蒸汽重組器自備製氫市場機會、成長動力、產業趨勢分析和 2024 年至 2032 年預測

2023 年，全球蒸汽重組器自備製氫市場估值為1,170 億美元，預計2024 年至2032 年複合年成長率為6.2%。廠等工業設施內。蒸汽甲烷重整將天然氣等碳氫化合物轉化為氫氣，是該系統使用的主要過程。對具有成本效益且節能的氫氣生產解決方案（效率在 65% 至 75% 之間）的需求正在推動該技術的採用。現場生產使工業設施能夠生產清潔燃料，同時保持營運預算，減少對外部供應商的依賴。

這種方法還提供了靈活性，這對於旨在簡化氫氣供應的行業至關重要。各產業越來越注重對氫氣生產的完全運作控制。這使他們能夠客製化純度水平，確保按需可用性並保持可預測的輸出。加氫裂解或化學合成等關鍵製程對可靠、清潔燃料供應的需求不斷成長，也鼓勵採用即時監控和自動化等先進技術，進一步提高製程效率。

在應用方面，到2032年，化學領域蒸汽重整器自備製氫市場預計將超過1000億美元。這些解決方案消除了與商用氫氣相關的運輸和交付費用，有助於降低營運成本。此外，化學工業面臨越來越大的脫碳和滿足監管標準的壓力，這正在推動碳捕獲與儲存（CCS）技術的整合以生產更清潔的氫氣。歐洲預計將引領市場，其蒸汽重整器自備製氫產業預計到2032 年將超過390 億美元。 。

此外，在地緣政治不穩定加劇的情況下，歐洲致力於減少對外部能源供應的依賴，這導致各行業優先考慮本地化氫氣生產。在美國，氫基礎設施的發展在能源部能源地球計畫等聯邦計劃的支持下，透過蒸汽重整促進清潔能源生產。 《通貨膨脹減少法案》(IRA) 等政策為採用 CCS 設計的蒸汽活動者提供稅收抵免，也鼓勵低碳氫化合物的生產，進一步塑造產業格局。

目錄

第 1 章：方法與範圍

第 2 章：執行摘要

第 3 章：產業洞察

• 產業生態系統
• 監管環境
• 產業影響力
  • 成長動力
  • 產業陷阱與挑戰
• 成長潛力分析
• 波特的分析
• PESTEL分析

第 4 章：競爭格局

• 介紹
• 戰略儀表板
• 創新與科技格局

第 5 章：市場規模與預測：按應用分類，2021 - 2032

• 主要趨勢
• 石油精煉廠
• 化學
• 金屬
• 其他

第 6 章：市場規模與預測：按地區分類，2021 - 2032 年

• 主要趨勢
• 北美洲
  • 美國
  • 加拿大
  • 墨西哥
• 歐洲
  • 德國
  • 義大利
  • 荷蘭
  • 俄羅斯
• 亞太地區
  • 中國
  • 印度
  • 日本
• 中東和非洲
  • 沙烏地阿拉伯
  • 伊朗
  • 阿拉伯聯合大公國
  • 南非
• 拉丁美洲
  • 巴西
  • 阿根廷
  • 智利

第 7 章：公司簡介

• Air Products and Chemicals
• Clariant
• Chennai Petroleum Corporation
• HyGear
• Linde Gas
• Messer Group
• Mangalore Refinery and Petrochemicals
• Nuberg EPC
• Raven SR
• Siemens Energy
• Thyssenkrupp

The Global Steam Reformer Captive Hydrogen Generation Market was valued at USD 117 billion in 2023 and is expected to expand at 6.2% CAGR from 2024 to 2032. This method of hydrogen production occurs on-site, particularly within industrial facilities such as refineries and chemical plants. Steam methane reforming, which converts hydrocarbons like natural gas into hydrogen, is the primary process used in this system. The demand for cost-effective and energy-efficient hydrogen generation solutions, offering efficiencies between 65% and 75%, is driving the adoption of this technology. On-site production enables industrial facilities to produce clean fuel while maintaining operational budgets, reducing dependence on external suppliers.

This approach also provides flexibility, which is crucial for industries aiming to streamline their hydrogen supply. Industries are increasingly focusing on having complete operational control over hydrogen production. This allows them to customize purity levels, ensure on-demand availability, and maintain predictable outputs. The growing need for a reliable, clean fuel supply for critical processes like hydrocracking or chemical synthesis also encourages the adoption of advanced technologies such as real-time monitoring and automation, further enhancing process efficiency.

In terms of applications, the steam reformer captive hydrogen generation market in the chemical sector is set to exceed USD 100 billion by 2032. The rising demand for clean fuel in chemical processes drives the adoption of cost-effective hydrogen generation methods. These solutions help reduce operational costs by eliminating transportation and delivery expenses associated with merchant hydrogen. Additionally, chemical industries are under increasing pressure to decarbonize and meet regulatory standards, which is driving the integration of carbon capture and storage (CCS) technologies to produce cleaner hydrogen. Europe is projected to lead the market, with its steam reformer captive hydrogen generation sector expected to surpass USD 39 billion by 2032. Stringent environmental regulations, such as the European Union's Fit for 55 initiative and the Carbon Border Adjustment Mechanism, are pushing industries to reduce their carbon footprint, accelerating the adoption of steam reforming technologies.

Furthermore, Europe's focus on reducing reliance on external energy supplies amid rising geopolitical instability is leading industries to prioritize localized hydrogen production. In the U.S., the development of hydrogen infrastructure, supported by federal initiatives like the Department of Energy's Energy Earthshots program, promotes clean energy production through steam reforming. Policies such as the Inflation Reduction Act (IRA), offering tax credits for steam campaigners designed with CCS, also encourage the production of low-carbon hydrogen, further shaping the industry landscape.

Table of Contents

Chapter 1 Methodology & Scope

• 1.1 Research design
• 1.2 Base estimates & calculations
• 1.3 Forecast model
• 1.4 Primary research & validation
  • 1.4.1 Primary sources
  • 1.4.2 Data mining sources
• 1.5 Market definitions

Chapter 2 Executive Summary

• 2.1 Industry 360° synopsis, 2021 - 2032

Chapter 3 Industry Insights

• 3.1 Industry ecosystem
• 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

Chapter 4 Competitive landscape, 2023

• 4.1 Introduction
• 4.2 Strategic dashboard
• 4.3 Innovation & technology landscape

Chapter 5 Market Size and Forecast, By Application, 2021 - 2032 (USD Billion)

• 5.1 Key trends
• 5.2 Petroleum refinery
• 5.3 Chemical
• 5.4 Metal
• 5.5 Others

Chapter 6 Market Size and Forecast, By Region, 2021 - 2032 (USD Billion)

• 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 Italy
  • 6.3.3 Netherlands
  • 6.3.4 Russia
• 6.4 Asia Pacific
  • 6.4.1 China
  • 6.4.2 India
  • 6.4.3 Japan
• 6.5 Middle East & Africa
  • 6.5.1 Saudi Arabia
  • 6.5.2 Iran
  • 6.5.3 UAE
  • 6.5.4 South Africa
• 6.6 Latin America
  • 6.6.1 Brazil
  • 6.6.2 Argentina
  • 6.6.3 Chile

Chapter 7 Company Profiles

• 7.1 Air Products and Chemicals
• 7.2 Clariant
• 7.3 Chennai Petroleum Corporation
• 7.4 HyGear
• 7.5 Linde Gas
• 7.6 Messer Group
• 7.7 Mangalore Refinery and Petrochemicals
• 7.8 Nuberg EPC
• 7.9 Raven SR
• 7.10 Siemens Energy
• 7.11 Thyssenkrupp