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Use of Mobile Laser Scanning Complexes for Precise Determination of the Beam Gradient by Metal Bridges. 8th FIG Regional Conference Surveying towards Sustainable Development. Ivo Milev 26 – 29 November 2012 Montevideo, Uruguay.
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Use of Mobile Laser Scanning Complexes for Precise Determination of the Beam Gradient by Metal Bridges 8th FIG Regional Conference Surveying towards Sustainable Development Ivo Milev 26 – 29 November 2012 Montevideo, Uruguay
Weser bridge Dreye Strategic infrastructure for the german railways(Track number. 2200, km 229,2 - 229,8)
Weser bridge Dreye 1927 constructionHamburg-Bremen-Köln-Venlo 1870-73 Weser as natural barrier
Content 1 Comparison of the data aquisition methods for bridge sleepers exchange 1.1 Classic method 1.2 Data aquisition with laserscanning based multisensor system 2 Steps for data aqusition and calculation using laserscanning 2.1 Geopositioning of the multisensor system 2.2 Detection of the bridge beams 2.3 Processing of the kinematic scans with SiRailScan 2.4 Automated generated register of the sleepers with Verm.esn 3 Impression from the building 4 Summary / Conclusion
Comparison of the data aquisition methods for bridge sleepers exchange 1.1 Classic method • levelling the horizontal steel beams (as follow named beams) of the bridge frame. The results are heights relative to the benchmark consoles • Tachymetric detection of the beam edges • Traditional method used till 2011-characteristics • Average daily output (8h) with classic method: 250 sleepers • Average processing performance (geodetic data total station and leveling) of the measurement : 300 sleepers per day
Classic measuring method • time consuming process to record the beams and random mounted bearings (x,y,z) at the right location cost for SiPo (safety personal of DB AG) and accommodation of the surveyor team. One troop 4 people with 2 hours frequency of exchange looking in both directions 500m with walkie-talkie ~1000 EUR/day + min two people surveyors • Few after work processes, if a hierarchic number system is used during the measuring process • Potential difficulties to detect measuring errors (polar • tacheometric measuring design without control) • Slight graphic documentation of the measuring • data, the beams are represented with 4 points • Non homogeneous information about the beam surface
1.2 Data aquisition with laserscanning • multisensor system with integrated laserscanner • capturing of the whole beam shape (surface heights and • edges) in one run via 3D technique • objects that prohibit the seeing of the laserscanner has to • be removed if necessary (for instance the security plates) • Laserscanning method • Average daily output (8h) with laserscanning method : 3000 sleepers • Average processing time for the captured data : 200 sleepers per day – based on the current status of automatization!
2 Steps for measuring and analyzing with laser-scanning2.1 Geopositioning of the multisensor system • Positioning of the scanner above the rails resp. beams • Defining the position of the scanner each 20m via tachymetric free station based on 4 bechmarks (mounted prism adaptors with constant offset) • Simultaneously scanning the benchmark points of the • track (GV) marked with spheres Rail transition to the bridge
2.2 kinematic laserscanning of the bridge beams • Multi sensor system to scan based capturing of the environment • Measurement performance - 2 km/h • Short times of track locking • Optional: the system could be lifted out • of the rails within 8s, (horn signal) • a complete locking of the track is not a must • For this bridge it was not possible • Each day of surveyor work on the bridge is a • big safety risk!
2.3. Processing of the laser scans with SiRailScan Georeferencing and synchronizing the scans Cutting out the detected beam geometry Calculation of the beam heights 04.01.2020
Example for a structure change 04.01.2020
Structure change Height based color coded beams: scan overview: Hidden by the sleepers 04.01.2020
Milled out sleeper 04.01.2020
If an 4 cm height difference on the steel beam surface is detected a sleepers milling is necessary cmiling m An automated algorithm is searching for the heightsmiling m Bearing with plates 04.01.2020
Transversal beam with plates The coloring of the heights of the beams relieved the control an the detection of the plates (height differences) The standard height on the steel beam is blue, the plates are colored green The height differences are approximately 1,5cm Correspondingly the milling for some sleepers has to be adapted 04.01.2020
Milled out sleeper with plate - puzzle numered sleepers Nürnberg Approximated fitted height with plates – milling is still needed – 2 cm plates 04.01.2020
Corrosion protection damaged – source for outliers by the leveling Rail force bearer with plates (height coded coloring) Hier sieht man die Höhendifferenzen im Bauwerk – sind über 2,5 cm. Mit den Lagenwechseln des Trägers und Platten (beim blauen). Durch die Platten wurden die Höhendifferenzen der Träger halbwegs ausgeglichen. Trotzdem musste man dies bei den Fräsungen beachten 04.01.2020
Change in the bearing thickness on the top beam belt Rail force bearer with plates (height coded coloring) Hier sieht man die Höhendifferenzen im Bauwerk – sind über 2,5 cm. Mit den Lagenwechseln des Trägers und Platten (beim blauen). Durch die Platten wurden die Höhendifferenzen der Träger halbwegs ausgeglichen. Trotzdem musste man dies bei den Fräsungen beachten 04.01.2020
Bearing plate not detectable by classical surveying Rail force bearer with plates (height coded coloring) Hier sieht man die Höhendifferenzen im Bauwerk – sind über 2,5 cm. Mit den Lagenwechseln des Trägers und Platten (beim blauen). Durch die Platten wurden die Höhendifferenzen der Träger halbwegs ausgeglichen. Trotzdem musste man dies bei den Fräsungen beachten 04.01.2020
Rail force bearer with plates (height coded coloring) The height differences in the structure are shown ~ 2,5 cm. It‘s still the main point of focus during the menufacturing of the sleepers 04.01.2020
Results of the beam measurement homogenity check Gegengleis-Träger mit Plattungen (Höhencodierte Einfärbung) 04.01.2020
Results of the beam bending Excell graphiken Gegengleis-Träger mit Plattungen (Höhencodierte Einfärbung) 04.01.2020
SiRailScan processing Results Detection of the sleeper coordinates in pointfiles Half automated determination of the beams heights for the sleepers Summary Output of the data in Excel Transfer of the result heights and coordinates to Ver.esm Gegengleis-Träger mit Plattungen (Höhencodierte Einfärbung) 04.01.2020
Import the coordinates and heights to Verm.esn • Setting of the beam widths for calculation of possible not measured points • Setting of the designed track geometry (chainage, track, gradient)! • Automatic calculation of the sleeper file with the beam heights • Automatic calculation of the sleeper files -BRS (optional also in Excel) for the sleeper manufacturer 2.4 Generate the sleepers register with Verm.esn
3 Impressions of the building structure Bridge over the Weser – frame bridge
…Extracting old sleepers Build in the new sleepers…
...Align the sleepers, marking and drilling, then screwing Put the new rails on and lock them
4 Summary / Conclusion • The demanded precision for the sleeper modernization (3mm in xy, 2mm in z) were fulfilled with the multi sensor scanning system and the optimized processing. Brand new and innovative method! • The advantage is the short locking time of the track for the measurement • Half automated algorithms for detecting the beams heights and edges • detection of the beam shapes (heights and edges) in one run via 3D technique • Continues (complete) model of the beam – not just spots • Complete documentation of every sleeper, beam and the near environment relations in 3D - preservation of evidence