废煤再生（ORC）市场机会、成长要素、产业趋势分析及2026年至2035年预测

全球废热回收（ORC）市场预计到 2025 年将达到 46 亿美元，到 2035 年将达到 129 亿美元，年复合成长率为 10.6%。

这一增长是由加速推进的脱碳进程、日益严格的环境法规以及工业运营商面临的不断增长的能源效率提升压力所驱动的。工业过程中产生的大量可回收热量正日益被视为一种尚未开发的能源资源，而非浪费的资源。有机朗肯循环（ORC）技术可以将这些剩余热能转化为可用电能，从而在提高整体效率的同时减少排放。能源价格波动和长期成本管理需求也是推动ORC技术普及的因素，因为ORC系统可以降低对电网的依赖，并有助于降低营运成本。技术的成熟和系统规模的扩大持续降低平准化电力成本（LCOE），使得ORC技术的应用范围不再局限于大型设施。系统设计、组件效率和运作可靠性的提升，在提高发电量的同时降低了维护需求，使得ORC解决方案在更广泛的运作环境中都具有商业性吸引力。

预计到2035年，5-10兆瓦以上容量的电厂市场规模将达15亿美元。此容量范围的系统主要用于高容量余热回收应用，其稳定、大的热流能够实现有效的现场发电。监管合规目标和长期永续性持续推动对更高容量电厂的投资。

预计到2025年，美国有机朗肯循环（ORC）废热能源市场规模将达到6.6亿美元，占市场份额的73%。有利的政策框架、不断上涨的能源成本以及排放重视减排，都推动了市场成长。此外，人们对分散式发电和本地能源韧性的关注也进一步促进了该技术的应用。

目录

第一章调查方法和范围

第二章执行摘要

第三章业界考察

• 生态系分析
  • 原物料供应及采购分析
  • 製造能力评估
  • 供应链韧性与风险因素
  • 配电网路分析
• 监管环境
• 产业影响因素
  • 司机
  • 产业潜在风险与挑战
• 成长潜力分析
• 波特五力分析
• PESTEL 分析
• 感应加热系统的成本结构分析
• 新的机会与趋势
• 投资分析及未来展望
• 将永续发展措施与工业4.0结合

第四章 竞争情势

• 介绍
• 按地区分類的公司市占率分析
  • 北美洲
  • 欧洲
  • 亚太地区
  • 中东和非洲
  • 拉丁美洲
• 战略仪錶板
• 策略倡议
  • 重要伙伴关係与合作
  • 重大併购活动
  • 产品创新与新产品发布
  • 市场扩大策略
• 竞争标竿分析
• 创新与永续性格局

第五章 依产量分類的市场规模及预测（2022-2035年）

• <=1兆瓦
• 1 至 5 兆瓦以上
• 超过 5 至 10 兆瓦
• 超过 10 兆瓦

第六章 2022-2035年各地区市场规模及预测

• 北美洲
  • 美国
  • 加拿大
  • 墨西哥
• 欧洲
  • 德国
  • 英国
  • 义大利
  • 法国
  • 比利时
  • 西班牙
  • 俄罗斯
• 亚太地区
  • 中国
  • 澳洲
  • 印度
  • 日本
  • 韩国
• 中东和非洲
  • 沙乌地阿拉伯
  • 阿拉伯聯合大公国
  • 南非
• 拉丁美洲
  • 巴西
  • 阿根廷

第七章 公司简介

• ABB
• ALFA LAVAL
• Atlas Copco AB
• Calnetix Technologies, LLC
• Elvosolar, as
• Enertime
• ENOGIA
• Exergy International Srl
• General Electric
• INTEC GMK
• Kaishan USA
• Mitsubishi Heavy Industries, Ltd.
• ORCAN ENERGY AG
• Ormat Technologies
• Triogen
• Turboden SpA

The Global ORC Waste Heat to Power Market was valued at USD 4.6 billion in 2025 and is estimated to grow at a CAGR of 10.6% to reach USD 12.9 billion by 2035.

Growth is driven by accelerating decarbonization efforts, tightening environmental regulations, and rising pressure on industrial operators to improve energy efficiency. Large volumes of recoverable heat generated during industrial processes are increasingly viewed as an untapped energy resource rather than a loss. ORC technology enables this residual thermal energy to be converted into usable electricity, improving overall efficiency while reducing emissions. Volatile energy pricing and long-term cost control priorities are further strengthening adoption, as ORC systems help offset grid dependence and lower operational expenses. Continuous declines in the levelized cost of electricity, supported by technological maturity and scaling of system deployment, are expanding adoption beyond large facilities. Advances in system design, component efficiency, and operational reliability are improving output while reducing maintenance requirements, making ORC solutions more commercially attractive across a wider range of operating environments.

The greater than 5 to 10 MWe capacity segment is expected to reach USD 1.5 billion by 2035. Systems within this range are selected for high-volume heat recovery applications where large, stable thermal streams allow for meaningful on-site power generation. Regulatory compliance goals and long-term sustainability commitments continue to support investment in higher-capacity installations.

United States ORC Waste Heat to Power Market held 73% share in 2025, generating USD 660 million. Market growth is supported by favorable policy frameworks, rising energy costs, and increased focus on emissions reduction. Interest in distributed power generation and localized energy resilience further contributes to adoption momentum.

Key companies active in the Global ORC Waste Heat to Power Market include Turboden S.p.A, Ormat Technologies, Mitsubishi Heavy Industries, Ltd., ABB, General Electric, Atlas Copco AB, Alfa Laval, Kaishan USA, Enertime, ENOGIA, Exergy International Srl, ORCAN ENERGY AG, Calnetix Technologies, LLC, Elvosolar, a.s., INTEC GMK, and Triogen. Companies operating in the Global ORC Waste Heat to Power Market strengthen their market position through technology innovation, system efficiency improvements, and strategic expansion. Leading players invest in advanced system designs to increase conversion efficiency while lowering lifecycle costs. Portfolio diversification across different capacity ranges allows suppliers to address a broader customer base. Strategic partnerships with engineering firms and energy solution providers help accelerate project deployment and market access. Manufacturers also focus on modular system development to reduce installation time and improve scalability.

Table of Contents

Chapter 1 Methodology & Scope

• 1.1 Research design
  • 1.1.1 Research approach
  • 1.1.2 Data collection methods
• 1.2 Base estimates and calculations
  • 1.2.1 Base year calculation
  • 1.2.2 Market estimates & forecast parameters
• 1.3 Forecast
  • 1.3.1 Key trends for market estimates
  • 1.3.2 Quantified market impact analysis
    • 1.3.2.1 Mathematical impact of growth parameters on forecast
  • 1.3.3 Scenario analysis framework
• 1.4 Primary research and validation
  • 1.4.1 Some of the primary sources (but not limited to)
• 1.5 Data mining sources
  • 1.5.1 Paid Sources
  • 1.5.2 Sources, by region
• 1.6 Research trail & scoring components
  • 1.6.1 Research trail components
  • 1.6.2 Scoring components
• 1.7 Research transparency addendum
  • 1.7.1 Source attribution framework
  • 1.7.2 Quality assurance metrics
  • 1.7.3 Our commitment to trust
• 1.8 Market definitions

Chapter 2 Executive Summary

• 2.1 Industry synopsis, 2022 - 2035
  • 2.1.1 Business trends
  • 2.1.2 Power output trends
  • 2.1.3 Regional trends

Chapter 3 Industry Insights

• 3.1 Industry ecosystem analysis
  • 3.1.1 Raw material availability & sourcing analysis
  • 3.1.2 Manufacturing capacity assessment
  • 3.1.3 Supply chain resilience & risk factors
  • 3.1.4 Distribution network analysis
• 3.2 Regulatory landscape
• 3.3 Industry impact forces
  • 3.3.1 Growth drivers
  • 3.3.2 Industry pitfalls & challenges
• 3.4 Growth potential analysis
• 3.5 Porter's analysis
  • 3.5.1 Bargaining power of suppliers
  • 3.5.2 Bargaining power of buyers
  • 3.5.3 Threat of new entrants
  • 3.5.4 Threat of substitutes
• 3.6 PESTEL analysis
  • 3.6.1 Political factors
  • 3.6.2 Economic factors
  • 3.6.3 Social factors
  • 3.6.4 Technological factors
  • 3.6.5 Legal factors
  • 3.6.6 Environmental factors
• 3.7 Cost structure analysis of induction heating systems
• 3.8 Emerging opportunities & trends
• 3.9 Investment analysis & future prospects
• 3.10 Sustainability initiatives & industry 4.0 integration

Chapter 4 Competitive Landscape, 2025

• 4.1 Introduction
• 4.2 Company market share analysis, by region, 2025
  • 4.2.1 North America
  • 4.2.2 Europe
  • 4.2.3 Asia Pacific
  • 4.2.4 Middle East & Africa
  • 4.2.5 Latin America
• 4.3 Strategic dashboard
• 4.4 Strategic initiatives
  • 4.4.1 Key partnerships & collaborations
  • 4.4.2 Major M&A activities
  • 4.4.3 Product innovations & launches
  • 4.4.4 Market expansion strategies
• 4.5 Competitive benchmarking
• 4.6 Innovation & sustainability landscape

Chapter 5 Market Size and Forecast, By Power Output, 2022 - 2035 (USD Million)

• 5.1 Key trends
• 5.2 ≤ 1 MWe
• 5.3 > 1 - 5 MWe
• 5.4 > 5 - 10 MWe
• 5.5 > 10 MWe

Chapter 6 Market Size and Forecast, By Region, 2022 - 2035 (USD Million)

• 6.1 Key trends
• 6.2 North America
  • 6.2.1 U.S.
  • 6.2.2 Canada
  • 6.2.3 Mexico
• 6.3 Europe
  • 6.3.1 Germany
  • 6.3.2 UK
  • 6.3.3 Italy
  • 6.3.4 France
  • 6.3.5 Belgium
  • 6.3.6 Spain
  • 6.3.7 Russia
• 6.4 Asia Pacific
  • 6.4.1 China
  • 6.4.2 Australia
  • 6.4.3 India
  • 6.4.4 Japan
  • 6.4.5 South Korea
• 6.5 Middle East & Africa
  • 6.5.1 Saudi Arabia
  • 6.5.2 UAE
  • 6.5.3 South Africa
• 6.6 Latin America
  • 6.6.1 Brazil
  • 6.6.2 Argentina

Chapter 7 Company Profiles

• 7.1 ABB
• 7.2 ALFA LAVAL
• 7.3 Atlas Copco AB
• 7.4 Calnetix Technologies, LLC
• 7.5 Elvosolar, a.s.
• 7.6 Enertime
• 7.7 ENOGIA
• 7.8 Exergy International Srl
• 7.9 General Electric
• 7.10 INTEC GMK
• 7.11 Kaishan USA
• 7.12 Mitsubishi Heavy Industries, Ltd.
• 7.13 ORCAN ENERGY AG
• 7.14 Ormat Technologies
• 7.15 Triogen
• 7.16 Turboden S.p.A