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Author Soriano Hernández, Iván Gaspar |
Abstract Currently, several industrial sectors need real-time monitoring of hydrogen or its isotopes, such as occurs in high-temperature processes in the metallurgical industry or in future nuclear fusion technology. In response to the lack of commercial devices capable of on-site measurements given adverse operating conditions, prototypes of hydrogen sensors based on solid-state electrolytes have emerged. These materials have certain crystalline structures that have ionic conductivity, such as the perovskite type ceramic Sr(Ce0,9Zr0,1)0,95Yb0,05O3-δ, selected for the development of this Master's Thesis due to its promising properties related to the conductivity of the proton. With this, a study begins on the influence of the initial particle size of this ceramic on the manufacture and properties of a hydrogen sensor. In order to reach the nanoscale in the synthesis of ceramic particles, a tubular reactor heated by electrical resistance was simulated with SolidWorks software. The final design obtained from the simulations resulted to be inconvenient due to technical factors related to its construction and operation, so the system was discarded. As an alternative, a Flame Spray Pyrolysis system was developed. All the components of this system were purchased. Gas, combustion and drainage control systems tested. Future work is required to finish the particle extraction and filtering system, as well as experimentation with the flame synthesis process.
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Director Colominas Fuster, Sergi |
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Degree IQS SM - Master’s Degree in Chemical Engineering |
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Date 2020-07-15
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