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電気活性高分子(EAP)アクチュエーターおよびセンサー:種類・アプリケーション・新規開発・産業構造・世界市場

Electro-Active Polymer Actuators and Sensors - Types, Applications, New Developments, Industry Structure and Global Markets

発行 Innovative Research and Products (iRAP) 商品コード 268873
出版日 ページ情報 英文 129 Pages
納期: 即日から翌営業日
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電気活性高分子(EAP)アクチュエーターおよびセンサー:種類・アプリケーション・新規開発・産業構造・世界市場 Electro-Active Polymer Actuators and Sensors - Types, Applications, New Developments, Industry Structure and Global Markets
出版日: 2013年03月31日 ページ情報: 英文 129 Pages
概要

世界のEAP(エレクトロアクティブポリマー)アクチュエーターおよびセンサー市場は2012年に1億4,800万米ドルに達しました。同市場は2017年までに3億6,300万米ドルに増加する見込みです。医療装置は2012年において最大の市場シェアを占め、2017年までリードを維持するでしょう。同部門の予測期間中の平均年成長率(AAGR)は11.8%となる見込みです。地域別では北米が66%で最大の市場シェアを占め、2017年まで60%前後のシェアを維持すると見られています。

当レポートでは、電気活性高分子アクチュエータおよびセンサーの世界市場について分析し、産業の概要、地域・セグメント別の市場動向、技術動向、特許動向などについてまとめ、概略下記の構成でお届けいたします。

イントロダクション

エグゼクティブサマリー

産業概要

  • EAPの技術と種類
  • フィールド活性または電子EAP
  • 定義
  • アクチュエーター
  • アクチュエーターアプリケーション向けEAP材料
  • EAPアクチュエーターのアプリケーション
  • アプリケーション詳細
  • アプリケーション別市場
  • 医療アプリケーション
  • ロボティクス模倣生物学
  • ロボティクス市場
  • 触覚アクチュエーター
  • 触覚アプリケーション
  • 携帯電話用カメラの可変アパーチャー
  • 大歪センシング機能:壁専断応力センサー
  • 壁専断応力センサー 市場
  • ウェアラブル誘電エラストマーアクチュエーター
  • ウェアラブル市場
  • アプリケーション別の合計市場
  • 材料種類別の市場

産業構造・力学

  • 市場業績成功の影響因子
  • ビジネスモデル・産業参入企業
  • 地域市場
  • M&A

EAPアクチュエーター・センサーの技術概要

  • 誘電性EAPおよびエラストマーアクチュエーター
  • 構造・特徴
  • イオン性ポリマー金属複合材料アクチュエーター
  • 電導性ポリマーアクチュエーター
  • EAPアクチュエーターvs.その他アクチュエーターの比較
  • EAPセンサーの比較
  • EAPアクチュエーターに用いられている材料
  • EAPアクチュエーターの特徴
  • EAP技術の開発

新開発・特許分析

  • 米国特許・特許分析
  • EAPアクチュエーター・センサーにおける国際的な米国特許活動の概要
  • EAP・デバイスに発行された米国特許の詳細、ほか

付録?:企業プロファイル

付録?:EAP材料サプライヤーのリスト

目次
Product Code: ET-116

Abstract

An electroactive polymer (EAP) is a polymer that exhibits a mechanical response -such as stretching, contracting, or bending, for example - in response to an electric field, or a polymer that produces energy in response to a mechanical stress.

The actuator property of some EAPs has been attractive for a broad range of potential applications, including but not limited to robotic arms, grippers, loudspeakers, active diaphragms, dust wipers, heel strikers (dental) and numerous automotive applications. There are also numerous applications within the medical field, including but not limited to artificial muscles, synthetic limbs or prostheses, wound pumps, active compressing socks, and catheter or other implantable medical device steering elements.

EAP materials have high energy density, rapid response time, customizability (shape and performance characteristics), compactness, easy controllability, low power consumption, high force output and deflections/amount of motion, natural stiffness, combined sensing and actuation functions, relatively low raw materials costs, and relatively inexpensive manufacturing costs.

Electroactive ceramic actuators (for example, piezoelectric and electro-strictive) are effective, compact actuation materials, and they are used to replace electromagnetic motors. While these materials are capable of delivering large forces, they produce a relatively small displacement, on the order of magnitude of a fraction of a percent.

Since the beginning of the 1990s, new EAP materials have emerged that exhibit large strains, and they have led to a paradigm shift because of their capabilities. The unique properties of these materials are highly attractive for bio-mimetic applications such as biologically inspired intelligent robots. Increasingly, engineers are able to develop EAP-actuated mechanisms that were previously imaginable only in science fiction. Electric motors tend to be too weak, while hydraulics and pneumatics are too heavy for use in robotics or prosthetics. In comparison, EAPs are lightweight, quiet and capable of energy densities similar to biological muscles.

In ionic EAPs, actuation is caused by the displacement of ions inside the polymer. Only a few volts are needed for actuation, but the ionic flow implies a higher electrical power needed for actuation, and energy is needed to keep the actuator at a given position. Examples of EAPS in this area are dielectric elastomers, polymers, ionic polymer metal composites (IPMCs), conductive polymers and responsive gels.

An EAP actuator not only is completely different from conventional electromechanical devices, but also separates itself from other high-tech approaches that are based on piezoelectric materials or shape-memory alloys by providing a significantly more power-dense package and, in many instances, a smaller footprint.

Electro-active polymer technology could potentially replace common motion-generating mechanisms in positioning, valve control, pump and sensor applications, where designers are seeking quieter, power efficient devices to replace cumbersome conventional electric motors and drive trains.

This study reports new concepts in mechanism design and digital mechatronics, which have the potential to significantly impact a wide variety of systems and devices, including medical devices, haptic actuators, haptic switches, aperture adjustments in mobile cameras, manufacturing systems, toys and robotics, among others. The survey mainly targets dielectric elastomer actuators, conductive polymers actuators and IMPC actuators as the most likely candidates to act as EAP devices, on the basis of material characteristics, maturity of technology, reliability, and cost to meet design requirements of applications considered.

Study goal and objectives

Markets for EAP devices are strongly driven by the expanding medical market, E-textiles and robotics, with its demand for a novel class of electrically controlled actuators based on polymer materials. Almost any laboratory for molecular biology must be equipped with a dextrous robotic gripper. The artificial muscle envisioned is a low-cost actuator capable of being accurately electrically controlled, expanding or contracting linearly, and performing in a manner similar to natural skeletal muscles. Such an actuator has potential applications in areas where flexibility of a moving system goes together with a need for accurate control of the motion: haptic actuators, haptic switches, aperture adjustments in mobile phone cameras, robotics, advanced consumer products like smart fabrics, toys and medical technology. Totally new design principles and novel products for everyday use with a large economic potential can be anticipated.

In addition, new and much larger markets will open up if microfluidic devices using micropumps and microvalves can enter the arena of clinical and point-of-care medicine and even the home diagnostics market. This study focuses on EAP devices, types, applications, new developments, industry and global markets, providing market data about the size and growth of the application segments, including a detailed patent analysis, company profiles and industry trends. Another goal of this report is to provide a detailed and comprehensive multi-client study of the market in North America, Europe, Japan and the rest of the world (ROW) for EAPs and potential business opportunities in the future.

The objectives include thorough coverage of the underlying economic issues driving the EAP and devices businesses, as well as assessments of new advanced EAPs and devices that are being developed. Another important objective is to provide realistic market data and forecasts for EAPs and devices. This report provides the most thorough and up-to-date assessment that can be found anywhere on the subject. The study also provides extensive quantification of the many important facets of market developments in EAPs and devices all over the world. This, in turn, contributes to the determination of what kinds of strategic responses companies may adopt in order to compete in this dynamic market.

REASONS FOR DOING THE STUDY

EAPs exhibit many qualities that make them ideal for a low-cost actuator capable of being accurately electrically controlled, expanding or contracting linearly, and performing in a manner that resembles the natural skeletal muscles. Such an actuator has potential applications in areas where flexibility of a moving system goes together with a need for accurate control of the motion, such as EAP-based medical devices, advanced consumer products like haptic actuators, aperture adjustments in mobile phone cameras, robotics, smart fabrics, and toys.

Development of EAP fields will benefit companies that use EAP components to add value to products and services, companies skilled in using EAP to design new products and services, and materials processors that add value to raw materials. The small volumes of EAP consumption likely will have little impact on raw materials suppliers. Near-term returns on investment by EAP suppliers generally will be modest, because most EAP fields still are building infrastructure and knowledge bases for efficient and effective production, marketing and use of EAPs. The specialized knowledge necessary to produce EAPs and incorporate those effectively into products will slow the spread of EAP use, but it also has led to high market valuations for companies developing products for high-value applications.

EAPs also are finding applications in haptics, which provides a tactile feedback technology taking advantage of the sense of touch by applying forces, vibrations, or motions to the user. Haptic feedback interface devices using EAP actuators provide haptic sensations and/or sensing capabilities. A haptic feedback interface device is in communication with a host computer and includes a sensor device that detects the manipulation of the interface device by the user and an EAP actuator responsive to input signals and operative to output a force to the user caused by motion of the actuator. The output force provides a haptic sensation to the user.

Smart structures, which fully integrate structural and mechatronic components, represent the most refined use of EAPs and might eventually enjoy very large markets. Only a very simple EAP-based smart-structure product is in commercial use today. Other important areas of opportunity include applications in which designers are looking for performance improvements or new features but are unwilling to accept the compromises necessary to use conventional mechanisms and products (including non-mechanical devices) that must operate in a variety of conditions but have rigid designs optimized for a single operating point. Though improvements in EAP performance would increase the range of possible applications, the major barriers to widespread EAP use are users' lack of familiarity with the technology, the need for low-cost, robust production processes, and the need for improved design tools to enable non-experts to use the materials with confidence.

Since publishing our last report in 2008, many changes have occurred, including the emergence of new market segments such as haptic sensors and adjustable apertures for cellular phone cameras, new materials and new fabrication processes, new manufacturers and new patents. Therefore, iRAPfelt a need to do a detailed technology update and analysis of this industry.

Contributions of the study

The study is intended to benefit existing manufacturers of robotics, advanced consumer products like smart fabrics, toys, and medical technology, who seek to expand revenues and market opportunities through new technology such as low-cost EAPs and devices, which are positioned to become a preferred solution over conventional actuator applications.

This study also provides the most complete accounting of EAPs and devices growth in North America, Europe, Japan and the rest of the world currently available in a multi-client format. The markets have also been estimated according to the type of materials used, such as dielectric elastomer actuators, conductive polymers and ionic polymer metal composites.

The report provides the most thorough and up-to-date assessment that can be found anywhere on the subject. The study also provides extensive quantification of the many important facets of market developments in the emerging markets of EAPs and devices, such as China. This, in turn, contributes to the determination of what kind of strategic response suppliers may adopt in order to compete in this dynamic market.

SCOPE AND FORMAT

The market data contained in this report quantify opportunities for EAPs and devices. In addition to product types, the report also covers the many issues concerning the merits and future prospects of the EAP and devices business, including corporate strategies, information technologies, and the means for providing these highly advanced products and service offerings. It also covers in detail the economic and technological issues regarded by many as critical to the industry's current state of change. The report provides a review of the EAP and devices industry and its structure and the many companies involved in providing these products. The competitive position of the main players in the market and their strategic options are also discussed, as well as such competitive factors as marketing, distribution and operations.

TO WHOM THE STUDY CATERS

The study will benefit existing manufacturers of EAP-tipped catheters, haptic actuators, aperture adjustment mechanisms in mobile cameras, robotics, advanced consumer products like smart fabrics and toys, and medical technology. EAP materials exhibit large strains, and they led to a paradigm shift based on their capabilities. The unique properties of these materials are highly attractive for biomimetic applications such as biologically inspired intelligent robots.

This study provides a technical overview of EAPs and related devices, especially recent technology developments and existing barriers. Therefore, audiences for this study include marketing executives, business unit managers and other decision makers working in the areas of haptic applications, aperture adjustment mechanisms in mobile cameras, robotics, advanced consumer products like smart fabrics and toys, and medical technology, as well as those in companies peripheral to these businesses.

REPORT SUMMARY

Electroactive polymers are increasingly used in niche actuators and sensor applications demanding large strains as compared to other piezoelectric materials. New applications are emerging in medical devices, haptic actuators, cellular phone cameras, smart fabrics for sensors, digital mecha-tronics and high strain sensors.

New EAP devices are already replacing some mechanisms that rely on direct or indirect displacement to produce power. Shape-memory alloys contract with a thermal cycle, and piezoelectric technologies expand and contract with voltage at high frequencies. While both these technologies provide direct displacement, they are usually limited to 1% direct displacement. Electromagnetic solutions typically consist of a motor that rotates an output shaft, so there is no direct displacement from the motor itself, but there can be "indirect"displacement from a mechanism connected to the output shaft.

EAP devices are facing competition in a new rapidly evolving and highly competitive sector of the medical market. Increased competition could result in reduced prices and gross margins for EAP products and could require increased spending on research and development, sales and marketing, and customer support.

This study separated markets for EAP devices and products into six application segments -medical devices, haptic actuators, adjustable apertures for cellular phone cameras, smart fabrics, digital mechatronics, and high-strain sensing instruments for construction.

Major findings of this report:

  • Global market for EAP actuators and sensors reached $148 million in 2012. This will increase to $363 million by 2017.
  • Medical devices had the largest market share in 2012 followed by haptic actuators, adjustable apertures for cellular phones, high strain sensing in construction, smart fabrics, and digital mechatronics.
  • While medical devices will continue to maintain the lead in 2017, that sector will see a modest average annual growth rate (AAGR) of 11.8% for the period. Haptic actuators will see maximum growth at an AAGR of 35% from 2012 to 2017.
  • Among the regions, North America has the largest market share with 66% of the market and will be maintained around 60% share till 2017.

Table of Contents

INTRODUCTION

  • STUDY GOAL AND OBJECTIVES
  • REASONS FOR DOING THE STUDY
  • CONTRIBUTIONS OF THE STUDY
  • SCOPE AND FORMAT
  • METHODOLOGY
  • INFORMATION SOURCES
  • WHOM THE STUDY CATERS TO
  • AUTHOR'S CREDENTIALS

EXECUTIVE SUMMARY

  • SUMMARY TABLE A -GLOBAL MARKET SIZE/PERCENTAGE SHARE FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS BY APPLICATION, 2012 AND 2017
  • SUMMARY FIGURE A - GLOBAL MARKET SIZE/PERCENTAGE SHARE FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS BY APPLICATION, 2012 AND 2017
  • SUMMARY TABLE B - NORTH AMERICAN AND GLOBAL MARKET FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS, 2012 AND 2017
  • SUMMARY FIGURE B - NORTH AMERICAN AND GLOBAL MARKET FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS, 2012 AND 2017

INDUSTRY OVERVIEW

  • EAP TECHNOLOGY AND TYPES
  • IONIC EAPS
  • FIELD-ACTIVATED OR ELECTRONIC EAPS
  • Dielectric Polymers
  • Dielectric Polymers (Continued)
  • Phase Transition Polymers
    • TABLE 1 - SUMMARY OF THE ADVANTAGES AND DISADVANTAGES OF THE TWO BASIC EAP GROUPS
  • DEFINITIONS
    • TABLE 2-DEFINITIONS OF TECHNICAL TERMS USED FOR ELECTRO-ACTIVE POLYMER
  • ACTUATORS
  • EAP MATERIALS FOR ACTUATOR APPLICATIONS
  • EAP ACTUATOR APPLICATIONS
  • DETAILED APPLICATIONS
  • DETAILED APPLICATIONS (CONTINUED)
  • DETAILED APPLICATIONS (CONTINUED)
  • MARKET ACCORDING TO APPLICATIONS
    • TABLE 3 - GLOBAL MARKET SIZE/PERCENTAGE SHARE FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS
  • 2012 AND 2017
    • FIGURE 1- GLOBAL MARKET FOR EAP ACTUATORS AND SENSORS BY APPLICATION IN 2012 AND 2017
  • MEDICAL APPLICATIONS
  • Micro-pumps
  • Micro-pumps(Continued)
  • Active Catheters
  • Active Catheters (Continued)
  • Active Catheters (Continued)
    • FIGURE 2 - APPLICATION OF AN EAP CATHETER
  • Enabling new functionality for medical devices
  • Enabling new functionality for medical devices (Continued)
  • Eye focus correction
    • FIGURE 3 -ILLUSTRATION OF EYELID SLING ATTACHED TO EAP ARTIFICIAL MUSCLE DEVICE25
  • Disposable Infusion Pumps
    • FIGURE 4 - APPLICATION OF ELECTROACTIVE POLYMER IN A DIAPHRAGM PUMP
  • Medical Markets
    • TABLE 4 - FORECAST OF ELECTROACTIVE POLYMER USE IN MICRO-PUMPS, ACTIVE CATHETERS, MRI EQUIPMENT, EYE FOCUS CORRECTION AND DISPOSABLE INFUSION PUMPS 2012 - 2017
  • ROBOTICS EMULATING BIOLOGY
  • ROBOTICS EMULATING BIOLOGY (CONTINUED)
  • ROBOTICS EMULATING BIOLOGY (CONTINUED)
    • FIGURE 5- APPLICATION OF EAP ACTUATORS IN ROBOTS
  • ROBOTICS MARKET
    • TABLE 5 -FORECAST FOR EAP DEVICE USAGE IN DIGITAL MECHATRONICS FOR MEDICAL BIOMETICS ROBOTICS AND TOY ROBOTICS, 2012 AND 2017
  • HAPTIC ACTUATORS
  • HAPTIC ACTUATORS (CONTINUED)
    • FIGURE 6 -APPLICATION OF ELECTROACTIVE POLYMER-HAPTIC SWITCH
    • FIGURE 7 -APPLICATION OF ELECTROACTIVE POLYMER - HAPTIC SWITCH LAYOUT
    • TABLE 6- FORECAST FOR EAP ACTUATOR USAGE IN
  • HAPTIC APPLICATIONS, 2012 AND 2017
  • ADJUSTABLE APERTURES FOR CELLULAR PHONE CAMERAS
    • TABLE 7 -SPECIFICATIONS FOR TYPICAL EAP APERTURE MECHANISMS IN MOBILE PHONES
    • FIGURE 8 -ILLUSTRATIONS OF EAP APERTURE MECHANISMS FOR PHONE CAMERAS
    • TABLE 8 -FORECAST FOR EAP DEVICE USAGE IN AJUSTABLE APERTURE ACTUATORS FOR CELL PHONE CAMERA APPLICATIONS, 2012 AND 2017
  • LARGE STRAIN SENSING FUNCTIONS: WALL SHEAR STRESS SENSORS
  • LARGE STRAIN SENSING FUNCTIONS: WALL SHEAR STRESS SENSORS (CONTINUED)
  • WALL SHEAR STRESS SENSOR MARKET
    • TABLE 9 - FORECAST FOR EAP DEVICE USAGE AS SENSORS IN CIVIL AND STRUCTURAL CONSTRUCTION, 2012 AND 2017
  • WEARABLE DIELECTRIC ELASTOMER ACTUATORS
  • WEARABLE DIELECTRIC ELASTOMER ACTUATORS (CONT.)
  • WEARABLE DE MARKET
    • TABLE 10 - FORECAST FOR EAP DEVICE USAGE IN SMART FABRIC SENSORS, 2012 AND 2017
  • COMBINED MARKET ACCORDING TO APPLICATIONS
    • TABLE 11 - SUMMARY OF GLOBAL MARKET FOR EAP ACTUATORS BY APPLICATION, 2012 AND 2017
  • MARKET ACCORDING TO MATERIAL TYPES
    • TABLE 12 - FORECAST FOR MATERIAL USAGE IN EAP ACTUATORS AND SENSORS, 2012 AND 2017
    • FIGURE 9 - ILLUSTRATION OF MARKET SHARE FOR MATERIAL USAGE IN EAP ACTUATORS AND SENSORS 2012 AND 2017

INDUSTRY STRUCTURE AND DYNAMICS

  • TABLE 13 - BRANDED EAP ACTUATORS ON THE MARKET IN 2012
    • TABLE 13 - BRANDED EAP ACTUATORS ON THE MARKET IN 2012 (CONTINUED)
  • FACTORS INFLUENCING MARKET PERFORMANCE SUCCESS STORIES
  • BUSINESS MODELS AND INDUSTRY PARTICIPANTS
  • BUSINESS MODELS AND INDUSTRY PARTICIPANTS (CONTINUED)
    • TABLE 14 - EAP DEVICE MANUFACTURERS AND PRODUCT AREAS
    • TABLE 14 - EAP DEVICE MANUFACTURERS AND PRODUCT AREAS (CONTINUED)
    • TABLE 15 - MARKET SHARE OF TOP MANUFACTURERS OF EAP ACTUATORS IN 2012
  • REGIONAL MARKETS
    • FIGURE 10 - REGIONAL PERCENTAGES OF MARKET SHARE FOR EAP DEVICES, 2012 AND 2017
  • ACQUISITIONS AND MERGERS
    • TABLE 17 - PARTNERSHIP AND COLLABORATION DEALS OF POLYMER ACTUATORS, 2005 TO 2012
    • TABLE 17 - PARTNERSHIP AND COLLABORATION DEALS OF POLYMER ACTUATORS, 2005 TO 2012 (CONTINUED)

TECHNOLOGY OVERVIEW OF EAP ACTUATORS AND SENSORS

  • DIELECTRIC EAPS AND ELASTOMER ACTUATORS
  • CONSTRUCTION AND CHARACTERISTICS
  • CONSTRUCTION AND CHARACTERISTICS (CONTINUED)
    • FIGURE 11 - DIELECTRIC ELASTOMER POLYMER ACTUATOR CONSTRUCTION
  • IONIC POLYMER METAL COMPOSITES ACTUATORS
    • FIGURE 12 - STRUCTURE OF IONIC POLYMER METAL COMPOSITES
  • CONDUCTIVE POLYMER ACTUATORS
  • COMPARISON OF EAP ACTUATORS VERSUS OTHER ACTUATORS
    • FIGURE 13 - COMPARISION OF EAP ACTUATORS WITH OTHER ACTUATORS
    • FIGURE 14 - PERFORMANCE OF KEY TYPES OFACTUATORS
  • COMPARISON OF EAP SENSORS
    • TABLE 18 - COMPARISON OF IONOMERIC POLYMER SENSORS AND PIEZOELECTRIC SENSORS
  • MATERIALS USED IN EAP ACTUATORS
    • TABLE 19 - MATERIALS USED IN ELECTROACTIVE ACTUATORS AND SENSORS
  • CHARACTERSTICS OF EAP ACTUATORS
  • CHARACTERSTICS OF EAP ACTUATORS (CONTINUED)
    • TABLE 20 - CHARACTERISTICS AND PROPERTIES OF EAP-TYPE ACTUATORS
  • DEVELOPING EAP TECHNOLOGIES
    • TABLE 21 - COMPARISION OF WORK DENSITIES AND STRAINS OF EAP ACTUATORS

NEW DEVELOPMENTS AND PATENT ANALYSIS

  • U.S. PATENTS AND PATENT ANALYSIS
    • TABLE 22 - NUMBER OF U.S. PATENTS GRANTED TO COMPANIES MANUFACTURING EAP ACTUATORS AND SENSORS FROM 2008 THROUGH 2012 (TO MAY 31)
    • FIGURE 15 - TOP COMPANIES IN TERMS OF U.S.PATENTS GRANTED FOR EAP ACTUATORS AND SENSORS FROM JANUARY 2008 THROUGH MAY 012
  • OVERVIEW OF INTERNATIONAL U.S. PATENT ACTIVITY IN EAP ACTUATORS AND SENSORS
    • TABLE 23 - NUMBER OF U.S. PATENTS GRANTED BY ASSIGNED COUNTRY/REGION FOR EAP ACTUATORS AND SENSORS FROM JANUARY 2008 THROUGH MAY 2012
  • DETAILS OF U.S. PATENTS ISSUED FOR ELECTROACTIVE POLYMERS AND DEVICES
  • ELECTROACTIVE POLYMER ACTUATED DEVICES
  • INTERNAL MEDICAL DEVICES FOR DELIVERY OF THERAPEUTIC AGENT IN CONJUNCTION WITH A SOURCE OF ELECTRICAL POWER
  • DEVICES AND METHODS FOR STRICTURE DILATION
  • ELECTROACTIVE POLYMER ACTIVATION SYSTEM FOR A MEDICAL DEVICE
  • METHOD FOR FABRICATING ELECTROACTIVE POLYMER TRANSDUCER
  • ELECTROADHESIVE DEVICES
  • WALL CRAWLING ROBOTS
  • ELECTROACTIVE POLYMER BASED ARTIFICIAL SPHINCTERS AND ARTIFICIAL MUSCLE PATCHES
  • ELECTROACTIVE POLYMER DEVICE
  • ELECTROCHEMICAL ACTUATOR
  • ELECTROACTIVE POLYMER TRANSDUCERS BIASED FOR OPTIMAL OUTPUT
  • OPTICAL LENS DISPLACEMENT SYSTEMS
  • METHOD OF FABRICATING AN ELECTROACTIVE POLYMER TRANSDUCER
  • ELECTROACTIVE POLYMER ACTUATED MEDICAL DEVICES
  • ELECTROCHEMICAL ACTUATOR
  • ELECTROCHEMICAL METHODS, DEVICES, AND STRUCTURES
  • HIGH-PERFORMANCE ELECTROACTIVE POLYMER TRANSDUCERS
  • CIRCUITS FOR ELECTROACTIVE POLYMER GENERATORS
  • ELECTROACTIVE POLYMER DEVICES FOR CONTROLLING FLUID FLOW
  • ELECTROACTIVE POLYMER TRANSDUCERS FOR SENSORY FEEDBACK APPLICATIONS
  • EMBEDDED ELECTROACTIVE POLYMER STRUCTURES FOR USE IN MEDICAL DEVICES
  • OPTICAL LENS DISPLACEMENT SYSTEMS
  • ROTATABLE CATHETER ASSEMBLY
  • METHOD FOR FORMING AN ELECTROACTIVE POLYMER TRANSDUCER
  • MEDICAL BALLOON INCORPORATING ELECTROACTIVE POLYMER AND METHODS OF MAKING AND USING THE SAME
  • ELECTROACTIVE POLYMER TRANSDUCERS BIASED FOR INCREASED OUTPUT
  • ELECTROACTIVE POLYMER ACTUATED LIGHTING
  • ELECTROACTIVE POLYMER-BASED ARTICULATION MECHANISM FOR MULTI-FIRE SURGICAL FASTENING INSTRUMENT
  • FAULT-TOLERANT MATERIALS AND METHODS OF FABRICATING THE SAME
  • MONOLITHIC ELECTROACTIVE POLYMERS
  • CATHETERS HAVING ACTUATABLE LUMEN ASSEMBLIES
  • COMPLIANT ELECTROACTIVE POLYMER TRANSDUCERS FOR SONIC APPLICATIONS
  • OPTICAL LENS IMAGE STABILIZATION SYSTEMS
  • ELECTROACTIVE POLYMER-BASED ACTUATION MECHANISM FOR GRASPER
  • CONDUCTIVE POLYMER COMPOSITE STRUCTURE
  • ACTUATOR BODY AND THROTTLE MECHANISM
  • INTERNAL MEDICAL DEVICES FOR DELIVERY OF THERAPUTIC AGENT IN CONJUNCTION WITH A SOURCE OF ELECTRICAL POWER
  • TEAR RESISTANT ELECTROACTIVE POLYMER TRANSDUCERS SURFACE DEFORMATION ELECTROACTIVE POLYMER TRANSDUCERS
  • ELECTROACTIVE POLYMER PRE-STRAIN
  • MRI RESONATOR SYSTEM WITH STENT IMPLANT
  • VARIABLE STIFFNESS CATHETER ASSEMBLY
  • ELECTROACTIVE POLYMER ACTUATED GASTRIC BAND
  • ELECTROACTIVE POLYMER-BASED LUMEN TRAVERSING DEVICE
  • ELECTROACTIVE POLYMER ACTUATED MOTORS.
  • ELECTROACTIVE POLYMER-BASED PERCUTANEOUS ENDOSCOPY GASTROSTOMY TUBE AND METHODS OF USE
  • ELECTROACTIVE POLYMER TORSIONAL DEVICE
  • HAPTIC STYLUS UTILIZING AN ELECTROACTIVE POLYMER
  • POLYMER ACTUATOR HAVING ACTIVE MEMBER LAYER THAT EXPANDS OR CONTRACTS UPON APPLICATION OF ELECTRIC FIELD
  • SURGICAL STAPLING INSTRUMENTS STRUCTURED FOR DELIVERY OF MEDICAL AGENTS
  • ARTICULATION JOINT WITH IMPROVED MOMENT ARM EXTENSION FOR ARTICULATING AN END EFFECTOR OF A SURGICAL INSTRUMENT
  • ROBOTIC ENDOSCOPE
  • WAVE POWERED GENERATION
  • SURGICAL STAPLING INSTRUMENT HAVING AN ELECTROACTIVE POLYMER ACTUATED SINGLE LOCKOUT MECHANISM FOR PREVENTION OF FIRING
  • THREE-DIMENSIONAL ELECTROACTIVE POLYMER ACTUATED DEVICES
  • ELECTROACTIVE POLYMER ACTUATED DEVICES
  • ELECTROACTIVE POLYMER BASED ARTIFICIAL SPHINCTERS AND ARTIFICIAL MUSCLE PATCHES
  • SURGICAL INSTRUMENT HAVING FLUID ACTUATED OPPOSING JAWS
  • WAVE POWERED GENERATION
  • POLYMER ACTUATOR
  • MULTIPLE FIRING STROKE SURGICAL INSTRUMENT INCORPORATING ELECTROACTIVE POLYMER ANTI-BACKUP MECHANISM
  • ELECTROACTIVE POLYMER TRANSDUCERS BIASED FOR INCREASED OUTPUT
  • EXTERNAL COUNTERPULSATION DEVICE USING ELECTROACTIVE POLYMER ACTUATORS
  • SURGICAL INSTRUMENT INCORPORATING EAP COMPLETE FIRING SYSTEM LOCKOUT MECHANISM
  • ELECTROACTIVE POLYMER ELECTRODES
  • ANASTOMOTIC RING APPLIER DEVICE UTILIZING AN ELECTROACTIVE POLYMER
  • ELECTROACTIVE POLYMER MOTORS
  • BIFURCATED STENT
  • ELECTROACTIVE POLYMER PRE-STRAIN
  • HIGH POWER-TO-MASS RATIO ACTUATOR
  • ELECTROACTIVE POLYMER ANIMATED DEVICES
  • ELECTROACTIVE POLYMER-BASED ACTUATION MECHANISM FOR CIRCULAR STAPLER
  • ELECTROACTIVE POLYMER-BASED ACTUATION MECHANISM FOR LINEAR SURGICAL STAPLER
  • ELECTROACTIVE POLYMER-BASED ACTUATION MECHANISM FOR MULTI-FIRE SURGICAL FASTENING
  • INSTRUMENT
  • ELECTROACTIVE POLYMER DEVICES FOR MOVING FLUID
  • ELECTROACTIVE POLYMER TORSIONAL DEVICE
  • ELECTROACTIVE POLYMER ACTUATED HEART-LUNG BYPASS PUMPS
  • ELECTROACTIVE POLYMER GENERATORS
  • ELECTROACTIVE POLYMER-BASED PUMP
  • HAPTIC DEVICES USING ELECTROACTIVE POLYMERS
  • ELECTROACTIVE POLYMER ACTUATED SHEATH FOR IMPLANTABLE OR INSERTABLE MEDICAL DEVICE

APPENDIX I - COMPANY PROFILES

  • ARTIFICIAL MUSCLE, INC.
  • BOSTON SCIENTIFIC INC.
  • CEDRAT RECHERCHE SA (CEDRAT)
  • CENTRO RICERCHE FIAT (CRF) S.P.A.
  • CTSYSTEMS LTD.
  • CYPRESS SEMICONDUCTOR CORPORATION
  • DANFOSS POLYPOWER A/S
  • EAMEX CORPORATION
  • ENVIRONMENTAL ROBOTS INC.
  • ETHICON ENDO-SURGERY, INC. (EES)
  • HANSON ROBOTICS
  • JET PROPULSION LAB
  • MCNC RESEARCH & DEVELOPMENT INSTITUTE
  • MEDIPACS LLC
  • MICROMUSCLE AB
  • OPHTHALMOTRONICS LLC
  • OPTOTUNE AG
  • PHILIPS RESEARCH EUROPE
  • PIEZOTECH S.A.S.
  • SENSATEX INC.
  • SENSEG

APPENDIX II - LIST OF SUPPLIERS OF EAP MATERIAL

  • 3M
  • ABTECH SCIENTIFIC, INC.
  • ALFA AESAR
  • AMERICAN DYE SOURCE, INC.
  • ASAHI GLASS
  • DEGUSSA GMBH
  • DOW CORNING CORPORATION
  • DUPONT COMPANY
  • HERAEUS HOLDING
  • JOHNSON MATTHEY PLC
  • KLÖCKNER PENTAPLAST OF AMERICA, INC.
  • MARKTEK INC.
  • MERCK KGAA
  • NANOSONIC, INC.
  • ORMECON GMBH
  • RTP COMPANY
  • SIGMA-ALDRICH CORPORATION
  • STERLING FIBERS, INC.
  • SUMITOMO CHEMICAL
  • THE DOW CHEMICAL COMPANY

  • SUMMARY TABLE A - GLOBAL MARKET SIZE/PERCENTAGE SHARE FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS, 2012 AND 2017
  • SUMMARY TABLE-B-NORTH AMERICAN AND GLOBAL MARKET FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS, 2012 AND 2017
  • TABLE 1 -SUMMARY OF THE ADVANTAGES AND DISADVANTAGES OF THE TWO BASIC EAP GROUPS
  • TABLE 2 - DEFINITIONS OF TECHNICAL TERMS USED FOR ELECTRO-ACTIVE POLYMER ACTUATORS
  • TABLE 3 - GLOBAL MARKET SIZE/PERCENTAGE SHARE FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS, 2012 AND 2017
  • TABLE 4 - FORECAST OF ELECTRO-ACTIVE POLYMERS IN MICRO-PUMPS, ACTIVE CATHETERS, MRI EQUIPMENT AND EYE FOCUS CORRECTION, 2012-2017
  • TABLE 5 - FORECAST OF ELECTRO-ACTIVE POLYMER DEVICES IN DIGITAL MECHTRONICS USED IN MEDICAL BIOMETICS ROBOTICS AND TOY ROBOTICS, 2012-2017
  • TABLE 6- FORECAST OF USAGE OF EAP AS ACTUATORS IN HAPTIC APPLICATIONS , 2012-2017
  • TABLE 7 - SPECIFICATION OF TYPICAL ELECTROACTIVE POLYMER -APERTURE MECHANISM OF MOBILE PHONE
  • TABLE 8 - FORECAST OF USAGE OF EAP AS AJUSTABLE APERATURE ACTUATORS FOR CELLULAR PHONE CAMERAS APPLICATIONS 2012-2017
  • TABLE 9- FORECAST OF USAGE OF EAP AS SENSOR (DEVICES) IN CIVIL AND STRUCTURAL CONSTRUCTIONS, 2012-2017
  • TABLE 10 - FORECAST OF USAGE OF EAP AS SMART FABRIC SENSORS IN 2012-2017
  • TABLE 11 - SUMMARY OF GLOBAL MARKE OF ELECTROACTIVE POLYMER ACTUATORS BY APPLICATIONS THROUGH 2017
  • TABLE 12 - SUMMARY OF GLOBAL MARKET OF ELECTROACTIVE POLYMER ACTUATORS BY TECHNOLOGY THROUGH 2017
  • TABLE 13 - BRANDED ELECTROACTIVE POLYMER ACTUATORS IN MARKET IN 2012
  • TABLE 14 - COMPANY PRODUCT/REFERENCE OF MANUFACTURERS OF ELECTRO-ACTIVE POLYMERS ACTUATORS
  • TABLE 15 - MARKET SHARE OF TOP MANUFACTURERS OFELECTRO-ACTIVE POLYMER ACTUATORS IN 2012
  • TABLE 16 - SUMMARY OF GLOBAL MARKET OF ELECTROACTIVE POLYMER DEVICES BY REGION THROUGH 2017
  • TABLE 17 - PARTENRSHIP AND COLLABORATION DEALS OF POLYMER ACTUATORS 2005-2012
  • TABLE 18 - COMPARISON OF IONOMERIC POLYMER SENSORS AND PIEZOELECTRIC SENSORS
  • TABLE 19 - MATERIALS USED IN ELECTRO-ACTIVE ACTUATORS AND SENSORS
  • TABLE 20 - CHARACTERSTICS AND PROPERTIES OF ELECTROACTIVE POLYMER (EAP) ACTUATORS
  • TABLE 21 - COMPARISION OF WORK DENSITIES AND STRAINS OF ELECTRO-ACTIVE POLYMERS (EAP) ACTUATORS
  • TABLE 22 - NUMBER OF US. PATENTS GRANTED TO COMPANIES MANUFACTURING ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS FROM 2008 THROUGH 2012 (TO MAY 31)
  • TABLE 23 - NUMBER OF US PATENTS GRANTED BY ASSIGNED COUNTRY/REGION FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS FROM 2008 THROUGH 2012 (TO MAY 31)

LIST OF FIGURES

  • SUMMARY FIGURE A - GLOBAL MARKET SIZE/PERCENTAGE SHARE FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS, 2012 AND 2017
  • SUMMARY FIGURE B - NORTH AMERICAN AND GLOBAL MARKET FOR ELECTRO-ACTIVE POLYMER ACTUATORS AND SENSORS BY APPLICATION
  • FIGURE 1 - MARKET SHARE FOR EAP DEVICES BY APPLICATION FIGURE 2 - APPLICATION OF ELECTROACTIVE POLYMER CATHETER
  • FIGURE 3 - ILLUSTRATION EYELID SLING ATTACHED TO EAP ARTIFICIAL MUSCLE DEVICE
  • FIGURE 4 - APPLICATION OF ELECTROACTIVE POLYMER IN A DIAPHRAGM PUMP
  • FIGURE 5 - APPLICATION OF ELECTROACTIVE POLYMER ACTUATORS -ROBOTS
  • FIGURE 6 - APPLICATION OF ELECTROACTIVE POLYMER - HAPTIC SWITCH
  • FIGURE 7 - APPLICATION OF ELECTROACTIVE POLYMER - HAPTIC SWITCH-LAYOUT
  • FIGURE 8 - APPLICATION OF ELECTROACTIVE POLYMER - APERTURE MECHANISM OF PHONE CAMERAS
  • FIGURE 9 - ILLU.S.TRATION OF MARKET SHARE FOR ACTUATORS AND SENSORS BY TYPE OF EAP MATERIAL USED IN 2012 AND 2017
  • FIGURE 10 - REGIONAL PERCENTAGES OF MARKET SHARE FOR EAP AND DEVICES IN 2012 AND 2017
  • FIGURE 11 - DIELECTRIC ELASTOMER POLYMER ACTUATOR CONSTRUCTION
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