Filtern
Erscheinungsjahr
Dokumenttyp
- Konferenzveröffentlichung (41)
- Buch (Monographie) (11)
- Arbeitspapier (8)
- Wissenschaftlicher Artikel (7)
Schlagworte
- Impact test (veh) (67) (entfernen)
Institut
One main objective of the EU-Project SENIORS is to provide improved methods to assess thoracic injury risk to elderly occupants. In contribution to this task paired simulations with a THOR dummy model and human body model will be used to develop improved thoracic injury risk functions. The simulation results can provide data for injury criteria development in chest loading conditions that are underrepresented in PMHS test data sets that currently proposed risk functions are based on. To support this approach a new simplified generic but representative sled test fixture and CAE model for testing and simulation were developed. The parameter definition and evaluation of this sled test fixture and model is presented in this paper. The justification and definition of requirements for this test set-up was based on experience from earlier studies. Simple test fixtures like the gold standard sled fixture are easy to build and also to model in CAE, but provide too severe belt-only loading. On the other hand a vehicle buck including production components like airbag and seat is more representative, but difficult to model and to be replicated at a different laboratory. Furthermore some components might not be available for physical tests at later stage. The basis of the SENIORS generic sled test set-up is the gold standard fixture with a cable seat back and foot rest. No knee restraint was used. The seat pan design was modified including a seat ramp. The three-point belt system had a generic adjustable load limiter. A pre-inflated driver airbag assembly was developed for the test fixture. Results of THOR test and simulations in different configurations will be presented. The configurations include different deceleration pulses. Further parameter variations are related to the restraint system including belt geometry and load limiter levels. Additionally different settings of the generic airbag were evaluated. The test set-up was evaluated and optimized in tests with the THOR-M dummy in different test configurations. Belt restraint parameters like D-ring position and load limiter setting were modified to provide moderate chest loading to the occupant. This resulted in dummy readings more representative of the loading in a contemporary vehicle than most available PMHS sled tests reported in the literature. However, to achieve a loading configuration that exposes the occupant to even less severe loading comparable to modern vehicle restraints it might be necessary to further modify the test set-up. The new generic sled test set-up and a corresponding CAE model were developed and applied in tests and simulations with THOR. Within the SENIORS project with this test set-up also volunteer and PMHS as well as HBM simulations are performed, which will be reported in other publications. The test environment can contribute in future studies to the assessment of existing and new frontal impact dummies as well as dummy improvements and related instrumentation. The test set-up and model could also serve as a new standard test environment for PMHS and volunteer tests as well as HBM simulations.
Accident analysis
(2014)
For the assessment of vehicle safety in frontal collisions compatibility (which consists of self and partner protection) between opponents is crucial. Although compatibility has been analysed worldwide for years, no final assessment approach has been defined to date. Taking into account the European Enhanced Vehicle safety Committee (EEVC) compatibility and frontal impact working group (WG15) and the EC funded FP5 VC-COMPAT project activities, two test approaches have been identified as the most promising candidates for the assessment of compatibility. Both are composed of an off-set and a full overlap test procedure. In addition another procedure (a test with a moving deformable barrier) is getting more attention in today- research programmes. The overall objective of the FIMCAR project is to complete the development of the candidate test procedures and propose a set of test procedures suitable for regulatory application to assess and control a vehicle- frontal impact and compatibility crash safety. In addition an associated cost benefit analysis should be performed. The specific objectives of the work reported in this deliverable were: - Determine if previously identified compatibility issues are still relevant in current vehicle fleet: Structural interaction, Frontal force matching, Compartment strength in particular for light cars. - Determine nature of injuries and injury mechanisms: Body regions injured o Injury mechanism: Contact with intrusion, Contact, Deceleration / restraint induced. The main data sources for this report were the CCIS and Stats 19 databases from Great Britain and the GIDAS database from Germany. The different sampling and reporting schemes for the detailed databases (CCIS & GIDAS) sometimes do not allow for direct comparisons of the results. However the databases are complementary " CCIS captures more severe collisions highlighting structure and injury issues while GIDAS provides detailed data for a broader range of crash severities. The following results represent the critical points for further development of test procedures in FIMCAR.
Als passive Schutzeinrichtungen werden Systeme bezeichnet, die von der Fahrbahn abkommende Fahrzeuge abweisen und aufhalten, wie Stahlschutzplanken oder Betonschutzwände. Schutzeinrichtungen müssen als wichtigsten Eignungsnachweis erfolgreiche Anprallversuche mit handelsüblichen Pkw und/oder Lkw absolvieren. Die Grundlage dafür bilden Europäische Normentwürfe. Bewertungskriterien für die Eignung einer Schutzeinrichtung sind ihr maximales Aufhaltevermögen, ihre dynamische seitliche Auslenkung, das Fahrzeugverhalten und die Insassenbelastung. Durch die Einführung der Europäischen Normen, vermutlich Anfang 1997, wird es auch in Deutschland Veränderungen für die Anforderungen an Schutzeinrichtungen geben. Zukünftig werden Leistungsklassen an Stelle der jetzt in den nationalen Richtlinien explizit genannten Systembeschreibungen treten, das heißt, Schutzeinrichtungen werden nicht nach ihrer Bauart, sondern nach ihrer Leistungsbeschreibung ausgewählt. Die sich abzeichnenden Europäischen Normen bieten ein breites Spektrum neuer Klassen, mit der Möglichkeit, auch in Deutschland höhere Leistungsklassen als bisher wählen zu können. Gleichzeitig wird in Zukunft sicher noch deutlich mehr in die Einrichtung von passiven Schutzeinrichtungen investiert werden müssen, weil nicht nur die Verkehrsbelastung und damit die Gefahr des Abkommens von der Fahrbahn steigt, sondern auch die Schwere der durch Lkw mit höheren Radlasten verursachten Unfälle. Die dazu notwendigen Finanzmittel und die zu erwartenden volkswirtschaftlichen Auswirkungen müssen sorgfältig gegeneinander abgewogen werden. Bei einem vorhandenen Straßennetz von circa 228.000 km (außerorts) in Deutschland und abgeschätzten Kosten für die Umrüstung in dreistelliger Millionenhöhe müssen alternative Überlegungen in Betracht gezogen werden, wie die Orientierung am DTV-Schwerlastverkehr oder eine gewichtete Aufteilung der Mittel auf die verschiedenen Straßenklassen. Aufgrund der angespannten Haushaltssituation wird der zur Verfügung stehende Rahmen zwangsläufig sehr eng sein. Trotzdem muss es vorrangiges Ziel bleiben Schutzeinrichtungen an Straßen aufgrund ihrer positiven Wirkung auf die Unfallfolgen in einer Qualität und in einem Umfang einzusetzen, der allen Verkehrsteilnehmern ein möglichst hohes Maß an Sicherheit bietet.
An approach to the standardization of accident and injury registration systems (STAIRS) in Europe
(1998)
STAIRS is a European Commission funded study whose aim is to produce a set of guidelines for a harmonised, crash injury database. The need to evaluate the effectiveness of the forthcoming European Union front and side impact directives has emphasised the need for real world crash injury data-sets that can be representative of the crash population throughout Europe. STAIRS will provide a methodology to achieve this. The ultimate aim of STAIRS is to produce a set of data collection tools which will aid decision making on vehicle crashworthiness as well as providing a means to evaluate the effectiveness of safety regulations. This paper will disseminate the up-to-date findings of the group as they try to harmonise their methods. The stage has been reached where studies into the diverse methods of the UK, French and German systems of crash injury investigation have been undertaken. An assessment has already been made of the relationships between the three current systems in order to define the areas of agreement and divergence. The conclusions reached stated that there were many areas that are already closely related and that the differences were only at the detailed level. With the emphasis on secondary safety and injury causation, core data sets were decided upon, taking into account: vehicle description, collision configuration, structural response of vehicles, restraint and airbag performance, child restraint performance, Euro NCAP, pedestrian and vehicle occupant kinematics, injury description and causation. Each variable was studied objectively, the important elements isolated and developed into a form that all partners were agreeable on. A glossary of terms is being developed as the project progresses which includes ISO standards and other definitions from the associated CAREPLUS project, which addresses the comparability of national data sets. A major consideration of the group was the data collection method to be employed. The strengths and weaknesses of each study were investigated to obtain a clear idea of which aspects offered the best way forward. The quality of this information and transference into a common format, as well as the necessary error checking systems to be employed have just been completed and are described. In tandem with this area of study the problem of the statistical relationship of each sample to the national population is also being investigated. The study proposes a mechanism to use a sample of crash injury data to represent the national and international crash injury problem
Werden die in Deutschland gebräuchlichen Stahlschutzplanken umgestaltet um das Verletzungsrisiko für Motorradfahrer zu verringern, zeigt sich ein Kompatibilitätsproblem: Die Erhöhung der Sicherheit für Motorradfahrer wird mit Einschränkungen der Sicherheit von Pkw-Insassen erkauft. Um dieses Kompatibilitätsproblem zu lösen wurden unter Federführung der Bundesanstalt für Straßenwesen (BASt) neue Nachrüstkomponenten für Stahlschutzplanken entwickelt. Dabei lag der Schwerpunkt auf der Senkung der Verletzungsschwere für Motorradfahrer. Im vorliegenden Projekt sollten die Nachrüstkomponenten des Systems "EuskirchenPlus" ihre Tauglichkeit auch für Pkw-Insassen in Anprallprüfungen (Crashtests) beweisen. Dies gelang zunächst nicht. Daher wurden die Nachrüstkomponenten zu neuen Konstruktionen ("ESP-Motorrad" und "EDSP-Motorrad") weiterentwickelt, und es gelang, die "ESP-Motorrad" erfolgreich zu prüfen. Die Eignung der "EDSP-Motorrad" wurde aus den vorliegenden Forschungsergebnissen und den Erfahrungen der BASt abgeleitet. Das Kompatibilitätsproblem konnte zwar nicht umfassend gelöst, jedoch soweit beseitigt werden, dass keine relevanten Einsatzbeschränkungen mehr aufrecht erhalten werden müssen. Die "ESP-Motorrad" und die "EDSP-Motorrad" sind auf nahezu allen für Motorradunfälle relevanten Strecken grundsätzlich geeignet, die klassischen Stahlschutzplanken ESP beziehungsweise EDSP zu ersetzen.
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.
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.
Automotive interiors have long been a potentially injurious impact area to occupants during accidents, especially in the absence of adequate padding. The U.S. Federal Motor Vehicle Safety Standard (FMVSS) 201, Occupant Protection in Interior Impact, outlines test procedures and performance criteria in order to mitigate potentially injurious head impacts to interior surfaces. FMVSS 201 specifies a finite set of impact locations and applies to passenger vehicles of a specified year range and with a gross vehicle weight rating less than 10,000 lb. In this paper, two head impact test methodologies are presented, a pendulum-test device and a Free Motion Headform (FMH) launching device, which allows for dynamic, repeatable impact evaluation of various vehicle interior surfaces and their impact attenuation abilities. The presented testing includes multiple series that evaluate the effect of differing vehicle upper interior padding on occupant head injury. One study in particular, analyzes a head impact to the side header of a heavy truck (not included in FMVSS 201) during a 90 degree rollover. Additionally, two other series of tests are presented which assess the injury reduction effect of side airbags to near side as well as far side occupants in a side impact scenario. Lastly, a forensic analysis is presented which evaluates two possible head impact locations experienced in a real world accident by analysis of the resulting interior compartment damage utilizing the FMH launching device test method. The data collected and presented includes accelerometer instrumentation and high speed video analysis. These studies demonstrate that adequate padding and airbags are very effective at mitigating head injury potential at impact speeds of 12-25 mph (19-40 kph).
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.
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.
The purpose of this paper is to review injuries found in real world lateral collisions and determine the mechanisms responsible for certain kinds of biomechanical failure. During the last years the distribution of deaths among the different types of accidents has changed. Lateral collisions now are the most frequent cause of fatal and other serious injuries. Every third accident is an impact from the side, while every second fatality is the result of a lateral accident. Just a few years ago this value was no higher than 30%. This is probably the result of increasing safety standards for frontal collisions (airbags, seatbelt usage, structural improvements of cars, etc.). Although the number of registered vehicles increased, the total amount of fatalities decreased during the same period. Thus it is now necessary to pay greater attention to the lateral accident situation in order to improve road safety and decrease the number of traffic injuries. Several European organisations had decided to launch the project SID2000, which was funded by the European Commission, with the intention of gathering more knowledge on injuries occurring in lateral accidents and the mechanisms that lead to such injuries. This should enable the group to define the requirements for a new side impact dummy (SID) to be designed. Within the same project the existing TNO-EUROSID 1 was enhanced by another group and the experience gained has now enabled allowed to design a better measuring device for side impacts. The data used for this contribution came from sources from all over Europe and had to be gathered in such a manner that as many accident parameters as possible were taken into account.
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.
Cost benefit analysis
(2014)
Although the number of road accident casualties in Europe is falling the problem still remains substantial. In 2011 there were still over 30,000 road accident fatalities [EC 2012]. Approximately half of these were car occupants and about 60 percent of these occurred in frontal impacts. The next stage to improve a car- safety performance in frontal impacts is to improve its compatibility for car-to-car impacts and for collisions against objects and HGVs. Compatibility consists of improving both a car- self and partner protection in a manner such that there is good interaction with the collision partner and the impact energy is absorbed in the car- frontal structures in a controlled way which results in a reduction of injuries. Over the last ten years much research has been performed which has found that there are four main factors related to a car- compatibility [Edwards 2003, Edwards 2007]. These are structural interaction potential, frontal force matching, compartment strength and the compartment deceleration pulse and related restraint system performance. The objective of the FIMCAR FP7 EC-project was to develop an assessment approach suitable for regulatory application to control a car- frontal impact and compatibility crash performance and perform an associated cost benefit analysis for its implementation.
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.
Although the statistics show a decreasing rate of child injuries and fatalities in German road accidents more efforts can be made to protect children in cars e.g. by developing appropriate child restraint systems. An important part in of this work can be achieved with the help of crash tests using child dummies. However these crash tests cannot completely reflect the situation of real world crashes as factors like children moving out of the optimal position or children incorrectly fastened by their parents are difficult to predict. Therefore this study gives an overview over the current accident and injury situation of child occupants in cars in German road accidents.
At the 2005 ESV conference, the International Harmonisation of Research Activities (IHRA) side impact working group proposed a 4 part draft test procedure, to form the basis of harmonisation of regulation world-wide and to help advances in car occupant protection. This paper presents the work performed by a European Commission 6th framework project, called APROSYS, an further development and evaluation of the proposed procedure from a European perspective. The 4 parts of the proposed procedure are: - A Mobile Deformable Barrier test; - An oblique Pole side impact test; - Interior headform tests; - Side Out of Position (OOP) tests. Full scale test and modelling work to develop the Advanced European Mobile Deformable Barrier (AE-MDB) further is described, resulting in a recommendation to revise the barrier face to include a bumper beam element. An evaluation of oblique and perpendicular pole tests was made from tests and numerical simulations using ES-2 and WorldSID 50th percentile dummies. It was concluded that an oblique pole test is feasible but that a perpendicular test would be preferable for Europe. The interior headform test protocol was evaluated to assess its repeatability and reproducibility and to solve issues such as the head impact angle and limitation zones. Recommendations for updates to the test protocol are made. Out-of-position (OOP) tests applicable for the European situation were performed, which included additional tests with Child Restraint Systems (CRS) which use is mandatory in Europe. It was concluded that the proposed IHRA OOP tests do cover the worst case situations, but the current test protocol is not ready for regulatory use.
When the EEVC proposed the full-scale side impact test procedure, it recommended that consideration should be given to an interior headform test in addition. This was to evaluate areas of contact not assessed by the dummy. EEVC Working Group 13 has been researching the parameters of a possible European headform test procedure in four phases. Earlier stages of the research have been presented at previous ESV conferences. The conclusions from these have suggested that the US free motion headform should be used in any European test procedure and that it should be a free flight test, not guided. This research has now culminated in proposals for a European test procedure. This paper presents the proposed EEVC side impact interior headform test procedure, giving the rationale for the test and the first results from the validation phase of the test protocol.
The ASSESS project is a collaborative project that develops test procedures for pre-crash safety systems like Automatic Emergency Braking (AEB). One key criterion for the effectiveness of e.g. AEB is reduction in collision speed compared to baseline scenarios without AEB. The speed reduction for a given system can only be determined in real world tests that will end with a collision. Soft targets that are crashable up to velocities of 80 km/h are state of the art for these assessments, but ordinary balloon cars are usually stationary targets. The ASSESS project goes one step further and defines scenarios with moving targets. These scenarios define vehicle speeds of up to 100 km/h, different collision scenarios and relative collision speeds of up to 80km/h. This paper describes the development of a propulsion system for a soft target that aims to be used with these demanding scenario specifications. The Federal Highway Research Institute- (BASt-) approach to move the target is a self-driving small cart. The cart is controlled either by a driver (open-loop control via remote-control) or by a computer (closed-loop control). Its weight is limited to achieve a good crashability without damages to the test vehicle. To the extent of our knowledge BASt- approach is unique in this field (other carts cannot move at such high velocities or are not crashable). This paper describes in detail the challenges and solutions that were found both for the mechanical construction and the implementation of the control and safety system. One example for the mechanical challenges is e.g. the position of the vehicle- center of gravity (CG). An optimum compromise had to be found between a low CG oriented to the front of the vehicle (good for driveability) and a high CG oriented to the rear of the vehicle (good for crashability). The soft target itself which is also developed within the ASSESS project will not be covered in detail as this is work of a project partner. Publications on this will follow. The paper also shows first test results, describes current limitations and gives an outlook. It is expected that the presented test tools for AEB and other pre-crash safety systems is introduced in the future into consumer testing (NCAP) as well as regulatory testing.
Passive Schutzeinrichtungen wie Stahlschutzplanken und Betonschutzwände werden in Deutschland bereits seit den 1950er Jahren eingesetzt und spielen seitdem eine bedeutende Rolle für die passive Sicherheit auf unseren Straßen. Die Entwicklung von passiven Schutzeinrichtungen lässt sich in mehrere Zeitabschnitte von den Anfängen in den 1930er Jahren über die Normung auf europäischer Ebene in den 1990er Jahren bis heute untergliedern. Die Entwicklung der heute bekannten und eingesetzten Stahlschutzplankensysteme hat ihren Ursprung in umfangreichen Versuchsreihen in den 1960er Jahren. Nicht zuletzt auch auf Grund der europäischen Normung ist in den letzten Jahren eine Vielzahl von neuen Systemen hinzugekommen. Jedes System, das auf europäischen Straßen zukünftig eingesetzt werden soll, muss seine Leistungsfähigkeit nach den Vorgaben der Europäischen Normen beweisen. Darin werden einheitliche Anforderungen für die Wirkungsweise von Schutzeinrichtungen bei der Abnahmeprüfung mittels Anprallversuchen festgelegt. Die Auswahl für die nationale Verwendbarkeit der Systeme und deren Einsatzbereiche wird auch weiterhin in nationalen Richtlinien geregelt. Diese zu erarbeiten und umzusetzen, stellt die große Herausforderung für die nächsten Jahre dar.
As set out in the Terms of Reference, the objective of European Enhanced Vehicle-safety Committee (EEVC) Working Group (WG) 15 Car Crash Compatibility and Frontal Impact is to develop a test procedure(s) with associated performance criteria for car frontal impact compatibility. This work should lead to improved car to car frontal compatibility and self protection without decreasing the safety in other impact configuration such as impacts with car sides, trucks, and pedestrians. Since 2003, EEVC WG 15 served as a steering group for the car-to-car activities in the "Improvement of Vehicle Crash Compatibility through the development of Crash Test Procedures" (VC-COMPAT) project that was finalised at the end of 2006 and partly funded by the European Commission. This paper presents the research work carried out in the VC-COMPAT project and the results of its assessment by EEVC WG 15. Other additional work presented by the UK and French governments and industry " in particular the European industry - was taken into consideration. It also identifies current issues with candidate testing approaches. The candidate test approaches are: - an offset barrier test with the progressive deformable barrier (PDB) face in combination with a full width rigid barrier test - a full width wall test with a deformable aluminium honeycomb face and a high resolution load cell wall supplemented by the forces measured in the offset deformable barrier (ODB) test with the current EEVC barrier. These candidate test approaches must assess the structural interaction and give information of frontal force levels and compartment strength for passenger vehicles. Further, this paper presents the planned route map of EEVC WG 15 for the evaluation of the proposed test procedures and assessment criteria.
EEVC Working Group 15 (Compatibility Between Passenger Cars) has carried out research for several years thanks to collaborative project funded by the E.C. and also by exchanging results of projects funded by national programmes. The main collaborative activity of the EEVC WG15 for the last four years was a research project partly funded by the European Commission, where the group made the first attempt to investigate compatibility between passenger cars in a comprehensive research program. Accident, crash test, and mathematical modelling data were analysed. The main result was that structural incompatibilities were frequently found and identified as the main source of incompatibility problems but were not easy to quantify. Unfortunately as little vehicle information other than mass is recorded in most accident databases, most analyses have only been able to show the effect of mass or mass ratio. Common ideas to improve compatibility have been reached by this group and from discussion with other research groups. They will be investigated in the next phase, where research work will concentrate on the development of methods to assess compatibility of passenger cars. The main idea is that the prerequisite to improve crash compatibility between cars is to improve structural interaction. The most important issue is that improved compatibility must not compromise a vehicle- self protection. Test methods should lead to vehicles which show good structural interaction in car to car accidents. Test methods to prove good compatibility may be an adaptation of existing regulatory test procedures (offset deformable barrier test or full width test like in the USA) for frontal impact or may be new compatibility tests. Additional criteria, e.g. impact force distribution, and maximum vehicle deceleration or maximum vehicle impact force should result in compatible cars. Attempts will be made to estimate the benefit of a more compatible car fleet for the European Community.
At the 2001 ESV-Conference the EEVC working group on compatibility (WG 15) reported the first phase of the research work to investigate the major factors influencing compatibility between passenger cars. Following this, WG15 performed an interim study, which was partly subventioned by the European Commission, the results of which are reported in this paper. In the next phase of work, it is intended to complete the development of a suite of test procedures and associated performance criteria to assess the compatibility of passenger cars in frontal impacts The main areas of work for the interim study were: - in depth accident data analysis - the development of methods to assess the potential benefit of improved compatibility - crash testing. The accident analysis identified the major compatibility problems to be poor structural interaction, stiffness mismatching and compartment strength. Different methods to assess the potential benefit of improved compatibility were applied to in depth accident data. Full scale crash testing including a car to car test was performed to help develop the following candidate compatibility test procedures: - a full width wall test with a deformable aluminium honeycomb face and a high resolution load cell wall - an offset barrier test with the EEVC barrier face and a high resolution load cell wall - an offset barrier test with the progressively deformable barrier (PDB) face. The results of the interim study will be presented in detail and the proposed methodology of the next phase to complete the development of a suite of test procedures for the assessment of car to car compatibility in frontal impacts will be outlined
EEVC Status report
(2001)
Von der Bundesanstalt für Straßenwesen (BASt) und dem Rheinisch-Westfälischen TÜV wurde 1988/89 eine Pilotstudie zum Einfluss der Korrosion auf die passive Sicherheit von Pkw bei drei unterschiedlichen Fahrzeugtypen durchgeführt. Es wurde je ein dem Alter entsprechend durchschnittlich durch Korrosion geschädigtes älteres und ein möglichst gering geschädigtes jüngeres Fahrzeug bezüglich des Korrosionszustandes vermessen und im Aufprallversuch getestet. Bei den von der BASt durchgeführten Wandaufpralltests versagten insbesondere bei den älteren Fahrzeugen sicherheitsrelevante Fahrzeugteile. Es wurde daraufhin beschlossen, die Pilotstudie mit der vorliegenden zweiten Untersuchung unter den folgenden zwei Vorgaben fortzuführen: - Verbreiterung der Datenbasis von Tests mit weiteren Fahrzeugtypen mit starker Korrosion. - Prüfung von Fahrzeugen des gleichen Typs wie in der Pilotstudie, jedoch sollten an ihnen Korrosionsschutzmaßnahmen verwirklicht sein, welche die Automobilindustrie mit Beginn der 80er Jahre in die Fertigung eingeführt hatte. Die stark korrodierten Fahrzeuge der jetzt vorliegenden Untersuchung zeigten ein ähnliches Versagensspektrum wie die stark korrodierten Fahrzeuge der Pilotstudie. An den korrosionsgeschützten und auch jüngeren Nachfolgemodellen der Fahrzeuge der Pilotstudie konnte kein korrosionsbedingter Einfluss auf die passive Fahzeugsicherheit mehr gefunden werden.
Es ist zu beobachten, dass trotz einer Abnahme der Zahl der Verletzungen und der Verletzungsschwere der Insassen bei Pkw-Unfällen Halswirbelsäulen (HWS)-Distorsionen, speziell im unteren Geschwindigkeitsbereich häufiger auftreten. Neben anderen Faktoren werden auch veränderte Beschleunigungs- und Verzögerungsimpulse, die im Crashfall auf die Insassen wirken, als möglicherweise ursächlich für die Entstehung von HWS-Distorsionen angesehen. In der vorliegenden Arbeit wird untersucht, welchen Einfluss konstruktive Veränderungen, die durch Versicherungseinstufungstests bedingt werden, auf die Beschleunigungs- und Verzögerungsimpulse im Fahrzeuginnenraum haben. Versuche zum Fußgängerschutz wurden einvernehmlich nicht durchgeführt, da die Fahrzeuge noch nicht konsequent nach Fußgängerschutzkriterien konzipiert werden. Die Untersuchungsmethode lässt sich gliedern in: - Analyse von internationalen Versicherungssystemen und Analyse der aus den Versicherungseinstufungstests resultierenden Veränderungen von Fahrzeugstrukturen; - Durchführung und Analyse von eigenen Aufprallversuchen mit Fahrzeugteilstrukturen und vergleichende Analyse von Vollfahrzeugversuchen der Versicherungswirtschaft; Zusammenführen der getätigten Schritte. Bei der Ersteinstufung eines Pkw in die Vollversicherung dient der Versicherungseinstufungstest des RCAR/AZT (Prüfgeschwindigkeit 15 km/h) zur Bestimmung der Schadenshöhe und damit zur Einstufung in eine Typklasse. In vielen weiteren Staaten dienen dieser oder ähnliche Tests zur Bewertung der Reparaturfreundlichkeit von Pkw. Um bei einem Versicherungseinstufungstest den Schaden möglichst gering zu halten, haben nahezu alle Neufahrzeuge Querträgersysteme mit kostenarm wechselbaren Absorptionselementen, die die Crashenergie gezielt auf kurzem Weg aufnehmen. Durch die neu EG-Richtlinie 2003/102/EG zum Fußgängerschutz müssen zukünftig hinter der Stoßfängeraußenhaut und vor dem massiven Querträger weiche Schäume untergebracht werden. Der Bauraum für Querträger und Energieabsorptionselemente wird dadurch weiter eingeschränkt. Diese Anforderungen veranlassen die Hersteller dazu, die Energieabsorptionselemente steifer zu gestalten, um einen effektiven Energieabbau bei kurzen Stopplängen zu gewährleisten. Durch diese Maßnahmen wird zwar der Insassenschutz bei Frontalaufprallen im Hochgeschwindigkeitsbereich verbessert, es werden aber zugleich höhere Innenraumverzögerungen (schnellerer Anstieg, höhere mittlere Verzögerung) bei Crashs im gesamten Geschwindigkeitsbereich erzeugt. Eine durchgeführte Korrelation zwischen konstruktiven Veränderungen am Fahrzeug und empirisch bestimmten Verzögerungsverläufen zeigte, dass eine günstigere Einstufung in der Fahrzeugvollversicherung nicht zwangsläufig höhere Verzögerungsimpulse für den Innenraum bedingen muss. Bei der Analyse von 172 Crashversuchen des Allianz Zentrums für Technik mit Neufahrzeugen aus den Jahren 1992 bis 2003 zeichnen sich aber statistisch bedeutsame ßnderungen in den Verzögerungsverläufen über die Prüfjahre ab: - Anstieg der Verzögerung wird steiler; - Mittelwert der Verzögerung wird grösser; - Zeitdauer bis zum Auftreten der maximalen Verzögerung wird kürzer; - dynamische Gesamtdeformation wird kleiner. Die steife Auslegung der für den Versicherungseinstufungstest relevanten Crashteile verbessert den Insassenschutz bei Hochgeschwindigkeitscrashs. Wenn es sich aber durch weitere Untersuchungen bestätigt, dass höhere Verzögerungs- beziehungsweise Beschleunigungsimpulse die Auftretenswahrscheinlichkeit von HWS-Verletzungen im Niedriggeschwindigkeitsbereich vergrößern, so sollten gezielt Maßnahmen zur Verringerung dieser Verletzungsrisiken ergriffen werden. Dazu gehören die weitere Optimierung der Sitzstrukturen einschließlich der Kopfstützen und die Entwicklung adaptiver Crashstrukturen, die dem Crashfall angepasste Kraft-Weg-Kennlinien ermöglichen.