FR2703457A1 - Method and device for determining the permeability of a subterranean formation - Google Patents

Abstract

The object of the proposed method is to determine the hydraulic properties of the subterranean formation around the well, and in particular to indicate the levels and the favoured flow directions, to specify the effect on the fluid flow of certain stratographic and structural elements (faults) already located by seismic exploration, to characterise the main drains and permeability barriers around the well, etc.. The method essentially consists in identifying the volume of the formation progressively contaminated with gaseous fluid which is injected in a relatively small quantity over a period which ranges from a few days to a few weeks, in carrying out seismic monitoring by means of seismic sensors placed at the surface or distributed along a well at different depth levels, and of one or more sources placed at a succession of different locations chosen to obtain 2D or 3D subsoil profiles. Application to characterising a formation producing petroleum effluent, for example.

Description

 The present invention relates to a method for studying the permeability of an underground formation in the vicinity of a well - by injection into this fluid well and monitoring the displacement of the injected fluid.

 The permeability of an underground formation containing petroleum fluids can be estimated when, for example, doing the biology of assisted recovery operations. For these operations, one or more vertical or more or less inclined injection wells are drilled as far as the formation to be stimulated and a fluid under pressure is injected (carbon dioxide, vapor injected or produced in situ by combustion, etc.) capable of to move the effluents. By one or more drains, the effluents moved out of the area swept by the injected fluid are pumped. The amount of effluent recovered is an indication of the permeability of the formation.

 Logging methods are known to more directly measure the displacement of a fluid injected into a formation by an injection well which essentially consists of injecting a fluid into the well and testing its displacement in depth in the terrain surrounding the well at by means of a logging probe such as for example an electrical or gamma type probe. A process of this kind is described for example in US patent 4,420,975.

It is also known for example from B. Blondin et al in
Geophysical Prospecting 34, 73-93, 1986, to test the filling of an underground tank intended to store natural gas at successive instants of its loading, by means of a seismic system comprising a seismic source to apply disturbances to the ground surface and a receiving device comprising alignments of sensors arranged on the surface and coupled with the ground. The gas injection significantly modifying the speed of sound in the reservoir formation, the variation of the time difference on the seismic recordings is determined, between two reflectors located one above, the other at- We can also follow the evolution of the filling, by measuring the variation in the amplitude of the waves which are reflected at successive instants at the level of the layers of the reservoir at successive instants of the filling.

 The filling of such tanks is generally very long. Unless a whole seismic exploration system is permanently immobilized on the ground, it is forced to reinstall it with each new seismic recording session, which affects the reproducibility of the coupling conditions with the ground of the installation.

The method according to the invention makes it possible to identify the zones of greatest permeability of formations surrounding a well which contain petroleum effluents following the underground configuration of these formations, to study the role played by certain structural elements (such as faults) , or stratigraphic (such as lenses), which can act as drains or on the contrary as barriers in the flow of fluids, as well as the permeability anisotropy. It is characterized in that it comprises in combination - installation seismic sensors in contact with the formation,
whether on the ground surface or in a well to a plurality
of different depths; - the injection into the formation in relatively small quantity,
of a fluid (such as a gas that is taken for example in
an available underground accumulation, or even
vapor or nitrogen for example) this fluid being capable of
significantly modify wave characteristics
propagating through training (thus adding a role of
acoustic marker), this injection being made for example
in the well where the seismic sensors are placed, or
still in another well; carrying out cycles during the injection process
of seismic exploration each comprising emission of waves
simics in formation from a succession of points
emission (on the surface for example or even in a
other well), the reception of the waves which propagated to the
through training to the various seismic sensors
in the well and recording the waves received during
different cycles; and - the comparison of the records obtained during the
different successive cycles to determine the directions of
propagation of the fluid in the formation, from the well
injection, the progression of the fluid depending on the
permeability of rocks crossed by the fluid.

 The method according to the invention has many advantages.

 The period of seismic observation is relatively short (of the order of a few days to a few weeks) because the amount of fluid which must be injected to constitute a good seismic marker, is relatively small.

 The comparison of the seismic recordings made before and during the injection of fluid, at different successive instants, makes it possible to establish a two or three dimensional mapping of the permeability of the subsoil, by an identification of the directions of propagation of the fluid, to recognize the areas of the formation which are impregnated even very slightly by the injected fluid, from those which are not yet. We also determine the dynamic behavior of certain elements such as faults or lenses promoting or blocking the progression of the injected fluid.

 The method can be implemented in the context of an assisted recovery operation due to the fact that fluid injection means are installed for this purpose.

 It can also be implemented because the formation conceals for example a gas cap (gas cap) where one can pulse ld fluid to be injected.

pu r t wec er.

 The method can also be implemented to test an underground formation chosen to store gas there, before the start of storage operations.

 The method is also easy to implement because the well where the sensors are placed (behind a tubing or a cemented casing) remains available for other operations and in particular for performing the injection of the fluid.

 The device for implementing the method comprises in combination a plurality of seismic sensors distributed along a well, a control and recording station at the surface, at least one seismic source, a fluid generator and conduits to connect the generator to a fluid injection area in the formation.

 According to one embodiment, the seismic sensors are distributed along a tube lowered into and outside a well, and are connected to the control and recording station, the fluid possibly being injected through this tube.

 According to another embodiment, the seismic sensors are installed behind a casing tube cemented in a well and connected to the control and recording station.

With the method and the device according to the invention, it is possible, at each new acquisition cycle - to determine the geometry, if possible in 3D (levels,
digitations) of the volume where the acoustic parameters were
modified since the previous acquisition cycle: measurement of
transit time between two reflections and comparison of
seismic amplitudes; and - interpret the previous data on the one hand so
qualitative by identifying the main drains and barriers of
permeability around the well on the other hand so
quantitative in ilIVUllldllL the parameters of the
tank that we were able to establish before, so that the
results by the simulation represent the geometry well and and
the timing of the advancement of the non-zero saturation front
in gas.

Other characteristics and advantages of the method and of the device according to the invention will appear better on reading the following description of embodiments described by way of nonlimiting examples, with reference to the appended drawings where: Fig.l schematically shows a first mode of
realization with sensors positioned behind a tube
casing cemented in a well serving as an injection well; - Fig.2 schematically shows a second mode of
realization using sensors associated with a column
tubular lowered into a well also serving as a well
injection; - Fig.3 schematically shows an arrangement where the well
injection is separate from that where the sensors are placed; and - Fig. 4, shows schematically how can vary the
propagation speed of liquid saturated rock waves
as the gaseous fluid is injected.

 The method according to the invention comprises the installation of a seismic assembly. This set includes a set of seismic receivers R1, R2, ... Rn which are installed for example in a well 1 at different depths. Each of them has one or more geophones capable of detecting seismic waves in one and preferably several directions (tri-axial geophones for example). According to the embodiment of Fig. 1 described in more detail in patent FR 2 600 172, these geophones are placed behind a casing tube 2 and embedded in the cement which is generally injected into the space ring 3 between it and the well.

 The geophones can also (Fig. 2) be associated with a tubular column (tubing) 4 that lton descends into a cased well for operating operations: production of a well or tube for injecting a fluid intended to move petroleum effluents to a production drain etc. These geophones are pressed into operation against the casing tube so as to better collect the seismic signals coming from the formations surrounding the well. Arrangements of geophones are described for example in patents FR 2 656 034 and 91 / 02.939. In both cases, the sensors are connected to a central control and recording station 5 on the surface by one or more connecting cables 6.

 The seismic assembly also includes one or more seismic sources S which are coupled with the ground surface.

A gas injection system is set up which comprises, for example, a tubular column 7 which is lowered specially into the cased well (Fig.l). In the mode of Fig. 2, one can use for example column 4 supporting the receivers R1 to
Rn. This tubular column 4, 7 is connected to a generator (not shown) of injection fluid of a known type used for example in oil well stimulation operations, producing for example steam, carbon dioxide etc.

You can also use natural gas or nitrogen.

A first series of emission-reception and seismic acquisition cycles is carried out, each time changing the location Si, Sj, Sk, Sp ... of the source S relative to the axis OZ of the injection hole 1 (following a "walk-away" technique) and by recording the arrivals at receivers R1 to
Rn as a function of time t.

 The source can be moved along a radial axis OX and a two-dimensional seismic representation is obtained, vertical in the plane (X, t) or (X, Z).

 Several vertical planes passing through the well can be represented successively by changing the azimuth of the line along which the source or each of them is displaced.

 We can also move the sources all around the injection hole 1 so as to obtain a 3D seismic representation (X, Y, t) or else (X, Y, Z), the Y axis being perpendicular to OX and OZ .

In practice, sources S can be moved on either side of hole 1 over a distance (or a radius) dm which can reach 1000 or 2000 meters.

 After delimiting the underground zone where the injection is to be carried out, by means 8 of containment such as packers, a fluid injection is carried out in the formation by means of the tubular column 4, 7. At regular intervals (every six or twelve hours for example or every day), new series of seismic emission-reception cycles are carried out by positioning the source in substantially the same places as above. Each time, it is possible to establish seismic records of the basement.

 The injection period can last from a few days to a few weeks.

 The injected fluid which impregnates the rocks has the effect of modifying their density and the speed of the waves which propagate there.

Gassman's law well known to geophysicists applies, and we can observe a very rapid variation in the speed of waves, (from 10% to 30%), following a very slight variation (of the order of 1G / o ) of the saturation in gaseous fluid injected into rocks initially saturated with liquid, as shown in Fig. 4. This results in a very significant change in the amplitudes or arrival times of the seismic signals received. By comparison between the successive recordings, the directions of propagation of the fluid are very clearly detected and one can locate the faults F which facilitate the propagation or, on the contrary, prevent it.

 The method also applies in the case where the injection well PI is separate from the well 1 where the seismic receivers R1 to Rn are placed.

 The method according to the invention is suitable for carrying out seismic injection monitoring in a radius rm around a well of a few hundred meters.

 Preferably a readily available gaseous fluid is used. It can take advantage of a fluid injection decided to sweep an oil production area and improve its production. We can also take advantage of a gas cap existing above the area to be studied and extract the gas necessary for injection.

 Optionally, water can be injected into the formation in place of the gas. The comparison of the different records obtained in this case mainly shows the seismic modifications resulting from variations in the effective pressure and / or temperature in the swept formation. In practice, the area investigated is narrower than in the case of a gas injection.

 The method according to the invention as it has been described, is advantageously implemented by means of sensors installed in wells. It would not, however, depart from the scope of the invention to use sensors of which at least part is coupled with the ground surface.

 We would not go beyond the scope of the invention either by carrying out seismic injection monitoring also with seismic sources displaced in another well.

Claims (16)

 1) Method for determining the zones of greatest permeability of a formation surrounding a well (1), which conceals effluents, resulting from the underground configuration of these formations, characterized in that it comprises in combination: - the installation seismic sensors (R 1-Rn) in contact with the  training; - injection into training in relatively small quantities,  of a fluid capable of appreciably modifying  characteristics of waves propagating through the  training;; - carrying out cycles during the injection process  of seismic exploration each comprising the emission of waves  simics in formation from a succession of points  of emission (S), the reception of waves which have propagated  through training to the various seismic sensors  as well as the recording of the waves received during  different cycles; and - the comparison of the records obtained during the  different successive cycles to determine the directions of  propagation of the fluid in the formation, from the well  injection, the progression of the fluid depending on the  permeability of rocks crossed by the fluid.  2) Method according to claim 1, characterized in that one couples at least part of said sensors with the ground surface.  3) Method according to claim 1 or 2, characterized in that at least part of the sensors are installed in at least one well, at a plurality of different depths.  4) Method according to claim 3, characterized in that said fluid is injected into the well where the seismic sensors are installed.  5) Method according to claim 3, characterized in that said fluid is injected into another well separate from the well where the seismic sensors are installed.  6) Method according to one of the preceding claims, characterized in that the emission points are chosen at the surface of the formation.  7) Method according to one of the preceding claims, characterized in that the emission points are chosen from a well.  8) Method according to one of the preceding claims, characterized in that the injected fluid is a gas.  9) Method according to claim 8, characterized in that the gas is taken from an underground accumulation of natural gas.  10) Method according to one of claims 1 to 7, characterized in that the injected fluid is steam.  11) Method according to one of claims 1 to 7, characterized in that the injected fluid is a liquid.  12) Method according to one of the preceding claims, characterized in that the sensors are installed at a fixed position in a well.  13) Device for the implementation of the method according to one of the preceding claims, characterized in that it comprises in combination a plurality of seismic sensors (R1-Rn) coupled with the formation, a control station and recording (5) at the surface, at least one seismic source (S), a fluid generator and conduits (7) for connecting the generator to a zone for injecting the fluid into the formation.  14) Device according to the preceding claim, characterized in that the seismic sensors are distributed along a tubular column (4) lowered into a well and outside of it, and are connected to the control station and recording (5).  15) Device according to claim 14, characterized in that the conduits for connecting the generator to the injection zone include the tube (4) supporting the seismic sensors.  16) Device according to claim 13, characterized in that the seismic sensors are installed behind a casing tube (2) cemented in a well (1) and connected to the control and recording station (5).