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綠色能源智慧電網

市場調查報告書

商品編碼

1640638

微電網控制系統：市場佔有率分析、產業趨勢與統計、成長預測（2025-2030 年）

Microgrid Control Systems - Market Share Analysis, Industry Trends & Statistics, Growth Forecasts (2025 - 2030)

出版日期: 2025年01月05日 | 出版商:

Mordor Intelligence | 英文 120 Pages | 商品交期: 2-3個工作天內

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簡介目錄

微電網控制系統市場規模預計在 2025 年為 48.2 億美元，預計到 2030 年將達到 87.8 億美元，預測期內（2025-2030 年）的複合年成長率為 12.77%。

控制和能源管理的持續改進預計將對市場成長產生積極影響。分散式可再生能源和電池技術價格的下降，以及能源管理系統的技術進步，正在帶來更有效率的可再生能源電網和先進的智慧電網技術。

主要亮點

根據 2022 年 5 月發表的世界經濟論壇報導，傳統電網可以覆蓋整個大陸或國家，這意味著，如果暴風雨或停電導致某個地區的主要電網癱瘓，許多家庭、企業和關鍵服務可能會受到影響。微電網可以與主電網隔離，從而允許其在緊急情況下繼續供電。這個過程被稱為「孤島化」。
由於微電網應用於許多領域並與燃料電池等新技術相結合，需要高效可靠的控制系統來處理新系統的複雜性。這導致對高效和集中的微電網控制器的需求增加。傳統網路由於排隊較長而被認為效率很低。
2022 年 11 月，先進電力和能源計畫 (APEP) 與南加州愛迪生公司 (SCE)、能源部 (DOE)、KB Home、SunPower 和Schneider Electric合作，宣佈在梅尼菲建立影子公用事業。規劃中開發、部署和測試了兩個微電網社群。總體而言，APEP 將確保微電網控制器符合國家標準 (IEEE 2030.7)，該標準是在 APEP 為 DOE 完成的領先工作的基礎上發展起來的，利用UCI 微電網作為演示和開發平台。。
然而，高昂的實施成本可能會阻礙市場成長。這些系統需要不斷維護，並需要熟練的人員來排除技術問題。這些因素阻礙了市場的成長。
COVID-19 疫情以多種方式影響了微電網控制系統市場。 COVID-19疫情爆發導致供應鏈中斷和早期計劃延遲。自那時起，人們對彈性能源基礎設施和遠端能源管理的關注度不斷提高，加速了微電網控制系統的採用和投資。

微電網控制系統市場趨勢

公共產業部門佔據了大部分市場佔有率

微電網透過適應太陽能發電裝置和電動車等再生能源來源的日益成長的使用，實現了高效、動態的電網。此外，透過減少輸配電過程中的能源損失以及利用當地能源滿足家庭需求，可以進一步提高電力供應系統的效率。
根據美國能源局的數據，到 2035 年，微電網將成為具有彈性、脫碳且價格合理的新型電力系統的關鍵基石。
2023年3月，Volvo遍達與電池能源儲存領域分散式微電網系統領導者公共事業 Innovation Group建立合作關係。兩家公司將共同努力，透過電池儲存和整合來提高電網的可靠性和彈性，並充分利用太陽能和風能等可再生能源。
此外，2023年1月，加州電力公司PG&E將與以重力解決方案聞名的Energy Vault公司合作，建造結合綠色氫能和電池的長效能源儲存微電網。兩家公司正在合作營運和部署公共事業規模的電池和綠色氫能能源儲存系統。
隨著電力需求的增加，電力公司正在轉向替代能源並整合更多分散式能源來源。在管理這種複雜而分散的能源網路時，最佳化電力流和微電網控制系統以實現可再生能源的無縫整合至關重要。根據美國能源資訊署 (EIA) 的數據，2022 年美國公用事業的發電量與前一年相比小幅增加約 2,537兆瓦時。

北美佔據很大市場佔有率

預計預測期內可再生能源發電和分散式發電系統的增加將推動市場發展。傳統電網市場面臨越來越大的壓力。同時，我們老化的基礎設施需要進行大規模整修。美國環保署（EPA）正在實施前所未有的溫室氣體法規，進一步推動可再生能源綜合微電網控制系統市場的發展。
此外，該地區市場參與者的發展預計將推動市場發展。例如，自動化和能源管理數位轉型的領導者Schneider Electric於 2023 年 5 月宣布，EcoStruxure Microgrid Flex 將顯著縮短計劃週期時間，並在整個計劃生命週期內實現更高的回報。微電網解決方案對於內部系統投資，這是該行業首次為應對這些挑戰而設計的。據估計，到 2050 年，分散式能源將占美國發電量的 40%，從而推動對微電網的需求。微電網系統需要大量的工程時間和集中的注意力來配置、規劃和部署系統。
2022 年 10 月，ENGIE North America（ENGIE）宣布已為聖塔芭芭拉聯合學區安裝最先進的設備，擴展了其微電網產品範圍。停電和安全性降低已成為加州的新常態，給社區帶來了減輕和適應直接影響的巨大壓力。
政府以資金補助和州級復原力計畫形式提供的支持不斷增加，推動了教育機構和校園應用的需求，成為美國市場成長的主要驅動力。例如，2023 年 5 月，美國能源局(DOE) 宣布撥款 3,400 萬美元，用於推進阿拉斯加 18 個美洲原住民和原住民社區的清潔能源技術。這筆資金將透過增加微電網和太陽能的使用、為未通電的部落建築供電以及提高能源安全性和彈性來加強部落社區。
預計能源儲存價格下降將降低可再生能源的整合成本。預計這一因素也將提高大型社區以及商業和工業領域採用微電網的比例。

微電網控制系統產業概況

微電網控制系統市場相當分散，因為進入該市場需要大量的前期投資。市場的主要企業包括 ABB 集團、西門子股份公司、日立有限公司、伊頓公司、普林斯頓電力系統、通用電氣公司、帕累托能源有限公司、霍尼韋爾國際公司、北方電力系統公司和 Exelon 公司。市場近期的主要發展包括：

2023 年 3 月，西門子加拿大公司與漢博學院合作，在學校北校區開發可再生技術和永續微電網實驗室 (SMART Lab)。漢博學院的 SMART Lab 投資基於永續數位技術，並得到安大略省的支持。電動車充電站、太陽能智慧花卉和電池儲存系統等設備整合到微電網控制系統中，以在局部產生和分配能源，並實現更有效率和永續的電力使用和消耗。

2023年3月，ABB投資直流微電網新興企業Direct Energy Partners，加速能源轉型。直流（DC）能源網路對於能源產業的發展至關重要，此次夥伴關係增強了 ABB 在未來關鍵成長市場的技術領導地位。 Direct Energy Partners 的軟體平台可將直流微電網的設計和採購流程自動化。

2022 年 8 月，工程和管理顧問公司 Tetra Tech 為大曼徹斯特郡奧爾德姆議會推出了 300kW 未來微型電網。 ABB宣布交付配電和控制系統。計劃的初始階段計劃於 2023 年春季完成，將包括太陽能發電面板、500kVA並聯型、電動車充電站和透過空氣源熱泵供暖，以滿足辦公大樓的能源需求。

其他福利：

Excel 格式的市場預測 (ME) 表
3 個月的分析師支持

按類型
- 電網連接
- 離網
- 混合
按應用
- 公共產業
- 城市和市政當局
- 防禦
- 產業
- 其他用途
按地區
- 北美洲
  - 美國
  - 加拿大
- 歐洲
  - 德國
  - 英國
  - 法國
  - 其他歐洲國家
- 亞太地區
  - 中國
  - 日本
  - 印度
  - 其他亞太地區
- 拉丁美洲
- 中東和非洲

第7章競爭格局

公司簡介
- ABB Group
- Siemens AG
- Hitachi, Ltd
- Eaton Corporation PLC
- Princeton Power Systems
- General Electric Corporation
- Pareto Energy, Ltd
- Honeywell International, Inc.
- Northern Power Systems Corporation
- Exelon Corporation

第8章投資分析

第9章市場機會與未來趨勢

簡介目錄

Product Code: 56122

The Microgrid Control Systems Market size is estimated at USD 4.82 billion in 2025, and is expected to reach USD 8.78 billion by 2030, at a CAGR of 12.77% during the forecast period (2025-2030).

Microgrid Control Systems - Market - IMG1

Continued control and energy management improvements are expected to impact market growth positively. Declining prices for distributed renewable energy and battery technology and technological advances in energy management systems have led to more efficient renewable energy grids and advanced smart grid technologies.

Key Highlights

As per an article by the World Economic Forum published in May 2022, many homes, businesses, and critical services could be affected if a region's primary power grid were to go down due to storms or power outages, as conventional power grids can cover entire continents or countries. Microgrids can switch off from the primary grid and continue to supply power during such emergencies. This process is known as "islanding."
As microgrids are used in many fields and integrated with new technologies, including fuel cells, efficient and reliable control systems are needed to handle the new systems' complexity. Therefore, there is a growing need for effective and centralized microgrid controllers. Traditional networks are considered very inefficient due to long lines.
November 2022, Advanced Power and Energy Program (APEP) collaborated with Southern California Edison (SCE), the Department of Energy (DOE), KB Home, SunPower, and Schneider Electric on the development, deployment, and testing of two microgrid communities in the Shadow Mountain master plan in Menifee. Overall, APEP will guarantee that the microgrid controller meets the (IEEE 2030.7) national standards that advanced from prior research achieved by APEP for the DOE utilizing the UCI Microgrid as a platform for both demonstration and development.
However, high implementation costs may hinder market growth. These systems require constant maintenance and need skilled workers to troubleshoot technical issues. These factors impede market growth.
The COVID-19 outbreak had mixed impacts on the microgrid control systems market. The outbreak caused supply chain disruptions and project delays in the early stages. Subsequently, increased focus on resilient energy infrastructure and remote energy management has accelerated adopting and investing in microgrid control systems.

Microgrid Control System Market Trends

Utilities Segment Accounts for a Significant Share in the Market

Microgrids allow an efficient and dynamic electricity grid by adapting to the growing use of renewable energy sources, such as photovoltaic equipment and electric vehicles. Additionally, reducing energy loss in transmission and distribution further increases the electricity delivery system's efficiency by using Local Energy Resources to serve households' needs.
As per the U.S. Department of Energy, microgrids will be essential building blocks for a new electricity delivery system by 2035 to ensure resilience, decarbonization, and affordability.
In March 2023, Volvo Penta partnered with Utility Innovation Group, a decentralized microgrid systems leader in the battery energy storage sector. Both companies cooperate to improve power grid reliability and resilience through battery storage and integration, maximizing renewable energy sources use, including solar and wind.
Moreover, in January 2023, California utility PG&E created an energy storage microgrid, which has a long duration by combining green hydrogen and batteries, in collaboration with Energy Vault, the firm known for its gravity-based solution. The two firms are partnering to operate and deploy utility-scale battery and green hydrogen energy storage systems.
As demand for electricity increases, electric power companies are looking at alternative energy sources and have integrated a more decentralized energy source. In managing such complex and decentralized energy networks, optimizing electrical flows to help integrate renewable energies seamlessly and microgrid control systems are essential. According to the EIA, in 2022, electricity generation from electrical utilities in the U.S. increased slightly compared with the preceding year by about 2,537 terawatt hours.

North America Accounts for a Significant Share in the Market

The increase in renewable energy and distributed generation systems is anticipated to drive the market during the forecast period. The traditional grid market is under increasing pressure. At the same time, its aging infrastructure requires significant overhauls. The US EPA (Environmental Policy Agency) has imposed unprecedented greenhouse gas regulations, further driving the integrated renewable energy microgrid control systems market.
Moreover, developments by market players in the region are expected to drive the market. For instance, in May 2023, Schneider Electric, a leader in the automation and energy management digital transformation, announced that EcoStruxure Microgrid Flex is an industry-first designed to significantly reduce project cycle times and achieve higher returns throughout the project lifecycle, announced an innovative standardized microgrid solution about investing in in-house systems. Distributed energy resources are estimated to account for 40% of U.S. electricity generation by 2050, increasing the microgrids demand to meet that need. Microgrid systems need significant engineering time and focused attention to configure, plan, and deploy the system.
In October 2022, ENGIE North America (ENGIE) announced that it had expanded its microgrid offering with state-of-the-art equipment for the Santa Barbara Unified School District. Power and safety outages have become the new normal in California, putting communities under tremendous pressure to mitigate and adapt their immediate impact.
The rising governmental support in the form of funding and state-level resiliency programs has increased the demand from institutions or campus applications, making it a key driver for U.S. market growth. For instance, in May 2023, the U.S. Department of Energy (DOE) announced USD 34 million in funding to advance clean energy technologies in 18 Native American and Indigenous communities in Alaska. The funds will empower tribal communities by increasing access to microgrids and solar power, powering non-electrified tribal buildings, and increasing energy security and resilience.
The drop in energy storage prices is expected to lower the cost of integrating renewable energy. This factor is also expected to drive the adoption rate of Microgrids in larger communities and commercial and industrial sectors.

Microgrid Control System Industry Overview

The Microgrid Control Systems Market is moderately fragmented due to the large initial investments required to start a firm in the market. Some of the major companies in the market include ABB Group, Siemens AG, Hitachi Ltd, Eaton Corporation PLC, Princeton Power Systems, General Electric Corporation, Pareto Energy Ltd, Honeywell International Inc., Northern Power Systems Corporation, and Exelon Corporation, among others. Some key recent developments in the market include:

In March 2023, Siemens Canada partnered with Humber College to develop a Renewable Technology and Sustainable Microgrid Lab (SMART Lab) at its North Campus. Humber's investments in the SMART Lab are based upon sustainable digital technology, supported by the Province of Ontario. To generate and distribute energy locally and to allow for more efficient and sustainable use and consumption of electricity, devices such as electric vehicle charging stations, solar Smartflower, and battery energy storage systems will be used in the microgrid control system.

In March 2023, ABB invested in Direct Current microgrid start-up Direct Energy Partners to accelerate energy transformation. Direct Current (DC) energy networks will be crucial to the evolution of the energy industry, and this partnership enhances ABB's technological leadership in a significant future growth market. Direct Energy Partners' software platform automates the design and sourcing processes for DC Microgrids.

In August 2022, Engineering and management consulting firm Tetra Tech was implementing a 300kW future Microgrid for Oldham Council in Greater Manchester. ABB announced the delivery of electrical distribution and control systems for it. The project's initial phase, scheduled to be finished by the spring of 2023, was to incorporate solar photovoltaic panels, a 500kVA grid connection, EV charging stations, and the energy needs of an office building as heating provided by an air source heat pump.

Additional Benefits:

The market estimate (ME) sheet in Excel format
3 months of analyst support

1 INTRODUCTION

1.1 Study Deliverables
1.2 Study Assumptions
1.3 Scope of the Study

2 RESEARCH METHODOLOGY

3 EXECUTIVE SUMMARY

4 MARKET INSIGHTS

4.1 Market Overview
4.2 Value Chain Analysis
4.3 Industry Attractiveness - Porter's Five Forces Analysis
- 4.3.1 Bargaining Power of Buyers/Consumers
- 4.3.2 Bargaining Power of Suppliers
- 4.3.3 Threat of New Entrants
- 4.3.4 Threat of Substitute Products
- 4.3.5 Intensity of Competitive Rivalry

5 MARKET DYNAMICS

5.1 Market Drivers
- 5.1.1 Increasing Demand for Backup Solutions (For Support, In Case Of Emergency Blackouts)
- 5.1.2 Growing Need to Improve Operational Efficiency
5.2 Market Restraints
- 5.2.1 High Implementation Costs and Operational and Technical Issues

6 MARKET SEGMENTATION

6.1 By Type
- 6.1.1 Grid-connected
- 6.1.2 Off-Grid
- 6.1.3 Hybrid
6.2 By Application
- 6.2.1 Utilities
- 6.2.2 Cities and Municipalities
- 6.2.3 Defense
- 6.2.4 Industrial
- 6.2.5 Other Applications
6.3 Geography
- 6.3.1 North America
  - 6.3.1.1 United States
  - 6.3.1.2 Canada
- 6.3.2 Europe
  - 6.3.2.1 Germany
  - 6.3.2.2 UK
  - 6.3.2.3 France
  - 6.3.2.4 Rest of Europe
- 6.3.3 Asia-Pacific
  - 6.3.3.1 China
  - 6.3.3.2 Japan
  - 6.3.3.3 India
  - 6.3.3.4 Rest of Asia-Pacific
- 6.3.4 Latin America
- 6.3.5 Middle East & Africa

7 COMPETITIVE LANDSCAPE

7.1 Company Profiles
- 7.1.1 ABB Group
- 7.1.2 Siemens AG
- 7.1.3 Hitachi, Ltd
- 7.1.4 Eaton Corporation PLC
- 7.1.5 Princeton Power Systems
- 7.1.6 General Electric Corporation
- 7.1.7 Pareto Energy, Ltd
- 7.1.8 Honeywell International, Inc.
- 7.1.9 Northern Power Systems Corporation
- 7.1.10 Exelon Corporation