DE1209975B - Process for the extraction of oil from an underground storage facility - Google Patents

Description

Process for extracting oil from an underground reservoir The invention relates to a method for extracting oil from an underground Deposit that is exposed by drilling and relates to such a process, in which a heat transfer medium through injection probes into an upper reservoir section injected and thereby oil from a lower reservoir section via production probes is promoted.

It is known formations that contain an oil of comparatively high levels Viscosity included, to be heated by the production probes to make the oil more fluid to make and thereby bring into a suitable condition for funding. In this process, however, only those immediately adjacent to the production probes are used Deposit areas heated so that the effectiveness of this method is limited and its profitability is in question.

A method is also known in which, in addition to the actual production or conveying probes; further injection probes guided in a distributed manner into the oil-containing formation are provided, via which a heat transfer medium is injected into the formation. With an appropriate number and arrangement of the injection wells, a warming emanating from different points of the formation and thereby the development of larger deposit areas is achieved. Another effect which is very beneficial for the promotion is given by the fact that the heat transfer medium introduced under pressure drives the oil out of the formation so that it is pressed towards the production wells. It is known to open a certain level starting from the injection probes and another level starting from the production probes by using the frac process, so that the introduced heat transfer medium is initially distributed essentially at the introduction level, from where the heat flow or The heat carrier flow advances essentially perpendicularly in the direction of the other level, the production level, to which it supplies oil in the process. But even this method does not lead to satisfactory results in all cases. It turns out to be a disadvantage that the two factors favoring oil production, namely heating and high injection pressure, occur at the same time with their maximum values in the area of the discharge level, so that particularly favorable delivery conditions prevail here, which, however, decrease rapidly in the direction of the production level, because both the pressure as the temperature drop in that direction. If, however, near the production level there is a zone that is not or only barely heated and in which the injection pressure of the heat transfer medium does not act or does not act to a sufficient extent, this zone represents a barrier layer and the oil is not expelled and conveyed. Such a blocking layer leads to a build-up of heat transfer medium, so that further or more uniform heating of the formation between the two levels hardly takes place even in the course of the conveying process.

The invention is directed to a conveying method that has these disadvantages overcomes and more favorable recovery ratios within an oil of high viscosity containing formation creates.

According to the invention, the method for the recovery of oil from a underground deposit, opened up by boreholes, where a heat transfer medium pressed by injection probes into an upper reservoir section and thereby Oil is extracted from a lower section of the reservoir via production wells, characterized by a preheating period in which a heat transfer medium in separate Circuits over the injection wells through the upper reservoir section and over the production probes are passed through the lower section of the reservoir.

The procedure according to this method, the formation is heated, so that more uniform temperature conditions prevail on both levels from within the ölhaltien Fprmation and in the conveying t prior to the actual pumping phase, phase without the aforementioned difficulties can be promoted. Since the heat transfer medium penetrates the formation during this production phase, the heat that is now supplied on one side is at the same time better distributed over the oil-containing formation.

In the case of less permeable deposits, it proves to be useful; through the reservoir sections at the various levels in a known manner Break up frac process. In some cases it is advantageous to use a means of support to be provided in the fracture points, especially if the pressure of the overburden is so large that the break points are not kept open with the aid of the heat transfer pressure can be.

For even heating of the formation during the preheating period it is also advantageous to arrange the injection probes and the production probes in such a way that and in each case the one used for the supply and return of the heat transfer medium Select part of the probes so that they overlap or are symmetrical to each other staggered flow surfaces arise at the discharge and production level.

The invention is described below with reference to schematic drawings explained in more detail using an exemplary embodiment.

F i g. 1 shows in a schematic plan view the essentially horizontally running heat carrier flows during the preheating period, where the hatched areas show the course of the flow in the lower reservoir section mark; F i g. 2, 3 and 4 are vertical sections along lines 2-2, 3-3 and 4-4 in FIG. 1 and show the directions of flow in the various probes during the preheating period.

The various probes leading into the oily formation are best in the vertical sections according to FIG. 2 to 4 can be recognized. These probes are to be divided into two groups, namely the press-fit probes 1 to 9,11,13,15,17, opening into an upper portion of the formation and production wells 10, 12, 21-26 which open into a lower reservoir section of the formation. While in FIG. 3 and 4 it is shown that the various probes correspond accordingly their mouth in the upper or in the lower reservoir section different Have length, according to FIG. 2 also equally deep and cased holes be provided, the piping, depending on whether it is a press-fit or is a production probe, in the area of the upper or lower section of the deposit is broken.

In the F i g. 2 and 3 can also be seen that the formation is both broken up in both the upper and lower sections of the deposit using the frac method was to the breakpoints 30 in the upper deposit section and 34 in the lower Generate deposit section. The production probes are in the area of the upper reservoir section by cementations 31, 32, 33 compared to the sealed upper reservoir section, while in the example according to F i g. 2 where the injection probes 2, 6 are also carried out as far as the lower reservoir section also this one sealing cementation 35, 36 in the area of the lower reservoir section exhibit. In contrast, in FIG. 4 a comparatively permeable formation based, so that here the breaking up of the oil-containing formation by the frac process apart is.

In Fig. 1 is a typical example of the mutual arrangement the injection probes and the production probes are given alternately and in geometric Form distributed are provided. The production probes are at the characteristic or end points of the hatched areas and the press-fit probes at the characteristic or end points of the non-hatched areas.

The aforementioned arrangement is used to carry out the method according to the invention, shown in the figures by drawing in flow arrows or by flow surfaces (FIG. 1) is indicated. It should be emphasized that the flow arrows in all figures indicate the conditions during the preheating phase, so only the heat carrier flow or both heat carrier flows, but not one Show oil or delivery flow.

To initiate the method according to the invention, both the injection probes and the production probes are divided into two groups; Thus, the injection probes comprise feed probes 2, 4, 6, 8, through which a heat transfer medium is fed to the upper reservoir section or the fractures 30 , and outlet probes 1, 3, 5, 7, 9, 11, 13, 15, 17, through which the heat transfer medium circulated through the upper section of the deposit during the preheating period is returned to the surface of the earth. According to FIG. 1, the feed probes and outlet probes forming the injection probes are arranged alternately with one another according to a geometric pattern. During the preheating period, essentially flat heat carrier flows form within the upper reservoir area or within the fracture points 30, which flows through the non-hatched flow areas in FIG. 1 are reproduced.

Similarly, the production probes are also divided into feed probes 10, 12 and outlet probes 21-26 during the preheating period. The heat transfer medium introduced in the circuit through the inlet probes 10, 12 into the lower reservoir section flows within the lower reservoir section or within the lower fracture points 34 in a substantially planar flow to the production probes serving as outlet probes 21 to 26, as indicated by the hatched areas in FIG F i g. 1 is indicated.

During the preheating period, those between the upper and oily formation located in the lower section of the reservoir and to some extent Perimeter also heats the areas above and below this zone, which the highly viscous oil in this zone or in these areas in one for the promotion suitable flow or. eligible state is brought. By the arrangement according to FIG. 1 developing and mutually overlapping flow surfaces, at which the points of greatest heat input in the two reservoir sections do not lie vertically on top of each other, but are offset laterally, becomes a proportionate good heat distribution within the conveying zone between the upper and lower Deposit section reached.

After the conveying zone has warmed up sufficiently, it closes the actual funding process where a heat transfer medium in the injection probes pressed and thereby the oil of the production zone over the production probes is promoted. It is not necessary that the heat transfer medium has all Injection probes is initiated. For example, during the preheating period serving as outlet probes sealed and the heat transfer medium only via the Press-fit probes already used as feed probes during the preheating period 2, 4, 6, 8 can be initiated. Similarly, only a part of the Production probes to be used for the promotion, what then the other production probes, for example the production probes that serve as feed probes during the preheating period 10, 12, are closed.

As a heat transfer medium both during the preheating period and during the actual delivery phase preferably uses steam. This is done during during the preheating period the speed of the steam supply and the condensate drain as follows regulated that condensation over the entire flow path through the upper Deposit section or fracture 30 as through the lower deposit section or break 34, takes place. During the funding period, the steam pressure can be reduced so that the condensate formed by cooling within the oil-containing Formation evaporates again and thereby the heated oil to the lower reservoir section or the break 34 and thus the production probes. This measure is particular also advantageous if the oily formation is still below the lower one Deposit area or the lower fracture point 34 extends. When reducing the pressure becomes water or condensate, which in the area below the lower Leaked deposit section, evaporated. This will also make oil out of the with the heated area below the lower deposit section the production probes fed and promoted. Also with regard to the heated area above of the upper deposit section or the upper fracture point 30 is the measure This is an advantage, because the water vapor generated from the condensate as a result of the pressure reduction penetrates upwards into this area and in doing so presses what is heated and therefore eligible for funding Oil in the direction of the lower reservoir section, so that this oil is also promoted can be. This greatly improves the efficiency of the process, as well the unavoidable heat losses in the area above or below the The production zone can still be partially used for oil production.

Claims (4)

Claims: 1. Method for extracting oil from an underground, Opened by boreholes, in which a heat transfer medium through injection probes pressed into an upper reservoir section and thereby oil from a lower one Deposit section is promoted via production probes, marked d u r c h a preheating period in which a heat transfer medium is in separate circuits Via the injection probes (2, 4, 6, 8; 1, 3, 5, 7, 9, 11, 13, 15, 17) through the upper one Deposit section and the production probes (10, 12; 21 to 26) through the lower deposit section is performed. 2. The method according to claim 1, characterized characterized in that the deposit in a known manner in the area of the upper and of the lower section of the deposit has been broken up by fracing. 3. Procedure according to claim 2, characterized in that the production probes (10, 12; 21 to 26) in a known manner against the break points (30) in the area of the upper deposit section are sealed. 4. The method according to claims 1 to 3, characterized in that that the deposit during the preheating period on both deposit sections is preheated in the form of overlapping flow surfaces (FIG. 1). Into consideration Drawn Documents: U.S. Patent No. 2,946,382.