SU1346796A1 - Method of hydraulic excavation of materials from thick producing levels - Google Patents

Abstract

The invention relates to mining and geology and m. used in downhole hydraulic mining and gross testing of productive formations. The goal is to increase the extraction efficiency by improving the conditions for hydrotransport of the rock mass in the excavation chamber and hydrotreatment of rocks. The powerful productive horizon is opened by the borehole 1, in which the jetting unit 2 is placed. The hydraulic formation of the rock mass is carried out by radial inlets with a bottom-shaped petal-like shape. Within each run-in, the hydraulic jacking is carried out by layers 5. For this, the jetting jet 6 is moved from the bottom mark of the hydraulic jacking to the top 8, giving an arcuate shape in the vertical plane. After hydroforming the layer 5, by moving the jet 6 in a vertical plane from the upper mark 8 to the lower mark 7, the rock mass is flushed from the bottom of the chamber to the suction side of the dispenser. The method can be implemented using vertical or horizontal nozzles. 2 3.p. f-ly, 2 ill. with (L 00 Oi WITH Oi

Description

one

The invention relates to mining and geology and can be used in downhole hydraulic mining, as well as in gross testing of productive horizons.

The aim of the invention is to improve the efficiency of extraction by improving the conditions of hydrotransport of the rock mass in the excavation chamber and the hydrofusion of rocks.

Figure 1 shows the bottom of the excavation chamber, a view in plan; FIG. 2 is a scheme for mining the horizon in a vertical plane.

A powerful productive horizon is opened by a borehole 1, in which a downhole jetting unit 2 with a packing 3 is placed, which can rotate in a vertical plane. The hydroturbing of the rock mass is produced by radial in- wards 4, giving the shape of a petal in shape. Within each gate 4, the hydroforming is performed by layers 5. To do this, the jetting jet 6 is moved from the lower elevation mark 7 to the upper 8. At the same time, a step 9 forms in the bump stop 5, which prevents the pulp from escaping upwards and all the pulp is directed at high speed streams formed during erosion of the layer 5 trench down to the inlet of the dispensing device of the unit 2, which significantly, in comparison with the known method, improves the conditions of delivery. After hydroforming of layer 5, the jet 6 is moved in the same vertical plane from mark 8 to mark 7 and all the remaining rock mass on the bottom of the chamber is flushed to the suction side of the dispenser.

After the extraction of the next layer 5 in one step, the unit is turned with the location of the nozzle opposite the adjacent step and the next layer is dredged in the last layer, and thus the layers are hydrofluorised in the steps. It is also possible to work out several layers at once within each step 4.

When the layer 5 rotating in the vertical plane of the nozzle 3 is eroded, the optimal shape of the disease is arcuate, since it best meets the requirements of efficient hydrotransport in the chamber, and

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on the other hand, it allows hydroforming without changing the speed of the vertical movement of the jet within the interval of movement.

In the presence of weakening bonds in the rocks, the direction of which is closer to the vertical, the hydrostatic rock formation

10 by a jet moved in a vertical plane allows one to achieve significantly better results than for hydrotube with a horizontal jet displacement.

15 The pulp in the chamber enters the suction unit of unit 2 and is discharged to the surface for further processing.

The method can be implemented with

20 using downhole units with a horizontal arrangement of nozzles. In this case, when the rocks are washed out at the bottom of the chamber, the unit is raised more rapidly than when the rocks are washed out.

25 of the top mark of hydraulic breakdown.

Claims (3)

1. A method for the hydraulic extraction of materials from powerful production horizons, including opening the well horizon, placing the well jet assembly therein and hydrofluording the layers with pulp discharging onto the surface, characterized in that 35 in order to improve the extraction efficiency by improving the conditions of hydrotransport of the rock mass in the excavation chamber and hydrotreatment. Genus, material extraction 40 are radial in- terrations with a face-down in petal-shaped plan, and hydraulic backing within each inlet is layered to form an arc-shaped face in the vertical plane by moving the jet in a vertical plane from the lower end of the hydrocheck to the top with periodic by flushing the rock mass from the bottom of the chamber by moving the jet in a vertical plane from the top mark to the bottom. 2. Method POP.1, differing by the fact that the arcuate bottom is formed by rotating the nozzle of the hydro55 of the romonitor assembly in the vertical plane. 3. The method according to claim 1, about tl and h and Yu and with the fact that the arcuate bottom is formed horizontal on 1346796 the cages of the jetting unit of the lifting at the lower mark of the breaking when lifting, while the speed is greater than that of the upper one. Editor N.Lazarenko Compiled by N. Chertova Tehred A. Kravchuk Proofreader A. Ilyin Order 5105/32 Circulation 452. Subscription VNIIPI USSR State Committee for Inventions and Discoveries 4/5, Moscow, Zh-35, Raushsk nab. 113035 Production and printing company, Uzhgorod, st. Project, 4