TY - GEN
T1 - Crashworthiness enhancement of a composite intensive, multimaterial fully- electric urban car
AU - Holtz, J.
AU - Eguia, I.
AU - Pedersen, M.
AU - Molinero, R.
AU - Tress, M.
AU - Torres, Ruben
AU - Finez, Javier
N1 - Publisher Copyright:
© 2016, Institution of Engineering and Technology. All rights reserved.
PY - 2016
Y1 - 2016
N2 - The purpose of this study is to present the activities carried out with the aim to obtain the best-in-class rating (following Euro NCAP protocols) of a subcompact urban electric car, BEHICLE, featuring a composite intensive, multimaterial body-in-white that allows for a total car weight below 600 kg. Lightweighting is ensured via reinforced composite panels, aluminium greenhouse, and energy absorbing thermoplastic composites distributed along the entire bodywork, mechanically joined to form a solid structure. In order to ensure adult occupant protection, apart from a carefully designed passenger compartment, two complementary strategies have been followed: on the one hand, the design of an efficient frontal and lateral crumple zone, taking advantage of the energy absorbing capability of thermoplastic composites; on the other hand, a full set of passive restraint systems has been dimensioned and implemented, consisting of a driver airbag, side and curtain airbags, and a four-point belt system for the front centred occupant. The entire iterative development process has been conducted using CAE tools in an effort to minimize costs, allowing for both full vehicle and sled system virtual testing and analysis.
AB - The purpose of this study is to present the activities carried out with the aim to obtain the best-in-class rating (following Euro NCAP protocols) of a subcompact urban electric car, BEHICLE, featuring a composite intensive, multimaterial body-in-white that allows for a total car weight below 600 kg. Lightweighting is ensured via reinforced composite panels, aluminium greenhouse, and energy absorbing thermoplastic composites distributed along the entire bodywork, mechanically joined to form a solid structure. In order to ensure adult occupant protection, apart from a carefully designed passenger compartment, two complementary strategies have been followed: on the one hand, the design of an efficient frontal and lateral crumple zone, taking advantage of the energy absorbing capability of thermoplastic composites; on the other hand, a full set of passive restraint systems has been dimensioned and implemented, consisting of a driver airbag, side and curtain airbags, and a four-point belt system for the front centred occupant. The entire iterative development process has been conducted using CAE tools in an effort to minimize costs, allowing for both full vehicle and sled system virtual testing and analysis.
KW - Crashworthiness
KW - Euro NCAP
KW - Lightweight
KW - Multimaterial
KW - Occupant protection
UR - https://www.scopus.com/pages/publications/85013329022
U2 - 10.1049/cp.2016.0978
DO - 10.1049/cp.2016.0978
M3 - Conference contribution
AN - SCOPUS:85013329022
SN - 9781785612947
T3 - IET Conference Publications
BT - IET Conference Publications
PB - Institution of Engineering and Technology
T2 - 6th Hybrid and Electric Vehicles Conference, HEVC 2016
Y2 - 2 November 2016 through 3 November 2016
ER -
