EP1225299A1 - High pressure fluid jet drilling tool - Google Patents

Abstract

The tool comprises a body (40) with a lower end (42) provided with several mechanical cutting parts (44) and with nozzles (46) for creating a pressurized fluid jet for breaking up the ground. It has an upper end (48) provided with connections (50) to a drilling string and a pressurized fluid supply. A valve (56) gives the pressurized fluid jet a temporary non-symmetrical distribution relative to the tool longitudinal axis.

Description

The present invention relates to a jet drilling assembly of pressurized liquid which enables deviated drilling.

The technique known as "jet grouting" consists in carrying out soil concrete columns using high pressure fluid to deconstruct the terrain. This destructuring operation is carried out from a mechanical drilling materializing the axis of the column which will be thus obtained. The position and in particular the verticality of these columns are very important for the quality of the final work in particular when this must have a sealing function. For example, for obtain good continuity of a veil resulting from the juxtaposition of columns or that of a massif, it is necessary to position very precisely the axes of all the columns making up this work. To correct positioning errors and in particular of verticality, we use directional drilling techniques to correct deviations from the axis of the drilling in progress.

The directional drilling technique is based on two systems: on the one hand the detection of the drilling position and on the other hand the possibility of diverting this drilling in the desired direction in order to correct the verticality error or, more generally, the direction error.

• l'insertion d'un coude dans la ligne d'outil ;
• l'utilisation de déflecteurs commandés qui créent un effort latéral sur l'outil ; et
• le changement de l'incidence de l'outil, par exemple en faisant fléchir son axe.

The techniques commonly used in hard ground, that is to say essentially in the field of oil drilling, are based on three principles:

• inserting an elbow into the tool line;
• the use of controlled deflectors which create a lateral force on the tool; and
• changing the incidence of the tool, for example by bending its axis.

These three techniques are associated with the continuous rotation of the drilling tool driven either by a downhole motor or directly by the drill head via the drill string. The drilling tool is only fitted with mechanical cutting devices. The putting into circulation of a drilling fluid or mud is only intended to lubricate the organs mechanical cutting and allowing the recovery of soil debris torn.

In the cover areas, other drilling techniques deviated are used. They are based on the sinking of a pallet inclined with which the tool is fitted, this sinking is sometimes assisted by a drilling fluid jet. To carry out the deviation, the rotation of the train rods at the end of which the tool is mounted must be stopped and after orientation, the tool is dark in the ground for a few centimeters before to resume its rotation. This operation is repeated several times until that we obtain a significant deviation capable of correcting the error of management. For normal drilling, the tool is rotated keep on going.

In the case of boreholes used for the construction of columns by "jet grouting", these are necessarily located in land which can be destroyed by a high pressure jet, that is, relatively loose terrain.

A drilling technique used in the land inconsistent alluvial deposits consists of destructuring the soil with a jet of pressurized fluid directed towards the front of the tool. This technique is called launching. It is widely used in uncompact sandy soils. The disadvantage of this drilling principle is that it does not work as soon as that it encounters a slightly harder obstacle.

An object of the invention is to provide a drilling assembly into the soil by injection of pressurized fluid which allows, in certain drilling phases, to carry out a directed drilling in order to correct a drilling direction error.

• une pluralité de tiges de forage raccordées entre elles et comportant des moyens formant conduite pour un fluide sous pression, lesdites tiges formant un train de tiges ;
• une tête de forage pour commander la mise en rotation dans un sens et dans l'autre et la translation verticale dudit train de tiges ;
• un outil de forage fixé à l'extrémité inférieure dudit train de tiges, ledit outil ayant un corps présentant un axe longitudinal prolongeant l'axe du train de tiges, une extrémité inférieure munie de n organes de coupe (n > 1) et des moyens pour créer un jet de fluide sous pression pour désagréger le sol, des moyens de raccordement des moyens formant conduite aux moyens de création de jet et des moyens pour donner audit jet une distribution moyenne non symétrique par apport audit axe longitudinal dudit outil ; et
• des moyens pour alimenter lesdits moyens formant conduite sous une pression suffisante pour que le jet produit réalise effectivement une désagrégation du sol.

To achieve this goal, the drilling assembly in the ground by injection of pressurized fluid comprises:

• a plurality of drill pipes connected together and comprising pipe means for a pressurized fluid, said pipes forming a drill string;
• a drilling head for controlling the rotation in one direction and in the other and the vertical translation of said drill string;
• a drilling tool fixed to the lower end of said drill string, said tool having a body having a longitudinal axis extending the axis of the drill string, a lower end provided with n cutting members (n> 1) and means for creating a jet of pressurized fluid for disaggregating the ground, means for connecting the means forming a pipe to the means for creating a jet and means for giving said jet an average distribution that is not symmetrical by adding said longitudinal axis to said tool; and
• means for supplying said pipe-forming means with sufficient pressure for the jet produced to effectively disintegrate the soil.

In the present text, by means for creating a jet of fluid under pressure, we have to hear means which make it possible to create the lower end of the drilling tool a pressurized fluid outlet, can actually consist of a single jet or a plurality of jets.

In addition, the drilling tool being able to be animated with a movement of continuous or alternating rotation about its longitudinal axis, by non-symmetrical mean distribution with respect to the longitudinal axis, we hears not only the static jet distribution (in the absence but also dynamic, i.e. all of the positions of the jet (s) during a period of rotation of the tool around its axis.

According to a first mode of implementation, the tool is characterized in that the means for creating a jet of pressurized fluid include q injection nozzles distributed symmetrically with respect to the longitudinal axis of said tool and in that it comprises means for temporarily order the interruption of the supply of certain said nozzles so that said r supplied nozzles have a non-symmetrical distribution with respect to the longitudinal axis said tool.

It is understood that, in this first mode of implementation, outside the deflection phases, the jet of pressurized fluid presents symmetrical distribution with respect to the axis of the tool and the jet is modified temporarily in the deviation phases to introduce a asymmetry in the desired direction.

According to a second embodiment, the drilling tool directional is characterized in that said means for creating the jet of pressurized fluid include q pressure injection nozzles, said q nozzles being distributed non-symmetrically with respect to the axis longitudinal of said tool, and it comprises means for supplying simultaneously said nozzles.

In this second embodiment, the fluid jet under pressure is asymmetrical about the axis of the tool body permanence and, in the deviation phases, we therefore obtain the deviation. However, apart from the deviation phases, the tool is controlled in continuous rotation to make the average distribution of the jet of fluid under symmetrical pressure over a period of rotation of the tool.

la figure 1 est une vue en élévation d'un ensemble de forage par jet sous pression ;

la figure 2A est une vue en coupe longitudinale d'un outil de forage selon un premier mode de réalisation de l'invention ;

la figure 2B est une vue de face de l'outil de la figure 2A ;

la figure 3A est une vue de face d'un outil de forage selon un deuxième mode de réalisation ; et

la figure 3B est une vue de côté de l'outil de la figure 3A montrant l'effet de déviation.

Other characteristics and advantages of the invention will appear better on reading the following description of several embodiments of the invention given by way of non-limiting examples. The description refers to the appended figures in which:

Figure 1 is an elevational view of a pressurized jet drilling assembly;

FIG. 2A is a view in longitudinal section of a drilling tool according to a first embodiment of the invention;

Figure 2B is a front view of the tool of Figure 2A;

FIG. 3A is a front view of a drilling tool according to a second embodiment; and

Figure 3B is a side view of the tool of Figure 3A showing the deflection effect.

In Figure 1, there is shown a drilling assembly comprising a platform 10 preferably mounted on tracks 14 or any other displacement system. On platform 10 is articulated a guide mast 16 for guiding in translation a carriage 18. The carriage 18 supports a drilling head 20 for the rotation and the translational movement of a drill string 22 at the end lower 22a from which is mounted the drilling tool 24. The drilling tool 24 is of the type capable of creating jets of fluid under pressure.

The pressure supply is carried out by a source of pressurized fluid 26, preferably a liquid, which supplies a pipe not shown arranged inside the drill rods 2, this pipe can be constituted by the rods themselves and connected to the latter by a flexible tube 28 and a rotating joint 30. The control of the vertical movements of the drilling head 20 is ensured for example by a cable 32 or chain system, driven by a motor not shown, while the rotation of the drill string is produced for example by a motor 34.

Referring first to Figures 2A and 2B, we will describe a first embodiment of the drilling tool which bears the reference 24a. This tool includes a body 40 which has one end lower 42 on which are mounted cutting members such as 44 of the classic type. In the lower face 42 are also provided nozzles such as 46 capable of creating a jet of pressurized liquid directed substantially along the longitudinal axis XX ′ of the body 40 of the tool. The body 40 of the tool has a second end 48 provided with a thread 50 for connection to the drill string 22. There is shown also in the drill string 22 a liquid supply line under pressure 52. This pipe 52 is connected to passages such that 54 arranged in the body of the tool to supply the nozzles 46. As shown in Figure 2A, the nozzle 46a is equipped with a switch controllable 56. In FIG. 2B, four tools are shown cutting mechanics such as 44 and four injection nozzles 46a, 46b, 46c and 46d. These nozzles are arranged at 90 ° relative to the other. More generally, these nozzles, the number of which may be different of 4 are arranged generally symmetrically with respect to the axis XX ' of the tool.

It is understood that, when the nozzles are supplied with liquid under pressure, the nozzles 46b, 46c and 46d permanently create a jet localized liquid while the nozzle 46a creates such a jet or does not create any jet according to the state of the switch 56. The switch 56 can for example be controlled by a bistable system whose state depends on the application temporary overpressure.

We understand that, when the tool 24a is not driven in rotation and that the nozzle 46a is closed, the overall jet of liquid under pressure created by nozzles 46b, 46c and 46d is asymmetrical and goes allow the deviation of the tool path in the ground. On the contrary, if the nozzle 46a is supplied, the overall jet is symmetrical and no deviation occurs.

It is possible during the deviation phase to combine the effect pressurized jets and the mechanical action of the cutting members 44 to get the drilling. To maintain the deflection effect, simply cause the alternating rotation of the tool by an angle equal to 90 ° for example, which does not alter the asymmetry of the jet, but allows the action of different 360 degree cutting tools. More generally, if the tool has n cutting members 40, the alternating rotation will be at an angle at least equal to 360 / n degrees and less than 360 degrees to maintain asymmetry average of the jets produced by the nozzles. The motor 34 of the head of drilling should be ordered accordingly.

In the embodiment shown in FIGS. 3A and 3B, the drilling tool which bears the reference 24b comprises three section 60 and three pressurized liquid injection nozzles 62a, 62b and 62c. The injection nozzles 62a and 62c are permanently closed then that the nozzle 62b is permanently open. It would also be possible to provide a tool having only one nozzle. We understand that when the drilling tool is supplied with pressurized fluid, the jet resulting global is, in the static state, that is to say in the absence of rotation of the tool, asymmetrical with respect to the axis XX 'of the drilling tool. We can thus cause the deviation of the tool as shown in Figure 3B. To allow the action of the various cutting members 60, it is possible to give the tool an alternating rotational movement F at an angle equal to 120 °. Indeed, this rotation allows the action of the cutting members on 360 ° but does not alter the average asymmetry of the liquid jet under overall pressure produced by the nozzle 62b. More generally, if the tool has n cutting members 40, the alternating rotation must correspond at an angle at least equal to 360 / n degrees to ensure a 360 cut degrees. The alternating rotation angle must respect the condition of asymmetrical average distribution of the jet (or jets) of liquid under pressure. This angle is therefore necessarily less than 360 degrees.

However, apart from the tool deflection phases, we can give it a continuous rotation movement controlled by the drilling head 20. In fact, on average, the single jet produced by the nozzle 62b occupies all the angular positions relative to the axis XX ' on a full rotation. We can also cause rotations of the tool more or less 360 degrees.

Of course the number of active liquid injection nozzles drilling could be different from one.

It suffices that the number of active nozzles and their arrangement angular with respect to the longitudinal axis of the tool causes the jets to be asymmetrical with respect to this axis.

Claims (5)

Drilling set in the ground by injection of pressurized fluid comprising: a plurality of drill rods (22) connected together and having conduit means for pressurized fluid (28, 30), said rods forming a drill string; a drill head (20) for controlling the rotation and the vertical translation of said drill string; a drilling tool (24) fixed to the lower end of said drill string, said tool having a body (40) having a longitudinal axis extending the axis of the drill string, a lower end (42) provided with n section (n> 1) and means for creating a jet of pressurized fluid for disaggregating the ground, means for connecting means forming a pipe to the means for creating a jet and means for giving said jet an average distribution that is not symmetrical by addition to said longitudinal axis of said tool; and means for supplying said pipe-forming means with sufficient pressure for the jet produced to effectively disintegrate the soil. Drilling unit according to claim 1, characterized in that the means for creating a jet of pressurized fluid comprise q injection nozzles (46) distributed generally symmetrically with respect to the longitudinal axis of said tool and in that it comprises means (56) for temporarily controlling the interruption of the supply of some of said nozzles so that said r supplied nozzles will produce a distribution that is not symmetrical with respect to the longitudinal axis of said tool. Drilling unit according to claim 1, characterized in that said means for creating the jet of pressurized fluid comprise q injection nozzles (62) under pressure, said q nozzles being distributed generally non-symmetrically with respect to the longitudinal axis of said tool, and in that it comprises means for simultaneously supplying said nozzles. Drilling assembly in the ground by injection of pressurized fluid according to claim 2, characterized in that said drilling tool (24a) comprises n cutting members (44) and in that , during the deflection phases, only r of said nozzles (r ≤ n) are supplied with pressurized fluid and the drilling head (20) is controlled to cause alternating rotation in one direction and in the other of the drill string by an angle at least equal to 360 / n degrees and less than 360 degrees. Drilling assembly in the ground by injection of pressurized fluid according to claim 3, characterized in that said drilling tool comprises n cutting members (60) with n ≥ q and in that the drilling head is controlled to cause the continuous rotation in the same direction, or alternating rotations of more or less 360 degrees of the drill string during the drilling phases without deviation and in that said drilling head is controlled to cause alternating rotation in one direction and in the other of the drill string with an angle at least equal to 360 / n degrees and less than 360 degrees during the deflection phases.

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