RU2199657C2 - Underground-surface method of development of high- viscosity oil deposit - Google Patents

Abstract

FIELD: oil and gas industry, specifically, thermal oil mine method of development of high-viscosity oil and natural bitumen. SUBSTANCE: mine working is driven in productive pool or beneath it. From mine working there are drilled gently rising steam-distribution and production wells. Vertical injection wells are drilled from surface. Heat transfer agent is injected into them. Steam is utilized as heat transfer agent. Steam is distributed over pool through gently rising steam-distribution wells. They are drilled from mine working in parallel to production wells. Bottoms of steam-distribution wells are oriented towards roof of oil pool. They cross injection wells or pass in zone of their influence. Additional production wells are oriented beneath bottoms of vertical injection wells. Each steam- distribution and additional production well is drilled from one point of mine working in the form of radial rays located in one vertical plane. When additional production well is filled with steam it is transferred to category of steam-distribution wells. EFFECT: accelerated bringing of developed section to planned level of oil production, decreased time of development of deposit. 2 dwg

Description

 The invention relates to the oil industry, in particular to thermal mine methods for developing fields of high viscosity oils and natural bitumen.

 A known method for the production of highly viscous oil (see US patent 4434849, E 21 B 43/24, publ. 06.03.84), including the injection of coolant into injection wells drilled from the surface and from a mine, the selection of oil through radially located production wells, drilled out of a mine.

 The disadvantage of this method is that steam is injected from the mine through radially located wells. This leads to uneven heating of the reservoir, as well as to significant heat generation in the mine workings, which leads to a violation of sanitary and hygienic standards and high costs for normalizing the thermal regime in the mine workings with working personnel.

 The closest in technical essence, adopted by the authors for the prototype, is an underground-surface method for developing a highly viscous oil field (see RF patent 2114289, E 21 B 43/24, 03/12/97), including the selection of oil through half-rising production wells drilled from mining, passed in or below a productive oil reservoir, pumping coolant (steam) into injection wells drilled from the surface, followed by distribution of coolant (steam) through the reservoir through half-rising steam distribution wells, the faces of which are oriented in the roof of the oil reservoir and cross injection wells or pass in the zone of their influence, while they are drilled from a mine parallel to the production wells in the gap between them.

 The disadvantage of this method is the long time it takes to establish a hydrodynamic connection between steam distribution and production wells. This is due to the high viscosity of the reservoir oil, the small amount of free vapor space through which the coolant can propagate, which is very significant for sufficiently large distances between the steam distribution and production wells, while the possibility of increasing the injection pressure of the coolant, which is mainly used as saturated water vapor, for oil displacement is limited by the properties of oil and the conditions of mine development (danger of sublimation of oil and the flow of oil gases to the furnace e generation). All this leads to a decrease in the rate of coolant injection and oil production and, consequently, to an increase in the time it takes to reach the project oil production.

 The objective of the present invention is to accelerate the withdrawal of the developed section to the design level of oil production and reduce the development time of the field.

 The problem is solved by the fact that the development of a highly viscous oil field is carried out by the underground-surface method, while the oil is extracted through half-rising production wells drilled from a mine drilled in or below the oil reservoir, the coolant is pumped into injection wells drilled from the surface with its subsequent distribution in the oil reservoir through the half-rising steam distribution wells, the faces of which are oriented to the roof of the oil reservoir, the intersection injection wells or pass in the zone of their influence, moreover, steam distribution wells are drilled from the mine parallel to production wells, while additional production wells are drilled from the mining, oriented below the bottom of the vertical injection wells, and each steam distribution well and additional production well are drilled from one place mining in the form of radial rays located in one vertical plane, after filling additional mining sk Azhinov it is converted into steam discharge steam distribution holes.

Salient features of the claimed invention is that:
- drill additional production wells, oriented below the bottom of the vertical injection wells;
- steam distribution wells and additional production wells are drilled from one mining site in the form of radial rays located in one vertical plane;
- transfer the additional production well after the breakthrough into it of steam in the category of steam distribution.

 The specified set of essential distinguishing features contributes to the activation of heating the oil reservoir and oil production. So, due to the location of steam distribution and additional production wells in the form of radial rays, the distance between the wells decreases, therefore, the pressure of the coolant (steam) supplied to the steam distribution wells is sufficient to displace the heated oil into additional production wells and free up the vapor space that will be filled with steam, providing intensive formation heating and the rate of coolant injection into injection wells. The mouth of the steam distribution well is closed during the injection of steam, the column of liquid (condensed steam) inside it creates a natural hydraulic lock that prevents the breakthrough of steam into the mine workings. The location of the steam distribution and additional production wells in the same vertical plane ensures uniform heating of the reservoir, while the advancement of the heat front along the oil reservoir occurs from the roof to the bottom of the oil reservoir. After the breakthrough of steam into additional production wells, they are transferred to the category of steam distribution. By this time, a significant amount of steam space in the area of the shafts of the steam distribution and production wells will be freed from oil and produced water and occupied by steam, which will ensure intensive heating of the oil reservoir due to the large surface of the interaction of steam with the oil reservoir and will lead to the establishment of a hydrodynamic connection between the injection and steam distribution producing wells. The main oil production after the establishment of hydrodynamic connection will occur through production wells.

 Thus, the claimed method provides the activation of the process of heating the reservoir and oil production, which helps to accelerate the withdrawal of the developed section to the design level of oil production and reduce the development time.

 The claimed features of the invention are not obvious to the average person skilled in the art. In this regard, the authors believe that the claimed invention has an inventive step.

 The claimed combination of essential features is not known to the authors of the prior art, therefore, the claimed invention is new. The invention is industrially applicable, since the available domestic equipment and technology developed by the authors make it possible to use the method in full.

 In FIG. 1 shows a plot of a developed field in plan; figure 2 - the same section with mine workings and wells, section aa of figure 1.

At the site of the oil field (Fig. 1, 2) of high-viscosity oil or natural bitumen to be developed, at least two vertical shaft shafts 1 (lift and ventilation) are constructed, providing access to the oil layer 2, sinking and ventilation of mine workings (galleries) 3 that are built at the bottom of the oil reservoir 2 or below it (near the oil-water contact - VNK). Near the boundary of section 4, a number of injection wells 5 are drilled from the surface to the middle part of formation 2. From the gallery 3, flat-rising production wells 6 are drilled at an angle of 1-5 ^° to the boundary of section 4.

 Production wells 6 (figure 2) are arranged in parallel rows in two or more tiers depending on the thickness of the oil reservoir 2 in the middle of the interval between the injection wells 5.

 In the middle between the production wells 6, rows of two half-rising wells are drilled, one of which is oriented to the top of the formation and crosses the injection well 5 or is in the zone of its influence — the steam distribution well 7, and the second — the additional production well 8 passes below the bottom of the injection well 5, wherein the steam distribution well 7 and the additional production well 8 are drilled from one mining site in the form of radial rays located in one vertical plane. The steam distribution well 7, intersecting with the bottomhole zone of the injection well 5, forms a single injection system for pumping the coolant. Additional production well 8 serves to drain the oil reservoir 2 in the area of the injection 5 and the steam distribution wells 7.

 Vertical injection wells 5 are drilled to the middle of the oil reservoir 2 and equipped to inject steam and water. All underground wells: production 6, steam distribution 7 and additional production 8 are cased to a depth of 30-50 m and equipped with shutoff valves. Discussion of steam distribution 7 and additional producing 8 wells to a depth of 30-50 m will allow the creation of a natural hydraulic lock from condensed steam and formation fluid in the wells, which will prevent steam from breaking into the mine workings. The casing of production wells 6 by 30-50 m will allow you to postpone the moment of approach of the heat front to mining at the end of the development period of the site.

 The claimed method is as follows.

 Stage 1. The steam is pumped into all injection wells 5. It enters the steam distribution wells 7, heating the borehole. Since the production wells 6 are located quite far from the steam distribution wells 7, before establishing a hydrodynamic connection between them, oil will be displaced into additional production wells 8, which are located nearby. At this stage, the mouths of the wells 6, 8 are open, and the steam distribution 7 open only for the descent of the accumulated fluid in the trunks.

 Stage 2. At this stage, breakthrough of steam occurs in additional production wells 8 and they are transferred to the category of steam distribution, while steam distribution 7 and additional production 8 wells are closed and opened only to drain the accumulated fluid in the trunks. This indicates the formation of a razrenirovanny zone of oil reservoir 2 in the area of the steam distribution wells 7 and additional production wells 8, which provides a large surface for the interaction of steam with oil formation 2. At this stage, a hydrodynamic connection is established between the steam distribution 7 and additional production 8 wells with production 6. a constant increase in oil flow rate in producing wells 6. In the event of steam breakthrough into production wells 6 in highly permeable zones or fractures of these wells We close it, while steam is injected into all injection wells 5 at the highest possible cost for the early heating of oil reservoir 2. To more evenly distribute heat throughout the volume of oil reservoir 2, incidentally produced water is periodically pumped, which takes heat from highly permeable, well-drained and heated zones and transfers it to other parts of the oil reservoir 2.

 Stage 3. By the beginning of this stage, oil reservoir 2 is quite well and evenly heated. Intensive oil recovery is taking place. All producing wells 6 are open, and when steam breaks through them, injection wells 5 are closed, which have a direct hydrodynamic connection with them along highly permeable zones or cracks. Along the way, simultaneously produced water is pumped, which performs the functions of oil displacement and heat distribution in the oil reservoir 2. Steam distribution 7 and additional producing 8 wells are opened only to lower the accumulated liquid in them.

 Stage 4. At this stage, steam is pumped only into injection wells 5, which are associated with the least developed sections of oil reservoir 2. All production 6 and steam distribution 7 and additional production 8 wells that are not associated with injection wells 5, into which steam injection is conducted, are open . They are closed as steam breaks through them. For the best washing of oil from the formation rocks, surfactants and associated water are pumped.

 The proposed method significantly increases the rate of oil extraction through the use of an additional production well 8, made in the form of diverging radial rays, with a steam distribution well 7 located in the same vertical plane, since favorable conditions are created for the rapid formation of a razrenirovanny zone in the area of the steam distribution wells 7 and additional producing 8 wells, which provides a large surface for the interaction of the coolant and the oil reservoir.

 Heating of formation 2 occurs from the roof to the bottom of the oil formation and from the boundaries 4 of the developed area to gallery 3, which leads to a decrease in heat losses in the mine atmosphere and provides normal working conditions for production personnel.

 Example. The claimed method can be implemented on the Yaregskoye field of high viscosity oil, where the viscosity of the oil in reservoir conditions is 15-20 thousand MPa • s. The oil reservoir lies at a depth of 180-200 m from the surface.

 Create a set of underground workings - lifting and ventilation shafts 1 with near-barrel yards and cameras for technological purposes (in Fig. 1, a near-barrel yard and technological cameras are not shown).

 Trunks 1 extend 20 m below the oil reservoir, creating sumps to collect fluid (oil, water). The distance between the trunks 1 on the originally developed area of 600 m or more. The trunks 1 are connected by a mine working (gallery 3), which pass at the bottom of the oil part of the formation 2 or below it.

Gallery 3 is built with a cross-section of at least 10 m ² in the light, which is necessary to place a drilling rig in it (for example, PBS-2T). From gallery 3, in different directions, production wells 6 are drilled in parallel rows at an angle to the horizon of 1-5 ^o up to 250 m long. In each row there are two wells located in two tiers. Wells are cased to a depth of 30-50 m and cemented, and then there is an open trunk or cased with a perforated column.

 In the middle of the gap between the rows of production wells 6, rows of wells are drilled, each of which consists of a steam distribution 7 and an additional production 8 wells parallel to the rows of production wells 6, up to 250 m long, while a steam distribution 7 and additional production 8 wells are drilled from one mining site (the distance between the mouths of the wells of 0.2-0.5 m) in the form of radial rays located in the same plane. Wells are cased to a depth of 30-50 m and cemented, and then there is an open trunk or cased with a perforated column.

 A number of vertical injection wells 5 are drilled from the surface to the middle of the oil reservoir 2 on each side of the gallery 3 at a distance of 50-70 m from the boundary of section 4. Wells 5 are located in the middle of the gap between the rows of production wells 6.

 Steam distribution wells 7 are oriented in the roof of the oil reservoir and cross the injection wells 5 or pass in the zone of their influence, and additional production wells 8 extend in the oil reservoir 2 below the bottom of the injection wells 5.

Steam from a boiler or steam generator installation (CCGT) is fed into injection wells at a maximum rate of 5 with a pressure of up to 1.0 MPa and a temperature of up to 180 ^o C (with a higher temperature, steam cannot be pumped in the mine development of the Yarega field due to the possibility of the start of sublimation of oil and emissions of volatile fractions that may fall into mine workings).

 The produced fluid from underground wells 6, 7, 8 is transported through a special groove in gallery 3 or through a pipeline laid in gallery 3 to collection tanks at the shaft of mine 1. After preliminary preparation of oil, it is pumped to the surface for further preparation and transportation to the oil refinery.

 The entire field is mined simultaneously or sequentially in separate sections.

 The invention compared with the prototype allows to increase the pace of field development and by reducing the time of its development to reduce the specific heat consumption per unit of oil produced, and therefore, to reduce heat loss in the surrounding rocks and mine workings.

Claims (1)

 An underground-surface method for developing a highly viscous oil field, including oil extraction through half-rising production wells drilled from a mine drilled in or below the oil reservoir, pumping coolant into injection wells drilled from the surface, followed by steam distribution through the reservoir through half-rising steam distribution wells , the faces of which are oriented in the roof of the oil reservoir, cross the injection well or pass in the zone of their influence, drilled from the mining th production parallel to the production wells, characterized in that additional production wells are drilled from the mining, oriented below the bottom of the vertical injection wells, and each steam distribution well and additional production well are drilled from one mining site in the form of radial rays located in one vertical plane, after filling the additional production well with steam, it is transferred to the category of steam distribution wells.

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