熱分解と解重合プラントが2033年までにプラスチック廃棄物を毎年2000万トン以上リサイクルする見通し
プラスチックのケミカルリサイクルと溶解 2023-2033年
混合や均質なプラスチック廃棄物の熱分解、ガス化、解重合、溶媒抽出。10年間市場予測、インタビューに基づく有力企業概要と技術評価
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プラスチックのケミカルリサイクルは著名な批評家や支持者の双方を引き付けています。これはプラスチックのバリューチェーンのすべてのステークホルダーが直面している持続可能性の課題への万能の解決策にはなりませんが、循環型経済の追求において無意味というものでもありません。この市場レポートは、熱分解、解重合、ガス化と溶解プロセスを含め、この分野の独自分析を提供しています。10年間市場予測は、重要な偏りのない見通しを提供しています。
「プラスチックのケミカルリサイクルと溶解 2023-2033年 」が対象とする主なコンテンツ
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市場分析: プラスチック廃棄物のケミカルリサイクルと溶解
● 熱分解、解重合、ガス化、溶解の10年間市場予測とポリマー別の適切な予測
● 各技術の環境影響と経済的実現可能性の概要
● 主要メーカー分析(提携関係、資金調達、生産能力拡大)
● 成功例と失敗例(製品立ち上げを含む)。エンドユーザー活動 - FMCGパッケージングの使い捨てプラスチックからテキスタイル、自動車部品、電子機器など。
● 主要ポリマーのソリューションと開発動向: PP、PET、PS、PE、PU、PMMA、PA、PC、PLA。
● 主要市場推進要因分析: 政府、企業(製品メーカー、ブランドや小売業にまたがるステークホルダー)、NGOなど。
● 世界のプラスチック・リサイクル市場動向:リサイクル率、加工流通過程、地域、リサイクル可能なデザインなどを含む
技術評価: 熱分解、解重合、ガス化と精製(溶媒抽出/溶解による)
● 循環型経済を実現するケミカルリサイクルと溶解プロセスの技術的評価(長所、制約、課題、批判、予測を含む)
● 各プロセスの技術提供者包括的サマリー
● 世界で稼働中のプラントと計画中のプロジェクトの完全リスト。対応するケミカルリサイクル市場シェア。
● 商業的影響を盛り込んだ最新の研究開発と技術トレンド分析(マイクロ波や酵素を用いた解重合プロセス、熱分解の競合となる水熱処理アプローチ、新ポリマーの開発などを含む)
● インタビューに基づく有力企業概要
When it comes to history and awareness, polymer additive manufacturing leads the 3D printing industry. The first type of 3D printing to be invented in the 1980s was stereolithography, while thermoplastic filament extrusion holds the most public recognition amongst additive technologies. In fact, IDTechEx finds that demand for polymer materials by mass far exceeds that of metal materials for 3D printing.
Source IDTechEx
With this popularity, the potential for polymer 3D printing to supply custom shoes, personalized prosthetics, or other high-value items has been increasingly explored in the past decade. Yet, actual applications of polymer AM were often restricted to prototyping and one-offs, with the limitations of polymer printing materials and lack of end-user experience preventing more meaningful usage of 3D printing in important sectors. IDTechEx's new report, Polymer Additive Manufacturing 2023-2033: Technology and Market Outlook, finds that polymer 3D printing is moving beyond prototyping to high-value adoption by end-users, which will propel its growth to $21 billion in 2033.
IDTechEx's Polymer Additive Manufacturing 2023-2033 report provides insight into the industry's growth and future through granular analysis of polymer hardware and materials demand. Any company in the polymer 3D printing supply chain or looking to enter the industry will find valuable insights in this report, like materials suppliers, printer manufacturers, service providers, end-users, and more. This report breaks down the hardware market into 10 technology segments and the materials market into 17 segments to create 85 forecast lines across 14 forecasts. The forecasts provide a ten-year outlook for polymer 3D printer installation base, revenue from polymer 3D printer sales, and mass demand and revenue for polymer 3D printing materials.
End-Use Sectors Finding Value in Polymer Additive Manufacturing
The polymer AM market is finding more end-users integrating AM into their supply chain beyond prototyping and one-offs; the question is: what industries do these end-users belong to? Through user interviews, IDTechEx has identified several application areas, such as:
- Automotive
- Consumer Goods
- Medical Devices
- Dentistry
- Aerospace and Defense
- Manufacturing Plants
IDTechEx's analysis extensively discusses these application areas where polymer additive manufacturing is finding higher-volume applications that utilize better performing materials. It is meaningful adoption in all these industries that is encouraging polymer hardware and materials purchases, helping fuel the polymer AM market's multi-billion-dollar growth over the next decade.
Technology Trends and Market Forecasts for Polymer Additive Manufacturing Hardware and Materials
Essential to understanding the evolution of the polymer 3D printing industry is exploring the change from low-cost printing technologies and materials to the slow growth and adoption of innovative polymer printing technologies and materials, from viscous thermosets to carbon fiber composites to foams. IDTechEx presents technical analyses of thirty polymer printing technologies, ranging from the established (i.e. digital light processing, selective laser sintering) to the emerging (i.e. viscous lithography manufacturing, volumetric additive manufacturing); within these analyses, the strengths, weaknesses, opportunities, and threats presented by and to each technology are identified. Similar SWOT and application analyses are provided for 17 different material categories across the main three polymer form factors - thermoplastic filaments, thermoplastic powders, and photopolymer resins. IDTechEx's deep technical exploration of polymer printing technologies and materials will provide readers with the full context surrounding the future development of polymer additive technologies and materials.
These trends, identified using extensive primary and secondary research, have informed IDTechEx's detailed 10-year market forecast for the polymer 3D printing market, which look at polymer 3D printing hardware and materials through eighty-five different forecast lines. The hardware forecasts break the market down by install base and technology type, while the materials forecasts segment the market into polymer form factor and further into polymer material categories. This analysis reveals how polymer hardware and materials sales growth will lead the industry to a $21 billion market size in 2033.
IDTechEx conducted exhaustive primary research with companies positioned throughout the entire 3D printing value chain for key insights into the trends impacting growth to 2033. This includes printer manufacturers, materials suppliers, and service providers. Over 55 company profiles have been included in the report including Stratasys, 3D Systems, EOS, Markforged, Evonik, and Covestro, amongst others. These profiles give insight into the companies leading the industry, their position amongst their competitors, and the opportunities and challenges they face in the future.
Key questions that are answered in this report
- What are the current and emerging polymer printer technology types?
- How do metrics such as price, build speed, build volume and precision vary by technology type?
- What are the strengths and weaknesses of different polymer 3D printing technologies?
- What is the current installed base of polymer 3D printers?
- Who are the main players?
- What are the market shares of those active in the market?
- What are the current and emerging polymer 3D printing materials in 2022?
- What are the market shares of each material class?
- What are the key drivers and restraints of market growth?
- What are the main application areas of polymer additive manufacturing?
- How will sales of different polymer printer types evolve from 2023 to 2033?
- What is the projected demand by mass and annual revenue growth for polymer materials from 2023 to 2033?
- How has COVID-19 positively or negatively impacted the polymer 3D printing industry?
Key aspects
This report provides the following information
Technology trends, materials trends, & manufacturer analysis
- Detailed summaries of all polymer 3D printing technologies, both established and emerging
- Comparison studies between polymer 3D printers of different technologies
- Analysis for polymer 3D printing materials, broken into three feedstock categories and seventeen individual feedstock types
- Exploration of auxiliary 3D printing categories, like post-processing and services
- Overview of additive manufacturing applications in key industries like aviation, healthcare, space, automotive, and more.
- Primary interviews with key companies.
Market Forecasts & Analysis:
- 10-year granular market forecasts of hardware unit sales, install base, and annual revenue segmented by 10 printer technologies
- 10-year granular market forecasts for polymer materials demand and revenue by 4 form factors and 17 material categories
- Extensive discussion of the COVID-19 pandemic's effects on the 3D printing industry, through primary interviews and revenue analysis.
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詳細
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アイディーテックエックス株式会社 (IDTechEx日本法人)
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担当: 村越美和子 m.murakoshi@idtechex.com
| 1. | EXECUTIVE SUMMARY AND CONCLUSIONS |
| 1.1. | The circular economy |
| 1.2. | What is chemical recycling? |
| 1.3. | Significant chemical recycling news and developments |
| 1.4. | Global plastics production increasing |
| 1.5. | The four types of recycling: Process definitions |
| 1.6. | Summary of chemical recycling approaches |
| 1.7. | Plant economics and pricing: Overview |
| 1.8. | Environmental viability of chemical recycling |
| 1.9. | Partnerships: Mixed plastics, PP, and PMMA |
| 1.10. | Partnerships: PET and PS |
| 1.11. | End-user adoption examples |
| 1.12. | Capacity and players |
| 1.13. | Overview of existing and operational plants |
| 1.14. | Market drivers |
| 1.15. | Market forecast (2021-2033) by recycling process |
| 1.16. | Market forecast (2021-2033) by polymer type |
| 1.17. | Scope for gasification processes in a circular economy |
| 1.18. | Market forecast (2021-2033) of recycling MSW |
| 1.19. | IDTechEx sustainable polymers portfolio |
| 2. | MARKET ANALYSIS |
| 2.1. | Chemical recycling market forecasts |
| 2.1.1. | Current and future capacity by process |
| 2.1.2. | Dissolution market forecast (2021-2033) by plastic waste |
| 2.1.3. | Depolymerisation market forecast (2021-2033) by plastic waste |
| 2.1.4. | Pyrolysis market forecast (2021-2033) by plastic waste |
| 2.1.5. | Gasification market forecast (2021-2033) by plastic waste |
| 2.2. | Industry activity: partnerships and products |
| 2.2.1. | Partnerships: Mixed plastics, PP, and PMMA |
| 2.2.2. | Partnerships: PET and PS |
| 2.3. | Market drivers |
| 2.3.1. | Market drivers: Governments |
| 2.3.2. | Market drivers: Brands & retailers |
| 2.3.3. | Market drivers: NGOs |
| 2.3.4. | Market drivers: Public |
| 2.4. | Environmental and economic viability |
| 2.4.1. | Impact of oil price |
| 2.4.2. | Overview of public companies |
| 2.4.3. | Concerning case studies for chemical recycling |
| 2.4.4. | Plant economics and pricing: Overview |
| 2.4.5. | Criticisms of chemical recycling |
| 2.4.6. | The environmental argument: LCAs |
| 2.4.7. | Life Cycle Assessments (LCA): Polystyrene |
| 2.4.8. | Life Cycle Assessments (LCA): Pyrolysis |
| 2.4.9. | Utilising renewable energy in chemical recycling |
| 2.5. | Applications of recycled material |
| 2.5.1. | Packaging |
| 2.5.2. | Recycled content for automotive applications |
| 2.5.3. | Chemical recycling in the automotive industry |
| 2.5.4. | Chemical recycling in the automotive industry (2) |
| 2.5.5. | Electronics: Chemical recycling opportunity |
| 2.5.6. | Carpets: Feedstock and application for chemical recycling |
| 2.5.7. | Mattresses: Feedstock and application for chemical recycling |
| 3. | CHEMICAL RECYCLING OVERVIEW |
| 3.1. | The four types of recycling: Process definitions |
| 3.2. | Understanding end-of-life plastics |
| 3.3. | Single vs multiple stream recycling |
| 3.4. | Why are plastic recycling rates so low? |
| 3.5. | Plastic recycling varies by polymer type |
| 3.6. | Recycling key polymer types |
| 3.7. | Are bioplastics the answer? |
| 3.8. | Chemical recycling in the polymer value chain |
| 3.9. | Complementary approaches for recycling |
| 3.10. | Chemical recycling PET |
| 3.11. | Chemical recycling PE |
| 3.12. | Chemical recycling PP |
| 3.13. | Chemical recycling PS |
| 3.14. | Chemical recycling other polymer types |
| 3.15. | Technology status by polymer feedstock |
| 3.16. | Closing the loop on chemical recycling |
| 3.17. | Tracking recycling: the chain of custody |
| 3.18. | Chain of custody: mass balance (1) |
| 3.19. | Chain of custody: mass balance (2) |
| 3.20. | Designing polymers with dynamic bonds |
| 3.21. | Alternative recycling routes for MSW |
| 3.22. | What is recyclability by design? |
| 4. | PYROLYSIS |
| 4.1. | Pyrolysis of plastic waste: Introduction |
| 4.2. | Pyrolysis of plastic waste - process diagram |
| 4.3. | Comparison of pyrolysis processes |
| 4.4. | Size limitations |
| 4.5. | Contamination |
| 4.6. | The impact of contamination |
| 4.7. | Hydrogen deficiency |
| 4.8. | Advantages and challenges in plastic pyrolysis |
| 4.9. | Pyrolysis drivers and restraints |
| 4.10. | Advancements in pyrolysis |
| 4.11. | Hydrothermal Liquefaction of plastic waste |
| 4.12. | Pyrolysis expansion projects: capacity (tonnes) |
| 4.13. | Plant economics and pricing: pyrolysis |
| 4.14. | Comprehensive list of pyrolysis players |
| 4.15. | Comprehensive list of hydrothermal players |
| 5. | DEPOLYMERISATION |
| 5.1. | Depolymerisation overview |
| 5.2. | Depolymerisation of PET |
| 5.3. | Depolymerisation of polystyrene |
| 5.4. | Depolymerisation of polyolefins |
| 5.5. | Depolymerisation of biodegradable polymers |
| 5.6. | Depolymerisation by product type |
| 5.7. | Depolymerisation drivers and restraints |
| 5.8. | Depolymerisation expansion projects: capacity (tonnes) |
| 5.9. | Plant economics and pricing: depolymerisation |
| 5.10. | Microwave technology for chemical recycling |
| 5.11. | Enzyme technology for chemical recycling |
| 5.12. | Enzyme technology for chemical recycling (2) |
| 5.13. | Ionic liquids role in chemical recycling |
| 5.14. | Comprehensive list of depolymerisation players |
| 6. | GASIFICATION |
| 6.1. | Gasification of plastic waste: Introduction |
| 6.2. | Scope for gasification processes in a circular economy |
| 6.3. | Understanding gasification |
| 6.4. | Options for syngas from gasification |
| 6.5. | Gasification adoption in Japan |
| 6.6. | Challenges in gasification |
| 6.7. | Gasification: integrated methanol production |
| 6.8. | Gasification: integrated Fischer-Tropsch process |
| 6.9. | Comprehensive list of gasification players |
| 6.10. | Plastic waste to hydrogen |
| 7. | SOLVENT EXTRACTION |
| 7.1. | Dissolution: technology overview |
| 7.2. | Dissolution plant overview |
| 7.3. | Dissolution plant overview (2) |
| 7.4. | Related and early-stage purification technology |
| 7.5. | Dissolution drivers and restraints |
| 7.6. | Plant economics and pricing: dissolution |
| 7.7. | VinyLoop-PVC: a warning case study |
| 7.8. | Comprehensive list of solvent extraction players |
| 8. | APPENDIX |
| 8.1. | Pyrolysis project list |
| 8.2. | Depolymerisation project list |
| 8.3. | Additional projects |
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プラスチックのケミカルリサイクルと溶解 2023-2033年
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レポート概要
| スライド | 144 |
|---|---|
| フォーキャスト | 2033 |
| ISBN | 9781915514233 |
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