RU2074925C1 - Method for construction of vertical drainage - Google Patents

Abstract

FIELD: drainage for land reclamation, deep water supply, construction of basins. SUBSTANCE: method implies constructing several drain wells with filter columns, creation a through channel in earth from them section by section, introduction of water collection pipeline into channel from its end face with passing through filter columns, creation of openings inside columns in water collection pipeline. If necessary, drilled between drain wells are additional bore-holes down to depth of water collection pipeline, and sections of through channel are formed from them. In loose and non-cohesive ground, channel section are formed by washing-out of ground by streams of liquid in gas flow. EFFECT: high efficiency. 3 cl, 7 dwg

Description

 The invention relates to the field of construction and can be used to drain territories, pits, for water supply from groundwater.

 A known method of constructing vertical drainage, including drilling a number of wells, installing filter columns in them, laying a drainage collector and attaching filter columns to it (Flooding forecasts and calculation of drainage systems in built-up and built-up areas. Reference guide to SNiP M.I. 1991, p . 122-124, Fig. 50).

 The disadvantage of this method is the laying of the collector in the trench, as well as in the construction of inspection wells above the wellhead, which complicates the work and requires increased costs, especially with a significant depth of laying the collector in water-saturated soils.

 Closest to the claimed technical solution is a method of constructing vertical drainage, including the construction of a number of vertical drainage wells with filter columns and an underground drainage pipe connected to them (see AS USSR N 1532658, E 02 B 11/00, 1987).

 The disadvantages of this method are laying the pipeline into the trench and connecting it to the filters through the filter bed, which complicates the work, especially with a significant depth of the pipeline, and creates excessive hydraulic resistance between the wells and the drainage pipe.

 The technical result of the invention is to reduce costs and construction time due to trenchless laying of the catchment pipeline and its direct connection with the filter columns of the wells.

 The specified technical result is achieved due to the fact that in the method of constructing vertical drainage, including the construction of a number of vertical drainage wells with filter columns and an underground drainage pipe connected to them, a through opening under the pipeline is made in each filter column, after constructing wells from the openings of the filter columns sectional formation of a through channel in the soil, a drainage pipeline is introduced into the channel from its end, the front end of which is closed and supplied They are guided by a guide tip and form holes in the pipeline inside the filter columns. Between drainage wells, additional wells can be drilled to the depth of the drainage pipeline and the formation of sections of the through channel from them. The formation of sections of the through channel, mainly in incoherent and weakly connected soil, is carried out by erosion of the soil by streams of liquid directed along the axis of the pipeline in the gas stream. In this case, before the formation of sections of the through channel, the water intake part of the filter column is isolated from the opening, before the holes are formed in the pipeline, hardening material is supplied to the opening location, and when the holes are formed in the pipeline, the insulation of the water reception part of the filter column is removed.

 In FIG. 1 shows the formation of a channel in the ground and the introduction of a drainage pipe into it; in FIG. 2 built vertical drainage with a drainage pipe located above the water intake parts of the filter columns; in FIG. 3 constructed vertical drainage with a catchment located under the water intake parts of the filter columns; in FIG. 4 insulation of the water intake located under the pipeline; in FIG. 5 isolation of the water intake located above the pipeline; in FIG. 6 - formation in the soil of the channel section; in FIG. 7 interfacing the water intake of the filter with the drainage pipe.

 The method is as follows.

 At the end of the drainage route, a workplace is prepared for the subsequent input of the drainage pipeline, for example, in well 1, which will then serve as the drainage drainage well, or at platform 2 at the bottom of the pit, etc. At the workplace, a mechanism 3 for introducing the pipeline, for example a jack installation or winch with pulley block.

 On the drainage route, drainage wells 4 are drilled and filter columns 5 are installed in them. Each filter column 5 has a through opening 6 located at the level of the drainage pipe 7. From the filter columns 5, through the openings 6, the connecting sections 8 of the through channel 9 are formed, from which the pipe 7 is introduced at its end by a mechanism 3. The pipe 7, moving inside the channel 9, passes through the openings 6 in the filter columns 5. After entering the pipe 7, holes 10 are formed inside the filter columns 5, providing hydraulic ical filter connection with a catchment pipe. These operations are common to various soil conditions.

 The specific auxiliary operations, the method and means of forming the through channel 9 may be different depending on the soil conditions for laying the catchment pipe 7.

 The description below refers to the most common soil conditions for the use of drainage, namely, incoherent and weakly connected soils, including water-saturated, sand, sandy loam, loam, silt, etc.

 Before or after the installation of 4 filter columns 5 in the wells, they isolate the water intake part 11 from the aperture 6 to protect it from contamination during subsequent operations. When the water intake part 11 is located below the opening 6, insulation is carried out, for example, by a jumper 12, and when the water reception part 11 is located above the opening 6, for example, by a pipe 13. The opening 6 is closed with a temporary plug 14, for example, in the form of an inflatable swab.

 After installation in the well 4 of the filter column 5, the water inlet portion 11 is sprinkled with filter material 15. The location of the opening 6 is sprinkled with fine-grained soil 16, and a layer 17 of hardening material is formed above it. The rest of the annulus is filled with arbitrary material, such as local soil.

 Then, the following operations are carried out for laying the catchment pipeline 7. In the well 4 closest to the beginning of the route, a temporary plug 14 is removed from the filter column 5 and a downhole monitor 18 with side nozzles 19 in its lower part is installed in the filter column 5. The nozzles 19 are located at the level of the opening 6 and are oriented along the axis of the pipeline 7. In the monitor 18, liquid and gas, such as water and air, are separately supplied under pressure. The streams of liquid 20 flowing from the nozzles 19 in the gas stream 21 erode one or two oppositely directed extended caverns (sections of the future through channel) in the soil, one of which reaches the wall of the well 1. When the cavity 8 is eroded, the pulp 22 enters the filter column 5 and expires along her (or protective tube 13) to the surface. At the end of the erosion of the caverns 8, another liquid, for example, a clay solution, providing long-term stability of the caverns, can be fed into them. The downhole monitor 18 is removed from the filter column 5. Then, similar operations for the formation of caverns 8 are performed from the next well 4, connecting the caverns with the previous ones. A sign of the connection of adjacent cavities is the disturbance of the liquid, the appearance of gas bubbles, level fluctuations in the previous well 4.

 If the distance between the drainage wells 4 exceeds the length of the two oncoming caverns 8, between the drainage wells 4, additional wells 23 are drilled to the depth of the pipeline 7 and the next sections of the cavern channel 8 are formed from them.

 The connection of the cavity 8 form a through channel 9 passing through the openings 6 in the filter columns 5 of the drainage wells 4.

 In the channel 9 from its end at the beginning of the route, for example from the well 1, pipeline 7 is introduced using the mechanism 3. It is advisable to enter the pipeline 7 simultaneously with the formation of the next sections 8 of the channel 9, ahead of the advancement of the pipeline 7.

 To facilitate the advancement of the pipeline 7, its front end is closed and provided with a guide, for example, a conical tip. In this case, the pipeline 7 is filled with air and has buoyancy in the liquid filling the channel 9, and zero buoyancy can be ensured, which minimizes the friction of the pipeline 7 on the ground and makes it possible to lay it for a long length.

 The pipeline 7 in the process of laying inevitably passes through the openings 6 in the filter columns 5, since the channel 9, through which the pipeline 7 moves, was formed from these openings 6.

 At the end of the input of the pipeline 7, a hardening material 24 is supplied to the filter column 5 in the location of its columns, for example, cement slurry is pumped over the opening 6. The hardening material 24 can also enter the annular part of the channel 9, displacing the liquid in it, for example water or clay , and forming a clip of the pipeline 7, which will ensure its fixation and isolation.

 After the solidification of the material 24 in it and simultaneously in the pipe 8 and the jumper 12 form a hole 25, for example, by drilling. If there is a pipe 13 that insulated the water intake part 11 above the opening 6, the pipe 13 is removed. This completes the operation of laying the pipeline 7 and connecting it to the water receiving parts 11 of the filter columns 5.

 To increase the throughput, the catchment pipe 7 can be laid in several tiers in depth.

 At the end of the operations for laying the pipeline 7, auxiliary equipment is removed and operational equipment is installed, for example, in well 1, for receiving and removing drainage water, which will by gravity come from drainage wells through pipeline 7.

 To implement the method, each filter column 5 containing a water intake 11 and a blind tubular part has a through opening 6 within the blind part. The transverse dimensions of the latter must exceed the transverse dimensions (diameter) of the catchment pipe 7, which will pass through the openings 6. The opening 6 may be made in the form of two opposite holes (if the diameter of the filter column 5 is greater than the diameter of the pipe 7) or in the form of a gap between the parts of the filter column 5 connected by means of overlays 26.

 Example. A vertical drainage is being constructed along a straight route of 800 m in length. Drainage wells are located in increments of 20 m, a water intake well is located in the middle of the drainage route. The depth of the drainage wells is 15 m. Two branches of the 400 m long drainage pipeline with a diameter of 200 mm are laid at a depth of 5 m. The soil is fine-grained, water-saturated sands.

 First of all, a water intake well is constructed with a diameter of 4 m and a depth of 7 m. Two holes are made in the walls of the well for introducing pipeline branches, and sealing devices are placed in the holes. A mechanism with a jack is installed in the well.

 On one of the branches of the drainage route, drainage wells are drilled with a depth of 15 m and a diameter of 500 mm. The well closest to the well is located at a distance of 8 m from its wall, the rest with a step of 20 m. A filter column with a diameter of 200 mm is installed in each well with a water intake part 7 m long, a settler 1 m long and an upper blind part 7 m long. Above the water intake part a jumper made of metal sheet is installed inside the pipe. In the blind part at a depth of 5 m there is an opening in the form of a gap between pipes connected by curly plates. The dimensions of the opening are 400x400 mm. At the opening level, an inflatable swab with a diameter of 200 mm and a length of 1.5 m is installed.

 The water intake part of the filter column is sprinkled with a sand and gravel mixture, fine-grained sand is poured over it into the interval of the opening location to a depth of 4 m, cement-sand mortar is poured above it with a layer 1 m high and local soil is poured.

After the construction of drainage wells, operations to lay a drainage pipeline begin. An inflatable swab is removed from the filter column of the well closest to the well and a two-pipe downhole monitor is installed in it (to prevent sand from sanding into the opening of the filter column, a clay solution is poured into it before removing the swab). The monitor has a head at the lower end with two pairs of oppositely directed water and air nozzles. The nozzles are oriented along the axis of the pipeline. Separately, water is supplied to the monitor pipes under a pressure of 5-6 MPa with a flow rate of 50-60 m ³ / h and air under a pressure of 0.1 MPa with a flow rate of 3-4 m ³ / h.

 (According to the experimental data of inkjet technology in the construction of anti-filter curtains, soil strengthening and downhole hydraulic mining of minerals, water-air jets with the indicated parameters erode extended caverns up to 10-15 m long, 250-300 mm in diameter in sandy soil. In loosely connected sandy loam soils, loams, silts, the erosion range and the diameter of the caverns are less, and other parameters of the jets are required.In specific soil conditions of the object, technological parameters and sizes of eroded caverns are set by experimentally).

 Water jets flowing from the nozzles of the monitor in the air stream erode in the ground two oppositely directed extended caverns, one of which, directed towards the well, reaches its wall at the hole with a seal. Cavern erosion occurs within a few minutes. In the process of erosion, the water-air-ground pulp enters the filter column in which the monitor is installed, and is poured out of it into a container installed on the surface. At the end of the erosion of the caverns, a clay solution is fed into them through the monitor, displacing water. The monitor is removed from the filter column and installed in the next well, from which the next section of the through channel of two oppositely directed cavities is washed in the same way, one of which is connected to the cavity formed from the previous well.

 Simultaneously with the erosion of the second channel section, the pipeline begins to enter from the well into the first channel section. The pipeline is introduced section by section using a mechanism installed in the well. The formation of subsequent sections of the channel in the ground and the introduction into the channel of the pipeline are conducted in parallel with the advanced formation of sections of the channel. The pipeline entry is completed after the arrival of its tip through the opening of the filter column of the last well. At the end of the pipeline in the well, a valve is installed.

 At the end of laying the pipeline, a swab is immediately installed in the filter columns of the wells immediately above the pipeline and a cement mortar is pumped, which plugs the zones of the interface between the pipeline and the filter columns, and also forms a tube clip in the channel between the wells. After the cement mortar has hardened, it is drilled in each filter column with a diameter of 150 mm, forming through holes in the pipeline and the bridge over the water intake part of the filter column.

 Similar operations are carried out along the second branch of the drainage, after which the mechanism for laying the pipeline is removed from the well and operational equipment is installed to receive and remove drainage water.

 Using the proposed method allows the construction of vertical drainage with trenchless laying of the catchment pipeline practically regardless of the depth of its location at a considerable distance, providing direct hydraulic connection of the pipeline with filters of drainage wells. The advantages of the method are to reduce costs and construction time, in the possibility of carrying out work in cramped conditions, for example, urban development.

Claims (4)

 1. A method of constructing vertical drainage, including the construction of a number of vertical drainage wells with filter columns and an underground drainage pipe connected to them, characterized in that through the openings under the drainage pipe are made in the filter columns, from which, after the construction of the wells, they form a sectional channel in the soil, then a drainage pipeline is introduced into the channel from its end, the front end of which is closed and provided with a guide, for example, a cone-shaped tip, and after the introduction of the pipeline, holes are formed inside the filter columns.  2. The method according to claim 1, characterized in that the formation of sections of the through channel, mainly in disconnected and weakly connected soil, is carried out by erosion of the soil by means of liquid streams directed along the axis of the pipeline in the gas stream.  3. The method according to claims 1 and 2, characterized in that between the drainage wells, additional wells are drilled to the depth of the drainage pipe and form sections of the through channel from them.  4. The method according to claims 1 and 2, characterized in that before the formation of sections of the through channel in each filter column, the water receiving part is isolated from the opening, hardening material is supplied to the opening location in the pipeline before making holes in the pipeline, and when holes are made in the pipeline remove the insulation of the inlet portion of the filter column.

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