Vehicle to Grid (V2G) Public Charger Market Analysis by Charger Type (AC, DC), Deployment Applicatio...

Description

Vehicle to Grid (V2G) Public Charger Market Overview

The Vehicle-to-Grid (V2G) public charging market represents a pivotal element within the electric mobility industry. This innovative technology allows electric vehicles to not only receive power from the utility grid but also to return surplus stored energy, thereby establishing them as adaptable, mobile energy storage solutions. The overall V2G infrastructure market, which includes both hardware and software components, is presently valued at several billion US dollars annually, with forecasts suggesting a trajectory of continuous growth over the forthcoming decade.

Current market trends indicate a pronounced emphasis on bidirectional technology, which is essential for V2G operations. Direct Current (DC) bidirectional charging stands out as a significant advancement, providing greater efficiency for power transfer in comparison to Alternating Current (AC) systems. The combination of public V2G charging with renewable energy sources is a key focus area, enabling electric vehicles to capture excess solar or wind energy and contribute to grid stability. Collaborations between automakers and utility companies are crucial, as they seek to develop standardized protocols and formulate effective business models for utilizing parked vehicles to bolster energy networks. The increasing number of Battery Electric Vehicles (BEVs), characterized by their enhanced battery capacities, plays a vital role in unlocking the full potential of this public infrastructure.

The global Vehicle to Grid (V2G) Public Charger Market size was valued at US$ 0.20 Billion in 2025 and is poised to grow from US$ 0.26 Billion in 2026 to 1.41 Billion by 2033, growing at a CAGR of 45.5% in the forecast period (2026-2033)

Vehicle to Grid (V2G) Public Charger Market Impact on Industry 

The V2G public charging market is fundamentally transforming the electric vehicle (EV) sector, altering the view of EVs from mere energy consumers to significant grid assets. This change requires enhanced collaboration among automakers, charging infrastructure providers, and software developers. For automakers, it necessitates the inclusion of full bidirectional capabilities and advanced battery management systems in new vehicle designs, which affects vehicle design and warranty agreements. Charger manufacturers are also impacted, as they must innovate to create sophisticated, higher-cost DC bidirectional hardware. The market encourages new revenue models for EV owners and fleet operators, enabling them to generate income by offering grid services, which serves as an incentive for broader EV adoption and increased use of public charging infrastructure.

The most significant impact of this technology is on the energy and utility sectors, where V2G public charging is becoming a vital element of contemporary grid management. Publicly accessible V2G points consolidate vehicle batteries into virtual power plants (VPPs), providing utility companies with a flexible and distributed capacity resource for balancing supply and demand. This functionality is essential for optimizing the integration of intermittent renewable energy sources such as wind and solar. By permitting parked vehicles to discharge during peak demand periods, V2G aids in postponing expensive infrastructure upgrades to local power distribution networks, facilitating a shift towards a more resilient, decentralized, and intelligent energy ecosystem.

Vehicle to Grid (V2G) Public Charger Market Dynamics:

Vehicle to Grid (V2G) Public Charger Market Drivers

A primary factor driving the V2G public charger market is the swift global uptake of electric vehicles (EVs), which is significantly increasing the availability of distributed energy storage units—EV batteries—for grid services. This rise in EV adoption is generating an urgent demand for sophisticated energy management solutions like V2G to alleviate pressure on local electricity grids. Additionally, the necessity for improved power grid stability serves as a crucial motivator. V2G enables public chargers to operate as two-way connections, allowing EVs to return stored energy to the grid during peak demand or unforeseen outages, a feature that utilities highly appreciate for reducing grid congestion and ensuring reliable service. The drive for decarbonized energy services by businesses and governments, along with heightened public awareness regarding energy conservation, further bolsters V2G, as it plays a vital role in the effective utilization of intermittent clean energy sources such as solar and wind power.

Challenges

A notable obstacle for the V2G public charger market is the apprehension regarding battery degradation among EV owners. Consumers are concerned that the frequent charging and discharging cycles associated with V2G operations may reduce their vehicle’s battery lifespan and lower its resale value, which can lead to reluctance in engaging with V2G programs. Another significant challenge is the absence of standardized communication protocols among various EV models, charging stations, and grid operators. The lack of a universally accepted standard, such as a well-established ISO 15118 implementation, results in interoperability challenges that hinder the deployment and smooth integration of V2G networks. Lastly, the intricacy of incorporating V2G into the existing physical grid infrastructure and utility operational systems poses a practical challenge, often involving lengthy and complex permitting and deployment processes.

Opportunity

A significant market opportunity exists within the rapidly growing field of electric fleet management. Commercial and public fleets, including taxis, buses, and delivery vans, typically have predictable parking and driving patterns, rendering them ideal candidates for Vehicle-to-Grid (V2G) programs with high utilization rates. These fleets can be managed centrally as integrated virtual power plants, delivering dependable, large-scale grid services while generating substantial additional revenue for fleet operators. Another substantial opportunity lies in the creation of ancillary grid services that extend beyond mere energy time-shifting. V2G-enabled public charging stations can provide high-value services such as frequency regulation and reserve capacity, which are essential for ensuring the power quality and dynamic stability of the grid. This development paves the way for new and profitable business models for owners of public charging networks, enabling them to monetize these services to utility companies.

The Vehicle to Grid (V2G) Public Charger Market Key Players: –

• Winline Technology
• NARI Technology
• Beijing SOJO Electric
• Magnum Cap
• Enphase
• CJNOO
• Shenzhen Auto Electric Power Plant
• ABB
• UUGreenPower
• EVBox
• Wallbox
• Infypower
• TELD

Recent Development:-

October 21, 2025 Bidirectional Energy, a software provider enabling EVs to serve as flexible energy resources, today announced in partnership with Wallbox (NYSE: WBX), a global provider of electric vehicle (“EV”) charging and energy management solutions, the launch of North America’s first multi-state bidirectional charging program, open to 180 homes across California and Connecticut.

June 25, 2025 Infypower is at the forefront of this transformation, offering a range of DC bidirectional charging solutions. As we roll out our next-gen V2H/V2G charging solutions, we’ve compiled the most frequently asked questions from experienced fleet operators, charge point operators (CPOs), and infrastructure installers to help you better understand our solutions.

Vehicle to Grid (V2G) Public Charger Market Regional Analysis: – 

Europe: The Leading Market Power

Europe has long been, and remains, a significant player in the V2G public charger sector. The region’s dominance is attributed to its proactive and thorough decarbonization initiatives, which emphasize the integration of renewable energy and the modernization of the grid. European nations have developed robust policy frameworks that include incentives, subsidies, and explicit regulatory requirements that promote the implementation of V2G technology. Countries such as the Netherlands, Germany, and the UK have been pioneers, conducting numerous successful V2G pilot programs that showcase the economic advantages and grid stability improvements. Europe boasts a well-developed and interconnected EV ecosystem, resulting in a substantial and accessible fleet of V2G-capable vehicles alongside an advanced smart grid infrastructure prepared to interact with bidirectional chargers. Given this solid groundwork and ongoing policy backing, Europe is frequently anticipated to maintain a significant market share in the near future, reinforcing its status as the leader in V2G adoption.

Asia Pacific: The Fastest Growing Region

The Asia Pacific (APAC) region is widely recognized as the area projected to demonstrate the highest Compound Annual Growth Rate (CAGR) throughout the forecast period, frequently reported with a growth rate between 34.2% and 34.6% for the overall V2G technology market. This remarkable growth is supported by several key factors. Nations such as China, Japan, and South Korea are witnessing an unprecedented and swift rise in electric vehicle (EV) sales, resulting in the largest and most rapidly growing EV fleet globally. Accelerated urbanization and substantial government investments in smart city projects and grid modernization initiatives create a conducive environment for V2G implementation. Additionally, the region’s substantial energy consumption and considerable dependence on variable renewable energy sources, especially solar, generate a pressing demand for the load balancing and energy storage solutions that V2G technology offers. Although Europe may currently hold the lead in total installed capacity, the vast scale of the EV market and infrastructure development in APAC will propel its remarkable growth rate, positioning it to emerge as the largest regional market by the conclusion of the forecast period.

North America: Accelerated Investment and Fleet Focus

North America, mainly propelled by the United States and Canada, is anticipated to experience substantial growth, characterized by vigorous market activity, especially in the public charging sector. The region is advantaged by increasing federal and state funding initiatives, including the National Electric Vehicle Infrastructure (NEVI) program and other supportive policies, which are starting to explicitly incorporate V2G capabilities as part of the next-generation infrastructure development. Although the primary emphasis has been on establishing foundational DC fast charging, there is a noticeable and expanding trend towards the integration of V2G, particularly within commercial and government fleets, such as electric school buses. Fleet operators are beginning to acknowledge the economic advantages of utilizing their stationary EVs for grid services. North America is projected to witness a robust CAGR, driven by considerable investments from public utilities and the private sector aimed at enhancing grid resilience and assimilating the rapidly expanding electric vehicle fleet into the energy network.

Vehicle to Grid (V2G) Public Charger Market Segmentation:

By Types (Charger Specification/Technology)

• By Charger Type
  • DC Fast V2G Chargers
  • AC V2G Chargers
  • Wireless Charging (Emerging)
• By Power Output (Public/Fast Charging)
  • 20kW and Below
  • 20-30kW
  • Above 30kW
• By Charging Type/Technology
  • Bidirectional Charging (V2G)
  • Unidirectional Charging (V1G/Smart Charging)

By Applications

• By Vehicle Segment
  • Passenger Cars (BEVs, PHEVs)
  • Commercial Cars (Taxis, Ride-Share Fleets)
  • Electric Bus/School Bus Fleets
  • Other Fleets (Logistics, Delivery)
• By End-User/Deployment
  • Public Charging Stations (e.g., Highway, Urban Hubs)
  • Fleet Charging Depots (e.g., Transit Authorities, Corporate Fleets)
  • Commercial Establishments (e.g., Shopping Malls, Parking Garages)
  • Workplace Charging (Often semi-public/fleet-focused)
• By Grid Service (Utility Application)
  • Frequency Regulation & Reserve
  • Time Shifting (Arbitrage)
  • Distribution Services (Voltage Support)
  • Emergency Backup

By Region

• North America
  • United States (U.S.)
  • Canada
  • Mexico
• Europe
  • Germany
  • United Kingdom (U.K.)
  • Netherlands
  • France
  • Nordics (Norway, Sweden, Denmark)
  • Rest of Europe
• Asia Pacific (APAC)
  • China
  • Japan
  • South Korea
  • India
  • Southeast Asia
  • Rest of APAC
• Latin America (LAMEA/RoW)
  • Brazil
  • Mexico
  • Rest of Latin America
• Middle East & Africa (LAMEA/RoW)
  • UAE
  • South Africa
  • Rest of MEA