Equivalence between <scp>C5F10O</scp> Addition and <scp>PTFE</scp> Vapor Contamination in the Particle Composition and Critical Electric Field Strength of High‐Temperature <scp>CO2</scp>/<scp>O2</scp> Gas Mixture

Tsusaka, Akihiro; Kurahashi, Jun; Yokoi, Toshiya; Matsumura, Toshiro; Nanahara, Toshiya; Yukita, Kazuto; Goto, Yasuyuki; Yokomizu, Yasunobu

doi:10.1002/tee.23797

IEEJ Transactions Elec Engng

2023

DOI: 10.1002/tee.23797

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Equivalence between C₅F₁₀O Addition and PTFE Vapor Contamination in the Particle Composition and Critical Electric Field Strength of High‐Temperature CO₂/O₂ Gas Mixture

Akihiro Tsusaka

Jun Kurahashi

Toshiya Yokoi

et al.

Abstract: SF6 has been introduced as an insulating and extinguishing gas in gas circuit breakers. However, its global warming potential is significantly high at approximately 25 200. Therefore, development of alternative gases is essential. We have been investigating the dielectric breakdown characteristics of high temperature CO2 gas contaminated by various gases. This study discusses the equivalent condition between high temperature CO2/O2/C5F10O gas mixture and CO2/O2 gas mixture contaminated with PTFE (C2F4) vapor… Show more

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2024

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The decomposition pathways of C4F7N/CO2/O2 mixtures in the PTFE vapors

Liu,

Li,

Geng

et al. 2024

AIP Advances

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The C4F7N/CO2/O2 mixtures have better arc-extinguishing performance compared to the C4F7N/CO2 mixtures, and they have a broader application prospect as a substitute for SF6 in high-voltage circuit breakers and gas insulated substation pipelines. Under high-temperature conditions, the polytetrafluoroethylene (PTFE) vapor produced by insulating materials can affect the decomposition path of the C4F7N/CO2/O2 mixed gas, thereby impacting the arc-extinguishing performance of the mixed gas. This paper conducts quantum chemical calculations based on density functional theory to study the decomposition mechanism of the C4F7N/CO2/O2 mixed gas under the influence of PTFE vapor. This study optimizes the structure of reactants and intermediates and evaluates the energy of molecules using the Gaussian-4 theoretical method. By analyzing the potential energy of the decomposition paths that the C4F7N/CO2/O2 mixed gas may undergo under PTFE vapor, the final decomposition path of the mixed gas under PTFE vapor is obtained. This research can provide a reference for the development of environmentally friendly gases in the study of high-voltage circuit breakers.

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The decomposition pathways of C4F7N/CO2/O2 mixtures in the PTFE vapors

Liu,

Li,

Geng

et al. 2024

AIP Advances

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show abstract

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Equivalence between C₅F₁₀O Addition and PTFE Vapor Contamination in the Particle Composition and Critical Electric Field Strength of High‐Temperature CO₂/O₂ Gas Mixture

Cited by 1 publication

References 13 publications

The decomposition pathways of C4F7N/CO2/O2 mixtures in the PTFE vapors

The decomposition pathways of C4F7N/CO2/O2 mixtures in the PTFE vapors

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Equivalence between C5F10O Addition and PTFE Vapor Contamination in the Particle Composition and Critical Electric Field Strength of High‐Temperature CO2/O2 Gas Mixture

Cited by 1 publication

References 13 publications

The decomposition pathways of C4F7N/CO2/O2 mixtures in the PTFE vapors

The decomposition pathways of C4F7N/CO2/O2 mixtures in the PTFE vapors

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Equivalence between C₅F₁₀O Addition and PTFE Vapor Contamination in the Particle Composition and Critical Electric Field Strength of High‐Temperature CO₂/O₂ Gas Mixture