市場調查報告書

摩擦充電的能源採集及感測 (TENG) :2020-2040年

Triboelectric Energy Harvesting and Sensing (TENG) 2020-2040

出版商 IDTechEx Ltd. 商品編碼 929141
出版日期 內容資訊 英文 179 Slides
商品交期: 最快1-2個工作天內
價格
摩擦充電的能源採集及感測 (TENG) :2020-2040年 Triboelectric Energy Harvesting and Sensing (TENG) 2020-2040
出版日期: 2020年03月19日內容資訊: 英文 179 Slides
簡介

本報告提供摩擦充電的能源採集及感測 (TENG)市場調查,彙整能源採集 (EH:Energy Harvesting)概要,初期的商業化案例,材料的特異性,穿戴式設備·外科用設備的TENG,IoT和泛在感測趨勢,自我發電感測器趨勢,高功率用途及其他的EH整合型技術趨勢等資料。

第1章 摘要整理·總論

第2章 簡介

  • 能源採集 (EH)的基本
  • 能源採集的特徵
  • 低功率 vs 高功率離網
  • EH能源來源的種類
  • EH候補:各輸出功率
  • 特徵:低功率EH vs 高功率EH
  • EH轉換器的原理·材料
  • EH傳感器市場成功:各技術
  • 能源採集系統
  • 摩擦充電效果
  • TENG的適合性:EH轉換器選擇比較
  • TENG的運行原理·設備的最佳化
  • 未來的教訓

第3章 初期的商業化案例:過濾器·玩具·新穎性

  • 初期的商業化案例
    • 自我發電靜電過濾器
    • 可洗面膜
    • 不帶電池的電子玩具
    • 不含再生塑膠電池的電子遊戲

第4章 材料的特異性:自我修復性·透明度·伸縮性·疏水性·生物適合性等

  • 自我修復性
  • 透明度·伸縮性
  • 生物適合性
  • 無枝晶鋰金屬電池
  • 材料的市場機會

第5章 穿戴式設備·外科用設備

  • 概要
  • 穿戴式技術成熟度曲線
  • 穿戴式·外科用TENG範例
  • TENG必須應對的穿戴式技術趨勢
  • 基本的穿戴式設備:各元件類型
  • 穿戴式感測器的分類
  • 實驗的TENG設計範例
  • TENG人體實驗設計:其他示例
  • 通過陽光和運動產生電能的紡織品
  • 三種纖維狀部件
  • 電子介面的超伸縮性透明的摩擦充電奈米發電機
  • 彈性自我發電觸覺感測皮膚貼片

第6章 IoT和泛在感測

  • 概要
  • 消除許多物聯網挑戰
  • 無線傳感器可用於收集能量的環境能量
  • 物聯網時代的集成式摩擦電納米發電機
  • 適用於IoT等的自供電摩擦電有源傳感器
  • 具備自供電IoT無線傳感器的感應線圈

第7章 自我發電感測器

  • 自供電傳感器概述
  • 柔性觸摸板可檢測接觸位置
  • 使用柔軟的平面螺旋電極進行接近和接觸檢測
  • 寬範圍壓力傳感器,可穿戴
  • 用於液體檢測的微流體系統
  • 壓力映射觸摸
  • 自供電式植入式心臟監護儀

第8章 高功率用途及其他的EH整合型技術

  • 大功率蓄電池充電
  • TENG作為改變世界的結構電子學的一部分
  • 挑戰結構電子領域重大進步的公司
  • 智慧之路
  • 中國:光伏道路上的Pavenergy
  • 按行業劃分的結構電子製造/技術響應水準
  • 結構電子產品作為保護塗層或包裹物:應用比較
  • 結構電子作為承重結構:應用比較
  • 結構電子技術比較
  • 技術形態
  • TENG機能:構成別
  • 河流/海洋運動發電
  • 使用樹木和樹葉
  • 整合多模式能量收集的演進
目錄

Title:
Triboelectric Energy Harvesting and Sensing (TENG) 2020-2040
Triboelectric nanogenerators, HV sources, filters Materials, capabilities, opportunities, technology roadmaps, forecasts.

"New triboelectrics address big issues such as pandemics to create billion dollar businesses."

Of the twelve types of energy harvesting, five are capturing motion and the latest of these is analysed and forecasted in the new IDTechEx report, "Triboelectric Energy Harvesting and Sensing (TENG) 2020-2040". Self-powered sensors and filters are also there.

This report is intended to be an easily absorbed summary of progress and forecast of the future of the new form of energy harvesting invented in 2012 yet already demonstrated in an unprecedented variety of forms: edible, biodegradable, self-cleaning, even integrated with most other harvesting technologies.

The focus is the commercial prospects and how to benefit society, matching achieved to needed. IDTechEx makes no attempt to compete with excellent academic summaries but if you want forecasts for the markets being targeted - vehicles, skin patches, wearable technology, ocean wave power etc., those forecasts are here and only here. Understand the work not yet prioritised for commercial launch.

Insights are based on extensive travel by IDTechEx PhD level analysts, new interviews in local languages, conference attendance, data searches. The work is mostly carried out in 2020 with ongoing updates. Many scientific advances in 2020 are assessed. Easily comprehended by those wishing to make the necessary materials, devices and systems, it de-risks investment.

The report helps investors, potential users, companies active in Internet of Things, personal electronics, electrics, healthcare, automotive, industrial, off-grid power for microgrids and vehicles. The most promising future applications are identified. Emphasis is commercialisation and which industrial sectors could benefit when missing elements of the routes to market are in place. Opportunities for added value materials are evaluated. A ten-year forecast is given plus a roadmap to 2040.

All vibration harvesting has been a commercial failure. Will the triboelectric nanogenerator TENG version succeed? First commercialisation has been triboelectric air filters. Why, where, next improvement? Which of the four harvesting modes are useful for what and where is the best work? See new infograms, graphs, timelines rather than equations. Why are fluoropolymers 55% of electro-negative materials used - a challenge and an opportunity? Next?

The "Executive Summary and Conclusions" is sufficient for those in a hurry with 30 primary conclusions and that host of relevant forecasts including haptics and active RFID markets, technology summary, future. Energy harvesters, triboelectric air filters and self-powered sensors and actuators and favoured materials explained: gaps in the market.

"Introduction" explains energy harvesting, twelve technologies - materials, capability, market needs overall. Learn systems aspects, parameters, practicalities of the triboelectric series and the troublesome variety of influencing factors. Four modes are looked at in great detail, electrostatic harvesting generally and lessons for the future. Chapter 3 details "Early Commercialisation: Self-Powered Filters, Toys and Novelties" already sold and what comes next . Chapter 4 analyses "Materials Virtuosity: Self-healing, Transparent, Stretchable, Hydrophobic, Biocompatible and More". IDTechEx presents new ideas and benchmarking.

With many new tables and pictures, Chapter 5 is "Wearable and Surgical". Much is being developed for these sectors: appropriate needs are manifold. Chapter 6 assesses the place in, "Internet of Things and Ubiquitous Sensing" cutting through exaggeration in these industries. Chapter 7 is where "Self-powered Sensors" TENG research is leading. Chapter 8 considers huge potential for "High Power and Combined with Other EH" critically scoping opportunity in wave and wind power, smart roads etc. and the emergence of structural electronics of which triboelectrics is a part. In contrast to many research papers dismissive or ignorant of other options, this also places the report "Triboelectric Energy Harvesting and Sensing (TENG) 2020-2040" firmly in the real world and the other improving technologies again with new ideas from IDTechEx.

Analyst access from IDTechEx

All report purchases include up to 30 minutes telephone time with an expert analyst who will help you link key findings in the report to the business issues you're addressing. This needs to be used within three months of purchasing the report.

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY AND CONCLUSIONS

  • 1.1. Purpose of this report
  • 1.2. Misnomers
  • 1.3. Wishful thinking
  • 1.4. Background
  • 1.5. Primary conclusions: context
  • 1.6. Primary conclusions : research and development effort
  • 1.7. Primary conclusions : performance available matched to potential applications
  • 1.8. Healthcare sensors: learn from piezoelectrics
  • 1.9. Energy harvesting of motion: transducer options compared
  • 1.10. The vibration harvesting mirage
  • 1.11. Primary conclusions: technical challenges and progress to market
  • 1.12. Primary conclusions: matching TENG to market needs
    • 1.12.1. Energy harvesting technology choice by intermittent power generated
    • 1.12.2. Some appropriate markets
    • 1.12.3. Market priorities for improvement
    • 1.12.4. Hype curve for triboelectric devices
    • 1.12.5. Timeline: triboelectric air filters & HV power, triboelectric sensors & actuators, TENG harvesters 2012-2040
  • 1.13. Primary conclusions: theory still needed
  • 1.14. Primary conclusions: materials opportunities
  • 1.15. Market forecasts
    • 1.15.1. TENG transducer and sensor low vs high power 2020-2040 $ million
    • 1.15.2. Addressable high power market
    • 1.15.3. Total zero-emission power market <100MW systems 2030 and 2040
    • 1.15.4. Wearable technology market forecast
    • 1.15.5. Forecast: cardiac monitoring skin patches
    • 1.15.6. Forecast: skin patches for continuous diabetes management
    • 1.15.7. Forecast: medical motion sensing patches
    • 1.15.8. Haptics forecast
    • 1.15.9. Forecast: battery assisted and active RFID
    • 1.15.10. Potential for triboelectric air filters TAF in cars 2020-2030
    • 1.15.11. Triboelectric Air Filter TAF forecast

2. INTRODUCTION

  • 2.1. Basics of energy harvesting (EH)
  • 2.2. Features of energy harvesting
  • 2.3. Low power vs high power off-grid
  • 2.4. Types of EH energy source
  • 2.5. Some of the candidates for EH by power
  • 2.6. Low power vs high power EH features
  • 2.7. EH transducer principles and materials
  • 2.8. Energy harvesting transducer market success by technology
  • 2.9. Fantasy
  • 2.10. Energy harvesting systems
    • 2.10.1. Architecture
  • 2.11. Triboelectric effect
    • 2.11.1. Overview
    • 2.11.2. Commercialisation of EH of motion showing some TENG opportunities
  • 2.12. How TENG fits in: EH transducer options compared
    • 2.12.1. Production status by technology
    • 2.12.2. Comparison of desirable features of EH technologies
    • 2.12.3. Basics for harvesting and sensing: triboelectric dielectric series
    • 2.12.4. Triboelectric dielectric series examples showing wide choice of properties
    • 2.12.5. Commentary on dielectric series
    • 2.12.6. Four ways to make a TENG
    • 2.12.7. TENG modes with advantages, potential uses
    • 2.12.8. Parametric advantages and challenges of triboelectric EH
    • 2.12.9. TENG relative benefits
    • 2.12.10. TENG relative benefits matched to potentially large markets
  • 2.13. TENG operating principle and device optimisation in detail
    • 2.13.1. Contact and sliding modes compared
    • 2.13.2. Single electrode and contactless modes compared
    • 2.13.3. Basic devices eliminating batteries: Clemson University
    • 2.13.4. Electrostatics in energy harvesting
  • 2.14. Lessons for the future

3. EARLY COMMERCIALISATION: FILTERS, TOYS AND NOVELTIES

  • 3.1. First commercialisation
    • 3.1.1. Self-powered electrostatic filters
    • 3.1.2. Washable face masks
    • 3.1.3. Battery free electronic toys
    • 3.1.4. Electronic game with no battery from recycled plastic

4. MATERIALS VIRTUOSITY: SELF HEALING, TRANSPARENT, STRETCHABLE, HYDROPHOBIC, BIOCOMPATIBLE AND MORE

  • 4.1. Self Healing
  • 4.2. Transparent, stretchable
  • 4.3. Biocompatible
  • 4.4. Dendrite-free lithium metal batteries
  • 4.5. Materials opportunities
    • 4.5.1. Overview
    • 4.5.2. Functionalisation and other options
    • 4.5.3. Materials for 24 laminar TENG
    • 4.5.4. Materials for 12 vertical arch TENG
    • 4.5.5. Materials for 4 textile and fibre TENG
    • 4.5.6. Materials for 8 rotating TENG
    • 4.5.7. Materials for 13 other TENG variants

5. WEARABLE AND SURGICAL

  • 5.1. Overview
  • 5.2. Wearables hype curve
  • 5.3. Examples of TENG for wearable and surgical
  • 5.4. Trends in wearable technology that TENGs must address
  • 5.5. Basic wearable device by component type
  • 5.6. Categorisation of wearable sensors
  • 5.7. Examples of experimental TENG designs
  • 5.8. Other examples of experimental TENG designs for the human body
  • 5.9. Textiles harvesting solar and movement
  • 5.10. Three fibre-shaped components
  • 5.11. Ultrastretchable, transparent triboelectric nanogenerator as electronic skin
  • 5.12. Flexible self-powered tactile sensing skin patches

6. INTERNET OF THINGS AND UBIQUITOUS SENSING

  • 6.1. Overview
  • 6.2. Many challenges of IoT have been solved
  • 6.3. Ambient energy available for energy harvesting by wireless sensors
  • 6.4. Integrated Triboelectric Nanogenerators in the Era of the Internet of Things
  • 6.5. Self-powered triboelectric active sensors for IOT etc
  • 6.6. Induction coils with self-powered IoT wireless sensors

7. SELF-POWERED SENSORS

  • 7.1. Self-powered sensors overview
  • 7.2. Examples of sensors with printing and film
  • 7.3. Flexible touch pad detecting contact location
  • 7.4. Proximity and contact detection using soft planar spiral electrodes
  • 7.5. Sensor for wide-range pressure detection in wearables
  • 7.6. Microfluidic system for liquid sensing
  • 7.7. Pressure mapping, touch
  • 7.8. Self-powered implantable heart monitor

8. HIGH POWER AND COMBINED WITH OTHER EH

  • 8.1. Charging high power energy storage
  • 8.2. TENG as part of structural electronics changing the world
  • 8.3. Some organisations attempting significant SE advances
    • 8.3.1. Structural electronics patents
    • 8.3.2. SE product and technology roadmaps 2019-2040
  • 8.4. Smart roads
  • 8.5. Solar road Pavenergy China
  • 8.6. Structural electronics manufacturing and technology readiness by applicational sector
  • 8.7. Structural electronics as protective coating or wrap: applications compared
  • 8.8. Structural electronics as load bearing structure: applications compared
  • 8.9. Structural electronics technologies compared
  • 8.10. Formats of technology
  • 8.11. TENG capabilities by configuration
  • 8.12. Electricity from river and sea motion
    • 8.12.1. Hype curve for water power
    • 8.12.2. Global potential for strong ocean power near population
    • 8.12.3. Open water wave power options compared
    • 8.12.4. Likely blue energy successes 2020-2030
    • 8.12.5. Favoured configurations so far
    • 8.12.6. TENG for wind and ocean wave
    • 8.12.7. Long-lived rotational TENG for water power
    • 8.12.8. Capillary approach to water power
    • 8.12.9. Spherical wave power generator
    • 8.12.10. Wave power using self-cleaning surface
  • 8.13. TENG using leaves and TENG tree for wind power
  • 8.14. Evolution of integrated multi-mode energy harvesting
    • 8.14.1. Four TENG modes as multi-mode harvesters
    • 8.14.2. Much can be done with metal patterning
    • 8.14.3. TENG multi-mode energy harvesting cases