Download This PaperDiscovery of a Novel Binary Azeotrope with Positive Synergistic Insulation Strength as Eco-Friendly Sf6-Alternative
41 Pages Posted: 8 Feb 2024
Abstract
ABSTRACT. With the energy sector having a greater carbon impact than every other industry combined, the urgent need for decarbonization to combat climate change cannot be overstated. Sulfur hexafluoride (SF6), as the arc extinguishing and insulating medium, is broadly applied in power equipment. While it is very essential to find an environmentally friendly substitute gas for SF6 due to its strong greenhouse effect. Efforts are underway to bring Zero carbon closer. Although there are many potential alternatives, most have relatively high boiling points that cannot meet the minimum operating temperature of the power equipment. In the past, the liquefaction temperature of the mixture was reduced by mixing with buffer gases, such as CO2, N2, or dry air. But this method cannot take the insulation performance requirements of eco-friendly insulating gas into account. Therefore, given the current problems and challenges, a novel approach is presented to exploring new eco-friendly gases by incorporating the azeotropic theory. Achieving decarbonization while ensuring reliability, and the liquefaction temperature of the gas mixture can be reduced simultaneously while the insulation strength is increased. In this approach, a theoretical prediction model E-PPR78 was introduced to predict the vapor-liquid equilibrium data and RC318 was found to exhibit azeotrope behavior with HFO-1336mzz(E) at 17%, while GWP is also much lower than SF6. Furthermore, the predicted VLE data obtained through "cycle analysis" were validated against experimental and literature results, affirming the efficacy of the proposed model. Subsequently, to assess its insulation performance, breakdown tests were conducted under both AC and lightning impulse voltages, revealing significant positive synergistic effects in the gas mixture. The possible mechanisms of this positive synergistic effect were also discussed. This study offers an innovative way of tackling high boiling point issues plaguing eco-friendly gases. The findings may also enlighten the design of eco-friendly switchgear that utilizes HFO-1336mzz(E) mixtures to replace traditional SF6 gases making a greener grid achievable. This approach is sustainability-oriented in design to deliver a superior environmental performance compared to conventional solutions.
Keywords: decarbonization, ENVIRONMENTALLY FRIENDLY INSULATING GAS, SF6-ALTERNATIVE, AZEOTROPIC SYSTEM, GROUP CONTRIBUTION METHOD, DIELECTRIC STRENGTH
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