RU2575193C1 - Method to level building, structure - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method to level a building, a structure includes their research, building preparation, including manufacturing and installation of wales, jack niches and installation of a jack system, comprising flat jacks and a pump station, and also an internal control system comprising resistor sensors of small movements, formation of an external control system. After the installation of wales they drill wells along bearing walls or in the area of the foundation bed, where metal injectors are driven. High-frequency vibrators are fixed to the injectors installed at the side opposite to the building, structure tilt. After lifting of the building, structure with the jack system, they moisturize the subsiding soil via the installed injectors to moisture of 0.75-0.85, close to subsiding properties manifestation by soil. Then high-frequency vibrations are sent to the moist soil, then by means of the jack system starting they correct the building position.

EFFECT: increased operational reliability of a building, reduced material intensity and labour intensiveness in levelling of a structure and its foundation, increased bearing capacity of soils in the process of lifting and levelling of buildings and structures on natural foundations with jacks.

12 cl, 9 dwg

Description

The invention relates to construction and can be used for lifting and leveling multi-storey buildings and various structures that have received excessive rolls, in particular due to precipitation of soils.

There are various methods of lifting and leveling buildings and structures. For example, there is a known method and device for the continuous lifting and leveling of buildings, according to the patent of the Russian Federation No. 2090703 for the invention (IPC E02D 35/00). This method includes: researching the building, on the basis of the results of which they develop the project, then prepare the building, including making and installing power belts, making jack niches and installing a jacking system consisting of flat jacks and a pumping station, as well as an internal monitoring system consisting of small displacement sensors, form an external control system, then detach the building from the foundations and then carry out its alignment by setting a uniform speed odema jacking each niche and lifting factor control value of the time of each jack. But this analogue has several disadvantages. So, the process of lifting a building is carried out step by step, each lifting cycle is divided into subcycles, in each of which they act in such a way that after turning on the hydraulic system, the movements of all jack niches are controlled. After lifting all jacking niches to a predetermined value, the jacks located along one of the main axes of the building (for example, Y) are turned off, then after a given time interval the jacks located on the nearest parallel axis (Y1) are turned off, then after the next specified time interval , disconnect the jacks located on the next parallel axis (Y2), and so on until the jacks are disconnected on the second collinear main axis of the building. This technique provides step-by-step leveling of the building at the same lifting speed on all jacks and control of the lifting values by the time factor. Moreover, on each axis along which the jacks stop, the building is deformed, since this axis is the axis of rotation. In accordance with this, the leveled buildings undergo additional deformations and, as a result, additional destruction.

A known method of leveling the base of the structure by the method of controlled soaking (SNiP 2.01.09-91 Appendix 2. "Features of the design of buildings and structures taking into account their alignment during operation"), the essence of which is to drill wells in a compressible thickness of the soil from the side opposite to the heel, and pumping water into them. At the same time, subsiding soils are moistened and compressed, which leads to the building settling in the guided direction. The positive side of the known method is that the building is aligned with the foundation. The disadvantage of this method is its practical uncontrollability. You can either not bring the building to the required position, or it can acquire a roll to another angle.

The closest to the totality of existing features, an analogue to the claimed invention (prototype) is a method of leveling buildings, carried out by an adjustable foundation with variable stiffness of the supporting part, according to the RF patent No. 99790 for utility model (IPC E02D 27/00). This utility model includes: foundation tape, basement wall, distribution belts, jack openings in basement walls, jack assemblies, a system for lifting and leveling, while jack openings are arranged at different heights from the base of the foundation, additionally forming a broken line the line of separation of the building dividing the lifting part from the supporting foundation part so that the supporting foundation part has different stiffness, when lifting and leveling the building, the forces from the jack nodes c are transferred to the supporting foundation part, the redistribution of forces and compression of the soil base occurs due to the flexibility of the supporting foundation part. The disadvantage of this foundation is the technical complexity of arranging distribution belts and jack openings at different levels. And also the inability to align the foundation itself, which can lead to a building roll in the opposite direction after leveling, since the soil from the side opposite the roll is less compressed than from the roll side. In addition, the disadvantage of this foundation is the broken line of the separation of buildings, separating the raised part and the supporting foundation part. When lifting and leveling buildings, the forces from the jack assemblies are transferred to the supporting foundation part. Redistribution of efforts and compression of the soil base occurs due to the flexibility of the supporting foundation part. All this leads to additional rear deformations and additional destruction.

The task set by the developer of a new method of leveling a building, structure, was to create a method that would improve the further operational reliability of the building, structure, reduce the cost and time of leveling the building, structure and its foundation. And also to increase the bearing capacity of soils when lifting and leveling jacks of buildings and structures on natural grounds in comparison with the prototype and other analogues.

The technical result of the proposed method is to increase the bearing capacity of soils due to their moistening and the use of high-frequency vibrations and, as a result, to increase the operational reliability of the building, structure, as well as reducing the time and cost of leveling the building, structure.

The essence of the invention lies in the fact that the method of leveling buildings, structures includes their study, preparation of the building, including the manufacture and installation of distribution belts, jack niches and the installation of a jack system consisting of flat jacks and a pump station, as well as an internal control system consisting from resistive sensors of small displacements, the formation of an external control system, after mounting the distribution belts, drill wells along load-bearing walls, or over the area of the foundation litas into which metal injectors are driven into, injectors mounted on the side opposite the roll of the building, structure are fastened with high-frequency vibrators, after lifting the building, building the jack system through the installed injectors, the subsiding soil is moistened to a moisture content of 0.75-0.85, which is close to the manifestation of subsidence properties by the soil, then high-frequency oscillations are transmitted to the moistened soil, then by turning on the jack system, the building is adjusted.

Also, the essence lies in the fact that high-frequency vibrations are transmitted to the moistened soil, with a frequency of 1500-3000 vibrations / min with a driving force of 6.1-12.3 kN. In addition, wells with a diameter of 32 mm to 48 mm are drilled. Injectors are also used, which are a metal pipe with an internal diameter of 32 mm to 50 mm and a wall thickness of 3 mm. Injectors are used, made with a plugged and pointed tip and perforation to a depth of subsidence. The distribution belt is made of two channels mounted on both sides of the bearing walls, interconnected by studs, or of monolithic reinforced concrete. The distribution belt parameters are calculated depending on the weight of the building and the distances between the jack units. An external control system is formed of reflective marks installed on the facades of the building, geodetic points, over which coordinate-determining measuring instruments are centered. After adjusting the position of the building, structures through the installed injectors, cement mortar is injected, preventing any further drawdown of the building, structure. After cementation of the soil, the resulting gap between the foundation and the building is selected with metal plates, followed by expansion with steel wedges. In the formed gap, the metal plates are installed one on one, and the last two plates are wedge-shaped, they are hammered on both sides of the building wall towards each other until the gap between them completely disappears. At the same time, along the separation line of the building between the jack openings, an armature frame is mounted, the formwork is mounted and monolithic with concrete mortar.

The invention is illustrated by drawings, in which:

figure 1 shows a building that received a roll, with the injectors installed on it, a distribution belt, flat jacks, and also vibrators located on the injectors installed on the side opposite to the building’s roll;

figure 2 shows the flat jacks in a compressed state;

figure 3 shows the flat jacks in the expanded state;

figure 4 shows the distribution belt in the context of the wall;

figure 5 shows the installed reinforcement and concrete gap monolithic between the raised building and the foundation;

figure 6 shows metal plates and steel wedges hammered before removing the flat jacks;

figure 7 shows the process of aligning a building with a foundation plate;

on Fig depicts the process of eliminating the resulting gap between the foundation and the building after the final elimination of the roll of the building;

figure 9 shows a system of external monitoring of changes in the position of the building.

The inventive method of leveling buildings, structures is as follows.

First, a distribution belt 2 is mounted on all the bearing walls 1. Distribution belt 2 is a beam that receives the load from building 3 between the located jackets 4. Distribution belt 2 is made of two channels 5. The cross-section of channels 5 is selected based on the weight of the building 3 and the distance between the jack packages 4. Channel bars 5 are mounted on both sides of the bearing walls 1 of the building 3, are connected together by studs 6. The distribution belt 2 is placed on the bearing walls 1 for transfer to it in 3. By building ca distribution belt 2 operate the jack openings 7 for mounting flat jacks 8. The flat jacks 8 mounted in a compressed state. Then, an internal control system consisting of displacement sensors 9 is mounted. Displacement sensors 9 are located near each jack opening 7. The displacement sensor 9 converts the rectilinear movement of the building 3, with which it is connected mechanically, into an electrical signal. An electrical signal allows the operator to see in real time the movement of the building 3 relative to the foundation 10. Next, an external control system is formed, which is a geodesic observation of the position of the building 3 and the foundation 10. Geodetic monitoring of the position of the building 3 and the foundation 10 allows the operator to monitor in real time time, the position of the building 3 and the foundation 10 relative to the horizon. An external control system consists, for example, of reflective grades 11 and geodetic points 12. Reflective grades 11 are installed on the facades 13 of building 3. Coordinate-measuring instruments, for example, laser total stations 14, are centered above the geodetic points 12. Then, along the thickness of subsiding soil 15 the load-bearing walls 1 of building 3 or, by the area of the base plate 16, bore holes 17. Wells 17 are drilled in increments of 1 m to a depth of subsidence soil 15. The depth of subsidence soil 15 is determined by the results of geological and yskany. Wells 17 are drilled with a diameter of 32 mm to 48 mm. Next, metal injectors 18 with a diameter of 32 mm to 50 mm are clogged. Injectors 18 are a metal pipe with a wall thickness of 2-3 mm. The inner diameter of the injector 18 is from 32 mm to 50 mm. The inner diameter of the injector 18 is experimentally established by the ratio: ease of immersion, sufficient throughput when pumping the solution. Injectors 18 are performed with a damped and pointed tip 19 and perforation 20 to the depth of subsidence soil 15. Perforation 20 is a drilled or burnt hole. Further, from the side of the building 3, opposite the roll, high-frequency vibrators 21 are attached to the installed injectors 18. To align the buildings and structures in the considered way, a platform vibrator IV-106 with a power of 1.07 kW, the weight of the vibrator is 50 kg is used. The vibrators 21 are attached to the installed injectors 18 located on the side opposite to the roll of the building 3. High-frequency vibrations are created thanks to a three-phase electric motor with a squirrel-cage rotor equipped with pair imbalances. The device operates from a power source of 380 V. The number of vibrators 21 is determined based on the area of the building 3, located on the side opposite the roll of the building 3. Then, the working fluid 22, for example hydraulic oil, is fed into the flat jacks 8. The supply of the working fluid 22 is carried out by turning on the hydraulic pump 23. For the supply and injection of the working fluid 22, a hydraulic pump 23 of the NSh-10 type is used, weighing 3 kg, with a working volume of 10 cm ³ , with a nominal outlet pressure of 16 MPa, a shaft rotation speed of 3000 rpm, volumetric flow 21 l / min. The parameters of the hydraulic pump 23 are selected depending on the number of simultaneously activated jacks 8 and the required lifting speed of the building 3. When the hydraulic pump 23 is operating, the pressure valve 24 is open and the valve on the drain line 25 is closed. The control commands are given from the control panel 26. The flat jacks 8 expand under the action of the pressure of the working fluid 22, and the building 3 is torn off from the foundation 10. Then, the water supply starts to the installed injectors 18.

In this case, the subsidence soil 15 is moistened at the base 27 of building 3. The moisture content is carried out to a moisture content of 0.75-0.85, which is close to the manifestation of subsidence properties by the soil 15. Further, high-frequency vibrators 21 are included. In this case, the oscillation frequency is 1500-3000 vibrations / min, with a driving force of 6.1-12.3 kN. High-frequency vibrators 21 mounted on the injectors 18 transmit high-frequency vibrations to the moistened soil 28. As a result, the thixotropic properties of the moistened soil 28 are manifested, therefore, it is compressed. In this case, thixotropy is understood as the ability of a substance to reduce viscosity (liquefy) from mechanical stress and increase viscosity (thicken) at rest. Under the influence of thixotropy and mass of building 3, the foundation 10 and building 3 are rotated in the direction opposite to the roll. With the help of retroreflective grades 11 and geodetic points 12, the precipitation of building 3 is continuously monitored. If the position of the foundation 10 is approaching a predetermined level, or the movement of the foundation 10 has stopped, or there is a tendency to exceed the calculated values, then the high-frequency vibrators 21 are turned off. Turning off the high-frequency vibrators 21 leads to the disappearance of the thixotropic properties of the moistened soil 28 and the displacement of the base 27 of the building 3. The adjustment of the position of the building 3 is then carried out using flat jacks 8 assembled in jacking bags 4. Next, cement mortar is injected through the installed injectors 18 (cementation is performed soil). Cementation of soils prevents any further subsidence of moistened soils 28 and, as a result, a change in the geometric position of building 3. Then, the final adjustment of the position of building 3 is performed using flat jacks 8 assembled in jackets 4. After completing the removal of the building’s heel 3, a gap between the foundation 10 and the building 3 are selected with metal plates 29. Then the metal plates 29 are wedged with wedge-shaped metal plates 30. In the resulting gap between the foundation 19 and building 3 are installed one on one metal plate 29. The last two metal plate 30 are wedge-shaped. Wedge-shaped metal plates 30 are driven from two sides of the wall 1 of the building 3 towards each other until the gap between them disappears completely. Then, along the separation line 31 of the building 3 and between the jack openings 7, an armature frame 32 is mounted. The armature frame 32 is a combination of a structure composed of rods of the same direction of opposite reinforcement zones of a reinforced concrete element connected by clamps, oblique rods or transverse mounting rods. Next, formwork 33 is mounted and monolithic with concrete mortar 34. Then flat jacks 8 are removed and jack openings 7 are monolithic.

The use of a new method of leveling a building, structure will significantly increase the further operational reliability of the building, structure, reduce the cost and time of leveling the building, structure and its foundation. And also to increase the bearing capacity of soils when lifting and leveling jacks of buildings and structures on natural grounds in comparison with the prototype and other analogues.

Claims (12)

1. A method of leveling a building, construction, including their study, building preparation, including the manufacture and installation of distribution belts, jack niches and the installation of a jack system consisting of flat jacks and a pump station, as well as an internal control system consisting of small resistor sensors displacements, the formation of an external control system, characterized in that after mounting the distribution belts, wells are drilled along the bearing walls or along the area of the base plate, in which clog the metal injectors, high-frequency vibrators are attached to the injectors installed on the side opposite to the building’s roll, after lifting the building, building the jack system through the installed injectors, moisten the subsidence soil to a moisture content of 0.75-0.85, which is close to the manifestation of subsidence soil properties, then high-frequency vibrations are transmitted to the moistened soil, then by turning on the jack system, the building is adjusted. 2. The method of leveling the building, structure according to claim 1, characterized in that high-frequency vibrations with a frequency of 1500-3000 vibrations / min with a driving force of 6.1-12.3 kN are transmitted to the moistened soil. 3. The method of leveling the building, structure according to claim 1, characterized in that the wells are drilled with a diameter of 32 mm to 48 mm. 4. The method of leveling buildings, structures according to claim 1, characterized in that injectors are used, which are a metal pipe with an inner diameter of 32 mm to 50 mm and a wall thickness of 3 mm. 5. The method of leveling the building, structure according to claim 1, characterized in that injectors are used made with a damped and pointed tip and perforated to a depth of the subsidence thickness. 6. The method of leveling the building, structure according to claim 1, characterized in that the distribution belt is made of two channels mounted on both sides of the bearing walls connected by studs. 7. The method of leveling the building, structure according to claim 1, characterized in that the parameters of the distribution belt are calculated depending on the weight of the building and the distances between the jack packages. 8. The method of leveling the building, structure according to claim 1, characterized in that the external control system is formed from reflective grades installed on the facades of the building, survey points, over which coordinate-determining measuring instruments are centered. 9. The method of leveling the building, structure according to claim 1, characterized in that after adjusting the position of the building, the structure through the installed injectors inject cement, preventing any further drawdown of the building, structure. 10. The method of leveling the building, structure according to claim 1, characterized in that after cementation of the soil, the resulting gap between the foundation and the building is selected with metal plates, followed by expansion with steel wedges. 11. The method of leveling the building, structure according to claim 1, characterized in that the metal plates are installed one on one in the formed gap, and the last two plates are wedge-shaped, driving them from two sides of the building wall towards each other until the gap between them completely disappears . 12. The method of leveling the building, structure according to claim 1, characterized in that along the separation line of the building, the structure between the jack openings, an armature frame is mounted, mounting the formwork and monoling it with concrete mortar.

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