LT4980B - Method and device for thermohydroinsulation of underground constructions, disposed in water - bearing ground - Google Patents

Abstract

The invention is intended for protection of underground buildings from the action of underground water and may be used for thermal- and hydro-isolation of underground buildings, built in the aqueous soils. The mode presumes the creation of the hydro-isolated cavity around the building and the creation of thermal- and hydro-isolated layer under the basement of the building and along its external surface. The novelty is the creation of temporary hydro-isolated cavity near the building by inserting the bladdery hermetic telescopic body to the necessary depth by creating the vibration in its internal space and simultaneously pumping the soil out of it. At the bottom of the inserted bladdery pipe the layer of drainage soil is formed as well as the layer of hydro-isolating material on top of the former. The base of the building is laid on the latter layer. The side surfaces of the building are covered by the hydro- and thermal-isolating materials. The empty cavity among the walls of the building and internal walls of the telescopic body is filled with the water-resistant material after what the telescopic body is pulled out.

Description

The invention relates to the protection of various underground devices or structures against the effects of groundwater and may be used for the thermal waterproofing of various underground structures, such as prefabricated reinforced concrete structures, manifolds, gutters, piles, supports and other underground building elements.

A known method of protecting structures in aquifer soils comprises the following steps: forming a cavity under the base of the structure (pad), isolated from the surrounding aquifer, then filling said cavity with drainage material, then removing water from the drainage material by blowing compressed air Patent No. 3930372).

Known protection does not protect the structure from temperature fluctuations.

A known method of protecting structures in aquifer soils, comprising these steps. Underneath the base of the structure (sole) and around its lateral surface forms a space isolated from the surrounding aquifer; the insulated cavity is formed by encircling the structure with a downwardly tapered dome of waterproofing material, the upper edge of which is hermetically fixed to the side surface of the structure above groundwater level and the lower edge is sealed with a waterproofing layer, followed by a drainage material, blowing compressed air removes water from the draining material (see former USSR al. 1067153).

The known method of protection is sluggish because it is necessary to simultaneously form a waterproofing dome and fill its inner cavity with drainage material. The known method is not reliable because the drainage material is in direct contact with the dome of the waterproofing material, which can quickly tear. In addition, a large amount of ground must be excavated around the structure in this way in order to safely perform hydrothermal insulation work, especially when the underground structure to be hydro-thermally insulated is small.

The object of the invention is to increase the reliability of thermal waterproofing and the comfort and safety of work.

The essence of the problem solution is that in the method of thermal waterproofing of underground structures installed in aquifer soils, which comprises formation of a waterproofed cavity on the construction site and formation of a thermal waterproofing layer under and around the soil to form a hollow waterproofing telescopic body to the required depth, forming a layer of drainage material at the bottom of the hollow body cavity, vibrating and pumping the soil at the same time, and forming a layer of waterproofing material on top of the underlying cavity , and wraps the side surface of the structure and attaches to it a layer of hydrothermal insulating material, an empty space between the lateral hydrothermal insulation layer enclosing the structure the inside walls of the oxy and telescopic body fill with waterproof material and then the telescopic body is pulled out.

The proposed method of thermal waterproofing of structures in aquatic soils is to additionally form a waterproof layer around the structure surrounded by a thermal waterproofing layer by filling the gap between the coin layer and the inner wall of the telescopic body temporarily the layer around which the structure is surrounded. Providing a temporary waterproofing cavity by penetrating into the soil to the required depth, the hollow waterproofing telescopic body provides safe and comfortable working conditions by covering the side surface of the structure with a thermal waterproofing layer. In addition, this way, underground construction and thermal waterproofing does not require the construction of a large pit, does not damage the environment of the construction site, and is therefore simple and does not involve high labor costs.

The lateral surface of the molded structure is thermohydro-insulated in parts from bottom to top, starting from the lowest part enclosed by a layer of waterproofing material, then the gap between the waterproofing material and the inside wall of the molded casing fills the telescopic body with height , and then performs similarly the other parts at the bottom until the entire side surface is hydrothermally insulated and the housing is pulled out.

The telescopic body, which forms a temporary insulated cavity, allows the building to be thermohydro-insulated in parts, which allows convenient, reliable and safe thermal-waterproofing of high-rise structures.

The underground structure is injected into the cavity of the telescopic body and positioned centrally in the body, leaving a gap between the inside side wall of the body and the side wall of the body, providing convenient access by covering the structure with a waterproofing layer.

The concentric positioning of the structure leaving a technological gap for comfortable operation in the enclosed waterproofing cavity, and subsequent filling of this cavity with waterproof material improves the reliability of the static thermal waterproofing.

The thermal insulation layer surrounding the lateral surface of the underground structure is a layer of stone wool, coated on both sides with a bituminous coating. This material is inexpensive and reliable.

The drainage layer is stone chippings. The material is local, inexpensive.

The watertight material used to fill the gap between the static lateral waterproofing layer and the inside wall of the molded casing is clay. It is a local, inexpensive and reliable waterproofing material.

At the bottom of the shell cavity, the waterproofing layer formed above the drainage layer is a layer of hydroconcrete covered with a hydro-film.

A device for forming a cavity of underground structures in aquiferous soils, comprising a device for forming a cavity waterproofed against aquiferous soil at the site of the structure and means for forming a thermo-waterproofing layer in said cavity beneath and around the base of the structure, for waterproofing a temporary cavity with ground water, having a housing consisting of at least two telescopically and hermetically sealed hollow sections of waterproofing material, in a housing cavity with a movable and fixed vibrator and suction sleeve fitted in the required part of the housing cavity .

The unit is simple, compact, does not take up much space and is easy to transport, and enables the water-borne soils to comfortably and safely perform thermal insulation of the structures that are injected into the soil.

The invention is explained in more detail in the drawing, which shows a schematic device implementing the method.

The proposed method of thermal waterproofing of underground structures in aquifer soils includes this sequence of actions. Provides a temporary waterproofing cavity at the installation site of the structure by injecting a hollow telescopic body into the soil to the required depth. By allowing the telescopic body to run simultaneously in its cavity, it creates a ground vibration and its suction. Forms a layer of drainage material at the bottom of the inner cavity of the molded temporary telescopic body, for example, a layer of rubble. Forms a layer of waterproofing material on the crushed stone layer, such as a layer of hydroconcrete, which is covered with a hydro-film. On the last layer is placed the base of a structure that is flushed into said cavity and is positioned on a telescopic body that is concentricly flushed, leaving a technological gap (a) between the interior side wall of the flush body and the side wall of the structure. The side surface of the structure is enveloped with a layer of hydrothermal insulation material, such as a layer of rock wool covered on both sides with a bituminous coating. The space between the static side hydrothermal insulation layer and the inner wall of the telescopic body is filled with a waterproofing material such as clay and then the telescopic body is pulled out. If the inlet structure to be thermally hydro-insulated is very high, then its thermohydro-insulation shall be carried out in parts from the bottom to the top. First, the lower part of the structure is covered and anchored by a thermo-waterproofing layer, the gap between the thermo-waterproofing layer and the inner wall of the telescopic body is filled with waterproofing material such as clay, and then the lower part of the The coating and waterproofing process is repeated analogously to the other bottom part of the structure until the entire lateral surface of the structure is thermohydro-insulated and the telescopic body is removed from the ground and raised to the surface.

The device comprises a telescopic body comprising at least two telescopically connected hollow cylindrical parts, the upper part 1 and the lower part 2 made of a waterproofing material, for example, of metal. The housing parts 1 and 2 are interconnected by a hermetically elastic annular seal 3 and have symmetrically spaced weight eyelets 4. In the telescopic housing cavity, with the ability to move and engage in the required part of the housing cavity, a vibrator 5 and a suction sleeve 6 means (not shown) for forming a drainage layer 8 and a waterproofing layer consisting of a hydrobeton layer 9 and a waterproofing film 10, and a gap (a) between the thermo-waterproofing layer 11 consisting of stone wool layer 12 coated on both sides with a bituminous coating 13; the inner walls of the housing are filled with waterproofing material, forming a waterproofing thick layer 14 around the entire side surface of the structure. The device also has means for concentrating an underground structure 15 (not shown in the drawing) in the cavity of the telescopic body.

The proposed thermal insulation of underground structures is performed in this way. Instead of installing the underground structure, a telescopic body is mounted by means of weight loops 4. In the housing cavity, the vibrator 4 and the suction sleeve 6 are fixed in the required position by the vibrator 4, while the suction device 7 sucks the soil out of the housing cavity while the housing slides downwards. The soil is vibrated and pumped until the telescopic body holds the required depth of the aquifer and forms a temporary cavity, waterproofed against the surrounding aquifer. Thereafter, the waterproofed cavity forms a drainage layer 8 of rubble on the bottom, forming a hydrobeton layer 9, which is covered with a hydro-film 10, for example ruberoid, and on the base of the underground structure 15, concentrating the structure and leaving a technological gap (a), providing convenient access by further covering the side surface of the structure 15 and attaching thereto a thermo-waterproofing layer 11, such as a stone wool layer 12 coated on both sides with a bituminous coating 13. When the side surface of the structure is finished, the gap (a) between the lateral layer 11 the walls are filled with a waterproofing layer, such as clay, and then the telescopic body (first lower, then upper) is brought to the surface, reliably closing the underground structure surrounded by a thermo-waterproofing clay enclosure. For thermohydro-insulation of high-rise underground structures, the described thermo-hydro-insulation is carried out analogously, but starting from the lower part of the structure, raising the casing in the same way, until the entire side surface is waterproofed and the casing is removed to the surface.

Claims (8)

DEFINITION OF INVENTION 1. A method of thermo-waterproofing underground structures in aquifer soils, comprising forming a waterproofed cavity at the site's installation and forming a thermo-waterproofing layer under and around the base of the structure, characterized in that it forms a temporary forms a layer of drainage material at the bottom of the hollow body of the hollow body, forming a layer of waterproofing material on the bottom of the hollow body of the hollow body, by vibrating and pumping soil to the required depth, and wraps the side surface of the structure with a layer of hydrothermal insulation, an empty space between the side of the structure covering the side and the inner walls of the telescopic body fill with waterproof material and then the telescopic body is pulled out. 2. A method according to claim 1, characterized in that the lateral surface of the poured structure is thermohydro-insulated in a partial bottom-to-top direction, starting from the lowest part enclosed by a layer of hydrothermal insulation material, a gap between the hydrothermal insulation layer and the inner bottom wall of the telescopic body. Raises the telescopic body at a height less than the height of the enclosure, and then thermohydro-insulates the other bottom parts in an analogous manner until the entire lateral surface is hydrothermally insulated and the body is removed. 3. A method as claimed in claims 1 to 2, characterized in that the underground structure is injected into the cavity of the telescopic body and positioned centrally thereon, leaving a gap between the inner side wall of the body and the static side wall for convenient access by covering the static waterproofing layer. 4. A method according to claims 1 to 2, characterized in that the thermal insulation layer surrounding the lateral surface of the underground structure is a layer of rock wool coated on both sides with a bituminous coating, 5. A method according to claims 1 to 2, characterized in that the drainage layer is rubble. 6. A method according to claims 1 to 2, wherein the waterproof material which fills the gap between the static lateral waterproofing layer and the inner wall of the molded body is clay. 7. A method according to claim 1, characterized in that the waterproofing layer formed at the bottom of the housing cavity above the drainage layer is a layer of hydroconcrete covered with a hydro-film. An apparatus for the thermo-waterproofing method of underground structures to be installed in aquiferous soil according to claim 1, comprising a device for forming a cavity waterproofed from the aquatic soil at the site of the structure and means for forming a thermo-waterproofing layer underneath said cavity. that device for forming a temporary cavity sealed against groundwater, having a housing comprising at least two telescopically and hermetically sealed hollow sections of waterproofing material in the housing cavity, with the ability to move and lock in the required portion of the housing cavity, connected to a ground suction device.