The aim of this paper is to design and analyze cost-effective and high energy absorbing buffer systems for high speed roadways. Unlike conventional crash cushions, the proposed buffer design is based on the assembly of a series of cylindrical hollow tubes (cells) with thorough slots around the cells. The idea is that during the collisions, the kinetic energy of the errant vehicles will be absorbed by the progressive deformation of the cells, hence minimizing damage to the vehicle and allowing a comfortable ride down deceleration of the vehicle’s occupants. As the cell was the fundamental unit of the buffer design, three cells with different geometry were studied to understand the underlying deformation of the individual cells. Nonlinear quasi-static tests using three-dimensional (3D) finite element (FE) simulation and experimental techniques were performed to evaluate the deformation and energy absorption capacity of the cells. Simulation results matched closely with experimental ones with relatively small errors. Based on the experimental results of single cells, a number of potential buffer systems were designed for 80 and 100 km/h speed roadways. Results indicate that the buffers with larger diameter cells are favorable to be used in high speed zones as they reduce the overall size of buffers and contain less number of cells, while being able to absorb the required amount of impact energy. Consequently, they are found to result in a reduced cost associated with materials and fabrication. All the buffer designs were relatively shorter than commercially available buffers used in roadways. In addition, due to their reduced and compact size, the designed buffers can potentially be used in a space limited and hazardous road environment to reduce the vehicle crash with the fixed objects.
References
[1]
BITRE (2000) Cost of Road Crashes in Australia. Bureau of Infrastructure, Transport and Regional Economics, Canbera, Australia.
[2]
BITRE (2011) Cost of Road Crashes in Australia. Bureau of Infrastructure, Transport and Regional Economics, Canbera, Australia.
[3]
IIHS (2011) Fatality Facts: Collisions with Fixed Objects and Animals. Insurance Institute for Highway Safety.
[4]
Berg, A. and Ahlgrimm, J. (2010) Tree Impacts—Still One of the Most Important Focal Points of Road Deaths. Berichte Bundesanst, Fuer Strassenwes, Unterreihe Fahrzeugtechnik, No. 77.
[5]
Zivkovic G. (2008) Energy Absorbing Pole/Tree Buffer. Automotive Safety Engineering Pty Ltd., Adelaide, Australia.
[6]
Lake, G. (2010) Local Government and Road Safety. Journal of the Australasian College of Road Safety, 21, 17-19.
[7]
Wang, Y.G., Chen, K.M., Ci, Y.S. and Hu, L.W. (2011) Safety Performance Audit for Roadside and Median Barriers Using Freeway Crash Records: Case Study in Jiangxi, China. Scientia Iranica, 18, 1222-1230.
http://dx.doi.org/10.1016/j.scient.2011.11.020
[8]
Lu, G. and Yu, T.X. (2003) Energy Absorption of Structures and Materials. Woodhead Publishing Limited, Cambridge, UK.
[9]
Njuguna, J. (2011) The Application of Energy Absorbing Structures on Side Impact Protection Systems. International Journal of Computer Applications in Technology, 40, 208-207. http://dx.doi.org/10.1504/IJCAT.2011.041657
[10]
Baker, B.C., Nolan, J.M., O’Neill, B. and Genetos, A.P. (2008) Crash Compatibility between Cars and Light Trucks: Benefits of Lowering Front-End Energy-Absorbing Structure in SUVs and Pickups. Accident Analysis & Prevention, 40, 116-125. http://dx.doi.org/10.1016/j.aap.2007.04.008
[11]
Tay, Y.Y., Lim, C.S. and Lankarani, H.M. (2014) A Finite Element Analysis of High-Energy Absorption Cellular Materials in Enhancing Passive Safety of Road Vehicles in Side-Impact Accidents. International Journal of Crashworthiness, 19, 288-300. http://dx.doi.org/10.1080/13588265.2014.893789
[12]
Xie, S., Liang, X. and Zhou, H. (2015) Design and Analysis of a Composite Energy-Absorbing Structure for Use on Railway Vehicles. Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail and Rapid Transit, 0954409714566058.
[13]
Otte, D., Sferco, R., Schaefer, R., Eis, V., Thomas, P. and Welsh, R. (2009) Assessment of Injury Severity of Nearside Occupants in Pole Impacts to Side of Passenger Cars in European Traffic Accidents—Analysis of German and UK In-Depth Data.
[14]
Lacy, K., Srinivasan, R., Zegeer, C., Pfefer, R., Neuman, T., Slack, K. and Hardy, K. (2004) NCHRP Report 500: Guidance for Implementation of the AASHTO Strategic Highway Safety Plan—Volume 8: A Guide for Reducing Collisions Involving Utility Poles. Transportation Research Board of the National Academies, Washington DC.
[15]
Elvik, R. (1995) The Safety Value of Guardrails and Crash Cushions: A Meta-Analysis of Evidence from Evaluation Studies. Accident Analysis & Prevention, 27, 523-549. http://dx.doi.org/10.1016/0001-4575(95)00003-I
[16]
Pang, T.Y. and Tristian, H. (2014) Experimental and Finite Element Nonlinear Dynamics Analysis of Formula SAE Impact Attenuator. In: Jazar, R.N. and Dai, L., Eds., Nonlinear Approaches in Engineering Applications 2, Springer, New York, 213-229. http://dx.doi.org/10.1007/978-1-4614-6877-6_7
[17]
Thiyahuddin, M.I., Gu, Y.T., Thambiratnam, D.P. and Thilakarathna, H.M. (2014) Impact and Energy Absorption of Portable Water-Filled Road Safety Barrier System Fitted with Foam. International Journal of Impact Engineering, 72, 26-39. http://dx.doi.org/10.1016/j.ijimpeng.2014.04.008
[18]
Roberts, M. (2014) Development of a Finite Element Model for Predicting the Impact Energy Absorbing Performance of a Composite Structure. Masters Theses Project Reports, California Polytechnic State University, San Luis Obispo, CA, USA.
[19]
Boria, S. and Pettinari, S. (2014) Mathematical Design of Electric Vehicle Impact Attenuators: Metallic vs Composite Material. Composite Structures, 115, 51-59. http://dx.doi.org/10.1016/j.compstruct.2014.04.010
[20]
Wilson, A.H. (1979) Roadside Tree/Pole Crash Barrier Field Test. Jet Propulsion Laboratory, California Institute of Technology, Pasadena.
[21]
Krage, W.G. and Denman, O.S. (1988) Collapsible Highway Barrier. US4784515 A.
[22]
Nabors, D.T. and Hossain, M. (1998) Development of a Low-Cost Crash Cushion Using Recycled Automobile Tires.
[23]
Michalec, C.R. (2005) Development of an Optimal Impact Energy Absorber for Highway Crash Cushions. Texas A&M University, College Station.
[24]
Whitehead, M. (2014) Road Safety Barrier Systems, End Treatments and Other Related Road Safety Devices. Department of Transport and Main Roads, Queensland.
Zivkovic, G. and Day, J. (2012) Safety Barrier Product Information Report. Automotive Safety Engineering Pty Ltd., Adelaide.
[30]
Zivkovic, G. and Winfield, M. (2010) A Study into the Lateral Compression of a 115 mm Diameter Steel Tube. Automotive Safety Engineering Pty Ltd., Adelaide.
[31]
Ansys (2015) Finite Element Analysis Tool. Ansys Inc. http://www.ansys.com
[32]
Fildes, B.N., Lane, J.C., Lenard, J. and Vulcan, A.P. (1991) Passenger Cars and Occupant Injury. Monash University Accident Research Centre.
[33]
Sicking, D., Mak, K., Rohde, J. and Reid, J. (2009) Manual for Assessing Safety Hardware. American Association of State Highway Transportation Officials, Washington DC.
