WO2004067845A1

WO2004067845A1 - Method for installing a pre-fabricated unit and device for receiving measuring vees

Info

Publication number: WO2004067845A1
Application number: PCT/EP2003/013863
Authority: WO
Inventors: Ullrich FREITÄGER
Original assignee: Max Bögl Bauunternehmung GmbH & Co. KG
Priority date: 2003-01-27
Filing date: 2003-12-06
Publication date: 2004-08-12
Also published as: DE10303177A1; CN100523378C; KR20050097518A; CN1745217A; KR101255347B1; EP1587987A1; AU2003294810A1; EP1587987B1

Abstract

The invention relates to a method for installing a pre-fabricated unit (1), especially a pre-fabricated slab for constructing a ballastless track, whereby a plurality of successively arranged pre-fabricated units (1) form a section. Polygonal points (3) define an outer geometry of the course of the section. A measuring appliance, especially a tachymeter (4), is placed on a first polygonal point (3) and oriented in relation to at least one target point. The actual positions of a plurality of measuring points of the pre-fabricated unit (1) are measured, and compared with the nominal positions thereof, and the pre-fabricated unit (1) is installed according to the difference between the actual positions and the nominal positions. The invention also relates to a device for receiving at least one measuring vee (11), said device being arranged on a pre-fabricated unit (1), especially a pre-fabricated slab, for constructing a ballastless track, and comprising a measuring vee carrier (21,22) containing at least one measuring vee (11) at a pre-determined point of the pre-fabricated unit or at a pre-determined distance from said pre-fabricated unit (1).

Description

Method for setting up a finished part and device for receiving measuring prisms

The present invention relates to a method for setting up a prefabricated part, in particular a prefabricated plate for the construction of a slab track, which forms a route together with a plurality of prefabricated parts arranged one behind the other, with polygon points which determine an external geometry of the course of the route and a device for accommodating several Measuring prisms, which is arranged on a prefabricated part, in particular a prefabricated plate, for building a slab track.

EP 0 780 514 B1 discloses a method for spatially precise positioning of production facilities, which is controlled using reference points in such a way that rail fastening bodies are arranged at the desired location with the desired accuracy. The manufacturing facility can be moved and can measure at least one reference point for selected positions. The arrangement of the rail fastening bodies is controlled by the production device depending on the position to the reference points. For this purpose, sensors are designed as television cameras on the production device, which detects the height of the production device in comparison to the height of the respective associated reference point. The deviation of the actual from the target position is calculated, whereupon the production device is shifted in the longitudinal and transverse directions into the target position. The rail fastening body is then positioned and fastened.

A disadvantage of this device is that a large number of reference points is required for precise laying of the rail fastening body in order to be able to carry out the positioning of the rail fastening body with the accuracy required for high-speed railways. The reference points must be arranged along the route so that the manufacturing facility can use them as a guide. A lot of work is therefore required to create the reference points. In addition, the position of a production device is precisely determined with the proposed method. However, the proposed method does not check whether the production device subsequently positions the rail fastening body correctly.

It is therefore an object of the present invention to provide a method and a device with which the above-mentioned disadvantages are avoided and, in particular, a quick and reliable setting up of precast panels is possible with little manpower. Furthermore, it is an object of the invention to be able to use simple and standardized measuring devices for precise measurement and setup of the finished parts.

The object is achieved with the features of the independent claims.

The method according to the invention is used to set up a prefabricated part, in particular a prefabricated plate for the construction of a slab track. Several finished parts arranged one behind the other form a line. The route composed of the finished parts has polygon points which determine an external geometry of the course of the route. According to the invention, a measuring device, in particular a tachymeter, is set up at a first polygon point and oriented with respect to at least one target point. Then measuring points of the finished part are measured based on this target point orientation with regard to their actual position and compared with their target position. The finished part is then set up according to the difference between the actual and target position. The orientation of the tachymeter and the measurement of the actual position of the measuring points of the finished part is done by creating a target line or orientation line between the tachymeter and the target point, from which the position of the measuring points is determined. The win- point can be used. This is often the better and easier way to determine the position of the measuring point. A tolerance of +/- 0.1 mm may be permitted.

With these tolerances, the position of the finished part or its measuring points is from the target line, i.e. given the internal geometry with very high accuracy .. The kinks between the individual sections of the route, which are determined by the finished parts, are particularly small. It is assumed that the finished parts are very precisely manufactured. The operation of high-speed trains on the prefabricated parts of the slab track is therefore very convenient and safe to perform.

The measuring points of the finished part are advantageously measuring prisms which are arranged on the finished part. They can either be placed on the finished part with a gauge that simulates, for example, the upper edge of the rails and thus indirectly indicate the position of the finished part, or they can be arranged directly on the finished part and thus directly indicate the position of the finished part.

It is particularly advantageous if a measuring prism arranged at a polygon point is used as the target point. The measuring prism is particularly well suited for sighting through the measuring device or the tachymeter. If the measuring prism is arranged at a polygon point, the line between the tachymeter and the polygon point forms the orientation or target line at which the finished part is aligned. With a correspondingly precise positioning of the individual polygon points, the tachymeter and the measuring prism at the respective polygon point, a sufficiently precise target line is created, which enables the laying of finished parts with only slight kinks.

If the target point is set up on a finely aligned, preferably on the last finely aligned finished part, the laying of the successive angle between the orientation line and the line between the tachymeter and the measuring point, and the distance of the measuring point from the tachymeter, and compared with target values. If these target values do not match the required actual values, the position of the finished part is corrected. In contrast to the individual polygon points, which determine the outer geometry of the route, the target lines of the individual finished parts are part of the inner geometry of the route, ie they determine the neighborhood accuracy of successive finished parts.

The polygon points near the axis of the route are advantageously chosen. These polygon points close to the axis are subject to the parameters of the internal geometry to be maintained with regard to their neighborhood accuracy. This means that neighboring polygon points have only an extremely small deviation from the required internal geometry. Overall, the polygon points represent the outer geometry of the route section and can allow a greater tolerance in this regard. In the case of prefabricated parts for the construction of a slab track, orders of magnitude for the tolerance that can easily be achieved with the inventive measuring system are approximately +/- 0.2 mm with regard to the neighborhood accuracy or internal geometry. The polygon points close to the axis have the advantage that they map the outer geometry of the line and thus enable the actual laying of the line on the axis defined by the polygon points.

The measuring points are advantageously measured with regard to their position in relation to the line between the tachymeter and the target point. The decisive factor is the distance between the tachymeter and the measuring point and the angle between the finish line and the line from the tachymeter to the measuring point. For the distance measurement of the distance between the tachymeter and the measuring point, a tolerance of approximately +/- 1 mm is insignificant when laying a slab track. Instead of the angular deviation from the finish line, the transverse deviation from the finish line can also be used to assess the accuracy of the measurement prefabricated parts even more precisely than is the case with the arrangement of the target point at a polygon point. This compensates for any inaccuracy when laying the last finely aligned finished part. This actually smoothes the actual inner geometry,

The finished part is advantageously carried by means of adjusting elements, in particular spindles, on a base, in particular a hydraulically bound base layer (HGT). By turning the spindles, the finished part is brought into its target position in accordance with the specifications of the measurement.

If the adjustment elements, in particular spindles, are screwed to ground contact before measuring the actual position, a defined position of the spindles and the finished part is created, from which the finished part can be set up.

It is particularly easy if the spindle contact with the ground is determined by a predefined torque on the spindle. As soon as this torque is applied to the spindle or the screwdriver, a defined position of the spindle and the finished part is obtained, from which the finished part is then adjusted. In order to obtain additional safety when fine-tuning the finished parts, it is advantageous if the difference between the actual and target positions is displayed first and released before the finished part is actually set up. This prevents the precast part from being set up incorrectly in the event of a faulty measurement and the measurement and setting up of the precast part having to be carried out from scratch. The display can be used to perform a plausibility check and, if necessary, the measurement can be carried out again. If the spindles are adjusted using automatically controlled setting screwdrivers, the finished part can be set up very quickly, reliably and in a way that saves personnel.

It is particularly simple and advantageous if the measuring points are measured automatically. The total station independently determines the actual position in all measuring points and then displays the adjustment or positioning data of the adjustment elements, in particular the spindles, by means of a display device. The manual aiming of the individual measuring points by an operator is no longer necessary.

After the actual position has been determined, compared with the target position and the difference has been calculated, the finished part is set up, in particular by adjusting the adjusting elements, in particular the spindles. Then the measuring points are measured again and compared with their target position. If the difference is still outside the permissible tolerance, the fine adjustment process is repeated until the difference between the actual and the target position no longer exceeds a predetermined value.

The last measured values of the precision straightening process are advantageously stored as a measurement log in order to be able to document the position of the finished part and, if necessary, to be able to prove this to the client.

A device according to the invention, which can be used in the implementation of the method according to the invention for setting up a prefabricated part, has a receptacle for a plurality of measuring prisms, which is provided for arrangement on a prefabricated part, in particular a prefabricated plate, for the construction of a slab track. The device has a measuring prism holder which holds at least one measuring prism at a predetermined position on the finished part or at a predetermined distance from the finished part when the device is arranged on the finished part. The device has the particular advantage that, in particular in the case of a plurality of measuring prisms, it creates the assignment of the individual measuring prisms to one another and thus makes it unnecessary to adjust these measuring prisms to one another when fine-tuning a finished part. The device forms a measuring gauge for setting up the finished part, so to speak. The measuring prisms are located at defined positions in relation to the finished part and can therefore be observed when measuring any number of finished parts. After a finished part has been set up, the device is removed from this finished part and moved to the next finished part. It only has to be roughly positioned there in order to be able to create the target points for the measurement of the finished part.

The measuring prism of the device is advantageously arranged in the region of a supporting spindle of the finished part. As a result, the measured value on the measuring prism can be converted directly into an adjustment of the supporting spindle. It is hereby established that when the spindle is adjusted by a certain amount, the position of the measuring prism is also changed by this amount. An additional conversion is therefore not necessary.

If the measuring prism is arranged in the area of a rail base, the support of a rail on the prefabricated part of a slab track can be measured. The measuring prism can be placed directly on the rail support point or, according to a particularly advantageous embodiment, can be arranged at a predetermined distance from the rail support point and thereby, for example, correspond to the distance of the upper edge of the rail from the finished part. By arranging the measuring prism at a defined distance from the finished part, the later installed rail is simulated and aligned with this point that is decisive for the train's operation.

If at least two measuring prisms are arranged on the measuring prism carrier, which describe the distance between two parallel rails, the prefabricated plate is aligned according to the course of the rail. This ensures a particularly comfortable operation of the rail vehicle since shocks are avoided. In addition, additional special adjustment measures and compensation measures on the rails are hardly necessary anymore when they are being installed. This arrangement also compensates for differences in height in the surface of the finished part in the vicinity of the spindle and thus results in a uniform, defined course of the rails.

It is particularly advantageous for the measurement and positioning of the device if the measuring prism support has a device for the measuring prism which can be placed on a rail base and then corresponds to the distance of a rail head from the rail base. The device thus defines a rail head at the predefined distance from its bearing point. A substructure, which is arranged, for example, in the form of rubber plates under the rail foot, can also be taken into account for the corresponding distance.

In order to be able to measure several finished parts in succession, it is particularly advantageous if the device according to the invention can be moved on the finished part. For this purpose, wheels can be connected to the device, for example, which guide the device on the finished part and can be pushed onto the subsequent finished part after the finished part has been set up. If at least one servomotor for adjusting a supporting spindle of the finished part is arranged on the device, the setting up of the finished part is very quick and simple _. perform. When the servomotor receives a corresponding signal, it is set in motion and rotates the supporting spindle of the finished part by a predetermined amount in order to raise or lower the finished part.

It is particularly advantageous if the servomotor aligns the finished part both in height and transversely to the longitudinal axis of the finished part. For this purpose, the same or a further servomotor can be provided, one servomotor for the height adjustment and another servomotor for the transverse adjustment of the finished part.

For automatic adjustment of the position of the finished part, it is advantageously provided that the servomotor is controlled via a computer or an evaluation device of the tachymeter. The measured values obtained from the tachymeter can be forwarded directly to the servomotors via the control and can result in a corresponding adjustment of the finished part to its target position.

With a cross-slope sensor, the measurement can advantageously be carried out in connection with one of three measuring prisms arranged in series and thus alternatively determine the position of the finished part.

Further advantages of the invention are described in the following exemplary embodiments. Show it:

FIG. 1 shows a plan view of a measuring device,

Figure 2 shows a cross section through a precast plate with a measuring device and plate 1 '. In addition, the measuring prisms 11.1 to 11.6 are located in the vicinity of spindles 12, which are provided for the adjustment of the precast plate V. The adjustment of the spindles 12 takes place with servomotors 13, which rotates the spindle 12 more or less in a thread and thus raises or lowers the prefabricated plate 1 '.

To measure the actual position of the prefabricated panel 1, the deviation of the individual measuring prisms 11.1 to 11.6 is determined on the basis of the orientation line 6 using the tachymeter 4. For this purpose, the distance of the individual measuring prisms 11.1 to 11.6 from the tachymeter 4 is measured and the angle α between the orientation line 6 and the measuring beam 14.1 to 14.6 to the individual measuring prisms 11.1 to 11.6 is determined. The values are compared with a specified target value. If the two values lie within a permissible tolerance, the precast plate 1 'is set up. Otherwise, the respective spindle 12 is actuated via a signal to the servomotors 13 and the position of the precast plate 1 'is changed. Then measurements on the measuring prisms are started again and the position now present is compared with the target value. This process continues until the target and actual values are within a permissible tolerance range.

When the precast plate 1 'is set up, the measuring device 10 is removed and brought to the precast plate 1 ". This is done by moving the tachymeter 4 to a next polygon point 3. The target prism 5 is placed on the polygon point 3' and the measuring device 10 is moved from the precast plate V to the precast plate 1 ". For this purpose, the measuring device 10 has wheels 15 which can roll on the precast plate V and 1 ″. To keep the measuring device 10 in track, it also has supporting wheels 16 in addition to the wheels 15, which act laterally on the precast plates 1 and thus the measuring device 10 on the

- Center the precast plate 1. The measuring device 10 is then positioned on the precast plate 1 ″ in such a way that the servomotors 13 on the spin 3 shows the top view of a further measuring arrangement.

FIG. 1 shows a plan view of a measuring arrangement on three successive prefabricated plate 1 of a slab track for rail-guided vehicles. Each of the precast panels 1 has rail support points 2, on which rails for the rail-guided vehicle are mounted after the precast panel 1 has been set up. The prefabricated panel 1 partially drawn on the left in the figure is already in its desired position, while the middle and right prefabricated panels V and 1 "still have to be set up. FIG. 1 shows the setting up of the middle prefabricated panel V.

Polygon points 3 and 3 'are arranged between the prefabricated panels 1. The polygon points essentially mark the outer geometry of the route. Within the outer geometry, which can have relatively large deviations from the target geometry, the inner geometry, i.e. the course of the polygon, which results from the stringing together of a plurality of prefabricated panels 1, should be as uniform as possible in order to be able to carry out the driving operation of the vehicle in a particularly comfortable manner.

The polygon point 3 is located between the prefabricated panel 1 already set up and the prefabricated panel 1 'to be set up. It was used to set up the precast slab 1 as a position for a tachymeter 4. This tachymeter 4 is now located on the polygon point 3 'for setting up the precast slab 1 ^* . To orientate the tachymeter 4, the tachymeter 4 aims with a beam at a target prism 5, which is located on the polygon point 3. As a result, an orientation line 6 is set up between the tachymeter 4 and the target prism 5, according to which the precast plate V is aligned.

A measuring device 10 is located on the precast plate V. Six measuring prisms 11.1 to 11.6 are arranged on the measuring device 10. The measuring prisms 11.1 to 11.6 are located at support points 2 of the precast Your 12 can attack and rotate it to position the plate 1 ". The measuring process for setting up the precast plate 1" is then carried out in the same way as for plate 1 '.

Alternatively or in addition to these measurements, the measurement of only one direction strand, i.e. only the measuring prisms in a row, i.e. measuring prisms 11.2, 11.4 and 11.6 or 11.1, 11.3 and 11.5. The values of tilt sensors 110 are used as additional measured values, which indicate the bank of the plate 1 based on the measured measuring prisms. This also enables a very precise determination of the position of the precast plate 1. The tilt sensors, also called inclinometers, are arranged, for example, on the connecting struts of the measuring device 10. The required setting of the spindles 17 can be calculated from their signals in conjunction with the values of the measuring prisms.

FIG. 2 shows a section through a prefabricated plate 1, which is arranged with spindles 12 on a hydraulically bound base layer 20. The spindles 12 support the precast plate 1 on the top of the base layer 20. The polygon point 3, which defines the outer geometry of the route, is arranged in the base layer 20. The tachymeter 4 is arranged at the polygon point 3. The tachymeter 4 sends a measuring beam 14.1 and 14.2 to the measuring prisms 11.1 and 11.2. The position of the finished part plate 1 is determined from the position of these measuring prisms 11.1 and 11.2 relative to a desired position.

The measuring prisms 11.1 and 11.2 are located on the measuring device 10. They are arranged on the support points 2 of the precast plate 1 with the aid of feet 21. The feet 21 simulate the track later mounted on the support points 2. The measuring prisms 11.1 and 11.2 are thus at a height that corresponds to the later rail head. In order to also be able to take the track gauge of the track into account when measuring the precast slab 1 NEN, the two measuring prisms 11.1 and 11.2 are connected to a connecting rod 22.

In order to convey the laying of the measuring device 10 from an installed prefabricated plate 1 to a new prefabricated plate 1, the measuring device 10 has wheels 15. The feet 21, the connecting rod 22 and the servomotors 13 are arranged on the measuring device 10. As a result, the displacement of the measuring device 10 can be carried out very quickly and without great expenditure on personnel.

FIG. 3 shows a measurement method which corresponds in principle to the measurement method of FIG. 1, but works even more precisely with regard to the internal geometry. The determination of the orientation line does not take place with the sighting of a polygon point 3, which is close to a prefabricated plate 1 that has already been set up. Rather, the orientation line 6 'is directed to points which are already set up precisely and which are located on the precast plate 1. For this purpose, an auxiliary device 25 is arranged on support points 2 of the precast plate 1, which has target prisms 5 '. The tachymeter 4 is now oriented on these target prisms 5 ', which results in two orientation lines 6'. The measuring prisms 11.1 to 11.6 are now measured starting from the orientation lines 6 '. An inaccuracy which is present between the polygon point 3 and the actually installed prefabricated panel 1 is eliminated by this setup method, since the actual prefabricated panel 1, which has already been set up, is decisive.

Another difference of this measuring method compared to the measuring method according to FIG. 1 is that the tachymeter 4 is not arranged at the closest polygon point 3, but at a more distant polygon point 3. This creates a longer measuring beam, which results in a more precise measurement and thus a lower measurement error. The precast panel 1 'can hereby be set up even more precisely. The present invention is not limited to the exemplary embodiments shown, in particular a combination of the two embodiments of the invention shown in FIG. 1 and FIG. 3 can take place. For example, the tachymeter 4 can be arranged closer to the prefabricated panel to be set up than is shown in FIG. 3. In addition, it is not always necessary that the setting of the spindles 12 is carried out by means of servomotors 13. The adjustment of the spindles 12 can of course also be done manually. For the rest, it is sufficient in most cases if only a height adjustment is carried out with the spindles 12. The lateral adjustment of the precast plate with the spindles 17 and possibly servomotors 13 connected to it will not be necessary in every case. It can also be set manually using appropriate adjustment devices. Instead of the spindles, it is of course also possible to use another adjusting element with the same effect. Hydraulic or pneumatic cylinders, for example, are suitable for this purpose, which bring the precast plate into the desired position. The scope of protection therefore also extends to such adjustment elements.

Claims

P a t e n t a n s r u c h e

1. Method for setting up a prefabricated part (1), in particular a prefabricated part slab for the construction of a slab track, which together with several prefabricated parts (1) arranged one behind the other forms a route, with polygon points (3) which determine an external geometry of the course of the route, characterized in that a measuring device, in particular a tachymeter (4), is set up at a first polygon point (3) and oriented with respect to at least one target point, that subsequently several measuring points of the finished part (1) are measured with regard to their actual position, with the target -Position compared and the finished part (1) is set up according to the difference between the actual and target position.

2. The method according to the preceding claim, characterized in that the polygon points (3) are selected near the axis of the route.

3. The method according to any one of the preceding claims, characterized in that adjacent polygon points (3) do not exceed a predetermined tolerance to the outer geometry.

4. The method according to any one of the preceding claims, characterized in that the measuring points are measured with respect to their position to the line between the tachymeter (4) and the target point.

5. The method according to any one of the preceding claims, characterized in that the measuring points on the finished part (1) are arranged measuring spisms (11).

6. The method according to any one of the preceding claims, characterized in that the target point is a measuring prism (5) arranged on a polygon point (3).

7. The method according to any one of the preceding claims, characterized in that the target point is set up on a fine-tuned, preferably on the last fine-tuned finished part (1).

8. The method according to any one of the preceding claims, characterized in that the finished part (1) is carried on a surface by means of an adjusting element, in particular spindles (12).

9. The method according to any one of the preceding claims, characterized in that the adjusting elements, in particular the spindles (12) are screwed to ground contact before measuring the actual position.

10. The method according to any one of the preceding claims, characterized in that the ground contact of the spindle (12) is determined via a predetermined torque on the spindle (12).

11. The method according to any one of the preceding claims, characterized in that the difference between the actual and target position and / or setting values of the adjusting elements, in particular the spindles (12) are displayed and released before setting up.

12. experienced according to one of the preceding claims, characterized in that the spindles (12) with automatically controlled adjusting screwdrivers (13) are adjusted.

13. The method according to any one of the preceding claims, characterized in that the measurement of the measuring points is carried out automatically.

14. The method according to any one of the preceding claims, characterized in that the fine straightening process is repeated until the difference between the actual and target position no longer exceeds a predetermined value.

15. The method according to any one of the preceding claims, characterized in that the last measured values of the fine straightening process are stored as a measurement protocol.

16. Device for receiving at least one measuring prism (11), which is provided for arrangement on a prefabricated part (1), in particular a prefabricated plate for the construction of a slab track, characterized in that the device has a measuring prism carrier (21, 22) which at least one measuring prism (11) at a predetermined location of the finished part (1) or in a predetermined one

Keeps distance to the finished part (1).

17. The device according to the preceding claim, characterized in that the measuring prism (11) is arranged in the region of an adjusting element, in particular a supporting spindle (12) of the finished part (1).

18. Device according to one of the preceding claims, characterized in that the measuring prism (11) is arranged in the region of a rail support point (2).

19. Device according to one of the preceding claims, characterized in that the predetermined distance of the measuring prism (11) corresponds to the distance of the upper edge of the rail from the finished part (1).

20. Device according to one of the preceding claims, characterized in that the measuring prism carrier (21, 22) at least two measuring prisms (11), which are arranged at a distance from two parallel rails.

2 I .Device according to one of the preceding claims, characterized in that the measuring prism carrier (21, 22) is a device for

Measuring prism (11) which, when placed on a rail base, corresponds to the distance of a rail head from the rail base (2).

22. Device according to one of the preceding claims, characterized in that the device (10) on the finished part (1) is displaceable.

23. Device according to one of the preceding claims, characterized in that at least one servomotor (13) for adjusting an adjusting element, in particular a supporting spindle (12) of the finished part (1), is arranged on the device (10).

24. Device according to one of the preceding claims, characterized in that the servomotor (13) aligns the finished part (1) in height and / or transversely to the longitudinal axis of the finished part (1).

25. Device according to one of the preceding claims, characterized in that the servomotor (13) is controlled by a computer or an evaluation device.

26. Device according to one of the preceding claims, characterized in that the device (10) has a bank sensor (110).