SU1120096A1 - Mineral ic mud - Google Patents

Abstract

1. METHOD OF RESEARCH OF THE MINERAL RESOURCES, including drilling of the main and additional boreholes, coring in the reservoir with minerals and conducting core and reservoir surveys, in order to improve the informativity of the research by obtaining the filtration and geotechnological characteristics of the mineral, a column of pipes is lowered into an additional trunk, overlapping the space between the column pipes and the walls of the additional trunk above the bedding interval th fossil packer, and filtration and geotechnical characteristics of the mineral is determined by pumping a liquid working agen- that through an array of mineral additional trunk sist essentially. 2. Method POP.1, distinguished by the fact that a disturbing effect is created in the main wellbore, and the parameters of the working agent are measured in an additional wellbore.

Description

i

The invention relates to the study of minerals by drilling wells and determining the filtration characteristics, as well as washout, razmokimosti, solubility of minerals in natural occurrence and can be used to study the minerals at all stages of exploration to substantiate the possibility of mining the methods of underground leaching, well mining and hydro mining.

Methods are known for exploring mineral resources by drilling a single well, followed by measuring the filtration and geotechnological characteristics of a mine.

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However, these methods are inaccurate.

Methods for studying minerals by drilling two or more wells, followed by measuring the filtration and geotechnological characteristics of the mineral, are also known.

 At the same time, to measure the filtration characteristics, one well is used as injection or dewatering, and the other - as observant. Dp of determining the geotechnological characteristics of one well is used as an injection, and the other is used as a pulp pT.

However, in the exploration of a deep-seated mineral, these methods require a large amount of drilling.

The closest in technical essence to the invention is a method of exploring a mineral, including drilling the main additional borehole, boring a core in a reservoir with a mineral, and conducting core and reservoir 3j studies.

The disadvantage of this method is the impossibility of obtaining reliable data on the filtration and geotechnological characteristics of the mineral in the array.

The aim of the invention is to increase the informative value of research by obtaining the filtration and geotechnological characteristics of the mineral.

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This goal is achieved by the fact that according to the method of research of minerals, including drilling the main and additional wells, coring in the reservoir with minerals and conducting core and reservoir studies, a string of pipe is lowered into the additional shaft, blocking the annular space between the pipe string and the walls of the additional trunk are higher than the interval of occurrence of the mineral by the packer, and the filtration and geotechnological characteristics 5 of the mineral are determined by pumping a liquid agent through an array of minerals from an additional trunk to the main and back,

0 In addition, a disturbing effect is created in the main well bore, and the parameters of the working agent are measured in the additional bore.

The drawing shows a diagram of mineral exploration.

The scheme includes mineral I, main well 2, additional well 3, string of pipes 4 with packer seals 5 installed on Q, casing 6 planted in the main well bore, deflecting wedge 7, connected to casing 6 .

The method is implemented as follows.

Mineral J, occurring in the form of a seam, line, vein, or other geological body, is drilled with a coring from the trunk of two wells. Geophysical and hydrogeological and core studies of the mineral are carried out in the well by any known method. If there are results that positively characterize the mineral from the point of view of the possibility of its development by underground leaching or borehole hydraulic mining, the described method is realized, Dp of this main borehole in the interval of the mineral deposit is lined with a perforated column 6. At the upper end of the column there is a 5 deflection wedge 7, having perforations in the wedge gutter, allowing free passage of fluid through the wellbore 2 from the bottom to the mouth and vice versa. Then, he drills an additional trunk 3 with coring to the intersection of the mineral. A string of pipes, for example, drill pipes, with packer seals 5 installed on it, is introduced into barrel 3. After this, fluid is pumped in a closed loop: from the flush pump through drill pipes 4 to the bottom of the additional wellbore 3, then through the mineral the wellbore, where the liquid rises along the column 6, and through the holes in the deflecting clique 7 does not come out through the wellbore 2 surface to the flushing pump. Filtration characteristics of a fossil fossil are determined by hydraulic resistances when pumping fluid between the main and additional boreholes. In studies of a mineral resource represented by formations containing a liquid reservoir agent for investigating the filtration and hydrodynamic properties of the formation, a disturbing effect is also carried out, such as lowering the level of the liquid agent in the main borehole 2, and the parameters of the reservoir agent in the drill pipe 4 are recorded. This cavity of the drill pipe performs the functions of a reactive well. After assessing the filtration characteristics of the mineral, the unsatisfactory values of the filtration characteristics are produced at an increase in the permeability of the mineral array, such as hydraulic fracturing. Then, pumping a liquid working agent, for example, industrial water, through the array of minerals from supplementary 3 to the main stem 2 and vice versa, dissolve or erode the mineral and transport it to the surface. At the same time, the geotechnological characteristics of the mineral in natural deposits, such as washability, solubility, razmokeemost, portability, etc., are determined. The degree of extraction of the mineral by the expected method from the rock massif makes it possible to reasonably judge the prospects for the development of this method using a subsurface fossil or borehole leaching of the earth. For example, I. It is necessary to investigate a deep-seated formation of loose watered uranium-containing ores to assess the feasibility of their development by methods of underground hydroproduction and clarify the hydrogeological characteristics of the reservoir. The method is implemented in the following sequence. - A drill hole of a typical exploration diameter, e.g. 112 mm, drill pipe diameter 50 mm, before crossing the mineral formation layer with core sampling. This specifies the interval of the reservoir. A column of casing perforated in the interval of the bed is then installed. At the upper end of the casing string, a deflecting wedge 7 is fastened, also containing perforations, allowing free passage of fluid through the wellbore. At the upper end of the wedge there is a detachable adapter with a loose thread, a column of overflow pipes with a deflector wedge fixed to it, mounted on the drill pipes and lowered into the first well. After orienting the wedge with known methods and installing a casing with a wedge in the borehole, the left-hand rotation of the drill string is disconnected from the adapter mounted on the diverting wedge and removed from the borehole. Then a wedge is drilled and an additional wellbore is drilled with a smaller diameter, e.g. 93 mm, before the secondary formation intersection. At the same time, the drill string passes through a detachment adapter mounted on the deflecting wedge, then along the wedge chute into the additional bore 3 of the well. At the end of the drilling of an additional barrel, inclinometry is carried out and a test tool is mounted, including a perforated pipe on the lower cone of the drill pipe and a packer device 5, driven by loading the drill pipe string, mounted on the bottom of the additional trunk. Packers are installed in the bedding area of dense, stable rocks and provide for 1 the generalization of the annular spaces of the additional and main boreholes. The tool is inserted into an additional barrel and is packaged in its annular space. Then, hydrogeological studies of the formation are carried out using any and 3 methods. In this case, the annular space of the well performs the functions of the central well and the cavity of the drill pipe functions as an observation well. In order to determine the hydraulic gradient of the formation, fluid levels are measured, for example, using an electrical level meter, in the annular space of the main wellbore 2 and in the cavity of the drill pipe 4. The difference in the measured levels is related to the distance between the main and additional wellbores determined by inclinometry, gives the value of the hydraulic gradient of the reservoir. In order to determine the filtration coefficient and the piezoconductivity coefficient of the formation, pumping or pouring methods are used. The liquid is removed from the annular space of the main wellbore by vacuuming or an airlift. At the same time, the fluid level values in the drill pipe are recorded. Then, the values of the piezoelectric conductivity and filtration coefficients are calculated using the Verigin and Bochevar formulas. In this case, in the formulas, instead of the values from the central well to the observation; the distance from the main wellbore to the additional one, calculated from the inclinometer data for the formation interval, is indicated. In order to determine the geotechnical characteristics of the mineral, the working fluid, such as process water, is injected into the drill pipe using a flush pump. At the same time, the fluid pressure in the pump discharge line is recorded. The fluid flows to the bottom of the additional wellbore and then is filtered into the formation. Gradually increasing the pressure of the injection line, from the filtered erosion of the mineral and its removal into the main wellbore, from which the slurry in the casing string 6 and further along the annular space of the main barrel 2 enters the surface. At the surface, the mineral is separated from the working fluid in the separators or cyclones, and the working fluid is fed back to the bottom. In the study of minerals, the pressure and flow rate of liquid raberchea required for filtration erosion and removal of minerals to the surface, the composition of the hydraulic pulp, the particle size distribution of the solid component, the density, the formula of particles and their abrasivity are determined. The smearing, soaking, and solubility of the mineral and host rocks are determined on the basis of a comparative amount and qualitative analysis of the core and hydropulse. Periodically, the washout process is stopped, the drill string is removed from the well, and the parameters of the resulting cavity are monitored by known methods, for example, using sonar. By the shape and size of the chamber formed, the stability of the rocks that make up the mineral is judged - and the roof of the seam. The ratio of the volume of mineral extracted to the surface of the mineral and the volume of KaMepiii makes it possible to estimate the extent to which the mineral has been extracted from the reservoir by the method of erosion. The cost of labor, materials and energy per unit mass of the extracted minerals makes it possible to judge the effectiveness of the method of hydro mining. And p 2. It is necessary to investigate the deep-lying lens of sylvinite ores in order to evaluate the possibility of its development by the method of underground leaching. The method is carried out as follows. A drill hole with a diameter of, for example, 99 mm to the intersection of the mineral. As in Example 1, an additional barrel with a diameter of 76 mm is bored. Hydrogeological and geotechnical studies are then carried out in the following sequence. By zoning, a portion of the mineralized fluid is removed from the well. A drill pipe string containing perforations of c. bottom, and packers .. Packer

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the contact interval of the ore lens with the underlying rocks. Then, the filtration coefficient of the underlying rocks is determined by the pouring method. To do this, a mineralized liquid is poured into the annular space of the barrel, while at the same time fixing the levels of liquid in the annular space of the main trunk with electro-gages. in the cavity of the drill pipe. The filter coefficient values are calculated using the Dupuy formula. At low values of the filtration coefficient, hydraulic fracturing of the underlying rocks is carried out, and mineralized washing fluid is pumped into the cavity of the drill pipe by a drilling pump or cementing unit. After the additional and main boreholes are hydraulically connected at the contact of the lens with the underlying rocks, the geotechnological characteristics of the ore are studied by pumping a leaching agent, such as technical iodine, from the additional borehole to the main along the bottom of the lens using a flush pump. Measurements are similar to those in Example 1. The liquor obtained on the surface is tested for compliance with the requirements of the mining and chemical industries. By changing the hydraulic 1x resistance to pumping the leaching fluid through the mineral resource, Darcy’s dependence is judged to change the filtration characteristics of the mineral in the working area from which the mineral is removed

 ,

&R

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where K is the filtration coefficient; . W - filter area

flow,

Q is the fluid flow rate fixed at the well exit, J is the distance between the additional and main well bore;

iR is the hydraulic resistance to the pumping of fluid through the fossil, and UP is determined by the formula

- Pj,

where P is the pressure in the injection line 15 of the flushing pump when pumping fluid through the fossil J Pn is the pressure loss to flush the well while drilling the main borehole in the interval of the mineral deposit. In accordance with the dissolution of the mineral between the boreholes of the well 25, a hydraulic channel in the form of a cavity is formed. At the same time, the indicator K characterizes the specific hydraulic resistance to the flow of lye with particles of insoluble 30 rocks along the cavity.

Technical and economic efficiency. The proposed method is that the method of research. minerals using the main and additional borehole, I report tsix through the mineral array, compared with the known method allows to evaluate the filtration and geotechnological properties of the deep mineral in the array with the minimum amount of drilling operations using typical geological exploration obo5 rudovani and tool.

Claims (2)

1. METHOD FOR RESEARCH OF USEFUL FOSSIL, including drilling of the main and additional wells, core sampling in the reservoir with minerals and core and reservoir studies, so that in order to increase the information content of research by to obtain filtration and geotechnological characteristics of a mineral, a pipe string is lowered into an additional barrel, the annular space between the pipe string and the walls of the additional barrel is closed above the interval of occurrence of a mineral by the packer, and the filtration and geotechnological characteristics of the mineral are determined by pumping the liquid working agent through the mineral array from the additional trunk to the main one. 2. The method of Pop. 1, distinguished by a rain and the fact that the disturbing effect is created in the main wellbore, and the parameters of the working agent are measured in the additional wellbore.