Attachment for drilling and/or foundation work

Abstract

The present invention relates to an attachment for drilling and/or foundation work, in particular a casing oscillator or casing rotator, comprising a receiving apparatus for clamping at least one pipe and a drive for generating a rotational movement of the clamped pipe, wherein the attachment comprises at least one integral control unit for an independent carrying out of control functions of the attachment.

Claims

1. An attachment for drilling and/or foundation work, comprising a reception apparatus for clamping at least one pipe and a drive for generating a rotational movement of the clamped pipe, wherein the attachment comprises at least one integral control unit having a control logic for an independent carrying out of at least one control function of the attachment and at least one communication interface for communication with a base machine, with the control unit invoking machine-relevant parameters of the base machine via the communication interface and/or providing machine-relevant parameters of the attachment via the communication interface, at least one transmission and reception unit is provided to enable a wireless and/or wired communication with at least one external unit, and at least one control function is the control of automatic movement routines for an automatic oscillating system and/or an automatic pipe drawing device.

2. An attachment in accordance with claim 1, wherein the attachment comprises one or more sensors whose sensor data can be read by the control unit and can be evaluated and can be taken into account for the carrying out of the control functions.

3. An attachment in accordance with claim 1, wherein control commands for controlling the attachment can be received via the communication interface and can be interpreted by the control unit to control one or more actuators of the attachment and/or to carry out control functions of the control unit.

4. An attachment in accordance with claim 1, wherein the attachment comprises at least one display element for reproducing the machine-relevant or control-relevant data and/or data invoked via the communication interface.

5. An attachment in accordance with claim 1, wherein an electric and/or hydraulic and/or pneumatic supply of the attachment can be provided via an interface by a base machine.

6. An attachment in accordance with claim 1, wherein at least one control function is the provision of at least one assistance system for operation and/or putting into operation the attachment.

7. An attachment in accordance with claim 6, wherein the control unit is configured to carry out an assisted setting of the pile inclination during which the control unit controls one or more actuators to set the desired pipe inclination while taking account of the sensor values.

8. An attachment in accordance with claim 6, wherein the control unit is configured to carry out an automated depth measurement of the casing/of the drilling pipe as an assistance system and optionally to prepare and output a prediction with respect to the completion of the pile.

9. An attachment in accordance with claim 1, wherein the control unit is configured to generate an automatic request to increase and/or to decrease the hydraulic power provided by a base machine in dependence on the process-dependent power requirement of the attachment and to transmit it via the communication interface.

10. An attachment in accordance with claim 1, wherein the control unit comprises or is connectable to at least one memory to carry out a continuous data recording during the work operation of the attachment.

11. An attachment in accordance with claim 1, wherein the communication interface is a CAN bus.

12. An attachment in accordance with claim 1, wherein the wireless and/or wired communication with the at least one external unit takes place via a cellular radio network.

13. An attachment in accordance with claim 1, wherein the machine-relevant and/or control-relevant parameters of the attachment are able to be transmitted to an external server via the transmission unit.

14. A system comprising a base machine, including an excavating assembly for excavating a borehole, and at least one attachment installed at the base machine independently from the excavating assembly and for introduction of a casing into a around simultaneously with excavating, wherein the attachment comprises at least one integral control unit having a control logic for an independent carrying out at least one control function of the attachment, the excavating assembly comprises a grab for excavating the borehole, and the attachment is configured to rotate or oscillate the casing clamped thereto to introduce the casing into the ground by rotational movements synchronously to the excavation.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further advantages and properties of the invention will be explained in the following in more detail with reference to an embodiment shown in the Figures. There are shown:

(2) FIG. 1: a sketched side view of the system in accordance with the invention comprising a cable excavator and the casing oscillator in accordance with the invention; and

(3) FIGS. 2a, 2b: a side view and a plan view of the casing oscillator in accordance with the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

(4) During drilling with a hammer grab using a casing oscillator, two units that are independent per se, that is, a cable excavator 1 and the attachment of the cable excavator 1 in the form of the casing oscillator, work together to prepare a pile. As is shown by way of example in FIG. 1, the cable excavator 1 comprising a slewable superstructure, a boom 2, and a grab 3 takes over the excavation of a hole. A casing oscillator comprising a base plate 201 and a table 301 adjustable in distance with respect to the base plate 201 is attached to the cable excavator 1. A casing 100 can be driven into the ground by this casing oscillator in the following manner. The table 301 is, for example, latched to the casing 100 with the aid of a clamping cylinder. The base plate 201 is subsequently raised, whereby the weight force of the casing 100, of the table 301, and of the base plate 201 acts downwardly. To overcome the sticking friction, the table 301 is set into motion in a further step, for example into horizontal oscillations (so-called casing oscillators) or also into continuous rotation (so-called casing rotators). The casing 100 is lowered into the ground by this interplay while the cable excavator 1 excavates the soil within the casing.

(5) The casing oscillator is shown with more details in FIGS. 2a, 2b that show the casing oscillator with the casing 100 in a side view and in a plan view. The table can, for example, be clamped to the pipe 100 by means of clamps. The base plate 201 can be raised between the connection points 211/311 and 212/312 by lifting cylinders. The table 301 can carry out rotational movements with respect to the base plate 201 by synchronized movements of the two oscillation cylinders between the connection points 313/413 and 314/414. A rigid steering rod is installed at the table 301 in articulated fashion at the point 321, on the one hand, and is installed in articulated fashion at the point 421 at the element 401, on the other hand. The inclination of the casing 100 about the y axis can be set by movement of a steering cylinder that is installed in an articulated manner at the steering rod at the point 415, on the one hand, and in articulated manner at the base plate 201 at the point 215. The inclination of the casing 100 about the x axis can thereby be set by different stroke heights of the two lifting cylinders. The centers of rotation 413, 414, and 421 can be displaced by means of the guide 401 horizontally with respect to the structure 202 fixedly connected to the table 201. An inclinometer 501 that is fastened to the table 301 detects the current inclination of the table 301. The inclinometer 502 installed at the steering rod detects the current inclination of the steering rod. The hydraulic and electric energy for the operation of the casing oscillator is provided by the base machine 1.

(6) The casing oscillator shown further comprises a control unit that receives and evaluates the measurement values of the sensors 501, 502 and takes them into account for the control of the actuators, i.e. of the lifting cylinders, of the steering cylinder, of the clamping cylinders, and of the oscillating cylinders. Control-relevant data can additionally be output during the running time via a display means of the casing oscillator. The casing oscillator can take over control work and carry out intelligent functions such as assistance systems independently with the aid of the control unit. Functions for communication with the base machine 1 and with a (machine data) server are likewise available. Machine data can be collected independently of the base machine 1 and can be transmitted to a server. A querying of machine data should thereby be made possible remote from the construction site and in an uncomplicated manner.

(7) A display of (evaluated) data should be presented to the operator (on the control panel). This should additionally make possible different assistance functions and automated routines independently of the base machine 1.

(8) There are Inter Alia Made Possible: independent depth measurement of the casing/of the drilling pipe and prediction of the completion of the pile via monitoring of the depth; an automatic request for or reduction of hydraulic power in dependence on the process-dependent requirements of the casing oscillator (VRM) and of the availability at the base machine 1; automatic movement routines such as an automatic oscillating system, automatic pipe drawing device, and further sequences carried out in an automated manner that can also be stopped when, for example, a specific parameter is reached. The determination of the optimum oscillating angle additionally takes place as a function of the depth; and automatic dressing system: The alignment of the verticality of the pipe 100 takes place by an internal logic of the control unit.

(9) The processing of control signals of a base machine 1 becomes possible for the first time by the control unit on the attachment. Existing operating elements (master switch, master display, . . . ) can thus be used on the base machine 1.

(10) The communication between the VRM and the base machine 1 is made possible via a CAN bus. Here, the respective control units transmit and receive data that can additionally be used for combined evaluations. Information from the attachment machine and base machine 1 is directly presented to the operator (operator in the cabin+operator outside with control panel) by this connection, whereby work becomes more efficient. The transmitted data are shown graphically, and optionally in converted form, on the control panel of the base machine 1.

(11) The control unit of the VRM in conjunction with an independent transmission and reception unit of the VRM provide a data transmission via the cellular radio network to an external server that saves and manages these data.

(12) The server can be accessed via further units 801 and data can thus be queried directly and remote from the construction site. This brings about a plurality of improvements: time saving by direct data querying for e.g. the construction site manager; more efficient documentation; and increased work quality by direct data access.

(13) To ensure a seamless data recording, a temporary and permanent data storage is possible in the VRM by at least one memory element. Important information such as the service life consumption of individual components can hereby be saved independently of the base machine 1 at which the attachment is currently being used. The saved data are additionally available for evaluations and thus represent a basis for e.g. automation and assistance systems.

(14) The data measurement takes place directly at the attachment, whereby a high variety of data can be detected and additionally a high measurement accuracy can be achieved. A seamless machine data and process data recording is ensuredindependently of the mode of operation (external unit, powerpack, separate unit)by the integrated control unit that independently controls the recording and monitoring.

(15) A self-monitoring of the VRM is additionally made possible by the control unit. A large number of improvements in the total process introducing a pipe into the ground can be achieved with the aid of the recorded data and their evaluation. Processes can run more precisely and faster and the operator is relieved of workload by automated processes. Process routines are furthermore assisted with the help of assistance systems, whereby the process quality is increased and the operating effort is decreased. Incorrect operations are greatly reduced or precluded. The integrated control unit can additionally e.g. be used for forecasts or prioritization of work processes. Safety at the workplace is improved overall since the work in the hazardous zone (zone at and around the attachment) is reduced.

(16) A prediction on when the pile is completed can be prepared via a monitoring of the depth to e.g. set the time boundaries for the delivery of the concrete for the pile. This prediction can be made more accurately in a further sequence by a recording of ground profiles of adjacent piles. They e.g. display the strength of the ground as a function of the depth.

(17) The following takes place on a change of the direction of rotation of the VRM: the rotation of the casing 100 stops and the two oscillating cylinders change their lifting directions. Initially, a sticking friction acts between the pipe and the ground that is generally higher than the dynamic friction. As soon as the sticking friction has been overcome over the total casing 100, the pipe 100 rotates over its whole length; only the dynamic friction still acts. The casing 100 is now further introduced into the ground by its own weight and by the additional weight of the VRM. The following effects influence this behavior: The proportion of energy that can be converted into a torque of the casing 100 (efficiency) depends on the position of the two oscillating cylinders. The efficiency is high at a small maximum oscillating angle. The greater the maximum oscillating angle is, the smaller the efficiency becomes due to the geometry of the VRM. This behavior is counteracted, on the one hand, by smaller slipping between the individual elements of the casing 100, but also by a possible axial deformation over the total length of the casing 100. It may occur with a long casing that the pipes 100 already rotate at the surface of the ground, but that this rotation does not extend at the very bottom at the tip; and It can be recognized: the optimum maximum oscillating angle is therefore a function of the depth. Whereas a small oscillating angle is optimum at a small drilling depth due to the efficiency, a large oscillating angle becomes optimum at large drilling depths due to a possible axial deformation.

(18) The energy effort can therefore, on the one hand, as in the previously described paragraph, be optimized by setting the energy distribution; as a second parameter, the maximum oscillating angle can also be set as a function of the depth.

(19) There follows a brief example of use for the use of the VRM for pile foundation:

(20) A VRM attached to a cable excavator 1 is controlled by an operator in the operator's cabin or by an operator using a control panel. The VRM has an integrated control unit that is used as the basis for automation and for assistance systems. Machine-related and process-related data can be presented to the operator by the data recording and by the communication (data exchange) of the control units of the VRM and of the cable excavator 1. A combined evaluation and representation of the data is also possible by the linking of the data. Recorded and evaluated data are transmitted from the VRM and the cable excavator 1 via a connection to a server. The construction site manager can e.g. review the data on this server at his mobile device 801 and can thus monitor the work routine without having to be directly present in situ. Some processes of the manual data recordings (spirit level for measuring the vertical deviation of the pipe 100, reading the introduction depth, etc.) can be reduced by the digital representation of the data.