Fine particulate matter (PM2.5) is a critical and imperative problem in Asia. It has been classified as the 1A carcinogen by The United Nations International Agency for Research on Cancer (IARC). According to the latest TEDS 9.0 (Taiwan Emission Data System 9.0), it shows that oil mist emissions from restaurants account for 6.39% of the total PM2.5 emissions in 2013. This ratio is even higher than power supply industries that only contributes 3.64％ of total emission. For housewives who do not smoke in Taiwan, their risk to develop lung cancer can increase by 3.2% to 12.2% through a long term exposure of oil mist at high temperature. Therefore, an effectively control to oil mist emissions is a very important task nowadays However, common commercial fiber-based filters can be quickly masked by oil mist and are needed to be replaced frequently. In order to prolong the lifetime of the fiber filter, an inertial impactor plate and stainless steel mesh filter are used in this paper. They are less likely to clog when filtering oil mist and oils can be directed for collection by design of oil trenches. Furthermore, a high voltage stainless steel mesh array with a high electric field are also introduced to collect charged particles in the air for long term usage. For the impactor developed in this study, liquid channels are designed in the inertial impactor plate, and the filtered oil droplets are collected and drained in the channel. At the flow rate of 45 cm/s, the oil mist with aerodynamic diameter larger than 6 μm can be filtered. For the particles smaller than aerodynamic diameter of 6 μm can be captured by the multi-layered high-voltage electrostatic mesh filter. A high electric field is applied to the multi-layered mesh filter for improving filtration efficiency. Parameters include the electric field, the number of filter layers, the filtration flow rate and the filter structure. Finally, we developed a 27-layer 100-mesh stainless steel filter driven under 1.4 kV/mm electric field with the optimal performance. At a filtration flow rate of 15 cm/s, the filtration efficiency of particles with particle size larger than 50 nm is above 50%, and the filtration of particles with particle size larger than 120 nm reached 70%. This method provides means to reduce the oil mist loading on the back fiber filter and prolong its lifetime for long term usage.