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實現塑料回收的技術進步

Technological Advancements Enabling Polymer Recycling

出版商 Frost & Sullivan 商品編碼 985474
出版日期 內容資訊 英文 96 Pages
商品交期: 最快1-2個工作天內
價格
實現塑料回收的技術進步 Technological Advancements Enabling Polymer Recycling
出版日期: 2020年12月22日內容資訊: 英文 96 Pages
簡介

本報告提供了有關各種塑料回收技術的信息,並評估了每種技術的功能,並用於機械回收,化學回收,生物回收和聯合回收等技術趨勢和每種技術的發展。分析。

目錄

戰略勢在必行

  • 戰略要務8
  • 三大戰略要務對聚合物回收的影響
  • 增長機會助推增長管道引擎
  • 調查方法

第1章執行摘要

  • 調查範圍
  • 本次調查的聚合物調查範圍
  • 主要調查結果

第2章聚合物回收:現狀分析

  • 需要聚合物回收
  • 推動聚合物回收工作的因素
  • 資源保護和回收法(RCRA)有望促進北美的回收活動
  • 歐洲綠色協議旨在使歐洲成為碳中和地區
  • 中國和日本將在未來五年內專注於聚合物回收
  • 數字技術的集成可以提高聚合物回收的效率
  • 在整個回收過程中,仍不斷出現數字技術集成
  • 越來越多的市場進入計劃將回收的內容納入投資組合,從而促進了回收活動和技術開發
  • 聚合物回收技術的當前挑戰
  • Covid-19對聚合物回收的影響:中度至嚴重影響
  • 主要回收技術

第3章技術評估:機械回收

  • 機械回收技術是聚合物回收的傳統方法
  • AgPR Arbeitsgemeinschaft PVC-Bodenbelag回收有限公司
  • AMP機器人
  • Polychem的最新機械回收技術可以回收各種聚合物
  • TRS橡膠回收具有與化學和生物回收過程整合的靈活性
  • Neidhardt Rohstoff的機械回收可以有效地回收難以回收的PVC聚合物。

第4章技術評估:化學回收

  • 化學回收對於減少多種資源的浪費具有吸引力
  • 化學回收技術的工藝流程
  • 常規熱解是應用最廣泛的化學回收技術
  • 等離子體熱解可以回收各種廢聚合物,但消耗大量能量
  • 與傳統的熱解相比,接觸熱解是一種節能過程。
  • 基於溶劑的工藝被認為具有吸引力,因為它們需要更少的能源並產生更少的二氧化碳。
  • 熱氧化工藝仍處於商業化的早期階段
  • 傳統的熱解,催化熱解和溶劑基工藝有望在不久的將來獲得發展
  • Tyromer Inc.
  • Carbon Conversions,Inc.
  • Polystyvert Inc.
  • Ioniqa Technologies B.V
  • Agilyx,Inc.
  • 溶劑溶解過程可有效回收高性能聚合物
  • Vartega的回收工藝可以為多個回收週期提供穩定,高質量的聚合物
  • 美國愛荷華州立大學的接觸加氫裂化工藝回收消費包裝廢料
  • 英國劍橋大學的微波輔助催化工藝可提供高性能聚合物
  • Madreperla的熱解工藝可生產98%的純Mma單體
  • Aquafil Engineering的解聚工藝可回收所有類型的聚□胺及其混合物
  • 美國伊士曼化學公司的碳再生技術可以徹底改變分子水平上的回收利用

第5章技術評估:生物循環

  • 生物回收是減少塑料廢物和溫室氣體排放的新技術方法
  • 與基於微生物的回收相比,□的回收具有更高的採用潛力
  • Carbios的□促工藝通過返回原始單體而無休止地回收塑料
  • 生物增強工藝成功地利用消費品包裝回收了LDPE
  • 歐洲研究人員成功鑑定出可用於多種聚合物生物回收的微生物
  • MHETase□可以成功回收各種廢聚合物
  • 歐盟委員會鼓勵□回收研究

第6章技術評估:組合回收

  • 組合回收技術是減少浪費的三明治方法
  • CuRe技術
  • Jeplan,Inc.
  • PureCycle Technologies的回收過程可以去除分子水平上的幾乎所有污染物
  • Mobius組合過程通過返回原始單體無限地回收PU
  • 用於PMMA回收和升級的單體技術
  • 弗勞恩霍夫研究所IVV組合工藝可用於有效回收多種聚合物

第7章創新指標

  • 越來越重視化學回收和生物回收
  • 全球專利活動穩定增長
  • 溶劑基和催化劑回收引領專利申請趨勢
  • □回收在知識產權領域引起關注
  • 化學品回收是融資和投資活動的重點
  • 收購是重要的利益相關者選擇策略
  • 在世界範圍內加大技術許可和研發力度

第8章增長機會

  • 增長機會1:基於溶劑的聚合物回收技術
  • 增長機會2:聚合物回收的組合技術

第9章附錄

  • 附錄:縮寫列表
  • 附錄:技術響應級別的描述

第10章主要聯繫人

第11章後續步驟

目錄
Product Code: D9D5

Increasing R&D and Technology Adoption Efforts Facilitates Value Creation from Polymer Waste

This research service titled "Technological Advancements Enabling Polymer Recycling," provides information on various recycling technologies and assess the capabilites of each technology. This research service covers different recycling technologies such as mechanical, chemical, biological, and chemical with more emphasis on the emerging technology trends and developments in chemical and biological recycling technologies.

This research service also provides a comprehensive overview of key stakeholders in the polymer recycling technology development space, and the technology readiness level for acceptance of each of the technology in a wide range of end-use industries in the near future.

Various strategies opted by stakeholders such as technology licensing, mergers and acquisitions are also highlighted along with details on recent funding for the development and commercialization of recycling technologies. The study also highlights the initiatives taken by stakeholders and researchers in the polymer recycling technology domain for development of recycled polymers with virgin polymer-like properties, which can be used in a wide range of industrial applications.

Table of Contents

Strategic Imperatives

  • The Strategic Imperative 8™
  • The Strategic Imperative 8™
  • The Impact of The Top Three Strategic Imperatives on Polymer Recycling
  • About The Growth Pipeline Engine™
  • Growth Opportunities Fuel The Growth Pipeline Engine™
  • Research Methodology

1.0 Executive Summary

  • 1.1 Research Scope
  • 1.2 Polymers of Scope in the Research Study
  • 1.3 Key Findings

2.0 Polymer Recycling: Landscape Analysis

  • 2.1 Need of Polymer Recycling
  • 2.2 Factors Driving Efforts on Polymer Recycling
  • 2.3 Resource Conservation and Recovery Act is Expected to Boost Recycling Activities in North America
  • 2.4 European Green Deal Aiming to Make Europe a Carbon Neutral Region
  • 2.5 China and Japan are Focusing on Implementing Polymer Recycling in Next Five Years
  • 2.6 Integration of Digital Technologies can Boost Efficiency of Polymer Recycling
  • 2.7 Integration of Digital Technologies is Still Emerging Across the Recycling Process
  • 2.8 Increasing Initiatives by Industry Participants to Incorporate Recycled Content in Their Portfolio Fuel Recycling Activities and Technology Development
  • 2.9 Current Challenges for Polymer Recycling Technologies
  • 2.10 Impact Of Covid-19 On Polymer Recycling- Moderate To Severe Impact
  • 2.11 Key Recycling Technologies

3.0 Technology Assessment: Mechanical Recycling

  • 3.1 Mechanical Recycling Technology is The Conventional Pathway for Polymer Recycling
  • 3.2 AgPR Arbeitsgemeinschaft PVC-Bodenbelag Recycling GmbH
  • 3.3 AMP Robotics
  • 3.4 Polychem's State-of-the-art Mechanical Recycling Technology can Recycle a Wide Spectrum of Polymers
  • 3.5 TRS's Rubber Recycling has the Flexibility to be Integrated with Chemical and Biological Recycling Processes
  • 3.6 Neidhardt Rohstoff's Mechanical Recycling can Effectively Recover Difficult to Recycle PVC Polymers

4.0 Technology Assessment: Chemical Recycling

  • 4.1 Chemical Recycling is Attractive for Reducing Waste from Multiple Sources
  • 4.2 Process Flow for Chemical Recycling Technologies
  • 4.3 Conventional Pyrolysis is the Most Widely Adopted Chemical Recycling Technology
  • 4.4 Plasma Pyrolysis can Recycle all Types of Waste Polymers, but is Highly Energy Intensive
  • 4.5 Catalytic Pyrolysis is an Energy Saving Process Compared to Conventional Pyrolysis
  • 4.6 Solvent-based Process is Considered Attractive as it Requires Less Energy and Produces Less Carbon Dioxide
  • 4.7 Thermo-oxidative Process is Still in Early Stages of Commercialization
  • 4.8 Conventional Pyrolysis, Catalytic Pyrolysis and Solvent Based Processes to Gain Momentum in the Near Future
  • 4.9 Tyromer Inc.
  • 4.10 Carbon Conversions, Inc.
  • 4.11 Polystyvert Inc.
  • 4.12 Ioniqa Technologies B.V
  • 4.13 Agilyx, Inc.
  • 4.14 Solvent Dissolution Process Can Effectively Recycle High-performance Polymers
  • 4.15 Vartega's Recycling Process can Deliver Consistent Quality Polymers for Multiple Recycling Cycles
  • 4.16 Catalytic Hydrogenolysis Process For Recycling Of Consumer Packaging Waste by Iowa State University, USA
  • 4.17 Microwave Assisted Catalytic Process Can Deliver High Performance Polymers by University of Cambridge, UK
  • 4.18 Madreperla's Thermal Cracking Process Can Yield 98% Pure Mma Monomars
  • 4.19 Aquafil Engineering's Depolymerization Process can Recycle all Types of Polyamides and Their Mixtures
  • 4.20 Carbon Renewal Technology Can Revolutionize Recycling at Molecular Level- Eastman Chemical Company, USA

5.0 Technology Assessment: Biological Recycling

  • 5.1 Biological Recycling Is An Emerging Technological Pathway For Reducing Of Plastic Waste And Greenhouse Gas Emissions
  • 5.2 Enzymatic Recycling Has High Adoption Potential Compared To Micro- Organisms-based Recycling
  • 5.3 Carbios's Enzymatic Process Recycles Plastics To Infinity By Returning To The Original Monomers
  • 5.4 Bioaugmentation Process can Successfully Recycle LDPE in Consumer Packaging
  • 5.5 Researchers in Europe Have Successfully Identified The Microorganisms For Biological Recycling Of Wide Range Of Polymers
  • 5.6 MHETase Enzyme Can Successfully Recycle Various Waste Polymers
  • 5.7 European Commission is Encouraging Research on Enzymatic Recycling

6.0 Technology Assessment: Combination Recycling

  • 6.1 Combination Recycling Technologies Is The Sandwich Pathway For Reducing Waste
  • 6.1 CuRe Technology
  • 6.2 Jeplan, Inc.
  • 6.3 PureCycle Technologies Recycling Process Can Remove Virtually All Containments At Molecular Level
  • 6.4 Mobius's Combination Process Recycles PU To Infinity By Returning To The Original Monomers
  • 6.5 Monomeros's Technology is Used for Recycling and Upcycling of PMMA
  • 6.6 Fraunhofer Institute IVV's Combination Process Can Be Leveraged For The Effective Recycling Of Wide Range Of Polymers

7.0 Innovation Indicators

  • 7.1 Growing Focus On Chemical And Biological Recycling
  • 7.2 Steady Increase in Patent Activities Across the Globe
  • 7.3 Solvent Based And Catalytic Recycling Lead in Patent Filing Trends
  • 7.4 Enzymatic Recycling Is Gaining Focus in IP Landscape
  • 7.5 Chemical Recycling is of Focus for Funding and Investment Activities
  • 7.6 Acquisition is a key Strategy Opted By Stakeholders
  • 7.7 Technology Licensing and Increase in R&D Efforts Witnessed Across the Globe

8.0 Growth Opportunities

  • 8.1 Growth Opportunity 1: Solvent-based Technology for Polymer Recycling
  • 8.1 Growth Opportunity 1: Solvent-based Technology for Polymer Recycling (Continued)
  • 8.2 Growth Opportunity 2: Combination Technology for Polymer Recycling
  • 8.2 Growth Opportunity 2: Combination Technology for Polymer Recycling (Continued)

9.0 Appendix

  • 9.1 Appendix : List of Abbreviations
  • 9.2 Appendix : Explanation of Technology Readiness Levels

10.0 Key Contacts

  • 10.1 Key Contacts

11.0 Next Steps

  • 11.1 Your Next Steps
  • 11.2 Why Frost, Why Now?
  • Legal Disclaimer