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This study aimed to better understand nitrate transport in the soil system in a part of the state of North Rhine-Westphalia, in Germany, and to aid in the development of groundwater protection plans. An advection-diffusion (AD) cell was used in a miscible displacement experiment setup to characterize nitrate transport in 12 different soil samples from the study area. The three nitrate sorption isotherms were tested to define the exact nitrate interaction with the soil matrix. Soils varied in their properties which in its turn explain the variations in nitrate transport rates. Soil texture and organic matter content showed to have the most important effect on nitrate recovery and retardation. The miscible displacement experiment indicated a decrease in retardation by increasing sand fraction, and an increase in retardation by increasing soil organic matter content. Soil samples with high sand fractions (up to 94 %) exhibited low nitrate sorption capacity of less than 10 %, while soils with high organic matter content showed higher sorption of about 30 %. Based on parameterization for nitrate transport equation, the pore water velocity for both sandy and loamy soils were significantly different (P < 0.001). Pore water velocity in sandy soil (about 4 x 10 high 3 m/s) was about 100 to 1000 larger than in loamy soils (8.7 x 10 high 5 m/s). On the other hand, the reduction in nitrate transport in soils associated with high organic matter was due to fine pore pathways clogged by fine organic colloids. It is expected that the existing micro-phobicity increased the nitrate recovery from 9 to 32 % resulting in maximum diffusion rates of about 3.5 x 10 high 5 m/s2 in sandy soils (sample number CS-04) and about 1.4 x 10 high 7 m/s2 in silt loam soils (sample number FS-02).
Non-point sources of traffic-related pollution become a major concern as they " compared to the point-source inputs " are more difficult to be defined or controlled. It is crucial to evaluate the fraction of traffic-related contamination that is transported to the road surroundings as it could negatively impact soil, surface water and groundwater. This study describes two means through which pollutants leave the road to the surrounding environment. Three German motorways were selected (A4, A555, and A61), where runoff and deposits were analyzed to determine pollutant load moving into the roadside soil or into the drainage system. Each of the three motorways carries approximately 70,000 vehicles a day on 4 to 6 driving lanes; and they cover a broad range of truck participation in the total traffic load ranging from 5.4% to 19.8%. The three motorways represent several topographical and landscape features as forest with noise barrier and parallel as well as perpendicular orientation to the main wind direction. Sampling of runoff and deposition was done on monthly basis. Bulk deposition was collected in Bergerhoff vessels at two heights (1.5 m and 0.3 m above the ground) and in 1 m, 2.5 m, 5 m and 10 m distances from the road edge. The results showed that heavy metals as well as large amounts of mineral compounds are moving from the driving lanes into the roadside environment. This includes sodium from applying deicing salts in winter seasons, which could be found in soil, dust and water samples. Calcium and iron were also detected in almost comparable concentrations. The annual deposition flow (bulk deposition) measured at a height of 1.5 m was higher than the comparative values for urban areas and background measuring points. The spatial distribution of material deposition showed clear differences between the three motorways. The pollutant load in deposition measured near the ground surface was higher than those measured at 1.5 m above the land surface. At all three sites, a clear negative correlation between pollutant load and the distance from the roadside could be found. Nearly 90% of the concentration values of heavy metals in road runoff were below or in the range of the test values for seepage water in the German Soil Protection and Contamination Ordinance. The pH-values around 7 in runoff and adjacent soil provide a good retention capacity in the soil for the heavy metal input.
The road transport infrastructure is facing many challenges and the subsequent adaptation of the infrastructure is of utmost concern. These challenges are as follows: globalization, sustainability, technological and demographic change, an increase in goods transport and climate change. Various climate projections predict changing climatic parameters such as temperature, precipitation and wind speed for Germany. This could have severe impacts on road transport infrastructure as well as road traffic itself. At the Federal Highway Research Institute (Bundesanstalt für Straßenwesen), a strategy was developed to adapt roads and engineering structures to the impacts of climate change. The strategy "Anpassung der Straßenverkehrsinfrastruktur an den Klimawandel /Adaptation of road traffic infrastructure to climate change (AdSVIS)" currently comprises about 15 projects. Adaptation measures are to be developed for the identified risk areas and consequently their effectiveness has to be assessed.
Automated driving will provide many kinds of benefits - some direct and some indirect. The benefits originate at the individual level, from changes in the behaviour of drivers and travellers with regard to driving and mobility, ending up with benefits at the social level via changes in the whole transport system and society, where many of the current planning and operations paradigms are likely to be transformed by automated driving. There may also be disbenefits, particularly at a social level, for example in intensity of travel which could result in additional congestion and increased use of natural resources. There may also be unintended consequences. For example, we do not know the impacts on public transport: driverless vehicles could provide a means to a lower cost service provision, but the availability of automated cars could lead to more car travel at the expense of collective transport.
Motorcycling is a fascinating kind of transportation. While the riders' direct exposure to the environment and the unique driving dynamics are essential to this fascination, they both cause a risk potential which is several times higher than when driving a car. This chapter gives a detailed introduction to the fundamentals of motorcycle dynamics and shows how its peculiarities and limitations place high demands on the layout of dynamics control systems, especially when cornering. The basic principles of dynamic stabilization and directional control are addressed along with four characteristic modes of instability (capsize, wobble, weave, and kickback). Special attention is given to the challenges of braking (brake force distribution, dynamic over-braking, kinematic instability, and brake steer torque induced righting behavior). It is explained how these challenges are addressed by state-of-the-art brake, traction, and suspension control systems in terms of system layout and principles of function. It is illustrated how the integration of additional sensors " essentially roll angle assessment " enhances the cornering performance in all three categories, fostering a trend to higher system integration levels. An outlook on potential future control systems shows exemplarily how the undesired righting behavior when braking in curves can be controlled, e.g., by means of a so-called brake steer torque avoidance mechanism (BSTAM), forming the basis for predictive brake assist (PBA) or even autonomous emergency braking (AEB). Finally, the very limited potential of brake and chassis control to stabilize yaw and roll motion during unbraked cornering accidents is regarded, closing with a promising glance at roll stabilization through a pair of gimbaled gyroscopes.
In line with the new definition introduced by the European Commission (EC), the number of seriously injured road casualties in Germany for 2014 is assessed in this study. The number of MAIS3+ casualties is estimated by two different methodological approaches. The first approach is based on data from the German Inâ€Depth Accident Study (GIDAS), which is closely related to the German Road Traffic Accident Statistics. The second approach is based on data from the German TraumaRegister DGU-® (TRâ€DGU), which includes many more hospitals but not all MAIS3+ injuries.
Im Erd- und Straßenbau ist es in den letzten Jahren bei bindemittelbehandelten sulfathaltigen Böden wiederholt zu teilweise erheblichen Schäden durch Quellhebungen gekommen, die auf eine Mineralreaktion im Boden zurückzuführen sind. Werden Böden mit natürlichem Sulfatgehalt zu bautechnischen Zwecken mit calciumbasierten Bindemitteln behandelt, so kann das Bindemittel unter bestimmten Randbedingungen mit den im Gips enthaltenen Sulfationen zum Mineral Ettringit reagieren. Infolge der mit dieser Mineralneubildung verbundenen Volumenvergrößerung kann es zu erheblichen Hebungsschäden kommen. Die für die Reaktion des Sulfattreibens im Boden maßgebenden Einflussfaktoren sind zwar grundsätzlich bekannt, quantitative Prüfmethoden und standardisierte Strategien zur Gefahrenabwehr lagen bis dato allerdings noch nicht vor. Das Ziel des Forschungsvorhabens, über das in diesem Beitrag berichtet wird, war die Entwicklung eines praxistauglichen Prüfverfahrens als Grundlage für eine hieraus abzuleitende Prüfvorschrift. Hierfür wurden an Proben aus verschiedenen Boden-Bindemittelgemischen mit definierten Sulfatgehalten Quellhebungsversuche geplant, durchgeführt und ausgewertet. Im Ergebnis wurde ein annähernd linearer Zusammenhangzwischen dem Sulfatgehalt im Boden und den eingetretenen Quellhebungen festgestellt. Die Ergebnisse zeigen ferner, dass eine Behandlung sulfathaltiger Böden mit Weißfeinkalk mit größeren Quellhebungen verbunden ist als eine Behandlung mit Zement.
Brücken stellen eine wichtige Komponente unserer Verkehrsinfrastruktur dar, allerdings werden heutzutage die meisten Entscheidungen im Rahmen von Vergaben auf Grundlage der Herstellungskosten getroffen. Dieses Vorgehen greift indes zu kurz, da die Leistungsfähigkeit von Brücken in der Nutzungsphase und die mit Brückenbaumaßnahmen verbundenen Verkehrsbeeinträchtigungen eine wichtige Rolle spielen. Daher muss es ein Ziel sein, eine lebenszyklusorientierte Analyse und Bewertung in der Planungspraxis zu etablieren. Hierfür stellt der vorliegende Beitrag Grundlagen bereit, indem für die Nachhaltigkeitsanalyse von Brücken einzusetzende Methoden erläutert und in umfangreichen Vergleichsrechnungen angewendet werden. Die Ergebnisse sollen zuständige Behörden, Planern und Bauherren sowohl bei der Gestaltung von Nachhaltigkeitsbewertungssystemen unterstützen als auch Vergleichswerte für typische Autobahnüberführungen bereitstellen.
Die Ergebnisse der turnusmäßig alle fünf Jahre durchgeführten manuellen Straßenverkehrszählung (SVZ) werden als Tabellen mit differenzierten Kennwerten zur Verkehrsbelastung veröffentlicht. In der Verkehrsmengenkarte erfolgt durch die proportionale Darstellung der durchschnittlichen täglichen Verkehrsstärke (DTV) auf den Hauptverkehrsstraßen visuell ein flächenhafter Raumbezug. Für Autobahnen werden die ermittelten Verkehrsstärken anhand der Entwicklung an den automatischen Dauerzählstellen jährlich fortgeschrieben. Für eine derartige Fortschreibung im nachgeordneten Straßennetz war die Datengrundlage bisher nicht ausreichend. Durch die Fortführung der bei der SVZ 2015 erstmals zugelassenen Kfz-Erhebung mit Seitenradargeräten kann diese Lücke zukünftig geschlossen werden. Ziel ist u. a. die Ableitung regionsbezogener Indikatoren zur Verkehrsentwicklung.