Table of Content
1. Research Scope & Methodology
1.1. Study Objectives
1.2. Scope Of Study
1.3. Methodology
1.4. Assumptions & Limitations
2. Executive Summary
2.1. Market Size & Estimates
2.2. Market Overview
3. Waste-To-Energy Outlook
3.1. Introduction
3.2. Sources Of Waste
3.3. Waste-To-Energy: The Concept
3.4. Benefits Of Waste-To-Energy
3.5. Challenges To Waste-To-Energy
3.6. Waste-To-Energy Technology Analysis
3.6.1. Thermal
3.6.1.1. Incineration
3.6.1.2. Gasification
3.6.1.3. Pyrolysis
3.6.1.4. Plasma Arc Wte Technology
3.6.2. Biological
3.6.2.1. Anaerobic Digestion
3.6.2.2. Biogas To Energy
3.6.3. Physical
3.7. Waste-To-Energy Strategy Analysis
3.8. Applications Of Waste-To-Energy
3.8.1. Electricity
3.8.2. Heat
3.8.3. Combined Heat And Power (Chp)
3.8.4. Transport Fuels
4. Market Dynamics
4.1. Market Definition
4.2. Key Drivers
4.2.1. Depletion Of Conventional Energy Resources Augmenting Demand Of Renewable Energy
4.2.2. Growing Energy Demand
4.2.3. Increasing Municipal Waste Generation
4.2.4. Decline In The Number Of Landfill Sites
4.3. Key Restraints
4.3.1. High Initial Setup Cost
4.3.2. Resistance From Local Communities & Environment Groups
4.3.3. Stringent Environmental Guidelines
4.3.4. Lack Of Infrastructure & Skilled Workforce
4.3.5. Threat From Established Commercial Technologies Such As Solar Power, Hydropower, And Wind Power
4.3.6. Technological And Economical Obstacles
5. Key Analytics
5.1. Impact Of Covid-19 On Waste To Energy
5.2. Key Investment Insights
5.3. Porter’S Five Forces Analysis
5.3.1. Buyer Power
5.3.2. Supplier Power
5.3.3. Substitution
5.3.4. New Entrants
5.3.5. Industry Rivalry
5.4. Opportunity Matrix
5.5. Vendor Landscape
5.6. Value Chain Analysis
5.6.1. Waste Producers
5.6.2. Waste Collection
5.6.3. Suppliers
5.6.4. Manufacturers
5.6.5. Distributors
5.6.6. Retailers
5.6.7. End-Users
5.7. Key Buying Criteria
5.7.1. Price
5.7.2. Product Availability
5.7.3. Environmental Concerns
5.7.4. Alternatives
5.8. Regulatory Framework Regarding Waste Management
5.8.1. Europe
5.8.1.1. Current Practices
5.8.1.2. Waste Legislation And Policies
5.8.1.3. Role Of Biogas Feed-In Tariffs And Related Policies In Europe
5.8.1.4. Waste Management Practices In Europe
5.9. Automation In Waste To Energy
6. Market By Technology
6.1. Thermal
6.2. Biological
6.3. Physical
7. Market By Application
7.1. Electricity
7.2. Heat
7.3. Combined Heat & Power Units
7.4. Transport Fuels
7.5. Other Applications
8. Market By Waste Type
8.1. Municipal Waste
8.1.1. Residential
8.1.2. Commercial & Institutional
8.1.3. Construction & Demolition
8.1.4. Other Municipal Wastes
8.2. Process Waste
8.3. Medical Waste
8.4. Agriculture Waste
8.5. Other Wastes
9. Geographical Analysis
9.1. Europe
9.1.1. United Kingdom
9.1.2. Germany
9.1.3. France
9.1.4. Italy
9.1.5. Russia
9.1.6. Belgium
9.1.7. Poland
9.1.8. Rest Of Europe
10. Company Profiles
10.1. Amec Foster Wheeler Plc (Acquired By Wood Group)
10.2. Babcock & Wilcox Enterprises Inc
10.3. C&G Environmental Protection Holding Ltd
10.4. China Everbright International Ltd
10.5. Covanta Holding Corporation
10.6. Green Conversion Systems Inc
10.7. Hitachi Zosen Corporation
10.8. Keppel Seghers
10.9. Mitsubishi Heavy Industries Ltd
10.10. Plasco Conversion Systems (Acquired By Rmb Advisory Services)
10.11. Suez Environment Company
10.12. Veolia Environnement S.A.
10.13. Waste Management Inc
10.14. Wheelabrator Technologies Inc. (Acquired By Macquarie Infrastructure Partners)
10.15. Xcel Energy Inc
10.16. Bta International Gmbh
10.17. Martin Gmbh
10.18. Mvv Energie Ag
List of Figures
Figure 1: Composition Of Municipal Solid Waste (Msw)
Figure 2: Basic Pathways Of Waste-To-Energy
Figure 3: Thermal Waste-To-Energy Technology Types
Figure 4: Worldwide Renewable Electricity Installed Capacity, By Source, 2012–2019 (Gw)
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 Tons Of Oil Equivalent)
Figure 7: Worldwide Available Municipal Waste For Wte, 2009–2016 (Million Tons)
Figure 8: Competing Renewable Technologies
Figure 9: Key Investment Insights
Figure 10: Market Investment For Incineration In Asia Pacific, Europe, And North America
Figure 11: Porter’S Five Forces Analysis
Figure 12: Opportunity Matrix
Figure 13: Vendor Landscape
Figure 14: Value Chain Analysis
Figure 15: Key Buying Criteria
Figure 16: Europe Waste-To-Energy (Wte) Market, Growth Potential, By Technology, In 2019
Figure 17: Europe Waste-To-Energy (Wte) Market, By Thermal, 2019-2028 (In $ Million)
Figure 18: Europe Waste-To-Energy (Wte) Market, By Biological, 2019-2028 (In $ Million)
Figure 19: Europe Waste-To-Energy (Wte) Market, By Physical, 2019-2028 (In $ Million)
Figure 20: Europe Waste-To-Energy (Wte) Market, Growth Potential, By Application, In 2019
Figure 21: Europe Waste-To-Energy (Wte) Market, By Electricity, 2019-2028 (In $ Million)
Figure 22: Europe Waste-To-Energy (Wte) Market, By Heat, 2019-2028 (In $ Million)
Figure 23: Europe Waste-To-Energy (Wte) Market, By Combined Heat & Power Units, 2019-2028 (In $ Million)
Figure 24: Europe Waste-To-Energy (Wte) Market, By Transport Fuels, 2019-2028 (In $ Million)
Figure 25: Europe Waste-To-Energy (Wte) Market, By Other Applications, 2019-2028 (In $ Million)
Figure 26: Europe Waste-To-Energy (Wte) Market, Growth Potential, By Waste Type, In 2019
Figure 27: Europe Waste-To-Energy (Wte) Market, By Municipal Waste, 2019-2028 (In $ Million)
Figure 28: Europe Waste-To-Energy (Wte) Market, Growth Potential, By Msw Type, In 2019
Figure 29: Europe Waste-To-Energy (Wte) Market, By Residential, 2019-2028 (In $ Million)
Figure 30: Europe Waste-To-Energy (Wte) Market, By Commercial & Institutional, 2019-2028 (In $ Million)
Figure 31: Europe Waste-To-Energy (Wte) Market, By Construction & Demolition, 2019-2028 (In $ Million)
Figure 32: Europe Waste-To-Energy (Wte) Market, By Other Municipal Wastes, 2019-2028 (In $ Million)
Figure 33: Europe Waste-To-Energy (Wte) Market, By Process Waste, 2019-2028 (In $ Million)
Figure 34: Europe Waste-To-Energy (Wte) Market, By Medical Waste, 2019-2028 (In $ Million)
Figure 35: Europe Waste-To-Energy (Wte) Market, By Agriculture Waste, 2019-2028 (In $ Million)
Figure 36: Europe Waste-To-Energy (Wte) Market, By Other Wastes, 2019-2028 (In $ Million)
Figure 37: Europe Waste-To-Energy (Wte) Market, Regional Outlook, 2019 & 2028 (In %)
Figure 38: United Kingdom Waste-To-Energy (Wte) Market, 2019-2028 (In $ Million)
Figure 39: Number Of Waste-To-Energy Facilities In United Kingdom, 2014-2016
Figure 40: Germany Waste-To-Energy (Wte) Market, 2019-2028 (In $ Million)
Figure 41: France Waste-To-Energy (Wte) Market, 2019-2028 (In $ Million)
Figure 42: Italy Waste-To-Energy (Wte) Market, 2019-2028 (In $ Million)
Figure 43: Russia Waste-To-Energy (Wte) Market, 2019-2028 (In $ Million)
Figure 44: Belgium Waste-To-Energy (Wte) Market, 2019-2028 (In $ Million)
Figure 45: Poland Waste-To-Energy (Wte) Market, 2019-2028 (In $ Million)
Figure 46: Rest Of Europe Waste-To-Energy (Wte) Market, 2019-2028 (In $ Million)
List of Tables
TABLE 1: MARKET SNAPSHOT - WASTE-TO-ENERGY (WTE)
TABLE 2: TYPES OR SOURCES OF WASTE
TABLE 3: KEY BENEFITS OF WASTE-TO-ENERGY PROCESSES
TABLE 4: KEY CHALLENGES TO WTE MARKETS
TABLE 5: KEY THERMAL WTE SUPPLIERS BY TYPE OF INCINERATION
TABLE 6: KEY ALTERNATIVE THERMAL WTE TECHNOLOGY PROVIDERS WITH NUMBER OF PLANTS, THROUGHPUT AND TECHNOLOGY CONFIGURATION
TABLE 7: COMPARISON BETWEEN COMBUSTION, GASIFICATION, AND PYROLYSIS
TABLE 8: COMPARISON OF CONVENTIONAL TECHNOLOGIES WITH ALTERNATIVE WTE TECHNOLOGIES
TABLE 9: LIST OF METHODS UNDER INVESTIGATION FOR IMPROVING BIOGAS YIELDS
TABLE 10: DIFFERENCE BETWEEN ANAEROBIC AND AEROBIC DIGESTION
TABLE 11: LIST OF POTENTIAL MUNICIPAL SOLID WASTES
TABLE 12: IMPORTANT PARAMETERS FOR ANAEROBIC DIGESTION
TABLE 13: DIFFERENCE BETWEEN MESOPHILIC AND THERMOPHILIC ANAEROBIC DIGESTION
TABLE 14: BENEFITS AND LIMITATIONS OF DIFFERENT ANAEROBIC DIGESTION PROCESS CONFIGURATIONS
TABLE 15: COMPARISON OF GENERAL CHARACTERISTICS OF VARIOUS POWER GENERATORS
TABLE 16: DIFFERENT FUEL CELL TYPES USED FOR BIOGAS CONVERSION
TABLE 17: PROJECTED WASTE GENERATION DATA FOR 2025, BY REGION
TABLE 18: CARBON EFFICIENCY OF SEVERAL BIOFUEL PRODUCTION PROCESSES
TABLE 19: ANTICIPATED WTE PROJECTS ACROSS WORLD
TABLE 20: KEY LEGISLATION AND POLICIES FOR WASTE MANAGEMENT IN EUROPE
TABLE 21: COMPARISON OF FINANCIAL INCENTIVE POLICIES ADOPTED BY VARIOUS EUROPEAN COUNTRIES
TABLE 22: SOME OF THE PROMISING CASES OF AUTOMATION IN WTE
TABLE 23: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY TECHNOLOGY, HISTORICAL YEARS, 2016-2019 (IN $ MILLION)
TABLE 24: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY TECHNOLOGY, FORECAST YEARS, 2019-2028 (IN $ MILLION)
TABLE 25: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY APPLICATION, HISTORICAL YEARS, 2016-2019 (IN $ MILLION)
TABLE 26: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY APPLICATION, FORECAST YEARS, 2019-2028 (IN $ MILLION)
TABLE 27: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY WASTE TYPE, HISTORICAL YEARS, 2016-2019 (IN $ MILLION)
TABLE 28: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY WASTE TYPE, FORECAST YEARS, 2019-2028 (IN $ MILLION)
TABLE 29: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY MSW TYPE, HISTORICAL YEARS, 2016-2019 (IN $ MILLION)
TABLE 30: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY MSW TYPE, FORECAST YEARS, 2019-2028 (IN $ MILLION)
TABLE 31: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY COUNTRY, HISTORICAL YEARS, 2016-2019 (IN $ MILLION)
TABLE 32: EUROPE WASTE-TO-ENERGY (WTE) MARKET, BY COUNTRY, FORECAST YEARS, 2019-2028 (IN $ MILLION)
TABLE 33: LEVELS OF WASTE MANAGEMENT IN EUROPE
US $
Euro €
GBP £