Wireless charging technology and the future of electric transportation / lead author, In-Soo Suh (Professor, Korea Advanced Institute of Science and Technology) ; co-authors, Dong-Ho Cho [and eight others].

Format:

Book

Author/Creator:

Sŏ, In-su, author.

Cho, Dong-Ho, author.

Contributor:

Society of Automotive Engineers, Content Provider.

Language:

English

Subjects (All):

Electric vehicles--Batteries.

Electric vehicles.

Battery chargers.

Electricity in transportation.

Electronics in transportation.

Electromagnetic induction.

Electric power transmission.

Physical Description:

1 online resource (xiii, 209 pages) : illustrations

Edition:

1st ed.

Place of Publication:

Warrendale, Pennsylvania, USA : SAE International, [2015]

Language Note:

English

Summary:

Covers the current status of wireless power transfer (WPT) technology and its potential applications to the future road and rail transportation systems. The book brings an in-depth analysis of the most important areas of interest in this new area.

Contents:

Intro

Executive Summary

Table of Contents

Foreword

Acknowledgments

Chapter 1 Introduction

1.1 Introduction to Wireless Power Transfer Technology

1.1.1 Theory of Wireless Power Transfer

1.1.2 General Application Field

1.1.2.1 Consumer Electronics

1.1.2.2 Industrial Automation and Heavy Equipment

1.1.2.3 Transports

1.1.2.4 Medical Implants

1.1.3 Technology Development Potential

1.2 Wireless Power Transfer in Transportation

1.2.1 WPT in Automobile Applications

1.3 Micro Mobility and Wireless Power Transfer

1.4 Structure of the Book

References

Chapter 2 Green Transportation and Electric Vehicles

2.1 Future Automotive Power Drive Trend

2.1.1 Motivation

2.1.2 Automotive Industry

2.1.3 Key Elements of Future Automotive Technology

2.1.4 Classifications of the Environmentally Friendly Vehicles

2.1.5 Market Growth

2.1.5.1 U.S. Market Forecasting

2.1.5.2 EU Market Forecasting

2.1.5.3 Japanese Market Forecasting

2.1.5.4 Chinese Market Forecasting

2.2 Intelligent Transportation System

2.2.1 Intelligent Vehicle Technology

2.2.2 Cooperative ITS

2.3 Electric Vehicle Charging Systems

2.3.1 Market Trend

2.3.2 Challenges

2.4 WPT Application to EV

2.4.1 Efficiency of WPT

2.5 Implications of Wireless Charging in Future Transportation

2.5.1 Efficient Power Management

2.5.2 Safety

2.5.3 Convenience

2.5.4 CO2 Reduction

Chapter 3 EV Charging Technology: Conductive and Wireless

3.1 Conductive Charging

3.2 Wireless Charging

3.3 Commercial WPT Technologies

3.4 Rollout of Wireless Charging

Chapter 4 An Overview of OLEV Technology

4.1 Background

4.2 SMFIR Technology

4.3 Overall System

4.3.1 System Operation

4.4 Design of Power Supply Infrastructure

4.4.1 Road-Embedded Power Systems.

4.4.2 Inverter and Electrical Segmentation Design

4.4.3 Power Line Module

4.5 Design of Power Collection Systems

4.5.1 Pick-Up Module

4.5.2 Rectifier and Regulator

4.6 Application of SMFIR Technology to Bus

4.6.1 OLEV Power Supply Infrastructure

4.6.2 Electric Vehicle System Architecture

4.7 Application of SMFIR Technology to Trains

4.7.1 Concept

4.7.2 Main Advantages

Chapter 5 Wireless Power Transfer Technical Issues and Challenges

5.1 Vehicle to Infrastructure Communications

5.2 Alignment to Primary Charging Pad

5.3 Challenge of Gap Variations

5.4 Control of Charging Process

5.5 Obstacle Detection

5.6 Emergency Shut-Down

5.7 Normal Shut-Down

5.8 Electrical Safety: High-Frequency Isolation Transformer

5.9 Emission

5.10 Grid Connection Power Quality

5.11 Installation and Commissioning

5.12 Summary

Chapter 6 Markets, Strategies, and Standards for EVs with WPT

6.1 Introduction

6.2 Optimization Problem for WPT in Electrified Vehicles

6.2.1 Battery Size (kWh)

6.2.2 Power Transfer Rate (kW)

6.2.3 Infrastructure Allocation

6.3 Simulation Approach to Determine an Optimized WPT Infrastructure Design

6.4 Fields of Application for Fleet-Operated Vehicles Using WPT Systems

6.4.1 Harbor Logistics (Small Operating Range)

6.4.2 Local Public Transport (Medium Operating Range)

6.4.3 Long-Distance Heavy Truck Transport (Large Operating Range)

6.5 Conclusions

Chapter 7 Wireless Charging of Consumer Electronics in the Automotive Industry

7.1 Wireless Charging of Consumer Electronics

7.1.1 Wireless Power Transfer Technologies in Hand

7.1.1.1 Inductive Charging Technology

7.1.1.2 Non-Radiative Resonance Charging

7.2 Design Considerations

7.3 Wireless Charging in Automotive Applications.

7.3.1 Physical Safety

7.3.2 Interferences

7.3.3 Vehicle Power Interface

7.3.4 Extremely High Temperature

Chapter 8 Railway Application of WPT

8.1 System Overview of Railway Application of WPT

8.2 Track Segment Switching

8.3 Metro and Light Rail Applications

8.4 TRANSRAPID Maglev Train

8.5 Light Rail Application

8.6 Wireless Low-Floor Train

Chapter 9 Long-Distance Power Transfer

9.1 Introduction

9.2 History of Long-Distance Power Transfer

9.3 Theory of Long-Distance Power Transfer

9.4 Recent Applications of Long-Distance PowerTransfer

9.5 Conclusions

Chapter 10 Industrial Applications of WPT

10.1 System Overview

10.2 Crane Applications

10.3 Automated Guided Vehicles

10.4 Skillet Conveyor

10.5 Transfer Car

10.6 Electric Monorail System

10.7 Sorter Technology

10.8 Clean-Room Technology

10.9 Elevator Systems

Concluding Remarks

Index

About the Authors.

Notes:

Bibliographic Level Mode of Issuance: Monograph

Includes bibliographical references and index.

Description based on print version record.

Description based on publisher supplied metadata and other sources.

ISBN:

0-7680-8859-3

1-5231-0223-3

OCLC:

1066180347