VESENJAK, Matej ;REN, Zoran . Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact. Strojniški vestnik - Journal of Mechanical Engineering, [S.l.], v. 49, n.12, p. 586-592, november 2017. ISSN 0039-2480. Available at: <https://www.sv-jme.eu/sl/article/dynamic-analysis-of-a-road-restraint-systems-deformation-resulting-from-a-vehicle-impact/>. Date accessed: 09 dec. 2024. doi:http://dx.doi.org/.
Vesenjak, M., & Ren, Z. (2003). Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact. Strojniški vestnik - Journal of Mechanical Engineering, 49(12), 586-592. doi:http://dx.doi.org/
@article{., author = {Matej Vesenjak and Zoran Ren}, title = {Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {49}, number = {12}, year = {2003}, keywords = {roadside safety; road-restraint bariers; dynamic analysis; numerical simulations; nonlinear simulations; }, abstract = {This paper describes a dynamic analysis of a steel road-restraint system that is used on public roads to prevent a vehicle from veering off the road or breaking through to the opposite side of the road. The European standard EN 1317 provides the exact criteria that the road-restraint system has to fulfill. Practical observations of installed systems indicate that the current distance spacer is too stiff, which results in unacceptable decelerations during vehicle impact. The stiffness of the restraint system in the initial phase of the crash is largely attributed to the distance-spacer design. The purpose of this research was to evaluate new designs of the distance spacer with increased crash-energy absorption due to a more controlled deformation during vehicle impact. The stiffness of various designs was evaluated with nonlinear dynamic (material, geometric and structural-contact nonlinearity) analysis of a three-dimensional road-restraint system within the framework of the finite-element method. The computational analyses prove that the currently used distance spacer is indeed far too stiff and that the new designs ensure controllable elasto-plastic deformation and absorb more crash energy, which in turn reduces decelerations during the impact and increases the safety of road users.}, issn = {0039-2480}, pages = {586-592}, doi = {}, url = {https://www.sv-jme.eu/sl/article/dynamic-analysis-of-a-road-restraint-systems-deformation-resulting-from-a-vehicle-impact/} }
Vesenjak, M.,Ren, Z. 2003 November 49. Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact. Strojniški vestnik - Journal of Mechanical Engineering. [Online] 49:12
%A Vesenjak, Matej %A Ren, Zoran %D 2003 %T Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact %B 2003 %9 roadside safety; road-restraint bariers; dynamic analysis; numerical simulations; nonlinear simulations; %! Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact %K roadside safety; road-restraint bariers; dynamic analysis; numerical simulations; nonlinear simulations; %X This paper describes a dynamic analysis of a steel road-restraint system that is used on public roads to prevent a vehicle from veering off the road or breaking through to the opposite side of the road. The European standard EN 1317 provides the exact criteria that the road-restraint system has to fulfill. Practical observations of installed systems indicate that the current distance spacer is too stiff, which results in unacceptable decelerations during vehicle impact. The stiffness of the restraint system in the initial phase of the crash is largely attributed to the distance-spacer design. The purpose of this research was to evaluate new designs of the distance spacer with increased crash-energy absorption due to a more controlled deformation during vehicle impact. The stiffness of various designs was evaluated with nonlinear dynamic (material, geometric and structural-contact nonlinearity) analysis of a three-dimensional road-restraint system within the framework of the finite-element method. The computational analyses prove that the currently used distance spacer is indeed far too stiff and that the new designs ensure controllable elasto-plastic deformation and absorb more crash energy, which in turn reduces decelerations during the impact and increases the safety of road users. %U https://www.sv-jme.eu/sl/article/dynamic-analysis-of-a-road-restraint-systems-deformation-resulting-from-a-vehicle-impact/ %0 Journal Article %R %& 586 %P 7 %J Strojniški vestnik - Journal of Mechanical Engineering %V 49 %N 12 %@ 0039-2480 %8 2017-11-11 %7 2017-11-11
Vesenjak, Matej, & Zoran Ren. "Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact." Strojniški vestnik - Journal of Mechanical Engineering [Online], 49.12 (2003): 586-592. Web. 09 Dec. 2024
TY - JOUR AU - Vesenjak, Matej AU - Ren, Zoran PY - 2003 TI - Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact JF - Strojniški vestnik - Journal of Mechanical Engineering DO - KW - roadside safety; road-restraint bariers; dynamic analysis; numerical simulations; nonlinear simulations; N2 - This paper describes a dynamic analysis of a steel road-restraint system that is used on public roads to prevent a vehicle from veering off the road or breaking through to the opposite side of the road. The European standard EN 1317 provides the exact criteria that the road-restraint system has to fulfill. Practical observations of installed systems indicate that the current distance spacer is too stiff, which results in unacceptable decelerations during vehicle impact. The stiffness of the restraint system in the initial phase of the crash is largely attributed to the distance-spacer design. The purpose of this research was to evaluate new designs of the distance spacer with increased crash-energy absorption due to a more controlled deformation during vehicle impact. The stiffness of various designs was evaluated with nonlinear dynamic (material, geometric and structural-contact nonlinearity) analysis of a three-dimensional road-restraint system within the framework of the finite-element method. The computational analyses prove that the currently used distance spacer is indeed far too stiff and that the new designs ensure controllable elasto-plastic deformation and absorb more crash energy, which in turn reduces decelerations during the impact and increases the safety of road users. UR - https://www.sv-jme.eu/sl/article/dynamic-analysis-of-a-road-restraint-systems-deformation-resulting-from-a-vehicle-impact/
@article{{}{.}, author = {Vesenjak, M., Ren, Z.}, title = {Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {49}, number = {12}, year = {2003}, doi = {}, url = {https://www.sv-jme.eu/sl/article/dynamic-analysis-of-a-road-restraint-systems-deformation-resulting-from-a-vehicle-impact/} }
TY - JOUR AU - Vesenjak, Matej AU - Ren, Zoran PY - 2017/11/11 TI - Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact JF - Strojniški vestnik - Journal of Mechanical Engineering; Vol 49, No 12 (2003): Strojniški vestnik - Journal of Mechanical Engineering DO - KW - roadside safety, road-restraint bariers, dynamic analysis, numerical simulations, nonlinear simulations, N2 - This paper describes a dynamic analysis of a steel road-restraint system that is used on public roads to prevent a vehicle from veering off the road or breaking through to the opposite side of the road. The European standard EN 1317 provides the exact criteria that the road-restraint system has to fulfill. Practical observations of installed systems indicate that the current distance spacer is too stiff, which results in unacceptable decelerations during vehicle impact. The stiffness of the restraint system in the initial phase of the crash is largely attributed to the distance-spacer design. The purpose of this research was to evaluate new designs of the distance spacer with increased crash-energy absorption due to a more controlled deformation during vehicle impact. The stiffness of various designs was evaluated with nonlinear dynamic (material, geometric and structural-contact nonlinearity) analysis of a three-dimensional road-restraint system within the framework of the finite-element method. The computational analyses prove that the currently used distance spacer is indeed far too stiff and that the new designs ensure controllable elasto-plastic deformation and absorb more crash energy, which in turn reduces decelerations during the impact and increases the safety of road users. UR - https://www.sv-jme.eu/sl/article/dynamic-analysis-of-a-road-restraint-systems-deformation-resulting-from-a-vehicle-impact/
Vesenjak, Matej, AND Ren, Zoran. "Dynamic Analysis of a Road-Restraint System’s Deformation Resulting from a Vehicle Impact" Strojniški vestnik - Journal of Mechanical Engineering [Online], Volume 49 Number 12 (11 November 2017)
Strojniški vestnik - Journal of Mechanical Engineering 49(2003)12, 586-592
© The Authors, CC-BY 4.0 Int. Change in copyright policy from 2022, Jan 1st.
This paper describes a dynamic analysis of a steel road-restraint system that is used on public roads to prevent a vehicle from veering off the road or breaking through to the opposite side of the road. The European standard EN 1317 provides the exact criteria that the road-restraint system has to fulfill. Practical observations of installed systems indicate that the current distance spacer is too stiff, which results in unacceptable decelerations during vehicle impact. The stiffness of the restraint system in the initial phase of the crash is largely attributed to the distance-spacer design. The purpose of this research was to evaluate new designs of the distance spacer with increased crash-energy absorption due to a more controlled deformation during vehicle impact. The stiffness of various designs was evaluated with nonlinear dynamic (material, geometric and structural-contact nonlinearity) analysis of a three-dimensional road-restraint system within the framework of the finite-element method. The computational analyses prove that the currently used distance spacer is indeed far too stiff and that the new designs ensure controllable elasto-plastic deformation and absorb more crash energy, which in turn reduces decelerations during the impact and increases the safety of road users.