脉冲电弧下 CF3I 和 CO2 环保型绝缘气体混合物的电弧淬火性能仿真分析

IF 1.2 Q4 COMPUTER SCIENCE, INFORMATION SYSTEMS Journal of Electrical and Computer Engineering Pub Date : 2024-05-18 DOI:10.1155/2024/8604095
Dong Wu, Wengui Chen, Zelin Ji
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引用次数: 0

摘要

由于具有优异的绝缘性能,SF6 气体被广泛应用于电力行业。然而,由于 SF6 气体的环保性能较差,在追求绿色电力的背景下,寻找生态上可接受的绝缘气体已成为电力行业面临的严峻挑战。本研究模拟了 CF3I 和 CO2 混合气体的熄弧性能,这种混合气体被认为是 SF6 气体的可行替代品。根据磁流体力学(MHD)理论的概念,利用 COMSOL 软件建立了单管熄弧室的二维模型。通过对单管熄弧室中的纯 CO2 气体、含 10% CF3I 和 90% CO2 的混合气体以及含 30% CF3I 和 70% CO2 的混合气体施加电刺激,产生雷电脉冲电流。结果表明,在电弧形成的第一阶段,含 10% 和 30% CF3I 的 CF3I/CO2 混合气体的导电率低于纯 CO2 气体。该观测采用了幅值为 4 kA 的 8/20 μs 雷电脉冲电流波形。纯 CO2 的最高气流速度为 1744 m/s,但 10%/90% CF3I/CO2 混合物的最高气流速度为 1593 m/s。30%/70% CF3I/CO2 混合物的最高气流速度为 1840 米/秒。当混合气体中的 CF3I 浓度较高时,气流速度会增加,熄弧室中的过压时间也会延长。因此,这些因素大大缩短了灭弧时间。当混合气体中的 CF3I 气体量增加时,熄弧室的过压时间也会延长,从而增加气流速度。因此,这些因素都会大大缩短熄弧时间。
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Simulation Analysis of Arc-Quenching Performance of Eco-Friendly Insulating Gas Mixture of CF3I and CO2 under Impulse Arc
Due to its superior insulating qualities, SF6 gas is extensively used in the power sector. However, because of its poor environmental protection properties, finding ecologically acceptable insulating gas has become a critical challenge in the power sector in the context of pursuing green electricity. This work simulates the arc-quenching performance of a gas mixture of CF3I and CO2, which is thought to be a workable substitute for SF6 gas. The COMSOL software is used to build a two-dimensional model of a single-pipe arc-quenching chamber based on the concepts of magnetohydrodynamics (MHD) theory. The lightning impulse current is made by applying electrical stimulation to pure CO2 gas, gas mixtures with 10% CF3I and 90% CO2, and gas mixtures with 30% CF3I and 70% CO2 in the single-pipe arc-quenching chamber. During the first stage of arc formation, the results show that CF3I/CO2 gas mixtures with 10% and 30% CF3I have lower electrical conductivity than pure CO2 gas. An 8/20 μs lightning impulse current waveform with a magnitude of 4 kA is used for this observation. The highest airflow velocity for pure CO2 is 1744 m/s, but the mixture of 10%/90% CF3I/CO2 has a maximum airflow velocity of 1593 m/s. The 30%/70% CF3I/CO2 mixture has the highest maximum airflow velocity at 1840 m/s. Airflow velocity increases and the overpressure in the arc-quenching chamber is prolonged when there is a greater concentration of CF3I gas in the gas mixture. Consequently, these factors greatly reduce the duration of the arc-extinguishing time. The arc-quenching chamber’s overpressure is extended when the amount of CF3I gas in the gas mixture is increased, which increases the velocity of the airflow. As a result, these factors significantly decrease the duration of the arc-extinguishing time.
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来源期刊
Journal of Electrical and Computer Engineering
Journal of Electrical and Computer Engineering COMPUTER SCIENCE, INFORMATION SYSTEMS-
CiteScore
4.20
自引率
0.00%
发文量
152
审稿时长
19 weeks
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