Summary

Virtual Power Plant Market Growth & Trends

The global virtual power plant market size is expected to reach USD 16.65 billion by 2030, growing at a CAGR of 22.0% from 2023 to 2030, according to a new report by Grand View Research, Inc. Virtual power plants (VPPs) can play a significant role in reducing carbon emissions in the energy sector. Virtual power plants can be programmed to prioritize the use of clean energy sources and minimize the use of carbon-intensive generation sources, when possible, thus lowering overall emissions associated with electricity production. Through advanced control algorithms and real-time monitoring, virtual power plants can optimize energy production and consumption, reducing energy waste and associated emissions.

Virtual power plants offer several benefits to customers, both residential and commercial, by providing them with greater control over their energy consumption and cost savings. Customers can reduce their energy bills by participating in virtual power plant programs. Virtual power plant enables customers to take advantage of time-of-use pricing and demand response opportunities, allowing them to shift energy consumption to lower-cost periods and avoid peak-demand charges. Virtual power plants often come with advanced energy management tools and applications that allow customers to monitor and control their energy usage in real time.

Stringent government regulations can play a significant role in driving the use of virtual power plants. Regulations aimed at reducing greenhouse gas emissions often incentivize adopting clean energy technologies. Virtual power plants, by enabling the integration of renewables and demand response, contribute to reducing carbon emissions in the energy sector, aligning with government emission reduction goals. Governments often invest in grid modernization efforts to improve the overall efficiency and intelligence of the power grid.

The COVID-19 pandemic underscored the importance of digitalization in the energy sector. VPPs leverage advanced analytics, IoT sensors, and real-time data to optimize energy generation and consumption. As organizations sought to minimize operational disruptions and reduce costs during the pandemic, they turned to VPPs to maximize the use of their existing energy assets.

Virtual Power Plant Market Report Highlights

• Based on technology, the demand response segment dominated the market in 2022. Demand response aligns with the broader sustainability goals, making it a critical driver of the VPP market's growth as the world increasingly transitions towards greener and more responsive energy systems

• Based on end-user, the industrial segment dominated the market in 2022 due to its substantial energy demands, complex energy management needs, and the potential for significant cost savings and carbon footprint reduction through VPP adoption

• North America dominated the market in 2022. Many North American states and provinces have set ambitious clean energy and emission reduction targets. Virtual power plants play a crucial role in achieving these goals by facilitating the integration of renewables and improving grid reliability. Moreover, North America has a diverse energy landscape with varying energy sources, grid configurations, and energy challenges, and virtual power plants can provide flexible solutions that address these diverse needs

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Table of Contents

Table of Contents

Chapter 1. Methodology and Scope
1.1. Market Segmentation & Scope
1.2. Market Definitions
1.3. Information Procurement
1.4. Information Analysis
1.4.1. Market Formulation & Data Visualization
1.4.2. Data Validation & Publishing
1.5. Research Scope and Assumptions
1.6. List of Data Sources
Chapter 2. Executive Summary
2.1. Market Outlook
2.2. Segmental Outlook
2.3. Competitive Landscape Snapshot
Chapter 3. Market Variables, Trends, and Scope
3.1. Market Lineage Outlook
3.2. Industry Value Chain Analysis
3.3. Market Dynamics
3.3.1. Market Driver Impact Analysis
3.3.1.1. Expansion of renewable energy resources
3.3.1.2. The continual expansion of capacity renewable energy plants
3.3.2. Market Challenge Impact Analysis
3.3.2.1. Challenge of integrating diverse and decentralized energy resources into a unified platform
3.3.3. Market Opportunity Impact Analysis
3.3.3.1. VPPs' role in grid modernization and the transition to renewable energy sources
3.4. Industry Analysis Tools
3.4.1. Porter’s Analysis
3.4.2. PESTEL Analysis
Chapter 4. Virtual Power Plant Market: Technology Estimates & Trend Analysis
4.1. Technology Movement Analysis & Market Share, 2022 & 2030
4.2. Virtual Power Plants Market Estimates & Forecast, By Technology
4.2.1. Distributed Energy Resource
4.2.2. Demand Response
4.2.3. Mixed Asset
Chapter 5. Virtual Power Plant Market: End-user Estimates & Trend Analysis
5.1. End-user Movement Analysis & Market Share, 2022 & 2030
5.2. Virtual Power Plant Market Estimates & Forecast, By End-user
5.2.1. Industrial
5.2.2. Commercial
5.2.3. Residential
Chapter 6. Virtual Power Plant Market: Regional Estimates & Trend Analysis
6.1. Virtual Power Plant Market: Regional Outlook
6.2. North America
6.2.1. North America virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.2.2. U.S.
6.2.2.1. U.S. virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.2.3. Canada
6.2.3.1. Canada virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.3. Europe
6.3.1. Europe virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.3.2. UK
6.3.2.1. UK virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.3.3. Germany
6.3.3.1. Germany virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.3.4. France
6.3.4.1. France virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.4. Asia Pacific
6.4.1. Asia Pacific virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.4.2. China
6.4.2.1. China virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.4.3. India
6.4.3.1. India virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.4.4. Japan
6.4.4.1. Japan virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.4.5. South Korea
6.4.5.1. South Korea virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.4.6. Australia
6.4.6.1. Australia virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.5. Latin America
6.5.1. Latin America virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.5.2. Brazil
6.5.2.1. Brazil virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.5.3. Mexico
6.5.3.1. Mexico virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.6. Middle East & Africa
6.6.1. Middle East & Africa virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.6.2. Kingdom of Saudi Arabia (KSA)
6.6.2.1. Kingdom of Saudi Arabia (KSA) virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.6.3. UAE
6.6.3.1. UAE virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
6.6.4. South Arica
6.6.4.1. South Africa virtual power plant market estimates & forecasts, 2017 - 2030 (USD Million)
Chapter 7. Competitive Landscape
7.1. Company Categorization
7.2. Participant’s Overview
7.2.1. Siemens
7.2.2. Toshiba Energy Systems & Solutions
7.2.3. Next Kraftwerke
7.2.4. Hitachi, Ltd.
7.2.5. ABB
7.2.6. Tesla
7.2.7. AutoGrid Systems, Inc.
7.2.8. Limejump Limited
7.2.9. Sunverge Energy, Inc.
7.2.10. Centrica
7.3. Financial Performance
7.4. Product Benchmarking
7.5. Company Market Positioning
7.6. Company Market Share Analysis, 2022
7.7. Company Heat Map Analysis
7.8. Strategy Mapping
7.8.1. Expansion
7.8.2. Collaborations
7.8.3. Mergers & Acquisitions
7.8.4. New Product Launches
7.8.5. Partnerships
7.8.6. Others