Global Microgrid Market

MARKET SCOPE:

The global Microgrid market is projected to grow significantly, registering a CAGR of 18.7% during the forecast period (2024 – 2032).

A microgrid is a localized and decentralized energy system that can operate independently or in conjunction with the main power grid. It typically consists of distributed energy resources (DERs) such as solar panels, wind turbines, energy storage systems (batteries), combined heat and power (CHP) systems, and advanced control systems. Microgrids are designed to generate, store, and distribute electricity to meet the needs of a specific community, facility, or geographic area. They can operate autonomously, enhancing energy resilience, reliability, and sustainability. Organizations and communities seek solutions to enhance energy resilience, ensuring a continuous power supply during grid outages or disruptions. The desire to incorporate renewable energy sources into the energy mix has led to increased interest in microgrids, which are well-suited for integrating solar, wind, and other clean energy technologies. Microgrids offer a degree of energy independence, allowing users to generate and manage their own electricity, reducing reliance on external power sources. Microgrids are deployed to provide reliable power to critical facilities such as hospitals, data centers, and emergency response centers. Microgrids are essential for providing electricity to remote areas and islands, where connecting to the main grid may be challenging or economically unfeasible. The emphasis on sustainability and reducing carbon emissions drives interest in microgrids, especially those incorporating renewable energy and energy-efficient technologies. Government incentives, subsidies, and supportive policies encourage the adoption of microgrids, aligning with broader energy and environmental goals.

MARKET OVERVIEW:

Driver: Increasing demand for modern grid technologies is driving the market growth.

Efforts to modernize aging grid infrastructure and enhance overall grid resilience are crucial components of the evolving energy landscape. As traditional power grids face challenges such as aging infrastructure, increased demand, and the need for greater flexibility, the integration of microgrids plays a significant role in complementing grid modernization efforts Microgrids contribute to grid modernization by providing localized power generation capabilities. Instead of relying solely on centralized power plants, microgrids enable distributed energy resources (DERs) like solar panels, wind turbines, and energy storage to generate electricity at or near the point of use. Microgrids help reduce transmission losses by generating and delivering electricity locally. Traditional power grids can experience significant energy losses during long-distance transmission. Microgrids, with their localized generation, minimize these losses, improving overall energy efficiency. Microgrids enhance grid reliability and resilience by providing a decentralized and flexible energy infrastructure. In the event of disruptions or outages in the main grid, microgrids can continue to operate autonomously, supporting critical loads and maintaining essential services.

Opportunities: Rise in Distributed Energy Resources (DERs) is anticipated for the market growth in the upcoming years.

The increasing integration of distributed energy resources (DERs) such as solar panels, wind turbines, and energy storage is a key trend in the energy sector. This trend is driven by various factors, including technological advancements, environmental concerns, and the desire for a more resilient and sustainable energy infrastructure. Solar panels and wind turbines are key components of distributed renewable energy generation. They convert sunlight and wind into electricity at or near the point of use. Energy storage, particularly in the form of batteries, plays a crucial role in managing the intermittency of renewable energy sources. Batteries store excess energy generated during periods of high renewable output and release it when needed. DERs enable decentralized power generation, allowing energy to be produced closer to where it is consumed. This reduces transmission losses and enhances the efficiency of the overall energy system. By incorporating solar panels, wind turbines, and energy storage at the point of use, businesses, communities, and individuals can enhance their energy independence and resilience. This is particularly valuable during grid outages or disruptions. The adoption of DERs supports the development of community-scale and distributed generation projects. Communities can generate their own electricity, fostering energy independence and local economic development. Ongoing advancements in renewable energy technologies, such as improved solar panel efficiency and the development of more cost-effective wind turbines, contribute to the increasing feasibility and attractiveness of DERs.

COVID IMPACT:

The COVID-19 pandemic has had various impacts on the energy sector, including the deployment and operation of microgrids. The specific effects can vary depending on regional responses, the nature of the microgrid applications, and the overall economic environment. The pandemic led to disruptions in construction activities and supply chain delays, affecting the deployment of microgrid projects. Lockdowns, social distancing measures, and restrictions on movement could have slowed down construction timelines. Economic uncertainties and financial challenges resulting from the pandemic may have affected the funding and investment landscape for microgrid projects. Investors and project developers may have faced challenges in securing financing for new or ongoing projects. The need for social distancing and lockdowns may have prompted changes in how microgrids are operated and managed. Remote monitoring and control systems became more crucial, and operators may have adopted digital technologies to manage and optimize microgrid performance from a distance. Changes in work patterns, with more people working from home, could have influenced energy demand patterns. Some commercial and industrial microgrid applications may have experienced shifts in load profiles, impacting the optimization of microgrid operations. The pandemic underscored the importance of resilient energy infrastructure. Institutions and critical facilities may have increased their focus on microgrids as a means to ensure a reliable and continuous power supply, especially for critical loads and essential services.

SEGMENTATION ANALYSIS:

Remote Power Systems segment is anticipated to grow significantly during the forecast period

Remote power systems and microgrids play a crucial role in providing reliable and sustainable electricity in areas where access to the main power grid is limited or non-existent. The market for remote power systems and microgrids has been growing, driven by various factors. Remote power systems are essential for off-grid applications, including rural electrification, remote industrial sites, and isolated communities. The need for electricity in areas without grid access, coupled with advancements in renewable energy technologies, drives the demand for remote power systems. Microgrids in remote areas often integrate renewable energy sources such as solar, wind, and hydropower to generate electricity locally. The push for clean energy and the decreasing costs of renewable technologies make microgrids with renewable integration economically viable and environmentally sustainable. Governments and organizations focus on rural electrification initiatives to bring power to remote and underserved areas.

The Institutional Sites segment is anticipated to grow significantly during the forecast period

Microgrids are increasingly being deployed at institutional sites to enhance energy resilience, reliability, and sustainability. Institutional sites, which include government facilities, educational campuses, healthcare institutions, and other public or private organizations, can benefit from microgrid solutions in various ways. Microgrids provide institutional sites with energy resilience by ensuring a continuous power supply during grid outages or disruptions. This is critical for facilities that house essential services, emergency response centers, or critical infrastructure. Hospitals, government offices, and other critical institutions can deploy microgrids to maintain operations during power interruptions, supporting patient care, emergency response, and essential services.

REGIONAL ANALYSIS:

The Asia Pacific region is set to witness significant growth during the forecast period.

The concept of microgrids is gaining traction globally, including in the Asia-Pacific region. Microgrids are localized energy systems that can operate independently or in conjunction with the main power grid. They often incorporate renewable energy sources, energy storage, and advanced control systems to provide resilient, sustainable, and decentralized power solutions. Microgrids are particularly relevant in remote and island communities where access to the main power grid may be limited or challenging. Microgrids enhance energy resilience in disaster-prone areas, providing critical infrastructure with a reliable power source during natural disasters. Countries in the Asia-Pacific, prone to events like typhoons and earthquakes, can deploy microgrids to ensure continuous power supply for emergency services, hospitals, and evacuation centers. Microgrids play a role in rural electrification initiatives, bringing electricity to off-grid or underserved rural areas. In parts of the Asia-Pacific region where rural electrification is a priority, microgrids help bridge the energy access gap, improving the quality of life and supporting economic activities. Microgrids are deployed in industrial zones and commercial areas to enhance energy reliability, reduce downtime, and manage electricity costs. In rapidly developing economies of the Asia-Pacific, microgrids offer industrial and commercial facilities a way to optimize energy use, integrate renewables, and ensure uninterrupted operations.

COMPETITIVE ANALYSIS

The global Microgrid market is reasonably competitive with mergers, acquisitions, and product launches. See some of the major key players in the market.

Hitachi Energy Ltd

General Electric Company

In January 2024, GE Vernova’s Nuclear business, GE Hitachi, selected for UK Future Nuclear Enabling Fund.

Siemens AG

In May 2024, Siemens acquired Mass-Tech Controls’ EV division, expanding emobility offering in India. Acquisition to strengthen Siemens’ capability to address fast-growing demand for electric vehicle charging infrastructure in India, expand local market presence, enable creation of export hub

Eaton Corporation PLC

Honeywell International Inc.

Toshiba Corp.

Schneider Electric SE

Standard Microgrid Inc.

ENGIE EPS SA

Electric Co.

SCOPE OF THE REPORT

By Type

Custom Microgrid

Remote Power Systems

Other Types

By Application

Institutional Sites

Commercial Facilities

Remote - Off - Grid Communities

Others

By Region

North America (the United States & Canada)

Europe (Germany, UK, France, Spain, Italy, and the Rest of Europe)

Asia Pacific (China, Japan, India, and Rest of Asia Pacific)

Rest of the World (the Middle East & Africa, and Latin America)

KEY REASONS TO PURCHASE THIS REPORT

It provides a technological development map over time to understand the industry’s growth rate and indicates how the Microgrid market is evolving.

The report offers a dynamic method to various factors that drive or restrain the growth of the market and specifies which Microgrid submarket will be the main driver of the overall market from 2024 to 2032.

It renders a definite analysis of changing competitive dynamics and stipulates the leading players and what are their prospects over the forecast period.

It builds a nine-year estimate based on how the market is predicted to grow and shows what will market shares of the global region change by 2032 and which country will lead the market in 2032. Show more