SU1504340A1 - Method of extracting materials from producing formations - Google Patents

Abstract

The invention relates to geology and mining and can be used in the testing of productive horizons with coarse inclusions (CLC) and in the mining of mineral resources. The goal is to increase the efficiency of material extraction with a high content of COB by ensuring the reliability of the unit operation. The subterranean formation is opened by a well in which a jetting unit (GMA) is placed. The test interval is divided into layers. The well is filled with bulk material and a perforated pipe (P) is installed at the lower boundary of each layer. The inner diameter P is greater than the maximum outer diameter of the GMA. The dimensions of the perforation holes P do not exceed the size of the overall lifting size of the piece of rock mass, according to the conditions. The development of the reservoir is carried out from the top down by the GMA with the erosion of the rocks of each layer by cutting from the bottom up. When the rock mass is hydraulically lifted to the surface, the overall fractions pass through the holes P, and the COB accumulates at P. When the heaps form, the COB is clamped by them P. After the upper layer has been worked out, the COB is bypassed from P, and P is lowered onto P below lay For this, a simultaneous impact of the jets on the bulk of the COB and the wall P is carried out, which ensures its release. The operations are repeated until the materials are completely removed from the reservoir. 4 il.

Description

The invention relates to geology and mining and can be used in testing of productive horizons with clotted | 1 and inclusions, as well as in the hydroproduction of minerals from similar horizons.

The invention invention - improving the efficiency of material extraction

with a high content of coarse-grained inclusions by ensuring the reliability of the operation of the unit.

Figure 1-4 presents diagrams illustrating the sequence of operations of the method.

The method is illustrated by the example of testing a powerful subterranean formation, which is opened by a well.

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one . The sampling interval is divided into layer 2-4 and a perforated pipe 5 is placed on the border of each layer with the underlying diameter, the internal diameter of which is greater than the maximum external diameter of the downhole jetting unit 6, and the size of the perforation opening is not larger than the size of the rock mass. The pipe 5 in each layer is installed with support on the bulk material, such as sand, gravel, etc., that is poured into the well interval of the underlying layer.

After these preparatory works are carried out, the upper layer 2 is being developed. For this, the well 1 is released from the specified LIRE and the wall of the nozzle 5 is released, and it moves along the stand of the unit 6 to the nozzle located at the lower boundary of the underlying layer 3. As a result, the nozzle system is obtained on the nozzle, around which there are below the coarse clastic inclusions of layer 3 and the coarse clastic inclusions of the upper layer 2 that are retracted from the upper chamber following the descent of the nozzle. The topic is in a clamped state with a new bulk.

After that, proceed to the development of the lower layer 4 with the repetition of these operations.

inert material to the bottom

the end of the pipe 5, located on the border of the upper layer 2 with the underlying layer 3. Then through the holes of the perforation erase the inclined bottom and proceed to the erosion of the layer 2 cut with the bottom up. When the backflow is eroded, the hearth mass is flushed to the perforations of the nozzle 5. At the same time, the overall fractions pass through the openings,

and the coarse inclusions gradually accumulate at the nozzle 5. This prevents the suction body of the unit 6 from being clogged and failed. After working the layer 2 around the pipe 5, a bulk of 7 coarse-grained inclusions is formed, which clamp the pipe 5.

Following this, the well is released from inert material within the underlying layer 3 to the lower end of the nozzle 5 located at the lower boundary of this layer. The nozzle of the overlying layer 2 hangs in the well, as it is tightly clamped in bulk 7. The lower layer 3 is worked out in the same sequence as the overlying layer 2.

When the rear sight between layers 2 and 3 reaches its minimum thickness, the jet of hydraulic unit 6 produces undermining of the rocks behind the branch pipe 5, which is in a hanging position. Due to the simultaneous jet impact on the bulk of 7 coarse inclusions

Claims (1)

Invention Formula A method of extracting materials from productive strata, including opening the well by a well, placing a well jetting unit in it, testing the productive layer in layers from top to bottom with erosion of the rocks of each layer cut up from bottom to top, hydronically lifting the rock mass to the surface to form a pile of coarse inclusions at the lower boundary of the layer and by passing the above inclusions of the overlying layer to the coarse clastic inclusions of the underlying layer at the end of the mining of the latter, characterized in that, in order to increase The efficiency of material extraction with a large content of coarse-grained inclusions due to ensuring the reliability of the unit operation, the well is filled with loose material with the perforated branch pipe installed at the lower border of each layer, whose internal diameter is greater than the maximum external diameter of the unit and the size of perforation holes m of lifting of a piece of rock mass, when a heap of coarse-grained inclusions is formed, they clamp the nozzle, and when In the case of inclusions, they also lower the nozzle onto the nozzle of the underlying layer. 1 FIG. 2 Compiled by N. Chertova. Editor I. Casarda Tehred M. Khodanych Order 5226/33 Circulation 449 VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Moscow, F-33, 4/5, Raushsk nab. Production and Publishing Combine Patent, Uzhgorod, st. Gagarin, 101 FIG. 3 FIG. four Proofreader N. Borisova Subscription