RU2352723C1 - Method for correction of vertical position of buildings and structures on panel-wall foundation - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method for correction of vertical position of buildings and structures on panel-wall foundation. Vertically oriented injection conductors are installed in slab body with elevation of one end above the upper cut of slab or level of subgrading and deepening of the other end in soil under foot or slab foundation mattress, through which movable mortar is injected under part of building in direction of careen till supply pressure increases by 40-50% relative to working pressure or until movable mortar flow increases in volume of 2 m³ in one injection horizon. Number and altitude position of injection horizons are assigned according to data of geological engineering survey and are clarified according to results of measurement of rate of injector submersion in soil. Necessity of injection works performance is determined by materials of geodesic survey over building or structure in process of construction and during the first years of operation.

EFFECT: reduced labour intensiveness during works performance, increased reliability of injection method application, increased operational reliability of buildings and structures on panel-wall foundations.

2 cl, 6 dwg

Description

The invention relates to the construction and can be applied in the construction of buildings and structures on a slab foundation on any soil base, especially composed of weak or bulk soils of high power.

A known method of constructing a slab foundation (Patent No. 2184812, E02D 27/28, 27/26. A method of adapting a slab foundation to a change in the characteristics of a soil base, auth. Snev VM, Lubyagin AV, Fedorov VK Publ. 07/10/2002, bull. No. 19 - prototype), which includes the device in the plate body of adaptive technological and measuring channels and the installation of primary measuring transducers in them, with the help of which the physical and mechanical characteristics of the soil are evaluated and, if necessary, injection of sealing and fixing solution in the zone of reduced density of the soil base, while the adaptive technological channels are made in the form of a truncated cone of foam, foam concrete or porous concrete in contact with a large diameter ground foundation, which is the closest to the proposed method in technical essence and selected as a prototype.

The disadvantages of the prototype method are the high complexity of the adaptive technological and measuring channels in the plate body, the difficulty of their implementation in densely reinforced slab foundations due to their significant volume, the indirectness of determining the need for injection work on the physical and mechanical characteristics of the soil, the uncertainty of the height of the injection horizons.

The technical problem solved by the invention is: reducing the complexity in the production of works on the device of the basement; the ability to install injection conductors in any slab foundations, including a considerable height and densely reinforced; improving the reliability of the injection method in order to adjust the vertical position of buildings and structures under construction; improving the operational reliability of buildings and structures on slab foundations, erected on a soil foundation, folded, including weak or bulk soils, due to the timely elimination of uneven sediments and banks that arise during construction or further operation by injecting the soil of the base with mobile solutions.

The technical problem is solved as follows. In the method for adjusting the vertical position of buildings and structures on a slab foundation, vertically oriented injection conductors are installed in the slab body with one end elevated above the top edge of the slab or the level of the soil level and the other end deepened into the ground under the sole or concrete slab preparation, through which the injection of rolling mortar is performed under a part of the building in the direction of the roll until the supply pressure increases by 40-50% in relation to the working (steady-state) pressure or to the flow and a mobile solution in a volume of 2 m on one injection horizon. In this case, the number and altitude of the injection horizons are prescribed according to engineering and geological surveys and specified by measuring the speed of immersion of the injector in the ground. As injection conductors, it is advisable to use plastic, metal or asbestos-cement pipes of industrial production with an internal diameter sufficient to immerse injectors through them with a minimum gap, which makes it possible to arrange injection conductors in densely reinforced plates and significantly reduces the complexity of building slab foundations. Preliminary designation of the number and height of injection horizons according to engineering and geological surveys and their refinement based on the results of measuring the speed of immersion of injectors in the ground, significantly reduces the complexity and material consumption of injection work, and also increases the reliability of adjusting the vertical position of the building by injection. The end of the injection process with an increase in supply pressure by 40-50% with respect to the worker, or with the consumption of a mobile solution in a volume of 2 m ³ on one horizon, reduces material consumption and improves the quality of injection work, because in case of further excess injection pressure, instead of compaction of the soil, new slit-like discontinuities of the soil base are formed with uncontrolled spread of the mobile solution.

During the construction process and the first years of operation of the building, constant geodetic observations are carried out. In the event of unacceptable precipitation and rolls exceeding the design, they perform the injection of mobile solutions into weak zones of the soil base through injection conductors installed in the body of the slab in order to compact the soil and increase its deformation modulus and, as a result, adjust the vertical position of the building. The criterion for the end of injection of a mobile solution on one horizon is an increase in the supply pressure, monitored by a manometer, by 40-50% relative to the working (steady-state) or flow rate of the mobile solution in a volume of 2 m ³ . The location of the injection points is assigned according to the results of the analysis of geodetic measurements - as a rule, at the end of the building in the direction of the roll. The number of injection horizons and their altitude location is determined by the materials of engineering and geological surveys and specified according to the measurement of the speed of immersion of the injector when it is driven into the ground (M. Nuzhdin, Prevention of uneven precipitation of the foundation slab using high-pressure injection. // Building construction and reconstruction experience and constructions on soft soils: Mat.International, Scientific and Technical Conference - Arkhangelsk: Publishing House of the Arkhang. State Technical University, 2003. - p.119-122). To implement the method, when erecting the slab foundation of a building while laying reinforcement, vertically oriented injection conductors are installed in the plate body — plastic, metal or asbestos-cement pipes of industrial production with an inner diameter sufficient to immerse the injectors in them with a minimum clearance, and fasten them with wire or welding (for metal pipes) to the working reinforcement of the plate. In this case, injection conductors are installed with the elevation of one end above the top edge of the slab or the level of planning and the deepening of the other end into the ground under the sole or concrete preparation of the slab. Placement of injection conductors in the plan is carried out with a step, assigned depending on the ground conditions of the site and the pressure of the plate on the soil base. After installing the conductors to prevent accidental ingress of concrete or construction debris into them, they are covered with a lid.

Figure 1 shows the dependence of the value of the supply pressure on the volume of the injected mobile solution; figure 2 is an example of the location of the injection conductors near the internal load-bearing wall of the building in plan; figure 3 is the same, in section; figure 4 is an example of the location of the injection conductors near the outer load-bearing wall of the building in plan; figure 5 is the same, in section; figure 6 shows the data of engineering and geological surveys and injection horizons.

From the dependence shown in Fig. 1, it can be seen that the value of the working (steady-state) pressure during the injection process is of the order of 4 atmospheres (ordinate axis P, atm) and begins to increase with the injected volume of the sealing solution about 1.75 m ³ (abscissa axis V, m ³ ). When the supply pressure reaches a value of 5.6 ... 6.0 atm, that is, an increase of 40-50% relative to the working one, the injection process on this injection horizon ceases, as its further increase may cause uncontrolled spread of the mobile solution due to the formation of slit-like fracture of the soil base.

Figure 2-5 shows: 1 - foundation plate; 2 - basement wall, figure 2, 3 - internal, figure 4, 5 - the outer wall; 3 - concrete preparation; 4 - soil base; 5 - injection conductors; 6 - upper edge of the foundation plate; 7 - the sole of the base plate; 8 - level of planning; 9 - backfill; 10 - cover.

From the data of engineering and geological surveys shown in FIG. 6 (materials of static sounding of the soil), it is seen that the weakest areas of the soil base with the lowest values of soil resistivity to immersion of the probe cone are located at depths of 5, 9 and 12 meters. At these levels, injection horizons 11 are preassigned.

In the manufacture of the slab foundation of the building, during the installation of the reinforcement, vertically oriented injection conductors 5 are installed in the body of the plate 1 and fastened to the working reinforcement with wire or welding (for metal pipes), while the injection conductors 5 are installed with one end elevated above the upper edge plate 6 (figure 3) or the level of soil 8 (figure 5) and the deepening of the other end into the soil 4 under the sole or concrete preparation of the plate 3. The placement of injection conductors 5 in the plan is performed in increments, depending on the soil conditions of the construction site and the pressure of the plate 1 on the soil base 4. During the construction and the first years of operation of the building, constant geodetic observations are carried out. In the event of uneven precipitation and rolls exceeding the design, they are eliminated by injecting mobile solutions into weak zones of the soil base 4 through injection conductors 5 installed in the body of the plate 1 in order to increase the deformation modulus and, as a result, adjust the vertical position of the building. The criterion for the end of injection on one injection horizon is an increase in the supply pressure, monitored by the manometer, by 40-50% with respect to the working (steady-state) pressure or flow rate of the mobile solution in a volume of 2 m ³ . Injection points are assigned according to the results of the analysis of geodetic observations, usually at the end of the building in the direction of the roll. The number of injection horizons 11 and their altitude are determined according to engineering and geological surveys and specified by measuring the speed of immersion of the injector when it is driven into the ground. After installing the conductors to prevent accidental ingress of concrete or construction debris into them, I close them with a lid 10.

Example 1. The soil base of a 25-storey residential building with a reinforced concrete frame along Zalessky St. in Novosibirsk is represented by layers: bulk soil IGE-1, up to 1.8 m thick, sandy loam of low degree of water saturation IGE-2, power 6.6 ... 9.5 m, loam of light dusty medium degree of water saturation and water-saturated IGE-3 - IGE-5, with a total thickness of 12.6 m and sandy loamy sandy saturated water IGE-6, opened with a thickness of up to 12.4 m. Engineering deformation module geological layers of the soil base is in the range of 10.1 ... 21.9 MPa. As the foundations for the building, it was decided to use a monolithic reinforced concrete slab of a solid cross section with a thickness of 1200 mm, with dimensions in the plan of 30.0 × 30.0 m. and random rolls that may occur during the construction process and the first years of operation of the building, the installation of injection conductors in the body of the foundation plate was provided. Injection conductors - plastic pipes with a diameter of 110 mm were installed on a continuous grid with a pitch of 0.9 ... 1.1 m. Conductors were installed in a vertical position and were attached by wire to the reinforcing frame of the plate during its installation. The lower end of the conductors was buried in the soil of the base under the foundation slab by 5 ... 10 cm, the other end - rose 2 cm above the upper edge of the slab. During concreting and subsequent operation, the upper end of the injection conductors was closed with a special cover to exclude the possibility of concrete mortar and construction debris getting into the pipes.

In case of detection by geodetic observations during the construction process or during the first years of operation of uneven building sediments approaching the maximum permissible (Δs / L) u = 0.002 specified in Appendix 4 of SNiP 2.02.01-83 * “Foundations of buildings and structures”, injection work is carried out mobile solutions in the ground in order to straighten the vertical position of the building. In this case, injection points are assigned at the end of the building in the direction of its roll.

Example 2. In the process of building a 12-story residential building in Novosibirsk, located on a soil foundation, composed of bulk soils of high power (up to 15 meters), uneven precipitation already approached the maximum permissible specified by SNiP at the construction stage. In order to correct its vertical position, work was carried out on the injection of mobile solutions into the ground. Injection points were assigned along the end of the load-bearing wall in the direction of the building roll; initially, according to engineering and geological surveys, 8 injection horizons were assigned for each. Their altitude location was specified by measuring the speed of immersion of the injector in the ground during injection work. In almost all injection horizons, the value of the working (steady-state) pressure was about 3.5 ... 4.0 atmospheres. Thus in most injecting horizons working pressure is monotonically increased to a value of 5.4 ... 6.0 atmospheres at a solution volume injected movable about 1.5 ... 1.75 m ^3, then work on this horizon injection stop. At some injection horizons, a noticeable increase in supply pressure relative to the worker during the injection process was not observed and work was carried out until the flow of the mobile solution in the volume of 2.0 m ³ , after which the injection work on this horizon also stopped. The overall quality and duration of the injection work was monitored based on the results of constant geodetic observations.

Claims (2)

1. A method of adjusting the vertical position of buildings and structures on a slab foundation, characterized in that vertically oriented injection conductors are installed in the slab body with the elevation of one end above the top edge of the slab or the level of the leveling of the ground and the deepening of the other end into the ground under the sole or concrete preparation of the slab, through which injecting the rolling solution under a part of the building in the direction of the roll until the supply pressure increases by 40-50% with respect to the working pressure or of flow of the movable solution in a volume of 2 m ³ per one injection horizon, while the number and height position injecting horizons administered according geotechnical investigations and clarify the results of measuring the sink rate of the injector into the ground, and the need for injection works determined based on geodetic observations behind a building or structure during the construction process and the first years of operation. 2. The method of adjusting the vertical position of buildings and structures on a slab foundation according to claim 1, characterized in that plastic, metal or asbestos-cement pipes of industrial production with an inner diameter sufficient to immerse injectors through them with a minimum clearance are used as injection conductors.

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