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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.
In the last several years, global market of Waste Heat to Power developed stably, with an average growth rate of 6.2%. In 2016, global revenue of Waste Heat to Power is nearly 1767 M USD.
The classification of Waste Heat to Power includes Organic Rankine Cycles, Steam Rankine Cycle and Kalina Cycle. The proportion of Organic Rankine Cycles in 2016 is about 65%, and the proportion is in fluctuation trend from 2012 to 2016.
Waste Heat to Power is widely used in wide industry. It include Chemical Industry, Metal Manufacturing, Oil and Gas and Others Industries.
According to this study, over the next five years the Waste Heat to Power market will register a xx% CAGR in terms of revenue, the global market size will reach US$ xx million by 2024, from US$ xx million in 2019. In particular, this report presents the global market share (sales and revenue) of key companies in Waste Heat to Power business, shared in Chapter 3.
This report presents a comprehensive overview, market shares, and growth opportunities of Waste Heat to Power market by product type, application, key manufacturers and key regions and countries.
This study considers the Waste Heat to Power value and volume generated from the sales of the following segments:
Segmentation by product type: breakdown data from 2014 to 2019, in Section 2.3; and forecast to 2024 in section 11.7.
Steam Rankine Cycle
Organic Rankine Cycles
Kalina Cycle
Segmentation by application: breakdown data from 2014 to 2019, in Section 2.4; and forecast to 2024 in section 11.8.
Chemical Industry
Metal Manufacturing
Oil and Gas
Others
This report also splits the market by region: Breakdown data in Chapter 4, 5, 6, 7 and 8.
Americas
United States
Canada
Mexico
Brazil
APAC
China
Japan
Korea
Southeast Asia
India
Australia
Europe
Germany
France
UK
Italy
Russia
Spain
Middle East & Africa
Egypt
South Africa
Israel
Turkey
GCC Countries
The report also presents the market competition landscape and a corresponding detailed analysis of the major vendor/manufacturers in the market. The key manufacturers covered in this report: Breakdown data in in Chapter 3.
Siemens
GE
ABB
Amec Foster Wheeler
Ormat
MHI
Exergy
ElectraTherm
Dürr Cyplan
GETEC
CNBM
DaLian East
E-Rational
In addition, this report discusses the key drivers influencing market growth, opportunities, the challenges and the risks faced by key manufacturers and the market as a whole. It also analyzes key emerging trends and their impact on present and future development.
Research objectives
To study and analyze the global Waste Heat to Power consumption (value & volume) by key regions/countries, product type and application, history data from 2014 to 2018, and forecast to 2024.
To understand the structure of Waste Heat to Power market by identifying its various subsegments.
Focuses on the key global Waste Heat to Power manufacturers, to define, describe and analyze the sales volume, value, market share, market competition landscape, SWOT analysis and development plans in next few years.
To analyze the Waste Heat to Power with respect to individual growth trends, future prospects, and their contribution to the total market.
To share detailed information about the key factors influencing the growth of the market (growth potential, opportunities, drivers, industry-specific challenges and risks).
To project the consumption of Waste Heat to Power submarkets, with respect to key regions (along with their respective key countries).
To analyze competitive developments such as expansions, agreements, new product launches, and acquisitions in the market.
To strategically profile the key players and comprehensively analyze their growth strategies.
The base year for the study has been considered 2019, historic year 2014 and 2018, the forecast period considered is from 2020 to 2027. The regions analyzed for the market include North America, Europe, South America, Asia Pacific, and Middle East and Africa. These regions are further analyzed at the country-level. The study also includes attractiveness analysis of type, application and regions which are benchmarked based on their market size, growth rate and attractiveness in terms of present and future opportunity for understanding the future growth of the market.
Market is segmented on the basis:
The report offers in-depth analysis of driving factors, opportunities, restraints, and challenges for gaining the key insight of the market. The report emphasizes on all the key trends that play a vital role in the enlargement of the market from 2019 to 2026.
The report provides company profile of the key players operating in the market and a comparative analysis based on their business overviews industry offering, segment market share, regional presence, business strategies, innovations, mergers & acquisitions, recent developments, joint venture, collaborations, partnerships, SWOT analysis, and key financial information.
Table of Contents
2019-2024 Global Waste Heat to Power Consumption Market Report
1 Scope of the Report
1.1 Market Introduction
1.2 Research Objectives
1.3 Years Considered
1.4 Market Research Methodology
1.5 Economic Indicators
1.6 Currency Considered
2 Executive Summary
2.1 World Market Overview
2.1.1 Global Waste Heat to Power Consumption 2014-2024
2.1.2 Waste Heat to Power Consumption CAGR by Region
2.2 Waste Heat to Power Segment by Type
2.2.1 Steam Rankine Cycle
2.2.2 Organic Rankine Cycles
2.2.3 Kalina Cycle
2.3 Waste Heat to Power Consumption by Type
2.3.1 Global Waste Heat to Power Consumption Market Share by Type (2014-2019)
2.3.2 Global Waste Heat to Power Revenue and Market Share by Type (2014-2019)
2.3.3 Global Waste Heat to Power Sale Price by Type (2014-2019)
2.4 Waste Heat to Power Segment by Application
2.4.1 Chemical Industry
2.4.2 Metal Manufacturing
2.4.3 Oil and Gas
2.4.4 Others
2.5 Waste Heat to Power Consumption by Application
2.5.1 Global Waste Heat to Power Consumption Market Share by Application (2014-2019)
2.5.2 Global Waste Heat to Power Value and Market Share by Application (2014-2019)
2.5.3 Global Waste Heat to Power Sale Price by Application (2014-2019)
3 Global Waste Heat to Power by Players
3.1 Global Waste Heat to Power Sales Market Share by Players
3.1.1 Global Waste Heat to Power Sales by Players (2017-2019)
3.1.2 Global Waste Heat to Power Sales Market Share by Players (2017-2019)
3.2 Global Waste Heat to Power Revenue Market Share by Players
3.2.1 Global Waste Heat to Power Revenue by Players (2017-2019)
3.2.2 Global Waste Heat to Power Revenue Market Share by Players (2017-2019)
3.3 Global Waste Heat to Power Sale Price by Players
3.4 Global Waste Heat to Power Manufacturing Base Distribution, Sales Area, Product Types by Players
3.4.1 Global Waste Heat to Power Manufacturing Base Distribution and Sales Area by Players
3.4.2 Players Waste Heat to Power Products Offered
3.5 Market Concentration Rate Analysis
3.5.1 Competition Landscape Analysis
3.5.2 Concentration Ratio (CR3, CR5 and CR10) (2017-2019)
3.6 New Products and Potential Entrants
3.7 Mergers & Acquisitions, Expansion
4 Waste Heat to Power by Regions
4.1 Waste Heat to Power by Regions
4.1.1 Global Waste Heat to Power Consumption by Regions
4.1.2 Global Waste Heat to Power Value by Regions
4.2 Americas Waste Heat to Power Consumption Growth
4.3 APAC Waste Heat to Power Consumption Growth
4.4 Europe Waste Heat to Power Consumption Growth
4.5 Middle East & Africa Waste Heat to Power Consumption Growth
5 Americas
5.1 Americas Waste Heat to Power Consumption by Countries
5.1.1 Americas Waste Heat to Power Consumption by Countries (2014-2019)
5.1.2 Americas Waste Heat to Power Value by Countries (2014-2019)
5.2 Americas Waste Heat to Power Consumption by Type
5.3 Americas Waste Heat to Power Consumption by Application
5.4 United States
5.5 Canada
5.6 Mexico
5.7 Key Economic Indicators of Few Americas Countries
6 APAC
6.1 APAC Waste Heat to Power Consumption by Countries
6.1.1 APAC Waste Heat to Power Consumption by Countries (2014-2019)
6.1.2 APAC Waste Heat to Power Value by Countries (2014-2019)
6.2 APAC Waste Heat to Power Consumption by Type
6.3 APAC Waste Heat to Power Consumption by Application
6.4 China
6.5 Japan
6.6 Korea
6.7 Southeast Asia
6.8 India
6.9 Australia
6.10 Key Economic Indicators of Few APAC Countries
7 Europe
7.1 Europe Waste Heat to Power by Countries
7.1.1 Europe Waste Heat to Power Consumption by Countries (2014-2019)
7.1.2 Europe Waste Heat to Power Value by Countries (2014-2019)
7.2 Europe Waste Heat to Power Consumption by Type
7.3 Europe Waste Heat to Power Consumption by Application
7.4 Germany
7.5 France
7.6 UK
7.7 Italy
7.8 Russia
7.9 Spain
7.10 Key Economic Indicators of Few Europe Countries
8 Middle East & Africa
8.1 Middle East & Africa Waste Heat to Power by Countries
8.1.1 Middle East & Africa Waste Heat to Power Consumption by Countries (2014-2019)
8.1.2 Middle East & Africa Waste Heat to Power Value by Countries (2014-2019)
8.2 Middle East & Africa Waste Heat to Power Consumption by Type
8.3 Middle East & Africa Waste Heat to Power Consumption by Application
8.4 Egypt
8.5 South Africa
8.6 Israel
8.7 Turkey
8.8 GCC Countries
9 Market Drivers, Challenges and Trends
9.1 Market Drivers and Impact
9.1.1 Growing Demand from Key Regions
9.1.2 Growing Demand from Key Applications and Potential Industries
9.2 Market Challenges and Impact
9.3 Market Trends
10 Marketing, Distributors and Customer
10.1 Sales Channel
10.1.1 Direct Channels
10.1.2 Indirect Channels
10.2 Waste Heat to Power Distributors
10.3 Waste Heat to Power Customer
11 Global Waste Heat to Power Market Forecast
11.1 Global Waste Heat to Power Consumption Forecast (2019-2024)
11.2 Global Waste Heat to Power Forecast by Regions
11.2.1 Global Waste Heat to Power Forecast by Regions (2019-2024)
11.2.2 Global Waste Heat to Power Value Forecast by Regions (2019-2024)
11.2.3 Americas Consumption Forecast
11.2.4 APAC Consumption Forecast
11.2.5 Europe Consumption Forecast
11.2.6 Middle East & Africa Consumption Forecast
11.3 Americas Forecast by Countries
11.3.1 United States Market Forecast
11.3.2 Canada Market Forecast
11.3.3 Mexico Market Forecast
11.3.4 Brazil Market Forecast
11.4 APAC Forecast by Countries
11.4.1 China Market Forecast
11.4.2 Japan Market Forecast
11.4.3 Korea Market Forecast
11.4.4 Southeast Asia Market Forecast
11.4.5 India Market Forecast
11.4.6 Australia Market Forecast
11.5 Europe Forecast by Countries
11.5.1 Germany Market Forecast
11.5.2 France Market Forecast
11.5.3 UK Market Forecast
11.5.4 Italy Market Forecast
11.5.5 Russia Market Forecast
11.5.6 Spain Market Forecast
11.6 Middle East & Africa Forecast by Countries
11.6.1 Egypt Market Forecast
11.6.2 South Africa Market Forecast
11.6.3 Israel Market Forecast
11.6.4 Turkey Market Forecast
11.6.5 GCC Countries Market Forecast
11.7 Global Waste Heat to Power Forecast by Type
11.8 Global Waste Heat to Power Forecast by Application
12 Key Players Analysis
12.1 Siemens
12.1.1 Company Details
12.1.2 Waste Heat to Power Product Offered
12.1.3 Siemens Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.1.4 Main Business Overview
12.1.5 Siemens News
12.2 GE
12.2.1 Company Details
12.2.2 Waste Heat to Power Product Offered
12.2.3 GE Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.2.4 Main Business Overview
12.2.5 GE News
12.3 ABB
12.3.1 Company Details
12.3.2 Waste Heat to Power Product Offered
12.3.3 ABB Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.3.4 Main Business Overview
12.3.5 ABB News
12.4 Amec Foster Wheeler
12.4.1 Company Details
12.4.2 Waste Heat to Power Product Offered
12.4.3 Amec Foster Wheeler Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.4.4 Main Business Overview
12.4.5 Amec Foster Wheeler News
12.5 Ormat
12.5.1 Company Details
12.5.2 Waste Heat to Power Product Offered
12.5.3 Ormat Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.5.4 Main Business Overview
12.5.5 Ormat News
12.6 MHI
12.6.1 Company Details
12.6.2 Waste Heat to Power Product Offered
12.6.3 MHI Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.6.4 Main Business Overview
12.6.5 MHI News
12.7 Exergy
12.7.1 Company Details
12.7.2 Waste Heat to Power Product Offered
12.7.3 Exergy Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.7.4 Main Business Overview
12.7.5 Exergy News
12.8 ElectraTherm
12.8.1 Company Details
12.8.2 Waste Heat to Power Product Offered
12.8.3 ElectraTherm Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.8.4 Main Business Overview
12.8.5 ElectraTherm News
12.9 Dürr Cyplan
12.9.1 Company Details
12.9.2 Waste Heat to Power Product Offered
12.9.3 Dürr Cyplan Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.9.4 Main Business Overview
12.9.5 Dürr Cyplan News
12.10 GETEC
12.10.1 Company Details
12.10.2 Waste Heat to Power Product Offered
12.10.3 GETEC Waste Heat to Power Sales, Revenue, Price and Gross Margin (2017-2019)
12.10.4 Main Business Overview
12.10.5 GETEC News
12.11 CNBM
12.12 DaLian East
12.13 E-Rational
13 Research Findings and Conclusion
List of Tables and Figures
Figure Picture of Waste Heat to Power
Table Product Specifications of Waste Heat to Power
Figure Waste Heat to Power Report Years Considered
Fi
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