SU1423739A1 - Method of forming cavities in earth through wells - Google Patents

Abstract

The invention relates to the field of construction and can be used mainly in the formation of backfraction screens, guiding drainage screens, for erecting walls in the ground, etc. The goal is to increase the efficiency of cavity formation by ensuring that the soil is eroded with a free stream. When a cavity is formed in the ground, an operational and a production well (c) is drilled. A hydromonitor is placed in operational C, which is introduced into C through a preventer, i.e. mouth C is sealed to washout. The scouring of the soil in the cavity is performed by a downward gas-liquid jet at an angle to the pulp surface. When eroding rocks, the slurry fraction and small fractions of the soil are transported through the dispersed C. Gas (air) gradually accumulates in the bottomhole, the gas-slurry displaces in it, i.e. with the formation of the air layer between the bottom and the surface of the pulp. The gas-slurry section is maintained at the level of the interface with the dispenser C. f-ly, 1 ill. S (l

Description

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The invention relates to construction and can be used primarily in the formation of filtration screens, drainage screens, as well as for erecting walls in the ground, etc.

The aim of the invention is to improve the efficiency of the formation of cavities by providing the erosion of the soil with a free stream.

The drawing shows the circuit of the method implementation.

The method is illustrated by the example of the formation of an underground television cavity for the subsequent construction of a wall B soil. After drilling two wells — operational 1 and dispensing 2 —, a preventer 3 is installed at the wellhead of production well 1, through which well pump 4 is introduced into well 1 to the lower level of the cavity. The soil is washed out in the cavity by a liquid-liquid jet 5. To do this, on the surface of the scoop, liquid is supplied to the pressure column of hydromonitor 4 through an ejector, through which air is drawn into the pressure column. In this case, during erosion, the disintegration of the soil is carried out by a downward stream directed

at an acute angle to the surface of the pulp.

Immediately after the start of erosion, a part of the air separated from the jet enters the annulus of production well 1 and begins to push the liquid back to the bottom of it. When the rocks are eroded, the sludge fraction and small fractions of the soil are transported through the output well 2 by gas-liquid streams to the surface, and the gas (nozzle) gradually accumulates in the bottomhole a gas-liquid separation in the headroom between the 1 and 6 bottom of the well 2. In the process of scouring, the amount of gas introduced into the pressure column is experimentally determined so that the gas-liquid section does not rise at the level of the inlet interface with the production well 2. The gas-liquid level in the bottomhole can be maintained at a given level. It is possible to control with the help of the known level sensors fixed at the end of the jetting machine 4. Thus, in each specific case, the distance between the gas-slurry and the inclination of the jet can be known.

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determine the position of the gas-liquid section and, if necessary, increase the amount of air drawn in by the ejector in case of a gas-liquid interface level.

When sealing the mouth of the production well 1, eroding the rocks with a downward gas-liquid jet and maintaining the gas-liquid section at the specified level, the rock disintegrating is performed with a free jet, which dramatically increases the efficiency of the gas. we increase the effective length of the jet by an order of magnitude.

When conducting research, it was found that the angle of inclination of the jet to the horizon should be no less than Y. Otherwise, the fluid in the bottomhole begins to be ejected by the jet and involved in the circulation, i.e. the jet ceases to be free and becomes partially flooded, which significantly reduces the effectiveness of its impact on the ground.

The upper limit of the angle is determined by the technological and economic factors.

In the event that it is necessary to remove a large material aerated in its depleted space from the cavity, in the dispensing well 2 a slit-lift column is installed, equipped with a hydroelectric heater or air liftm. The rock suction is performed in a sequence from top to bottom, with the addition of a pulp-subsurface that is magnetized to the suction in addition to Moscow time; Colo using a jet jet. After the cavity of the stationed fraction of rock is released, it can be filled with hardening material.

If it is necessary to create an anti-filtration curtain, it is possible to simultaneously inject in a mazmazanized breed with a spray a bonding material, such as cement milk, in a jet. To do this, in the process of erosion, a jet injector is placed in the dispensing well 2, with which the binding material is injected in an upward order as the level of the stored fractions in the developed space increases.

In a number of cases it is advisable to carry out one central operation of an OHHyio well and two peripheral output wells. Then, rock erosion is produced by two inclined jets directed toward the peripheral wells.

Claims (1)

1. A method of forming cavities in the soil through wells, including drilling production and production wells, placing a jetting machine in a production well, washing out the soil with a gas: bone stream from bottom to top with formation of the bottom hole between the wells, formation of pulp and removal of slurry fractions to the surface for a production well, characterized in that, in order to increase the efficiency of cavity formation by providing erosion soil with a free stream, before erosion of the soil, seal the mouth of the production well, and erosion is carried out with a descending stream at an angle to the pulp surface to form. i of the air layer between the bottom and the surface of the pulp, while the section Gg of the s-pulp is secured at the level of the bottom-hole interface, 2, the method according to claim 1, characterized in that the erosion is carried out at an angle of at least y.