RU2361067C1 - Method of well production of liquid mineral susceptible to temperature phase transition - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention refers to oil and gas industry, particularly to well production of liquid minerals. The method consists in pumping hot heat carrier via a closed circulation system formed by means of arrangement of an additional suspended process column between a conductor string and a producer connecting annular and interior spaces of the suspended process column and surface capacity and pump equipment after the principle of communicating vessels through a well head piping. To this purpose in the process of producer boring upon cementing the conductor string there is carried out well sinking for the suspended process column and further for the producing column; first the suspended, then producing columns are lowered; cement behind the producing column is lifted to depth of 50 m below a shoe of the suspended column; formed circulation system is immediately flushed. Further the producing reservoir is exposed; the producing column is protected from solid formations by means of thermostating owing to continuous or periodical pumping of hot heat carrier via the formed circulation system.

EFFECT: increased reliability of column protection and reduced costs.

1 dwg, 1 ex

Description

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

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 cooled and undergo a temperature phase transition, which results in contamination of the well equipment with solid formations, partial or complete plugging spaces with precipitated salts and a decrease or complete cessation of the yield of natural brine from the well. The loss of salts in the column and the formed salt plugs do not allow the production of borehole brines downhole.

There is a method of protecting downhole equipment from the formation of solid precipitation by periodically injecting the estimated amount of scale inhibitor through the well into the absorption zone [SU 1462873 A1, 2000]. 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 [RU 21622513 C1, 01/27/2001], providing 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. When using this method, the efficiency of extraction and transportation of organic liquid and gaseous minerals increases due to a decrease in their viscosity. This method does not prevent the 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 closest analogue is the "Method for the extraction of liquid minerals prone to a temperature phase transition" (Vakhromeev AG Method for the extraction of minerals prone to a temperature phase transition. Patent No. 2229587, publ. Bulletin No. 15, 05.27.2004), in which protection of the production casing from solid formations deposited on the walls of the casing from the extracted mineral in the process of its movement from the reservoir to the wellhead, and the removal of liquid mineral from the reservoir are solved through thermostats s production casing in a 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. To do this, before lowering the production casing in the well by means of hydraulic fracturing (Fracturing), an absorption zone is formed located in the interval of the geological section below the regional confinement pack, isolated from other productive and absorbing horizons by casing strings and communicating through the annular space with a ground receiving device and injection equipment, for why lower the production casing and cement the annular space from the bottom to the bottom of the formed absorption zone, they provide communication through the annular space of the absorption zone with the ground receiving device and injection equipment, then the productive formation is opened and in the process of developing the reservoir and the extraction of liquid minerals, protection against solid formations is carried out by continuously or periodically pumping hot coolant through the annular space into the formed absorption zone moreover, as a heat carrier use a brine of sodium chloride or part of its own minerals - Calcium and magnesium chlorides, or waste processing.

As the tests of the method proposed above showed, it (this method) uses the flow system "ground tanks - annular space - absorption zone", which is irrational due to constant loss of coolant. The coolant does not return to the cycle, but is irrevocably pumped into the absorption zone, which ultimately forms a constant cost component (for the coolant) and its heating in the structure of the cost of fishing, i.e. leads to higher cost of work. The second disadvantage: using this method, it is not always possible to prevent spontaneous crystallization of salts in the absorption zone, which leads to irreversible calcination (absorption zone), which (calmatization) can occur as a result of the irreversible mixing of two different geochemical types of natural waters saturated with salts ( Dzyuba A.A. Unloading of brines of the Siberian platform (Novosibirsk, Nauka, 1984). When the absorption zone is mussed, the bypass flow system ceases to work and the temperature control of the production casing is impossible.

The above-mentioned disadvantages are solved by the proposed method, in which the hot coolant is pumped through a closed circulation system formed by placing an additional suspended technical column between the conductor and the production string, which connects the annular and internal space of the suspended technical column and ground capacitive through the wellhead harness and pumping equipment.

To do this, during the drilling (deep well), the suspension of the technical column is made after the well is deepened under both the suspended technical and production columns, then the production string is lowered, the cement behind the production string is raised to a depth of 50 meters below the shoe string shoe, a double washing cycle is given through the formed circulation system and then open the reservoir, and during the production of liquid minerals protect the production string from solid formations suschestvlyayut incubation of the production string in the range of probable phase transition due to a continuous or intermittent pumping hot coolant - sodium chloride or calcium chloride and magnesium - by annular space formed in the circulation system.

The main advantage of the proposed method for the extraction of "liquid" minerals is the possibility of more reliable and less costly control of the properties of the thermobaric unstable system, which contains substances that are prone to phase transitions due to the closed circulation system of the hot heat carrier, which provides the formation of a thermal curtain around the production column of deep pickling wells on a relatively small volume of circulating coolant.

Thus, the hallmark of the proposed method is the use of a closed loop circulation system through the use of an additional suspended technical column in a deep well and, further, constant or periodic pumping of the coolant in the cycle at the selected optimal mode, maintaining the coolant temperature through its heating in a special apparatus.

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 producing well, in the process of drilling (sinking) which was carried out by the inventive method.

Example.

At the Znamenskoye field of industrial brines, a productive brine bed (6) lies at a depth of 1820-1830 m. To protect the downhole equipment - production casing from the formation of solid sediments (salts) in it that impede the output of produced liquid minerals, here - lithium bromine brine, The following sequence of actions was designed and implemented during the construction of a deep well.

The design of the production well (1) provides for the placement of an additional suspended technical column (2) in the depth interval from the surface to the estimated depth of 700 m, below which the temperature of the rocks exceeds the temperature of the onset of crystallization of saturated saturated brines, the production of which is planned to be organized.

1. The casing-conductor 299 mm (3) is lowered to Ch. 770 m to the bottom of the regional confinement - deposits of the Verkholensk and Litvintsev formations of the Lower Cambrian to isolate the upper freshwater aquifers, and the annulus of the conductor is cemented to the mouth.

2. Next, the diameter of the rock cutting tool is changed and drilling is performed under the production (4) string (114 mm) to a depth of 1730 m, not reaching about 90-100 m to the productive formation (6).

3. Lower the suspended (2) column (219 mm), placing the shoe at a depth of 700 m, then lower the production (4) column (114 mm) to a depth of 1720 m and cement the annular space of the production casing, with cement behind the column ( 4) raise to a mark 50 m below the shoe of the suspension column (2) 219 mm, which is 750 m (see figure 1). A flushing cycle is immediately carried out by pumping a double volume of drilling fluid through the formed conductor (3) - suspended technical string (2) - production string (4) circulation system to prevent the shoe of the suspended string from sticking if cement has been lifted from the production string.

4. Next, the productive brine formation (5) is opened, the wellhead piping (7) is changed, the tubing (6) is lowered and the mouth is tied with a special tank for heating the coolant (8) (solution of sodium chloride or calcium and magnesium chlorides), and the extraction of liquid minerals, prone to a temperature phase transition - bromo-cast brine, in the interior of the production casing is carried out in parallel with the simultaneous or periodic pumping of hot water by ground pumping equipment (9) lonositelya from the heated container (8) into the pipe space outboard of the column (2). This allows you to raise the temperature of the production string. Going down to the shoe of the suspension column, the heat carrier heats the wall of the production string and then through the annular space of the suspension column (spent heat carrier) again enters the ground tanks (8) for reheating.

Thus, in the annulus “conductor (3) - suspended technical column (2) - production casing (4)” of the producing well, a closed working space is formed to ensure the circulation of hot brine for the purpose of temperature control of the production casing (4).

During the test of the pressure brine reservoir along the production string (4), over 6,000 m ^{3 of} liquid minerals, prone to a temperature phase transition - lithium-bromine brines, with simultaneous (independent of the production process) constant pumping of hot coolant sodium chloride or calcium and magnesium chlorides) by mud pumps at the selected optimum mode (2-5 m ³ / h) into the pipe space of the suspension column (2). Uninterrupted operation of the producing well is ensured through heating of the production string with a hot coolant flow in a closed circulation system in the low-temperature interval of the geological section.

Thus, sequentially, according to claims 1 to 4, the claimed “method for downhole extraction of liquid minerals” is implemented ...

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.

Claims (1)

A method for downhole production of a liquid mineral prone to a temperature phase transition, including protecting the production casing of the producing well from solid formations deposited on the walls of the column from the produced mineral in the process of moving it from the reservoir to the wellhead by temperature control of the column in the interval of a probable phase transition by continuous or periodic pumping of a hot heat carrier - a solution of sodium chloride or calcium and magnesium chlorides, and removal from the product a distinct reservoir of liquid minerals, characterized in that the hot coolant is pumped through a closed circulation system formed by placing an additional suspended technical column between the conductor and the production column, connecting the annular and internal space of the suspended technical column through the wellhead piping through the wellhead piping and ground capacitive and pumping equipment, for which, in the process of drilling a production well after cementing, the conduct the ora deepen the well under the suspended technical string, and then under the production string, lower the suspended technical string, then the production string, cement behind the production string is raised to a depth of 50 m below the shoe of the suspended string, immediately flushing through the formed circulation system and then the producing formation is opened, and during the production of liquid minerals, the protection of the production casing from solid formations is carried out by thermostating of the production casing in the probability interval phase transition due to the continuous or periodic pumping of the hot coolant through the formed circulation system.