The invention relates to a method for determining wear of a force-loaded linkage of an earth-working device and an earth-working device configured for carrying out the method.
Earth-working devices, for example (horizontal) drilling apparatuses and apparatuses for rehabilitating already existing channels in the ground (bores, old pipes), for example expansion devices and pipe pulling devices, typically include a drive apparatus and a linkage, to which the corresponding tool (e.g., the drill head, expansion head or pipe pulling adapter) is attached, connected to the drive apparatus. The drive forces from the drive apparatus are transferred by the linkage to the tool, whereby the tool is advanced in the ground. Pressing forces are typically applied to the tool (the drill head) for a drilling operation of the earth-working device, so that the tool is pushed through the ground. Conversely, pulling forces are typically applied when widening existing bores, bursting existing old pipes and pulling new pipes into existing bores or old pipes. If only pulling forces need to be transmitted, i.e., in an earth-working device which is only used for widening, then cables or chains can also be used as pulling means instead of a linkage. The linkage of an earth-working device consists generally of a plurality of interconnected rod sections which are sequentially connected with each other (in a pushing operation) commensurate with the advance of the tool in the ground or detached from each other (in a pulling operation). The rod sections can be connected, for example, via threaded connections or plug-in couplings. When transmitting the drive forces to the tool with a linkage, only linear drives are employed, which transfer the drive forces and/or drive movements stepwise to the linkage, i.e., with a load stroke, where the linkage is connected with the linear drive, and an idle stroke, wherein the connection between the linear drive and the linkage is released. All conventional linear drives for earth-working devices operate with hydraulic cylinders as drive source, because these are able to produce the large forces while having comparatively compact dimensions. However, linear drives with rack and pinion drives are also known.
If only pulling forces are to be transmitted (in particular, if additional use as drilling device is not contemplated), then pull cables or chains can also be used for transmitting the drive forces to the tool. The pull cables or chains can either also cooperate with the linear drive, which then must have corresponding clamping elements for affixing the pull cable or chain, or may be used with (hydraulic) winches.
A problem has surfaced during use of the aforedescribed earth-working devices in that the expected service life of fundamentally all components of this device, however in particular of the force transmitting element (i.e., the linkage, the pull cable or the chain), is difficult to estimate. This is particularly due to the fact that the service life of the components depends on how the load is applied, in addition to the geometric dimensions and the employed material. In particular, the magnitude of the applied forces and the fraction of dynamic loads to the total load affect the service life of the components. The fraction and the magnitude of the dynamic, i.e., non-static loads (i.e., loads with a constant force from a constant direction) in earth-working devices depend in turn significantly on the external circumstances (e.g., the conditions of the ground) and the employed drive apparatus. In addition, the time at which a rod section is inserted in the strand of a linkage, has a significant effect on the loads to which this rod section is subjected during the performed earthwork, and hence on the service life of this rod section.
The loads on the linkage cause material fatigue which increases with the fraction and the magnitude of the dynamic loads on the total loads. Material fatigue can cause cracks at geometric weak points (e.g., notches or other transitions in the cross-section) and material-related flaws (e.g., material inclusions), which propagate with progressing rocker number of the dynamic loads and finally result in failure of the linkage due to breakage or tearing. This can be associated with a significant safety risk for the operating personnel of the earth-working device, if a rod section which is still in the working draft fails, or can lead to additional work, in particular when the cracked rod section can only be retrieved by digging.
A number of computation methods have been developed to calculate an expected service life of a dynamically loaded component, wherein particularly the magnitude of the loads and the frequency of the occurrence of these loads is evaluated—in addition to the geometric dimensions and the employed material of the respective component—and used for estimating the expected service life.
Starting from the current state-of-the-art, it was an object of the invention to increase the operating safety of an earth-working device of this type.
This object is attained by the subject matter of the independent claims. Advantageous embodiments are recited in the corresponding dependent claims and can also be inferred from the following description of the invention.
The core of the invention suggests to measure the instantaneous load on the linkage of an earth-working device during the operation of this earth-working device and to use the results of this measurement for performing a service life calculation.
Measuring the actual load during operation has significant advantages compared to conventional load tests performed under laboratory conditions, because the measured values will always be significantly more accurate than simulations under laboratory conditions.
Accordingly, the earth-working device according to the invention has a drive apparatus and a linkage connected to the drive apparatus, where in the linkage is force-loaded by the drive apparatus. The earth-working device also includes a measuring device for measuring the instantaneous load on the linkage during operation as well as an evaluation device for performing a service life calculation for the linkage.
“Earth-working devices” are intended to refer to all devices where forces are transmitted from a drive apparatus via a force-transmitting element to a tool, which is thereby moved in the ground or in a hollow space (e.g., a bore or an old pipe) in the ground.
“Linkages” refers within the context of the invention not only to rigid linkages composed of interconnected rod sections, but more particularly to all force-transmitting elements that can be employed with an earth-working device according to the invention. These may also include, in particular, pull cables and chains. In addition, the term “linkage” according to the invention is intended to refer not only to the force-transmitting element arranged between the drive apparatus of the earth-working device and a tool, but in general to all components of a load strand of the earth-working device that are subjected to a load resulting from forces and/or torques generated by the drive apparatus. Included are here particularly the respective tool of the earth-working device itself or components thereof.
The evaluation device may, for example, include a counter for determining the position and/or for determining the number of loadings.
In a preferred embodiment, the sum of the instantaneous loads during the operation of the earth-working device is measured and the loads of previous uses of the earth-working device are taken into consideration when performing the service life calculation. This provides particularly accurate information about the ageing state of the linkage.
In a preferred embodiment, the measured load and/or the result of the service life calculation is stored. The results of the service life calculation can then be updated after each use of the linkage and hence be precisely outputted. The earth-working device according to the invention has for this purpose preferably a storage device for storing the measured loads and/or the result of the service life calculation.
In another preferred embodiment of the present invention, the operating forces of a drive apparatus connected with the linkage are measured for determining the instantaneous load of the linkage. Such measurement of the operating forces of the drive apparatus can typically be easily performed, for example by measuring the hydraulic pressure in the hydraulic cylinders of a linear drive and converting the measured value into a value for the force with which the linkage is loaded. Ageing of the linkage and/or the remaining service life can be determined from the determined operating forces. To this end, the earth-working device according to the invention has preferably a measuring device arranged on the drive apparatus.
Preferably, the evaluation device can also be arranged on the drive apparatus.
The method according to the invention is particularly suited for determining the wear of a linkage which includes a plurality of interconnected rod sections. Preferably, the individual loads of individual or of all the rod sections are measured and individual service life calculations are performed. This can again significantly increase the accuracy of the performed service life calculations. One particular reason is that in a load event, i.e., when performing a close-ended work project (e.g., a bore, a bursting operation or a pipe pulling operation) the individual rod sections are under load for different lengths of time depending on the time when they are inserted into the linkage strand. The individual rod sections are additionally used with many different work projects, wherein it is typically difficult to reconstruct which rod section was used in which work project and how long the rod section was under load. It has thus so far not been possible to determine for how long an individual rod section has already been under load in order to estimate the service life of this actual rod section based on service life calculations performed in a laboratory. This now becomes feasible owing to the preferred individual measurement of the loads on the individual rod sections according to the invention and the corresponding evaluation. To this end, the values for the individual rod sections are preferably stored separately, which can preferably be done in a storage element that is itself connected with the respective rod section. By providing individual or all rod sections with corresponding storage elements, it can be prevented that the individual measurements and service life calculations are mixed up. In addition, complex data management is eliminated when the different rod sections are intermixed for the different work projects and employed at different work sites.
However, the values for the individual rod sections may also be centrally stored, wherein each rod section has an identifiable code (e.g., the serial number of the rod section which is, for example, determined optically), which is then associated with the centrally stored values.
Preferably, the measured loads and/or the individual service life calculations of a load event may be transmitted from the drive apparatus to the individual storage elements. This may preferably take place when the corresponding rod section is in the drive apparatus for insertion in or detachment from the linkage strand. To this end, a transmission device is provided in the drive apparatus which is used to transmit the measured loads and/or the results of the service life calculations to the storage elements of the rod sections. The transmission devices are preferably arranged in the drive apparatus.
In a particularly preferred embodiment in a linkage subjected to pull, which includes a plurality of interconnected rod sections, the measured loads and/or individual service life calculations of a load event can be transmitted when the linkage is stepwise pulled with the drive apparatus through a bore in the ground, wherein the individual rod sections are sequentially pulled from the bore and detached from the rest of the linkage, by transmitting the loads or results of the service life calculations to the storage element of the rod section to be detached shortly before detachment, during the detachment of the rod section or shortly thereafter, in particular as long as the rod section is in the range of the drive apparatus.
In order to be able to include in the service life calculations also those loads, to which the individual rod sections were subjected in previous load events, the loads and/or the results of the service life calculations stored in the storage elements of the individual rod sections may be initially transmitted to the drive apparatus and subsequently updated in the drive apparatus with the loads (e.g. the number of work strokes with the corresponding force values) and/or the service life calculations of the previous load event, whereafter the updated values are stored again in the storage elements. In this way, ageing of the individual rod sections at the current worksite can be reconciled with those at the previous work sites.
With respect to the device, a receiving device is preferably provided which is configured to read out from the storage elements the data relating to the previous loads and/or the previous results of the service life computations. The receiving device can hereby be an active device, i.e., it reads the data stored in a passive storage element. Alternatively, the receiving device can also cooperate with active storage elements which transmit the desired values to the receiving device.
In a particularly preferred embodiment, the transmitting and/or receiving device operates wirelessly, for example with any type of data transmission technologies (e.g., with electromagnetic waves (e.g., radio), infrared data transmission, etc.). Wireless within the context of the invention is to be understood as any contactless transmission of data.
The invention also relates to a rod section of a linkage of an earth-working device which includes a storage element and information relating to the loads to which the rod section was subjected stored on the storage element.
The core idea of the invention is fundamentally suited for determining the wear of all devices having a service life which is difficult to estimate due to strongly varying loads.
The invention will now be described in more detail with reference to an exemplary embodiment illustrated in the drawings.
The drawings show in:
The illustrated drive apparatus is suitable for both pushing and pulling operation. This makes it possible, for example, to initially introduce in pushing operation a pilot bore into the ground (not shown) starting from an (unillustrated) start shaft in the ground, whereby the linkage 6 of the earth-working device is stepwise advanced into the ground. After each work stroke of the drive apparatus 1, the linkage 6, which is composed of a plurality of rod sections 8 connected by way of quick connects 7, is extended by a new rod section 8. As soon as the drill head (not shown), which in the earth-working device of
According to the invention, the earth-working device illustrated in
With the earth-working device according to the invention, the individual loads to which the individual rod sections 8 are subjected can be determined and individual service life calculations can be performed therefrom. To this end, the data stored on the corresponding RFID chip 12 (including, if applicable, also data from previous uses of this rod section 8) are read out with the receiving device 11 for each of the rod sections 8 before they are detached and after widening the pilot bore. During the elapsed time between attachment and detachment of the individual rod sections 8, a defined number of work strokes is applied to the linkage 6 and the corresponding rod section 8 via the drive apparatus 1, wherein the magnitude of the corresponding applied loads can be determined with the pressure sensor 9. Based on these concrete values, an individual service life calculation can be performed in the computing unit 13 for each individual rod section 8 of the linkage 6. The result of this service life calculation, wherein previous loads on the respective rod section 8 are also taken into consideration in addition to loads from to the current work project, is stored via the transmitting device 10 again on the RFID chip 12 of the corresponding rod section 8, so that the data are once more available for a subsequent use of the corresponding rod segment 8 and can be considered in an additional update of the service life circulation.
A corresponding service life calculation is performed for each of the rod sections 8 of the linkage 6, because different results are obtained for all the rod sections 8, depending on the position where they are inserted in the linkage 6. For example, the first rod section 8 of the linkage, which is directly connected with the drill head or the expansion head, is under load for the longest time, because it is the first rod section attached when the pilot bore is established and the last rod section detached after widening and, if applicable, pulling in the new pipe. The loads on this rod section 8 are therefore significantly greater than, for example, on the rod segment 8 that was attached last and was therefore also detached last.
The following data are stored on the RFID chip 12 of each rod section 8:
Production order number,
Average pressure,
Crack test yes/no,
Lifetime wear,
Total number of strokes,
Number of strokes for each stress level (8×),
Total damage to date,
Most damaging stress level,
Expected service life under full load,
Expected service life under average load.
The earth-working device illustrated in
In addition, a portable handing device may be provided which has at least a corresponding receiving device and a display. With this portable handing device, the RFID chips 12 of stored rod sections 8 can be read out independent of the drive apparatus 1 to facilitate planning of future use of the individual rod sections 8. The read out values may be used, for example, for inventory control or for generating lease lists, etc.
In the aforedescribed embodiment of the method of the invention, the new linkage data are read out as well as calculated and transmitted again to the RFID chip 12 of the corresponding rod section 8 shortly before or during the detachment of the rod section 8. In this way, the calculation is always performed for the correct rod section 8.
It may also be feasible to display the linkage data also when the rod section 8 is inserted in the drive apparatus when establishing the pilot bore, thus enabling continuous monitoring that no “worn out” rod section 8 is used.
It will be understood that not only pushing and pulling forces, but for example also torsion forces, torques, bending moments and rotation speeds, may be taken into account in the measurement of the instantaneous load and a service life calculation based thereon.
A corresponding service life calculation is performed individually for each of the rod sections of the linkage.
Number | Date | Country | Kind |
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10 2008 052 510.3 | Oct 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/007539 | 10/21/2009 | WO | 00 | 9/8/2011 |