NO810302L - DRILLING AND USING THE SAME. - Google Patents

Description

The present invention relates to rotary drill bits

and a method for using such, and is particularly concerned with drill bits that are used when drilling holes in underground formations, for the extraction of oil, gas or water, or in mining or when core drilling. The drill bit is mounted at the front end of a drill string.

The drill bits comprise a bit housing with an internal channel, for example for a liquid such as drilling mud, which opens on the outside of the bit housing, cutting elements which are arranged on the outer surface of the bit housing, and a number of fluid channels which extend along the front of the drill bit, from the mouth of the internal channel and beyond some of the cutting elements and to the periphery. The cutting elements can consist of diamond, synthetic diamonds and the like,

and they can penetrate the layer formation by real cutting effect or by grinding action. Such drill bits are e.g. known from US Patents 2,371,489, 2,809,808, 3,709,308 and 3,727,704. When using such a drill bit, it is through the channel

drilling fluid "mud" is pumped into the drill bit housing, which runs out through the openings and flows outwards and upwards along the many fluid channels on the front of the bit housing and to the well ring channel. The mud flushes material fragments away from the drill bit and cleans and cools the cutting or grinding elements, besides cooling the formation in which it is being drilled to some extent. The drill bit can include many cutting elements but considerably fewer openings, so that the mud flow from one opening has to flush loose material away from several cutting elements. This is because the passage cross-section of each opening must be sufficiently large, so that randomly occurring foreign bodies in the sludge can pass, and the total passage cross-section must be: sufficiently small to ensure a satisfactory discharge velocity, so that the channels are kept open and the front of the drill bit is rinsed.

In the ideal case, the mud flow that passes through the channel and the openings will run out "clean" at the crown, i.e. that the 'undissolved, solid particles are only of microscopic size. In practice, however, the sludge will contain random foreign bodies such as pieces of rubber, metal or rock. For example, pieces of rubber or metal can detach from valves or pistons in the mud pumps connected to the drilling rig. These foreign objects will often occur in sizes between 2 and 12 mm, and can often cause blockage of the mud openings in the drill bit.

Such foreign bodies can also interfere with the successful functioning of a downhole motor, e.g. a mud turbine, near the lower end of the drill string. When using such a turbine, it is common practice to connect a coarse sieve with approx. 6 mm hole diameter immediately below the so-called kelly and above the top section of the drill string. The strainer must be changed: every time a further 10-metre drill string section is connected. The strainer is cleaned before the next connection, to be reused, so that it is necessary to use two such strainers. In spite of this precaution it has shown

that foreign bodies are still being carried to the drill bit, and this may be due to dirty drill pipes, impure sealant or accidental and unintentional omission of the strainer.

Another source of contaminated mud is waste that has been left in the hole from previous drilling processes and that penetrates the drill string through the drill bit, while it is lowered to the bottom of the hole.

Another possible reason for the blocking of such drill bits with small openings is the occasionally occurring but significant use during drilling of so-called "lost circulation material" which is added to the mud to seal a random fracture formation in the formation in which it is being drilled. This material can consist of large flakes of mica or even walnut shells, and particles of this size can block small openings with a diameter of 6 mm or less. The need to use such material can arise quickly and unexpectedly.

In order to avoid this blocking of small openings in the drill bit, it has been proposed to arrange a strainer inside the bit itself. Although such a strainer will be able to prevent blocking of the openings on the outside of the drill bit, the strainer itself can be re-sealed by collected, retained material, and the strainer will also exclude the use of lost circulation material, as the larger particles in this material would be caught by the strainer.

The purpose of the invention is to produce a drill bit

of a construction which will prevent blockage of small openings in the crown as a result of foreign bodies, and at the same time allow the use of lost circulation material.

According to the invention, a rotary drill bit for use in underground layer formations has been developed, which comprises a drill bit housing with an internal channel for a drilling fluid, and cutting elements that are mounted on the outer wall of the bit housing, for milling or scraping out the formation, where the channel opens at a number of adjacent nozzles to the cutting elements and is equipped with an internal filter, a characterized wood separator device for sorting out larger particles from the sludge and for diverting such particles away from the nozzles and out of the drill bit.

The separator device has the task of preventing foreign bodies in the drilling fluid from being carried to the smaller openings and blocking them, and instead allow them to pass or lead them to the drilling fluid to the larger opening or openings. There is consequently little risk of the smaller openings being blocked internally by foreign objects in the drilling fluid. If it proves necessary to use lost circulation material, this material will be able to pass through the drill bit and be diverted from the bit by means of the separator device, without passing through the smaller openings.

The separator device can be of different construction, and arranged to function in a static or dynamic manner. In a simple design, the device consists of a plate or disk with perforations for the retention of foreign bodies, and larger perforations, which are connected by pipes leading to the outside of the drill bit and which are arranged to guide foreign bodies out of the bit. In another, preferred, static version, the separator device consists of a cone or cylinder which is preferably placed in the channel in the drill bit and which is connected to an outlet on the outside of the drill bit, independently of the nozzles. The pipe can instead be placed in a channel in another part of the drill string, e.g. in the stabilizer, and be connected to the outlet of the drill bit.

The separator device may be constructed and arranged to function as a hydrocyclone or centrifugal separator. As the drilling fluid flows through the separator, the particles in the fluid are accelerated at different speeds, and foreign bodies with a different specific gravity than the drilling fluid can thus be separated from the drilling fluid itself.

Due to the presence of the separator device, the nozzles can be made with a smaller and mostly the same diameter, whereby the nozzle density and/or sludge discharge speed is increased.

The invention includes a method for drilling using a drill bit as described above, whereby any foreign bodies in the drilling fluid are diverted to the outside of the bit and away from the nozzles. The invention includes a method as indicated, whereby it is used

lost circulation material in the drilling fluid.

The invention is described in more detail below in connection with the accompanying drawings, in which: Fig. 1 shows a vertical section of a rotary drill bit

which is equipped with an internal separator element.

Fig. 2 shows a vertical section similar to fig. 1, where

the separator element is arranged in the drill string stabilizer.

Fig. 3 shows a vertical section of a rotary drill bit which includes a separator element which functions as a hydrocyclone.

In the following description, similar parts in the different embodiments are as far as possible designated with the same reference number.

A drill bit 10 of a known shape is connected to a number of not shown, prefabricated, cutting elements of synthetic, agglomerated, polycrystalline material. The drill bit is preferably of the type described in British patent application 810075. A central channel 11 extends from the rear end of the drill bit towards the front end. The channel 11 tapers at the front end of the drill bit, and a line 12 of reduced diameter extends from the channel 11 to the outside of the drill bit. Borings 13 emanating from the central channel end in nozzles 14 which are arranged in liquid channels 15. The drawing shows only three borings 13, but the nozzles are arranged in a large number. The nozzles, which will normally be circular, can have a diameter of 2 to 6 mm , while the wire 12 is usually trefoil-shaped with a diameter of 12 to 20 mm.

A separator element 16 is mounted in the central channel 11. The element shown, which is conical and extends along the central channel, is connected at its narrow end to a short tube 17 in the line 12. The element walls include perforations 18 which, in relation to the nozzles 14, are dimensioned as follows, that they are preferably smaller than the nozzles, so that, for example, the diameter of the perforations can be 1.5 mm and of the nozzles approx. 2 mm. The element can be made of sheet metal or of expanded metal. The perforations are preferably circular, but can have a different shape.

During operation, drilling fluid is pumped downwards into the middle channel 11 and into the upper end of the element 16. Part of the liquid flows through the element 16 and through the line 12, from where it flows out and upwards through the liquid channels 15. A certain part of the liquid passes through the perforations 18 and continues through the bores 13 to the nozzles 14. The element 16 acts as a static separator, in that foreign objects of sufficient size to block the nozzles 14 will not pass through the perforations 18 but are carried downwards through the larger opening 12. The liquid which flows to the nozzles 14 will consequently be "clean" and there is little probability that the nozzles 14 will be resealed internally.

If it proves necessary to use lost circulation material, this will pass through the full length of the separator element 16 and through the line 12, without being carried to the narrow nozzles 14.

During use of the drill bit, some of the perforations 18 will be able to be resealed, but considering their large number in relation to the number of narrow nozzles 14, this can be tolerated.

In the version according to fig. 2, the separator element 2 is mounted in a central channel 19 in a stabilizer 20 which is connected to the drill bit. The pipe 17 is longer than according to fig. 1 and extends along the full length of the central channel 11 in the drill bit housing.

The version according to fig. 3 includes a hydrocyclone separator. A disk 30 is arranged at the rear of the drill bit 10. The disk is equipped with inlet openings 31 which are in connection with outlet openings 32 which point in a tangential direction. The disk 30 is located above a cone part 33 (not perforated) and a channel 34 runs between the underside of the disk 30 and the upper part of the cone 33. The upper part of the cone 33 has a smaller diameter than the cavity in the drill bit housing, and the ring chamber 35 thus formed is in connection with bores 13 leading to nozzles 14.

Through a pipe 36, drilling mud is led to the channel 34. The parts 30 to 34 and the pipe 36 together form the aforementioned hydrocyclone.

During operation, drilling mud flows downwards through the channel in the drill bit and through the inlets 31 in the disk 30. As the mud flows out of the outlet openings 32, the speed is increased whereby any larger particles are flung to the outside of the cone 33, while the clean mud is pushed upwards through the tube 36 and along the channel 34 to the nozzles 14. The larger particles run out through the line 12 at the front end of the drill bit. In this way, the separator will separate the clean mud from the foreign bodies that are led out of the drill bit.

The invention is not limited to the described versions.

The element 16 can e.g. be cylindrical rather than conical. The separator element according to fig. 3 can be equipped with spiral-shaped chambers or guide vanes. There may be arranged turbine-like blades that will bring the drilling mud into rotation about the drill bit axis. The drill bit according to fig. 3 may include a second

separator element for the removal from the sludge of foreign bodies of a lower specific gravity than the sludge.

Claims (13)

1. Rotary drill bit for use in underground formations, comprising a drill bit housing with an internal channel for drilling fluid, and cutting elements, mounted on the outside of the drill bit, for milling or scraping out the formation, where the channel opens into a number of nozzles at the cutting elements, and where the channel occupies a filter, characterized in that a separator is arranged for removing larger particles from the drilling mud and diverting these from the nozzles and out of the drill bit. 2. Drill bit in accordance with claim 1, characterized in that the separator is designed to function statically or dynamically. 3. Drill bit in accordance with claim 1 or 2, characterized in that the separator is static and consists of a perforated element with a pipe system for guiding foreign bodies towards the outside of the drill bit. 4. Drill bit in accordance with claim 1 or 2, characterized in that the separator is static and consists of a pipe which is mounted in the drill bit channel and includes a perforated wall where the majority of the perforations in the wall have a smaller diameter than the nozzles, and which is connected at one end to an outlet on the outside of the drill bit. 5. Drill bit in accordance with claim 4, characterized by a line that extends from the end of the channel to the outlet, and a cylinder that is connected to a pipe in the line. 6. Drill bit in accordance with one of claims 2, 4 or 5, characterized by a separator cylinder which is arranged in a channel in a drill string behind the bit, and a pipe that extends from the cylinder, through the channel in the drill bit and to an outlet on the outside of the drill bit. 7. Drill bit in accordance with claim 1, characterized in that the separator is dynamic and arranged as a hydrocyclone or a centrifugal separator. 8. Drill bit in accordance with claim 7, characterized in that a disk is arranged across the channel in the drill bit, and that the disk is equipped with through openings that are arranged for propelling the drilling fluid, and that a barrier is also arranged that guides it flowing drilling fluid to the nozzles and the flowing larger particles to an outlet on the outside of the drill bit. 9. Drill bit in accordance with claim 7 or 8, characterized in that the disk includes a depressed part, and that the through openings are arranged in the side walls of this part. 10. Drill bit in accordance with one of the preceding claims, characterized in that all nozzles have largely the same diameter. 11. Procedure for drilling, characterized by forcing a rotating drill bit in accordance with one of the preceding requirements into an underground layer formation and pumping down a drilling fluid through the drill bit, any foreign matter being diverted to the outside of the drill bit and away from the nozzles. 12. Procedure in accordance with claim 11, character! - characterized by the fact that lost circulation material is pumped into the drill bit channel, which is led to the outside of the drill bit and away from the nozzles. 13. Drill string or stabilizer for use with a drill bit in accordance with claim 6, characterized in that it comprises a channel which occupies a cylinder which is arranged to be brought into connection with the drill bit outlet.