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Die Kenntnis von Materialeigenschaften spielt bei der Entwicklung oder Optimierung von Betonen und Bauweisen für den Straßenbau sowie der Qualitätskontrolle und -sicherung eine bedeutende Rolle. Gleichermaßen bilden physikalische Materialkennwerte die Grundlage für die rechnerische Dimensionierung und die Restsubstanzbewertung von Betonfahrbahndecken. Einen relevanten Kennwert bei der Untersuchung thermisch induzierter Spannungs- und Verformungszustände stellt der thermische Ausdehnungskoeffizient von Beton dar. Dieser beeinflusst beispielsweise maßgeblich das Längsdehnungsverhalten des Deckensystems sowie das Ausmaß von Plattenkrümmungen und Fugenbewegungen. Im Zuge der systematischen Weiterentwicklung der rechnerischen Dimensionierung aber auch im Zusammenhang mit der gezielten Verbesserung der Gebrauchseigenschaften von Fahrbahndecken gilt es zu hinterfragen, ob lastunabhängige Formänderungseigenschaften, wie z. B. der thermische Ausdehnungskoeffizient der verwendeten Betone, aktuell ausreichend Beachtung finden, ob allgemeine Literaturwerte für die heutigen Fahrbandeckenbetone stets Gültigkeit besitzen und ob deren Implementierung in moderne Rechenmodelle zu validen Ergebnissen führt. Für eine empirische Herangehensweise ist die Verfügbarkeit adäquater Prüfverfahren von entscheidender Bedeutung. In Deutschland existiert aktuell jedoch kein standardisiertes oder genormtes Verfahren für die prüftechnische Bestimmung des thermischen Ausdehnungskoeffizienten von Beton. Daher wurden unter Beachtung straßenbauspezifischer Gesichtspunkte zwei Prüfansätze entwickelt, die in diesem Beitrag vorgestellt und hinsichtlich möglicher Messunsicherheiten und Messungenauigkeiten diskutiert werden. Außerdem erfolgt die Darstellung ausgewählter Ergebnisse aus Analysen an Bestandsbetonen aus dem BAB-Netz. Im Ergebnis sollen die Untersuchungen einen Beitrag zur Schaffung der prüftechnischen Voraussetzungen für eine abgesicherte Quantifzierung der thermischen Dehnung von Fahrbahndeckenbetonen leisten.
Knowledge of material properties is of great importance when developing new types of concrete and construction methods for road building, and for quality control and quality assurance. Physical material characteristics are likewise the basis for dimensioning and assessing the residual substance of concrete pavements. One relevant characteristic when examining thermally induced stress and deformation is the coefficient of thermal expansion (CTE) of concrete. This indicator, for example, significantly influences the longitudinal expansion of the pavement system as well as the degree of curling of slabs and joint movements. Extensive tests were conducted during the technical engineering assessment of the structural substance of concrete pavements in the German motorway network, including tests to determine the CTE of existing types of concrete. Because no standardised procedure currently exists in Germany for using tests to determine the CTE of concrete, the initial task was to develop a suitable test procedure from a road-building perspective, taking consideration of the national prevailing structural conditions. This article presents the results of selected status analyses, in which the CTE was determined for a total of 656 individual samples. The values calculated for the top and bottom drilled core layer are in the range 8.9 – 13.2 x 10-6/K, whereby the average CTE assumes a value of 10.7 x 10-6/K. The deviations of the CTEs from the bottom and top drilled core layer are in principle significantly below the limitation to a maximum of 2.50 x 10-6/K recommended in literature.
Die EU-Umgebungslärmrichtlinie (2002/49/EG) sieht Lärmkarten und Lärmaktionspläne (Maßnahmenpläne) für Ballungsräume vor. Verbunden mit einer generell steigenden Sensibilisierung gegenüber Umweltthemen, kommt der Lärmminderung in bebauten Gebieten große Bedeutung zu. Durch die Auswahl geeigneter Lärm mindernder Asphaltdeckschichten kann die Straßenoberfläche hier einen Beitrag leisten. Die Planung und Ausführung derartiger Baumaßnahmen unterliegt in bebauten Gebieten einigen Besonderheiten, denen Rechnung getragen werden muss. Soll zudem eine Einschätzung der akustischen Wirksamkeit erfolgen, zum Beispiel im Rahmen von Erprobungsstrecken, so müssen die Randbedingungen bei der Messung von Schallpegeln im Nahfeld (Anhänger) oder mit der Methode der statistischen Vorbeifahrt beachtet werden.
The Netherlands is on the way to change its existing skid resistance measuring method for its highway network from the Dutch RAW 72, a longitudinal force method, to the Sideway Force method. This method is described in the Technical Specification 15901-8 (SKM device) as well as 15901-6 (SCRIM device) and is in use in 9 European countries. The CEN TC 227 WG5 on Surface Characteristics is currently working on combining of these two technical Specifications into a European standard for Sideway-Force (SWF) measurement devices. The idea of this change in the Netherlands was perceived in 2013 and since then a lot of meetings have been held with the different Dutch decision makers as well as with countries which currently operate SWF devices. There was an intensive exchange of knowledge about these devices and their corresponding quality assurance systems, because the Netherlands wanted to incorporate and rely on an existing system of a neighbor country without losing their present level of quality. The Netherlands has therefore decided to incorporate the German SKM approach. The network monitoring with the new system will start in 2017. To ensure the quality of skid resistance measurements and further cooperation in this field, it has been decided to initiate an alliance between BASt and the Dutch road owner Rijkswaterstaat (RWS). This alliance will facilitate an exchange of research activities, calibration of the Dutch systems according to the existing German Standard as well as control measurements with a BASt-device on the Dutch network during the network monitoring. During 2016 also comparative measurements will be performed on a network level with the current Dutch device and with an SKM device to determine a conversion between the two and to be able to define new threshold values.
APT with the mobile load simulator MLS10 towards non-destructive pavement structural analysis
(2019)
In 2014 a research program has been started about non-destructive test methods to evaluate the structure of pavements. This task has been given to two research groups - first research group is led by RWTH Aachen University (Rheinisch-Westfälische Technische Hochschule) and the second by University of Siegen. This paper focuses on the initial findings of the running research program. The assessment of the existing infrastructure and its condition will be one of the main tasks during the next years in order to use the available budget for maintenance accurately and efficiently. Therefore, it is necessary to identify possible damages and examine their effects on the road construction. BASt (Federal Highway Research Institute) is using the Mobile Load Simulator MLS10 for accelerated pavement testing (APT) on different types of pavements. In addition to non-destructive test methods, sensors are applied to measure structural impacts. The overall objective of this research program is to develop a non-destructive test method that allows the calculation of the remaining life time and load cycles of pavements. To simulate realistic wheel loads in a short period of time the MLS10 on German full scale standard pavement constructions has been used. The first pavement test section was loaded with 3 x 10 high 6 50 kN wheel loads while the second, thinner pavement test section was loaded with 3 x 10 high 5 50 kN wheel loads. Both loads are equivalent to the pavement design load. Three different strategies have been used to analyze and monitor structural changes. The innovative measurements have been realized by the two research groups to collect data for their models. The RWTH Aachen collected data with twelve geophones aligned in a row parallel to the wheel path. The geophones measure the entire vertical deflection basin of the pavement surface that exists due to the passing real truck wheels. These measurements were done for different truck speeds and at different transverse distances to the wheel path. The University of Siegen collected data by using acceleration sensors on the surface of the road construction. After recording the data they were integrated into displacement signals and evaluated. Additionally to those measurements BASt used conventional equipment to monitor the pavement structure and surface characteristics. The measurements and evaluation tools used for the innovation program have a high potential to validate APT programs in the future. Based on this research it is possible to start further research activities to push the non-destructive evaluation of pavements structures - not only in APT - into an improved direction.