用于分散式发电的高温燃料电池：最新创新、发展和成长机会

High-temperature Fuel Cells for Decentralized Power Generation: Recent Innovations, Developments, and Growth Opportunities

出版日期: 2024年07月01日 | 出版商:

Frost & Sullivan | 英文 50 Pages | 商品交期: 最快1-2个工作天内

价格

简介目录

分析实施 HTFC 技术以实现低碳未来的技术经济优势

分散式发电需求的增加、政府支持政策以及氢经济的发展将推动分散式发电的高温燃料电池（HTFC）产业的成长。住宅、商业和工业领域对可靠和清洁发电的能源独立性和安全性的日益重视，提高了 HTFC 技术作为主要和备用电源的作用。

HTFC 在 500°C 以上的温度下运行，不易发生一氧化碳中毒，并使用非贵金属，提供燃料灵活性和内部改性能力。固体氧化物燃料电池（SOFC）技术在HTFC技术中占主导地位，其次是熔融碳酸盐燃料电池（MCFC）技术。在全球范围内，製造商都致力于提高热电联产 (CHP) 发电应用的 HTFC 系统的耐用性、使用寿命并降低成本。

美国、韩国和日本在热电联产和基本负载发电应用的 HTFC 开发和部署方面处于领先地位，其次是欧盟 (EU)，其兴趣和战略倡议日益浓厚。

本报告涵盖以下主题：

SOFC与MCFC技术概述

低温与高温燃料电池技术比较分析，HTFC微型热电联产机组技术性能探讨

评估关键成长机会、成长动力和限制、产业关键创新者以及专利格局

The increasing demand for decentralized power generation, supportive government policies, and the progress of the hydrogen economy will drive the growth of the high-temperature fuel cells (HTFC) industry for decentralized power generation. The focus on energy independence and security across the residential, commercial, and industrial sectors for reliable and clean power generation has increased the role of HTFC technologies as a primary and backup power device.

HTFCs operating at temperatures above 500°C are less prone to carbon monoxide poisoning and utilize non-precious metals, offering fuel flexibility and internal reforming capabilities. Solid-oxide fuel cell (SOFC) technology dominates the HTFC technologies landscape, followed by molten-carbonate fuel cell (MCFC) technology. Globally, manufacturers are focusing on improving durability and lifespan and reducing the cost of HTFC systems for combined heat and power (CHP) generation applications.

The United States, South Korea, and Japan are leaders in the development and deployment of HTFCs for CHP generation and baseload power generation applications, followed by the European Union, which is demonstrating growing interest and implementing strategic initiatives.

This Frost & Sullivan study covers the following topics:

It offers a technology overview of SOFC and MCFC technologies.

It provides a comparative analysis of low-temperature and high-temperature fuel cell technologies and discusses the technological performance of HTFC-based micro-CHP units.

The study also evaluates key growth opportunities, growth drivers and restraints, important innovators in the industry, and the patent landscape.

Strategic Imperatives

Why Is It Increasingly Difficult to Grow?
The Strategic Imperative 8™
The Impact of the Top 3 Strategic Imperatives on High-temperature Fuel Cells for Decentralized Power Generation
Growth Opportunities Fuel the Growth Pipeline Engine™
Research Methodology

Growth Opportunity Analysis

Scope of Analysis
Segmentation

Growth Generator

Growth Drivers
Growth Restraints

HTFCs

Hydrogen Economy Value Chain
HTFCs' Role in Decentralized Power Generation
SOFCs' Working Mechanism
MCFCs' Working Mechanism
LTFC and HTFC Technologies: A Comparative Analysis
HTFCs: Cost Analysis
HTFC-based Micro-CHP Units: Technical Performance

Innovation Ecosystem

Global Initiatives Driving HTFC Deployment
Case Study: Electricity and Heat for the Hermann-Josef-Krankenhaus (HJK) Hospital in Erkelenz, Germany
The United States Leads the HTFC Patent Landscape

Companies to Action

Key HTFC Participants
HTFC Participants to Watch
Emerging HTFC Participants

Growth Generator

Growth Opportunity 1: Hybrid Microgrids Offer Energy Security for a Wide Range of Industries
Growth Opportunity 2: High-temperature Fuel Cells' Strong Potential for Carbon Capture
Growth Opportunity 3: Diverse Business Models Make the HTFC Industry Attractive