RU2189439C2 - Method of developing oil deposits and block complex system of plants for method embodiment - Google Patents

Abstract

FIELD: oil producing industry, particularly, development of oil deposits. SUBSTANCE: method includes recovery of liquid and gaseous hydrocarbons with produced formation water from development oil wells and injection water wells. All plants in oil deposit development are made in blocks, at one section of land surface and arranged with consideration of wind rose. Fire safety of said plants are properly ensured. Infrafield oil gathering system, injection of working agent in the form of water, gas, oil into oil-bearing horizons and infrafield power network are replaced by intraplant connections and oil trunk pipelines and high-voltage power lines connecting development site with oil consumer and power supplying plants. Said plants are constructed simultaneously with well drilling and their successive putting into operation, their connection with oil and water discharge pipelines, aerial and cable power lines and, if require, they are laid in rapidly dismantled tubes connected with one another by put-on couplings. All plants with circuit supply from various feeders are provided with electric power. Development wells are arranged in clusters, by several rows, and their hole bottoms provide for uniform drainage of entire oil-bearing pool due to combination of various types of drilling with vertical, inclined and horizontal wellbores drilled from one parent wellbore. Optimal formation pressure and filtration conditions of formation fluid to wells are maintained due to selective injection of associated gas into poorly permeable zones of oil-bearing formation. Used simultaneously is back injection of produced water into formation boundary zone and selectively into depressed sections inside oil pool outline. Use is also made of gas-water mixture as a working agent for maintaining of rational formation pressure. In so doing, injected into formation or into well are residual gas and gas supplied for use as a fuel of fire heater applicable for heating of well products and provision of full preparation of oil, gas and water for their realization. In production of nonemulsified or slightly emulsified oil, it is supplied directly to tubular gas-water separator and separated from the latter gas and water are, respectively, supplied to accumulating vessel and to lower part of gas-water separator with a stabilizing column head. Oil with low content of residual water, which in case of necessity of its deep desalting, is mixed with hot fresh water and demulsifier is supplied to vertical gas-water separator. For treatment of nonemulsified oil, it is supplied to middle part of tubular gas-water separator upper half. Residual gas is discharged through upper bypass valve to common gas line, and water, through automatically controlled valve. Opening or closing of said valve provides for regulation of position of water-oil contact between upper and lower permissible points controlled by level gages. EFFECT: reduced expenditures for deposit development, increased oil recovery from formations. 5 cl, 1 dwg

Description

 The invention relates to the oil industry, namely to the development of oil fields.

 There is a method of developing oil fields by using dispersed objects (wells, a collection and injection system with installations for measuring production rates of well products, preparing oil, gas and water, and for their implementation) on the surface of the earth over the entire area occupied by the oil field (1).

 The method involves the use of an intertwined network of oil pipelines, gas pipelines, water pipelines connecting the wells with the objects of measurement, preparation and injection, requiring large capital costs and operating costs.

The disadvantages of this method:
- High costs for drilling wells, arranging the area of an oil field, large transportation, energy costs, for the direct servicing of objects of extraction and sale of oil, gas, water and for work at other auxiliary production facilities, which increase with a decrease in oil reserves, especially from hard-to-recover and sparse oil deposits;
- Large capital and labor costs to maintain environmental safety, safety and fire safety;
- High costs for automation, computerization of the operation of production facilities, inhibiting the development of equipment and technologies for the production of oil production.

 The closest technical solution is a method of developing oil fields using a cluster of production oil production wells, which are transported to individual measuring pipelines to individual pipelines, after which the collection to booster pumping units is carried out by common individual pipelines, where the separated part of the water or gas is pumped separately to consumers, and oil is pumped out with residual gas and water to oil treatment points located mostly away from the developed oil field (2).

The disadvantages of the method:
- the main disadvantages are saved in a slightly reduced form compared with the first method;
- high costs for the return transportation to injection facilities extracted from associated water wells and other waste waters;
- large losses of oil and gas from various oil field facilities scattered throughout the oil field, due to imperfect technology, due to accidents occurring in oil and gas pipelines and other facilities;
- high capital costs of funds for automation and dispatching of production processes in the oil company.

 The purpose of the invention: reducing the cost of developing oil fields: capital, material, labor, etc., especially in small and medium fields, improving the state of labor and nature protection, increasing oil recovery.

The goal is achieved by concentrating all the objects of the oil field development system: wells, measuring units, oil treatment plants, injecting working agents to maintain the value of reservoir pressure, electrical transformer substations, control centers and other blocks made on one site on the ground surface of the developed field, which actually eliminates the infield system for collecting oil, injecting a working agent: water, gas, oil into the oil horiz nt and the field transmission network, reducing them only to the installation harnesses, main oil pipelines and high-voltage lines connecting the development site with power plants, the construction of which is carried out simultaneously with the drilling of wells and their subsequent commissioning, tying them with oil and water flow pipelines, air or cable power lines, if necessary, laying them in quick-disconnect pipes connected to each other by overhead couplings, providing with electricity, all objects with a ring supply from various feeders, in which production wells are located in bushes, in several rows, the bottom of which due to a combination of different types of drilling with vertical, inclined and horizontal shafts drilled in several directions from the same trunk, provides uniform drainage of the entire oil-bearing reservoirs, maintaining the optimal value of reservoir pressure and the optimal mode of filtration of formation fluid to the wells due to selective injection oil gas to the poorly permeable zones of the oil-bearing reservoir, simultaneously with the back injection of produced water both into its circulating zone and selectively, into lower areas inside the oil-bearing circuit, using, respectively, gas compressors or universal pumps that are used for energy: water , oil, gas pumped through their motor pumps and pumped further into the well. as lifting energy, or into the oil-bearing formation, also using a gas-water mixture as a working agent to maintain a rational value of the reservoir pressure in the formation, while both residual gas and gas conducted for its use as a fire heater fuel are pumped into the formation or into the well, used to heat well products and ensure complete preparation of oil, gas and water for their implementation by stepwise preparation, in rhombic, vertically mounted pipe-in-pipe heat exchangers with by the preliminary discharge of water from their lower points and the release of gas released from oil — from high points, of newly incoming well products from the last sections of heat exchangers, at the entrance to the fire heater, after its preliminary heating with heat leaving the furnace with a counter flow of products heated to a temperature of 80 -90 ^o C, from which also before its exit to the vertical gas separator, and when producing non-emulsion or weak emulsion oils directly into the pipe gas separator, from which they are separated from phthis gas and water, respectively, enter the storage tank and the lower part of the gas separator with a stabilization column, and oil with a small content of residual water, which, if deeper desalination is necessary, is mixed with hot fresh water with a demulsifier, is fed into the vertical separator when processing emulsion oils -gas separator, and in the processing of non-emulsion oils in - pipe gas separator in the middle part of its upper half, slightly lower from the border of the oil-water contact, but higher partitions that prevent the direct removal of residual oil droplets along the lower surface of the pipe to the water intake zone and ensure the oil rises in the zone of quiet production flow to the upper part of the gas separator, to the stabilization column located at the upper end of the gas separator, from where oil with a given density through the drain valve, regulated by a float regulator - hydrometer, they are passed into a pipe measuring device, which determines the amount of pumped oil to consumers, the rest intramural gas through the upper valve gazoperepusknoy discharged into a common gas line, and the water - through an automatic adjustment valve, opening it or covering it, regulate water contact position between the upper and lower permissible points controlled by a level indicator.

 This goal is achieved by the fact that they continuously monitor the operation of the entire reservoir-well system, measurement objects - preparation, injection into the reservoir and wells, and sales of products by measuring oil, gas and water flow rates, pressures and temperatures of individual wells and the total number of products of all wells, as well as by their measurement in separate blocks of preparation and sale, as well as by the measurement of consumed electricity continuously in time at separate blocks and objects, and in the whole oil field, at All parameters are measured by rum: the flow rates of individual wells and their total number according to the directions of the wells and throughout the oil field in the tube volumetric-mass measuring devices installed on the common measuring unit of the production site, two devices for separate directions - one for sequentially-sequential measurement of flow rates individual wells, and another - to measure the flow rates of all wells in a given direction, in which pressure and temperature values and their average values at time are simultaneously recorded data, as well as for individual wells and for groups of wells connected to transformer substations of consumed electric power values, also the indicated parameters characterizing the operating modes in individual links are measured in all other blocks of the development system, which are processed in separate or in common electronic blocks and continuously in time are transferred to the general dispatch control.

 This goal is also achieved by the fact that in cases where oil fields occupy large areas, when it is not possible to cover the entire oil field with wells located on only one site, several are constructed, and the main one, where the wells are fully prepared products are placed on the basis of ensuring conditions for the development of the entire field at all stages of operation of the facilities with minimal cost of funds, making maximum use of the energy stored in the reservoirs from the very beginning of hydrocarbon production, in order to maintain its rational value by reverse controlled injection of produced water and part of the light gas fractions of oil into the wells and into oil-bearing strata as an energy carrier for production, using downhole gas lift, or hydrostatic pressure of part of the downhole water supplied to the well by differential universal pumps installed both on the surface of the earth and in wells, using the same pumps for infield pumping of various components of production products, having also used rocking machines of deep-pumping plants for their drive, for which the components used as energy sources come from storage tanks, which are part of oil treatment plants and which, depending on the preparation requirements, provide the main installation with fire heaters, and at other sites, only tube gas separators are installed, in which, during the production of viscous and emulsion gas-liquid mixtures, to ensure the required quality under the products being prepared are directly supplied to the wells by demulsifiers, separate lifting and collection of oil and water are carried out, or the products arriving at the bottom of the wells are heated to rational temperatures using downhole fire heaters.

 This goal is achieved by an integrated system of block installations, when all installations, devices and structures are installed in separate blocks, taking into account their safe maintenance, on one site on the surface of the earth in the area occupied by the oil field, where the clusters of production and injection wells are located in rows, a block of a complex of measuring devices where tube volumetric mass meters are located - water flow meters, electric meters, pressure and temperature sensors, pparatury measurement data processing and transmission to the control room for monitoring and control, a plant for the preparation of products well consisting track combustion heater complete with rhombic type heat exchangers "pipe in pipe" installed vertically with taps. Vertical gas and gas separator, tube gas separator with stabilization column heads, with float regulators of oil and water levels according to their density, gas bypass valves, automatic means for monitoring and controlling the sale of oil and water, tube volumetric meters, trough densitometers in an oil pipeline and water supply system , water separators, storage tanks, power units mounted on the surface of the earth, ground and underground differential or universal pumps sys, pumps, compressors, pipelines, electrical wires, control and monitoring units connecting individual devices.

 This goal is also achieved by the fact that when the development of an oil field, occupying large areas, is carried out from several sites with the concentration of block complex systems of plants and structures on them, full oil treatment is carried out only in the central site, and only pre-treatment units are installed on the remaining sites oil, consisting only of a tube gas separator, which, when producing highly emulsified and viscous gas-liquid mixtures, is equipped with vertical end haulage columns installed to stabilize the oil - on the upper end of the inclined gas separator, and to stabilize the water - below the lower end of the gas separator, which are connected respectively to the gas and water reservoir with flow lines, as well as pipelines with wells and an oil and gas collection system, and in the case of the production of highly viscous and highly efficient oils, the wells are equipped with downhole firing equipment using downhole firing heaters, air and gas compressors or universal air and gas pumps - differential compressors driven by power units and pipelines connecting them.

 The claimed technical solutions differ from the prototype in that the development of an oil field of small sizes is carried out mainly from one site of the earth, and large sizes of fields are produced at several sites on which all objects are concentrated - development systems, which allows to reduce all types of development costs: capital , material, labor, etc., and to exercise full control over the work of all ground and underground facilities and creates the conditions for the prompt implementation of new equipment and technologies for improving increase the efficiency of the entire development system and fully automate all technological processes of oil production, carry out operational control and regulate the operation modes of all parts of the system, reservoir - well - equipment.

 It also differs in that the concentration of all the objects of the development system on one site and their block production can significantly increase the labor productivity of the work performed, and therefore reduce the cost of developing an oil field.

 Concentration of development facilities on one site allows the return of completely associated water and part of the gas left over from their use as a working agent into the oil reservoir without large expenditures.

 At the same time, the infield gathering system, the injection system and the system of the commercial network of power lines, communications are sharply reduced, and therefore, the cost of land rent, their construction and maintenance are reduced.

 It also differs in that in the case when several sites are used on them to cover the development of large fields, in addition to the main site, only preliminary preparation is carried out, mainly only in tube water and gas separators. This ensures a centralized supply of: coolant, chemicals to the wells, gas and air to their bottom when heated by downhole heaters, gas - when using gas lift operation with your own gas for flushing wells and killing.

 It also differs in that the methods for measuring the necessary parameters characterizing the operation of an integrated block system: oil, gas and water flow rates using tube mass-volume measuring devices installed in two devices for individual well directions, one for sequentially measuring the flow rates of individual wells, and another - to measure the flow rates of all wells in a given direction, in which pressure and temperature values are simultaneously recorded, and changes in their average values over time, as well as on individual wells and by groups of wells connected to the transformer substation, the value of electricity consumed, then received measurement data is processed in the electronic units and continuously in time are transferred to the dispatch control, which allows automatic control and manage the production process, providing the necessary return on the development of oil fields.

 The oil preparation unit is distinguished by a tube heat exchanger having a vertically mounted rhombic shape, from which a part of the water and gas separated in the collection system and released during heating in the heat exchanger is diverted, respectively, to the tube gas separator and gas line, which can significantly reduce energy consumption, spent on heating well products in a fire heater, and their subsequent separation in a vertical separator representing the second stage of separation, and their separate supply a: gas - in the pipeline, and oil and water in the respective pipe sections of the water separator increases the quality of the oil preparation with a significant reduction of the displacement volume setting for the preparation of oil.

 It also differs in that the quality of the oil preparation leaving the installation and from its pipe water separator is ensured by a float regulator — a hydrometer and volumetric mass flow meters, respectively installed in the vertical stabilizer and after it, and the compliance of the sold oil with existing standards is determined by the data of pipe volumetric mass measuring devices in time.

 These allow us to conclude that the claimed invention is interconnected by a single inventive concept.

 A comparison of these claimed technical solutions with the prototype made it possible to establish compliance with their criteria of novelty.

 In the study of other known solutions in these areas of engineering and technology, the features that distinguish the claimed invention from the prototype were not identified and therefore they provide the claimed technical solution with the criterion of "significant differences".

 The integrated block system of installations for implementing the development method in figure 1 consists of oil wells 1 and injection, 2 flow 3, 4 and receiving 5 pipelines, block measuring installations 6, 7 with tube volumetric meters 8, 9 for gas-liquid mixtures, oil, water meters 10, gas-diaphragm flow meters 11 or spiral interchangeable pipes 12 of a certain length, sensors for measuring pressure 13 and temperature 14, meters of electricity consumed by various installations, training installations oil 15, gas and water separation, consisting of stages: sections of vertically mounted rhombic heat exchangers of the “Pipe in pipe” type 16, vertical separator - gas separator 17, pipe gas separator 18 with stabilization columns 19 with float level and density regulators 20 leaving the oil and gas separator and water, gas relief valve 21, automatic adjustable valves 22, operating from the position of the interface between water and oil in the pipe gas separator 18, pipe volumetric meter 23 - for measuring sold oil with a residual water and gas content, ground-based and borehole differential universal pumps 24, pump-compressors 25, power liquid pumps 26, and air and gas compressors 27 driven by internal combustion engines or electric motors, communication networks oil pipelines, water pipelines, gas pipelines, power lines and automatic control lines, information processing and control system blocks with external and internal communication, life-communication baking, ensuring labor safety and fire safety.

The method is as follows:
After studying the structure of the relief of the earth’s surface, the area corresponding to the structure occupied by the oil reservoir, select a site for the construction of facilities for the development of oil fields. The site for the placement of objects is selected based on the development of the field at the lowest cost of energy, equipment, materials, vehicles, taking into account the wind rose with convenient entrances.

 Site development begins after the approval of a project for the development and drilling of wells with their consecutive commissioning, simultaneous construction of oil pipelines and high-voltage power lines, and elements of arrangement within the site, assembly and strapping of block installations, organization of work similar to the construction of factory-type enterprises in a short time .

 Arrangement of the site territory after drilling wells located in a row in rows, the optimum number of which is determined based on ensuring rational drainage of the developed deposits and uniform contraction of the oil content contours due to the rational placement of vertical, deviated and horizontal wells and injection of water into its lower parts and oil gas, especially in its areas with reduced reservoir properties, allowing to increase the oil recovery coefficients of oil deposits. At the same time, for the most part gas injection is used universal differential piston type pumps, carried out in the work of energy carriers supplied to them by power units: piston, electric centrifugal pumps and gas compressors. All three components can be used as energy carriers: water, oil and gas. If water is used as an energy carrier, then it is also pumped into the lower parts of the oil reservoir, and when gas or oil is used for these purposes, they are also used to reduce the density and viscosity of the borehole products being raised, which reduces the amount of electricity consumed for oil production.

Drilling production wells is carried out by bushes, placing them in parallel rows on one or two sides of the objects used to collect, prepare oil, gas, water, measure, control and control. At the same time, two oil lines are laid from each direction of production wells to measuring units 3, 4: one for measuring and transporting the products of each individual well 3, and the other for transporting and measuring produced products from all wells together 4 in tube volumetric meters 8.9, allowing to keep records of all products extracted from wells before and after their preparation 23, located: for production wells - on one common measuring unit, and products sold, component-wise - in dr gom measuring unit. After the measuring installation, all products + extracted from the wells, from the common comb of the distribution point through two oil pipelines, enter the preparation unit for the well products 15, into its heat exchanger 16, into which a demulsifier is fed before it arrives. In a pipe-in-pipe type heat exchanger, representing blocks of vertically mounted rhombuses, well products moving along an external channel towards its stream exiting the fire heater of a product with a high temperature up to 80-90 ^o С, heats up to 30-50 ^o С, which when a low pressure of the medium is established, it is accompanied by intensification of gas evolution and separation from oil, as well as water separation, which then go through the upper and lower points of the heat exchanger section, respectively: gas - to gas line 29, water - to the lower half of the pipes gas separator 18, and oil with residual gas and water, in a reduced volume, enters the vertical separator-gas separator 17, from which the gas accumulating in its upper part goes to the gas line, and then to the gas storage tank 30, water from its lower part is discharged through the water line to the gas separator 18, and oil, with a small content of water and gas, enters the upper half of the gas separator, where oil and gas accumulate in its upper stabilization column 19, whence oil with a residual content of odes, not exceeding the established norm, through the float regulator 20, the hydrometer is forced through the mass-volume measuring device 23 into the flow oil pipeline 28. In the mass-volume measuring device 19, both the total quantity and component composition of the liquid passing through it are determined, which allows continuous accounting of products sold.

 From the lower stabilization head through the water line and the water meter is discharged into the tank - sump 31 associated water, from which it enters the power units 26, 27 and is used as an energy carrier, or as a working agent to maintain a rational value of reservoir pressure.

 The gas coming from all stages of the oil treatment unit to the gas storage tank 30 at a given pressure is continuously measured by a diaphragm or spiral gas flow meter, part of which is then fed as fuel to the fire heater 32, the remaining amount is used for gas lift operation of the wells, as a working agent for injection into layer - as fuel - to downhole fired heaters and other consumers.

The block-complex installation system used to develop oil fields works as follows:
Oil production from wells located on a separate section of the production site is carried out using various existing methods. The predominant of these are mechanized production methods: universal hydraulic piston pumps, local gas lift in combination with deep pump production of various designs, for example, differential hydraulic piston 24.25, driven by the pressure of the energy source supplied by the power unit 26.27, when lifting is also used for lifting the effect of gas, gas-oil mixture, oil; sucker rod pump combined with a local gas lift; electric submersible centrifugal pump in combination with a gas lift; clean gas lift, using gas released from the oil itself. At the same time, energy is supplied to several wells from one power unit located in one pump (compressor), which serves all the wells, or wells located in the same section, in directions, through one pipeline 33, which runs parallel to the discharge oil 3.4 serving for transportation of wells to points of measurement of their flow rates. Thus, in those wells that are more rationally exploited using energy carriers extracted from the most oil wells, energy is supplied through separate pipelines, and through others it returns to the oil preparation unit 13 for repeated further reuse, which can dramatically reduce its total the amount used as lifting energy, to increase, for example, the use of gas as a fuel for ground and downhole fired heaters 32, and also to increase e o the amount used as a working agent - to increase the oil recovery coefficient of oil-bearing formations and maintain a rational pressure value in them, and also to fully use the produced produced water for this purpose by pumping it back into the formation both through special water pipes 34 to injection wells 2, and in the most remote zones of horizontal oil wells 1, opening at the end points, below the level of oil-water contact, the aquifer of the reservoir.

 The products of each direction, or several directions, extracted from the wells, are transported to measuring devices 8.9 only in two oil lines: in one measuring device of volumetric-mass type, the production rates of the total production and its constituent components: oil, water and gas, in turn, of individual wells are measured and in another 9 - the total number of products and also in the component, oil, water and gas components of all other wells, which are then summed up in the electronic unit, fixing their values over time for all wells storages and oil fields. In them, simultaneously with the flow rates of the wells, the pressure values in the wells, as well as at other objects of the block integrated system of installations, are recorded.

 In addition to measuring the production rates of wells and fluid flow through separate blocks, changes in pressure and temperature at its inlet and outlet from separate blocks, they also measure the amount of electricity consumed by electric meters, which are then transferred to the information processing system, and then to control points and management of the operation of all objects of the block integrated system of installations involved in the development of the entire oil field in rational modes.

After measuring the amount of produced well products, it enters the common comb, and then passes through oil pipelines 35 to the oil preparation unit 15, to its heat exchangers 16, where it is heated by the heat of the oncoming stream coming out of the fire furnace with a temperature of 89-90 ^o С to a temperature of 30-50 ^o C. in the heat exchanger 16 of the gas and water are separated from the oil and discharged, respectively, through the pipeline 29 and the water pipe 36 in the pipeline 29 and pipe 18 gazovodootdelitel oil with the residual gas and water fed to the riser separability OP is a gas separator 17, where their main quantity is separated, which then also enters, respectively, the gas pipeline 29 and the middle part of the gas separator 18 with stabilization column heads 19, and oil with a small amount of residual gas, at a working pressure established in vertical separator - gas separator 17, enters the upper part of the pipe gas separator 18, where there is complete degassing and dehydration of oil to the values established by the standards. Dehydrated oil is gradually squeezed out from the stabilization column 19 into a mass-volume meter 23. The quality of the squeezed oil is controlled using a float regulator - hydrometer 20.

 In the production of low-emulsion oil, well products after heating in a fire furnace 32 and separating some of the gas and water from it in heat exchangers 16 enter a gas separator 18 with stabilization column heads 1, where they provide oil preparation to a standard quality, which is then measured when delivered to consumers and they monitor its compliance with established standards using volumetric meters 23 in time and are pumped through comb 37 into the main oil pipeline 28.

Sources of information
1. Development and operation of oil and gas fields, II Muravyov, R. Andriyasov, R. S. Gimatudinov, G. A. Govorova, V. T. Polozkov. M .: Subsoil. 1968.

 2. Features of the operation of cluster wells. S.M. Gadiev. Gostoptekhizdat, 1963.

Claims (5)

1. The method of development of oil fields, which consists in the production of liquid and gaseous hydrocarbons with associated formation water from production oil wells and injection water wells located separately and clusters associated with other oil field facilities: group measuring units, booster pump stations, collection and preparation units oil and water, compressor stations, cluster injection water stations, a network of pipelines serving for infield oil gathering and, gas and water, for their implementation, and trunk pipelines, gas pipelines, high-voltage power lines, communication and automation networks, as well as a network of access roads to all oil field facilities, characterized in that all objects of the oil field development system: wells of measuring units, installations for the preparation of oil, the injection of working agents to maintain the value of reservoir pressure, electrical transformer substations and control centers, are made block-wise on one site of the earth’s surface, the di of the field being developed, placed taking into account the wind rose, ensuring their fire safety, and replace the infield system for collecting oil, injecting the working agent: water, gas, oil, into oil-bearing horizons and the infield transmission network to intra-strapping pipelines, oil pipelines and high-voltage power lines connecting development site with oil consumers and energy supply enterprises, the construction of which is carried out simultaneously with the drilling of wells and sequentially by putting them into operation, bundling them with oil and water flow pipelines, overhead or cable power lines, if necessary, they are laid in quick-disconnect pipes connected to each other by overhead couplings, provide electricity to all objects with ring power from various feeders, at which wells have bushes, several rows, the faces of which are due to a combination of different types of drilling, with vertical, inclined and horizontal shafts drilled in how many directions from one trunk, ensure uniform drainage of the entire oil reservoir and maintain optimal reservoir pressure and the optimal mode of filtration of the reservoir fluid to the wells by selectively injecting oil gas into the poor-permeable zones of the reservoir, while simultaneously injecting produced water into the reservoir, as in the marginal zone, and selectively, in lowered areas inside the oil circuit using respectively gas compressors and universally x pumps driven by energy carriers: water, oil, gas pumped through their motor pumps and pumped further into the well as lifting energy or into the oil reservoir, the gas-water mixture is also used as a working agent to maintain a rational value of reservoir pressure in the reservoir, this injects into the formation or into the well both residual gas and gas supplied for its use as fuel of a fire heater used to heat the well products and ensure complete oil preparation , gas and water for their implementation by stepwise preparation in rhombic vertically installed tube-in-pipe heat exchangers with preliminary discharge of water from the lower points and the release of gas released from oil from the high points of the newly incoming well products from the last section of the heat exchanger at the entrance to the fire heater after pre-heating heat its exiting the furnace counter flow of products heated to 80-90 ^o C, and from which prior to its exit to the vertical gazovodootdelitel, and the extraction of n emulsion or weakly emulsion oil - directly to the gas separator tube, from which the gas and water released from the oil respectively enter the storage tank and into the lower part of the gas separator with a stabilization column head, and oil with a small residual water content, which, if necessary, is more deeply desalted, is mixed with hot fresh water with a demulsifier, served in the processing of emulsion oil in a vertical separator-gas separator, and when processing non-emulsion oil and - into the gas separator in the middle part of its upper half, slightly below the border of the oil-water contact, but above the partitions that prevent the direct entrainment of residual oil droplets, along the lower surface of the pipe into the water intake zone and ensuring the rise of oil in the zone of quiet movement of products to the upper part of the water separator in stabilization column head located on the upper end of the gas separator, from where oil with a given density through the drain valve, adjustable float regulator-hydrometer rum is passed into a pipe measuring device, which determines the amount of pumped oil to consumers, the residual gas is discharged into the common gas line through the upper gas bypass valve, and the water through an automatic adjustable valve, opening it or closing it, regulates the position of the oil-water contact between the two, upper and lower, permissible points controlled by level gauges.  2. The method of developing oil fields according to claim 1, characterized in that they continuously monitor the operation of the entire reservoir-well system — measurement objects — objects of preparation, injection into the reservoir and wells and sales of products by measuring oil, gas and water flow rates, pressures, and temperatures of individual wells and the total number of products of all wells, as well as their measurements in separate blocks for the preparation and sale, as well as the measurement of electricity consumed continuously in time at individual blocks and objects and in general for an oil field, in which all parameters are measured: flow rates of individual wells and their total number in the directions of the wells and throughout the oil field - in tube volumetric measuring devices installed on a common measuring unit of the production site, two devices for separate directions, one for sequential sequential measurement of the flow rates of individual wells, and another for measuring the flow rates of all wells in a given direction, in which pressure values are simultaneously recorded and those temperatures and their average values in time, as well as for individual wells and for groups of wells connected to transformer substations, the amount of electricity consumed, as well as the specified parameters characterizing the operation modes of individual links, are measured in all other blocks of the development system, which are processed in separate or , in general, electronic units and continuously in time, transmit to the General dispatch control.  3. The method of developing oil fields according to claim 1, characterized in that when the oil fields occupy large areas, when the wells located on only one site fail to cover the entire oil field with development, several such sites are being built, and the main one, where they fully prepare downhole products, place them on the basis of providing conditions for the development of the entire field at all stages of operation of the facilities with minimal cost of funds, making maximum use of energy, accumulated in the reservoirs from the very beginning of hydrocarbon production, in order to maintain its rational value by reverse controlled injection of produced water and part of light gas fractions of oil into wells and into oil-bearing formations as an energy carrier for production, using downhole gas lift or hydrostatic pressure of part of the downhole water supplied to the well using differential universal pumps installed both on the surface of the earth and in wells, using the same pumps and for infield pumping of various components of the extracted products, rocking machines of deep pumping units are also used for their drive, for which the components used as energy sources come from storage tanks, which are part of oil treatment plants and which, depending on the preparation requirements, provide the main unit with fire heaters, and on other sites only pipe gas separators are installed, in which, when producing viscous and emulsion gas-liquid mixtures, it is necessary to ensure of product as Preparation fed directly into wells demulsifiers, produce lift and separate collection of oil and water or arrives at the hole bottom product is heated to a temperature of rational using downhole combustion heater.  4. An integrated system of block installations, including bushes for production oil and injection wells, flow and receiving pipelines, measuring units for flow rates of well products, oil treatment units with a heating furnace, heat exchangers, sedimentation tanks, storage tanks for separating and accumulating individual components of produced well products and preparations for their implementation, a system of injection pipelines of a working agent, pumping and pumping units pumping it, and a network electrical wires and automation lines, a control panel, characterized in that all the device installations and structures are installed in separate blocks, taking into account their safe maintenance on one site on the surface of the earth in the area occupied by the oil field, where the clusters of production and injection wells are located in rows , a block of a complex of measuring devices where tube volumetric meters, water flow meters, electric meters, pressure and temperature sensors, are located atures for processing and transmitting measurement data to the control and monitoring center, installation for the preparation of wells with a path fire heater complete with rhombic tube-in-tube heat exchangers installed vertically with taps, a vertical gas separator, a gas separator with stabilization columns, heads with float regulators of oil and water levels by their density, gas bypass valves, automatic means for monitoring and controlling the delivery of of oil and water sold: tube mass-volume meters, flow densitometers in an oil pipeline, in a water separator water supply system, storage tanks, power units installed on the surface of the earth, ground-based or underground differential or universal pumps, pumps - compressors, connecting separate devices and installations, pipelines , electrical wires, control and monitoring units.  5. The complex system of block installations according to claim 4, characterized in that when the development of an oil field occupying large areas is carried out at several sites with the concentration of block complex systems of installations and structures on them, complete oil treatment is provided only in the central site, and at other sites, only oil pre-treatment plants are installed, consisting only of a gas separator, which is equipped with highly emulsified and viscous gas-liquid mixtures end vertical stabilization tanks installed to stabilize the oil at the end of the inclined gas separator, and to stabilize the water below the lower end of the gas separator, which are connected respectively to the water and gas reservoirs by flow pipelines, as well as pipelines - with wells and an oil and gas collection system, and in cases of production of highly viscous high-emulsion borehole products, equipment for downhole fire heating with downhole fired heaters was lowered into the wells fir trees, as well as gas and air compressors installed on the surface, universal air and gas pumps - differential compressors, driven by power units and pipelines connecting them.