RU2187632C2 - Method and device for oil withdrawal from pool - Google Patents

Abstract

FIELD: methods and devices for oil withdrawal and its primary processing at place of oil production for in-house needs. SUBSTANCE: heat-carrying pipe is installed into casing string, and it is provided with, at least, one seal. Injected under pressure into oil producing formation through well are exhaust product of combustion of hydrocarbon fuel of engine of rotary-cylinder type. Force pump is used in form of, at least, one rotary-cylinder force pump. Combustion products of rotary-cylinder engine and/or force pump are injected into oil-bearing formation in form of gases or vapor-gas mixture through heat-carrying pipe heat-carrying pipe is sealed by seal when gas or gas mixture is supplied under pressure to seal. Said pipe is subjected to heat-air insulation. Device for oil withdrawal from pool includes engine producing hydrocarbon fuel combustion products, at least, one injection well and, at least, one producing well, and force pump for supply of exhaust products of combustion of hydrocarbon fuel to oil-bearing formation. Injection well has heat-carrying pipe located inside casing string. Heat-carrying pipe has, at least, one seal which is operated by supply under pressure of gases or vapor-gas mixture with organization of its gas-air heat insulation. Engine and force pump are communicated with injection well. EFFECT: provided complex utilization of technical serviceability of hydrocarbon fuel for increase of oil recovery from oil- bearing formation. 3 cl, 4 dwg

Description

 A comprehensive group of inventions with a universal rotary-cylinder engine uniting them relates to methods and devices for extracting oil from a reservoir and its primary processing on site for own needs. At the same time it can be used to generate electric and thermal energy for production and communal needs of oil production and refining units.

The prototype of the proposed is a method of extracting oil from the reservoir A. with. for the invention of the USSR 376552, which consists in the fact that components soluble in oil and water, for example carbon dioxide, are introduced into the heated water through an injection well under pressure. The method involves introducing into the preheated water components that are soluble in oil and water, lowering the temperature of the mutual solubility of oil and water. Adding to water, for example, carbon dioxide at a volume ratio of water to carbon dioxide from 1: 4 to 1:15 reduces the temperature of solubility of oil in water by 70-130 ^o C.

 A known method of increasing oil recovery according to the patent of the Russian Federation 2061858, which provides for the use in the field close to the injection well of a well-known cumbersome very material and energy-intensive oil refining plant with the addition of its cumbersome low-efficient material-intensive waste heat boiler for burning low-grade oil products, mixing the fumes produced in it gases and water vapor, pumping the resulting gas into the reservoir, as well as mixing the said unit selected from the wastewater system the processing of hot water oil with wastewater and the subsequent injection of the mixture into the reservoir to maintain pressure and displace steam and gas.

 In 1998, in the United States, oil production due to the application of enhanced oil recovery methods amounted to 39.337 million tons, including 23.28 due to thermal methods, of which 22.92 due to steam injection and due to gas exposure 16.05, of which due to miscible carbon dioxide - 9.34, due to chemical exposure - 0.007.

 It is expected that carbon dioxide emitted by industrial enterprises and thermal power plants will be used to pump oil into the reservoir and increase oil recovery from productive formations. The required quantities of carbon dioxide are supplied and will be delivered via pipelines after preliminary treatment. In the combustion products of internal combustion engines, boilers, most of them are carbon dioxide, some water vapor, unburned oxygen, highly toxic oxides of nitrogen and carbon, mechanical impurities in the form of soot, ash.

The disadvantages of the known methods:
- as a solvent agent for the introduction of components using a large amount of water from ground or underground sources (wells, wells, reservoirs);
- hot water is prepared in expensive heat exchangers operating under high pressure and at high temperature with a significant consumption of oil for own needs;
- the combustion products of hydrocarbon fuels, usually used to heat water in known devices, worsen the environmental situation;
- when preparing hot water (solvent agent) and injecting it with the components dissolved in it into the pool, there are increased heat losses due to heating of the casing string and adjacent rocks, unproductive expenses and loss of technical performance of the fuel in the process of converting its energy into hot energy water with components.

 These disadvantages are eliminated in the proposed method.

 The aim of the invention is the integrated use of the technical operability of hydrocarbon fuel to increase oil recovery of oil-containing formations, to produce electric and thermal energy, to bury highly toxic products of fuel combustion in the bowels of the Earth, as well as the primary processing of some oil and the production of light petroleum from it on-site for own needs and other consumers .

 In the proposed method for extracting oil from a deposit, which includes the injection of a supercharger with an overpressure into an oil-containing formation through a well of exhaust products of combustion of a hydrocarbon fuel of an engine, this is achieved by using at least one rotary-cylinder engine as an engine, and as a supercharger at least one rotary-cylinder supercharger, wherein the combustion products of the rotary-cylinder engine and / or rotary-cylinder supercharger are injected into the oil-containing formation in the idea of gases or gas-vapor mixture through a heat-carrying pipe installed inside the casing and equipped with at least one shutter, which seal the heat-carrying pipe with the pressure of gases or gas-vapor mixture and organize its gas-air heat insulation.

Oil, water and the rock in which they are located are heated at the same time with minimal heat loss directly to the deposits by the hot products of the combustion of hydrocarbon fuels, which are pumped under high pressure to the reservoir with at least one rotary-cylinder (RC) supercharger and / or a rotary cylinder engine (RCD). According to its technical capabilities, a rotary-cylinder supercharger and / or engine allows pumping crude combustion products containing mechanical and other impurities with a temperature of up to 1000 ^o C or more, which is significantly higher than the temperature of water vapor, carbon dioxide, hydrocarbon gases, which are usually pumped into a productive oil-containing formation. used for injection into the reservoir. A rotary-cylinder supercharger can receive combustion products for injection into the formation from its own drive engine, for example, an RCD, piston, gas turbine, as well as from extraneous power units with any engines.

 Moreover, for heating oil, water and rock directly in the reservoir, a fully or partially hot heat carrier can be used, for example water vapor, a gas-vapor mixture used to cool housings, rotors, sealing elements, end caps of rotary-cylinder superchargers and / or internal or external engines combustion.

The method also allows for the heating of oil in the compression region of a rotary-cylinder engine for subsequent separation of a portion of the produced oil in the presence of a catalyst or without it into cheap heavy fractions and expensive light fractions, followed by the use of heavy fractions in place of fuel for RCD and light fractions for engines and power units that require the use of liquid fuel of certain conditions. This is achieved in two ways:
1. thermal separation of oil into volatile light fractions removed from the compressive region of the RCD in the form of vapor under excessive pressure, and heavy fractions stored inside the housing of the RCD for subsequent combustion in its expanding region. In this embodiment, oil is used as a coolant for cooling heated housings, end caps, rotors and RCD sealing elements, is heated due to their heat and is simultaneously separated under pressure directly in the compressing part of the RCD. Volatile oil fractions in the form of steam are condensed in a separate heat exchanger. In this case, mainly low-boiling fractions are released and unstable gasolines are obtained.

 2. thermal separation of oil removed from the compressing region of the RCD in the form of an overheated liquid under excessive pressure in a separate chamber having liquid and vapor fraction outlet pipes, inside which nets are placed, some of which are equipped with heating elements and filled with catalyst, while the evaporation chamber is connected with a sprayer, for example centrifugal, and a heat exchanger. In this embodiment, oil is used as a coolant for cooling heated housings, end caps, rotors and RCD sealing elements, is heated due to their heat, and when superheated, with respect to temperature and pressure in the evaporation chamber, enters the atomizer, where one part of the liquid self-evaporates, and the remainder is sprayed. Due to the pressure difference in the chamber and the heat exchanger (condenser), the vapor-liquid mixture penetrates through the first grids, on which large droplets precipitate and flow down, and the vapor and small droplets pass through the second grids filled with a catalyst that is superheated relative to the temperature in the chamber. In the presence of an overheated catalyst, an additional amount of medium-boiling oil fractions are released from the droplets of the liquid fraction, which combine with low-boiling ones, and the vapor mixture condenses in a separate heat exchanger. At the same time, low-boiling and medium-boiling fractions make it possible to obtain stable gasolines and other light oil products.

 To implement the proposed method, one or more rotary-cylinder engines and superchargers according to the patents of the Russian Federation for inventions 2143078, 2143570, 2153088 can be used.

 Each of these rotary-cylinder engines (RCD) consists of at least one cylindrical body, end caps with support and thrust bearings and seals, and a finned rotor with seals in the form of cylindrical bodies of revolution eccentrically placed in it. The area of the engine's RC in which the expansion of the air-fuel mixture burned in the external combustion chamber or combustion and expansion of the air-fuel mixture inside the body occurs is expanding, and the other region in which the compression occurs is compressive. The cylindrical body, end caps and rotor are equipped with cooling jackets and channels for introducing steam or liquid, which can significantly increase the temperature of continuous combustion of fuel in the external or internal combustion chamber and, accordingly, make better use of the technical performance of the fuel to generate electric and thermal energy. The RCD device can be equipped with a RC air blower and a fuel-air ratio regulator according to the technical solution in accordance with the RF patent for invention 2143078. Unlike the known energy converters, the RCD is the only one that allows cooling the working parts of the engine and thereby obtain the highest fuel combustion temperature and thermal efficiency. For him, the octane number of the fuel and the amount of resinous substances in it are not significant.

 Known devices for extracting oil from deposits, containing at least one injection and at least one producing well, for example, as for the invention of the USSR 1464552. A disadvantage of the known device is the need to include in the composition of the device, in addition to two wells, an oil processing plant, a waste heat boiler, i.e. consisting of a main and auxiliary set of equipment, in particular pumps, compressors, receivers, dispensers, pressure controllers for injecting water or steam and / or a miscible agent, for example carbon dioxide, into the formation through an injection well. hydrocarbon solvent, hydrocarbon gas.

 The disadvantages of the known are eliminated in the proposed device for implementing the proposed method for extracting oil from the reservoir and its primary processing into light petroleum products.

 The aim of the invention of the device is the integrated use of the technical operability of hydrocarbon fuel to increase oil recovery of oil-containing formations, to produce electric and thermal energy, to bury highly toxic products of fuel combustion in the bowels while reducing fuel consumption for oil production, quantity and material consumption of equipment, pipelines, devices for extracting oil from deposits, as well as the production of light petroleum products for their own needs and other consumers.

 In the proposed device for extracting oil from a deposit according to the aforementioned method, comprising an engine with production of products of combustion of hydrocarbon fuel, at least one injection well, at least one production well, and / or a supercharger for supplying exhaust products of combustion of hydrocarbon fuel to an oil-containing formation, the goal is achieved by the fact that the injection well is equipped with a heat-carrying pipe placed inside its casing and having, but at least one shutter for If the heat-carrying pipe is overpressured by gases or gas-vapor mixture and organizes its gas-air heat insulation, the engine is made in the form of at least one rotary-cylinder engine, and the supercharger is in the form of at least one rotary-cylinder supercharger, wherein said engine and / or a supercharger connected to an injection well.

 The goal is also achieved by the fact that in the aforementioned device, the production well is provided with a heat-carrying pipe, placed inside it of the casing, with at least one rotary-cylinder supercharger connected to the carbon-carrying pipe, a centrifugal cyclone and / or a separator for separating the gas-oil mixture into liquid and gas fractions and a vacuum rotary cylinder pump for sampling a gas fraction with a high liquid content.

 The goal is also achieved by the fact that the said device is equipped with an evaporation chamber connected to the compression area of the rotary cylinder engine having an oil spray, liquid and vapor fraction outlet pipes and catalytic material grids, some of which have heating elements.

 The oil recovery device may be equipped with a heat exchanger for simultaneously cooling the gas-vapor mixture containing light fractions and heating the crude oil mixture, which is supplied under pressure to the heated compression region of the RCD to cool the housing, end caps, rotor and sealing elements in the form of cylindrical bodies of revolution and subsequent combustion in an expanding area.

 The oil recovery device may be provided with a dispenser, for example with or without a pump, for supplying liquid chemical, microbiological and other components that enhance oil recovery from productive layers to the injection well.

Schematically shown:
- figure 1 is a longitudinal section of a single-cylinder RC engine-steam generator-gas generator:
- in FIG. 2 is a cross section of the RC engine-steam generator-gas generator in figure 1;
- figure 3 is a cross-section of a three-cylinder RC engine-steam generator-gas generator of one air-injection RC and two gas expansion RC machines, for example high and low pressure;
- figure 4 is a schematic diagram of a device for extracting oil from a reservoir and its primary processing using an engine / s, a supercharger / s, a vacuum pump / s, superchargers.

 All machines and apparatuses for oil recovery devices are interconnected by pipelines, the main of which are shown in Fig. 4.

Directions indicated by arrows mean:
A - rotation of the rotors of the RC engines, blowers, vacuum pumps, blowers;
B - rotation of cylindrical seals of rotary-cylinder machines;
In - circulation and supply, including flow, water;
G - the movement of the exhaust gaseous products of combustion;
D - gas movement from the producing well;
To - the movement of condensed volatile fractions;
L - the movement of compressed air;
M - the movement of oil, fuel oil or other liquid fuel;
M ₁ - the movement of the remainder of the oil or other shared material;
MB - the movement of a mixture of water and oil in an oil-containing formation;
N - the movement of combustion products from extraneous sources, such as power units, fire furnaces, furnaces of waste heat boilers, reciprocating, gas turbine engines;
GHG - the movement of a gas-vapor mixture of water vapor and combustion products;
C, T - circulation of intermediate coolants, such as BOT, tasol;
C - the movement of the gas-air mixture circulating through the supercharger 15 and the producing well 13;
CM - movement of a mixture of oil, water, gas, gas condensate from a producing well 13 into an airtight cyclone 18.

 Referring to FIG. 1-4 abbreviations correspond to abbreviations in the description. The number of wells, RC engines-steam generators-gas generators, blowers, cyclones, separators, collectors, pumps, heat exchangers, other elements is specified in accordance with the calculations when developing a project for the development of each specific field.

 The method can be implemented using the proposed device (Fig. 4) for extracting oil from a reservoir, which includes at least one injection well 9, at least one producing well 13, an engine 9.3 with the production of products of combustion of hydrocarbon fuel, and / or a supercharger 10 for supplying exhaust products of the combustion of hydrocarbon fuel to the oil-containing formation 25. The injection well 9 is provided with a heat-carrying pipe 9.10 located inside its casing and has at least one shutter 9.11 for sealing the heat-carrying pipe 9.10 with excess pressure of gases or a gas-vapor mixture and organizing its gas-air heat insulation. Engine 9.3 is made in the form, at least. one rotary cylinder engine, and the supercharger 10 in the form of at least one rotary cylinder supercharger, wherein said engine and / or supercharger are connected by pipelines to the injection well 9, as shown in FIG. 4. At least one self-sealing shutter 9.11 is installed slightly above the location of the oily layer 25.

 In the aforementioned device, the producing well 13 is equipped with a heat-carrying pipe 13.1 with a perforated tip 13.2, located inside it of the casing, at least one rotary-cylinder supercharger 15 connected to the heat-carrying pipe 13.1, a centrifugal cyclone 18 and / or a separator for separating the gas-oil mixture into liquid and gas fractions and a vacuum rotary cylinder pump 20 for sampling a gas fraction with a high liquid content. The connections are sealed and form a sealed circulation circuit.

 Said device may be provided with an evaporation chamber 28 connected to the compression region of the rotary cylinder engine 9.3, having an oil atomizer 27, liquid outlet pipes 28.1 and steam 28.2 fractions and grids 28.3 and 28.4 made of catalytic material, some of which have heating elements 28.5 .

 A single-cylinder RC engine-steam generator-gas generator (Fig. 1, 2) consists of interconnected hollow cylindrical body 1, end caps 2 and 3 with thrust bearings 4, eccentrically located in the body of a cylindrical finned rotor 5 with movable seals 6 in the form of cylinders, resting on the ribs and the inner surface of the housing 1. The housing 1 has protruding crowns 1.9 at the ends, which during the manufacture of the engine are rubbed with end caps 2 and 3, are checked for leaks and jointly marked Xia. The assembly of the housing 1 and the end caps 2 and 3 is provided using calibrated graphite, metal gaskets or without gaskets, which can increase the gaps between the housing and the end caps and significantly reduce the efficiency of the engine. Movable seals 6 in the form of cylindrical bodies of revolution are solid or hollow, closed from the ends. They seal the gaps between the housing 1. by the rotor 5 and the end caps 2 and 3 only during the rotation of the rotor 5. The mechanical seals between the rotor 5, the seals 6 in the form of cylinders and the end caps 2 and 3 are achieved due to the very small gaps in the manufacture of the housing 1 and rotor 5 with the use of special equipment that ensures parallelism and perpendicularity of the surfaces of stationary and rotating parts during assembly and during engine operation. The movement of the seals 6 is carried out by the ribs of the rotating rotor 5. During the rotation of the rotor 5, as shown by arrow A, they due to centrifugal forces are tightly attached to the inner surface of the housing 1 and create a seal between the ribs of the rotor 5 and the inner surface of the cylindrical housing 1. Due to the friction forces, arising during the movement, the cylindrical seals 6 also acquire a rotational movement, as shown by arrow B. In this case, there is rolling and sliding friction against the inner surface of the housing 1 and the surface of the rebate rotor r 5. Friction forces in both cases are very insignificant. Wear of friction surfaces will also be very slight.

The end caps 2 and 3, in addition to the thrust bearings 4, have stuffing boxes 2.1 and 3.1, inlet pipes 2.2 and 3.2, exhaust pipes 2.3 and 3.3, annular chambers for coolant 2.4 and 3.4. The single-cylinder RC engine-steam generator-gas generator is made with a hollow shaft 7 equipped with thrust bearings 7.1 and 7.2, each of which is installed between the outer side of the end cap and nut 7.3 with lock nut 7.4. The conventional neutral plane drawn through the centers of the rotor O ₁ and the cylindrical body O ₂ , the cylinder body is divided into a compression region, where the volume decreases along the rotor 5, and an expansion region, where the volume increases. In the field of compression, the housing 1 is equipped with nozzles for introducing cooling 1.1 and output of the compressed heated coolant 1.2. In the expansion area, the housing 1 has a multi-channel nozzle 1.3 for separate input of the components of the air-fuel mixture or combustion products from the external combustion chamber, for example by means of the injector 9.5 in Fig. 4, either from an adjacent engine or from an industrial fire furnace, boiler, other power unit, or installation. In the housing 1 or the end caps 2 and / or 3 in the compression area, additional nozzles can be provided for introducing fuel or air-fuel mixture, for example, nozzle 1.8. The quantity, location, cross-section of additional nozzles is determined by the type of fuel, the designed temperature regime, the presence of fuel additives or the use of hot combustion products from extraneous sources, such as fire stoves, power units, plants, and waste heat boilers. Closer to the boundary of the regions of expansion and contraction, a branch pipe 1.4 is arranged to discharge expanded exhaust gases. These pipes can be placed in the end caps 2 and / or 3. The housing 1 is equipped with a cooling jacket 1.5 with a pipe 1.6 for introducing a coolant, such as an intermediate, and pipe 1.7 for its output. The finned rotor 5 is provided with a cooling jacket 5.1 connected by radial channels 5.4 to the hollow shaft 7. The hollow shaft 7 has a partition inside. The input and output of coolant in the hollow shaft 7 is carried out through additional devices not shown in the drawing. Inside the housing 1 can be installed a removable cylindrical insert. In some cases, channels for accommodating glow plugs, such as glow plugs, may be provided for igniting an air-fuel mixture with a low flash point and pressure in the housing 1 and / or end caps 2 and 3. The RC engine-steam generator-gas generator can be used as an internal combustion engine to drive working machines, for example, an electric generator, as well as an expansion machine-steam generator-gas generator for the production of carbon dioxide, a gas-vapor mixture for injection into an oil-containing formation. When supplemented with an external combustion chamber, a centrifugal gas separator, it can be used as an expansion machine, an expansion machine-steam generator, engine-steam generator-gas generator with simultaneous external and / or internal or only external combustion of the air-fuel mixture. The multifunctionality of the engine opens up new possibilities, especially when used in devices for various purposes, power, with different intermediate coolants, working fluids.

 If necessary, RC engines, RC superchargers of combustion products, air can be multi-stage, that is, have on the common shaft 7 several unified rotors 5 and casings 1. For example, each of the gas-air expansion machines of the three-cylinder RC of the engine-steam generator-gas generator (Fig. 3) 1.15 and 1.16 with a supercharger 1.17 air is similar to a single-cylinder RC engine. Cylinder 1.17 and rotor 5.3 are RC air blower. RCD can be made of three cylindrical housings 1.15 and 1.16, and 1.17, end caps 2 and 3 with stuffing box seals 2.1, pillow block bearings 4, eccentrically placed in the housings between the intermediate walls 1.11 and 1.12 of the three-section finned rotor 5.1 and 5.2, and 5.3 with seals 6 in the form of cylindrical bodies of revolution. The common hollow shaft 7 of the RCD is supplemented by thrust bearings 7.1 and 7.2, each of which is installed between the outer side of the end cap and nut 7.3 with lock nut 7.4. The body, end caps and the rotor of the RCD have cooling shirts with nozzles for entering and leaving the coolant 1.18 and 1.19, and 2.2 and 2.3, and 3.2, and 3.3, and 2.6. The intermediate walls 1.11 and 1.12 are also equipped with nozzles 1.13 and 1.14 for the input and output of the cooling coolant. Other expansion and injection machines, in particular reciprocating engines, compressors and gas turbines and centrifugal compressors, can also be used in the oil recovery device. However, their application, in terms of efficiency the use of the technical operability of the fuel, unification of equipment, acceptable operating parameters, is less preferable, and in some cases due to the high temperature and the presence of mechanical, especially tarry coking impurities, is unacceptable.

 An injection well 9 (FIG. 4) with a heat-carrying pipe 9.10 and gates 9.11, perforation 9.1 in the calculated area of the oil-containing layers 25 is located near the oil reservoir. It can be vertical, inclined, horizontal, with one or more trunks. In the process of construction, opening of reservoirs, commissioning and operation, additional perforation can be made in it. Well 9 on the liner of the casing string can be equipped with a sandblasted filter from profiled wire and, if necessary, can be reversible, that is, operate in the injection or production mode after appropriate conversion.

 A production well 13 with a heat transfer pipe 13.1, a perforation 13.3 of the casing and a sand filter in the calculated area of the oil layer (s) 25 is located near the injection well 9. The specific location, quantity, parameters, set of equipment and the relative position of the producers 13, 14,. .., ..., and injection wells 9 is determined by the results of the study of the field and is periodically updated during operation. It is desirable that the predicted oil flows during production should be directed along lines ascending to the horizon. The optimal placement of production wells 13, 14, ..., ... near the injection / 9 of them is determined by the results of geophysical studies, taking into account the determination of the delivery and absorption intervals, inflow and injection profiles, bottomhole pressure, temperature, hydraulic conductivity and gas conductivity, expected productivity and a number of other conditions. Production wells 13, 14, ...,. . . can be vertical, inclined, horizontal, with one or more trunks. In the process of construction, opening of productive formations, adjustment work in the well, additional perforation can be done. The well on the liner of the casing string can be equipped with an anti-sand filter of profiled wire and, if necessary, can be reversible, that is, operate in the injection or production mode after appropriate conversion.

 A production well, for example 13, can be equipped with at least one rotary-cylinder supercharger 15 connected to a heat-carrying pipe 13.1 located inside the well with a perforated tip 13.2, and a centrifugal separator or hermetic cyclone 18 for separating the gas-oil mixture into fractions, and a vacuum pump 20, for example, a RC, which is designed to select a gas fraction with a high liquid content. It can be used in the development of new and depleted oil and gas deposits with low dynamic levels and large gas factors. Cyclone 18 is designed to work with high overpressure. In order to avoid a decrease in efficiency due to pressure losses in the circulation circuit, cyclone 18 is tightly connected to the RC vacuum pump 20. A centrifugal separator, for example, separating the mixture into oil, water and heavy impurities - earth, clay, sand, can be installed sequentially behind the cyclone.

 In this case, the producing well 13 can be equipped with at least one rotary-cylinder supercharger 15 connected to a heat-carrying pipe 13.1 located inside the well 13 with a perforated tip 13.2. and a liquid centrifugal separator or cyclone 18 for separating the gas-oil mixture into fractions, as well as a vacuum pump-supercharger 20 for sampling the gas fraction, for example RC. The RC supercharger 15 and the RC vacuum pump-supercharger 20 are similar to the RC air blower 9.2 (FIG. 4) of the RC engine 9.3. To raise oil from production wells, for example 14, well-known submersible pumps driven by a rocking machine 14.4 can also be used. In this case, an electric motor or a RC engine 14.3 can be used to drive the rocking machine, the combustion products from which can be sent to the suction pipe 12.2 of the jet compressor 12 or directly to the suction pipe of the RC supercharger 15.

The device for extracting oil can be equipped with a single or multi-cylinder RC engine (figure 3), including, for example, high, medium and low pressure cylinders. Each of the cylinders of the RDC can have a common or separate shafts connected to an electric generator and / or a supercharger of combustion products, for example, an RC, into an injection well. Its branch pipe 9.9 for outputting combustion products can be connected to the inlet pipe of the injection well 9 directly or through a single or multi-stage supercharger 10 of combustion products, for example an RC, and / or a centrifugal compressor, and / or a jet compressor 12. The RC engine can run on raw oil, oil, from which a part of light and medium boiling fractions is selected, fuel oil, associated gas, gasoline, kerosene, diesel fuel, regardless of the octane rating. The cooling of each cylindrical body, rotor, cylindrical seals of the RCD, RC superchargers, RC vacuum pumps can be performed by the same or different cooling fluids, including intermediate, for example, oil, water, tasol, high-temperature organic coolant (BOT). The temperature of continuous combustion of fuel in the RCD, depending on the type of fuel and oxidizing agent, can reach 3000 ^o C. The RCD can operate with full or partial expansion of the combustion products, with various overpressures and temperatures at the outlet of the pipe 9.9 or 10.1 of the release of combustion products. One and / or several RDCs can operate autonomously and / or as part of the power unit according to the patent for the invention of the Russian Federation 2143570. In this case, the products of combustion from all or part of the RC, reciprocating, gas turbine engines of the power units can be used for supplying to one or several injection wells. For example, combustion products from RCD 9.3, RCD 11 for driving the RC supercharger 10, RCD 14.3 for driving the submersible pump 14.1, RCD 16 for driving the RC vacuum pump-supercharger 15, RCD 21 for driving the vacuum pump-supercharger 20 gas taken from the well 13, and a number of other power units with different parameters can be collected in the inlet pipe 12.2 of the jet compressor 12 and through the supercharger RC 10 are sent to the injection well 9.

 The device for oil extraction and its primary processing can be equipped with a heat exchanger 24.1 for simultaneous cooling of the gas-vapor mixture (arrow SG) leaving the compressible region of the RCD 9.3 (arrow PG) and heating with the said mixture of crude oil supplied under pressure to the heated compression region of the same RCD, for example RCD 9.3, for cooling the housing 1, the end caps 2 and 3, the rotor 5 and the sealing elements 6 in the form of cylindrical bodies of revolution and subsequent combustion in the expanding region. The vapor-gas mixture can be supplied to an additional heat exchanger, for example 24.2, for condensation and obtaining volatile liquid fractions, in particular for their own needs.

 The oil recovery device may be equipped with an oil atomizer 27, for example, centrifugal, connected to an evaporation chamber 28 having liquid outlet pipes 28.1 and steam 28.2 fractions, while the first meshes 28.3 and the second are placed inside the chamber 28 in the direction of the sprayed oil in the form of a vapor-liquid mixture 28.4, part of which 28.4 is equipped with heating elements 28.5, for example thermoelectric heating, and is filled with a catalyst and a heat exchanger 24.2 for condensation of vapors. The device is designed to extract from the extracted oil a part, for example, up to 50%, of light petroleum products, primarily for own needs, and at the same time use the remainder of the oil for combustion in the RCD, for example, RCD 9.3.

 The oil recovery device may be provided with a dispenser 26, for example with or without a pump, for continuously or periodically supplying liquid chemical, microbiological and other components that enhance oil recovery from productive layers to the injection well 9.

 The method is carried out according to one of the following options.

1. When extracting oil from fields with low reservoir pressure (Fig. 4), it is sufficient to use only one RC engine-steam generator-gas generator 9.3 with an RC air blower 9.2. From a foreign source, such as a small starting or starting engine, the common shaft 7 is rotated. The rotors of the engine 9.3, the air blower 9.2, the electric generator 9.6 placed on the common shaft begin to rotate. Generator 9.6 at the time of engine start is disconnected from consumers. The air coming out under pressure from the air blower 9.2 (arrow L) enters the inlet pipe 9.4 of the engine 9.3. It is fed under pressure (arrow M, M ₁ ) fuel, for example oil, oil after removal of part of the volatile fractions from it, diesel fuel. In the external combustion chamber 9.4 of the engine 9.3, under the thermal influence of a glow plug, the atomized air-fuel mixture ignites and expands. There is a pressure difference at the inlet and outlet of the engine 9.3. In this case, due to the difference in the area of the ribs of the rotor 5 with the seals 6, there is a difference in the forces acting on the ribs of the rotor 5 in the direction indicated by arrow A. The rotors of the engine 9.3, air blower 9.2, electric generator 9.6 placed on the common shaft continue to rotate due to the expansion of the combustible air-fuel mixture. As fuel is added, the rotational speed of the common shaft 7 increases. When the desired temperature of combustion of the air-fuel mixture in the engine-steam generator-gas generator 9.3 is reached, the supply of cooling coolant, for example oil or water under pressure, starts to the pipe 9.7 (arrow M, B). Water in contact with the hot casing 1, rotor 5 and cylindrical seals 6 of the engine 9.3, removes heat from them and turns into steam, which is mixed with the residual products of combustion inside the compression region of the housing 1. A mixture of gases and water vapor (arrow PG) in the compression region engine 9.3 is compressed, additionally heated by compression and under pressure leaves the pipe 9.8 of engine 9.3. In the future, it can be used for communal consumers and / or connected to the combustion products coming out under a given pressure (arrow G) from the pipe 9.9 of the engine 9.3 and sent under pressure to the heat-carrying pipe 9.10 of the injection well 9. In the well 9, the pressure of the gases or gas-vapor mixture bursts the shutter 9.11 and due to the excess pressure of gases or gas mixture over the force of the reservoir pressure is squeezed through the perforated part 9.1 of the casing string into the oil-containing formation 25. In this case, gas air thermal insulation of the casing string, heat loss is reduced and intense energy and mass transfer occurs. Some of the vapor soluble in oil and water, carbon dioxide and other gases dissolve in them and transfer oil, water and rock their heat directly in the reservoir. The presence of a heat-carrying pipe 9.10 with several self-sealing shutters 9.11 makes it possible to organize effective gas-air heat insulation of the heat-carrying pipe 9.10 inside the casing, to reduce the thermal stresses acting on it and the heat loss in the rock along the length of the casing of the injection well 9. The remaining gas (arrows G) along the pores in it penetrates into the upper regions of the reservoir and displaces the denser oil, water, and gas condensate from the inaccessible domes of the reservoir into the underlying layers of the rock. Due to the dissolution of gases and heating of the rock, the solubility of oil and water increases, the viscosity of the mixture decreases. At the same time, the reservoir pressure somewhat increases, which leads to an increase in the filtration rate of the oil-containing mixture (arrow MB) in the direction of producing wells 13, 14, ..., ..., and mechanical and other highly toxic fuel wastes are buried in the bowels.

 The combustion of the air-fuel mixture in the engine-steam generator-gas generator 9.3 can be carried out with a shortage or excess of air or a stoichiometric ratio of fuel and air. The pressure of the combustion products at the outlet of the RC engines can vary widely from 0 with full expansion to 100 bar or more with a given, but economically feasible, limited expansion.

 Production wells 13, 14, ..., ... receive an additional increase in reservoir pressure, static and dynamic levels, a slight decrease in the viscosity of the oil-water mixture, an increase in its filtration rate through sand filters and a corresponding increase in production.

 A production well, for example 13, equipped with at least one rotary-cylinder supercharger 15 connected to a heat-carrying pipe 13.1 located inside the well with a perforated tip 13.2. and a centrifugal separator or cyclone 18 for separating the gas-oil mixture into fractions, as well as a vacuum pump-supercharger 20 for sampling the gas fraction, for example, rotary-cylinder, is used as follows. The start of the RCD 16 with the RC air blower 17 is performed as described for RCD 9.3. A single or multi-cylinder RC gas compressor 15 pumps overpressure through a heat-carrying pipe 13.1 at the first start-up air into a perforated tip 13.2, which is immersed in a layer of oil-water mixture. The pressure of the air heated by compression exceeds the static pressure of the mixture column. Through a perforated tip 13.2 the smallest spherical bubbles of compressed air, and in the steady state, gas from low-boiling oil components, penetrate into the oil-containing formation 25 and form an air-oil mixture, which has a density significantly lower than oil. Heat transfer from the hot heat-carrying pipe 13.1 and hot circulating compressed gas from low-boiling oil fractions to the mixture helps to reduce the density of the mixture and its viscosity. Due to the pressure difference in the region of the tip 13.2 and inside the sealed cyclone 18, the mixture (arrow CM) rises into cyclone 18, where less dense air and gases dissolved in the mixture under the action of centrifugal forces float from the walls of the cyclone to the center and concentrate on the inner surface of the oil-water mixture, which, under the action of gravity, falls into the lower part of cyclone 18. Here, denser water drops down and is periodically or continuously discharged through a treatment device, such as a liquid centrifugal separator, to ornoy reinjection or other location, in accordance with the project. For wells having a low water content in the oil-containing layer 25, this operation is no longer needed. A mixture of air and low boiling oil fractions with a high liquid content from the upper nozzle of cyclone 18 (arrow C), without losing residual pressure through the pipeline, is sucked in by the gas compressor 15 and continues to circulate along the circuit. With sufficient reservoir pressures, the entire circulation circuit, including pump 18 and cyclone 20, can operate at overpressure.

 Gradually, the initial amount of air is carried away by the oil and only hot oil vapors remain circulating in the circuit. Oil with a small content of water and dissolved gases (arrow M) by the pump 19 is discharged into the reservoirs 22 and then to the destination. Part of the oil can be used for own needs, for example, for RCD 9.3, 11, 16, 21, 14.3, which can also work on associated gas (arrow D). If there is associated petroleum gas in the productive layer 25, the latter can be discharged by a vacuum pump 20, for example, an RC intended for sampling a gas fraction with a high liquid content, into receiver 23 (arrow D) or through pipelines to consumers or for other purposes.

 2. When extracting oil from fields with significant reservoir pressure, it is necessary to use one RC one- or multi-cylinder engine-steam generator-gas generator (Fig. 3) with an additional one or more RC gas-air blowers 10. In addition, jet compressors 12 can be used for collection and preliminary for compressing rarefied products of combustion from RCD 9.3, RCD 11 for driving the RC of the gas blower 10. RCD 14.3 for driving a submersible pump 14.1, RCD 16 for the drive of the RC vacuum pump-supercharger 15, RCD 21 for driving a vacuum pump-compressor 20 from the bleed passage 13 associated gas, as well as piping 31 from units with different parameters. A multi-cylinder RC gas blower 10 can provide a discharge pressure of up to 500 bar, which will fully ensure production from wells up to 5000 m deep.

 A device for extracting oil, equipped with a heat exchanger 24.1 for simultaneous cooling of the oil-gas mixture containing light fractions and heating said mixture of crude oil supplied under pressure to the heated compression region of the RCD, for example 9.3. for cooling the housing 1, the end caps 2 and 3, the rotor 5 and the sealing elements 6 in the form of cylindrical bodies of revolution and subsequent combustion in the expanding region, works as follows (Fig.2,4). Oil pump 19 is fed into the annular space of the heat exchanger 24.1 and, passing through it, is heated in pairs, which are formed in the process of cooling the hot body 1, end caps 2 and 3, rotor 5 and cylindrical sealing elements 6. The amount supplied to the channel 1.1 (Fig. 2 ) through an oil atomizer (arrow M) is equal to the amount of RCD 9.3 vaporized in the compressible region and burned in its expanding region. Fuel consumption control can be carried out manually by a valve or automatically using an oxygen sensor (lambda probe) in the combustion products. In the steady state, due to the high temperature difference between the thin film of oil and the walls of the above-mentioned parts of the RC engine, there is a rapid transfer of heat from the parts to a thin layer of oil in the atmosphere of residual hot combustion products. Due to the energy received, low-boiling volatile oil fractions evaporate almost instantly, and the more viscous hard-volatile fractions do not have time to completely evaporate, adhere to the rapidly rotating sealing elements 6, the walls of the finned rotor 5 and are transferred by them to the expanding region of the RCD, where they come into contact with the channel 1.3 (Fig. .2) or channel 9.4 (Fig. 4) with hot air (arrow L) containing an oxidizing agent-oxygen. The oil residues on the rotor 5, elements 6 and, if necessary, the additional amount of oil, which is pumped through the sprayer 9.5 to the external combustion chamber of the RCD 9.3, is combined, oxidized with heat, expanding the volume and increasing the pressure of the combustion products inside the cylinder 1. In this case, an additional amount oil or other type of fuel, in order to fine-tune fuel consumption, the process of thermal separation of oil into fractions and at the same time stabilize the speed of the electric generator 9.6, can be fed 1.8 channel (arrow M). Due to the pressure difference at the inlet and outlet, the combustion products expand and drive the rotor 5 of the RCD to rotate. A mixture of vapors (arrow PG) of volatile oil components and residues of combustion products under excessive pressure passes through the tubes of the heat exchanger 24.1, where it gives its heat to the oil flow moving in the annulus, partially cools and condenses. Then the mixture of vapors of volatile fractions of oil, condensate from them and the remains of gaseous products of combustion under pressure of an additional pump, for example an RC, can be sent for complete cooling, condensation, and then to collector 22 or other consumers who need fuel from low boiling fractions. In collectors 22, the mixture is completely cooled, the combustion products evaporate, or only a very small fraction of them without additional excess pressure can dissolve in oil. Due to the insignificance of their amount, oil saturation will practically not occur. At the same time, the quality of the extracted oil is somewhat improved due to the removal of part of the hardly volatile components used for own needs. In this mode, one or more RCDs can be operated. In this embodiment, there is no need to use water to cool the housings 1, rotors 5, sealing elements 6 of the RC engines.

A device for oil recovery and primary processing, equipped with an oil atomizer 27, for example, centrifugal, connected to the evaporation chamber 28, having liquid outlet pipes 28.1 and steam 28.2 fractions, while inside the chamber 28, nets 28.3 are placed in the direction of the sprayed oil in the form of a vapor-liquid mixture 28.4, part of which 28.4 is equipped with heating elements 28.5, for example, heat-electric heating, and is filled with a catalyst and a heat exchanger 24.2 for condensation of vapors, it allows to significantly increase the number of light products is envisaged, which can be allocated in place of the extracted oil. It works as follows. Oil heated to a predetermined temperature, for example, 300-400 ^o C, in the compression region of the engine's RC, for example 9.3, is supplied under pressure to the atomizer 27. It can be steam or centrifugal, for example in the form of a conical sieve with holes 60-100 microns, rotation speed up to 6000-8000 rpm, the angle of inclination of the generatrix of the cone 45-55 degrees. Due to overheating under pressure by the RC engine 9.3, with respect to the temperature inside the chamber 28 of evaporation, and rotation, oil is distributed on the surface of the sieve in a thin layer, for example, up to 200-400 microns thick. In this case, low-boiling fractions are intensively separated from superheated oil, and the liquid fraction is sprayed and converted into hot fog through openings in a sieve under the action of centrifugal forces. The vanes 27.1 placed outside the rotating sieve pump the atomized mixture of vapors and liquid droplets into the chamber 28. In this case, large and medium-sized droplets are retained on the first nets 28.3 along the stream, flow down them and are discharged from the chamber 28 through the nozzle 28.1 to the pump 29.1, for example, the RC, and then into the pipe 9.5 RC engine 9.3 for combustion. Vapors of volatile oil components and small droplets of oil, commensurate with the dimensions of a mineral catalyst, for example, aluminosilicate, zeolite size of 1-6 microns, due to the pressure difference in the chamber 28 and the condenser 24.2, penetrate through the mesh filled with the catalyst 28.4 and exit the pipe 28.2 into the condenser 24.2, which is cooled, for example, with fresh oil or water. The catalyst in the grids 28.4 with heating elements 28.5, for example, electric heating, is preheated and in operation is at a temperature higher than the temperature of the oil vapor in the chamber 28. The excess can be 100-300 ^o C. When passing through a tiny droplet of atomized oil a thin layer of superheated catalyst, they almost instantly collapse. Fractions are released from them, the initial boiling point of which corresponds to the temperature on the surface of the catalyst particles and the pressure in the chamber. This allows you to get, for example, up to 50-60% of light petroleum products, primarily for their own needs, and at the same time use heavy fractions of oil for on-site combustion in the RCD. The yield of light oil products can be increased by using grids 28.3 and 28.4 from a material with a catalytic effect. The device may be provided with one or more evaporation chambers. The cameras can work autonomously or as a battery. An installation for more complete distillation of oil into fractions, which can be used in oil fields and other oil refineries, can be assembled from several successively working chambers. The device can operate under vacuum and in this embodiment can be used to isolate ultra light and ultra narrow fractions. In this embodiment, it is supplemented with special, for example, barometric capacitors, vacuum pumps and, for example, piston, RC, subcoolers, airtight locks.

 A device for oil recovery, equipped with a dispenser 26, for example, with or without a pump, for supplying liquid chemical, microbiological and other components that enhance oil recovery from productive layers to the injection well 9, operates as follows. Due to the high cost of these components, it is advisable to add them to productive formations mainly during the period of completion of work to extract oil from the reservoir in connection with the depletion of its resources. In this embodiment, the introduction of additives can be done periodically by gravity from the dispenser 26 after stopping the supply of combustion products under overpressure. In other embodiments, for simultaneous exposure to the formation of combustion products and liquid additives after the dispenser 26, an additional pump is used that provides the required overpressure, or heat-resistant additives are introduced directly into the nozzle 12.2 of the jet compressor 12.

The advantages of the method and device:
1 . The integrated use of the technical operability of hydrocarbon fuel to increase oil recovery of oil-containing formations, to produce electric and thermal energy, as well as the burial of highly toxic products of fuel combustion in the bowels of the Earth.

 2. There is no need to heat and use a large amount of water from ground or underground sources (wells, wells, ponds) or steam as an intermediate solvent for introducing components.

 3. Improving the environmental situation in areas of oil production.

 4. They allow the use of hot and chilled products, cleaned and untreated from mechanical and other impurities, from third-party suppliers, such as power units of oil fields, enterprises, thermal power plants with any engines and fuels.

 5. RICs for enhanced oil recovery can be used in other vehicles, such as wheeled, tankers, including high-speed ones, for transporting oil and oil products within the country and abroad. Using our own oil for these purposes will allow us to refuse to purchase our own fuel, such as diesel, abroad.

 RC engines due to the wet cleaning of the combustion products and lowering their temperature before being released into the atmosphere can reduce the toxicity of the combustion products and increase the efficiency, for example, in oil production, up to 80%. This is significantly better than that of the well-known piston, gas turbine, steam and gas turbine engines of power units of small and large thermal power plants. According to G.N. Alekseev. General heat engineering. - M.: Higher School, 1980, p. 436, 511, useful work or energy consumption for a steam turbine engine used at thermal power plants is only 35.5%, for a gas turbine engine - 26.2%, and the entire boiler unit-power unit is only 45.6% (p. 314), diesel internal combustion engines only 43.8%. The efficiency (efficiency) of modern steam-gas-turbine engines and power units of thermal power plants is 39.4-44% (p. 511). In areas of oil production, gas turbine units (GTU) with waste heat boilers, in which the share of fuel energy converted to electricity, does not exceed 40%, have often been used. Due to the mismatch of the daily and especially seasonal production and communal consumption schedules of heat and electric energy, the economic and financial efficiency (the ratio of the technical operability of the spent fuel over a long period of time to the useful one) with the use of gas turbines remains at the level of 40-55%.

 6. RCDs as a part of oil extraction devices make it possible to organize the production of light oil products of good quality at the fields for their own needs and third-party consumers, and to refuse to import conditioned fuel.

 7. The method and devices can be used in the development of new and depleted oil and gas deposits with low dynamic levels and large gas factors.

Claims (4)

 1. A method of extracting oil from a deposit, comprising supplying a supercharger at an excess pressure to an oil-containing formation through a well of exhaust products of combustion of a hydrocarbon fuel of an engine, characterized in that at least one rotary cylinder engine is used as an engine, and as a supercharger, at least one rotary-cylinder supercharger, wherein the combustion products of the rotary-cylinder engine and / or rotary-cylinder supercharger are injected into the oil-containing formation in the form of gases or steam gas mixture through the heat-carrying pipe positioned inside the casing and provided with at least one gate, which seal the heat-carrying pipe pressure gas or gas mixture and arrange its gas-air heat insulation.  2. A device for extracting oil from a deposit, comprising an engine with the production of products of combustion of hydrocarbon fuel, at least one injection well, at least one production well, and / or a supercharger for feeding exhaust products of combustion of hydrocarbon fuel to an oil-containing formation, characterized the fact that the injection well is equipped with a heat-carrying pipe placed inside its casing and having at least one shutter for sealing the heat-carrying pipe with excess gas pressure or gas-vapor mixture and the organization of its gas-air heat insulation, the engine is made in the form of at least one rotary-cylinder engine, and the supercharger is in the form of at least one rotary-cylinder supercharger, wherein said engine and / or supercharger are connected to injection well.  3. The device for extracting oil from the reservoir according to claim 2, characterized in that the producing well is provided with a heat pipe placed inside its casing with at least one rotary cylinder supercharger connected to the heat pipe, a centrifugal cyclone and / or separator for separating the gas-oil mixture into liquid and gas fractions and a vacuum rotary cylinder pump for removing the gas fraction with a high liquid content.  4. The device for extracting oil from the reservoir according to claim 2, characterized in that it is equipped with a chamber connected to the compression area of the rotary cylinder engine, having an oil atomizer, nozzles for withdrawing liquid and vapor fractions and a mesh from a material with a catalytic effect, part of which has heating elements.

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