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市場調查報告書

智慧紡織品及穿戴式:市場,應用,及技術

Smart Textiles and Wearables: Markets, Applications and Technologies

出版商 Cientifica Ltd 商品編碼 368922
出版日期 內容資訊 英文 143 Pages
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智慧紡織品及穿戴式:市場,應用,及技術 Smart Textiles and Wearables: Markets, Applications and Technologies
出版日期: 2016年09月06日 內容資訊: 英文 143 Pages
簡介

本報告以智慧紡織品及穿戴式市場為焦點,提供紡織品為基礎的穿戴式技術,製造企業,及賦能技術的相關調查,主要的與成長領域,最新的進步其應用等詳細分析。

簡介

市場

  • 整體市場、年複合成長率
  • 採用了技術的紡織品的附加價值
  • 為奈米材料加上功能和價值的方法
  • 經營模式

應用

  • 運動福利
    • 第1代技術
    • Under Armour的 Healthbox 穿戴式
    • 第2代技術
    • 第3代技術
  • 儲能、發電
    • 採用了智慧型紡織品的軍服
    • BAE Systems的 Broadsword Spine
    • 伸縮性電池
    • LG Chem的電纜電池
    • 超級電容器儲能
  • 能源採集
    • 動力學
    • 太陽光
  • 流行
    • 第1代技術
    • 第2代技術
    • 第3代技術
  • 娛樂
    • 穿戴式新手法行銷

主要技術

  • 電路
    • 布料用導電油墨
    • 導電性光纖
    • 印刷電子產品
  • 感測器
    • 電動式
    • 機器式
  • 環境
    • 光顯象性紡織品
  • 溫度
  • 氣體、化學品
    • 紡織品氣體感測器
  • 能源
    • 儲存
    • 發電
  • 光學
    • 分子冷光

調查對象企業

圖表清單

目錄

A new report from Cientifica Research, ‘Smart Textiles and Wearables: Markets, Applications and Technologies’ examines the markets for textile based wearable technologies, the companies producing them and the enabling technologies. This is creating a 4th industrial revolution for the textiles and fashion industry worth over $130 billion by 2025.

Advances in fields such as nanotechnology, organic electronics (also known as plastic electronics) and conducting polymers are creating a range of textile-based technologies with the ability to sense and react to the world around them. This includes monitoring biometric data such as heart rate, the environmental factors such as temperature and The presence of toxic gases producing real time feedback in the form of electrical stimuli, haptic feedback or changes in color.

The report identifies three distinct generations of textile wearable technologies.

  • 1. First generation is where a sensor is attached to apparel and is the approach currently taken by major sportswear brands such as Adidas, Nike and Under Armour
  • 2. Second generation products embed the sensor in the garment as demonstrated by products from Samsung, Alphabet, Ralph Lauren and Flex.
  • 3. In third generation wearables the garment is the sensor and a growing number of companies including AdvanPro, Tamicare and BeBop sensors are making rapid progress in creating pressure, strain and temperature sensors.

Third generation wearables represent a significant opportunity for new and established textile companies to add significant value without having to directly compete with Apple, Samsung and Intel.

The report predicts that the key growth areas will be initially sports and wellbeing followed by medical applications for patient monitoring. Technical textiles, fashion and entertainment will also be significant applications with the total market expected to rise to over $130 billion by 2025 with triple digit compound annual growth rates across many applications.

The rise of textile wearables also represents a significant opportunity for manufacturers of the advanced materials used in their manufacture. Toray, Panasonic, Covestro, DuPont and Toyobo are already suppling the necessary materials, while researchers are creating sensing and energy storage technologies, from flexible batteries to graphene supercapacitors which will power tomorrows wearables. The report details the latest advances and their applications.

Companies Mentioned

  • Adidas
  • AdvanPro Limited
  • AIQ
  • ALATEX
  • Alink Co., Ltd
  • Alphabet
  • Analog Devices
  • Athos
  • Baar
  • BAE Systems
  • Barclays
  • BeBop Sensors
  • Bischoff Textil AG,
  • Bonar Technical Fabrics NV,
  • Borgstena Group
  • Chromat
  • Cintas
  • Clothing+
  • Covestra
  • Creative Materials
  • Cute Circuit
  • Cyanine Technologies srl,
  • DuPont
  • Durex
  • EHO Textiles
  • Endomondo,
  • ETH Zurich, Wearable Computing Lab;
  • Flex
  • Forster Rohner
  • Foster Rohner
  • Fraunhofer Institute for Silicate Research
  • Goldwin Inc.
  • Google
  • Heddoko
  • Huenenberg;
  • IMEC
  • Intel
  • Intelligent Textiles Ltd
  • JabilCircuit
  • King's Metal Fiber Technologies
  • Konarka
  • Levi's
  • LG Chem
  • LG Innotek
  • Lindstrand Technologies,
  • Lumo Bodytech
  • Lyle & Scott
  • Makefashion
  • MapMyRun
  • MAS Holdings
  • Medical Engineering Lab;
  • Microsoft
  • Noble Biomaterials Inc
  • Novonic
  • NTB Buchs,
  • NTT Corporation
  • Odlo International AG,
  • Ohmatex
  • Panasonic
  • Peerless Plastics & Coatings Ltd,
  • PLUX
  • PolarBeat
  • Polyera
  • Powertextiles Limited
  • Ralph Lauren
  • Schiller AG,
  • Sefar AG,
  • Sensing Tech S.L.
  • Sensoglove
  • Sensoria
  • Serge Ferrari SA,
  • Sphelar Power
  • St. Gallen
  • StartToday
  • Steinhausen
  • Strava,
  • Strela Development AG,
  • StretchSense
  • SUPA
  • SupaSpot Inc
  • Swarovski
  • Swiss Textile School STF,
  • Tamicare
  • Tex Ray Group
  • Textronics
  • The Unseen
  • Toray Industries
  • Toyobo Co Ltd
  • TWI
  • Umicore Materials AG
  • Unaxis Balzers AG
  • Under Armour
  • Unico Swiss Tex GmbH
  • VDS Weaving NV.
  • VTT Research Centre Finland
  • W. Zimmermann GmbH & Co. KG
  • Wearable Experiments
  • Wearable Life Sciences
  • Xotox
  • Zietromec
  • ZOZOTOWN

Table of Contents

  • Contents
  • List of Tables
  • List of Figures

Introduction

  • How to Use This Report
  • Wearable Technologies and the 4Th Industrial Revolution
  • The Evolution of Wearable Technologies
  • Defining Smart Textiles
  • Factors Affecting The Adoption of Smart Textiles for Wearables
    • Cost
    • Accuracy
    • On Shoring
    • Power management
    • Security and Privacy

Markets

  • Total Market Growth and CAGR
    • Market Growth By Application
  • Adding Value To Textiles Through Technology
  • How Nanomaterials Add Functionality and Value
  • Business Models

Applications

  • Sports and Wellbeing
    • 1st Generation Technologies
    • Under Armour Healthbox Wearables
      • Adidas MiCoach
      • Sensoria
      • EMPA's Long Term Research
    • 2nd Generation Technologies
      • Google's Project Jacquard
      • Samsung Creative Lab
      • Microsoft Collaborations
      • Intel Systems on a Chip
      • Flex (Formerly Flextronics) and MAS Holdings
      • Jiobit
      • Asensei Personal Trainer
      • OmSignal Smart Clothing
      • Ralph Lauren PoloTech
      • Hexoskin Performance Management
      • Jabil Circuit Textile Heart Monitoring
      • Stretch Sense Sensors
      • NTT Data and Toray
      • Goldwin Inc. and DoCoMo
      • SupaSpot Inc Smart Sensors
      • Wearable Experiments and Brand Marketing
      • Wearable Life Sciences Antelope
      • Textronics NuMetrex
    • 3rd Generation Technologies
      • AdvanPro Pressure Sensing Shoes
      • Tamicare 3D printed Wearables with Integrated Sensors
      • AiQ Smart Clothing Stainless Steel Yarns
      • Flex Printed Inks And Conductive Yarns
      • Sensing Tech Conductive Inks
      • EHO Textiles Body Motion Monitoring
      • Bebop Sensors Washable E-Ink Sensors
      • Fraunhofer Institute for Silicate Research Piezolectric Polymer Sensors
      • CLIM8 GEAR Heated Textiles
      • VTT Smart Clothing Human Thermal Model
      • ATTACH (Adaptive Textiles Technology with Active Cooling and Heating)

    Energy Storage and Generation

    • Intelligent Textiles Military Uniforms
    • BAE Systems Broadsword Spine
    • Stretchable Batteries
    • LG Chem Cable Batteries
    • Supercapacitors
      • Swinburne Graphene Supercapacitors
      • MIT Niobium Nanowire Supercapacitors

    Energy Harvesting

    • Kinetic
      • StretchSense Energy Harvesting Kit
      • NASA Environmental Sensing Fibers
  • Solar
    • Powertextiles
    • Sphelar Power Corp Solar Textiles
    • Ohmatex and Powerweave
  • Fashion
    • 1st Generation Technologies
      • Cute Circuit LED Couture
      • MAKEFASHION LED Couture
    • 2nd Generation Technologies
      • Covestro Luminous Clothing
    • 3rd Generation Technologies
      • The Unseen Temperature Sensitive Dyes
  • Entertainment
    • Wearable Experiments Marketing

Key Technologies

  • Circuitry
    • Conductive Inks for Fabrics
      • Conductive Ink For Printing On Stretchable Fabrics
      • Creative Materials Conductive Inks And Adhesives
      • Dupont Stretchable Electronic Inks
      • Aluminium Inks From Alink Co
    • Conductive Fibres
      • Circuitex Silver Coated Nylon
      • Textronics Yarns and Fibres
      • Novonic Elastic Conductive Yarn
      • Copper Coated Polyacrylonitrile (PAN) Fibres
    • Printed electronics
      • Covestro TPU Films for Flexible Circuits
  • Sensors
    • Electrical
      • Hitoe
      • Cocomi
      • Panasonic Polymer Resin
      • Cardiac Monitoring
    • Mechanical
      • Strain
        • Textile-Based Weft Knitted Strain Sensors
        • Chain Mail Fabric for Smart Textiles
        • Nano-Treatment for Conductive Fiber/Sensors
        • Piezoceramic materials
        • Graphene-Based Woven Fabric
        • Pressure Sensing
        • LG Innotek Flexible Textile Pressure Sensors
        • Hong Kong Polytechnic University Pressure Sensing Fibers
        • Conductive Polymer Composite Coatings
        • Printed Textile Sensors To Track Movement
  • Environment
    • Photochromic Textiles
  • Temperature
    • Sefar PowerSens
  • Gasses & Chemicals
    • Textile Gas Sensors
  • Energy
    • Storage
      • Graphene Supercapacitors
      • Niobium Nanowire Supercapacitors
      • Stretchy supercapacitors
    • Energy Generation
      • StretchSense Energy Harvesting Kit
      • Piezoelectric Or Thermoelectric Coated Fibres
  • Optical
    • Light Emitting
      • University of Manchester Electroluminescent Inks and Yarns
      • Polyera Wove

Companies Mentioned

List of Tables

  • Table 1: CAGR by application
  • Table 2: Value of market by application 2016-25 (millions USD)
  • Table 3: % market share by application
  • Table 4: CAGR 2016-25 by application
  • Table 5: Technology-Enabled Market Growth in Textile by Sector (2016-22)
  • Table 6: Value of nanomaterials by sector 2016-22 ($ Millions)

List of Figures

  • Figure 1: The 4th Industrial Revolution (World Economic Forum)
  • Figure 2: Block Diagram of typical MEMS digital output motion sensor: ultra low-power high performance 3-axis “femto” accelerometer used in fitness tracking devices.
  • Figure 3: Interior of Fitbit Flex device (from iFixit)
  • Figure 4: Internal layout of Fitbit Flex. Red is the main CPU, orange is the BTLE chip, blue is a charger, yellow is the accelerometer (from iFixit)
  • Figure 5: Intel's Curie processor stretches the definition of 'wearable'
  • Figure 6: Typical Textile Based Wearable System Components
  • Figure 7: The Chromat Aeros Sports Bra "powered by Intel, inspired by wind, air and flight."
  • Figure 8: The Evolution of Smart textiles
  • Figure 9: Goldwin's C2fit IN-pulse sportswear using Toray's Hitoe
  • Figure 10: Sensoglove reads grip pressure for golfers
  • Figure 11: Textile Based Wearables Growth 2016-25(USD Millions)
  • Figure 12: Total market for textile based wearables 2016-25 (USD Millions)
  • Figure 13: Health and Sports Market Size 2016-20 (USD Millions)
  • Figure 14: Health and Sports Market Size 2016-25 (USD Millions)
  • Figure 15: Critical steps for obtaining FDA medical device approval
  • Figure 16: Market split between wellbeing and medical 2016-25
  • Figure 17: Current World Textile Market by Sector (2016)
  • Figure 18: The Global Textile Market By Sector ($ Millions)
  • Figure 19: Compound Annual Growth Rates (CAGR) by Sector (2016-25)
  • Figure 20: The Global Textile Market in 2022
  • Figure 21: The Global Textile Market in 2025
  • Figure 22: Textile Market Evolution (2012-2025)
  • Figure 23: Total Value of Nanomaterials in Textiles 2012-2022 ($ Millions)
  • Figure 24: Value of Nanomaterials in Textiles by Sector 2016-2025 ($ Millions)
  • Figure 25: Adidas miCoach Connect Heart Rate Monitor
  • Figure 26: Sensoria's Hear Rate Monitoring Garments
  • Figure 27: Flexible components used in Google's Project Jacquard
  • Figure 28: Google and Levi's Smart Jacket
  • Figure 29: Embedded electronics Google's Project Jacquard
  • Figure 30: Samsung's WELT 'smart' belt
  • Figure 31: Samsung Body Compass at CES16
  • Figure 32: Lumo Run washable motion sensor
  • Figure 33: OMSignal's Smart Bra
  • Figure 34: PoloTech Shirt from Ralph Lauren
  • Figure 35: Hexoskin Data Acquisition and Processing
  • Figure 36: Peak+™ Hear Rate Monitoring Garment
  • Figure 37: StretchSense CEO Ben O'Brien, with a fabric stretch sensor
  • Figure 38: C3fit Pulse from Goldwin Inc
  • Figure 39: The Antelope Tank-Top
  • Figure 40: Sportswear with integrated sensors from Textronix
  • Figure 41: AdvanPro's pressure sensing insoles
  • Figure 42: AdvanPro's pressure sensing textile
  • Figure 43: Tamicare 3D Printing Sensors and Apparel
  • Figure 44: Smart clothing using stainless steel yarns and textile sensors from AiQ
  • Figure 45: EHO Smart Sock
  • Figure 46: BeBop Smart Car Seat Sensor
  • Figure 47: Non-transparent printed sensors from Fraunhofer ISC
  • Figure 48: Clim8 Intelligent Heat Regulating Shirt
  • Figure 49: Temperature regulating smart fabric printed at UC San Diego
  • Figure 50: Intelligent Textiles Ltd smart uniform
  • Figure 51: BAE Systems Broadsword Spine
  • Figure 52: LG Chem cable-shaped lithium-ion battery powers an LED display even when twisted and strained
  • Figure 53: Supercapacitor yarn made of niobium nanowires
  • Figure 54: Sphelar Textile
  • Figure 55: Sphelar Textile Solar Cells
  • Figure 56: Katy Perry wears Cute Circuit in 2010
  • Figure 57: Cute Circuit K Dress
  • Figure 58: MAKEFASHION runway at the Brother's “Back to Business” conference, Nashville 2016
  • Figure 59: Covestro material with LEDs are positioned on formable films made from thermoplastic polyurethane (TPU).
  • Figure 60: Unseen headpiece, made of 4000 conductive Swarovski stones, changes color to correspond with localized brain activity
  • Figure 61: Eighthsense a coded couture piece.
  • Figure 62: Durex Fundawear
  • Figure 63: Printed fabric sensors from the University of Tokyo
  • Figure 64: Tony Kanaan's shirt with electrically conductive nano-fibers
  • Figure 65: Panasonic stretchable resin technology
  • Figure 66: Nanoflex moniroring system
  • Figure 67: Knitted strain sensors
  • Figure 68: Chain Mail Fabric for Smart Textiles
  • Figure 69: Electroplated Fabric
  • Figure 70: LG Innotek flexible textile pressure sensors
  • Figure 71: Smart Footwear installed with fabric sensors. (Credit: Image courtesy of The Hong Kong Polytechnic University)
  • Figure 72: SOFTCEPTOR™ textile strain sensors
  • Figure 73: conductive polymer composite coating for pressure sensing
  • Figure 74: Fraunhofer ISC_ printed sensor
  • Figure 75: The graphene-coated yarn sensor. (Image: ETRI)
  • Figure 76: Supercapacitor yarn made of niobium nanowires
  • Figure 77: StretchSense Energy Harvesting Kit
  • Figure 78: Energy harvesting textiles at the University of Southampton
  • Figure 79: Polyera Wove Flexible Screen
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