Sonstige
Analysis of pedestrian leg contacts and distribution of contact points across the vehicle front
(2015)
Determining the risk to pedestrians that are impacted by areas of the front bumper not currently regulated in type-approval testing requires an understanding of the target population and the injury risk posed by the edges of the bumper. National statistics show that approximately 10% of all accident casualties are pedestrians, with 20% to 30% of these pedestrian casualties being killed or seriously injured. However, the contact position across the front of the bumper is not recorded in national statistics and so in-depth accident databases (OTS, UK and GIDAS, Germany) were used to examine injury risk in greater detail. The results showed that some injury types and severities of injuries appear to peak around the bumper edges. Although there are sometimes inconsistencies in the data, generally there is no evidence to suggest that the edges of the bumper are less likely to be contacted or cause injury.
Many safety-relevant tasks in control or diagnostics require binary choices such as "conflict versus separation" in air traffic control, "normal versus pathological" when interpreting x-ray pictures, or "permitted versus forbidden" when inspecting airport security scans. Deciders often are uncertain, but nevertheless required to decide between two alternatives, that is, they have not only to decide upon an action, but also about the admissible level of uncertainty. If the accepted level of judgment certainty is not taken into account, the sequence of decisions does not capture the full picture of the underlying decision process. Differences in judgment certainty are relevant, because they reflect not only the adequacy of the human-machine interface that is evaluated, but also the differences in expertise of the decider and the requirements of the actual situation or task. Therefore, capturing both judgment certainty and discrimination performance is essential. A comparison of different human-machine-interfaces (for air traffic control) is used to illustrate a methodological approach, which allows for integrated analyses of decision processes based on receiver-operator-characteristics and practical guidelines for the evaluation of human-machine-interfaces for safety-relevant operation procedures are provided.
Detailed anthropometric data of pregnant women have been collected and used in the development of a computational model of the pregnant occupant model "Expecting". The model is complete with a finite element uterus and multi-body fetus, which is a novel feature in the models of this kind. The computational pregnant occupant model has been validated and used to simulate a range of impacts. The strains developed in the utero-placental interface are used as the main criteria for fetus safety. Stress distributions due to inertial loading of the fetus on the utero-placental interface play a role on the strain levels. Inclusion of fetus model is shown to significantly affect the strain levels in the utero-placental interface. This series of studies has led to the design of seatbelt features specifically for the pregnant women to enable them use the seatbelt correctly and comfortably.
SEEKING is looking for answers regarding electric powered bicycles and their relation to traffic safety issues. Does a cyclist need "E"? Is it as risky as riding a moped or are E-bikes creating conflicts with other cyclists? The project described herein, funded by the Austrian Ministry of Transport, has the aim of seeking answers to these hot topics. The SEEKING-team shows an in-depth investigation of vehicle dynamic sensing, together with subjective feedback of test riders to detect similarities and differences between conventional cycling and E-biking. Following an overview on the international status quo, measurement runs and their analyses are performed to find a set of preventative measures to make (E-)biking safer. A specific focus is the detection of curve handling, stopping and acceleration phases as well as conflict studies on course-based test rides and "real world" tests on cycling paths (naturalistic riding).
Im von der DG Home (CIPS Program) geförderten Projekt "SecMan " Security Manual for Road Infrastructures" wurde ein vierstufiges Verfahren zur Identifikation kritischer Straßeninfrastrukturen, ihre Bewertung hinsichtlich diverser von Menschen verursachter Gefahren sowie die Bestimmung effektiver Schutzmaßnahmen entwickelt. Diese Ergebnisse wurden in einem ganzheitlichen "best-practice" Handbuch zusammen getragen, welches einen trans-nationalen Sicherheitsmanagement-Ansatz für Betreiber und Eigentümer von Straßeninfrastrukturen in Europa ermöglicht. Im Folgenden wird die entwickelte Methodik vorgestellt, ausgehend von der Bewertung der Netzkritikalität über die Attraktivität und Vulnerabilität eines Bauwerks hin zu einer Bewertungsmethodik für die Auswahl geeigneter Schutzmaßnahmen.
Um die Sicherheit der Straßentunnel zu gewährleisten, werden mehr als 400 m lange Tunnel ständig durch eine Tunnelleitzentrale überwacht. Die dort eingehende Flut von Einzelinformationen, wie Kamerabilder und zahlreiche Sensordaten, muss permanent durch das Personal erfasst und beurteilt werden. Das Projekt ESIMAS (Echtzeit-Sicherheits-Management-System für Straßentunnel) wird neue Wege aufzeigen, um die Leitstellenmitarbeiter zu unterstützen. Auf Grundlage der Datenanalyse und -bewertung von ESIMAS können zukünftig sicherheitsrelevante Ereignisse, wie ein Brand im Tunnel, zuverlässig und rechtzeitig erkannt werden. Im Ernstfall soll ESIMAS dem Leitzentralenpersonal sowie den Einsatz- und Rettungsdiensten Handlungsempfehlungen zur Ereignisbewältigung zur Verfügung stellen. Auf Basis dieser Handlungsempfehlungen können Maßnahmen schnellstmöglich und gezielt durchgeführt werden. Der innovative Ansatz von ESIMAS besteht in der ganzheitlichen Betrachtung aller Einzelinformationen und ihrer automatischen Auswertung und Bewertung. Hierdurch ist eine schnellere Reaktion der Leitstelle zum Schutz der Verkehrsteilnehmer möglich.
Radfahren - aber sicher!
(1989)
Bei der Veranstaltung, die am 16. und 17. November 1987 zu dem Thema "Radfahren - aber sicher!" in Wiesbaden stattfand, ging es darum, dem Sicherheitsbedürfnis des zunehmenden Radfahrverkehrs in der Bundesrepublik Deutschland gerecht zu werden, andererseits aber auch das nicht unproblematische Verhältnis zwischen der Radfahrerpopulation auf der einen und den übrigen Verkehrsteilnehmergruppen auf der anderen Seite auszuleuchten. In der jüngeren Vergangenheit wurden Klagen geäußert wie etwa die, dass sich die Radfahrer ihr eigenes Gesetz schafften. Von den Betroffenen wird dagegengehalten, dass die den Straßenverkehr betreffenden Gesetze und Verordnungen aus dem Blickwinkel des Kraftfahrers heraus gemacht worden seien und ein Verstoß dagegen für Radfahrer oft die naheliegendste Möglichkeit sei, einer Selbstgefährdung zu entgehen. Aus diesem Grunde wurde die Thematik in dem von der Deutschen Verkehrswacht gemeinsam mit der Bundesanstalt für Straßenwesen (BASt) und dem Bundesverkehrsministerium durchgeführten Symposium aus unterschiedlichster Sicht angesprochen. Vertreten war sowohl die Unfallforschung, die Straßenplanung, die Fahrzeugtechnik und die Polizei wie auch die Interessenvertreter der Rad- und der Autofahrer. Von vornherein war klar, dass ein Symposium dieser Art nicht dazu angetan sein konnte, "Patentlösungen" zu erarbeiten. Ziel der Veranstaltung war es vielmehr, das gegenseitige Verständnis der unterschiedlichen Verkehrsteilnehmergruppen füreinander zu wecken bzw. zu fördern. Dabei wurde deutlich, dass auch die Problematik des "Rollenwechsels" keineswegs frei von Schwierigkeiten ist: Das Verhalten des möglicherweise überwiegenden Teils der Verkehrsteilnehmer ist nicht so sehr an einem Grundwissen und ein Grundverhalten gebunden, als vielmehr von der Art der jeweiligen Verkehrsteilnahme abhängig.
This study aimed at prediction of long bone fractures and assessment of lower extremity injury mechanisms in real world passenger car to pedestrian collision. For this purpose, two pedestrian accident cases with detail recorded lower limb injuries were reconstructed via combining MBS (Multi-body system) and FE (Finite element) methods. The code of PC Crash was used to determine the boundary conditions before collision, and then MBS models were used to reproduce the pedestrian kinematics and injuries during crash. Furthermore, a validated lower limb FE model was chosen to conduct reconstruction of injuries and prediction of long bone fracture via physical parameters of von Mises stress and bending moment. The injury outcomes from simulations were compared with hospital recorded injury data and the same long bone fracture patterns and positions can be observed. Moreover, the calculated long bone fracture tolerance corresponded to the outcome from cadaver tests. The result shows that FE model is capable to reproduce the dynamic injury process and is an effective tool to predict the risk of long bone fractures.
Cycling supports the independence and health of the aging population. However, elderly cyclists have an increased injury risk. The majority of injured cyclists is victim of a single-sided accident, an accident in which there is no other party involved. The aim of the project "Safe and Aware on the bicycle" is to develop guidelines for an advisory system that is useful in preventing single-sided accidents. This system is able to support the elderly cyclist; enabling the cyclist to timely adapt his cycling behaviour and improve cycling safety and comfort. For the development of such advisory system the causes of singles accidents and the wishes of the elderly cyclist must be known. First step to obtain this insight was a literature survey and an GIDAS research. Unfortunately accidentology research with GIDAS did not give the full understanding of the pre-crash situations and (especially the behaviour related) factors leading to the accident. The second step was consultation of elderly cyclist through a questionnaire (n=800), in-depth interviews (n=12) and focus group sessions (n=15). This offered complementary information and a much better understanding of the behavioural aspects. Results concern the behaviour in traffic and identify specific physical (i.e. problems looking backwards over the shoulder) and mental issues. Furthermore, the needs and wishes for support in specific cycling situations were identified. In conclusion; The GIDAS results together with the information obtained contacting the elderly cyclists enabled setting up requirements for an advisory system, which is useful in preventing single-sided accidents.
Since a number of human models have been developed it appears sensible to use these models also in the accident analysis. Especially the understanding of injury mechanisms and probably even injury risk curves can be significantly improved when interesting accidents are reconstructed using human body models. However, an important limitation for utilising human models for accident reconstruction is the effort needed to develop detailed FE models of the accident partners or to prepare the human model reconstruction by running physical accident reconstructions. The proposed approach for using human models for accident reconstruction is to use simplified and parametric car models. These models can be adapted to the crash opponents in a fast and cost effective way. Although, accuracy is less compared to detailed FE models, the relevant change in velocity can be simulated well, indicating that the computation of a detailed crash pulse is not needed. Two frontal impact test accidents that were reconstructed experimentally and using the parametric car models are indicating sufficient correlation of the adapted parametric car models with the full scale crash reconstructions. However, further developments of the parametric models to be capable for the use in lateral impacts and rear impacts are needed. For the PC Crash simulation runs the output sampling rate is too large to allow sufficient analysis. In addition the performance appears to be too general.