RU2162147C2 - Method of demudding bottom-hole zone and interhole space of holes for mining of rare metals by method of underground leaching - Google Patents

Abstract

FIELD: operation of boreholes. SUBSTANCE: prior to treatment of bottom-hole zone with field of elastic vibrations, hydrodynamic connection of holes with bed is analyzed and bed hydraulic permeability in interhole space is determined on the basis of hydrodynamic, geological, geophysical information and analysis of parameters of holes of given deposit in the course of their operation. Results of data processing are used for determination of conditions of treatment of bottom-hole zone and interhole space with elastic vibration field. Treatment with elastic vibration field is carried out in preset regime. Rate of removal of mudding materials from bottom hole and interhole space and rate of transfer of metal into leaching solution are monitored. On the basis if monitoring, conditions of treatment with elastic vibration field are corrected and recommendations are given on optimal conditions of hole operation at new values of permeability of bottom-hole zone and interhole space. Concrete conditions of treatment with elastic vibration field of bottom-hole zone and interhole space are offered. EFFECT: higher intensity of operation of production holes in mining of rare metals, for instance, uranium by treatment of bottom-hole zone and interhole space with elastic vibration field. 9 cl, 5 dwg

Description

 The invention relates to the field of operation of boreholes and is intended for cleaning from muds of the bottomhole zone and the inter-well space of technological wells for the production of rare metals by underground leaching.

 A prerequisite for using the method of underground leaching, which has become widespread in the mining of rare metals, such as uranium (see "Underground leaching complexes" / Edited by O.L. Kedrovsky.- M.: Nedra, 1992), is the possibility of the movement of the leaching reagent in ore zone, i.e. ore-bearing rocks must have natural or artificially created permeability.

 Wells are known to lose their productivity during production. This may be a consequence of the natural development of reservoir reserves, a decrease in the permeability of formation rocks in the inter-well pore space, the clogging (clogging) of filters, filter zones of pumping and injection wells. In the pore space, clogging can be caused by the precipitation of gypsum in the case of rocks with increased carbonate content and a number of other reasons. As a result, the effective cross-section of the leach solution flowing into the wells decreases.

 If the decrease in well productivity is not associated with the natural development of reservoir reserves, then it is possible to partially or completely restore the productivity of wells by cleaning the pore space of the bottom-hole zones and the inter-well space or by changing the structure of these areas.

 There are various ways to solve this problem. These include, in particular, exposure to high pressure, water hammer, explosions of small explosive charges, chemical study of the colmated zone (sediment dissolution). All these methods require stopping the wells for a long period and they are unsafe from an environmental point of view (see, for example, the above-mentioned book "Underground leaching complexes").

 It is also known that the action of elastic vibrations on a porous substance by a field (see, for example, Ultrasound. Small Encyclopedia, Sovetskaya Encyclopedia Publishing House .- M., 1979) allows us to solve the problem of its purification from colmatants and to intensify leaching processes during underground metal leaching.

 There is a method of raskolmatization of the bottom-hole zone and inter-well space, based on the removal of mud products by periodically exposing the well and inter-well space to a field of elastic vibrations (see, for example, A. A. Doroshenko, V. A. Belkina, M. A. Kasov "Justification geological criteria for evaluating the expected effectiveness of acoustic impact in oil wells "," Geology, geophysics and oil field development ", N 4, 1994).

 In the known method, the technology of the impact does not go beyond the descent of the downhole emitter of elastic vibrations into the filter zone of the well and processing the bottom hole with an acoustic field. At the same time, it is not taken into account that the effect of the impact may not be positive in all wells (see, for example, I.A. Efimova "Evaluation of the success of acoustic treatment of the bottom-hole zone of an oil reservoir based on data from geophysical and hydrodynamic studies", Proceedings of the All-Russian Research Institute, 113, 1991, pp. 97-100). An analysis of the results showed that the neglect of the features of the reservoir and the state of the bottom-hole zones of the wells can lead to zero or even negative results.

 In addition, the known method does not use the possibility of increasing the effectiveness of the impact by optimizing its modes on the basis of geological data. Also, the possibilities of correction of exposure modes according to operational control data during exposure are not used. T.O. the advantages obtained as a result of increasing the permeability of the pore space of the near-well and inter-well areas after exposure by the field to the action of the field of elastic vibrations cannot always be realized under well operating conditions that were applied before the impact.

 Closest to the proposed method is a method for raskolmatization of the bottomhole zone and interwell space of technological wells for the production of rare metals by underground leaching, including the removal of colmatization products by periodically exposing the well and interwell space to the field of elastic vibrations using one or more sources of elastic vibrations (see SU 1739015 A1, CL E 21 B 43/28, 07/07/1992).

 However, the known method does not take into account the features of the reservoir and, in addition, in the known method there is no correction of the impact regimes according to the operational control during the impact process, which does not always allow it to be used in well operating modes that are used before the impact.

 The present invention solves the problem of increasing the intensity of operation of technological wells in the production of rare metals, in particular uranium, by the method of underground leaching using the impact on the bottom hole zone of the wells and the interwell space by the field of elastic vibrations by choosing the mode of action taking into account the composition and properties of the treated formation and leaching solution and bottom-hole zone state, process efficiency control during exposure and correction of well operation modes after action.

 To this end, in the method of raskolmatization of the bottom-hole zone and the inter-well space of technological wells for the production of rare metals by the underground leaching method, including the removal of mud products by periodically exposing the well and inter-well space to the field of elastic vibrations using one or more sources of elastic vibrations, using one or more sources elastic vibrations, before exposure to a field of elastic vibrations analyze the hydrodynamic connection of wells with the reservoir and they determine the hydraulic conductivity of the formation in the interwell space based on hydrodynamic, geological, geophysical information, as well as the analysis of the parameters of the wells in the field during their operation, according to the data processing results, those wells are selected for which the decrease in productivity is caused by the mudding of the bottomhole zone and the interwell space for the selected wells determine the modes of exposure of the field of elastic vibrations to the borehole zone and the interwell space, including the amplitude, The frequency, duration, order of occurrence, common mode, impact on the bottomhole zone and the interwell space are carried out by exciting elastic vibrations of predetermined exposure modes in them, the rate of removal of colmatants from the downhole zone and interwell space and the rate of metal transfer to the leach solution are controlled, the exposure modes are adjusted according to the results of the control and give recommendations on the optimal modes of well operation at new values of permeability of the bottom-hole zones and inter-well spaces Resulting from exposure to a field of elastic vibrations, then all the operations are repeated. In this case, the data processing when choosing wells for exposure to a field of elastic vibrations is carried out according to the analysis of the structure of the pore space, type of mud and rock permeability of the productive horizon in the interwell space, hydraulic resistance and filtration characteristics of the filter zone, as well as gas saturation of the solution during operation. The above parameters are used to determine the mode of exposure by the field of elastic vibrations, including the amplitude of the elastic vibrations, duration, common mode and sequence of exposure. In the event of a decline in the productivity of wells during their operation, the field is repeatedly exposed to the field of elastic vibrations. To implement the method, equipment is used that consists of a ground-based power source connected by a cable to a borehole source of elastic vibrations or a system of power sources and borehole sources of elastic vibrations, each source containing customizable transducers of electrical vibrations into acoustic ones.

Moreover, the transducers of electrical vibrations into acoustic ones can be performed with a frequency in the range of 5-200 kHz and an elastic vibration energy of up to 10 W / cm ² on the surface of a borehole source of elastic vibrations or with the possibility of working in pulsed mode with a pulse frequency of up to K 5 kHz and medium energy elastic vibrations up to 5 W / cm ² .

 Separate downhole sources of elastic vibrations can operate in the same or different modes, and the exposure mode of downhole sources of elastic vibrations is determined by the results of periodic sampling and analysis of fluid samples with subsequent correction of exposure modes.

 The method of raskolmatization of the bottom-hole zone and the inter-well space of technological wells for the production of rare metals by underground leaching is illustrated in the drawing, where in FIG. 1 schematically shows the dynamics of changes in well productivity over time, in FIG. 2 shows a dynamics curve for the removal of colmatants from the bottomhole zone and the interwell space of the reservoir during exposure to the field of elastic vibrations, FIG. 3 shows the layout of technological wells during the extraction of rare metals by underground leaching, and in FIG. 4 shows an installation for implementing the method.

In FIG. 1 marked:
T ₁ , T ₂ , T ₃ - time points when the treatment of the bottom-hole zone and the inter-well space.

 The dashed line shows the dynamics of changes in the productivity of a well Q without treatment of the bottom-hole zone and inter-well space.

In FIG. 2 is indicated:
T ₁ - the time termination of the field of elastic vibrations,
P - dynamics of changes in the removal of muds from the bottomhole zone.

 In FIG. Figure 3 shows the group and cellular arrangement of wells, and the distance between the wells, the shape of the cells (3-, 4-, 5-, etc. - faceted) depend on many geological and hydrogeological factors, technological requirements, etc.

In FIG. 4 are indicated:
1 - borehole source of elastic vibrations,
2 - cable
3 - ground power source,
4 - casing,
5 - ore deposit,
6 - filter.

 The method of raskolmatization of the bottom-hole zone and the inter-well space of technological wells for the production of rare metals by the underground leaching method according to this invention is applicable only to those wells for which the dynamics of decrease in productivity (see Fig. 1, curve ABC) is a consequence of the "sealing" of the porous space of the bottom-hole zone and formation rocks in the interwell space.

 The selection of such wells according to this invention is carried out by a comprehensive analysis of information on the structure of the porous space, type of mud and rock permeability of the productive horizon in the interwell space, hydraulic resistance and filtration characteristics of the filter zone, as well as gas saturation of the solution during operation, reservoir power, composition and properties of the fluid , the rate of transfer of metal into the solution at the site of ore. The dynamics of the operational parameters of the well is also being studied: productivity, gas factor, bottomhole pressure and reservoir pressure during the life of the well. The methodology for measuring and analyzing the operational parameters of a well is described, for example, in the article "Justification of geological criteria for evaluating the expected effectiveness of acoustic impact in oil wells" by A. A. Doroshenko, V. A. Belkina and M. A. Kasov "Geology, geophysics and development oil fields ", N 4, 1994.

 Based on this analysis, those wells are selected for which the decrease in productivity is due to the mudding of the bottomhole zone and the interwell space. For selected wells, based on the information listed, the modes of exposure to the field of elastic vibrations are set: the intervals of exposure, duration, amplitude, frequency and energy of elastic vibrations, the sequence of exposure to various sections of the interwell space. According to the curves of the dynamics of the decrease in productivity (see Fig. 1), the sequence of exposure in different wells is determined taking into account the degree of decrease in their productivity.

 Having a list of wells selected by the above method, as well as a schedule for the priority of their treatment, they begin work on impacts on the bottom-hole zone and inter-well space in this field.

To implement the proposed method, equipment is used consisting of one power source 3 connected by a cable 2 to a borehole source 1 of elastic vibrations, or a system of power sources 3 and borehole sources of elastic vibrations. Each of the sources of elastic vibrations contains customizable transducers of electrical vibrations into acoustic ones. In this case, the transducers can be performed with a frequency in the range of 5-200 kHz and an elastic vibration energy of up to 10 W / cm ² on the surface of the borehole source of elastic vibrations, and can operate in a pulsed mode with a pulse frequency of up to 5 kHz and an average elastic vibration energy of up to 5 W / cm ² .

 A device for implementing the method works as follows.

 The downhole source of elastic vibrations 1 is lowered on cable 2 to the zone of the productive interval of the selected well (if necessary, several sources of elastic vibrations can be simultaneously affected on the interwell space), the frequency and energy of vibrations are adjusted by changing the parameters of the ground source of electrical vibrations 3 and power and the field is elastic fluctuations in the corresponding bottom-hole zones and inter-well space according to the previously determined values of time and step in impact. In the process of exposure, periodic sampling of the fluid and analysis of the content of colmatant and dissolved metal in it are carried out.

The Kolmatant removal rate curve (see Fig. 2) and the analysis of the dissolved metal content in the solution allow the correction of exposure modes during operation at this point and determine the exposure end time T ₁ (see Fig. 2). Then, sequential processing of other sections of the rock and bottom-hole zones of the wells is performed.

 The degree of effectiveness of the given impact is determined by the increment of well productivity after the impact.

 The impact of the field of acoustic vibrations on the bottom-hole zones of the well and the inter-well space of the productive formations significantly changes the structure and permeability of the pore space.

Further analysis of the decline curve of well productivity over time allows you to determine the time of repeated actions (see Fig. 1, points T ₂ and T ₃ ), the implementation of which will ensure long-term maintenance of well productivity at a high level.

 The above experimental studies have confirmed the possibility of increasing the intensity of operation of technological wells for the production of rare metals by underground leaching by exposure to the filter zone of wells and inter-well space by a field of elastic vibrations (see "Act on a field experiment on acoustic effects on the filter zone of wells", Leninabad Mining and Chemical plant, RU5, from 04.28.87).

Claims (9)

 1. The method of raskolmatization of the bottom-hole zone and the inter-well space of technological wells for the production of rare metals by the underground leaching method, including the removal of mud products by periodically exposing the well and inter-well space to the field of elastic vibrations using one or more sources of elastic vibrations, characterized in that before exposure to the field elastic vibrations analyze the hydrodynamic connection of the wells with the formation and determine the hydraulic conductivity of the formation in the interwell space based on hydrodynamic, geological, geophysical information, as well as analysis of well parameters of a given field during their operation, according to the data processing results, those wells are selected for which the decrease in productivity is caused by mudding of the bottomhole zone and interwell space, for the selected wells, the modes of exposure to the elastic field are set oscillations in the near-wellbore zone and inter-well space, including amplitude, frequency, duration, sequence, common mode, impact They conduct seeding to the bottomhole zone and interwell space, exciting elastic vibrations of predetermined exposure regimes in them, control the rate of removal of colmatants from the near-well zone and interwell space and the rate of metal transfer to the leach solution, adjust the exposure regimes according to the results of the control and provide recommendations on optimal well operation modes with new values of the permeability of the bottom-hole zones and the interwell space obtained as a result of the action of the field by elastic oscillations, then all operations are repeated.  2. The method according to p. 1, characterized in that the data processing when choosing wells for exposure to a field of elastic vibrations is carried out according to the results of the analysis of the structure of the threshold space such as colmatants and rock permeability of the productive horizon in the interwell space, hydraulic resistance and filtration characteristics of the filter zone, and gas saturation of the solution during operation.  3. The method according to claim 2, characterized in that the above parameters are used to set the modes of exposure to the field of elastic vibrations, including the frequency, amplitude of the elastic vibrations, duration, common mode and sequence of exposure.  4. The method according to any one of claims 1 to 3, characterized in that when the productivity of the wells decreases, they are repeatedly exposed to the field of elastic vibrations during their operation.  5. The method according to any one of claims 1 to 4, characterized in that for the implementation of the method using equipment consisting of one power source connected by a cable to a borehole source of elastic vibrations, or a system of several power sources and borehole sources of elastic vibrations, each of the sources of elastic vibrations contains customizable transducers of electrical vibrations into acoustic ones. 6. The method according to any one of claims 1 to 5, characterized in that the transducers of electrical vibrations into acoustic ones are made with a frequency in the range of 5-200 kHz and elastic energy up to 10 W / cm ² on the surface of the borehole source of elastic vibrations. 7. The method according to any one of claims 1 to 5, characterized in that the electrical to acoustic signal converter is configured to operate in an artificial mode with a pulse frequency of up to 5 kHz and an average elastic energy of up to 5 W / cm ² .  8. The method according to any one of claims 1 to 7, characterized in that the individual downhole sources of elastic vibrations can operate in the same or different modes.  9. The method according to any one of paragraphs.5 to 7, characterized in that the mode of exposure of the borehole sources of elastic vibrations is set according to the results of periodic sampling and analysis of fluid samples with subsequent correction of the modes of exposure.

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