1st Edition

Wearable Solar Cell Systems

By Denise Wilson Copyright 2020
    164 Pages 35 B/W Illustrations
    by CRC Press

    164 Pages 35 B/W Illustrations
    by CRC Press

    Smartwatch? Fitness tracker? Portable ECG? Smartphone? Posture monitor? Hearing aid? MP3 player? E-reader? Wireless headset? Hiking watch? Gaming headset? Sleep monitor? Laptop computer? Tablet?

    Indeed, a dizzying array of portable and wearable electronic devices is available to the modern consumer. Not surprisingly, as the number of devices an individual chooses to wear or carry increases so does the energy required to power those devices. Judging by the increasing popularity of portable power banks, waiting to recharge many of these devices using standard wall outlets is no longer a standard practice.

    Wearable Solar Cell Systems looks at the possibilities for supporting the energy demand of these devices without the need to return to the dreaded wall outlet for recharging. While crystalline silicon dominates world markets, second- or third-generation solar cell technologies may be more suitable to wearable systems. Array size, architecture, and management must also be chosen to best serve portable and wearable devices and harvest light energy from different light sources under a broad range of input conditions.

    This book is intended to serve a wide audience from students who desire a basic introduction to solar (photovoltaic) cell technology to professionals seeking a holistic picture of wearable solar cells and systems.

    Chapter 1: The Power of Light
    1.1 Portable, Mobile, and Wearable Devices
    1.2 Impacts of Wearable Solar Systems
    1.3 Feasibility of Wearable Solar Cell Systems
    1.4 Summary

    Chapter 2: Fundamentals
    2.1 Light
    2.2 PV Materials
    2.3 Conversion of Light to Electrical Energy
    2.4 Advanced PV Designs
    2.5 Performance of PV Cells
    2.6 Shading and Other Irregularities
    2.7 Summary

    Chapter 3: First Generation Solar Cells
    3.1 Monocrystalline Silicon
    3.2 Polycrystalline Silicon
    3.3 Amorphous Silicon
    3.4 Summary

    Chapter 4: Second Generation Solar Cells
    4.1 Gallium Arsenide (GaAs)
    4.2 Cadmium Telluride (CdTe)
    4.3 Copper Indium Gallium Selenide (CIGS)
    4.4 Summary

    Chapter 5: Third Generation Solar Cells
    5.1 Organic PV (OPV) Cells
    5.2 Dye-Sensitized PV Cells
    5.3 Perovskites
    5.4 Quantum Dot PV Cells
    5.5 Summary

    Chapter 6: Arrays of PV Cells
    6.1 Basic PV Array Design
    6.2 Array Management
    6.3 Maximum Power Point Tracking (MPPT)
    6.4 Array Reconfiguration
    6.5 Summary

    Chapter 7: Energy Storage
    7.1 DC-DC Conversion
    7.2 Energy Storage
    7.3 Summary

    Chapter 8: Wearable and Portable Technology
    8.1 Mobile Phones
    8.2 Other Portables
    8.3 Wearable Devices
    8.4 Overall Energy Demand
    8.5 Summary

    Chapter 9: Wearable Solar Systems
    9.1 Basic Performance
    9.2 Flexibility, Cost, Toxicity, and Stability
    9.3 Array Considerations
    9.4 Charge Controller and Battery Considerations
    9.5 Surface Area Considerations
    9.6 Summary


    Denise Wilson is a professor in the Department of Electrical and Computer Engineering at the University of Washington in Seattle where she has worked since 1999. Previously, she held a similar position at the University of Kentucky in Lexington, Kentucky.

    Denise is also founder and managing director of Coming Alongside, an environmental services non-profit organization whose mission is to make hazards posed by the environment to human and animal health visible and actionable.

    "This book after reviewing the fundamentals of solar cells and basic power conversion systems for converting the PV energy into desired current and voltage levels, provides some comparisons of various cell materails for wearable devices powered by PV cells....This is a book for students or interested readers who want to learn some basic fundamentals of PV cells, the different types of cells, and some of the considerations when designing with PV cells for wearable applications."
    -IEEE Electrical Insulation Magazine, July/August