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Silicon Tetrachloride as innovative working fluid for high temperature Rankine cycles: Thermal Stability, material compatibility, and energy analysis

Michele Doninelli, Gioele Di Marcoberardino, Paolo Iora, Marcello Gelfi, Costante Mario Invernizzi, Giampaolo Manzolini

2024Applied Thermal Engineering21 citationsDOIOpen Access PDF

Abstract

Silicon Tetrachloride (SiCl4) is proposed as a new potential working fluid for high-temperature Rankine Cycles. The capability to overcome the actual thermal stability limit of fluids commercially employed in the state-of-the-art Organic Rankine Cycles (ORC) is demonstrated by static thermal stability and material compatibility tests. Experimental static test proves its thermo-chemical stability with a conventional stainless-steel alloy (AISI 316L) up to 650 °C. A preliminary material compatibility analysis performed with optical microscope on the AISI 316L cylinder, after exposure of 300 h to SiCl4 at temperature higher than 550 °C, confirms the potentiality of this fluid when coupled with high-grade heat sources. A thermodynamic analysis has been carried out accounting for the effect of operating conditions on the axial turbine efficiency. A comparison with fluids adopted in medium–high temperature ORCs is performed, evidencing that the proposed fluid could achieve more than + 10 % points as thermal efficiency gain compared to any commercial solutions when coupled with high-temperature sources such as solar, biomass, waste heat from industrial processes and prime movers. A 2 MW SiCl4 cycle operating full-electric at 550 °C reaches a thermal efficiency of 38 %, exceeding values attainable by any other working fluid under similar conditions and power size.

Topics & Concepts

Compatibility (geochemistry)Degree RankineWorking fluidMaterials scienceSilicon tetrachlorideThermal stabilityMechanical engineeringRankine cycleThermalNuclear engineeringSiliconPetroleum engineeringThermodynamicsMechanicsWaste managementEngineeringProcess engineeringComposite materialChemical engineeringMetallurgyPhysicsPower (physics)Phase Equilibria and ThermodynamicsThermodynamic and Exergetic Analyses of Power and Cooling SystemsRefrigeration and Air Conditioning Technologies