Flow field analysis of cigarette filter through micro-CT-based geometries and CFD simulation

Yunfei Song; Zixuan Liu; Zhiwei Sun; Wen Du; Zhiguo Wang; Zhigang Hu; Ming Ma; Zhiyong Wang

doi:10.1016/j.heliyon.2024.e29253

Flow field analysis of cigarette filter through micro-CT-based geometries and CFD simulation

Heliyon. 2024 Apr 4;10(8):e29253. doi: 10.1016/j.heliyon.2024.e29253. eCollection 2024 Apr 30.

Authors

Yunfei Song¹, Zixuan Liu², Zhiwei Sun³, Wen Du³, Zhiguo Wang³, Zhigang Hu², Ming Ma², Zhiyong Wang²

Affiliations

¹ The Institute of Technological Sciences, Wuhan University, Wuhan, 430072, China.
² School of Mechanical Engineering, Wuhan Polytechnical University, Wuhan, 430048, China.
³ Technology Center of China Tobacco Hunan Industrial Co., Ltd., Changsha, 410007, China.

Abstract

The cigarette filter is an essential component of modern cigarettes and studying the flow distribution within the cigarette filter is of great significance in reducing the harm of cigarettes and optimizing smoking sensations. As the object of numerical simulation research, a three-dimensional model of the cigarette was accurately constructed through micro-CT reverse engineering, achieving a scanning accuracy of 4.05 μm. An overall porous media model of the cigarette filter was established to characterize the pressure distribution inside the filter. Based on the three-dimensional reconstruction, a local simulation model of the cavity-filtered filter was created by extracting a 1/36 geometric model. The simulation results of the overall porous media model of the cigarette filter were used as the pressure boundary conditions for the local simulation model of the cavity-filtered filter, and the effects of the wrapped paper and cavity on the flow field were analyzed. The results show that the simulated pressure drop in the overall porous media model of the cigarette filter had a deviation of less than 3.5% compared to the experimental results. This suggests that the porous media model can effectively predict the changes in pressure drop within the filter. When both wrapped paper and cavity were present, the velocity at the interface between acetate fiber and wrapped paper increased by 141.54%, while the pressure approached 0 Pa. Similarly, at the interface between acetate fiber and cavity, the velocity increased by 130.77%. It indicates that both wrapped paper and cavity significantly influenced the flow field characteristics within the cigarette filter. Additionally, as the porosity of the wrapped paper gradually increased from 0.69 to 0.99 in the radial direction, the fluid velocity increased by 14.46%, while the fluid pressure decreased by 29.09%. These changes were particularly evident when the porosity was below 0.87.

Keywords: Cigarette filter; Computational fluid dynamics; Flue gas; Micro-CT reverse engineering; Porous media; Wrapped paper.