EP2339109B1 - Earth drilling tool and method - Google Patents
Earth drilling tool and method Download PDFInfo
- Publication number
- EP2339109B1 EP2339109B1 EP10196499.7A EP10196499A EP2339109B1 EP 2339109 B1 EP2339109 B1 EP 2339109B1 EP 10196499 A EP10196499 A EP 10196499A EP 2339109 B1 EP2339109 B1 EP 2339109B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- drill bit
- bit portion
- drilling tool
- central
- drive shaft
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Not-in-force
Links
- 238000005553 drilling Methods 0.000 title claims description 64
- 238000000034 method Methods 0.000 title claims description 7
- 230000008878 coupling Effects 0.000 claims description 25
- 238000010168 coupling process Methods 0.000 claims description 25
- 238000005859 coupling reaction Methods 0.000 claims description 25
- 238000011010 flushing procedure Methods 0.000 claims description 12
- 238000009527 percussion Methods 0.000 claims description 8
- 230000013011 mating Effects 0.000 claims description 7
- 230000002093 peripheral effect Effects 0.000 claims description 6
- 239000000463 material Substances 0.000 description 9
- 230000008901 benefit Effects 0.000 description 7
- 238000004519 manufacturing process Methods 0.000 description 7
- 229910000831 Steel Inorganic materials 0.000 description 3
- 230000000712 assembly Effects 0.000 description 3
- 238000000429 assembly Methods 0.000 description 3
- 230000005540 biological transmission Effects 0.000 description 3
- 239000010959 steel Substances 0.000 description 3
- 239000002699 waste material Substances 0.000 description 3
- 230000015572 biosynthetic process Effects 0.000 description 2
- 238000005422 blasting Methods 0.000 description 2
- 238000012423 maintenance Methods 0.000 description 2
- 239000011435 rock Substances 0.000 description 2
- 229910000760 Hardened steel Inorganic materials 0.000 description 1
- 230000004075 alteration Effects 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000001419 dependent effect Effects 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 230000007613 environmental effect Effects 0.000 description 1
- 230000007246 mechanism Effects 0.000 description 1
- 238000005555 metalworking Methods 0.000 description 1
- 230000008569 process Effects 0.000 description 1
- 230000000284 resting effect Effects 0.000 description 1
- 238000003466 welding Methods 0.000 description 1
Images
Classifications
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B7/00—Special methods or apparatus for drilling
- E21B7/20—Driving or forcing casings or pipes into boreholes, e.g. sinking; Simultaneously drilling and casing boreholes
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B10/00—Drill bits
- E21B10/64—Drill bits characterised by the whole or part thereof being insertable into or removable from the borehole without withdrawing the drilling pipe
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B7/00—Special methods or apparatus for drilling
- E21B7/20—Driving or forcing casings or pipes into boreholes, e.g. sinking; Simultaneously drilling and casing boreholes
- E21B7/208—Driving or forcing casings or pipes into boreholes, e.g. sinking; Simultaneously drilling and casing boreholes using down-hole drives
Definitions
- the present invention relates to a drilling tool for down-the-hole drilling, which drilling tool is intended to drill a hole ahead of a following casing tube, the drilling tool comprising a drill assembly which comprises a central pilot drill bit portion, a peripheral ring shaped drill bit portion and a coupling device, said assembly being coupled to a drill string.
- Drilling tools for down the hole drilling are previously known that comprise an assembly of parts forming a central drill bit portion, i.e. a central reusable drill bit portion with a pilot drill, a peripheral ring shaped drill bit portion and a ring shaped coupling device.
- a central drill bit portion i.e. a central reusable drill bit portion with a pilot drill
- a peripheral ring shaped drill bit portion and a ring shaped coupling device are left in the drill hole whereas the central pilot drill bit portion is retracted from the hole together with the drill string and can be reused.
- Known types of drilling tools are seen in EP1402146 , US4773489 , US5803192 and WO9534740 .
- drill bit portions of various types are used.
- the size of the pilot drill bit portion is also varied depending on the desired diameter of the hole to be drilled. For each new circumstance the drill bit portion is switched into one that meets the new requirements, which may often be a time consuming process. If the drill bit portion is worn out it is disposed of and replaced by a new central drill bit portion. This leads to considerable waste of material which is undesirable both from an economical and environmental point of view.
- Another problem related to presently known drilling tools is that production of the large and heavy drill bit portions is associated with a laborious and uneconomical production process. Often an initial large piece of steel material is cut in a metalworking lathe into a desired shape, which often leads to loss of material. During production of drill bit portions it is not uncommon that an initial steel block is reduced from a thickness of 800 mm to a final diameter of 100 mm, meaning a substantial amount of cut away steel is merely thrown as waste.
- a first object of the present invention is to be able to easily exchange the central drill bit portion so that the same drive shaft may be provided with a new pilot drill bit portion whereas the drive shaft itself is reused. This will lead to a number of advantages, such as
- Figs. 1 and 2 the drilling tool according to one embodiment of the invention.
- the shown drilling tool is intended for down-the-hole drilling, wherein a hole is drilled ahead of a following casing tube 13.
- a chuck 12 is coupled to a continuous drill string (not shown), via a hammer unit (not shown) in a casing tube 13, by means of which a drill assembly 10 rotates clockwise in the embodiment illustrated and receives percussion energy from the hammer unit.
- the drill assembly 10 can be assigned percussion energy via a down-the-hole hammer (not shown) or a left-rotating top-hammer coupled in a torsionally rigid manner (not shown).
- the drill string, hammer unit and their parts are of a conventional type and are not shown in the figures.
- the drilling tool 1 comprises a drill assembly 10 which has a central, reusable pilot drill bit portion 2, a peripheral ring shaped disposable ring drill bit portion 4 and a disposable coupling device 3 in the form of a casing shoe.
- the casing shoe 3 is fixed to the casing tube 13 by means of welding 5 (as in known per se).
- the ring drill bit portion 4 has external threads 45 at the top sides which are used to thread it into the casing shoe 3, past the threads on the casing shoe 3, to allow the ring drill bit portion 4 some axial play between the threads 35 and an intermediate edge 36.
- the said assembly 10 is coupled to the drill string, via the chuck 12 , which in turn via internal splines 121 transfer torque to a drive shaft device 9 (via mating splines 98), which releasably interfits with the pilot drill bit portion 2 for transmitting torque from the drill string to the drill assembly 10.
- a drive shaft device 9 via mating splines 98
- the top flange 97 of the drive shaft device has splines to allow the chuck 12 to be moved onto it from above.
- the drive shaft device 9 interfits with the pilot drill bit portion 2 via a central hole 22 within the pilot drill bit portion 2, as will be explained more in detail below.
- the chuck 12 Around the upper part 91 of said drive shaft 9 there is mounted the chuck 12, which in its turn is resting on a ring shaped blast protection unit 15.
- the blast protection ring 15 is interposed between the chuck 12 and the central pilot drill bit portion 2.
- the chuck 12 is arranged with outer threads and an edge 121 for interfit with the casing of the hammer (not shown). The blows from the hammer hit on the top 99 of the drive shaft device 9 .
- the chuck 12 is arranged to axially slide along the splines 98 and also as a concequence along the cylindrical surface of the drive shaft below the splines 98. As known per se coupling halves (not shown), blocked by the upper edge 97 keep the chuck 12 safely in place together with the drive shaft device 9.
- a flushing medium such as pressurized air
- a flushing medium such as pressurized air
- Any by drilling loosened matter/gravel is activated by the onset of flushing medium and is removed from the drill hole through longitudinal flushing grooves 21 (see Fig. 3-4 ) on the outer side of the pilot drill bit portion 2. This results in a blasting stream of drilled loose matter which exits flushing grooves 21 in an upward direction.
- said blast protecting ring 15 is positioned adjacent to the opening of the flushing grooves 21 so that the blasted matter will hit the surface of said ring 15 instead of hitting the guide body 12 thus protecting it from wear which is advantageous since the guide body 12 is made of a more expensive material compared to the ring 15 unit.
- the blast protecting ring 15 is made of a hardened steel material which will resist the heavy onset of blasting matter/gravel. When worn out the ring 15 is very easily exchanged into a new one.
- the ring 15 preferably has a tapered cross section with a narrow base abutting the top part of the pilot drill bit portion 2 and the wider portion abutting the guide body 12. The tapered shape leads to that the flushed matter/gravel is guided outwards and upwards and is transported along the inner walls of the casing tube 13.
- the releasable connection between the drive shaft 9 and the pilot drill bit portion 2 is preferably achieved in two ways cooperating with each other. First in that a number of connecting bits 16 torsionally interconnect the two units 2, 9, and second in that at least one locking ball 250 is positioned within circumferential recesses 25, 95 preventing the drive shaft 9 from being retracted out of the central hole 22 (see Fig. 3 ) of the pilot drill bit portion 2.
- the connection between the drive shaft 9 and the pilot drill bit portion 2 will be described in more detail in connection to Fig. 2 , Fig. 4B and Fig. 8 - 9 .
- the second axial coupling may be achieved in other ways than by means of a locking ball, for instance by means of a locking pin or the like preventing axial retraction.
- the present design of a drilling tool 1 leads to that only the pilot drill bit portion 2 may be exchanged by reusing the same drive shaft device 9, which provides many advantages, e.g. cost advantages (smaller part leads to less material and easier production) and easier maintenance. Thanks to the invention it is possible to use modular design and subdivide the components of a drilling tool into modular units which may be combined in a highly flexible way into a desired drilling tool 1. This also leads to less heavy exchange part and easier accessible releasable connection.
- Fig. 2 shows an exploded view of one embodiment according to the invention.
- the drive shaft 9 has an upper 91 and a lower 92 portion, where the lower portion is intended to be introduced into the central hole 22 (see Fig. 3 ) of the pilot drill bit portion 2.
- the drive shaft is provided with a number of longitudinal recesses 93, preferably three outer recesses 93, which are symmetrically arranged around the outer surface of the drive shaft 9.
- Each recess matches a removable connecting bit 16.
- the central hole 22 of the pilot drill bit portion 2 comprises a number of inner recesses 23, preferably the same number of inner recesses 23 as there are outer recesses 93 within the drive shaft 9, that is, in the embodiment of Fig.
- connecting bits 16 and inner recesses 23 respectively can be more than three, depending on the required torque momentum transmission of a particular drilling assembly 1. For larger drilling assemblies as many as twelve connecting bits 16 may be necessary in order to achieve a strong enough torque transmitting coupling, whereas for medium type assemblies six or eight may be enough.
- a connecting bit 16 is positioned within each of said recesses 93 so that each bit 16 is partly projecting radially out from the drive shaft 9.
- the arrangement according to the invention 1 comprises retaining means or a retaining mechanism for at least temporarily retaining the connecting bits 16 within the matching recesses 93 of the drive shaft 9.
- the connecting bits 16 will remain positioned within the recessed until being removed, which may for instance be done manually. Retaining of the connecting bits 16 may be achieved in many different ways, for example with of one or more O-rings being introduced around the plurality of connecting bits 16 keeping them in place.
- each of the connecting bits 16 is arranged with an outer radius, and in a corresponding manner each of said inner recesses 23 has an inner radius mating the outer radius of said connecting bit 16.
- the radial mating surfaces of the connecting bits 16 and the inner recesses 23 respectively leads to a firm connection between the drive shaft 9 and the drill bit portion 2 where torque is transmitted from the drive shaft 9 to the drill bit 2 over the entire radius of the connecting bit 16, leading to a very effective transfer of forces and also to a significantly improved mechanical sustainability compared to known drilling tools.
- a benefit of the releasable connecting bits 16 is that they are easily replaceable when worn out, leading to that by means of just shifting minor components of the connection its lifetime may be extended thus postponing the need for replacing the whole drive shaft 9, which obviously is expensive and leads to undesired waste of materials.
- the drive shaft 9 further comprises an outer circumferential recess 95.
- the outer recess 95 Upon introduction of the drive shaft 9 into the central hole 22 of the pilot drill bit portion 2 the outer recess 95 is arranged to be positioned to face an inner circumferential recess 25 within the central hole 22 of the pilot drill bit portion 2 (see Fig. 4B ) thus jointly creating a kind of inner annular groove 25, 95.
- one or more locking balls 250 are put through a radial bore inlet 251 within the drill bit portion 2, leading to the circumferential groove 25, 95, which allows the balls 250 to interconnect the drive shaft 9 and the pilot drill bit portion 2 in the axial direction, but with some play to not cause damage to the balls 250 upon blows from the hammer.
- the inlet 251 is arranged with a releasable plug (not shown) that extends into the periphery of the recess 25 to safety position the balls 250 within the groove 25, 95.
- a particular advantage provided by the present invention relates to that threaded connections between the releasable components 2, 4; 2, 9 of the drilling tool 1 are essentially avoided. Threaded connections are often very hard to release after a drilling operation, whereas the couplings according to the invention on the contrary are quite easy to loosen.
- Fig. 3 shows a perspective view of a pilot drill bit portion 2 according to one embodiment of the invention with said central hole 22 and inner recesses 23 dimensioned to match the connecting bits 16.
- the pilot drill bit portion 2 is further provided with a number (here three) of outer flushing grooves 21 which function as transporting channels for drilled matter and gravel out of the drilled hole.
- the lower part of the pilot drill bit portion 2 comprises protrusions 24 intended for connecting the pilot drill bit portion 2 to the ring drill bit portion 4 (see Figs. 7A-B ).
- the upper portion of the pilot drill bit portion 2 comprises a first 27 and a second 28 flange which function will be more described later.
- Figs. 4A-B show the underside, a cross section and the upper side of a pilot drill bit portion 2 respectively.
- the lower drill surface 29 has openings of said flushing channels 26, the diameter of which is adapted to the desired flushing medium and/or flow quantity.
- a first 27 and a second flange 28 are arranged at the upper part of the pilot drill bit portion 2 resulting in a first 270 and a second meeting edge 280. These edges assist in transferring the percussion energy that via the top 99 is transferred to the bottom 97 of the drive shaft device 9 and there from partly transferred to the ring drill bit portion 4 .
- the task of the first meeting edge 270 is to abut the top edge 30 of casing shoe 3.
- the second meeting edge 280 is intended to meet and abut a inner top edge 443 of the ring drill bit portion 4 (as is also seen in Fig. 1B ).
- the described design with double flanges 27, 28 on the pilot drill bit portion 2 leads to the advantage of substantially reduced wear on the equipment compared to a design with one flange, since percussion energy is absorbed by two pairs of meeting edges instead of one.
- the percussion energy will first be transferred to the central drill bit portion 2, some of which will directly act at its drill face 29, and some that via first edge 270, further via its intermediate edge 36 to an outer top edge 42 of the ring drill bit portion 4, and further some that via the second edge 280 will be transferred to the inner top edge 43 of the ring drill bit portion 4.
- percussion energy is transferred from the drill bit portion 2 to the ring drill bit portion 4 at two radially off-set positions/edges 42, 43. Accordingly in total a large transfer area is obtained, which is even increased by having tapered mating surfaces 43/280; 42/36.
- the design of the assembly 10 results in that the backward recoil energy created during drilling operation will be effectively absorbed by the components of the drill assembly 10. Upon kickback, recoil energy will be transferred from the pilot drill bit portion 2 via the connecting protrusions 24 to the casing shoe 4, and there from to the lower end surface 36 of the ring bit portion 3. Also this design will lead to substantially reduced wear and tear on the drilling tools.
- FIGs. 5 and 6 showing perspective views of the blast protecting ring 15 and the drive shaft device 9 respectively.
- the blast protecting ring 15 is tapered with a lower narrow end 150 and a wider upper end 151, where the diameter of the wider end preferably corresponds to the outer diameter of the lower end of the chuck 12.
- the perspective view of the drive shaft device 9 further shows the central flushing channel 94 intended for flushing of medium.
- Figs. 7A-B are seen the ring drill bit portion 4 according to a preferred embodiment.
- the ring drill bit portion 4 comprises a number of connecting grooves 40 which matches the connection protrusions 24 of the pilot drill bit portion 2.
- the protrusions 24 are introduced into the grooves 40, until edges 280 and 43 meet, and the parts 2,4 are then turned so that relative to each other the protrusions 24 are fit into a recess 44 arranged at the bottom of each groove 40.
- the recesses 44 are positioned for right-hand rotation (seen from above) intended for the protrusions 24.
- the recesses 44 shall be positioned in a mirror-image position compared to Fig. 7A .
- the drill string is turned the opposite direction, so that the protrusions 24 of the pilot drill bit portion 2 are released/moved out from the recesses 44, whereby the drill string with shaft device 9 and pilot drill bit portion 2 is free to lift upwards from the ring drill bit portion 4 which is left in the drilled hole together with said casing shoe 3.
- a drive shaft device 9 according to another embodiment of the invention.
- Fig. 8A showing a perspective view of a drive shaft 9, there is seen that the component has a first upper end 91 and a second lower end 92, whereat in said upper end 91 there is arranged a top flange 97 arranged to keep the chuck 12 safely in place together with the drive shaft device 9.
- a protruding flange 920 ensures that the drill shaft 9 when connected to a drill bit portion 2 is introduced into the drill bit portion 2 to the right extent and is positioned correctly in order for the outer recess 95 and the inner circumferential recess 25 within the central hole 22 of the pilot drill bit portion to meet and jointly creating a kind of inner annular groove 25, 95.
- the embodiment seen in Fig. 8A comprises in its lower end 92 a plurality of elongated connecting members 96 fixedly arranged onto and forming an integrated part of the drive shaft device 9.
- the connecting members 96 may be fixedly attached onto the drive shaft 9 or they may be cut out during the production of the drive shaft 9.
- Each of the connecting members 96 is formed with an outer radius, similar to the releasable connecting bits 16 previously described, and are arranged to match with inner recesses 23 of a mating drill bit portion 2 (see Fig. 9A - B ).
- FIG. 8B there is shown an end view of the drill shaft 9 of Fig. 8A , exposing the central through hole 94.
- the plurality of connecting members 96 circumferentially distributed around the lower end 92 of a drill shaft 9.
- the connecting members 96 are evenly positioned around the circumference of the shaft 9 in order to achieve a balanced torque transmission upon operation.
- the shaft 9 comprises eight connecting members 96, whereat two neighbouring connecting members 96 are arranged with an angle ⁇ in between as is illustrated in Fig. 8B .
- ⁇ is the same for all connecting members 96, meaning in this example (i.e. eight members 96) ⁇ equals 45°.
- connecting members 96 are also possible meaning that also angle ⁇ will vary.
- angle ⁇ will vary.
- the drilling assembly 10 may be used for a variety of sizes of drilling equipment.
- Fig. 8B shows the diameter D of the lower end 92 of the drill shaft 9.
- the diameter D may be between 50 - 250 mm depending on the size of the pilot drill bit portion 2 to be coupled to the drill shaft 9.
- the size of the pilot drill bit portion 2 will determine the size of the hole to be drilled, and the drill bit portion 2 in its turn must be adapted to the size of the casing tube 13.
- An advantageous aspect of the present invention is that one type of drill shaft 9 can be used for connecting many different types (e.g. sizes) of pilot drill bit portions 2, meaning that the drilling equipment is easily and quickly adapted to different types of drilling operations (e.g. in order to handle different typed of holes and different types of grounds respectively).
- the assembly 10 can cover a wide variety of different sizes of drilling tools 1, meaning for instance when a certain type of drill shaft 9 is too small to handle a given drill bit portion 2 changing of the shaft 9 into a larger one enables further operation with said drill bit portion 2 (providing that the casing tube 13 is also compatible, as is obvious to the skilled person).
- Fig. 9A there is seen a perspective view of a pilot drill bit portion 2 according to another embodiment of the invention, arranged to mate with and be connected to a drill shaft 9 as the one shown in Fig. 9A-B .
- Fig. 9B there is seen a cross sectional view along line IXB in Fig. 9A .
- the lower end 92 portion of a drill shaft 9 is arranged to be introduced into the central opening 22 of the drill bit portion 2 to achieve a torque coupling.
- Axial coupling is achieved by means of for instance a ball lock arrangement.
- the inner recesses 23 of the drill bit portion 2 are arranged with an inner radius mating the outer radius of said connecting members 96 so that a firm connection between the connecting members 96 and the inner recesses 23 is achieved resulting in an excellent torque momentum transmission over the entire radius surface.
- the size of the drill bit portion 2 will determine the size of the hole to be drilled.
- Various dimensions of drill bits 2 can be used in a drilling tool 1 according to the invention, and the diameter d of the drill bits 2 may vary between 90 - 610 mm for different types of drill bits 2. Thanks to the invention it is possible to rather easily adapt the equipment to handling different types of drilling, by providing a plurality of central pilot drill bit portions 2 (including at least two different drill bit portions 2) and exchange of one central drill bit portion 2 to a different kind.
- a check valve device 6 may be used to hinder dirt (pressurized) to enter into the hammer device during stand still.
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- Mining & Mineral Resources (AREA)
- Physics & Mathematics (AREA)
- Environmental & Geological Engineering (AREA)
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Description
- The present invention relates to a drilling tool for down-the-hole drilling, which drilling tool is intended to drill a hole ahead of a following casing tube, the drilling tool comprising a drill assembly which comprises a central pilot drill bit portion, a peripheral ring shaped drill bit portion and a coupling device, said assembly being coupled to a drill string.
- Drilling tools for down the hole drilling are previously known that comprise an assembly of parts forming a central drill bit portion, i.e. a central reusable drill bit portion with a pilot drill, a peripheral ring shaped drill bit portion and a ring shaped coupling device. When a hole is done the peripheral ring shaped drill bit portion and the ring shaped coupling device are left in the drill hole whereas the central pilot drill bit portion is retracted from the hole together with the drill string and can be reused. Known types of drilling tools are seen in
EP1402146 ,US4773489 ,US5803192 andWO9534740 - Depending on the type of ground to be drilled (e.g. soft, medium or hard formation rock) different drill bit portions of various types are used. The size of the pilot drill bit portion is also varied depending on the desired diameter of the hole to be drilled. For each new circumstance the drill bit portion is switched into one that meets the new requirements, which may often be a time consuming process. If the drill bit portion is worn out it is disposed of and replaced by a new central drill bit portion. This leads to considerable waste of material which is undesirable both from an economical and environmental point of view.
- Another problem related to presently known drilling tools is that production of the large and heavy drill bit portions is associated with a laborious and uneconomical production process. Often an initial large piece of steel material is cut in a metalworking lathe into a desired shape, which often leads to loss of material. During production of drill bit portions it is not uncommon that an initial steel block is reduced from a thickness of 800 mm to a final diameter of 100 mm, meaning a substantial amount of cut away steel is merely thrown as waste.
- It is an object of the present invention to overcome or at least minimize at least one of the drawbacks and disadvantages of the above described known drilling tools.
- A first object of the present invention is to be able to easily exchange the central drill bit portion so that the same drive shaft may be provided with a new pilot drill bit portion whereas the drive shaft itself is reused. This will lead to a number of advantages, such as
- reduced material consumption (i.e. only the actual pilot drill portion of the drilling tool which is subject to wear and tear is exchanged while the drive shaft is reused),
- the possibility of easily switching between differently dimensioned pilot drill portions enabling for quick adjustments of the equipment for drilling different types of holes and different types of ground (e.g. soft, medium or hard formation rock),
- easier manufacturing of the drilling tool due to that the smaller units of the invented tool can be produced with less material consumption compared to production of one large central drill bit portion as is known prior art,
- easier maintenance due to smaller and less heavy parts.
- This and other objects, which are obvious to the expert, have been able to be realized in a surprising manner by designing the drilling tool in accordance with the characterizing part of
claim 1. Preferred embodiments of the invented drilling tool are defined in the dependent claims. - The invention will be described in more detail with reference to the enclosed figures, in which:
- Fig. 1A
- is an elevational view of the lower portion of a drilling tool according to one embodiment of the invention,
- Fig. 1B
- is a vertical cross sectional view of the lower portion of the drilling tool shown in
Fig. 1A , - Fig. 2
- is an exploded view showing a drilling tool according to one embodiment of the invention,
- Fig. 3
- is a perspective view showing the central pilot drill bit portion according to one embodiment of the invention,
- Figs. 4A-C
- show different views of the central pilot drill bit portion shown in
Fig. 3 , - Fig. 5
- is a perspective view showing the blast protection ring according to one embodiment of the invention,
- Fig. 6
- is a perspective view showing the drill shaft according the one embodiment of the invention,
- Figs. 7A-B
- show different views of the casing shoe according to one embodiment of the invention,
- Fig. 8A
- is a perspective view showing the drill shaft according the another embodiment of the invention,
- Fig. 8B
- shows an end view of the drill shaft shown in
Fig. 8A , - Fig. 9A
- is a perspective view showing a central pilot drill bit portion according to another embodiment of the invention, and
- Fig. 9B
- is a cross sectional view of the central pilot drill bit portion in
Fig. 9A . - The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings. Further, the description, and the examples contained therein, are provided for the purpose of describing and illustrating certain embodiments of the invention only and are not intended to limit the scope of the invention in any way.
- In
Figs. 1 and2 is shown the drilling tool according to one embodiment of the invention. The shown drilling tool is intended for down-the-hole drilling, wherein a hole is drilled ahead of a followingcasing tube 13. As is known per se achuck 12 is coupled to a continuous drill string (not shown), via a hammer unit (not shown) in acasing tube 13, by means of which adrill assembly 10 rotates clockwise in the embodiment illustrated and receives percussion energy from the hammer unit. Thedrill assembly 10 can be assigned percussion energy via a down-the-hole hammer (not shown) or a left-rotating top-hammer coupled in a torsionally rigid manner (not shown). The drill string, hammer unit and their parts are of a conventional type and are not shown in the figures. - The
drilling tool 1 comprises adrill assembly 10 which has a central, reusable pilotdrill bit portion 2, a peripheral ring shaped disposable ringdrill bit portion 4 and adisposable coupling device 3 in the form of a casing shoe. Thecasing shoe 3 is fixed to thecasing tube 13 by means of welding 5 (as in known per se). The ringdrill bit portion 4 hasexternal threads 45 at the top sides which are used to thread it into thecasing shoe 3, past the threads on thecasing shoe 3, to allow the ringdrill bit portion 4 some axial play between thethreads 35 and anintermediate edge 36. According to the invention the saidassembly 10 is coupled to the drill string, via thechuck 12 , which in turn viainternal splines 121 transfer torque to a drive shaft device 9 (via mating splines 98), which releasably interfits with the pilotdrill bit portion 2 for transmitting torque from the drill string to thedrill assembly 10. (Also thetop flange 97 of the drive shaft device has splines to allow thechuck 12 to be moved onto it from above.) - The
drive shaft device 9 interfits with the pilotdrill bit portion 2 via acentral hole 22 within the pilotdrill bit portion 2, as will be explained more in detail below. Around theupper part 91 of saiddrive shaft 9 there is mounted thechuck 12, which in its turn is resting on a ring shapedblast protection unit 15. Theblast protection ring 15 is interposed between thechuck 12 and the central pilotdrill bit portion 2. As is known per se thechuck 12 is arranged with outer threads and anedge 121 for interfit with the casing of the hammer (not shown). The blows from the hammer hit on the top 99 of thedrive shaft device 9 . Thechuck 12 is arranged to axially slide along thesplines 98 and also as a concequence along the cylindrical surface of the drive shaft below thesplines 98. As known per se coupling halves (not shown), blocked by theupper edge 97 keep thechuck 12 safely in place together with thedrive shaft device 9. - As is common knowledge, upon drilling a flushing medium (such as pressurized air) is supplied through the central through
hole 94 of theshaft 9 and further via flushingchannels 26, 26' within the pilotdrill bit portion 2. Any by drilling loosened matter/gravel is activated by the onset of flushing medium and is removed from the drill hole through longitudinal flushing grooves 21 (seeFig. 3-4 ) on the outer side of the pilotdrill bit portion 2. This results in a blasting stream of drilled loose matter which exits flushinggrooves 21 in an upward direction. According to the invention saidblast protecting ring 15 is positioned adjacent to the opening of the flushinggrooves 21 so that the blasted matter will hit the surface of saidring 15 instead of hitting theguide body 12 thus protecting it from wear which is advantageous since theguide body 12 is made of a more expensive material compared to thering 15 unit. Preferably theblast protecting ring 15 is made of a hardened steel material which will resist the heavy onset of blasting matter/gravel. When worn out thering 15 is very easily exchanged into a new one. As is seen inFig. 1B thering 15 preferably has a tapered cross section with a narrow base abutting the top part of the pilotdrill bit portion 2 and the wider portion abutting theguide body 12. The tapered shape leads to that the flushed matter/gravel is guided outwards and upwards and is transported along the inner walls of thecasing tube 13. - The releasable connection between the
drive shaft 9 and the pilotdrill bit portion 2 is preferably achieved in two ways cooperating with each other. First in that a number of connectingbits 16 torsionally interconnect the twounits locking ball 250 is positioned withincircumferential recesses drive shaft 9 from being retracted out of the central hole 22 (seeFig. 3 ) of the pilotdrill bit portion 2. The connection between thedrive shaft 9 and the pilotdrill bit portion 2 will be described in more detail in connection toFig. 2 ,Fig. 4B andFig. 8 - 9 . The second axial coupling may be achieved in other ways than by means of a locking ball, for instance by means of a locking pin or the like preventing axial retraction. - The present design of a
drilling tool 1 leads to that only the pilotdrill bit portion 2 may be exchanged by reusing the samedrive shaft device 9, which provides many advantages, e.g. cost advantages (smaller part leads to less material and easier production) and easier maintenance. Thanks to the invention it is possible to use modular design and subdivide the components of a drilling tool into modular units which may be combined in a highly flexible way into a desireddrilling tool 1. This also leads to less heavy exchange part and easier accessible releasable connection. -
Fig. 2 shows an exploded view of one embodiment according to the invention. Thedrive shaft 9 has an upper 91 and a lower 92 portion, where the lower portion is intended to be introduced into the central hole 22 (seeFig. 3 ) of the pilotdrill bit portion 2. At thelower portion 92 the drive shaft is provided with a number oflongitudinal recesses 93, preferably threeouter recesses 93, which are symmetrically arranged around the outer surface of thedrive shaft 9. Each recess matches a removable connectingbit 16. As is shown inFig. 3 thecentral hole 22 of the pilotdrill bit portion 2 comprises a number ofinner recesses 23, preferably the same number ofinner recesses 23 as there areouter recesses 93 within thedrive shaft 9, that is, in the embodiment ofFig. 2 and 3 a number of three. The skilled person understands that the number of connectingbits 16 andinner recesses 23 respectively can be more than three, depending on the required torque momentum transmission of aparticular drilling assembly 1. For larger drilling assemblies as many as twelve connectingbits 16 may be necessary in order to achieve a strong enough torque transmitting coupling, whereas for medium type assemblies six or eight may be enough. - The coupling of a
drive shaft 9 and a pilotdrill bit portion 2 is now to be described.
A connectingbit 16 is positioned within each of said recesses 93 so that eachbit 16 is partly projecting radially out from thedrive shaft 9. Preferably the arrangement according to theinvention 1 comprises retaining means or a retaining mechanism for at least temporarily retaining the connectingbits 16 within the matching recesses 93 of thedrive shaft 9. Thus when disconnecting thedrive shaft 9 from a pilotdrill bit portion 2 the connectingbits 16 will remain positioned within the recessed until being removed, which may for instance be done manually. Retaining of the connectingbits 16 may be achieved in many different ways, for example with of one or more O-rings being introduced around the plurality of connectingbits 16 keeping them in place. It is also possible to provide some sort of mechanical formfitting between the connectingbits 16 and therecesses 93, for instance matching protrusions and grooves, having an engaging effect. Thedrive shaft 9 is introduced into thecentral hole 22 of the pilotdrill bit portion 2. Upon introduction of thedrive shaft 9 the protruding connectingbits 16 are positioned to slide into theinner recesses 23 resulting in a torsional connection/coupling between thedrive shaft 9 and the pilotdrill bit portion 2. According to a preferred aspect of the invention the outer surface of each of the connectingbits 16 is arranged with an outer radius, and in a corresponding manner each of saidinner recesses 23 has an inner radius mating the outer radius of said connectingbit 16. The radial mating surfaces of the connectingbits 16 and theinner recesses 23 respectively leads to a firm connection between thedrive shaft 9 and thedrill bit portion 2 where torque is transmitted from thedrive shaft 9 to thedrill bit 2 over the entire radius of the connectingbit 16, leading to a very effective transfer of forces and also to a significantly improved mechanical sustainability compared to known drilling tools. - A benefit of the releasable connecting
bits 16 is that they are easily replaceable when worn out, leading to that by means of just shifting minor components of the connection its lifetime may be extended thus postponing the need for replacing thewhole drive shaft 9, which obviously is expensive and leads to undesired waste of materials. - The
drive shaft 9 further comprises an outercircumferential recess 95. Upon introduction of thedrive shaft 9 into thecentral hole 22 of the pilotdrill bit portion 2 theouter recess 95 is arranged to be positioned to face an innercircumferential recess 25 within thecentral hole 22 of the pilot drill bit portion 2 (seeFig. 4B ) thus jointly creating a kind of innerannular groove drive shaft 9 and the pilotdrill bit portion 2 in an axial direction one ormore locking balls 250 are put through aradial bore inlet 251 within thedrill bit portion 2, leading to thecircumferential groove balls 250 to interconnect thedrive shaft 9 and the pilotdrill bit portion 2 in the axial direction, but with some play to not cause damage to theballs 250 upon blows from the hammer. After supply of theballs 250 theinlet 251 is arranged with a releasable plug (not shown) that extends into the periphery of therecess 25 to safety position theballs 250 within thegroove - A particular advantage provided by the present invention relates to that threaded connections between the
releasable components drilling tool 1 are essentially avoided. Threaded connections are often very hard to release after a drilling operation, whereas the couplings according to the invention on the contrary are quite easy to loosen. -
Fig. 3 shows a perspective view of a pilotdrill bit portion 2 according to one embodiment of the invention with saidcentral hole 22 andinner recesses 23 dimensioned to match the connectingbits 16. The pilotdrill bit portion 2 is further provided with a number (here three) ofouter flushing grooves 21 which function as transporting channels for drilled matter and gravel out of the drilled hole. The lower part of the pilotdrill bit portion 2 comprisesprotrusions 24 intended for connecting the pilotdrill bit portion 2 to the ring drill bit portion 4 (seeFigs. 7A-B ). - According to a preferred embodiment the upper portion of the pilot
drill bit portion 2 comprises a first 27 and a second 28 flange which function will be more described later. - Referring now to
Figs. 4A-B which show the underside, a cross section and the upper side of a pilotdrill bit portion 2 respectively. Thelower drill surface 29 has openings of saidflushing channels 26, the diameter of which is adapted to the desired flushing medium and/or flow quantity. As is clear fromFig. 4B a first 27 and asecond flange 28 are arranged at the upper part of the pilotdrill bit portion 2 resulting in a first 270 and asecond meeting edge 280. These edges assist in transferring the percussion energy that via the top 99 is transferred to the bottom 97 of thedrive shaft device 9 and there from partly transferred to the ringdrill bit portion 4 . The task of thefirst meeting edge 270 is to abut thetop edge 30 ofcasing shoe 3. Likewise, thesecond meeting edge 280 is intended to meet and abut a inner top edge 443 of the ring drill bit portion 4 (as is also seen inFig. 1B ). During drilling operation the described design withdouble flanges drill bit portion 2 leads to the advantage of substantially reduced wear on the equipment compared to a design with one flange, since percussion energy is absorbed by two pairs of meeting edges instead of one. Hence, the percussion energy will first be transferred to the centraldrill bit portion 2, some of which will directly act at itsdrill face 29, and some that viafirst edge 270, further via itsintermediate edge 36 to an outertop edge 42 of the ringdrill bit portion 4, and further some that via thesecond edge 280 will be transferred to the innertop edge 43 of the ringdrill bit portion 4. - Hence, percussion energy is transferred from the
drill bit portion 2 to the ringdrill bit portion 4 at two radially off-set positions/edges 42, 43. Accordingly in total a large transfer area is obtained, which is even increased by having tapered mating surfaces 43/280; 42/36. - Another beneficial aspect of the invention is that the design of the assembly 10 (i.e. the meeting surfaces) results in that the backward recoil energy created during drilling operation will be effectively absorbed by the components of the
drill assembly 10. Upon kickback, recoil energy will be transferred from the pilotdrill bit portion 2 via the connectingprotrusions 24 to thecasing shoe 4, and there from to thelower end surface 36 of thering bit portion 3. Also this design will lead to substantially reduced wear and tear on the drilling tools. - As is seen in the cross sectional view in
Fig. 4B there is aradial bore 251 for the lockingballs 250, adapted to the diameter of theradial recess 25. - For clarifying reasons are provided
Figs. 5 and 6 showing perspective views of theblast protecting ring 15 and thedrive shaft device 9 respectively. Theblast protecting ring 15 is tapered with a lowernarrow end 150 and a widerupper end 151, where the diameter of the wider end preferably corresponds to the outer diameter of the lower end of thechuck 12. - The perspective view of the
drive shaft device 9 further shows thecentral flushing channel 94 intended for flushing of medium. - In
Figs. 7A-B are seen the ringdrill bit portion 4 according to a preferred embodiment. When shown from above, as inFig. 7A , it is seen that the ringdrill bit portion 4 comprises a number of connectinggrooves 40 which matches theconnection protrusions 24 of the pilotdrill bit portion 2. Theprotrusions 24 are introduced into thegrooves 40, untiledges parts protrusions 24 are fit into arecess 44 arranged at the bottom of eachgroove 40. Here therecesses 44 are positioned for right-hand rotation (seen from above) intended for theprotrusions 24. In case of a drilling tool with a left-hand rotation therecesses 44 shall be positioned in a mirror-image position compared toFig. 7A . When the drilling operation is completed the drill string is turned the opposite direction, so that theprotrusions 24 of the pilotdrill bit portion 2 are released/moved out from therecesses 44, whereby the drill string withshaft device 9 and pilotdrill bit portion 2 is free to lift upwards from the ringdrill bit portion 4 which is left in the drilled hole together with saidcasing shoe 3. - In
Fig. 8A - B is shown adrive shaft device 9 according to another embodiment of the invention. InFig. 8A , showing a perspective view of adrive shaft 9, there is seen that the component has a firstupper end 91 and a secondlower end 92, whereat in saidupper end 91 there is arranged atop flange 97 arranged to keep thechuck 12 safely in place together with thedrive shaft device 9. A protrudingflange 920 ensures that thedrill shaft 9 when connected to adrill bit portion 2 is introduced into thedrill bit portion 2 to the right extent and is positioned correctly in order for theouter recess 95 and the innercircumferential recess 25 within thecentral hole 22 of the pilot drill bit portion to meet and jointly creating a kind of innerannular groove
The embodiment seen inFig. 8A comprises in its lower end 92 a plurality of elongated connectingmembers 96 fixedly arranged onto and forming an integrated part of thedrive shaft device 9. The connectingmembers 96 may be fixedly attached onto thedrive shaft 9 or they may be cut out during the production of thedrive shaft 9. Each of the connectingmembers 96 is formed with an outer radius, similar to the releasable connectingbits 16 previously described, and are arranged to match withinner recesses 23 of a mating drill bit portion 2 (seeFig. 9A - B ). - In
Fig. 8B there is shown an end view of thedrill shaft 9 ofFig. 8A , exposing the central throughhole 94. Herein is seen the plurality of connectingmembers 96 circumferentially distributed around thelower end 92 of adrill shaft 9. Preferably the connectingmembers 96 are evenly positioned around the circumference of theshaft 9 in order to achieve a balanced torque transmission upon operation. In this example theshaft 9 comprises eight connectingmembers 96, whereat two neighbouring connectingmembers 96 are arranged with an angle α in between as is illustrated inFig. 8B . Preferably α is the same for all connectingmembers 96, meaning in this example (i.e. eight members 96) α equals 45°. However other numbers of connectingmembers 96 are also possible meaning that also angle α will vary. For larger drilling equipment (i.e. larger pilot drill bits 2) as many as twelve connectingmembers 96 might be necessary for attaining enough strength in the torque coupling, whereas a lesser number may suffice forsmaller drilling assemblies 10. - The
drilling assembly 10 according to the invention may be used for a variety of sizes of drilling equipment.Fig. 8B shows the diameter D of thelower end 92 of thedrill shaft 9. The diameter D may be between 50 - 250 mm depending on the size of the pilotdrill bit portion 2 to be coupled to thedrill shaft 9. The size of the pilotdrill bit portion 2 will determine the size of the hole to be drilled, and thedrill bit portion 2 in its turn must be adapted to the size of thecasing tube 13. An advantageous aspect of the present invention is that one type ofdrill shaft 9 can be used for connecting many different types (e.g. sizes) of pilotdrill bit portions 2, meaning that the drilling equipment is easily and quickly adapted to different types of drilling operations (e.g. in order to handle different typed of holes and different types of grounds respectively). By also being able to exchange thepilot drill bit 9 theassembly 10 according to the invention can cover a wide variety of different sizes ofdrilling tools 1, meaning for instance when a certain type ofdrill shaft 9 is too small to handle a givendrill bit portion 2 changing of theshaft 9 into a larger one enables further operation with said drill bit portion 2 (providing that thecasing tube 13 is also compatible, as is obvious to the skilled person). - In
Fig. 9A there is seen a perspective view of a pilotdrill bit portion 2 according to another embodiment of the invention, arranged to mate with and be connected to adrill shaft 9 as the one shown inFig. 9A-B . InFig. 9B there is seen a cross sectional view along line IXB inFig. 9A . In a corresponding manner to what's previously been described thelower end 92 portion of adrill shaft 9 is arranged to be introduced into thecentral opening 22 of thedrill bit portion 2 to achieve a torque coupling. Axial coupling is achieved by means of for instance a ball lock arrangement. Theinner recesses 23 of thedrill bit portion 2 are arranged with an inner radius mating the outer radius of said connectingmembers 96 so that a firm connection between the connectingmembers 96 and theinner recesses 23 is achieved resulting in an excellent torque momentum transmission over the entire radius surface. - As is well understood by the skilled person the size of the
drill bit portion 2 will determine the size of the hole to be drilled. Various dimensions ofdrill bits 2 can be used in adrilling tool 1 according to the invention, and the diameter d of thedrill bits 2 may vary between 90 - 610 mm for different types ofdrill bits 2. Thanks to the invention it is possible to rather easily adapt the equipment to handling different types of drilling, by providing a plurality of central pilot drill bit portions 2 (including at least two different drill bit portions 2) and exchange of one centraldrill bit portion 2 to a different kind. - It is understood that the objects of the present invention set forth above, among those made apparent by the detailed description, shall be interpreted as illustrative and not in a limiting sense. Within the scope of the following claims the set-up of various alterations of the present invention may be possible. For instance, for the skilled person it is evident that there exist a big variety of different solutions to achieve the couplings used between the
drive shaft device 9 and the pilotdrill bit portion 2, e.g. to achieve the axial coupling, by means of bores and pins (as known per se), or plate formed segments fitting into corresponding recesses, etc. Likewise the releasable torque coupling can be achieved in many different ways, e.g. by the use of splines, etc. Further it is also feasible to achieve the coupling by having a threaded connection between thedrive shaft device 9 and the pilotdrill bit portion 2. Further it is foreseen that a check valve device 6 (seefig 1 ) may be used to hinder dirt (pressurized) to enter into the hammer device during stand still.
Claims (16)
- Drilling tool for down-the-hole drilling, which drilling tool is arranged to drill a hole ahead of a following casing tube (13), the drilling tool comprising a drill assembly (10) which comprises a central pilot drill bit (2, 9), a casing shoe (3) and an outer peripheral ring shaped drill bit portion (3, 4) releasably attached to said central pilot drill bit (2, 9), said assembly (10) being coupled to a drill string, characterized in that the central pilot drill bit (2), comprises a central pilot drill bit portion (2) and a drive shaft device (9) which are arranged to releasably interfit to transmit torque from the drill string to the drill assembly (10), wherein the drive shaft device (9) has a lower, shaft formed portion (92), which releasably interfits within a central hole (22) of the pilot drill bit portion (2) by means of a first coupling arrangement (16, 96, 23, 93), wherein said shaft formed portion (92) is arranged with connecting members (16, 96) each comprising an outer radius arranged to mate with inner recesses (23) within the central hole (22), each recess (23) comprising an inner radius mating with the outer radius of said connecting members (16, 96), whereby a torque transmitting coupling is achieved.
- Drilling tool according to claim 1, wherein said first coupling (16, 23, 93) is arranged by means of releasable, connecting bits (16) arranged to match recesses (93) around the periphery of said second end (92), and also to match inner recesses (23) in said central hole (22), so that upon coupling the rotational movement from the drive shaft (9) is transmitted to said assembly (10).
- Drilling tool according to any preceding claim, wherein the drive shaft device (9) is axially coupled to the central pilot drill bit (2) by means of a second releasable axial coupling arrangement (25, 95, 250).
- Drilling tool according to claim 3, wherein said second releasable coupling arrangement (25, 95, 250) comprises at least one locking ball (250), preferably a number of locking balls (250), arranged within a circumferential recess (25) within said central hole (22) of the central pilot drill bit (2) and also a circumferential recess (95) around the periphery of the drive shaft device (9).
- Drilling tool according to claim 4, wherein there is arranged a radial bore (251) in the body of said central pilot drill bit (2) arranged to facilitate supply and removal of said locking ball/s (250).
- Drilling tool according to claim 5, wherein the central pilot drill bit portion (2) comprises a first (27) flange and a second flange (28), wherein said first (27) flange (27) is arranged to transmit percussion energy to said drill bit portion (2) indirectly via said casing shoe (3) and said second flange (28) is arranged to transmit percussion energy directly to said drill bit ring (4).
- Drilling tool according to any preceding claim, wherein the drilling tool (1) comprises a chuck (12) arranged to transmit torque from said drill string to said drill assembly (10).
- Drilling tool according to claim 7, wherein there is a blast protecting ring (15) positioned in between the central pilot drill bit portion (2) and the chuck (12).
- Drilling tool according to claim 8, wherein the blast protecting ring (15) has a tapered cross section.
- Drilling tool according to any preceding claim, wherein the central pilot drill bit portion (2) comprises axially extending flushing grooves (21).
- Drilling tool assembly comprising a plurality of central pilot drill bit portions (2) according to any preceding claim, wherein said plurality of central pilot drill bit portions (2) include at least two different drill bit portions (2) arranged to handle different types of drilling.
- Method for assembling a drilling tool comprising the steps ofa. providing a drill assembly (10) with a central pilot drill bit portion (2), a peripheral ring shaped drill bit portion (4) and a casing shoe (3),b. providing a casing tube (13) which and a drill string,c. characterized ind. further providing a drive shaft device (9) ande. connecting the drive shaft device (9) to transfer torque from a drill string, andf. releasably connecting the drive shaft device (9) by means of a torque coupling (16, 23, 93) to the central drill bit portion (20).
- Method according to claim 12, further also releasably connecting the drive shaft device (9) by means of a axial coupling (25, 95, 250) to the central drill bit portion (20).
- Method according to claim 13, further providing a plurality of central pilot drill bit portions (2) including at least two different drill bit portions (2) and exchange of one central drill bit portion (2) to a different kind of drill bit portion (2) to handle different types of drilling.
- Method according to claim 14, wherein said exchange is related to handle different types of holes.
- Method according to claim 14, wherein said exchange is related to handle different kind of grounds.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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SE0951022 | 2009-12-23 |
Publications (3)
Publication Number | Publication Date |
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EP2339109A2 EP2339109A2 (en) | 2011-06-29 |
EP2339109A3 EP2339109A3 (en) | 2016-09-14 |
EP2339109B1 true EP2339109B1 (en) | 2017-12-20 |
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Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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EP10196499.7A Not-in-force EP2339109B1 (en) | 2009-12-23 | 2010-12-22 | Earth drilling tool and method |
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EP (1) | EP2339109B1 (en) |
Families Citing this family (6)
Publication number | Priority date | Publication date | Assignee | Title |
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CN102561951A (en) * | 2012-01-14 | 2012-07-11 | 中国石油天然气集团公司 | Double-stage and double-speed well drilling tool |
SE537708C2 (en) * | 2012-04-04 | 2015-10-06 | Lkab Wassara Ab | Drilling device for pipe drive |
WO2014001601A1 (en) * | 2012-06-28 | 2014-01-03 | Oy Atlas Copco Rotex Ab | Method and apparatus for use of a drilling device meant for down-the-hole drilling |
EP3498967A4 (en) * | 2016-08-09 | 2020-03-18 | Mitsubishi Materials Corporation | Excavating tool |
JP6751643B2 (en) * | 2016-10-13 | 2020-09-09 | 昌稔 野並 | Drilling tool |
JP6312280B1 (en) * | 2017-12-25 | 2018-04-18 | 青葉建機株式会社 | Drilling rig |
Family Cites Families (6)
Publication number | Priority date | Publication date | Assignee | Title |
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DE3613265A1 (en) | 1986-04-19 | 1987-10-22 | Christensen Inc Norton | CORE DRILLING TOOL FOR STONE DRILLING |
SE503324C2 (en) * | 1990-02-19 | 1996-05-28 | Sandvik Ab | Drilling tool for lowering drilling, with central pilot crown |
WO1995034740A1 (en) | 1994-06-10 | 1995-12-21 | Ilomaeki Valto | Drilling apparatus |
US5803192A (en) | 1996-05-13 | 1998-09-08 | Holte; Ardis L. | Drill bit retainer for a down hole hammer assembly |
SE522135C2 (en) | 2001-07-02 | 2004-01-13 | Uno Loef | Drilling tools for lowering drilling |
SE526511C2 (en) * | 2004-04-07 | 2005-09-27 | Atlas Copco Rotex Ab Oy | Device for lowering drilling tools with pilot drill bit, pusher and guide body |
-
2010
- 2010-12-22 EP EP10196499.7A patent/EP2339109B1/en not_active Not-in-force
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EP2339109A3 (en) | 2016-09-14 |
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