Waste Heat to Power (WHP) is the process of recovering waste heat and using it to generate power with no combustion and no emissions. WHP systems use the same technologies deployed in a number of industries, including the geothermal industry. Anywhere there is an industrial process that involves transforming raw materials into useful products - steel mills, paper plants, refineries, chemical plants, oil and gas pipelines, and general manufacturing - heat is wasted as a byproduct. This waste heat is produced whenever the operation is running, often 24 hours a day, seven days a week, 365 days a year. If not recovered for reuse as lower temperature process heat or to produce emission-free power, the heat will dissipate into the atmosphere, a wasted opportunity.
The Waste Heat to Power market revenue was xx.xx Million USD in 2019, and will reach xx.xx Million USD in 2025, with a CAGR of x.x% during 2020-2025.
Under COVID-19 outbreak globally, this report provides 360 degrees of analysis from supply chain, import and export control to regional government policy and future influence on the industry. Detailed analysis about market status (2015-2020), enterprise competition pattern, advantages and disadvantages of enterprise products, industry development trends (2020-2025), regional industrial layout characteristics and macroeconomic policies, industrial policy has also been included. From raw materials to end users of this industry are analyzed scientifically, the trends of product circulation and sales channel will be presented as well. Considering COVID-19, this report provides comprehensive and in-depth analysis on how the epidemic push this industry transformation and reform.
In COVID-19 outbreak, Chapter 2.2 of this report provides an analysis of the impact of COVID-19 on the global economy and the Waste Heat to Power industry.
Chapter 3.7 covers the analysis of the impact of COVID-19 from the perspective of the industry chain.
In addition, chapters 7-11 consider the impact of COVID-19 on the regional economy.
The Waste Heat to Power market can be split based on product types, major applications, and important countries as follows:
Key players in the global Waste Heat to Power market covered in Chapter 12:
Siemens
Echogen
Ormat
Thermax
Mitsubishi
AQYLON
Kalina power
Amec Foster Wheeler
Enogia SAS
Cyplan
ABB
ElectraTherm
Triogen
In Chapter 4 and 14.1, on the basis of types, the Waste Heat to Power market from 2015 to 2025 is primarily split into:
Steam Rankine Cycle
Organic Rankine Cycle
Kalina Cycle
In Chapter 5 and 14.2, on the basis of applications, the Waste Heat to Power market from 2015 to 2025 covers:
Petroleum Refining
Cement
Heavy Metal
Chemical
Paper
Food & Beverage
Glass
Geographically, the detailed analysis of consumption, revenue, market share and growth rate, historic and forecast (2015-2025) of the following regions are covered in Chapter 6, 7, 8, 9, 10, 11, 14:
North America (Covered in Chapter 7 and 14)
United States
Canada
Mexico
Europe (Covered in Chapter 8 and 14)
Germany
UK
France
Italy
Spain
Russia
Others
Asia-Pacific (Covered in Chapter 9 and 14)
China
Japan
South Korea
Australia
India
Southeast Asia
Others
Middle East and Africa (Covered in Chapter 10 and 14)
Saudi Arabia
UAE
Egypt
Nigeria
South Africa
Others
South America (Covered in Chapter 11 and 14)
Brazil
Argentina
Columbia
Chile
Others
Years considered for this report:
Historical Years: 2015-2019
Base Year: 2019
Estimated Year: 2020
Forecast Period: 2020-2025
Table of Content
1 Waste Heat to Power Introduction and Market Overview
1.1 Objectives of the Study
1.2 Overview of Waste Heat to Power
1.3 Scope of The Study
1.3.1 Key Market Segments
1.3.2 Players Covered
1.3.3 COVID-19's impact on the Waste Heat to Power industry
1.4 Methodology of The Study
1.5 Research Data Source
2 Executive Summary
2.1 Market Overview
2.1.1 Global Waste Heat to Power Market Size, 2015 - 2020
2.1.2 Global Waste Heat to Power Market Size by Type, 2015 - 2020
2.1.3 Global Waste Heat to Power Market Size by Application, 2015 - 2020
2.1.4 Global Waste Heat to Power Market Size by Region, 2015 - 2025
2.2 Business Environment Analysis
2.2.1 Global COVID-19 Status and Economic Overview
2.2.2 Influence of COVID-19 Outbreak on Waste Heat to Power Industry Development
3 Industry Chain Analysis
3.1 Upstream Raw Material Suppliers of Waste Heat to Power Analysis
3.2 Major Players of Waste Heat to Power
3.3 Waste Heat to Power Manufacturing Cost Structure Analysis
3.3.1 Production Process Analysis
3.3.2 Manufacturing Cost Structure of Waste Heat to Power
3.3.3 Labor Cost of Waste Heat to Power
3.4 Market Distributors of Waste Heat to Power
3.5 Major Downstream Buyers of Waste Heat to Power Analysis
3.6 The Impact of Covid-19 From the Perspective of Industry Chain
3.7 Regional Import and Export Controls Will Exist for a Long Time
3.8 Continued downward PMI Spreads Globally
4 Global Waste Heat to Power Market, by Type
4.1 Global Waste Heat to Power Value and Market Share by Type (2015-2020)
4.2 Global Waste Heat to Power Production and Market Share by Type (2015-2020)
4.3 Global Waste Heat to Power Value and Growth Rate by Type (2015-2020)
4.3.1 Global Waste Heat to Power Value and Growth Rate of Steam Rankine Cycle
4.3.2 Global Waste Heat to Power Value and Growth Rate of Organic Rankine Cycle
4.3.3 Global Waste Heat to Power Value and Growth Rate of Kalina Cycle
4.4 Global Waste Heat to Power Price Analysis by Type (2015-2020)
5 Waste Heat to Power Market, by Application
5.1 Downstream Market Overview
5.2 Global Waste Heat to Power Consumption and Market Share by Application (2015-2020)
5.3 Global Waste Heat to Power Consumption and Growth Rate by Application (2015-2020)
5.3.1 Global Waste Heat to Power Consumption and Growth Rate of Petroleum Refining (2015-2020)
5.3.2 Global Waste Heat to Power Consumption and Growth Rate of Cement (2015-2020)
5.3.3 Global Waste Heat to Power Consumption and Growth Rate of Heavy Metal (2015-2020)
5.3.4 Global Waste Heat to Power Consumption and Growth Rate of Chemical (2015-2020)
5.3.5 Global Waste Heat to Power Consumption and Growth Rate of Paper (2015-2020)
5.3.6 Global Waste Heat to Power Consumption and Growth Rate of Food & Beverage (2015-2020)
5.3.7 Global Waste Heat to Power Consumption and Growth Rate of Glass (2015-2020)
6 Global Waste Heat to Power Market Analysis by Regions
6.1 Global Waste Heat to Power Sales, Revenue and Market Share by Regions
6.1.1 Global Waste Heat to Power Sales by Regions (2015-2020)
6.1.2 Global Waste Heat to Power Revenue by Regions (2015-2020)
6.2 North America Waste Heat to Power Sales and Growth Rate (2015-2020)
6.3 Europe Waste Heat to Power Sales and Growth Rate (2015-2020)
6.4 Asia-Pacific Waste Heat to Power Sales and Growth Rate (2015-2020)
6.5 Middle East and Africa Waste Heat to Power Sales and Growth Rate (2015-2020)
6.6 South America Waste Heat to Power Sales and Growth Rate (2015-2020)
7 North America Waste Heat to Power Market Analysis by Countries
7.1 The Influence of COVID-19 on North America Market
7.2 North America Waste Heat to Power Sales, Revenue and Market Share by Countries
7.2.1 North America Waste Heat to Power Sales by Countries (2015-2020)
7.2.2 North America Waste Heat to Power Revenue by Countries (2015-2020)
7.3 United States Waste Heat to Power Sales and Growth Rate (2015-2020)
7.4 Canada Waste Heat to Power Sales and Growth Rate (2015-2020)
7.5 Mexico Waste Heat to Power Sales and Growth Rate (2015-2020)
8 Europe Waste Heat to Power Market Analysis by Countries
8.1 The Influence of COVID-19 on Europe Market
8.2 Europe Waste Heat to Power Sales, Revenue and Market Share by Countries
8.2.1 Europe Waste Heat to Power Sales by Countries (2015-2020)
8.2.2 Europe Waste Heat to Power Revenue by Countries (2015-2020)
8.3 Germany Waste Heat to Power Sales and Growth Rate (2015-2020)
8.4 UK Waste Heat to Power Sales and Growth Rate (2015-2020)
8.5 France Waste Heat to Power Sales and Growth Rate (2015-2020)
8.6 Italy Waste Heat to Power Sales and Growth Rate (2015-2020)
8.7 Spain Waste Heat to Power Sales and Growth Rate (2015-2020)
8.8 Russia Waste Heat to Power Sales and Growth Rate (2015-2020)
9 Asia Pacific Waste Heat to Power Market Analysis by Countries
9.1 The Influence of COVID-19 on Asia Pacific Market
9.2 Asia Pacific Waste Heat to Power Sales, Revenue and Market Share by Countries
9.2.1 Asia Pacific Waste Heat to Power Sales by Countries (2015-2020)
9.2.2 Asia Pacific Waste Heat to Power Revenue by Countries (2015-2020)
9.3 China Waste Heat to Power Sales and Growth Rate (2015-2020)
9.4 Japan Waste Heat to Power Sales and Growth Rate (2015-2020)
9.5 South Korea Waste Heat to Power Sales and Growth Rate (2015-2020)
9.6 India Waste Heat to Power Sales and Growth Rate (2015-2020)
9.7 Southeast Asia Waste Heat to Power Sales and Growth Rate (2015-2020)
9.8 Australia Waste Heat to Power Sales and Growth Rate (2015-2020)
10 Middle East and Africa Waste Heat to Power Market Analysis by Countries
10.1 The Influence of COVID-19 on Middle East and Africa Market
10.2 Middle East and Africa Waste Heat to Power Sales, Revenue and Market Share by Countries
10.2.1 Middle East and Africa Waste Heat to Power Sales by Countries (2015-2020)
10.2.2 Middle East and Africa Waste Heat to Power Revenue by Countries (2015-2020)
10.3 Saudi Arabia Waste Heat to Power Sales and Growth Rate (2015-2020)
10.4 UAE Waste Heat to Power Sales and Growth Rate (2015-2020)
10.5 Egypt Waste Heat to Power Sales and Growth Rate (2015-2020)
10.6 Nigeria Waste Heat to Power Sales and Growth Rate (2015-2020)
10.7 South Africa Waste Heat to Power Sales and Growth Rate (2015-2020)
11 South America Waste Heat to Power Market Analysis by Countries
11.1 The Influence of COVID-19 on Middle East and Africa Market
11.2 South America Waste Heat to Power Sales, Revenue and Market Share by Countries
11.2.1 South America Waste Heat to Power Sales by Countries (2015-2020)
11.2.2 South America Waste Heat to Power Revenue by Countries (2015-2020)
11.3 Brazil Waste Heat to Power Sales and Growth Rate (2015-2020)
11.4 Argentina Waste Heat to Power Sales and Growth Rate (2015-2020)
11.5 Columbia Waste Heat to Power Sales and Growth Rate (2015-2020)
11.6 Chile Waste Heat to Power Sales and Growth Rate (2015-2020)
12 Competitive Landscape
12.1 Siemens
12.1.1 Siemens Basic Information
12.1.2 Waste Heat to Power Product Introduction
12.1.3 Siemens Production, Value, Price, Gross Margin 2015-2020
12.2 Echogen
12.2.1 Echogen Basic Information
12.2.2 Waste Heat to Power Product Introduction
12.2.3 Echogen Production, Value, Price, Gross Margin 2015-2020
12.3 Ormat
12.3.1 Ormat Basic Information
12.3.2 Waste Heat to Power Product Introduction
12.3.3 Ormat Production, Value, Price, Gross Margin 2015-2020
12.4 Thermax
12.4.1 Thermax Basic Information
12.4.2 Waste Heat to Power Product Introduction
12.4.3 Thermax Production, Value, Price, Gross Margin 2015-2020
12.5 Mitsubishi
12.5.1 Mitsubishi Basic Information
12.5.2 Waste Heat to Power Product Introduction
12.5.3 Mitsubishi Production, Value, Price, Gross Margin 2015-2020
12.6 AQYLON
12.6.1 AQYLON Basic Information
12.6.2 Waste Heat to Power Product Introduction
12.6.3 AQYLON Production, Value, Price, Gross Margin 2015-2020
12.7 Kalina power
12.7.1 Kalina power Basic Information
12.7.2 Waste Heat to Power Product Introduction
12.7.3 Kalina power Production, Value, Price, Gross Margin 2015-2020
12.8 Amec Foster Wheeler
12.8.1 Amec Foster Wheeler Basic Information
12.8.2 Waste Heat to Power Product Introduction
12.8.3 Amec Foster Wheeler Production, Value, Price, Gross Margin 2015-2020
12.9 Enogia SAS
12.9.1 Enogia SAS Basic Information
12.9.2 Waste Heat to Power Product Introduction
12.9.3 Enogia SAS Production, Value, Price, Gross Margin 2015-2020
12.10 Cyplan
12.10.1 Cyplan Basic Information
12.10.2 Waste Heat to Power Product Introduction
12.10.3 Cyplan Production, Value, Price, Gross Margin 2015-2020
12.11 ABB
12.11.1 ABB Basic Information
12.11.2 Waste Heat to Power Product Introduction
12.11.3 ABB Production, Value, Price, Gross Margin 2015-2020
12.12 ElectraTherm
12.12.1 ElectraTherm Basic Information
12.12.2 Waste Heat to Power Product Introduction
12.12.3 ElectraTherm Production, Value, Price, Gross Margin 2015-2020
12.13 Triogen
12.13.1 Triogen Basic Information
12.13.2 Waste Heat to Power Product Introduction
12.13.3 Triogen Production, Value, Price, Gross Margin 2015-2020
13 Industry Outlook
13.1 Market Driver Analysis
13.1.2 Market Restraints Analysis
13.1.3 Market Trends Analysis
13.2 Merger, Acquisition and New Investment
13.3 News of Product Release
14 Global Waste Heat to Power Market Forecast
14.1 Global Waste Heat to Power Market Value & Volume Forecast, by Type (2020-2025)
14.1.1 Steam Rankine Cycle Market Value and Volume Forecast (2020-2025)
14.1.2 Organic Rankine Cycle Market Value and Volume Forecast (2020-2025)
14.1.3 Kalina Cycle Market Value and Volume Forecast (2020-2025)
14.2 Global Waste Heat to Power Market Value & Volume Forecast, by Application (2020-2025)
14.2.1 Petroleum Refining Market Value and Volume Forecast (2020-2025)
14.2.2 Cement Market Value and Volume Forecast (2020-2025)
14.2.3 Heavy Metal Market Value and Volume Forecast (2020-2025)
14.2.4 Chemical Market Value and Volume Forecast (2020-2025)
14.2.5 Paper Market Value and Volume Forecast (2020-2025)
14.2.6 Food & Beverage Market Value and Volume Forecast (2020-2025)
14.2.7 Glass Market Value and Volume Forecast (2020-2025)
14.3 Waste Heat to Power Market Analysis and Forecast by Region
14.3.1 North America Market Value and Consumption Forecast (2020-2025)
14.3.2 Europe Market Value and Consumption Forecast (2020-2025)
14.3.3 Asia Pacific Market Value and Consumption Forecast (2020-2025)
14.3.4 Middle East and Africa Market Value and Consumption Forecast (2020-2025)
14.3.5 South America Market Value and Consumption Forecast (2020-2025)
15 New Project Feasibility Analysis
15.1 Industry Barriers and New Entrants SWOT Analysis
15.1.1 Porter
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