EP0055675A1 - Method and apparatus for determining the stuck point of drill pipes in a borehole - Google Patents

Abstract

The invention relates to methods and devices for detecting the point of jamming of rods in a borehole. The usual devices include a body suspended on a cable and formed by two parts (23 and 24) mounted movable relative to each other. Each part is anchored independently in the rods and movements between these parts are detected when stresses are applied to the rods (11) at the surface. The invention makes it possible to remove any constraint on the detection means during the measurement. A spring intended to push the two parts of the body towards each other, is decoupled from the upper part of the body after anchoring. The angular detection means are mounted between a movable sleeve and the upper part of the body. During the measurement, the sleeve is blocked in the lower part. Before the measurement, the sleeve is decoupled from this lower part and reset to zero relative to the upper part.

Description

The invention relates to methods and devices used in soundings, for detecting the point of jamming of a column of rods in a sounding.

When a column of rods, such as a drill string, is stuck in a borehole, a conventional method for determining the depth of the pinch point is to apply twists and pulls to the column on the surface, and determine to what depth these deformations are transmitted. To detect these deformations, a device is used which is lowered into the column at the end of a cable and placed at successive depths.

A conventional jamming point detection device, described for example in US Patent No. 3,686,943 granted to WD Smith, comprises a body having an upper part and a lower part mounted movable one by the other. compared to each other. Upper and lower anchoring members mounted respectively on these upper and lower parts immobilize each of the body parts in two zones longitudinally spaced from the column. Electric motors controlled by the cable are used to separate and bring the anchoring members closer to the body. Detection means, mounted between the parts of the body, measure the relative movements between these parts when the column is elastically blocked by stresses applied to the surface.

An improved anchoring process, described in United States Patent No. 4,104,911 (J.C. Lavigne and Y. Nicolas), involves first anchoring the upper part of the body. The lower part is then anchored after having released the cable tension. The advantage of this process is that it does not compress the moving parts of the body for measurement. During this measurement, it is however necessary that the two parts of the body are longitudinally in the contracted position in order to be able to move away from each other when applying pulls to the column of rods. For this purpose, the apparatus generally comprises an elastic member or spring which applies a restoring force to the parts of the body to urge them towards each other. The disadvantage of known devices is that this restoring force is opposed to the relative longitudinal movements between the two parts of the body during detection.

A first object of the invention is to minimize such a longitudinal restoring force during the measurement.

For the detection of the movements between the parts of the body, it is interesting to use a sensor described in the French patent application No. 80.09751 (inventor P.Moulin), which provides two output signals one independent of the rotations and l other independent of the longitudinal displacements between the parts of the body. The apparatus then comprises a reset system for placing the detection means in an initial angular position before the measurement. A complicated sequence of operations is necessary to order this reset. In other known devices, the angular reset system comprises a spring, or any other elastic means, the restoring torque of which prevents rotation between the two parts of the body during detection.

A second object of the invention is to provide an automatic angular reset system that does not exhibit a restoring torque during the measurement.

Finally, a usual reset system is generally driven by a motor member which is specific to it and controlled separately.

Another object of the invention is a device whose - reset to zero takes place automatically after anchoring of the lower part of the body.

• - descendre dans les tiges un dispositif comprenant un corps en deux parties montées mobiles l'une par rapport à l'autre et normalement sollicitées l'une vers l'autre par une force de rappel;
• - ancrer chacune desdites parties à l'intérieur des tiges par une commande de surface; et
• - détecter, par des moyens de détection, les mouvements relatifs entre lesdites parties lorsqu'on déforme les tiges en leur appliquant des contraintes en surface. Ce procédé comprend en outre l'étape consistant à découpler la force de rappel de la première desdites parties du corps après l'étape d'ancrage et avant l'étape de détection afin de supprimer l'application de cette force entre lesdites parties pendant la détection. La force de rappel est appliquée entre la deuxième partie du corps et un organe mobile couplé, avant l'étape d'ancrage, à la première partie du corps mais déconnectable de cette dernière. Après l'étape d'ancrage, cet organe est découplé de la première partie du corps pour découpler la force de rappel de la première partie.

According to one aspect of the invention, a method for detecting the point of jamming of the rods in a borehole comprises the following steps:

• - descend into the rods a device comprising a body in two parts mounted movable relative to one another and normally biased towards one another by a restoring force;
• - anchoring each of said parts inside the rods by a surface control; and
• - Detecting, by detection means, the relative movements between said parts when the rods are deformed by applying surface stresses to them. This method further comprises the step of decoupling the restoring force from the first of said body parts after the anchoring step and before the detection step in order to suppress the application of this force between said parts during the detection. The restoring force is applied between the second part of the body and a movable member coupled, before the anchoring step, to the first part of the body but disconnectable from the latter. After the anchoring step, this member is decoupled from the first part of the body to decouple the restoring force from the first part.

• - avant l'étape d'ancrage, maintenir, dans une position de zéro les moyens de détection angulaires découplés d'une deuxième desdites parties du corps; et
• - coupler les moyens de détection angulaires à ladite deuxième partie après l'étape d'ancrage et avant l'étape de détection sans changer sensiblement la position de zéro desdits moyens de détection.

The method further comprises the following steps:

• - before the anchoring step, maintain, in a position of zero, the angular detection means decoupled from a second of said parts of the body; and
• - coupling the angular detection means to said second part after the anchoring step and before the detection step without substantially changing the zero position of said detection means.

According to another aspect of the invention, a device for detecting the point of jamming of the rods in a borehole, comprises a body adapted to be suspended on a cable and having two parts mounted movable relative to each other.

Each part can be anchored inside the rods by a surface control and means detect relative movements between said parts when the rods are deformed by applying stresses to the surface.

Return means are provided to apply to the body parts a longitudinal return force which biases them towards each other. Disconnectable connecting means which connect the return means to a first of said parts of the body are decoupled by motor means after anchoring of the two parts inside the rods in order to suppress the application of the return force between said parts during detection.

The connecting means comprise a member mounted movable between a first position connected to the first part of the body and a second position decoupled from the first part. The return means are arranged between the second part and this member to urge this member towards the first position and then apply the return force to the first part of the body. The drive means, arranged in the second part of the body, move the movable member to the second position to decouple this member from the first part.

The movable member is blocked relative to the second part of the body in the second position and decoupled from this second part in the first position. The detection means are arranged on this member and the first part of the body to be sensitive to angular movements between this member and the second part. Reset means place the movable member relative to the first part of the body when this member is in the first position so that the angular detection means are substantially at zero. The reset means comprise oblique ramps for placing the sleeve in the zero position under the action of the return means.

Longitudinal movement detection means are disposed on said movable member and the first part of the body to detect longitudinal extension movements between this first part and this member. Motor resources are adapted to anchor the lower part of the body in the rods before moving the sleeve to the second position.

• - la figure 1 est une vue en cours d'opération, d'un dispositif selon l'invention pour détecter le point de coincement d'une colonne de tiges dans un sondage;
• - les figures 2A et 2B sont des coupes longitudinales de l'appareil de fond de la figure 1;
• - la figure 3 est une coupe transversale selon la ligne 3-3 de la figure 2B; et
• - la figure 4 est une coupe longitudinale similaire à celle de la figure 2B mais dans laquelle les organes internes sont en position de descente dans le sondage.

The characteristics and advantages of the invention will emerge more clearly from the description which follows, given by way of nonlimiting example with reference to the appended drawings in which:

• - Figure 1 is a view during operation, of a device according to the invention for detecting the point of jamming of a column of rods in a borehole;
• - Figures 2A and 2B are longitudinal sections of the bottom apparatus of Figure 1;
• - Figure 3 is a cross section along line 3-3 of Figure 2B; and
• - Figure 4 is a longitudinal section similar to that of Figure 2B but in which the internal organs are in the lowering position in the borehole.

Referring to Figure 1, a jamming point detection device comprises a bottom device 10 suspended in a column of rods 11 at the end of a cable 12. The rods 11 disposed in a borehole 13 are trapped by the terrain formations at a point 14 whose depth is to be determined. The rods are suspended on the surface in a known manner from a drilling tower (not shown) equipped with mechanisms making it possible to apply tensile and torsional forces to these rods. The cable 12 comprises one or more electrical conductors connected to a surface device 15. This device is suitable for sending an electrical supply current and electrical control signals to the downhole device and for receiving the signals coming from this device. to process, display and save them.

The downhole apparatus 10 generally comprises an electronic section 20 formed by a sealed envelope containing electronic circuits, and a mechanical section 21. At the bottom of the mechanical section is fixed a support 22 adapted to receive an explosive as for example several lengths of detonating cord intended to be ignited at a selected joint of the rods. The purpose of this explosion is to unscrew all of the rods located above the joint selected during an operation called "back off" by specialists.

The mechanical section 21 comprises a body produced in two parts 23 and 24 mounted movable relative to one another with limited displacements longitudinally and angularly. Each part is equipped with several anchoring arms such as 25 for the upper part and 26 for the lower part. The anchoring arms are articulated on the body and can be moved apart by a surface control to come to anchor inside the rods.

The mechanical section is shown in more detail in Figures 2A and 2B. The sealed envelope 30 of the electronic section is fixed by a threaded ring 31 to the upper part 23 of the body. The electrical connections between the electronic and mechanical sections are provided by plug-in connectors 32 which pass through a sealed and isolated head 33 fixed in the upper part 23 of the body. Inside the upper part 23 of the body, a first chamber 35 is produced below the head 33. The chamber 35 is filled with a hydraulic fluid maintained substantially at the sounding pressure as will be seen later.

At the lower part of the chamber 35 is produced a bore 36 in which is slidably mounted in an sealed manner an actuating rod 37 fitted with an O-ring 38. The part 23 of the body carries cutouts 40 adapted to receive three arms d anchor 25 mounted to rotate about pivots 41. On each anchoring arm is mounted rotating a pin 42 which engages in a transverse groove of the actuating rod 37 so that a longitudinal movement of this rod rotates the arms around the pivots 41. The actuating rod 37 passes at its lower part a longitudinal bore 43 produced in the part 23 of the body. An O-ring 44, mounted on this rod, seals this crossing. The rod 37 thus enters a second chamber 45 which communicates with the first 35 via a longitudinal passage 46 produced in the axis of the rod 37.

In the second chamber 45, is placed a housing 47 which contains motor members for longitudinally moving the actuating rod 37. At the bottom of the housing 47 is fixed an assembly 50 formed by an AC motor and a reduction gear. The gear unit output shaft is connected by an Oldham seal 51 to a ball bearing 52 and then to a ball screw 53. The nut element of the ball screw 53 is fixed to the enlarged lower end of the actuating rod 37. When the motor 50 is supplied with current, the output shaft of the reduction gear rotates, driving the ball screw 53 which moves the actuating rod 37 longitudinally. The motor can be controlled from the surface to rotate in either direction so as to open or close the anchoring arms 25. The chamber 45 communicates with the interior of the housing by a passage -54, so that the free spaces are occupied by fluid hydraulic which bathes the motor 50, the stop 52 and the ball screw 53. Passages are provided between the housing 47 and the body to allow the wiring of the electrical conductors from the connectors 32 to the bottom of the chamber 45.

At the lower part of the chamber 45, the body comprises an axial tube 54 the interior of which communicates with the chamber 45. At its periphery, the body also has a cylindrical wall 55 around the tube 54 so as to delimit an annular chamber 56 in which a floating piston 57 slides, pressure equalizer. Above the floating piston 57, the annular chamber 56, filled with hydraulic fluid, communicates with the interior of the tube 54 by a passage 60. The underside of the piston 57 is in contact with the probing fluids by a passage 61. The seal between the piston and the tube 54 is produced by a seal 62 and that between the piston and the cylindrical wall 55 by a seal 63.

The upper part 23 of the body extends downwards, below the annular chamber 56, by a mandrel 65 which penetrates into the lower part 24 of the body. A seal 66 seals between this lower part 24 and an annular end 67 of the upper part 23. The lower part 24 of the body can move away and rotate relative to the annular end 67 at the shoulder 59. In the lower part 24 of the body and around the mandrel 65, a sleeve 70 is movably mounted between a high position (FIG. 2B) and a low position (FIG. 4). The mandrel 65 is pierced with an axial channel 68 which places the chamber 45 in communication with the interior of the tube 54 with another chamber 69 produced in the lower part of the body. Channel 68 also serves as a passage for electrical conductors.

A disconnectable link connects the sleeve, in the low position, to the upper part of the body. At this connection, Figure 2B is a section along line 5-5 of Figure 3. On the mandrel 65 are fixed, by screws 71, diametrically opposed lugs 72 having two sides parallel to the longitudinal direction and a upper edge in an inverted V shape. In the sleeve 70 are cut opposite windows 73 having oblique ramps at their upper part. The pins 72 are placed in the windows 73, the dimensions of which are chosen to allow, in the upper position of the sleeve, limited movements longitudinally and angularly, of the mandrel 65 relative to the sleeve 70. The upper edges of the pins 78 and of the windows 73 form ramps which immobilize the sleeve 70 downwards in a first position angularly corresponding to the zero of the angular detection means.

The sleeve has an upper part of smaller diameter around which is placed a helical spring 74 mounted in compression between this sleeve and a shoulder 75 of the lower part of the body. When the windows come to bear on the top of the lugs (FIG. 4), the sleeve 70 is immobilized in the low position relative to the mandrel 65 and the spring 74 applies to the two parts of the body a restoring force which biases them one towards the other. This restoring force is sufficient to maintain the two parts of the body in the retracted position when the device is suspended by the cable 12 when it descends into the borehole. The upward movement of the sleeve 70 is limited by the shoulder 75 of the lower part of the body against which the upper end of the sleeve abuts.

The apparatus includes means for detecting longitudinal and angular movements between the sleeve and the mandrel. These detection means, described in detail in the already cited French patent application No. 80.09751 of April 30, 1980, include two differential transformers. A first transformer with axial coils comprises a primary 80 fixed to the mandrel and a secondary formed by two coils 81 and 82 fixed to the sleeve. This first transformer detects longitudinal movements between body parts while being insensitive to angular movements. A second transformer with radial coils comprising a primary 83 fixed to the mandrel and a secondary formed by two coils 84 and 85 fixed to the sleeve, detects angular movements but is insensitive to longitudinal movements between the parts of the body. At zero of the longitudinal detection means, the primary 80 of the first transformer is centered between the two coils 81 and 82 of the secondary as shown in FIG. 2B. At zero of the angular detection means the primary 83 of the second transformer has its axis perpendicular to that of the coils 84 and 85 of the secondary. The sleeve and the mandrel are placed before the measurement in this initial position by the interaction of the pins 72 and the windows 73.

A housing 86 containing driving members is slidably mounted in the lower part 24 of the body below the sleeve 70. The interior of the housing communicates with the chamber 69 through a passage 88. In the housing 86 is fixed an assembly 87 constituted by a AC electric motor and a reducer. The output shaft 90 of the reduction gear, mounted rotating in the housing by a ball bearing 91, is connected to the threaded shaft of a ball screw 92. The nut member of the ball screw 92 is fixed to a actuating rod 93 which leaves the housing 86 and passes through a transverse partition 94 of the body closing down the chamber 69 filled with hydraulic fluid. The seal between the actuating rod 93 and the transverse partition 94 is ensured by a seal 95. Below the transverse partition 94, the body has cutouts 96 in which are arranged three anchoring arms 26 articulated on pivots 97. Below the cutouts 96, the rod actuator 93 passes through a bore 100 made in the axis of the body to open into a chamber 101. A seal 102 seals between the rod 93 and the body. Between the seals 95 and 102, the actuating rod has a triangular cross section with three transverse grooves 103. On each anchoring arm 26 is mounted rotating a pin 104 having a projecting rib which engages in one of the grooves 103.

The motor-reduction unit can be supplied with electric current so as to move the actuating rod 93, either downwards or upwards, relative to the housing 86. A longitudinal channel 105 cut out in the actuating rod 98 communicates the chamber 69 with the chamber 101. An electrical conductor placed in the channel 105 is connected to a connector 106 mounted in an isolated and sealed manner at the bottom of the lower part 24 of the body. On this end is fixed by screws 107 the upper part 108 of the support 22 of explosives. An electric detonator (not shown) for igniting this explosive is connected to connector 106.

To perform a jamming point measurement, first connect the bottom device 10 to the cable 12 in order to lower it into the rods 11. The upper 25 and lower 26 anchoring arms are closed and the various members contained. in the lower part of the body are in the position shown in FIG. 4. In particular, the housing 86 is in bottom abutment against the transverse partition 94. The actuating rod 93, in the high position in the housing 86, keeps the lower anchoring arm 26. The sleeve 70, pushed back by the spring 74, is in the low position, immobilized by the pins 72 which bear on the top of the windows 73. The angular motion detector formed by the coils 83, 84 and 85 is thus placed in its angular position of zero. The spring 74 also applies to the lower part of the body an ascending restoring force which maintains the two parts 23 and 24 in the retracted position.

The apparatus 10 is then lowered into the borehole to a first depth where it is desired to determine whether the rods are free. _' At this depth, current is supplied to the motor 50 (Figure 2A), so as to spread the arms upper anchoring 25. After anchoring the upper part of the body 23 and after releasing the tension of the cable 12, the motor 87 is supplied with current. The lower anchoring arms move away from the body until they come to bear against the internal wall of the rods 11. The housing 86 rises slightly in the lower part of the body until it comes to bear on the bottom of the sleeve 70. At this instant, the lateral force of application of the anchoring arms 26 is determined by the longitudinal return force of the spring 24, transmitted by the sleeve 70 and the housing 86 to the actuating rod 93. The anchoring arms 26 having reached their maximum spacing in the rods, stop the displacement of the rod actuation 93 relative to the lower part 24 of the body.

When the engine continues to run, the housing 86 moves upwards, causing the sleeve 70 which compresses the spring 74. This movement continues until the upper end of the sleeve 70 comes to bear against the shoulder 75. The sleeve 70 is then locked in the high position in the lower part 24 of the body. During this movement, the oblique contact surfaces of the windows and the pins move away from each other, which decouples the connection between the sleeve 70 and the mandrel 65. With respect to the mandrel 65, the sleeve 70, blocked at this instant in the lower part 24 of the body, is free to move with limited movements angularly to the right or to the left and longitudinally in extension. This upper position of the sleeve, for which the angular and longitudinal detection means are substantially at zero, is shown in FIG. 2B. The device is then ready to carry out a measurement, that is to say to detect movements between the parts of the body when tensile or torsional stresses are applied to the rods at the surface.

After such a measurement, the motors 87 and 50 are supplied with current to close the upper and lower anchoring arms. The bottom device can then be moved using the cable 12 to carry out other measurements at different depths.

During the movements of the apparatus in the borehole (FIG. 4) the sleeve 70 is held on the mandrel 65 in a low position for which the angular movement detector is substantially at zero. On the other hand, in this position of the sleeve, the longitudinal movement detector indicates a maximum elongation. In fact, the coil 80 is offset upwards by a distance d from the midpoint of the coils 81 and 82.

After anchoring of the two parts of the body, the sleeve 70 is anened, relative to the mandrel, in its high position which, angularly, is not modified from the previous low position. For this position, the longitudinal movement detector is substantially at zero. From this position, the sleeve 70 secured to the lower part of the body is decoupled from the upper part. Any restoring force tending to oppose longitudinal or angular movements between the parts of the body is eliminated during the measurement. In addition, the indication provided by the longitudinal movement detector when the device is anchored can be followed on the surface to ensure that it functions properly. When this detector indicates that the two parts of the body have approached each other from a value d to a value substantially zero, the operator knows that the sleeve 70 has moved correctly in the lower part of the body. its low position to its high position. This provides information on the proper functioning of the automatic reset system of the device.

The device which has just been described can obviously be the subject of numerous variants while remaining within the scope of the invention. In particular, the detection means can be produced in a form different from the electromagnetic sensor described above.

Claims (21)

1. Method for detecting the point of sticking of the rods in a borehole comprising the following steps: - descend into the rods a device comprising a body in two parts mounted movable relative to one another and normally biased towards one another by a restoring force; - anchoring each of said parts inside the rods by a surface control; and - Detecting, by detection means, the relative movements between said parts when the rods are deformed by applying surface stresses to them; characterized in that it further comprises the step consisting in: - Decouple the restoring force from the first of said body parts after the anchoring step and before the detection step in order to suppress the application of this force between said parts during detection. 2. Method according to claim 1, characterized in that it comprises the following steps: - Apply the restoring force between the second part of the body and a movable member coupled, before the anchoring step, to said first part of the body but disconnectable from said first part; and - Decouple after the anchoring step said member from the first part of the body to decouple the restoring force from said first part. 3. Method according to claim 2 in which the detection means comprise means for detecting angular movements between said parts, characterized in that it further comprises the following steps: - before the anchoring step, maintain, in a position of zero, the angular detection means decoupled from a second of said parts of the body; and - coupling the angular detection means to said second part after the anchoring step and before the detection step without substantially changing the zero position of said detection means. 4. Method according to claim 3 characterized in that it further comprises the following steps: - Detecting, by the detection means, the relative movements between the first part of the body and said member which is, before the anchoring step, decoupled from said second part of the body; - Maintain, relative to said first part, said member in said zero position, before the anchoring step; and - After the anchoring step, couple said member to the second part of the body while decoupling it from the first part, in order to detect, by said detection means, movements between the two parts of the body. 5. Method for detecting the stuck point of the rods in a borehole comprising the following steps: - descend into the rods a device comprising a body in two parts mounted movable relative to one another and means for detecting relative movements, in particular angular, between said parts; - anchoring each of said parts inside the rods by a surface control; and - detecting relative movements between said parts when the rods are deformed by applying surface stresses to them; characterized in that it further comprises the steps consisting in: - Maintain in a position of zero the angular detection means decoupled from a second of said body parts before the anchoring step; and - coupling the angular detection means to said second part after the anchoring step and before the detection step, without substantially changing the zero position of said detection means. 6. Device for detecting the point of jamming of the rods in a borehole comprising: - A body adapted to be suspended from a cable and having two parts mounted movable relative to each other, each part being adapted to be anchored inside the rods by a surface control; - Means for detecting relative movements between said parts when the rods are deformed by applying surface stresses to them; and - return means arranged in the body to normally apply to said parts of the body a longitudinal return force which biases them towards each other; characterized in that it further comprises: - disconnectable connecting means for longitudinally connecting the return means to a first of said body parts; and - motor means arranged in the body for decoupling the connecting means of the first part of the body, after anchoring of the two parts inside the rods, in order to suppress the application of the restoring force between said parts during detection relative movements. 7. Device according to claim 6, characterized in that said connecting means comprise: a member mounted movable between a first position connected to said first part of the body and a second position decoupled from said first part, said return means being arranged between the second part of the body and said member to urge said member towards the first position and applying the restoring force between said first and second parts when said member is in the first position. 8. Device according to claim 7, characterized in that said motor means arranged in the second part of the body are adapted to move said member towards said second position in order to decouple said member from said first part. 9. Device according to claim 8, characterized in that: - Said member is blocked relative to said second part in the second position and decoupled from said second part in the first position; and - The detection means are arranged on said member and said first part of the body to be sensitive to movements between said member and said first part. 10. Device according to claim 9, characterized in that said detection means comprise angular detection means sensitive to angular movements between said member and said first part and in that it further comprises: resetting means for angularly placing said member relative to the first part in a zero position of said angular detection means when said member is in the first position. 11. Device for detecting the point of jamming of the rods in a borehole comprising: - A body adapted to be suspended from a cable and having first and second parts mounted movable relative to each other, each part being adapted to be anchored inside the rods by a surface control; and - means for detecting relative movements between said parts; characterized in that it further comprises: a member mounted movable in the body between a first position decoupled from the second part and a second position locked with respect to the second part, said detection means comprising means for detecting angular movements between said member and the first part of the body ; - reset means for placing said member relative to said first part in a position zero angular detection means when said member is in said first position; and - motor means for moving said member from the first to the second position, after anchoring of the two parts of the body, in order to block said member relative to the second part and disconnect the reset means without substantially changing the position from zero detection means. 12. Device according to claim 11, characterized in that it further comprises return means between said member and the second part of the body to urge said member towards the first position. 13. Device according to claim 12, characterized in that said member is connected to the first part of the body in the first position, and decoupled from said first part in the second position, the return means being arranged between said member and the second part of the body so as to apply a restoring force between the two parts of the body when said member is in the first position, said restoring force not being applied to said first part when said member is in the second position. 14. Device according to one of claims 10 to 13, characterized in that the reset means comprise contact surfaces between said member and the first part of the body, at least one of said contact surfaces comprising ramps obliques to place said member, under the action of the return means, in said position of zero relative to the first part of the body. 15. Device according to claim 14, characterized in that it comprises a shoulder produced in the second part of the body so that said motor means immobilize said member in said second position against said shoulder. 16. Device according to one of claims 10 to 15, characterized in that said angular movement detection means comprise a transformer with radial coils having primary and secondary windings fixed one to the first part of the body and the other said organ. 17. Device according to one of claims 10 to 16, characterized in that said detection means comprise longitudinal detection means sensitive to longitudinal movements between said first part and said member in order to indicate the movements of said member caused by said means engines. 18. Device according to claim 17, characterized in that said means for detecting longitudinal movements comprise a transformer with axial coils having primary and secondary windings fixed one to the first part of the body and the other to said organ. 19. Device according to one of claims 8 to 18, characterized in that said motor means are adapted to anchor the lower part of the body in the rods before moving said member to the second position. 20. Device according to claim 19, characterized in that said motor means comprise two actuating elements mounted movable in the second part of the body and capable of being longitudinally distant from each other, one of said elements being adapted to actuate anchoring arms articulated on the second part of the body to separate them from the body and anchor them inside the rods, and the other of said elements being adapted to move said member from the first to the second position. 21. Device according to one of claims 8 to 20, characterized in that the first and the second part of the body are respectively the upper and lower parts of the body, said motor means being adapted to move said member after anchoring of the lower part from the body.

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