The invention relates to a method for correcting individual faults of a railroad track formed by rails and sleepers.
A method for correcting the position of individual faults is known from EP1 028 193 B1. In “Handbuch Gleis”; Dr. Bernhard Lichtberger, DVV Media Group GmbH/Eurailpress (ISBN 978-3-7771-0400-3), as published in 3rd edition from 2010, an individual fault correction machine is described on page 472 with the “UNIMAT Sprinter”.
Tamping units of track tamping machines penetrate the ballast of a track bed with tamping tools in the area between two sleepers (intermediate compartment) in the area of the support of the sleeper in the ballast under the rail and compact the ballast by a dynamic vibration of the tamping tines between the opposing tamping tines which can be adjusted to each other. The more uniformly a track is compacted from sleeper to sleeper, the more durable is the achieved geometric track position after maintenance work. When ballast is used for a long time (long lay times typically more than 10 years), the ballast is usually heavily contaminated and worn. First, the ballast grains break off at the grain tips, and the broken-off pieces then lie between the ballast grains. Rock dust collects in between (abrasion of the ballast grains under traffic load). This results in different ballast conditions and stiffnesses from sleeper to sleeper. Under the wheel loads, different depressions occur under the sleeper depending on the stiffness of the ballast. The wheels react to this with fluctuations in wheel force, which on the one hand negatively influence the running behavior of the trains and on the other hand place high stresses on the track and the vehicles. This increases the wear of the wheels and the running gear. It also leads to a rapid deterioration in the quality of the track.
Results from practice show that approx. one individual fault per km of track can be expected on the operated railroad lines. These show no correlation to the track geometry. They occur with about the same frequency in straight lines, in curves or in transition curves. The position corrections carried out according to the procedure described in EP1 028 193 B1 and with the individual fault correction machine “UNMAT Sprinter” show that between 50-60% of the individual faults corrected in this way could not be durably eliminated and return to their previous size after a short period of operation. Since there is no obvious connection with track geometry elements, the cause of the recurring individual faults must be sought in the ballast properties or the subgrade. With the current methods according to the known prior art, no indication can be given in the sense of an objective proof of quality, as well as with regard to the durability of the corrected individual fault or the condition of the ballast after the elimination of an individual fault.
Often the trigger of an individual fault is a singular track discontinuity such as an uneven rail joint or a hollow sleeper. Trains running over this unevenness exert high dynamic forces. As a result, the ballast under these areas is subjected to high stress, breaks at the edges, rounds off, and the fractions of fines fill the voids between the ballast grains. The fault not only becomes larger, but also expands longitudinally because of the wheel-rail interaction. Due to the excited car bodies (deflection and rebound stimulated by the track fault), subsequent individual faults occur with typically smaller and decreasing fault height.
The individual fault correction method known from EP1 028 193 B1 has the following shortcomings:
Electronic smoothing is performed, which means that the actual fault lying in the track is only approximated.
The left and right rails are only tamped underneath on the respective fault length of the individual rail side. If these faults are clearly offset from each other in the longitudinal direction, a twisting fault is installed. The method starts with the position correction by under-tamping the track at the respective determined starting point (at the high point) without lifting. It is known from investigations that already with tamping without lifting, a settlement of 5 mm occurs under the tensile loads. According to the method described in EP1 028 193 B1, this results in up to four successive twisting faults (calculated with the usual twisting base of 3 m) of up to 5 mm each. The intervention threshold requiring track correction is close to this value. The track geometry left behind would therefore already be borderline in terms of twisting.
The beginning and end of tamping is placed exactly on the high point. The high point of the track is formed by particularly tightly resting sleepers. If these remain in their extremely firm support, then after tamping an abrupt transition between hard (before the track fault) and soft (along the length of the track fault) remains. This maintains the high dynamic wheel-rail interaction. The corrected fault will recur quickly.
Another disadvantage of the method according to EP1 028 193 B1 is that no check of the determined nominal geometry with regard to the expected twisting errors is carried out before the actual work and a correction of the design is possibly carried out.
Another disadvantage is that the use of multiple tamping or the choice of tamping parameters is left to the machine operator and he can proceed as he sees fit. The current state of the ballast is not recorded and is not included in the planning of the design of the track geometry.
According to EP1 028 193 B1, only the track geometry left behind is recorded as a check on the quality of the work performed. This does not provide any information about the durability of the track correction and also no information about the ballast conditions in the fault area.
It is known to provide guidance computers for tamping machines with which track geometries can be recorded and stored. With inertial systems or north-based navigation systems, the directional errors and the track superelevation can be recorded in addition to the elevation errors.
There are also tamping units with fully hydraulic tamping drives that measure the ballast bed hardness by measuring the compaction force and the compaction distance. These provide information about the contamination of the ballast and the ballast condition by recording the ballast hardness and the achieved compaction (compaction force) of the ballast by tamping. If, for example, only a low compaction force is measured during tamping (typically 10-30 kN compaction force, ballast bed hardness<150 Nm) then the ballast is crushed and rounded there. Sufficient interlocking of the ballast grains cannot be achieved. The tamping will not have any durability. The corrected individual fault will form again shortly (typically within 1-2 million Lto). Depending on the level of the fault, multiple tamping will be used according to the prior art. For a track elevation of more than 40 mm, for example, tamping twice or, from 60 mm, tamping three times at the same sleeper is applied.
A method for correcting vertical positional errors of a track by means of a track tamping machine and a dynamic track stabilizer is known from WO2018082798 (A1), in which, on the basis of a detected actual track position, an overlift value is specified for a processed track point, with which the track is raised and tamped into a preliminary overlift track position and subsequently lowered into a resulting final track position by means of dynamic stabilization. A smoothed actual track position is formed from a course of the actual track position, and an overlift value is specified for the processed track point as a function of the course of the actual track position with respect to the smoothed actual track position course. A further method for correcting the position of a track consisting of track sections arranged next to one another and branch tracks connecting them is known from EP 0 930 398 (A1), wherein the track position correction is carried out with synchronous raising and/or lateral displacement on the basis of track correction values determined from the nominal and actual position.
The invention is therefore based on the object of providing a method for correcting the track position of extreme individual longitudinal height faults which substantially increases the durability of the track position of the corrected individual faults compared to the methods known to date, and which offers the possibility of predicting the durability by objective measurement.
According to the invention, this object is solved with a method characterized by the following steps:
Surveying the amplitude- and phase-true non-distorted elevation progression of the left and right rails, the directional error and the superelevation using an inertial measurement system or a north-based navigation measurement system.
Determining the height error length of the left and right rail to be corrected.
Determining the reference elevation line for the left and right rails with calculation of the elevations to be performed for the left and right rails.
Selecting the starting point N sleepers (typically 6) before the high point before the individual fault and selection of the end point M sleepers (typically 6) after the high point after the individual fault.
Checking compliance with permissible torsion of the determined and planned target geometry of both elevations.
Positioning of the tamping unit exactly at the determined starting point and termination of tamping exactly at the determined end point.
Carrying out track position correction with simultaneous independent control and correction of the heights of the left and right rail tracks.
According to the invention, the method can be extended by trial tamping to determine the ballast hardness with the tamping unit. For this purpose, e.g. after measuring the track geometry in the now known fault area, a test tamping without lifting is carried out to determine the ballast bed hardness and the compaction force and thus the ballast condition. Depending on the condition of the ballast, the track can then be overlifted to achieve better durability.
According to the invention, after this trial determination of the ballast condition in the area of the individual fault, the worn ballast can be removed and replaced by new ballast with machines carried along, if necessary, in order to be able to rule out a recurrence of the track fault.
According to the invention, the ballast condition (ballast hardness, compaction force) is measured and recorded at each sleeper during track position correction. These values can be used to make a prediction about the durability of the track geometry in the area of the individual fault that has been corrected. This measurement data can then be used to plan the ballast replacement under sleepers with worn ballast, so that when the new individual fault is corrected in the expected short time, this can be done permanently.
According to the invention, in addition to the dominant longitudinal height errors, the directional error and the superelevation are corrected at the same time. The directional error is derived analogously from the IMU measurements and the resulting correction values are specified to the machine control system. The superelevation is included in the calculation of the reference heights of the two rails.
The main advantages of the method according to the invention are the precise phase- and amplitude-true detection of the individual faults, a leveling out of the vertical stiffness, an extension of the durability of the track geometry of the corrected individual fault and a quality verification by means of the ballast hardness and the compaction force for the individual sleepers to be processed and, based on this, well-founded statements about the expected durability of the track fault correction. A low ballast hardness (W . . . soft, N . . . normal, H . . . hard) is an indication of destroyed ballast and greatly reduced durability of the tamping.
The drawings describe the method according to the invention, wherein:
The twist V is calculated as: V=[u(n)+h(n)]−[u(n+B)+h(n+B)] where n is the sleeper under consideration. The twist is calculated for all positions starting at the starting point (or B=3 m before) to the end point (or B=3 m after) and compliance with the acceptance threshold for the twist is checked. If this is not complied with, then the reference elevation lines must be modified accordingly. This is necessary, as shown in the next figures, especially if the track is superelevated for reasons of higher durability of the track position, so that it adapts to the optimum straight reference line after the expected settlement during the stabilization phase of the track.
The settlement S can be simplified depending on the uplift H as follows:
For the remaining uplift H′ depending on the track fault F, the following applies:
As can be seen from the formulas and the diagram, the track settles by S=5 mm at zero H=0 uplift. The reason for this is that the tamping tools 8, 15 take up space and displace part of the ballast just by dipping the tines into the ballast. This corresponds to a loosening of the ballast in the area of the sleepers, which then begin to settle under the live load.
is used to calculate the necessary uplift H′ (line with circles). The reference line for the height of the rail is now not a straight line running between the maxima but a curved line (line with diamonds). Under the tensile load, the track settles and assumes the reference height line (line with triangles) after complete stabilization. At the initial and final areas R, the lifting value H′ is built up via a ramp (length typically e.g. 3 m). Since the lifting values are initially zero or very small, the track settles below the zero reference line. This corresponds to a small residual longitudinal height error at the beginning and at the end which cannot be avoided, but can be neglected in practice. The overlift ü, the settlement s and the track position I after stabilization are shown.
Number | Date | Country | Kind |
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A 50701/2018 | Aug 2018 | AT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AT2019/060256 | 8/12/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/037343 | 2/27/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3875865 | Plasser | Apr 1975 | A |
5012413 | Sroka | Apr 1991 | A |
6260485 | Theurer et al. | Jan 2001 | B1 |
6220170 | Theurer et al. | Apr 2001 | B1 |
7181851 | Theurer | Feb 2007 | B2 |
9631325 | Lichtberger | Apr 2017 | B2 |
11174598 | Auer | Nov 2021 | B2 |
20190316300 | Auer | Oct 2019 | A1 |
Number | Date | Country |
---|---|---|
0930398 | Jul 1997 | EP |
1028193 | Aug 2000 | EP |
3358079 | Aug 2018 | EP |
2018082798 | May 2018 | WO |
Entry |
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B. Lichtberger, Handbuch Gleis, DW Media Group GmbH/Eurailpress, 2010, pp. 472-473. |
Number | Date | Country | |
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20210222373 A1 | Jul 2021 | US |