RU2291253C1 - Method for existent building, building structure and underground service line protection in construction affected zone - Google Patents

Abstract

FIELD: construction, particularly to protect existent objects near construction site.

SUBSTANCE: method involves forming geotechnical screen in ground, wherein the geotechnical screen is made by driving injectors in ground between foundations of existent objects and objects to be erected and injecting consolidation solution in ground under pressure. The geotechnical screen is composite and formed with the use of injectors grouped in two rows, namely in passive and active ones. The passive injector row is located from side of object to be erected. The active injector row is installed from side of existent object. Consolidation solution is initially supplied to passive injector row by single solution injection in ground and then in active injector row by repeated solution injection in ground to obtain initial deflected mode of existent object base and foundation ground.

EFFECT: reduced negative influence of geotechnical screen on filler structures of objects to be erected, increased efficiency and reliability of object protection in densely built-up areas.

4 cl, 3 dwg

Description

The invention relates to the construction and for ensuring the safety of existing buildings.

There is a method of arranging a separation wall between the foundation of an existing and constructed building by installing drill piles in increments, arranging gaps between them, filling them with a thixotropic mortar and immersing metal corrugated sheets connected to a beam installed on the heads of the piles. In this case, the gap is cut to the depth of the compressible soil layer of the base of the building being constructed [1].

The disadvantage of this method is its complexity, material consumption, the inability to restore the initial stress-strain state of the soil of the base and foundations of the building, as well as lifting and leveling the foundations of the building.

There is a method of protecting buildings and structures from the negative impact of mine workings, which consists in leveling buildings and structures by jacking. For these purposes, niches for jack installation, reinforced concrete belts for load distribution from jacks on the ground, etc. are arranged in the basement of the walls of buildings and structures [2].

The disadvantages of this method are the complexity and complexity of the work, since construction work is carried out directly in the existing building and, as a rule, requires strengthening and changing the design of the existing object and interrupting its operation.

Closest to the proposed method is a method of erecting underground structures in the urban area, including the installation of a geotechnical barrier in the ground by introducing a number of vertical injectors into the ground along the wave propagation path to change the stress-strain state of the soil and pumping the cement to achieve Kr≥0.5, where Kr is the relaxation coefficient equal to the ratio of the final pressure in the soil after relaxation to the maximum injection pressure of the solution, and in the process of building walls terrestrial control structures are deflected soil condition in which changes produce an additional supply of grout to restore soil stress-strain state.

The disadvantages of this method is that there is a negative additional pressure on the impermeable enclosing structures (for example, a sheet piling of a foundation pit made of pipes with removal of welded metal sheets) of the erected structure as a result of pumping the solution into the ground at pressures close to or higher than the fracture pressure; there is a danger of leakage of the injected solution into the pit with permeable enclosing structures (for example, sheet piling of the pit from pipes without clogging); the construction of a vertical barrier in a zone of tight urban development is not possible in some cases. In addition, it is difficult to determine the relaxation coefficient, since it is very difficult to obtain a “final pressure in the soil” without setting a criterion for pressure stabilization over time.

The technical task is to increase the efficiency and reliability of the protection of existing buildings, structures and underground utilities by eliminating the negative impact of the geotechnical barrier on the building envelope of the facility being built, in expanding the technological capabilities of carrying out construction work in the area of close development of the city.

The problem is solved in such a way that in the method of protecting existing buildings, structures and underground utilities in the area of influence of the construction, including the installation in the ground of a geotechnical screen from the injectors immersed in the ground between the foundations of existing buildings, structures and underground utilities with the subsequent injection of the fixing solution into soil under pressure, according to the invention, the geotechnical screen is arranged combined - from two rows of injectors, passive, from the side of the constructed object that, and active, from the side of the existing object, and the fixing solution is first supplied to the passive row of injectors by a single injection of the solution, and then to the active row of injectors by repeatedly injecting the solution into the ground until the initial stress-strain state of the base soils and foundations of existing buildings is restored, facilities and underground utilities. Moreover, the geotechnical screen is arranged from two rows of injectors with a mutual arrangement of the projections of the injectors at an angle to each other. In addition, the geotechnical screen is arranged at an angle to the vertical. In this case, when injecting the solution into the active row of injectors of the geotechnical screen, the pressure of the solution is first increased to the pressure of the hydraulic fracturing of the soil, and then reduced.

The proposed method differs from the known one in that the geotechnical screen is arranged as a combination of two rows of injectors, passive, from the side of the being built object, and active, from the side of the existing object, and the fixing solution is fed first to the passive row of injectors by a single injection of the solution, and then into the active a number of injectors by repeated injection of a solution into the soil until the initial stress-strain state of the base soils and foundations of existing buildings, structures is restored and underground utilities.

The passive part of the screen is carried out by the erected structure, arranged, as a rule, by fixing the soil. It serves to reduce additional pressure on the building envelope of the constructed object when injecting the solution injected into the soil in the active part of the screen and directing the injection of the solution towards the base soils of the existing object. The active part of the screen is performed by the protected buildings and structures. It is arranged by repeated injection of a solution into the soil, serves to restore the initial stress-strain state of the base soils and foundations of existing buildings, structures and underground utilities. Moreover, to increase rigidity and continuity, the geotechnical screen is arranged so that the mutual arrangement of the projections of the injectors of the active and passive rows are at an angle to each other. In addition, the geotechnical screen is arranged at an angle to the vertical, the angle is determined by the relative position of the structure being erected and the foundations of the protected objects. In this case, at each i-th injection cycle of the solution into the active row of injectors of the geotechnical screen, the injection pressure of the solution is first increased to the pressure of the hydraulic fracture of the soil P _gri , and then reduced to K · P _gri , where K = 0.5 ... 0, 9 - coefficient determined as a result of experimental work.

An example of the protection of an existing building, located in the zone of influence of the tunnel, by means of a combined geotechnical screen.

The protection method is illustrated by drawings, where in Fig. 1 a diagram of a geotechnical screen device is shown, in Figs. 2 - 1-1 of Fig. 1, in Figs.

Between the foundations of the existing building 1 and the tunnel being laid 2, a geotechnical screen is arranged in the ground, which consists of injectors 3 of the passive row 4 and active row 5 immersed in the ground.

Geotechnical parameters of the screen: depth, pitch, plan alignment and tilt of the injectors of both parts of the screen, the composition of the solution, the radius of fixation and the characteristics of the fixed soil in the passive part of the screen, the volume of the solution injected into the soil in the active part of the screen is assigned taking into account the results of modeling changes in stress-strain the state of the soil mass and the foundation structures of the building as a result of tunneling and pilot work at the facility.

The parameters of the geotechnical screen are selected in such a way that the predicted additional deformations (maximum additional draft, maximum relative difference of the sediment, maximum additional roll, maximum additional curvature of the base of the foundation) of the building foundations from the influence of tunnel penetration do not exceed 10 ... 30% of the limit values.

A combined geotechnical screen is arranged before the tunnel is drilled. In front of the screen device, a system of instrumental control of movements of the foundation structures of the building to be protected is created (engineering and geodetic observations of 1-2 accuracy classes for wall marks installed on the basement of the exterior walls of the building, the installation of beacons on existing cracks in the walls of the building, etc.) and changes stress-strain state (VAT) of the soil mass (measurement of horizontal movements of the soil using inclinometers; measurement of vertical movements of the soil using grades osloynyh deformations soil etc.). After the control system is installed, a zero measurement cycle is performed. To monitor the movements of the building, it is preferable to use a system of operational monitoring such as CYCLOPS using tacheometers with a servo drive.

Injector 3 passive 4 and active 5 rows of the screen are immersed in the ground. Injectors have holes located at a certain pitch along the length. For the active row of the screen, cuff-tampon type injectors are used.

Through a passive series of screen injectors, the soil is fixed by a single injection into the soil of solutions prepared on the basis of cement, sodium silicate or synthetic resins. The injection pressure of the solutions should be less than the pressure of the hydraulic fracturing of the soil. According to the installed control system, the first cycle of control measurements is performed.

Through a system of injectors of the active row of the screen, a zero (preliminary) cycle of pumping the solution into the soil is produced. For this, cement mortar with various additives can be used, for example. The purpose of the zero injection cycle is to check the entire injection system, initial “pressure testing” (precompression) of the soil, comparing the predicted design response of the soil mass and the building to the injection of the mortar, and, as a result, updating the adopted compensation compensation method. The solution injection pressure initially increases to a pressure P _{gi of} hydraulic fracturing of the soil surrounding the injector. After reaching P _gri it decreases to a value of 0.8 · P _gri . The injection is performed until the reaction of the protected building is detected - its movements up to 1 ... 3 mm. In the process of injection produce periodic cycles of control measurements.

In the process of tunneling according to the established control system, periodic control measurements are performed. After additional deformations of the building will reach 10 ... 30% (not less than 5 mm) of the limiting values, the first and subsequent cycles of compensatory injection of the solution into the soil through a system of injectors in the active part of the screen are performed. In this case, the injection pressure of the solution is first increased to the pressure P _{gi of the} hydraulic fracture, which expands after each injection of the "shell" from the reinforced soil. Then the pressure is reduced to a value of 0.8 · P _gri . Compensatory pumping is carried out until the initial stress-strain state of the foundation soils and foundations of the building is restored, and its foundations are raised and leveled. Slightly raising the building by 1 ... 3 mm is allowed. In the process of injection, periodic cycles of control measurements and calculations of additional deformations of the building foundations are performed.

After tunneling and completion of construction work, the final (one or more) injection cycles are performed. The frequency of control measurements and injection cycles after tunneling near the building is significantly less than during tunneling.

The technical result of the invention is to reduce the negative impact of the geotechnical screen on the building envelope of the structure under construction, increase efficiency and reliability (create a directed injection, move the screen closer to the base of the protected buildings and structures, create the effect of soil reinforcement) and expand the scope of the geotechnical screen (for cases when the structure under construction is partially or completely located under the protected building or structure).

Information sources

1. Application of the Russian Federation No. 94007986, cl. E 02 D 5/30, BI No. 34, 12/10/95

2. Foundations, foundations and underground structures. - M.: Stroyizdat, 1985, 480 p.

3. RF patent №2245966, cl. E 02 D 31/08, BI No. 5, 2005.02.10 (prototype).

Claims (4)

1. A method of protecting existing buildings, structures and underground utilities in the zone of influence of construction, including a device in the ground of a geotechnical screen from the injectors immersed in the ground between the foundations of existing and constructed buildings, structures and underground utilities, followed by injection of a fixing solution into the ground under pressure, characterized in that the geotechnical screen is arranged by a combination of two rows of injectors - passive from the side of the constructed object and active from the side of the existing object, and the fixing solution is first supplied to the passive row of injectors by a single injection of the solution, and then into the active row of injectors by repeatedly injecting the solution into the soil until the initial stress-strain state of the base soils and foundations of existing buildings, structures and underground utilities is restored. 2. The method according to claim 1, characterized in that the geotechnical screen is arranged from two rows of injectors with a mutual arrangement of the projections of the injectors at an angle to each other. 3. The method according to claim 1, characterized in that the geotechnical screen is arranged at an angle to the vertical. 4. The method according to claim 1, characterized in that when the solution is injected into the active row of injectors of the geotechnical screen, the injection pressure of the solution is first increased to the pressure of the hydraulic fracturing of the soil, and then reduced.

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