DE1286475B - Flooding process for secondary recovery of oil from a storage facility with at least one injection well and one production well - Google Patents

Description

The invention relates to a flooding process for the secondary extraction of oil from a reservoir provided with at least one injection well and a production well using a light hydrocarbon in combination with carbon dioxide as the displacement medium, which is introduced into the reservoir through the injection well before a propellant medium.

When a well leading into a subterranean reservoir is completed, the oil present therein is normally removed through the wellbore by primary extraction methods. In this way of working, the natural reservoir energy is used in the form of water or gas, which is available under sufficient pressure to drive the oil from the reservoir through the borehole to the surface of the earth. However, this natural reservoir energy is mostly depleted long before all of the oil present in the reservoir has been removed therefrom. Further oil extraction is therefore achieved by secondary extraction processes, with the energy being supplied from the outside before or after the natural energy of the reservoir is exhausted.

m In the displacement method, are introduced in order to displace the oil from the pores of the deposit and to propel to a production well using an immiscible phase in the reservoir through an insertion hole, one or more media that are miscible with the reservoir oil. In this case, the miscible medium is introduced with a sufficiently high pressure into the insertion hole, so that it can be driven through the reservoir, collects therein and the reservoir oil floats to the Produktionsbohrun 'g.

In one embodiment of the mode of operation with a mixable flooding agent becomes a bank or layer of liquefied hydrocarbons within the Deposit formed by placing a condensable through the introductory borehole Carbon-C hydrogen, e.g. B. liquefied petroleum gas, propane or butane, at one introduces such a pressure that the hydrocarbon is converted into the liquid phase becomes or remains in the liquid phase. It can also be used for this purpose normally liquid hydrocarbon, e.g. B. light naphtha are introduced. The liquefied one Hydrocarbon, which is miscible with the reservoir oil, is used to obtain the Oil drifted through the formation. Other miscible materials, for example dilute hydrocarbon resulting from the condensables given above Hydrocarbons in dilution with natural gas can also be used, -elanaen, the diluted flood agent being liquid or diluted to such an extent may be in the form of an enriched gas associated with the reservoir oil is miscible.

In this mode of operation, a propellant gas is normally introduced into the formation behind the gaseous or liquid miscible hydrocarbon in order to propel it through the reservoir formation to the production well. In general, the procedure is carried out with a miscible flooding agent at a pressure of about 70 atmospheres or more.

The above operation sometimes has serious difficulties in maintaining a steady flooding front as the fluid moves through the formation to the production well. The evenness with which the flooding structure can be maintained, i.e. that is, the spatial configuration assumed by the mass or body of the displacing fluid is generally referred to as the expulsion efficiency of the flood. Generally, when the flood breaks out of a structure with a uniform frontal boundary, some or all of the flood is advanced prematurely to the production well, leaving substantial amounts of the reservoir oil behind. This unevenness of the flooding limit is often referred to as "finger formation". The efficacy of a flood formation is considered with regard to the horizontal as well as the vertical formation. The spatial shape of the flooding structure in a horizontal plane that extends through the formation at right angles to the introduction and production wells is commonly referred to as the face of the formation. The formation of the flood formation in a vertical plane, which extends through the formation between the introduction and production holes, is referred to as vertical exit. Horizontal and vertical blowout efficiencies are affected by several factors including the mobility ratio of the displacing to displaced media, which ratio is a measure of the relative ease with which the media moves through the formation. When a medium that is not very mobile is displaced by a very flexible medium, a particularly bad and ineffective sprout formation develops, in which finger formation is quickly developed, whereby the very mobile medium advances in finger-shaped expansions in and in front of the medium, For example, when a low viscosity gas is used to displace a viscous oil, the gas forms a number of finial patterns which rapidly advance through the body of oil and eventually reach the production well, leaving behind a substantial portion of the oil The mobility of the reservoir oil and the media used to displace the oil is directly influenced by the viscosity of these materials. An improvement in the structure can therefore be achieved if the viscosity of the displaced and the displacing media can be changed to an extent that that differences of any size along any be reduced to a minimum in a particular line or zone in a flood.

A number of procedures are known in which carbon dioxide is dissolved in a solvent and the solution of carbon dioxide gas and the solvent is injected into the formation. C 4D A propellant is then introduced into the formation to move the solution of the solvent and carbon dioxide through the formation. As a solvent for the carbon dioxide, for. B. crude oil, light hydrocarbons, liquefied petroleum gas or an oxygen-containing solvent is used.

In these known procedures, two adjacent liquid zones are created between the oil and the propellant medium, namely (1) a solution containing the solvent used, carbon dioxide and oil , and (2) a solution of carbon dioxide and the solvent. Since there are only two adjacent liquid zones between the oil and the propellant medium, no suitable gradation or no suitable gradual transition of the viscosity between the oil and the propellant medium is achieved, and accordingly these known procedures with regard to the desired reduction in finger formation and improvement of the Efficacy of expulsion or flushing out not yet satisfactory.

Dissolving carbon dioxide in a solvent appears to reduce its viscosity. Accordingly, in these known methods of operation there is a large jump in viscosity between the oil in the deposit and the first liquid zone, this jump in viscosity being even greater than when the solvent is used alone.

The object of the invention is therefore to create an improved method for the secondary extraction of oil from a reservoir provided with at least one injection well and a production well using a light hydrocarbon in combination with carbon dioxide as the displacement medium, which is introduced into the reservoir through the injection well before a propellant medium, improved efficacy of expulsion being achieved.

The flooding method according to the invention is characterized in that one after the other separated carbon dioxide, a liquefied carbon-C hydrogen and injects the propellant into the reservoir through the injection bore.

According to a particular embodiment of the invention, the carbon dioxide is introduced into the introduction borehole in the liquefied state, since less energy is then required than when it is used in the gaseous state. When liquid carbon dioxide is introduced through the introduction borehole, it naturally experiences an increase in temperature, with it being converted into the gaseous state either in the borehole or in the formation in the immediate vicinity of the borehole. The temperature of most deposits is above the critical temperature of carbon dioxide, i. H. 40.01 C, and thus the liquid carbon dioxide can in most cases rapidly exceed the gaseous state when it is introduced.

Preferably the carbon dioxide is introduced at an injection pressure which results in a molar volume of carbon dioxide in the range from 50 to 625 dm3 / kmol at reservoir temperature.

The carbon dioxide is driven through the formation into contact with the oil to be displaced, in which it is highly soluble and generally much more soluble than in water. Some of the carbon dioxide therefore goes into solution in the reservoir oil, thereby causing the oil to decrease in viscosity. In addition to the decrease in viscosity, there is preferential extraction of light intermediate hydrocarbons of 2 to 5 carbon atoms from the oil by the carbon dioxide, thereby forming an intermediate-rich carbon dioxide bank near the line of contact between the reservoir oil and the carbon dioxide. Z, depending on the composition of the lag, erstättenmedien, in particular on the amount of Intermediärstoffen and under suitable conditions of temperature and pressure, the carbon dioxide interinediärreiche bank may be completely miscible with the reservoir oil. In addition, there is a swelling of the reservoir oil due to the dissolution of carbon dioxide in the oil.

The carbon dioxide is introduced in sufficient quantity to create a transition zone from a flowing medium having a gradually changing viscosity from that of the oil to that of the displacing liquid hydrocarbon. In the part closest to the reservoir oil, the transition zone consists of a mixture of carbon dioxide and reservoir oil. This part is followed by flowing carbon dioxide in phase equilibrium with any non-flowing oil in which carbon dioxide is dissolved, then a mixture of carbon dioxide and liquid hydrocarbon adjacent to the bulk of pure liquid hydrocarbon. The flow range of the primary carbon dioxide phase need not be more than a trace since the primary purpose is to create a smooth viscosity transition from the reservoir oil to the liquid hydrocarbon displacer. The required menae of carbon dioxide, which is influenced by the storage facility conditions with regard to temperature and pressure and the properties of the storage facility media, can be determined according to known procedures by laboratory flooding under simulated storage facility conditions.

In the second stage of the process according to the invention, according to the introduction of carbon dioxide into the liquefied hydrocarbon material Formation introduced through the introduction wellbore. The term used here "Liquefied hydrocarbons" includes such condensable hydrocarbons, z. B. Liquefied petroleum gas, propane, butane and light naphthas, which are under normal Conditions relating to temperature and pressure exist as a liquid. The condensable Hydrocarbons that are introduced at a pressure at which they are liquefied Remain in contact with the carbon dioxide with which they are a have high mutual solubility, Cletriebe. A solution is formed of carbon dioxide and liquefied hydrocarbons, as described above creates a transition zone from the carbon dioxide to the liquid hydrocarbons. Through the gradual mixing of the reservoir oil through to the liquefied one Hydrocarbon post is made when using liquid hydrocarbons finger formation normally observed as a displacement material to a minimum returned, because in this way pronounced viscosity differences between the Reservoir oil and the liquefied hydrocarbon that cause finger formation, be avoided.

As a result of the improvement in the efficacy of expulsion of the liquefied Hydrocarbon produced by the carbon dioxide injected in front of the hydrocarbon is effected, along with the increase in volume or swelling of the reservoir oil the carbon dioxide makes it an effective one displacement of the reservoir oil required amount of liquefied hydrocarbons lowered below normal requirements.

After the liquefied hydrocarbons have been introduced, a propellant medium is passed through the introduction well into the formation to displace the carbon dioxide and liquefied hydrocarbons and reservoir oil through the formation to a production well through which these media are driven to the surface. The propellant medium used is preferably a dry hydrocarbon gas, eg separator gas, which consists predominantly of methane with small amounts of ethane and trace amounts of higher-boiling hydrocarbons, although a propellant medium consisting of exhaust gas or air can also be used. In some cases it may be useful to treat the introduced liquefied hydrocarbons with an amphipathic liquid, ie a liquid having mutual solubility with water and a hydrocarbon medium, e.g. B. alcohol with 3 or 4 carbon atoms, and aldehyde or ketone, followed by water to drive. The introduction of the blowing medium gt C. is continued to a displacement of the reservoir oil to effect through the production well until either the entire 01 is displaced from the formation or to the economic limit of the ratio of propellant to reach reservoir oil. The above-described method according to the invention can be carried out using a single initiation and production well as discussed above. However, it is also applicable to all of the various known borehole patterns, for example the 5-point system of the borehole arrangement.

Claims (2)

Patentanspräche: 1. flood method for secondary recovery of oil from a provided with at least one injection well and a production well deposit using a light hydrocarbon in conjunction with carbon dioxide as a displacing medium to be introduced in front of a blowing medium through the injection well into the reservoir, d a d u rch g e - indicates that carbon dioxide, a liquefied hydrocarbon and the propellant medium are injected into the deposit through the injection hole, one after the other. 2. The method according to claim 1, characterized in that the carbon dioxide is introduced in the liquefied state into the introduction well. 3. The method according to claim 1 or 2, characterized in that the carbon dioxide is introduced at a pressure at which the molar volume of the carbon dioxide is in the range from 50 to 625 dm3 / Kmol at deposit temperature.