FR2918102A1 - METHOD FOR RECOVERING OIL OR BITUMEN BY INJECTING A RECOVERY FLUID AND A DIVERSION AGENT - Google Patents

Abstract

The present invention relates to a method for the recovery of heavy oil or bitumen contained in a geological reservoir (1) comprising: a) a step of injection into the reservoir of an oil extraction fluid, b ) a step of producing the heavy oil or bitumen extracted, etc.) a step of injecting a diversion agent to limit the circulation of said extraction fluid in the part of the tank where the heavy oil or the bitumen has been extracted.

Description

The present invention relates to the field of heavy crude production

  requiring the injection of a recovery fluid, in particular a hot fluid for fluidifying the crude to make it mobile. Different methods are used for the recovery of heavy oil or bitumen in tanks located a few tens or hundreds of meters deep. In situ recovery techniques for heavy oil or bitumen are applied to indigenous resources that can not be mined by mining techniques because of the thickness of the land above them. It is recognized that in situ mining methods disrupt considerably less on the surface and therefore require fewer activities than mining techniques. In situ recovery methods can recover between 25 and 75% of the volume of oil or bitumen initially in place. In general, in situ recovery processes are designed to reduce the viscosity of heavy oil or bitumen to allow them to flow better to the production well and then to the surface.

  Known methods for in situ recovery of heavy oil or bitumen use one of the following means: temperature, pressure and / or a solvent to reduce their viscosity and improve their flowability into the reservoir.

  One of these in situ recovery methods is known as SAGD (Steam Assisted Gravity Drainage) described in US Pat. No. 4,344,485. This is a gravity-assisted gravity drainage process employing two parallel horizontal wells drilled into the reservoir and located one above the other. In this process, the wells are drilled vertically from the surface and then horizontally into the reservoir at two different depths. Ideally, the producing well is located at the base of the tank and the injector a few meters above the producer. The latter is used as a water vapor injection well generated on the surface. The vapor enters the tank through the horizontal portion of this well and forms a vapor chamber which increases with time towards the roof of the tank, thereby increasing the temperature in the tank. By heat transfer to the surrounding environment, the steam reduces the viscosity of the heavy oil or bitumen present in the tank. It is along the wall of the chamber that the heating of heavy oil or bitumen takes place mainly. At this point, the steam condenses in hot water which flows under the action of gravity at the same time as the fluidized oil or bitumen to the lower horizontal well located at the base of the tank. These fluids, condensed vapor and warmed oil, are then pumped to the surface where they are separated. The hot oil produced is usually transported by pipeline to a refinery or "upgrader". The theoretical concepts and implementation required to conduct a SAGD field operation have been published and have been discussed extensively in the petroleum literature. These include: Butler (Thermal recovery of oil and bitumen, Grav-Drain Inc., Calgary, 1997) Komery et al. (Paper 1998.214, 7h UNITAR International Conference, Beijing, 1998), Butler et al. (J. Can Pet., Tech., 39 (1), 18, 2000). A major component of the capital and operating costs of an SAGD industrial operation are surface facilities for: a) generating steam, b) separating hydrocarbons from condensed vapor, and c) treating and recycling water in the generators. Current generators require large amounts of water, which are heated in boilers using natural gas or some of the oil produced. The amounts of water vapor used in SAGD operations are expressed in m3 of equivalent liquid hot water. The oil produced is liquid and its quantity is expressed in m3. The ratio of the amount of steam injected per quantity of oil produced is called the SOR of the English Steam-Oil Ratio. SORs of 2 and more generally between 3 and 5 are anticipated in SAGD's industrial projects. SAGD is a process that therefore requires a huge volume of steam to maintain the steam chamber while the volume drained by the steam is quickly desaturated from the hydrocarbons it contained before being filled with steam.

  According to a variant of the SAGD method called Steam and Gas Push (SAGP) described in the publication (Butler, RM, "Steam and Gas Push (SAGP)", CIM 97-137, 48th Annual Meeting of CIM, Calgary, June 1997), a non-condensable gas is injected with the steam to provide a thermal insulation layer at the roof of the steam chamber and thus limit heat losses to the layers above the tank. Although a better thermal efficiency can result from this co-injection, the use of a non-condensable gas adds a cost and complexity to the process without significantly reducing the amount of steam injected.

  These previous methods for the recovery of heavy oil or bitumen in situ are not sufficiently effective both in terms of recovery rate and extraction costs not to mention their negative impact on the environment. The present invention proposes in particular a method capable of increasing the quantity of oil produced and / or extracting it more economically than what is done according to the prior art.

  The present invention provides a process recovering more heavy oil or bitumen and requiring less steam, on the one hand to reduce the amount of water and on the other hand the amount of energy used to generate steam. Reducing the amount of steam has a direct and strong impact on the economy of the process, since there will be less water to recycle in the effluents produced. Not to mention the reduction in the amount of CO2 generated during the production of steam, CO2 that is currently released to the atmosphere.

  Thus, the present invention relates to a method for the recovery of heavy oil or bitumen contained in a geological reservoir comprising: a) a step of injection into the reservoir of an oil extraction fluid, b) a step of producing the heavy oil or bitumen extracted, and c) a step of injecting a diversion agent to limit the circulation of said extraction fluid in the part of the tank where the heavy oil or the bitumen has been extracted. According to the method, step c) can be carried out at least in part while step a) continues.

  Step c) can be performed so that the diversion agent replaces within the tank at least partially the heavy oil or bitumen produced. The extraction fluid may comprise at least one of the following compounds: water, steam, hydrocarbon vapor or mixtures thereof.

  The diversion agent may comprise at least one of the following compounds: water, foam, viscosity additive, surfactant, polymer, or mixtures thereof. The foam may consist of liquid and gas stabilized by conventional surfactants, according to known techniques in petroleum production. Preferably, an aqueous foam is used. The viscosity of the diversion fluid is adjusted according to the rules of the art, as well as its density. Those skilled in the art thus control the placement and stability of the diversion fluid with respect to the injection of the extraction fluid. The extraction fluid and the diversion agent can be introduced at distinct locations in the reservoir. The extraction fluid and the diversion agent may be provided by at least one drain, wherein the heavy oil or bitumen produced is recovered by at least one drain and wherein the portion of these drains in the reservoir are distinct from each other. At least one of these portions may be horizontal. At least one portion of each type of drain may be horizontal, and in which these portions may be substantially in the same vertical plane. The extraction fluid can be injected into the reservoir at a level below that at which the diversion agent is injected into the reservoir. The invention also relates to a system for implementing the method according to the invention. The invention also relates to the hydrocarbon having a component resulting at least in part from the refining of an oil produced according to the method.

  By diversion agent is meant any fluid capable of preventing the circulation of steam in the area that this diversion agent will occupy. It may be, for example, recycled hot water from production, foam or any other fluid having the property of preventing the circulation of steam in the area it will occupy. The composition of the diversion fluid will be optimized so that its placement in the tank is compatible with the steam chamber. It should be noted that the diversion agent will not be able to be injected into the tank until the steam chamber has reached the roof of the tank, or at least the side of the well into which this agent will be injected. Indeed, the resistance to the flow of heavy oil or bitumen in place will not allow this injection without the risk of fracturing the tank. Which is not desired. On the contrary, when the steam chamber has reached the roof of the tank, the injection of the diversion agent will be without difficulty since its injection will take place in a part of the tank already swept by the steam whose resistance to flow is much less than that of heavy oil or bitumen.

  Of course, the diversion agent can be of several kinds: one can successively inject several types of diversion agent. The main purpose of injecting the diversion agent into the upper part of the steam chamber is to reduce the volume of this vapor chamber and to prevent any new quantity of injected vapor from going into an area of the reservoir already desaturated the heavy oil or bitumen it contained, thus avoiding heating and keeping unnecessarily hot all this part of the tank. The amount of steam required to heat the heavy oil or bitumen, and allow it to flow by gravity to the (or) production wells will be greatly reduced when the diversion agent is going to be injected. Indeed, upon injection of this agent, it will repel the steam towards the wall of the steam chamber. Another advantage of the injection of the diversion agent will be to limit heat losses to the layers above the tank. The main advantage of injecting an inexpensive diversion agent such as those mentioned above, however, is a substantial reduction in the amount of steam required to recover the same amount of heavy oil or bitumen. This benefit translates into reduced investment costs and operating costs by reducing the amount of water needed to generate steam, reducing the energy required to turn water into steam, and reducing greenhouse gas emissions from burning the fuel used to turn water into steam. If the produced water is used as a diversion agent, either alone or as a component of this agent, the volume of water produced to be treated for recycling at the steam generator will also be less.

  The present invention will be better understood and its advantages will appear more clearly on reading the following description of exemplary embodiments of the invention illustrated by the appended figures, in which: FIG. 1 shows the formation of the chamber steam in a configuration with three horizontal wells according to the invention; Figure 2 shows the expansion of the steam chamber according to the previous configuration; FIG. 3 shows the injection of the diversion agent; Figure 4 shows the expansion of the steam chamber with regard to the distractor; Figure 5 shows an alternative configuration; Figure 6 shows another configuration variant; Figure 7 shows a steam chamber according to a procedure of the invention.

  Several configurations of drainage architecture can be envisaged for the implementation of the recovery method according to the invention. According to the invention: • the injection of the steam for the formation of the steam chamber is carried out by at least one injection well, • the injection of the diversion agent by at least one other injection drain • and the production of heated oil by at least one production well.

  In the basic configuration according to Figures 1 to 4, the three wells are parallel and located substantially on top of each other: the production well at the base of the tank, the steam injection well a few meters above production well as in the SAGD process described above, and the injection well of the diversion agent in the upper part of the tank. In Figure 1, there is shown a schematic view in vertical and lateral sections showing the implementation of the invention in a preferred configuration. A tank 1 is limited by its roof 3 and its wall 2. A production well 10 is drilled from the surface 5 and passes through the dead lands 4 before entering the tank 1. This well ends with a substantially horizontal portion located towards the base of the tank. A steam injection well 11 is drilled in the same way. It also ends in the tank 1 by a horizontal part. The steam is injected into the well 11 and forms a vapor chamber 21 in the reservoir. The heavy oil or bitumen made less viscous by heat transfer flows together with the condensed vapor to the production 10 along the wall 20 of the steam chamber. A well 12 is drilled like the wells 10 and 11 from the surface 5. It ends with a horizontal portion located in the upper part of the tank 1. The three wells 10, 11 and 12 are parallel and located above each other. other. They have substantially the same horizontal length. As shown in FIG. 1, the steam chamber 20 is in formation and has not yet reached the side of the well 12 or the roof 3 of the tank. In general, nothing is injected into the well 12 until the vapor chamber 21 has reached the roof of the tank 3, or even the side of the horizontal part of this well 12 (as long as it is not the case, the viscosity of the heavy oil or bitumen may be too high to allow the injection of a fluid into the well 12 without fracturing the tank). The arrows above the well 11 indicate the rise of steam in the tank 1. The arrows along the wall 20 of the steam chamber 21 indicate the direction of flow of the oil displaced from the steam chamber 21 towards the wall 20 of this chamber as well as the flow of the condensed vapor. The oil and water flow to the production well 10. Figure 2 shows a schematic view of the configuration of Figure 1, when the steam chamber 21 has reached the roof 3 of the tank. From this moment, all the part of the tank located in this chamber is desaturated with heavy oil and bitumen. The injection of the diversion agent to reduce the area invaded by the steam can begin in the well 12. Figure 3 shows the beginning of the injection of the diversion agent for the purpose of repelling the vapor towards the wall 20 of the steam chamber 21 and thus minimize the tank volume of the zone to be heated. In fact, only the part close to the wall in the zone not yet drained requires steam. The zone 30 invaded by the diversion agent increases in volume by moving downwards taking into account the impermeability of the roof of the tank 1. FIG. 4 shows the evolution of the steam chamber after several months of injection of the diversion agent, a period of time since the start of injection during which the injection of steam into the well 11 has been continued. It is observed that the steam chamber 21 grows laterally. The zone 30 invaded by the diversion agent is also becoming larger, leaving a small area of vapor in contact with the tank not yet swept.

  Other configurations of injection wells and drainage are possible.

  The steam injection well may be replaced by one or more vertical or multi-branch wells and the diversion agent injection well by one or more vertical or multi-branched vertical wells (FIG. 5). The injections of the vapor and the diversion agent can be carried out in different wells as in the basic configuration but also from the same wells if they are vertical. In this case, the injections are carried out thanks to a double completion of the wells allowing the injection of steam into the lower part of the wells and the injection of the diversion agent into an upper part of the wells. In the configuration where the wells are horizontal, the injections of the steam and the diversion agent can be made from the same well. Only two wells are then needed as in the conventional SAGD, one for injection, the other for production. In this diagram, the injection of steam takes place in the horizontal part of the injection well while the injection of the diversion agent takes place in the part of the well located near the roof of the tank inside the -this. Another well configuration close to the previous one is to consider an injection well having two horizontal branches drilled from the same vertical part. The upper branch is used to inject the diversion agent, the lower branch to inject the steam (Figure 6). The injection of the diversion agent can also be carried out while the steam injection is reduced for a certain time so that a large part of the volume occupied by the steam is almost completely replaced by this agent (FIG. ). This replacement of the steam by the diverting agent will cause a migration of the already injected vapor to the wall or front of the steam chamber thus limiting the need to inject as much steam for a certain time. When the replacement has been made, the steam injection rates and the diverting agent will be adjusted so that the effective vapor volume between the area occupied by the distractor and the area not yet swept by the steam is minimum.

Claims (11)

  A method for the recovery of heavy oil or bitumen contained in a geological reservoir comprising: a) a step of injecting an oil extraction fluid into the reservoir, b) a step of producing the oil. heavy oil or bitumen extracted, and c) a step of injecting a diversion agent to limit the circulation of said extraction fluid in the part of the tank from which the heavy oil or bitumen has been extracted.   2. The method of claim 1 wherein step c) is performed at least in part while step a) continues.   3. Method according to one of the preceding claims wherein step c) is performed so that the diversion agent replaces within the tank at least in part the heavy oil or bitumen product.   4. Method according to one of the preceding claims wherein the extraction fluid comprises at least one of the following compounds: water, steam, hydrocarbon vapor or mixtures thereof.   5. Method according to one of the preceding claims wherein the diversion agent comprises at least one of the following compounds: water, foam, viscosity additive, surfactant, polymer. 20   6. Method according to one of the preceding claims wherein the extraction fluid and the diversion agent are introduced at different locations in the tank.   7. Method according to one of the preceding claims, wherein the extraction fluid and the diversion agent are provided by at least one drain, wherein the heavy oil or bitumen produced is recovered by at least one drain and wherein the portion of these drains in the tank are distinct from each other.   The method of claim 7, wherein at least one of these portions is horizontal.   9. The method of claim 8, wherein at least a portion of each type of drain is horizontal, and wherein these portions are substantially in the same vertical plane.   10. Method according to one of claims 7 to 9, wherein the extraction fluid is injected into the reservoir at a level below that at which the diversion agent is injected into the reservoir.   11. Hydrocarbon comprising a component resulting at least in part from the refining of an oil produced according to one of the methods of claims 1 to 10.