WO2004068083A1

WO2004068083A1 - Device for measurement of rail loading

Info

Publication number: WO2004068083A1
Application number: PCT/EP2004/000827
Authority: WO
Inventors: Peter Groll
Original assignee: Schenck Process Gmbh
Priority date: 2003-02-01
Filing date: 2004-01-30
Publication date: 2004-08-12
Also published as: DE10304008A1; DE10304008B4

Abstract

The invention relates to a device for measurement of rail loading within a given measured run, by means of several force transducers (1), for determination of the vertical forces acting on a rail, arranged between the rails (3) and a sleeper (5). Said device for rail loading is characterised in that a recess (2) is provided in each rail (3), at least in the longitudinal region bridging the sleepers (5) to a height below the rail head (4). A longitudinally arranged shear force transducer (1) is arranged in said recess (2) which supports the rail head (4) on the sleeper upper surface (15). The total height of the device with the shear force transducer (1) arranged below the rail head (4) thus corresponds to the height of a conventional rail (3) and is fixed to conventional wood or concrete sleepers (5).

Description

Device for measuring the rail load

The invention relates to a device for measuring the rail load according to the preamble of claim 1.

A few years ago, the rail load was only used to determine the axle or vehicle weights of rail-bound vehicles. In the meantime, it is increasingly important for the safety of rail traffic at ever higher train speeds to also recognize non-roundness and flat spots on the vehicle wheels. For example, the wheel support force that acts on the rail consists of both a static weight load and a dynamic component that can increase with increasing speed. The dynamic portion of the wheel contact force increases when the wheel is out of round or has flat spots. Particularly at high train speeds, this dynamic wheel contact force can become so great in the event of roundness or flat spots that it causes damage to the wheel, the rail or the track construction, which can also lead to train accidents. Furthermore, the total track load can also be used to determine the track condition, which makes repair or repair work necessary when a specified total load is reached.

A dynamic weighing method for rail vehicles is known from EP 0 500 971 AI, by means of which a large part of the rail load when rail traffic is traveling over can be detected. For this purpose, the shear stress is recorded and evaluated in the neutral phase of the rail. For this purpose, a weighing rail applied with strain gauges is welded into the rail network, in which at least two strain gauges are arranged between the sleepers. The wagon weight is thereby Axial addition of the weight signals determined. With such a device, however, a reliable flat spot detection cannot be carried out since this cannot be detected in the area of the thresholds.

Such a device for determining non-round wheels on railway vehicles is already known from DE 44 39 342 Cl. In this device, two sensors made of strain gauges are applied to both sides of a measuring section on the rail foot in the area of each threshold, which sensors detect the threshold reaction forces. Shear force sensors are also provided, which are arranged at the beginning and end of the measuring section in the neutral phase of the rail. With such a device, however, it is obviously not possible to determine an exact weight load when vehicle wheels roll over.

From DE 198 34 030 AI a device for determining the weight load on the rail by running over track vehicles is known. For this purpose, two double bending beams are arranged in the area of the threshold parallel to each track, which are connected to the rail via side mounting plates. The connection between the rails and the two double bending beams is made in front of and behind the threshold in the so-called threshold compartment. In the middle, the double bending beams are each supported on the threshold so that the vertical forces acting on the rail are recorded, with which non-roundness and flat spots can also be identified. However, reliable detection of flat spots or out-of-roundness requires detection on at least one wheel rotation of approx. 3.5 m measuring distance, for which at least 28 force transducers are necessary with conventional sleeper compartments. Since the force transducers are special high-precision double-sided double bending beams, a high outlay on equipment is necessary for a rail loading device with flat position detection. From DE 44 44 337 AI a rail weighing device with only one load cell for two sleeper compartments per rail is known. With a weighing device of this type for measuring rolling-over track vehicles, the total load of rolling vehicle wheels on a rail can also be determined in the case of several weighing cells arranged one behind the other. For this purpose, the measuring section is elastically coupled to the rest of the track system via a start and an end recess in the rail foot and web. To measure the vertical loads between the rail and the base, the rail is supported on a rotationally symmetrical load cell, which is likewise arranged lengthways under a recess between the other two recesses. For this purpose, a support frame is provided in the recess above the load cell, which enables the vertical rail loading to be applied horizontally and axially. However, the load measuring device cannot be arranged between a conventional threshold and the rail without increasing the overall height. If such devices for load measurement were to be installed to a greater extent in the rail track, larger construction measures would be necessary, as a result of which the railway line would have to be blocked over longer periods of time.

From DE 199 41 843 AI a special device for determining flat spots and out-of-roundness on rail-bound vehicle wheels is known. In this device for detecting the rail load when the rail vehicle wheels pass over, special measuring thresholds are provided, into which the force transducers are embedded and on which the

Support rails. This has the disadvantage that not only the rails but also the sleepers have to be replaced when installing a measuring section of several force measuring devices in an existing track section. The invention is therefore based on the object of providing a device for measuring various rail loads by rail-bound vehicles which can be integrated into the rail network quickly and easily and which delivers relatively accurate measurement results.

This task will. solved by the invention specified in claim 1. Further developments and advantageous exemplary embodiments of the invention are specified in the subclaims.

The invention has the advantage that approximately half the rail height is used for the installation of a measuring device due to the recess above the threshold area. As a result, only the old rails need to be screwed and cut off from the sleepers during installation and replaced with new or retrofitted rails with cutouts. The force transducer as a rail on the sleepers up ^'screwable and their holders are preferably welded to the sleeper head. Since the conventional sleepers can remain in the track bed, such a reinstallation of the measurement section by track construction teams can be carried out in a very short time, as is the case when conventional rails are exchanged, without the track section having to be interrupted for long periods for rail traffic.

The arrangement of the force transducer directly beneath the rail head are advantageously all vertical rail pressures detected _e that of the railway track can be evaluated both for a Überfahrtwägung, flats recognition ,, runout detection, adverse Beladungs- load measurement conditions of the cars, Radbeschädigungen as well as a total. At the same time, this also has the advantage that even when recording an entire wheel revolution or an entire bogie of a track vehicle, only 14 force transducers are required for the entire measuring section, which increases the cost keeps wall low and can therefore be installed on a large scale in existing rail networks.

The invention also has the advantage that, due to the recesses in the rail foot and web, the force transducers are elastically coupled to the continuing rail network, so that force shunt effects hardly occur, for example for axle load weighing, even though the ^ rail line in the rail head overrun is uninterrupted and as a result no impact effects occur.

The invention has the additional advantage that no special rail material is required by the force transducer in the recess of the lower rail half, as with an application of the strain gauges on the rail web or foot, but only in the standard profile material, the recesses must be provided, which also is possible on site. As a result, considerable transport costs can advantageously be avoided, particularly in international goods traffic.

A special embodiment of the invention with shear force transducers has the advantage that, due to the design, in particular the vertical force detection under the middle of the rail means that lateral transverse force introductions do not flow into the measurement result and thus cannot falsify the measured values. The shear force transducers also compensate for other parasitic forces and moments, so that relatively high sensitivities and measuring accuracies can be achieved in a simple manner with such a measuring device, and this even at relatively high crossing speeds.

Another special form of training with axially displaceable round bolts as force introduction elements has the advantage that even in the axial direction there is no tension caused by heat expansion or assembly inaccuracies can be introduced into the transducer so that only the vertical forces are recorded.

The invention is explained in more detail using an exemplary embodiment which is illustrated in the drawing. Show it:

1: the side view of a longitudinally installed force transducer; Fig. 2: a sectional view in front view through a

Force introduction element of a longitudinally installed force transducer; Fig. 3: the side view of a transversely installed force transducer, and Fig. 4: a sectional view in front view through a

Force introduction element of a transversely installed force transducer.

In Fig. 1 of the drawing, a section of a rail track with built-in force transducer 1 is shown in side view. The force transducer 1 is arranged in an axially aligned recess 2 below the rail head 4 and supports the rail 3 on a threshold 5.

The force transducer 1 is part of a measuring section, not shown, of preferably seven transducers 1 per rail 3, which extends over a distance of approximately 3.5 m in the rail track and detects at least one wheel revolution of a wheel or a bogie of a rail-bound vehicle. In the case of higher accuracy requirements, the measuring section can also be provided over a length of two wheel revolutions of approximately 7 m in length or a multiple of 3.5 m in length. Such a measuring section is used to record all static and dynamic forces that are generated in the vertical direction by a rail vehicle wheel that runs over or is stationary. The Measuring section is provided in an existing track section by dismantling and cutting out the existing rails 3. Thereafter, the transducers 1 are preferably screwed onto the existing commercially available wooden or concrete sleepers 5 like a rail foot by means of a clamp connection. A rail 3 with recesses 2, which can also be designed as a half rail, which only consists of the rail head 4, is then placed on this. This half rail or rail 3 with recesses 2 of approximately 3.5 m in length is prefabricated and also contains notches 10 on the two rail cheeks 6, which serve to fit the brackets 8, 9. The built-in force transducer 1 is shown in detail in the sectional view through the left bracket 8 in FIG. 2 of the drawing. The notches 10 for the use of the brackets 8, 9 are rectangular cutouts which are provided at the fastening points of the half rail 7 to be used. The track head can also be designed as a profile material with two lateral notches over the entire measuring section, to which the brackets can be welded at any point. The half rail 7 or rail 3 with recesses 2 is preferably made from a profile material of a conventional rail 3, the recesses 2 also only having to extend to the area above the sleepers 5, the recesses 2 being necessary only for the length of the force transducers 1. are dig.

The entire part of the recesses 2 or the part of the measuring section formed as the entire half rail 7 is then transferred by rail construction teams working on site into an existing track section or in the course of a new track section into the latter

Welds 24 inserted. At the same time, the U-shaped legs 11 of the two brackets 8, 9 of a transducer 1 are welded into the notches 10 in the side cheeks 6. The brackets 8, 9 could also be screwed and the like on the rail head 4 be consolidated. Such a measuring section can thus be inserted into the rail network in a relatively short assembly time.

The force transducer 1 for detecting the vertical forces acting on the rail 3 is designed as a double-sided shear force transducer. It consists of a longitudinal beam approx. 400 mm long and approx. 70 mm high. The shear force transducer 1 is formed symmetrically with respect to a vertical center axis 12 and contains a similar separate transducer part in each half of the beam and therefore represents double-sided shear force transducer 1. The two transducer parts with the active strain range 14 are arranged on the left and right sides of the central bearing surface 15. In the central area 15, the pickup 1 is cuboid and has 15 lateral on its central contact surface

Cross flanges 16, which are designed like a rail foot 23 and are clamped onto the sleepers 5 by the rail fastenings 17. Elongation bodies 14, which preferably also have a rectangular cross section, are arranged on the longitudinal side of this central fastening region 15. In this expansion body 14 two mutually directed blind holes 18 are embedded, - the connecting surface of which represents a vertical flat wall 19 of a predetermined thickness. On this connecting surface 19 two shear force resistors arranged at an angle of 45 ° to each other are applied as strain gauges on both sides, which convert the vertical forces into electrical signals. At least the expansion body 14 lies in the longitudinal direction next to the contact surface 15 of the sleepers 5 and is exposed at the bottom.

At the end areas of the two transducer halves, a round bolt 20 is provided for force introduction, which is non-positively connected to the respective holder 8, 9 of the transducer 1. The bracket 8, 9 consists of an elongated rectangular profile material, which has a through hole in the longitudinal direction of the transducer, which is provided for the use of the round bolts 20. To fasten the brackets 8, 9, two U-shaped legs 11 are attached, which engage in the two notches 10 arranged in parallel in the rail head 4 and are fastened to them. During installation, the brackets 8, 9 are placed so far on the round bolt 20 of the force transducer 1 that a gap 21 of approximately 1 mm remains between the two expansion bodies 14 and the end faces of the brackets 8, 9, through which an axial displacement can be compensated for without tension can. In particular, this enables tension-free longitudinal compensation in the event of manufacturing inaccuracies and large temperature fluctuations in the rail track. As a result, slight tilting movements in the rail track can be compensated for at the same time, so that the introduction of transverse forces into the transducer 1 which falsifies the measured value is avoided.

Such double-sided shear force transducers 1 are provided on the measuring section above each threshold 5 and on each track side and fed to an electronic evaluation device (not shown) by means of a line for evaluation. These are the shear force transducer 1 with its strain gauges 22 to form a Wheatstone ^'' see connected measuring bridge. The shear force transducer 1 can, however, also be equipped with only one transducer system as in the case of one transducer half, or it can also be designed as a bending beam. In the electronic evaluation device (not shown), the signals of each individual pickup 1 are preferably amplified individually and converted into a digital value. With a corresponding combination of the signals, the weight, an out-of-roundness, a flat spot or a broken tire can then be determined from the determined vertical force components of a vehicle wheel that is running or stationary, or an axle or bogie. In particular, roundness, flat spots and wheel tire bumps are Before it can be determined at high crossing speeds due to the strong fluctuations in vertical force on the measuring section which deviate from a predetermined mean value.

Advantageously, train identification devices can also be provided, with the aid of which trains traveling over are located and possibly stopped due to excessive stress on the rails or suspected damage. The crossing load can, however, also be added up according to special wear assessments, for example in the case of heavy flat point loads, and used for calculation or track maintenance purposes. This is particularly advantageous in the case of high-speed lines, in which even a few passes with strong flat spots on the vehicle wheels can necessitate repair measures.

The shear force transducers 1 are preferably produced from an alloyed special stainless steel material as series parts. For the weather-independent closure, the bores 18 for the strain gauges 22 are sealed with thin stainless steel sheets by a laser welding process and are thus permanently protected from damage. The brackets 8, 9 of the shear force transducer 1, however, are also made of simpler steels such as. B. to produce tool steel, which only have to have the necessary strength values and are weldable on site.

3 and 4 of the drawing, an embodiment of a device for measuring the rail load is shown, in which the force transducers 1 are arranged transversely to the longitudinal direction of the rail in a recess 2 below the rail head 4. The rail head 4 is also supported on the transversely installed force transducer 1 on a threshold 5 of the rail track. Such an embodiment is preferably used for determining the weight of rail vehicles, since the transverse forces can advantageously be introduced into the sleepers over the length of the force transducer. The measuring section according to FIG. 3 of the drawing differs from the embodiment according to FIG. 1 of the drawing mainly in that the installation direction of the force transducers instead of longitudinally transversely to the longitudinal direction of the rails. direction are provided. The force transducer 1 is basically designed to be comparable to the force transducer 1 according to FIGS. 1 and 2 of the drawing. The force transducer is also designed as a double-sided shear force transducer, which is shown in detail in the sectional view according to FIG. 4 of the drawing. The force transducer 1 consists of a longitudinal bar of approximately 400 mm in length and approximately 70 mm in height and has two expansion bodies 14 on the side of a vertical central axis 12, which are also applied with shear force transducers 22 arranged on a wall 19. The force transducer 1 is supported laterally with two support plates 25 on a conventional railroad tie 5 and is preferably fastened to it.

In the central region 15 of the force transducer 1, a transverse bore 26 is provided, through which a round bolt 20 is guided in a form-fitting manner, which is approximately 50 mm above the transverse surfaces of the longitudinal beam. kens protrudes. For the introduction of force, a bracket 8, 9, which are designed like the bracket 8, 9 according to FIGS. 1 and 2 of the drawing, are pushed on both sides of this round bolt 20. These brackets 8, 9 are also firmly connected to the rail head and introduce the rail load symmetrically into the transversely arranged force transducer 1.

This rail load is then detected by the shear force transducer 22 and can be evaluated as described for FIGS. 1 and 2.

Claims

Device for measuring the rail load

1. Device for measuring the rail load within a predetermined measuring section with the aid of several force transducers (1) for determining the vertical forces acting on the rail (3), which are arranged between the rails (3) and stationary sleepers (5) characterized in that in the height below the rail head (4) in the rail at least in the longitudinal region spanning the sleepers (5) there is a recess (2) in which a longitudinally flat force transducer (1) in the longitudinal or transverse direction of the rail is arranged, which supports the rail head (4) on the threshold top.

2. Device according to claim 1, characterized in that the recess (2) is provided over the entire measuring section or only over the thresholds (5) of the measuring section and in this area forms a half rail (7) which only from the rail head (4th ) consists.

3. Device according to claim 1 or 2, characterized in that in the side cheeks (6) of the rail head (4) in the region of the end points of each force transducer (1) axially spaced notches (10) or two lateral notches are provided as a profile, in which legs (11) of a holder (8, 9) for the force transducers (1) are fastened.

4. Device according to one of the preceding claims, characterized in that each force transducer (1) is designed as a fla- rather longitudinal bar which two axially spaced Dete shear force transducer parts (22) and which is symmetrical to a vertical central axis (12).

Apparatus according to claim 4, characterized in that each force transducer (1) has a round bolt (20) at its ends or in the central region (15), which is used for non-positive fit into the associated holder (8, 9).

6. Device according to one of the preceding claims, characterized in that everyone _. Force transducer (1) in the central area (15) has transverse flanges (16) which are used for the clamp fastening (17) on conventional or modified wooden or concrete sleepers (5).

7. Device according to one of claims 1 to 5, characterized in that each force transducer (1) has at its ends support plates (25) which serve for lateral support on the threshold (5).

8. Device according to one of the preceding claims, characterized in that for fastening each force transducer (ϊ) on the rail head (4) two identical Haϊteruή- ^" gene (8, 9) are provided, which have a cuboid main part that has two U-shaped protruding legs (11) and in the cuboid part (13) has a through hole for the use of the round bolts (20).

9. The device according to claim 7, characterized in that ^• the brackets (8, 9) consist of simple steel material which can be connected to the rail head (4) by means of conventional welding processes.

10. Device according to one of the preceding claims, characterized in that the measuring section consists of two similar, parallel, at least 3.5 m long rails (7) with at least seven recesses (2), in each of which a force transducer (1) is arranged, which supports the rail head (4) on each threshold side.

11. Device according to one of the preceding claims, characterized in that the measuring section is welded into a track piece and that the height of the measuring section, which results from the rail head (4) and the force transducer (1) and its brackets (8, 9th ) composed, the height of a conventional rail (3) corresponds.

12. The apparatus according to claim 9, characterized in that the measuring section has conventional or modified wooden or concrete sleepers, on the clamping devices (17), the force transducers (1) are attached.

13. Device according to one of the preceding claims, characterized in that the sensors (1) of the measuring section are connected to an electrical evaluation device which, from the measured value signals, has a wheel, axle or vehicle weight and / or flat spots, out-of-roundness and wheel defects and / or a total route load is determined.