Description du projet
Donner un souffle d’énergie à l’ammoniac renouvelable
L’usage de l’ammoniac vert, fabriqué grâce à un procédé sans la moindre émission de CO2 et 100 % renouvelable, est très répandu pour produire des engrais agricoles. Sa densité volumique énergétique est presque deux fois supérieure à celle de l’hydrogène, et il est beaucoup plus facile de le transporter, de le stocker et de le distribuer. Le projet HiPowAR, financé par l’UE, va développer un réacteur pour convertir directement l’énergie du combustible à base d’ammoniac en électricité. Plus précisément, il mettra au point et validera un nouveau procédé basé sur un réacteur à membrane, simple et moins onéreux qu’une pile à combustible à oxyde solide. L’objectif consiste à promouvoir l’acceptation de l’ammoniac comme combustible de synthèse sans émissions de CO2, en encourageant l’adoption de technologies d’alimentation à l’ammoniac.
Objectif
Renewable ammonia is considered increasingly as a carbon-free green fuel opening up the path to a new nitrogen-based energy economy. Its energy density by volume is nearly twofold compared to hydrogen with easier shipping, storage and distribution. As the market grows due to efforts of various companies (e.g. YARA) into greening the production process, the distribution routes for importing ammonia and ammonia fueling technologies will follow suit. The proposal shall promote the acceptance of ammonia as a synthetic fuel without CO2 emissions. It focuses on a breakthrough in the direct energy conversion from NH3 fuel to power. For that purpose, a new promising process based on a membrane reactor will be realized and characterized experimentally. The process is comparable to a fuel cell with an inner short circuit but without any typical electrical interconnections avoiding electrical losses. Therefore, the system is much simpler and less expensive than a SOFC (Solid oxide fuel cell). The chemical energy of liquid ammonia is converted into a highly compressed gas (N2 + H2O) through a so-called self-pressurizing combustion in a pressure vessel with constant volume. The power is collected by the work of expansion using a gas expander, e.g. in a gas expander like a steam turbine or engine. Since high pressure enhances the total process efficiency, membrane reactor consists of tubular ceramic membranes able to withstand very high outside gas pressure. The membranes are conductive for oxide ions and electronic charge carriers and realize the inner electrical short circuit in a single element. They are also called MIEC (Mixed Ionic Electronic Conductor), ITM (Ion transporting Membranes), OTM (Oxygen transporting Membranes). Comparable to the fuel cell, thermodynamic efficiency of the process is not restricted. In contrast to internal combustion engines, steam power plants or other processes based on cycling of a working fluid, a much higher efficiency is expected.
Champ scientifique
- natural scienceschemical scienceselectrochemistryelectrolysis
- engineering and technologyenvironmental engineeringenergy and fuelssynthetic fuels
- engineering and technologyenvironmental engineeringenergy and fuelsfuel cells
- engineering and technologyenvironmental engineeringenergy and fuelsenergy conversion
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