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Melodia Lucass bilde

Melodia Lucas

Ph.d.-kandidat, R&D ingeniør (Gexcon)
  • E-postmelodia.lucas@uib.no
  • Besøksadresse
    Allégaten 55
    5007 Bergen
  • Postadresse
    Postboks 7803
    5020 Bergen
Vitenskapelig artikkel
  • Vis forfatter(e) (2023). CFD modelling of hydrogen and hydrogen-methane explosions – Analysis of varying concentration and reduced oxygen atmospheres. Journal of Loss Prevention in the Process Industries.
  • Vis forfatter(e) (2022). CFD Analysis of Explosions with Hydrogen-Methane-Air Mixtures in Congested Geometries. Chemical Engineering Transactions. 163-168.
  • Vis forfatter(e) (2021). Assessing the influence of real releases on explosions: Selected results from large-scale experiments. Journal of Loss Prevention in the Process Industries.
  • Vis forfatter(e) (2020). Simulating vented hydrogen deflagrations: Improved modelling in the CFD tool FLACS-hydrogen. International Journal of Hydrogen Energy.
  • Vis forfatter(e) (2019). Eulerian-Eulerian model for photothermal energy conversion in nanofluids. AIP Conference Proceedings.

Se fullstendig oversikt over publikasjoner i CRIStin.

Lucas, M.; Hisken, H.; Skjold, T.; Arntzen, B.J. (2022). CFD Analysis of Explosions with Hydrogen-Methane-Air Mixtures in Congested Geometries. Chemical Engineering Transactions, 20: 163-168. DOI: https://doi.org/10.3303/cet2290028

Lucas, M., Atanga, G., Hisken, H., Mauri, L. & Skjold, T. (2021). Simulating vented hydrogen deflagrations: Improved modelling in the CFD tool FLACS-Hydrogen. International Journal of Hydrogen Energy, 46: 12464-12473. DOI: https://doi.org/10.1016/j.ijhydene.2020.09.073

Lucas, M.; Hisken, H.; Skjold, T. (2020). Computational fluid dynamics simulations of hydrogen releases and vented deflagrations in large enclosures. Journal of Loss Prevention in the Process Industries, 63: 103999. DOI: https://doi.org/10.1016/j.jlp.2019.103999 

Improved modelling of hydrogen explosions (PhD project funded by the Research Council of Norway with projet number 317782)

Results from consequence models that have been developed to handle hydrogen applications specifically, can in principle be used to support the design process. The consequence model FLACS is based on computational fluid dynamics, and is developed by Gexcon AS. The capability of FLACS to represent the consequences of accident scenarios involving hydrogen has been developed as part of several research programs. However, several of these initiatives have also uncovered limitations in the predictive capabilities of the model. For example, the predicted reactivity for a range of concentrations of hydrogen (when mixed with air) has been found to be overly conservative in the present commercial version of FLACS. A combustion model that alleviates this problem exists in-house in Gexcon, however, this model requires further development to be sufficiently general. Furthermore, the present version of FLACS can only account for the mitigating effect by introducing additional nitrogen to the atmosphere, while it would be highly relevant to also represent the effect of water, CO2, and various types of chemical inhibitors. The primary objective of the doctoral project is therefore to develop a general framework for modelling burning velocities of gas mixtures containing hydrogen in FLACS, and to demonstrate improved accuracy of model predictions of accident scenarios relevant for hydrogen installations.