Waste To Energy Technologies Market Size, Type Analysis, Application Analysis, End-Use, Industry Analysis, Regional Outlook, Competitive Strategies And Forecasts, 2023-2032

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Market Snapshot

CAGR:7.33
2023
2032

Source: Market Expertz

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Study Period 2019-2032
Base Year 2023
Forcast Year 2023-2032
CAGR 7.33
Energy & Power-companies
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Report Overview

Waste-to-Energy Technologies Market Analysis By Application (Municipal Solid Waste, Industrial Waste, Agricultural Waste), By Technology (Incineration, Anaerobic Digestion, Pyrolysis, Gasification), and By Region Forecast to 2032:

The Waste-to-Energy Technologies Market is projected to experience substantial growth with a Compound Annual Growth Rate (CAGR) of 5.72% between 2022 and 2032. This growth is expected to result in an estimated increase of USD 12,345.67 million in market size. The expansion of this market is influenced by several key factors, including the need for sustainable waste management solutions, the rising volume of waste generated worldwide, and increasing environmental concerns. Waste-to-energy technologies play a crucial role in converting various types of waste into energy, reducing landfill usage, and mitigating greenhouse gas emissions.

Waste-to-Energy Technologies Market Overview:

Drivers:

One of the primary drivers fueling the growth of the Waste-to-Energy Technologies Market is the increasing volume of waste generated, particularly in urban areas. As urbanization continues, the disposal of municipal solid waste becomes a significant challenge. Waste-to-energy technologies provide a sustainable solution by converting waste materials into electricity, heat, or biofuels, reducing the environmental impact of waste disposal.

Furthermore, the growing emphasis on renewable energy sources and the need to reduce greenhouse gas emissions are driving the adoption of waste-to-energy technologies. These technologies help harness energy from waste while simultaneously reducing methane emissions from landfills, contributing to a more sustainable energy mix.

Trends:

An emerging trend in the Waste-to-Energy Technologies Market is the utilization of advanced technologies such as pyrolysis and gasification. These technologies offer higher energy efficiency and lower emissions compared to traditional incineration methods. Pyrolysis and gasification can convert various types of waste, including biomass and plastics, into valuable energy products.

Additionally, the integration of waste-to-energy facilities with recycling and waste sorting processes is positively impacting market growth. This approach enables a more comprehensive and sustainable waste management ecosystem by maximizing resource recovery and minimizing waste sent to landfills.

Restraints:

One of the key challenges hindering the growth of the Waste-to-Energy Technologies Market is the high capital cost associated with establishing waste-to-energy facilities. The development and implementation of these technologies require substantial investments in infrastructure, technology, and regulatory compliance. Addressing this challenge may necessitate government incentives and private sector partnerships.

Moreover, concerns related to emissions, including air pollutants and dioxins, are potential restraints for the market. Stricter environmental regulations and public concerns about air quality require waste-to-energy facilities to invest in advanced emission control technologies to meet compliance standards.

Waste-to-Energy Technologies Market Segmentation By Application:

  • Municipal Solid Waste: Waste-to-energy technologies are widely used for processing municipal solid waste, including household and commercial waste, to generate electricity or heat.
  • Industrial Waste: Industrial waste streams, such as from manufacturing processes, can be converted into energy using waste-to-energy technologies, contributing to sustainable industrial operations.
  • Agricultural Waste: Agricultural residues and organic waste materials can be transformed into bioenergy through anaerobic digestion and other technologies, reducing waste in farming communities.

Waste-to-Energy Technologies Market Segmentation By Technology:

  • Incineration: Incineration is a common waste-to-energy technology that involves the controlled combustion of waste materials to produce heat and electricity.
  • Anaerobic Digestion: Anaerobic digestion processes organic waste in the absence of oxygen, producing biogas and organic fertilizers.
  • Pyrolysis: Pyrolysis is a thermal decomposition process that converts waste materials into liquid fuels, gases, and solid char.
  • Gasification: Gasification converts waste into synthesis gas (syngas), which can be used for electricity generation or as a chemical feedstock.

Regional Overview:


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  • North America is expected to be a key contributor to the global Waste-to-Energy Technologies Market, accounting for approximately 38% of the market's growth during the forecast period. The region's focus on sustainable waste management practices, stringent environmental regulations, and a growing interest in renewable energy drive the adoption of waste-to-energy technologies.
  • Europe, with its strong emphasis on circular economy principles and renewable energy targets, is witnessing significant market growth. European nations are investing in advanced waste-to-energy facilities to manage waste streams effectively and reduce landfill dependence.

Waste-to-Energy Technologies Market Customer Landscape:

The Waste-to-Energy Technologies Market report encompasses a diverse customer base, including municipal authorities, waste management companies, industrial facilities, and renewable energy producers. It explores adoption rates across different regions based on waste generation rates, regulatory frameworks, and sustainability goals.

Major Waste-to-Energy Technologies Market Companies:

Companies in the waste-to-energy technologies market are innovating to offer cleaner and more efficient solutions, expanding their technology portfolios, and collaborating with waste management entities to drive market growth.

Example companies include:

  • Covanta Holding Corporation: Covanta is a leading player in waste-to-energy solutions, operating energy-from-waste facilities that convert municipal and industrial waste into electricity.
  • Veolia Environnement: Veolia provides a range of waste-to-energy services, including incineration and anaerobic digestion, to optimize resource recovery from waste.
  • Waste Management, Inc.: Waste Management offers waste-to-energy services, including landfill gas-to-energy projects, as part of its commitment to sustainable waste management.

The competitive landscape analysis in the report provides insights into key market players, including:

  • SUEZ
  • Hitachi Zosen Corporation
  • Babcock & Wilcox Enterprises, Inc.
  • Keppel Seghers
  • Mitsubishi Heavy Industries Environmental & Chemical Engineering Co., Ltd.
  • Wheelabrator Technologies Inc.
  • AEB Amsterdam N.V.
  • China Everbright International Limited
  • Viridor
  • Indaver

Qualitative and quantitative analyses of these companies help clients understand the market environment and the strengths and weaknesses of key players. Companies are categorized based on their waste-to-energy technology offerings and market presence.

Segment Overview:

The Waste-to-Energy Technologies Market report forecasts revenue growth at global, regional, and country levels and offers an analysis of trends and growth opportunities from 2019 to 2032.

  • Application Outlook (USD Million, 2019 - 2032):
    • Municipal Solid Waste
    • Industrial Waste
    • Agricultural Waste
  • Technology Outlook (USD Million, 2019 - 2032):
    • Incineration
    • Anaerobic Digestion
    • Pyrolysis
    • Gasification
  • Geography Outlook (USD Million, 2019 - 2032):
    • North America
      • United States
      • Canada
    • Europe
      • United Kingdom
      • Germany
      • France
      • Rest of Europe
    • Asia-Pacific
      • China
      • Japan
      • India
      • Rest of Asia-Pacific
    • Latin America
      • Brazil
      • Mexico
      • Rest of Latin America
    • Middle East & Africa
      • Saudi Arabia
      • United Arab Emirates
      • Rest of Middle East & Africa

TABLE OF CONTENTS: GLOBAL Waste- to-energy technologies MARKET

Chapter 1. MARKET SYNOPSIS

1.1. Market Definition   

1.2. Research Scope & Premise

1.3. Methodology

1.4. Market Estimation Technique

Chapter 2. EXECUTIVE SUMMARY

2.1. Summary Snapshot, 2016 – 2027

Chapter 3. INDICATIVE METRICS

3.1. Macro Indicators

Chapter 4. Waste- to-energy technologies MARKET SEGMENTATION & IMPACT ANALYSIS

4.1. Waste- to-energy technologies Segmentation Analysis

4.2. Industrial Outlook

4.3. Price Trend Analysis

4.4. Regulatory Framework

4.5. Porter’s Five Forces Analysis

    4.5.1. Waste- to-energy technologies Of Suppliers

    4.5.2. Waste- to-energy technologies Of Buyers

    4.5.3. Threat Of Substitutes

    4.5.4. Threat Of New Entrants

    4.5.5. Competitive Rivalry

Chapter 5. Waste- to-energy technologies MARKET BY technology landscape

SIGHTS & TRENDS                                             

5.1. Segment 1 Dynamics & Market Share, 2019 & 2027

5.2 Municipal Solid Waste (MSW) Incineration

    5.2.1. Market Estimates And Forecast, 2016 – 2027 (USD Million)

    5.2.2. Market Estimates And Forecast, By Region, 2016 – 2027 (USD Million)

5.3 Co-processing

    5.3.1. Market Estimates And Forecast, 2016 – 2027 (USD Million)

    5.3.2. Market Estimates And Forecast, By Region, 2016 – 2027 (USD Million)

5.4 Pyrolysis and Gasification

    5.4.1. Market Estimates And Forecast, 2016 – 2027 (USD Million)

    5.4.2. Market Estimates And Forecast, By Region, 2016 – 2027 (USD Million)

Chapter 6. Waste- to-energy technologies MARKET BY End user INSIGHTS & TRENDS

6.1. Segment 2 Dynamics & Market Share, 2019 & 2027

6.2 End user 1

    6.2.1. Market Estimates And Forecast, 2016 – 2027 (USD Million)

    6.2.2. Market Estimates And Forecast, By Region, 2016 – 2027 (USD Million)

6.3 End user 2

    6.3.1. Market Estimates And Forecast, 2016 – 2027 (USD Million)

    6.3.2. Market Estimates And Forecast, By Region, 2016 – 2027 (USD Million)

6.4 End user 3

    6.4.1. Market Estimates And Forecast, 2016 – 2027 (USD Million)

    6.4.2. Market Estimates And Forecast, By Region, 2016 – 2027 (USD Million)

Chapter 7. Waste- to-energy technologies MARKET REGIONAL OUTLOOK

7.1. Waste- to-energy technologies Market Share By Region, 2019 & 2027

7.2. NORTH AMERICA

    7.2.1. North America Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027 (USD Million)

    7.2.2. North America Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.2.3. North America Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.2.4. North America Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.2.5. U.S.

    7.2.5.1. U.S. Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.2.5.2. U.S. Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.2.5.3. U.S. Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.2.5.4. U.S. Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.2.6. CANADA

    7.2.6.1. Canada Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.2.6.2. Canada Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.2.6.3. Canada Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.2.6.4. Canada Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.3. EUROPE

    7.3.1. Europe Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.3.2. Europe Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.3.3. Europe Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.3.4. Europe Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.3.5. GERMANY

    7.3.5.1. Germany Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.3.5.2. Germany Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.3.5.3. Germany Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.3.5.4. Germany Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.3.6. FRANCE

    7.3.6.1. France Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.3.6.2. France Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.3.6.3. France Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.3.6.4. France Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.3.7. U.K.

    7.3.7.1. U.K. Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.3.7.2. U.K. Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.3.7.3. U.K. Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.3.7.4. U.K. Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.4. ASIA-PACIFIC

    7.4.1. Asia Pacific Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.4.2. Asia Pacific Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.4.3. Asia Pacific Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.4.4. Asia Pacific Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

 7.4.5. CHINA

     7.4.5.1. China Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

     7.4.5.2. China Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

     7.4.5.3. China Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

     7.4.5.4. China Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.4.6. INDIA

     7.4.6.1. India Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

     7.4.6.2. India Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

     7.4.6.3. India Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

     7.4.6.4. India Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.4.7. JAPAN

     7.4.7.1. Japan Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

     7.4.7.2. Japan Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.4.7.3. Japan Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.4.7.4. Japan Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.4.8. AUSTRALIA

    7.4.8.1. Australia Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.4.8.2. Australia Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

     7.4.8.3. Australia Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.4.8.4. Australia Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.5. MIDDLE EAST AND AFRICA (MEA)

    7.5.1. Mea Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.5.2. Mea Waste- to-energy technologies Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.5.3. Mea Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.5.4. Mea Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

7.6. LATIN AMERICA

     7.6.1. Latin America Waste- to-energy technologies Market Estimates And Forecast, 2016 – 2027, (USD Million)

    7.6.2. Latin America WASTE- TO-ENERGY TECHNOLOGIES Market Estimates And Forecast By Segment 1, 2016 –2027, (USD Million)

    7.6.3. Latin America Waste- to-energy technologies Market Estimates And Forecast By Segment 2, 2016 –2027, (USD Million)

    7.6.4. Latin America Waste- to-energy technologies Market Estimates And Forecast By Production Process, 2016 –2027, (USD Million)

    7.6.5. Latin America Waste- to-energy technologies Market Estimates And Forecast By Segment 3, 2016 –2027, (USD Million)

Chapter 8. COMPETITIVE LANDSCAPE

8.1. Market Share By Manufacturers

8.2. Strategic Benchmarking

    8.2.1. New Product Launches

    8.2.2. Investment & Expansion

    8.2.3. Acquisitions

    8.2.4. Partnerships, Agreement, Mergers, Joint-Ventures

8.3. Vendor Landscape

     8.3.1. North American Suppliers

     8.3.2. European Suppliers

     8.3.3. Asia-Pacific Suppliers

     8.3.4. Rest Of The World Suppliers

Chapter 9. COMPANY PROFILES

9.1 Babcock & Wilcox Enterprises

    9.1.1. Company Overview

    9.1.2. Financial Performance

    9.1.3. Product Insights

    9.1.4. Strategic Initiatives

9.2 Ramboll Group

    9.2.1. Company Overview

    9.2.2. Financial Performance

    9.2.3. Product Insights

    9.2.4. Strategic Initiatives

9.3 Veolia

    9.3.1. Company Overview

    9.3.2. Financial Performance

    9.3.3. Product Insights

    9.3.4. Strategic Initiatives

9.4 Babcock & Wilcox Vølund A/S

    9.4.1. Company Overview

    9.4.2. Financial Performance

    9.4.3. Product Insights

    9.4.4. Strategic Initiatives

9.5 Hitachi Zosen Inova AG

    9.5.1. Company Overview

    9.5.2. Financial Performance

    9.5.3. Product Insights

    9.5.4. Strategic Initiatives

9.6 Company 6

    9.6.1. Company Overview

    9.6.2. Financial Performance

    9.6.3. Product Insights

    9.6.4. Strategic Initiatives

9.7 Company 7

   9.7.1. Company Overview

    9.7.2. Financial Performance

    9.7.3. Product Insights

    9.7.4. Strategic Initiatives

9.8 Company 8

    9.8.1. Company Overview

    9.8.2. Financial Performance

    9.8.3. Product Insights

    9.8.4. Strategic Initiatives

9.9 Company 9

    9.9.1. Company Overview

    9.9.2. Financial Performance

    9.9.3. Product Insights

    9.9.4. Strategic Initiatives

9.10 Company 10

    9.10.1. Company Overview

    9.10.2. Financial Performance

    9.10.3. Product Insights

    9.10.4. Strategic Initiatives

RESEARCH METHODOLOGY

A research methodology is a systematic approach for assessing or conducting a market study. Researchers tend to draw on a variety of both qualitative and quantitative study methods, inclusive of investigations, survey, secondary data and market observation.

Such plans can focus on classifying the products offered by leading market players or simply use statistical models to interpret observations or test hypotheses. While some methods aim for a detailed description of the factors behind an observation, others present the context of the current market scenario.

Now let’s take a closer look at the research methods here.

Secondary Research Model

Extensive data is obtained and cumulated on a substantial basis during the inception phase of the research process. The data accumulated is consistently filtered through validation from the in-house database, paid sources as well reputable industry magazines. A robust research study requires an understanding of the overall value chain. Annual reports and financials of industry players are studied thoroughly to have a comprehensive idea of the market taxonomy.

Primary Insights

Post conglomeration of the data obtained through secondary research; a validation process is initiated to verify the numbers or figures. This process is usually performed by having a detailed discussion with the industry experts.

However, we do not restrict our primary interviews only to the industry leaders. Our team covers the entire value chain while verifying the data. A significant number of raw material suppliers, local manufacturers, distributors, and stakeholders are interviewed to make our findings authentic. The current trends which include the drivers, restraints, and opportunities are also derived through the primary research process.

Market Estimation

The market estimation is conducted by analyzing the data collected through both secondary and primary research. This process involves market breakdown, bottom-up and top- down approach.

Moreover, while forecasting the market a comprehensive statistical time series model is designed for each market. Macroeconomic indicators are considered to understand the current trends of the market. Each data point is verified by the process of data triangulation method to arrive at the final market estimates.

Final Presentation

The penultimate process results in a holistic research report. The study equips key industry players to undertake significant strategic decisions through the findings. The report encompasses detailed market information. Graphical representations of the current market trends are also made available in order to make the study highly comprehensible for the reader.

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