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1348578

智慧涂料的技术进步：研发与应用分析

Technological Advancement in Smart Coatings: R&D and Application Analysis

出版日期: 2023年08月30日 | 出版商:

Frost & Sullivan | 英文 113 Pages | 商品交期: 最快1-2个工作天内

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简介目录

技术策略着重于效能改进、成本降低和环境效益

智慧涂料在广泛的工业和用途领域中发挥着重要作用，因为它们具有独特的功能，例如改善表面性能、添加各种功能、提高效率、抵御环境因素以及增强结构的美观性。

Frost & Sullivan 的《智慧涂料的进展：研究、开发和用途分析》考察了多家公司和大学正在进行的研究，旨在开发领域各类别智慧涂料的新材料和工艺。主动识别和分析。开发主要分为四种方法：自修復涂层、防水涂层、导电涂层和基于感测器的涂层。此分析确定了采用智慧涂料的促进因素和阻碍因素。传统涂料液中的毒性以及重金属和挥发性有机化合物的存在将促进智慧涂料的研究、开发和普及。在北美和欧洲，EPA 和 ECHO法规以及其他严格配合措施透过减少有害排放和提高资源效率来促进永续性。然而，将智慧涂料整合到现有的製造流程中、开发新材料和遵循製造协议所需的资金以及回收构成了重大挑战。

总体而言，随着各种技术进步的整合、工业对先进功能的需求不断增加，以及对永续性和环境保护的重视，智慧涂料市场正在崛起，提供了多种成长机会。

自修復涂层概述
自修復涂料的关键性能指标
自修復涂层分类的内在和外在方法
用于改进性能和应用的新材料和变体
自修復聚合物广泛应用于各领域
自修復涂料的用途前景
自修復涂层解决的挑战
自修復涂料技术开发
积极开发自修復涂料的主要相关人员
自修復涂料的研究、开发和商业化方面的伙伴关係和协作

防水涂料技术分析

防水涂料概述
防水涂料的主要性能指标
防水涂层技术所用材料
防水涂料所用材料
防水涂料所用材料及应用领域
防水涂料的应用前景
开发防水涂料技术，满足用途中未满足的需求
积极开发防水涂料的相关人员
防水涂料研究、开发和商业化的伙伴关係和协作

导电涂料技术分析

导电涂料的独特相互作用、功能和保护特性
导电涂料的关键效能指标
用于开发导电涂层的材料
导电涂料应用前景
导电涂料的技术开发可满足未满足的应用需求
积极开发导电涂料的相关人员
导电涂料研究、开发和商业化的伙伴关係和协作

基于感测器的涂层技术分析

感测器涂层概述
基于感测器的涂层的关键性能指标
感测器涂层应用前景
积极开发基于感测器的涂层的主要相关人员
基于感测器的涂层的研究、开发和商业化的伙伴关係和协作

智慧涂料智慧财产权分析

2019年至2023年专利申请活动：智慧涂层
各地区专利申请趋势：智慧涂层
2019-2023年专利申请趋势：自修復涂料
参会企业专利申请动向：自修復涂料
按技术分類的专利申请趋势：自修復涂层
2019-2023年专利申请趋势：防水涂料
参与企业专利申请动向：防水涂料
专利申请技术趋势：防水涂层
2019-2023年专利申请趋势：导电涂料
参与企业专利申请趋势：导电涂料
按技术分類的专利申请趋势：导电涂料
2019年至2023年专利申请趋势：基于感测器的涂层
参与公司的专利申请趋势：基于感测器的涂层
按技术分類的专利申请趋势：基于感测器的涂层

弗罗斯特的视角

世界趋势：美国和加拿大
世界趋势：欧洲、英国、以色列
世界趋势：亚太地区（亚洲、澳新银行、日本、中国）
世界趋势：其他地区（中东、中南美洲、非洲、南美洲）
智慧涂料研发、加工问题及缓解方法
与製造智慧涂料相关的风险以及如何缓解这些风险
智慧涂料商业化的相关风险以及如何缓解这些风险

充满成长机会的世界

成长机会 1：提高耐用性和寿命
成长机会2：有效的回收策略
成长机会3：具有治癒功能的多功能防水涂层
成长机会4：不含PFAS的防水涂料

附录

技术成熟度等级 (TRL)：解释

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简介目录

Product Code: DAB0

Technology Strategies focus on Improved Performance, Cost Savings, and Environmental Benefits

Smart coatings play a significant role in a wide range of industrial and application segments because of their unique capabilities, such as improving surface properties, adding different functionalities, increasing efficiency, protecting against environmental elements, and enhancing the aesthetics of the structure.

Frost & Sullivan's "Advances in Smart Coatings: R&D and Application Analysis" focuses on identifying and analyzing research initiatives taken by different companies and universities for the development of novel materials and processes across different industrial segments under each category of smart coatings. The developments are categorized into four major approaches: self-healing coatings, repellent coatings, conductive coatings, and sensor-based coatings. The analytics identifies drivers and restraints that lead to the adoption of smart coatings. The toxicity of conventional coating solutions, the presence of heavy metals and volatile organic compounds drive R&D and uptake of smart coatings. EPA and ECHO regulations and other strict initiatives in North America and Europe are promoting sustainability by reducing harmful emissions and encouraging resource efficiency. However, integrating smart coatings into existing manufacturing processes, capital required to develop novel materials and follow production protocols, and recycling are major challenges.

Overall, the market for smart coatings is poised for expansion and presents several growth opportunities that are driven by the convergence of different advancements in technology, increasing industry demand for advanced functionalities, and focus on sustainability and environmental protection.

Strategic Imperatives

The Strategic Imperative 8™Factors Creating Pressure on Growth in the Smart Coatings Market
The Strategic Imperative 8™
The Impact of the Top 3 Strategic Imperatives on the Smart Coatings Industry
Growth Opportunities Fuel the Growth Pipeline Engine™
Research Methodology

Growth Opportunity Analysis

Smart Coatings to Improve Lifespan of Industrial and Consumer Products
Smart Coating Manufacturing Techniques
Additional Responsive Functionalities
Growth Drivers
Growth Restraints
Scope of Analysis
Segmentation

Technology Analysis of Self-Healing Coatings

Overview of Self-Healing Coatings
Key Performance Indicators of Self-Healing Coatings
Intrinsic or Extrinsic Approach to Self-healing Coating Classification
New Materials and Variations for Improved Performance and Application
Self-Healing Polymers Widely Used Across Sectors
Self-Healing Coating Application Outlook
Challenges that Self-healing Coatings Address
Technological Developments in Self-Healing Coatings
Key Stakeholders Active in Developing Self-Healing Coatings
Partnerships and Collaborations for R&D and Commercialization of Self-Healing Coatings

Technology Analysis of Repellent Coatings

Repellent Coatings Overview
Key Performance Indicators of Repellent Coatings
Materials Used for Repellent Coatings Technology
Materials Used for Repellent Coatings
Materials used for Repellent Coatings and Application Areas
Repellent Coatings: Application Outlook
Technological Developments in Repellent Coatings to Address Unmet Needs of Applications
Key Stakeholders Active in Developing Repellent Coatings
Partnerships and Collaborations for R&D and Commercialization of Repellent Coatings

Technology Analysis of Conductive Coatings

Unique Interactive, Functional, and Protective Properties of Conductive Coatings
Key Performance Indicators of Conductive Coatings
Materials used to Develop Conductive Coatings
Conductive Coatings: Application Outlook
Technological Developments in Conductive Coatings to Address Unmet Needs of Applications
Key Stakeholders Active in Developing Conductive Coatings
Partnerships and Collaborations for R&D and Commercialization of Conductive Coatings

Technology Analysis of Sensor-based Coatings

Sensor Coating Overview
Key Performance Indicators of Sensor-Based Coatings
Sensor Coatings: Application Outlook
Key Stakeholders Active in Developing Sensor-Based Coatings
Partnerships and Collaborations for R&D and Commercialization of Sensor-Based Coatings

Smart Coatings: IP Analysis

Patent Filing Activity from 2019 to 2023: Smart Coatings
Patent Filing Trend by Region: Smart Coatings
Patent Filing Activity from 2019 to 2023: Self-healing Coatings
Patent Filing Trend by Participant: Self-healing Coatings
Patent Filing Trend by Technology: Self-healing Coatings
Patent Filing Activity from 2019 to 2023: Repellant Coatings
Patent Filing Trend by Participant: Repellent Coatings
Patent Filing Trend by Technology: Repellent Coatings
Patent Filing Activity from 2019 to 2023: Conducive Coatings
Patent Filing Trend by Participant: Conducive Coatings
Patent Filing Trend by Technology: Conducive Coatings
Patent Filing Activity from 2019 to 2023: Sensor-based Coatings
Patent Filing Trend by Participant: Sensor-based Coatings
Patent Filing Trend by Technology: Sensor-based Coatings

Frost Perspective

Global Trends: US and Canada
Global Trends: Europe, UK, and Israel
Global Trends: APAC (Asia, ANZ, Japan and China)
Global Trends: Rest of the World (Middle East, LATAM, Africa, South America)
Challenges Related R&D, Processing of Smart Coatings and How to Mitigate hem
Risks Associated with Manufacturing of Smart Coatings and How to Mitigate Them
Risks Associated with Commercialization of Smart Coatings and How to Mitigate Them

Growth Opportunity Universe

Growth Opportunity 1: Higher Durability and Longevity
Growth Opportunity 2: Effective Recycling Strategies
Growth Opportunity 3: Multifunctional Repellent Coatings with Healing Properties
Growth Opportunity 4: PFAS-free Repellent Coatings

Appendix

Technology Readiness Levels (TRL): Explanation

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