FR2797466A1 - Method, for measuring parameter in well at pre-determined depths, includes sliding down tube in well, inserting probe, with probe moving slowly upwards with tube between measurements - Google Patents

Abstract

Method includes : (a) drill well (5) using drilling tool (9) until pre-determined depth (2) is reached; (b) slide down lagging tube (6) along walls of well, tube following progression of drilling, and drilling waste being discarded through inside (8) of tube; (c) when depth is reached, reduce diameter of drilling tool until outer diameter of tools is inferior than inner diameter of tube. Method follows by : (d) completely remove tool through tube; (e) introduce probe (3) in tube; and (f) take measurements using probe. After each measurement, probe is slowly moved upwards, with tube following progression of probe, so that probe always stays below lower end (10) of tube. An Independent claim is also included for the apparatus for measuring a parameter at level situated at pre-determined depth from ground surface.

Description

The present invention relates to methods for measuring a parameter of a part of a soil by means of a probe capable of measuring this parameter, this part of soil being situated at a given distance from its surface.

The present invention also relates to devices for carrying out these methods.

There are already methods for measuring a parameter of a portion of a soil located at a given distance from its surface, by means of a probe capable of measuring this parameter.

These known methods essentially consist, first of all, in drilling the beginning of a well over a certain depth by means of a drilling tool and in making first measurements at this first portion of wells.

When these first measurements are completed, the wall of the first well portion is jacketed by means of a tube. The drilling of the well is then continued by means of the lining tube itself, the end of which is used as a drilling tool, until, in successive steps, the desired level is reached in the subsoil, the measurements of the parameter being carried out as the well is drilled, after each time raising the liner tube in a sufficient amount to allow the probe to make the measurement. These measurements are therefore made from a level close to the surface of the ground to end at the deep level of the desired basement.

This prior known method undoubtedly has disadvantages. In particular, its implementation is relatively long because it is necessary to perform several successive maneuvers, and repeatedly for each level of measurements.

In fact, it is first necessary to dig a part of the well, for example with the lining tube, then remove the drilling waste, raise the lining tube by a determined quantity, set up the probe, measure , remove the probe, and repeat all these operations several times all the way down to the deep soil level to be reached.

In addition, the waste produced by drilling can of course go up through the inside of the liner tube, but also between the outer wall of the tube and the wall of the well portion already drilled. However, this waste contains solid particles that can damage the well wall, which can be a disadvantage for subsequent operations.

It is also possible that a significant amount of time elapses between the beginning of well drilling and the time of the last measurement, that which occurs when the well has reached the desired depth. This time can lead to errors in the measurements, for example in the case of the measurement of the pressure in the soil, because the rocks of the soil on which the measurements must be made have time to relax before the last measurement is done. The results are then not really representative of the true values of the parameter that the soil presented before drilling the well.

Also, the present invention aims to implement a method for measuring a parameter of a portion of a soil located at a given distance from its surface, which overcomes the disadvantages mentioned above methods of the prior art.

In particular, the object of the present invention is to implement a method for measuring a parameter of a part of a soil situated at a given distance from its surface, which makes it possible, compared with the methods of the prior art, to save time between different measures of the parameter at different levels.

The present invention also aims to implement a method for measuring a parameter of a portion of a soil located at a given distance from its surface, using a wellbore to lower a measurement probe of the parameter, which avoids the alteration of the well wall, especially by drilling waste.

The present invention also aims to implement a method for measuring a parameter of a portion of a soil located at a given distance from its surface, which very significantly minimizes the duration of well drilling and time between the first measure of the parameter and the last one.

The present invention also aims to provide a device for implementing the method according to the invention.

More specifically, the subject of the present invention is a method for measuring a parameter of a part of a soil located at a given distance from the surface of said soil, characterized in that it consists in drilling a well from the ground surface by means of a drilling tool to reach said portion of the ground, down a lining tube along the wall of the well as drilling progresses the well, the outer diameter of the liner tube being equal to diameter of the well made by the drilling tool, said lining tube following the drilling tool as said drilling tool descends into the ground to drill said well, the waste resulting from the drilling of the well being eliminated by inside the liner tube, to retract the drilling tool when the well has reached the desired depth, the retraction of the drilling tool being obtained by bringing said drill bit into a configuration in its outer diameter is less than the inner diameter of the liner tube, withdrawing said retracted drill bit from the inside of the liner tube, into said well through the inside of the liner tube, in place of the drilling tool, a probe able to measure said parameter, up to the level just below the lower end of the lining tube, and to measure the parameter by means of the probe by going up after each measurement, the liner tube being raised substantially the same amount as the probe so that the probe remains below the lower end of the liner tube.

The present invention also relates to a device for implementing the method defined above, this device being characterized in that it comprises at least one lining tube of a well of a given diameter, the diameter outside the lining tube being equal to the given diameter of the well, and a drilling tool capable of having two configurations, a first configuration called "working configuration" in which said drilling tool has an outer radius outside of a value substantially equal to the outer radius of the liner tube, and a second configuration called "retraction configuration" in which said drilling tool has an outer diameter outside a value less than the inside diameter of the liner tube.

Other features and advantages of the invention will become apparent from the following description given with reference to the accompanying drawings for illustrative but not limiting purposes, in which Figures 1, 2 and 3 illustrate various steps of the method according to the invention to measure a parameter of a part of a ground situated at a given distance from its surface, FIG. 2 itself representing two of these stages, and FIGS. 4 and 5 are two diagrammatic sectional views of an embodiment of one of the essential means of the device for carrying out the method according to the invention, FIG. 4 being a cross section referenced IV-IV in FIG. 5, FIG. 5 being a cross section referenced VV in FIG. 4.

It is first of all specified that, in all of the figures, the same references designate the same elements, whatever the figure on which they appear and whatever the mode of representation of these elements. The method according to the invention for measuring a parameter of a part 2 of a soil I located at a given distance from the surface 4 of this soil, consists in drilling a well 5 from the surface 4 of the soil by means of 9 to reach the ground portion 2, FIG. 1, and to lower a liner tube 6 along the wall of the well as drilling of the well progresses, FIG. 1, the outer diameter of the well tube liner 6 being equal to the diameter of the well made by the drill bit 9, the liner tube 6 following the drill bit 9 as the drill bit descends into the ground to drill the well and the waste 7 resulting from the drilling of the well being removed from the inside 8 of the lining tube 6, for example by means of a fluid capable of conveying this waste. Such a fluid is known per se and therefore will not be particularly described here.

When the drilling of the well has reached the desired depth, the method then consists in retracting the drill bit 9, bringing the drill bit into a configuration in which its outside diameter outside, FIG. 2, is smaller than the inside diameter. 6. A possible embodiment for such a drilling tool will be described hereinafter with reference to FIGS. 4 and 5.

The method then consists in removing the retracted drilling tool 9 by moving it upwards through the inside 8 of the lining tube 6, FIG. 2, this FIG. 2 also showing a phase of the process during which the drilling tool 9 would be introduced into the lining tube 6 which would have been disposed in a pre-well previously made, to continue drilling the well, the drilling tool then taking the configuration shown in Figure 1.

After the operations described above, the method consists in introducing into the well 5, downwardly through the inside 8 of the lining tube 6, in place of the drill bit 9, a probe 3 able to measure the desired parameter, to the level located just below the lower end 10 of the lining tube 6, FIG. 3, and then to measure the parameter by means of this probe 3 by raising it after each measurement, the tube liner 6 is also raised substantially the same amount as the probe 3, 3, so that the probe remains constantly below the lower end 10 of the liner tube and preferably in the same relative position.

In possible implementations, the probe 3 is raised step by step, the liner tube 6 being raised in phase relative to the probe, in a stepwise displacement of the same step value as the displacement of the probe, or the probe 3 is raised continuously, the liner tube 6 is then raised in phase relative to the probe, in a continuous movement and at the same speed as the probe. In a preferred embodiment, the method consists in protecting the probe 3, when it is located at a level just below the lower end of the liner tube 6, for example by means of a protective sheath which is able to deform at least radially. Advantageously, this sheath is for example constituted by a so-called "lantern" tube, known to those skilled in the art, which is abutted at the lower end of the liner tube 6 and in its axis.

By way of example, this lantern tube is constituted by a relatively thin-walled tube in which longitudinal slots are made which allow the tube to inflate radially by shortening, by compensation, under the action of radial forces exerted for example by the probe 3 as defined below. This lanterned tube has a length which is determined so that it completely surrounds the probe 3 in all circumstances. In this way, when the probe cooperates with the wall of the well, it is at least separated from it by the wall. of this lantern tube and is therefore protected.

In addition, preferably, to know the direction in which the measurements will be made by the probe 3, the method advantageously consists in indexing or determining the position of the probe in at least one of these positions: position at depth and angular position in a plane substantially perpendicular to the axis 11 of the well 5. These means for indexing the probe 3 do not present any difficulty of realization for a person skilled in the art. They may be formed for example by stops, notches, which will be made for example in the inner wall of the lantern tube, when it is present during the implementation of the method and is fixed relative to the liner tube 6, or directly into the wall of the liner tube when the lantern tube is missing.

FIG. 3 represents by way of illustration the phase of the process according to the invention described above. The probe 3 and the lining tube 6 are for example first in the position shown in dot-dots. When the first measurement is made, the probe 3 and the tube 6 are raised by the amount P, to take the position shown in dot-dot-dashes, and a second measurement is performed. When this second measurement is performed, the probe and the tube are again raised by the same amount, equal to <B> P </ B> or different, depending on the case. This position is illustrated in Figure 3 in solid lines.

It is clearly stated that, if the probe 3 is able to carry out continuous measurements, the probe 3 and the lining tube 6 will be wound up again continuously.

In a preferred implementation, drilling of the well 5 is carried out by means of a drilling tool 9 which is rotated about an axis substantially coinciding with the axis provided for the well 5. liner tube, it may consist of a tube made in one piece, for example for a well of relatively low depth. But for greater depths, for example of the order of one hundred meters or several hundred meters, the lining tube can be made by a plurality of portions of abutting tubes to each other. This operation is well known to those skilled in the art and will not be described further here, for the sole purpose of simplifying the present description.

The present invention also relates to a device for carrying out the method as described above.

This device essentially comprises a lining tube 6 of a well 5 of a given diameter, the outside diameter of the lining tube 6 being equal to the given diameter of the well, and a drilling tool 9.

According to an important characteristic of the invention, this drilling tool is able to have two configurations, a first configuration called "working configuration" as that shown in FIG. 1, in which it has a radius <B> R </ B > outside all exterior, that is to say the radius of the drilling section that can achieve when it is rotated, a value equal to the outer radius of the liner tube 6, and a second configuration called "retraction configuration" as that shown in FIG. 2, in which this drilling tool 9 has an outside diameter D which is smaller than the inside diameter 8 of the lining tube 6.

An exemplary embodiment of such a tool is shown schematically by way of example in FIGS. 4 and 5.

In this embodiment, the drilling tool 9 comprises a base 20 of cylindrical general shape of revolution of a diameter smaller than the diameter of the inside 8 of the lining tube 6, first drilling means 21 mounted in cooperation with this base 20, for example digging teeth or the like whose shape is only evoked in these figures 4 and 5.

The drilling tool further comprises a cam 22, second drilling means 23 mounted in cooperation with the cam 22, for example of the same nature as the first drilling means 21, means 24 for mounting the cam 22 in rotation by relative to the base 20, for example a rotation shaft 40 mounted in cooperation with bearings made in the base.

These means 24 for mounting the cam 22 in rotation relative to the base are further arranged so that the cam 22 can take two positions, a first position shown in continuous lines in Figures 4 and 5, wherein at least one part 25 of this cam 22 is projecting laterally relative to the base 20 (this first position of the cam 22 is also visible in Figure 1), and a second position in which the cam 22 is entirely contained in the cylindrical surface 26 enveloping the base, for example in a housing 45 formed for this purpose at the periphery 46 of this base, this second position being shown in broken lines in Figure 5 and visible, both in continuous and interrupted lines, on the figure 2.

The drilling tool 9 comprises means 27 for controlling the rotation of the cam 22 relative to the base 20 so as to move it from its first position to the second and vice versa. These means may be constituted, for example, by a control arm 41, a first end of which is connected for example to the shaft 40 mentioned previously and whose other second end 43 emerges from the well 5 so that, acting in rotation on this arm 41 by means of a key or the like, in one direction or the other, it is possible to pass the cam 22 from one of its two positions to the other, these two positions being by construction stable states.

The drilling tool also comprises means 28 for controlling the rotation of the base 20-cam assembly 22 about an axis substantially coincident with the axis of revolution 29 of the base. These means 28 diagrammatically shown in FIG. 4 may for example consist of a rod 60, a first end 61 of which is connected for example to the base 20 and whose other second end 62 emerges from the well so that, acting in rotation on the rod 60 by any means, for example by means of a motor or the like, it is possible to drive in rotation this base 20-cam assembly 22.

To allow the implementation of the method described above, the device further comprises a probe 3 able to measure the desired parameter, means 30 for lowering the probe 3 in the well through the inside 8 of the lining tube 6, and means 31 for controlling the probe 3 so that it can measure the parameter when it is located below the lower end of the liner tube as explained in the process description.

There are many probes 3 which are known in themselves and which meet the definition given above. These probes are for example able to measure at least one of the following parameters: mechanical resistance, static pressure, dynamic pressure, temperature, permeability, porosity, remanent magnetic field.

Such a probe, with the means 30 and 31 defined above, is for example marketed by GEOMATECH under the trademark GEOSTAR.

Claims (11)

A method for measuring a parameter of a portion (2) of a soil (1) located at a given distance from the surface (4) of said soil, characterized in that it consists in drilling a well (5) starting from the surface (4) of the ground by means of a drilling tool (9) to reach said part (2) of the ground, said well being made along a given axis (11), to lower a lining tube ( 6) along the well wall as well drilling progresses (Figure 1), the outer diameter of the liner tube (6) being equal to the diameter of the well made by the drill bit (9), liner tube following the drilling tool as said drill bit descends into the ground to drill said well, the waste (7) resulting from well drilling being removed from the inside (8) of the drill pipe; lining (6), to retract the drilling tool (9) when the well has reached the desired depth, the retraction of the drill bit (9) being o bentu by bringing said drill bit into a configuration in which its outside outer diameter (Fig. 2) is smaller than the inner diameter of the liner tube (6), withdrawing said retracted drilling tool (9) back up by the inside (8) of the lining tube (6) (FIG. 2), to introduce, into said well by the inside of the liner tube, in place of the drilling tool, a probe (3) able to measure said parameter, up to the level just below the lower end (10) of the liner tube (6), and to measure the parameter by means of the probe (3) back up after each measurement, the liner tube (6) being raised substantially the same amount as the probe (3) (Figure 3) so that the probe remains below the lower end (10) of the liner tube. 2. Method according to claim 1, characterized in that said probe (3) is raised step by step, said liner tube (6) being raised in phase relative to the probe, in a stepwise displacement of a same step value as moving the probe. 3. Method according to claim 1, characterized in that said probe (3) is raised continuously, said liner tube (6) being raised in phase with respect to the probe, in a continuous displacement at the same speed as the probe. 4. Method according to one of claims 1 to 3, characterized in that the drilling of the well (5) is performed by means of a drilling tool (9) driven by a rotational movement about an axis (11) substantially coincides with the axis provided for said well. 5. Method according to one of claims 1 to 4, characterized in that the lining tube (6) is formed by a plurality of portions of abutting tubes to each other. 6. Method according to one of the preceding claims, characterized in that it consists in protecting said probe (3), when it is located at a level just below the lower end (10) of the liner tube (6), by a protective sheath. 7. Method according to one of the preceding claims, characterized in that it consists in indexing the position of said probe (3) in at least one of the following position positions in depth and angular position in a plane substantially perpendicular to the axis (l 1) of the well (5). 8. Device for implementing the method according to one of claims 1 to 7, characterized in that it comprises at least one lining tube (6) of a well (5) of a given diameter. , the outside diameter of the lining tube (6) being equal to the given diameter of the well, and a drilling tool (9) capable of presenting two configurations, a first configuration called "working configuration" (FIG. 1) in which said tool drill has an outermost radius of a value substantially equal to the outer radius of the liner tube, and a second configuration called "retraction configuration" (Figure 2) in which said drill bit (9) has a diameter out any outside of a value less than the inside diameter (8) of the lining tube (6). 9. Device according to claim 8, characterized in that said drilling tool (9) comprises a base (20) of cylindrical general shape of revolution of a diameter smaller than the diameter of the inside (8) of the liner tube (6), first drilling means (21) mounted in cooperation with said base (20), a cam (22), second drilling means (23) mounted in cooperation with said cam (22), means (24), ) for mounting said cam (22) in rotation relative to said base (20) so that said cam can take two positions, a first position in which at least a portion (25) of said cam (22) is laterally projecting relative to said base (20) and a second position in which said cam (22) is entirely contained in the cylindrical surface (26) enveloping the base, means (27) for controlling the rotation of said cam (22) by relative to the base (20), and means (28) for controlling the rotation of the base assembly (20) - cam (22) about an axis substantially coincident with the axis of revolution (29) of said base. 10. Device according to one of claims 8 and 9, characterized in that it further comprises a probe (3) adapted to measure the given parameter, means (30) for lowering said probe (3) in said well from the inside of the liner tube (6) and means (31) for controlling said probe so that it can measure the parameter when it is located below the lower end (10) of the tube. jacketing. 11. Device according to claim 10, characterized in that said probe (3) is a probe for measuring at least one of the following parameters: mechanical strength, static pressure, dynamic pressure, temperature, permeability, porosity, magnetic field retentive.