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In most of developed countries, the progress made in passive safety during the last three decades allowed to drastically reduce the number of killed and severely injured especially for occupants of passenger cars. This reduction is mainly observed for frontal impacts for which the AIS3+ injuries has been reduced about 52% for drivers and 38% for front passengers. The stiffening of the cars' structure coupled with the generalization of airbags and the improvement of the seatbelt restraint (load limiter, pretension, etc.) allowed to protect vital body regions such as head, neck and thorax. However, the abdomen did not take advantage with so much success of this progress. The objective of this study is to draw up an inventory on the abdominal injuries of the belted car occupants involved in frontal impact, to present adapted counter-measures and to assess their potential effectiveness. In the first part the stakes corresponding to the abdominal injuries will be defined according to types of impact, seat location, occupants' age and type of injured organs. Then, we shall focus on the abdominal injury risk curves for adults involved in frontal impact and on the comparisons of the average risks according to the seat location. In the second part we will list counter-measures and we shall calculate their effectiveness. The method of case control will be used in order to estimate odds ratio, comparing two samples, given by occupants having or not having the studied safety system. For this study, two type of data sources are used: national road injured accident census and retrospective in-depth accident data collection. Abdominal injuries are mainly observed in frontal impact (52%). Fatal or severe abdominal occupant- injuries are observed at least in 27% of cases, ranking this body region as the most injured just after the thorax (51%). In spite of a twice lower occupation rate in the back seats compared to the front seats, the number of persons sustaining abdominal injuries at the rear place is higher than in the front place. In recent cars, the risk of having a serious or fatal abdominal injury in a frontal impact is 1.6% for the driver, 3.6% for the front passenger and 6.3% for the rear occupants. The most frequently hurt organs are the small intestine (17%), the spleen (16%) and the liver (13%). The most common countermeasures have a good efficiency in the reduction of the abdominal injuries for the adults: the stiffness of the structure of the seats allows decreasing the abdominal injury risk from 54% (driver) to 60% (front occupant), the seatbelt pretensioners decrease also this risk from 90% (driver) to 83% (front passenger).
This work aims at bringing evidence for mass incompatibility in frontal impact for cars built according to the UNECE R94 regulation. French national injury accidents database census for years 2005 to 2008 were used for the analysis. The heterogeneity of frontal self-protection among cars of different masses is investigated, as well as the partner protection parameter offered by these cars. The last part of the analysis deals with the estimation of the benefit, in terms of fatal and severe injuries avoided, if crashworthiness was harmonized for the whole fleet of vehicle. This calculation is done for France and is extended to all Europe.
Rollover scenarios in Europe
(2005)
Rollover accidents seem to be a rising problem in Europe and therefore the systematic of this accident scenario should be investigated. Based on statistical investigations on major European accident databases for different countries a series of 73 real world rollover accidents was analysed. These cases were reconstructed using PC-Crash and preliminary categorised using a modified USbased rollover classification. In a first step, the rollover events were reconstructed from the point of conflict to the vehicle- rest position. The vehicles kinematics as well as its linear and rotational velocities were derived. In a second step typical velocity characteristics as well as kinematics were identified and the events categorised according to these criteria. Based on these results four main categories were defined, covering all reconstructed accidents. This categorisation was based on mechanical parameters (rotatory and translator kinematical data of the vehicle). Significant differences can be seen for different scenarios for the "first phase of rollover".
The presentation deals with the simulation tool rateEFFECT which intends to answer the following questions: Which active safety systems should be developed to maximize safety benefit in real traffic accidents? What is the effectiveness of a specific active safety system in the real world? How many casualties could be avoided by such a system? It is shown that a lot of information is required to simulate existing accidents in order to estimate ADAS effects. This particularly includes numerical values for the pre-crash and in-crash phase. The database GIDAS provides a required minimum number of these parameters for a statistically significant sample.
Qualität von on-trip Verkehrsinformationen im Straßenverkehr : BASt-Kolloquium 23. und 24.03.2011
(2011)
Am 23. und 24. März 2011 veranstaltete die Bundesanstalt fuer Straßenwesen ein, um die Ergebnisse der erwähnten Projekte und Initiativen präsentieren zu lassen und mit anderen Experten zu diskutieren. Der vorliegende Tagungsband fasst die Ergebnisse des Kolloquiums zur "Qualität von on-trip Verkehrsinformationen" zusammen. Die Bereitstellung von Verkehrsinformationen ist geprägt von vielen Akteuren. Die Wertschöpfungskette beginnt bei der Sammlung grundlegender Verkehrsdaten zur Erstellung von Verkehrsinformationen und setzt sich mit der Datenverarbeitung und -interpretation bis hin zur Meldungserstellung fort. Die Weitergabe kann über verschiedene Übertragungsmedien erfolgen und beim Nutzer (z.B. im Navigationsgerät) empfangen werden. Jeder einzelne Schritt der Wertschoepfungskette kann sowohl von unterschiedlichen Partnern (privat oder öffentlich) übernommen werden als auch in der Hand eines Partners liegen. Diese Komplexität der Zusammenarbeit spiegelt sich demzufolge auch in Qualitätsmanagementprozessen wider. Im Rahmen des Kolloquiums wurden zwei wesentliche Qualitätsaspekte näher betrachtet: - die Datenqualität mit dem Focus auf Aktualitaet, Stimmigkeit der Daten verglichen mit einer gemessenen Realitaet sowohl zu Beginn der Wertschöpfungskette als auch an jeglichen Schnittstellen, - die Prozessqualität, welche sich insbesondere mit der reibungslosen Datenübergabe an den Schnittstellen der Wertschoepfungskette beschäftigt. Beide Qualitätsaspekte helfen zu verstehen, worin die heutigen Qualitätsprobleme bestehen und welche Massnahmen im Einzelnen ergriffen werden müssten, um eine nachhaltige Verbesserung zu erreichen. Einerseits kann es vorkommen, dass die Information über ein Verkehrsereignis an einer oder mehreren Stellen der Wertschöpfungskette korrekt vorliegt, jedoch durch ungenuegende technische oder organisatorische Schnittstellen im Prozessablauf wieder verloren geht und dem Nutzer folglich nicht zur Verfügung steht. Prominentes Beispiel eines solchen Problems in der Prozessqualität ist die fehlerhafte Interpretation der Meldung im Navigationsgerät, denkbar sind solche Informationsverluste jedoch an jeder Stelle der Wertschoepfungskette. Eine wichtige Massnahme zur Verbesserung der Prozessqualität ist die Standardisierung sowie die Überprüfung, ob die definierten Standards an jeder Stelle der Wertschöpfungskette eingehalten werden. Andererseits kann es vorkommen, dass die Datenqualität in Bezug auf ihre Genauigkeit von Anfang an so schlecht ist, dass der Nutzer eine fehlerhafte oder gar keine Nachricht übermittelt bekommt. Beispiel hierfür ist die Vielzahl von Stauereignissen, die entweder nicht gesendet wurden oder gesendet wurden, obwohl sie nicht vorhanden waren. Eine wichtige Massnahme zur Verbesserung dieser Situation ist die Verbesserung der Ereignisdetektion. Der Tagungsband enthaelt Präsentationen, die den Status Quo analysieren, Methoden zur verbesserten Datenerfassung vorschlagen und Möglichkeiten zur Verbesserung von Daten- und Prozessqualität vorstellen. Offen geblieben sind darüber hinaus folgende Fragestellungen: - Wie kann die Prozessqualität der gesamten Wertschöpfungskette bei der Vielzahl der Partner kontrolliert werden? Wer überwacht die Wertschöpfungskette? Wird hierfuer überhaupt eine zentrale Stelle benötigt? Oder ist es ausreichend, wenn jeder Partner eine angemessene Eingangs bzw. Ausgangskontrolle durchführt? - Obwohl es nur eine Realität gibt, entsteht doch Wettbewerb über die (Qualität der) Information zu dieser Realität. Wie kann Konsistenz zwischen allen Anbietern von sicherheitsrelevanten Informationen erreicht werden? Wo sollte der Wettbewerb enden und wie kann dies technisch, organisatorisch und wirtschaftlich realisiert werden? - Welche Prozesse sollten geschaffen werden, um Partner zu integrieren, die sich nicht an geschaffene Qualitätsstandards halten (z.B. kommerzielle Diensteanbieter, die nicht mit der Verkehrsinformationsszene vernetzt sind)? - Und nicht zuletzt, wie kann die Wahrnehmung des Nutzers über verschiedene Qualitätslevel unterschiedlicher Produkte verbessert werden? Ist der Nutzer in der Lage, die unterschiedlichen Qualitätsstufen von Verkehrssystemen zu unterscheiden? Falls nicht, welche Art von Unterstuetzung braucht der Kunde? Ein "European Information Services Assessment Programme" vergleichbar zu Euro NCAP für Fahrzeuge? Die Ergebnisse des Kolloquiums sollen die laufende Diskussion um die Verbesserung der Qualität von Verkehrsinformationen unterstützen.
An analysis of NASS and FARS was conducted to determine crash conditions that involved injuries that are not currently being directly addressed by vehicle safety standards or by consumer information test protocols. Analysis of both field data and US NCAP tests were conducted to determine the relative safety provided by seating position and by vehicle model year. Opportunities for improvements were determined by crash categories with large populations of injuries that were not addressed by safety tests or smaller numbers that were increasing in frequency. Areas of opportunities include improved occupant restrain in rollovers, improved frontal protection for rear seat occupants and improved fire prevention in frontal and rollover crashes.
This paper set out to examine the possibilities for injury avoidance implications for older drivers in crashes, based on crash and injury patterns among older drivers and current trends in ageing in most western societies. A number of safety technologies were identified and discussed which have potential for improving vehicle older driver crash avoidance and crashworthiness. While there were some promising estimates available of the likely benefits of this technology for improving safety, it is evident that they need to be confirmed for older drivers, given their age-related disabilities and sensory limitations. Further research is urgently required to ensure that these technologies yield safety benefits without any disbenefits for older drivers.rn
From an automotive safety occupant protection standpoint, effective occupant restraint requires a system capable of providing non-injurious occupant ride down of anticipated crash forces. This is not only the case for frontal collisions, where occupant restraint is provided primarily by seatbelts and airbags, but is also critical for other crash modes such as side impacts, rear impacts, rollovers, as well as multiple impact events. In the rear impact crash mode, occupant restraint is provided primarily by the seatbacks and to some extent the seatbelts. Foundationally, therefore, what becomes fundamental to the seatback's role in rear occupant protection is its ability to contain the occupant within the seat, preventing occupant ramping, as well as preventing the seat's, and/or its occupant's, dangerous intrusion into the rear occupant's survival space where contact with rear compartment components and/ or rear seated occupants can present a significant injury risk. An analysis is presented of a series of rear impact sled testing conducted by the authors that evaluates the timing, position and extent of the front seatback's reward displacement toward and into the rear occupant compartment as well as consideration of the front seat occupant' ramping potential and its injury potential relative to the rear compartment. Additionally, three other series of testing are presented which assess various seat designs occupant retention capabilities. Lastly, a matched-pair comparison test series is presented which evaluates occupant motion in rear impact with and without use of a typical vehicle body mounted 3-point seatbelt. Discussion of restraint system performance observed in all the testing is included along with ATD biofidelity and thigh-gap considerations. The data collected and presented includes accelerometer instrumentation and high speed video analysis.
Motorcycle safety research
(2007)
Honda- global motorcycle sales exceeded the 10 million units mark since 2004, and further expansion is expected. As a responsibility for a company to provide mobility, Honda is focusing on motorcycle safety as top priority and has been working on various activities for both aspects of hardware and software. Here, we present Honda- activity for the safety technology of motorcycles. At present, Honda is promoting motorcycle safety in the four themes of prevention and collision safety such as safety education, recognition assistance, accident prevention and injury reduction. First, in the area of the safety education, the "Honda Safety Driving Promotion Center" was established in 1970, and motorcycle riders and vehicle driver trainings have been organized, and the traffic training centers are used as an actual practice field not only in Japan but also in many other regions in the world. Through our training activities, the new area of safety training with hardware assistance was developed and Honda- unique technology was accumulated such as the riding simulator which can provide experience of potentially dangerous situations without risk. Especially, the "riding trainer", the popular version of the riding simulator, was introduced at several motor shows in various countries and launched in September 2005. It was distributed first in Europe and is expected to expand globally aiming at 3000 units worldwide.. And in Europe, the newest version, which includes the suburban roads program, jointly developed with ADAC, will be released in near future. In the area of recognition assistance, "vehicle to vehicle communication technology" is under development using the advantage of being a manufacturer of both motorcycles and cars. This technology is under research as Honda "ASV-3" in Japan, and as part of C2C activity in Europe. As for the accident prevention, advanced brake systems for motorcycles to assist more effective brake operation have been expanded, Honda signed the European Road Safety Charter in April 2004 with the advanced brake systems commitment and furthermore, they are expanding according to vehicle characteristics and region. Then all models above 250 cc will have a version of the system by 2010. And as the last theme, "motorcycle airbag system" is introduced which is equipped on a mass production motorcycle for the first time in the world. It has been researched and developed for a long time as an injury reduction technology for collision accidents. Honda automobile technology was used for the research and development of the motorcycle airbag, and many specific issues such as the analysis of the collision conditions particular to motorcycles have been solved to realize today- success. It might be known that ADAC in-house crash test held in August this year confirmed the high effectiveness of the airbag system and showed a positive result. This motorcycle airbag system is equipped to the Honda Gold Wing and launched in North America in August, 2006. Also in Europe, it will be sold by the end of this year. Each theme of Honda motorcycle safety technology can be seen at the Honda booth.
Mit dem Seminar SILENCE wurde ein Forschungsprojekt abgeschlossen, das aus zehn Unterprojekten bestand, und an dem 46 internationale Partner beteiligt waren. Ziel des Projektes war es, die Belästigung durch Verkehrslärm in Ballungsräumen zu reduzieren. Das Projekt wurde in den Jahren 2005 bis 2008 mit insgesamt rund 9 Millionen Euro durch die Europäische Union gefördert. Auf dem SILENCE-Seminar im Mai 2008 in den Räumen der Bundesanstalt für Straßenwesen wurden die aktuellen Forschungsergebnisse von Vertretern der verschiedenen beteiligten Disziplinen präsentiert und diskutiert mit dem Ziel, die gefundenen Problemlösungen an die Anwender zu übermitteln