EP0886035A2 - Method of enhanced recovery of hydrocarbons in an underground formation - Google Patents

Abstract

The displacement of oil from a subterranean seam comprises a stage of injection, under pressure, by one or more injection wells successively with plugs of fluid to displace the hydrocarbons in the formation, and a recovery stage, by one or more production wells, of the displaced hydrocarbons. The injection stage comprises the successive injection of plugs of moist fluid which have been saturated with a gas under pressure and gaseous plugs to scavenge the more permeable zones. The production stage comprises the relaxation of the pressure in the formation so as to generate, in-situ, gas bubbles by nucleation in the pores of the less permeable zone, and to free hydrocarbons to the more permeable zones where they are scavenged by the gaseous plugs.

Description

The present invention relates to an enhanced recovery method for petroleum fluids in an underground deposit making it possible to increase the efficiency of scanning and more particularly to improve a recovery technique.

To better move petroleum fluids towards production wells, we can use well-known primary or secondary recovery methods specialists. Recovery is said to be of primary type when using energy in if you. The expansion of the fluids initially under high pressure in the deposit allows to recover part of the oil in place. During this phase, the pressure in the deposit can drop below the bubble point and a gas phase appears, which helps increase the recovery rate.

To avoid an excessive drop in the pressure in the deposit, we have rather use secondary recovery methods. The principle consists in displacing petroleum fluids by an external energy supply to the deposit. Fluids are injected into the deposit through one or more wells injection and the displaced petroleum fluids (hereinafter referred to as "oil") are recovered by production wells.

Water can be used as a displacement fluid but its efficiency is limited. A large part of the oil remains in place, in particular because its viscosity is often much stronger than that of water. The oil also often remains trapped by narrowing of the pores due to the high interfacial tension between them and water. As the deposit is often heterogeneous, the water easily sweeps the areas the most permeable, bypassing the others, resulting in a significant loss of recovery.

It is also known to inject gas under pressure which penetrates into the pores of rocks and displaces a significant amount of the oil in place. Even if water has first injected into the deposit, as often happens, the gas has the property well known to displace a sizeable additional amount of oil.

The notable drawback of this gas recovery technique is that it is much less viscous than the oil it has to move and also than the water possibly in place. Because of its great mobility, the gas crosses the deposit in using only a few of the most permeable channels reaching the well (s) production without having displaced a large amount of oil.

If the deposit is not homogeneous, but has layers or cores of different permeabilities, this effect is further accentuated and the gas bypassing the Least permeable places reach production wells even faster. When the gas thus pierces early without having the expected displacement effect, it loses all efficiency. Continuing the injection no longer has any practical effect.

It is also known to combine the two techniques according to a method called WAG. We successively inject water and gas, and repeat this sequence by alternating the water caps and the gas caps and this too long as oil is produced under good economic conditions. This combined injection method gives better results because the gas of each plug, more efficient than water at pore level, sees its mobility relatively reduced by the presence of the water plug which precedes it. But the reduced volume of plugs in front of the path they must travel between the injection wells and production, and the heterogeneity of the deposit make the scanning efficiency macroscopic does not last long. Surfactants can be added to water to lower the water-oil interfacial tension, and improve the efficiency of these combined injections. The foam that forms in the presence of gas has the effect of reduce gas mobility and digitations. Such a method with alternating plugs is described for example by US Patent No. 5,465,790.

By patent FR 2 735 524 of the applicant, we know a method for to move petroleum fluids out of an underground deposit by means of injections successive, by one or more injection wells, of plugs of a wetting fluid such only water, and gas caps, and recovery, by one or more wells of production, petroleum fluids displaced by the wetting fluid and the injected gas. This method essentially consists in adding in at least one cap of the wetting liquid injected, a quantity of substances capable of making the spread coefficient. Alcohol is used in the proportion of 1 to 5% by weight for example. It may for example be a low-weight alcohol molecular of the class of isobutyl or isoamyl alcohol. We can also use light polar compounds such as amines, fluorinated products or acids light.

The method according to the present invention makes it possible to move fluids tankers retained in the pores of a porous underground deposit. It has a pressure injection step by one or more injection wells successively, caps of fluids intended to move the hydrocarbons in the rock-reservoirs, and a stage of recovery, by one or more production wells, of displaced hydrocarbons.

It is characterized in that the injection step includes the successive injection plugs of the wetting liquid which have been saturated with a gas under soluble pressure in the said wetting liquid and gas caps intended to sweep the areas more permeable, and the production stage involves the release of the prevailing pressure in the deposit, so as to generate gas bubbles in situ by nucleation in the pores of less permeable areas (part of the matrix with the most pores small) and drive the oil out to the more permeable areas where they are moved by gas caps.

On expansion, part of the dissolved gas is released in the form of bubbles preferably on the irregular surface elements and therefore on the walls of the pores.

The nucleation effect is more marked where the density of pore walls by volume unit is the largest i.e. in areas of lower permeability with smaller pores where the oil is the most difficult to remove. The very efficient scanning caused by this nucleation in the least accessible from the deposit, greatly improves the recovery rate oil.

There is therefore a two-stage scanning operation. Firstly, by releasing the pressure of the gas dissolved in the water plugs and nucleation, the oil is expelled from the least permeable pores towards the more permeable areas, and in a later time, the gas from the following gas caps is used, the function is precisely to scan the most permeable areas, to move this oil initially recovered to the producing well.

The wetting fluid is for example water, at least one plug of water injected being saturated with carbon dioxide under pressure for example or hydrogen sulfide.

According to an embodiment, at least one of the liquid stoppers wetting agent injected during the injection step may include water with a substance capable of making the spreading coefficient of the drops negative hydrocarbons and for example alcohol. We can thus alternate the plugs of wetting liquid, some saturated with pressurized gas, others with added said substance, others without any additives.

According to another embodiment, at least one of the plugs wetting liquid injected during the injection step includes water added foaming agents or surfactants, so that the release of pressure in the deposit generates the in situ formation of mosses which greatly simplifies the implementation of this type of scanning.

Comparative laboratory tests on a physical rock model heterogeneous oil impregnated, have shown that the recovery rate obtained by application of the method according to the invention could reach almost 20%, while a conventional WAG type process, at best only leads to a recovery rate of 8 to 9%.

Other characteristics and advantages of the method according to the invention, will appear on reading the experimental results below.

We used to remain the validity of the process the physical model which was carried out to model a heterogeneous medium and which is described in the request for Applicant's patent FR 2,748,471. It includes an inhomogeneous block obtained in juxtaposing in a container for example at least two volumes of materials of porosities and different melting temperatures, and placing the container in a oven whose temperature is programmed to gradually rise to a sufficient temperature for softening the porous material of lower melting temperature during a first time interval, stabilize there during a second defined time interval and decrease more slowly to temperature ambient, during a third time interval. The porous material that has softened is a means of bonding materials preventing formation for example any air gap which would constitute a preferential passage for fluids, avoiding the creation of an interzone forming a capillary barrier.

To constitute such a block, one can use a juxtaposition of a material natural porous such as sandstone in particular with a permeability of around 70mD for example, and a composite material such as powdered glass for example.

The physical model formed is in the form of a bar of length L = 21.2 cm and section S = 19.6 cm ² , the pore volume of which is 110 cm ³ . The bar is provided at its two opposite ends with two end pieces which have conventionally been connected to water and oil injection and drainage circuits.

The bar was prepared by the following operations to successively bring it into a state of saturation with irreducible water Swi and residual saturation with oil Sor. Getting Swi VOLUME OF OIL INJECTED RECOVERED WATER VOLUME INJECTION PRESSURE 100 cm3 / h 75 cm3 22 kPa 200 cm3 / h 82 cm3 28 kPa 300 cm3 / h 85 cm3 35 kPa 400 cm3 / h 88 cm3 40 kPa Oil volume in place = 88 cm3 ⇒ Swi = (110 - 88) / 110 = 20% Setting in Sor VOLUME OF WATER INJECTED RECOVERED OIL VOLUME INJECTION PRESSURE 200 cm3 / h 64 cm3 24 kPa 400 cm3 / h 65 cm3 54 kPa dead volume Vm = 2 cm3 ⇒ Sor = (88-67) / 110 = 21/110 = 19%

A conventional method called WAG was carried out with alternating injection in the model of water and gas plugs of 10 cm 3 at the injection pressure and with the flow rates indicated, the oil recovery results being recorded in the table below:

Results:% of oil recovery in place 1.8 / 21 * 100 = 8.5%

The method according to the invention was then implemented in the manner next:

Preparation of water saturated with gas at a pressure P sat = 150 kPa. Injection of this water at low flow rate into the model: 1 Vp in around 6 hours - with P _inlet = 150 kPa, P outlet = 135 kPa - Sudden relaxation at atmospheric pressure, nucleation inside the porous medium for 16 hours. Sending a cap of water at 100 cm3 / h recovery of 2 cm3 of additional oil or 2/21 or, in percentage, 9.5% of the Sor or 10.5% of the gain after ternary recovery, which represents a considerable improvement compared to what can bring a traditional method.

A new injection of a cap of water saturated with carbon dioxide followed by a water cap, brought the oil recovery in place (Sor) to 12.5%, an increase of 3%.

According to another embodiment, water plugs are added injected with foaming agents or surfactants. The pressure drop caused after injection, has the effect of foaming or emulsifying these additives, which allows to greatly simplify the problems generally posed by the injection of these additives.

According to another embodiment, it is possible to combine the effects specific to the method according to the invention with those described in the aforementioned patent FR 2 735 524, that is to say the formation of menisci resulting from the addition of substances such as alcohol which changes the spreading coefficient.

In the previous examples, we chose carbon dioxide to saturate at least some of the water plugs, this because of the low cost of this gas. Onne would not go beyond the scope of the method using other gases presenting more marked than carbon dioxide, the particularity of being soluble in wetting liquid such as for example hydrogen sulphide.

Claims (6)

Method for displacing hydrocarbons retained in the pores of reservoir rocks an underground deposit comprising a pressure injection stage by one or more injection wells successively, of fluid caps intended for move the oil in the reservoir rocks, and a recovery stage, by one or more production wells, displaced hydrocarbons, characterized in that the injection step involves the successive injection of caps of the liquid wetting agent which has been saturated with a pressurized gas soluble in said liquid wetting and gas caps intended to sweep more permeable areas, and the production stage involves the release of the pressure prevailing in the deposit, so as to generate gas bubbles in situ by nucleation in the pores less permeable areas and expel the hydrocarbons towards the more permeable where they are swept away by gas caps. Method according to claim 1, characterized in that the wetting fluid is water, at least one cap of injected water being saturated with dioxide of carbon under pressure. Method according to claim 1, characterized in that the wetting fluid is water, at least one plug of injected water being saturated with hydrogen sulfide. Method according to one of the preceding claims, characterized in that at least one of the plugs of wetting liquid injected during the injection step contains water containing a substance capable of making the coefficient negative spreading drops of hydrocarbons, for example alcohol. Method according to the preceding claim, characterized in that one at fewer plugs of wetting liquid injected during the injection step have water without additives. Method according to one of the preceding claims, characterized in that at least one of the plugs of wetting liquid injected during the injection step contains water with foaming agents or surfactants, so that the release of pressure in the deposit results in the formation of foam in situ or emulsions.