FR2935426A1 - PROCESS FOR EXTRACTING HYDROCARBONS BY HIGH-FREQUENCY HEATING FROM UNDERGROUND IN SITU FORMATION - Google Patents

Abstract

The invention relates to a hydrocarbon extraction plant in an underground formation (1), comprising: - at least one well (2); - sampling means (21) of hydrocarbons; at least one high frequency generator (4) in the well (2), comprising a vacuum tube (7) and at least one anode (10) and at least one cathode (8) arranged in the vacuum tube ( 7); at least one radiating load (6) in the well (2), connected to the high frequency generator (4); and means for recovering the heat emitted by the anode (10) comprising at least one fluid transport pipe (3), said means being adapted to transfer at least a portion of the heat emitted by the anode (10). ) hydrocarbons or underground formation (1). The invention also relates to a hydrocarbon extraction process that can be implemented in this installation.

Description

The present invention relates to a method for extracting hydrocarbons by in situ high-frequency heating of the underground formation, as well as to a method for extracting hydrocarbons by high-frequency heating in situ from the underground formation, as well as to a method for extracting hydrocarbons by high-frequency heating in situ from the subterranean formation. installation adapted to the implementation of this process.

BACKGROUND ART The high viscosity of the hydrocarbons present in certain deposits (heavy oils) poses considerable extraction problems. In such cases, it is generally necessary to reduce the viscosity (fluidify) of heavy oils so as to make them more mobile and therefore able to extract them. The challenge is in particular that of the exploitation of sands or oil shales. Many techniques have been proposed for this purpose, including the SAGD (steam assisted gravity drainage), which involves injecting steam into the reservoir, heating by conduction of heat (for example by means of electrical resistors) or in situ combustion, which consists of injecting an oxidant, usually air, into the deposit via injection wells and initiating combustion within the deposit, so as to develop combustion fronts from the wells air injection and towards the production wells. Another technique that has been proposed is to heat the reservoir by high-frequency radiation: (radio frequency or microwaves). However, no high-frequency heating system has so far gone beyond the pilot stage because of a number of disadvantages.

One of the first examples of high frequency heating scheme is in US 4,193,448. This document describes an oil extraction device comprising a microwave emission apparatus disposed in the well. The microwave emission apparatus comprises a microwave generator (which is a magnetron), a waveguide, and radiation scattering means. The fluidized hydrocarbon sample is taken above the microwave emission apparatus. In the context of extraction of liquid hydrocarbons, this system has the disadvantage that the heated hydrocarbons tend to move downwards under the effect of gravity; therefore a sample taken above the maximum heating zone is not optimal.

Similarly, the document system only allows heating at a reduced distance from the transmitting apparatus, but not at a great distance. In subsequent proposals in other patent documents, the high frequency generator is usually provided on the surface. For example, according to WO 2007/078350 and WO 2007/078352, the electromagnetic energy is transmitted by means of coaxial cables to antennas located at the bottom of the well. According to these documents, the extraction of hydrocarbons is also assisted by the injection of critical fluids by diffusion in the subsoil, with reactants or catalysts. Thanks to the heating, the reactants react with the hydrocarbons of the tank which facilitates their extraction in liquid, vapor or dissolved form in the critical fluids. In the document WO 2007/147053, likewise, a radiofrequency generator is provided on the surface. The generated energy is radiated by means of a radiofrequency antenna disposed in a horizontal or vertical specific well. The production well, part of which is horizontal, is located under the radiofrequency antenna. However, the use of a high frequency generator on the surface is problematic. On the one hand, it may be necessary to pass the electromagnetic energy produced over hundreds of meters between the surface and the bottom of the tank; however, the appropriate equipment (coaxial cables) is expensive and fragile. On the other hand, on the surface, the authorized frequency bands (ISM) are strictly limited by the regulations in force. Unless shielding is particularly difficult to apply, the system is therefore very inflexible with respect to the radiation frequency. In addition, high frequency generators dissipate much of the energy produced in thermal form and not in electromagnetic form. This heat is generally lost in all systems proposed in the state of the art. There is therefore a real need to provide improved hydrocarbon extraction facilities and processes by high frequency heating of the tank, including better performing facilities and processes. In particular, there is a need to develop a high frequency heating device that can heat a larger area of the underground formation compared to the state of the art, and that can adapt flexibly to variations in physical characteristics. chemical reservoir.

SUMMARY OF THE INVENTION The invention relates primarily to a hydrocarbon extraction facility in a subterranean formation, comprising: R: Patents 27800'27888--080822-text depot.doc- August 22, 2008 5 10 15 20 25 at least one well; means for sampling hydrocarbons from at least one high frequency generator in the well, comprising a vacuum tube and at least one anode and at least one cathode disposed in the vacuum tube; at least one radiant charge in the well, connected to the high frequency generator; and means for recovering the heat emitted by the anode comprising at least one fluid transport pipe, said means being adapted to transfer at least a portion of the heat emitted by the anode to the hydrocarbons or the subterranean formation. According to one embodiment: the fluid transport pipe is a pipe for transporting hydrocarbons taken to the surface; and the means for recovering the heat emitted by the anode are adapted to transfer at least a portion of the heat emitted by the anode to the collected hydrocarbons circulating in the fluid transport conduit. According to one embodiment: the fluid transport pipe is an auxiliary fluid transport pipe to the bottom of the well; and the heat recovery means through the anode are adapted to transfer to the emitting less part of the auxiliary fluid emitted heat flowing through the anode the fluid transport conduit 30; and the installation also comprises: means for dispersing the auxiliary fluid in the formation. According to one embodiment, the installation comprises at least one additional well, the means of

R. ',. Patents 2780027888-080822-texte_depot.doc- 22 August 2008 removal of hydrocarbons being located in the additional well. According to one embodiment, the hydrocarbon sampling means are located in the well, and preferably are located downstream of the high frequency generator. According to one embodiment: - the vacuum tube surrounds the fluid transport pipe, and preferably the vacuum tube has a substantially cylindrical geometry and the fluid transport pipe is disposed along the axis of the vacuum tube; and / or - the radiating charge surrounds the fluid transport conduit, and preferably the radiating charge has a substantially cylindrical geometry and the fluid transport conduit is disposed along the axis of the radiating charge. According to one embodiment: - the fluid transport pipe is disposed outside the vacuum tube, preferably surrounds the vacuum tube; and / or - the fluid transport pipe is disposed outside the radiant charge, preferably surrounding the radiant charge.

According to one embodiment, the vacuum tube has a substantially cylindrical geometry and the anode is closer than the cathode of the axis of the vacuum tube, the cathode surrounding preferably the anode. According to one embodiment, the installation further comprises an oscillating circuit located between the high frequency generator and the radiating load or integrated in the vacuum tube and / or the radiant load. According to one embodiment, the radiating charge is capable of translation along the well.

According to one embodiment, the radiating load is an antenna or an applicator. According to one embodiment, the high frequency generator is chosen from a magnetron, a triode, a tetrode or a pentode, and is preferably devoid of an adaptation system. frequency. According to one embodiment, the installation comprises a plurality of modules along the well, each module comprising: at least one high frequency generator comprising a vacuum tube and at least one anode and at least one cathode disposed in the tube empty; at least one radiant charge; and means for recovering the heat emitted by the anode comprising at least one fluid transport pipe, said means being adapted to transfer at least a portion of the heat emitted by the anode to the hydrocarbons or the subterranean formation. The invention also relates to a hydrocarbon extraction process in an underground formation, comprising. the emission of electromagnetic radiation by means of a radiating assembly disposed in a well, said radiating assembly comprising: at least one high frequency generator comprising a vacuum tube and at least one anode and at least one cathode arranged in the vacuum tube; and at least one radiant charge; - the heating of the underground formation by means of the emitted electromagnetic radiation; - removal of hydrocarbons from the underground formation and transport of hydrocarbons to the surface; and recovering at least a portion of the heat emitted by the anode and transferring at least a portion of this heat to the subterranean formation or to the hydrocarbons removed. According to one embodiment, the radiant load comprises an antenna and the subterranean formation is heated directly by means of the emitted electromagnetic radiation. According to one embodiment, the radiant charge comprises an applicator, and the heating of the subterranean formation by electromagnetic radiation comprises: - heating an auxiliary fluid by means of electromagnetic radiation; dispersion of the auxiliary fluid in the subterranean formation; and heating the underground formation with the dispersed auxiliary fluid. According to one embodiment, the transfer of the heat emitted by the anode to the subterranean formation comprises: the transfer of the heat emitted by the anode to an auxiliary fluid; dispersion of the auxiliary fluid in the subterranean formation; and heating the underground formation with the dispersed auxiliary fluid. According to one embodiment, the heat emitted by the anode is transferred to the hydrocarbons removed, during their transport to the surface.

According to one embodiment, the subterranean formation comprises organic materials and the heating of the subterranean formation by means of the emitted electromagnetic radiation and / or the transfer of the heat emitted by the anode to the subterranean formation induce the conversion of organic matter into hydrocarbons. According to one embodiment, the heating of the underground formation by means of the emitted electromagnetic radiation and / or the transfer of the heat emitted by the anode to the subterranean formation or to the hydrocarbons removed induce upgrading of the hydrocarbons. According to one embodiment, the above-mentioned method is implemented in an installation as described above. In the context of the invention, by heating an object means a heat transfer to this object, that is to say the transfer of a positive amount of thermal energy from a heat source to this object. The notion of heating here comprises both the direct heat transfer from the heat source to the object without passing through an intermediate material (this is the case for example when the object is heated by the radiation emitted by a radiant source); and the indirect heat transfer from the heat source to the object via another material, for example an auxiliary fluid (heat transfer fluid). Upgrading means any process known in the oil / gas field to modify the quality of hydrocarbons (especially oils) and in particular to make hydrocarbons more valuable. The term "upgrading" covers in particular any chemical transformation process making it possible to obtain lighter hydrocarbons than the hydrocarbons initially present in the underground formation. Upgrading notably facilitates the production of hydrocarbons in the tank, or facilitates the transport of hydrocarbons on the surface. By conversion, we mean any process of transformation of organic matter into hydrocarbons, in particular the pyrolysis of oil shales into hydrocarbons. By organic materials are meant materials comprising substances essentially having a carbon-based structure and comprising hydrocarbon compounds and their derivatives. A: Patents 27800 27888--080822-Text Depot.doc- 22 August 2008 The term "hydrocarbons" means chemical compounds containing exclusively carbon and hydrogen atoms. The present invention overcomes the disadvantages of the state of the art. More particularly, it provides an improved hydrocarbon extraction facility and process by heating the subterranean formation using high frequency radiation. This method and this installation are more energy efficient than the methods and installations of the state of the art. This is accomplished by the development of an electromagnetic radiation heater, in which at least a portion of the thermal energy produced by the high frequency generator located at the bottom of the well is transmitted to the subterranean formation. Indeed, a high frequency vacuum tube generator (triode type for example) dissipates about 1/3 of its energy in the form of heat and not in the form of radiation. The invention makes it possible to recover this heat energy for heating a fluid. It can be directly hydrocarbon fluid that is otherwise heated (directly or indirectly) by electromagnetic radiation, or an auxiliary fluid that itself serves to heat the subterranean formation. This device has the decisive advantage of being able to be placed directly in a well. Thus, in particular, problems of limiting the frequency domain, which are related to a surface position of the generator, are avoided. According to some particular embodiments, the invention also has one or preferably more of the advantageous features listed below. - When the generator is a triode or a similar system, it is possible to dispense with any adaptation system of R Bresets 27800 27888u080822-text depot dot: - August 22, 2008 frequency (which is necessary in case of surface position of the generator because of regulatory constraints on bandwidth). In this case, the frequency and the power of the generator more easily adapt to the load that is the whole of the high frequency antenna and the underground formation itself. In particular, the generator automatically adapts to any change in the structure of the underground formation, for example when the formation is depleted, and therefore its impedance evolves. It is therefore generally not necessary to replace the antenna and / or the generator during extractivity. When the generator is a triode or similar system, lower frequencies and higher powers can be achieved than with a magnetron, so that the penetration distance of the electromagnetic waves into the subterranean formation is greater. When the heat dissipated by the anode of the generator is transmitted to the extracted hydrocarbons, the paraffin deposit in the well and / or the viscosity of the hydrocarbons and / or the pressure drops in the well are reduced. By making the high frequency antenna movable in the well, a better homogeneity of treatment of the underground formation is obtained. This is also the case when using a succession of generator / antenna modules in the well. Such modules can not be implemented with the type of generator geometry described in the state of the art. - The radiation in the underground formation can also be used to obtain upgrading of hydrocarbons in situ. 10 R: Patents 27800 27888--080822 -testing depot.doc- August 22, 2008 - Compared to the prior art of associating a downhole antenna with a surface generator, connected by a coaxial cable, the losses are limited between the generator and the antenna. In addition, the plant according to the invention can be implemented directly in the extraction well, without necessarily additional well. It is also possible to envisage a multi-well configuration in the case of initially mobile oils (because a scanning mechanism can then be introduced). The invention enables improved hydrocarbon recovery (EOR) with reduced water consumption and without directly generating carbon dioxide. It is possible to heat the rock of the underground formation away from the well and at controlled temperature. Thin banks and shallow to very deep formations can be heated. The presence of non-ferrous clay (non-magnetic) is not an obstacle to the homogeneous heating of the underground formation. If ferrous clay is present, it is also possible to choose lower frequencies. Clay then acts as a susceptor. The implementation of the invention is also possible in formations with low or very low permeability.

BRIEF DESCRIPTION OF THE FIGURES FIG. 1 schematically shows a hydrocarbon extraction plant according to the invention. Figure 2 schematically shows an example of an electromagnetic radiation fluid heater according to the invention. FIG. 3 is a detailed schematic representation of an example of a high frequency generator used in the context of the invention. FIG. FIG. 4 schematically shows in detail an example of a hydrocarbon extraction installation according to the invention.

DESCRIPTION OF EMBODIMENTS OF THE INVENTION The invention is now described in more detail and in a nonlimiting manner in the description which follows.

General description of the hydrocarbon extraction installation according to the invention Referring to FIG. 1, a hydrocarbon extraction installation according to the invention comprises at least one well 2 disposed in an underground formation 1. Well 2 may be vertical, essentially vertical, inclined or it may comprise portions of different inclinations. In particular, it may comprise a horizontal or essentially horizontal portion. In general, the underground formation 1 comprises hydrocarbons or comprises a material (organic materials) that can be converted into hydrocarbons by physical or chemical transformation. The formation 1 may for example be sandy, clay or carbonated. It can be a tank of any type of gaseous or liquid hydrocarbons, including natural gas, bitumen, heavy oils, mobile oils and conventional oils. Formation 1 may also include oil shale, oil sands, methane hydrates or adsorbed gas on clay. It can also be: a coal deposit. The installation according to the invention comprises means 21 for collecting hydrocarbons. These sampling means 21 can be arranged in the well 2 R. Patents 27800 -880822-text-file August 22, 2008 (in which case the well 2 is a heating and extraction well) or in a well additional (in which case well 2 is a heating well and the additional well is an extraction well).

In the well 2 is provided a radiating assembly, which mainly comprises a high frequency generator 4, an oscillating circuit 5 and a radiating load 6 connected to the output of the generator 4. The radiating assembly is adapted to emit electromagnetic radiation.

By high frequency generator is meant a generator capable of producing radiofrequency or microwave electromagnetic radiation, that is to say an electromagnetic radiation of frequency between a few hundred kHz (for example about 200 kHz) and a few GHz (for example for example about 2 GHz), preferably between 500 to 600 kHz and 10 to 15 MHz. The radiating load 6 connected to the output of the generator 4 may be a radiating antenna (for example of the dipole type) or an applicator, that is to say an element comprising an enclosure and adapted to provide electromagnetic radiation in the enclosure. The radiating charge 6 may also consist of different applicators and / or antennas associated in series to form a processing line. In this chain, the different elements emit in the frequency range best suited to their function. The generator 4 consists of different elements inside an envelope intended to provide mechanical protection and maintain a vacuum of 10-9 torr. Thus, with reference to FIG. 2, the generator 4 comprises a vacuum tube 7. In this vacuum tube 7 at least one cathode 8, at least one anode 10 and at least one control grid 9 are arranged. The control circuit 9 may be brought to a potential by means of a bias circuit to control the flow of electrons between the cathode 8 and the anode 10. August 2008 The vacuum tube 7 may also include matching capacitors, capacitors and decoupling inductors, a power supply system for the control gate 9. The assembly is thus made reliable with respect to the carrying capacity voltage, it being understood that the vacuum has an excellent dielectric strength. Preferably, the vacuum tube 7 is of substantially cylindrical geometry. In this case, the anode 10 and the grid 9 are preferably of cylindrical geometry.

According to a first variant, the anode 10 is located towards the periphery of the vacuum tube 7 and the cathode 8 is located towards the center of the vacuum tube 7. The cathode 8 may for example be along the axis of the vacuum tube, or preferably arranged around the axis.

However, unlike the usual arrangement in the high frequency generators, and according to a second variant which is preferred, the anode 10 is located towards the center of the vacuum tube 7 (for example along the axis of the vacuum tube or preferably around the axis) and the cathode 8 is located towards the periphery of the vacuum tube 7. This variant is shown in FIG. 2. The generator 4 is preferably selected from a magnetron, a triode, a tetrode cu a pentode. More particularly preferably, the generator 4 is chosen from a triode, a tetrode or a pentode. Ideally, it is a triode, as shown in FIG. 2. The choice of a triode type generator or the like makes it possible to have a more intense radiation and a lower frequency than with a magnetron . This choice also makes it possible to benefit from a variable and adaptable radiation frequency according to the circumstances of use, in particular when the device is devoid of any frequency matching system, as is the case according to a particular embodiment. According to a particular embodiment, said push-pull mode, the generator 4 can: include two triodes in phase opposition in the same vacuum tube. A: Patents 2780027888--080822-text_potdoc- August 22, 2008 This embodiment provides a double power. The generator 4 also includes various circuits to ensure the control of operation, collect and transmit information to the user, block the electromagnetic leakage that would be conducted by the primary power supply cables. The oscillating circuit 5 is provided between the generator 4 and the radiating load 6, either in the form of a separate element, as shown in FIG. 1, or in an integrated manner in the generator 4 (in the vacuum tube 7) and / or radiant charge E, partially or totally.

In particular, the generator 4 may comprise a capacitive bridge forming part of the oscillating circuit 5. Symmetrically, when the radiating load 6 is an antenna, this antenna may be powered by a coaxial waveguide and whose impedance is adjusted to constitute the inductive part of the oscillating circuit 5 associated with the generator 4. When the oscillating circuit 5 is completely integrated with the generator 4 and / or the c-wide radiator 6, the size of the device is reduced and the risk of capacity breakdown is limited . This type of assembly is more particularly indicated at low frequencies of the operating range of the generator. At higher frequencies, it is more convenient to use an oscillating circuit 5 in full distributed constants. The circuit is then made of two coaxial nested one in the other around the same axis. The central conductor, connected to the control grid 9, serves as both an inner conductor for the peripheral coaxial and an outer conductor for the inner coaxial. This conductor has a shorter length than the other two and, in its space, the device represents two capacities. The central and outer conductors are extended to constitute the inductive portion and may be a transformer, and these conductors constitute a coaxial which is terminated by the load. radiator 6, applicator or antenna.In addition, the installation according to the invention comprises means for recovering the heat emitted by the anode 10. These means for recovering the heat emitted by the anode 10 comprise a transport pipe. fluid 3 disposed in the well 2. More specifically, these means are adapted to transmit at least a portion of the heat emitted by the anode 10 to a fluid flowing in the fluid transport conduit 3. In doing so, the means of The recovery of the heat emitted by the anode 10 is also adapted to transfer at least a portion of the heat emitted by the anode 10 to either the formation 1 or to the hydrocarbons removed. the anode with the underground formation or with the hydrocarbons taken can be direct or indirect (that is to say by means of an auxiliary fluid). These different variants are explained below. The fluid transport pipe 3 is preferably of substantially cylindrical geometry. The fluid transport line 3 may be a hydrocarbon transport line taken to the surface or an auxiliary fluid transport line to the bottom of the well. In both cases, fluid pumping means 26 (see Fig. 4) may be provided. They make it possible to circulate the fluid (harvested hydrocarbons or auxiliary fluid) in the fluid transport pipe 3. When the fluid transport pipe 3 is a hydrocarbon transport pipe taken (adapted to convey the hydrocarbons taken from the formation 1 to the surface), well 2 is a heating and extraction well. The hydrocarbon sampling means 21 are then placed in the well 2 and feed the fluid transport pipe 3 in the form of hydrocarbons from the formation 1. in this case, the means for recovering the heat emitted by the anode 10 are adapted to transfer part of the heat emitted by the anode 10 to the collected hydrocarbons flowing in the fluid transport pipe 3. Still according to this mode embodiment, the hydrocarbon sampling means 21 may comprise in particular a set of slots 20 formed on the fluid transport pipe 3 (see Figures 3 and 4), so as to allow the entry of hydrocarbons into the pipe. The slots 20 can be replaced by strainers or holes or any other element known in the field to suit the sampling function. These hydrocarbon sampling means 21 may be provided at the bottom of the well 2, that is to say downstream of the generator 4, and preferably downstream of the radiating charge 6 (this is particularly suitable for an oil reservoir because the hydrocarbons mobilized in the tank then tend to sink deep under the effect of gravity) or on the contrary upstream of the generator 4 (this is particularly suitable for a gas tank because the hydrocarbons mobilized in the tank then have a tendency to go up to the surface). The term upstream refers to the direction towards the surface, and the term downstream refers to the direction towards the bottom of the well. Still according to this embodiment, the above-mentioned fluid pumping means are means for pumping hydrocarbons. They are provided upstream of the generator 4 (that is to say between the generator 4 and the surface) or downstream of the generator 4 (that is to say between the generator 4 and the bottom of the well 2), for example at the end of the radiating charge 6 located towards the bottom of the well 2. These pumping means are adapted to induce the flow of hydrocarbons in the fluid transport pipe 3 from the bottom of the well to the surface. However, it is possible in some cases to dispense with pumping means, the pressure in the underground formation being sufficient to expel the fluids. When, on the other hand, the fluid transport line 3 is an auxiliary fluid transport line, the well 2 may also be a heating and extraction well (in which case an additional hydrocarbon transport line is provided in the well), or may be only a heating well (i.e. the hydrocarbon withdrawal means 21 is then disposed in an additional well which serves as an extraction well, said additional well being provided with a hydrocarbon transport pipe). The above-mentioned fluid pumping means are then means for pumping auxiliary fluid; they are adapted to induce the circulation of the auxiliary fluid in the fluid transport pipe 3 from the surface to the bottom of the well. These pumping means are optional since the gravity can be sufficient to ensure the circulation of the auxiliary fluid. As the auxiliary can be used water, a suitable aqueous solution or other suitable heat transfer fluid. As auxiliary fluid, or in addition to the auxiliary fluid, can be injected in the formation 1 any substance useful for the conversion of oil shale, the mobilization of hydrocarbons and / or upgrading thereof, including a solvent hydrocarbons (liquid or gaseous), a chemical product of any type, a catalyst, a gas (carbon dioxide, methane, flue gas) ... In addition, in this case, the means for recovering the heat emitted by the anode 10 are adapted to transfer a portion of the heat emitted by the anode 10 to the auxiliary fluid circulating in the fluid transport pipe 3. In this case, the installation according to the invention comprises dispersion means of the auxiliary fluid in the formation, arranged at the downstream end of the RBrevets 2780027888--080822-text depot_doc- 22 August 2008 fluid transport line 3, that is to say downstream of the generator 4 and possibly downstream of the radiant charge 6, e.g. example downhole. Thus, the heat emitted by the anode 10 is transmitted from the anode 10 to the auxiliary fluid circulating in the fluid transport pipe 3, and this auxiliary fluid to the formation 1. Whatever the fluid flowing in the pipe of fluid transport 3 (hydrocarbons or auxiliary fluid), the fluid transport pipe 3 is preferably of substantially cylindrical geometry, and passes through the generator 4 and the radiating load 6. Thus, the vacuum tube 7 surrounds the transport pipe fluid 3 and the radiating load 6 (antenna or applicator) also surrounds this pipe. To surround is meant to be around. More specifically, there is at least one position along the axis of the fluid transport pipe 3 to which the fluid transport pipe 3 faces the vacuum pipe 7 in all directions perpendicular to the axis of the pipe. conduct. Preferably, the fluid conveying conduit 3 is disposed along the axis of the vacuum tube 7, as is the case in FIG. 2. In other words, the vacuum tube 7 has an annular shape (shape of hollow cylinder or sheath), the fluid line being disposed within the internal cavity of the vacuum tube 7. But according to another possibility, the vacuum tube 7 does not surround the fluid transport line 3 and / or the radiating load 6 (antenna or applicator) does not surround this conduct either. It is then said that the fluid transport pipe 3 is disposed outside the vacuum tube 7 and / or outside the radiating load 6. According to one particular embodiment, the fluid transport pipe 3 surrounds the pipe 7, and preferably surrounds the radiating load 6. The fluid transport conduit 3 then has an annular shape. To describe in more detail the means for recovering the heat emitted by the anode 10, the wall of the fluid transport pipe 3 may be in direct contact with the surface of the anode 10. Alternatively, an interstice may be provided. between the anode 10 and the fluid transport pipe 3 filled with a liquid having good heat conduction capabilities, for example water which, by vaporizing, considerably increases its heat transfer capacity. This vapor can then provide a combined effect with the high frequency radiation. It is preferred that the anode 10 be closer to the fluid transport conduit 3 than the cathode 8. This simplifies and optimizes the heat transfer from the anode 10 to the fluid contained in the transport pipe. fluid 3. This is the case for example, in cylindrical geometry, with a fluid transport duct 3 located in the axis of the vacuum tube 7 and the radiating charge 6 and with an anode 10 in the central position in the vacuum tube 7 surrounding the fluid transport pipe 3 (see Figure 2). This is also the case when the anode 10 is in the peripheral position in the vacuum tube 7 and the fluid transport conduit 3 surrounds the vacuum tube 7 and the radiating load 6. It is nevertheless possible to also provide conversely, that the cathode 8 is closer to the fluid transport conduit 3 than: the anode 10. The anode 10 may for example be centrally located in the vacuum tube 7 (for example according to the invention). axis of the cylindrical tube) and the fluid transport pipe 3 to be in peripheral position with respect to the vacuum tube 7 (and in particular to surround it). Conversely, the anode 10 may be in the peripheral position in the vacuum tube 7 and the fluid transport conduit 3 may be located in the axis of the vacuum tube 7. R: Patents 27800.27S88--080822-text. It is appropriate in such cases to provide an additional heat transfer device (such as an intermediate coolant circuit) between the anode 10 and the fluid transport line 3. A such additional heat transmission device is more generally suitable in all schemes where the anode 10 and the fluid transport pipe 3 are not in close proximity to each other. For example, an additional heat transmission device is required when the fluid transport pipe 3 is disposed outside the vacuum tube 7, for example parallel to it, without however surrounding it (and this, that the anode 10 is in the central position or not).

When the installation is in operation, the cathode 8 is at high temperature. However, because the surface of the cathode 8 is generally very small, the thermal power dissipated by the cathode 8 is also very low. Nevertheless, it is possible to provide thermal insulation of the cathode 8 if necessary, to protect the cathode 8 from cooling and to protect the external environment (elements of the installation, hydrocarbons removed, underground formation) from excessive local heating.

According to one embodiment, the radiating charge 6 is mobile and capable of sliding in the well 2 (that is to say capable of performing translation movements along the axis of the well). This is particularly appropriate when the radiating load 6 is an antenna. For example, it is possible to provide that the radiating assembly, comprising the generator 4, the oscillating circuit 5 and the radiating load 6, is integral and is slidably mounted in the well 2. In particular, in the case where the anode 10 is central and where a thermal conductive liquid is provided in the gap between the anode 10 and the fluid conveying conduit 3, it is possible to choose a thermal conductive liquid which is also a lubricant, R 13revets 2780027888ù 080822-texte_depot .doo- 22 August 2008 to facilitate the sliding of the radiator assembly relative to the transpert conduit fluid 3. It is also possible to provide sliding guides, for example polytetrafluoroethylene.

Thus, by making slow reciprocating movements to the radiating load 6 (or to the generator set 4 and the radiating load 6), a more uniform and widespread electromagnetic radiation emission is ensured in the formation, and it increases thus the mobilization of oils. These movements make it possible to obtain a thermal profile suitable for recovery. In the context of the installation according to the invention, it may be appropriate to provide protection and safety devices to prevent the rise of electromagnetic radiation on the surface. By way of example, quarter-wave traps can be provided in the well, a grid placed on the ground surface (to prevent the rise of radiation via the subsoil) and decoupling filters in the vacuum tube 7 (to prevent a rise of radiation via the power supply). It may also be appropriate to provide several successive modules of radiating assemblies as described above in the well, including two, three or more than three. Each module comprises at least one generator and one or more radiant charges (applicator or antenna). This also makes it possible to heat a wider area of the formation 1. In addition, the power of each radiating assembly can then be lower, at equal efficiency. Depending on the size of the formation 1, it may be appropriate to provide several wells 2, each being equipped with a radiating assembly as described above. When the well 2 is a heating well but is not an extraction well, it is possible to associate a plurality of additional extraction wells (for example at least two or at least three). The position of the additional well (s) R: extraction patents with respect to each heating well is determined by those skilled in the art to allow optimum recovery of the hydrocarbons, for example above or below the heating shaft, for gas or oil respectively. The additional extraction wells will advantageously comprise a horizontal portion in order to increase the quantity of hydrocarbons extracted, even when the heating well or wells are vertical.

It is also possible to have a servo system. In this case, the generator 4 is regulated according to the bottom-of-well measurement result (pressure, temperature, flow rate, water saturation, oil saturation, gas saturation and / or reflection of the electromagnetic field). Any appropriate underground formation control means is used to manage the process. With reference to FIG. 4 and according to particular embodiments of the invention, the installation according to the invention may also comprise. a casing 23, preferably of composite material (s), transparent with respect to the high-frequency radiation, enveloping the lower part of the installation (generator 4, oscillating circuit 5 and radiating load 6) ); conventional drilling casing 24 (casing) in the oil / gas field, enveloping the upper part of the installation (between the generator 4 and the surface); a connection system 25 between the casing 23 enveloping the lower part of the installation and the casing 24 enveloping the upper part of the installation; a power supply 27 for the pumping means 26; A: Brecets`2780027888--080822-texte_depot.doc- August 22, 2008 - a high frequency transformer 28 (participating in the generator / antenna adaptation) - means for supplying coolant 29 (for the generator 4); a gravel pack (to filter the oil and prevent the production of sand); connectors 31 for the hydrocarbon transport pipe; seal 32 to allow the separation between the oil production zones and the antenna (zone under neutral gas). Examples of Specific Embodiments of the Hydrocarbon Extraction Facility, and Related Extraction Methods According to the preferred embodiment of the invention, which is shown in FIGS. 1 to 3: Well 2 is a extraction and heating wells; the radiating load 6 is an antenna; the fluid transport pipe 3 is a hydrocarbon transport pipe; the vacuum tube 7 and the radiating load 6 have cylindrical; the anode 10 is located towards the vacuum 7 and the cathode 8 the periphery of the vacuum tube 7 the vacuum tube 7 and the essentially

the center of the tube is located towards the; and a radiating load 6 a geometry 35 surround the fluid transport pipe 3, which is located in the axis of the vacuum pipe 7 and the radiating charge 6. According to this preferred embodiment, the emitted electromagnetic radiation heats the formation underground 1, including hydrocarbons and the water it contains, which makes it possible to mobilize the hydrocarbons and to take them up. The heated hydrocarbons are mobilized and recovered towards the end of the well by the hydrocarbon sampling means 21. Pumping means 26 transport the hydrocarbons taken to the surface in the fluid transport line 3. The hydrocarbons taken can be liquid or gaseous. They may pre-exist in the subterranean formation prior to sampling, or may be obtained by. upgrading from heavier hydrocarbons present in the underground formation; conversion from organic matter (particularly coal or oil shale) present in the underground formation. If necessary, upgrading and / or conversion are obtained in situ at least in part by heating the underground formation according to the invention.

The fluid transport pipe 3 is located centrally relative to the radiating assembly. The collected hydrocarbons thus circulate in the direction of the axis of the radiating load (antenna) 6. Virtually no electromagnetic radiation is emitted by the antenna in this direction. Thus, it avoids wasting the electromagnetic energy emitted by heating the hydrocarbons taken, and almost all of the radiation energy is used to heat the formation 1.

On the other hand, the heat dissipated by the anode 10 is evacuated and transferred at least in part to the hydrocarbons taken up in the fluid transport pipe 3. The hydrocarbons taken are therefore used to cool the high frequency generator 4 (this is that is, to cool the anode 10). Thus, the efficiency of the generator is optimized. The heat recovery is used to reduce the paraffin deposition in the well and / or the viscosity of the hydrocarbons and / or the pressure drops in the well. . It can also allow upgrading of the hydrocarbons taken (as defined above) during their transport. The temperature required for this is of the order of 350 to 400 ° C. It is possible to provide a mechanism for regulating this temperature (for example upstream pumping), controlled from the surface. Because the cathode 8 is located peripherally in the vacuum tube 7 and the anode 10 is centrally located in the vacuum tube 7, the life of the cathode is prolcngée. Indeed, the cathode must be heated to a high temperature to produce the flow of electrons in the vacuum tube 7. By limiting the unwanted cooling of the cathode in this mode in steady state (since the flow of hydrocarbons circulates not near the cathode), it avoids having to overheat the cathode. Alternatively, or in a complementary manner, it is possible to provide a thermal insulation vis-à-vis the external environment, around the cathode 8 this thermal insulation may also be an electrical insulation. In a triode type high frequency generator, the anode is typically at a temperature of the order of 400 ° C. The power transferred from the anode to the hydrocarbon pipe is typically between 30 and 60 kW for a triode of 100 to 200 kW. It can be seen that this recovered thermal power is of the order of magnitude of the purely resistive heats published in the bibliography. Still according to this preferred embodiment, a complementary cooling of the generator may be necessary, especially in the dema = gage phase. For this purpose, either a complementary circuit may be used, or water (or other heat transfer fluid) may be circulated in the formation using the fluid transport line 3 in the opposite direction. In this case, the water is preferably vaporized by the heat input R: Patents 27800'27888-080822-text_depot.doc- August 22, 2008 of the anode. Then, when the formation has been sufficiently heated by the electromagnetic radiation, the flow direction is reversed in the fluid transport pipe 3 and the hydrocarbons are started.

The hydrocarbon extraction process corresponding to this preferred embodiment comprises: emitting electromagnetic radiation by means of the radiating assembly described above for heating the subterranean formation; the removal of hydrocarbons and the transport of hydrocarbons in the above-mentioned fluid transport line; and recovering at least a portion of the heat emitted by the anode and transferring it to the withdrawn hydrocarbons in the aforementioned fluid transport conduit. A first alternative embodiment is the same as the preferred embodiment described above, except that: well 2 is a heating well but not necessarily an extraction well; the fluid transport conduit 3 is an auxiliary fluid transport conduit to the bottom of the well; and the installation comprises means for dispersing the auxiliary fluid in the formation 1. According to this first alternative embodiment, the emitted electromagnetic radiation heats the formation 1 directly (including the hydrocarbons and the reservoir water which it contains), which makes it possible to mobilize the hydrocarbons and to collect them in an additional well (extraction well). The heat emitted by the anode 10 is evacuated and transferred at least in part to the auxiliary fluid flowing in the fluid transport line 3. The heated auxiliary fluid is poured into the formation 1 by the dispersion means 15 R. Patents 2780027888--080822-text_depot.doc-August 22, 2008 of the auxiliary fluid. It transmits heat to the formation 1 and drives the hydrocarbons. Upgrading and / or conversion of the hydrocarbons can be carried out in a manner similar to that described above in connection with the preferred mode. The auxiliary fluid can be in particular water, an aqueous solution or a supercritical fluid (for example CO2). The auxiliary fluid is heated and optionally vaporized by the heat energy dissipated by the anode 10. The steam produced is dispersed in the formation 1, it infiltrates into the rock, then, cooling (by giving in particular the hydrocarbon heat of formation), becomes liquid again. In addition, the auxiliary fluid in liquid form dispersed in the formation is capable of capturing the electromagnetic radiation emitted by the radiating assembly. Thus, the auxiliary fluid makes it possible to increase the heating efficiency of the formation 1. According to this first alternative embodiment, both the electromagnetic radiation and the heat emitted by the anode 10 are transmitted to the formation 1. the transmission of the heat emitted by the anode 10 is indirect: it is effected by means of the auxiliary fluid. Thus, the SAGD method is associated with the electromagnetic heating of the formation 1, and thus the heating of the formation is maximized. Compared to the systems proposed in the state of the art in which water is vaporized on the surface and injected into the well, the present invention makes it possible to carry out a vaporization in the well itself, at depth, which increases the efficiency of the system. The generator 4 can operate in class A, AB or C depending on the need for the underground steam formation. This choice has an impact on the efficiency of the generator and therefore on the amount of cooling water that can be used in the form of steam in the underground formation. The hydrocarbon extraction process corresponding to this first alternative method comprises: R-Patents 2780027888-080822-text_depot.doc- August 22, 2008 the emission of electromagnetic radiation by means of the radiating assembly described above to heat the underground formation; the removal of hydrocarbons and the transport of hydrocarbons in a hydrocarbon conveying line (distinct from the susmentio-ined fluid transport pipe); and recovering at least a portion of the heat emitted by the anode and transferring it to an auxiliary fluid flowing in the aforementioned fluid transport conduit, the heated auxiliary fluid being injected into the subterranean formation. A second alternative embodiment is identical to the first alternative embodiment described above, except that: the radiating load 6 is an applicator and not an antenna. According to this second alternative embodiment, as in the previous embodiment, the heat emitted by the anode 10 is discharged and transferred at least in part to the auxiliary fluid flowing in the fluid transport pipe 3; the heated auxiliary fluid is spread in the formation 1 by the means for dispersing the auxiliary fluid and thus transmits heat to the formation 1. But, unlike the first alternative embodiment, the emitted electromagnetic radiation also heats the fluid Thus, according to this embodiment, the hydrocarbons of the formation 1 are heated only indirectly through the auxiliary fluid. The heating method is therefore a SAGD type process, in which the radiating assembly is used to heat in situ (ie downhole) the auxiliary fluid injected into the formation. This maximizes the efficiency of the SAGD process. The method of extracting hydrocarbons corresponding to this second alternative mode comprises: the emission of electromagnetic radiation by means of the radiating assembly described above for heating an auxiliary fluid flowing in the above-mentioned fluid transport line, the heated auxiliary fluid being injected into the formation; recovering at least a portion of the heat emitted by the anode and transferring it to the above-mentioned auxiliary fluid in the aforementioned fluid-carrying conduit; and removing hydrocarbons and transporting hydrocarbons in a hydrocarbon pipeline (distinct from the aforementioned fluid transport line). Numerous variants are possible from the examples described above: in particular, it is possible to implement the first alternative embodiment or the second alternative embodiment without additional well. In this case, the well 2 is a heating and extraction well, and an additional hydrocarbon transport line is provided in the well 2 itself, diffrent from the fluid transport conduit 3 (which serves to transport the auxiliary fluid). Likewise, it is possible to provide a peripheral and non-central fluid transport line 3. This is particularly appropriate when the anode 10 itself is in the peripheral and non-central position in the vacuum tube 7. In this case, the fluid transport pipe may for example be of cylindrical shape and located parallel to the vacuum tube. 7 or may be annular and surround the generator 4. This assembly is particularly suitable for a vertical well where the steam (generated by the cooling of the generator) is injected into the upper part of the tank. R: Patents 2780027888--080822-text depot doc-22 August 2008 Example of realization of a radiating assembly for an installation according to the invention Referring to Figures 3 and 4 and according to a particular embodiment of the invention, certain particular aspects of the radiating assembly are described in greater detail in the following. The generator 4 is powered by a power supply system 17, which provides a unidirectional current, such as a direct current or a rectified current. Alternatively, it is possible to provide a power supply by a three-phase cable and a rectifier system in the well; this has the advantage of reducing Joule losses online. The anode 10 can be connected to ground, as is the case according to FIG. 3. Alternatively, the power supply system can be of two-wire type. Short-circuit elements 11 may be located at the free end of the radiating load (antenna) 6.

These short-circuit elements 11, which may be metal cylinders, are intended to short-circuit the coaxial conductors that are on the one hand the anode 10 and on the other hand the outer wall of the antenna 6 to facilitate the 'adaptation.

Alumina windows 12 may be provided on the antenna 6. Brazed on the dipoles of the antenna, they provide mechanical strength and prevent any entry of pollutant. They thus improve the dielectric strength. The antenna 6 comprises dipole strands 13. Retaining means 22 make it possible to maintain the strands of the dipole 13 in particular during the installation of the antenna 6 in the well 2. From p = _us, the holding means 22 allow to seal this area or the electric field is maximum.

An electromagnetic connection device 14 may be provided between the generator 4 and the antenna 6 to provide mechanical flexibility to the assembly. A: Passive insulators 15 may be provided at the end of the vacuum tube 7 directed towards the antenna 6, in order to provide insulation with respect to the fluid conveying conduit 3 connected to the ground and sealing the tube. A passage insulator 15 is also provided at the other end of the vacuum tube 7, at the level of the electrical power supply system 17. In the vacuum tube 7, adjustable capacitors 18, adjustable at a distance of 10 l are provided. operator via carrier currents. They allow optimization of generator / antenna impedance matching. A voltage regulating element and filter 16 may be provided in the vacuum tube 7. It allows the distribution of a voltage adapted to the control gate 9 and to the cathode 8, in addition to filtering the high frequencies which may The anode 10 being grounded, the cathode 8 must have a negative potential. A sliding electrical contact 19 can provide the electrical connection of the anode 10 and equipotemperature envelope of the vacuum tube 7. Five distances must be adjusted to adjust the impedance matching between the antenna 6 and generator 4. These distances are as follows. D1: distance between the insulators of passage 15 located at the end of the vacuum tube 7 directed towards the antenna 6 and the end of the antenna 6 directed towards the generator 4. D2: length of the dipole strands 13 which can be around a quarter of a wavelength or half a wavelength. D3: distance between the center of the alumina windows 12 and the short-circuit elements 11. D4: distance between the passage insulators 15 located at the end of the vacuum tube 7 directed towards the antenna 6 and the transformer 28. D 35: length of the alumina windows 12. The distance D2 corresponds to a distance calculated to obtain the best radiation of the antenna. The distances D1 and D4 must be calculated in order to obtain an inductive line at the frequencies considered at the output of the generator. The distance D5 is calculated in order to guarantee, on the one hand, the voltage withstand and, on the other hand, an inductive line at the frequencies considered at the output of the generator.

The calculation of these distances is done by those skilled in the art and it must obtain an average value of the equivalent impedance of the oscillator plus the antenna 6 including the medium receiving the radiation (that is to say the formation groundwater). In calculating the average value of the equivalent impedance, the evolution of the electrical properties of the underground formation is included so as to have a good adaptation at mid-exploitation of the deposit. The distances D1 to D5 can be adjusted during the manufacture of the system, before setting up the radiating assembly in the well, but they can also be adjustable in situ during the operation of the installation, by remote adjustment. from the surface.

Be that as it may, the device is self-adaptive thanks to its particular geometry that acts as a closed loop of regulation. A variant of the previous scheme, in which the antenna 6 is an integral part of the oscillating circuit 5, uses a so-called coaxial re-entrant in the field. This coaxial, particularly well suited for use in a well, consists of three coaxial tubes whose median tube, shorter than the other two, is both the inner conductor of the largest coaxial and the outer conductor of the coaxial tube. smaller. The large and the small tube, after the interruption of the middle conductor, constitute an ordinary coaxial connected to the load. The triode is connected to the other end of the device, the grid is connected to the middle tube. The electric field is of opposite direction in the two spaces of the coaxial, which is favorable to a counter-reaction. This type of oscillator is suitable for the case where the charge does not naturally contain an inductive component. A: Patents.27800`27888-080822-text_depot.doc- August 22, 2008

Claims (21)

REVENDICATIONS1. A hydrocarbon extraction plant in an underground formation (1), comprising: at least one well (2); hydrocarbon sampling means (21); at least one high frequency generator (4) in the well (2), comprising a vacuum tube (7) and at least one anode (10) and at least one cathode (8) disposed in the vacuum tube (7). ); at least one radiating load (6) in the well (2), connected to the high frequency generator (4); and means for recovering the heat emitted by the anode (10) comprising at least one fluid transport pipe (3), said means being adapted to transfer at least a portion of the heat emitted by the anode (10) hydrocarbons or underground formation (1. 25 2. Installation according to claim 1, wherein: the fluid transport pipe (3) is a hydrocarbon transport pipe taken to the surface; and the means for recovering the heat emitted by the anode (10) are adapted to transfer at least a portion of the heat emitted by the anode (10) to the collected hydrocarbons circulating in the fluid transport pipe (3). The plant of claim 1, wherein: the fluid transport conduit (3) is an auxiliary fluid transport conduit towards the bottom of the well (2), and the means for recovering the heat emitted by the anode (10) are adapted to transfer at least a portion of the heat emitted by the anode (10) to the auxiliary fluid flowing in the fluid transport pipe (3), the installation also comprising: means for dispersing the auxiliary fluid in the formation (1). 4. Installation according to one of claims 1 to 3, comprising at least one additional well, the sampling means (21) of hydrocarbons being located in the additional well. 5. Installation according to one of claims 1 to 3, wherein the sampling means (21) of hydrocarbons are located in the well (2), and preferably are located downstream of the high frequency generator (4). 6. Installation according to one of claims 1 to 5, wherein: the vacuum tube (7) surrounds the fluid transport pipe (3), and preferably the vacuum tube (7) has a substantially cylindrical geometry and the fluid transport line (3) is arranged along the axis of the vacuum tube (7); and / or - the radiating charge (6) surrounds the fluid transport pipe (3), and preferably the radiating charge (6) has a substantially cylindrical geometry and the transport pipe of R: Brevets'2780027888--080822- text_depotdoc- August 22, 2008fluid (3) is arranged along the axis of the radiant charge (6). 7. Installation according to one of claims 1 to 5, wherein: the fluid transport duct (3) is disposed outside the vacuum tube (7), preferably surrounds the vacuum tube (7); and / or the fluid transport pipe (3) is disposed outside the radiant charge (6), preferably surrounding the radiant charge (6). 8. Installation according to one of claims 1 to 7, wherein the vacuum tube (7) has a substantially cylindrical geometry and the anode (10) is closer than the cathode (8) of the axis of the tube to vacuum (1), the cathode (8) preferably surrounding the anode (10). 9. Installation according to one of claims 1 to 8, further comprising an oscillating circuit (5) located between the high frequency generator (4) and the radiating load (6) or integrated in the vacuum tube (7) and / or the radiant charge (6). 10. Installation according to one of claims 1 to 9, wherein the radiating charge (6) is capable of translation along the shaft (2). 11. Installation according to one of claims 1 to 10, wherein the radiant charge (6) is an antenna or an applicator. 25 30 R: `, Patents 2780027888-080822-text_depot.doc- August 22, 2008 12. Installation according to one of claims 1 to 11, wherein the high frequency generator (4) is selected from a magnetron, a triode, a tetrode or a pentode, and is preferably devoid of frequency matching system. 13. Installation according to one of claims 1 to 12, comprising a plurality of modules along the well (2), each module: omprenant: at least one high frequency generator (4) comprising a vacuum tube (7) as well as at least one anode (10) and at least one cathode (8) disposed in the vacuum tube (7); at least one radiant charge (6); and means for recovering the heat emitted by the anode (10) comprising at least one fluid transport pipe (3), said means being adapted to transfer at least a portion of the heat emitted by the anode (10) hydrocarbons or underground formation (1). 25 A method of extracting hydrocarbons in a subterranean formation, comprising: emitting electromagnetic radiation at the middle of a radiating assembly disposed in a well, said radiating assembly comprising: at least one high frequency generator comprising a tube vacuum and at least one anode and at least one cathode disposed in the vacuum tube; and at least one radiant charge; the heating of the underground formation by means of the emitted electromagnetic radiation; Roots 27800 27888-080822-texte_depot.doc- August 22, 2008the removal of hydrocarbons in the underground formation and the transport of hydrocarbons to the surface; and recovering at least a portion of the heat emitted by the anode and transferring at least a portion of that heat to the subsurface formation oa the harvested hydrocarbons. The method of claim 14, wherein the radiant charge comprises an antenna and the subterranean formation is heated directly by means of emitted electromagnetic radiation. The method of claim 14 or 15, wherein the radiant charge comprises an applicator, and heating the subterranean formation by electromagnetic radiation includes: heating an auxiliary fluid with electromagnetic radiation; the dispersion of the auxiliary fluid in the subterranean formation; and heating the subterranean formation by the dispersed auxiliary fluid. 17. Method according to one of the dreams: adications 14 to 16, wherein the transfer of the heat emitted by the anode to the subterranean formation comprises: the transfer of the heat emitted by the anode to an auxiliary fluid; the dispersion of the auxiliary fluid in the subterranean formation; and heating the subterranean formation by the dispersed auxiliary fluid. A: Patents 27800 27888--080822-Text Deposit.doc- August 22, 2008 25 30 35 18. Method according to one of claims 14 to 16, wherein the heat emitted by the anode is transferred to the hydrocarbons taken during their transport to the surface. 19. The method according to one of claims 14 to 18, wherein the subterranean formation comprises organic materials and wherein the heating of the subterranean formation by means of electromagnetic radiation emitted and / or the transfer of heat emitted by the anode. underground formation induces the conversion of organic matter into hydrocarbons. 20. Method according to one of claims 14 to 19, wherein the heating of the subterranean formation by means of the emitted electromagnetic radiation and / or the transfer of the heat emitted by the anode to the subterranean formation or to the hydrocarbons removed induces the upgrading of hydrocarbons. 21. Method according to one of claims 14 to 20, implemented in an installation according to one of claims 1 to 13. R: Patents 2780027888--080822-text_depot.doc- August 22, 2008