February 2025 – i-Stentore

Demonstration and Evaluation Activities in i-STENTORE

i-STENTORE introduces an umbrella framework aiming to showcase stand-alone and hybrid storage solutions, highlighting the multi-purpose use of storage, not only as an energy buffer, but also as an active grid component capable of providing services and contributing to grid resilience, stability and efficient operation. The overall i-STENTORE framework will be applied, implemented, and validated in 5 real-life demos, and 1 Living Lab, across 6 countries with different system and actor needs, economic conditions or different climates. The aim of these demos will be twofold: first, demonstrating the i-STENTORE storage technologies’ performance and architecture either as SASSs or HESSs. Second, creating proof of concept on the way that storage technologies can be transformed from passive “energy buffers” into valuable assets that can effectively interact with renewables, specific demand sectors and existing, established infrastructure, offering grid-supporting services.

Demonstration activities are meant to take place following a three-loop cycle structure that encompasses a Pre-demo phase (M5-M16) involving early technology assessment and experimentation, a Full Demo Operation phase (M21-M25), foreseeing the deployment of the complete i-STENTORE framework within controlled environments at the demo sites and targeting performance and usability testing, as well as a Large Scale Demo Operation phase (M30-M33), entailing the final demo validation, and thereby focusing on scalability testing.

In line with the demonstration activities’ goals and aspirations, evaluation in i-STENTORE will be multi-dimensional, addressing accordingly the different types of outcomes that will derive from the project demos. The specifics of the i-STENTORE demos evaluation, as well as the identification, definition and scheduling of all related activities are prescribed by the i-STENTORE Planning, Measurement and Verification Framework.

The Framework consists of four pillars, two horizontal, i.e. the “Planning” and “Measurement and Verification”, and two vertical ones, namely the “Context, Actors and Infrastructures” and “Risk Analysis and Assessment”. The Planning pillar involves the identification of the demo implementation activities, their structuring into the i-STENTORE double V-model – a V-model (Verification and Validation) approach that takes into account the existence of two demo operation phases, i.e. the Full Demo and Large Scale Demo Operation phases – as well as the integration of the timing dimension that results in the demos’ engagement and implementation plans, which act as the means for tracking and monitoring the demos’ status and progress.

The demo implementation activities are organized into four main streams, namely:

Preparatory activities: these have been initiated since the beginning of the project but will be present throughout the whole duration of the demos’ implementation, as they involve the demo engagement and implementation plans design or update (if applicable), the demo scenarios identification, the KPIs definition and update along with their baseline calculation, as well as the identification and analysis of demo-related risks.
Infrastructure-related activities: these refer to the procurement, installation, development, deployment and integration of the equipment, tools and services, necessary for each demo’s implementation.
Monitoring, Measurement and Evaluation activities: these make up the core of the demos’ implementation and involve operation and testing, data collection and results’ evaluation.
Reporting activities: these correspond to the preparation and compilation of each demo’s deliverables and reports.

The Measurement and Verification pillar, on the other hand, outlines all details around the evaluation of the i-STENTORE demos, namely the demo evaluation axes, the respective evaluation perspectives, as well as the data collection and evaluation methods. The demo evaluation axes include:

I. the demos’ actual implementation progress and outcomes

II. the novel stand alone or Hybrid Energy Storage Systems (HESS) to be implemented and

III. the digital services to be developed.

Axis I concerns the progress of the demo activities, as well as the demo outputs themselves, the latter being systems, services, business models, collaborations or other outcomes. Axis II reflects the improved features and performance of the novel stand alone or hybrid energy storage systems to be implemented (as compared to the baseline energy storage infrastructure in place or the HESS individual components), whereas Axis III relates to more specific aspects of the digital services to be developed.

Evaluation perspectives in turn involve those of Completion, Effectiveness, Efficiency, Adequacy, Usability and Compatibility and are to be captured via Key Performance Indicators (KPIs) and questionnaire-based surveys. KPIs are metrics that derive from the demos’ characteristics and describe how well the latter are progressing according to predefined standards and goals. They are accompanied by a baseline assessment as well as an estimated target value, which are intended to facilitate the quantification of impact of the energy storage technologies and innovative solutions introduced by the i-STENTORE project, enabling the comparison of the ‘as-is’ and ‘to-be’ circumstances for each demo.

KPIs further follow a classification scheme which enables their categorization into technological (T), economic/financial (EC/F), business (B), environmental (EN), social (S) and governance (G) depending on their scope, as well as into quantitative and qualitative depending on their nature. This classification aims at facilitating the analysis and highlighting specific aspects, depending on the evaluation perspective of interest.

The two vertical pillars, “Context, Actors and Infrastructures” and “Risks Analysis and Assessment” are complementary pillars, allowing determining the context and circumstances under which the demos will operate, and thereby providing input regarding their planning and execution as well as the targets and goals for their evaluation.

Author(s): Ourania Markaki (National Technical University of Athens)

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The importance of Replication and Scalability in i STENTORE

The global energy landscape is changing rapidly as nations work to integrate renewable sources, reduce carbon emissions, and strengthen resilience in the sector. This transformation is supported by the i-STENTORE project, a pioneering European initiative that showcases innovative Hybrid Energy Storage Systems (HESS). A crucial factor for the project’s success depends on its commitment to replication and scalability. These concepts ensure that the project’s outcomes can expand and adapt to diverse scenarios increasing their impact across Europe. This section explores the importance of replication and scalability and highlights how i-STENTORE aligns with the European Union’s broader sustainability goals.

The value of Replication and Scalability

Replication and scalability are more than technical objectives, they are the foundation of systemic transformation in the energy sector. Replication enables the application of i STENTORE’s innovative solutions and lessons learnt across different countries, while scalability allows these to transition from pilot projects to full-scale deployments. These principles accelerate the transition to cleaner systems, ensuring successful projects can be expanded to achieve maximum impact.

Collaboration among partners is essential to achieving replication and scalability. By bringing together partners, i-STENTORE fosters knowledge exchange, regulatory alignment, and best practice adoption. This collective effort helps overcome regional challenges, facilitate the integration of energy storage solutions, and accelerate deployment. Moreover, strong partnerships enhance co-development and co-financing opportunities, bridging the gap between innovation and real-world application. The diverse expertise and resources of these collaborations enhance technical and economic feasibility while building trust and acceptance within communities, ensuring long-term sustainability. Through this cooperative approach, i-STENTORE is shaping a more resilient and interconnected European energy landscape.

For the EU, achieving carbon neutrality by 2050 under the European Green Deal relies heavily on scalable and replicable solutions. These approaches minimize resource waste, maximize financial and technological efficiency, and accelerate the adoption of renewable technologies. They also improve grid stability, accommodate variable power sources like solar and wind, and decrease reliance on fossil fuels.

By considering diverse regulatory frameworks, i-STENTORE’s approach to replication fosters compliance with EU directives, such as the Renewable Energy Directive (RED II). This ensures better policy alignment and makes it easier to implement these solutions across the EU. Additionally, scalable systems contribute to economic growth by creating jobs, developing local supply chains, and lowering costs for consumers. When solutions are designed to address regional needs while aligning with EU goals, they not only meet local energy demands but also enhance innovation and resilience across the continent.

The i-STENTORE approach to Replication and Scalability

The i-STENTORE project employs a robust strategy to make its storage solutions adaptable and widely applicable. By testing its technologies in diverse environments,

such as urban, rural, and industrial, the project ensures their versatility. For example, molten glass thermal storage systems and agri-photovoltaic installations with energy storage capabilities are being evaluated under different conditions to guarantee their adaptability.

A key element of the project is its emphasis on knowledge sharing and stakeholder involvement. Through the establishment of Living Lab, i-STENTORE brings together local stakeholders, policymakers, and technical experts to foster collaboration. These engagements ensure that solutions are not only effective but also tailored to the unique requirements of each region. By providing stakeholders with the knowledge and tools to implement these technologies, the project builds local capacity and promotes long term independence.

To track progress and optimize solutions, i-STENTORE employs an evaluation framework based on technological, economic, environmental, social, and governance dimensions, providing a holistic assessment of the project’s impact. This structured evaluation helps identify areas for improvement and highlights the benefits of i-STENTORE’s technologies, making them more appealing to potential adopters.

One notable example of i-STENTORE’s approach is its regional multiplier study in Western Macedonia, Greece. The region, historically dependent on lignite-based energy, faces significant challenges in transitioning to renewables. By addressing these challenges with tailored solutions, the project demonstrates how its technologies can drive regional transformations. The study serves as a practical model for replication, showcasing how innovative storage solutions can be adapted to address local requirements and accelerate the shift to clean energy.

Aligning with EU policies and strategies

Adherence to EU regulations is central to i-STENTORE’s mission, ensuring its energy storage solutions contribute to Europe’s broader sustainability and climate-neutrality goals. By focusing on renewable integration, decarbonization, and system flexibility, the project aligns with key EU strategies to address the challenges of transitioning to clean systems. Through innovative Hybrid Energy Storage Systems (HESS) and a commitment to scalability, i-STENTORE not only supports policy objectives but also provides practical, impactful solutions that drive Europe’s energy transition forward.

Moreover, i-STENTORE places significant emphasis on building a strong business case for its energy storage solutions. By demonstrating their cost-effectiveness, operational efficiency, and long-term benefits, the project attracts both public and private investments. This economic viability ensures that the solutions are financially sustainable, paving the way for broader adoption across Europe.

In summary, replication and scalability are at the core of i-STENTORE’s mission to revolutionize energy storage. By focusing on these principles, the project ensures its solutions move beyond pilot phases and make a significant contribution to Europe’s clean energy transition.

These efforts demonstrate the transformative potential of scalable and replicable storage systems. By combining technological innovation with practical applications and policy alignment, i-STENTORE sets a standard for future initiatives. The project’s work

highlights the importance of creating solutions that can adapt to diverse needs while maintaining a focus on sustainability, resilience, and equity. Through these efforts, i STENTORE paves the way for a sustainable future, ensuring its impact endures for generations to come.

Author(s): Vagia Gaidatzi, Junior Project Manager (CluBE), Ioanna Mikrouli Junior Project Manager (CluBE)

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