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Global Waste to Energy Market (2023-2028) Competitive Analysis, Impact of Covid-19, Ansoff Analysis

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    Report

  • 172 Pages
  • February 2024
  • Region: Global
  • Infogence Global Research
  • ID: 5635969

Most common WtE technologies used at the municipal scale are incineration, co- processing, anaerobic digestion (AD), landfill gas (LFG) and pyrolysis/gasification

The Global Waste to Energy Market is estimated to be USD 58.17 Bn in 2023 and is expected to reach USD 120.29 Bn by 2028 growing at a CAGR of 15.64%.

Market Dynamics

Market dynamics are forces that impact the prices and behaviors of the Global Waste to Energy Market stakeholders. These forces create pricing signals which result from the changes in the supply and demand curves for a given product or service. Forces of Market Dynamics may be related to macro-economic and micro-economic factors. There are dynamic market forces other than price, demand, and supply. Human emotions can also drive decisions, influence the market, and create price signals.

As the market dynamics impact the supply and demand curves, decision-makers aim to determine the best way to use various financial tools to stem various strategies for speeding the growth and reducing the risks.

Market Segmentations

  • The Global Waste to Energy Market is segmented based on Technology, Vertical, and Geography.
  • By Technology, the market is classified into Biochemical and Thermal.
  • By Vertical, the market is classified into Public Sector and Private Sector.
  • By Geography, the market is classified into Americas, Europe, Middle-East & Africa and Asia-Pacific.

Company Profiles

The report provides a detailed analysis of the competitors in the market. It covers the financial performance analysis for the publicly listed companies in the market. The report also offers detailed information on the companies' recent development and competitive scenario. Some of the companies covered in this report are Andritz AG, Arrow Ecology, Axpo Holding, Babcock & Wilcox Enterprises, Biogen, BMF HAASE, BTA International, China Everbright, Chongqing Sanfeng Covanta Environmental Industry, Covanta Holding, etc.

Countries Studied

  • America (Argentina, Brazil, Canada, Chile, Colombia, Mexico, Peru, United States, Rest of Americas)
  • Europe (Austria, Belgium, Denmark, Finland, France, Germany, Italy, Netherlands, Norway, Poland, Russia, Spain, Sweden, Switzerland, United Kingdom, Rest of Europe)
  • Middle-East and Africa (Egypt, Israel, Qatar, Saudi Arabia, South Africa, United Arab Emirates, Rest of MEA)
  • Asia-Pacific (Australia, Bangladesh, China, India, Indonesia, Japan, Malaysia, Philippines, Singapore, South Korea, Sri Lanka, Thailand, Taiwan, Rest of Asia-Pacific)

Competitive Quadrant

The report includes Competitive Quadrant, a proprietary tool to analyze and evaluate the position of companies based on their Industry Position score and Market Performance score. The tool uses various factors for categorizing the players into four categories. Some of these factors considered for analysis are financial performance over the last 3 years, growth strategies, innovation score, new product launches, investments, growth in market share, etc.

Ansoff Analysis

  • The report presents a detailed Ansoff matrix analysis for the Global Waste to Energy Market. Ansoff Matrix, also known as Product/Market Expansion Grid, is a strategic tool used to design strategies for the growth of the company. The matrix can be used to evaluate approaches in four strategies viz. Market Development, Market Penetration, Product Development and Diversification. The matrix is also used for risk analysis to understand the risk involved with each approach.
  • The publisher analyses the using the Ansoff Matrix to provide the best approaches a company can take to improve its market position.
  • Based on the SWOT analysis conducted on the industry and industry players, the publisher has devised suitable strategies for market growth.

Why buy this report?

  • The report offers a comprehensive evaluation of the Global Waste to Energy Market. The report includes in-depth qualitative analysis, verifiable data from authentic sources, and projections about market size. The projections are calculated using proven research methodologies.
  • The report has been compiled through extensive primary and secondary research. The primary research is done through interviews, surveys, and observation of renowned personnel in the industry.
  • The report includes an in-depth market analysis using Porter's 5 forces model and the Ansoff Matrix. In addition, the impact of Covid-19 on the market is also featured in the report.
  • The report also includes the regulatory scenario in the industry, which will help you make a well-informed decision. The report discusses major regulatory bodies and major rules and regulations imposed on this sector across various geographies.
  • The report also contains the competitive analysis using Positioning Quadrants, the Proprietary competitive positioning tool.

Report Highlights:

  • A complete analysis of the market, including parent industry
  • Important market dynamics and trends
  • Market segmentation
  • Historical, current, and projected size of the market based on value and volume
  • Market shares and strategies of key players
  • Recommendations to companies for strengthening their foothold in the market

Table of Contents

1 Report Description
1.1 Study Objectives
1.2 Market Definition
1.3 Currency
1.4 Years Considered
1.5 Language
1.6 Key Stakeholders
2 Research Methodology
2.1 Research Process
2.2 Data Collection and Validation
2.2.1 Secondary Research
2.2.2 Primary Research
2.2.3 Models
2.3 Market Size Estimation
2.3.1 Bottom-Up Approach
2.3.2 Top-Down Approach
2.4 Assumptions of the Study
2.5 Limitations of the Study
3 Executive Summary
3.1 Introduction
3.2 Market Size, Segmentations and Outlook
4 Market Dynamics
4.1 Drivers
4.1.1 Rising Public Disposable Waste and Industrial Waste
4.1.2 Governments Initiatives and Financial Schemes to Encourage Production of Energy from Industrial and Agricultural Wastes
4.1.3 Increasing Demand for Waste to Energy (WTE) Methods to Produce Heat and Electricity
4.2 Restraints
4.2.1 Financial Burden Associated with Incinerators
4.3 Opportunities
4.3.1 Dendro Liquid Energy Emerging Waste-To-Energy Technologies
4.3.2 Increasing Development in Incineration and Gasification Technologies
4.4 Challenges
4.4.1 Rising Concerns Related to the Environmental Hazards Associated with the Incineration Process
5 Market Analysis
5.1 Regulatory Scenario
5.2 Porter's Five Forces Analysis
5.3 Impact of COVID-19
5.4 Ansoff Matrix Analysis
6 Global Waste to Energy Market, By Technology
6.1 Introduction
6.2 Biochemical
6.2.1 Gasification
6.2.2 Incineration
6.2.3 Pyrolysis
6.3 Thermal
6.3.1 Gasification
6.3.2 Incineration
6.3.3 Pyrolysis
7 Global Waste to Energy Market, By Vertical
7.1 Introduction
7.2 Public Sector
7.3 Private Sector
8 Americas’ Waste to Energy Market
8.1 Introduction
8.2 Argentina
8.3 Brazil
8.4 Canada
8.5 Chile
8.6 Colombia
8.7 Mexico
8.8 Peru
8.9 United States
8.10 Rest of Americas
9 Europe’s Waste to Energy Market
9.1 Introduction
9.2 Austria
9.3 Belgium
9.4 Denmark
9.5 Finland
9.6 France
9.7 Germany
9.8 Italy
9.9 Netherlands
9.10 Norway
9.11 Poland
9.12 Russia
9.13 Spain
9.14 Sweden
9.15 Switzerland
9.16 United Kingdom
9.17 Rest of Europe
10 Middle East and Africa’sWaste to Energy Market
10.1 Introduction
10.2 Egypt
10.3 Israel
10.4 Qatar
10.5 Saudi Arabia
10.6 South Africa
10.7 United Arab Emirates
10.8 Rest of MEA
11 APAC’s Waste to Energy Market
11.1 Introduction
11.2 Australia
11.3 Bangladesh
11.4 China
11.5 India
11.6 Indonesia
11.7 Japan
11.8 Malaysia
11.9 Philippines
11.10 Singapore
11.11 South Korea
11.12 Sri Lanka
11.13 Thailand
11.14 Taiwan
11.15 Rest of Asia-Pacific
12 Competitive Landscape
12.1 Competitive Quadrant
12.2 Market Share Analysis
12.3 Strategic Initiatives
12.3.1 M&A and Investments
12.3.2 Partnerships and Collaborations
12.3.3 Product Developments and Improvements
13 Company Profiles
13.1 Andritz
13.2 Arrow Ecology
13.3 Axpo Holding
13.4 Babcock & Wilcox Enterprises
13.5 Biogen (UK)
13.6 BMF HAASE
13.7 BTA International
13.8 China Everbright
13.9 Chongqing Sanfeng Covanta Environmental Industry
13.10 Covanta Holding
13.11 Emery Energy Company
13.12 Essent
13.13 Evoqua Water Technologies
13.14 Flex Energy Solutions
13.15 Hitachi Zosen Inova
13.16 John Wood Group
13.17 Keppel Seghers
13.18 PyroGenesis Canada
13.19 Suez Environment
13.20 Veolia Environment
13.21 Waste Management
13.22 Ylem Energy
14 Appendix
14.1 Questionnaire

Companies Mentioned

  • Andritz
  • Arrow Ecology
  • Axpo Holding
  • Babcock & Wilcox Enterprises
  • Biogen (UK)
  • BMF HAASE
  • BTA International
  • China Everbright
  • Chongqing Sanfeng Covanta Environmental Industry
  • Covanta Holding
  • Emery Energy Company
  • Essent
  • Evoqua Water Technologies
  • Flex Energy Solutions
  • Hitachi Zosen Inova
  • John Wood Group
  • Keppel Seghers
  • PyroGenesis Canada
  • Suez Environment
  • Veolia Environnement
  • Waste Management
  • Ylem Energy

Table Information