Aerosol Formation and Transfer in Open- and Closed-Ended Heated Tobacco Products

Author:

Li Bin1,Sun Yue1,Fu Lili1,Feng Lulu1,Lei Ping2,Liu Chuan1,Han Jingmei2,Shang Shanzhai2,Wang Shuang1,Wang Le1,Pan Yonghua2,Zhang Qi1,Guo Zhongya1,Huang Feng1,Zhang Mingjian1,Tang Jianguo1,Wang Bing1,Zhang Ke1

Affiliation:

1. Zhengzhou Tobacco Research Institute of CNTC , Zhengzhou , China

2. China Tobacco Yunnan Industrial Co., Ltd. , Kunming , , China

Abstract

Summary A lit cigarette forms a positive and negative pressure zone by a puff with respect to the position of its paper burn line. Smoke aerosols generated from the two zones are then pulled through the rod under the puff to form the mainstream smoke. This phenomenon is fundamental to the thermophysics and the resultant chemical composition of the mainstream smoke. In this study, we created two different airflow pathways inside a heated tobacco rod by a puff, and investigated the differences in aerosol formation and its chemical compositions. The two different pressure-induced conditions, one through an open-ended tobacco rod (marked as HNB, a label of a designed airflow pathway of commercial heated tobacco products called heat-not-burn prior), and the other through a closed-ended tobacco rod (marked as NSC, a label of a novel-designed airflow pathway of heated tobacco products), were compared for their aerosol collected mass (ACM), the contents of nicotine, water and added aerosol agents such as propylene glycol (PG) and glycerol (VG), as well as selected aldehydes and ketones in the mainstream aerosol. Aerosol particle distribution and the heated temperature along different rod locations were also compared during a puff. The results indicated marked differences in the aerosol formation processes between the two HNB and NSC systems. The transfer ratios of the main aerosol components were significantly higher for the NSC; the levels of formaldehyde and acetaldehyde were significantly lower under the NSC than the HNB condition. There were also significant differences for the aerosol particle number concentration (APNC) and count median diameter (CMD) for the two systems. The lack of convective heat transfer in the aerosol formation under the NSC condition resulted in a relatively stable thermal aerosol generation zone, reflected by the temperature difference between the two systems in the selected locations. The NSC mode of tobacco heating thus offers a novel and enhanced aerosol generation for heat tobacco product designs.

Publisher

Walter de Gruyter GmbH

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