Sonstige
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.
In the European Project FIMCAR, a proposal for a frontal impact test configuration was developed which included an additional full width deformable barrier (FWDB) test. Motivation for the deformable element was partly to measure structural forces as well as to produce a severe crash pulse different from that in the offset test. The objective of this study was to analyze the safety performance of vehicles in the full width rigid barrier test (FWRB) and in the full width deformable barrier test (FWDB). In total, 12 vehicles were crashed in both configurations. Comparison of these tests to real world accident data was used to identify the crash barrier most representative of real world crashes. For all vehicles, the airbag visible times were later in the FWDB configuration. This was attributed to the attenuation of the initial acceleration peak, observed in FWRB tests, by the addition of the deformable element. These findings were in alignment with airbag triggering times seen in real world crash data. Also, the dummy loadings were slightly worse in FWDB compared to FWRB tests, which is possibly linked to the airbag firing and a more realistic loading of the vehicle crash structures in the FWDB configuration. Evaluations of the lower extremities have shown a general increasing of the tibia index with the crash pulse severity.
The goal of the project FIMCAR (Frontal Impact and Compatibility Assessment Research) was to define an integrated set of test procedures and associated metrics to assess a vehicle's frontal impact protection, which includes self- and partner-protection. For the development of the set, two different full-width tests (full-width deformable barrier [FWDB] test, full-width rigid barrier test) and three different offset tests (offset deformable barrier [ODB] test, progressive deformable barrier [PDB] test, moveable deformable barrier with the PDB barrier face [MPDB] test) have been investigated. Different compatibility assessment procedures were analysed and metrics for assessing structural interaction (structural alignment, vertical and horizontal load spreading) as well as several promising metrics for the PDB/MPDB barrier were developed. The final assessment approach consists of a combination of the most suitable full-width and offset tests. For the full-width test (FWDB), a metric was developed to address structural alignment based on load cell wall information in the first 40 ms of the test. For the offset test (ODB), the existing ECE R94 was chosen. Within the paper, an overview of the final assessment approach for the frontal impact test procedures and their development is given.
Das Ziel der Untersuchung war, die Grenzen der Belastbarkeit eines Rollstuhl- und Personenrückhaltesystems mit Kraftknoten nach DIN 75078-2 zu ermitteln. Dazu wurden dynamische Schlittenversuche durchgeführt, bei denen die Verzögerungspulse sowie das Gesamtgewicht von Rollstuhl und Prüfpuppe variiert wurden. Für die Untersuchungen kamen ein Prüfrollstuhl, definiert nach ISO 10542, und Rückhaltesysteme mit Kraftknoten gemäß DIN 75078-2 zum Einsatz. Das Rückhaltesystem bestand aus einem Rollstuhl- und einem Personenrückhaltesystem, wobei das Rollstuhlrückhaltesystem (RRS) mit vier bzw. sechs Gurten und entsprechenden Retraktoren an einem dynamischen Schlittenaufbau befestigt wurde. Das Personenrückhaltesystem (PRS) bestand aus einem am Rollstuhl integrierten Beckengurt sowie einem Schulterschräggurt, der am Beckengurt und am Schlittenaufbau befestigt wurde. Ferner wurden bei den Versuchen Prüfpuppen verschiedener Alters- und Gewichtsklassen (P6, HIII 5 %, HIII 50 % und HIII 95 %) eingesetzt Die Belastungsanforderungen für das Rückhaltesystem wurden sukzessiv erweitert, indem einerseits das Gesamtgewicht (Rollstuhl und Prüfpuppe) und andererseits auch die Verzögerungspulse bis zur Versagensgrenze erhöht wurden. Das Vier-Gurt-Rückhaltesystem konnte bei einem Verzögerungspuls von 10 g einem Gesamtgewicht von bis zu 221 kg standhalten. Bei einem Verzögerungspuls von 20 g und einem Gesamtgewicht von 134 kg wurde das Vier-Gurt-System bis über die Grenzen belastet. Das Sechs-Gurt-Rückhaltesystem hat Belastungen bis 221 kg standgehalten. Infolgedessen ist bei einer Erhöhung der Verzögerungspulse auf 20 g und einem Gesamtgewicht von mehr als 109 kg ein Sechs-Gurt-System zu empfehlen.
This study updates previous IIHS studies comparing estimated delta Vs for crash tested vehicles to the distribution of estimated delta Vs in the National Automotive Sampling System (NASS) Crashworthiness Data System (CDS). The delta V estimates for 232 frontal crash tests at 64.4km/h into a deformable barrier with 40 percent overlap are compared with estimates from frontal offset crashes in the 1997-2004 NASS database. All delta V estimates were based on SMASH, the delta V estimating program used by NASS since 1997. Results indicated that for all vehicles tested by IIHS, SMASH delta Vs were, on average, 32 percent lower than impact speeds and about 28 percent lower than the expected delta V. Almost 80 percent of all real-world frontal crashes resulting in AIS 3+ injuries and just over 60 percent of all fatal crashes occur at or below the average estimated delta V calculated for crash tested vehicles.
The utilisation of secondary-safety systems to protect occupants has attained a very high level over the past decades. Further improvements are still possible, but increasingly minor progress is only to be had with a high degree of effort. Thus, a key aspect must be the impact to overall safety in an accident. If reliable information is available on an imminent crash, measures already taken in the pre-crash phase can result in a significantly great influence on the outcomes of the crash. With this background preventive measures are the key to a sustainable further reduction of the figures of crash victims on our roads. This paper aims to show a preventive approach that can contribute to lessening the consequences of a crash by creating an optimum interaction of measures in the fields of primary and secondary safety. To further enhance vehicle safety, driver assistant systems are already available that warn the driver of an imminent front-to-rear-end crash. The next step is to support him in his reactions or if he fails to react sufficiently, to even initiate an automatic braking when the crash becomes unavoidable. Automatic pre-crash braking can, in an ideal situation, fully prevent a crash or can significantly reduce the impact speed and thus the impact energy (and the severity of the accident). If a vehicle is being braked in the pre-crash phase, the occupants are already being pre-stressed by the deceleration. The information available about the imminent crash can be used to activate the belt tensioners and likewise other secondary safety systems in the vehicle right before the impact. The pre-crash deceleration also causes the front of the vehicle to dip. Conventional crash tests do not take this specific impact situation into consideration. This is why, for example, the influences of the pre-crash displacements of the occupants are not recorded in the test results. Furthermore, a reproducible representation of the benefit of the vehicle safety systems which prepare the occupants for the imminent impact is not possible. In order to demonstrate the functions of automated pre-crash braking and to investigate the differences during the impact as a consequence of the altered occupant positions as well as the initiation of force and deformations of the vehicle front, DEKRA teamed up with BMW to carry out a joint crash test with the latest BMW 5 series vehicle. It involved the vehicle braking automatically from a starting test speed of 64 km/h (corresponding to the impact speed set by Euro NCAP) down to 40 km/h. The test was still run by the intelligent drive system of the crash test facility. This required several modifications to be made to the test facility as well as to the vehicle. The paper will describe and discuss some relevant results of the crash test. In addition, the possible benefits of such systems will also be considered. The test supplemented the work of the vFSS working group (vFSS stands advanced Forward-looking Safety Systems).
The price of a new car increased almost every year for a long period. In recent years however, the budget available to most people for purchasing a car either did not grow or became even smaller. Therefore it was in the interest of some OEMs to offer economical car models in the so-called "8,000- Euro class". Here an important question arose regarding the safety of these vehicles. There is no question that the very high safety level of cars reached in Europe during the last decades should not be sacrificed as a consequence of smaller budgets. Customers with sense of responsibility have the right to be properly informed about the balance between safety and price so that they can make a deliberate decision when buying either a new or a used car. Against this background, the German magazine "AutoBILD" commissioned DEKRA to conduct fullscale frontal crash tests with a view to publishing the results. These tests have been carried out in accordance with the corresponding Euro NCAP crash test requirements and performance criteria. The tested vehicles were two new Logans produced by the manufacturer Dacia, two used cars of the type VW Golf IV (registration date 2000) and one new VW Fox. This paper describes the safety features of the vehicles and the results of the five crash tests to demonstrate state-of-the-art safety levels and what levels may be expected from vehicles in the "8,000- Euro class". Looking at real-world crashes it is of interest to think about future trends in a more detailed manner. Therefore it will be more and more necessary to supplement the federal statistics with more detailed in-depth information about the consequences of accidents and the safety performance of crashed vehicles.
Neben der zunehmenden Bedeutung der aktiven Sicherheit bleiben Maßnahmen der passiven Sicherheit bei der Entwicklung moderner Kraftfahrzeuge unabdingbar. Die Weiterentwicklung von Maßnahmen zum passiven Fußgängerschutz war zunächst größtenteils durch Verbraucherschutztests wie zum Beispiel Euro NCAP oder JNCAP getrieben und ist nun auch durch gesetzliche Regelungen verpflichtend geworden. Im vorangegangenen Forschungsprojekt der BASt FE 82.229/2002 Schutz von Fußgängern beim Scheibenaufprall ist die Grundlage eines modularen Prüfverfahrens für den Kopfaufprall im Bereich der Windschutzscheibe, bestehend aus einem Versuchs- und einem Simulationsteil, erarbeitet worden. Im Rahmen dieses Projektes wurde ein hybrides Testverfahren bestehend aus Versuch und Simulation ausgearbeitet, das den Bereich der Windschutzscheibe und dabei auch crashaktive Systeme wie Airbags berücksichtigt. Das Testverfahren kombiniert Komponentenversuche mit einem Simulationsteil, in dem Fahrzeug-Fußgänger-Simulationen und lmpaktorsimulationen durchgeführt werden. Zusätzliche Dummyversuche dienten zur Bewertung des Testverfahrens. Alle erarbeiteten virtuellen und realen Testmethoden wurden an einem Referenzfahrzeug (Opel Signum), welches repräsentativ für eine durchschnittliche Mittelklasselimousine steht, durchgeführt. Das Fahrzeug wurde mit einem Airbagsystem ausgerüstet und der Testprozedur mit und ohne diesem System vergleichend unterzogen. Innerhalb dieser Untersuchungen konnte gezeigt werden, dass neue Testmethoden unter Ausnutzung von Simulationen und Komponententests es erlauben, realistischere Versuchsbedingungen unter Berücksichtigung von potenziellen Kopfaufprallpositionen und -zeiten zu definieren. Dabei können sehr gute Übereinstimmungen zwischen Fußgängersimulation und Dummyversuch erreicht werden. Die Randbedingungen für den Kopfaufprall und die Aufprallzeit wurden durch den Einsatz von Fußgängermodellen ermittelt. Weiterhin ermöglichen die Simulationen, zusätzliche Einflussdaten wie Vektoren mit den Kopfaufprallgeschwindigkeiten und -winkeln zu bestimmen.
Side-impact safety of passenger cars is assessed in Europe in a full-scale test using a moving barrier. The front of this barrier is deformable and represents the stiffness of an 'average' car. The EU Directive 96/27/EC on side impact protection has adopted the EEVC Side Impact Test Procedure, including the original performance specification for the barrier face when impacting a flat dynamometric rigid wall. The requirements of the deformable barrier face, as laid down in the Directive, are related to geometrical characteristics, deformation characteristics and energy dissipation figures. Due to these limited requirements, many variations are possible in designing a deformable barrier face. As a result, several barrier face designs are in the market. However, research institutes and car manufacturers report significant difference in test results when using these different devices. It appears that the present approval test is not able to distinguish between the different designs that may perform differently when they impact real vehicles. Therefore, EEVC Working Group 13 has developed a number of tests to evaluate the different designs. In these tests the barrier faces are loaded and deformed in a specific and/or more representative way. Barrier faces of different design have been evaluated. In the paper the set-up and the reasoning behind the tests is presented. Results showing specific differences in performance are demonstrated.
Impact severity is a fundamental measure for all in-depth crash investigation projects. One methodology used in the UK is based on the US Calspan software package CRASH3. The UK- in-depth crash investigation studies routinely use AiDamage3 a software package which is based on an updated version of the original CRASH3 algorithm, including enhancements to the vehicle stiffness coefficients. Real world accident-damaged vehicles are measured and their crush is correlated with a library of stiffness coefficients. These measurements are then used, along with other parameters, to calculate the crash energy and equivalent changes of velocity of the vehicles (delta-v), which is a measure of the impact severity. UK in-depth accident studies routinely validate the crash severity methodologies applied as the vehicle fleet changes. This is achieved by analysing crash test data and using the appropriate residual crush damage and other inputs to AiDamage3 and checking the program- outputs with the known crash severity parameters. This procedure checks, at least in part, the default stiffness values in the data libraries and the reconstruction methods used.
In North America, frontal crash tests in both the regulatory environment and consumer-based safety rating schemes have historically been based on full-width and moderate-overlap (40%) vehicle to barrier impacts. The combination of improved seat-belt technologies, notably belt tensioning and load limiting systems, together with advanced airbags, has proven very effective in providing occupant protection in these crash modes. Recently, however, concern has been raised over the contribution of narrower frontal impacts, involving primarily the vehicle corners, to the incidence of fatality and serious injury as a result of the potential for increased occupant compartment intrusion and performance limitations of current restraint systems. Drawing on data documented in the National Automotive Sampling System (NASS)/ Crashworthiness Data System (CDS) for calendar years 1999 to 2012, the present study examines the characteristics of existing and proposed corner crash test configurations, and the nature of real-world collisions that approximate the test environments. In this analysis, particular emphasis is placed on crash pulse information extracted from vehicle-based event data recorders (EDR's).
Over the past two decades the popularity of consumer crash test programs, commonly referred to as New Car Assessment Programs (NCAP), has grown across the world. They are popular among government regulators as they afford a means of promoting safety innovations and levels of vehicle performance beyond those dictated by national standards. They also fulfill the demand for information regarding the safety ranking of vehicles among consumers contemplating the purchase of a new vehicle. There is no question that consumer crash test programs greatly influence vehicle design changes as well as accelerate the fitment of new safety features. The extent to which these changes can be expected to reduce serious and potentially fatal injuries will be influenced by how well the testing protocols and associated rating schemes correctly reflect the nature of the residual safety problem they seek to address. Drawing on data contained primarily in the US National Automotive Sampling System (NASS), the field relevance of current and proposed testing and rating protocols addressing frontal crash test protection is examined. Emphasis is placed on examining how accurately injury rates computed from the dummy responses measured in consumer crash tests correspond to actual injury rates observed in the field. Additional data from Canadian field investigations and US databases such as the National Motor Vehicle Crash Causation Survey (NMVCCS) are examined to see how well frontal airbag firing times, crush pulse durations and other determinants of injury are replicated in consumer testing protocols. This portion of the analysis draws on data obtained from Event Data Recorders (EDR) in both field collisions and staged tests of the same vehicle model. Vehicle rankings and overall frontal crash test ratings were found to be particularly sensitive to the choice of injury risk functions employed in the test. This was particularly true in the case of injury risk functions used to assess neck injury potential. Neck injury risk derived from Nij was found to show the least agreement with the field. Agreement between field chest injury rates and those derived from crash tests was improved considerably when chest injury risk functions for "older" occupants were employed. The paper concludes with a discussion of how different current testing protocols could be improved to enhance their field relevance.
Accidents involving two wheels vehicles represent one of the more important types of accidents in Europe. These accidents are usually not easy to reconstruct specially for the analysis of the injuries and its correlation with accident dynamics and evidences. Different methodologies are applied in this work for the reconstruction of two wheeler accidents, especially accident involving motorcycles. From the typologies of road evidences like skid marks, to the use of Pc-Crash and the use of Madymo models, different reconstruction of real accidents are presented. One of the questions that sometimes arise for legal purposes when some type of head injuries arise is if the occupant was wearing or not a helmet. The correlation of head injuries with the use of the helmet is a very important issue, therefore an important legal aspect. One of the key questions for the reconstructions that is difficult to analyze, is if the vehicle occupant, was or not, wearing the helmet. Based on the previously collected information, a generic model of a helmet was developed on CAD 3D, followed by its conversion into finite elements, all in order to perform impact tests using the Madymo software that would help improve the helmet- safety, but that also can be used as a tool in accident reconstruction.
The frontal crash is still an important contributor to deaths and serious injured resulting from road accidents in Europe. As the Hybrid-III dummy used in crash tests is over two decades old, the European Enhanced Vehicle-safety Committee is studying the potential for a new test device. Key is the availability of a well-defined set of requirements that identifies the minimum level of biofidelity required for an advanced frontal dummy. In this paper, a complete set of frontal impact biofidelity requirements, consisting of references , description of test conditions and corridors, is presented.
Although the number of road accident casualties in Europe (EU27) is falling the problem still remains substantial. In 2011 there were still over 30,000 road accident fatalities. Approximately half of these were car occupants and about 60 percent of these occurred in frontal impacts. The next stage to improve a car's safety performance in frontal impacts is to improve its compatibility. The objective of the FIMCAR FP7 EU-project was to develop an assessment approach suitable for regulatory application to control a car's frontal impact and compatibility crash performance and perform an associated cost benefit analysis for its implementation. This paper reports the cost benefit analyses performed to estimate the effect of the following potential changes to the frontal impact regulation: • Option 1 " No change and allow current measures to propagate throughout the vehicle fleet. • Option 2 " Add a full width test to the current offset Deformable Barrier (ODB) test. • Option 3 " Add a full width test and replace the current ODB test with a Progressive Deformable Barrier (PDB) test. For the analyses national data were used from Great Britain (STATS 19) and from Germany (German Federal Statistical Office). In addition in-depth real word crash data were used from CCIS (Great Britain) and GIDAS (Germany). To estimate the benefit a generalised linear model, an injury reduction model and a matched pairs modelling approach were applied. The benefits were estimated to be: for Option 1 "No change" about 2.0%; for Option 2 "FW test" ranging from 5 to 12% and for Option 3 "FW and PDB tests" 9 to 14% of car occupant killed and seriously injured casualties.
In the EC FP6 Integrated Project Advanced Protection Systems, APROSYS, the first WorldSID small female prototype was developed and evaluated by BASt, FTSS, INRETS, TRL and UPM-INSIA during 2006 and 2007. Results were presented at the ESV 2007 conference (Been et al., 2007). With the prototype dummy scoring a biofidelity rating higher than 6.7 out of 10 according to ISO/TR9790, the results were very promising. Also opportunities for further development were identified by the evaluation group. A revised prototype, Revision1, was subsequently developed in the 2007-2008 period to address comments from the evaluation group. The Revision1 dummy includes changes in the half arms and the suit (anthropometry and arm biomechanics), the thorax and abdomen ribs and sternum (rib durability), the abdomen/lumbar area and the lower legs (mass distribution). Also a two-dimensional chest deflection measurement system was developed to measure deflection in both lateral and anterior-posterior direction to improve oblique thorax loading sensitivity. Two Revision1 prototype dummies have now been evaluated by FTSS, TRL, UPM-INSIA and BASt. The updated prototype dummies were subjected to an extensive matrix of biomechanical tests, such as full body pendulum tests and lateral sled impact tests as specified by Wayne State University, Heidelberg University and Medical College of Wisconsin. The results indicated a significant improvement of dummy biofidelity. The overall dummy biofidelity in the ISO rating system has significantly improved from 6.7 to 7.6 on a scale between 0-10. The small female WorldSID has now obtained the same biofidelity rating as the WorldSID mid size male dummy. Also repeatability improved with respect to the prototype. In conclusion the recommended updates were all executed and all successfully contributed in achieving improved performance of the dummy.
Past European collaborative research involving government bodies, vehicle manufacturers and test laboratories has resulted in a prototype barrier face called the Advanced European Mobile Deformable Barrier (AE-MDB) for use in a new side impact test procedure . This procedure offers a better representation of the current accident situation and, in particular, the barrier concept is a better reflection of front-end stiffness seen in today- passenger car fleet compared to that of the current legislative barrier face. Based on the preliminary performance corridors of the prototype AE-MDB, a refined AE-MDB specification has been developed. A programme of barrier to load cell wall testing was undertaken to complete and standardise the AE-MDB specification. Barrier faces were supplied by the four leading manufacturers to demonstrate that the specification could be met by all. This paper includes background, specification and proof of compliance.
This paper provides an overview of the research work of the European Enhanced Vehicle-safety Committee (EEVC) in the field of crash compatibility between passenger cars. Since July 1997 the EC Commission is partly funding the research work of EEVC. The running period of this project will be two years. The progress of five working packages of this research project is presented: Literature review, Accident analysis, Structural survey of cars, Crash testing, and Mathematical modelling. According to the planned time schedule the progress of research work is different for the five working packages.
A series of drop tests and vehicle tests with the adult head impactor according to Regulation (EC) 631/2009 and drop tests with the phantom head impactor according to UN Regulation No. 43 have been carried out by the German Federal Highway Research Institute (BASt) on behalf of the German Federal Ministry of Transport, Building and Urban Development (BMVBS). Aim of the test series was to study the injury risk for vulnerable road users, especially pedestrians, in case of being impacted by a motor vehicle in a way described within the European Regulations (EC) 78/2009 and (EC) 631/2009. Furthermore, the applicability of the phantom head drop test described in UN Regulation No. 43 for plastic glazing should be investigated. In total, 30 drop tests, thereof 18 with the adult head impactor and 12 with the phantom head impactor, and 49 vehicle tests with the adult head impactor were carried out on panes of laminated safety glass (VSG), polycarbonate (PC) and laminated polycarbonate (L-PC). The influence of parameters such as the particular material properties, test point locations, fixations, ambient conditions (temperature and impact angle) was investigated in detail. In general, higher values of the Head Injury Criterion (HIC) were observed in tests on polycarbonate glazing. As the HIC is the current criterion for the assessment of head injury risk, polycarbonate glazing has to be seen as more injurious in terms of vulnerable road user protection. In addition, the significantly higher rebound of the head observed in tests with polycarbonate glazing is suspected to lead to higher neck loads and may also cause higher injury risks in secondary impacts of vulnerable road users. However, as in all tests with PC glazing no damage of the panes was observed, the risk of skin cut injuries may be expected to be reduced significantly. The performed test series give no indication for the test procedure prescribed in UN Regulation No. 43 as a methodology to approve glass windscreen not being feasible for polycarbonate glazing, as all PC panes tested fulfilled the UN R 43 requirements. The performance of the windscreen area will not be relevant for vehicle type approval according to the upcoming UN Regulation for pedestrian protection. However, it is recommended that pedestrian protection being considered for plastic windscreens to ensure at least the same level of protection as glass windscreens.
Straßenseitige Fahrzeug-Rückhaltesysteme haben entsprechend der Richtlinie für passiven Schutz an Straßen durch Fahrzeug-Rückhaltesysteme (RPS) die Aufgabe, die Folgen von Verkehrsunfällen so gering wie möglich zu halten. Sie kommen dabei sowohl zum Schutz unbeteiligter Personen, des Gegenverkehrs bei zweibahnigen Straßen sowie schutzbedürftiger Bereiche neben der Straße als auch zum Schutz der Fahrzeuginsassen vor schweren Folgen infolge Abkommens von der Fahrbahn zum Einsatz. Vor dem Einsatz der unterschiedlichen Systeme muss die Wirksamkeit des jeweiligen Systems für den entsprechenden Anwendungsfall nachgewiesen werden. Dabei regeln die RPS, welche Anforderungen an welchen örtlichen Gegebenheiten erfüllt sein müssen. In DIN EN 1317 sind die zugehörigen Prüfverfahren beschrieben. Da ein normiertes Prüfverfahren nicht alle real auftretenden Unfallszenarien abdecken kann, stellte sich die Frage, wie sich Stahlschutzplanken und Betonschutzwände beim großwinkligen Anprall kleiner und leichter Fahrzeuge verhalten und wie es um die Insassensicherheit bestellt ist. Eine im Rahmen des resultierenden Forschungsprojektes durchgeführte Analyse des Unfallgeschehens ergab für das Jahr 2007 die Zahl von 25.038 polizeilich registrierten Unfällen mit Anprall gegen eine Schutzeinrichtung [Statistisches Bundesamt]. Angaben zu Anprallwinkel, Kollisionsgeschwindigkeit und Fahrzeugmasse können dieser Statistik nicht entnommen werden. Für die In-depth-Analyse wurden daher 69 Unfallgutachten zu Kollisionen mit großem Anprallwinkel (≥ 25-°) aus der DEKRA-Unfalldatenbank herangezogen. Der Schwerpunkt wurde dabei auf 39 Unfälle gelegt, die sich auf Bundesautobahnen ereignet hatten. Mit zunehmendem Anprallwinkel nahm die Unfallhäufigkeit ab. Der größte Winkel lag bei 60-°. Die Masse der anprallenden Fahrzeuge lag zwischen 750 kg und 1.935 kg. Auffällig war die Häufung von Schleuderunfällen. In 29 Fällen kam es zu einem prekollisionären Schleudervorgang. Die Analyse des Unfallgeschehens hat so gezeigt, dass Anpralle gegen passive Schutzeinrichtungen auf Bundesautobahnen mit zunehmendem Anprallwinkel seltener werden und dass der in der Norm für die Systemprüfung geforderte Maximalwinkel von 20-° das Gesamtunfallgeschehen sehr gut abdeckt. Auf Basis der gewonnenen Ergebnisse erfolgte die Festlegung einer Crash-Test-Konfiguration zur Erlangung von Erkenntnissen über die Insassensicherheit bei großwinkligen Anprallen. Dabei wurde als Grundlage der Anprallversuch TB 11 verwendet, wobei der Anprallwinkel von 20-° auf 45-° erhöht wurde. Die Kollisionsgeschwindigkeit von 100 km/h sowie die Fahrzeugmasse von 900 kg blieben unverändert. Die Anpralltests erfolgten gegen eine simulierte Ortbetonwand sowie gegen eine Stahlschutzplanke vom Typ Super-Rail-®. Die Versuchsfahrzeuge waren typgleich mit den Modellen, die für die ursprüngliche TB-11-Prüfung der Systeme verwendet wurden. Die Versuche haben gezeigt, dass beide Systeme die Rückhaltung der anprallenden Fahrzeuge sicher gewährleisteten. Für die Fahrer beider Fahrzeuge hätte aber keine Überlebenschance bestanden. Über das Schutzniveau der Fahrzeuginsassen entscheiden bei derartigen Anprallkonstellationen letztendlich das Niveau der passiven Sicherheit der anprallenden Fahrzeuge sowie das Energieabsorptionsvermögen der die Fahrgastzelle umschließenden Strukturen.