Global Waste Heat to Power Market Size 2021, Revenues, Business Overview, Growth Rate, SWOT Analysis, Impact of COVID-19 on Global Industry and Recovery

Waste Heat to Power Market is valued at USD 14.4 Billion in 2018 and expected to reach USD 32.7 Billion by 2025 with a CAGR of 12.43% over the forecast period. Increasing concern regarding global warming and government regulations are the key driving factors for the growth of global waste heat to power market.

Waste Heat to Power Market – Key highlights of the report

Product sales patterns

Profit returns amassed by each product segment

Consumption rate of all the products

Market share held by each product type

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Waste Heat to Power Market report published by the AI Market Report provides the detail information about Waste Heat to Power Market from various aspects. This report consists of drivers, challenges and opportunities which help the market to grow over the analysis period and recent trends which supports the growth of market. This report consists of regional segmentation with product type and applications.

Waste heat is the energy that is produced in industrial processes which is not put into any practical useand is wasted and dumped into the atmosphere. Sources of waste heat mostly include heat loss transferred through conduction, convection and radiation from industrial products, equipment and processes and heat discharged from combustion processes. Waste heat loss can be classified into high temperature, medium temperature and low temperature grades. Waste heat to power systems are introduced for each range of wasteheat to allow the most optimum efficiency of waste heat recovery to be obtained. Recovering the waste heat i.e. waste heat to power can be conducted through various waste heat recovery technologies to provide valuable energy sources and reduce the overall energy consumption.

Increasing concern regarding global warming with the task of reducing greenhouse gas emissions and improving the efficiency of their sites are the major driving factors for waste heat to power market growth. The use of waste heat to power systems in industrial processes has been as one of the major areas of research to reduce fuel consumption, improve production efficiency and lower harmful emissions. Stringent energy policies of governments regarding the carbon dioxide emission from the waste heat is also driving the growth of waste heat to power market. New technological advancements by the WHP system suppliers is another important driver for the waste heat to power market expansion globally. There is a general lack of end-user awareness of waste heat to power technologies and benefits is major restraining factor for the growth of the waste heat to power market. Developing economic and environmental drivers are creating new opportunities to evaluate waste heat to power market in the forecast period.

Key Players for Waste Heat to Power Market Report to

Key Players of waste heat to power market are Siemens, GE, ABB, AMEC Foster Wheeler, Ormat, MHI, Exergy, ElectraTherm, Dürr Cyplan, GETEC, CNBM, DaLian Eastand others.

Waste Heat to Power Market Segmentation to

By Type:

Steam Rankine Cycle
Organic Rankine Cycles
Kalina Cycle

By Application:

Chemical Industry
Metal Manufacturing
Oil and Gas
Others
By Region:

North America
U.S.
Canada
Europe
UK.
France
Germany
Italy
Asia Pacific
China
Japan
India
Southeast Asia
Latin America
Brazil
Mexico
Middle East and Africa
GCC
Africa
Rest of Middle East and Africa

 

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Table of Content
1 Study Coverage
1.1 Waste Heat to Power Product
1.2 Key Market Segments in This Study
1.3 Key Manufacturers Covered
1.4 Market by Type
1.5 Market by Application
1.6 Study Objectives
1.7 Years Considered

2 Executive Summary
2.1 Global Waste Heat to Power Market Size
2.1.1 Global Waste Heat to Power Revenue 2014-2025
2.1.2 Global Waste Heat to Power Production 2014-2025
2.2 Waste Heat to Power Growth Rate (CAGR) 2020-2025
2.3 Analysis of Competitive Landscape
2.3.1 Manufacturers Market Concentration Ratio
2.3.2 Key Waste Heat to Power Manufacturers
2.3.2.1 Waste Heat to Power Manufacturing Base Distribution, Headquarters
2.3.2.2 Manufacturers Waste Heat to Power Product Offered
2.3.2.3 Date of Manufacturers Enter into Waste Heat to Power Market
2.4 Key Trends for Waste Heat to Power Markets & Products

3 Market Size by Manufacturers
3.1 Waste Heat to Power Production by Manufacturers
3.1.1 Waste Heat to Power Production by Manufacturers
3.1.2 Waste Heat to Power Production Market Share by Manufacturers
3.2 Waste Heat to Power Revenue by Manufacturers
3.2.1 Waste Heat to Power Revenue by Manufacturers (2014-2020)
3.2.2 Waste Heat to Power Revenue Share by Manufacturers (2014-2020)
3.3 Waste Heat to Power Price by Manufacturers
3.4 Mergers & Acquisitions, Expansion Plans

4 Waste Heat to Power Production by Regions
4.1 Global Waste Heat to Power Production by Regions
4.1.1 Global Waste Heat to Power Production Market Share by Regions
4.1.2 Global Waste Heat to Power Revenue Market Share by Regions
4.2 North America
4.2.1 North America Waste Heat to Power Production
4.2.2 North America Waste Heat to Power Revenue
4.2.3 Key Players in North America
4.2.4 North America Waste Heat to Power Import & Export
4.3 Europe
4.3.1 Europe Waste Heat to Power Production
4.3.2 Europe Waste Heat to Power Revenue
4.3.3 Key Players in Europe
4.3.4 Europe Waste Heat to Power Import & Export
4.4 China
4.4.1 China Waste Heat to Power Production
4.4.2 China Waste Heat to Power Revenue
4.4.3 Key Players in China
4.4.4 China Waste Heat to Power Import & Export
4.5 Japan
4.5.1 Japan Waste Heat to Power Production
4.5.2 Japan Waste Heat to Power Revenue
4.5.3 Key Players in Japan
4.5.4 Japan Waste Heat to Power Import & Export

5 Waste Heat to Power Consumption by Regions
5.1 Global Waste Heat to Power Consumption by Regions
5.1.1 Global Waste Heat to Power Consumption by Regions
5.1.2 Global Waste Heat to Power Consumption Market Share by Regions
5.2 North America
5.2.1 North America Waste Heat to Power Consumption by Application
5.2.2 North America Waste Heat to Power Consumption by Countries
5.2.3 United States
5.2.4 Canada
5.2.5 Mexico
5.3 Europe
5.3.1 Europe Waste Heat to Power Consumption by Application
5.3.2 Europe Waste Heat to Power 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 Heat to Power Consumption by Application
5.4.2 Asia Pacific Waste Heat to Power Consumption by Regions
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 Heat to Power Consumption by Application
5.5.2 Central & South America Waste Heat to Power Consumption by Country
5.5.3 Brazil
5.6 Middle East and Africa
5.6.1 Middle East and Africa Waste Heat to Power Consumption by Application
5.6.2 Middle East and Africa Waste Heat to Power Consumption by Countries
5.6.3 Turkey
5.6.4 GCC Countries
5.6.5 Egypt
5.6.6 South Africa

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