The present invention is a device that imparts a percussive force to a tool when that tool meets resistance to rotation, if the resistance continues this percussive force can be periodically applied. Specific applications include rock drills used to drill into the ground and small drills used to drill concrete and the like where variations in the material being drilled can slow or stall the drill; and pile drivers. In an alternative form the device incorporates a locking mechanism that forces the percussive device into a percussion only form.
When a drill is used to drill into rock it can meet material that can slow or stop that drill, to continue drilling the drill head can be backed off from the surface and whilst rotating the drill head pushed into contact in an attempt to clear the material to recommence the drilling operation. This takes time and does not always allow drilling to recommence, sometimes the drill needs to be withdrawn and a different drill head or drill used until the obstructive material is cleared or passed through. If the drill is rotating and it meets material that stops the drill's rotation quickly then damage to the drill head and/or drill string and/or drive unit may occur.
Conventional drilling is often used with non-impact, purely friction methods, this is, or can be, slow.
To overcome the requirement to withdraw the drill, or back the drill head off and back into contact, some drill strings incorporate a percussion unit to apply a periodic percussive force to the drill string or drill tip. These devices include percussion hammers driven by pneumatic or hydraulic systems these can be expensive to run, require an auxiliary source of energy to run the percussion, often via the drilling fluid medium. These devices often require compressed air which in some situations can be problematic. In addition many of these percussion devices operate continuously or at a fixed rate once engaged; this may not be optimum in many situations. Often the drill head on a percussion hammer drill string is held on by one or more split rings, if these rings break the drill head can be lost, or at least difficult to recover.
For some subsurface operations it would be useful to apply a percussive force with some rotational impulse, however percussion hammers cannot do this.
Any discussion of the prior art throughout the specification is not an admission that such prior art is widely known or forms part of the common general knowledge in the field.
It is an object of the present invention to provide a solution to ameliorate one or more of the problems outlined above, or at least provide a consumer with a useful choice.
The present invention provides a percussion device including
Preferably at least one of said at least one drive transmitter is configured to slide or roll along at least part of a length of said drive transmitter pathway.
Preferably, where the drive transmitter pathway is part of the percussion impactor, the percussion impactor includes an impact end and a force input end (FI end) where the impact end and the FI end are the opposite terminal ends of the percussion impactor, and the drive transmitter pathway includes at least one lift section and at least one lead section.
Preferably, where the drive transmitter pathway is part of the percussion impactor, as you move along any one lift section the distance between the FI end and the drive transmitter pathway increases, and as you move along any one lead section the distance between the FI end and the drive transmitter pathway suddenly decreases to a minimum, one lift section followed by one lead section forms a tooth section.
Alternatively, where the drive transmitter pathway is part of the percussion impactor, as you move along any one lift section the distance between the FI end and the drive transmitter pathway initially decreases forming a scalloped section at the start of the lift section, then the distance increases, and as you move along any one lead section the distance between the FI end and the drive transmitter pathway suddenly decreases to a minimum, one lift section followed by one lead section forms a tooth section.
In a preferred form, where the drive transmitter pathway is part of the percussion impactor, as you move along the lift section at a constant rate, the rate of change of the distance between the FI end and the drive transmitter pathway changes, creating a variable slope to the lift section.
Preferably there are at least two drive transmitters. In a highly preferred form there are an even number of drive transmitters. Preferably there are from 1 to 8 drive transmitters.
Preferably, where the drive transmitter pathway is part of the percussion impactor, one tooth section is followed by a base section, where the base section is essentially a constant distance from the FI end. Preferably the base section is inclined at a slope much less than the tooth section.
In an alternative preferred form, where the drive transmitter pathway is part of the outer casing, the drive transmitter pathway includes at least one lift section and at least one lead section. Preferably as you move along any one lift section the distance between the input side and the drive transmitter pathway increases, and as you move along any one lead section the distance between the input side and the drive transmitter pathway suddenly decreases to a minimum, one lift section followed by one lead section forms a tooth section. In an alternative preferred form, as you move along any one lift section the distance between the output side and the drive transmitter pathway increases, and as you move along any one lead section the distance between the output side and the drive transmitter pathway suddenly decreases to a minimum, one lift section followed by one lead section forms a tooth section.
Preferably the scalloped lead in section is incorporated into the variants where the drive transmitter pathway is incorporated into the outer casing. In preferred variations, where the drive transmitter pathway is part of the outer casing, the slope of the lift section can be variable and/or include scalloped sections.
Preferably one tooth section followed by one base section is a wave with a wavelength A. Alternatively one tooth section is a wave with a wavelength A.
Preferably the drive transmitter pathway includes from 2 to 1000 wavelengths. In a highly preferred form the drive transmitter pathway includes from 2 to 20 wavelengths.
Preferably there is a force unit in contact with the force input end that is configured to store energy as the or each drive transmitter moves along the lift section it is in contact with. Preferably when the or each drive transmitter passes into the lead section the stored energy is released into the percussion impactor accelerating it towards a percussion anvil which is part of the output section, upon contact with the percussion anvil some or all of the stored energy is transferred from the percussion impactor to the output section as a percussive impulse. Preferably the percussive impulse includes a rotational component.
In an alternative form the present invention provides a percussion device that includes:
Preferably the percussion impactor is rotationally linked to the percussion anvil.
Preferably the output section includes an impactor shaft which is an elongate member extending above the percussion anvil and the percussion impactor includes an impactor shaft tunnel which is a longitudinally co-axially aligned void, such that the impactor shaft is a longitudinal sliding fit within the impactor shaft tunnel, wherein the impactor shaft and the impactor shaft tunnel are dimensionally configured to transmit rotational motion of the percussion impactor to the output section. Preferably the cross section of the impactor shaft and the impactor shaft tunnel are selected from the following list, rectangular, square, irregular polygon, regular polygon star shaped, cross shaped, oval, elliptical, lobed, any of the previously mentioned shapes with rounded corners (if present) and obround. Preferably the impactor shaft is longitudinally twisted. Preferably the twist is between 1/20th and ¾ of a turn. More preferably between 1/20th and ½ a turn.
Preferably the drive transmitter pathway is a continuous circumferential pathway. In an alternative form the drive transmitter pathway is a plurality of disconnected tooth sections, which in combination with spaces between said tooth sections form a continuous circumferential pathway.
Preferably the input side includes a casing which at least partially surrounds the percussion impactor and percussion anvil. Preferably the casing includes a force face, where said force face is an inner face of the casing that faces the force input end of the percussion impactor.
Preferably a force unit lies between the force face and the force input end. Preferably the force unit stores energy as it is compressed. Preferably the force unit is one or more devices independently selected from the following list a constant or variable rate compression spring, a constant or variable rate solid elastomeric spring, a constant or variable rate magnetic spring and a gas spring.
In one preferred form the drive transmitter pathway forms part of, or is attached to, the percussion impactor and the at least one drive transmitter is attached to a drive wall, where the drive wall is an inner wall of the casing.
In an alternative preferred form the at least one drive transmitter forms part of the percussion impactor and the drive transmitter pathway is attached to, or formed as part of, a drive wall, where the drive wall is an inward facing wall of the casing.
Preferably the at least one drive transmitter is a roller or a follower configured to slide or roll along at least part of the length of the drive transmitter pathway.
Preferably the lift section includes a scalloped indent.
Preferably the output section can be rotationally locked. Preferably when the output section is rotationally locked the percussion device imparts essentially percussive force to the output section.
Preferably the output section is attached to a drill string including a drill bit, or a drill bit.
Preferably the percussion device is used as part of a drilling rig.
In an alternative preferred form the percussion device is used to extract a jammed drill string or drill bit.
In an alternative form the percussion device is used to percussively drive a pile or casing into the ground or through a piece of material.
Preferably the at least one drive transmitter is configured to unload when it passes over an apex of a tooth section.
Preferably at least one tooth section is followed by a base section, where the base section is a space or a portion of the drive transmitter pathway. Preferably the base section is either:
In a preferred alternative the base section is inclined at a slope much less than the tooth section.
Preferably one tooth section followed by one base section is a wave with a wavelength λ. Alternatively one tooth section is a wave with a wavelength λ.
Preferably the drive transmitter pathway includes from 2 to 1000 wavelengths λ. In a highly preferred form the drive transmitter pathway includes from 2 to 20 wavelengths λ.
In any preferred or alternative variant the length of the base section, measured circumferentially, is between 0.5 and 4 times the length of the tooth section, measured circumferentially.
Preferably there are from 1 to 8 drive transmitters. In a highly preferred form there are 2 to 8 drive transmitters.
Preferably there is one tooth section for each drive transmitter.
By way of example only, a preferred embodiment of the present invention is described in detail below with reference to the accompanying drawings, in which:
Sawtooth: is a waveform that has an inclined section extending from a base to an apex which drops abruptly to the base after the apex. This term is intended to cover waveforms that are similar to breaking surf or otherwise include an undercut section below the apex, as well as waveforms which have sharp or rounded apexes and curved or linear inclined sections.
Shaft: a thin long piece of rigid material that turns or is turned to pass on power or movement to another part, it may have any cross-sectional shape appropriate for the purpose, it may be hollow (tube like) or a solid material:
Please note that where a range is provided it is intended that any sub-range falling within that range is also specifically covered, for example a range of 2 to 20 covers all ranges defined by the formula x to y where x is selected from 2 to 20 and y is selected from x to 20; 0.05 Hz to 500 Hz covers all ranges defined by the formula a to b where a=0.05 to 500 Hz and b=a to 500 Hz. The interval depends on what the range covers, if the range covers the number of objects present then it is likely the smallest division is one object so a range of 1 to 10 would be 1, 2, 3, 4, 5, 6, 7, 8, 9 and 10; if the range was for example a frequency range then it includes fractional parts down to the limitations of measurement.
Please note that the drawings are representative only and some of the relative dimensions or relative scales differ from that present in the preferred or optimum versions, this is for clarity reasons.
Referring to
Referring to
Referring to
Where the input assembly (20) is located on the input side (10) of the percussion device (1) and the output assembly (27) is located on the output side (11) of the percussion device (1).
Referring to
The first section (30) includes a first section side surface (30a) (FS side surface (30a) for brevity) and the pathway section (32) includes a second section side surface (32a) (SS side surface (32a) for brevity). Where the side surfaces (35,36) are the exposed sides of the relevant section. The drive transmitter pathway (26) extends from the FS side surface (30a) to the SS side surface (32a) where the first section (30) and pathway section (32) are coterminous. The drive transmitter pathway (26) is a continuous path that encircles the percussion impactor (25). It is preferred, but not necessarily required, that the surface of the drive transmitter pathway (26), at any point along its path, lies on a plane perpendicular to the longitudinal axis of the percussion impactor (25).
The pathway section (32) is shown circular in cross-section with a diameter greater than the largest cross-sectional dimension of the first section (30). In this case the first section (30) is shown with a circular cross-section so the width (W) of the drive transmitter pathway (26) is constant around the percussion impactor (25) but, in some configurations, the cross sectional shape of the first section (30) will not be circular (it may be polygonal or oval for example).
The IS tunnel (34) is an open-ended void aligned with the longitudinal axis of the percussion impactor (25), with apertures at each terminal end of the percussion impactor (25). The cross-sectional shape and dimensions of the IS tunnel (34) are such that when engaged with the impactor shaft (29) the percussion impactor (25) can slide along a portion of the length of the impactor shaft (29). The complementary cross sectional shapes of the IS tunnel (34) and the impactor shaft (29) are such that there is minimal differential rotational motion between the percussion impactor (25) and the impactor shaft (29) when engaged. It is preferred that the percussion impactor (25) can freely slide along at least a portion of the length of the impactor shaft (29). In
The impact end (31), in this first variant, is a flat surface that lies on a plane perpendicular to the longitudinal axis of the percussion impactor (25).
The distance between the force input end (31) and the drive transmitter pathway (26) varies as you move along the length of the drive transmitter pathway (26). Moving along the drive transmitter pathway (26) in the direction of arrow C the distance between the force input end (31) and the drive transmitter pathway (26) increases then rapidly decreases and then remains the same until it increases again then rapidly decreases and then remains the same before repeating the pattern. The pathway waveform (75) is essentially a tooth with each tooth spaced apart. The number of rises for each full rotation of the percussion impactor (25) will vary but it is thought that it will be an even number (2 to 1000) and in use will result in a percussive frequency of between 0.1 to 150 Hz, though some applications may fall in the range of 0.05 Hz to 500 Hz.
The percussion impactor (25) is expected to be a dense rigid material, most likely metal and preferably one or more forms of steel. In this first variant the percussion impactor (25) is an essentially solid construction, but, it may, in certain configurations, include voids that can be filled with liquid materials to change the behaviour of the percussion impactor (25). For example the void could be partially filled allowing the liquid to move or the mass of the percussion impactor (25) could be adjusted whilst in use by adding or removing liquid. If mercury was used then the mass would be greater than a steel percussion impactor (25); the density of mercury is 13.5 tonne/m3 and the density of steel is about 7.8 tonne/m3.
Referring to
Referring to
The outer casing (2) includes an open terminal end, the open casing end (57), where the open casing end (57) and the base portion (51) are opposite terminal ends of the outer casing (2).
The outer casing (2) includes a drive wall (58) and an exposed casing wall (59), the exposed casing wall (59) is the face of the outer casing (2) that is coterminous with the exposed surface of the percussion device (1). The drive wall (58) and the exposed casing wall (59) are the opposite faces of the outer casing (2). The alpha section (23) is a flat ring of material attached to, and extending perpendicularly from, a portion of the drive wall (58) close to the open casing end (57), an annulus extending from the portion of the drive wall (58). When the percussion device (1) is in the assembled form the alpha section (23) lies between the isolation support (37) and the isolation disc (39), with a sliding or clearance fit between the alpha section (23) and the isolator (38). There is also a sliding or clearance fit between the drive wall (58) and both the isolation disc (39) and the isolation support (37).
The force unit (22) is shown as a coil spring, either constant rate or variable rate, extending from the force face (55). The force unit in this case is coaxially aligned with the outer casing (2). The force unit (22) includes the primary end (60) and a secondary end (61), with the primary end (60) and secondary end (61) being opposite terminal ends of the force unit (22). As previously indicated the primary end (60) is the end closest to the force face (55). The force unit (22) can include springs, pressurised gas (e.g. gas strut), magnetic sources with like poles closest, or a plurality of items independently selected from this list.
Referring to
Referring now to
The cross sectional shapes of the impactor shaft (29) and the IS tunnel (34) are complementary and do not allow differential rotational motion between them (unless the impactor shaft (29) has a longitudinal twist).
Referring to
Before describing this first variant of the percussion device (1) in use we will describe some variants of the drive transmitter pathway (26) by stretching it out and laying it flat so the pathway waveform (75) can be viewed. Referring to
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Referring to
Referring to
It should be noted that the height (H) may be as low as 1 mm to 10 mm and up to the diameter of the pathway section (32) (though it may be necessary in some applications to extend this to two times the diameter of the pathway section (32)). The maximum diameter of the percussion device (1) is the diameter of the hole that the drill bit forms, the percussion impactor (25) will have a diameter less than this as it fits within the outer casing (2).
One preferred method of operation of the percussion device (1) will now be described with reference to any one of
Referring to
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Referring to
If the output assembly (27) is attached to a drill bit that has hit hard material and stopped this percussive impulse should clear it. The base section (80) puts a period of time between percussions which can be optimised for various drill and/or ground conditions. The intermittent percussive action when a drill is slowed by ground conditions to below a certain value is expected to improve penetration rates in certain problematic formations.
Referring to
An optional supplementary isolation buffer (91) is shown between the alpha section (23) and the isolation support (37); this is similar in configuration to the isolation buffer (90).
The isolation buffer (90) and the optional supplementary isolation buffer (91) are shown partially filling the gap, in some variants they may completely fill the gap.
In further configurations the isolation buffer (90) or supplementary isolation buffer (91), if present, includes, or is, a coil spring or annular magnets with like poles facing.
The supplementary isolation buffer (91) can, when present, act to isolate the percussion device (1) from impacts and other impulse forces applied by the components downstream of the output section (11). For example if the percussion device (1) is attached to a drill bit (not shown) that impacts hard material causing it to bounce this impulse can be damped.
Properly dimensioned the isolation buffer (90) and the optional supplementary isolation buffer (91) can seal against the surface of the isolator (38) to minimise or eliminate the ingress of material into the interior of the percussion device (1).
Referring to
With a twist the vertical section of the drive transmitter pathway (26) could contact the drive transmitters (21) (not shown in
Referring to
Referring to
The primary shaft (101) includes a primary reduced section (104) and primary expanded end (105), the primary reduced section (104) is a length of the primary shaft (101) that has a smaller outside diameter than the minimum cross sectional dimension of the remainder of the primary shaft (101). The primary expanded end (105) is the terminal end of the primary shaft (101) most distant from the force face (55) and the primary reduced section (104) is immediately adjacent to the primary terminal end (106). The primary expanded end (105) is an annulus with a primary shaft hole (107).
The secondary shaft has a tau terminal end (108) where the tau terminal end (108) is the terminal end of the secondary shaft (102) furthest from the isolation support (37). The tau terminal end includes a tau aperture (109) which is a circular aperture dimensioned to accept the primary reduced section (104) but too small to allow the primary expanded end (105) to pass through. The tau aperture is a pathway to a cylindrical void within the secondary shaft (102), a connection void (110). The diameter of the connection void (110) is greater than the diameter of the tau aperture (109). The primary reduced section (104) sits within the tau aperture (109) and the primary expanded end (105) sits within the connection void (110). The dimensions of the primary expanded end (105) and the connection void (110) are such that they form a sliding fluid tight seal that rotationally isolates the primary shaft (101) from the secondary shaft (102). The length of the primary reduced section (104) and the connection void (110) allows the length of the impactor shaft (29) to change whilst the fluid seal and rotational isolation remains. This variant of the output section (27) could also incorporate any of the known means of providing a fluid pathway that rotational isolates a primary shaft (101) and a secondary shaft (102) whilst allowing differential longitudinal movement and maintaining a fluid seal.
Referring to
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In the extraction configuration the percussion impactor (25) is inverted and the force input end (FI end) (33) is located adjacent to the isolation support (37), with the force unit (22) separating the isolation support (37) and percussion impactor (25).
The impactor shaft (29) includes a shaft terminal end (125), which is the terminal end of the impactor shaft (29) that is not attached to the isolation support (37). In this extraction variant the percussion anvil (28) is a disc that is coterminous with the shaft terminal end (125).
In operation the outer casing (2) is turned in the direction of arrow E, and the output shaft (40) is locked (prevented from rotating) by the locking device (115). The drive transmitters (21) move along the base section (80) up the lift section (96) storing energy in the force unit (22). The drive transmitters (21) pass over the vertex into the lead section (95) releasing the energy stored in the force unit (22) which accelerates the percussion impactor (25) towards the percussion anvil (28). The percussion impactor (25) hits the percussion anvil (28) transferring a percussive impulse to the impactor shaft (29) which transfers this percussive impulse to the output shaft (40). This percussive impulse is transferred to the object (not shown) to be extracted, which could be a pile, a drill bit, or a drill string or any components of that drill string.
Referring to
The swivel (131) is a standard piece of equipment used for drills that provides a pathway for a material to be introduced into a rotating portion of the drill string (133) from a static point, or it allows a component within the drill string (133) to be isolated from the rotation of other components. In this case the swivel (131) provides a pathway for the fluid conduit (130) to pass through the outer casing (2) into the percussion device (1) interior.
The fluid conduit (130) is a tube or other form of hollow elongate member that provides a pathway for a fluid introduced above ground to be fed to the drill bit (132), or part of the drill string (133) below the percussion device (1).
The fluid conduit (130) passes through an impactor pathway (134) which is a centrally aligned open ended hole through the impactor shaft (29), the impactor pathway (134) being dimensioned and configured to allow the fluid conduit (130) to be rotationally isolated from the impactor shaft (29). The fluid conduit (130) also passes through an output pathway (135) which is a centrally aligned open ended hole through the output section (36). The output pathway (135) being dimensioned and configured to allow the fluid conduit (130) to be rotationally isolated from the output section (36). The fluid conduit (130) then passes down the drill string (133) below the percussion device (1) to the drill bit (132). The fluid conduit (130) is connected to the drill bit (132) by a bit sliding joint (136). The bit sliding joint (136) allows the fluid conduit (130) to feed a fluid into the drill bit (132), or drill string (133) below the percussion device (1), whilst still rotationally isolating the fluid conduit (130) on the input side (10) from the drill bit (132). The bit sliding joint (136) allows for a certain amount of horizontal or co-axial longitudinal movement between the drill bit (132) and the terminal end of the fluid conduit (130), whilst maintaining a fluid seal, this may be accomplished in a similar manner to that shown in
Referring to
The percussion device (1) is attached to a percussion drive unit (120) that, in use, allows the outer casing (2) to be rotated. A locking device (115) that can rotationally lock the output side (11) of the percussion device (1) is attached to the mast (136) and the percussion unit (1).
In use the main drive unit (5) drives the drill bit (132) rotationally and the rig (3) inserts it into the ground (117). When the casing (141) is to be driven into the ground (117) the output side (11) of the percussion device (1) is engaged with an end of the casing (141), the percussion drive unit (120) and locking device (115) are engaged to generate percussive impulses. The percussive impulses from the percussion device (1) are transferred to the casing (141) which assists in driving the casing (141) into the ground (117).
In this variation the percussion operation can be turned on and off by locking/unlocking the output shaft (4) which allows extra casing sections to be inserted and control the rate of casing (141) installation; and/or by engaging or disengaging the percussion drive unit (120).
Referring to
Though described with reference to a drilling rig (3) for drilling holes into the ground the percussion device (1) can be used with smaller power tools to provide a percussive impulse when drilling holes in hard or specific materials. In addition the percussion device (1) can be used in any suitable application which requires the conversion of a rotational motion to a percussive and/or rotational motion.
Where the ranges include the terminal figures, of operational parameters for a drilling rig (3), using any of the variants or combinations of the variants:
Number of wavelengths per complete rotation of the percussion impactor (25)=1 to 40, preferably an even number from 2 to 20. Smaller diameter applications may extend this range to 1 to 1000, but this is yet to be confirmed and some may not be practical.
Height (H)=2×the diameter of the drill bit to 1 mm, preferably about the diameter of the drill bit to 5 mm. If there is no drill bit then the range is 1.2 m to 1 mm. Between 100 mm and 900 mm is expected to be most useful for drilling operations.
Rotational velocity (in rpm)=1 rpm to 50 rpm for drills above about 600 mm in diameter and 4 to 1200 rpm for drills below about 600 mm in diameter. For extraction and pile driving applications the frequency and/or the percussive impulse force will determine the acceptable range. For smaller power tools the rotational velocity is determined by the application, for example a power drill with a tungsten carbide drill being used for concrete drilling will be different to a high speed drill being used for drilling wood, metal or ceramic. The rotational velocity (in rpm) for smaller power tools will also change as the diameter of the drill changes, for example a drill used for printed circuit boards could run as fast as 30,000 rpm and be 0.3 mm in diameter whereas a wood drill could be 65 mm in diameter and run at 600 rpm. Those skilled in the art can easily determine the required rotational velocity (rpm) optimum for various material tool combinations for smaller power tools. Though the percussion device (1) may be built into a smaller power tool it could also be provided as a separate attachment for a smaller power tool, for example driven by the chuck of an electric drill. Notwithstanding the above ranges it is expected that for drilling rig applications the percussive impulse frequency will be from 0.1 to 150 Hz, though some applications may fall in the range of 0.05 Hz to 500 Hz
In a further variant there are two interlinked percussion impactors (25), one for starting a pile and the other for driving it to completion able to be separated so as to engage the one required. This could also be a single percussion impactor (25) with two separate drive transmitter pathways (26) and a method of varying how far the drive transmitters (21) extend from the drive wall (58). The drive transmitters (21) engaging with the desired drive transmitter pathway (26) depending on the extension.
The force unit (22) for any of the variants can be any known device that allows the storage of energy as it is compressed, and the release of this energy as it is allowed to decompress. For example compression springs with constant or variable rates, a plurality of compression springs of constant or variable rate, gas springs of variable or constant rate, solid elastomeric springs (for example those described in US20130069292) sometimes called elastomer springs, magnetic springs (for example those described in U.S. Pat. No. 3,467,973) or a combination of one or more of these.
For certain applications the force unit (22) may be a space that allows the percussion impactor (25) to rise upwards against gravity, the percussion impactor (25) simply falling under gravity to generate the percussive impulse.
Though not shown in all variants, for clarity, the isolation buffer (90) and optional supplementary isolation buffer (91) can be present in any variant. The isolation buffer (90) and optional supplementary isolation buffer (91) can be as described earlier or have a construction similar to that described for the force unit (22).
The isolation buffer (90) and optional supplementary isolation buffer (91) may act to seal the gap between the outer casing (2) and the isolator (38) or there may be additional sealing rings of known type present.
Where the term drive unit (5,120) is used it is intended to cover any drive device used to rotationally drive a drill string, drill or drill bit, for example a hydraulic or electric motor, a diesel engine, a hydraulic motor with gearbox, an electric motor plus gearbox, etc.
The number of drive transmitters (21) present can be any number from 1 upwards, the specific variants are likely to have 2 to 6, but for correct operation it is believed that the number should not exceed the number of wavelengths present in the drive transmitter pathway (25).
With the loads applied to the or each drive transmitter (21) and drive transmitter pathway (26) a mechanism that reduces the load on, and/or contact force between, these components may be necessary to increase their lifespan, and/or increase the efficiency of the percussion device (1) (see any of
The sigma device (150) is optional and though in optimum configurations it is likely to be present the form of the sigma device (150) can vary.
For clarity
Referring to
It should be noted that although the drive transmitter pathway (26) is shown as a continuous pathway, it may in fact be implemented as a series of disconnected teeth as the drive transmitters (21) are not intended to contact the base section (80) immediately downstream of the lift section (96). If a drive transmitter (26) impacts the base section (80) downstream of the lift section, as/before the percussive impulse is generated, it will likely reduce the percussive impulse generated as the percussion impactor (25) hits the percussion anvil (28), in addition the drive transmitters (21) may be damaged by the impact. This variant, implemented on a percussion impactor (25), is shown in
As can be seen various components from different variants and/or embodiments can be combined without departing from the inventive concept to achieve different operational parameters. For example the spacing between the tooth sections, the number of tooth sections, the length of the lead section, whether the drive transmitters are attached to the percussion impactor or the casing, the number of drive transmitters, whether the drive transmitter pathway is a series of spaced apart tooth sections or a continuous path, the form of the force unit, the form of the drive transmitters, the presence of a sigma device, or any similar components can be combined without deviating from the inventive concept.
Number | Date | Country | Kind |
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712842 | Sep 2015 | NZ | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2016/055812 | 9/29/2016 | WO | 00 |