机械能源储存（MES）技术取得突破

长期能源储存的进步增加了大规模可再生能源部署的未来成长潜力

本研究分析了机械能源储存(MES) 技术的突破性进展。随着可再生能源成本的下降，清洁能源系统对全球电力结构的贡献将大幅增加，到2022年将达到30%左右。因此，对能源储存技术的需求正在迅速增长。

MES 技术是满足此需求的理想能源储存解决方案系列，因为它可以解决电网稳定性、电能品质和可靠性问题。大多数MES系统的特点是储能时间长、使用寿命长，使其适合电网规模的能源管理解决方案。这些技术也被用来提供电网稳定性和各种配套服务。

本研究概述了 MES 技术，描述了其主要特征，并确定了该领域的当前趋势。我们也关注这些技术的应用领域，并与竞争储存解决方案进行比较分析。确定了该行业的主要相关人员，并检验了驱动和限制市场成长的因素。我们也考察专利格局和该领域的最新发展，包括彻底改变的 MES 技术。最后，确定并总结了该行业变化带来的成长机会，供市场参与者和相关人员利用。

目录

战略问题

• 为什么成长如此困难？ ：阻碍成长的因素
• The Strategic Imperative 8（TM）
• 机械能源储存（MES）技术产业三大战略挑战的影响
• 成长机会推动Growth Pipeline Engine（TM）
• 调查方法

成长机会分析

• 分析范围
• 分割
• 生长促进因子
• 成长抑制因素

MES：技术简介

• MES系统需求
• 能源储存在现代电网中的作用
• 各种应用中能源储存解决方案的关键要求
• PHS-技术概述
• PHS-主要特性
• CAES-技术概述
• CAES-关键特性
• FES-技术概述
• FES-主要特性
• GES-技术概述
• GES-关键特性
• LAES-技术概述
• LAES-主要特点
• 领先的长期能源储存技术比较

创新生态系统

• 北美和欧洲引领 MES资金筹措和支持倡议
• MES领域重要企业
• MES专利形势

成长机会领域

• 成长机会一：电动车快充网络
• 成长机会2：微电网和分散式能源系统
• 成长机会3：下一代混合小灵通及可再生能源发电计划

附录

• 技术成熟度等级 (TRL)：解释

下一步

Advancements in Long-duration Energy Storage Enhance Future Growth Potential for Large-scale Renewable Energy Adoption

This study analyzes breakthrough advancements in mechanical energy storage (MES) technologies. With the decreasing cost of renewable energy, the contribution of clean energy systems to the global electricity mix has significantly increased, reaching around 30% in 2022. This, in turn, has led to an exponential surge in the demand for energy storage technologies.

MES technologies are a set of energy storage solutions ideally placed to meet this demand as they can address grid stability, power quality, and reliability concerns. A defining feature of most MES systems is their extensive storage durations and exceptionally long life, which makes them suitable for grid-scale energy management solutions. These technologies are also being deployed to provide stability to the grid and a range of ancillary services.

This study provides an overview of MES technologies, describing key attributes and identifying the current trends in this space. It also looks at the application areas for these technologies, providing a comparative analysis against competing storage solutions. The study identifies key stakeholders in this space and examines the factors driving and restraining the growth of this market. The patent landscape and the latest developments in this area, including disruptive MES technologies, have also been discussed. The study concludes by identifying the growth opportunities emerging from the changes in this space for market players and stakeholders to leverage.

Table of Contents

Strategic Imperatives

• Why Is It Increasingly Difficult to Grow?The Strategic Imperative 8™: Factors Creating Pressure on Growth
• The Strategic Imperative 8™
• The Impact of the Top 3 Strategic Imperatives on the Mechanical Energy Storage (MES) Technology Industry
• Growth Opportunities Fuel the Growth Pipeline Engine™
• Research Methodology

Growth Opportunity Analysis

• Scope of Analysis
• Segmentation
• Growth Drivers
• Growth Restraints

MES: Technology Snapshot

• Need for MES Systems
• Role of Energy Storage in Modern Grid
• Key Requirement of Energy Storage Solutions for Various Applications
• PHS-Technology Overview
• PHS-Key Attributes
• CAES-Technology Overview
• CAES-Key Attributes
• FES-Technology Overview
• FES-Key Attributes
• GES-Technology Overview
• GES-Key Attributes
• LAES-Technology Overview
• LAES-Key Attributes
• Comparison of Key Long-duration Energy Storage Technologies

Innovations Ecosystem

• North America and Europe Lead the Way in MES Funding and Supportive Initiatives
• Important Players in the MES Space
• MES Patent Landscape

Growth Opportunity Universe

• Growth Opportunity 1: Electric Vehicle Fast-charging Network
• Growth Opportunity 2: Microgrids and Distributed Energy Systems
• Growth Opportunity 3: Next-generation Hybrid PHS and Renewable Energy Projects

Appendix

• Technology Readiness Levels (TRL): Explanation

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