Practical Battery Design And Control
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Practical Battery Design and Control
Battery technologies play a vital role in day-to-day life, and with the continued growth of the battery market, there is an increasing demand for a comprehensive text such as this, that encompasses aspects of electrochemistry, materials science, physical chemistry, and machine learning. Aimed at early-to-mid career battery engineers, this book addresses common problems that are likely to be encountered on the job. This book discusses several topics, including the prediction of battery longevity, how to extend battery life with machine learning algorithms, cost reduction and sustainability, and battery charging problems relating to wearables, electric vehicles, drones, smart phones, laptops, and portable devices. Designed to help readers obtain practical knowledge through intuitive explanations and broad coverage of battery topics, this one-of-a-kind book is a must have resource for practicing battery engineers throughout their career.
Lithium-Ion Battery Standards
Lithium-Ion Battery Standards is an essential guide for understanding Lithium-ion batteries and the standards that govern them. This comprehensive resource covers everything from the basics of Lithium-ion battery systems to the intricacies of safety, design, and regulatory requirements. The book explains the differences between Lithium-ion batteries and other battery systems, highlighting the critical importance of system integration and design. It offers insights into battery system architectures, terminology, and the safety features that can be specified for Lithium-ion cells. The reader will find a detailed exploration of safety concerns, including failure modes in electronic components and high voltage systems, as well as an in-depth discussion on the differences between standards and regulatory requirements, both in the U.S. and internationally. The book also covers industry-specific standards, providing a comprehensive list of applicable regulations for various battery system architectures. Additionally, it includes practical information on the shipping and labeling of Lithium-ion batteries, with special attention to prototype and damaged batteries. This is the go-to resource for understanding and navigating the complex world of Lithium-ion battery standards and regulations.
Battery Management Systems, Volume III: Physics-Based Methods
This book -- the third and final volume in a series describing battery-management systems – shows you how to use physics-based models of battery cells in a computationally efficient way for optimal battery-pack management and control to maximize battery-pack performance and extend life. It covers the foundations of electrochemical model-based battery management system while introducing and teaching the state of the art in physics-based methods for battery management. Building upon the content in volumes I and II, the book helps you identify parameter values for physics-based models of a commercial lithium-ion battery cell without requiring cell teardown; shows you how to estimate the internal electrochemical state of all cells in a battery pack in a computationally efficient way during operation using these physics-based models; demonstrates the use the models plus state estimates in a battery management system to optimize fast-charge of battery packs to minimize charge time while also maximizing battery service life; and takes you step-by-step through the use models to optimize the instantaneous power that can be demanded from the battery pack while also maximizing battery service life. The book also demonstrates how to overcome the primary roadblocks to implementing physics-based method for battery management: the computational-complexity roadblock, the parameter-identification roadblock, and the control-optimization roadblock. It also uncovers the fundamental flaw in all present “state of art” methods and shows you why all BMS based on equivalent-circuit models must be designed with over-conservative assumptions. This is a strong resource for battery engineers, chemists, researchers, and educators who are interested in advanced battery management systems and strategies based on the best available understanding of how battery cells operate.