EA013235B1 - Method of extraction of heavy high-viscous oils, bitumens and other caustobiolits - Google Patents

Abstract

This invention relates to the mining and can be used in the process of oil, bitumen and other caustobiolits deposit development. The objective of the invention is to increase effectiveness of heavy high-viscous oils, bitumen and other caustobiolits deposit (layer, lense) development and also the preservation of the ecological balance in the working area. Method of heavy high-viscous oils, bitumen and other caustobiolits deposit development, including opening-upof theproductive layer (lense) with wells, influence on the productive stratum through the pump-compressor pipes with the static pressure and the elastic waves with turn of the wave from the reflector oriented in space in the given direction, the packer installation in the well differing in the following: the productive stratum (lense) is opened up at least with one pumping and one extraction wells, from each well on a rated distance vertically from the productive layer (lense) medium line and perpendicularly to the medium line no less than three bias oriented shifts are drilled with an exit to the settlement marks, from which the top shift is sinking in the roof rocks, lower is sinking in the subface of the stratum (lense), and others are sinking in the productive stratum (lense) body, between the pumping and extraction wells the top shifts linkage is carried out in roof and lower shifts linkage is carried out in the bottom of productive stratum, with gas-waterproofing screen formation generating the closed loop round the productive stratum (lense) body, thus the shifts linkage and the gas-waterproofing screen formation are carried out with the help of rocks processing in the linkage area with the elastic waves transferring through the working medium, containing colmatation additives, the extraction of the mineral is carried out with the help of the elastic waves energy that is transferring into the productive stratum (lense) through the pumping well passing the wave guide representing the working medium that is able to thin heavy high-viscous oil, bitumen and other caustobiolits at the expense of their solution, and/or hydrogenation, and/or gasification and/or other way, the intake of the product of the necessary consistency is generated through the extraction well.

Description

The invention relates to mining and can be used in the development of oil, bitumen and other caustobioliths.

Known methods of oil production and enhanced oil recovery of productive formations, consisting in thermal effects on oil-containing rocks when using different designs of oil wells and applied technological solutions [1-6].

These methods are ineffective in the development of highly viscous heavy oils due to large losses of thermal energy, low coverage of the thermal effects of the reservoir, low oil recovery factor, the need to build a dense network of production and injection wells and, as a consequence, the high cost of raw materials.

Known methods of thermal effects on the reservoir [7,8], including both thermal and wave effects. Thermal impact is carried out by supplying a coolant (superheated steam) into the reservoir through a pressure oscillation generator installed in an injection or production well, while the wave effect is carried out at oscillation frequency values determined from the corresponding dependencies.

The disadvantages of these methods are the loss of heat energy for heating the reservoir, low recovery rates of the useful product, which ultimately affects the high cost of oil production. When using these methods, a breakthrough of oil emulsions into aquifers is also possible, which will lead to a deterioration of the ecological situation in the region of production.

There is a method of developing mineral resources, including opening a reservoir of at least two wells, supplying the solvent through the casting wells, impacting the deposit with pressure pulses with a periodically varying waveform, asymmetric distribution of the energy of the pulses with respect to zero amplitude, and discharging the mineral through the pumped wells [9] - analogue.

This method is also ineffective, because does not take into account the possibility of breakthrough of oil-containing fluids in aquifers and pollution of the region of oil production.

There is a method of increasing the permeability of the formations, including opening the productive formations by wells, the effects on the formations by static pressure and elastic waves along the wave fluid filling the tubing with rotation of the wave from the reflector oriented in space in a given direction, the installation of a packer in the well to protect the production string and overlying layers from the impact of shock waves [10] - a prototype.

This method is ineffective in the development of deposits of high-viscosity heavy oils and bitumen, while there is also the possibility of breakthrough of oil-containing solutions in nearby aquifers, which will lead to disruption of the ecological balance in the region of production.

The objective of the invention is to increase the efficiency of the development of deposits (reservoir, lenses) of highly viscous heavy oils, bitumen and other caustobioliths, as well as the preservation of the ecological balance in the area of work.

The task is achieved by the fact that in the method of increasing the permeability of formations, including opening of productive formations by wells, the impact on the formation through tubing pipes with static pressure and elastic waves with their rotation from a reflector oriented in space in a given direction, installing a packer in the well, productive the formation (lens) is opened at least one injection and one production well, from each well at the calculated vertical distances from the midline of the reservoir (lenses) and perpendicular to the midline of the Buryats with access to the calculated marks of at least three obliquely oriented trunks, of which the upper trunk passes in the rocks of the roof, the lower - the bottom of the reservoir (lens), and the rest the injection and production wells carry out the assembly of the upper trunks along the roof and the lower ones along the sole of the productive formation (lens) with the formation of a gas-waterproofing screen forming a closed loop around the body of the productive formation (lens), with the assembly of the trunks and the formation of a gas-waterproofing screen is carried out by treating the rocks at the connection site with elastic waves transmitted through the working medium containing clogging additives; extraction of the mineral is performed using the energy of elastic waves transmitted to the reservoir (lens) through the injection well through the waveguide representing the working medium capable of thinning high viscosity heavy oil, bitumen or other caustobioliths due to their dissolution and / or hydrogenation and / or gasification And / or otherwise, and the product the required consistency fence produced through production wells.

The distances between the trunks and the median line (the line passing through the center of the cross section of the productive formation (lens) along its strike) depend on the permeability of the roof and bottom rocks, as well as the geometry and properties of the productive formation (lens).

FIG. Figures 1 and 2 provide a scheme for the development of deposits of highly viscous heavy oils, bitumens and other caustobioliths.

The proposed method for the development of deposits of highly viscous heavy oils, bitumens and other caustobioliths is as follows.

- 1 013235

Inside the contour of the field 1, the productive formation (lens) 2 opens at least one injection 3 and one production 4 wells. From each well in the rocks of the roof 5 and the base 6 of the productive formation (lens) 2 at the calculated height from the midline and in the direction of the perpendicular 7 restored in the horizontal plane on both sides of the midline, two upper 8 and two lower 9 are inclined oriented the trunk.

The upper trunks 8 and the lower trunks 9 are fixed perforated along the entire length of the casing. The mouths of the injection and production wells are equipped with a fountain armature and a wave radiator 10 for processing the productive formation (lens) 2 with elastic directional waves. On pump-compressor pipes 11, wave reflectors 12 are lowered into all trunks to the calculated elevations.

In the injection well 3, the reflectors 12 are oriented in the direction of the production well 4, and the reflectors 12 in the production well 4 are oriented in the direction of the injection well 3. In the upper and lower trunks, both in the injection well and in the production well, packers 13 are installed at the calculated distance from the reflectors 12. Then, the upper 8 and lower 9 shafts are connected between the injection 3 and production 4 wells, respectively, along the roof 5 and the base 6 of the productive formation (lens) 2. The breaking is carried out from the injection well 3 to the production well 4 by using static Whose pressure and energy of the directed elastic waves transmitted through the waveguide. As a waveguide, a liquid working medium with clogging additives (for example, viscoelastic components) is used, which simultaneously with the assembly of trunks allow cementing and clogging loose and fractured rocks of the roof 5 and soles 6 of the productive formation (lenses) 2, forming around the body of the formation (lenses) gas barrier screen 14, which prevents the penetration of oily emulsions, gases, hydrocarbons and / or other caustobioliths outside the reservoir (lens) during its development. The amplitude of the directed elastic waves should not exceed 0.7 of the ultimate strength of rocks. To accelerate the formation of the gas-insulating screen 14 when the upper trunks 8 and lower trunks 9 of the inlet 3 and production 4 wells are assembled, the rocks of the roof 5 and the base 6 of the productive formation (lens) 2 produce a counter-impact from the production 4 to the injection well 3 up to to ensure the design characteristics of pickup of these rocks. The formation of a hydrogastight screen 14 is carried out so as to form an enclosed space 15 around the reservoir (lens) 2, with boundaries that prevent the penetration of natural and technological fluids beyond the reservoir (lens) 2 and ensure the extraction of minerals with the maximum possible extraction of viscous heavy oils, bitumen and other caustobioliths without loss of thermal energy, displacement of valuable light fractions from the reservoir (lens) 2 and while maintaining ecological balance in the area of work.

A step-by-step system for extracting viscous heavy oils, bitumens, and caustobioliths can be created within the created confined space 15 by drilling additional injection and production wells by liquefying, dissolving, hydrogenating, changing the state of aggregation, etc. with the formation of zones with predominant concentration of methane.

Removing highly viscous heavy oils, bitumens and other caustobioliths from the reservoir (lenses) 2 begin with the descent through the injection well 3 reflectors of the directed elastic waves 12 into the trunks 16 in the body of the reservoir (lenses) 2 on the tubing 11. The reflectors 12 are oriented in space in the direction of the working area along the strike of the productive formation (lens) 2 and open the packers 13. After mounting the set of equipment for processing the productive formation (lens) 2 with directed elastic waves, yayut stored pressure borehole mining 3 working medium. Depending on the composition of highly viscous heavy oils, bitumens or other caustobioliths, the mining working medium may be a liquid mixture of saturated and / or unsaturated hydrocarbons with water, gases (eg H2, CO2, etc.), as well as other components in percentage terms, chosen in depending on the reservoir conditions, the composition of the mineral and the stage of mining of the productive formation (lens) according to the condition of the most complete extraction and ensuring the required quality of the mining product. At the same time, the wave emitter 10 is also filled with the working medium. The air or gas cushion is released into the atmosphere through a special valve. The fluid pressure at the wellhead is established from the condition of maintaining an equilibrium between the hydrostatic pressure of the working medium column in the shafts 16 together with the pressure at the wellhead with the pressure of rocks preventing the penetration of reservoir fluids with the working medium beyond the created closed space 15.

Similar procedures are performed for the production well 4.

Processing of the productive formation (lenses) is carried out mainly in the direction of the production well 4, while the amplitude of elastic waves should not exceed 0.7 of the elasticity of rocks. During the wave processing of the productive formation (lens), a static balance is maintained between the rock pressure and the pressure of the working medium column in the shafts 16 on the reflectors 12.

At the onset of bonding wells 3 and 4 and receiving the first portion of the dissolved high viscosity heavy oil, bitumen and working agent from the production well 4, tensile waves will radiate towards the injection 3. Continue the process to achieve the project production

- 2 013235 Chi mixture consisting of a mineral and working environment. Extraction of a mixture of minerals and the working medium can be performed by vacuuming with time-varying pressure.

To ensure the process of hydrogenation of highly viscous heavy oils, bitumens, and other viscous caustobioliths in reservoir conditions on the tubing 11 can be lowered to the calculated depth of the downhole hydrogen generator.

At the stage of mineral extraction, static pressure with the imposition of elastic waves transmitted in the right direction provides effective dissolution, hydrogenation and gasification of viscous oils, bitumens and other caustobioliths, with full coverage of the productive space (lens) between injection and production wells.

Thus, the proposed method of extraction can significantly improve the development of deposits of highly viscous heavy oils, bitumens and other caustobioliths, as well as maintain the ecological balance in the area of work.

Claims (2)

1. A method of producing highly viscous heavy oils, bitumen and other caustobioliths, including opening the reservoir by wells, exposing the reservoir through pumping pipes by static pressure and elastic waves with wave rotation from the reflectors, installing a poker in the well, characterized in that the reservoir is opened as at least one injection and one production well, from each well perpendicular to the midline, at least three obliquely oriented shafts are drilled, of which the upper l passes in the rocks of the roof, the bottom - the bottom of the formation, and the rest - in the body of the reservoir, in the injection well, the reflectors are oriented in the direction of the production well, and in the production well, the reflectors are oriented in the direction of the injection well, between the injection and production wells the upper trunks are broken on the roof and lower - on the bottom of the reservoir with the formation of a closed loop gas-waterproofing screen around the body of the reservoir, with the failure of the trunks and the formation of gas the insulating screen is carried out by treating the rocks in the breakdown area with elastic waves transmitted through a working medium containing clogging additives, extraction of minerals is carried out using elastic wave energy transmitted to the reservoir through the injection well through a waveguide representing a working medium that can dilute highly viscous heavy oil, bitumen or other caustobiolites, and the product of the required consistency is sampled through a production well. 2. The method according to claim 1, characterized in that the waveguide is a working medium capable of liquefying highly viscous heavy oil, bitumen or other caustobiolites due to dissolution and / or hydrogenation and / or gasification.