TY - GEN
T1 - Hybrid energy storage system integration for vehicles
AU - Wang, Jia
AU - Li, Kun
AU - Lv, Qin
AU - Zhou, Hai
AU - Shang, Li
PY - 2010
Y1 - 2010
N2 - Energy consumption and the associated environmental impact are a pressing challenge faced by the transportation sector. Emerging electric-drive vehicles have shown promises for substantial reductions in petroleum use and vehicle emissions. Their success, however, has been hindered by the limitations of energy storage technologies. Existing in-vehicle Lithium-ion battery systems are bulky, expensive, and unreliable. Energy storage system (ESS) design and optimization is essential for emerging transportation electrification. This paper presents an integrated ESS modeling, design and optimization framework targeting emerging electric-drive vehicles. Based on an ESS modeling solution that considers major run-time and long-term battery effects, the proposed framework unifies design-time optimization and run-time control. It conducts statistical optimization for ESS cost and lifetime, which jointly considers the variances of ESS due to manufacture tolerance and heterogeneous driver-specific run-time use. It optimizes ESS design by incorporating complementary energy storage technologies, e.g., Lithium-ion batteries and ultracapacitors. Using physical measurements of battery manufacture variation and real-world user driving profiles, our experimental study has demonstrated that the proposed framework can effectively explore the statistical design space, and produce cost-efficient ESS solutions with statistical system lifetime guarantee.
AB - Energy consumption and the associated environmental impact are a pressing challenge faced by the transportation sector. Emerging electric-drive vehicles have shown promises for substantial reductions in petroleum use and vehicle emissions. Their success, however, has been hindered by the limitations of energy storage technologies. Existing in-vehicle Lithium-ion battery systems are bulky, expensive, and unreliable. Energy storage system (ESS) design and optimization is essential for emerging transportation electrification. This paper presents an integrated ESS modeling, design and optimization framework targeting emerging electric-drive vehicles. Based on an ESS modeling solution that considers major run-time and long-term battery effects, the proposed framework unifies design-time optimization and run-time control. It conducts statistical optimization for ESS cost and lifetime, which jointly considers the variances of ESS due to manufacture tolerance and heterogeneous driver-specific run-time use. It optimizes ESS design by incorporating complementary energy storage technologies, e.g., Lithium-ion batteries and ultracapacitors. Using physical measurements of battery manufacture variation and real-world user driving profiles, our experimental study has demonstrated that the proposed framework can effectively explore the statistical design space, and produce cost-efficient ESS solutions with statistical system lifetime guarantee.
KW - Battery
KW - Design
KW - Electric-drive vehicle
KW - Energy storage system
KW - Optimization
UR - http://www.scopus.com/inward/record.url?scp=77957937483&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=77957937483&partnerID=8YFLogxK
U2 - 10.1145/1840845.1840925
DO - 10.1145/1840845.1840925
M3 - Conference contribution
AN - SCOPUS:77957937483
SN - 9781450301466
T3 - Proceedings of the International Symposium on Low Power Electronics and Design
SP - 369
EP - 374
BT - ISLPED'10 - Proceedings of the 16th ACM/IEEE International Symposium on Low-Power Electronics and Design
T2 - 16th ACM/IEEE International Symposium on Low-Power Electronics and Design, ISLPED'10
Y2 - 18 August 2010 through 20 August 2010
ER -
