BOR4STORE: Development of solid state hydrogen storage from fundamentals to application
BOR4STORE Final Event - Posters
Renewable Energy → H2 → Boronhydride based tank → Net independent Power
Boron Compound ↑
Overview and Targets
BOR4STORE follows an integrated, multidisciplinary approach for the development and testing of novel, optimised and cost-efficient boron hydride based H2 storage materials with superior performance (capacity more than 8 wt.% and 80 kg H2/m3) for specific fuel cell applications.
Building on the results of past and ongoing EC funded projects on H2 storage, BOR4STORE aspires to tackle the S&T challenges that still hinder the practical use of the extremely attractive boron hydrides. The technical objectives of the project reflect an innovative and carefully designed strategy involving:
(a) new methods for the synthesis and modification of stable and unstable boron hydrides, as well as their combinations resulting in Reactive Hydride Composites and eutectic mixtures,
(b) systematic and rationalised investigation of the effect of special catalysts and additives, and
(c) adaptation of scaffolding concepts,
in an attempt to use all possible ways for understanding and tailoring the key aspects of boron hydrides H2 storage performance (storage capacity, reaction pathways and enthalpies, hydrogenation/dehydrogenation kinetics, cycling stability (98% preserved capacity over 500 cycles)).
The most promising material(s), to be indicated by a rigorous downselection process, will be used for the development of a prototype laboratory H2 storage system that will be integrated and tested in connection with a 1 kW SOFC (representative for fuel cell applications e.g. for stationary power supply). Special attention will be given, practically for the first time, to significant cost reduction by pursuing cost efficient material synthesis and processing methods (target material price <50 EUR /kg) but also by investigating the level of tolerable impurities of the new materials (target system price 500 EUR /kg of stored H2).