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市場調查報告書

醫療保健的壓電獵能及感測:2019-2029年

Piezoelectric Harvesting and Sensing for Healthcare 2019-2029

出版商 IDTechEx Ltd. 商品編碼 759135
出版日期 內容資訊 英文 109 Pages
商品交期: 最快1-2個工作天內
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醫療保健的壓電獵能及感測:2019-2029年 Piezoelectric Harvesting and Sensing for Healthcare 2019-2029
出版日期: 2018年12月21日內容資訊: 英文 109 Pages
簡介

壓電感測系統市場規模,預計2029年成為10億4,000萬美元。

本報告提供醫療保健壓電獵能及感測市場相關調查,全球醫療保健情形與特別是感測器的能源採集的必要性,工作形態、邏輯、化學、電子產品的基本原理,主要的實例,及研究、產品銷售等的組織的簡介等分析。

第1章 摘要整理、結論

第2章 簡介

第3章 基本原理

  • 背景、定義
  • 壓電效應 - 直接
  • 基本方程式
  • 設計選擇
  • 分子模式
  • 設備作成、工作的原理
  • 無鉛及新形態的探求:氧化鋅
  • 震動壓電能源採集
  • 能源採集系統的設計
  • Piezotronics
  • 壓電性高分子
  • 生物分解性壓電感測器、獵能器:幾個選擇登場

第4章 醫療保健的壓電性獵能及感測:實例、教訓

  • 醫療保健的低等級機械性張力的感測
  • 人體上、人體內、人體的壓電獵能器
  • 植入式心臟整流去顫器、心律調節器
  • 內耳
  • 腕帶健康螢幕
  • 患者行動監測
  • 拋棄式,植入,穿戴式的膠原蛋白壓電
  • 手控制器
  • 無線感測器,IoT
  • MEMS獵能的實例、其他

第5章 對醫療保健的壓電有興趣的企業

  • Algra (瑞士)
  • Arveni (法國)
  • Fraunhofer IKTS (德國)
  • Georgia Institute of Technology (美國)
  • Holst Centre/TNO (荷蘭)
  • IMEC (比利時)
  • Imperial College London (英國)
  • Meggitt (美國)
  • Piezo.com (美國)
  • SILEX (瑞典)
  • Tyndall National Institute (愛爾蘭)
  • University of Princeton (美國)
目錄

Title:
Piezoelectric Harvesting and Sensing for Healthcare 2019-2029
Harvesting & sensing: new research, applications, potential.

"In healthcare beyond imaging, expect a piezoelectric sensing systems market of $1.04 billion in 2029."

Healthcare Sensors: Piezoelectrics the New Gymnasts

Healthcare electronics is rapidly deploying for wellness, electroceuticals, intrusive medical procedures and more, powered by new technologies. Much of it is trending to diagnostics and treatment on the move and removing the need for the patient to perform procedures on time. Instruments become wearables including electronic skin patches and implants. The new IDTechEx report, "Piezoelectric Harvesting and Sensing for Healthcare 2019-2029" notes that preferably sensors should be self-powered, non-poisonous even on disposal and many need to be biocompatible and even biodegradable. We need to detect biology, vibration, force, acceleration, stress and linear movement and do imaging. Devices must reject bacteria and be useful in wearables and Internet of Things nodes. Preferably we must move to one device performing multiple tasks.

The report explains how new forms of piezoelectric will sense all those parameters and harvest creating electricity for sensors and more. That includes biosensors where the piezo senses the swelling of a biomolecule recognizing a target analyte. The most important form of self-powered (one material, two functions) piezo sensing is ultrasound imaging. The IDTechEx report, "Piezoelectric Harvesting and Sensing for Healthcare 2019-2029" looks at what comes next based on global travel and interviewing by its PhD level analysts in 2018 with continuous updates. IDTechEx has long staged conferences on these subjects and it shares privileged information in the report.

Piezo is already sold as a variety of self-powered sensors but there is more to come. Learn how it is reinvented as paint, print, layers on integrated circuits and in microelectromechanical systems MEMS chips. New applications for lead-based ceramics in new formats are revealed but polymer film and device layers come center stage. New piezotronics means piezoelectric doubles as semiconductor. Piezo-phototronics takes that up a notch. Light modulation enhances performance of photocells, sensitivity of photodetectors, efficiency of an LED, even strain-controlled LED emission directly images force/pressure distribution on the device with micrometer-resolution. The resulting piezopotential gated diodes, strain sensors, force/flow sensors and more revealed in the report promise to be invaluable in healthcare as will mapping pressure distribution on a surface. Integrate with photonic technologies for fast data transmission, processing and recording? Enable the development of highly intelligent human-machine interfaces? A major step towards on-chip recording of mechanical signals by optical means, yet another case of multi-functionality? Hospital pad, pillow and bolt sensors using piezos revealed in 2018 look promising but so do harvesters implanted on the heart and many other emerging capabilities discussed.

The IDTechEx report, "Piezoelectric Harvesting and Sensing for Healthcare 2019-2029" starts with an Executive Summary and Conclusions sufficient for those with limited time to grasp the emerging capabilities, issues and dreams with market forecasts for the piezoelectric harvesting and sensing systems, transducers and materials. Chapter 2 is the introduction giving the global healthcare situation and how energy harvesting and particularly sensors are increasingly vital. Piezoelectrics are at the heart of that. Chapter 4 Fundamentals goes deeper into the operating modes, theory, chemistry and electronics involved even embracing routes to biodegradability.

Chapter 4 reveals many examples of present and future piezoelectric harvesting and sensing in healthcare. It draws lessons from this. Finally Chapter 5 profiles 13 interesting organisations involved in researching, integrating and selling healthcare harvesting and sensor piezoelectric devices and materials

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. Definition and scope
  • 1.2. Primary conclusions
  • 1.3. Prospective healthcare applications for piezotronics
  • 1.4. Piezoelectric harvesting and sensing systems
  • 1.5. Routes to success in piezoelectric energy harvesting
  • 1.6. Battery elimination
  • 1.7. Piezo devices applicational market split 2029
  • 1.8. Global medical sensors market size - 2019 & 2029
  • 1.9. Piezoelectric harvesters and sensors global market value $ billion 2019-2029
  • 1.10. Piezoelectric value chain, energy harvesting and sensing 2029 $ billion by segment
  • 1.11. Piezoelectric EH&S Systems, Transducers, Materials 2019- 2029 $ billion

2. INTRODUCTION

  • 2.1. Scope
  • 2.2. Global healthcare trend
  • 2.3. Global healthcare trend: disease, spend, regional differences
  • 2.4. Two major needs addressed in this report
  • 2.5. What is piezoelectric harvesting and sensing?
  • 2.6. Piezoelectric Advantages
  • 2.7. Manufacture: typical processes
  • 2.8. Printable gallium phosphate
  • 2.9. Modes of operation and standards
    • 2.9.1. Function
    • 2.9.2. Force
    • 2.9.3. Pressure
    • 2.9.4. Standards
  • 2.10. Benefits and challenges of piezoelectric harvesting
  • 2.11. Multifunctional piezoelectric devices: Novasentis Arkema Piezotech
  • 2.12. Some of the main areas of research in piezoelectrics for healthcare

3. FUNDAMENTALS

  • 3.1. Background and Definitions
  • 3.2. Piezo effect - direct
  • 3.3. Basic equations
  • 3.4. Design options
  • 3.5. Molecular models
  • 3.6. Principle of device creation and operation
  • 3.7. Quest for lead-free and new morphologies: zinc oxide
  • 3.8. Vibrational Piezoelectric Energy Harvesters
    • 3.8.1. Overview
    • 3.8.2. Challenges: the quest for power and acoustic bandwidth
    • 3.8.3. Research base: wide acoustic bandwidth piezo harvesting
    • 3.8.4. Parameters of piezoelectrics for vibration harvesting
  • 3.9. Energy harvesting system design
  • 3.10. Piezotronics
    • 3.10.1. Overview
    • 3.10.2. Mechanisms and devices
  • 3.11. Quest for lead-free and new morphologies: zinc oxide
  • 3.12. Piezoelectric polymers
    • 3.12.1. Overview
  • 3.13. Biodegradable piezoelectric sensors and harvester: several options emerging
    • 3.13.1. PLLA biodegradable sensors
    • 3.13.2. PVDF-DNA biodegradable harvesters

4. PIEZOELECTRIC HARVESTING AND SENSING IN HEALTHCARE: EXAMPLES AND LESSONS

  • 4.1. Sensing low level mechanical strain in healthcare
  • 4.2. Piezo harvesters on, in and by the human body
  • 4.3. Implanted defibrillators and pacemakers
  • 4.4. Inner ear
  • 4.5. Wrist health monitor
  • 4.6. Patient behaviour monitoring
  • 4.7. Collagen piezoelectric for disposables, implants, wearables
  • 4.8. Hand controllers
  • 4.9. Wireless sensors, IOT
  • 4.10. Examples of MEMS harvesting
  • 4.11. Progression of integration
  • 4.12. Piezoelectric, pyroelectric, triboelectric combined
  • 4.13. Piezoelectric with triboelectric
  • 4.14. Sensor definition and function
  • 4.15. Sensor requirements by power level
  • 4.16. Signal processing
  • 4.17. Relative advantages
  • 4.18. Multifunctional sensors
  • 4.19. Piezoelectric sensor limitations
  • 4.20. Static sensing
  • 4.21. Temperature effects
  • 4.22. Sensors of biological functions using piezotronics
  • 4.23. Piezoelectric pressure sensing
  • 4.24. Sensor switches
  • 4.25. Point of care biosensors for infectious diseases
    • 4.25.1. Needs
    • 4.25.2. Piezoelectrics in context for bioreceptor biosensors
    • 4.25.3. Piezoelectric bioreceptor biosensors in action
  • 4.26. Microphones Vesper
  • 4.27. Internet of Things healthcare market map

5. INTERESTING ORGANISATIONS IN HEALTHCARE PIEZOELECTRICS

  • 5.1. Algra Switzerland
  • 5.2. Arveni France
  • 5.3. Fraunhofer IKTS Germany
  • 5.4. Georgia Institute of Technology USA
  • 5.5. Holst Centre/TNO Netherlands
  • 5.6. IMEC Belgium
  • 5.7. Imperial College London UK
  • 5.8. Meggitt USA
  • 5.9. Piezo.com USA
  • 5.10. SILEX Sweden
  • 5.11. Tyndall National Institute Ireland
  • 5.12. University of Princeton USA
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