Tesi etd-02282023-135354 |
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Tipo di tesi
Tesi di laurea magistrale
Autore
ROTUNDO, ROCCO
URN
etd-02282023-135354
Titolo
Numerical investigation of hazard potential of small pulsed releases of hydrogen in a confined and constrained environment
Dipartimento
INGEGNERIA DELL'ENERGIA, DEI SISTEMI, DEL TERRITORIO E DELLE COSTRUZIONI
Corso di studi
INGEGNERIA ENERGETICA
Relatori
relatore Prof. Desideri, Umberto
correlatore Ing. Melideo, Daniele
correlatore Ing. Melideo, Daniele
Parole chiave
- CFD
- hydrogen dispersion in confined spaces
- safety analysis
- ventilated container
Data inizio appello
20/04/2023
Consultabilità
Non consultabile
Data di rilascio
20/04/2093
Riassunto
In recent years, new chemical release agents based on silane are being used in the tire industry. Silane is an inorganic chemical compound consisting of a silicon backbone and hydrogen, that can be thermally decomposed into high-purity silicon and hydrogen. If silane is stored and transported in Intermediate Bulk Containers (IBCs) equipped with safety valves in vented semi-confined spaces, such as ISO-Containers, hydrogen can be accumulated and mixture with air can become flammable or even explosive. A CFD analysis using the GASFLOW-MPI code has been carried out to assess the hydrogen risk inside the vented containers. Two types of containers with different natural ventilation systems were investigated under various hypothetical accident scenarios. A continuous release of hydrogen due to the chemical decomposition of silane from IBCs was studied as the reference case. The effect of the safety valves on hydrogen accumulation in the container which results in small pulsed releases of hydrogen was investigated. The external effects of the sun and wind on hydrogen distribution and ventilation were also evaluated. The results can provide detailed information on hydrogen dispersion and mixing within the vented enclosures and used to evaluate the hydrogen risks of flammability. Based on the assumptions used in this study, it indicates that the geometry of ventilation openings plays a key role in the efficiency of the indoor air exchange process. In addition, the use of safety valves makes it possible to reduce the concentration of hydrogen. The effect of the sun, which results in a temperature difference between two container walls, allows a near-perfect mixing of hydrogen and air, which helps to obtain a concentration lower in the first hours. But the best results for the venting process are obtained with the wind that can drive the mixture to the downwind wall vent holes.
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