Waste Heat to Power Industry Research Report 2024

Waste Heat to Power Industry Research Report 2024


Waste heat to power (WHP) is the process of capturing heat discarded by an existing industrial process and using that heat to generate power.

Energy intensive industrial processes—such as those occurring at refineries, steel mills, glass furnaces, and cement kilns—all release hot exhaust gases and waste streams that can be harnessed with well-established technologies to generate electricity (see Appendix). The recovery of industrial waste heat for power is a largely untapped type of combined heat and power (CHP), which is the use of a single fuel source to generate both thermal energy (heating or cooling) and electricity.

According to APO Research, The global Waste Heat to Power market was valued at US$ million in 2023 and is anticipated to reach US$ million by 2030, witnessing a CAGR of xx% during the forecast period 2024-2030.

Europe is the largest Waste Heat to Power market with about 53% market share. North America is follower, accounting for about 30% market share.

The key players are Siemens, GE, ABB, Amec Foster Wheeler, Ormat, MHI, Exergy, ElectraTherm, Dürr Cyplan, GETEC, CNBM, DaLian East, E-Rational etc. Top 3 companies occupied about 51% market share.

Report Scope

This report aims to provide a comprehensive presentation of the global market for Waste Heat to Power, with both quantitative and qualitative analysis, to help readers develop business/growth strategies, assess the market competitive situation, analyze their position in the current marketplace, and make informed business decisions regarding Waste Heat to Power.

The report will help the Waste Heat to Power manufacturers, new entrants, and industry chain related companies in this market with information on the revenues, sales volume, and average price for the overall market and the sub-segments across the different segments, by company, by Type, by Application, and by regions.

The Waste Heat to Power market size, estimations, and forecasts are provided in terms of sales volume (MW) and revenue ($ millions), considering 2023 as the base year, with history and forecast data for the period from 2019 to 2030. This report segments the global Waste Heat to Power market comprehensively. Regional market sizes, concerning products by Type, by Application, and by players, are also provided. For a more in-depth understanding of the market, the report provides profiles of the competitive landscape, key competitors, and their respective market ranks. The report also discusses technological trends and new product developments.

Key Companies & Market Share Insights

In this section, the readers will gain an understanding of the key players competing. This report has studied the key growth strategies, such as innovative trends and developments, intensification of product portfolio, mergers and acquisitions, collaborations, new product innovation, and geographical expansion, undertaken by these participants to maintain their presence. Apart from business strategies, the study includes current developments and key financials. The readers will also get access to the data related to global revenue, price, and sales by manufacturers for the period 2019-2024. This all-inclusive report will certainly serve the clients to stay updated and make effective decisions in their businesses. Some of the prominent players reviewed in the research report include:

Siemens
GE
ABB
Amec Foster Wheeler
Ormat
MHI
Exergy
ElectraTherm
Dürr Cyplan
GETEC
CNBM
DaLian East
E-Rational

Waste Heat to Power segment by Type
Steam Rankine Cycle
Organic Rankine Cycles
Kalina Cycle

Waste Heat to Power segment by Application
Chemical Industry
Metal Manufacturing
Oil and Gas
Others

Waste Heat to Power Segment by Region
North America
U.S.
Canada
Europe
Germany
France
U.K.
Italy
Russia
Asia-Pacific
China
Japan
South Korea
India
Australia
China Taiwan
Indonesia
Thailand
Malaysia
Latin America
Mexico
Brazil
Argentina
Middle East & Africa
Turkey
Saudi Arabia
UAE

Key Drivers & Barriers

High-impact rendering factors and drivers have been studied in this report to aid the readers to understand the general development. Moreover, the report includes restraints and challenges that may act as stumbling blocks on the way of the players. This will assist the users to be attentive and make informed decisions related to business. Specialists have also laid their focus on the upcoming business prospects.

Reasons to Buy This Report

1. This report will help the readers to understand the competition within the industries and strategies for the competitive environment to enhance the potential profit. The report also focuses on the competitive landscape of the global Waste Heat to Power market, and introduces in detail the market share, industry ranking, competitor ecosystem, market performance, new product development, operation situation, expansion, and acquisition. etc. of the main players, which helps the readers to identify the main competitors and deeply understand the competition pattern of the market.
2. This report will help stakeholders to understand the global industry status and trends of Waste Heat to Power and provides them with information on key market drivers, restraints, challenges, and opportunities.
3. This report will help stakeholders to understand competitors better and gain more insights to strengthen their position in their businesses. The competitive landscape section includes the market share and rank (in volume and value), competitor ecosystem, new product development, expansion, and acquisition.
4. This report stays updated with novel technology integration, features, and the latest developments in the market
5. This report helps stakeholders to gain insights into which regions to target globally
6. This report helps stakeholders to gain insights into the end-user perception concerning the adoption of Waste Heat to Power.
7. This report helps stakeholders to identify some of the key players in the market and understand their valuable contribution.

Chapter Outline

Chapter 1: Research objectives, research methods, data sources, data cross-validation;
Chapter 2: Introduces the report scope of the report, executive summary of different market segments (by region, product type, application, etc), including the market size of each market segment, future development potential, and so on. It offers a high-level view of the current state of the market and its likely evolution in the short to mid-term, and long term.
Chapter 3: Detailed analysis of Waste Heat to Power manufacturers competitive landscape, price, production and value market share, latest development plan, merger, and acquisition information, etc.
Chapter 4: Provides profiles of key players, introducing the basic situation of the main companies in the market in detail, including product production/output, value, price, gross margin, product introduction, recent development, etc.
Chapter 5: Production/output, value of Waste Heat to Power by region/country. It provides a quantitative analysis of the market size and development potential of each region in the next six years.
Chapter 6: Consumption of Waste Heat to Power in regional level and country level. It provides a quantitative analysis of the market size and development potential of each region and its main countries and introduces the market development, future development prospects, market space, and production of each country in the world.
Chapter 7: Provides the analysis of various market segments by type, covering the market size and development potential of each market segment, to help readers find the blue ocean market in different market segments.
Chapter 8: Provides the analysis of various market segments by application, covering the market size and development potential of each market segment, to help readers find the blue ocean market in different downstream markets.
Chapter 9: Analysis of industrial chain, including the upstream and downstream of the industry.
Chapter 10: Introduces the market dynamics, latest developments of the market, the driving factors and restrictive factors of the market, the challenges and risks faced by manufacturers in the industry, and the analysis of relevant policies in the industry.
Chapter 11: The main points and conclusions of the report.
Chapter 11: The main points and conclusions of the report.


1 Preface
1.1 Scope of Report
1.2 Reasons for Doing This Study
1.3 Research Methodology
1.4 Research Process
1.5 Data Source
1.5.1 Secondary Sources
1.5.2 Primary Sources
2 Market Overview
2.1 Product Definition
2.2 Waste Heat to Power by Type
2.2.1 Market Value Comparison by Type (2019 VS 2023 VS 2030) & (US$ Million)
2.2.2 Steam Rankine Cycle
2.2.3 Organic Rankine Cycles
2.2.4 Kalina Cycle
2.3 Waste Heat to Power by Application
2.3.1 Market Value Comparison by Application (2019 VS 2023 VS 2030) & (US$ Million)
2.3.2 Chemical Industry
2.3.3 Metal Manufacturing
2.3.4 Oil and Gas
2.3.5 Others
2.4 Global Market Growth Prospects
2.4.1 Global Waste Heat to Power Production Value Estimates and Forecasts (2019-2030)
2.4.2 Global Waste Heat to Power Production Capacity Estimates and Forecasts (2019-2030)
2.4.3 Global Waste Heat to Power Production Estimates and Forecasts (2019-2030)
2.4.4 Global Waste Heat to Power Market Average Price (2019-2030)
3 Market Competitive Landscape by Manufacturers
3.1 Global Waste Heat to Power Production by Manufacturers (2019-2024)
3.2 Global Waste Heat to Power Production Value by Manufacturers (2019-2024)
3.3 Global Waste Heat to Power Average Price by Manufacturers (2019-2024)
3.4 Global Waste Heat to Power Industry Manufacturers Ranking, 2022 VS 2023 VS 2024
3.5 Global Waste Heat to Power Key Manufacturers, Manufacturing Sites & Headquarters
3.6 Global Waste Heat to Power Manufacturers, Product Type & Application
3.7 Global Waste Heat to Power Manufacturers, Date of Enter into This Industry
3.8 Global Waste Heat to Power Market CR5 and HHI
3.9 Global Manufacturers Mergers & Acquisition
4 Manufacturers Profiled
4.1 Siemens
4.1.1 Siemens Waste Heat to Power Company Information
4.1.2 Siemens Waste Heat to Power Business Overview
4.1.3 Siemens Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.1.4 Siemens Product Portfolio
4.1.5 Siemens Recent Developments
4.2 GE
4.2.1 GE Waste Heat to Power Company Information
4.2.2 GE Waste Heat to Power Business Overview
4.2.3 GE Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.2.4 GE Product Portfolio
4.2.5 GE Recent Developments
4.3 ABB
4.3.1 ABB Waste Heat to Power Company Information
4.3.2 ABB Waste Heat to Power Business Overview
4.3.3 ABB Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.3.4 ABB Product Portfolio
4.3.5 ABB Recent Developments
4.4 Amec Foster Wheeler
4.4.1 Amec Foster Wheeler Waste Heat to Power Company Information
4.4.2 Amec Foster Wheeler Waste Heat to Power Business Overview
4.4.3 Amec Foster Wheeler Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.4.4 Amec Foster Wheeler Product Portfolio
4.4.5 Amec Foster Wheeler Recent Developments
4.5 Ormat
4.5.1 Ormat Waste Heat to Power Company Information
4.5.2 Ormat Waste Heat to Power Business Overview
4.5.3 Ormat Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.5.4 Ormat Product Portfolio
4.5.5 Ormat Recent Developments
4.6 MHI
4.6.1 MHI Waste Heat to Power Company Information
4.6.2 MHI Waste Heat to Power Business Overview
4.6.3 MHI Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.6.4 MHI Product Portfolio
4.6.5 MHI Recent Developments
4.7 Exergy
4.7.1 Exergy Waste Heat to Power Company Information
4.7.2 Exergy Waste Heat to Power Business Overview
4.7.3 Exergy Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.7.4 Exergy Product Portfolio
4.7.5 Exergy Recent Developments
4.8 ElectraTherm
4.8.1 ElectraTherm Waste Heat to Power Company Information
4.8.2 ElectraTherm Waste Heat to Power Business Overview
4.8.3 ElectraTherm Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.8.4 ElectraTherm Product Portfolio
4.8.5 ElectraTherm Recent Developments
4.9 Dürr Cyplan
4.9.1 Dürr Cyplan Waste Heat to Power Company Information
4.9.2 Dürr Cyplan Waste Heat to Power Business Overview
4.9.3 Dürr Cyplan Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.9.4 Dürr Cyplan Product Portfolio
4.9.5 Dürr Cyplan Recent Developments
4.10 GETEC
4.10.1 GETEC Waste Heat to Power Company Information
4.10.2 GETEC Waste Heat to Power Business Overview
4.10.3 GETEC Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.10.4 GETEC Product Portfolio
4.10.5 GETEC Recent Developments
4.11 CNBM
4.11.1 CNBM Waste Heat to Power Company Information
4.11.2 CNBM Waste Heat to Power Business Overview
4.11.3 CNBM Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.11.4 CNBM Product Portfolio
4.11.5 CNBM Recent Developments
4.12 DaLian East
4.12.1 DaLian East Waste Heat to Power Company Information
4.12.2 DaLian East Waste Heat to Power Business Overview
4.12.3 DaLian East Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.12.4 DaLian East Product Portfolio
4.12.5 DaLian East Recent Developments
4.13 E-Rational
4.13.1 E-Rational Waste Heat to Power Company Information
4.13.2 E-Rational Waste Heat to Power Business Overview
4.13.3 E-Rational Waste Heat to Power Production, Value and Gross Margin (2019-2024)
4.13.4 E-Rational Product Portfolio
4.13.5 E-Rational Recent Developments
5 Global Waste Heat to Power Production by Region
5.1 Global Waste Heat to Power Production Estimates and Forecasts by Region: 2019 VS 2023 VS 2030
5.2 Global Waste Heat to Power Production by Region: 2019-2030
5.2.1 Global Waste Heat to Power Production by Region: 2019-2024
5.2.2 Global Waste Heat to Power Production Forecast by Region (2025-2030)
5.3 Global Waste Heat to Power Production Value Estimates and Forecasts by Region: 2019 VS 2023 VS 2030
5.4 Global Waste Heat to Power Production Value by Region: 2019-2030
5.4.1 Global Waste Heat to Power Production Value by Region: 2019-2024
5.4.2 Global Waste Heat to Power Production Value Forecast by Region (2025-2030)
5.5 Global Waste Heat to Power Market Price Analysis by Region (2019-2024)
5.6 Global Waste Heat to Power Production and Value, YOY Growth
5.6.1 North America Waste Heat to Power Production Value Estimates and Forecasts (2019-2030)
5.6.2 Europe Waste Heat to Power Production Value Estimates and Forecasts (2019-2030)
5.6.3 China Waste Heat to Power Production Value Estimates and Forecasts (2019-2030)
5.6.4 Japan Waste Heat to Power Production Value Estimates and Forecasts (2019-2030)
6 Global Waste Heat to Power Consumption by Region
6.1 Global Waste Heat to Power Consumption Estimates and Forecasts by Region: 2019 VS 2023 VS 2030
6.2 Global Waste Heat to Power Consumption by Region (2019-2030)
6.2.1 Global Waste Heat to Power Consumption by Region: 2019-2030
6.2.2 Global Waste Heat to Power Forecasted Consumption by Region (2025-2030)
6.3 North America
6.3.1 North America Waste Heat to Power Consumption Growth Rate by Country: 2019 VS 2023 VS 2030
6.3.2 North America Waste Heat to Power Consumption by Country (2019-2030)
6.3.3 U.S.
6.3.4 Canada
6.4 Europe
6.4.1 Europe Waste Heat to Power Consumption Growth Rate by Country: 2019 VS 2023 VS 2030
6.4.2 Europe Waste Heat to Power Consumption by Country (2019-2030)
6.4.3 Germany
6.4.4 France
6.4.5 U.K.
6.4.6 Italy
6.4.7 Russia
6.5 Asia Pacific
6.5.1 Asia Pacific Waste Heat to Power Consumption Growth Rate by Country: 2019 VS 2023 VS 2030
6.5.2 Asia Pacific Waste Heat to Power Consumption by Country (2019-2030)
6.5.3 China
6.5.4 Japan
6.5.5 South Korea
6.5.6 China Taiwan
6.5.7 Southeast Asia
6.5.8 India
6.5.9 Australia
6.6 Latin America, Middle East & Africa
6.6.1 Latin America, Middle East & Africa Waste Heat to Power Consumption Growth Rate by Country: 2019 VS 2023 VS 2030
6.6.2 Latin America, Middle East & Africa Waste Heat to Power Consumption by Country (2019-2030)
6.6.3 Mexico
6.6.4 Brazil
6.6.5 Turkey
6.6.5 GCC Countries
7 Segment by Type
7.1 Global Waste Heat to Power Production by Type (2019-2030)
7.1.1 Global Waste Heat to Power Production by Type (2019-2030) & (MW)
7.1.2 Global Waste Heat to Power Production Market Share by Type (2019-2030)
7.2 Global Waste Heat to Power Production Value by Type (2019-2030)
7.2.1 Global Waste Heat to Power Production Value by Type (2019-2030) & (US$ Million)
7.2.2 Global Waste Heat to Power Production Value Market Share by Type (2019-2030)
7.3 Global Waste Heat to Power Price by Type (2019-2030)
8 Segment by Application
8.1 Global Waste Heat to Power Production by Application (2019-2030)
8.1.1 Global Waste Heat to Power Production by Application (2019-2030) & (MW)
8.1.2 Global Waste Heat to Power Production by Application (2019-2030) & (MW)
8.2 Global Waste Heat to Power Production Value by Application (2019-2030)
8.2.1 Global Waste Heat to Power Production Value by Application (2019-2030) & (US$ Million)
8.2.2 Global Waste Heat to Power Production Value Market Share by Application (2019-2030)
8.3 Global Waste Heat to Power Price by Application (2019-2030)
9 Value Chain and Sales Channels Analysis of the Market
9.1 Waste Heat to Power Value Chain Analysis
9.1.1 Waste Heat to Power Key Raw Materials
9.1.2 Raw Materials Key Suppliers
9.1.3 Waste Heat to Power Production Mode & Process
9.2 Waste Heat to Power Sales Channels Analysis
9.2.1 Direct Comparison with Distribution Share
9.2.2 Waste Heat to Power Distributors
9.2.3 Waste Heat to Power Customers
10 Global Waste Heat to Power Analyzing Market Dynamics
10.1 Waste Heat to Power Industry Trends
10.2 Waste Heat to Power Industry Drivers
10.3 Waste Heat to Power Industry Opportunities and Challenges
10.4 Waste Heat to Power Industry Restraints
11 Report Conclusion
12 Disclaimer

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