NO820347L - BACKGROUND TOOLS TOOL - Google Patents

Description

The present invention relates to tools for drilling up or expanding the diameter of a deep hole by rotary movement of a drilling unit in an underground formation, for example for extracting oil, gas, water, minerals or geothermal energy, or for injecting gas or liquid for the purpose of creating pressure in a reservoir, or for placing waste.

It will sometimes be necessary to drill in the formation

a hole with a diameter larger than the inner diameter of the wellhead and/or guide pipe and/or well pipe leading to the section where the hole is to be expanded. It may also be necessary to increase the diameter of a previously drilled pilot hole.

It is known a tool, "hole expander with eccentric".

blade" which is designed to meet these requirements. This tool normally comprises a centering device and a milling device, the latter of which is located at the top when the tool is in use. The centering device may be connected to or include a pilot hole drill. The milling device comprises a number of chips which normally project on one side only. The omission of chips on the other side enables the tool to pass through the wellhead or well pipe of smaller inside diameter than that created by the milling device. This is possible because the centering device is brought out of function as it passes through the wellhead or well pipe and out of the control hole.

As the cuts are concentrated on one side or mainly

on one side, the forces exerted against the shears will unfortunately develop a side-directed resultant component, which must be largely balanced by the forces against the centering device. These forces can cause additional friction between the centering device and the formation, wear on the centering device and wear

on the pilot hole wall. In the latter case, the tool can be forced to rotate about the wrong axis, and this results in an irregular hole channel with too small or variable diameter.

It is an object of the invention to produce a tool, an eccentric hole opener, where the cutting forces that occur during use have a relatively small, laterally directed resultant component.

A tool according to the invention, which is intended for the specified purpose, comprises an annular base which, at least at one end, is arranged for connection with other units in the subassembly in a drill string, where the connection means are arranged so that the element is mounted eccentrically on the subassembly, and where an end surface of the base is connected to cutting elements in a pattern that will reduce the imbalance between the transverse components of the cutting forces, which occurs when the hole expander is in operation.

The cutters can be placed in appropriate positions and/or positions around the end surface. In one arrangement, the cuttings are placed at approximately the same distance from the periphery of the end face. The exact radial distance of the cutters from the central axis of the hole expander is selected individually, to determine the cutting pattern and to equalize the lifetime of the cutters to the greatest extent possible. Depending on the intended use, the cuttings can be evenly or unevenly distributed around the periphery. The sum of the horizontal cutting forces that occur when the tool is in use consists of a force pair + a horizontal component due to imbalance. According to the present invention, this imbalance component can be reduced to less than 50%, preferably approx. 20% of the total horizontal shear force.

The eccentric hole expander according to the invention can be designed in different ways. Although the plinth may be round, viewed in the horizontal plane, in practice it does not need to have a completely round side wall. The end surface of the eccentric hole expander can be planar, conical or parabolic.

During operation, the eccentric hole expander will constitute a

of the devices in the drill string subassembly. The hole expander will usually be connected to a centering device. This can be integrated with the eccentric hole expander and/or be arranged in the form of a stabilizer and/or a roller reamer and/or a steering drill bit, which in each case can cooperate with a steering hole that has been drilled in advance or is being drilled

of the guide crown while the hole is expanded. If the eccentric hole reamer is used in a tool with a guide drill bit, the location pattern of the cutters on the hole reamer can be adjusted taking into account the cutting forces produced by the drill bit's cutting elements. It can e.g. be arranged cutters only on one side of the guide bit, and the cutters on the eccentric hole expander can

be located diametrically opposite to the cuttings on the guide bit. -^-^^--^^-- E^ t^ rnifaYsrQeS f or no Id me\L i about the diameters of the s t y r e h u 11 e t, the hole to be drilled and the channel through which the tool must pass may be such that there is no room for cut around the entire eccentric periphery. In such a case, a favorable partial lateral force balance can be achieved by placing the cuttings as far as possible around the eccentric periphery. Further improvement can be achieved in this case by varying the mutual distance and/or orientation of the cuttings.

According to a feature of the invention, the cuttings can be irregularly distributed around the axis, mainly on the side where there is the most space, and they can be oriented in such a way that they run in a side-oblique direction, in order to reduce the imbalance of the cutting forces in the side direction.

Combinations of the above-mentioned placement methods can be implemented. The cuttings do not have to lie in the same horizontal plane, as they e.g. may be arranged in a cone or parabolic plane coaxial with the centering device.

The blades may be made of any suitable material, such as natural diamond, synthetic diamond and/or tungsten carbide. They can consist of polycrystalline compact diamonds. They can be arranged in the form of toothed rollers,

similar to tapered roller rock drill bits.

The invention will be described in more detail below

with reference to the accompanying drawings, in which:

Fig. 1 shows a side view of an eccentric hole expander

according to the invention.

Fig. 2 shows an end view, seen in the direction of arrow A in fig.

Fig. 3 shows a plan view of the hole expander according to fig.

1 and 2, introduced into a well hole.

Fig. 4 shows a perspective view of another, eccentric

hole expander.

Fig. 5 shows a side view of another eccentric hole expander. Fig. 6 shows an end view, seen from below, of the tool according to fig. 5 . Fig. 7 shows a view similar to fig. 5, but by a different tool.

The hole expander according to fig. 1 and 2 comprise a stabilizer device 1, an eccentric hub 2 with cutting elements 9 and 10

as well as an upper fishing neck or gripper neck 3. A connecting thread part 4 is arranged at each end of the tool

and 14, and the tool is equipped with a through channel 5

for conveying drilling fluid. The stabilizer device 1 includes a number of smooth fields 6 which are partially protected by wear plates of tungsten carbide or other hard material.

The cutters 9, which can preferably consist of natural diamond or the like, but preferably of polycrystalline compact diamond, are inserted in the peripheral part P of the front surface part of the eccentric hub. A few shears 10 are further arranged upwards along the side surface of the hub 2, for dimensional adjustment of the enlarged hole. The rear end part of the hub 2 is chamfered at 11, for steering, particularly through the wellhead, of the tool during recovery from a well. The neck part 3 is gripped by rigging pliers during the creation of the tool joints 4 and 14. The neck part 3 is designed for fishing,

in case the tool is dropped in a hole.

During operation, a rotating guide drill bit with approximately the same diameter as the stabilizer device 6 is connected to the thread zone 4, and the thread zone 14 is connected to the lowest drill flange in the hole subassembly. The assembly is lowered into the hole and operated in the same way as a rotating drill bit. The guide crown drills at the front, and the cutters 9 mill out or grind the bottom of the extended part of the hole, which is thus extended at the same pace. With the help of the cutters 10, the enlarged hole is adjusted to its full diameter.

Due to the location of the cutting edges 9 around the periphery of the part P, the wear on the stabilizer device 1 will be small and the damage caused to the control hole wall by the stabilizer device, minimal, thereby ensuring that the tool will rotate about the desired axis, with consequent improved hole design and reduced friction -torque. Another advantage of the tool is that all the drilling fluid that passes through the control table is forced to flow closely past the cutters, which will provide better cleaning and cooling. In previously known, blade-type eccentric hole expanders, a large part of the drilling fluid will pass unimpeded between the blades.

Nozzles (not shown) may be provided for delivery

of drilling fluid to the bottom of the expanded hole, as in other hole expanders.

The tool according to fig. 1 and 2 are particularly suitable for use when advancing through a wellhead with a channel diameter of 386 mm, drilling a 211 mm pilot hole and expanding the diameter to approx. 4 4 5 mm.

It appears from fig. 3. which schematically shows a tool

in a wellbore 20, how the cuttings are oriented at a side-bevel angle, to balance the "lateral forces in cases where there is insufficient space to spread the cuttings around the entire circumference of the tool. For clarity, only three cuttings are shown, but a larger number may be provided. The side-slope angle of the cutting edge 9a is equal to zero, and the force exerted by the formation on the cutting edge is indicated as a vector A. The side-slope angle of the cutting edge 9b causes the cutting force vector B to rotate and form a component C which is opposite in direction to the force A.

A corresponding component D cooperates with the component C to partially or extensively side balance the force A.

In the embodiment shown in fig. 4, the eccentric hole expander 40 comprises a lower, truncated cone-shaped base part 41 with rows 43 of single cutting edges 42. An integrated, upper base part 44 is provided for controlling the hole expander during removal from the borehole. Although the cuttings are shown arranged in vertical rows 43, this pattern can be replaced by another, e.g. a screw line. Due to the fact that the cuttings are distributed around the circumference of the hole expander 40, the unbalance components of the horizontal cutting forces that occur during operation will be reduced.

In the embodiments shown in fig. 5 and 6, the hole subassembly comprises a guide bit 51 which is designed in one with an eccentric hole expander 52. The guide bit includes rows of conventionally arranged bits 53. As is most clearly evident from fig. 6, the hole expander comprises a largely circular side part X which transitions into a side part Y with the same radius as in the expanded hole being drilled. The lower end surface 54 of the hole expander 52 leans towards the main axis of the guide bit 51, as most clearly shown in fig. 5. The cutters 55 are placed in groups in the side part X of the surface part 54 in a pattern for balancing the cutting forces produced by the elements 54 at the periphery of the side part Y. Further cutters 56 are arranged in the side surface of the part Y, as shown in fig. 5. Drilling mud that flows out through an outlet 57 in the guide drill bit 51 is forced upwards through channels W past the cuttings 53 in the bit and the cuttings 55 in the hole expander.

In the version according to fig. 7 includes the hole subassembly

a guide drill bit 71 which is designed in one piece with an eccentric hole expander 72. There are only arranged rows of bits 73 on one side of the bit, i.e. the left according to fig. 7. The hole expander has a largely circular side section that transitions into a side section with the same radius as in the expanded hole being drilled. The lower end surface 74 of the hole expander 72 leans towards the main axis of the guide table 71, and cutters 75 are arranged in groups on the right side of the drill bit, in a pattern for balancing the cutting forces produced by the cutters 73. The hole expander is on

balanced in this way, even though the cutting edges 73 and 75 are vertically separated along the tool.

It is understood that when the tool rotates eccentrically,

is this relative to the local axis of rotation. Furthermore, the imbalance is calculated in relation to the scalar sum of the horizontal cutting forces.

Claims (10)

Tool for use in underground formations, which comprises an annular base which, at least at one end, is equipped with connecting means for connecting the tool with other devices in a drill string subassembly, where the connecting means are positioned so that the base is mounted eccentrically on the hole subassembly, and where the base is connected with cutting elements, characterized in that the cutting elements (9,43,55,75) are distributed around an end surface (P) of the base (2, 41,52,72) in a pattern to reduce the imbalance between the laterally aligned components of the cutting forces that occur when using the hole expander. 2. Tool in accordance with claim 1, characterized in that the cutters are positioned in such a way that the unbalance component is less than 50% of the horizontal cutting force. 3. Tool in accordance with claim 2, characterized in that the cutting edges are positioned in such a way that the imbalance component is approx. 20% of the horizontal cutting force. 4. Tools in accordance with one of claims 1-3, characterized in that the cutting edges are made of natural diamond, synthetic diamond and/or tungsten carbide, polycrystalline compact diamond or in the form of toothed rollers. 5. Tool in accordance with one of claims 1-4, characterized in that the base is largely circular or oval, seen in a horizontal plane, and that the cuttings are distributed largely evenly around the base, immediately at the circumference of the end surface. 6. Tool in accordance with one of claims 1-5, characterized in that the cutting edges are oriented with a side-bevel angle to reduce the imbalance of the cutting forces in the side direction. 7. Tool in accordance with one of the preceding claims, characterized in that there is a cutter on the end surface, for widening the hole, and cutters (10,56,76) behind the end surface, for adjusting the hole wall. 8. A tool in accordance with one of claims 1-5, characterized in that the base is largely frustoconical (41, fig. 4) and that the cutting edges (42) are arranged in rows (43). 9. Tool in accordance with one of claims 1-5, characterized in that the base (52,72) is connected to a guide drill bit (51, fig. 5 and 6; 71, fig. 7) and includes a largely circular side part ( X) which transitions into a side part (Y) with practically the same radius as the hole being drilled, and that the cuttings (55) are placed along the sloping end surface of the base (52). 10. Tool in accordance with claim 9, characterized in that a drill bit (73) is arranged mainly on one side of the drill bit (71), and that the eccentric base (72) is equipped with a bit (75) mainly on the diametrically opposite side side of the tool.