塑胶回收 - 技术和全球市场分析

目录

摘要整理

介绍

• 塑胶回收技术的现况
  • 机械回收：已奠定基础
  • 化学回收：克服复杂性
  • 生物回收方法：下一个前沿领域
  • 协同回收：整合塑胶和其他废弃物流
• 转型为循环且更安全的聚合物价值链

生物回收技术的现况

• 生物回收技术的类型
  • 可生物分解聚合物
  • 酵素降解
  • 微生物降解
  • 混合降解方法
• 2026-2031年技术路线图
• 专利分析
  • 可生物降解聚合物
  • 生物化学回收

竞争格局

• 公司概况概述
• 公司简介：可生物降解聚合物
  • 公司概况分析结论
• 可生物降解聚合物产业面临的挑战
  • 经济限制因素
  • 技术限制因素
  • 制度障碍
• 可生物分解聚合物相关法规
  • ASTM D6400
  • ISO 17088
  • EN 13432
  • NF T 51-800
  • ASTM WK81525
  • 一次性塑胶指令
  • 欧盟包装与包装废弃物法规
• 公司简介 – 生物化学回收
  • 公司简介分析结论
• 生物化学回收业面临的挑战
  • 技术限制
  • 营运限制
  • 经济限制
• 生物化学回收相关法规
  • 欧盟
  • 美国
  • 中国

全球市场分析

• 全球可生物分解聚合物市场概述
  • 依材料分类
  • 产业趋势
  • 依应用领域分类
  • 依地区划分
• 淀粉基聚合物
• PLA基聚合物
• P BAT基聚合物
• 纤维素基聚合物
• PHA基聚合物
• PBS基聚合物
• 其他聚合物
• 可生物降解聚合物回收的现状
  • 重新定义有机回收
  • 可生物降解聚合物回收方法及当前挑战
  • 从设计阶段开始的回收解决方案
  • 可生物分解聚合物回收领域的主要参与者
• 概述：全球生化回收市场
  • 依材料划分
  • 产业趋势
  • 依应用领域划分
  • 依地区划分
• PET衍生中间体
• 尼龙衍生中间体
• 其他中间商

调查手法及实际成果

• 研究方法
• 分析师资质
• 关于 AMG NEWTECH
• 联络我们

Scope and Coverage Overview

This report examines the emergence of biorecycling as a critical pillar in the transition toward circular and lower-carbon plastics value chains. It positions biorecycling as an advanced group of technologies when compared to mechanical and chemical recycling and evaluates its role in addressing plastics that remain structurally difficult to recycle using conventional methods.

Technology Scope

The report covers biological and biochemical pathways for plastic degradation and circular reuse, including:

• Biodegradable polymers, with analysis of commercially available and emerging materials including single polymers and blends.
• Enzymatic recycling, focusing on enzyme-driven depolymerization of plastics with attention to technology status, process performance, and industrial deployment.
• Microbial degradation, assessing whole-cell biological systems, their metabolic pathways, and their current limitations.
• Hybrid biochemical recycling, integrating chemical, electrochemical, and other pretreatment with biological conversion to address hard-to-recycle plastics.

The report evaluates each pathway in terms of technology maturity, scalability, circularity potential, and other factors.

Materials Covered

The report covers over 10 polymer types as well as blends and multilayer streams.

Market and Industry Coverage

The study provides global market analysis for both biodegradable polymers and biochemical recycling intermediates, including:

• Market size and forecasts by material type, application, and region
• Industry trends shaping adoption, including regulations and end-of-life constraints
• Over nine application sectors such as agriculture, consumer goods, and packaging.

A competitive landscape section features detailed profiles and short descriptions for over 70 leading industrial players, startups, and technology developers, highlighting strategic positioning, new products, and other initiatives.

Intellectual Property and Regulation

The report includes:

• Patent landscape analysis for biodegradable polymers and biochemical recycling technologies.
• Regulatory analysis covering major international standards and policy frameworks.

Geographic Scope and Time Horizon

• Geographic coverage is global, with regional analysis for North America, Europe, Asia Pacific, and the rest of the world.
• Market forecasts and technology roadmaps span the 2026-2031 period.

What This Report Does Not Cover

• Detailed plant-level engineering designs or proprietary process parameters
• Company financials beyond publicly available information
• Consumer behavior studies unrelated to material or technology adoption

Table of Contents

EXECUTIVE SUMMARY

INTRODUCTION

• THE LANDSCAPE OF PLASTIC RECYCLING TECHNOLOGIES
  • MECHANICAL RECYCLING: THE ESTABLISHED BACKBONE
  • CHEMICAL RECYCLING: BREAKING DOWN COMPLEXITY
  • BIORECYCLING APPROACHES: THE NEXT FRONTIER
  • CO-RECYCLING: INTEGRATING PLASTICS WITH OTHER WASTE STREAMS
• TRANSITIONING TO CIRCULAR AND SAFER POLYMER VALUE CHAINS

BIORECYCLING TECHNOLOGY STATUS

• BIORECYCLING TECHNOLOGY TYPES
  • BIODEGRADABLE POLYMERS
  • ENZYMATIC DEGRADATION
  • MICROBIAL DEGRADATION
  • HYBRID METHODS
• 2026-2031 TECHNOLOGY ROADMAP
• PATENT ANALYSIS
  • BIODEGRADABLE POLYMERS
  • BIOCHEMICAL RECYCLING

COMPETITIVE LANDSCAPE

• INTRODUCTION TO COMPANY PROFILES
• COMPANY PROFILES - BIODEGRADABLE POLYMERS
  • CONCLUSIONS FROM THE COMPANY PROFILE ANALYSIS
• INDUSTRY CHALLENGES FOR BIODEGRADABLE POLYMERS
  • ECONOMIC CONSTRAINTS
  • TECHNICAL CONSTRAINTS
  • SYSTEMIC BARRIERS
• REGULATIONS RELATED TO BIODEGRADABLE POLYMERS
  • ASTM D6400
  • ISO 17088
  • EN 13432
  • NF T 51-800
  • ASTM WK81525
  • SINGLE-USE PLASTICS DIRECTIVE
  • EU PACKAGING AND PACKAGING WASTE REGULATION
• COMPANY PROFILES – BIOCHEMICAL RECYCLING
  • CONCLUSIONS FROM THE COMPANY PROFILE ANALYSIS
• INDUSTRY CHALLENGES FOR BIOCHEMICAL RECYCLING
  • TECHNICAL CONSTRAINTS
  • OPERATIONAL CONSTRAINTS
  • ECONOMIC CONSTRAINTS
• REGULATIONS RELATED TO BIOCHEMICAL RECYCLING
  • EUROPEAN UNION
  • UNITED STATES
  • CHINA

GLOBAL MARKET ANALYSIS

• GLOBAL MARKET SUMMARY FOR BIODEGRADABLE POLYMERS
  • GLOBAL MARKET BY MATERIAL TYPE
  • INDUSTRY TRENDS
  • GLOBAL MARKET BY APPLICATION
  • GLOBAL MARKET BY REGION
• STARCH-BASED POLYMERS
• PLA-BASED POLYMERS
• PBAT-BASED POLYMERS
• CELLULOSE-BASED POLYMERS
• PHA-BASED POLYMERS
• PBS-BASED POLYMERS
• OTHER POLYMERS
• CURRENT STATUS OF RECYCLING FOR BIODEGRADABLE POLYMERS
  • RECLASSIFYING ORGANIC RECYCLING
  • RECYCLING METHODS FOR BIODEGRADABLE POLYMERS AND CURRENT CHALLENGES
  • RECYCLABLE-BY-DESIGN
  • KEY PLAYERS IN RECYCLING OF BIODEGRADABLE POLYMERS
• GLOBAL MARKET SUMMARY FOR BIOCHEMICAL RECYCLING
  • GLOBAL MARKET BY MATERIAL TYPE
  • INDUSTRY TRENDS
  • GLOBAL MARKET BY APPLICATION
  • GLOBAL MARKET BY REGION
• PET-DERIVED INTERMEDIATES
• NYLON-DERIVED INTERMEDIATES
• OTHER INTERMEDIATES

METHODOLOGY AND CREDENTIALS

• METHODOLOGY
• ANALYST CREDENTIALS
• ABOUT AMG NEWTECH
• CONTACT