This application claims priority under 35 U.S.C. ยง 119 to EP Patent Application No. 16175645.7, filed on Jun. 22, 2016, which the entirety thereof is incorporated herein by reference.
The present disclosure relates to a rock drill, and more particularly to a rock drill having a frame, a percussion member, a shank and an axial sleeve.
It is known to use an axial sleeve in a rock drilling machine for moving the shank to the intended percussion point during drilling and for adjusting the percussion power by adjusting the position of the shank. On the other hand, the axial sleeve can be used to dampen stress pulses reflected from the rock back to the drilling machine.
Many problems are associated with different arrangements available in the market. They do not provide sufficient dampening of stress pulses reflected from the rock, they require external pressure control and/or they cause problems for rattling threads of drill rods open.
To overcome the above disadvantages, the present disclosure is directed to a novel and improved rock drill.
An idea of the disclosed solution is that the rock drill includes a first pressure channel connected to a first pressure space provided in an axial direction on the side of the shank in relation to the axial sleeve, a pressure accumulator connected to the first pressure channel and that flow of the pressure medium outwards from the first pressure space is throttled by throttling the flow of the pressure medium from the first pressure space to the tank and/or the pressure lower than that of the external pressure connected to the second pressure space.
An aspect of the disclosed solution is that in the solution the axial sleeve provides a continuous support for the shank and the solution also provides good dampening of the reflection back from the rock to the drilling machine when the tool hits the rock. Additionally, the solution provides without external control a simple automatic rock drill internal control of the functional state change between drilling, during which a continuous support from the axial sleeve to the shank is needed, and rattling, in other words hitting/rattling the threads of the drill rod open, during which the axial sleeve should be kept from contacting the shank.
In the Following the Invention Will be Described in Greater Detail by Means of Preferred Embodiments with Reference to the Attached Drawings, in which
General structures and working principles of pressure-medium-operated rock drills used for percussive drilling are well known in the art. Therefore, they are not explained in more detail in this description. The figures are provided for illustrating the principles of the current solution. For the sake of clarity, not all necessary bearings, seals and ducts and other structural parts of a rock drilling rig and rock drill are shown in the figures, for example.
The shank 3 may be provided on the front side of the percussion member 2 in the direction of the impact A. In other words, the shank 3, and in particular an impact surface 4 of the shank 3, may be arranged to receive the impact pulses. The shank 3 may then further transmit the impact pulse to a tool, such as a drill bit 28. The impact pulse may include for instance a strike provided by kinetic energy of a percussion piston or a stress pulse provided by a transmission piston compressing the tool in its longitudinal direction. According to an embodiment, the axial shank 3 may include an integral drill rod. In other words, in such an embodiment the impact surface 4 receiving the impact pulses from the percussion member 2 may be arranged on the integral drill rod instead of a separate shank structure. Otherwise, this kind of an embodiment may be similar to an embodiment described in this description and comprising a separate shank structure or a combination of such embodiments.
The rock drill 1 may further include an axial sleeve 5 provided within the frame 6. More particularly, the percussion member 2, the shank 3 and the axial sleeve 5 may be provided within a space provided inside the frame 6 of the rock drill 1. The axial sleeve 5 may be used for moving the shank 3 to the intended percussion point during drilling and for adjusting the percussion power by adjusting the position of the shank 3, as well as for dampening stress pulses reflected from the rock back to the drilling machine when the tool is brought into contact with the rock to be drilled.
The axial sleeve 5 may include a first pressure surface 8 provided in a first pressure space 7 and a second pressure surface 10 provided in a second pressure space 9. The first pressure space 7 may be provided in an axial direction on the side of the shank 3 in relation to the axial sleeve 5 and the second pressure space 9 is provided in an axial direction on the side of the axial sleeve 5 opposite to that of the shank 3. Thereby the first pressure surface 8 of the axial sleeve 5 may be facing towards the shank 3 and the second pressure surface 10 may be facing away from the shank 3.
Pressure medium fed to the first and second pressure spaces 7, 9 may be arranged to act on the first pressure surface 8 and/or on the second pressure surface 10 for moving the axial sleeve 5 in the axial direction. The pressure medium may, thus, be arranged to act on one or both the first and the second pressure surface 8, 10 at the same time or in turns. Thereby, the axial sleeve 5 may have different position in relation to the frame 6 during a work cycle of the rock drill 1. A first channel 11 may be provided in the axial sleeve 5, which first channel 11 provides a connection between the first pressure space 7 and the second pressure space 9 in at least one position of the axial sleeve 5 in the frame 6, in other words in at least one position of the axial sleeve 5 in relation to the frame 6.
According to an embodiment, during drilling, the rock drill 1 is pushed forward in the impact direction A by a feeding force that is larger than balancing the momentum of the strikes. The difference between these forces causes the shank 3 to push the axial sleeve 5 backwards, in other words in return direction B. Thereby, the position of the axial sleeve 5 in relation to the frame 6 opens and closes the first channel 11 in such a manner, that the pressure medium in the first pressure space 7 acts the first pressure surface 8 with such a force that the axial sleeve 5 is kept in its position by a force that is a resultant of the force acting on the second pressure surface 10 and pushing the axial sleeve 5 forward in impact direction A and of the force acting on the first pressure surface 8 and pushing the axial sleeve 5 backwards in return direction B. When the forces change, the axial sleeve 5 moves by a small distance in relation to the frame 6, whereby the first channel 11 opens slightly more or less, which affects the pressure in the first pressure space 7 and, thereby, the force acting on the first pressure surface 8 changes keeping the resultant force between the forces pushing the axial sleeve 5 forward and backwards stable.
The rock drill 1 may further include a second pressure channel 13 connected to the second pressure space 9. The second pressure channel 13 may be connectable to external pressure, thus connecting the second pressure space 9 to the external pressure through the second pressure channel 13. The second pressure channel 13 may be provided at least partly in the frame 6.
The rock drill 1 may further include a pressure accumulator 14 connected to the first pressure space 7. The accumulator may use any accumulator known, as such for use in connection with pressure medium driven systems.
The flow of the pressure medium outwards from the first pressure space 7 may be throttled. Thereby, an improved control regarding the operation of the rock drill may be provided at the same time when the accumulator keeps pressure more stable than in known solution.
According to an embodiment, the rock drill 1 may further include a first pressure channel 12 connected to the first pressure space 7. The first pressure channel may be provided at least partly in the frame 6. The first pressure channel 12 may extend between the first pressure space 7 and the pressure accumulator 14.
According to an embodiment, the rock drill 1 may further include a fourth pressure channel 21 connected to the first pressure space 7 directly, such as in the embodiment of
According to an embodiment, when the threads of the drill rod 27a, 27b are rattled open, the rock drill 1 is pushed forward in a horizontal position by a feeding force that is only sufficient for balancing the momentum of the strikes. Thereby, the feeding force does not push the rock drill 1 forward and the shank 3 does not push the axial sleeve 5 backwards. In such conditions a sufficient amount of pressure medium flows from the second pressure space 9 through the first channel 11 to the first pressure space 7 and, on the other hand, to the pressure accumulator 14 to provide by the pressure medium in the first pressure space 7 and in the second pressure space 9 forces acting on the first pressure surface 8 and the second pressure surface 10, respectively, that are equal to one another but acting on opposite directions A and B. Thereby, the axial sleeve 5 is kept in place without pushing the shank 3 forward. In a balance situation the position of the axial sleeve 5 with respect to the frame 6 is such that the first channel 11 is at least partly open and an equal volume of pressure medium flow takes into the first pressure space 7 through the first channel 11 and outwards from the first pressure space 7 through throttling, whereby the pressures and the pressure medium flow stay unchanged.
According to an embodiment, the pressure accumulator 14 enables fast movements, whereby the axial sleeve 5 dampens the stress pulses 33 reflected from the rock 31 back to the drilling machine. During drilling, when the percussion member 2 generates an impact pulse to the shank 3 the percussion member 2 hits the shank 3 forward. The axial sleeve 5 then has pushing force that starts to move the axial sleeve 5 forward, in other words in the impact direction A, whereby the volume of pressure medium displaced from the first pressure space 7 is directed to the pressure accumulator 14. According to an embodiment, the throttling of the flow of the pressure medium outwards from the first pressure space 7, the areas of the first pressure surface 8 and the second pressure surface 10, as well as the capacity and the pre-charge pressure of the pressure accumulator 14, and in some embodiments also a second throttle 17 in the second pressure channel 13 and/or a non-return valve 18, are dimensioned in such a manner that the axial sleeve 5 is in contact with the shank 3 before the reflected stress pulse 33 is received by the shank 3, whereby the reflected stress pulse 33 is transmitted to the axial sleeve 5. The axial sleeve 5 thereby moves backwards, in other words in the return direction B, whereby the pressure medium volume displaced to the pressure accumulator 14 returns to the first pressure space 7.
The current solution thus enables solving the problem of many known solutions where the axial sleeve tends to push the shank 3 forward thereby making it difficult or impossible to rattle drill rod threads open in this manner without additional arrangements.
According to an embodiment, the flow of the pressure medium outwards from the first pressure space 7 may be throttled by dimensioning a clearance between the axial sleeve 5 and the frame 6 to throttle the leakage flow between the axial sleeve 5 and the frame 6. This clearance and, thus, throttling may be provided on an area towards the shank 3 or an area towards the second pressure space 9 from the first pressure space 7, as will be explained in connection with some related embodiments.
According to an embodiment, a second throttle 17 may be provided in the second pressure channel 13. According to an embodiment, the second throttle 17 may be adjustable to control the amount of pressure medium flowing through the throttle. According to a further embodiment, a non-return valve 18 may be provided in the second pressure channel 13 connected and in parallel with the second throttle 17, such that the non-return valve 18 enables flow of the pressure medium in to the second pressure space 9 but not outwards from the second pressure space 9. Thereby flow of the pressure medium outwards from the second pressure space 9 can only take place through the second throttle 17. In other words, flow of the pressure medium to the second pressure space 9 is not throttled, but the flow of the pressure medium outwards from the second pressure space 9 is throttled.
According to an embodiment, a sixth pressure channel 19 may be provided in the frame 6 on an area on the opposite side of the second pressure space 9 in relation to the first pressure space 7 and the shank 3. The sixth pressure channel 19 may be used to direct leakage flow between the axial sleeve 5 and the frame 6 backwards from the second pressure space 9 to a tank or to a pressure lower than the external pressure provided to the second pressure space 9.
According to an embodiment, the third pressure channel 16, the fourth pressure channel 21 and/or the fifth pressure channel 23 may be connected to a tank 20. In other words, the first pressure space 7 may be connected to a tank 20 through the first pressure channel 12, the third pressure channel 16, the fourth pressure channel 21 and/or the fifth pressure channel 23. According to a further embodiment, the first pressure space 7 may be connected through the first pressure channel 12, the third pressure channel 16, the fourth pressure channel 21 and/or the fifth pressure channel 23 to a pressure lower than that of the external pressure connected to the second pressure space 9 instead of or in addition to being connected to the tank 20.
According to an embodiment, the flow of the pressure medium outwards from the first pressure space 7 is throttled by throttling the flow of the pressure fluid from the first pressure space 7 to the tank 20 and/or the pressure lower than that of the external pressure connected to the second pressure space 9. As explained above, the throttling may be provided by a first throttle 15 provided in a fourth pressure channel 21 or by a clearance between the axial sleeve 5 and the frame 6. The throttled channel, which, depending on the embodiment, may be the third pressure channel 16, the fourth pressure channel 21 and/or the fifth pressure channel 23, may be connected to the first pressure space 7 directly or indirectly via another channel, such as via the first pressure channel 12.
According to an embodiment there is no throttling or at least no substantial amount of throttling capable of affecting the operation of the rock drill 1, between the first pressure space 7 and the pressure accumulator 14. In other words, the connection between the first pressure space 7 and the pressure accumulator is substantially not throttled. In other words, the pressure fluid is enabled to flow substantially in a substantially unthrottled manner from the first pressure space 7 to the pressure accumulator 14 directly or through the first pressure channel 12.
According to an embodiment, the rock drill 1 is a hydraulically driven rock drill and the pressure medium comprises a hydraulic fluid.
It will be obvious to a person skilled in the art that, as the technology advances, the inventive concept can be implemented in various ways. The invention and its embodiments are not limited to the examples described above but may vary within the scope of the claims.
Number | Date | Country | Kind |
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16175645 | Jun 2016 | EP | regional |
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Number | Date | Country | |
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20170370150 A1 | Dec 2017 | US |