Technologies for optimized methanol combustion
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It refers to the Task 3.3. Report on the design and specifications of the systems layout and components integrations. The aim is to design a new burner that operates efficiently in MILD/flameless combustion while minimizing pollutant emissions for an air-cooled furnace in a Brayton cycle.
Force and heat transfer models
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It refers to the Task 2.3. Implementation of models for forces and heat transfer for different cylindrical biomass granulates. THe aim of the deliverable is, depending on supplied fuel, to achieve highest H2/CO ratio in syngas before introducing to the plasma reactor.
Enhanced Brayton cycle theoretical development
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It refers to the Task 4.1. Report on the methodology, characterization and results of a theoretical study of a high-temperature air Brayton cycle with regeneration. Provides basic design parameters for thedevelopment of key devices (heat exchanger, compressor).
Technologies for optimized methanol production
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It refers to the Task 2.5. Report on the methodology, characterization and results of the experimental stand of methanol production. The key issue is the selection and modification of appropriate catalysts.
Modelling and experimental burner optimization
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It refers to the Task 3.2. Report on the methodology, characterization and results of the virtual and experimental prototyping of the methanol burner. The aim will be gaining a deeper understanding of methanol combustion to guide the design of efficient low-emission burner concepts by means of predictive methods and measurement tools for analyzing practical systems.
Multi-class Largrangian approach
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It refers to the Task 2.3. Implementation of different particle classes (i.e., biomass, biochar and ash particles) in the Lagrandian approach. The aim is to extend the point-particle LES-Euler/Lagrange approach with the energy equation and the particle temperature equation, as well as the associated two-way coupling.