廃熱発電（WHP）の世界市場レポート2025年

廃熱発電（WHP）市場規模は、今後数年で急成長が見込まれます。2029年には322億8,000万米ドルに成長し、CAGRは11.9％となります。予測期間の成長は、電力需要の増加、政府のイニシアティブ、投資の増加に起因しています。予測期間の主な動向には、パートナーシップとコラボレーション、廃棄物電力回収のための鉛フリー材料の開発、熱電材料を使用した直接廃棄物回収の出現、製品の革新などがあります。

今後5年間の成長率11.9%という予測は、この市場の前回予測から0.3%の小幅な減少を反映しています。この減少は主に米国と他国との間の関税の影響によるものです。特に欧州と日本から輸入される高効率タービンと熱交換器に対する関税の実施は、米国における廃熱発電（WHP）システムの開発を妨げ、資本支出を増加させ、産業回収プロジェクトの財政的実行可能性を低下させる可能性があります。また、相互関税や、貿易緊張の高まりと制限による世界経済と貿易への悪影響により、その影響はより広範囲に及ぶと思われます。

産業部門の成長は、今後数年間、電力市場における廃熱を大幅に押し上げると予想されます。産業成長に影響を与える主な要因には、資本投資、労働投入、金融投資、技術革新などがあります。特に、非金属鉱物生産、石油精製、重金属生産などのセクターは、廃熱回収の大きな機会を提供しています。例えば、2023年12月、米国の政府機関である国立標準技術研究所（NIST）は、2022年の米国のGDPに製造業が2兆3,000億米ドル寄与し、GDP全体の11.4％を占めたと報告しました。さらに、全製造業の生産者物価は2020年7月から2022年7月の間に33.4％上昇しました。このように、産業部門の成長が電力市場における廃熱の拡大を後押ししています。

目次

第1章 エグゼクティブサマリー

第2章 市場の特徴

第3章 市場動向と戦略

第4章 市場：金利、インフレ、地政学、貿易戦争と関税、そしてコロナ禍と回復が市場に与える影響を含むマクロ経済シナリオ

第5章 世界の成長分析と戦略分析フレームワーク

• 世界の廃熱発電（WHP）：PESTEL分析（政治、社会、技術、環境、法的要因、促進要因と抑制要因）
• 最終用途産業の分析
• 世界の廃熱発電（WHP）市場：成長率分析
• 世界の廃熱発電（WHP）市場の実績：規模と成長, 2019-2024
• 世界の廃熱発電（WHP）市場の予測：規模と成長, 2024-2029, 2034F
• 世界の廃熱発電（WHP）：総潜在市場規模（TAM）

第6章 市場セグメンテーション

• 世界の廃熱発電（WHP）市場：製品別、実績と予測, 2019-2024, 2024-2029F, 2034F
• スチームランキンサイクル
• オーガニックランキンサイクル
• カリーナサイクル
• 世界の廃熱発電（WHP）市場：用途別、実績と予測, 2019-2024, 2024-2029F, 2034F
• 予熱
• 蒸気と電力の発電
• その他の用途
• 世界の廃熱発電（WHP）市場：最終用途別、実績と予測, 2019-2024, 2024-2029F, 2034F
• 石油精製
• セメント産業
• 重金属生産
• 化学産業
• パルプと紙
• 食品・飲料
• ガラス産業
• その他のエンドユーザー
• 世界の廃熱発電（WHP）市場、スチームランキンサイクルのサブセグメンテーション、タイプ別、実績と予測, 2019-2024, 2024-2029F, 2034F
• 従来型蒸気ランキンサイクル
• 超臨界蒸気ランキンサイクル
• 世界の廃熱発電（WHP）市場、オーガニックランキンサイクルの種類別サブセグメンテーション、実績と予測, 2019-2024, 2024-2029F, 2034F
• 乾式有機ランキンサイクル
• 湿式有機ランキンサイクル
• 等温有機ランキンサイクル
• 世界の廃熱発電（WHP）市場、カリーナサイクルのサブセグメンテーション（タイプ別）、実績と予測, 2019-2024, 2024-2029F, 2034F
• アンモニア水カリーナサイクル
• エタノール-水カリーナサイクル

第7章 地域別・国別分析

• 世界の廃熱発電（WHP）市場：地域別、実績と予測, 2019-2024, 2024-2029F, 2034F
• 世界の廃熱発電（WHP）市場：国別、実績と予測, 2019-2024, 2024-2029F, 2034F

第8章 アジア太平洋市場

第9章 中国市場

第10章 インド市場

第11章 日本市場

第12章 オーストラリア市場

第13章 インドネシア市場

第14章 韓国市場

第15章 西欧市場

第16章 英国市場

第17章 ドイツ市場

第18章 フランス市場

第19章 イタリア市場

第20章 スペイン市場

第21章 東欧市場

第22章 ロシア市場

第23章 北米市場

第24章 米国市場

第25章 カナダ市場

第26章 南米市場

第27章 ブラジル市場

第28章 中東市場

第29章 アフリカ市場

第30章 競合情勢と企業プロファイル

• 廃熱発電（WHP）市場：競合情勢
• 廃熱発電（WHP）市場：企業プロファイル
  • Mitsubishi Heavy Industries Ltd Overview, Products and Services, Strategy and Financial Analysis
  • Bosch Thermotechnology Overview, Products and Services, Strategy and Financial Analysis
  • Ormat Technologies Overview, Products and Services, Strategy and Financial Analysis
  • IHI Corporation Overview, Products and Services, Strategy and Financial Analysis
  • Durr Group Overview, Products and Services, Strategy and Financial Analysis

第31章 その他の大手企業と革新的企業

• Thermax Limited
• Exergy SPA
• Siemens Energy
• ElectraTherm
• Enogia SAS
• Shenzhen Energy Group
• Kawasaki Heavy Industries Ltd
• Siemens AG
• Orcan Energy
• Vital Energi
• EDF Energy
• E. ON Next
• ScottishPower
• Shell Energy
• Hitachi Zosen Inova（HZI）

第32章 世界の市場競合ベンチマーキングとダッシュボード

第33章 主要な合併と買収

第34章 最近の市場動向

第35章 市場の潜在力が高い国、セグメント、戦略

• 廃熱発電（WHP）市場2029：新たな機会を提供する国
• 廃熱発電（WHP）市場2029：新たな機会を提供するセグメント
• 廃熱発電（WHP）市場2029：成長戦略
  • 市場動向に基づく戦略
  • 競合の戦略

第36章 付録

Waste heat to power refers to the process of harnessing heat discarded by an existing thermal process to generate electricity, thereby reducing pollution, equipment size, and auxiliary energy consumption.

The primary methods in waste heat to power are the steam Rankine cycle, the organic Rankine cycle, and the Kalina cycle. The steam Rankine cycle is a simplified thermodynamic process where heat converts into mechanical work within a constant-pressure heat engine. This cycle typically employs water (in liquid and vapor phases) as its working fluid. Applications of waste heat to power include preheating, steam and electricity generation, among others, across various industries such as petroleum refining, oil and gas extraction, cement, heavy metal production, chemicals, pulp and paper, food and beverage, glass manufacturing, and more.

Note that the outlook for this market is being affected by rapid changes in trade relations and tariffs globally. The report will be updated prior to delivery to reflect the latest status, including revised forecasts and quantified impact analysis. The report's Recommendations and Conclusions sections will be updated to give strategies for entities dealing with the fast-moving international environment.

The sharp rise in U.S. tariffs and the ensuing trade tensions in spring 2025 are having a notable impact on the utilities sector, particularly across power generation, grid modernization, and renewable energy initiatives. Increased duties on imported equipment such as turbines, transformers, solar panels, and battery storage systems are driving up both capital and operational expenses for utility companies, prompting many to delay projects or pass higher costs on to consumers through increased energy rates. The water and waste management sectors are similarly affected, as tariffs inflate the cost of essential machinery, piping, and treatment technologies. Moreover, retaliatory tariffs from key trading partners have disrupted the supply of critical raw materials-such as rare earth elements vital for clean energy technologies-posing further challenges to the shift toward sustainable energy. In response, the sector is increasingly focusing on domestic procurement, digital transformation, and efficiency-enhancing innovations to control rising costs while safeguarding energy reliability and meeting regulatory demands.

The waste heat to power market research report is one of a series of new reports from The Business Research Company that provides waste heat to power market statistics, including waste heat to power industry global market size, regional shares, competitors with a waste heat to power market share, detailed waste heat to power market segments, market trends and opportunities, and any further data you may need to thrive in the waste heat to the power industry. This waste heat to power market research report delivers a complete perspective of everything you need, with an in-depth analysis of the current and future scenario of the industry.

The waste heat to power market size has grown rapidly in recent years. It will grow from $18.58 billion in 2024 to $20.61 billion in 2025 at a compound annual growth rate (CAGR) of 10.9%. The growth in the historic period can be attributed to increasing demand for clean energy, strong economic growth in emerging markets and growth in industrial sector.

The waste heat to power market size is expected to see rapid growth in the next few years. It will grow to $32.28 billion in 2029 at a compound annual growth rate (CAGR) of 11.9%. The growth in the forecast period can be attributed to rising electricity demand, government initiatives and increasing investments. Major trends in the forecast period include partnership & collaboration, development of lead-free materials for waste power recovery, emergence of direct waste recovery using thermoelectric materials and product innovation.

The forecast of 11.9% growth over the next five years reflects a modest reduction of 0.3% from the previous estimate for this market. This reduction is primarily due to the impact of tariffs between the US and other countries. The enforcement of tariffs on imported high-efficiency turbines and heat exchangers especially from Europe and Japan may hinder the development of waste heat to power systems in the U.S., increasing capital expenditure and reducing the financial viability of industrial recovery projects. The effect will also be felt more widely due to reciprocal tariffs and the negative effect on the global economy and trade due to increased trade tensions and restrictions.

The growth of the industrial sector is expected to significantly boost the waste heat in the power market in the coming years. Key factors influencing industrial growth include capital investment, labor input, financial investment, and technological innovation. Notably, sectors such as non-metallic mineral production, petroleum refining, and heavy metal production present substantial opportunities for waste heat recovery. For example, in December 2023, the National Institute of Standards and Technology (NIST), a US-based government agency, reported that manufacturing contributed $2.3 trillion to the U.S. GDP in 2022, representing 11.4% of the total GDP. Additionally, producer prices for all manufacturing increased by 33.4% between July 2020 and July 2022. Thus, the growth in the industrial sector is driving the expansion of waste heat in the power market.

Government initiatives aimed at maximizing energy efficiency are poised to be key drivers for the waste heat to power market. Notably, government actions focusing on the management of waste heat in industries such as oil, gas, and cement are expected to have a positive impact on the market. An illustrative example is the announcement made by the government of India in January 2022. India has outlined ambitious targets, aiming to achieve net-zero emissions by 2070 and secure 50% of its electricity needs from renewable sources by 2030. This commitment reflects a novel approach to economic growth, sidestepping carbon-intensive strategies and potentially serving as a model for other emerging markets. The backing of government initiatives is expected to provide robust support for the waste heat to power market in the future.

Major companies in the waste-to-heat market are focusing on innovative pilot projects to develop and demonstrate advanced technologies for capturing and converting waste heat into usable energy. These projects aim to capture excess hydrothermal energy and convert it into grid-quality power, aligning with waste heat recovery objectives. For instance, in November 2022, Extract Energy, a Canada-based energy technology company, launched a pilot project in Hamilton, Ontario. This initiative focuses on capturing excess hydrothermal energy from a district heating and cooling plant and converting it into grid-quality power using their innovative Heat Engine, which features a nickel-titanium core. This technology is designed to target waste heat in the range of 70°C to 150°C, addressing the significant global energy loss of approximately 65%.

Partnerships and collaborations are emerging as key trends in the waste heat to power market. Companies in this sector are increasingly joining forces to strengthen their market position. For example, in September 2022, Transitional Energy, a US-based geothermal technology company, partnered with ElectraTherm, Inc., a US-based provider of waste heat recovery solutions, to convert waste heat to power in the oil and gas industry. This collaboration aims to enhance energy efficiency and reduce emissions, promoting more sustainable practices in a sector known for generating substantial waste heat. By leveraging geothermal technology alongside waste heat recovery solutions, this partnership seeks to effectively transform waste heat into usable power within the oil and gas industry.

In May 2022, Yokogawa Electric Corporation, a Japan-based engineering company, acquired Dublix Technology ApS for an undisclosed amount. This acquisition is intended to enhance Yokogawa's portfolio of solutions for waste-to-energy and biomass power plants by integrating Dublix Technology's advanced combustion control and boiler performance optimization technologies. The goal is to improve operational efficiency, reduce environmental impact, and support the increasing demand for sustainable energy generation.

Major companies operating in the waste heat to power market include Mitsubishi Heavy Industries Ltd, Bosch Thermotechnology, Ormat Technologies, IHI Corporation, Durr Group, Thermax Limited, Exergy SPA, Siemens Energy, ElectraTherm, Enogia SAS, Shenzhen Energy Group, Kawasaki Heavy Industries Ltd, Siemens AG, Orcan Energy, Vital Energi, EDF Energy, E. ON Next, ScottishPower, Shell Energy, Hitachi Zosen Inova (HZI), EcoTerra BioGas, CEZ Group, Romelectro, ZiO-Podolsk, Notus Energy, Polish Energy Group

Europe was the largest region in the waste heat to power market in 2024. The regions covered in the waste heat to power market report are Asia-Pacific, Western Europe, Eastern Europe, North America, South America, Middle East, Africa.

The countries covered in the waste heat to power market report are Australia, Brazil, China, France, Germany, India, Indonesia, Japan, Russia, South Korea, UK, USA, Italy, Spain, Canada.

The waste heat to power market includes revenues earned by entities by providing services such as ORC, steam cycle, and cascaded steam-organic cycle. The market value includes the value of related goods sold by the service provider or included within the service offering. Only goods and services traded between entities or sold to end consumers are included.

The market value is defined as the revenues that enterprises gain from the sale of goods and/or services within the specified market and geography through sales, grants, or donations in terms of the currency (in USD unless otherwise specified).

The revenues for a specified geography are consumption values that are revenues generated by organizations in the specified geography within the market, irrespective of where they are produced. It does not include revenues from resales along the supply chain, either further along the supply chain or as part of other products.

Waste Heat to Power Global Market Report 2025 from The Business Research Company provides strategists, marketers and senior management with the critical information they need to assess the market.

This report focuses on waste heat to power market which is experiencing strong growth. The report gives a guide to the trends which will be shaping the market over the next ten years and beyond.

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Where is the largest and fastest growing market for waste heat to power ? How does the market relate to the overall economy, demography and other similar markets? What forces will shape the market going forward, including technological disruption, regulatory shifts, and changing consumer preferences? The waste heat to power market global report from the Business Research Company answers all these questions and many more.

The report covers market characteristics, size and growth, segmentation, regional and country breakdowns, competitive landscape, market shares, trends and strategies for this market. It traces the market's historic and forecast market growth by geography.

• The market characteristics section of the report defines and explains the market.
• The market size section gives the market size ($b) covering both the historic growth of the market, and forecasting its development.
• The forecasts are made after considering the major factors currently impacting the market. These include:

The forecasts are made after considering the major factors currently impacting the market. These include the technological advancements such as AI and automation, Russia-Ukraine war, trade tariffs (government-imposed import/export duties), elevated inflation and interest rates.

• Market segmentations break down the market into sub markets.
• The regional and country breakdowns section gives an analysis of the market in each geography and the size of the market by geography and compares their historic and forecast growth.
• The competitive landscape chapter gives a description of the competitive nature of the market, market shares, and a description of the leading companies. Key financial deals which have shaped the market in recent years are identified.
• The trends and strategies section analyses the shape of the market as it emerges from the crisis and suggests how companies can grow as the market recovers.

Scope

• Markets Covered:1) By Product: Steam Rankine Cycle, Organic Rankine Cycle, Kalina Cycle
• 2) By Application: Preheating, Steam And Electricity Generation, Other Applications
• 3) By End Users: Petroleum Refining And Oil & Gas Extraction, Cement Industry, Heavy Metal Production, Chemical Industry, Pulp And Paper, Food And Beverage, Glass Industry, Other End Users
• Subsegments:
• 1) By Steam Rankine Cycle: Conventional Steam Rankine Cycle; Supercritical Steam Rankine Cycle
• 2) By Organic Rankine Cycle: Dry Organic Rankine Cycle; Wet Organic Rankine Cycle; Isothermal Organic Rankine Cycle
• 3) By Kalina Cycle: Ammonia-Water Kalina Cycle; Ethanol-Water Kalina Cycle
• Companies Mentioned: Mitsubishi Heavy Industries Ltd; Bosch Thermotechnology; Ormat Technologies; IHI Corporation; Durr Group; Thermax Limited; Exergy SPA; Siemens Energy; ElectraTherm; Enogia SAS; Shenzhen Energy Group; Kawasaki Heavy Industries Ltd; Siemens AG; Orcan Energy; Vital Energi; EDF Energy; E. ON Next; ScottishPower; Shell Energy; Hitachi Zosen Inova (HZI); EcoTerra BioGas; CEZ Group; Romelectro; ZiO-Podolsk; Notus Energy; Polish Energy Group
• Countries: Australia; Brazil; China; France; Germany; India; Indonesia; Japan; Russia; South Korea; UK; USA; Canada; Italy; Spain
• Regions: Asia-Pacific; Western Europe; Eastern Europe; North America; South America; Middle East; Africa
• Time Series: Five years historic and ten years forecast.
• Data: Ratios of market size and growth to related markets, GDP proportions, expenditure per capita,
• Data Segmentations: country and regional historic and forecast data, market share of competitors, market segments.
• Sourcing and Referencing: Data and analysis throughout the report is sourced using end notes.
• Delivery Format: PDF, Word and Excel Data Dashboard.

Table of Contents

1. Executive Summary

2. Waste Heat to Power Market Characteristics

3. Waste Heat to Power Market Trends And Strategies

4. Waste Heat to Power Market - Macro Economic Scenario Including The Impact Of Interest Rates, Inflation, Geopolitics, Trade Wars and Tariffs, And Covid And Recovery On The Market

• 4.1. Supply Chain Impact from Tariff War & Trade Protectionism

5. Global Waste Heat to Power Growth Analysis And Strategic Analysis Framework

• 5.1. Global Waste Heat to Power PESTEL Analysis (Political, Social, Technological, Environmental and Legal Factors, Drivers and Restraints)
• 5.2. Analysis Of End Use Industries
• 5.3. Global Waste Heat to Power Market Growth Rate Analysis
• 5.4. Global Waste Heat to Power Historic Market Size and Growth, 2019 - 2024, Value ($ Billion)
• 5.5. Global Waste Heat to Power Forecast Market Size and Growth, 2024 - 2029, 2034F, Value ($ Billion)
• 5.6. Global Waste Heat to Power Total Addressable Market (TAM)

6. Waste Heat to Power Market Segmentation

• 6.1. Global Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• Steam Rankine Cycle
• Organic Rankine Cycle
• Kalina Cycle
• 6.2. Global Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• Preheating
• Steam And Electricity Generation
• Other Applications
• 6.3. Global Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• Petroleum Refining
• Cement Industry
• Heavy Metal Production
• Chemical Industry
• Pulp And Paper
• Food And Beverage
• Glass Industry
• Other End Users
• 6.4. Global Waste Heat to Power Market, Sub-Segmentation Of Steam Rankine Cycle, By Type, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• Conventional Steam Rankine Cycle
• Supercritical Steam Rankine Cycle
• 6.5. Global Waste Heat to Power Market, Sub-Segmentation Of Organic Rankine Cycle, By Type, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• Dry Organic Rankine Cycle
• Wet Organic Rankine Cycle
• Isothermal Organic Rankine Cycle
• 6.6. Global Waste Heat to Power Market, Sub-Segmentation Of Kalina Cycle, By Type, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• Ammonia-Water Kalina Cycle
• Ethanol-Water Kalina Cycle

7. Waste Heat to Power Market Regional And Country Analysis

• 7.1. Global Waste Heat to Power Market, Split By Region, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 7.2. Global Waste Heat to Power Market, Split By Country, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

8. Asia-Pacific Waste Heat to Power Market

• 8.1. Asia-Pacific Waste Heat to Power Market Overview
• Region Information, Market Information, Background Information, Government Initiatives, Regulations, Regulatory Bodies, Major Associations, Taxes Levied, Corporate Tax Structure, Investments, Major Companies
• 8.2. Asia-Pacific Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 8.3. Asia-Pacific Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 8.4. Asia-Pacific Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

9. China Waste Heat to Power Market

• 9.1. China Waste Heat to Power Market Overview
• 9.2. China Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F,$ Billion
• 9.3. China Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F,$ Billion
• 9.4. China Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F,$ Billion

10. India Waste Heat to Power Market

• 10.1. India Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 10.2. India Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 10.3. India Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

11. Japan Waste Heat to Power Market

• 11.1. Japan Waste Heat to Power Market Overview
• 11.2. Japan Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 11.3. Japan Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 11.4. Japan Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

12. Australia Waste Heat to Power Market

• 12.1. Australia Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 12.2. Australia Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 12.3. Australia Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

13. Indonesia Waste Heat to Power Market

• 13.1. Indonesia Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 13.2. Indonesia Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 13.3. Indonesia Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

14. South Korea Waste Heat to Power Market

• 14.1. South Korea Waste Heat to Power Market Overview
• 14.2. South Korea Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 14.3. South Korea Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 14.4. South Korea Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

15. Western Europe Waste Heat to Power Market

• 15.1. Western Europe Waste Heat to Power Market Overview
• 15.2. Western Europe Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 15.3. Western Europe Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 15.4. Western Europe Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

16. UK Waste Heat to Power Market

• 16.1. UK Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 16.2. UK Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 16.3. UK Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

17. Germany Waste Heat to Power Market

• 17.1. Germany Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 17.2. Germany Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 17.3. Germany Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

18. France Waste Heat to Power Market

• 18.1. France Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 18.2. France Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 18.3. France Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

19. Italy Waste Heat to Power Market

• 19.1. Italy Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 19.2. Italy Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 19.3. Italy Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

20. Spain Waste Heat to Power Market

• 20.1. Spain Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 20.2. Spain Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 20.3. Spain Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

21. Eastern Europe Waste Heat to Power Market

• 21.1. Eastern Europe Waste Heat to Power Market Overview
• 21.2. Eastern Europe Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 21.3. Eastern Europe Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 21.4. Eastern Europe Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

22. Russia Waste Heat to Power Market

• 22.1. Russia Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 22.2. Russia Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 22.3. Russia Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

23. North America Waste Heat to Power Market

• 23.1. North America Waste Heat to Power Market Overview
• 23.2. North America Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 23.3. North America Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 23.4. North America Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

24. USA Waste Heat to Power Market

• 24.1. USA Waste Heat to Power Market Overview
• 24.2. USA Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 24.3. USA Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 24.4. USA Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

25. Canada Waste Heat to Power Market

• 25.1. Canada Waste Heat to Power Market Overview
• 25.2. Canada Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 25.3. Canada Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 25.4. Canada Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

26. South America Waste Heat to Power Market

• 26.1. South America Waste Heat to Power Market Overview
• 26.2. South America Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 26.3. South America Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 26.4. South America Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

27. Brazil Waste Heat to Power Market

• 27.1. Brazil Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 27.2. Brazil Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 27.3. Brazil Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

28. Middle East Waste Heat to Power Market

• 28.1. Middle East Waste Heat to Power Market Overview
• 28.2. Middle East Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 28.3. Middle East Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 28.4. Middle East Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

29. Africa Waste Heat to Power Market

• 29.1. Africa Waste Heat to Power Market Overview
• 29.2. Africa Waste Heat to Power Market, Segmentation By Product, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 29.3. Africa Waste Heat to Power Market, Segmentation By Application, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion
• 29.4. Africa Waste Heat to Power Market, Segmentation By End Use, Historic and Forecast, 2019-2024, 2024-2029F, 2034F, $ Billion

30. Waste Heat to Power Market Competitive Landscape And Company Profiles

• 30.1. Waste Heat to Power Market Competitive Landscape
• 30.2. Waste Heat to Power Market Company Profiles
  • 30.2.1. Mitsubishi Heavy Industries Ltd Overview, Products and Services, Strategy and Financial Analysis
  • 30.2.2. Bosch Thermotechnology Overview, Products and Services, Strategy and Financial Analysis
  • 30.2.3. Ormat Technologies Overview, Products and Services, Strategy and Financial Analysis
  • 30.2.4. IHI Corporation Overview, Products and Services, Strategy and Financial Analysis
  • 30.2.5. Durr Group Overview, Products and Services, Strategy and Financial Analysis

31. Waste Heat to Power Market Other Major And Innovative Companies

• 31.1. Thermax Limited
• 31.2. Exergy SPA
• 31.3. Siemens Energy
• 31.4. ElectraTherm
• 31.5. Enogia SAS
• 31.6. Shenzhen Energy Group
• 31.7. Kawasaki Heavy Industries Ltd
• 31.8. Siemens AG
• 31.9. Orcan Energy
• 31.10. Vital Energi
• 31.11. EDF Energy
• 31.12. E. ON Next
• 31.13. ScottishPower
• 31.14. Shell Energy
• 31.15. Hitachi Zosen Inova (HZI)

32. Global Waste Heat to Power Market Competitive Benchmarking And Dashboard

33. Key Mergers And Acquisitions In The Waste Heat to Power Market

34. Recent Developments In The Waste Heat to Power Market

35. Waste Heat to Power Market High Potential Countries, Segments and Strategies

• 35.1 Waste Heat to Power Market In 2029 - Countries Offering Most New Opportunities
• 35.2 Waste Heat to Power Market In 2029 - Segments Offering Most New Opportunities
• 35.3 Waste Heat to Power Market In 2029 - Growth Strategies
  • 35.3.1 Market Trend Based Strategies
  • 35.3.2 Competitor Strategies

36. Appendix

• 36.1. Abbreviations
• 36.2. Currencies
• 36.3. Historic And Forecast Inflation Rates
• 36.4. Research Inquiries
• 36.5. The Business Research Company
• 36.6. Copyright And Disclaimer