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Im Jahr 2005 hat sich der positive Trend in der Entwicklung des Unfallgeschehens im Straßenverkehr in Deutschland fortgesetzt. Nach Schätzungen der Bundesanstalt für Straßenwesen wird die Zahl der im Straßenverkehr Getöteten um mehr als 7% niedriger ausfallen als 2004. Die Gesamtzahl aller polizeilich erfassten Straßenverkehrsunfälle wird leicht auf ca. 2,24 Mio Unfälle sinken (Vorjahreswert: (2,26 Mio.). Bei der Zahl der Unfälle mit Personenschaden wird im Vergleich zu 2004 (339.310 Unfälle) ein Rückgang um etwa 1% auf weniger als 337.000 erwartet. Die Zahl der bei diesen Unfällen verunglückten (verletzten und getöteten) Personen wird dabei um knapp 2% abnehmen und im Jahr 2005 bei etwa 438.000 liegen. Die Anzahl der Getöteten im Straßenverkehr wird insgesamt um mehr als 7% auf knapp 5.400 sinken (Vorjahreswert: 5.842). Während innerorts der Rückgang mit nur 1% auf unter 1.480 Getötete gering ausfällt, ist auf Bundesautobahnen mit einem Rückgang der Getötetenzahl von fast 5% auf weniger als 670 Getötete zu rechnen. Die Anzahl der Getöteten außerorts (ohne BAB) wird sich mit einem Rückgang von fast 10% im Vergleich der Ortslagen am deutlichsten verringern und von 3.664 Getöteten im Jahre 2004 auf etwa 3.350 im Jahre 2005 sinken. Die Veränderungen in den verschiedenen Verkehrsbeteiligungsarten unterscheiden sich ebenfalls deutlich. Die Gesamtzahl der getöteten Kraftfahrzeuginsassen (2004: 3.521) wird im Jahr 2005 um etwa 10% auf weniger als 3.200 Getötete deutlich sinken. Die Anzahl der getöteten Fahrer und Mitfahrer von Motorrädern (einschließlich Leichtkrafträder) sinkt gleichzeitig um etwa 2% auf annähernd 840 Getötete (2004: 858). Bei den Moped/Mofa-Fahrern (2004: 122 Getötete) ist nach dem deutlichen Rückgang der Zahl der Getöteten von 9% im Vorjahr in diesem Jahr keine Verbesserung zu erwarten. Die Anzahl der getöteten Moped/Mofa-Fahrer wird voraussichtlich bei etwa 120 Getöteten stagnieren. Bei den Radfahrern steht dem sehr deutlichen Rückgang im letzten Jahr (mit 22,9% von 616 auf 475 Getötete) in diesem Jahr ein Anstieg auf etwa 540 Getötete gegenüber. Bei der Anzahl getöteter Fußgänger ist dagegen ein Rückgang absehbar - um mehr als 10% auf weniger als 750 (2004: 838). Bei den jungen Verkehrsteilnehmern im Alter von 18 bis 24 Jahren ist mit einem Rückgang um fast 10% auf ungefähr 1.150 Getötete im Jahr 2005 (2004: 1.269) zu rechnen. Bei den Kindern bis unter 15 Jahren (2004: 153 Getötete) wird nach dem starken Rückgang im Jahr 2004 (26,4%) seit fünf Jahren erstmals wieder ein Anstieg zu verzeichnen sein " um etwa 20 getötete Kinder auf ungefähr 170 Getötete. Bei den Senioren (2004: 1.201 Getötete) ist für das Jahr 2005 im Vergleich zum Vorjahr (Rückgang um 9,6%) ein sehr geringer Rückgang auf etwas weniger als 1.200 Getötete zu erwarten. Der rückläufige Trend hält bei den Alkoholunfällen auch im Jahr 2005 an. Gegenüber dem Vorjahr sinkt die Zahl der alkoholbedingten Unfälle mit Personenschaden um etwa 350 (mehr als 1%) auf knapp 22.200 (2004: 22.548). Für die Fahrleistungen der Kraftfahrzeuge werden im Jahr 2005 kaum Veränderungen erwartet. Nach vorläufigen Schätzungen wird die Gesamtfahrleistung mit einer Veränderung von 697,1 Mrd. Fz-km im Jahr 2004 auf etwa 699 Mrd. Fz-km im Jahre 2005 nahezu stagnieren. Unter Berücksichtigung dieser Entwicklung wird sich die Getötetenrate im Jahr 2005 insgesamt um fast 8% verringern.
This study is aimed to investigate the correlations of impact conditions and dynamic responses with the injuries and injury severity of child pedestrians by accident reconstruction. For this purpose, the pedestrian accident cases were selected from Sweden and Germany with detailed information about injuries, accident cars, and accident environment. The selected accident cases were reconstructed using mathematical models of pedestrian and passenger car. The pedestrian models were generated based on the height, weight, and age of the pedestrian involved in accidents. The car models were built up based on the corresponding accident car. The impact speeds in simulations were defined based on the reported data. The calculated physical quantities were analyzed to find the correlation with injury outcomes registered in the accident database. The reconstruction approaches are discussed in terms of data collection, estimating vehicle impact speeds, pedestrian moving speeds and initial posture, secondary ground impact, validity of the mathematical models, as well as impact biomechanics.
The so-called "seat-belt injuries" or "seat-belt syndromes", described as 2-point seat-belt injuries, contain heavy inflection injuries of the lumbal spinal column, combined with heavy abdominal injuries as rupture of the upper intestinal bold or heavy injuries of the upper entrails. With "playing" children in the font of the car, with inappropriate plant of 3-point belts, identical injuries can occur.
Nowadays airbags are part of the standard equipment in almost all new cars. While airbags are saving an increasing number of people from severe injuries and death in moderate and high speed crashes, they do not completely prevent dashboard injuries. The most common mechanism in dashboard injuries is a posteriorly directed force to the proximal tibia with the knee flexed. This may occur during a motor vehicle frontal impact accident when a knee of the driver or the front-seat passenger strikes the dashboard. The posterior force can be combined with a abducting or rotational force leading to concomitant lateral or posterolateral injury. Car and airbag manufacturers therefore develop special inflatable systems to reduce the impact force in dashboard injuries. Every new inflatable system, however, has to be evaluated in out of position situations in which the system might cause injuries to certain body areas. Therefore, we investigated a new kneebag system in different critical seating positions of post mortem test subjects (PMTS). The tested knee airbag module is a folded airbag (18 litre volume) which is installed below the lower section of the instrument panel of a passenger car. Using four PMTS (2 male, 2 female, age 36"67) the following positions were tested: normal seating position, knee flexed >90 degrees and knee flexed <60 degrees in static deployment tests with direct contact. In addition a dynamic test (48.8kph, AAMA-pulse) was carried out with the PMTS belted in a normal seating position. The inflation phase and the impact of the system on the knee/lower leg were analysed by high speed videos. After the test the lower legs of the PMTS were examined by Xray and autopsy. All soft tissue injuries and bone fractures were recorded. All the tests could be evaluated. Except some superficial skin lesions in the impact area no fracture of the bones around the knee and no knee ligament and tendon injuries were observed. Neither video analysis nor autopsy of the PMTS showed any critical contact injuries caused by the inflation process of the bag. Therefore, it can be concluded that in the tested seating positions which are the most critical for the knee area the knee bag system is safe.
Sedan type vehicles in which adult rear seat passengers were present and which were involved in frontal collisions were investigated, and the influence of unbelted rear seat passengers on the injuries of front seat occupants was studied. Unbelted rear seat passengers move forward during impact. It was observed that there were not only cases in which front seat occupants sustained injuries caused by direct contact with rear seat passengers, but also cases where front seat occupants received severe injuries due to additional force from rear seat passengers, either impacting directly or indirectly as a result of deformation of the front seat. Severe injuries of front seat occupants were observed in the latter cases. This research validates the importance of seat-belt use for rear seat passengers, not only to protect themselves but also to mitigate injuries of front seat occupants.
The improvement of passive car security devices led to a reduction of injuries, especially of the head, the neck and the torso mainly due to the airbag function. The passenger's foot and ankle could not profit from this development. Some investigators even reported a progression of leg injuries (1). In this study, we investigated a current collective of patients with foot and ankle fractures or severe soft tissue injuries in relation with defined crash parameters. Special interest was paid to the car's footwell.
The European Enhanced Vehicle-safety Committee (EEVC) Working Group 13 for Side Impact Protection has been developing an Interior Headform Test Procedure to complement the full-scale Side Impact Test Procedure for Europe and for the proposed IHRA test procedures. In real world accidents interior head contacts with severe head injuries still occur, which are not always observed in standard side impact tests with dummies. Thus a means is needed to encourage further progress in head protection. At the 2003 ESV-Conference EEVC Working Group 13 reported the results on Interior Headform Testing. Further research has been performed since and the test procedure has been improved. This paper gives an overview of its latest status. The paper presents new aspects which are included in the latest test procedure and the research work leading to these enhancements. One topic of improvement is the definition of the Free Motion Headform (FMH) impactor alignment procedure to provide guidelines to minimize excessive headform chin contact and to minimize potential variability. Research activities have also been carried out on the definition of reasonable approach head angles to avoid unrealistic test conditions. Further considerations have been given to the evaluation of head airbags, their potential benefits and a means of ensuring protection for occupants regardless of seating position and sitting height. The paper presents the research activities that have been made since the last ESV Conference in 2003 and the final proposal of the EEVC Headform Test Procedure.
Detailed investigations and reconstructions of real accidents involving vulnerable road users
(2005)
The aim of this research is to improve knowledge about vulnerable road users accidents and more specifically pedestrians or cyclists. This work has been based on a complete analysis of real accidents. From accidents chosen from an in-depth multidisciplinary investigation (psychology, technical, medical), we have tried to identify the configuration of the impact: car speed, pedestrian or cyclist orientations. Then, we have made a numerical modelling of the same configuration with a multibody software. In particular, we have reproduced the anthropometry of the victim and the front shape of the car. A first simulation has been performed on this starting configuration. Next, effects of some parameters such as car velocity or victim position at impact have been numerically studied in order to find the best correlations with all indications produced by the in-depth analysis. Finally, the retained configuration was close to the presumed real accident conditions because it reproduces in particular the same impact points on the car, the same injuries, and is according to the driver statement. This double approach associating an in-depth accident analysis and a numerical simulation has been applied on pedestrian-to-car and bicyclist-tocar accidents. It has allowed us to better understand the real kinematics of such impacts. Even if this method is based on a case to case study, it underlines which parameters are relevant on a vulnerable road user accident investigation and reconstruction.
The European Enhanced Vehicle-safety Committee wants to promote the use of more biofidelic child dummies and biomechanical based tolerance limits in regulatory and consumer testing. This study has investigated the feasibility and potential impact of Q-dummies and new injury criteria for child restraint system assessment in frontal impact. European accident statistics have been reviewed for all ECE-R44 CRS groups. For frontal impact, injury measures are recommended for the head, neck, chest and abdomen. Priority of body segment protection depends on the ECE-R44 group. The Q-dummy family is able to reflect these injuries, because of its biofidelity performance and measurement capabilities for these body segments. Currently, the Q0, Q1, Q1.5, Q3 and Q6 are available representing children of 0, 1, 1.5, 3 and 6 years old. These Q-dummies cover almost all dummy weight groups as defined in ECE-R44. Q10, representing a 10 year-old child, is under development. New child dummy injury criteria are under discussion in EEVC WG12. Therefore, the ECE-R44 criteria are assessed by comparing the existing P-dummies and new Q-dummies in ECE-R44 frontal impact sled tests. In total 300 tests covering 30 CRSs of almost all existing child seat categories are performed by 11 European organizations. From this benchmark study, it is concluded that the performance of the Q-dummy family is good with respect to repeatability of the measurement signals and the durability of the dummies. Applying ECE-R44 criteria, the first impression is that results for P- and Q-dummy are similar. For child seat evaluation the potential merits of the Q-dummy family lie in the extra measurement possibilities of these dummies and in the more biofidelic response.
In order to improve the protection of children transported in cars, within the CHILD programme (GR3D-CT2002-00791) real world road accidents are thoroughly analysed and then reconstructed in laboratory. Prior to comparing injury severities of real victims to physical parameter values measured on the dummies, the quality of the reconstructions is evaluated by experts who use their experience based on the investigation of numerous and various accidents. This paper presents a new tool aiming at better evaluating and validating accident reconstructions. It is based on statistical evaluation of vehicle deformations which gives weighing factors for every part of the car body structure finally leading to a specific Reconstruction Quality Score (RQS indicator). Furthermore, the reliability of this score, depending on the number of measured points, can be established. This tool includes a function aiming at adjusting the speed for a further reconstruction and at defining the launching speed and the pulse shape for complementary sled tests. Finally, the functions of the RQS software and database are presented.
Pelvic fracture, cracking or breaking of a portion of the pelvis are extremely common injuries in the side impact collisions of motor vehicles. Due to both its shape and structural architecture, mechanics of the pelvic bone is complicated. There is a lack of knowledge regarding the dynamic behavior of the pelvis and its biomechanical tolerance under impact environment. Hence this study is aimed at the understanding of the mechanical response of the human pelvis with three-dimensional finite element (FE) models, under side impact load, applied through a structure, equivalent to a car door. The door structure was modeled, considering few layers, consisting of foam (Styrodur®, 3035 CS), plastic (UHMWPE), steel, glass and steel, putting them in series. A soft tissue layer (equivalent to fat) was also considered on the greater trochanter location. These FE models (with and without the car door structure) were analyzed with ANSYS-LS-DYNA-® dynamic finite element software to compare the effect of the car door padding system for shock absorption. It was observed that with proper combination of shock absorbing material (foam, etc.) and its thickness, the transmission of impact load to the body part (pelvis, etc.) from the outer surface of the car door could be reduced.