EP3143237B1 - Joint and joint parts for drill string components - Google Patents
Joint and joint parts for drill string components Download PDFInfo
- Publication number
- EP3143237B1 EP3143237B1 EP15728942.2A EP15728942A EP3143237B1 EP 3143237 B1 EP3143237 B1 EP 3143237B1 EP 15728942 A EP15728942 A EP 15728942A EP 3143237 B1 EP3143237 B1 EP 3143237B1
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- Prior art keywords
- axial
- drill string
- male
- joint
- rotation torque
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- 230000008878 coupling Effects 0.000 claims description 135
- 238000010168 coupling process Methods 0.000 claims description 135
- 238000005859 coupling reaction Methods 0.000 claims description 135
- 238000005553 drilling Methods 0.000 claims description 52
- 230000035939 shock Effects 0.000 claims description 28
- 239000011435 rock Substances 0.000 claims description 16
- 238000009527 percussion Methods 0.000 claims description 15
- 238000007789 sealing Methods 0.000 claims description 13
- 238000005304 joining Methods 0.000 claims description 11
- 230000013011 mating Effects 0.000 claims description 10
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- 238000000926 separation method Methods 0.000 description 15
- 238000011010 flushing procedure Methods 0.000 description 13
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Images
Classifications
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B17/00—Drilling rods or pipes; Flexible drill strings; Kellies; Drill collars; Sucker rods; Cables; Casings; Tubings
- E21B17/02—Couplings; joints
- E21B17/04—Couplings; joints between rod or the like and bit or between rod and rod or the like
- E21B17/046—Couplings; joints between rod or the like and bit or between rod and rod or the like with ribs, pins, or jaws, and complementary grooves or the like, e.g. bayonet catches
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B17/00—Drilling rods or pipes; Flexible drill strings; Kellies; Drill collars; Sucker rods; Cables; Casings; Tubings
- E21B17/02—Couplings; joints
- E21B17/04—Couplings; joints between rod or the like and bit or between rod and rod or the like
- E21B17/042—Threaded
- E21B17/0426—Threaded with a threaded cylindrical portion, e.g. for percussion rods
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B17/00—Drilling rods or pipes; Flexible drill strings; Kellies; Drill collars; Sucker rods; Cables; Casings; Tubings
- E21B17/02—Couplings; joints
- E21B17/04—Couplings; joints between rod or the like and bit or between rod and rod or the like
- E21B17/042—Threaded
- E21B17/043—Threaded with locking means
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B17/00—Drilling rods or pipes; Flexible drill strings; Kellies; Drill collars; Sucker rods; Cables; Casings; Tubings
- E21B17/02—Couplings; joints
- E21B17/04—Couplings; joints between rod or the like and bit or between rod and rod or the like
- E21B17/07—Telescoping joints for varying drill string lengths; Shock absorbers
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B19/00—Handling rods, casings, tubes or the like outside the borehole, e.g. in the derrick; Apparatus for feeding the rods or cables
- E21B19/16—Connecting or disconnecting pipe couplings or joints
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B1/00—Percussion drilling
Description
- The invention relates to a joint for a drill rod. The invention also relates to parts of such a joint and a drill rod and other drill string components including such parts.
- Drill strings for percussion drilling are typically composed of a number of drill string components, such as drill rods, that are connected to each other via a threaded joint. The function of the drill rods is to transmit rotation, feed force and percussive impacts from the percussive rock drilling machine to the drill bit. Flushing medium is also transmitted through the drill rods.
- When the bore hole is completed or in case the drill bit has to be replaced prematurely, the drill string has to be retrieved by pulling it out of the bore hole and be successively disassembled.
- Today's conventional drill rods are simple to use and associated with low tooling costs. There are, however, drawbacks associated with the use of today's drill rods such as hole deviation and zig-zag-shaped hole walls. The requirement for skilled and experienced operators in order to obtain acceptable quality results is also a problem.
- The threaded joints limit the working life of the rods since the threads are frequently subjected to wear and different kinds of failures such as breakages. Furthermore, in order to ensure secure drilling, the threaded joints have to be continuously tightened so as to ensure proper shock wave transmission all the way through the drill string.
- In order to loosen threads prior to disassembly, the drill string has to be frequently rattled.
- When it comes to operator skills, an experienced driller is required in order to most optimally tune feed force and rotation and be careful and observant during start of drilling and to adapt drilling parameters to rock properties, encountered rock formations, start angles vis-à-vis drilling direction etc.
- The thread joints are subject to wear and are exposed to risk of failure for many reasons. Meeting threads are subject to relatively sliding or rubbing wear longitudinally due to percussion waves and reflections as well as laterally because of torsional shock waves generated when the bit cuts into the rock to the extent that thereby rotation is drastically slowed momentarily.
- In the root of the last turn of the male thread, the stress concentration factor can be greater than three, thus setting an upper limit to the allowed percussive stress level.
- The virtually universal non-linearity of bore holes produced with conventional drill rods in the drill string results in pulsating bending moments affecting the threaded joints. A threaded joint has potential for high stress concentration resulting from such bending moments. Added to bending moment resulting from hole-deviation and human error, premature fatal failures occur frequently.
- Finally, so-called "drilling loose" and also extensive rattling to loosen joints upon completion at a hole will induce excess damage to the joint. If not performed correctly, severe damage or even breakage can occur.
- In respect of a drill rod system intending to reduce problems with conventional drill string components there has been suggested to have the percussive shock waves by-passing the threads via a separate stack of rods provided in the centre of a series of tubes which are interconnected with threads. This system delivers high top-hammer penetration rates with quality corresponding to a down-the-hole drilling system and long service life. Because of relatively high investment costs, this system has so far reached only a high end market.
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EP0387218 describes a background art drill string component having a central rod surrounded by a tube.US6293360 andUS4687368 describe threaded drill string components.WO2008/004937 A1 describes a non-threaded joint for drill string components.US 2002/0189865 A1 relates to a rock drill including a drill rod being connected to a cup-shaped drilling head for joint rotation and allowing limited axial displacement.US 2013/0098689 A1 relates to a two-part drilling tool wherein there are co-operating wedge-shaped surfaces on an adapter part and a drill head. - It is an aim of the present invention to provide a system that solves or at least reduces the problems mentioned above.
- This aim is obtained in a joint for joining together drill string components for percussion drilling, wherein each drill string component extends along an axial direction, and wherein, in operation, impact shock waves and rotation torque are arranged to be transferred via the joint, the joint including a male part and a female part having meeting impact surfaces. The invention is distinguished in - that the male part exhibits: i. first rotation torque transfer means, and ii. first axial coupling means, - that the female part exhibits: iii. second rotation torque transfer means, and iv. second axial coupling means, - wherein the first and second rotation torque transfer means extend on the respective male and female parts such, and - wherein the first and second axial coupling means are positioned such - that when the drill string is subjected to rotation torque for drilling, relative axial movement is allowed between the male and the female parts when being in an interconnected state of co-operation between the first and second rotation torque transfer means, which is when the first and the second impact surfaces are adjacent to each other.
- Hereby several advantages over the background art are achieved. The invention makes it possible to transmit both rotation and percussive shock waves through the drill string over only two meeting elements in the joint. This is achieved with a hole quality being comparable to a system as described above (Coprod ®), wherein transmission of rotation and of percussive shock waves is separated in two separate elements for each drill string component unit.
- A drill string component including one or two parts of a joint according to the invention is hereby comparatively easy and cost-effective to produce and with a weight being about half that of a corresponding Coprod ® - element. In order to separate the individual components, there will no longer be required to rattle the drill string and since a joint can be produced such that bending forces are greatly reduced, the expected working life of the components goes far beyond that of conventional one piece drill rods.
- In order to drill high quality holes there is less demand on skilled and experienced drillers, and altogether it has been made possible to drill holes of high quality at a low cost.
- According to the invention, the first and the second rotation torque transfer means are laid out such as to allow a relative axial movement between the male and the female parts in the interconnected state in a region close to where the first and the second impact surfaces contact each other. In particular, a minor relative displacement between the male and female parts is allowed subsequent to an impact shock wave passage.
- The magnitude of the relative axial movement or separation between the parts of the joint is normally expected to be from about 0,2 to about 0,6 mm during drilling. The separation between the parts of the joint can, however in case of drilling in very hard rock and with a drill hammer without damping even be expected to be as high as between about 1,2 - 1,6 mm. Drilling in rock with cavities could result in even greater separation than that.
- For that reason the joint is preferably constructed for allowing at least 1 mm separation and preferably 2 mm or more of separation. It should, however be understood that the inventive joint can be constructed for considerably higher degree of separation such as even up to about 100 mm.
- Hereby it is avoided that high forces that otherwise would affect the components subsequent to a percussive shock wave passing the joint have to be received by elements of threads belonging to the joint parts.
- Instead these forces are counteracted by the feed force provided through the drill string. This is a great advantage, since it is no longer necessary to dimension joint parts, such as thread ridges, for receiving and counteracting these forces. Therefore a significantly longer service life is possible for an inventive joint. It is also possible to produce the inventive joints for allowing certain mutual misalignment between adjacent string components without inducing particular bending moments corresponding to what is being so harmful for conventional threaded joints.
- Another advantage is that the inventive joint provides greater energy transmission efficiency than that of conventional threaded connections.
- It is important to understand that, during percussion drilling, the drill hammer subjects the drill string to intense repeated impacts in the order of 200 MPa, whereby shock waves are transmitted from drill string component to drill string component, passing via the joints of the drill string all the way to the drill bit. This initial shock wave is in the form of a compressional wave propagating through the material of the drill string.
- As a result of reflexion at the bit end of the drill string of the initial shock wave, either a tensile wave or a compressional wave is generated propagating back through the drill string. Passage via a joint of these reflected waves has a separating effect to impact surfaces of the joints.
- In a threaded joint, separation is counteracted by the thread ridges resulting in subsequent fatigue problems and wear. Such a threaded joint is pre-loaded. In the case of bottom-drive the female part is in tension and the male part is in compression. In the case of shoulder-drive the situation is the opposite. When an impact wave arrives, the pre-loaded joint undergoes a partial or even a full release. Upon the passing of the shock wave, the joint regains its full preload.
- The drill string is also subjected to repeated reflected shock waves, either tensile or compressional. These reflected shock waves will either increase or decrease the degree of the pre-loading, adding more releasing and reloading effect to the joint. The elastic deformation associated with all these releasing and reloading effects causes relative movements of the two parts being connected, but there should be no rigidbody separation between them at any time. I.e. the impact surface of the male part is in constant contact with the impact surface of the female part.
- A feed force applied to the drill string depends on various parameters but can be said to be in the region up to about 5 MPa, i.e. only a minute fraction of the shock wave value.
- No realistic feed force can in any joint construction prevent shock wave passage induced influence to the joint parts. According to the invention, the problem associated with such influence is solved through the inventive completely new approach in allowing a certain relative axial movement between the parts. Hereby the intense but very short-lasting forces induced by the shock wave passage can be effectively absorbed by being counteracted by the feed force over a relatively longer period during the relative axial movement between the parts.
- In order to ensure that a relative axial movement between the parts can be obtained in practice during drilling, the inventive joint per se is free from pretension in either rotational or axial direction when being subjected to rotation for drilling. Any such pretension would result in mutually locking parts, wear because of relative micro-movements and fatigue problems.
- It is therefore important that co-operating, meeting, surfaces of the first and second rotation torque transfer means are arranged to contact each other in a rotational direction such that self-locking and pretensioning of the joint can not occur. This is achieved in that an angle between a flank direction and a radius where the contact occurs between two meeting surfaces of the first and second rotation torque transfer means is great enough to avoid self-locking and pretensioning of the joint. The angle is preferably at least 450, more preferred over 60° and most preferred over 70°. Hereby no tendencies of self-locking occurs.
- An important purpose of the first and the second axial coupling means of the male and the female parts is basically to ensure safe retrieval of the drill string. It is important to understand that in the interconnected state of two adjacent drill string components, the first and the second axial coupling means do not obstruct the relative axial movement between the joint parts. For that reason, at least in a state where the drill string is subjected to rotation torque or drilling, the first and the second axial coupling means allow and do not obstruct said relative axial movement.
- With "joint for joining together drill string components", here is in particular intended joints between tubular components that are to be positioned between a percussive rock drilling machine and a drill bit for percussion drilling since the invention is particularly advantageous for such components often referred to as a drill rod. This definition also includes a joint between the shank adapter and the first drill rod.
- The first and second rotation torque transfer means are preferably mating splines that are preferably comprised, for each one of the male and the female parts, of at least six ridges that are elongated and that extend along each one of the male and the female parts. Ridges are protruding radially inwards from an inside wall of a cylindrical member to form female splines. Ridges are protruding radially outwards from an outside wall of a cylindrical member to form male splines.
- It is in principle undesirable to have rotation inducing considerable contractive effect in the joint, because of the above mentioned force reception as well as the creation of undesired rigidity in the joint resulting in risk of fatal failure problems. Contacting surfaces therefore preferably extend in parallel with said axial direction on the respective male and female parts.
- It is, however, in some instances advantageous to have the contacting surfaces extending slightly helically in the direction of contraction on the respective male and female parts of the joint when the drill string is subjected to the normal forward rotation during drilling. This contraction must, however, be limited and contacting surfaces must extend so as not to prevent relative movements between the male and the female joint parts which could result in tendencies of the above problems. For that reason the helix angle of the contacting surfaces should preferably normally be from -20° up to about 20° to the axial direction. Negative values means that separation of the impact surfaces because of the above described effect results in separation between meeting first and second rotation torque transfer means.
- Forming the rotation torque transfer means helically is more complicated and expensive compared to forming these surfaces axially extending, but gives a somewhat softer rotation torque transfer between adjacent components.
- The joint is obviously not preloaded as a conventional threaded joint for drill string components.
- In case the contacting surfaces extend axially, basically no force inducted by the joint itself restricts the relative axial movement between the joint parts.
- The first and second axial coupling means advantageously include axial engagement means formed by radially directed protrusions on one of the male and the female parts.
- Axial engagement means advantageously includes radially directed protrusions in the form of hook elements or abutments on one of the male and the female parts for engagement with abutment surface portions on the other one of the male and the female parts. The axial engagement means are intended for temporary axial locking so as to limit and prevent exaggerated separation between the joint parts. One example when this is required is for allowing quick lifting of the drill string for clearing the bore hole from stuck drill cuttings.
- The axial engagement means can be arranged such that the first and the second axial coupling means, in an interconnected state of the joint, are made to engage in a positive, forward, rotation direction, i.e. in the normal rotation direction used during rock drilling or in the opposite, reverse, direction, whereby the connection is locked during reverse rotation but not locked during drilling. In the latter case, it will not be required to have an auto rod changer on the rig. It is also possible to have a joint arranged for locking in both forward rotation direction and in the opposite, reverse, direction. This embodiment is particularly advantageous for use for a shank adapter whereby faster operation is achieved. In all locking, axial movements between the parts is limited according to the above.
- It is preferred that one of the first and second axial coupling means, is constituted by end surfaces of splines on the male or female part for co-operation with the above mentioned hook elements or abutments. No extra elements have to be provided with this embodiment.
- It is preferred that the first and second axial coupling means include axial security coupling means. This provides for safe prevention against any accidental release of the joined components. Most preferred the axial security coupling means includes a thread coupling or a bayonet coupling.
- Advantageously, second axial security coupling means in the form of outside threads are positioned at a distal portion of a sleeve-shaped or rod-shaped element extending centrally of the female part and that mating first axial security coupling means in the form of inside threads are positioned at a distal portion of the male part. Suitably a distal portion of the rod-shaped element is cup-shaped with holes for flushing fluid and a rod base has holes for flushing fluid in order to ensure advantageous fluid transfer through the drill string during operation.
- It should be noted that it is advantageous to provide the one and the same inventive joint with first and second axial coupling means including axial security coupling means as well as axial engagement means for both safe drill string retrieval and enhanced functionality according to the above.
- The first and second axial coupling means can be arranged in various ways and for example as threaded means engaging only during a first stage of connection of two adjacent components. Hereby, upon termination of that first stage, free movement along the mating first and second rotation torque transfer means is allowed all the way to the operational position where the impact surfaces of the two adjacent components meet. In order to avoid that meeting end surfaces of splines initially abut each other axially and obstruct the connection phase, the end surfaces can be made pointed.
- Alternatively, bayonet coupling means can be used or intermeshing hooks on the inside of one of the first and second rotation torque transfer means that engage with inside ends of the second of the first and the second rotation torque transfer means or hooks or lugs on an outside of one of the first rotation torque transfer means for engagement with the outside of the other one of the first and second rotation torque transfer means. Said hooks or lugs make up the first and a second axial coupling means.
- In a preferred variant, the female part includes an inner and an outer, dual-wall construction, the walls being sleeve-shaped together to define an annular compartment for the reception of a sleeve-formed (portion of a) male part.
- The first rotation torque transfer means can be positioned on one of the inside and the outside of the sleeve-formed male part, whereas the first axial coupling means can be positioned on one the same side or on the opposite side from the first rotation torque transfer means.
- It is preferred that a sealing arrangement is positioned at an inside opening slot formed between the male and the female parts, as seen in an operative position with the first and second impact surfaces close to each other.
- The first and second impact surfaces can be arranged for either shoulder drive, bottom drive or dual drive (both shoulder and bottom drive).
- For clarifying purposes: In shoulder drive, impact surface shoulders are ring-shaped and are positioned radially outside the first and second rotation torque transfer means and the first and second axial coupling means.
- Shoulder drive has proved to be most advantageous for use with respect to the invention, since shoulder drive joints tend to be less subjected to wear because the transfer of the shock wave outside and in parallel with the portions of the joint parts supporting the rotation transfer means. Another important advantage with shoulder drive is that it makes it more easy to provide for a virtually closed continuous outside surface for the entire drill string. In particular it is possible to make the entire drill string or at least the regions of the joints between the individual drill string components forming a continuous cylindrical envelope surface. This reduces ware.
- It is also important that during the small relative axial movements in the joint in operation, impurities are prevented to enter into the joint. The risk for that is minimized by using shoulder drive and having mating co-operating circular cylindrical guiding surfaces closest to the meeting impact surfaces of two joining drill string components. Flushing fluid leaking between the impact surfaces when they are slightly separated adds to reduction of the risk for impurities entering the joint.
- It is advantageous in a more easily produced variant that the female part is sleeve-shaped with one wall, having both the second rotation torque transfer means and the second axial coupling means being oriented on an inside sleeve wall.
- Advantageously an angle between a radius of the joint parts and a flank direction forming a right angle against a main surface of the rotation torque transfer means is 60° - 90° and more preferably 70° - 90°. Hereby unwanted self-locking of the parts in a rotational direction is avoided and wear during drilling reduced to a minimum.
- It is highly advantageous that the male part externally has a proximal, cylindrical guide portion for co-operation with an internal, cylindrical guide surface at a distal portion of the female part. Advantageously, the male part at a distal region has part cylindrical outside guide surfaces for co-operation with an internal, cylindrical guide surface at a proximal portion of the female part. Hereby advantageous alignment of the joint is achieved.
- The invention also relates to a male part of a joint for joining together tubular drill string components to be positioned between a percussive rock drilling machine and a drill bit of a drill string for percussion drilling, wherein each drill string component extends along an axial direction, and wherein, in operation, impact shock waves and rotation torque are arranged to be transferred via the joint, wherein the male part is part of a first drill string component and is arranged to co-operate with a female part of a second drill string component, and wherein a first impact surface on the male part is arranged to co-operate with a second impact surface on the female part. The inventive male part exhibits: i. first rotation torque transfer means, and ii. first axial coupling means, for co-operation with iii. second rotation torque transfer means, and iv. second axial coupling means on the female part, - wherein the first rotation torque transfer means for contacting the second rotation torque transfer means extend on the male part such, and - wherein the first axial coupling means for co-operation with the second axial coupling means is positioned such - that when the drill string is subjected to rotation torque for drilling, relative axial movement is allowed between the male and the female parts when being in an interconnected state of co-operation between the first and second rotation torque transfer means, being when the first and the second impact surfaces are adjacent to each other.
- Preferably, the first rotation torque transfer means are splines having contacting surfaces that extend in parallel with said axial direction on the male part or extend helically on the respective male parts, at a helix angle (α) between 0° and 20° to the axial direction.
- Suitably, the first axial coupling means include axial engagement means formed by radially directed protrusions on the male part.
- Preferably, the axial engagement means includes radially directed protrusions in the form of hook elements or abutments on the male part for engagement with abutment surface portions on the female part.
- When the male and the female parts are interconnected, the axial engagement means are arranged to engage in forward rotation of the drill string and/or reverse rotation of the drill string and thereby limit relative axial movement between the male and the female part.
- Preferably, the first axial coupling means, is constituted by end surfaces of splines on the male part.
- Preferably, the first axial coupling means include axial security coupling means. Hereby the axial security coupling means preferably includes a thread coupling or a bayonet coupling.
- When second axial security coupling means in the form of outside threads are positioned at a distal portion of a sleeve-shaped or rod-shaped element extending centrally of the female part, mating first axial security coupling means in the form of inside threads are advantageously positioned at a distal portion of the male part.
- The first rotation torque transfer means is preferably positioned on one of the inside and the outside of the sleeve-formed male part.
- The first axial coupling means is preferably positioned on one of the inside and the outside of the sleeve-formed male part.
- A sealing arrangement is preferably positioned at an inside opening slot formed between the male and the female parts, as seen in an operative position with the first and second impact surfaces close to each other.
- The first impact surface is preferably arranged for one from the group: shoulder drive, bottom drive and dual drive.
- When the first impact surface is arranged for shoulder drive, outside surfaces of meeting drill string components, at least in the region of the joint, form an essentially continuous envelope surface.
- An angle (β) between a radius (R) of the joint parts and a flank direction (f) forming a right angle against a main surface of the rotation torque transfer means is preferably 60° - 90° and more preferably 70° - 90°.
- The male part has preferably externally a proximal, cylindrical guide portion for co-operation with an internal, cylindrical guide surface at a distal portion of the female part.
The male part has preferably at a distal region part cylindrical outside guide surfaces for co-operation with an internal, cylindrical guide surface at a proximal portion of the female part. - The invention also relates to a female part of a joint for joining together drill string components of a drill string for percussion drilling, wherein each drill string component extends along an axial direction, and wherein, in operation, impact shock waves and rotation torque from a percussion drilling machine at one end of the drill string is arranged to be transferred via the joint to a drill bit at an opposite end of the drill string, wherein the female part is part of a second drill string component and is arranged to co-operate with a male part of a first drill string component, wherein a second impact surface on the female part is arranged to co-operate with a first impact surface on the male part. The inventive female part exhibits: i. second rotation torque transfer means, and ii. second axial coupling means for cooperation with iii. first rotation torque transfer means, and iv. first axial coupling means, on the male part, - wherein the second rotation torque transfer means for contacting the first rotation torque transfer means extend on the female part such, and - wherein the second axial coupling means for cooperation with the first axial coupling means is positioned such - that when the drill string is subjected to rotation torque for drilling, relative axial movement is allowed between the male and the female parts when being in an interconnected state of co-operation between the first and second rotation torque transfer means, which is when the first and the second impact surfaces are adjacent to each other.
- Preferably, the second rotation torque transfer means is splines having contacting surfaces that extend in parallel with said axial direction on the female part or extend helically on the female part, at a helix angle (α) between 0° and 20° to the axial direction.
- The second axial coupling means preferably include axial engagement means formed by radially directed protrusions on one of the female parts.
- The axial engagement means preferably includes radially directed protrusions in the form of hook elements or abutments on the female part for engagement with abutment surface portions one the male part.
- When the male and the female parts are interconnected, the axial engagement means are arranged to engage in forward rotation of the drill string and/or reverse rotation of the drill string and thereby limit relative axial movement between the male and the female part.
- Preferably the second axial coupling means is constituted by end surfaces of splines on female part.
- Preferably the second axial coupling means include axial security coupling means.
- Preferably the axial security coupling means includes a thread coupling or a bayonet coupling.
- Second axial security coupling means in the form of outside threads are positioned at a distal portion of a sleeve-shaped or rod-shaped element extending centrally of the female part for mating with first axial security coupling means in the form of inside threads that are positioned at a distal portion of the male part.
- The female part preferably includes an inner and an outer wall, together defining an annular compartment for the reception of a sleeve-formed male part.
- A sealing arrangement is preferably positioned at an inside opening slot formed between the male and the female parts, as seen in an operative position with the first and second impact surfaces close to each other.
- The second impact surface is arranged for one from the group: shoulder drive, bottom drive and dual drive.
- When the second impact surface is arranged for shoulder drive, outside surfaces of meeting drill string components, at least in the region of the joint, preferably form an essentially continuous envelope surface.
- The female part is preferably sleeve-shaped having both the second rotation torque transfer means and the second axial coupling means being oriented on an inside sleeve wall.
- Advantageously, an angle (β) between a radius (R) of the joint parts and a flank direction (f) forming a right angle against a main surface of the rotation torque transfer means is 60° - 90° and more preferably 70° - 90°.
- When the male part externally has a proximal, cylindrical guide portion, it preferably co-operates with an internal, cylindrical guide surface at a distal portion of the female part.
- It is preferred that when the male part at a distal region has part cylindrical outside guide surfaces, it co-operates with an internal, cylindrical guide surface at a proximal portion of the female part.
- Shoulder drive is preferred because the shock wave can be transferred past the joint outside the very coupling elements making up the rotation torque transfer means and the axial coupling means. Hereby wear is reduced compared to what is the case with respect to a bottom drive solution. see also the above for more advantages of shoulder drive.
- The advantages explained above that are relating to the inventive joint are correspondingly achieved in respect of the male and the female parts. Subordinate optional features relating to the inventive joint are applicable also in respect of the inventive male and female parts.
- An inventive drill rod includes one such male part or/and one such female part or two such male parts or two such female parts.
- An inventive shank adapter for a rock drilling machine includes one such male part or one such female part.
- There are numerous ways in producing drill string components according to the invention. One method frequently used for producing drill rods is to friction weld the male and female parts onto a pipe-shaped rod blank. When it comes to female parts having the dual-wall construction, an inner sleeve making up the inner wall or an outer sleeve making up the outer wall may be friction welded to a base part including the other one of the walls.
- The drill rod according to the invention is also advantageous for use in drill strings for down the hole hammers that produce impacts at the end of a drill string as well as for drill strings for rotational drilling (e.g. tricone) only.
- The invention also relates to a method for joining together tubular drill string components to be positioned between a percussive rock drilling machine and a drill bit for percussion drilling, wherein each drill string component extends along an axial direction, and wherein impact shock waves and rotation torque are transferred via a joint, including the steps of:- initiating axial insertion of a male part of a first drill string component into a female part of a second drill string component,- rotate the first drill string component relative to the second drill string component to ensure engagement of axial security coupling means in the form of a thread coupling or a bayonet coupling,- continue axial insertion of the male part into the female part a determined distance whereby the first drill string component is allowed to rotate relative to the second drill string component to ensure engagement of axial engagement means and to ensure engagement of first and second rotation torque transfer means arranged on the respective male and female part.
- Further details and advantages are explained in the below detailed description of embodiments.
- The invention will now be described in greater detail at the background of embodiments and with reference to the annexed drawings, wherein:
-
Fig. 1 shows, in a simplified side view, partly in section, a top hammer with a drill string including drill rods and drill bit, -
Figs. 2a, b andc show in axial views a first embodiment of a joint with joint parts of a first and a second drill rod in three different states of connection, -
Fig. 2c1 shows a cross section of the first embodiment andFig. 2c2 shows in a greater scale a contact region between two meeting splines. -
Figs. 3a - d show in different views a second embodiment of a joint according to the invention, -
Fig. 4 shows a different joint part, -
Figs. 5a - d show a details of different joint part in different positions, -
Fig. 6 illustrates an alternatively constructed joint, -
Figs. 7a and b show further different joint parts, -
Figs. 8a - e show a further different joint and joint parts, -
Figs. 9a and b show an alternative male joint part, -
Figs. 10a and b show a further alternative male joint part, -
Fig. 11 shows a shank adapter in a side view. - Similar and like elements are indicated with same reference numerals in different figures.
- The
top hammer 1 inFig. 1 is movably supported by a (not shown) feed beam of a drill rig and is arranged to deliver impacts and a rotational movement to adrill bit 3 in order to disintegrate rock. - A
shank adapter 5, partly inside a front end region of thetop hammer 1, connects to a drill string component being a drill rod of thedrill string 2, said drill string being composed of a number of drill string components such asindividual drill rods 4 that are connected via joints. - The
drill bit 3 is connected to thelowermost drill rod 4 of thedrill string 2 via adrill head 31. - An example of an inventive joint for joining together drill rods according to the invention is shown in
Figs 2a, 2b and2c . Afirst drill rod 6 has amale part 8 to be connected to afemale part 9 of asecond drill rod 7. Themale part 8 is in this embodiment formed tubular as a sleeve having a free, distal, end and a proximal end being fastened to a tubular main part of thefirst drill rod 6. - The drill rods have an axially extending flushing channel for allowing a flow of flushing fluid from the top hammer to the drill bit.
- The joint in
Fig. 2a - c is constructed for shoulder drive and 10 indicates a first impact surface at a shoulder being included at a proximal end of the male part and being directed axially for co-operation with asecond impact surface 11 at a most distal end of thesecond drill rod 7. In this case there is provided shoulder drive impact between thedrill rods - It is also possible to have bottom drive, in which case an alternative impact surface at the distal end of the male part would have been arranged for co-operation with an alternative impact surface on (a bottom portion of) the female part. In so called "dual drive", shoulder drive as well as bottom drive would be active.
- The
male part 8 exhibits first rotation torque transfer means being in the form ofsplines 12 in to this embodiment. Thesplines 12 extend axially in parallel with an axis A of thedrill rods - In an interconnected state of the male and female parts, the first rotation torque transfer means 12 co-operate with mating second rotation torque transfer means 14 being arranged on an inside surface of a portion of the
female part 9. - The
male part 8 further includes first axial coupling means 13 in the form of a short screw thread on an inside surface of and at a distal region of the sleeve-formedmale part 8. The first axial coupling means 13 is arranged to co-operate with mating second axial coupling means 15, also in the form of a short screw thread on a portion of thefemale part 9 being positioned radially inside the second rotation torque transfer means 14 and directed radially outward. - The
female part 9 in this embodiment includes two sleeve-shaped coaxial members together forming an annular space or compartment for more or less completely receiving the coupling elements of themale part 8. Hereby the female part has an inner and an outer, dual-wall construction, to define said annular compartment for the reception of the sleeve-formed (portion of the) male part. In the shown embodiment according toFigs. 2a - 2c , the second axial coupling means being a short male screw tread is arranged at a distal region of an inner one of the sleeve-shaped coaxial members that together forming an annular space or compartment for receiving the coupling elements of themale part 8. - In
Fig. 2a themale part 8 and thefemale part 9 are shown in a state where themale part 8 has been inserted into the annular space of thefemale part 9 and the first axial coupling means 13 engage the second axial coupling means 15 by the short screw threads being threaded together with each other. - In the state shown in
Fig. 2b , themale part 8 has been threaded further with respect to thefemale part 9 in that the short screw threads being the first and second axial coupling means 13 and 15 have been through-threaded, passed their relatively short axial lengths. Themale part 8 can now basically be free to move axially into said annular space or compartment being formed in thefemale part 9, whereupon the splines being the first and second rotation torque transfer means 12 and 14, can come into engagement with each other so as to transfer rotation torque between the first and the second drill rods. - A state where the first and second rotation torque transfer means 12 and 14 have come into engagement with each other is illustrated in an axial and a radial sections in
Fig. 2c , wherein the coupling elements of themale part 8 has been completely pushed into said annular space inside thefemale part 9 such that the first and second impact surfaces 10 and 11 contact each other. - The position shown in
Fig. 2c is the operative position, wherein, during drilling, impact shock waves can be transmitted over the joint from thefirst drill rod 6 to thesecond drill rod 7 over the meeting impact surfaces 10 and 11. - Since the rotation torque transfer means 12 and 14 are also in engagement in this position, rotation induced by the top hammer can also be transferred from the
first drill rod 6 to thesecond drill rod 7. - According to the invention it is provided that tendencies to separate the impact surfaces 10 and 11 occurring immediately upon impact and also upon possible shock wave reflections passing the joint are not counteracted by the elements making up the joint. On the contrary, a relative movement of the
male part 8 and thefemale part 9 is possible which is counteracted neither by the co-operating rotation torque transfer means nor by the axial coupling means. - It is also ensured, according to the invention, that relative bending of the first and second drill rods does not essentially affect the male and the female parts of the joint, since also a limited relative bending movement is allowed. Altogether, the joint parts are not at all affected by harmful forces to the extent that normally affect joint parts of background art threaded joints.
-
Fig. 2a illustrates adrill rod 6 being produced by a tubular member being friction welded together with an element essentially making up themale part 8 via afriction weld 19, which can be produced in a per se known manner. 20 indicates a second friction weld between a female joint part and a similar tubular member together making up thesecond drill rod 7. - Normally a drill rod includes a tubular part having a male part at one end and a female part at the other end. It is, however, also possible that drill rods have exclusively male parts or female parts at both ends.
- 21 indicates a third friction weld wherein the member to be connected to the
second drill rod 7 is a part of the female joint part only. - The steps of welding together different parts into a completed drill rod is advantageous, since a relatively small complicated part of a component can be manufactured separately in a conventional machine in a conventional machining process.
-
Numeral 18 inFig. 2c indicates a sealing arrangement in the form of a sealing ring, for example of a synthetic material, which is arranged to seal aninside opening slot 30 being formed between the twodrill rods - It is possible to arrange and position both the axial coupling means and the rotation torque transfer means inverted such that the first rotation torque transfer means are arranged at the inside of the male part and the second rotation torque transfer means are arranged at an outside of a portion of the female part (but inside said annular space or compartment) receiving the male part. The first axial coupling means can be arranged at the outside of the male part and the second axial coupling means at the inside of the female part.
- It is also possible to arrange the female and male parts such that both the axial coupling means and the rotation torque transfer means of one of the parts are on the same side. In that case, the female part can be constructed without an annular space or compartment receiving the male part.
-
Figs. 3a - d show another joint embodiment, wherein the axial coupling means are constructed differently. As can be seen onFig. 3a , amale part 8 of adrill string component 6 has a plurality of axially extending splines constituting (first) rotation torque transfer means. The plural splines are evenly distributed around part of the length of the male part and are adapted for co-operation with corresponding plural splines constituting second rotation torque transfer means in an inside of a female part (7 inFigs. 3b - d ). - At a distal region of the
male part 8, from the main parts of the splines, there are radially protrudingportions 32 constituting (first) axial coupling means. These (first) axial coupling means in the form of protruding portions are adapted for co-operation betweensurfaces 33, directed axially from the distal end of the male part, andcorresponding surface portions 35 in a recess or recesses 34, constituting second axial coupling means, formed inside of a mating female part (see in particularFig. 3d ). -
Fig. 3b shows themale part 8 slightly entered into thefemale part 9, the protrudingportions 32 being entered between ridges of thesplines 14. Grooves between the spline ridges are deepened and measured to allow the protruding portions to be moved all the way to the completed interconnected state prevailing during drilling when the impact surfaces 10 and 11 meet. This state is shown onFig. 3c and more clearly yet on the partly cut perspective viewFig. 3d . One such deepened groove is referenced with 36 onFig. 3d . -
Figs. 3a - d basically illustrate a variant having a bayonet-like coupling being used instead of a threaded coupling making up the first and second axial coupling means as illustrated inFigs. 2a - c . In order to reach the position inFig. 3d , after having been fully inserted into thefemale part 9, themale part 8 has been rotated such that thesurfaces 33 face thesurfaces 35 inside therecess 34. Further rotation is prevented because of contact between thesplines 12 on the male part reaching contact with thesplines 14 inside the female part. - The bayonet-like coupling can be arranged for interlocking axial coupling means either as a result of forward rotation, used during drilling or as a result of reverse rotation. Interlock of the axial coupling means results in that the drill string can be extracted from the hole after completed drilling.
- 46 indicates two sealing rings that are received in surrounding grooves being provided on a circular cylindrical extension at a distal end region of the male
joint part 8. The sealing rings 46 constitute a sealing arrangement in this embodiment, where the female part is of a one wall type. The sealing rings contact and provide sealing co-operation together with a circularcylindrical sealing surface 47 inside a proximal portion of the femalejoint part 9. - In case of interlocking axial coupling means as a result of forward rotation, used during drilling, it is important that there is sufficient play between the
surfaces - An important feature of the invention is shown in the radial section
Fig. 2c1 , wherein an angle β is illustrated, being an angle between a radius R of the joint and a flank direction f, being a line forming a right angle against a main, or central, flank surface of the rotation torque transfer means (here being splines) as seen in a radial section. - Two meeting splines are indicated 39 and 40. The radius R extends through a contact region of meeting surfaces contacting each other at an angle β as defined above through the region of contact between the two meeting flank surfaces of the
splines - The embodiment in
Figs. 2a - c is an example, wherein a considerable axial separation of for example 100 mm is possible after having established the axial coupling through the axial coupling means. The embodiment inFigs. 3a - d is an example of forward locking (locking during forward rotation), wherein a smaller axial separation of for example 2 - 4 mm is possible after having established the axial locking through the axial coupling means. -
Fig. 4 showssplines 12 extending on amale part 8 forming a helix angle α with respect to an axial direction. This may be advantageous in order to obtain a very slight contracting effect onto meeting drill rods as an effect of forward rotation. The helix angle α must, however, be small enough such that the mutual movement between the parts is not at all restricted or leading to wear, limited working life or fatigue failure. - For that reason the helix angle α must be so small that there is no risk of inducing any self-locking effect between the first and second rotation torque transfer means in order to avoid reduction of the beneficial effects of the invention. This is normally achieved when the helix angle α is between 0° and 20°.
- As is illustrated in
Fig. 4 , for variants of splines having a helical path, the flank direction f1 also forms an angle α to a cross sectional plane CP through the joint part (-s). The resulting angle of the flank direction has to be calculated considering both α and β. -
Figs. 5a ,b and c show a variant where thesplines 12 on amale part 8 are arranged with hook-like abutments 37 for preventing separation when the drill string components are rotated in one direction. The hook-like abutments 37 co-operate withcontact surfaces 38 at ends ofsplines 14 inside thefemale part 9, which is shown partially cut, so as together make up the first and the second axial coupling means.Fig. 5b shows a relative rotational position between the male and the female part constituting a locked position, where the hook-like abutments 37 co-operate with contact surfaces 38.Fig. 5c shows a relative rotational position between the male and the female part constituting an unlocked position, where the hook-like abutments 37 are free from contact with the contact surfaces 38. -
Fig. 5d diagrammatically illustrates a further variant where thesplines 12 on a male part are arranged with hook-like abutments 37 being completed withupstanding lugs 51 so as to give an inverted J-shape. This prevents separation when the drill string components are relatively rotated in both directions when acorresponding lug 52 at the bottom end of eachfemale part spline 14 is engaged in a compartment limited by thelug 51 on the male part. - In advantageous and preferred embodiments, the arrangements in
Figs. 3a - d ,4 and5 with differently shaped and functioning co-operating hook-like abutments and contact surfaces are combined with the arrangement described in relation toFigs. 2a - 2c . - One example of this is illustrated on
Fig. 6 , wherein the joint parts on the one hand are provided withshort threads portions 32 and inrecesses 34 constituting first and second axial engagement means on the male and the female part respectively. Hereby the combinatory effect of the first and second axial coupling means including axial security coupling means as well as axial engagement means, the significance of which being explained above, is obtained. -
Figs. 7a and b illustrate a variant of axial coupling means shown inFigs. 3a - d being axial security coupling means. After the joint parts have been rotated relative to each other, to the position illustrated inFig. 7a , and have been axially displaced relative each other to the position illustrated inFig. 7b , each protrudingportion 32 is positioned in aseat 44 having an axial stop (not shown) for the protrudingportion 32 and arim element 45 preventing unintentional rotational movement of the protrudingportion 32 and thereby rotational displacement of the joint parts. During lifting of the drill string, this embodiment provides increased security against unintentional disassembly compared to the common embodiment ofFigs. 3a - d . - When the parts are being pressed together again (back to
Fig. 7a ) and the male part has been rotated in a release direction according to thearrow 48 in respect of the female part, the parts can be dismounted by the protrudingportions 32 being free to pass thefull grooves 49 between thesplines 50. -
Fig. 8a shows an axial section,Fig. 8b a sectioned perspective view andFig. 8c a cross section of an assembled joint with themale part 8 fully inserted into thefemale part 9 and themale slines 12 in engagement with thefemale splines 14. - In this embodiment, a rod-shaped
element 53 extends from arod base 55 adjoining to the inside of the pipe-shapedpart 56 of the female part. This is in contrast to the embodiment shown inFig. 6 and described above where an inner sleeve-shaped member of the female part at a distal region provides a male tread. - Furthermore regarding the embodiment in
Fig. 8a , at its distal region, the rod-shapedelement 53 is formed with a cup-shapedstructure 54 with acavity 57, an opening of which facing away from the rod base. At its outside, the cup-shapedstructure 54 carries amale thread 60 being female part (second) axial security coupling means of the second axial coupling means. - The cup-shaped
structure 54 is provided with a plurality of first throughholes 58 for flushing fluid. The rod base, which extends from the rod-shaped element radially outwards to pass over to the inside of the tubular outside of the pipe-shapedpart 56, is provided with a plurality of second throughholes 59 for flushing fluid. - The
male part 8 exhibits a sleeve shape and extends from a proximal region being adjoining to the evenly pipe-shaped part of a drill string component to a distal region having on its inside afemale thread 61 corresponding to the male thread 60 (male part (first) axial security coupling means of the first axial coupling means) together forming the axial security coupling means of the second axial coupling means. The passage between thefemale thread 61, the inside 62 of the sleeve shape and the outside surface of the rod-shaped elements form together with theholes splines part 63 most proximal on the on the male part and an inside surface of a cylindrical guidingpart 64 most distal on the on pipe-shaped part of the female part and subsequently between shoulder contact surfaces at 65 between impacts. - These inside and outside surfaces 63 and 64 of the male and the female parts respectively contribute to the alignment of the joint during operation. Furthermore, alignment of the joint is also advantageously effected through cooperation beween radially outwardly directed surfaces 72 on the
abutments 37 and aninside surface 71 inside the pipe-shaped part of the female part (seeFigs. 8a ,8e ,9b and10b ). The radially outwardly directedsurfaces 72 of theabutments 37 together form an interrupted annular envelope surface. - Ensuring proper contact between the
surfaces inside surface 71. Ensuring proper contact between thesurfaces - This combined guiding arrangement at two axially separated positions of the joint is advantageous for achieving stable alignment.
- The complete female part includes a rod portion comprising the rod-shaped
element 53, therod base 55 and a portion 56' of the pipe-shaped part as shown inFig 8d together with acontinuation 56" of the pipe-shaped part as shown inFig. 8e . The portion 56' is friction welded at 66" to a meeting surface at 66' of thecontinuation 56" to form aweld 66 of the complete female part. The female part is subsequently in turn friction welded to a pipe of the drill string component. - Furthermore, inside the
continuation 56" there are positioned female part splines 14. At the inside end of each sline 14 there are providedcontact surfaces 38 constituting female part axial engagement means (compare 38 inFigs. 5a - c ) . -
Figs. 9a and b illustrates the male part of the embodiment ofFig. 8a . From the side view inFig. 9b is evident thatabutments 37 are arranged free from the splines such that an annular groove can be said to be provided therebetween. This facilitates production and fine machining of contact surfaces on theabutments 37. The contact surfaces 37' are arranged for engagement in one rotational direction only withcontact surfaces 38 constituting female part axial engagement means (seeFig. 8e ). It is referred to the description above of different elements for full understanding of the male part. The male part is friction welded to a pipe forming the main part of a drill string component. -
Figs. 10a and b illustrates an alternatively configured male part. From the side view inFig. 9b is evident thatabutments 37 have contact surfaces 37' are arranged for engagement in a first rotational direction withcontact surfaces 38 constituting female part axial engagement means (seeFig. 8e ). This alternatively configured male part, however, hasabutments 37 arranged so as to havecontact surfaces 37" that are arranged for engagement also in a second rotational direction withcontact surfaces 38 constituting female part axial engagement means (seeFig. 8e ). - Furthermore, in this male part embodiment, there is no inner female thread making up a male part axial security coupling means most distally inside the
surface 62. Axial engagement thus relies fully on the axial engagement means. - The embodiment in
Figs. 10a and b is particularly applicable for ashank adapter 67, seeFig. 11 , where axial security coupling means would be an obstacle because of the repeated assembly, disassembly taking place between the shank adapter and the most adjacent drill string component. 68 indicates a male part as shown and described with reference toFigs. 10a and b. 69 indicates a drilling machine end of the shank adapter and 70 indicates an inside component of a swivel. - It is possible to use other means preventing rotation between interconnected parts besides splines as first and second rotation torque transfer means. Basically, interconnected parts having rotation preventing means that engage each other can be made in various configurations when they fulfil the requirements explained above. Use of splines is, however, preferred for a number of reasons such as ease of production and reliability. The number of splines can be adapted to the situation and if the joint parts have to be relatively rotated for achieving axial locking. The axial length of the splines is chosen so as to reach an acceptable surface load on the flanks of the splines.
- The embodiments shown in the Figs. illustrate drill strings having the male joint part of a joint being carried by a drill string component being closest to the drill hammer but it should be evident that the opposite situation with the female joint part being carried by the drill string component being closest to the drill hammer is fully possible.
- The term comprised is here intended as an open (and not closed) definition which is not restricted to the feature following the term. Also other features can be present.It is noted that the scope of protection of the current invention is defined by the appended claims.
Claims (15)
- Joint for joining together drill string components (6,7) in the form of drill rods or shank adapters for percussion drilling, wherein each drill string component extends along an axial direction (A), and wherein, in operation, impact shock waves and rotation torque are arranged to be transferred via the joint, the joint including a male part (8) and a female part (9) having meeting impact surfaces (10, 11),
characterized in- that the male part (8) exhibits:i. first rotation torque transfer means (12), andii. first axial coupling means (13),- that the female part (9) exhibits:iii. second rotation torque transfer means (14), andiv. second axial coupling means (15),- wherein the first and second rotation torque transfer means (12, 14) extend on the respective male and female parts such, and- wherein the first and second axial coupling means (13,15) are positioned such,that when the drill string is subjected to rotation torque for drilling, relative axial movement is allowed between the male (8) and the female (9) parts when being in an interconnected state of co-operation between the first and second rotation torque transfer means- that the first and second axial coupling means include axial engagement means formed by radially directed protrusions on one of the male and the female parts, and- that the first and second axial coupling means include axial security coupling means, and that the axial security coupling means includes a thread coupling or a bayonet coupling. - Joint according to claim 1, characterized in that the first and second rotation torque transfer means (12, 14) are mating splines having contacting surfaces that extend in parallel with said axial direction (A) on the respective male (8) and female (9) parts or extend helically on the respective male and female parts, at a helix angle (α) between 0° and 20° to the axial direction.
- Joint according to claim 2, characterized in that when the male (8) and the female (9) parts are interconnected, the axial engagement means are arranged to engage in forward rotation of the drill string and/or reverse rotation of the drill string and thereby limit relative axial movement between the male and the female part.
- Joint according to any one of claims 1 - 3, characterized in that the female part (9) includes an inner and an outer wall, together defining an annular compartment for the reception of a sleeve-formed male part.
- Joint according to any one of claims 1 - 4, characterized in that a sealing arrangement (18) is positioned at an inside opening slot formed between the male (8) and the female (9) parts, as seen in an operative position with the first and second impact surfaces close to each other.
- Joint according to any one of claims 1 - 5, characterized in that the first and second impact surfaces (10,11;16,17) are arranged for shoulder drive, and that outside surfaces of meeting drill string components, at least in the region of the joint, form an essentially continuous envelope surface.
- Joint according to any one of claims 1 - 6, characterized in that the female part is sleeve-shaped having both the second rotation torque transfer means and the second axial coupling means being oriented on an inside sleeve wall.
- Male part (8) of a joint for joining together drill string components (6,7) in the form of drill rods or shank adapters for percussion drilling, wherein each drill string component extends along an axial direction, and wherein, in operation, impact shock waves and rotation torque are arranged to be transferred via the joint, wherein the male part (8) is part of a first drill string component (6) and is arranged to co-operate with a female part of a second drill string component, and wherein an impact surface on the male part is arranged to co-operate with an impact surface on the female part,
characterized in- that the male part (8) exhibits:i. first rotation torque transfer means(12), andii. first axial coupling means (13),for co-operation withiii. second rotation torque transfer means, andiv. second axial coupling means,on the female part (9),- wherein the first rotation torque transfer means for contacting the second rotation torque transfer means extend on the male part such, and- wherein the first axial coupling means for co-operation with the second axial coupling means is positioned such,- that when the drill string is subjected to rotation torque for drilling, relative axial movement is allowed between the male (8) and the female (9) parts when being in an interconnected state of co-operation between the first and second rotation torque transfer means- that the first axial coupling means includes axial engagement means formed by radially directed protrusions on the male part, and- that the first axial coupling means includes first axial security coupling means, and that the first axial security coupling means is arranged to form part of a thread coupling or a bayonet coupling. - Female part (9) of a joint for joining together drill string components in the form of drill rods or shank adapters for percussion drilling, wherein each drill string component extends along an axial direction, and wherein, in operation, impact shock waves and rotation torque are arranged to be transferred via the joint, wherein the female part (9) is part of a second drill string component (7) and is arranged to co-operate with a male part of a first drill string component, wherein a second impact surface on the female part is arranged to co-operate with a first impact surface on the male part,
characterized in- that the female part (9) exhibits:i. second rotation torque transfer means (14), andii. second axial coupling means (15),for co-operation withiii. first rotation torque transfer means, andiv. first axial coupling means,on the male part (8),- wherein the second rotation torque transfer means for contacting the first rotation torque transfer means extends on the female part such, and- wherein the second axial coupling means for co-operation with the first axial coupling means is positioned such,- that, when the drill string is subjected to rotation torque for drilling, relative axial movement is allowed between the male (8) and the female (9) parts when being in an interconnected state of co-operation between the first and second rotation torque transfer means,- that the second axial coupling means includes axial engagement means formed by radially directed protrusions on the female part, and- that the second axial coupling means includes second axial security coupling means, and that the second axial security coupling means is arranged to form part of a thread coupling or a bayonet coupling. - Drill rod (6;7) for percussion rock drilling, characterized in that the drill rod includes at least one male part (8) of a joint according to claim 8.
- Drill rod (6;7) for percussion rock drilling, characterized in that the drill rod includes at least one female part (9) of a joint according to claim 9.
- Drill rod according to claim 10 or 11, wherein the first and second impact surfaces (10,11;16,17) are arranged for shoulder drive, characterized in that outside surfaces of joint parts of co-operating drill rods are formed such that at least in the region of the joint they form an essentially continuous envelope surface.
- Shank adapter (5) for a rock drilling machine (1), characterized in that the shank adapter (5) includes a male part of a joint according to claim 8 or a female part of a joint according to claim 9.
- Shank adapter according to claim 13, characterized in that the shank adapter is provided with axial engagement means that are arranged to engage in forward as well as reverse rotation of the drill string and thereby limit relative axial movement relative to an attached and engaged drill string component.
- Method for joining together drill string components (6,7) in the form of drill rods and shank adapters for percussion drilling, wherein each drill string component extends along an axial direction (A), and wherein, in operation, impact shock waves and rotation torque are transferred via a joint, including the steps of:- initiating axial insertion of a male part (8) of a first drill string component into a female part (9) of a second drill string component,- rotate the first drill string component relative to the second drill string component to ensure engagement of axial security coupling means in the form of a thread coupling or a bayonet coupling,- continue axial insertion of the male part (8) into the female part (9) a determined distance whereby the first drill string component is allowed to rotate relative to the second drill string component to ensure engagement of axial engagement means and to ensure engagement of first and second rotation torque transfer means (12, 14) arranged on the respective male and female part.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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SE1450576 | 2014-05-16 | ||
PCT/SE2015/050550 WO2015174920A2 (en) | 2014-05-16 | 2015-05-18 | Joint and joint parts for drill string components and components |
Publications (3)
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EP3143237A2 EP3143237A2 (en) | 2017-03-22 |
EP3143237C0 EP3143237C0 (en) | 2023-07-05 |
EP3143237B1 true EP3143237B1 (en) | 2023-07-05 |
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EP15728942.2A Active EP3143237B1 (en) | 2014-05-16 | 2015-05-18 | Joint and joint parts for drill string components |
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US (1) | US20170089149A1 (en) |
EP (1) | EP3143237B1 (en) |
AU (1) | AU2015259870B2 (en) |
CA (1) | CA2947836A1 (en) |
RU (1) | RU2687837C2 (en) |
WO (1) | WO2015174920A2 (en) |
ZA (1) | ZA201607211B (en) |
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---|---|---|---|---|
FR3020654B1 (en) * | 2014-05-05 | 2016-05-06 | Ifp Energies Now | UPRIGHT ROD COMPRISING AN INTERNAL LOCKING RING AND A MEANS FOR ADJUSTING THE PLAY BETWEEN THE AUXILIARY TUBE ELEMENTS AND THE MAIN TUBE ELEMENTS. |
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-
2015
- 2015-05-18 RU RU2016149147A patent/RU2687837C2/en active
- 2015-05-18 EP EP15728942.2A patent/EP3143237B1/en active Active
- 2015-05-18 AU AU2015259870A patent/AU2015259870B2/en active Active
- 2015-05-18 WO PCT/SE2015/050550 patent/WO2015174920A2/en active Application Filing
- 2015-05-18 US US15/311,754 patent/US20170089149A1/en not_active Abandoned
- 2015-05-18 CA CA2947836A patent/CA2947836A1/en not_active Abandoned
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2016
- 2016-10-19 ZA ZA2016/07211A patent/ZA201607211B/en unknown
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AU2015259870A1 (en) | 2016-12-01 |
RU2687837C2 (en) | 2019-05-16 |
EP3143237C0 (en) | 2023-07-05 |
CA2947836A1 (en) | 2015-11-19 |
EP3143237A2 (en) | 2017-03-22 |
WO2015174920A3 (en) | 2016-03-10 |
US20170089149A1 (en) | 2017-03-30 |
ZA201607211B (en) | 2019-01-30 |
RU2016149147A3 (en) | 2018-11-07 |
RU2016149147A (en) | 2018-06-19 |
AU2015259870B2 (en) | 2019-05-02 |
WO2015174920A2 (en) | 2015-11-19 |
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