EP0075515A1 - Method and installation for oil recovery by in situ combustion - Google Patents

Abstract

Enhanced recovery of oil from subterranean sedimentary formations by an in-situ combustion method employing a pattern of an injection well and several production wells, spaced-apart by a treatment zone. Combustion is controlled by placing at least one fluid conduit in a treatment zone and introducing a control fluid through it to modify the flame front. Oxygen may be introduced to take over from combustion air initially introduced through the injection well, to sustain combustion and advance the flame front. Water may be injected through the injection well, alternating with the oxygen through the control conduit to continue a wet combustion method started with air. The strategic placing of control conduits and the introduction of appropriate fluids may be employed to improve the sweep geometry by advancing the flame front or retarding it, or invading areas behind it. Safety means is provided for introducing the oxygen at a velocity greater than the maximum flame velocity encountered in the flame front.

Description

The invention relates to the recovery of petroleum by in situ combustion from deposits located in underground sedimentary formations.

Processes for recovering petroleum by in situ combustion from underground formations are described in the following published texts: "The Petroleum Reservoir", accelerated training course by Selley, Anstey and Donohue, International Human Resources Development Corporation, Boston, Mass, nineteen eighty one ; the manual "Enhanced Recovery of Residual and Heavy Oils", 2nd edition, edited by M.M. Schumacher, edited by Noyes Data Corporation, Parkridge, New Jersey, USA, 1980; "Heavy Oil Recovery by In Situ Combustion" by Dr. Phillip D. White, Tejas Petroleum Engineers Inc., Dallas, Texas, paper presented by S.P.E., Dallas Section, continuing education seminar, spring 1980; "Twenty Years Operation of an In Situ Combustion Project", by Jenkins and Kirkpatrick, Petroleum Society of C.I.M., 1978; and an article titled "In Situ Combustion Process - Results of a Five-Well Field Experiment, Southern Oklahoma", by Rosa, White and McNeil, Magnolia Petroleum Company, Dallas, Society of Petroleum Engineers of AIME, presented at the 33rd Annual Meeting Society Fall Festival, Houston, October 5-8, 1958.

White's article indicates that in 1979, in situ combustion processes still represented only a small percentage of the total production of petroleum by thermal methods. He concludes that one of the dissuasive elements is that the combustion processes require a much more intense technical effort than the other processes. In fact, these methods require well-designed equipment intended for well regulation, rapid and precise data collection, rapid data analysis and, also, perfectly trained field operators. The article indicates that these improvements can only be made if this type of process is very widespread.

Process regulation is essential and complex. To follow the advance of the combustion front and to predict operating problems, it is necessary to obtain basic data and analyze them, in particular the air speed and its pressure, the water injection rate. , gas evacuation speed in different wells, casing pressures on production wells, gas analysis, oil and water production rate, measurements temperature res. Other data, which are needed more rarely, but on a regular basis, include the density and viscosity of the oil leaving each well, the determination of chlorine in water, the p3 of water, the pressure drop of the injectors. The first group of data makes it possible to make calculations on the movement of the forehead, the efficiency of combustion and the use of oxygen. The second set of data makes it possible to make corrections to the calculated data and to prepare for the arrival of the thermal front in a production well.

In view of the above, the invention relates to an improved process for recovering petroleum by in situ combustion from underground formations.

According to the method of the invention, in situ combustion is regulated by the strategic placement of one or more fluid conduits, starting from the surface and crossing the overburden to reach the treatment zone, at a point located at a certain distance from the injection well, the regulating fluid being introduced into the deposit via said conduit, independently of the fluid injected into the injection well. According to a preferred embodiment of the invention, the control fluid introduced is oxygen, serving as auxiliary combustion gas and replacing the injection of a gas supporting combustion such as air in the well. injection. In this case, the fluid conduit is located near the injection well, but it is separated by a short distance, so as to allow the establishment, on the surface, of a separate regulation equipment. In the case of a wet combustion process, oxygen and water can be introduced alternately, the oxygen being sent through the fluid conduit and the water through the injection well.

According to another embodiment, when, when monitoring the flame front propagated by the air coming from the injection well, a cold zone is detected in which the flame front moves, for example too slowly to interfere in the geometry of the well layout arrangement and for the scanning efficiency, a regulating fluid conduit is placed in this zone, and oxygen is introduced to accelerate the flame front and improve the scanning. Or again, if during monitoring, we see that the flame front advances too quickly in a certain area, we can introduce a regulation conduit in this area and introduce appropriate fluids to slow the flame front and improve sweeping.

The invention is preferably used with a conventional in situ combustion model, preferably a multi-well mesh type well layout arrangement, in which air and water are introduced into a well. injection, which leaves the surface and crosses overburden to reach the oil field, in an injection zone, under conditions leading to the combustion of part of the oil and the flow of a part of the oil through a processing zone to at least one production well, disposed at a certain distance from the injection well; According to the invention, an oxygen introduction conduit is placed strategically, extending from the surface and crossing the overburden to the oil deposit, in the treatment zone. According to one embodiment of the invention, the oxygen conduit is placed near the injection well, but at a sufficient distance so that the equipment for regulating oxygen at the surface is distinct from the equipment. relatively complex regulator at the head of the injection well. For example, in a multi-well mail-hexagonal type well layout arrangement, in which the injection well is located about 122 m from several, for example six production wells, the separate oxygen conduit may be approximately 3 to 4.6 m from the injection well.

In this embodiment, air and water, in a representative treatment cycle, are introduced alternately into the injection well to advance the flame front to a certain point. The air injection is then stopped, then the injection well is used to introduce essentially only water. The air is replaced by oxygen, which is introduced into the deposit by the oxygen pipe to continue the advance of the flame front.

The invention also relates to a method of recovering petroleum from an underground sedimentary formation by the wet combustion process, method according to which there is an injection well, equipped to introduce air, or l water, or both, under conditions ensuring the combustion of part of the oil by air, and a certain number of production wells, arranged at a certain distance from the injection well, towards which one is s' drain the oil through a processing area. An oxygen duct separated from the surface, crosses the overburden and arrives in the formation treatment zone, at a point located at a relatively short distance from the injection well. The injection well is fitted with conventional, relatively complex air and water control equipment. The fact that the oxygen pipe is separated considerably simplifies the surface control system for both the air injection well and the oxygen pipe.

• - la figure 1 est un schéma, en vue de dessus, illustrant une disposition d'implantation de trois mailles de puits, équipés selon l'invention ;
• - la figure 2 est une coupe verticale schématique d'une formation souterraine sédimentaire, à grande échelle ;
• - la figure 3 est un diagramme schématique montrant une courbe représentative de la répartition des températures dans une formation qui a subi un procédé classique de combustion in situ, à l'échelle de la figure 2 ;
• - la figure 4 est une coupe verticale schématique, partiellement en élévation, d'une formation dans laquelle est placée une installation de combustion par voie humide équipée selon l'invention ;
• - la figure 5 est une coupe verticale d'un injecteur de sécurité selon l'invention.

The invention will be better understood on the basis of the description which follows and of the appended drawings, which represent examples of the invention, drawings in which:

• - Figure 1 is a diagram, in top view, illustrating an arrangement of installation of three mesh wells, equipped according to the invention;
• - Figure 2 is a schematic vertical section of an underground sedimentary formation, on a large scale;
• - Figure 3 is a schematic diagram showing a curve representative of the temperature distribution in a formation which has undergone a conventional in situ combustion process, on the scale of Figure 2;
• - Figure 4 is a schematic vertical section, partially in elevation, of a formation in which is placed a wet combustion installation equipped according to the invention;
• - Figure 5 is a vertical section of a safety injector according to the invention.

FIG. 1 represents an arrangement for the implantation of "three-mesh" wells, comprising three injection wells A, A and A ₂ . A series of production wells B are placed, for example, symmetrically with respect to the injection well A, at a certain distance from the latter. Air is injected through the injection well A into the underground formation in an injection area, to allow combustion of the oil. The production wells B located in the production areas are equipped with pumping means so that, when the combustion begins in the vicinity of the injection well A, the fluids, which include combustion products, water, steam and petroleum are entrained from the injection zone near well A, through a treatment zone, to reach a production zone at well B. A flame front is produced in the treatment zone between the injection area and the production area.

According to a representative mode of a conventional wet combustion, a cycle is carried out according to which air is introduced for two days, then water for one day, and this cycle is repeated continuously for several months or several years. For example, the injection well A is located in the center of the mesh and the production wells B are at the corners of the hexagon, at a distance of approximately 122m. The oil formation can be several tens to several hundred meters from the surface, for example 610 m. The thickness of the formation can range from a minimum of 0.3 m to more than 30 m. For example, most of the oil found in the Lloydminister area occurs in formations about 6 m thick. Exploitation can continue for several months before recovery begins in the production wells of oil from on-site combustion.

According to the invention, an oxygen conduit C starts from the surface, crosses overburden and arrives in the oil deposit, in the treatment zone, at a relatively short distance from the injection well A. For example, in the layout arrangement shown, the oxygen duct C can be 4.6 m from the injection well.

Although this distance is not critical, the fact remains that it is desirable that the oxygen duct be located at a certain distance from the injection well so as to allow independent realization l 'exploitation of both. In all cases, a fluid must constantly flow through the oxygen pipe and through the injection well.

According to the invention, once the flame front has advanced in the treatment zone, to the desired point, the injection of air and water is stopped in the injection well A and the introduction of oxygen in the oxygen line, alternating with the injection of water into the injection well.

In a typical start-up operation, the production well pumps are turned on and a certain amount of oil is extracted before in situ combustion. The flame can then be lit, for example by lowering a gas burner into the injection well, by sending air or natural gas to promote combustion. The burner can either stay in place, or be recovered, depending on the circumstances.

Figure 2 is a theoretical view of what happens during in situ wet combustion. This figure is a vertical section through an underground sedimentary formation containing petroleum, also known as an oil deposit, which has undergone wet combustion. The formation consists of an injection zone surrounding the injection well A, intended to introduce air to maintain the combustion of petroleum in the deposit and water to modify the heat transfer according to the method of wet combustion, and a production area surrounding the production well B, intended to extract the fluids pushed forward by the flame front. Between these two zones is a treatment zone, and the different materials making up this zone, at a particular stage of operation, are indicated by legends in the figure. According to the invention, a gas injection tube 0 is strategically placed in the treatment zone to introduce oxygen intended to promote combustion or to regulate the advance of the flame front, as will be described. in detail below. For example, as soon as the flame front has arrived at a certain point (see Figure 2), we can place an oxygen pipe, so that it enters the burned region, then introduce oxygen to promote combustion, oxygen which will replace the air injected into well A. In the case of wet combustion, one can alternate the introduction of oxygen into the oxygen duct and the introduction of water into the injection well. A representative method could include two days of oxygen injection and one day of water injection, during the entire treatment period, which can last up to several years.

In the layout arrangement of the type comprising three meshes with seven wells represented in FIG. 1, the injection well A is approximately 125 m (a) from the production well B. The treatment zone, between well A and wells B, covers approximately 4 hectares. The thickness of the sedimentary formation is between 0.3 and 30m, and it can be at a depth of about 610m, being covered by overburden in which there may be additional sedimentary oil formations separated by rock. Oxygen line C should be placed approximately 3.0 to 4.6 m from the injection well.

FIG. 4 represents an installation according to the invention, in vertical section, in an underground formation. In this figure, the reference A desires an air-water injection well. The well consists of a borehole, lined with a steel casing 15, which starts from the surface, descends through the overburden and arrives in the underground sedimentary formation in which the oil deposit is found. The borehole, outside the casing 15, is suitably filled with standard filling materials which form an envelope 17 internally lining the borehole. The casing 17 is lined with perforations 19 to allow the fluids to exit the borehole. The casing 15 is lined with a casing shoe 21. A lined tube 23 starts from a well head 25, located on the surface, to arrive at a recoverable "packer" 26, the lower end of which is centered in the 'envelope 17. An air and water pipe 27 leaves an injection unit, and can send to the wellhead 25 air or water under pressure. Valves 29 and 31 are provided, as well as check valves 33 and full-flow valves 35 and 36 to regulate the flow of air or water to the tube 23. The devices placed above from well A are frequently called "Christmas tree".

At a certain distance from the injection well A, an oxygen conduit C is placed, formed by a borehole housing a steel casing 37 and a concrete casing 36 filling the space between the borehole and the casing. An oxygen tube 41, which extends beyond the casing 37 and passes through a recoverable "packer" 43 to come out from below, extends into the borehole. The oxygen tube starts from the surface, crosses the overburden and enters the underground sedimentary formation, in the treatment zone located between the injection well A and the production wells. oxygen 45 starts from a pressurized oxygen source, passes through a full-flow valve 47 and arrives at the oxygen tube 41. Since only oxygen is introduced into the conduit C, the tube 41 does not need to be made of an expensive stainless steel such as that which is necessary for the injection well A where the presence of water causes corrosion. In addition, only relatively simple oxygen control equipment is required.

The lower end of the oxygen tube has a safety injector D, which is described in detail below.

Figure 5 is an enlarged partial vertical section of the bottom of the oxygen pipe. The end of the tube 41 carries an external thread intended to receive a cylindrical connector member 51 over its entire length. The member 51 has an internal bore, which has a cylindrical part 53, enlarged and tapped, meshing with the end of the pipe 41. The bore narrows into a frustoconical part 54 to arrive at a groove 55, which defines the inlet of a throttled central cylindrical passage 57. The lower end of the element 51 has an annular recess 58, which receives the end of a pipe 59 made of nickel alloy. The pipe 59 and the connector member 51 are welded to each other at 61.

A tip element 63 is mounted at the lower end of the pipe 59. The element 63 has a cylindrical body over its entire length, with an upper annular recess 60 receiving the end of the pipe 59. The element 63 and the pipe 59 are welded to each other at 65. The body of the element 63 has a central passage, which has an upper frustoconical part 67 narrowing to a short cylindrical groove 69, then widening in part frustoconical 71 ending in a shorter and wider frustoconical part 73. Parts 51 and 63 are made of a non-fissurable nickel alloy.

The dimensions of the oxygen pipe depend to a large extent on the force required to pull the "packer". The smallest diameter would be approximately 51 mm, the largest of 254 mm, 178 mm corresponding to a practical intermediate diameter. This diameter must be sufficient to allow the introduction of cement. Regarding the introduction of oxygen, a tube with a diameter of 51 mm is sufficient. The maximum diameter corresponds to a pipe which can be part of the well itself and still be cemented. To promote combustion, the pressure is generally the same as that of air, and is between 28 and 70 kg / cm ² . An empirical calculation method calculates the pressure, which will be about half a pound for 30 cm deep. The specific pressure depends on both the depth and the porosity of the formation. The boreholes can have any diameter. A plunger is provided to expel the cement. A unit on the surface supplies oxygen at low pressure at a rate of at least 18 tonnes per day, and compresses it to a pressure of 28 to 70 kgs / cm2. The oxygen line must be equipped to allow rapid replacement of oxygen with other fluids.

For safety reasons, at least part of the passage, through which the oxygen-containing gas is introduced, must be throttled so as to have a diameter such that the speed of the gas is greater than the maximum speed of the flame likely to to occur. This is what is obtained by using an injector such as that described in FIG. 5. This injector has throttled grooves, arranged in series, followed by an outlet opening of increasing diameter intended to allow the expansion of the gas. in order to reduce its speed and minimize the sanding effect inside the casing.

The safety injector as shown can be used not only for oxygen, but also for oxygen mixed with another fluid having desirable properties for the in situ combustion of a hydrocarbon deposit, for example CO ₂ , N ₂ air, ^H ₂ 0, etc ...

The tube downstream of the packer must resist cracking in contact with oxygen, heat, corrosion and erosion. Besides this, the tube must have maximum security. In an oil formation, for example, there may be disturbances and fuel seepage inside and around the injection tube.

A hydrocarbon can burn in the presence of air giving a flame having a certain speed. If the same hydrocarbon burns with oxygen, its flame propagation rate may be much higher. For example, the methane-air mixture gives a maximum flame propagation speed of 0.46 m / s, while the methane-oxygen flame has a maximum propagation speed of 4.57m / s. The hydrogen-air mixture has a maximum flame propagation speed of 3 m / s, while the hydrogen-oxygen flame has a maximum flame propagation speed of 14 m / s. As, among the various possible species that can be encountered in a formation of hydrocarbons during combustion in situ, it is the hydrogen-oxygen mixture which gives a flame having the highest maximum propagation speed, it it is imperative, from a safety point of view, to take precautions against the speed of propagation of this flame.

Another factor to consider is the effect of pressure on the speed of flame propagation. For example, the propagation speed of the flame H ₂ -0 ₂ is about ron 19.81 m / s under a pressure of 21 kg / cm ² , about 28.35 m / s under a pressure of 63 kg / cm2, and 30.48 m / s under a pressure of 105 kg / cm ² .

When designing the injection tubes at the bottom of the borehole, mechanical resistance must also be taken into account. To obtain the desired mechanical resistance, the internal diameter of the tube is generally too large, so as to allow the oxidizing gas to flow at a sufficiently high speed to avoid a flashback in the tube. In this case, a nozzle can be installed at the outlet of the tube, to accelerate the oxidizing gas to a speed greater than the maximum speed of propagation of the flame, to avoid a flashback in the tube. For additional security, one or more other nozzles can be placed upstream of the outlet nozzle, to resist any backfire.

If the flow rate of the oxidizing gas through the tube (which has sufficient mechanical strength) is high enough for the speed of the gas to be greater than the maximum speed of propagation of the flame likely to be at the level of the well. injection, it is not necessary to use nozzles accelerating the oxidizing gas.

These nozzles can be in the form of a straight bore, or they can be of a venturi type, such as that shown in FIG. 5, intended to avoid cracks in contact with oxygen which would reduce the resistance mechanical, and to prevent any backfire in the tube.

Preferably, one will choose for example the monel, for its resistance to combustion in contact with gaseous oxygen. In addition, it is relatively resistant to corrosion. A tube with a diameter of 50.8mm, nomenclature 80 is used (that is to say a tube having an external diameter of 60.31 mm and an internal diameter of 49.21 mm, the spacing of its walls being 5.5 mm), for its mechanical resistance, because it has a free length of 550m.

To avoid a flashback, a venturi nozzle is placed at the bottom, at the injector outlet. As additional security, another nozzle is placed upstream.

The injector is designed, for example, for an oxygen flow rate of 84,950 m ³ / day under a pressure of 31.5 kg / cm2 at room temperature. To be sure that we avoid the flashback thanks to one or the other of the two nozzles, the groove of the venturi nozzle has a diameter of approximately 11.4 mm, which allows the oxidizing gas to have a speed of 30.5 m / s, a speed which is higher than any flame propagation speed that can be encountered at the bottom an injection well or an oxygen pipe.

The outlet orifice (s) of the injector may be in the form of one or more holes. Each hole must be dimensioned so as to give the oxidizing gas injected a speed greater than the maximum flame propagation speed that can be encountered.

The downhole injector can only be used for oxidizing gas or a mixture of gases, or it can be used alternately with water injection, intermittently. For example, it can be used for the oxidizing gas and the mixture of gases with the other injected fluids (for example H ₂ 0 and / or air), injected into the formation by another injection well. In this case, water, air or other fluids need not be free of hydrocarbons (e.g. petroleum). Furthermore, if all the fluids intended for the injection well must be injected into the formation using only this single injector, all the fluids must be free of petroleum, in particular when the oxidizing gas is oxygen.

The invention is characterized by the introduction, defined in a strategic manner, of oxygen instead of air as a gas promoting combustion; by oxygen is meant here an oxygen having a volume concentration of 90% (under normal conditions), or more, and preferably a concentration of at least 99.5%.

The fact of using a separate oxygen conduit allows, compared to an injection well equipped to inject air and water, to selectively introduce oxygen without calling for expenses very high, from a technical and material point of view, an injection well equipped for oxygen injection. For example, due to the presence of corrosive elements and compounds in water, which, in the presence of oxygen, tend to accelerate the action of corrosion, it is necessary to use in a well of injection of materials giving sufficient protection against corrosion. These materials can be for example stainless steels, inconel, monel, haystellite, etc. In addition, the presence of petroleum in the ejected air, caused by the lubrication of the air compressor may, in the presence of oxygen, create a risk of explosion. To solve this problem, special oil filters must be used. The installation necessary, for safety reasons, to regulate the air and / or oxygen flow rates requires a complex installation on the surface.

If a separate line is used for injecting oxygen, these problems are avoided. Water does not flow through the oxygen pipe, so that it is completely dry and there is no need to use anti-corrosion materials. We can therefore use cheaper steel tubes. Given the relatively lower cost of this oxygen pipe, several can be used at successive points as the flame front advances. It may also be desirable, under certain conditions, to use oxygen with different concentrations of air, nitrogen or carbon dioxide or other gas at one or more points in the well layout arrangement. so as to produce special effects as described in the present invention.

The theoretical scanning efficiency which can be obtained with oxygen is about 45 to 50%, which is considerably lower than when using air. In fact, there is less nitrogen ballast and a higher partial pressure of CO ₂ in the oxygen combined with the coke. There is more CO ₂ in the oil, which decreases its viscosity, increases the production rate and decreases the entrainment of nitrogen in the production well. It is difficult to dissolve the emulsion that forms at the production well when using air as the combustion promoting gas. When using oxygen, the emulsion formed is easier to dissolve. The product leaving the production well, when using air, contains petroleum and sand, water, gas, C0 ₂ and nitrogen, a little methane, a little hydrogen and a little sulfur. When oxygen is used, there is very little nitrogen, more C0 ₂ , less sand, water and methane. The critical air flow would be approximately 5,660 m per well per day. With this same critical flow, we have five times more oxygen, a higher production flow, a lower entrainment and we recover a third more oil.

The various advantages of using oxygen over air in an in situ combustion have been described in Canadian Patent No. 770,434, Moore of October 31, 1967, and in the U.S. Patent States of America N ° 3.208.519, Moore of September 28 1965. These patents describe the advantages of using oxygen or a gas containing up to 80 _days , 1. free oxygen. However, the process of the invention should not be confused with those described in the Moore patents, which use an injection well, both for oxygen and for water. On the contrary, according to the invention, the introduction of the oxygen is carried out in a separate simple conduit into which the oxygen can be sent via a low-cost drill string, for example made of mild steel to carbon. The tube must simply have sufficient mechanical strength to withstand the forces applied during its installation, and its outlet orifice must be suitably shaped so as to withstand the temperatures to which it may be exposed. When, for example, the duct is installed in front of the flame front, the tube can be protected by a jacket of water or thick cement. There must always be a flow of fluid through the tube, in the same way as in the injection well, to avoid any backflow in the conduit. The extreme flexibility of using a pipe of this type for injecting oxygen is clear from the description above.

There are a number of patents describing variants of the in situ combustion process, involving the injection of other substances at the same time as air and / or water, and it is not considered necessary to study them in detail, because they are known in the art and do not affect the general implementation of the method according to the invention. In addition, it is understood that the representation of the siting of the wells is simplified. An arrangement of siting of wells with three meshes has been shown, but there may be any number of meshes in the siting plan of a field. In addition, observation wells are not shown, which are often used to study the nature of underground sedimentary formations. It is understood that the various means used for this purpose and for monitoring the advance of the flame front can be used in combination with the invention.

The use of one or more separate oxygen conduits also allows great flexibility for injecting oxygen into the formation, not only above the treatment area, but also at different levels. For example, conduits can go up to levels below which water is injected into the injection well in the case of wet combustion. By for example, oxygen can be introduced near the bottom of the oil deposit or at intermediate points. When water tends to flow downwards and oxygen upwards, a provision of this kind can improve the interactions between the oxygen introduced and the water injected with regard to the propagation and regulation of the flame front. With a simple conduit, the level of the outlet can be more easily adjusted than with an injection well.

The criteria for the relative amounts of oxygen and water to be injected at the different stages of in situ combustion and in the different states produced by it have already been established. In general, the ratio between water and free oxygen must be lower than that at which combustion would go out. Simultaneously, enough water must be injected into the injection well to maintain permeability to water from the heated part of the deposit behind the flame front and to reduce the temperature inside this heated part. The precise amounts, for a given treatment, depend on various factors, as is studied in the current state of the art.

Claims (20)

1. Process for recovering petroleum by in situ combustion from a sedimentary formation constituting an petroleum deposit, according to which air is introduced into an injection well extending from the surface and passing through the overburden to the interior of the petroleum deposit, in an injection zone, so as to burn part of the petroleum and cause fluids, including petroleum, to flow through a treatment zone to the least one production well is arranged at a distance from the injection well, characterized in that one introduces the ox ^y- gene in a separate conduit from the surface, through the overburden, and arriving in the oil deposit, said conduit being close to, but at a certain distance from, the injection well. 2. Method according to claim 1, characterized in that air and water are introduced into the injection well to advance the flame front to a certain point, then the introduction of water and oxygen is introduced into the oxygen pipe to continue advancing the flame front. 3. Method for recovering petroleum by in situ combustion from an underground sedimentary formation, according to which a gas supporting combustion, or water, or both, is introduced through a passage arranged in an injection well, so as to burn a part of the oil and to ensure that the fluids, including the oil, flow towards at least one production well disposed at a certain distance from the injection well, in a treatment zone, characterized in that oxygen is introduced through a separate passage, separate from the first passage mentioned above, starting from the surface and passing through the overburden until formation, said oxygen being introduced into the formation separately some water. 4. Method according to claim 2, characterized in that the flame front is advanced to a certain point in the treatment zone, then a separate conduit is placed behind said flame front, after its passage, and oxygen is introduced into said separate injection pipe, so that the oxygen reaches the burnt zone, depleted of hydrocarbons, to promote the combustion of coke by creating an additional source of heat behind the front of flame. 5. Method according to claim 1, characterized in that the oxygen is injected into the separated oxygen conduit at a speed higher than the maximum flame propagation speed in the immediate vicinity of the oxygen pipe. 6. Method according to claim 1, characterized in that the advance of the flame front through the treatment zone is regulated by the positioning of additional oxygen conduits inside the treatment zone to increase the efficiency of the sweep. 7. Method according to claim 1, characterized in that, when irregularities occur disturbing the symmetry of the in situ combustion pattern, at least one separate oxygen conduit is placed leaving the surface and crossing the overburden as far as the treatment zone, and a fluid is introduced into said conduit to modify the advance of the flame front, in order to improve the symmetry of the sweep. 8. Method according to claim 1 characterized in that the scanning symmetry is improved and regulated by the selective positioning of fluid conduits and by the introduction, into said conduits, of a combustion regulating fluid. 9. Process for recovering petroleum by in situ combustion from underground sedimentary formations containing an petroleum deposit, according to which air is introduced into an injection well, starting from the surface, crossing overburden and arriving in the oil field, in an injection zone, so as to burn part of the oil in order to form a flame front and cause fluids, including oil, to flow to a certain number of wells production from which fluids are extracted, said production wells being placed at a certain distance from the injection well so as to form a well layout arrangement, characterized in that one starts and continues the combustion of petroleum in the deposit by injecting air into the injection well to produce the flame front and advancing said flame front towards the production wells by crossing part of the treatment zone, then the injection is stopped. ection of air and oxygen is introduced into at least one separate conduit starting from the surface, crossing the overburden and arriving in the oil deposit, in the treatment zone, in the vicinity of the injection well, and continuing said oxygen injection to advance the flame front through another part of the treatment zone. 10. Method according to claim 9, characterized in that water is introduced alternately with air as the flame front advances through the first part of the treatment zone, and injects water into the injection well alternately with the introduction of oxygen into the oxygen conduit. 11. Method for recovering petroleum by in situ combustion from an underground sedimentary formation constituting an petroleum deposit, according to which an oxygen-containing gas and water are injected into an injection zone located in the oil field so as to burn a part of said oil to form a flame front and to cause fluids, including oil, to flow through a treatment zone towards at least one production well disposed at a certain distance from the injection well, characterized in that the water is injected into an injection well and in that the oxygen-containing gas is oxygen and is introduced by a separate conduit from the surface, crossing overburden and entering the oil field in the processing area. 12. Process for recovering petroleum by in situ combustion from an underground sedimentary formation containing an petroleum deposit, according to which air is introduced into an injection well starting from the surface, passing through the overburden and arriving in the oil field, in an injection zone, so as to burn a part of said oil to form a flame front and to cause fluids, including oil, to flow to a certain number of wells of production forming a well layout arrangement with the injection well, the fluids being extracted from said production wells at a certain distance from the injection well, the combustion of petroleum in the deposit is started and continued by injection of air into the injection well to produce the flame front, then air and water are injected into the injection well to advance the flame front through a section of the treatment area to 'au poi nt where there is a distortion of the scanning of the flame front under the effect of the slowing down of said flame front in a certain part of the treatment zone, characterized in that oxygen is introduced into a oxygen leaving the surface, crossing overburden and arriving in said certain part of the milking zone so as to advance the flame front to improve the progress of the latter. 13. Process for recovering oil by in situ combustion from an underground sedimentary formation constituting an oil deposit, according to which air is introduced into an injection well starting from the surface, passing through the overburden and arriving in the oil field, in an injection zone, in order to burn part of the oil and ensure that fluids, including oil, flow through a treatment zone towards at least one well of production located at a certain distance from the injection well, characterized in that one starts and continues the combustion of the oil in the deposit by injecting air into the injection well to produce a flame front, one makes advance said flame front through part of the treatment zone towards the production well (s), then the injection of air is stopped and oxygen is introduced into a separate conduit, starting from the surface, passing through the overburden and arriving in the oil field, in the treatment zone, in the vicinity of the injection well, and this oxygen injection is continued to advance the flame front through another part of said treatment zone. 14. The method of claim 13, characterized in that water is introduced alternately with air to advance the flame front through the first part of the treatment zone, then is introduced oxygen in a separate pipe from the surface, crossing the overburden and arriving in the oil field, inside the treatment zone near the injection well, and water is introduced into the well alternating injection with oxygen in the oxygen duct. 15. The method of claim 11, characterized in that oxygen is introduced into the separate conduit at a level lower than that at which water is injected into the injection well. 16. The method of claim 11, characterized in that oxygen is injected into several separate conduits at respectively different levels, below the level at which water is injected into the injection well. 17. Method according to claim 1, characterized in that the oxygen is introduced by throttled passages so as to increase its speed of introduction into the treatment zone. 18. Installation for the recovery of oil by in situ combustion from underground sedimentary formations containing an oil deposit, characterized in that it comprises an injection well starting from the surface, crossing overburden and arriving in the oil field, in an injection zone, said injection well being equipped with means for injecting air and water; a plurality of production wells in a production zone separated from the injection zone by a treatment zone, each of said production wells being equipped with means for extracting fluids from the formation; at least one fluid conduit leaving the surface, crossing the overburden and arriving in the treatment zone at a point situated at a certain distance from the injection well, said fluid conduit being equipped with means for introducing oxygen in training. 19. Installation according to claim 18, characterized in that the means for introducing oxygen comprise a cylindrical injection tube at the bottom of the well, having an inlet end and an outlet end; a first throttling element, mounted on the inlet orifice, having a cylindrical body over its entire length provided with a central passage, said passage having an enlarged portion which receives the inlet end of a descent, said body ending in a connector receiving the inlet end of the injection tube, welded to the latter; a nozzle element, mounted on the outlet end of the injection tube, having a cylindrical body over its entire length provided with a central passage and having a connector received by the outlet end of the injection tube; at least one of the throttles and nozzle elements having a throttle intended to increase the speed of the gas under pressure. 20. Installation according to claim 19, characterized in that the outlet end of the passage arranged in the nozzle element widens to allow the expansion of oxygen at the outlet orifice.

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