Report Detail
Global Waste-to-Energy Technologies Market Insights, Forecast to 2025
- RnM2849837 |
- 01 February, 2019 |
- Global |
- 124 Pages |
- QYResearch |
- Energy & Power
Waste-to-Energy (WTE) technology utilizes Municipal Solid Waste (MSW) to create electric and heat energy through various complex conversion methods
WTE technology provides an alternative source of renewable energy in a world with limited or challenged fossil reserves.
MSW is considered a source of renewable energy because it contains a large amount of biological and renewable materials.
WTE (Waste-to-Energy) is the process of generating energy in the form of electricity and/or heat from the primary treatment of waste. WTE is a form of energy recovery. Most WTE processes produce electricity and/or heat directly through combustion, or produce a combustible fuel commodity, such as methane, methanol, ethanol or synthetic fuels.
The classification of Waste-to-Energy Technologies includes Thermal Technologies and Biochemical Reactions. The proportion of Thermal Technologies in 2015 is about 97.3%.
Europe region is the largest supplier of Waste-to-Energy Technologies, with a waste treat share nearly 48.8% in 2015. North America is the second largest supplier of Waste-to-Energy Technologies, enjoying waste treat market share about 20.2% in 2015.
Europe is the largest energy generate place, with energy generate market share nearly 44% in 2015. Following Europe, North America and China are also both the large energy generate place with the energy generate market share of 27.4% and 11.5%.
The Waste-to-Energy Technologies market was valued at 10100 Million US$ in 2018 and is projected to reach 12700 Million US$ by 2025, at a CAGR of 2.9% during the forecast period. In this study, 2018 has been considered as the base year and 2019 to 2025 as the forecast period to estimate the market size for Waste-to-Energy Technologies.
This report presents the worldwide Waste-to-Energy Technologies market size (value, production and consumption), splits the breakdown (data status 2014-2019 and forecast to 2025), by manufacturers, region, type and application.
This study also analyzes the market status, market share, growth rate, future trends, market drivers, opportunities and challenges, risks and entry barriers, sales channels, distributors and Porter's Five Forces Analysis.
The following manufacturers are covered in this report:
Covanta
Suez
Wheelabrator
Veolia
China Everbright
A2A
EEW Efw
CA Tokyo 23
Attero
TIRU
MVV Energie
NEAS
Viridor
AEB Amsterdam
AVR
Tianjin Teda
City of Kobe
Shenzhen Energy
Grandblue
Osaka City Hall
MCC
Waste-to-Energy Technologies Breakdown Data by Type
Thermal Technologies
Biochemical Reactions
Waste-to-Energy Technologies Breakdown Data by Application
Power Plant
Heating Plant
Others
Waste-to-Energy Technologies Production by Region
United States
Europe
China
Japan
Other Regions
Waste-to-Energy Technologies Consumption by Region
North America
United States
Canada
Mexico
Asia-Pacific
China
India
Japan
South Korea
Australia
Indonesia
Malaysia
Philippines
Thailand
Vietnam
Europe
Germany
France
UK
Italy
Russia
Rest of Europe
Central & South America
Brazil
Rest of South America
Middle East & Africa
GCC Countries
Turkey
Egypt
South Africa
Rest of Middle East & Africa
The study objectives are:
To analyze and research the global Waste-to-Energy Technologies status and future forecast,involving, production, revenue, consumption, historical and forecast.
To present the key Waste-to-Energy Technologies manufacturers, production, revenue, market share, and recent development.
To split the breakdown data by regions, type, manufacturers and applications.
To analyze the global and key regions market potential and advantage, opportunity and challenge, restraints and risks.
To identify significant trends, drivers, influence factors in global and regions.
To analyze competitive developments such as expansions, agreements, new product launches, and acquisitions in the market.
In this study, the years considered to estimate the market size of Waste-to-Energy Technologies :
History Year: 2014 - 2018
Base Year: 2018
Estimated Year: 2019
Forecast Year: 2019 - 2025
This report includes the estimation of market size for value (million USD) and volume (K Units). Both top-down and bottom-up approaches have been used to estimate and validate the market size of Waste-to-Energy Technologies market, to estimate the size of various other dependent submarkets in the overall market. Key players in the market have been identified through secondary research, and their market shares have been determined through primary and secondary research. All percentage shares, splits, and breakdowns have been determined using secondary sources and verified primary sources.
For the data information by region, company, type and application, 2018 is considered as the base year. Whenever data information was unavailable for the base year, the prior year has been considered.
Table of Contents
1 Study Coverage
- 1.1 Waste-to-Energy Technologies Product
- 1.2 Key Market Segments in This Study
- 1.3 Key Manufacturers Covered
- 1.4 Market by Type
- 1.4.1 Global Waste-to-Energy Technologies Market Size Growth Rate by Type
- 1.4.2 Thermal Technologies
- 1.4.3 Biochemical Reactions
- 1.5 Market by Application
- 1.5.1 Global Waste-to-Energy Technologies Market Size Growth Rate by Application
- 1.5.2 Power Plant
- 1.5.3 Heating Plant
- 1.5.4 Others
- 1.6 Study Objectives
- 1.7 Years Considered
2 Executive Summary
- 2.1 Global Waste-to-Energy Technologies Market Size
- 2.1.1 Global Waste-to-Energy Technologies Revenue 2014-2025
- 2.1.2 Global Waste-to-Energy Technologies Production 2014-2025
- 2.2 Waste-to-Energy Technologies Growth Rate (CAGR) 2019-2025
- 2.3 Analysis of Competitive Landscape
- 2.3.1 Manufacturers Market Concentration Ratio (CR5 and HHI)
- 2.3.2 Key Waste-to-Energy Technologies Manufacturers
- 2.3.2.1 Waste-to-Energy Technologies Manufacturing Base Distribution, Headquarters
- 2.3.2.2 Manufacturers Waste-to-Energy Technologies Product Offered
- 2.3.2.3 Date of Manufacturers Enter into Waste-to-Energy Technologies Market
- 2.4 Key Trends for Waste-to-Energy Technologies Markets & Products
3 Market Size by Manufacturers
- 3.1 Waste-to-Energy Technologies Production by Manufacturers
- 3.1.1 Waste-to-Energy Technologies Production by Manufacturers
- 3.1.2 Waste-to-Energy Technologies Production Market Share by Manufacturers
- 3.2 Waste-to-Energy Technologies Revenue by Manufacturers
- 3.2.1 Waste-to-Energy Technologies Revenue by Manufacturers (2014-2019)
- 3.2.2 Waste-to-Energy Technologies Revenue Share by Manufacturers (2014-2019)
- 3.3 Waste-to-Energy Technologies Price by Manufacturers
- 3.4 Mergers & Acquisitions, Expansion Plans
4 Waste-to-Energy Technologies Production by Regions
- 4.1 Global Waste-to-Energy Technologies Production by Regions
- 4.1.1 Global Waste-to-Energy Technologies Production Market Share by Regions
- 4.1.2 Global Waste-to-Energy Technologies Revenue Market Share by Regions
- 4.2 United States
- 4.2.1 United States Waste-to-Energy Technologies Production
- 4.2.2 United States Waste-to-Energy Technologies Revenue
- 4.2.3 Key Players in United States
- 4.2.4 United States Waste-to-Energy Technologies Import & Export
- 4.3 Europe
- 4.3.1 Europe Waste-to-Energy Technologies Production
- 4.3.2 Europe Waste-to-Energy Technologies Revenue
- 4.3.3 Key Players in Europe
- 4.3.4 Europe Waste-to-Energy Technologies Import & Export
- 4.4 China
- 4.4.1 China Waste-to-Energy Technologies Production
- 4.4.2 China Waste-to-Energy Technologies Revenue
- 4.4.3 Key Players in China
- 4.4.4 China Waste-to-Energy Technologies Import & Export
- 4.5 Japan
- 4.5.1 Japan Waste-to-Energy Technologies Production
- 4.5.2 Japan Waste-to-Energy Technologies Revenue
- 4.5.3 Key Players in Japan
- 4.5.4 Japan Waste-to-Energy Technologies Import & Export
- 4.6 Other Regions
- 4.6.1 South Korea
- 4.6.2 India
- 4.6.3 Southeast Asia
5 Waste-to-Energy Technologies Consumption by Regions
- 5.1 Global Waste-to-Energy Technologies Consumption by Regions
- 5.1.1 Global Waste-to-Energy Technologies Consumption by Regions
- 5.1.2 Global Waste-to-Energy Technologies Consumption Market Share by Regions
- 5.2 North America
- 5.2.1 North America Waste-to-Energy Technologies Consumption by Application
- 5.2.2 North America Waste-to-Energy Technologies Consumption by Countries
- 5.2.3 United States
- 5.2.4 Canada
- 5.2.5 Mexico
- 5.3 Europe
- 5.3.1 Europe Waste-to-Energy Technologies Consumption by Application
- 5.3.2 Europe Waste-to-Energy Technologies Consumption by Countries
- 5.3.3 Germany
- 5.3.4 France
- 5.3.5 UK
- 5.3.6 Italy
- 5.3.7 Russia
- 5.4 Asia Pacific
- 5.4.1 Asia Pacific Waste-to-Energy Technologies Consumption by Application
- 5.4.2 Asia Pacific Waste-to-Energy Technologies Consumption by Countries
- 5.4.3 China
- 5.4.4 Japan
- 5.4.5 South Korea
- 5.4.6 India
- 5.4.7 Australia
- 5.4.8 Indonesia
- 5.4.9 Thailand
- 5.4.10 Malaysia
- 5.4.11 Philippines
- 5.4.12 Vietnam
- 5.5 Central & South America
- 5.5.1 Central & South America Waste-to-Energy Technologies Consumption by Application
- 5.5.2 Central & South America Waste-to-Energy Technologies Consumption by Country
- 5.5.3 Brazil
- 5.6 Middle East and Africa
- 5.6.1 Middle East and Africa Waste-to-Energy Technologies Consumption by Application
- 5.6.2 Middle East and Africa Waste-to-Energy Technologies Consumption by Countries
- 5.6.3 GCC Countries
- 5.6.4 Egypt
- 5.6.5 South Africa
6 Market Size by Type
- 6.1 Global Waste-to-Energy Technologies Production by Type
- 6.2 Global Waste-to-Energy Technologies Revenue by Type
- 6.3 Waste-to-Energy Technologies Price by Type
7 Market Size by Application
- 7.1 Overview
- 7.2 Global Waste-to-Energy Technologies Breakdown Dada by Application
- 7.2.1 Global Waste-to-Energy Technologies Consumption by Application
- 7.2.2 Global Waste-to-Energy Technologies Consumption Market Share by Application (2014-2019)
8 Manufacturers Profiles
- 8.1 Covanta
- 8.1.1 Covanta Company Details
- 8.1.2 Company Overview
- 8.1.3 Covanta Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.1.4 Covanta Waste-to-Energy Technologies Product Description
- 8.1.5 Covanta Recent Development
- 8.2 Suez
- 8.2.1 Suez Company Details
- 8.2.2 Company Overview
- 8.2.3 Suez Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.2.4 Suez Waste-to-Energy Technologies Product Description
- 8.2.5 Suez Recent Development
- 8.3 Wheelabrator
- 8.3.1 Wheelabrator Company Details
- 8.3.2 Company Overview
- 8.3.3 Wheelabrator Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.3.4 Wheelabrator Waste-to-Energy Technologies Product Description
- 8.3.5 Wheelabrator Recent Development
- 8.4 Veolia
- 8.4.1 Veolia Company Details
- 8.4.2 Company Overview
- 8.4.3 Veolia Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.4.4 Veolia Waste-to-Energy Technologies Product Description
- 8.4.5 Veolia Recent Development
- 8.5 China Everbright
- 8.5.1 China Everbright Company Details
- 8.5.2 Company Overview
- 8.5.3 China Everbright Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.5.4 China Everbright Waste-to-Energy Technologies Product Description
- 8.5.5 China Everbright Recent Development
- 8.6 A2A
- 8.6.1 A2A Company Details
- 8.6.2 Company Overview
- 8.6.3 A2A Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.6.4 A2A Waste-to-Energy Technologies Product Description
- 8.6.5 A2A Recent Development
- 8.7 EEW Efw
- 8.7.1 EEW Efw Company Details
- 8.7.2 Company Overview
- 8.7.3 EEW Efw Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.7.4 EEW Efw Waste-to-Energy Technologies Product Description
- 8.7.5 EEW Efw Recent Development
- 8.8 CA Tokyo 23
- 8.8.1 CA Tokyo 23 Company Details
- 8.8.2 Company Overview
- 8.8.3 CA Tokyo 23 Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.8.4 CA Tokyo 23 Waste-to-Energy Technologies Product Description
- 8.8.5 CA Tokyo 23 Recent Development
- 8.9 Attero
- 8.9.1 Attero Company Details
- 8.9.2 Company Overview
- 8.9.3 Attero Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.9.4 Attero Waste-to-Energy Technologies Product Description
- 8.9.5 Attero Recent Development
- 8.10 TIRU
- 8.10.1 TIRU Company Details
- 8.10.2 Company Overview
- 8.10.3 TIRU Waste-to-Energy Technologies Production Revenue and Gross Margin (2014-2019)
- 8.10.4 TIRU Waste-to-Energy Technologies Product Description
- 8.10.5 TIRU Recent Development
- 8.11 MVV Energie
- 8.12 NEAS
- 8.13 Viridor
- 8.14 AEB Amsterdam
- 8.15 AVR
- 8.16 Tianjin Teda
- 8.17 City of Kobe
- 8.18 Shenzhen Energy
- 8.19 Grandblue
- 8.20 Osaka City Hall
- 8.21 MCC
9 Production Forecasts
- 9.1 Waste-to-Energy Technologies Production and Revenue Forecast
- 9.1.1 Global Waste-to-Energy Technologies Production Forecast 2019-2025
- 9.1.2 Global Waste-to-Energy Technologies Revenue Forecast 2019-2025
- 9.2 Waste-to-Energy Technologies Production and Revenue Forecast by Regions
- 9.2.1 Global Waste-to-Energy Technologies Revenue Forecast by Regions
- 9.2.2 Global Waste-to-Energy Technologies Production Forecast by Regions
- 9.3 Waste-to-Energy Technologies Key Producers Forecast
- 9.3.1 United States
- 9.3.2 Europe
- 9.3.3 China
- 9.3.4 Japan
- 9.4 Forecast by Type
- 9.4.1 Global Waste-to-Energy Technologies Production Forecast by Type
- 9.4.2 Global Waste-to-Energy Technologies Revenue Forecast by Type
10 Consumption Forecast
- 10.1 Waste-to-Energy Technologies Consumption Forecast by Application
- 10.2 Waste-to-Energy Technologies Consumption Forecast by Regions
- 10.3 North America Market Consumption Forecast
- 10.3.1 North America Waste-to-Energy Technologies Consumption Forecast by Regions 2019-2025
- 10.3.2 United States
- 10.3.3 Canada
- 10.3.4 Mexico
- 10.4 Europe Market Consumption Forecast
- 10.4.1 Europe Waste-to-Energy Technologies Consumption Forecast by Regions 2019-2025
- 10.4.2 Germany
- 10.4.3 France
- 10.4.4 UK
- 10.4.5 Italy
- 10.4.6 Russia
- 10.5 Asia Pacific Market Consumption Forecast
- 10.5.1 Asia Pacific Waste-to-Energy Technologies Consumption Forecast by Regions 2019-2025
- 10.5.2 China
- 10.5.3 Japan
- 10.5.4 South Korea
- 10.5.5 India
- 10.5.6 Australia
- 10.5.7 Indonesia
- 10.5.8 Thailand
- 10.5.9 Malaysia
- 10.5.10 Philippines
- 10.5.11 Vietnam
- 10.6 Central & South America Market Consumption Forecast
- 10.6.1 Central & South America Waste-to-Energy Technologies Consumption Forecast by Regions 2019-2025
- 10.6.2 Brazil
- 10.7 Middle East and Africa Market Consumption Forecast
- 10.7.1 Middle East and Africa Waste-to-Energy Technologies Consumption Forecast by Regions 2019-2025
- 10.7.2 GCC Countries
- 10.7.3 Egypt
- 10.7.4 South Africa
11 Value Chain and Sales Channels Analysis
- 11.1 Value Chain Analysis
- 11.2 Sales Channels Analysis
- 11.2.1 Waste-to-Energy Technologies Sales Channels
- 11.2.2 Waste-to-Energy Technologies Distributors
- 11.3 Waste-to-Energy Technologies Customers
12 Market Opportunities & Challenges, Risks and Influences Factors Analysis
- 12.1 Market Opportunities and Drivers
- 12.2 Market Challenges
- 12.3 Market Risks/Restraints
13 Key Findings in the Global Waste-to-Energy Technologies Study
14 Appendix
- 14.1 Research Methodology
- 14.1.1 Methodology/Research Approach
- 14.1.1.1 Research Programs/Design
- 14.1.1.2 Market Size Estimation
- 14.1.1.3 Market Breakdown and Data Triangulation
- 14.1.2 Data Source
- 14.1.2.1 Secondary Sources
- 14.1.2.2 Primary Sources
- 14.1.1 Methodology/Research Approach
- 14.2 Author Details
Summary:
Get latest Market Research Reports on Waste-to-Energy Technologies . Industry analysis & Market Report on Waste-to-Energy Technologies is a syndicated market report, published as Global Waste-to-Energy Technologies Market Insights, Forecast to 2025. It is complete Research Study and Industry Analysis of Waste-to-Energy Technologies market, to understand, Market Demand, Growth, trends analysis and Factor Influencing market.
REPORT YOU MIGHT BE INTERESTED
Related Reports
Reason to Buy
Reports and Markets
Contact Us
+1-352-353-0818 (US)Newsletter
KEEP UP TO DATE ON ALL THE LATEST REPORTS
