The main objective of the HyCARE project is the development of a prototype hydrogen storage tank with use of a solid-state hydrogen carrier on large scale. The tank will be based on an innovative concept, joining hydrogen and heat storage, in order to improve energy efficiency of the whole system. The developed tank will be installed in the site of ENGIE LAB CRIGEN, which is a research and operational expertise center dedicated to gas, new energy sources and emerging technologies. The center and its 350 staff are located at Plaine Saint-Denis and Alfortville in the Paris Region (F). In particular, the solid-state hydrogen tank will be installed in a Living Lab aimed to develop and explore innovative energy storage solutions. The developed tank will be joined with a PEM electrolyzer as hydrogen provider and a PEM fuel cell as hydrogen user. The following goals are planned in HyCARE: - High quantity of stored hydrogen >= 50 kg - Low pressure < 50 bar and low temperature < 100°C - Low foot print, comparable to liquid hydrogen storage - Innovative design - Hydrogen storage coupled with thermal energy storage - Improved energy efficiency - Integration with an electrolyser (EL) and a fuel cell (FC) - Demonstration in real application - Improved safety - Techno-economical evaluation of the innovative solution - Analysis of the environmental impact via Life Cycle Analysis (LCA) - Exploitation of possible industrial applications - Dissemination of results at various levels - Engagement of local people and institution in the demonstration site

SusPIRE project assimilates in its conception the sustainable energy use challenge described in the European SETPLAN and in SPIRE road map. It addresses its efforts to energy intensive industries and within this segment market to energy recovery from residual heat streams. To achieve this goal a two clearly differentiated working areas will be key aspects of this project. Technology area will include the development of materials and equipments. New Heat Transfer Fluids (HTF) and Phase Change Materials (PCM) will be the base for manufacture high efficiency heat exchangers in terms of energy capture and storage. Two Borehole Thermal Energy Storage (BTE) areas(low temperature range (30-50ºC) and medium (50-80ºC) will support a energy cascading concept where energy will be sequentially used and finally stored for further use or commercialized to third parties. The methodology aspects of this projects wants to establish a framework to foster the energy commercialization of surplus energy . Living areas , symbiosis with other companies in industrial parks, sports centers.. will beneficiate from cheaper energy, environmental impact reduction and social acceptance of energy intensive industrial activities. The coordination of the manufacturing and the energy recovery processes will be carried out by means of a smart methodology. A protocol definition software will deploy actions to create best practices in terms of process adjustment and operating instructions. Management concepts based on energy recovery rate as Key Process Indicator (KPI), will be integrated into the decision making mechanism of the company assuring permanent advances in this field of activity in forthcoming years.