Patent Grant
11473375
The invention relates to a working machine, in particular a construction machine, having a mast, along which, by means of a positioning means, a rotary head is vertically movable, by which a telescopic Kelly rod having at least two Kelly bars is guided in a displaceable manner, wherein an outer Kelly bar designed for being supported on the rotary head and an inner Kelly bar are provided which comprises a rope suspension for a rope, by which the inner Kelly bar is vertically movable by means of a main rope winch, wherein, for the purpose of torque transmission, Kelly bars are provided on their external and/or internal sides with axially running drive keys as well as locking recesses on the drive keys and/or axial latch elements which can be moved into the locking recesses for axially locking the Kelly bars or moved out of the locking recesses for unlocking, in accordance with the preamble of claim 1.
The invention further relates to a method for working the ground with a working machine, having a mast, along which, by means of a positioning means, a rotary head is moved vertically, by which a telescopic Kelly rod having at least two Kelly bars is displaced and guided, wherein an outer Kelly bar that is supported on the rotary head and an inner Kelly bar are provided that is suspended on a rope, by which the inner Kelly bar is moved vertically by means of a main rope winch, wherein, for the purpose of torque transmission, the Kelly bars are provided on their external and/or internal sides with axially running drive keys as well as locking recesses on the drive keys and/or axial latch elements which are moved into the locking recesses for axially locking the Kelly bars or moved out of the locking recesses for unlocking, in accordance with the preamble of claim 7.
A Kelly rod is a telescopic tool rod which is composed of several tubular bar elements and has at least an outer Kelly bar and an inner Kelly bar. The inner Kelly bar, and thus the Kelly rod as a whole, is suspended on a rope, with the Kelly rod being guided by a Kelly guide and/or an annular rotary drive, also referred to as rotary head. Via the Kelly rod a torque can be transmitted from the rotary drive to a ground working tool, in particular a drilling tool, that is mounted on the lower end of the inner Kelly bar. Through a corresponding outward-telescoping of the individual Kelly bar elements with respect to each other greater drilling depths can also be reached.
For the torque transmission the individual Kelly bar elements have on their external side and their internal side axially running stop ledges that serve for the torque transmission. Moreover, in particular axial positions, especially in a starting and end region, locking recesses or latch elements are provided, through which the Kelly bar elements can be secured axially with respect to each other. In this way, axial compressive forces can also be applied via the drill drive to the Kelly rod and therefore the ground working tool. The outer Kelly bar can also be connected in an axially fixed manner to the drill drive.
Especially when working the ground in a discontinuous manner, for instance when producing a bore with a drilling bucket, the drilling bucket has to be moved repeatedly into the borehole and out of it again. Depending on the respective borehole depth the Kelly rod is accordingly telescoped inwards and outwards repeatedly. After filling of the drilling bucket with removed ground material this has to be withdrawn from the borehole for emptying. For this purpose, the individual Kelly bar elements have to be unlocked again and retracted into each other. In this retracted position the Kelly rod can be withdrawn from the borehole together with the drilling bucket and pivoted to an emptying position. Afterwards, for a further drilling step the drilling tool is moved into the borehole again with a renewed outward-telescoping of the Kelly rod.
The inward- and outward-telescoping of a Kelly rod requires time and skill on the part of the operator of the drilling apparatus. Usually, the locking positions are concealed so that the operator of the drilling apparatus is not able to identify where the latch element and a locking recess are located. It is known that the position of the individual Kelly bar elements with respect to each other is displayed to the operator of the drilling apparatus on his operating monitor. However, such displays are very complex from a control engineering viewpoint and require a precise calibration of the individual drive components and of the positions of the Kelly rod before commencement of drilling. Moreover, which type of Kelly rod is being used must be entered into the control.
A method for monitoring a Kelly drill rod is known from DE 10 2012 019 850 A1.
The invention is based on the object to provide a working machine and a method for working the ground which permit an especially efficient working with a Kelly rod.
The object is achieved on the one hand by a working machine having the features of claim 1 and on the other hand by a method having the features of claim 7. Preferred embodiments of the invention are stated in the respective dependent claims.
The working machine according to the invention is characterized in that a control is provided which is designed for the automatic locking and/or unlocking of the Kelly bar, in that by means of a first detection means a rotation angle of at least one Kelly bar can be detected and/or by means of a second detection means a force, torque or pressure change can be detected in a drive system, by which the positioning means, the rotary head and/or the main rope winch are driven, and in that the control is designed to determine a locking and/or unlocking of the Kelly bars depending on the detected rotation angle and/or the detected force, torque or pressure change.
A basic idea of the invention resides in the fact that a control is provided which is designed for the automatic locking and/or unlocking of the Kelly bars. By means of a first detection means a rotation angle of at least one Kelly bar can be detected. A latch element of a first Kelly bar can be applied with a certain slight pressure to the drive key of a second opposite Kelly bar. During a relative axial movement of the two Kelly bars with respect to each other the rotation angle initially remains the same. As soon as the latch element, during this axial movement, reaches a locking recess, which constitutes an axial recess along the drive key, the latch element rotates into the locking recess. This abrupt change of the rotation angle can be detected by the first detection means as an indication that a locking has taken place. The change of the rotation angle can be detected in a direct manner by suitable angle encoders, such as incremental encoders, or in an indirect manner by way of a force, torque or pressure change in the drive system of the rotary drive e.g. as a temporary load drop. The drive system can be designed as an electric or preferably as a hydraulic drive system.
According to a further aspect of the invention, alternative or additional provision is made in that by means of a second detection means a force, torque or pressure change is detected in the drive system, by which the positioning means, the rotary head and/or the main rope winch are driven. When a latch element locks into a locking recess two adjoining Kelly bars are interlocked. A simple axial movement of the latch element is then no longer possible which can be ascertained in the form of a corresponding power increase in the drive system of the axial drive unit. The axial displacement of the two Kelly bars with respect to each other can take place via the positioning means, the rotary head and/or the main rope winch. Depending on which drive unit is used e.g. the pressure in the respective hydraulic system or in the entire system can be monitored and a possible pressure increase can thus be detected. The same applies in the reverse order to an unlocking.
Depending on the detected rotation angle and/or the detected power change the control can thus reliably determine a locking and/or unlocking of the Kelly bar.
In the simplest case the Kelly rod consists of only two Kelly bars, namely a tubular outer Kelly bar and an inner Kelly bar arranged therein in a displaceable manner. To reach greater drilling depths it is advantageous in accordance with a further development of the invention that the Kelly rod has one or several intermediate Kelly bars that are arranged between the outer Kelly bar and the inner Kelly bar. In particular, Kelly rods having three or four Kelly bars are preferred.
Basically, the working machine according to the invention with the Kelly rod can be used for a variety of operations. According to a further development of the invention it is particularly expedient that on a lower end of the inner Kelly bar a drilling tool, in particular a drilling bucket or an auger, is mounted in a releasable manner. Such drilling tools can be employed for discontinuous drilling, in which a Kelly rod has to be extended and retracted repeatedly.
Another preferred embodiment of the invention resides in the fact that at least one input means is provided, with which a type and/or size of the Kelly rod, a position of the positioning means for the rotary head, a position of the rope and/or a type and/or size of the rotary head can be entered. In the simplest case, an input can be carried out via an input terminal. Alternatively, the positions can be detected automatically by means of sensors. Furthermore, it is possible to place the respective components into a defined starting position and to calibrate the working machine with these components. A preferred further development of the invention can be seen in the fact that the first detection means has a rotation angle encoder for detecting a rotation angle. By preference, the rotation angle encoder is integrated in the rotary head. However, provision can be made for any other sensor arrangements that are suitable for a direct or indirect detection of the rotation angle.
Another expedient embodiment variant of the invention resides in the fact that the second detection means has a pressure sensor for detecting a pressure increase. The pressure sensor can preferably be provided in a pressure line in the respective hydraulic system. By preference, the pressure sensor is located close to the component, the pressure of which is to be monitored in order to control the locking.
The method according to the invention is characterized in that by means of a control the Kelly bars are locked or unlocked automatically, that by means of a first detection means a rotation angle of at least one Kelly bar is detected and/or by means of a second detection means a force, torque or pressure change is detected in a drive system, by which the positioning means, the rotary head and/or the main rope winch are driven, and in that by the control a locking and/or unlocking of the Kelly bars is determined depending on the detected rotation angle and/or the detected force, torque or pressure change.
The method according to the invention can be implemented, in particular, with a working machine as described previously. Accordingly, the advantages described beforehand can be achieved.
An advantageous method variant of the invention resides in the fact that for the locking and/or unlocking a ground working tool on the Kelly rod is placed onto the ground, in particular onto a borehole bottom. In doing so, the ground working tool and the inner Kelly bar firmly connected thereto are located in a defined position. By preference, the outer Kelly bar or an intermediate Kelly bar according to the invention can now be moved relative to the inner Kelly bar until the desired locking or unlocking is realized. Basically, the method according to the invention can be used for every application, in which a tool with a Kelly rod is required. According to an embodiment variant it is especially preferred that a borehole is produced in the ground. The production of the borehole can be carried out by excavating the ground material.
According to a further embodiment variant of the invention provision is made in that the borehole is filled to form a foundation element. In the simplest case, the foundation element can be filled with a pourable material, such as sand or gravel. By preference, the foundation element is formed by filling a hardenable mass, more particularly a concrete material.
According to a further development of the method pursuant to the invention it is of advantage that for the locking of a Kelly bar a first torque is applied thereto, wherein a latch element is applied with slight pressure to a drive key of the opposite Kelly bar, and in that the two Kelly bars are moved axially relative to each other until the latch element rotates in the circumferential direction into a locking recess and/or abuts axially. The relative pressing-on between latch element and drive key takes place with an initial slight pressure that is predetermined by the control. In doing so, the pressure is set such that the two Kelly bars can still be moved axially relative to each other with relatively small frictional forces. When the latch element passes by a locking recess, the latch element rotates into the locking recess in the circumferential direction. This locking can be ascertained both by a change of the rotation angle between the two opposite Kelly bars and by a pressure change in the axial drive unit. Through the control an axial displacement of the two Kelly bars to each other is then set automatically. Where required, a further axial movement can take place if a further locking with another Kelly bar is desired.
According to the invention another method variant resides in the fact that the Kelly bar with the latch element is moved axially relative over a predetermined distance. The predetermined distance can range from some ten centimeters to a few meters. If, on running across this predetermined distance, no locking is ascertained, the movable Kelly bar can be reset by the control to the starting point, with an axial movement being once more effected over the predetermined distance. This process can be repeated once or several times. Should there still be no locking, an error indication or a request to carry out the locking in a conventional manner can be prompted to the operator of the drilling apparatus.
The invention is explained further hereinafter by way of preferred embodiments illustrated schematically in the drawings, wherein show:
The working machine 10 according to
According to the two embodiments pursuant to
At its upper end the outer Kelly bar 42 has a supporting collar 43, with which the outer Kelly bar 42 is supported on a rotary head 30, i.e. an annular rotary drive. For the damping of shocks a damping means 32 with springs is arranged between the rotary head 30 and the supporting collar 43 in the embodiment according to
In a known manner, corresponding drive keys 66 or latch elements are also arranged on the other external sides and internal sides of the further Kelly bar elements. On a lower side of the inner Kelly bar 46 a pin-shaped connection element 49 is provided, with which a ground working tool 36 can be mounted in a torque-proof manner. In the embodiments according to
In
For an axial locking of the outer Kelly bar 42 and the inner Kelly bar 46 the latch element 62 on the outer Kelly bar 42 is pressed lightly against the drive key 66 by applying a slight torque via the rotary head 30 by means of a control according to the invention. In this pressed-on position the outer Kelly bar 42 and the inner Kelly bar 46 are now moved axially to each other either via the positioning means 20 or the main rope winch 50. When the position illustrated in
Upon further axial movement of the outer Kelly bar 42 with respect to the inner Kelly bar 46 the block-like latch element 62 abuts axially against an axial stop 69 of the locking recess 68. A further axial movement of the outer Kelly bar 42 is now no longer possible or only with an increased expenditure of force which can be detected as a pressure increase in the hydraulic system 15, by which the axial drive member is driven. Likewise, an abutment of the latch element 62 in the circumferential direction against a lateral surface of the locking recess 68 can also be ascertained as a pressure change, a force change or a torque change by means of a second detection means 25, such as a pressure sensor, a force sensor or a torque sensor, in the hydraulic system 15 for driving the rotary head. These respective pressure, force or torque changes can be detected as a further indication for the presence of a successful locking of the Kelly bars and registered by the control.
| Number | Date | Country | Kind |
|---|---|---|---|
| 16185467 | Aug 2016 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2017/067529 | 7/12/2017 | WO |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2018/036713 | 3/1/2018 | WO | A |
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| Number | Date | Country | |
|---|---|---|---|
| 20190169941 A1 | Jun 2019 | US |
