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鋰離子電池回收的全球市場(2025年~2040年)
市場調查報告書
商品編碼
1555075

鋰離子電池回收的全球市場(2025年~2040年)

The Global Li-ion Battery Recycling Market 2025-2040
出版日期: | 出版商: Future Markets, Inc. | 英文 177 Pages, 29 Tables, 30 Figures, 98 Companies profiled | 訂單完成後即時交付

價格

電動車和再生能源儲存系統的日益普及推動了鋰離子電池回收市場的發展。隨著鋰離子電池的需求持續飆升,可持續的 EOL 解決方案變得至關重要。向電氣化的轉變是交通產業脫碳的關鍵部分。為了支持這項轉型和成長,電動車電池原料的穩定供應以及建立可持續的廢棄電池收集和回收系統至關重要。

預計未來 10 年回收市場將大幅擴張,數量和收入預計將大幅增加。這一成長的主要驅動力包括嚴格的環境法規、原材料成本上漲以及對循環經濟準則的日益重視。世界各國政府正在實施鼓勵電池回收的政策,而製造商也越來越認識到從廢棄電池中回收有價值的材料所帶來的經濟和環境效益。

市場格局的特點是老牌公司和創新新創公司混合在一起,每家公司都開發獨特的技術來提高回收效率和降低成本。濕式冶金、火法冶金和直接回收技術正在改進和擴大規模,以滿足不斷增長的需求。此外,機械化學預處理和電化學方法等新技術不斷湧現,有望提高回收率並減少對環境的影響。

本報告提供全球鋰離子電池回收市場相關調查分析,提供今後10年的市場趨勢,技術的進步,成長機會等相關知識和見解。

目錄

第1章 簡介

  • 鋰離子電池
    • 所謂鋰離子電池
    • 鋰離子正極
    • 鋰離子負極
    • 電池故障
    • EOL
    • 永續性
  • 電動車(EV)市場
    • 替換用電池組的新興市場
    • EV電池的封閉迴路型價值鏈
  • 鋰離子電池回收的價值鏈
  • 循環型生命週期
  • 全球法規和政策
    • 中國
    • 歐洲聯盟
    • 美國
    • 印度
    • 韓國
    • 日本
    • 澳洲
    • 運輸
  • 永續性和環境的利益

第2章 回收的手法和技術

  • 黑色粉末
  • 回收不同的陰極化學物質
  • 準備工作
  • 預處理
    • 放電
    • 機械預處理
    • 熱處理預處理
  • 回收技術比較
  • 濕式冶金
    • 手法概要
    • SWOT分析
  • 乾式冶金
    • 手法概要
    • SWOT分析
  • 直接回收
    • 手法概要
    • SWOT分析
  • 其他的手法
    • 機械化學性事前處理
    • 電化學手法
    • 離子液體
  • 特定零組件的回收
    • 負極(石墨)
    • 正極
    • 電解質
  • 鋰離子電池以外的回收
    • 傳統的流程和新的流程
    • 鋰金屬電池
    • 鋰硫電池(Li-S)
    • 全固體電池(ASSB)

第3章 市場分析

  • 推動市場要素
  • 市場課題
  • 目前市場
  • 近幾年的市場新聞,資金籌措,發展
  • 鋰離子電池回收的經濟利益
    • 金屬的價格
    • 二次能源儲存
    • LFP電池
    • 其他的零組件和材料
    • 降低成本
  • 競爭情形
  • 供應鏈
  • 全球處理能力,現行和計劃中
  • 未來預測
  • 全球市場(2018年~2040年)
    • 化學
    • 千噸
    • 收益
    • 地區

第4章 企業簡介(企業98公司的簡介)

第5章 用語和定義

第6章 調查手法

第7章 參考文獻

The market for lithium-ion battery recycling is driven by the increasing adoption of electric vehicles and renewable energy storage systems. As the demand for lithium-ion batteries continues to surge, the need for sustainable end-of-life solutions has become critical. The shift towards electrification is a crucial part of decarbonizing the mobility sector. To support this transition and growth, it is imperative to establish a stable supply of raw materials for electric vehicle batteries and a sustainable end-of-life battery collection and recycling system.

The recycling market is expected to expand significantly over the next decade, with projections indicating a substantial increase in both volume and revenue. Key factors fueling this growth include stringent environmental regulations, the rising cost of raw materials, and a growing emphasis on circular economy principles. Governments worldwide are implementing policies to encourage battery recycling, while manufacturers are increasingly recognizing the economic and environmental benefits of recovering valuable materials from spent batteries.

The market landscape is characterized by a mix of established players and innovative start-ups, each developing unique technologies to improve recycling efficiency and reduce costs. Hydrometallurgical, pyrometallurgical, and direct recycling methods are being refined and scaled up to meet the growing demand. Additionally, new techniques such as mechanochemical pre-treatment and electrochemical methods are emerging, promising higher recovery rates and lower environmental impact.

"The Global Li-ion Battery Recycling Market 2025-2035" is a comprehensive market research report that provides an in-depth analysis of the rapidly growing lithium-ion battery recycling industry. This report offers valuable insights into market trends, technological advancements, and growth opportunities in the global Li-ion battery recycling market over the next decade.

Key highlights of the report include:

  • Market Overview and Forecasts: The report provides detailed market size estimates and projections from 2025 to 2035, segmented by recycling technology, battery chemistry, and geographical region. It offers a comprehensive analysis of market drivers, restraints, opportunities, and challenges shaping the industry's future.
  • Technology Analysis: An in-depth examination of current and emerging Li-ion battery recycling technologies, including their strengths, weaknesses, opportunities, and threats (SWOT analysis).
  • Application Insights: The study explores various applications of recycled materials across multiple sectors, including electric vehicles, consumer electronics, and energy storage systems.
  • Competitive Landscape: A comprehensive analysis of key players in the Li-ion battery recycling market, including their recycling technologies, market strategies, and recent developments. The report profiles leading companies and emerging startups shaping the industry's future. Companies profiled include 24M, 4R Energy Corporation, ACE Green Recycling, Inc., Accurec Recycling GmbH, AE Elemental, Akkuser Oy, Allye Energy, Altilium, American Battery Technology Company (ABTC), Anhua Taisen, Aqua Metals, Inc., Ascend Elements, Attero Recycling, BASF, Battery Pollution Technologies, Batrec Industrie AG, Battri, Batx Energies Private Limited, BMW, Botree Cycling, CATL, Cirba Solutions, Circu Li-ion, Circunomics, Cylib, Dowa Eco-System Co., EcoBat, Econili Battery, EcoPro, Electra Battery Materials Corporation (Electra), Emulsion Flow Technologies, Energy Source, Enim, Eramet, ExPost Technology, Farasis Energy, Fortum Battery Recycling, Ganfeng Lithium, Ganzhou Cyclewell Technology Co. Ltd, GEM Co., Ltd., GLC RECYCLE PTE. LTD., Glencore, Gotion, Green Li-ion, Green Mineral, GS Group, Guangdong Guanghua Sci-Tech, Huayou Cobalt, HydroVolt, InoBat, Inmetco, J-Cycle, Inc., Jiecheng New Energy, JX Nippon Metal Mining, Keyking Recycling, Korea Zinc, Kyoei Seiko, LG Chem Ltd., Li Industries, Li-Cycle, Lithion Technologies, Lohum, Mecaware, Metastable Materials, Mitsubishi Materials, NEU Battery Materials, Nickelhutte Aue, Nth Cycle, OnTo Technology LLC, Orano, Posco HY Clean Metal, Princeton NuEnergy (PNE), ProtectLiB, RecycLiCo Battery Materials, RecycleKaro, Redivium Australia, Redwood Materials, Renewable Metals, RT Advanced Materials, Ruicycle Environmental Protection Technology, Ruilong Technology, Saidemei Resources Recycling Research Institute, Sebitchem, Shunhua Lithium, SiTration, SK Innovation Co. Ltd., Smartville Inc., Solvay, Sumitomo, Summit Nanotech, SungEel HITech, Technology Minerals plc/ Recyclus, Tozero GmbH, Umicore, Volkswagen, Voltfang, Young Poong Corp., and Zero Carbon Technologies (ZERO).
  • Future Outlook and Emerging Trends: Insights into technological advancements, potential disruptive technologies, and long-term market predictions extending to 2035 and beyond. The report identifies key growth areas and innovation hotspots in the Li-ion battery recycling industry.
  • Regional Analysis: A detailed examination of Li-ion battery recycling market dynamics across North America, Europe, Asia-Pacific, and other regions, highlighting regional adoption trends and growth opportunities.
  • Value Chain Analysis: An overview of the Li-ion battery recycling industry value chain, from battery collection to material recovery and reuse, providing a holistic view of the market ecosystem.
  • Regulatory Landscape: An examination of relevant regulations and standards affecting the development and adoption of Li-ion battery recycling technologies across different regions.

This report is an essential resource for:

  • Li-ion battery manufacturers and recyclers
  • Electric vehicle manufacturers
  • Consumer electronics companies
  • Energy storage system providers
  • Raw material suppliers and traders
  • Waste management companies
  • Investment firms and financial analysts
  • Government agencies and policymakers
  • Environmental organizations and researchers

Key features of the report include:

  • Over 100 tables and figures providing clear, data-driven insights
  • Detailed company profiles of more than 90 key players in the Li-ion battery recycling industry
  • Comprehensive market size and forecast data segmented by technology, battery chemistry, and region
  • In-depth analysis of emerging technologies and their potential impact on the market
  • Expert commentary on market trends, challenges, and opportunities

The global Li-ion battery recycling market is poised for significant growth, with increasing demand for sustainable battery lifecycle management across various industries. This report provides a thorough understanding of the current market landscape, emerging technologies, and future growth prospects, making it an invaluable tool for decision-makers looking to capitalize on opportunities in the Li-ion battery recycling sector. By leveraging extensive primary and secondary research, including interviews with industry experts and analysis of proprietary data, "The Global Li-ion Battery Recycling Market 2025-2035" offers unparalleled insights into this dynamic and rapidly evolving industry. Whether you're a technology provider, battery manufacturer, recycler, investor, or researcher, this report will equip you with the knowledge and understanding needed to navigate the exciting future of Li-ion battery recycling technologies.

TABLE OF CONTENTS

1. INTRODUCTION

  • 1.1. Lithium-ion batteries
    • 1.1.1. What is a Li-ion battery?
    • 1.1.2. Li-ion cathode
    • 1.1.3. Li-ion anode
    • 1.1.4. Battery failure
    • 1.1.5. End-of-life
    • 1.1.6. Sustainability
  • 1.2. The Electric Vehicle (EV) market
    • 1.2.1. Emerging market for replacement battery packs
    • 1.2.2. Closed-loop value chain for EV batteries
  • 1.3. Lithium-Ion Battery recycling value chain
  • 1.4. Circular life cycle
  • 1.5. Global regulations and policies
    • 1.5.1. China
    • 1.5.2. EU
    • 1.5.3. US
    • 1.5.4. India
    • 1.5.5. South Korea
    • 1.5.6. Japan
    • 1.5.7. Australia
    • 1.5.8. Transportation
  • 1.6. Sustainability and environmental benefits

2. RECYCLING METHODS AND TECHNOLOGIES

  • 2.1. Black mass powder
  • 2.2. Recycling different cathode chemistries
  • 2.3. Preparation
  • 2.4. Pre-Treatment
    • 2.4.1. Discharging
    • 2.4.2. Mechanical Pre-Treatment
    • 2.4.3. Thermal Pre-Treatment
  • 2.5. Comparison of recycling techniques
  • 2.6. Hydrometallurgy
    • 2.6.1. Method overview
      • 2.6.1.1. Solvent extraction
    • 2.6.2. SWOT analysis
  • 2.7. Pyrometallurgy
    • 2.7.1. Method overview
    • 2.7.2. SWOT analysis
  • 2.8. Direct recycling
    • 2.8.1. Method overview
      • 2.8.1.1. Electrolyte separation
      • 2.8.1.2. Separating cathode and anode materials
      • 2.8.1.3. Binder removal
      • 2.8.1.4. Relithiation
      • 2.8.1.5. Cathode recovery and rejuvenation
      • 2.8.1.6. Hydrometallurgical-direct hybrid recycling
    • 2.8.2. SWOT analysis
  • 2.9. Other methods
    • 2.9.1. Mechanochemical Pretreatment
    • 2.9.2. Electrochemical Method
    • 2.9.3. Ionic Liquids
  • 2.10. Recycling of Specific Components
    • 2.10.1. Anode (Graphite)
    • 2.10.2. Cathode
    • 2.10.3. Electrolyte
  • 2.11. Recycling of Beyond Li-ion Batteries
    • 2.11.1. Conventional vs Emerging Processes
    • 2.11.2. Li-Metal batteries
    • 2.11.3. Lithium sulfur batteries (Li-S)
    • 2.11.4. All-solid-state batteries (ASSBs)

3. MARKET ANALYSIS

  • 3.1. Market drivers
  • 3.2. Market challenges
  • 3.3. The current market
  • 3.4. Recent market news, funding and developments
  • 3.5. Economic case for Li-ion battery recycling
    • 3.5.1. Metal prices
    • 3.5.2. Second-life energy storage
    • 3.5.3. LFP batteries
    • 3.5.4. Other components and materials
    • 3.5.5. Reducing costs
  • 3.6. Competitive landscape
  • 3.7. Supply chain
  • 3.8. Global capacities, current and planned
  • 3.9. Future outlook
  • 3.10. Global market 2018-2040
    • 3.10.1. Chemistry
    • 3.10.2. Ktonnes
    • 3.10.3. Revenues
    • 3.10.4. Regional
      • 3.10.4.1. Europe
        • 3.10.4.1.1. Regional overview
      • 3.10.4.2. China
        • 3.10.4.2.1. Regional overview
      • 3.10.4.3. Rest of Asia-Pacific
        • 3.10.4.3.1. Regional overview
      • 3.10.4.4. North America
        • 3.10.4.4.1. Regional overview

4. COMPANY PROFILES(98 company profiles)

5. TERMS AND DEFINITIONS

6. RESEARCH METHODOLOGY

7. REFERENCES

List of Tables

  • Table 1. Lithium-ion (Li-ion) battery supply chain
  • Table 2. Commercial Li-ion battery cell composition
  • Table 3. Key technology trends shaping lithium-ion battery cathode development
  • Table 4. Cathode Materials Used in Commercial LIBs and Recycling Methods
  • Table 5. Fate of end-of-life Li-ion batteries
  • Table 6. Closed-loop value chain for electric vehicle (EV) batteries
  • Table 7. Li-ion battery recycling value chain
  • Table 8. Potential circular life cycle for lithium-ion batteries
  • Table 9. Regulations pertaining to the recycling and treatment of EOL batteries in the EU, USA, and China
  • Table 10. China regulations and policies related to batteries
  • Table 11. Sustainability and environmental benefits of Li-ion recycling
  • Table 12. Typical lithium-ion battery recycling process flow
  • Table 13. Main feedstock streams that can be recycled for lithium-ion batteries
  • Table 14. Comparison of LIB recycling methods
  • Table 15. Comparison of conventional and emerging processes for recycling beyond lithium-ion batteries
  • Table 16. Market drivers for lithium-ion battery recycling
  • Table 17. Market challenges in lithium-ion battery recycling
  • Table 18. Recent market news, funding and developments in Li-ion battery recycling
  • Table 19. Economic assessment of battery recycling options
  • Table 20. Retired lithium-batteries
  • Table 21. Global capacities, current and planned (tonnes/year)
  • Table 22. Global lithium-ion battery recycling market in tonnes segmented by cathode chemistry, 2018-2040
  • Table 23. Global Li-ion battery recycling market, 2018-2040 (ktonnes)
  • Table 24. Global Li-ion battery recycling market, 2018-2040 (billions USD)
  • Table 25. Li-ion battery recycling market, by region, 2018-2040 (ktonnes)
  • Table 26. Li-ion battery recycling market, in Europe, 2018-2040 (ktonnes)
  • Table 27. Li-ion battery recycling market, in China, 2018-2040 (ktonnes)
  • Table 28. Li-ion battery recycling market, in Rest of Asia-Pacific, 2018-2040 (ktonnes)
  • Table 29. Li-ion battery recycling market, in North America, 2018-2040 (ktonnes)

List of Figures

  • Figure 1. Li-ion battery cell pack
  • Figure 2. Lithium Cell Design
  • Figure 3. Functioning of a lithium-ion battery
  • Figure 4. LIB cathode recycling routes
  • Figure 5. Lithium-ion recycling process
  • Figure 6. Process for recycling lithium-ion batteries from EVs
  • Figure 7. Circular life cycle of lithium ion-batteries
  • Figure 8. Typical direct, pyrometallurgical, and hydrometallurgical recycling methods for recovery of Li-ion battery active materials
  • Figure 9. Mechanical separation flow diagram
  • Figure 10. Recupyl mechanical separation flow diagram
  • Figure 11. Flow chart of recycling processes of lithium-ion batteries (LIBs)
  • Figure 12. Hydrometallurgical recycling flow sheet
  • Figure 13. SWOT analysis for Hydrometallurgy Li-ion Battery Recycling
  • Figure 14. Umicore recycling flow diagram
  • Figure 15. SWOT analysis for Pyrometallurgy Li-ion Battery Recycling
  • Figure 16. Schematic of direct recyling process
  • Figure 17. SWOT analysis for Direct Li-ion Battery Recycling
  • Figure 18. Schematic diagram of a Li-metal battery
  • Figure 19. Schematic diagram of Lithium-sulfur battery
  • Figure 20. Schematic illustration of all-solid-state lithium battery
  • Figure 21. Li-ion Battery Recycling Market Supply Chain
  • Figure 22. Global scrapped EV (BEV+PHEV) forecast to 2040
  • Figure 23. Global Li-ion battery recycling market, 2018-2040 (chemistry)
  • Figure 24. Global Li-ion battery recycling market, 2018-2040 (ktonnes)
  • Figure 25. Global Li-ion battery recycling market, 2018-2040 (Billion USD)
  • Figure 26. Global Li-ion battery recycling market, by region, 2018-2040 (ktonnes)
  • Figure 27. Li-ion battery recycling market, in Europe, 2018-2040 (ktonnes)
  • Figure 28. Li-ion battery recycling market, in China, 2018-2040 (ktonnes)
  • Figure 29. Li-ion battery recycling market, in Rest of Asia-Pacific, 2018-2040 (ktonnes)
  • Figure 30. Li-ion battery recycling market, in North America, 2018-2040 (ktonnes)