) 20-50% colloidal silica 5-15% hydrated lime, e.g. Ca (OH) ₂ 10-25% mineral microfiller, for example carbonate flour 20-50% slurry viscosity regulator e.g. superplasticizer C-3 up to 2% by weight of the binder water retention additive, for example cellulose up to 5% by weight of the binder

Since the development of technology to eliminate the deformation of buildings and structures by injecting then a hardening solution then went in the direction of dividing the one-stage process into a two-stage process, corresponding requirements were made for each stage.

At the first stage, it was necessary to create an elastic matrix layer without changing the soil volume, but only by filling the pores with a highly permeable solution and creating a single elastic composite material capable of further injection of the solution, i.e. at the second stage, resist the appearance of cracks in which the injection process becomes uncertain.

This technical solution is a solution for injection in the first stage, i.e. is a solution that is characterized by high permeability, i.e. the ability to fill all the pores, on the one hand, and, on the other, the ability, connecting (mechanically) with the soil, to create an elastic composite material. It should be noted that the injection of the solution is subject to strict rules for ensuring the pressure and flow rate.

At the end of preliminary injection using this solution, the following indicators can be achieved: a decrease in the porosity coefficient by 80%, an increase in the deformation modulus by 20%, and an increase in the coefficient of transverse deformation by 15%. The calculated tensile resistance for the soil mass should remain the same (i.e., the pre-injection solution gains strength very slowly or does not gain at all). Such indicators neither in the analogue, nor in the prototype could not be achieved.

The essence of the technological process where the proposed solution is applied is as follows (see drawing). To eliminate deformations of building foundations, several tiers of channels 1 for mortar injectors are arranged under the building foundation, which are located under the building foundation 2, mortar injectors 3 located in channels 1, expandable layers 4 and matrix layers 5. Injectors 3 of solution through channels 7 arranged in the mine 6, connected to a pumping station 8 for supplying a solution, and through channels 9 connected to a compressor 10 for supplying compressed air.

Layers 4 and 5 are a mixture of local soil with an injected solution.

Pump station 8 at a pressure of not more than 5 atm delivers a solution for preliminary injection of the above composition.

As a result, the pores of the soil are filled, and the skeleton of the soil is not broken. This soil can absorb pressure and move under pressure, helping to lift the foundation. The expandable layer 4 is already formed during the period of the foundation’s immediate rise due to the injection of a poorly permeable solution under high pressure (20-50 atm). As a result, the soil is mixed with the solution, the total volume of the layer increases, the layer 5 moves and the foundation rises. The formation of an expandable layer (with compensatory injection) can go in several stages to obtain the required leveling accuracy of buildings or structures.

With preliminary injection, the best effect is achieved when pumping from the upper tier down, the reinforced zone is immediately limited from above, where cracks and tears are possible

In compensatory injection, the expandable layer expands up and down. To increase the efficiency, injection starts from the lower tier (see the drawing) and then continues according to the “bottom up” principle, therefore the total upward strain “δ _in ” (which is equal to the strain “δ _g ” of the building) is greater than the total strain “δ _n ” down.

An example embodiment of the invention.

When a metro line was drilled, deformation of a 3-story building on Dmitrovskoye Shosse occurred. The amount of precipitation was 25 mm. It was decided to apply compensation injection technology. This technology involved the creation of a matrix layer at the first stage by preliminary injection of a highly permeable solution into the soil, and then at the second stage, directly compensating injection of a layer of a low permeability solution.

The preliminary injection was carried out as described in this application, by impregnating the soil with a highly permeable aqueous suspension based on a particularly finely ground microcement (Microdur microcement - 40%, colloidal silica 10%, hydrated Ca (OH) ₂ - 15%, carbonate flour - 30%, superplasticizer C-3 - 2%, methyl cellulose - 3%). The injection was carried out through pre-installed cuff injectors with a pressure of P _{1, current} = 3.5 atm and a flow rate of Q _{1, current.} = 5 l / min. The end of the injection was completed at the moment when the flow rate decreased to Q _{1, min} , equal to 1 l / min, at a pressure P _{1, max} equal to 5.5 atm.

The performed impregnation filled all available pores and voids in the zone of possible injection, thereby ensuring the controllability and efficiency of the lifting process in the event of residual deformations.

The creation of a reliable matrix layer allows the effective application of compensatory injection, since the matrix layer holds the soil well against cracking. Due to the small settlement of the building, for the expandable layer (compensatory injection), it was decided to use the known mortar composition: Portland cement 50%, carbonate flour 49% and plasticizer 1%.

After compensatory injection, the residual deformation was 2 mm.

The effectiveness of this technical solution is to reduce labor costs and materials while increasing the reliability of the fixed base of buildings and structures by eliminating cracking and hydraulic fracturing of the soil.

Claims (1)

A solution for preliminary injection of soils into the soil when removing deformations of buildings and structures, containing a mixture of water and dry ingredients on a mineral basis, characterized in that it contains a composition in the following ratio, wt.%:
microcement (such as microduros) 20-50 colloidal silica 5-15 hydrated lime, e.g. Ca (OH) ₂ ) 10-25 mineral microfiller, for example carbonate flour 20-50 slurry viscosity regulator e.g. superplasticizer C-3 up to 2% by weight of the binder water retention aid, e.g. methyl cellulose up to 5% by weight of the binder

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