81 Unfallstatistik
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This study that was funded by the Research Association for Automotive Technology (FAT) develops a method for the evaluation of the placement of tanks or batteries by using the deformation frequencies in real-world accidents. Therefore, the deformations of more than 20.000 passenger cars in the GIDAS database are analysed. For each vehicle a contour of deformation is calculated and the deformed areas of the vehicles are transferred in a rangy matrix of deformation. Thereby, the vehicle is divided into more than 190.000 cells. Afterwards, all single matrices of deformation are summarized for each cell which allows representative analyses of the deformation frequencies of accidents with passenger cars in Germany. On the basis of these deformation frequencies it is possible to determine least deformed areas of all passenger cars. Furthermore, intended placements of tanks or batteries can be estimated in an early stage of development. Therefore, all vehicles with deformations in the intended tank areas can be analysed individually. Considering numerous parameters out of the GIDAS database (e.g. collision speed, kind of accident, overlap, collision partner etc.) the occurring forces can be calculated or the deformation frequency can be estimated. Furthermore, it is possible to consider the influence of primary and secondary safety systems on the deformation behaviour. The analysis of "worst case accident events" is an additional application of the calculated matrix of deformation frequency.
Novice drivers are at high risk for crash involvement. We performed an analysis of causations, injury patterns and distributions of novice drivers in cars and on motorcycles in road traffic as a basis for proper measurements. Method Data of accident and hospital records of novice drivers (licence < 2 years) were analysed focusing the following parameters: injury type, localisation and mechanism, Abbreviated Injury Scale (AIS), maximum AIS (MAIS), delta-v, collision speed and other technical parameters and have been compared to those of experienced drivers. In 18352 accidents in the area of Hannover (years1985"2004), 2602 novice drivers and 18214 experienced drivers were recorded having an accident. Novice car drivers were more often and severe injured than experienced and on motorcycles the experienced riders were at higher risk. Novice drivers of both groups sustained more often extremity injuries. 4.5 % novice car drivers were not restraint compared to 3.7 % of the experienced drivers and 6.1 % novice motorcycle drivers did not wear a proper helmet (versus 6.5 %). Severe injuries sustained at a rate of 20 % at collision speeds below 30 km/h and in 80% at collision speeds above 50 km/h. Novice car drivers drove significant older cars. The risk profile of novice drivers is similar to those of drivers older than 65 years. Structural protection and special lectures like skidding courses could be proper remedial action next to harder punishment of violations.
The accident research project in Dresden was founded in July 1999. To date over 6.000 crash investigations have been undertaken. About 10.000 vehicles have been documented and over 13.000 participants have been debriefed. But there is much more than this scientific success. Because of the interdisciplinary character between the medical and technical focus, the project affords an important contribution for the education of the involved students. Over 200 students of different fields of study have got experiences not only for the occupational career. This lecture describes the additional effects of the accident research project regarding the education of the students, the capacity for teamwork and learning about dealing with accident casualties.
Over the last decades the number of traffic accident fatalities on German roads decreased by 77% down to 4968 in the year 2007. This positive development is due to optimisations of vehicle safety, roads and infrastructure and medical rescue issues. Up to now mostly the optimisations of secondary safety measures lead to this effect on vehicle safety. Since some years more and more driver assistance systems are available and lead to a further reduction of all accidents. These new systems are often comfort systems and have not primarily been developed to increase vehicle safety. In contrast to secondary safety systems primary safety systems are able to mitigate and avoid accidents. So in the future it is important to estimate the benefit of these systems in reducing accident numbers as well. Current benefit estimation methods mostly focus on a single system only and not on the combination of systems. In this paper a new method for a multivariate benefit estimation based on real accident data is developed. The paper describes the basic method to estimate the benefit of primary and secondary safety systems in combination. With the presented method the benefit will not be overestimated as it would be by a simple addition of the benefits of single systems. The model will be validated by a multivariate prospective benefit estimation of different vehicle safety systems in comparison to single benefit estimations of the same systems. For this the German In-Depth Accident Database is used. The results show the importance to implement the interactions of safety systems in the estimation process and rate the overestimation by a simple addition of the single system benefits. The validation includes primary and secondary safety systems in combination. The validation is done using more than 3500 real accidents which were initiated by cars. This sample out of the GIDAS database is representative for the current accident situation in Germany. The paper shows the necessity of a multivariate estimation of the benefit for existing and future safety systems.
This study analyses no.39 cases in which n.41 motorcyclists were fatally injured, or 36% of total motorcycle fatalities in Northern Ireland between 2004 and 2010 (n.114). There were n.17 cases (43.6%) where the actions of another vehicle driver caused the collision, in thirteen of these cases the motorcycles had their lights switched on. The remaining n.22 collisions (56.4%) were due to the actions of the motorcyclist. In the approach to the collision scene, there were n.13 cases (31.7%) in which the approach was a right hand bend and in n.8 (19.5%) cases, the approach was a left hand bend. In the remaining n.18 (43.9%) cases, the approach was a straight road. Of the n.17 (41.4%) motorcycles that slid after falling, n.10 (24.4%) fell onto their right side and the remaining n.7 (17.1%) fell onto their left side. The information from this study identifies primary and contributory causes of motorcycle collisions.
Empirical vehicle crashworthiness studies are usually based on national or in-depth traffic accident surveys: Data on accident-involved cars/drivers are analysed in order to quantify the chance of driver injury and to assess certain risk factors like car make and model. As the cars/drivers involved in the same accident form a "cluster", where the size of the cluster equals the number of accident-involved parties, traffic accident survey data are typical multi-level data with accidents as first-level or primary and cars/drivers as secondlevel or secondary units (car occupants in general are to be considered as third level units). Consequently, appropriate statistical multi-level models are to be used for driver injury risk estimation purposes as these models properly account for the cluster structure of traffic accident survey data. In recent years various types of regression models for clustered data have been developed in the statistical sciences. This paper presents multi-level statistical models, which are generally applicable for vehicle crashworthiness assessment in the sense that data on single and multiple car crashes can be analysed simultaneously. As a special case of multi-level modelling driver injury risk estimation based on paired-by-collision car/driver data is considered. It is demonstrated that assessment results may be seriously biased, if the cluster structure inherent in traffic accident survey data is erroneously ignored in the data analysis stage.
Crash involvement studies using routine accident and exposure data : a case for case-control designs
(2009)
Fortunately, accident involvement is a rare event: the chance of an individual road user trip to end up in a crash is close to zero. Thus, according to general epidemiological principles one can expect the case-control study design to be especially suitable for quantifying the relative risk (odds ratio) of accident involvement of road users with a certain risk factor as compared to road users that do not have this characteristic. Ideally, of course, the database for such a case-control study should be established by drawing two independent random samples of cases (accidental units) and controls (nonaccidental units), respectively. If, however, special data collection is not an option, it is nevertheless possible to analyze routine accident and exposure data under a case-control design in order to fully exploit the information contained in already existing databases. As a prerequisite, accident and exposure data from different sources are to be combined in a single file of micro or grouped data in a way consistent with the case-control study design. Among other things, the proposed methodological approach offers the possibility to use in-depth data of the GIDAS type also in investigations of active vehicle safety by combining this data with appropriate vehicle trip data collected in mobility surveys.
Data concerning accidents involving personal injury which have been collected in the context of in-depth investigations on scene in the Hannover area since 1973 and in the Dresden area since 1999 represent an important basis for empirical traffic safety research. At national and international level various analyses and comparisons are carried out on the basis of "in-depth data" from the above mentioned investigations. In-depth data play a decisive role e.g. within the validation of EuroNCAP results on secondary safety (crashworthiness) of individual passenger car models. Thus, statistically sound methods of data analysis and population parameter estimation are of high importance. Since the 1st of August 1984 the "in-depth investigations on scene" in the Hannover area have been carried out according to a sampling plan developed by HAUTZINGER in the context of a research project on behalf of BASt. In the meantime a second region of in-depth investigation on scene was added with surveys in Dresden and the surrounding area. Internationally, the acronym GIDAS (German In-Depth Accident Study) is commonly used for the two above mentioned surveys. The objective of a current research project (topic of this contribution) is, among other things, to examine and adjust the previous weighting and expansion method for the two regional accident investigations to the current general conditions.
Ziel dieses Forschungsvorhabens war es, das bisherige Gewichtungs- und Hochrechnungsverfahren für die örtlichen Unfallerhebungen in den Regionen Hannover und Dresden zu überprüfen und an die aktuellen Rahmenbedingungen anzupassen. Darüber hinaus sollten neue Möglichkeiten der gemeinsamen Hochrechnung von Ergebnissen aus beiden Erhebungsgebieten unter Berücksichtigung der aktuellen Datenlage, insbesondere in der amtlichen Unfallstatistik, untersucht und entsprechende statistische Verfahren entwickelt werden. Der Stichprobenplan der Erhebungen folgt einem zweistufigen Stichprobenverfahren. Tests mit einem zweistufigen Hochrechnungsverfahren der Hannover-Stichproben 2000 und 2001 auf die Gesamtheit Hannover haben jedoch ergeben, dass die theoretisch zu erwartenden Vorteile dieser zweistufigen Methode im Vergleich zur "einfachen Gewichtung" in der Praxis relativ gering sind. Unter Beibehaltung der bisherigen Gewichtungsprozedur (Anpassung an eine n-dimensionale Kontingenztabelle) wurden daher für die regionalen Hochrechnungen Dresden und Hannover alternative Methoden entwickelt, in der z.B. das Merkmal Ortslage durch die Unfallart ersetzt oder zusätzlich die Anzahl Unfallbeteiligter zur Gewichtung herangezogen wird. Leider erbringen diese Verfahren im Vergleich zur bisherigen (simultanen) Gewichtung nach Unfallschwere, Tageszeit und Ortslage nur wenige oder gar keine Verbesserungen der Anpassungsgenauigkeit bei Merkmalen der amtlichen Statistik, die nicht in die Gewichtung eingehen. Unabhängig vom Gewichtungsverfahren lässt die Abbildungsgenauigkeit bei einzelnen Variablen sehr zu wünschen übrig. Auf der Basis der Stichprobendaten 2000 wurde ferner noch ein Gewichtungsverfahren für Hochrechnungen auf das Bundesgebiet entwickelt und anhand der beiden Einzelstichproben sowie der gepoolten Stichprobe (Dresden plus Hannover) getestet. Die gepoolten Stichprobe zeigte die besten Ergebnisse. Allerdings ließen sich auch auf der Grundlage der gepoolten Daten nicht bei allen Merkmalen (gemeint sind hier Merkmale, die nicht Gewichtungsmerkmale sind) Verbesserungen des Fits erzielen. Es bleiben relativ große Abweichungen zwischen der gewichteten gepoolten Stichprobe und den bundesdeutschen Verteilungen. Es ist zu erwarten, dass auch bei vielen GIDAS Merkmale durch die Gewichtung keine essentielle Korrektur der Stichprobenverzerrungen erzielt werden kann. Insgesamt hat sich gezeigt, dass es auch mit alternativen, meist hierarchischen Gewichtungsverfahren nicht möglich ist, alle Merkmale, deren Verteilungen aus der amtlichen Statistik bekannt sind, mit hinreichender Genauigkeit an die Verhältnisse der Grundgesamtheit anzupassen. Es ist zu erwarten, dass sich dies bei den eigentlich hochzurechnenden originären GIDAS-Variablen ähnlich darstellt. Somit muss der Ansatz eines einheitlichen Verfahrens für alle Jahre und beide Erhebungsgebiete in Frage gestellt werden. Für besonders wichtige Fragestellungen sollte daher eine spezielle, auf das jeweilige Untersuchungsmerkmal abgestellte Gewichtung durchgeführt werden, wie dies exemplarisch am Beispiel der maximalen Kollisionsgeschwindigkeit gezeigt wurde. Schließlich werden im Bericht noch Empfehlungen zur Datenqualität und zu der Frage gegeben, wie sich das derzeit praktizierte Stichprobenverfahren im Hinblick auf die Gewinnung einer repräsentativen Stichprobe möglicherweise verbessern lässt.
Die Verkehrssicherheit sowohl innerhalb als auch außerhalb von Ortschaften konnte in den zurückliegenden Jahren deutlich erhöht werden. Dabei ging die Anzahl der auf Landstraßen Getöteten am stärksten zurück, jedoch ereigneten sich hier immer noch ungefähr 60% aller tödlichen Verkehrsunfälle. Im benachbarten Ausland werden zunehmend schmale schwach belastete Landstraßen so markiert, dass der Verkehr ohne Begegnungsfall in der Mitte der Fahrbahn fließt. Im Begegnungsfall ist das Überfahren der seitlichen Markierung erforderlich. Diese Querschnittgestaltung ist gemäß dem Entwurf der Richtlinien für die Anlage von Landstraßen (RAL) auch in Deutschland für Straßen mit einer sehr geringen Verkehrsbedeutung vorgesehen. Im Rahmen dieser Arbeit wird das Unfallgeschehen auf Landstraßen mit Fahrbahnbreiten bis 6,00 m untersucht. Ziel der Untersuchung ist es, das Unfallgeschehen auf schmalen Landstraßenquerschnitten zu beschreiben und zu prüfen, welchen Beitrag die neue Querschnittgestaltung zur Verbesserung der Verkehrssicherheit auf schmalen Landstraßen leisten kann