TY  - JOUR
T1  - Particulate emission control for diesel engine by surface discharge electrostatic reactor
A1  - Fukui, Kento
A1  - Kawakami, Kohei
A1  - Madhukar, Apeksha
A1  - Kuroki, Tomoyuki
A1  - Yamasaki, Haruhiko
A1  - Okubo, Masaaki
Y1  - 2025///
KW  - Diesel Engine
KW  - plasma
KW  - NOx
KW  - PM
KW  - HC
KW  - simultaneous removal
JF  - International Journal of Plasma Environmental Science and Technology
VL  - 19
IS  - 1
SP  - e01007
EP  - e01007
DO  - https://doi.org/10.34343/ijpest.2025.19.e01007
UR  - http://ijpest.com/Contents/19/1/e01007.html
N2  - Diesel engines have better fuel economy and emit less CO2 than gasoline engines. However, because their exhaust gas contains large amounts of nitrogen oxides (NOx), particulate matter (PM), and hydrocarbons (HC), aftertreatment is necessary. We use a new plasma aftertreatment method to remove PM in the exhaust gas. Particle concentrations are measured before and after plasma treatment using a scanning mobility particle sizer (SMPS) and a laser particle counter (LPC). The engine load is set to 0%, 24%, 48%, and 72% using electric heaters. The exhaust gas is diluted with N2 + O2 mixed gas (O2 concentration 13%), and the mixed gas flow rate is adjusted to 5, 10, and 15 L min-1. The input power of the reactor is adjusted to 100, 200, 300, and 400 W. PM removal performance is measured, and the removal efficiency is 83% or more under all conditions. At flow rates of 5 and 10 L min-1, a removal efficiency of 95% or more is obtained. At a flow rate of 15 L min-1, 48% load, and input power of 100W, a removal efficiency of 95% or more is obtained. At a flow rate of 15 L min-1, the removal efficiency decreases under several conditions. Under these conditions, the residence time is short due to the high flow rate. It is also considered that sufficient removal is not achieved due to the large number of particles before treatment and the low discharge power. The increase in small particles reduces the removal efficiency in the small particle size range. Since previous studies have achieved high removal efficiencies of 67% NOx and 76% HC using equipment and conditions similar to those of this device, we believe that this surface discharge electrostatic reactor can achieve highly efficient simultaneous removal of PM, NOx, and HC.
ER  -