姜楠

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副教授

博士生导师

硕士生导师

性别:女

毕业院校:大连理工大学

学位:博士

所在单位:电气工程学院

学科:电工理论与新技术. 环境工程. 高电压与绝缘技术

办公地点:静电与特种电源研究所303

联系方式:jiangnan@dlut.edu.cn

电子邮箱:jiangnan@dlut.edu.cn

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An improved corona discharge ignited by oxide cathodes with high secondary electron emission for toluene degradation

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论文类型:期刊论文

发表时间:2019-04-15

发表刊物:CHEMICAL ENGINEERING JOURNAL

收录刊物:SCIE

卷号:362

页面范围:339-348

ISSN号:1385-8947

关键字:Corona discharge; Oxide cathode; High secondary electron emission; VOCs degradation

摘要:An improved corona discharge ignited by oxide cathodes (MgO/NiO/Ni cathode and NiO/Ni cathode) with high secondary electron emission is proposed for toluene degradation. The overall aim of this investigation is to explore the discharge characteristics and toluene degradation performance with oxide cathodes. Current-voltage characteristics results show that discharge currents with MgO/NiO/Ni cathode and NiO/Ni cathode are 2.6-17.4 times (applied voltage of 10.5-13.0 kV) and 1.2-13.5 times (applied voltage of 11.5-14.0 kV) larger, respectively, than the one with Ni cathode. Besides, from the discharge images and optical analysis, the ionization and excitation processes also take place around the oxide cathodes surface, except for the normal corona discharge around the discharge electrode (wires). Moreover, discharges with oxide cathodes exhibit remarkably better toluene degradation, mineralization, and energy performance than the one with Ni cathode. The toluene degradation efficiency, CO2 selectivity, and energy yield in the discharge with MgO/NiO/Ni cathode (P = 5.2 W) are 36.2%, 15.3%, 0.39 g.kWh(-1) higher, respectively, than with Ni cathode (P = 6.2 W), and they are 19.4%, 7.9%, 0.15 g.kWh(-1) higher, respectively, with NiO/Ni cathode (P = 5.5 W). It is believed that abundant secondary electrons emitted from oxide cathodes, which are induced by the intense electric field within the oxide layers caused by positive charges accumulated on the oxide layer surface, resulting the remarkable increase of discharge current. Besides, the emitted electrons cause extra gas discharge on the oxide layer surface, increasing the number and spatial distribution of electrons/reactive species in the whole discharge gap for good toluene degradation performance.