RU2229587C2 - Method for extracting liquid mineral inclined to temperature phase transition - Google Patents

Abstract

FIELD: liquid mineral extraction technology. SUBSTANCE: according to the method for protecting operation column from solid formations, forming of extracted liquid mineral during its transfer from productive layer to well mouth, before lowering of operation column in the well, by means of hydraulic fracturing, a thief zone is formed. It is formed in the interval of columnar geological section below the pack of regional confining layer, and it is isolated by casing columns of other productive and lost circulation horizons, and it is connected via inter-column space to surface receiving device and to delivery equipment. After that, operation column is lowered, and cementation is performed from well face to formed lost circulation zone. Then, productive layer is uncovered and during process of well completion and mineral extraction protection from solid formations is performed by thermostatting operation column in the interval of possible phase transition. It is performed due to continuous or cycling flow of hot heat carrier along inter-column space into formed lost circulation zone. EFFECT: prevented salt crystallization from oversaturated natural salt waters during their extraction from the well. 2 cl, 1 ex, 1 dwg

Description

The invention relates to downhole methods for the extraction of liquid minerals prone to temperature phase transitions, in particular, concentrated brines, to the lithium bromide industry.

Concentrated natural brines saturating deep-seated productive formations and moving during production from the bottom to the wellhead, revealing in the geological section intervals of permafrost or low-temperature rocks, are supercooled and undergo a temperature phase transition, which results in contamination of the well equipment with solid formations, partial or complete plugging space dropping salts and a decrease or complete cessation of the yield of liquid useful skopaemogo from the well.

There is a method of protecting downhole equipment from the formation of solid precipitation by periodically injecting the estimated amount of scaling inhibitor through the well into the absorption zone [1]. However, using this method, it is not possible to prevent the collapse, often avalanche-like, spontaneous crystallization of salts falling in the wellbore in the zone of permafrost and low-temperature deposits during transportation of concentrated natural brines from the bottom to the wellhead. Significant amounts of inhibitor are required for periodic treatment of the bottom-hole zone and the inner surface of the working columns, which leads to unjustified production costs, an increase in the cost of the production process.

A known method of extraction and transportation of liquid and gaseous minerals [2], which provides for the processing of technological equipment with electromagnetic modulated signals with a carrier frequency of 150-2000 kHz, a modulation frequency of 1-200 kHz and a deviation of 1 Hz, using this method increases the efficiency of extraction and transportation of organic liquid and gaseous minerals due to a decrease in their viscosity. This method does not allow to prevent crystallization of inorganic salts from supersaturated natural brines when they are extracted from wells that have permafrost and low-temperature deposits in the upper part of the section.

The technical essence of the proposed method for the extraction of liquid minerals, prone to a temperature phase transition, is to protect the production string from solid formations deposited on the walls of the column from the extracted mineral in the process of moving it from the reservoir to the wellhead, and removal of the liquid mineral from the reservoir why, before launching the production casing in the well by means of hydraulic fracturing, an absorption zone is formed located in the interval of the geological section packs of regional water confining, isolated from other productive and absorbing horizons by casing strings and communicating over the annular space with the ground receiving device and discharge equipment, for which they lower the production casing and cement the annular space of the technical column (annular space of the conductor and technical column) from the bottom to soles of the formed absorption zone, which ensures communication along the annular space of the absorption zone with the ground then open the reservoir and in the process of developing the reservoir and extracting the liquid minerals, protection against solid formations is carried out by thermostating the production string in the interval of the probable phase transition due to the continuous or periodic pumping of the hot coolant through the annular space into the formed absorption zone, and sodium chloride brine is used as a heat carrier, or a brine is part of its own mineral chloride calcium and magnesium, or waste processing.

The following example and drawing confirm the feasibility of the invention.

On the Siberian platform there is rich lithium content - Li (0.5-0.7 g / l), bromine - Br (11-13 g / l), magnesium - Mg (40-45 g / l), boron - B (up to 2.5 g / l) raw materials are concentrated brines of the deep horizons of the sedimentary cover, but it is characterized by limiting (645 g / l) mineralization values (the sum of dissolved salts). A slight violation of the thermobaric conditions when the productive formations 7 are opened by a deep well or in the subsequent production process leads to a shift in phase equilibria, a process of spontaneous, often avalanche-like crystallization of salts from liquid minerals and the formation of crystalline deposits on the inner surface of pipelines and in the production string of 6 deep wells. As a result of overgrowing of the pipe space and the bottom-hole zone, the exploitation of productive formations becomes impossible. This problem limits the industrial development of deposits of lithium bromine brines in Siberia and makes it impossible to test and operate deep wells.

The main advantage of the proposed method for the extraction of such a liquid mineral is the ability to control the properties of a thermally (thermobarically) unstable system containing in its composition substances prone to phase transitions, i.e. to crystal formation. These substances include highly concentrated salt systems with a salt content above 320-450 g / l, usually 560-630 g / l.

In the future, the invention is illustrated by a specific example of its implementation and the proposed drawing, which shows a schematic diagram of a deep well 3A, in the process of drilling (sinking) which was carried out by the inventive method.

Example.

At the Znamenskoye field of industrial brines (Irkutsk Region), the productive layer lies at a depth of 1925 m.To protect the downhole equipment from the formation of solid sediments that impede the production of produced liquid minerals, here - brine from the well, the following sequence was designed and implemented.

Before exploration well 3A, before passing through (drilling) the producing formation 7, an absorption zone 4 is formed in advance during the drilling process, for which:

- casing - a conductor of 299 mm 3 is lowered to a depth of 570 m at the bottom of the regional confinement - sediments of the Verkholensk Formation of the Lower Cambrian to isolate the upper freshwater aquifers and the annulus of the conductor is cemented to the mouth;

- they drill under 219 mm 6 production casing to a depth of 1825 m, not reaching 100 m to the reservoir, cement 5 behind the casing is raised to a mark 50-70 m below the conductor shoe - casing string of 299 mm;

- form the absorption zone 4 by the method of hydraulic fracturing (hydraulic fracturing) within the Bilchir horizon of the Angara Formation under a pack (thickness) of the regional aquifill. Hydraulic fracturing is carried out before the 219 mm production casing is lowered, but after drilling under the production casing so that the drilling fluid does not go into it (absorption zone). The injectivity of the absorption zone is determined, which is 1870 m ³ / day here when pumped with a high pressure pump;

- 219 mm production casing 6 is calculated for shear pressure in the interval of the working part of the annular space to the absorbing zone (i.e., that part of the casing that is supposed to be used for re-injection (pumping) of the hot heat carrier — spent brine through annular space 6 into the absorbing zone 4, while the pressure value is the sum of the injection pressure (at the mouth) and the pressure created by the liquid column;

- make the opening of a high-yield productive brine formation 7, with the simultaneous injection of high-temperature brines into the absorption zone 4.

Thus, in the annular space of the conductor - production casing 2 of well 3A of the Znamensky industrial brine field, a working space is formed to ensure continuous injection of hot brine into the absorption zone.

In the process of opening the reservoir by the production casing for four days, about 6,000 m ^{3 of} lithium-bromine brines was obtained by self-pouring with simultaneous continuous reverse injection of hot brine by drilling pumps at the selected optimal mode (5-50 m ³ / h) of brine into the absorption zone 4. Later during pilot operation hole 3A for 6 months received at different modes of self-flowing of about 20,000 m ³ of brine with parallel continuous injection of the proposed method, mud pumps at the selected optimal m mode hot brine thereby ensure smooth operation of the production well.

So, at the Znamenskoye field of industrial brines (Irkutsk region) in the section interval 0-800 m, characterized by temperatures below T _crests. 25 ° C, operation of the reservoir with T> 25 ° C based on the effect of the thermal curtain is ensured. In this case, a) the system (phenomenon) of heat flow (heat and mass transfer) was used; b) the isolation system of the production casing (through the annular-annular space) from the rocks in the low-temperature (below 25 ° C, i.e. below the crystallization onset temperature) interval of the geological section.

Thereby, a method of mining is sequentially implemented.

If for surface pipe systems the “pipe-in-pipe” construction leads to an increase in the cost of the transport system as a whole, then for deep wells the generally accepted “telescope” system just favors thermostating of the working (operational) string through the next one — the conductor, which suggests the claimed method. Favors the proposed technical solution and the fact that in deep wells with depth, the temperature rises by the value of the geothermal gradient. Therefore, it is the upper part of the well that needs temperature control, which is in the temperature range below T _crit 25 ° C. Technically, this is easily linked to the “telescope” design generally accepted in drilling, because in this upper interval of the geological section, the design of the deep well “column in column” is used.

Thus, the hallmark of the method is the use of the “Thermos” effect or the Dewar vessel - a thermal curtain around the production string of a deep desalination well, which ensures the stability of temperature conditions, which is achieved in series by constructing the described structure of the well, forming an absorption zone and its isolation relative to other horizons and, further, by constant injection at the selected optimum mode (5-50 m ³ / h) of the heat carrier — hot brine.

This feature allows you to:

1) for the first time under production conditions, it is reliable to ensure the continuity of the selection of liquid minerals, here concentrated industrial lithium-bromine brines; to increase the technical and economic indicators of the development of the field: a) by reducing the volume of deep drilling - here ~ $ 1700 thousand per one drilled, i.e. saved deep burying well and b) - due to optimization of the process and operation of the selection field - the shift teams and the shift supervisor for thawing salt plugs leave the work schedule (work schedule), and the work schedule looks continuous;

2) to ensure pumping of the injected fluid through the annular space, which in this particular example reduces the internal bursting pressure on the production string by 219 mm by about 50% due to the backpressure of the injection and the pressure provided by the specific gravity of the solution buried in the absorption zone.

Industrial applicability

The proposed technical solution through the preservation of stationary temperature conditions in the production casing operating with liquid minerals, namely, concentrated industrial bromo-lithium brine, allows to achieve the effect of continuous operation of the well and, therefore, the entire underground and surface complex - the ground part of the field, including pipelines and communications, factories for the processing of lithium bromine brines, which is confirmed by the industrial practice of the long-term operation of deep mining wells gins. This implies the possibility of optimizing the parameters of the productive formation, and through this - optimizing the parameters of the entire production complex and its technical and economic indicators.

The effect of using the method can be reflected as a technical effect - providing the fundamental possibility of industrial production of liquid minerals - concentrated natural brines that are prone to phase transitions, improving the operation of mining and conveying equipment and the associated economic effect of reducing the volume of deep drilling of individual injectors wells (in real conditions of the Znamenskoye field, this is about $ 1,700 thousand per well).

The environmental effect of the application of the proposed design is 100% utilization (burial) of the obtained liquid minerals and products of its processing in the version of work with industrial brines.

The proposed technical solution allows you to control the properties of a thermally unstable system (concentrated natural brine) containing substances that are prone to phase transitions, as well as to ensure the continuity of production (removal) of liquid minerals, in particular industrial lithium-bromine brines, from the reservoir wellhead.

Sources of information

1.SU 1462873, A1, 01.20.2000.

2. RU 21622513, C1, 01/27/2001.

Claims (2)

1. A method of producing liquid minerals prone to a temperature phase transition, including protecting the production string from solid formations deposited on the walls of the column from the extracted mineral in the process of moving it from the formation to the wellhead, and draining the liquid mineral from the formation, characterized in that before lowering the production casing in the well by means of hydraulic fracturing, an absorption zone is formed located in the interval of the geological section below the pack of regional water a, isolated by casing strings from other productive and absorbing horizons and communicating along the annular space with the ground receiving device and injection equipment, for which the production casing is lowered, the annular-annular annular space of the conductor and the technical casing is cemented from the bottom to the bottom of the formed absorption zone, open productive layer and in the process of developing the reservoir by extracting liquid minerals, protecting the production string from solid azovany performed by incubation of the production string in the range of probable phase transition due to a continuous or intermittent pumping of the hot coolant in the annular space formed by the absorption zone. 2. The method according to claim 1, characterized in that as the heat carrier use a hot brine of sodium chloride or part of its own minerals - brine of calcium and magnesium chlorides or the waste of its processing.