2023-2030年全球廢物變能源技術市場

在預測期內，全球廢物變能源技術市場預計將以5.8%的複合年成長率成長。市場的成長歸功於廢物產生量的增加、嚴格的廢物管理法規和技術進步等因素。全球各地的政府和環境機構正在實施嚴格的法規和政策，以減少垃圾填埋場的廢物，促進永續的廢物管理做法。根據美國能源資訊署（EIA）的數據，城市固體廢物（MSW）通常在專門的垃圾發電廠燃燒，利用火的熱量製造蒸汽來發電或加熱建築物。 2021年，64家美國發電廠通過燃燒約2800萬噸可燃性MSW發電，產生了約136億千瓦時的電力。生質能材料佔可燃MSW重量的約61%，佔發電量的約45%。其餘的可燃MSW沒有生質能可燃材料，主要是塑膠。許多大型垃圾填埋場也通過利用垃圾填埋場內生質能分解產生的甲烷氣體來發電。許多國家使用廢物變能源工廠來獲取MSW中的能源。在一些歐洲國家和日本，垃圾發電廠的使用率相對較高，部分原因是這些國家的垃圾填埋場開放空間很小。

細分市場前景

全球廢物變能源技術市場根據應用、技術和廢物類型進行細分。基於應用，市場被分類為電力和熱能。基於技術，市場被細分為熱化學和生物化學。此外，根據廢物類型，市場被細分為城市生活垃圾、加工廢物、農業廢物和其他）。在應用部分，由於全球永續發展對電力的需求不斷增加，預計電力子部分將在全球市場上佔據突出佔有率。

城市固體廢物（MSW）細分市場預計將在全球廢物變能源技術市場中佔據突出佔有率

在廢物類型中，由於全球各地產生的大量廢物和對永續廢物管理解決方案的需求，預計城市固體廢物子部分將在全球廢物變能源技術市場上佔據突出佔有率。此外，全球人口的成長、城市化和不斷變化的消費模式導致城市固體廢物的產生大幅增加。廢物變能源技術提供了一個高效和永續的解決方案，以管理這些廢物並將其轉化為寶貴的能源資源。嚴格的環境規則和政策為垃圾變能源技術創造了有利的氛圍，這些規則和政策旨在減少垃圾填埋場的垃圾，緩解溫室氣體排放。全世界的政府都在通過鼓勵政策和財政激勵措施來鼓勵採用這些技術。

美國能源部（DOE）宣佈為11個項目提供近3400萬美元的資金，這些項目將支持高影響力的研究和開發，以改進和生產生物燃料、生物電力和生物產品。這些生質能資源，也就是所謂的原料，可以由城市固體廢物（MSW）流和海藻生產，並轉化為低碳燃料，可以大大促進在電氣化方面面臨障礙的交通部門的去碳化，如航空和航海。

目錄

第一章：報告摘要

• 當前行業分析和成長潛力展望
• 研究方法和工具
• 市場細分
  • 按領域分類
  • 按地區

第二章：市場概述和洞察力

• 報告的範圍
• 分析師的洞察力和當前的市場趨勢
  • 主要發現
  • 建議
  • 總結

第三章：競爭格局

• 主要公司分析
• Abu Dhabi National Energy Co. Pjsc (Taqa)
  • 概述
  • 財務分析
  • SWOT分析
  • 近期發展情況
• Babcock & Wilcox Enterprises, Inc.
  • 概況
  • 財務分析
  • SWOT分析
  • 近期發展情況
• John Wood Group Plc
  • 進展概況
  • 財務分析
  • SWOT分析
  • 近期發展
• 關鍵戰略分析

第四章：市場細分

• 全球垃圾發電技術的應用市場
  • 電能
  • 熱能
• 按技術分類的全球廢物變能源技術市場
  • 熱化學
  • 生物化學
• 按廢物類型分類的全球廢物變能源技術市場
  • 城市固體廢棄物
  • 工藝廢棄物
  • 農業廢棄物
  • 其他廢物

第五章：區域分析

• 北美洲
  • 美國
  • 加拿大
• 歐洲
  • 英國
  • 德國
  • 義大利
  • 西班牙
  • 法國
  • 歐洲其他地區
• 亞太地區
  • 中國
  • 印度
  • 日本
  • 韓國
  • 亞太其他地區
• 世界其他地區

第六章：公司簡介

• China Jinjiang Environment Holding Co. Ltd
• Hitachi Zosen Corp
• MVV Energie AG
• Martin GmbH
• Veolia Environnement SA
• Mitsubishi Heavy Industries Ltd
• Waste Management Inc.
• Suez Group
• Martin GmbH
• Xcel Energy Inc.
• A2A SpA
• China Everbright Limited
• Wheelabrator Technologies Holdings Inc.
• Covanta Holding Corp.
• Plasco Energy Group Inc

Title:Global Waste-to-Energy Technologies Market Size, Share & Trends Analysis Report by Application (Electricity and Heat), by Technology (Thermochemical and Biochemical), and by Waste type (Municipal Solid Waste, Process Waste, Agricultural Waste, and Others) Forecast Period (2023-2030).

The global waste-to-energy technologies market is anticipated to grow at a CAGR of 5.8% during the forecast period. The market growth is attributed to factors such as the increasing waste generation, stringent waste management regulations and technological advancements. Governments and environmental agencies across the globe are implementing stringent regulations and policies to reduce landfill waste and promote sustainable waste management practices. According to the US Energy Information Administration (EIA), municipal solid waste (MSW) is usually burned at special waste-to-energy plants that use the heat from the fire to make steam for generating electricity or to heat buildings. In 2021, 64 U.S. power plants generated about 13.6 billion kilowatt-hours of electricity from burning about 28 million tons of combustible MSW for electricity generation. Biomass materials accounted for about 61% of the weight of combustible MSW and for about 45% of the electricity generated. The remainder of the combustible MSW was no biomass combustible material, mainly plastics. Many large landfills also generate electricity by using the methane gas that is produced from decomposing biomass in landfills. Many countries use waste-to-energy plants to capture the energy in MSW. The use of waste-to-energy plants in some European countries and in Japan is relatively high, in part because those countries have little open space for landfills.

Segmental Outlook

The global waste-to-energy technologies market is segmented based on the application, technology, and waste type. Based on the application, the market is segmented into electricity and heat. Based on technology, the market is sub-segmented into thermochemical and biochemical. Further, based on waste type, the market is segmented into MSW, process waste, agricultural waste, and others). Among the application segment, the electricity sub-segment is expected to hold a prominent share of the global market owing to the growing demand for the electricity as it is being used for sustainable development globally.

The Municipal Solid Waste (MSW)Sub-Segment Is Anticipated to Hold Prominent Share in the Global Waste-To-Energy Technologies Market

Among the waste type, the municipal solid waste sub-segment is expected to hold a prominent share of the global waste-to-energy technologies market across the globe, owing to the large volume of waste generated across the globe and the need for sustainable waste management solutions. In addition, the global population's growth, urbanization, and changing consumption patterns have resulted in a significant increase in municipal solid waste generation. Waste-to-energy technologies offer an efficient and sustainable solution to manage and convert this waste into valuable energy resources. An enabling atmosphere for waste-to-energy technology has been created by stringent environmental rules and policies that aim to reduce landfill trash and mitigate greenhouse gas emissions. Governments all over the world are encouraging the adoption of these technologies through encouraging policies and financial incentives.

The US Department of Energy (DOE) announced nearly $34 million in funding for 11 projects that will support high-impact research and development to improve and produce biofuels, biopower, and bioproducts. These biomass resources, otherwise known as feedstocks, can be produced by municipal solid waste (MSW) streams and algae and converted into low-carbon fuels that can significantly contribute to the decarbonization of transportation sectors that face barriers to electrification, such as aviation and marine.

Regional Outlook

The global waste-to-energy technologies market is further segmented based on geography including North America (the US, and Canada), Europe (Italy, Spain, Germany, France, and Others), Asia-Pacific (India, China, Japan, South Korea, and Others), and the Rest of the World (the Middle East & Africa, and Latin America). Among these, the Asia-Pacific region is expected to hold a prominent growth over the forecast period owing to the increasing waste generation along with the supportive government policies and growing focus on renewable energy. Governments in the Asia-Pacific region are increasingly recognizing the importance of sustainable waste management and renewable energy sources. Many countries including India have implemented favorable policies, regulations, and financial incentives to promote waste-to-energy projects. For instance, the Indian government's Swachh Bharat Abhiyan (Clean India Mission) and the focus on renewable energy integration provide a conducive environment for the growth of the waste-to-energy market.

Global Waste-to-Energy Technologies Market Growth, by Region 2023-2030

Source: OMR Analysis

North America is Anticipated to Cater Prominent Growth in the Global Waste-to-Energy Technologies Market

Among all regions, North America is anticipated to cater prominent growth over the forecast period owing to the favorable government policies, advanced technology adoption, energy security goals, and organic waste valorization. Advanced waste-to-energy technologies includes advanced incineration systems, anaerobic digestion with biogas recovery, and thermal gasification. These technologies offer higher efficiency, lower emissions, and improved waste treatment capabilities. In this region, the governments have implemented stringent waste management regulations and environmental policies. These initiatives promote the adoption of waste-to-energy technologies as an environmentally friendly alternative to landfilling. For instance, in March 2023, The US Department of Energy's Bioenergy Technologies Office (BETO) and the National Renewable Energy Laboratory (NREL) are launching the next phase of the organic Waste-to-Energy (WTE) Technical Assistance for Local Governments. This technical assistance program provides municipalities with the most relevant data to help with decision making. Municipalities can use the most pertinent data from this technical assistance program to aid in decision-making. Communities can utilise the data from this program to assess the practical final uses for their waste, such as reusing it for on-site heat/power, transportation fuels, fertiliser recovery, or other purposes.

Market Players Outlook

The major companies serving the global Waste-to-Energy Technologies market include Abu Dhabi National Energy Company PJSC (TAQA), John Wood Group Plc, Babcock & Wilcox Enterprises, Inc., and others. The market players are considerably contributing to the market growth by the adoption of various strategies including mergers and acquisitions, partnerships, collaborations, funding, and new product launches, to stay competitive in the market. For instance, in June 2021, the Asian Development Bank (ADB) and China Everbright Environment Group Limited (CEEGL) signed a memorandum of understanding (MOU) to promote the development of enhanced solid waste management systems in Asia to encourage public-private partnerships (PPP) in waste collection, transportation, and recycling, and to reduce land-based sources of marine debris and related impacts to marine life, coastal livelihoods, and human health.

The Report Covers:

• Market value data analysis of 2022 and forecast to 2030.
• Annualized market revenues ($ million) for each market segment.
• Country-wise analysis of major geographical regions.
• Key companies operating in the global waste-to-energy technologies market. Based on the availability of data, information related to new product launches, and relevant news is also available in the report.
• Analysis of business strategies by identifying the key market segments positioned for strong growth in the future.
• Analysis of market-entry and market expansion strategies.
• Competitive strategies by identifying 'who-stands-where' in the market.

Table of Contents

1. Report Summary

• Current Industry Analysis and Growth Potential Outlook
• 1.1. Research Methods and Tools
• 1.2. Market Breakdown
  • 1.2.1. By Segments
  • 1.2.2. By Region

2. Market Overview and Insights

• 2.1. Scope of the Report
• 2.2. Analyst Insight & Current Market Trends
  • 2.2.1. Key Findings
  • 2.2.2. Recommendations
  • 2.2.3. Conclusion

3. Competitive Landscape

• 3.1. Key Company Analysis
• 3.2. Abu Dhabi National Energy Co. Pjsc (Taqa)
  • 3.2.1. Overview
  • 3.2.2. Financial Analysis
  • 3.2.3. SWOT Analysis
  • 3.2.4. Recent Developments
• 3.3. Babcock & Wilcox Enterprises, Inc.
  • 3.3.1. Overview
  • 3.3.2. Financial Analysis
  • 3.3.3. SWOT Analysis
  • 3.3.4. Recent Developments
• 3.4. John Wood Group Plc
  • 3.4.1. Overview
  • 3.4.2. Financial Analysis
  • 3.4.3. SWOT Analysis
  • 3.4.4. Recent Developments
• 3.5. Key Strategy Analysis

4. Market Segmentation

• 4.1. Global Waste-to-Energy Technologies Market by Application
  • 4.1.1. Electricity
  • 4.1.2. Heat
• 4.2. Global Waste-to-Energy Technologies Market by Technology
  • 4.2.1. Thermochemical
  • 4.2.2. Biochemical
• 4.3. Global Waste-to-Energy Technologies Market by Waste Type
  • 4.3.1. Municipal Solid Waste
  • 4.3.2. Process Waste
  • 4.3.3. Agricultural Waste
  • 4.3.4. Others

5. Regional Analysis

• 5.1. North America
  • 5.1.1. United States
  • 5.1.2. Canada
• 5.2. Europe
  • 5.2.1. UK
  • 5.2.2. Germany
  • 5.2.3. Italy
  • 5.2.4. Spain
  • 5.2.5. France
  • 5.2.6. Rest of Europe
• 5.3. Asia-Pacific
  • 5.3.1. China
  • 5.3.2. India
  • 5.3.3. Japan
  • 5.3.4. South Korea
  • 5.3.5. Rest of Asia-Pacific
• 5.4. Rest of the World

6. Company Profiles

• 6.1. China Jinjiang Environment Holding Co. Ltd
• 6.2. Hitachi Zosen Corp
• 6.3. MVV Energie AG
• 6.4. Martin GmbH
• 6.5. Veolia Environnement SA
• 6.6. Mitsubishi Heavy Industries Ltd
• 6.7. Waste Management Inc.
• 6.8. Suez Group
• 6.9. Martin GmbH
• 6.10. Xcel Energy Inc.
• 6.11. A2A S.p.A.
• 6.12. China Everbright Limited
• 6.13. Wheelabrator Technologies Holdings Inc.
• 6.14. Covanta Holding Corp.
• 6.15. Plasco Energy Group Inc

LIST OF TABLES

• 1. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY APPLICATION, 2022-2030 ($ MILLION)
• 2. GLOBAL ELECTRICITY BY WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 3. GLOBAL HEAT BY WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 4. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY TECHNOLOGY, 2022-2030 ($ MILLION)
• 5. GLOBAL THERMOCHEMICAL WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 6. GLOBAL BIOCHEMICAL WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 7. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY WASTE TYPE, 2022-2030 ($ MILLION)
• 8. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES FOR MUNICIPAL SOLID WASTE MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 9. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES FOR PROCESS WASTE MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 10. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES FOR AGRICULTURAL WASTE MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 11. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES FOR OTHER WASTES MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 12. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY REGION, 2022-2030 ($ MILLION)
• 13. NORTH AMERICAN WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY COUNTRY, 2022-2030 ($ MILLION)
• 14. NORTH AMERICAN WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY APPLICATION, 2022-2030 ($ MILLION)
• 15. NORTH AMERICAN WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY TECHNOLOGY, 2022-2030 ($ MILLION)
• 16. NORTH AMERICAN WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY WASTE TYPE, 2022-2030 ($ MILLION)
• 17. EUROPEAN WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY COUNTRY, 2022-2030 ($ MILLION)
• 18. EUROPEAN WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY APPLICATION, 2022-2030 ($ MILLION)

19. EUROPEAN WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY TECHNOLOGY, 2022-2030 ($MILLION)

• 20. EUROPEAN WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY WASTE TYPE, 2022-2030 ($ MILLION)
• 21. ASIA-PACIFIC WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY COUNTRY, 2022-2030 ($ MILLION)
• 22. ASIA-PACIFIC WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY APPLICATION, 2022-2030 ($ MILLION)
• 23. ASIA-PACIFIC WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY TECHNOLOGY, 2022-2030 ($ MILLION)
• 24. ASIA-PACIFIC WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY WASTE TYPE, 2022-2030 ($ MILLION)
• 25. REST OF THE WORLD WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY COUNTRY, 2022-2030 ($ MILLION)
• 26. REST OF THE WORLD WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY APPLICATION, 2022-2030 ($ MILLION)
• 27. REST OF THE WORLD WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY TECHNOLOGY, 2022-2030 ($ MILLION)
• 28. REST OF THE WORLD WASTE-TO-ENERGY TECHNOLOGIES MARKET RESEARCH AND ANALYSIS BY WASTE TYPE, 2022-2030 ($ MILLION)

LIST OF FIGURES

• 1. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES MARKET SHARE BY APPLICATION, 2022 VS 2030 (%)
• 2. GLOBAL ELECTRICITY BY WASTE-TO-ENERGY TECHNOLOGIES MARKET SHARE BY REGION, 2022 VS 2030 (%)
• 3. GLOBAL HEAT BY WASTE-TO-ENERGY TECHNOLOGIES MARKET SHARE BY REGION, 2022 VS 2030 (%)

4. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES MARKET SHARE BY TECHNOLOGIES, 2022 VS 2030 (%/)

• 5. GLOBAL THERMOCHEMICAL WASTE-TO-ENERGY TECHNOLOGIES MARKET SHARE BY REGION, 2022 VS 2030 (%)
• 6. GLOBAL BIOCHEMICAL WASTE-TO-ENERGY TECHNOLOGIES MARKET SHARE BY REGION, 2022 VS 2030 (%)
• 7. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES MARKET SHARE BY WASTE TYPE, 2022 VS 2030 (%)
• 8. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES FOR MUNICIPAL SOLID WASTE MARKET SHARE BY REGION, 2022 VS 2030 (%)
• 9. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES FOR PROCESS WASTE MARKET SHARE BY REGION, 2022 VS 2030 (%)
• 10. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES FOR AGRICULTURAL WASTE MARKET SHARE BY REGION, 2022 VS 2030 (%)
• 11. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES FOR OTHER WASTES MARKET SHARE BY REGION, 2022 VS 2030 (%)
• 12. GLOBAL WASTE-TO-ENERGY TECHNOLOGIES MARKET SHARE BY REGION, 2022 VS 2030 (%)
• 13. US WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 14. CANADA WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 15. UK WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 16. FRANCE WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 17. GERMANY WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 18. ITALY WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 19. SPAIN WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 20. REST OF EUROPE WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 21. INDIA WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 22. CHINA WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 23. JAPAN WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 24. SOUTH KOREA WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 25. REST OF ASIA-PACIFIC WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)
• 26. REST OF THE WORLD WASTE-TO-ENERGY TECHNOLOGIES MARKET SIZE, 2022-2030 ($ MILLION)