AGISTIN

The Advanced Grid Interfaces for innovative STorage INtegration (AGISTIN) project addresses urgent challenges for industrial grid users, grid operators, renewables developers, storage manufacturers by:

Reducing pressure on grid connection capacity and grid reinforcement requirements for new renewables and industrial demand, beneficial to all grid users and grid operators.
Enabling major classes of industrial grid users to economically integrate significantly more renewables on-site than traditional integration approaches, through DC coupling.
Supporting the grid by providing advanced grid services such as grid forming control, fast frequency response and balancing flexibility that supports grid operators in operating low inertia grids and reducing curtailment of renewables within the emerging European market framework.

Avoiding delay in the electrification and decarbonisation of society using increasingly sustainable approaches, resulting in Mt of CO2 avoided per annum.

As the need for innovation in the integration of energy storage is shared across grid and grid users, AGISTIN proposes to develop grid integration architectures for energy storage with on-site renewables and emerging DC end uses. This follows the DC coupling approach considered in current PV + storage hybrids, extending it to include end use, grid users and system integrators.

As such, industrial grid users can benefit from the avoidance of additional hardware, reducing costs, improved operational efficiency, flexibility and self-consumption as compared to the AC connection approach. The project will develop control algorithms to coordinate between all three asset classes that will be open sourced for exploitation by system integrators and power electronics OEMs.

The AGISTIN solutions will be simulated and tested in three separate laboratory tests.

The German laboratory test will test the design’s controls and functionality on a fast-charging application for electric vehicles;
The Spanish laboratory test will test the concept on a pumping system before implementation in a real irrigation system;
The German laboratory test will test the developed solution for an electrolyzer application using a dynamic grid emulator.

The refined design will then be implemented in two field demonstrations:

The Spanish demonstration pilot will demonstrate the potential of using irrigation systems as an energy storage medium.
The Dutch demonstration pilot will demonstrate the use of energy storage and advanced control to maximize the use of renewables on a renewable hydrogen generation facility.

Project partners

EPRI Europe DAC
UNIVERSITY OF KASSEL
RTE
Fraunhofer
CARTIF
CIEMAT
SHELL
POLYTECHNIC UNIVERSITY OF CATALONIA
GEYSER BATTERIES
INFRAESTRUCTURES DE CATALUNYA
EASE
RINA
ETH Zurich
TeknoCEA

Financing

Funded by: European Union

Project duration: 1/2023 - 12/2026

Scope: EU

Microfocus: Controlling flexibilities
Evaluation of technical solutions to offer and trigger flexibilities

Macrofocus: Technical realization
Evaluation of technologies to orchestrate a (high) number of flexibilities by using e.g. software services

Degree of Prosumer & consumer involvement: Low
Rough evaluation of their needs and expectations as flexibility providers within the project

Technical Readiness Level (TRL):

Market Readiness Level (MRL):