Global Waste-To-Energy (WTE) Market 2019-2027

MARKET OUTLOOK
After analyzing the global waste-to-energy market in detail, the publisher has arrived upon the conclusion that the industry is set to display an upward trend, with 6.09% of CAGR in terms of revenue for the forecast years of 2019 to 2027.

The trend of producing reusable energy from waste has gained traction throughout the world. The world is facing a serious problem of increased waste generation. Overfilled landfills have led the world to shift its focus towards using waste for generating power. Waste-to-energy or WtE is an efficient solution provided for handling municipal waste. The commercialization of several WTE technologies has garnered growing interest towards the development of WtE projects, with increased investments.

The rising demand for energy & the need for energy security, considerable investments in new waste-to-energy projects, rapid rates of industrialization & urbanization, and the decrease in the number of landfills are the factors responsible for driving the waste-to-energy market. Moreover, the depletion of conventional energy resources and the emergence of new technologies, are excellent opportunities for the market to reach its projected growth.

However, the high costs involved in setting up WtE plants, strict environmental guidelines, availability of alternative technologies, are factors restraining the market growth. In addition, technological challenges and opposition from environmental groups & local communities are further creating hurdles for the growth of the waste-to-energy market.

REGIONAL OUTLOOK
The market for waste-to-energy spans across various regions, such as North America, the Asia-Pacific, Europe, Latin America, and the Middle East and Africa. The APAC market for waste-to-energy is growing the fastest at the global scale. The growing demand for energy and the aim of reducing dependence on fossil fuels have resulted in the growth of the waste-to-energy market in the countries of India and China. The rapid rates of industrialization & urbanization in these countries pose grave challenges for waste management for their governments.

The growing population has also been putting pressure on land space, prompting municipalities and governments across these countries to reduce landfill waste. Waste generation in the Asia-Pacific is expected to increase, owing to the growth in the GDP, and would force the governments to consider the implementation of waste-to-energy technologies and waste management sectors. Emerging economies in the Asia-Pacific serve as driving factors for the energy market, globally, and thus, manufacturers in the region have started to invest heavily in research & development of low-cost WtE technologies.

COMPETITIVE OUTLOOK
The notable players in the waste-to-energy market are Plasco Conversion Systems (acquired by RMB Advisory Services), Ze-gen, Inc., Amec Foster Wheeler Plc (acquired by Wood Group), Suez Environnement Company, BTA International GmbH, Babcock & Wilcox Enterprises, Inc., Keppel Seghers, Austrian Energy & Environment Group, Wheelabrator Technologies, Inc., and Covanta Holding Corporation.

Veolia Environment S.A. designs and implements solutions for water, waste, and energy. The company operates, maintains, and optimizes treatment plants. Veolia operates through three business segments: water, waste solutions, and energy services. The company strongly focuses on creating partnerships with its customers, suppliers, and other stakeholders to gather the full potential in the waste-to-energy market. It conducts extensive research into innovative technologies & solutions that can be used to convert energy from waste. Veolia has operations across Europe, Asia, Oceania, the Americas, the Middle East, and the Rest of World.

1. Global Waste-To-Energy (Wte) Market – Summary

2. Industry Outlook
2.1. Market Definition
2.2. Key Insights
2.2.1. Asia-Pacific Transforming Into A Promising Hub For Wte
2.2.2. Data Analytics & Big Data Optimizing Waste Management Value Chain
2.2.3. Incineration – Key Thermal Waste-To-Energy Technology
2.2.4. Growing Prominence Of Biological Wte Technology
2.3. Porter’S Five Forces Analysis
2.3.1. Bargaining Power Of Buyers
2.3.2. Bargaining Power Of Suppliers
2.3.3. Threat Of Substitute
2.3.4. Threat Of New Entrants
2.3.5. Threat Of Competitive Rivalry
2.4. Key Impact Analysis
2.4.1. Cost
2.4.2. Environment-Friendly
2.4.3. Substitutes
2.4.4. Availability
2.5. Market Attractiveness Index
2.6. Vendor Scorecard
2.7. Industry Components
2.7.1. Waste Generation
2.7.2. Waste Collection
2.7.3. Suppliers
2.7.4. Manufacturers
2.7.5. Distributors & Retailers
2.7.6. End-Users
2.8. Market Drivers
2.8.1. Rising Energy Demand & Need For Energy Security
2.8.2. Substantial Investments In New Wte Projects
2.8.3. Rapid Industrialization & Urbanization Contributing To The Increasing Municipal Waste
2.8.4. Declining Number Of Landfill Sites
2.9. Market Restraints
2.9.1. High Setup Cost – Major Drawback
2.9.2. Availability Of Alternative Technologies
2.9.3. Strict Environmental Guidelines
2.10. Market Opportunities
2.10.1. Depleting Conventional Energy Resources
2.10.2. Emerging Technologies
2.11. Market Challenges
2.11.1. Technological Challenges
2.11.2. Opposition From Environmental Groups & Local Communities

3. Global Waste-To-Energy (Wte) Market Outlook – By Technology
3.1. Thermal
3.2. Biological
3.3. Physical

4. Global Waste-To-Energy (Wte) Market Outlook – By Type Of Waste
4.1. Municipal Waste
4.1.1. Residential
4.1.2. Commercial & Institutional
4.1.3. Construction & Demolition
4.1.4. Other Municipal Wastes
4.2. Process Waste
4.3. Medical Waste
4.4. Agriculture Waste
4.5. Other Wastes

5. Global Waste-To-Energy (Wte) Market Outlook – By Application
5.1. Electricity
5.2. Heat
5.3. Combined Heat & Power Units
5.4. Transport Fuels
5.5. Other Applications

6. Global Waste-To-Energy (Wte) Market – Regional Outlook
6.1. North America
6.1.1. Market By Technology
6.1.2. Market By Type Of Waste
6.1.3. Market By Municipal Solid Waste (Msw)
6.1.4. Market By Application
6.1.5. Country Analysis
6.1.5.1. United States
6.1.5.2. Canada
6.2. Europe
6.2.1. Market By Technology
6.2.2. Market By Type Of Waste
6.2.3. Market By Municipal Solid Waste (Msw)
6.2.4. Market By Application
6.2.5. Country Analysis
6.2.5.1. United Kingdom
6.2.5.2. Germany
6.2.5.3. France
6.2.5.4. Spain
6.2.5.5. Italy
6.2.5.6. Russia
6.2.5.7. Rest Of Europe
6.3. Asia-Pacific
6.3.1. Market By Technology
6.3.2. Market By Type Of Waste
6.3.3. Market By Municipal Solid Waste (Msw)
6.3.4. Market By Application
6.3.5. Country Analysis
6.3.5.1. China
6.3.5.2. Japan
6.3.5.3. India
6.3.5.4. South Korea
6.3.5.5. Asean Countries
6.3.5.6. Australia & New Zealand
6.3.5.7. Rest Of Asia-Pacific
6.4. Latin America
6.4.1. Market By Technology
6.4.2. Market By Type Of Waste
6.4.3. Market By Municipal Solid Waste (Msw)
6.4.4. Market By Application
6.4.5. Country Analysis
6.4.5.1. Brazil
6.4.5.2. Mexico
6.4.5.3. Rest Of Latin America
6.5. Middle East And Africa
6.5.1. Market By Technology
6.5.2. Market By Type Of Waste
6.5.3. Market By Municipal Solid Waste (Msw)
6.5.4. Market By Application
6.5.5. Country Analysis
6.5.5.1. United Arab Emirates
6.5.5.2. Turkey
6.5.5.3. Saudi Arabia
6.5.5.4. South Africa
6.5.5.5. Rest Of Middle East & Africa

7. Competitive Landscape
7.1. Amec Foster Wheeler Plc (Acquired By Wood Group)
7.2. Babcock & Wilcox Enterprises, Inc.
7.3. C&G Environmental Protection Holdings Ltd.
7.4. China Everbright International Ltd.
7.5. Covanta Holding Corporation
7.6. Green Conversion Systems, Inc.
7.7. Hitachi Zosen Corporation
7.8. Keppel Seghers
7.9. Mitsubishi Heavy Industries, Ltd.
7.10. Plasco Conversion Systems (Acquired By Rmb Advisory Services)
7.11. Suez Environnement Company
7.12. Veolia Environnement S.A.
7.13. Waste Management, Inc.
7.14. Wheelabrator Technologies, Inc.
7.15. Xcel Energy, Inc.
7.16. Bta International Gmbh
7.17. Martin Gmbh
7.18. Ze-Gen, Inc.
7.19. Sako Brno A.S.
7.20. Austrian Energy & Environment Group

8. Research Methodology & Scope
8.1. Research Scope & Deliverables
8.2. Sources Of Data
8.3. Research Methodology

Table List
Table 1: Global Waste-To-Energy (Wte) Market, By Geography, 2019-2027 (In $ Million)
Table 2: Vendor Scorecard
Table 3: Anticipated Wte Projects Across The World
Table 4: Projected Waste Generation Data For 2025, By Region
Table 5: Competing Renewable Technologies
Table 6: Carbon Efficiency Of Several Biofuel Production Processes
Table 7: Global Waste-To-Energy (Wte) Market, By Technology, 2019-2027 (In $ Million)
Table 8: Global Waste-To-Energy (Wte) Market, By Type Of Waste, 2019-2027 (In $ Million)
Table 9: Global Waste-To-Energy (Wte) Market, By Municipal Solid Waste (Msw), 2019-2027 (In $ Million)
Table 10: Global Waste-To-Energy (Wte) Market, By Application, 2019-2027 (In $ Million)
Table 11: Global Waste-To-Energy (Wte) Market, By Geography, 2019-2027 (In $ Million)
Table 12: North America Waste-To-Energy (Wte) Market, By Country, 2019-2027 (In $ Million)
Table 13: North America Waste-To-Energy (Wte) Market, By Technology, 2019-2027 (In $ Million)
Table 14: North America Waste-To-Energy (Wte) Market, By Type Of Waste, 2019-2027 (In $ Million)
Table 15: North America Waste-To-Energy (Wte) Market, By Municipal Solid Waste (Msw), 2019-2027 (In $ Million)
Table 16: North America Waste-To-Energy (Wte) Market, By Application, 2019-2027 (In $ Million)
Table 17: Europe Waste-To-Energy (Wte) Market, By Country, 2019-2027 (In $ Million)
Table 18: Europe Waste-To-Energy (Wte) Market, By Technology, 2019-2027 (In $ Million)
Table 19: Europe Waste-To-Energy (Wte) Market, By Type Of Waste, 2019-2027 (In $ Million)
Table 20: Europe Waste-To-Energy (Wte) Market, By Municipal Solid Waste (Msw), 2019-2027 (In $ Million)
Table 21: Europe Waste-To-Energy (Wte) Market, By Application, 2019-2027 (In $ Million)
Table 22: Asia-Pacific Waste-To-Energy (Wte) Market, By Country, 2019-2027 (In $ Million)
Table 23: Asia-Pacific Waste-To-Energy (Wte) Market, By Technology, 2019-2027 (In $ Million)
Table 24: Asia-Pacific Waste-To-Energy (Wte) Market, By Type Of Waste, 2019-2027 (In $ Million)
Table 25: Asia-Pacific Waste-To-Energy (Wte) Market, By Municipal Solid Waste (Msw), 2019-2027 (In $ Million)
Table 26: Asia-Pacific Waste-To-Energy (Wte) Market, By Application, 2019-2027 (In $ Million)
Table 27: Latin America Waste-To-Energy (Wte) Market, By Country, 2019-2027 (In $ Million)
Table 28: Latin America Waste-To-Energy (Wte) Market, By Technology, 2019-2027 (In $ Million)
Table 29: Latin America Waste-To-Energy (Wte) Market, By Type Of Waste, 2019-2027 (In $ Million)
Table 30: Latin America Waste-To-Energy (Wte) Market, By Municipal Solid Waste (Msw), 2019-2027 (In $ Million)
Table 31: Latin America Waste-To-Energy (Wte) Market, By Application, 2019-2027 (In $ Million)
Table 32: Middle East And Africa Waste-To-Energy (Wte) Market, By Country, 2019-2027 (In $ Million)
Table 33: Middle East And Africa Waste-To-Energy (Wte) Market, By Technology, 2019-2027 (In $ Million)
Table 34: Middle East And Africa Waste-To-Energy (Wte) Market, By Type Of Waste, 2019-2027 (In $ Million)
Table 35: Middle East And Africa Waste-To-Energy (Wte) Market, By Municipal Solid Waste (Msw), 2019-2027 (In $ Million)
Table 36: Middle East And Africa Waste-To-Energy (Wte) Market, By Application, 2019-2027 (In $ Million)

Figure List
Figure 1: Market Investment For Incineration In Asia-Pacific, Europe And North America
Figure 2: Key Buying Impact Analysis
Figure 3: Market Attractiveness Index
Figure 4: Industry Components
Figure 5: Worldwide Gdp Growth Rate And Trends By Economy (Actual And Projected), 2010-2025 (In %)
Figure 6: Worldwide Region-Wise Energy Consumption, 2015-2035 (Mtoe = Million Ton Of Oil Equivalent)
Figure 7: Worldwide Available Municipal Waste For Wte, 2009-2016 (Million Ton)
Figure 8: Worldwide Renewable Electricity Installed Capacity, By Source, 2012-2019 (Gw)
Figure 9: Global Waste-To-Energy (Wte) Market, By Thermal, 2019-2027 (In $ Million)
Figure 10: Global Waste-To-Energy (Wte) Market, By Biological, 2019-2027 (In $ Million)
Figure 11: Global Waste-To-Energy (Wte) Market, By Physical, 2019-2027 (In $ Million)
Figure 12: Global Waste-To-Energy (Wte) Market, By Municipal Waste, 2019-2027 (In $ Million)
Figure 13: Global Waste-To-Energy (Wte) Market, By Residential, 2019-2027 (In $ Million)
Figure 14: Global Waste-To-Energy (Wte) Market, By Commercial & Institutional, 2019-2027 (In $ Million)
Figure 15: Global Waste-To-Energy (Wte) Market, By Construction & Demolition, 2019-2027 (In $ Million)
Figure 16: Global Waste-To-Energy (Wte) Market, By Other Wastes, 2019-2027 (In $ Million)
Figure 17: Global Waste-To-Energy (Wte) Market, By Process Waste, 2019-2027 (In $ Million)
Figure 18: Global Waste-To-Energy (Wte) Market, By Medical Waste, 2019-2027 (In $ Million)
Figure 19: Global Waste-To-Energy (Wte) Market, By Agriculture Waste, 2019-2027 (In $ Million)
Figure 20: Global Waste-To-Energy (Wte) Market, By Other Wastes, 2019-2027 (In $ Million)
Figure 21: Global Waste-To-Energy (Wte) Market, By Electricity, 2019-2027 (In $ Million)
Figure 22: Global Waste-To-Energy (Wte) Market, By Heat, 2019-2027 (In $ Million)
Figure 23: Global Waste-To-Energy (Wte) Market, By Combined Heat & Power Units, 2019-2027 (In $ Million)
Figure 24: Global Waste-To-Energy (Wte) Market, By Transport Fuels, 2019-2027 (In $ Million)
Figure 25: Global Waste-To-Energy (Wte) Market, By Other Applications, 2019-2027 (In $ Million)
Figure 26: Global Waste-To-Energy (Wte) Market, Regional Outlook, 2018 & 2027 (In %)
Figure 27: United States Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 28: Canada Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 29: United Kingdom Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 30: Germany Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 31: France Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 32: Spain Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 33: Italy Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 34: Russia Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 35: Rest Of Europe Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 36: China Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 37: Japan Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 38: India Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 39: South Korea Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 40: Asean Countries Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 41: Australia & New Zealand Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 42: Rest Of Asia-Pacific Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 43: Brazil Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 44: Mexico Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 45: Rest Of Latin America Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 46: United Arab Emirates Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 47: Turkey Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 48: Saudi Arabia Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 49: South Africa Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)
Figure 50: Rest Of Middle East & Africa Waste-To-Energy (Wte) Market, 2019-2027 (In $ Million)