SU1352062A1 - Method of hydraulic recovery of materials from underground formations - Google Patents

Abstract

The invention relates to the field of mining and geology, m. used in downhole hydraulic mining of minerals, in the gross testing of productive horizons. The goal is to increase the efficiency of mining steeps and inclined ore formations by ensuring the stability of excavation chambers. At the soil of the ore body 1, an inclined borehole .2 is placed, in which pulping column 3 and a borehole monitor 4 are placed. Erosion of rocks is performed in the direction from the bottom of the borehole to its mouth with interval, sector-like bores. As the camera is developed, the transverse supports 6 are periodically left in it to eliminate the possibility of overlapping overlying hydrogen. In pillars 6, by reducing the radius of the sector-shaped plots, openings 7 are formed. Due to the selected cross-sectional type, the openings remain in a stable state during the process of working the chamber. These holes are also used to bypass the pulp when working at the overlying horizons to the suction of the pulp column 3. 3 sludge. with (L oo JV GO o th

Description

one

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

The aim of the invention is to increase the efficiency of mining steeply dipping and inclined ore formations by ensuring the stability of excavation chambers.

Figure 1 shows the testing of the camera, a general view; FIG. 2 is a section A-A in FIG. on fig.Z - section bb in figure 1.

In the soil of the ore body 1, an inclined well 2 is carried out from the surface to the lower boundary of the extraction. Two parallel wells can also be conducted, one of which performs the functions of a production well and the other an outstanding one. In the inclined well 2 a pulp producing column 3 is placed at the bottom of the well 2 and the well jet 4. Then proceed to the erosion of the rocks of the ore body 1 with a jetting jet directed across the strike of this body with transverse inlets successively from the bottom of the well 2 to its mouth shaped stope 5 by rotating the jetting 4 in the transverse plane. The rocks are washed out over the well 2 with the formation of a chamber with a cross section in the form of a sector, with the sector angle being equal to 140-160 degrees from the conditions for providing gravity pulp from the peripheral to the axial zone of the chamber. The pulp in this axial zone is transported by gravity to the suction of the pulp column 3, which can be equipped with a hydraulic elevator, and is delivered to the surface. As the hydromonitor 4 rises and the rocks erode, there is a danger that the overburden may shift, therefore, as the chamber is worked out, transverse supporting pillars 6 are periodically left in it. To stop each rifle, the erosion radius of sector-like steps decreases, for example,

monitor 4 in the range of rock formations 6, in this case a passage 7 is formed in the rear sight, the cross section of which has the form of a sector with a radius smaller than the radius of the cross-section sector of the extraction chamber. Due to the selected cross-sectional view of passage 7, the pillars remain in a stable state during the process of working the chamber, and the said passages are simultaneously used to bypass the pulp when working at the overlying horizons to the inlet of the pulp-raising column. Conducting these passes while maintaining a stable state of the pillars allows reducing losses in the latter, while from a technological point of view, the performance of these passes presents no difficulties and is a repetition of operations on sectoral approaches, but with a smaller erosion radius.

If there are two wells in the lower displacement, the pulp-lifting column is in place, at the same time, the wells are knocked down at the suction level, and when the chamber is developed over the lower well, the rear sight is constantly maintained, which prevents the pulsating column from damage.

Claims (1)

The formula was invented, and a method for the hydraulic extraction of materials from underground formations, inclination of the formation borehole, placement of a downhole hydromonitor and pulp-lifting column in it with its suction at the bottom of the well, erosion of rocks and pulping to the surface, characterized in that, in order to increase the efficiency of mining of steeply dipping and inclined ore formations by ensuring the stability of excavation chambers , the scouring of rocks is carried out in the direction from the bottom of the well to its mouth at intervals, by sector-wise seams, while, as the excavation chamber is formed between intervals, supporting pillars are formed In which form the openings by reducing the erosion radius sec- toroidal zahodok for moving the pulp.