表紙
市場調查報告書

WtE (垃圾焚化發電) 市場 - 容量、CAPEX預測:2020年∼2030年

Waste to Energy (WtE) Market Forecast 2020-2030: Capacity (tpa) & CAPEX ($m) Forecasts for Incineration of Municipal Solid Waste (MSW) & Refuse-Derived Fuel (RDF) in Electricity Generation, District Heating & CHP, EfW Plants, Featuring Technologies

出版商 Visiongain Ltd 商品編碼 934267
出版日期 內容資訊 英文 325 Pages
商品交期: 最快1-2個工作天內
價格
WtE (垃圾焚化發電) 市場 - 容量、CAPEX預測:2020年∼2030年 Waste to Energy (WtE) Market Forecast 2020-2030: Capacity (tpa) & CAPEX ($m) Forecasts for Incineration of Municipal Solid Waste (MSW) & Refuse-Derived Fuel (RDF) in Electricity Generation, District Heating & CHP, EfW Plants, Featuring Technologies
出版日期: 2020年02月18日內容資訊: 英文 325 Pages
簡介

全球WtE (垃圾焚化發電) 市場,2019年達到164億美元,預計2020年∼至2030年以3.3%的年複合成長率成長。亞太地區,成為WtE開發主要的中心,預期在在預測期間內提供成長機會。熱技術,成為廢棄物生成能源所使用的主要技術受到關注。生物學性處理,預計2020年∼2025年以5.4%的年複合成長率急速成長。

發電的情況,CAPEX預計從2020年的146億8100萬美元,到2025年增加到179億9600萬美元,2020年∼至2025年以5.2%的年複合成長率成長。預計至2030年達到189億4100萬美元,2025年∼至2030年以1.1%的年複合成長率成長。

本報告提供全球WtE (垃圾焚化發電) 市場相關調查分析,市場概要,市場動態,市場預測,主要企業等相關的系統性資訊。

目錄

第1章 報告概要

第2章 WtE (垃圾焚化發電) 市場簡介

  • WtE (垃圾焚化發電) :概念
  • 全球WtE (垃圾焚化發電) 市場結構
  • 市場定義
  • WtE (垃圾焚化發電) 價值鏈分析
  • 市場動態

第3章 全球WtE (垃圾焚化發電) 市場概要

  • 各地區的WtE (垃圾焚化發電) 市場概要
  • 全球WtE (垃圾焚化發電) 市場的推動因素與阻礙因素

第4章 全球WtE (垃圾焚化發電) 次市場的預測

  • 全球WtE (垃圾焚化發電) 次市場的預測:各類型
  • 全球WtE (垃圾焚化發電) 次市場的預測:各用途

第5章 主要國家的WtE (垃圾焚化發電) 市場

  • 英國的WtE (垃圾焚化發電) 市場預測
  • 波蘭
  • 愛爾蘭
  • 丹麥
  • 芬蘭
  • 義大利
  • 瑞典
  • 捷克
  • 其他的歐洲
  • 中國
  • 日本
  • 印度
  • 其他的亞太地區
  • 美國
  • 加拿大
  • 南美
  • 中東、非洲

第6章 WtE (垃圾焚化發電) 市場PEST分析

  • 政治影響
  • 經濟影響
  • 社會影響
  • 技術性影響

第7章 WtE (垃圾焚化發電) 市場上主要企業

  • Covanta Energy Corporation
  • China Everbright International Limited
  • Sembcorp Industries
  • Suez Environment (SITA)
  • Keppel Seghers Belgium N.V.
  • Veolia Environmental Services
  • Wheelabrator
  • Clean Association of Tokyo 23
  • MVV Energie AG
  • China Metallurgical Group (MCC)
  • Hunan Junxin Environmental Protection
  • GCL-Poly
  • EDF
  • AMEC Foster Wheeler AG (舊:FOSTER WHEELER AG)
  • ANDRITZ AG
  • Arrow Ecology
  • Babcock & Wilcox Volund A/S
  • Biogas Nord AG
  • Biogen Greenfinch
  • BTA International Gmbh

第8章 WtE (垃圾焚化發電)的專利分析

  • 專利清單

第9章 結論與建議

第10章 詞彙表

附錄A

附錄B

目錄
Product Code: ENE0394

Title:
Waste to Energy (WtE) Market Forecast 2020-2030
Capacity (tpa) & CAPEX ($m) Forecasts for Incineration of Municipal Solid Waste (MSW) & Refuse-Derived Fuel (RDF) in Electricity Generation, District Heating & Combined Heat and Power (CHP), Energy from Waste (EfW) Plants; Featuring Technologies: Mass Burn, Gasification, Pyrolysis, Fluidised Bed, Advanced Thermal Treatment (ATT), & Advanced Conversion Technology (ACT).

Visiongain assesses that The global waste-to-energy market was valued at $16.4 billion in 2019, and it is expected to reach $22.6 billion by 2030, growing at a compound annual growth rate (CAGR) of 3.3% from 2020 to 2030. Read on to discover the potential business opportunities available.

The emergence of Asia-Pacific as a major hub for WTE development is expected to provide growth opportunities to market participants over the forecast period. The emerging economies of China and India have been developing their renewable resources to reduce carbon footprints to meet the carbon footprints seen in developed economies and have been involved in extensive R&D to develop low-cost WTE technologies. These efforts are expected to create immense opportunities for market participants.

Thermal technologies have emerged as the leading technology used for generating energy from waste. The segment accounted for 87% of total market revenue in 2019. Thermal technologies are further segregated into conventional thermal technologies and alternative thermal technologies. Thermal is the oldest and the most trusted technology used for generating energy from waste. However, the high cost associated with its installation, and its emission of harmful gases during incineration, are expected to hinder the market growth over the forecast period.

Biological treatment is expected to be the fastest growing technology at an estimated CAGR of 5.4% from 2020 to 2025. Biological treatments include the treatment of waste with microorganisms to generate energy. These methods are considered more environmental friendly than thermal technologies and are expected to increase their market penetration over the forecast period.

WTE is gaining status as an important component of integrated waste management strategies in which it plays the role of an alternative strategy to relieve the pressure on landfills. The added benefit of WTE over other waste management strategies is the potential for the extraction of energy. A major portion of this energy is used by the plant itself for its internal energy requirements; the remainder is supplied to the community.

Despite the potential that the sector offers both in terms of waste management and in terms of providing a cheap alternate energy source, many of the WTE technologies have been met with public opposition. For instance, thermal WTE projects have received bad publicity with concerns from environmental groups and local communities regarding several factors, including their impact on the environment and human health. Even though it is claimed that modern WTE combustion plants are safe and odor-free, public concern remains a barrier and continues to slow the implementation of new projects. However, several emerging technologies are much more efficient and promising and face less opposition. With growing waste volumes, the adoption of efficient and environmentally friendly waste management methods is becoming a priority for countries around the globe.

With reference to this report, waste-to-energy (WtE) facilities are considered as plants using municipal solid waste (MSW) as a primary fuel source for energy production. This includes direct combustion and advanced thermal, but not biological processes. The report covers the CAPEX spending of new and upgraded WtE plants globally. The report also forecasts MSW-processing capacity for global, regional and national markets from 2020-2030.

The report will answer questions such as:

  • What are the prospects for the overall waste-to-energy industry?
  • Where are the major investments occurring?
  • Who are the key players in the waste-to-energy industry?
  • What are the market dynamics underpinning the sector?
  • How consolidated is the sector amongst the large industry players?

Reasons Why You Must Order and Read This Report Today:

1) The report provides detailed profiles and analysis of 20 leading companies operating within the waste-to-energy market:

  • Covanta
  • China Everbright
  • Sembcorp Industries
  • Suez Environment
  • Keppel Seghers Belgium
  • Veolia Environmental
  • Wheelabrator
  • Clean Association of Tokyo 23
  • MVV Energie AG
  • China Metallurgical Group (MCC)
  • Hunan Junxin Environmental Protection
  • GCL-Poly
  • EDF
  • Amec Foster Wheeler (formerly Foster Wheeler)
  • Andritz Energy & Environment
  • Arrow Ecology
  • Babcock & Wilcox Volund A/S
  • Biogas Nord AG
  • Biogen Greenfinch
  • BTA International Gmbh

2) The study reveals where companies are investing in waste-to-energy and how much waste-processing capacity from WtE is expected. Analysis of three regional markets, national markets plus analysis of many more countries:

  • UK
  • Poland
  • Ireland
  • Denmark
  • Finland
  • Italy
  • Sweden
  • Czech Republic
  • Rest of Europe
  • India
  • China
  • Japan
  • Rest of AsiaPac
  • USA
  • Canada
  • LATAM

For electricity generation, the CAPEX is estimated to be $14,681 mn in 2020, increasing to $17,996 mn by 2025 at a CAGR of 5.2%. The market further grows but at a lower rate, reaching CAPEX of $18,941 mn by 2030, at a CAGR of 1.1% from 2025 to 2030. Overall the submarket would grow with a CAGR of 3.1% over the forecasted period.

Producing electricity is only one reason to burn MSW. Burning waste also reduces the amount of material that would probably be buried in landfills. Burning MSW reduces the volume of waste by about 87%. Generation of electricity through waste remains the major application of the global WtE market and is expected to grow more over the forecast period.

3) Discover details of hundreds of waste-to-energy projects revealing the following information in most cases:

  • Company
  • Project title
  • TPA capacity
  • MW capacity
  • $m investment
  • Completion year
  • Status

4) Learn about the following business-critical issues:

  • Legislation and landfill targets
  • Costs
  • Energy security
  • Pollution and public opposition
  • New technologies such as mass burn and advanced conversion

This independent 325-page report guarantees you will remain better informed than your competition. With 253 tables and figures examining the waste-to-energy market space, the report gives you a visual, one-stop breakdown of your market including capital expenditure forecasts from 2020-2030, as well as analysis PLUS municipal waste processing capacity forecasts from 2020-2030, keeping your knowledge that one step ahead helping you to succeed.

This report is essential reading for you or anyone in the energy or waste sectors with interest in waste-to-energy. Purchasing this report today will help you to recognise those important market opportunities and understand the possibilities there. I look forward to receiving your order.

Buy our report today Waste-to-Energy (WtE) Market Forecast 2020-2030: Capacity (tpa) & CAPEX ($m) Forecasts for Incineration of Municipal Solid Waste (MSW) & Refuse-Derived Fuel (RDF) in Electricity Generation, District Heating & Combined Heat and Power (CHP), Energy from Waste (EfW) Plants; Featuring Technologies: Mass Burn, Gasification, Pyrolysis, Fluidised Bed, Advanced Thermal Treatment (ATT), & Advanced Conversion Technology (ACT) . Avoid missing out by staying informed - order our report now.

Visiongain is a trading partner with the US Federal Government.

Table of Contents

1. Report Overview

  • 1.1 Waste-to-Energy Market Overview
  • 1.2 Market Structure Overview and Market Definition
  • 1.3 Why You Should Read This Report
  • 1.4 How This Report Delivers
  • 1.5 Key Questions Answered by This Analytical Report Include:
  • 1.6 Who is This Report For?
  • 1.7 Methodology
    • 1.7.1 Primary Research
    • 1.7.2 Secondary Research
    • 1.7.3 Market Evaluation & Forecasting Methodology
  • 1.8 Frequently Asked Questions (FAQ)
  • 1.9 Associated Visiongain Reports
  • 1.10 About Visiongain

2. Introduction to the Waste-to-Energy Market

  • 2.1 Waste-To-Energy: The Concept
  • 2.2 Global Waste-to-Energy Market Structure
  • 2.3 Market Definition
  • 2.4 Waste to Energy-Value Chain Analysis
  • 2.5 Market Dynamics
    • 2.5.1 Market Driver
    • 2.5.2 Challenges Of Waste-To-Energy
    • 2.5.3 Opportunities

3. Global Overview of Waste to Energy Market

  • 3.1 Regional Overview of Waste to Energy Market 2020-2030
  • 3.2 Global Waste to Energy Market Drivers and Restraints

4.Global Waste to Energy Submarkets Forecast 2020-2030

  • 4.1 Global Waste to Energy Submarkets Forecasts, by Type 2020-2030
    • 4.1.1 Global Thermal Waste to Energy Forecasts 2020-2030
      • 4.1.1.1 Global Thermal Waste to Energy Driver & Restraints
    • 4.1.2 Global Biological Waste to Energy Forecasts 2020-2030
      • 4.1.2.1 Global Biological WtE Driver & Restraints
    • 4.1.3 Global Waste to Energy Market- Comparison Matrix (Type VS Region)
  • 4.2 Global Waste to Energy Submarkets Forecasts, by Application 2020-2030
    • 4.2.1 Global Electricity Generation Waste to Energy Forecasts 2020-2030
      • 4.2.1.1 Global Electricity Generation Waste to Energy Driver & Restraints
    • 4.2.2 Global Steam Exports Waste to Energy Forecasts 2020-2030
      • 4.2.2.1 Global Steam Exports WtE Driver & Restraints
    • 4.2.3 Global CHP Waste to Energy Forecasts 2020-2030
      • 4.2.3.1 Global CHP WtE Driver & Restraints
    • 4.2.4 Global Waste to Energy Market- Comparison Matrix (Application VS Region)

5. Leading Nations in Waste to Energy Market 2020-2030

  • 5.1 The U.K. Waste-to-Energy Market Forecast 2020-2030
    • 5.1.1 Current Status of Waste-to-Energy in the U.K.
    • 5.1.2 U.K. Waste-to-Energy Market Analysis
    • 5.1.3 Major UK Waste-to-Energy Projects
    • 5.1.4 Drivers and Restraints in the U.K. Waste-to-Energy Market
  • 5.2 The Polish Waste-to-Energy Market Forecast 2020-2030
    • 5.2.1 Current Status of Waste-to-Energy in Poland
    • 5.2.2 Polish Waste-to-Energy Market Analysis
    • 5.2.3 Major Polish Waste-to-Energy Projects
    • 5.2.4 Drivers and Restraints in the Polish Waste-to-Energy Market
  • 5.3 The Irish Waste-to-Energy Market Forecast 2020-2030
    • 5.3.1 Current Status of Waste-to-Energy in Ireland
    • 5.3.2 Irish Waste-to-Energy Market Analysis
    • 5.3.3 Major Irish Waste-to-Energy Projects
  • 5.4 The Danish Waste-to-Energy Market Forecast 2020-2030
    • 5.4.1 Current Status of Waste-to-Energy in Denmark
    • 5.4.2 Danish Waste-to-Energy Market Analysis
    • 5.4.3 Major Danish Waste-to-Energy Projects
    • 5.4.4 Drivers and Restraints in the Danish Waste-to-Energy Market
  • 5.5 The Finnish Waste-to-Energy Market Forecast 2020-2030
    • 5.5.1 Current Status of Waste-to-Energy in Finland
    • 5.5.2 Finnish Waste-to-Energy Market Analysis
    • 5.5.3 Major Finnish Waste-to-Energy Projects
    • 5.5.4 Drivers and Restraints in the Finnish Waste-to-Energy Market
  • 5.6 The Italian Waste-to-Energy Market Forecast 2020-2030
    • 5.6.1 Current Status of Waste-to-Energy in Italy
    • 5.6.2 Italian Waste-to-Energy Market Analysis
    • 5.6.3 Major Italian Waste-to-Energy Projects
    • 5.6.4 Drivers and Restraints in the Italian Waste-to-Energy Market
  • 5.7 The Swedish Waste-to-Energy Market Forecast 2020-2030
    • 5.7.1 Current Status of Waste-to-Energy in Sweden
    • 5.7.2 Swedish Waste-to-Energy Market Analysis
    • 5.7.3 Major Swedish Waste-to-Energy Projects
    • 5.7.4 Drivers and Restraints in the Swedish Waste-to-Energy Market
  • 5.8 The Czech Republic Waste-to-Energy Market Forecast 2020-2030
    • 5.8.1 Current Status of Waste-to-Energy in Czech Republic Market
    • 5.8.2 Czech Republic Waste-to-Energy Market Analysis
    • 5.8.3 Major Czech Waste-to-Energy Projects
  • 5.9 Rest of Europe Waste-to-Energy Market Forecast 2020-2030
    • 5.9.1 The Rest of Europe Waste-to-Energy Projects
    • 5.9.2 The Emerging Markets of Eastern Europe
    • 5.9.3 The Developed Markets of Northern and Western Europe
  • 5.10 The Chinese Waste-to-Energy Market Forecast 2020-2030
    • 5.10.1 Current Status of the Chinese Waste-to-Energy Market
    • 5.10.2 Chinese Waste-to-Energy Market Analysis
    • 5.10.3 Major Chinese Waste-to-Energy Projects
    • 5.10.4 Drivers and Restraints in the Chinese Waste-to-Energy Market
  • 5.11 The Japanese Waste-to-Energy Market Forecast 2020-2030
    • 5.11.1 Current Status of Waste-to-Energy in Japan
    • 5.11.2 Japanese Waste-to-Energy Market Analysis
    • 5.11.3 Major Japanese Waste-to-Energy Projects
    • 5.11.4 Drivers and Restraints in the Japanese Waste-to-Energy Market
  • 5.12 The Indian Waste-to-Energy Market Forecast 2020-2030
    • 5.12.1 Current Status of Waste-to-Energy in India
    • 5.12.2 Indian Waste-to-Energy Market Analysis
    • 5.12.3 Major Indian Waste-to-Energy Projects
    • 5.12.4 Drivers and Restraints in the Indian Waste-to-Energy Market
  • 5.13 Rest of Asia Pacific Waste-to-Energy Market Forecast 2020-2030
    • 5.13.1 Rest of Asia-Pacific Waste-to-Energy Facilities and Upcoming Projects
    • 5.13.2 Rest of Asia-Pacific Waste-to-Energy Market Analysis
    • 5.13.3 Analysis of the Current Australian Waste-to-Energy Market
    • 5.13.4 Indonesian Market Outlook
    • 5.13.5 The Waste-to-Energy Potential in Malaysia
    • 5.13.6 Waste-to-Energy Growth Potential in the Philippines
    • 5.13.7 The Waste-to-Energy Market in Singapore
    • 5.13.8 South Korean potential in the Waste-to-Energy market
    • 5.13.9 Will the Taiwanese Market Grow?
    • 5.13.10 Can Thailand's Waste-to-Energy Market Grow?
    • 5.13.11 Vietnam's Waste-to-Energy Market
  • 5.14 The US Waste-to-Energy Market Forecast 2020-2030
    • 5.14.1 Current Status of Waste-to-Energy in the US Market
    • 5.14.2 US Waste-to-Energy Market Analysis
    • 5.14.3 Major US Waste-to-Energy Projects
    • 5.14.4 Drivers and Restraints in the US Waste-to-Energy Market
  • 5.15 The Canadian Waste-to-Energy Market Forecast 2020-2030
    • 5.15.1 Current Status of Waste-to-Energy in Canada
    • 5.15.2 Canada Waste-to-Energy Market Analysis
    • 5.15.3 Major Canadian Waste-to-Energy Projects
    • 5.15.4 Drivers and Restraints in the Canadian Waste-to-Energy Market
  • 5.16 Latin America Waste-to-Energy Market 2020-2030
    • 5.16.1 Waste-to-Energy Projects in Latin America
    • 5.16.2 Latin America Waste-to-Energy Market Analysis
  • 5.17 The Middle East & Africa Waste-to-Energy Market 2020-2030
    • 5.17.1 Waste-to-Energy Projects in the Middle East & Africa
    • 5.17.2 The Middle East & Africa Waste-to-Energy Market Analysis

6. PEST Analysis of the Waste-to-Energy Market

  • 6.1 Political Impact
  • 6.2 Economic Impact
  • 6.3 Social Impact
  • 6.4 Technological Impact

7. Leading Companies in Waste-to-Energy Market

  • 7.1 Covanta Energy Corporation
    • 7.1.1 Covanta Company Analysis
    • 7.1.2 Covanta Future Outlook & Business Strategy
  • 7.2 China Everbright International Limited
    • 7.2.1 China Everbright Company Analysis
    • 7.2.2 China Everbright Future Outlook & Business Strategy
  • 7.3 Sembcorp Industries
    • 7.3.1 Sembcorp Industries Company Analysis
    • 7.3.2 Sembcorp Industries Company Outlook
  • 7.4 Suez Environment (SITA)
    • 7.4.1 Suez Environment Company Analysis
    • 7.4.2 Suez Environment Company Outlook
  • 7.5 Keppel Seghers Belgium N.V.
    • 7.5.1 Keppel Seghers Company Analysis
    • 7.5.2 Keppel Seghers Future Outlook & Business Strategy
  • 7.6 Veolia Environmental Services
    • 7.6.1 Veolia Business Overview
    • 7.6.2 Veolia Recent Developments
    • 7.6.3 Veolia Business Strategy
  • 7.7 Wheelabrator
    • 7.7.1 Wheelabrator Business Overview
    • 7.7.2 Wheelabrator Recent Developments
    • 7.7.3 Wheelabrator Business Strategy
  • 7.8 Clean Association of Tokyo 23
    • 7.8.1 Clean Association of Tokyo 23 Business Overview
    • 7.8.2 Clean Association of Tokyo 23 Business Strategy
  • 7.9 MVV Energie AG
    • 7.9.1 MVV Energie AG Business Overview
    • 7.9.2 MVV Energie AG Business Strategy
  • 7.10 China Metallurgical Group (MCC)
    • 7.10.1 China Metallurgical Group (MCC) Business Overview
    • 7.10.2 China Metallurgical Group (MCC) Business Strategy
  • 7.11 Hunan Junxin Environmental Protection
    • 7.11.1 Hunan Junxin Environmental Protection Business Overview
    • 7.11.2 Hunan Junxin Environmental Protection Business Strategy
  • 7.12 GCL-Poly
    • 7.12.1 GCL-Poly Business Overview
  • 7.13 EDF
    • 7.13.1 EDF Business Overview
    • 7.13.2 EDF Business Strategy
  • 7.14 AMEC Foster Wheeler AG (Formerly FOSTER WHEELER AG)
    • 7.14.1 Business Overview
    • 7.14.2 AMEC Forest Wheeler's Product Portfolio
  • 7.15 ANDRITZ AG
    • 7.15.1 Business Overview
    • 7.15.2 ANDRITZ' Product Portfolio
  • 7.16 Arrow Ecology
    • 7.16.1 Business Overview
    • 7.16.2 Arrow Ecology's Product Portfolio
  • 7.17 Babcock & Wilcox Volund A/S
    • 7.17.1 Business Overview
    • 7.17.2 Babcock & Wilson Vφlund's Product Portfolio
  • 7.18 Biogas Nord AG
    • 7.18.1 Business Overview
    • 7.18.2 Biogas Nord's Product Portfolio
  • 7.19 Biogen Greenfinch
    • 7.19.1 Biogen's Product Portfolio
  • 7.20 BTA International Gmbh
    • 7.20.1 Business Overview
    • 7.20.2 BTA'S Product Portfolio

8. Waste-to-Energy Patent Analysis

  • 8.1 List of Patents

9. Conclusion & Recommendations

  • 9.1 Recommendations
  • 9.2 Policy Recommendations

10. Glossary

  • Associated Visiongain Reports
  • Visiongain Report Sales Order Form

Appendix A

  • About Visiongain

Appendix B

  • Visiongain report evaluation form

List of Tables

  • Table 2.1 Competing Renewable Technologies
  • Table 3.1 Global Waste to Energy Market Forecast 2020-2030 (MTPA, $ mn, AGR %, CAGR %, Cumulative)
  • Table 3.2 Global Waste to Energy Market by Regional Forecast 2020-2030 (MTPA, AGR %, CAGR %, Cumulative)
  • Table 3.3 Global Waste to Energy Market by Regional Forecast 2020-2030 ($mn, AGR %, CAGR %, Cumulative)
  • Table 3.4 Global Waste to Energy Market Drivers and Restraints
  • Table 4.1 Global Waste to Energy Market By Type Forecast 2020-2030 ($mn, MTPA, AGR %, Cumulative)
  • Table 4.2 Key Conventional WtE Suppliers By Type Of Technology
  • Table 4.3 Key Alternative Thermal WtE Technology Providers With Number Of Plants, Throughput And Technology Configuration
  • Table 4.4 Comparison Of Conventional Technologies With Alternative Wte Technologies
  • Table 4.5 Global Thermal Waste to Energy Market by Forecast 2020-2030 ($mn, MTPA, AGR %, CAGR %, Cumulative)
  • Table 4.6 Global Thermal Waste to Energy Market Drivers and Restraints
  • Table 4.7 Typical Components Of Biogas And Their Impacts On Biogas Quality
  • Table 4.8 Potential Of MSW
  • Table 4.9 Comparison Of Anaerobic And Aerobic Degradation Processes
  • Table 4.10 Global Biological Waste to Energy Market by Forecast 2020-2030 ($mn, MTPA, AGR %, CAGR %, Cumulative)
  • Table 4.11 Global Biological WtE Drivers and Restraints
  • Table 4.12 Global Waste to Energy Market Forecast 2020-2030, by Application ($mn, MTPA, AGR %, Cumulative)
  • Table 4.13 Global Electricity Generation Waste to Energy Market by Forecast 2020-2030 ($mn, MTPA, AGR %, CAGR %, Cumulative)
  • Table 4.14 Global Electricity Generation Waste to Energy Market Drivers and Restraints
  • Table 4.15 Global Steam Exports Waste to Energy Market by Forecast 2020-2030 ($mn, MTPA, AGR %, CAGR %, Cumulative)
  • Table 4.16 Global Steam Exports WtE Drivers and Restraints
  • Table 4.17 Global CHP Waste to Energy Market by Forecast 2020-2030 ($mn, MTPA, AGR %, CAGR %, Cumulative)
  • Table 4.18 Global CHP WtE Drivers and Restraints
  • Table 5.1 Global Waste-to-Energy Market, by Nation Forecast 2020-2030 ($Mn, AGR %, CAGR %, Cumulative)
  • Table 5.2 Global Waste-to-Energy Market, by Nation Forecast 2020-2030 (MTPA, AGR %, CAGR %, Cumulative)
  • Table 5.3 U.K. Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.4 Key U.K. WtE Statistics (Population, Annual MSW Production, Annual MSW Production per Capita, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction, 2019)
  • Table 5.5 Projects Awarded Contracts for Difference under Allocation Round One (Project Name, Developer, Technology, MW, £ / $ Strike Price, Delivery Year)
  • Table 5.6 Key UK WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.7 Driver and Restraints in the U.K. Waste-to-Energy Market
  • Table 5.8 Polish Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.9 Key Polish WtE Statistics (Population, Annual MSW Production, Annual MSW Production per Capita, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)-2019
  • Table 5.10 Major Polish WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.11 Drivers and Restraints in the Polish Waste-to-Energy Market
  • Table 5.12 Irish Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.13 Key Irish WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.14 Major Irish WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.15 Danish Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.16 Key Danish WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.17 Major Danish WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.18 Drivers and Restraints in the Danish Waste-to-Energy Market
  • Table 5.19 Finnish Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.20 Key Finnish WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.21 Major Finnish WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.22 Drivers and Restraints in the Finnish Waste-to-Energy Market
  • Table 5.23 Italian Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.24 Key Italian WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.25 Major Italian WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.26 Drivers and Restraints in the Italian Waste-to-Energy Market
  • Table 5.27 Swedish Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.28 Key Swedish WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.29 Major Swedish WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.30 Drivers and Restraints in the Swedish Waste-to-Energy Market
  • Table 5.31 Czech Republic Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.32 Key Czech WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.33 Major Czech WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.34 Rest of Europe Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.35 Rest of Europe Waste-to-Energy Projects by Country
  • Table 5.36 German WtE Capacity Changes (Company, Project Title, TPA Capacity, MW Capacity, Work Expected)
  • Table 5.37 Chinese Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.38 Key Chinese WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.39 Major Chinese WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year)
  • Table 5.40 Drivers and Restraints in the Chinese Waste-to-Energy Market
  • Table 5.41 Japanese Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.42 Key Japanese WtE Statistics (Population, Annual MSW Production, Annual MSW Production per Capita, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.43 Major Japanese WtE Projects (Company, Project Title, TPA Capacity, $m Investment, Completion Year)
  • Table 5.44 Drivers and Restraints in the Japanese Waste-to-Energy Market
  • Table 5.45 Indian Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.46 Key Indian WtE Statistics (Population, Annual MSW Production, Annual MSW Production per Capita, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.47 Major Indian WtE Projects (Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.48 Drivers and Restraints in the Indian Waste-to-Energy Market
  • Table 5.49 Rest of Asia Pacific Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.50 Rest of Asia-Pacific WtE Projects by Country
  • Table 5.51 Key Australian WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, ning / Construction)
  • Table 5.52 Major Australian WtE Projects (Company, Project Title, TPA Capacity, MW Capacity, $m Investment, Completion Year, Status)
  • Table 5.53 US Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.54 Key US WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, Energy Output, New Plants Under Planning / Construction)
  • Table 5.55 Major US WtE Projects (Company, Project Title, TPA Capacity, $m Investment, Completion Year)
  • Table 5.56 Drivers and Restraints in the US Waste-to-Energy Market
  • Table 5.57 Canadian Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.58 Key Canadian WtE Statistics (Population, Annual MSW Production, Incineration Rate, Landfill Rate, Recycling/Compost Rate, WtE Facilities, WtE Capacity, New Plants Under Planning / Construction)
  • Table 5.59 Major Canadian Waste-to-Energy Projects (Company, Project Title, TPA Capacity, $m Investment, Completion Year)
  • Table 5.60 Drivers and Restraints in the Canadian Waste-to-Energy Market
  • Table 5.61 Latin America Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.62 Major WtE Projects in Latin America (Company, Project Title, Country, TPA Capacity, Completion Year, Status)
  • Table 5.63 The Middle East & Africa Waste-to-Energy Market Forecast 2020-2030 ($ mn, Mtpa, AGR %, CAGR %, Cumulative)
  • Table 5.64 Major WtE Projects in the Middle East & Africa (Company, Project Title, Country, TPA Capacity, Completion Year, Status)
  • Table 6.1 PEST Analysis, Waste-to-Energy Market
  • Table 7.1 Covanta Energy Corporation Profile 2019 (Market Entry, Public/Private, Headquarters, No. of Employees, Total Company Revenue $bn, Change in Revenue, Geography, Key Market, Listed on, Products/Services)
  • Table 7.2 Covanta Energy Corporation Total Company Revenue 2014-2018 ($bn, AGR %)
  • Table 7.3 Covanta Energy Waste to Energy Facilities
  • Table 7.4 China Everbright International Limited Profile 2019 (Market Entry, Public/Private, Headquarters, No. of Employees, Total Company Revenue $bn, Change in Revenue, Geography, Key Market, Listed on, Products/Services)
  • Table 7.5 China Everbright's Product Portfolio
  • Table 7.6 China Everbright International Limited Total Company Revenue 2014-2018 ($bn, AGR %)
  • Table 7.7 China Everbright Waste-to-Energy Projects (Project Name, TPA Capacity, Location, Status, Investment)
  • Table 7.8 China Everbright Waste-to-Energy Projects (Project Name, TPA Capacity, Location, Status, Investment)
  • Table 7.9 Sembcorp Industries 2017 (Market Entry, Public/Private, Headquarters, No. of Employees, Total Company Revenue $bn, Change in Revenue, Geography, Key Market, Listed on, Products/Services)
  • Table 7.10 Suez Environment (SITA) 2019 (Market Entry, Public/Private, Headquarters, No. of Employees, Total Company Revenue $bn, Change in Revenue, Geography, Key Market, Listed on, Products/Services)
  • Table 7.11 Suez Environment Total Company Revenue 2014-2018 ($bn, AGR %)
  • Table 7.12 Suez Environment (SITA) Suez Environnement Waste-to-Energy Projects (Project, Country, TPA Capacity, Completion Year)
  • Table 7.13 Keppel Seghers Belgium N.V. Profile 2019 (Market Entry, Public/Private, Headquarters, Total Company Revenue $bn, Geography, Key Market, Products/Services)
  • Table 7.14 Keppel Seghers Belgium N.V. Waste-to-Energy Projects (Project Name, Country, TPA Capacity, Completion Year)
  • Table 7.15 Keppel Seghers Belgium N.V. Company Divisions & Capabilities
  • Table 7.16 Veolia Environmental Services Profile 2019 (Market Entry, Public/Private, Headquarters, Total Company Revenue $ bn, Change in Revenue, Geography, Key Markets, Listed on, Products/Services)
  • Table 7.17 Veolia Environmental Services Total Company Revenue 2014-2018 ($bn, AGR %)
  • Table 7.18 Wheelabrator Profile 2019 (Inception, Public/Private, Headquarters, Geography, Key Markets)
  • Table 7.19 Wheelabrator WtE Operations: Name, MSW Capacity (tpa)
  • Table 7.20 Clean Association of Tokyo 23 Profile 2019 (Inception, Public/Private, Headquarters, No. of Employees, Geography, Key Markets)
  • Table 7.21 MVV Energie AG Profile 2019 (Inception, Public/Private, Headquarters, No. of Employees, Revenue ($bn), Geography, Key Markets)
  • Table 7.22 China Metallurgical Group (MCC) Profile 2019 (Inception, Public/Private, Headquarters, No. of Employees, Geography, Key Markets)
  • Table 7.23 Hunan Junxin Environmental Protection Profile 2019 (Inception, Public/Private, Headquarters, Geography, Key Markets)
  • Table 7.24 GCL-Poly Profile 2019 (Inception, Public/Private, Headquarters, Total Company Sales $ bn, No. of Employees, Geography, Key Markets)
  • Table 7.25 EDF Profile 2019 (Inception, Public/Private, Headquarters, No. of Employees, Total Company Sales $ bn, Geography, Key Markets)
  • Table 7.26 AMEC Forest Wheeler's Product Portfolio
  • Table 7.27 ANDRITZ' Product Portfolio
  • Table 7.28 Arrow Ecology's Product Portfolio
  • Table 7.29 Babcock & Wilson Vφlund's Product Portfolio
  • Table 7.30 Biogas Nord's Product Portfolio
  • Table 7.31 Biogen's Product Portfolio
  • Table 7.32 BTA'S Product Portfolio
  • Table 8.1 U.S. Waste-to-Energy Patent Analysis, 2012-2019
  • Table 8.2 Europe Waste-to-Energy Patents Analysis, 2012-2019
  • Table 8.3 Japan Waste-to-Energy Patents Analysis, 2012-2019

List of Figures

  • Figure 1.1 Waste-To-Energy Cycle
  • Figure 2.1 Basic Waste-To-Energy Pathways
  • Figure 2.2 Global Waste to Energy (WtE) Market Segmentation Overview
  • Figure 3.1 Global Waste to Energy Market Forecast 2020-2030 (MTPA, AGR%)
  • Figure 3.2 Global Waste to Energy Market Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 3.3 Regional Waste to Energy Market Forecast 2020-2030 ($Mn)
  • Figure 3.4 Regional Waste to Energy Market Forecast 2020-2030(MTPA)
  • Figure 3.5 Global Waste to Energy Market by Regional % Share Forecast 2020, 2025, 2030 (Revenue)
  • Figure 4.1 Global Waste to Energy Submarket by Type Forecast 2020-2030 ($mn)
  • Figure 4.2 Global Waste to Energy Market by Type (CAPEX) Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 4.3 Waste to Energy Market, By Thermal Forecast 2020-2030 ($mn, AGR%)
  • Figure 4.4 Waste to Energy Market, By Thermal Forecast 2020-2030 (MTPA, AGR%)
  • Figure 4.5 Thermal Waste to Energy Market, By Type Forecast 2020-2030 ($ mn, AGR%)
  • Figure 4.6 Thermal Waste to Energy Market, By Type Forecast 2020-2030 (MTPA, AGR%)
  • Figure 4.7 Thermal Waste to Energy Market, % CAPEX Share by Type (2020)
  • Figure 4.8 Waste to Energy Market, By Biological Forecast 2020-2030 ($mn, AGR%)
  • Figure 4.9 Waste to Energy Market, By Biological Forecast 2020-2030 (MTPA, AGR%)
  • Figure 4.10 Global Waste to Energy Market, Comparison Matrix, by Type VS Region (Comparison Matric)
  • Figure 4.11 Global Waste to Energy Submarket Forecast 2020-2030, by Application ($mn)
  • Figure 4.12 Global Waste to Energy Market by Application (CAPEX) Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 4.13 Waste to Energy Market, By Electricity Generation Forecast 2020-2030 ($mn, AGR%)
  • Figure 4.14 Waste to Energy Market, By Electricity Generation Forecast 2020-2030 (MTPA, AGR%)
  • Figure 4.15 Waste to Energy Market, By Steam Exports Forecast 2020-2030 ($mn, AGR%)
  • Figure 4.16 Waste to Energy Market, By Steam Exports Forecast 2020-2030 (MTPA, AGR%)
  • Figure 4.17 Waste to Energy Market, By CHP Forecast 2020-2030 ($mn, AGR%)
  • Figure 4.18 Waste to Energy Market, By CHP Forecast 2020-2030 (MTPA, AGR%)
  • Figure 4.19 Global Waste to Energy Market, Comparison Matrix, by Application VS Region (Comparison Matrix)
  • Figure 5.1 Global Waste to Energy Market Forecast by Leading Nations, 2020-2030, CAPEX ($Mn)
  • Figure 5.2 Global Waste to Energy Market Forecast by Leading Nations, 2020-2030, Capacity (MTPA)
  • Figure 5.3 Leading Country/Regional Waste to Energy Market Share Forecast 2020 (% Share)
  • Figure 5.4 Leading Country/Regional Waste to Energy Market Share Forecast 2025 (% Share)
  • Figure 5.5 Leading Country/Regional Waste to Energy Market Share Forecast 2030 (% Share)
  • Figure 5.6 U.K. Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.7 U.K. Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.8 U.K. Municipal Waste To Landfill 2010-2017 (Thousand Tonnes)
  • Figure 5.9 U.K. Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.10 UK Waste to Energy Market, by Type, 2020
  • Figure 5.11 U.K. Waste Hierarchy
  • Figure 5.12 Polish Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.13 Polish Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.14 Polish Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.15 Polish Waste to Energy Market, by Type, 2019
  • Figure 5.16 Irish Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.17 Irish Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.18 Irish Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.19 Irish Waste to Energy Market, by Type, 2019
  • Figure 5.20 Danish Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.21 Danish Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.22 Danish Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.23 Danish Waste to Energy Market, by Type, 2019
  • Figure 5.24 Finnish Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.25 Finnish Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.26 Finnish Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.27 Finnish Waste to Energy Market, by Type, 2019
  • Figure 5.28 Italian Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.29 Italian Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.30 Italian Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.31 Italy Waste to Energy Market, by Type, 2019
  • Figure 5.32 Swedish Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.33 Swedish Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.34 Swedish Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.35 Sweden Waste to Energy Market, by Type, 2019
  • Figure 5.36 Czech Republic Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.37 Czech Republic Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.38 Czech Republic Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.39 Czech Republic Waste to Energy Market, by Type, 2019
  • Figure 5.40 Rest of Europe Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.41 Rest of Europe Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.42 Rest of Europe Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.43 Chinese Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.44 Chinese Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.45 Chinese Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.46 Chinese Waste to Energy Market, by Type, 2019
  • Figure 5.47 Japanese Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.48 Japanese Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.49 Japanese Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.50 Japan Waste to Energy Market, by Type, 2019
  • Figure 5.51 Indian Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.52 Indian Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.53 Indian Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.54 Indian Waste to Energy Market, by Type, 2019
  • Figure 5.55 Rest of Asia Pacific Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.56 Rest of Asia Pacific Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.57 Rest of Asia Pacific Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.58 Rest of Asia Pacific Waste to Energy Market, by Type, 2019
  • Figure 5.59 US Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.60 US Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.61 US Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.62 U.S. Waste to Energy Market, by Type, 2019
  • Figure 5.63 Canadian Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR%)
  • Figure 5.64 Canadian Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.65 Canadian Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.66 Canada Waste to Energy Market, by Type, 2019
  • Figure 5.67 Latin America Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.68 Latin America Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.69 Latin America Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.70 Latin America Waste to Energy Market, by Type, 2019
  • Figure 5.71 The Middle East & Africa Waste-to-Energy Market, by CAPEX Forecast 2020-2030 ($ Mn, AGR %)
  • Figure 5.72 The Middle East & Africa Waste-to-Energy Market, by Capacity Forecast 2020-2030 (Mtpa)
  • Figure 5.73 The Middle East & Africa Waste-to-Energy Market Share Forecast 2020, 2025, 2030 (% Share)
  • Figure 5.74 The Middle East & Africa Waste to Energy Market, by Type, 2019
  • Figure 7.1 Covanta Energy Corporation Revenue % Share, by Operating Segment, 2018
  • Figure 7.2 Covanta Energy Corporation Revenue % Share, by Waste & Services Revenue Breakup, 2018
  • Figure 7.3 Covanta Energy Corporation Total Company Revenue, ($bn & AGR %), 2014-2018
  • Figure 7.4 China Everbright International Limited Revenue % Share, by Business Segment, 2018
  • Figure 7.5 China Everbright International Limited Total Company Revenue ($bn & AGR %) 2014-2018
  • Figure 7.6 Sembcorp Industries Revenue % Share, by Business Segment, 2018
  • Figure 7.7 Sembcorp Industries Revenue % Share, by Geography Segment, 2018
  • Figure 7.8 Sembcorp Industries Revenue % Share, Capacity (MW), by Power Plant Type, 2018
  • Figure 7.9 Suez Environment (SITA) Revenue % Share, by Geographical Segment, 2018
  • Figure 7.10 Suez Environment (SITA) Total Company Revenue ($bn & AGR %), 2014-2018
  • Figure 7.11 Veolia Environmental Services Total Company Revenue ($bn & AGR %), 2014-2018
  • Figure 7.12 Veolia Environmental Services Revenue % Share, by Geographical Segment, 2018
  • Figure 7.13 MVV Energie AG, Electricity Generation Source 2018
  • Figure 7.14 MVV Energie AG, Installed Capacity (MW), by Source 2018
  • Figure 7.15 MVV Energie AG, Sales, by Regional Segment, 2018
  • Figure 7.16 MVV Energie AG, Sales, by Business Segment, 2018
  • Figure 7.17 GCL-Poly, by Sales, 2018 (% Share)
  • Figure 9.1 Global Waste-to-Energy Market Forecast 2020-2030 ($ mn, AGR %)
  • Figure 9.2 Global Waste-to-Energy Market Forecast 2020-2030 (MTPA, AGR %)

List of Companies Mentioned

  • A2A
  • Acea Group
  • ACWA Power
  • Aem Cremona
  • Air Products
  • AISA IMPIANTI
  • AmeyCespa
  • An Hui Wenergy
  • ATCO Power
  • Aurium Capital
  • Azienda Autonoma Municipale Pubblici Servizi
  • B&W Vφlund A/S
  • Bee'ah
  • Beijing Municipal Government
  • Biffa
  • Bioenergy Infrastructure Group (BIG)
  • Bioessence
  • Bodens Energi
  • Bollnäs Energi AB
  • Boras Energi Miljo
  • Borlänge Energi
  • Borui Green Energy
  • Bouygues Energies & Services
  • Brianza Energia Ambiente
  • Broadcrown
  • Cadence Enviropower
  • CAGT Engineering
  • CECEP
  • Cemex
  • Changshu Pufa Thermoelectricity
  • Chant Group
  • Chengdu Xingrong Renewable Energy
  • China Boqi
  • China Everbright
  • China Power New Energy
  • Chinook Urban Mining
  • CISC
  • Cixi Zhongke Zhongmao
  • Clean Association of Tokyo 23
  • CoGen
  • Consorzio Recuperi Energetici
  • Cory Environmental
  • Covanta
  • Coventry & Solihull Waste Dsiposal Company
  • Dalian TEDA Environmental Protection
  • Datong Fuqiao Waste Incineration Electricity
  • Devon Waste Management
  • Doosan
  • Drenl
  • Dundee Energy Recycling
  • Ebara
  • Eco Center
  • EDF
  • Ekokem
  • Ekokem Group (Sakab)
  • Eksjö Energi
  • Enviroparks Operations
  • EON
  • Equitix
  • Ethiopian Electric Power Corporation
  • Euro Energy Group
  • Falascaia
  • FCC Environment
  • Ferrero
  • Fiberight
  • Finspang
  • Fortum Carlisle Ltd
  • Fortum Keilaniemi
  • GCL-Poly
  • Gent Fairhead
  • Grandblue Environment
  • Grontmij
  • Grundon
  • Hangzhou Jinjiang Group
  • Helios Energy Investments
  • Hem
  • Herambiente
  • Hfab
  • Hitachi Zosen Inova
  • Hunan Junxin Environmental Protection
  • Indaver
  • International Electric Power
  • Iren
  • Jersey Transport and Technical Services
  • Jingjiang
  • Jönköping Energi
  • K3CHP
  • Kara/NOVEREN
  • Karlskoga Energi
  • Karlstad Energi
  • KIC Odpapdy
  • Kils Energi
  • Kingmoor Park Properties Ltd
  • Kotka Energia
  • Lahti Energy
  • Landskrona Energi AB
  • LECH
  • Lidköping
  • Ljungby Energi
  • Lomellina e Energia
  • Marcegaglia Energy
  • Martin GmbH
  • MCC
  • MES Environmental
  • MHIEC
  • Minamikawachi Environmental Partnership Secretariat
  • Mizuda Group
  • Mostostal Warszawa
  • Multifuel Energy
  • MVV Environment
  • Network Rail
  • New Earth Energy
  • Ningbo Beilun II
  • NLWA
  • North Beck Energy Ltd
  • Nybro Energi
  • Öresundskraft AB
  • Origin Renewable Energy
  • Osaka City Hall
  • Oulun Energia
  • Peel Environmental
  • PGNiG Termika
  • PHG Energy
  • Posco E&C
  • Prazské sluzby
  • Premier Aggregates
  • ProNatura
  • Quadrifoglio
  • Rabbit Group
  • Ramboll
  • Rank Progress
  • REA Dalmine
  • Reform Energy
  • Renova
  • Resource Recovery Solutions
  • Sako
  • Savini
  • Scarborough Power
  • Scarlino Energia
  • Se. Ver. A. SPA
  • Shenzhen Energy
  • Shore Energy
  • Shougang Corporation
  • SITA Sembcorp
  • Skövde Värmeverk AB
  • Socotec
  • Söder Energi
  • Sound Environmental Resources
  • State Communal Enterprise Koktem
  • Steinmuller Babcock Environment
  • Suez Environmental
  • Sundsvall Energi
  • Sysav
  • Tai'an Zhongke Environment
  • Tammervoima Oy
  • Taqa
  • Tata
  • Tekniska Verken
  • Termizo
  • TIRU
  • Turku Energia
  • Uddevalla Energi
  • Umea Energi
  • VafabMiljö
  • Vantaan Energia
  • Västervik
  • Vattenfall
  • Veolia
  • Viridor
  • Waste Gas Technology UK
  • Weiming
  • Wheelabrator
  • Zakland Utylizacyjny
  • Zevo
  • ZhongDe
  • Organistaions Mentioned
  • Abiko City Hall
  • Akita City
  • An Bord Pleanala (Irish Planning Board)
  • Atlantic County Utilities Authority (ACUA)
  • Atsugi City
  • Carlisle City Council
  • Chiba City
  • City of Hitachinaka
  • City of Kobe
  • City of Yokohama
  • Dan Municipal Sanitation Association/Nesher
  • Dubai Municipality
  • Environment Agency
  • Funabashi City
  • Gyoda City
  • Hadano Isehara Environmental Sanitation Union
  • Hanamaki City
  • Higashi Osaka City Cleaning Facility Union
  • Hirakata City
  • Hisashi Kennan Environment Union
  • Hofu City Hall
  • Imabari City Hall
  • Inagawa Upstream Garbage Treatment Facilities Union
  • Kasugai City
  • Kawasaki City Hall
  • Kitakata Union
  • Kodaira Murayama Yamato Sanitation Union
  • Middlesbrough Council
  • NHS Trust
  • North London Waste Authority
  • Sennan Cleaning Office Union
  • Shida Office Union
  • Southern Yue Cleaning Union
  • Stockholm Town
  • Teeside University
  • Warsaw City
  • West Akikawa Sanitation Union