LI JIE

Professor   Supervisor of Doctorate Candidates   Supervisor of Master's Candidates

Gender:Male

Alma Mater:大连理工大学

Degree:Doctoral Degree

School/Department:电气工程学院

Discipline:Environmental Engineering. Theory and New Technology of Electrical Engineering. High Voltage and Insulation Technology

Business Address:大连理工大学电气工程学院静电所


Paper Publications

High-Efficiency Removal of NOx From Flue Gas by Multitooth Wheel-Cylinder Corona Discharge Plasma Facilitated Selective Catalytic Reduction Process

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Indexed by:期刊论文

Date of Publication:2016-11-01

Journal:1st Sino-German Symposium on Atmospheric Pressure Gas Discharges and Plasma Applications

Included Journals:SCIE、EI、CPCI-S、Scopus

Volume:44

Issue:11,SI

Page Number:2738-2744

ISSN No.:0093-3813

Key Words:Corona discharge plasma; NOx removal; plasma-assisted selective catalytic reduction (SCR); V2O5-WO3/TiO2 catalyst

Abstract:In this paper, a plasma-assisted selective catalytic reduction (SCR) process was employed for the conversion of nitrogen oxides (NOx) from flue gas to nitrogen (N-2) and water (H2O) using V2O5-WO3/TiO2 catalyst over a broad reaction temperature (125 degrees C-550 degrees C) range. Ammonia (NH3) was used as a reducing agent, and nonthermal plasma was generated in a multitooth wheel-cylinder corona discharge reactor driven by a dc power supply. In order to optimize the geometry of the corona discharge reactor, the discharge power and the NO oxidation efficiency were compared for different discharge gaps and sawtooth slice numbers of the multitooth wheel electrode, respectively. The effects of reaction temperature, water vapor, and SO2 concentration on the plasma facilitated SCR of NOx were also investigated. The experimental results showed that shorter discharge gap (11 mm) appeared to be more advantageous with respect to NO oxidation. NO oxidation efficiency was less affected by sawtooth slice number. The plasma-assisted SCR process enhanced the catalytic activity of SCR catalyst and exhibited a remarkable improvement in NOx removal efficiency at a temperature range of 125 degrees C-300 degrees C. The presence of water vapor in plasma-assisted SCR process significantly improved the NOx removal, especially at low temperature. The addition of SO2 suppressed the NOx removal in plasma-assisted SCR process; however, the NOx removal was greatly promoted by the presence of SO2 and H2O, indicating that water vapor can significantly ameliorate the SO2 inhibiting effect in the plasma-assisted SCR process.

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