首页 > 市场调查报告书 > 能源/环境

燃料电池

市场调查报告书

商品编码

1568913

2024-2032年日本燃料电池堆回收再利用市场预测

Japan Fuel Cell Stack Recycling and Reuse Market Forecast 2024-2032

出版日期: 2024年10月12日 | 出版商:

Inkwood Research | 英文 140 Pages | 商品交期: 2-3个工作天内

价格

简介目录图表

主要调查结果

日本燃料电池堆回收再利用市场预计到2032年将达到 6,532万美元的收益，2024-2032年预测期间年复合成长率为 22.95%。

市场洞察

随着日本重点发展氢经济和永续发展，日本的燃料电池堆回收和再利用市场正经历显着成长。日本的氢基本策略目的是2030年建立完善的氢供应链，目的是透过间接刺激的交通和能源等各个领域促进燃料电池堆的生产和部署来进入这一市场。随着燃料电池技术变得越来越普遍，对有效回收和再利用过程来处理废电池组的需求变得越来越重要。

日本燃料电池堆回收和再利用市场的扩张受到该国到2050年实现碳中和和资源效率承诺的影响，这是其环境政策的核心。该国家战略强调燃料电池必需材料（例如铂）的回收和再利用，并支持循环经济模式。因此，燃料电池堆回收和再利用市场预计将与日本广泛的氢和清洁能源经济同步成长。

此外，日本对参与燃料电池回收的公司的补贴和税收优惠将鼓励对氢经济非常重要的基础设施发展。储能系统补助计划等计划为回收设施提供财政支持，并提高回收技术的经济可行性。这种基础设施支援对于容纳越来越多的即将报废的燃料电池堆以及充分实现燃料电池技术的环境效益非常重要。

投资氢基础设施并促进全国氢供应链将推动日本燃料电池堆回收和再利用市场的成长。将回收和再利用过程整合到氢经济中将加强资源安全，最大限度地减少浪费，并支持日本为适应气候变迁所做的努力。随着日本应对能源转型的复杂性，燃料电池堆回收和再利用市场处于有利地位，可满足永续未来的需求并解决能源领域的潜在挑战。

回收和再利用过程中的技术进步推动市场向前发展。材料回收方面的创新，特别是在铂金等贵金属的提取方面，提高回收方法的效率并减少其对环境的影响。这些技术发展不仅支持日本的永续发展目标，而且还透过将有价值的材料重新引进供应链来促进资源最佳化。

细分分析

日本的燃料电池堆回收和再利用市场依类型、回收过程和最终用途行业进行细分。回收製程板块进一步拓展为火法冶金回收、湿式冶金回收、机械回收等回收製程。

湿式冶金回收是从燃料电池堆中回收有价值金属的重要过程，特别是随着对清洁能源解决方案的需求不断成长。此方法利用水化学从废燃料电池中选择性地提取贵金属，例如铂、钯和铑。该过程包括几个关键步骤，包括浸出，用溶剂处理废燃料电池材料以溶解所需的金属。随后进行沉淀，使溶解的金属恢復为固体形式，将其分离和纯化。随后的精炼步骤提高了回收金属的品质，使其适合在新燃料电池或其他应用的生产中重复使用。

随着氢气技术的进步和可持续能源解决方案的推动，燃料电池市场不断成长，高效的湿式冶金回收製程可以最大限度地减少废弃物并改善燃料电池製造对环境的影响，这一点非常重要。这种方法不仅可以保护自然资源，还可以透过实现高价值材料的永续再利用来支持循环经济。

竞争考察

日本燃料电池堆回收再利用市场的主要公司包括Cummins Inc, Doosan Corporation, Johnson Matthey,等。

Doosan是一家总部位于韩国首尔的全球性企业集团，经营多元化业务，包括能源、机械、材料和 IT 服务。主要业务领域包括能源解决方案（Doosan Enerbility）、IT服务、广告、物流自动化、半导体测试和覆铜板製造。Doosan的子公司遍布北美、亚洲和欧洲，强调服务于广泛市场的全球足迹。到2023年，合併销售额将达到19.13兆韩元，总资产将达到28.287兆韩元，展现强大的财务基础和对工业成长的承诺。

作为永续技术创新的领导者，Doosan致力于开发支持工业发展和环境永续性的技术。公司广泛的全球网路，加上对研究和创新的投资，使Doosan成为促进永续发展和应对市场挑战的驱动力。

亲市场分析
主要市场动向
- 开发适合回收的製造技术
- 法规促进燃料电池回收并鼓励对材料回收和永续技术的投资
PESTLE分析
- 政治
- 经济
- 社会
- 技术
- 法律
- 环境
波特五力分析
成长前景图
- 日本的成长前景图
市场成熟度分析
市场集中度分析
价值链分析
主要购买基准
- 成本效益
- 环境影响
- 规制遵守
- 技术与流程效率
- 可靠性和一致性
燃料电池堆回收再利用市场监管框架

第5章市场：依类型

固体高分子形燃料电池（Pemfcs）
- 市场预测图表
- 细分分析
固体酸化物形燃料电池（Sofcs）
- 市场预测图表
- 细分分析
熔融碳酸盐燃料电池（mcfc）
- 市场预测图表
- 细分分析
磷酸燃料电池（PAFCS）
- 市场预测图表
- 细分分析
其他类型
- 市场预测图表
- 细分分析

第6章市场：依回收过程

干回收
- 市场预测图表
- 细分分析
湿式冶金回收
- 市场预测图表
- 细分分析
机械回收
- 市场预测图表
- 细分分析
其他回收流程
- 市场预测图表
- 细分分析

第7章市场：依最终用途产业

输送
- 市场预测图表
- 细分分析
固定式发电
- 市场预测图表
- 细分分析
携带式发电
- 市场预测图表
- 细分分析

第8章竞争情势

主要策略发展
- 併购
- 产品发布与开发
- 合作伙伴与协议
- 业务扩张与资产剥离
公司简介
- BALLARD POWER
- BLOOM ENERGY
- CUMINS INC
- DOOSAN CORPORATION
- JOHNSON MATTHEY
- NEDSTACK FUEL CELL TECHNOLOGY BV
- ROBERT BOSCH GMBH

简介目录图表

Product Code: 94838

KEY FINDINGS

The Japan fuel cell stack recycling and reuse market is predicted to grow at a CAGR of 22.95% over the forecast period of 2024-2032, reaching a revenue of $65.32 million by 2032.

MARKET INSIGHTS

The Japan fuel cell stack recycling and reuse market is experiencing significant growth, driven by the country's focus on developing a hydrogen-based economy and sustainability. Japan's Basic Hydrogen Strategy aimed at creating a full-fledged hydrogen supply chain by 2030, has indirectly stimulated this market by promoting the production and deployment of fuel cell stacks across various sectors, including transportation and energy. As fuel cell technology becomes more widespread, the need for efficient recycling and reuse processes to handle end-of-life stacks is increasingly crucial.

The expansion of Japan's fuel cell stack recycling and reuse market is influenced by the nation's commitment to carbon neutrality by 2050 and resource efficiency, both core aspects of its environmental policies. This national strategy highlights the recycling and reuse of critical materials in fuel cells, such as platinum, supporting a circular economy model. Consequently, the market for recycling and reusing fuel cell stacks is expected to grow in tandem with the country's broader hydrogen and clean energy economy.

Furthermore, Japan's subsidies and tax incentives for companies involved in fuel cell recycling initiatives foster the development of essential infrastructure for the hydrogen economy. Programs like the Subsidy Program for Promoting the Introduction of Energy Storage Systems offer financial support to recycling facilities, enhancing the economic feasibility of recycling technologies. This infrastructural support is pivotal for handling the increasing volume of fuel cell stacks reaching the end of their operational life, ensuring that the environmental benefits of fuel cell technologies are fully realized.

Investments in hydrogen infrastructure and the push for a national hydrogen supply chain facilitate the growth of Japan's fuel cell stack recycling and reuse market. Integrating recycling and reuse processes into the hydrogen economy enhances resource security, minimizes waste, and supports Japan's efforts in climate resilience. As Japan navigates the complexities of its energy transition, the fuel cell stack recycling and reuse market is well-positioned to meet the demands of a sustainable future and address potential challenges in the energy sector.

Technological advancements in recycling and reuse processes are driving the market forward. Innovations in materials recovery, particularly the extraction of valuable metals like platinum, have improved the efficiency of recycling methods, reducing their environmental impact. These technological developments not only support Japan's sustainability goals but also contribute to resource optimization by reintroducing valuable materials back into the supply chain.

SEGMENTATION ANALYSIS

The Japan fuel cell stack recycling and reuse market segmentation includes market by type, recycling process, and end use industry. The recycling process segment is further expanded into pyrometallurgical recycling, hydrometallurgical recycling, mechanical recycling, and other recycling processes.

Hydrometallurgical recycling is a critical process in the recovery of valuable metals from fuel cell stacks, particularly as the demand for clean energy solutions continues to rise. This method leverages aqueous chemistry to selectively extract precious metals, such as platinum, palladium, and rhodium, from spent fuel cells. The process typically involves several key steps, including leaching, where spent fuel cell materials are treated with solvents to dissolve targeted metals. This is followed by precipitation, where the dissolved metals are converted back into solid form, allowing for their separation and purification. Subsequent refining processes enhance the quality of the recovered metals, making them suitable for reuse in new fuel cell production or other applications.

As the market for fuel cells grows, driven by advancements in hydrogen technology and the push for sustainable energy solutions, efficient hydrometallurgical recycling processes will be essential for minimizing waste and reducing the environmental impact of fuel cell production. This approach not only conserves natural resources but also supports the circular economy by enabling the sustainable reuse of high-value materials.

COMPETITIVE INSIGHTS

Major players operating in the Japan fuel cell stack recycling and reuse market include Cummins Inc, Doosan Corporation, Johnson Matthey, etc.

Doosan Corporation is a global conglomerate headquartered in Seoul, South Korea, with diversified operations in energy, machinery, materials, IT services, and more. The company's key business segments include energy solutions (Doosan Enerbility), IT services, advertising, logistics automation, semiconductor testing, and the manufacturing of copper-clad laminates. Doosan's subsidiaries span across North America, Asia, and Europe, emphasizing a global footprint that caters to a broad market. With consolidated sales reaching KRW 19,130 billion in 2023 and total assets amounting to KRW 28,287 billion, the corporation showcases a strong financial base and commitment to industrial growth.

A leader in sustainable innovation, Doosan Corporation focuses on advancing technologies that support industrial development and environmental sustainability. The company's extensive global network, combined with investments in research and technological innovation, positions Doosan as a driving force in promoting sustainable development and meeting market challenges.

1. RESEARCH SCOPE & METHODOLOGY

1.1. STUDY OBJECTIVES
1.2. METHODOLOGY
1.3. ASSUMPTIONS & LIMITATIONS

2. EXECUTIVE SUMMARY

2.1. MARKET SIZE & ESTIMATES
2.2. COUNTRY SNAPSHOT - JAPAN
2.3. COUNTRY ANALYSIS
2.4. SCOPE OF STUDY
2.5. CRISIS SCENARIO ANALYSIS
2.6. MAJOR MARKET FINDINGS
- 2.6.1. STANDARDIZATION AND DESIGN FOR RECYCLING
- 2.6.2. PROTON EXCHANGE MEMBRANE FUEL CELLS ARE THE MOST COMMONLY RECYCLED AND REUSED TYPE OF FUEL CELL
- 2.6.3. PYROMETALLURGICAL RECYCLING IS THE PRIMARY PROCESS UTILIZED FOR FUEL CELL STACK RECYCLING AND REUSE
- 2.6.4. TRANSPORTATION IS THE LEADING END USE INDUSTRY FOR FUEL CELL STACK RECYCLING AND REUSE

3. MARKET DYNAMICS

3.1. KEY DRIVERS
- 3.1.1. SCARCITY OF PRECIOUS METALS
- 3.1.2. RISING ADOPTION OF FUEL CELL VEHICLES ACROSS INDUSTRIES
- 3.1.3. TECHNOLOGICAL ADVANCEMENTS IN RECYCLING METHODS
3.2. KEY RESTRAINTS
- 3.2.1. HIGH COSTS ASSOCIATED WITH RECYCLING
- 3.2.2. TECHNICAL COMPLEXITY OF RECYCLING FUEL CELLS

4. KEY ANALYTICS

4.1. PARENT MARKET ANALYSIS
4.2. KEY MARKET TRENDS
- 4.2.1. DEVELOPMENT OF RECYCLING-FRIENDLY MANUFACTURING TECHNOLOGIES
- 4.2.2. REGULATIONS DRIVE FUEL CELL RECYCLING, ENCOURAGING MATERIAL RECOVERY AND SUSTAINABLE TECH INVESTMENTS
4.3. PESTLE ANALYSIS
- 4.3.1. POLITICAL
- 4.3.2. ECONOMICAL
- 4.3.3. SOCIAL
- 4.3.4. TECHNOLOGICAL
- 4.3.5. LEGAL
- 4.3.6. ENVIRONMENTAL
4.4. PORTER'S FIVE FORCES ANALYSIS
- 4.4.1. BUYERS POWER
- 4.4.2. SUPPLIERS POWER
- 4.4.3. SUBSTITUTION
- 4.4.4. NEW ENTRANTS
- 4.4.5. INDUSTRY RIVALRY
4.5. GROWTH PROSPECT MAPPING
- 4.5.1. GROWTH PROSPECT MAPPING FOR JAPAN
4.6. MARKET MATURITY ANALYSIS
4.7. MARKET CONCENTRATION ANALYSIS
4.8. VALUE CHAIN ANALYSIS
- 4.8.1. RAW MATERIAL PROCUREMENT
- 4.8.2. FUEL CELL MANUFACTURING
- 4.8.3. FUEL CELL USAGE
- 4.8.4. END-OF-LIFE MANAGEMENT
- 4.8.5. DISMANTLING & RECYCLING
- 4.8.6. SECONDARY MARKET AND REUSE
- 4.8.7. DISPOSAL OF NON-RECYCLABLE MATERIALS
4.9. KEY BUYING CRITERIA
- 4.9.1. COST EFFECTIVENESS
- 4.9.2. ENVIRONMENTAL IMPACT
- 4.9.3. REGULATORY COMPLIANCE
- 4.9.4. TECHNOLOGY AND PROCESS EFFICIENCY
- 4.9.5. RELIABILITY AND CONSISTENCY
4.10. FUEL CELL STACK RECYCLING AND REUSE MARKET REGULATORY FRAMEWORK

5. MARKET BY TYPE

5.1. PROTON EXCHANGE MEMBRANE FUEL CELLS (PEMFCS)
- 5.1.1. MARKET FORECAST FIGURE
- 5.1.2. SEGMENT ANALYSIS
5.2. SOLID OXIDE FUEL CELLS (SOFCS)
- 5.2.1. MARKET FORECAST FIGURE
- 5.2.2. SEGMENT ANALYSIS
5.3. MOLTEN CARBONATE FUEL CELLS (MCFCS)
- 5.3.1. MARKET FORECAST FIGURE
- 5.3.2. SEGMENT ANALYSIS
5.4. PHOSPHORIC ACID FUEL CELLS (PAFCS)
- 5.4.1. MARKET FORECAST FIGURE
- 5.4.2. SEGMENT ANALYSIS
5.5. OTHER TYPES
- 5.5.1. MARKET FORECAST FIGURE
- 5.5.2. SEGMENT ANALYSIS

6. MARKET BY RECYCLING PROCESS

6.1. PYROMETALLURGICAL RECYCLING
- 6.1.1. MARKET FORECAST FIGURE
- 6.1.2. SEGMENT ANALYSIS
6.2. HYDROMETALLURGICAL RECYCLING
- 6.2.1. MARKET FORECAST FIGURE
- 6.2.2. SEGMENT ANALYSIS
6.3. MECHANICAL RECYCLING
- 6.3.1. MARKET FORECAST FIGURE
- 6.3.2. SEGMENT ANALYSIS
6.4. OTHER RECYCLING PROCESSES
- 6.4.1. MARKET FORECAST FIGURE
- 6.4.2. SEGMENT ANALYSIS

7. MARKET BY END USE INDUSTRY

7.1. TRANSPORTATION
- 7.1.1. MARKET FORECAST FIGURE
- 7.1.2. SEGMENT ANALYSIS
7.2. STATIONARY POWER GENERATION
- 7.2.1. MARKET FORECAST FIGURE
- 7.2.2. SEGMENT ANALYSIS
7.3. PORTABLE POWER GENERATION
- 7.3.1. MARKET FORECAST FIGURE
- 7.3.2. SEGMENT ANALYSIS

8. COMPETITIVE LANDSCAPE

8.1. KEY STRATEGIC DEVELOPMENTS
- 8.1.1. MERGERS & ACQUISITIONS
- 8.1.2. PRODUCT LAUNCHES & DEVELOPMENTS
- 8.1.3. PARTNERSHIPS & AGREEMENTS
- 8.1.4. BUSINESS EXPANSIONS & DIVESTITURES
8.2. COMPANY PROFILES
- 8.2.1. BALLARD POWER
  - 8.2.1.1. COMPANY OVERVIEW
  - 8.2.1.2. PRODUCTS
  - 8.2.1.3. STRENGTHS & CHALLENGES
- 8.2.2. BLOOM ENERGY
  - 8.2.2.1. COMPANY OVERVIEW
  - 8.2.2.2. PRODUCTS
  - 8.2.2.3. STRENGTHS & CHALLENGES
- 8.2.3. CUMINS INC
  - 8.2.3.1. COMPANY OVERVIEW
  - 8.2.3.2. PRODUCTS
  - 8.2.3.3. STRENGTHS & CHALLENGES
- 8.2.4. DOOSAN CORPORATION
  - 8.2.4.1. COMPANY OVERVIEW
  - 8.2.4.2. PRODUCTS
  - 8.2.4.3. STRENGTHS & CHALLENGES
- 8.2.5. JOHNSON MATTHEY
  - 8.2.5.1. COMPANY OVERVIEW
  - 8.2.5.2. PRODUCTS
  - 8.2.5.3. STRENGTHS & CHALLENGES
- 8.2.6. NEDSTACK FUEL CELL TECHNOLOGY BV
  - 8.2.6.1. COMPANY OVERVIEW
  - 8.2.6.2. PRODUCTS
  - 8.2.6.3. STRENGTHS & CHALLENGES
- 8.2.7. ROBERT BOSCH GMBH
  - 8.2.7.1. COMPANY OVERVIEW
  - 8.2.7.2. PRODUCTS
  - 8.2.7.3. STRENGTHS & CHALLENGES

简介目录图表

LIST OF TABLES

TABLE 1: MARKET SNAPSHOT - FUEL CELL STACK RECYCLING AND REUSE
TABLE 2: JAPAN REGULATORY FRAMEWORK
TABLE 3: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY TYPE, HISTORICAL YEARS 2018-2022 (IN $ MILLION)
TABLE 4: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY TYPE, FORECAST YEARS 2024-2032 (IN $ MILLION)
TABLE 5: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY RECYCLING PROCESS, HISTORICAL YEARS 2018-2022 (IN $ MILLION)
TABLE 6: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY RECYCLING PROCESS, FORECAST YEARS 2024-2032 (IN $ MILLION)
TABLE 7: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY END USE INDUSTRY, HISTORICAL YEARS 2018-2022 (IN $ MILLION)
TABLE 8: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY END USE INDUSTRY, FORECAST YEARS 2024-2032 (IN $ MILLION)
TABLE 9: LIST OF MERGERS & ACQUISITIONS
TABLE 10: LIST OF PRODUCT LAUNCHES & DEVELOPMENTS
TABLE 11: LIST OF PARTNERSHIPS & AGREEMENTS
TABLE 12: LIST OF BUSINESS EXPANSIONS & DIVESTITURES

LIST OF FIGURES

FIGURE 1: KEY MARKET TRENDS
FIGURE 2: PORTER'S FIVE FORCES ANALYSIS
FIGURE 3: GROWTH PROSPECT MAPPING FOR JAPAN
FIGURE 4: MARKET CONCENTRATION ANALYSIS
FIGURE 5: VALUE CHAIN ANALYSIS
FIGURE 6: KEY BUYING CRITERIA
FIGURE 7: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, GROWTH POTENTIAL, BY TYPE, IN 2023
FIGURE 8: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY PROTON EXCHANGE MEMBRANE FUEL CELLS (PEMFCS), 2024-2032 (IN $ MILLION)
FIGURE 9: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY SOLID OXIDE FUEL CELLS (SOFCS), 2024-2032 (IN $ MILLION)
FIGURE 10: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY MOLTEN CARBONATE FUEL CELLS (MCFCS), 2024-2032 (IN $ MILLION)
FIGURE 11: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY PHOSPHORIC ACID FUEL CELLS (PAFCS), 2024-2032 (IN $ MILLION)
FIGURE 12: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY OTHER TYPES, 2024-2032 (IN $ MILLION)
FIGURE 13: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, GROWTH POTENTIAL, BY RECYCLING PROCESS, IN 2023
FIGURE 14: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY PYROMETALLURGICAL RECYCLING, 2024-2032 (IN $ MILLION)
FIGURE 15: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY HYDROMETALLURGICAL RECYCLING, 2024-2032 (IN $ MILLION)
FIGURE 16: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY MECHANICAL RECYCLING, 2024-2032 (IN $ MILLION)
FIGURE 17: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY OTHER RECYCLING PROCESSES, 2024-2032 (IN $ MILLION)
FIGURE 18: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, GROWTH POTENTIAL, BY END USE INDUSTRY, IN 2023
FIGURE 19: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY TRANSPORTATION, 2024-2032 (IN $ MILLION)
FIGURE 20: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY STATIONARY POWER GENERATION, 2024-2032 (IN $ MILLION)
FIGURE 21: JAPAN FUEL CELL STACK RECYCLING AND REUSE MARKET, BY PORTABLE POWER GENERATION, 2024-2032 (IN $ MILLION)

02-2729-4219

+886-2-2729-4219

License/价格

2024-2032年日本燃料电池堆回收再利用市场预测

Japan Fuel Cell Stack Recycling and Reuse Market Forecast 2024-2032

主要调查结果

市场洞察

竞争考察

目录

第1章研究范围与研究方法

第2章执行摘要

第3章市场动态

第4章主要分析

第5章市场：依类型

第6章市场：依回收过程

第7章市场：依最终用途产业

第8章竞争情势

KEY FINDINGS

MARKET INSIGHTS

COMPETITIVE INSIGHTS

TABLE OF CONTENTS

1. RESEARCH SCOPE & METHODOLOGY

2. EXECUTIVE SUMMARY

3. MARKET DYNAMICS

4. KEY ANALYTICS

5. MARKET BY TYPE

6. MARKET BY RECYCLING PROCESS

7. MARKET BY END USE INDUSTRY

8. COMPETITIVE LANDSCAPE

LIST OF TABLES

LIST OF FIGURES

2024-2032年日本燃料电池堆回收再利用市场预测

Japan Fuel Cell Stack Recycling and Reuse Market Forecast 2024-2032

主要调查结果

市场洞察

竞争考察

目录

第1章 研究范围与研究方法

第2章 执行摘要

第3章 市场动态

第4章 主要分析

第5章 市场：依类型

第6章 市场：依回收过程

第7章 市场：依最终用途产业

第8章 竞争情势

KEY FINDINGS

MARKET INSIGHTS

COMPETITIVE INSIGHTS

TABLE OF CONTENTS

1. RESEARCH SCOPE & METHODOLOGY

2. EXECUTIVE SUMMARY

3. MARKET DYNAMICS

4. KEY ANALYTICS

5. MARKET BY TYPE

6. MARKET BY RECYCLING PROCESS

7. MARKET BY END USE INDUSTRY

8. COMPETITIVE LANDSCAPE

LIST OF TABLES

LIST OF FIGURES

第1章研究范围与研究方法

第2章执行摘要

第3章市场动态

第4章主要分析

第5章市场：依类型

第6章市场：依回收过程

第7章市场：依最终用途产业

第8章竞争情势