RU2657036C1 - Method of in-situ combustion - Google Patents

Abstract

FIELD: technological processes; oil and gas industry.

SUBSTANCE: invention relates to a method for recovering a mixture of heavy hydrocarbons from an underground formation by in-situ combustion. Method of in-situ combustion is that a number of vertical injection wells reaching the formation reservoir are made in the oil formation. Also, at least one gas production well separated laterally from a number of injection wells, and a horizontal production well located below the formation reservoir and injection wells are made. Oxygen-containing gas is supplied to each injection well and ignition is performed. Product obtained from the production well is produced. Gases formed as a result of in-situ combustion are obtained through the formation reservoir. After the start of combustion in one of the vertical injection wells, preferably in the vicinity of the center of the horizontal injection well, a temperature sensor is introduced at some depth. Based on the sensor readings, a portion of air-saturated water is injected under pressure with the addition of crushed aluminum chips. After the chips start burning, oxygen-containing gas is fed into the same vertical injection well for a while.

EFFECT: technical result consists in increasing the productivity of the well, reducing operating costs and increasing the flow rate of petroleum products.

1 cl, 1 dwg

Description

The present invention relates to a method for extracting a mixture of hydrocarbons, in particular a mixture of heavy hydrocarbons, from an underground formation by in situ combustion.

The prior art method of in-situ combustion for extracting a mixture of hydrocarbons, heavy hydrocarbons from an underground reservoir, described in the patent (USA 5456315 C2.10.10.1995).

A disadvantage of the known technical solution is that its implementation requires oxygen-enriched gas, which complicates and increases the cost of the process.

There is also a method of in-situ combustion described in the patent (RU 2564425 C2, 09/27/2015), and adopted as a prototype, in which a number of vertical injection wells are performed in the upper part of the reservoir, in addition, at least one gas production well is performed, separated laterally from a number of injection wells, and a horizontal production well located below the injection wells, an oxygen-containing gas, typically air, is injected through each injection well y and produce ignition, hydrocarbons produced from the horizontal production well, which lies below the injection interval and to initiate and maintain combustion in the reservoir is used to inject the oxygen-rich gas, for example a mixture of oxygen and CO _2.

The disadvantage of the prototype is that, like the analogue, with an excess of petroleum coke and with a small amount of bound water, such an event can lead to a certain decrease in temperature in the combustion zone and the transfer of heat to the zone located in front of the combustion front due to evaporation water and its subsequent condensation. In addition, for its implementation, like an analogue, an oxygen-enriched gas is required, which complicates and increases the cost of the process.

The objective of the invention is to increase the uniformity of the coverage of the formation by burning, reducing the viscosity of the oil in the formation, reducing air consumption and reducing the excess amount of coke, as well as providing a more uniform burning background in fields containing heavy high-viscosity oil, and reducing the cost of production.

The technical result achieved by the implementation of the invention is to increase the productivity of the well, reducing operating costs and increasing the debit of oil products.

The technical result is obtained due to the fact that in the method in which a series of vertical injection wells are reached reaching the reservoir, at least one gas production well is separated laterally from the series of injection wells and a horizontal production well located below the formation reservoir and injection wells, oxygen-containing gas is supplied to each injection well, ignition is carried out, and the resulting product is extracted from production well, and the gases generated as a result of the in-situ combustion are obtained through a reservoir according to the invention into one of the vertical injection wells, preferably to the horizontal injection well closest to the center, at some time, a temperature sensor is introduced to a certain depth, according to the results of sensor readings under pressure, a portion of water saturated with air with the addition of crushed aluminum chips and after the burning of chips into the same vertical injection well zhinu awhile fed oxygen-containing gas.

The specified technical result is also achieved due to the fact that, according to the signals of the said temperature sensor, a portion of water saturated with air is re-introduced with the addition of crushed aluminum chips.

The introduction of portions of air-saturated water with the addition of ground aluminum shavings into one of the vertical injection wells contributes to an increase in temperature inside the horizontal injection well due to the burning of the chips, which increases the uniformity of the formation coverage by combustion, decreases the viscosity of oil products in the formation, reduces air consumption and reduces excess quantity coke, as well as providing a more uniform combustion front in the fields, including the fields Containing high-viscosity oil.

The supply of oxygen-containing gas to the well, where the combustion of aluminum chips occurs, leads to the distribution of high temperature over a larger volume of the chamber.

Re-introducing a portion of air-carbonated water with the addition of crushed aluminum chips according to the temperature sensor signals leads to an increase in the positive effect of burning aluminum chips.

The method of in-situ combustion is illustrated by the drawing, which shows a diagram of in-situ combustion inside the well; oil saturation distribution; water saturation distribution; temperature distribution and several zones formed as a result of combustion are shown.

A diagram illustrating the proposed method is as follows.

During in situ combustion, several zones are formed in the formation.

1 - injection well; 2 - production well; 3 - distribution of oil saturation; 4 - distribution of water saturation; 5 - temperature distribution.

In this case, several zones located horizontally can be distinguished:

I. A burnt zone with traces of unburned oil or coke, in which the injected air is heated by the heat remaining in this zone after passing through the combustion front.

II. Combustion zone in which the maximum temperature reaches 1500-2500 ° C. The heat in this zone is transferred mainly due to convection.

III. Evaporation zone, in which sublimation of oil into fractions and cracking of residual oil as a result of its heating by hot gases coming from the combustion zone takes place. The produced and bound water in this zone turns into dry steam, decomposed under the influence of high temperature into atomic oxygen and hydrogen.

IV. Condensation zone in which condensation of hydrocarbons and water vapor occurs due to lower temperatures. Oil and water are pushed to production wells by non-condensing gases and gases resulting from combustion, such as СО ₂ , СО and N ₂ , also О, Н, О ₂ , Н ₂ СН ₄ and other gaseous products.

V. Zone of increased water saturation, containing all three components - oil, water and gases.

VI. The zone of increased oil saturation, formed as a result of the movement of oil from previous zones and containing low-viscosity oil due to its enrichment with light fractions of hydrocarbons.

VII. The undisturbed zone, in which the reservoir temperature remains practically the original, and therefore the viscosity of the displaced oil is low.

The solid lines show the parameters available in the traditional method, and the dashed lines indicate the predicted parameters for the claimed method. The drawing also shows a temperature sensor 7 and a hose 8 for feeding pulp containing shredded chips with the addition of water saturated with air.

The method is as follows.

A series of vertical injection wells extending to the formation reservoir is performed, at least one gas production well is also separated laterally from the series of injection wells, and a horizontal production well located below the formation reservoir and injection wells is formed. Then, in one of the vertical injection wells, preferably in the closest to the center of the horizontal injection well, a temperature sensor 7 is introduced on the rod. Oxygen-containing gas is supplied to each injection well and ignition is performed. Due to the burning of oil and gas products inside the reservoir, the sensor 7 shows an increase in temperature. Typically, the temperature inside the reservoir is slightly higher than 300-400 ° C. At a certain value of the sensor 7 readings, a hose 8. is introduced into the same well where the sensor is located, and a portion of water saturated with air is added under pressure with the addition of ground aluminum chips under this hose. As you know, aluminum chips spontaneously ignite at temperatures of 250 ° -300 ° C. When burning aluminum chips inside the reservoir, the temperature rises to values exceeding 2500 ° C. When this temperature sensor 7 signals a further increase in temperature inside the reservoir, which indicates the ignition of the chips.

Then, oxygen-containing gas is supplied to the well where combustion of aluminum chips occurs, which leads to the distribution of high temperature over a larger volume of the tank. The resulting water vapor contributes to the extrusion of petroleum products along the reservoir. At the same time, at such a high temperature, water vapor with the presence of burning aluminum decomposes into oxygen and hydrogen. Oxygen in turn reacts with petroleum coke. Intensively burning coke helps keep the temperature high. At high temperatures, sublimation of coke continues with the release of lighter fractions from it. At the same time, hydrogen can react with coke carbon, forming a mixture of gases consisting of methane, ethane, propane, etc. In this case, burning aluminum acts as a catalyst. As a result of high-temperature cracking, high-molecular-weight liquids (from pentanes and higher) and various compositions and phase states are additionally released from coke. As the processes occurring inside the reservoir reservoir, a portion of the aluminum chips introduced into it burns out and the temperature begins to drop. This fixes sensor 7. Based on previous experience, either at the request of the operator or with a decrease in the debit of oil products, an additional portion of air-saturated water is added to the formation with the addition of crushed aluminum chips. The process described previously is repeated.

Light, gaseous fractions, together with hydrogen, enter a gas production well and are removed from it for further processing.

Heated heavy hydrocarbons, having a lower viscosity than natural hydrocarbons, flow down under the action of gravity into a horizontal production well, from where they are pumped out for further processing and use.

Thus, the introduction of portions of air-carbonated water into one of the vertical injection wells with the addition of crushed aluminum chips and an additional air supply contribute to an increase in the temperature inside the horizontal injection well due to the combustion of the chips, increase the uniformity of the formation coverage by burning, reduce the viscosity of the oil in the formation, reduce air flow and reduce excess coke. At the same time, the productivity and productivity of the well increases significantly, the outflow of carbon dioxide decreases, the operating costs are reduced, and the air consumption is reduced. This allows to produce and use efficiently and hydrocarbons to produce with minimal impact on the environment, in particular emit less CO _2.

The in-situ combustion method is one of the most complex in terms of its mechanism, implementation conditions, modeling and prediction of possible efficiency.

Preliminary thermodynamic and hydrodynamic calculations show that the proposed method leads to the refinement of oil (thermal cracking, pyrolysis, etc.).

Claims (2)

1. The method of in-situ combustion, which consists in the fact that a number of vertical injection wells are reached in the oil reservoir reaching the reservoir, at least one gas production well is separated laterally from the series of injection wells, and a horizontal production well is located below reservoir reservoir and injection wells, oxygen-containing gas is supplied to each injection well and ignition is produced, and from the production well the resulting product is obtained, and the gases generated as a result of in-situ combustion are obtained through a reservoir, characterized in that after the start of combustion, a temperature sensor is introduced to a depth at one of the vertical injection wells, preferably to the center of the horizontal injection well, according to the results of the sensor readings, a portion of water saturated with air is added under pressure with the addition of ground aluminum chips and after the burning of the chips into the same vertical discharge th wellbore at a time is fed oxygen-containing gas. 2. The method according to p. 1, characterized in that, according to the signals of the said temperature sensor, a portion of air-carbonated water is reintroduced with the addition of ground aluminum chips.

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