Battery management systems and inductive balancing Alex Van den Bossche and Ali Farzan Moghaddam

Format:

Book

Author/Creator:

Bossche, Alex van den

Moghaddam, Ali Farzan, author.

Contributor:

Institution of Engineering and Technology, publisher.

Series:

IET energy engineering series 198

Energy Engineering

Language:

English

Subjects (All):

Electric batteries.

Electric batteries--Design and construction.

Electronic books.

batteries (electrical).

e-books.

Physical Description:

1 online resource

Place of Publication:

Stevenage, Herts, United Kingdom Published by The Institution of Engineering and Technology 2021

Summary:

This book addresses practical approaches to managing batteries to ensure their reliability and longevity. Batteries are key to the energy transition, for both stationary and mobile applications, but their inner workings must be understood in order to ensure effective management

Contents:

Intro

Title

Copyright

Contents

About the authors

Preface

Acknowledgements

Summary

Abbreviations

Part I Introduction to batteries and balancing

Chapter 1 Introduction to batteries

1.1 Preface

1.2 History of the battery

1.3 Introduction of the battery

1.4 Lithium-based batteries

1.5 Charging and discharging

1.6 Chemistry

1.7 Charging methods

1.8 Characteristics

1.9 Application areas

References

Appendix A: Open-circuit voltage (OCV)

Chapter 2 Discussion about batteries

2.1 Introduction

2.2 Are minerals available?

2.2.1 Lead-acid batteries

2.2.2 Lithium-ion batteries

2.3 Life extension

2.4 Reuse or second life

2.5 Recycling

2.6 CO2 emission to produce a kWh of battery storage

2.6.1 Lead-acid and CO2

2.6.2 Lithium ion and CO2

2.7 Avoiding battery storage

2.7.1 Water heaters

2.7.2 Storing cold

2.7.3 Direct use of solar PV

2.7.4 Flywheel storage

2.7.5 Gravity storage

2.7.6 Compressed air

2.7.7 Seasonal storage

Chapter 3 Overview of battery types

3.1 Introduction

3.2 Overview of actual types

3.3 Batteries with water-based electrolytes

3.3.1 Lead-acid

3.3.2 Nickel-metal hydride NiMH

3.3.3 Salt water battery

3.3.4 Rechargeable alkaline battery

3.4 Organic electrolyte-based batteries

3.4.1 Lithium family

3.4.2 Li-ion battery characteristic

3.4.3 Lithium-iron-phosphate characteristic LiFePO4

3.4.4 Lithium metal batteries

3.4.5 Sodium-, potassium-, magnesium-, calcium-, zinc-, and aluminium-based batteries

3.5 Molten salt batteries

3.6 Fuel cells

3.6.1 Low-temperature fuel cells LTFC

3.6.2 High-temperature fuel cells HTFC

3.7 Flow battery systems

3.8 Nernst and electrochemical potential

Chapter 4 Purpose of BMS, state of charge, state of health

4.1 State of charge, state of health, and state of power

4.1.1 State of charge

4.1.2 State of health

4.1.3 State of power

4.2 Sophisticated SoH modelling by BMS

4.3 Battery management system

4.4 Battery configuration

4.5 Types of battery management systems

4.5.1 One cell too low, one cell too high principle

4.5.2 Shunt resistor switching balancing (passive)

4.5.3 Capacitive shunting balancing (active)

4.5.4 Inductor balancing (active)

4.5.5 Transformer balancing (active)

4.5.6 Cuk converter balancing (active)

4.5.7 Flyback converter balancing (active)

4.5.8 Forward converter balancing (active)

Part II Passive cell balancing circuits

Chapter 5 A smart high-voltage cell detecting and equalizing

5.1 Introduction

5.2 Possible technologies

Section 1: High-voltage cell detecting and equalizing circuit

5.3 Proposed smart high-voltage cell equalizing detection

5.4 Practical implementation

5.5 Experimental results

5.6 Communication between battery and charger via Bluetooth

Notes:

Includes bibliographical references and index

Other Format:

ebook version :

Print version Van den Bossche, Alex. Battery Management Systems and Inductive Balancing

ISBN:

9781839533587

1839533587

OCLC:

1276853480

Access Restriction:

Restricted for use by site license