EP1329586A1 - Profiled element for rotary drilling equipment - Google Patents

Abstract

A shaped component (2) for rotary drilling equipment such as a drillrod (1), has an outside surface with projecting portions and recessed portions extending in radial directions, perpendicular to the axis in configuration that are helical about the axis of the shaped component. Each helix has an angle of inclination that increases in the axial flow direction of the drilling fluid in an annular space (10). A shaped component for rotary drilling equipment such as a drillrod, is in the form of a body of revolution of axis coinciding with the drilling axis of rotation, and having an outside surface with projecting portions and recessed portions extending in radial directions, perpendicular to the axis in configuration that are helical about the axis of the shaped component, to produce an effect of controlled stirring and accelerated rise of a drilling fluid, with cuttings in an annular space between the shaped component of the drilling equipment, and the wall of a borehole while the drilling equipment is rotating. Each helix along which the projecting portions and the recessed portions of the shaped component are disposed, has an angle of inclination relative to a plane perpendicular, to the axis of the shaped component that increases in the axial flow direction of the drilling fluid in the annular space, i.e. upwards when the drilling equipment is in its operating position. The axial flow of the drilling fluid is accelerated along the projecting portions, and the recessed portions because of the direction of rotation of the drillrod.

Description

The invention relates to a profiled element for drilling equipment. rotary.

In the field of research and exploitation of deposits petroleum, we use rotary drill rod trains made up of rods and possibly other tubular elements which are assembled end to end end, according to the needs of drilling.

Such sets of rods can in particular make it possible to produce deviated boreholes, i.e. boreholes whose inclination can be varied from vertical or azimuth direction, during drilling.

In the case of deviated boreholes with large offset comprising sections horizontal or almost horizontal, the friction torques due to the rotation of the drill string can reach very high values high during drilling. Friction couples can reset cause the equipment used or the objectives of the drilling. In addition, the ascent cuttings produced by drilling is very often difficult, account given the sedimentation of debris produced in the borehole, in particular in the strongly inclined part of the borehole. It follows a poor cleaning of the hole and an increase in both the coefficients of friction of the rods of the drill string inside the borehole and contact surfaces between the rods and the walls of the hole.

In order to decrease the coefficient of friction and the contact surface between the drill string and the walls of the drill hole and improve cleaning the borehole and the evacuation of debris in the drilling fluid, there was proposed, in patent application FR-97 03207, a drill pipe comprising at least one support zone having a central support part and two end sections on either side of the central support zone comprising on their external surface at least one groove arranged along a propeller and whose cross section has an undercut portion. The drill rod support area which has a larger diameter the diameter of the end sections and which can come into contact with the borehole wall, provides some reduction in friction between the drill pipe and the wall of the borehole. The end parts which have hydraulic profiles enable the circulation of the drilling fluid and take off the debris hanging on the wall of the hole drilling.

FR-99 01391 has proposed a profiled element for equipment rotary drilling rig with a global shape of revolution and a axis directed along the axis of rotation of the borehole and the projecting parts and recessed parts in radial directions on its outer surface, following arrangements substantially in the form of helices having for axis the axis of drilling equipment rotation including the projecting parts and the parts hollows have at least one geometric and dimensional characteristic which varies along the axial direction of the element, on a part at less than the length of this profile element.

Preferably, the hollow parts or grooves arranged according to profile element propellers have a cross section by a plane perpendicular to the axis of the drill rod decreasing in the axial direction and in the direction of circulation of the drilling fluid in the annular drilling.

Such profiled elements have certain advantages when are used on a drill string used in the case of drilling directional but in some cases it appeared that it might be desirable to further improve the agitation and entrainment effect of the drilling fluid and debris in the ring finger.

The object of the invention is therefore to propose a profiled element for a rotary drilling equipment having a global form of revolution and an axis directed along the axis of rotation of the borehole and the projecting parts and recessed parts in radial directions perpendicular to the axis on its external surface, in arrangements substantially in the form of a helix having as axis the axis of rotation of the drilling equipment, so as to produce an effect of controlled agitation and acceleration of the rise of a drilling fluid and cuttings in an annular space between the profiled element and the wall of the borehole during the rotation of the drilling equipment, this profiled element having improved fluid agitation properties drilling and debris and driving the drilling fluid in the ring finger drilling.

For this purpose, the angle of inclination of the propellers according to which are arranged the projecting parts and the hollow parts of the profiled element by relative to a plane perpendicular to the drilling axis, increases in the direction axial circulation of the drilling fluid in the annular space, that is to say from bottom to top, the axial circulation of the drilling fluid being accelerated along the projecting and recessed parts due to the direction of rotation of the drill pipe.

The invention also relates to other characteristics of the element profile which, combined with projecting and recessed portions of variable inclination according to the invention make it possible to further increase the stirring effect and for driving the drilling fluid and debris in the annular drilling.

La figure 1 est une vue en élévation latérale d'une tige de forage comportant trois éléments profilés suivant l'invention, en position de travail dans un trou de forage.

La figure 2 est une vue développée d'un élément profilé de la tige de forage représentée sur la figure 1.

La figure 3 est une demi-vue en coupe axiale de l'élément profilé représenté sur la figure 2, sous forme développée.

La figure 4A est une vue en coupe transversale selon 4-4 de la figure 2, montrant une partie de la section de l'élément profilé suivant un premier mode de réalisation.

La figure 4B est une vue en coupe transversale selon 4-4 de la figure 2, montrant un second mode de réalisation d'une partie de la section transversale de l'élément profilé.

La figure 5A est une vue en coupe transversale suivant 5A-5A de la figure 2 montrant un premier mode de réalisation de la section transversale.

La figure 5B est une vue en coupe suivant 5B-5B de la figure 2 montrant la section transversale d'une partie de l'élément profilé, suivant un second mode de réalisation.

La figure 6 est une vue en élévation d'une tige de forage comportant deux éléments profilés suivant un second mode de réalisation.

La figure 7 est une vue en élévation latérale et en coupe partielle d'un élément profilé de la tige représentée sur la figure 6.

La figure 8 est une vue en coupe transversale d'une tige de forage comportant un élément profilé suivant l'invention, en position de service dans un trou de forage.

In order to clearly understand the invention, a description will be given, by way of examples, with reference to the attached figures, of two embodiments of a drill pipe comprising profiled elements according to the invention. '

Figure 1 is a side elevational view of a drill pipe comprising three profiled elements according to the invention, in the working position in a borehole.

FIG. 2 is a developed view of a profiled element of the drill pipe shown in FIG. 1.

Figure 3 is a half view in axial section of the profiled element shown in Figure 2, in developed form.

Figure 4A is a cross-sectional view along 4-4 of Figure 2 showing a part of the section of the profiled element according to a first embodiment.

Figure 4B is a cross-sectional view along 4-4 of Figure 2, showing a second embodiment of part of the cross section of the profiled element.

Figure 5A is a cross-sectional view along 5A-5A of Figure 2 showing a first embodiment of the cross section.

Figure 5B is a sectional view along 5B-5B of Figure 2 showing the cross section of a portion of the profiled element, according to a second embodiment.

Figure 6 is an elevational view of a drill pipe comprising two profiled elements according to a second embodiment.

FIG. 7 is a side elevational view in partial section of a profiled element of the rod shown in FIG. 6.

Figure 8 is a cross-sectional view of a drill pipe comprising a profiled element according to the invention, in the service position in a borehole.

In Figure 1, we see a drill rod designated as a whole by the reference 1 which comprises, in three zones spaced along the direction axial of the rod, three profiled elements 2 according to the invention.

The drill pipe usually has at one of its ends (upper end), a female connector 1a and, at its end lower, a male connector 1b constituted by threaded parts of form frustoconical allowing to assemble successive rods 1 of a drill train.

In Figure 2, there is shown on a larger scale a section of the rod constituting a profiled element 2, in developed form.

The rod section constituting the profiled element 2 mainly comprises a zone 3 extending over most of the length of the section profile intended to ensure agitation of a drilling fluid around the rod drill hole 1, inside the borehole, in the annular space 10 between the outer surface of the drill pipe and the wall of the borehole shown in figure 1.

In zone 3, the outer surface of the drill pipe is shaped general cylindrical having as its axis the drilling axis 4 of the drilling rod has recessed portions 5 and protruding portions 6 extending from continuously along the entire length of zone 3 of agitation and turbulence of the profiled element.

The hollow parts 5 are formed in the form of grooves, the cross section may have the shape shown in Figure 4A (first embodiment) or in FIG. 4B (second embodiment).

The protruding parts 6 have the form of blades separating two successive recesses or grooves 5.

The grooves 5 and the blades 6 have a respective axis 5a, 6a arranged along a propeller having as axis the axis 4 of the coiled drill pipe in a direction allowing to favor the ascent of the drilling fluid in annular 10, due to the direction of rotation of the drill pipe (arrow Q on Figure 2.

According to the invention, the propellers 5a and 6a have an inclination increasing in the direction of circulation of the drilling fluid in the ring finger of drilling (arrow 7), i.e. in the direction from bottom to top, in the operating position of the drill pipe 1 inside the borehole, by relative to a transverse plane perpendicular to the axis 4 of the drill pipe.

In Figure 2, there is shown the trace, on the plane of the figure, of a plane of cross section 8 and the tangent to the propellers 5a and 6a of a groove 5 and a blade 6 of the area of agitation 3 of the profiled element. The tangents to the propellers 5a and 6a constituting the axes or median lines of the grooves 5 and the blades 6 make with the trace plane 8, in FIG. 2, an angle α _y which is the angle of inclination of the propeller at level of the cross-sectional plane of trace 8 having the ordinate (in the direction of the axis 4 of the drill pipe) y.

According to the invention, α _y is increasing with y, the ordinates of the points of the drill pipe in the direction of the axis 4 being increasing from bottom to top, that is to say in the direction 7 of circulation of the drilling fluid in the ring finger 10.

In particular, the angles of inclination α _e of the propellers 5a and 6a at the entrance to zone 3 are less than the angles of inclination α _s of the propellers at the exit from zone 3 of agitation and drive of the drill rod.

As can be seen in FIG. 4A, the grooves 5 can have, in cross section, a shape as described and claimed in the French patent application 97 03207, this form making it possible to produce a intense scooping of the drilling fluid in the annulus 10 of the borehole, the fact that the section of the groove 5 has in particular a part in undercut delimited by a straight part of the section making an angle β1 with the direction perpendicular to the axis 4 of the drill pipe, following the external edge of the section 5 disposed towards the rear of the groove 5, considering the direction of rotation Q of the drill pipe around its axis of rotation 4 (Figure 2).

In addition, the grooves arranged in a helix around the rod of drilling provide drilling fluid and drilling debris in the ring finger 10, upwards in the direction of the arrow 7, due to rotation of the drill pipe.

The increasing inclination of the propellers in the direction from bottom to top produces an increasing speed of the drilling fluid in the ring finger and an increased sweeping effect of the borehole. We get from this changes the speed field inside the ring finger 10, the speeds being modified in absolute value and in direction following direction y of axis 4 of the drill pipe and of the profiled element 2. The increase in the inclination of the propellers in the y direction can be adjusted as a function operating conditions of the drill pipe.

In addition, the sections s _y of the grooves 5 are decreasing in the direction of arrow 7, that is to say in the direction of the increasing ordinates y. The decreasing sections s _y of the grooves 5 can be obtained either from the fact that the grooves 5 have a decreasing depth in the direction of increasing ordinates y or from the fact that they have a decreasing width in the direction of increasing ordinates, or also from the because they have decreasing depth and width.

The protruding parts 6 or blades each arranged between two grooves 5 successive have, due to the section and the decreasing width of the grooves 5, an increasing section and width in the direction of the ordinates increasing y (or of the circulation of the fluid in the annular 10 represented by arrow 7).

As can be seen in FIG. 4B, the grooves 5 can have, in cross section, an asymmetrical shape with no undercut part, the scooping and agitation effect of the drilling fluid being however less intense than in the case of the grooves according to the first embodiment shown in Figure 4A, having an undercut portion. The grooves according to the second embodiment, the machining of which is easier, however make it possible to obtain a satisfactory scooping and agitation effect, due to the presence of the blades 6 between two successive grooves 5. As in the case of the first embodiment, the grooves 5 can have a decreasing section, depth and / or width in the direction 7 of circulation of the fluid in the annular 10 (direction of the ordinates y increasing), the blades 6 having a corresponding cross-section and width growing.

As can be seen in FIG. 2, the profiled element 2 comprises, in upstream of zone 3 of agitation and training, considering the meaning of circulation 7 of the drilling fluid, successively, a zone of prior agitation 9, a hydraulic preload zone 11 and a turbulence zone 13.

As can be seen in FIG. 3, the preload zone 11 is formed by a part of the drill rod having a diameter Φ _r substantially greater than the maximum diameter of the drill rod 1 in the agitation zone 3. The zone 11 may be delimited, on the external surface of the drill pipe, by a toric surface, as shown in particular in FIGS. 1 and 3, the maximum diameter Φ _r then being the diameter of the middle part of the zone 11 of shape ring.

The connection of the preload zone 11 of the drill pipe with the stirring zone 3 is achieved through zone 13 or turbulence zone in which the drill pipe has a decreasing diameter, along a curved surface whose section is shown on the figure 3.

The preload zone 11 is connected to the current part of the rod drilling, below the profiled element 2, through zone 9 prior agitation whose diameter is increasing in the direction of the ordinates y increasing (or direction of circulation 1 of the drilling fluid in the ring finger 10) and whose curved longitudinal section is substantially similar to the longitudinal section of the turbulence zone 13, as it is visible on Figure 3. The inclination of the curved part of the prior agitation zone 9 relative to a direction parallel to the axis 4 of the drill pipe, at the level of its connection with the preload zone 11, is less than the inclination of the connecting curve part of the turbulence zone 11 with the support zone (angle β2 ≤ β3) (in Figure 3).

On either side of the profiled element 2, the current part of the drill pipe has a nominal diameter Φ _DN .

The profiled element 2 is also connected to the current part of the drill pipe 1 with nominal diameter Φ _DN , at its downstream end, by a support zone 14 at the level of which the pipe has a substantially larger maximum diameter Φ _u or equal to the diameter Φ _r of the upstream preload zone 11 (which can, in certain cases, also be a support zone).

The diameters Φ _r and Φ _u are substantially greater than the nominal diameter Φ _DN of the current part of the drill pipe, the preload 11 and support 14 zones constituting two zones projecting radially, in the upstream end parts and downstream, respectively, of the profiled element 2.

In the prior agitation zone 9 and in the preload zone 11, the profiled element 2 has recessed or projecting parts 16 spaced apart from each other in the circumferential direction of the drill pipe and each arranged according to a propeller 16a whose inclination relative to a transverse plane of the drill pipe is increasing in the ordinate direction increasing y, in the same way as the propellers 5a and 6a of the grooves and projecting parts 5 and 6 of the stirring zone 3.

When the parts 16 are hollow parts in the radial direction and constitute grooves, their section, their depth and / or their width can be constant or decreasing in the y-direction growing there. When the parts 16 are projecting parts, their section and / or their width can be constant or increasing in the direction of increasing ordinates y. Their height can be decreasing in the direction increasing ordinates there.

This gives an increased entrainment effect of the drilling fluid in the initial agitation zone 9 and in the preload zone 11.

In addition, the presence of the curved surface of zones 9 and 11 which presents an increasing diameter in the direction of flow of the fluid produces a separation of the fluid threads from the drill pipe, these fluid threads being then returned in a turbulent flow, from the zone of preload 11, in the turbulence zone 13 where the drilling fluid constitutes favorable vortices to ensure mixing and training of drilling debris by the drilling fluid which is then taken up by the area training and main agitation 3.

In FIG. 5A, the cross section of grooves 16 is shown. arranged in helices and constituting recessed parts of the area prior agitation 9 and the preload zone 11, in a first mode of achievement. The grooves 16 generally have a depth and a constant width and therefore a cross-section in the direction of circulation of the fluid 7 or direction of increasing ordinates y. However, the width and / or the depth and therefore the section of the grooves 16 may also be decreasing in the direction of increasing ordinates. The grooves 16 are obtained by machining the outer surface of the drill pipe, at the level of the curved connecting surface of the current part of the rod drilling with the O-ring zone 11.

In FIG. 5B, there is shown, according to a second embodiment, protruding parts 16 constituting ribs along helices around the axis of the drill pipe. The inclination of the propellers according to which are arranged the ribs 16 is increasing in the direction of the ordinates growing. In addition, the width of the ribs 16 may be decreasing and / or their height decreasing along the direction of the ordinates y increasing, so that the cross section of the recessed areas 17 between two projecting parts 16 is decreasing in the y direction growing. Cross-flow of drilling fluid is thus obtained which increase turbulence and agitation.

The preload zone 11 allows deflection of the fluid drilling to the outside, which favors the ascent of the cuttings in the ring finger 10. In addition, the preload zone 11 allows, like the zone 9, to create a pre-agitation of the drilling fluid and the cuttings before zone 3.

The drilling fluid is also brought under pressure (preload) in zone 11.

A second charging zone 11 ′, analogous to zone 11 which has been described above, can be located downstream of the support zone 14 (in the direction of circulation 7 of the fluid in the ring finger 10), in order to reinforce the effect of recovery of spoil. This additional area constitutes an area of post-charge for the device.

For this, provision is made, downstream of the radial projecting part 14 of the device drilling, a second radial projecting part constituting zones similar to shaking zones 9 and preload zones 11 located upstream of the device.

In Figures 2 and 3, there is also shown a nozzle 18 which is introduced and fixed in the wall of the tubular drill pipe 1, in the shaking and training area 3.

The nozzle 18 can be placed for example in the bottom and in the part median of a groove 6 of the agitation and training zone 3. The nozzle 18 has a first conduit, or inlet channel 18a, in one direction substantially radial from the drill pipe, opening into space internal of the tubular drill pipe 1 and a second conduit 18b, or channel outlet, communicating with the inlet channel 18a having a direction substantially axial or slightly inclined towards the outside of the drill pipe 1, from bottom to top. The outlet channel 18b opens into the ring finger 10 outside the drill pipe on an upper end portion of the nozzle 18 directed upwards.

The drilling fluid circulating from top to bottom in the internal space of the annular drill pipe 1 (arrow 7 ') has a pressure substantially higher than the pressure of the drilling fluid flowing from bottom to top in the drill ring 10 outside the drill rod (arrow 7). From this done, drilling fluid is entrained inside the inlet channel 18a of the nozzle 18 then ejected through the outlet channel 18b upwards inside the groove 5 in which the nozzle 18 is fixed. The circulation speed is thus increased and agitation of the fluid, using one or more nozzles arranged preferably inside one or more agitation and drive grooves 5 of zone 3 of the profiled element 2 of the drill pipe.

In Figure 6, there is shown a drill pipe designated so general by reference 1 which has two double profiled elements according to the invention and according to an alternative embodiment designated by the reference 2 '.

As can be seen in FIG. 7, the profiled element 2 ′ of the rod drilling 1 is carried out in double form and comprises successively, from the bottom upwards, a first agitation and training zone 3'a, a first 13'a mechanical support and activation zone, a second activation zone and drive 3'b and a second support and mechanical activation zone 13'b.

The activation and training zones 3'a and 3'b are produced according to the invention, that is to say that they have grooves 5 ′ separated by blades 6 'arranged in helices whose angle with a transverse plane perpendicular to axis 4 of the drill pipe is increasing in the direction of flow 7 of the drilling fluid in a drilling ring 10 to the outside of the rod 1. The widths and / or the depths and therefore the sections transverse grooves 5 'can be decreasing in the direction 7 for circulation of the drilling fluid in the annular 10, so as to increase turbulence and to produce a fluid bearing effect.

In addition, the stirring zones 3'a and 3'b are also produced under the shape of deflection zones according to French patent application 01 05752, the outer surface of the drill pipe at the agitation zones and drive 3'a and 3'b inclined relative to the axis 4 of the rod borehole with a meridian line in an axial plane which moves away from the axis 4 of the profiled element 2 and the drill rod 1, in the direction of circulation 7 of the drilling fluid in the annular, that is to say in the direction going from bottom to top in the service position of the drill pipe inside of a borehole.

An increased agitation effect is thus obtained by the fact that a radial direction component at the speed of the drilling fluid driven by the grooves 5 ′ and the projecting parts 6 ′ of the stirring and training zones 3'a and 3'b.

The direction of rotation of the drill pipe in service in a borehole has been shown in the form of a circular arrow Q. There is shown, on either side of the profiled element 2 ′, on the upstream side and on the downstream side, the current part of the drill pipe with diameter Φ _DN .

The profiled element 3 ′ has, in the support and mechanical activation zones 13 ′ a and 13 ′ b, a maximum diameter substantially greater than the diameter Φ _DN . In zones 13'a and 13'b, the outer surface of the profiled element is machined to present two successive parts of maximum diameter separated by a central part of smaller diameter.

The two parts of maximum diameter of the support and activation zones mechanical 13'a and 13'b are machined so as to present at least a continuous helical groove having a small tilt angle, usually less than 30 ° from the transverse planes of the drill pipe perpendicular to axis 4, so that the two parts of the zones support and mechanical activation 13'a and 13'b on both sides of the area central without helical groove have a shape similar to a threaded element whose successive threads have substantially helical shapes. We obtain thus an effect of entrainment of the fluid in the support zone, during the rotation of the drill pipe following the arrow Ω (Archimedes screw effect) and a fluid bearing effect at the supports of the drill pipe via support zones 13'a and 13'b.

In Figure 8, there is shown the section of a profiled element 2 of a drill pipe 1, at a stirring zone such as the stirring zone 3 in which the profiled element 2 has asymmetrical grooves 5 and can have an undercut part ensuring perfect scooping the drilling fluid into the annular 10 inside the borehole 20, during rotation of the drill pipe in the direction of the arrow Ω. In the annular 10, the drilling fluid causes debris 19 products by drilling inside and along the throats 5 of the agitation zone and drive 3 of the profiled element. When it rotates inside the hole drill bit 20, drill pipe 1 approaches the edge of the drill hole, so that the ring finger 10 has a variable width in the circumferential direction of the drill pipe.

In Figure 8, there is shown the cross section of the rod drilling seen from the bottom of the drilling, the circulation of the drilling fluid in the drill ring causing the debris 9 occurring in a direction perpendicular to the section plane of Figure 8 and towards the back of the plan of figure 8.

The realization of the agitation and training zone 3 of the element profile of the drill pipe according to the invention ensures scooping and an upward drive of the drilling fluid and debris 19, such so that the recirculation of the drilling fluid and debris in the ring finger 10 occurs preferentially, in the remote zone 21 maximum of the outside surface of the drill pipe of the wall of the borehole 20 and not in zones 22 where the ring finger 10 does not not have a maximum width. The arrangements according to the invention thus allow in fact to obtain an ideal distribution of drive speeds vertical in the ring finger 10 around the drill pipe.

Similarly, the preload zone 11 makes it possible to create a gradient of speed and therefore pressure in the flow of drilling fluid in the ring finger 10, so as to direct the flow preferentially towards the zone 21.

The profiled element according to the invention therefore makes it possible to optimize agitation and entrainment of drilling fluid and drilling debris inside the ring finger, in particular in the case of deviated boreholes with parts practically horizontal.

The invention is not strictly limited to the embodiments which have been described.

One can imagine certain variants of the profiled elements. combining several agitation, charge and / or preload zones and drive and several support and mechanical activation zones such than those that have been described.

The invention applies to any element of a drill string and in particular the drill string elements used for drilling directional.

Claims (12)

Profiled element for rotary drilling equipment such as a drill rod (1) having an overall shape of revolution and an axis directed along the axis of rotation (4) of the borehole and projecting parts (6, 6 ') and recessed parts (5, 5 ') in radial directions perpendicular to the axis (4) on its external surface, according to arrangements substantially in the form of helices (5a, 6a) having for axis the axis of l profiled element (2), so as to produce a controlled stirring effect and accelerating the ascent of a drilling fluid and cuttings, in an annular space (10) between the profiled element (2) the drilling equipment (1) and the wall of a borehole (20), during the rotation of the drilling equipment (1), characterized in that the angle of inclination (α _y ) of the propellers (5a, 6a) along which are arranged the projecting parts (6, 6 ') and the hollow parts (5, 5') of the profiled element (2), relative to a plane p erpendicular to the axis of the profiled element (2), increases in the direction of axial circulation (7) of the drilling fluid in the annular space (10), that is to say from bottom to top in the operating position of the drilling equipment (1), the axial circulation of the drilling fluid being accelerated along the projecting parts and the recessed parts, due to the direction of rotation of the drilling rod. Profile element according to Claim 1, characterized in that the hollow parts (5, 5 ') of the profile element (2) constituted by grooves (5, 5') have at least one width in a circumferential direction of the profiled element (2) and of a depth in a radial direction perpendicular to the axis of the profiled element (2) and therefore a cross section in a plane perpendicular to the axis of the profiled element (2), decreasing in the direction of circulation (7) of the drilling fluid in the annular space (10). Profiled element according to either of Claims 1 and 2, characterized in that it comprises, on both sides, in the axial direction, a stirring and drive zone (3) in which the profiled element (2) has protruding parts (6) and hollow parts (5) arranged in the form of helices (5a, 6a), a preload zone (11) in which the drill pipe (1) has a part projecting radially towards the outside and a support zone (14) in which the drill pipe (1) also has a part projecting radially towards the outside and a maximum diameter greater than the maximum diameter of the element profiled in the stirring and drive zone (3) and at the nominal diameter (Φ _DN ) of the drill pipe (1) in common parts arranged on either side in the axial direction of the profiled element (2). Profile element according to either of Claims 1 and 2, characterized in that it comprises a second loading zone (11 ') or afterload zone similar to the preloading zone (11) located downstream of the bearing zone (14), in the direction of circulation of the drilling fluid in the annular space (10). Profiled element according to any one of claims 3 and 4, characterized in that it comprises, on either side of the preload zone (11) disposed upstream of the agitation zone and drive (3), in the direction of circulation (7) of the drilling fluid in the annular space (10), a stirring and prior drive area (9) located upstream and a turbulence area ( 13) located downstream in the direction of circulation (7) of the drilling fluid in the annular space (10), the external surface of the profiled element having an increasing diameter in the direction of circulation of the drilling fluid in the pre-stirring and drive zone (9) and a diameter decreasing in the direction of circulation (7) of the drilling fluid in the annular space (10), in the turbulence zone (13). Profiled element according to claim 5, characterized in that it comprises, in the agitation and prior drive zone (9) and in the preload zone (11), at least one of a plurality of recessed elements and projecting elements (16) spaced in the circumferential direction of the profiled element, arranged in the form of helices (16a) having for axis the axis (4) of the profiled element (2), of which the angle of inclination relative to a transverse plane perpendicular to the axis (4) of the profiled element (2) increases in the direction of circulation (7) of the drilling fluid in the annular space (10) . Profile element according to claim 6, characterized in that it comprises, in the pre-stirring and drive zone (9) and in the preload zone (11), recessed parts (16) constituted by grooves machined along the propellers (16a) on the outer surface of the profiled element (2) of the drill pipe (1). Profiled element according to claim 6, characterized in that it comprises, in the agitating and prior drive zone (9), projecting parts (16) constituted by ribs arranged in helices (16a) between which the outer surface of the profiled member of the drill pipe (1) is machined to form recessed portions (17). Profiled element according to any one of claims 1 to 8, characterized in that it comprises, at least in a stirring and drive zone (3) comprising hollow parts (5) and projecting parts (6) arranged along helices (5a, 6a), at least one nozzle (18) passing through a tubular wall of the profiled element (2) of a drill pipe (1) between an internal central fluid circulation space of drilling in the drill pipe and the annular space (10) outside the profiled element (2) of the drill pipe (1) having an inlet channel (18a) of substantially radial direction perpendicular to the axis (4) of the profiled element (2) of the drill rod opening into the internal space of the profiled element of the drill rod (1) and an outlet channel (18b) communicating with the inlet channel (18a) and opening outside the profiled element of the drill pipe, directed in a direction substantially parallel to the axis (4) of the profiled element (2) in the direction of circulation (7) of the drilling fluid in the annular space (10), that is to say upwards in the service position of the drill pipe (1). Profiled element according to claim 1, characterized in that it comprises at least one agitation and drive zone (3'a, 3'b) comprising recessed parts (5 ') and projecting parts ( 6 ') along propellers having as axis the axis (4) of the profiled element (2) and, in the axial extension of the at least one stirring and drive zone (3'a, 3' b), at least one support and mechanical activation zone (13'a, 13'b) in which the drill pipe has a maximum diameter and comprises, on its external surface, at least one helical groove. Profiled element according to claim 10, characterized in that the at least one support and mechanical activation zone (13'a, 13'b) comprises, in the direction of the axis (4) of the profiled element (2 ') of the drill pipe (1), a first portion of maximum diameter of the drill pipe (1) machined on its outer surface along at least one substantially continuous helical groove similar to a thread, a median zone having a diameter less than the maximum diameter of the drill pipe, without a helical groove and a second portion with maximum diameter of the drill pipe (1) machined on its outer surface to present at least one substantially continuous helical groove. Drilling equipment such as a drill rod (1) comprising at at least one profiled element according to any one of claims 1 to 11.

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