Boston, Mass., : Artech House, 2015

1-5231-1698-6

1-63081-024-X

1 online resource (xi, 327 p.) : ill

Artech House power engineering series

621.31242

Electric batteries

Lithium cells - Mathematical models

Battery chargers - Mathematical models

Electric vehicles - Batteries

Lithium cells

Inglese

Includes bibliographical references.

1. Battery Boot Camp -- 2. Equivalent-Circuit Models -- 3. Microscale Cell Models -- 4. Continuum-Scale Cell Models -- 5. State-Space Models and the Discrete-Time Realization Algorithm -- 6. Reduced-Order Models -- 7. Thermal Modeling.

Large-scale battery packs are needed in hybrid and electric vehicles, utilities grid backup and storage, and frequency-regulation applications. In order to maximize battery-pack safety, longevity, and performance, it is important to understand how battery cells work. This first of its kind new resource focuses on developing a mathematical understanding of how electrochemical (battery) cells work, both internally and externally. This comprehensive resource derives physics-based micro-scale model equations, then continuum-scale model equations, and finally reduced-order model equations. This book describes the commonly used equivalent-circuit type battery model and develops equations for superior physics-based models of lithium-ion cells at different length scales. This resource also presents a breakthrough technology called the discrete-time realization algorithmù that automatically converts physics-based models into

high-fidelity approximate reduced-order models.