FI64836C - STIGSKAER - Google Patents

Description

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Patents register shark Iitin (44) NihtivtiuipMon | a kuuLjglkai »un pvm. - 30.09.83

Patent · och! 'Ej> isterstyrelsen Aluekin utligd oeh utl.skrlfMn publlcirod (32) (33) (31) Revoked privilege —Bejird priorltet l6.0 9.7l USA (US) 506667 (Tl) Dresser Industries, Inc., The Dresser Building, Elm & Akard Streets, PO Box 718, Dallas, Texas 75221, USA (72) Norman Dean Dyer, Piano, Texas, Howard Earl Mitchell, Duncanville,

This invention relates to the field of earth drilling, and more particularly to a riser blade for enlarging a guide hole into a larger diameter hole by dispersing the ground formations surrounding the guide hole, the pitcher blade comprising a blade main body including a plurality of cutters that contact and disintegrate the soil formations surrounding the guide hole, and a drive arm releasably secured within the central opening of the blade body through conical surfaces.

A relatively large diameter hole can be formed in the mine between the first and second locations in the so-called nousuteräpo-rauksella. This is started by drilling a small diameter guide hole through the ground from the first location to the opening in the second location using a small diameter guide blade. Once the guide hole is made, the guide blade is removed from the drill column and the larger diameter riser blade is attached. The ncus blade is rotated and pulled back along the guide hole to enlarge the guide hole to the desired size.

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In many cases, a small guide hole extends into an area that can only be accessed through a small excavation or mining corridor. The detachable drive arm according to the invention provides a low riser blade which can be transported through small excavation tunnels or passages. E.g. po. a riser blade according to the invention with a diameter of 182.9 cm (72 ") can be conveyed through an excavation tunnel with a height of 76 cm, whereas a riser blade with a diameter of 183 cm and no detachable arm requires a tunnel with a height of is at least 132 cm.

During drill bit drilling, there is a huge wear and tear on the riser blade. The guide hole generally tends to deviate from the direction, with curved portions of holes in its longitudinal direction. When the riser blade is pulled along the guide hole, the drilling geometry changes. This results in a huge load being transferred to the riser blade as this is pulled through the sections of the curves. The radius outside the riser blade can be many times larger than the radius of the guide hole and therefore the torque generated is large. When cutters located on the outer radius of the riser blade meet resistance, e.g. when drilling along a curved section, a greater strain is applied to the riser blade. It is clear that any changes in formations encountered during ascent drilling will exacerbate these conditions and make drilling even more difficult.

The enormous strain and wear that occurs during riser drilling causes some parts of the riser blade to wear out much faster than others, especially cutters and the operating arm. Thanks to the blade according to the invention, those parts whose service life is relatively short can be replaced, which prolongs the service life of the blade and reduces costs. The operating arm must be removed and therefore replaced in the same way as individual cutters. This makes it easy to replace the parts that absorb the most stress and wear. The relatively short service life of individual cutters is the result of their almost continuous contact with the wall formations of the borehole and the fact that they are constantly subjected to wear and stress. The operating arm also touches the wall formations and receives a large amount of wear and stress. The drive arm absorbs a large amount of stress as it is the only joint between the drill column and the blade body. All energy from the rotating device is transferred to the riser blade via the operating arm.

The operating arm is very often prone to damage before the blade body is damaged. It is therefore desirable that the arm can be easily 3 64836 and quickly removed from the riser steel and replaced with a new drive arm. The shaft is usually made of a very strong, heat-treated material and would be weakened by welding. Therefore, it is desirable that the shank can be attached to and removed from the body of the riser blade without welding. It follows from the above that the stem must be made of a material that can withstand the harsh conditions that occur. Such a substance is expensive, and if this substance were needed less, this would mean cost savings. The blade according to the invention allows the handle to be made of a strong material, whereas the body may contain less strong and therefore cheaper material.

The shank or shank stabilizer portion should have an almost guide hole throughout the pitch drill bit to ensure smooth drilling performance. In order to be able to use the same blade body in different sized guide holes, it is desirable that the shaft can be detached from the riser blade body and replaced with a suitably sized shaft. The handle should be easily removable and replaceable using simple hand tools. In this case, the arm can be replaced in the field in difficult conditions.

U.S. Patent No. 3,220,494 provides a general description of ascending drilling. In the system described here, the guide hole is enlarged to the desired rise hole size by rotating and pulling the large diameter riser blade upwards along the guide hole.

U.S. Patent No. 3,659,659 discloses a riser blade with a large diameter and a replaceable shank. The blade body includes several shears around the center axis. The riser blade is attached to the drill post by a detachable shank connected to the blade main body, and the blade body includes a series of plates separated by a series of hollow support members.

U.S. Pat. No. 827,346 discloses a conical coupling between a wheel and an axle in which the wheel body has a tapered portion and an additional tapered sleeve in the axle. However, such a structure is relatively disadvantageous in manufacturing costs, so that the overall economy is no longer optimal with current technology.

The riser blades, manufactured by The Robbins Company, 650 South Orcas Street, Seattle, Washington 98108, include a shank that can be replaced by disconnecting conical sleeves at the upper end of the body that mate with the conical portion of the shank and disconnecting the bolt with a split, conical sleeve that extends through the lower end of the shaft.

4,64836

The riser blade according to the invention is mainly characterized in that the main body of the blade has a central opening with an upwardly tapering conical surface, the arm has a cylindrical non-tapered outer surface spaced from the conical surface and terminates at a flanged end, a conical surface and between the outer surface of the shank there are a plurality of detachable gripping portions arranged on the flange so as to prevent axial displacement with respect to the shank, each gripping portion having a conical outer surface mating with the conical surface and an inner surface mating with the non-tapered surface of the shank , and that the preloading device comprising a plate part resting on a flanged end and at an axial distance from the blade body and means adapted to move the blade body axially relative to the gripping parts are adapted to force the gripping parts into a tight wedge grip with a t-shaped surface so that the gripping parts can transfer axial and torsional loads from the shaft to the blade body.

The operating arm according to the invention can be removed and a new operating arm can be placed in its place. The riser blade according to the invention can be transported through small excavation tunnels or passages by removing the operating arm from the riser blade body. The operating arm can then be reattached and the riser blade is ready for operation. Welding does not weaken a very strong, heat-treated arm. The body of the riser blade can be made of materials that are less expensive than the materials that make up the working arm. Different sized drive arms can be attached to the riser blade body so that the riser blade can be used in different sized bypass holes. Removal of the shaft and its replacement with a new one can be carried out in the field in difficult conditions with simple hand tools. There is no clearance between the drive arm (12), the split grip sleeve (18, 19) and the collar (17). This ensures a rigid connection between the operating arm and the riser blade body.

In the structure according to the invention, the drive arm can be easily removed and replaced by a new arm without removing the cutting parts of the cutters next to the arm. The above and other features and advantages of the invention will become apparent from the following detailed description of the invention taken in conjunction with the drawings, in which: Figure 1 shows a side view of po. steel made in accordance with the invention; Fig. 2 is an exploded view of a portion of the riser blade shown in Fig. 1; and 5 64836 Fig. 3 shows the position of the parts shown in Fig. 2 assembled.

Figure 1 shows a side view of po. a riser steel according to the invention, indicated by the general reference numeral 10. The riser blade 10 includes a riser blade main body 11 or a cutter plane body and a drive arm 12. The upper part of the drive arm 12 is enlarged to form a stabilizing part 13. The riser blade 10 is designed to be connected to the rotating column of the drill by a threaded connection 14. A plurality of rolling cutters 15 are mounted on a corresponding number of support members 16. The support members 16 protrude from the riser body 11.

The riser blade 10 is used in the riser blade bore to form a relatively large diameter hole from the first well step to the second well level. Raising blade drilling is initiated by drilling a small diameter guide hole through the ground from the first location to the second location hole using a small diameter guide blade. When the guide hole is made, the guide blade is detached from the drill column and a riser blade 10 is attached to it.

Figure 2 shows an exploded view of a portion of the arm 12 and the main body 11 of the riser blade. A cylindrical collar 17 is attached to the main body 11 of the riser blade. The collar 17 has a truncated, conical inner surface 24. The apex of the conical surface 24 intersects the lower end of the drive arm . A two-part, split, detachable ring consisting of gripping parts 18 and 19 is arranged around the drive arm 12.

The part 18 includes a surface 25 which forms part of a conical outer surface which mates with the conical inner surface 2 4 of the collar 17. The part 19 includes a surface 26 which forms part of said conical outer surface which mates with the conical inner surface 24 of the collar 17. The portion 18 includes a surface 27 that forms part of a cylindrical inner surface that mates with the cylindrical outer surface of the drive arm 12. The part 19 includes a surface 28 which forms part of said cylindrical outer surface of the drive arm 12. The flange 20 protrudes from the lower end of the operating arm 12. The plate portion 21 is located under the flange 20 and the two bolts 22 and 23 are positioned so as to extend through the respective holes 30 and 31 of the cover 21 and engage the respective recesses 32 and 33 in the collar 17.

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Figure 3 shows the parts of Figure 2 assembled. The split ring parts 13 and 19 are arranged around the lower end of the drive arm 12. The arm 12 and the parts 18 and 19 are then pulled up inside the collar 17. A flange 20 projecting from the lower end of the arm 12 initially prevents the arm 12 from being pulled through the collar 17. The flange 20 also applies a force to the split ring portions 18 and 19 which forces the ring even more tightly against the collar 17. The mating, conical surfaces of the collar 17 and the split ring portions 18 and 19 force the portions 18 and 19 against the outer surface of the arm 12. The load applied to the riser blade increases said forces. The frictional forces generated between the collar 17 and the mating surfaces of the parts 18 and 19 and the drive arm 12 prevent rotational, radial and axial movement of the drive arm 12 relative to the riser main body 11. The system is preloaded to ensure proper torque transmission loads. Kui. the bolts 22 and 23 are tightened, they force the plate part 21 against the flange 20 and the parts 18 and 19 upwards in the collar 17.

Details of the structure of the riser blade made in accordance with the invention have been described above, and the blade shown in Figs. Ascent drilling is initiated by drilling a small diameter guide hole through the ground from the first location to the opening in the second location using a guide blade of small diameter. When the guide hole is made, the guide blade is removed from the drive arm and a riser blade 10 is attached to it. The riser blade is rotated and pulled along the guide hole, which enlarges the guide hole to the desired size. The collar 17 and the split ring portions 18 and 19 form a rigid connection between the drive arm 12 and the main body 11 of the riser blade.

The riser blade can be moved through small excavation tunnels or passages by removing the drive arm 12 and transporting the drive arm 12 and the riser blade main body 11 separately through the small tunnels or passages. The bolts 22 and 23 are removed and thus disconnect the plate portion 21 from the collar 17. The drive arm 12 and the split ring portions 18 and 19 are moved downward to disengage the split ring portions 18 and 19 from the collar 17. Once the split ring is removed, the drive arm 12 detach the riser blade from the main body 11. The different parts of the riser blade 10 can then be transported separately through a small tunnel or aisle. When the riser blade 10 is to be connected to the drive arm, the drive arm 12 is placed inside the blade body through the collar 7 64836 17. The split ring portions 18 and 19 are placed around the lower end of the drive arm 12 and the drive arm 12 and the split ring are moved upwardly inside the collar 17. The plate portion 21 is placed in contact with the flange 20 and the bolts 22 and 23 are connected to the respective threaded recesses 32 and 33. Tightening bolts 22 and 23 applies a preload to the system. The riser blade 10 is ready for operation again.

If the drive arm 12 is damaged before the main blade body 11 of the riser blade is damaged, the drive arm can be removed from the main body 11 of the riser blade and a new drive arm can be replaced. The bolts 22 and 23 are removed to disengage the plate portion 21 from the collar 17. The drive arm 12 and split ring portions 18 and 19 are moved downward, disengaging the drive arm 12 from the main blade body 11. The drive arm 12 is removed and a new drive arm is inserted through the collar 17. The split ring portions 18 and 19 are placed around the new drive arm and the new drive arm and split ring portions 18 and 19 are moved upwardly inside the collar 17. The plate portion 21 is placed in contact with a flange 20 at the end of the new drive arm 12, and bolts 22 and 23 are connected to threaded recesses 32 and 33. Tightening the bolts 22 and 23 applies a preload to the system and the riser blade is ready for operation.

Claims (6)

64836 8 A riser blade for enlarging a guide hole to a hole of larger diameter by breaking up the soil formations surrounding the guide hole, the riser blade comprising a blade main body (11) including a plurality of cutters that contact and break up the ground formations surrounding the guide hole and a drive arm (12), releasably mounted inside the central opening of the blade body by means of conical surfaces, characterized in that the main blade body (11) has a central opening with an upwardly tapering conical surface (24), the shaft (12) having a cylindrical non-tapered outer surface which located inside the conical surface (24) at a distance therefrom and terminating at the end provided with the flange (20), between the conical surface (24) and the outer surface of the shaft (12) there are a plurality of detachable gripping parts (18, 19) arranged on the flange so that axial displacement with respect to the shaft is prevented, each gripping part (18, 19) having a conical outer (25, 26) mating with the conical surface (24) and an inner surface (27, 28) mating with the non-tapered surface of the arm (12), and that the preloading device comprising the plate portion (21) , which rests on the flanged end and is axially spaced from the blade body, and means (22, 23) adapted to move the blade body axially relative to the gripping portions are adapted to force the gripping portions (18, 19) into tight wedge engagement with the conical surface (24). the gripping parts (18, 19) can transfer axial and torsional loads from the shaft (12) to the blade body. Lifting blade according to Claim 1, characterized in that the flange (20) at the end of the drive arm (12) contacts the gripping parts (18, 19). Lifting blade according to Claim 2, characterized in that the plate part (21J) therein covers the lower end of the opening in the blade body (11) together with bolts (22, 23) which force the plate part against the flange (20). Lifting blade according to Claim 1, 2 or 3, characterized in that the gripping parts (18, 19) form a two-part ring with a conical outer surface (25, 26). Lifting blade according to one of Claims 1 to 4, characterized in that a plurality of support parts (16) are mounted on the main body (11) of the blade and in that a plurality of rolling cutters (15) are arranged therein. Raising blade according to one of Claims 1 to 5, characterized in that the central opening is made in a collar (17) which is connected to the main body (11) of the blade.