TY - JOUR
T1 - System design and control strategy for a battery/supercapacitor electric bus with an integrated fast charger/bus stop station
AU - Hung, Yi Hsuan
AU - Li, Hong Wei
AU - Lee, Hung Chun
AU - Chen, Chien An
AU - Wu, Chien Hsun
PY - 2013
Y1 - 2013
N2 - The purposes of this study are to 1) select a suitable size of dual energy sources, 2) develop a dynamic model for a battery/supercapacitor (SC) electric bus with an integrated fast charger/bus stop station, and 3) establish control strategies among the fast charger, batteries, and the SC module. For 1), a global search method was used to locate a suitable-sized battery set and SCs under a preset cost function and basic properties. The cost ratio (CR) was calculated to maximize the energy storage capacity. For 2), 10 subsystems of the electric bus, including the driver maneuver, traction motor, the lithium battery module, the SCs, the onboard DC/DC converter, the longitudinal vehicle dynamics, accessories, and the transmission were constructed. For the fast charger/bus stop station, an AC/DC inverter was modeled. All modulized subsystems were then integrated into the vehicle/station simulator. For 3), the 10-mode control strategy properly conducts energy management using rule-based control laws, which are functions of vehicle speed, state-of charges (SOCs) of dual energy sources, and driving conditions. The control output section delivers the commands to the subsystem controllers, relays, and converters/inverters. The fast charger/bus stop station charges batteries and SCs when proper commands were sent by the vehicle control unit (VCU). All simulation results demonstrate that the optimized sizing of dual energy sources, electric bus and charger dynamics, and VCU control strategies were successfully completed. The feasibility study and specification design of Taiwan's E-Bus with a fast-charge station will be conducted through this study in the near future.
AB - The purposes of this study are to 1) select a suitable size of dual energy sources, 2) develop a dynamic model for a battery/supercapacitor (SC) electric bus with an integrated fast charger/bus stop station, and 3) establish control strategies among the fast charger, batteries, and the SC module. For 1), a global search method was used to locate a suitable-sized battery set and SCs under a preset cost function and basic properties. The cost ratio (CR) was calculated to maximize the energy storage capacity. For 2), 10 subsystems of the electric bus, including the driver maneuver, traction motor, the lithium battery module, the SCs, the onboard DC/DC converter, the longitudinal vehicle dynamics, accessories, and the transmission were constructed. For the fast charger/bus stop station, an AC/DC inverter was modeled. All modulized subsystems were then integrated into the vehicle/station simulator. For 3), the 10-mode control strategy properly conducts energy management using rule-based control laws, which are functions of vehicle speed, state-of charges (SOCs) of dual energy sources, and driving conditions. The control output section delivers the commands to the subsystem controllers, relays, and converters/inverters. The fast charger/bus stop station charges batteries and SCs when proper commands were sent by the vehicle control unit (VCU). All simulation results demonstrate that the optimized sizing of dual energy sources, electric bus and charger dynamics, and VCU control strategies were successfully completed. The feasibility study and specification design of Taiwan's E-Bus with a fast-charge station will be conducted through this study in the near future.
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U2 - 10.4271/2013-01-1459
DO - 10.4271/2013-01-1459
M3 - Conference article
AN - SCOPUS:84881194998
SN - 0148-7191
VL - 2
JO - SAE Technical Papers
JF - SAE Technical Papers
T2 - SAE 2013 World Congress and Exhibition
Y2 - 16 April 2013 through 18 April 2013
ER -