Design Approach for Improving Current Concrete Median Barriers on Highways in South Korea
Publication: Journal of Performance of Constructed Facilities
Volume 32, Issue 3
Abstract
The speed of vehicles on highways has increased due to improved driving environments. However, this increased speed has become one of the main reasons for collisions between vehicles and road barriers. Several fatalities have occurred recently in South Korea as a result of fragmentation due to the collision of a vehicle with a concrete median barrier. The current impact level of a concrete median barrier (CMB) is SB5-B (270 kJ). However, the impact level of the collision was estimated to be over SB7 (2,300 kJ). Inspired by this, many engineers agree on the use of improved CMBs to reduce the amount of concrete fragmentations due to vehicle impact. In the present study, several designs of CMBs have been presented and a numerical analysis was conducted to evaluate the impact resistance of CMBs against vehicle impact loadings. A new impact severity [SB5-B(20A)] was also proposed. Firstly, commercially available wire-mesh reinforcements and an increase in cross section were considered as design modifications under the proposed impact severity. In addition to this, a novel CMB, the High CMB (Hi-CMB) has also been introduced in this paper which has several shock absorbers without incurring any increase in construction cost. The newly developed Hi-CMB was evaluated by the developed collision model. It was found that the Hi-CMB with shock absorbers can reduce concrete fragmentation by 99% compared to the current type of CMB in South Korea. Shock absorbers generally activated and increased the impact resistance especially at high impact levels. As a result, an enhanced impact resistance, due to the addition of reinforcement, section expansion, and shock absorbers was obtained under SB5-B(20A). The mixed effects of those design modifications led to an effective design of CMBs against the impact loadings of heavy trucks.
Get full access to this article
View all available purchase options and get full access to this article.
Acknowledgments
The authors gratefully acknowledge the support of Korean Expressway Corporation Research Institute and Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Science, Information and Communication Technology (ICT) and Future Planning (NRF-2015R1C1A1A02036617).
References
AASHTO. (2012). AASHTO LRFD bridge design specifications, customary U.S. units, 6th Ed., Washington, DC.
CEN (European Committee for Normalization). (2012). “Road restraint systems.” EN 1317, Brussels, Belgium.
El-Tawil, S., Severino, E., and Fonseca, P. (2005). “Vehicle collision with bridge piers.” J. Bridge Eng., 345–353.
KMOLIT (Korea Ministry of Land, Infrastructure and Transport). (2015). Real impact test guideline for vehicle safety guard 2015, Sejong, South Korea.
Korea Expressway Corporation. (2015). 2014 highway traffic volume data, Dongtan, South Korea.
Lee, J., and Lopez, M. M. (2014). “An experimental study on fracture energy of plain concrete.” J. Eng. Mater. Technol., 8(2), 129–139.
Lee, J., Zi, G., Lee, I., Jeong, Y., Kim, K., and Kim, W. (2017). “Numerical simulation on concrete median barrier for reducing concrete fragment under harsh impact loading of a 25-ton truck.” J. Eng. Mater. Technol., 139(2), 021015.
LS-DYNA [Computer software]. Livermore Software Technology Corporation, Livermore, CA.
MC2010. (2012). “fib Model Code 2010.” Final Draft, Vol. 1, fib bulletin 66.
Murray, Y. D. (2007). “Users manual for LS-DYNA concrete material model 159.”, Federal Highway Administration, Washington, DC.
Murray, Y. D., Abu-Odeh, A., and Bligh, R. (2007). “Evaluation of LS-DYNA concrete material model 159.”, Federal Highway Administration, Washington, DC.
Thai, D., Kim, S., and Lee, H. (2014). “Effects of reinforcement ratio and arrangement on the structural behavior of a nuclear building under aircraft impact.” Nucl. Eng. Des., 276, 228–240.
Yi, K., Hedrick, K., and Lee, S. (1999). “Estimation of tire-road friction using observer based identifiers.” Int. J. Veh. Mech. Mobility Veh. Syst. Dyn., 31(4), 233–261.
Information & Authors
Information
Published In
Journal of Performance of Constructed Facilities
Volume 32 • Issue 3 • June 2018
Copyright
©2018 American Society of Civil Engineers.
History
Received: Aug 15, 2017
Accepted: Nov 30, 2017
Published online: Apr 5, 2018
Published in print: Jun 1, 2018
Discussion open until: Sep 5, 2018
Authors
Metrics & Citations
Metrics
Citations
Download citation
If you have the appropriate software installed, you can download article citation data to the citation manager of your choice. Simply select your manager software from the list below and click Download.