EA009992B1 - Method of buildings of underground constructions and the device for carrying out the method - Google Patents

Abstract

The invention relates to the filed of mining and to building of underground constructions, in particular, in complex mountain-geological conditions and in urban constrained conditions. The method of building underground constructions includes formation of a foundation ditch by installation of a dipping chamber, immersing of the chamber with a simultaneous excavating of soil from the chamber's internal space, while further in process of building the underground construction, the dipping chamber is moved upwards and dismantled. The dipping chamber is moved upwards by lifting mechanisms which are resting on a power girder and interior supports up to the height of individual zones of the dipping chamber. In process of building the underground construction hollows between stacks of the being built underground construction and the native soil are filled in with filled soil, and the telescoped top zone of the dipping chamber is dismantled. The dipping chamber consists of the lower strengthened zone, basic zones, with equidistant from each other interior supports, and passive zones. The lifting mechanisms rest on a reinstalled power girder. The zones of the dipping chamber are mounted of constituent parts. Prior to starting to build of a underground construction, in the formed foundation ditch, in the power zone of the dipping chamber, there is stipulated a possibility of installation of equipment for a piercing and/or drilling in any lateral direction for a laying and/or repairing of underground communications.

Description

The invention relates to the field of mining and the construction of underground structures, in particular, in complex mining and geological conditions and in urban cramped conditions.

There are many difficulties and obstacles that may arise during the construction of underground structures. In particular, during the construction of wells it is necessary to pass layers of soil saturated with water and eroding the walls of the mine, there may be a “hang” of the rings in the well shaft, the appearance of “flooded holes”. Granite, basalt and other rocks can also be found. Sandy soil creates additional difficulties in the construction of underground structures by digging the pit.

There is a method of building underground structures by digging a pit with slopes and alternately installing concrete or reinforced concrete rings on each other [1]. It is usually used for the construction of shallow, up to 3 m, wells. Ditches without strengthening walls for the construction of deeper wells are irrational due to the fact that they require significant amounts of earthworks and a corresponding increase in labor costs.

A known method of forming wells, the essence of which lies in the gradual undermining of the soil under the rings and in the excavation of the soil from the inner cavity of the rings. The well descends under its own weight rings [2]. This method justifies itself in the construction of deep wells, up to approximately 10-12 m. But it is inefficient and labor-intensive due to the large amount of manual labor and is used in most cases for the construction of water intake wells outside urban conditions [3].

In the industrial construction of underground structures most often used methods to reduce the collapse of the soil, which makes it possible to significantly get closer to existing sewage pumping stations, foundations of buildings and structures.

There is a method of strengthening the walls of the excavation sheet piling. The sheet pile wall is formed by driving or vibrating the sheet piles, excavation is carried out, and construction and other works are carried out inside such a pit [4]. Upon completion of construction of an underground facility and work on laying communications and engineering networks, sheet piles are to be removed, and the foundation pit is filled with soil. As a rule, it is impossible to remove a sheet pile from the ground without loss and some of it remains in the ground. When blocking, part of the sheet piles can be deformed and for reuse, after its extraction, becomes unsuitable.

The application of this method is advisable for weak, subsiding, swelling and other soils with special properties, high groundwater levels and especially in the construction of bridges and deep underground structures. This method is characterized by minimizing earthworks. However, it is impossible to use this technology near buildings, industrial buildings or underground utilities due to the probability of their damage or destruction. For the construction of underground structures of relatively small dimensions, this method is also irrational due to the high economic costs.

Lowering wells and the method of their construction are also known [5]. Such wells contain a lower part (trunk) with a knife part, which facilitates penetration into the soil, and the walls of the well grow from above. When excavating, the drop well is lowered under its own weight and additional load.

The lowering structure and the method of its construction, based on the principle of the lowering well, are known. In this case, for pushing the outer shell panels along vertical guides, pushers are used in the form of double-acting hydraulic cylinders, and for a better immersion of the lowering structure, its barrel is equipped with an anti-friction coating and a system for delivering an anti-friction and cement slurry to its outer surface [6].

The way of the bottom of the well does not require a large amount of earthworks, does not cause the need to backfill the soil, it allows to work in the presence of groundwater. However, the use of such a method is associated with the use of expensive equipment and auxiliary equipment; it is rational when building wells of large diameter or, for example, when installing piles in bridge construction.

The closest to the proposed method is the construction of the excavation, according to which a forshacht is constructed, at the base of which the knife edges of the lowering chamber are mounted, and the vertical walls of the lowering chamber are concrete cast on the knife edges. Immerse the camera along the guide posts, vertically immersed and located along the perimeter of the pit. Simultaneously with the immersion of the camera, using the thixotropic cutters, choose the soil [7].

The disadvantage of this method is that the method requires the construction of forshakhty, and therefore, in the cramped conditions of construction, the construction of the excavation involves an increase in working areas, additional installation of vertical guides. Simple, with the use of formwork, the formation of the walls of the lowering chamber implies a loss of time for the concrete mixture to freeze. Also a disadvantage is that the foundation pit constructed in this way does not imply the subsequent extraction of the lowering chamber. After carrying out certain works in the pit, the walls of the lowering chamber remain in the ground.

The present invention is to develop a method and a device for the erection

- 1 009992 underground structures in cramped urban conditions and in places of industrial buildings and the presence of underground utilities, with maximum mechanization of work and minimal construction time.

Another object of the present invention is to create conditions in the trench being formed for laying and repairing underground communications in the manner of a puncture and / or horizontal directional drilling.

The task is solved by mounting the walls of the lowering chamber from individual shields to the interconnected belts, dredging from the excavation, mainly mechanized, and simultaneously lowering the lowering chamber. Then, as the underground structure is erected inside the lowering chamber, it is gradually lifted and, as it grows, the foundation pit is filled with soil into the space between the walls of the underground structure and the walls of the pit below the lower chamber.

The extension of the lowering chamber is produced by lifting mechanisms, which are mounted on equidistantly located from each other supports on the inner surface of the support belts of the lowering chamber. For the lifting mechanism of the lowering chamber, the bottom support is a power beam, which is reinstalled when the walls of the underground structure are erected after the upper extended belt of the lowering chamber is dismantled.

In one embodiment, the lowering chamber is designed for installation in the lower power zone of the equipment for puncture and / or drilling in the lateral direction for laying and / or repairing underground utilities. It is possible to puncture and / or drill in an arbitrary lateral direction.

A more vivid way to build underground structures and a device for its implementation is shown in the drawings.

FIG. 1 is a vertical sectional view of the lowering chamber with the soil extracted from the pit;

FIG. 2 - view of the lowering chamber and the underground structure (well) from above;

FIG. 3 is a vertical sectional view characterizing the erection of an underground structure and the extension of the lower chamber belt;

FIG. 4 - view of the lowering chamber from above with the location of the power beam on the walls of the constructed underground structure (well);

FIG. 5 is a vertical sectional view of the discharge chamber when performing a horizontal puncture; FIG. 6 is a top view of the lowering chamber with equipment for making a puncture.

The method of erecting underground structures consists in the fact that after the formation of the excavation pit by mounting the lowering chamber and its immersion with simultaneous excavation from the inner space of the lowering chamber, the latter is advanced as the underground structure is erected.

The method of construction of underground structures implemented in the following sequence. On the site intended for the construction of an underground structure, mount the first, reinforced belt 1 of the lowering chamber and excavate from its internal space; in the process of excavation, the reinforced belt 1 of the lowering chamber is immersed under its weight and / or forcibly. Then, the following support 2 and passive 3 belts of the lowering chamber are successively mounted on top and continue to excavate and immerse the lowering chamber 4 mounted from the individual belts to the required depth (Fig. 1). In the resulting trench, that is, the inner space of the lowering chamber 4, the walls of the underground structure 5 (Fig. 2) are erected to a height commensurate with the height of the belt located in the upper part of the lowering chamber 4 (Fig. 3). Next, using the lifting mechanism 6 of the lowering chamber, power beam 7 and equidistant supports 8, the lowering chamber 4 is extended to the height of the extended belt 9 located in the upper part of the lowering chamber 4. Then, filling the voids of the excavation between the walls of the erected part of the underground structure 5 and main soil 11. The stage ends with the dismantling of the upper belt 9 of the lowering chamber 4. After removing the last, reinforced belt 1, the construction of the underground structure 5 is completed (Fig. 3).

Device for the construction of wells according to the above method is a lowering chamber 4 in the form of a closed space, consisting of reinforced belt 1, then at least one support belt 2, which on the inner surface equidistantly at least two supports 8 for mounting mechanism lifting the lowering chamber 6. The lowering chamber 4 also includes at least one passive belt 3 (Fig. 1). For lifting the lowering chamber, the device contains lifting mechanisms for the lowering chamber 6, which lower part rests on the power beam 7 and is attached from above to the supports 8 along the inner surface of the support belt 2. The power beam 7 reinstalls as the walls of the well 5 are erected after dismantling the upper extended belt 9 of the lowering chamber 4. (Fig. 3, 4).

When laying new and repairing old underground utilities 12 in the pit, formed by the lowering chamber 4, submerged to the required depth, and before the construction of the underground structure 5 begins, the possibility of carrying out tunneling works is calculated. For example, in the closed space of the lowering chamber 4, equipment 13 is installed to perform a horizontal puncture and / or drilling, followed by laying and / or repairing underground utilities in an arbitrary

- 009992 lateral direction (Fig. 5).

The direction of a horizontal puncture or horizontal well can be defined by a certain form of formwork belts in cross section. At the same time, to make several punctures or to drill several wells, it is sufficient to simply reinstall the corresponding equipment 13 inside the formwork 4 (FIG. 6). Upon completion of the work on laying or repairing communications 12, the underground structure 5 is erected and the lowering chamber 4 is ejected and dismantled, as described above.

Example. In cramped urban conditions, between the highway and the administrative building, it was necessary to lay underground pipelines in the shortest time possible with the construction of an underground structure such as a manhole and the placement of stop valves in it. The configuration and size of the lowering chamber belts were selected based on the available equipment for the production of a horizontal underground puncture, as well as to provide mechanized excavation with an excavator, which significantly reduces the time of work.

The installation of belts 1, 2, 3 of the lowering chamber and its immersion were carried out simultaneously with the mechanical excavation of an excavator based on a wheel tractor "Belarus" from the closed space of the lowering chamber 4. Upon reaching the required depth, the installation of 13 trenchless laying of pipes and 12 (pipes) communications were laid in two horizontal directions with the reinstallation of equipment 13 without the reinstallation of formwork 4 (Fig. 5). The sequence of the construction of the walls of the well 5 was to install standard reinforced concrete rings inside the lowering chamber 4 with the corresponding sequence of extending the lowering chamber 4 using two hydraulic cylinders that act as lifting mechanisms for the lowering chamber 6 and re-installing the power beam 7. Thus, the phased installation of reinforced concrete rings was alternated by phased reinstallation power beam 7 for support of hydraulic cylinders, gradual extension of the lowering chamber 4, stage-by-stage filling of 10 cavities with bulk soil, cat It is caught between the walls of the well and the bedrock 11 and the phased dismantling of the upper extended belt 9 (Fig. 3).

1. The pit is under the well, 1Shr: // \ ualter-sileshg.gi / o5sha-3.1it1

2. How to make a well, 1Shr: // \ y \ y \ y.hp; nkak.gn / \ u11.1bit1.

3. Construction of the well: methods and features, 1Shr: //koraet.gn/51goNe151uo.111t

4. Great Soviet Encyclopedia, State Enterprise "TSB", Moscow, 1957, t. 48, p. 174-175.

5. Great Soviet Encyclopedia, STI "TSB", Moscow, 1955, t. 31, p. 121.

6. Lowering structure and method of its construction. RF patent number 2099533 C1, 03/06/1995, published 12/20/1997.

7. The method of construction of the pit. The patent of the Russian Federation No. 2190725 C1, November 20, 2001, published on October 10, 2002.

Claims (5)

CLAIM 1. The method of construction of underground structures, including the formation of a pit by installing a lowering chamber and its immersion with simultaneous excavation from the inner space of the lowering chamber, characterized in that the lowering chamber is advanced as the construction of the underground structure. 2. The method according to claim 1, characterized in that the extension of the lowering chamber is carried out using the lifting mechanisms of the lowering chamber, the power beam and the internal supports to the height of a separate belt of the lowering chamber with filling the voids between the walls of the erected part of the underground structure and the bedrock as the extension of the lowering chamber and the subsequent dismantling of the upper extended belt of the lowering chamber. 3. The device for implementing the method according to claims 1 and 2, which is a lowering chamber forming a pit, consisting of a lower reinforced belt and at least one passive belt, characterized in that the walls of the lowering chamber are mounted as a prefabricated structure, which contains at least one support belt with at least two equally spaced supports located on its inner surface for mounting the lifting mechanism of the lowering chamber, which comprises a lifting mechanism of the lowering chamber, as well as at least one power beam, which serves as the lower support for the lifting mechanism of the lowering chamber and which is reinstalled when erecting the walls of the underground structure after dismantling the upper extended belt of the lowering chamber. 4. The device according to claim 3, characterized in that any of the belts of the lowering chamber is mounted before immersion of the lowering chamber of at least two components. 5. The device according to claims 3 and 4, characterized in that in the power zone of the lowering chamber prior to the construction of the underground structure, it is possible to install puncture and / or drilling equipment in an arbitrary lateral direction for laying and / or repairing underground utilities.