EP0254900A2 - Stabilizer for drill strings - Google Patents

Abstract

1. A stabilizer for deep-well drilling tools, consisting of a basic body (1) with stabilizer fins or ribs (2) which are arranged helically over its circumference and which define mud flues (3) between them and have wear-resistant outer surfaces (4) which come into contact with the wall of the well and comprise a main region (5) and a marginal region adjacent to the mud flues (3), the main region (5) being described by an envelope (7) axially symmetrical to the longitudinal axis of the stabilizer, characterised in that the marginal region (6) of the stabilizer ribs facing in the direction (13) of the bottom of the well forms a transition region which is drawn inwards in relation to the envelope (7).

Description

The invention relates to a stabilizer for deep drilling tools according to the preamble of patent claim 1.

Such a stabilizer is inserted at predetermined intervals in the deep drilling tool or its drill pipe string or arranged on it in order to be able to control the course of the drilling direction, to prevent the bit from drifting sideways and to increase the drilling performance by centering the bit about its axis of rotation. If it is a deep drilling tool with direct chisel drive, with which both directional drilling and straight drilling can be carried out, a distinction must be made between two operating phases, namely a directional drilling phase in which the stabilizer with its outer surfaces is moved longitudinally along the borehole wall without turning, and a straight drilling phase, in which the stabilizer is rotated in addition to the longitudinal displacement. In order to obtain unimpeded passage of the flushing liquid flowing upwards in the borehole annulus, the stabilizer is provided on its periphery with stabilizer fins, the outer surfaces of which are in contact with the borehole wall only in a limited area of the enveloping surface and delimit flushing channels between them. In the case of inclined boreholes and the associated one-sided radial loading of the stabilizer, secure centering is achieved in that the stabilizer fins are of spiral design and thus offer a contact surface with the borehole wall in every rotational position of the stabilizer. The spiral can be designed as a left or right-hand spiral.

Particularly when there is a pure longitudinal displacement in the borehole, as occurs above all in directional drilling, the stabilizer fins tend to penetrate into the formation with their edge regions adjacent to the mud channels and to block further movement or to remove the formations in an undesirable manner. The invention has for its object to provide a stabilizer of the type mentioned with spirally arranged stabilizer fins so that blocking of the stabilizer or removal of the formation is avoided when drilling the stabilizer in the borehole during drilling work.

This object is achieved by the invention in a stabilizer according to the preamble of patent claim 1 with the features specified in the characterizing part thereof. With regard to further refinements, reference is made to claims 2 to 10.

In the case of a stabilizer with axially extending stabilizer fins according to FR-A-1 521 208, it is known to chamfer the edge leading in the direction of rotation of the stabilizer in order to facilitate sliding of the stabilizer fins over the formation of the borehole wall. Because of the axial alignment of the stabilizer fins, the edge areas cannot penetrate into the formation anyway if the stabilizer is shifted longitudinally in the borehole.

• Fig. 1 bis 3 drei unterschiedliche Ausführungen des erfindungsgemäßen Stabilisators mit rechtsdrehender Spirale in Seitenansicht,
• Fig 4 einen Querschnitt durch den mittleren Be­reich der Stabilisatoren gemäß Fig. 1 bis 3,
• Fig. 5 bis 7 verschiedene Ausgestaltungen des Übergangs­bereichs von Stabilisatorflossen in abge­brochenen Querschnitten, und
• Fig. 8 eine Stabilisatorflosse in Seitenansicht, teilweise im Schnitt, zur Veranschau­lichung eines speziellen Konturverlaufes.

The invention is explained in more detail with reference to exemplary embodiments shown in the drawing. Show it

• Fig. 1 to 3 with three different versions of the stabilizer according to the invention clockwise spiral in side view,
• 4 shows a cross section through the central region of the stabilizers according to FIGS. 1 to 3,
• 5 to 7 different configurations of the transition area of stabilizer fins in broken cross sections, and
• Fig. 8 is a stabilizer fin in side view, partially in section, to illustrate a special contour course.

The stabilizers shown in Figures 1 to 3 each have a base body 1, on the circumference of which several, e.g. three stabilizer fins or ribs 2 are arranged. These are designed in the form of a right-handed spiral and each delimit a mud channel 3 between them for the passage of mud liquid flowing upward in the borehole annulus. The spiral shape of the stabilizer fins 2 ensures that there is contact between the stabilizer outer surfaces 4, the stabilizer fins 2 and the borehole wall in every rotational position of the stabilizer, be it that the outer surface 4 only one stabilizer fin 2 comes to rest against the borehole wall , be it that the outer surfaces 4 of the overlapping ends of two stabilizer fins 2 together form a contact surface.

The configuration of the outer surfaces 4 of the stabilizer fins 2 is illustrated in FIG. 4. As can be seen from the cross-sectional representation, the outer surface 4 has a main area 5 and one on a flushing channel Adjacent transition area 6. The main area 5 is described by a rotationally symmetrical envelope 7, and the transition area 6 is drawn in or directed in relation to the envelope 7, that is to say toward the tool axis. As the transition area 6 in the above sense, that edge area is formed which points in the direction 13 towards the bottom of the borehole. If the stabilizer is moved axially in the direction of the drilling progress without turning in the direction of arrow 13, the transition region 6 slides over the formation of the borehole wall without it being able to penetrate into the formation. This prevents the stabilizer from blocking or removing the formation.

For the formation of the transition area 6, three examples are illustrated in FIGS. 5 to 7. In Fig. 5, the transition area 6 is kinked with respect to the main area 5 and runs flat, i.e. straight in the cross-sectional view. In FIG. 6, the transition area 6 is shown as a curved surface, with a constant radius of curvature 8. In FIG. 7, the transition area likewise forms a curved surface, but with a radius of curvature that becomes smaller towards the adjacent irrigation channel 3. Of course, combinations of the three versions are also possible, or even courses that follow a different mathematical function, insofar as they are directed inwards.

For use in directional drilling of boreholes, it can be expedient to give the envelope 7 a surface that deviates from the preferred cylindrical shape. Such configurations are expedient in which the envelope 7 extends at least to one end of the stabilizer, but preferably to both ends tapered, ie approximating the tool axis. In Figure 2, a stabilizer is designed so that the envelope 7 of the outer surfaces 4 of the stabilizer fins is cylindrical only in a central region 10 of the stabilizer, but is conical towards the ends of the stabilizer in regions 11 and 12. The cone regions 11 and 12 can be designed symmetrically or, as shown in FIG. 2, asymmetrically. Fig. 3 finally shows an envelope 7, which is spherical.

In addition to the embodiments shown in FIGS. 2 and 3, there are also conceivable ones in which the envelope 7 has a combination of cylindrical, conical and spherical regions or also has another mathematical function, provided the envelope 7 tapers to at least one of the end regions.

If a stabilizer is designed with such an envelope 7, it may be sufficient to provide the transition region 6 of the stabilizer fins 2 only in the middle and lower region 10, 12 of the stabilizer and to design the outer surface 4 in the entire width in a rotationally symmetrical manner, such as that is indicated in Fig. 2. As illustrated in FIG. 8, depending on the design of the envelope 7, the contour of the stabilizer fins 2 results in a contour which may not only have simple cone regions at its ends, but instead also have more complex boundaries. For example, the stabilizer fin 2, which can be fastened to the base body 1 via a support body 14, is provided in the region of its upper end with a conical inclined surface 15, which has a partial region 16 of the outer surface 4 of the stabilizer fin that adjoins downward in the direction of the arrow 13 2 encloses an angle 17, which can be between 30 and 45 °. This sub-area 16 of the outer surface 4 can be followed by a further sub-area 18 at a very acute angle, which includes a sub-area 16 with an angle 19 of 1 to 4 °, preferably 2 °. A first lower inclined surface 20 extends to the partial region 18 at an angle 21 on the order of 6 to 15 °, and the first lower inclined surface 20 can merge into a second lower inclined surface 22 which forms an angle 23 of approximately 30 with the surface of the support body 14 up to 45 °. For the rest, the stabilizer fin 2 illustrated in FIG. 8 is provided with a coating 24 made of hard material, which extends only over the partial areas 16, 18 and 20 of the outer surface 4.

Claims (10)

1. Stabilizer for deep drilling tools, consisting of a base body (1) with stabilizer fins or ribs (2) arranged spirally on its circumference, which delimit rinsing channels (3) between them and have wear-resistant outer surfaces (4) that come into contact with the borehole wall. which have a main area (5) and border areas adjacent to the mud channels (3), the main area (5) being described by an envelope (7) which is rotationally symmetrical with respect to the longitudinal axis of the stabilizer, characterized in that the direction (13) towards the bottom of the borehole facing edge area (6) forms a transition area drawn inwards relative to the envelope (7). 2. Stabilizer according to claim 1, characterized in that the transition region (6) has a flat course. 3. Stabilizer according to claim 1, characterized in that the transition region (6) presents a curved surface with a constant radius of curvature (8). 4. Stabilizer according to claim 1, characterized in that the transition region (6) has a curved surface with the rinsing channel (3) becoming smaller and smaller radius of curvature (9). 5. Stabilizer according to one of claims 1 to 4, characterized in that the envelope (7) of the main region (5) is cylindrical. 6. Stabilizer according to one of claims 1 to 4, there characterized in that the envelope (7) is cylindrical only in a central region (10) and conical and / or spherical in at least one of the regions (11, 12) pointing towards the ends of the base body (1). 7. Stabilizer according to one of claims 1 to 4, characterized in that the envelope (7) is generally spherical. 8. Stabilizer according to claim 3 or 4, characterized in that the radius (8,9) of the transition region is 1 to 5 mm, preferably 2 mm. 9. Stabilizer according to Claim 6, characterized in that the stabilizer fin (2) has a contour composed of partial regions (15, 16, 18, 20, 22) adjoining one another in the axial direction (13). 10. Stabilizer according to claim 9, characterized in that the partial areas (15, 16, 18, 20, 22) run at acute angles (17, 19, 21) to one another.

Images